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Google This is a digital copy of a book that was preserved for generations on library shelves before it was carefully scanned by Google as part of a project to make the world's books discoverable online. It has survived long enough for the copyright to expire and the book to enter the public domain. A public domain book is one that was never subject to copyright or whose legal copyright term has expired. Whether a book is in the public domain may vary country to country. Public domain books are our gateways to the past, representing a wealth of history, culture and knowledge that's often difficult to discover. Marks, notations and other marginalia present in the original volume will appear in this file - a reminder of this book's long journey from the publisher to a library and finally to you. Usage guidelines Google is proud to partner with libraries to digitize public domain materials and make them widely accessible. 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About Google Book Search Google's mission is to organize the world's information and to make it universally accessible and useful. Google Book Search helps readers discover the world's books while helping authors and publishers reach new audiences. You can search through the full text of this book on the web athttp://books.google.com/ 412457 AAA away AAAA MOOR 1 SACA MWD D COOO A COOD 2009 MA MAR a SA A am 18 MANAY a "Do <<<<< CCC COOO OM MAA COCO CAC 3 COOO GA mm ACORD $200000 mome @@@@@@@@@@@@@@@@@ NO PASSPORT CASSOO « } CACABO CO mm PROPERTY OF University of Michigan Libraries 1817 ARTES SCIENTIA VERITAS Digitized by Google Digitized by Google APPLETON'S DICTIONARY OF MACHINES, MECHANICS, ENGINE-WORK, AND ENGINEERING. ILLUSTRATED WITH FOUR THOUSAND ENGRAVINGS ON WOOD. IN TWO VOLUMES. VOLUME I. NEW YORK: D. APPLETON & COMPANY, 200 BROADWAY. MDCCC LII. Digitized by Google Engin. Library T 9 ,A67 V.I Entered according to Act of Congress, in the year 1851, By D. APPLETON & COMPANY, 1 the Clerk's Office of the District Court of the United States for the Southern District 11 Now York. Digitized by Google Engineering List 6-18-64 PREFACE. ENCYCLOPEDIAS and Dictionaries of Art have now become so popular, and their ad- vantages so thoroughly tested, that it is entirely unnecessary to usher in the present work by dwelling on the peculiar merits of such publications. Every such work marks the era, or defines the position of the sciences treated, at its time of publication; and, in the lapse of years, is record of a step by which such sciences have advanced, affording material for history rather than practical working examples. On this account the older encyclopæ- dias have become almost useless to the practical man of the present day; but the later the works, the greater their value-provided they are, as they should be, latest records of the progress of science. No work like the one now offered to the public has ever originated here; and of the foreign works republished, none occupy the same ground, or exhibit, in the slightest de- gree, the state of mechanical arts in this country. The Dictionary is intended to be a Dictionary of Machines, Mechanics, Engine-work and Engineering ; to present con- cisely and compendiously the details of valuable machines in actual use, the laws of matter and their application, the construction and proportion of parts of engines and mill-work, together with the most successful and useful examples in engineering. In the progress of nations, it has always been remarked that the more liberal the gov- ernment, the more rapid are the strides and the greater the advance in mechanical and industrial pursuits, and nowhere in history can a more brilliant illustration of this be found than in the progress of our own country rich in natural resources, under a free and beneficent government, industry is encouraged and protected, yet comparatively sparsely populated, the country cannot, to the fullest extent, develop its resources or compete with the overstocked and poorly paid population of the older countries, unless machines are brought to supply the place of manual labor. Without encroaching on the grounds of Free Trade or Protection, it is evident that, to stand on fair ground with our competitors, we must understand the machines and processes employed by them, that these machines must be adapted or improved by us if possible, or new ones invented better to suit our resources and develop them. To show, therefore, the advance of the mechanical arts both here and abroad, to de- fine their exact position at the present time as far as possible, but more particularly in regard to machinery, to make, as it were, a " World Industrial Exhibition" of useful ma- chines, and a record of their application, is the object of the present work. For this purpose the editors have drawn from the publications of all countries distinguished in mechanical pursuits. Care has been taken, in selection, to admit only such as are con- sidered standard and practical. In many cases, credit has been given for these selections at the end of the articles; annexed also, a list of the books is given, from which selections were made. But credit is to be given especially to the Glasgow Engineer's and Machin- ist's Assistant, BOURNE on the Steam-Engine, HOLTZAPFFEL'S Turning and Mechanical Manipulation, Allgemeine Maschinen Encyclopädie, from which very able articles have been drawn. But whilst we have drawn largely from foreign works, we have not been unmindful of our own progress in mechanism and engineering. Many patentees of valuable ma- chines have kindly afforded us drawings and descriptions, among whom we would name Digitized by Google 8 PREFACE. E. B. BIGELOW, Esq., HENRY BURDEN, WM. MASON, G. H. CORLISS, JOHN J. HOWE, and many others. Very many drawings and specifications have been taken from the Patent Office, and descriptions will be found in this work of machines which cannot be seen in operation; as, from a mistaken consideration of the patentees, they are not open to inspection of visitors. We are also under obligations to WM. A. BURKE, of the Lowell Machine Shop, CALEB M. MARVEL, of the Essex Machine Shop, and WM. ELLIS, of the Washington Navy Yard, for drawings and descriptions of machines. In the Engine department, we are under obligations to Mr. COPELAND for the draw- ings and descriptions of the steamer Pacific. In Engineering, we owe much to the liberality of WILLIAM J. MCALPINE, in furnishing us with the description of the Dry Dock at Brooklyn, and the machinery used in its construction, together with the experi- ments made on the strength of the gates. The article GOLD has been furnished by a distinguished metallurgist. The article on METALLURGY is by F. OVERMAN, whose work on Iron stands deservedly high. The original communications have been numerous and valuable, and the publishers have spared neither labor nor expense to make the work what it should be. The illustrations have all been engraved expressly for the work, as large as the page would admit, and sufficiently distinct and in detail to answer for working drawings. The work is intended more directly for the practical and working man, and for those interested in industrial pursuits but to all classes it will be found important and instruc- tive. It will show how far the world has progressed in mechanical science-the science of automatic labor, the science which is destined to raise our country to the most elevated position in the world, to ennoble the mechanic and artisan, and to extend and diffuse knowledge. Among the works from which materials have been selected may be mentioned the following: Annales des Ponts et Chaussées. Bibliothèque des Arts Industriels: (Masson, Paris.) Civil En- gineer and Architect's Journal: (London.) Engineer and Machinist's Assistant: (Blackie, Glasgow.) Publication Industrielle: (Armengaud Ainé, Paris.) Jamieson's Mechanics of Fluids. Treatise on Mechanics: (Poisson.) Allgemeine Bauzeitung mit Abbildungen (Förster, Wien.) Organ für die Fortschritte des Eisenbahnwesens in technischer Beziehung: (Von Waldegg, Wiesbaden.) Glasgow Practical Mechanic. Silliman's Journal. Allgemeine Maschinen-Encyclopädie-Hilsse (Leipzig.) Cotton Manufacture of Great Britain and America contrasted. Holtzapffel's Turning and Mechanical Manipulation. The Steam-Engine: (J. Bourne.) Eisenbahn-Zeitung (Stuttgart.) Tredgold on the Steam-Engine. Dictionnaire des Arts et Manufactures: (Laboulaye, Paris.) Origin and Progress of Steam Navigation: (Woodcroft.) Essai sur l'Industrie des Matières Textiles: (Michel Alcan, Paris.) Griers' Mechanic's Pocket Dictionary. Templeton's Millwrights and Engineer's Pocket Companion. Marine Steam-Engine: (Brown.) Weisbach's Mechanics and Engineering. Barlow on Strength of Materials. Hann's Mechanics. Mechanical Principles of Engineering and Architecture: (Mosely.) Journal of the Franklin Institute. The Transactions of the Institute of Civil Engineers: (London.) The Artisan. Quarterly Papers on Engineering (Published by Weale, London.) Imperial Dictionary -Blackie: (Glasgow.) Professional Papers of the Corps of Royal Engineers. Student's Guide to the Locomotive-Engine. Railway Engine and Carriage-Wheels: (Barlow, London.) Recueil des Machines Instrumens et Appareils: (Le Blanc, Paris.) Buchanan on Mill-Work. Practical Examples of Modern Tools and Machines: (G. Rennie.) Repertoire de l'Industrie Française et Etrangère: (L. Mathias, Paris.) Treatise on the Manufacture of Gas: (Cleg, London.) Hodge on the Steam-Engine. Scien- tific American. Railroad Journal: (New York.) American Artisan. Mechanics' Magazine (London.) Nicholson's (Peter) Dictionary of Architecture. Dictionnaire de Marine a Voiles et à Vapeur: (De Bonnefoux, Paris.) Conway and Menai Tubular Bridges: (Fairbairn.) Brees' Railway Practice. Bar- low's Mathematical Dictionary. Bowditch's Navigation. Gregory's Mathematics for Practical Men. Engineers' and Mechanics' Encyclopeedia (Luke Herbert.) Patent Journal: (London.) Brees' Glos sary of Engineering. Encyclopedia of Civil Engineering: (Cresy.) Craddock's Lectures on the Steam- Engine. Assistant Engineer's Railway Guide: (Haskoll.) Mechanical Principia: (Leonard.) Weale's Mathematical Tables. Digitized by Google A DICTIONARY OF MACHINES, MECHANICS, ENGINE-WORK, AND ENGINEERING. AAM. A measure of liquids among the Dutch, equal 288 pints. ABACUS. An instrument employed by the ancients for facilitating calculations similar to that now frequently employed for teaching children the rudiments of arithmetic, and which is commonly sold in our stationers' shops. It usually consists of twelve parallel wires, fixed in a light rectangular frame each wire carrying 12 beads or balls. There are thus 12 times 12, answering to the common multipli- cation table, all the results of which it demonstrates to the dullest capacity. All the operations of ad- dition or subtraction are likewise performed by it, by merely moving the beads from one side to the other of the frame. By thus smoothing the difficulties of acquiring arithmetical knowledge at the very outset, and rendering it quite obvious and amusing at the same time, the apparatus becomes one of considerable importance in education. Another kind of Abacus consists of a series of parallel wires fixed in a frame like the former. On each wire there are nine little balls; the lowest stand for units, the next above for tens, the next hun- Fig. 1. c Millions Hundreds of Thousands Tens of Thousands Thousands Hundreds Tens Units dreds, and so on up to any number. The frame is divided into two compartments, a and b, by a cross wire at c, which is sufficiently raised above the wires to allow the little balls to slide under it. Suppose the whole 63 balls to be placed in the compartment a, and it be proposed to note the sum of 4,346,072; it is effected by sliding the balls shown in b from their previous situation in a. ABELE See WOODS, varieties of. ABSORBING AND PRODUCTIVE CASCADE an apparatus of great utility and elegance, in- vented by M. Clement. It is known that the absorption or solution of the gases takes place in proportion to the pressure on the absorbing liquid, the extent of surface exposed to the absorbing action, and to the length of time in which it is exposed. If the pressure, however, be very great, the vessels are liable to rupture and it therefore becomes an important object to strengthen the influence of the other two principles just mentioned, which has been obtained in a very eminent degree by the invention of M. Clement. In this apparatus, which is represented in the annexed diagram, the gas has no press- are to sustain, but the surfaces of its contact are exceedingly multiplied and extended. The column a is filled with a great number of small bilbs of glass or porcelain, its lower extremity resting in another cylinder b, of greater diameter, in which is a cavity adapted to the reduced diame- ter of the column, which communicates with two small tubes c, d, the former being employed to introduce the gas, and the latter to discharge the liquid. At e is a reservoir of water, with a con- ducting pipe f, the supply therefrom being regulated by a cock g. The water, in its passage to the lower part of the column, successively moistens all the small spheres, and being thus impeded in its progress, a very considerable time is occupied in its descent. On the other hand, the gas, as it is introduced, occupying all the vacant interstices, becomes infinitely divided and therefore, as it can only pass through the intermediate spaces very slowly, the duration of the contact is much prolonged, and the absorption promoted. The inventor calculates that the absorbing power of this apparatus is 322 times greater than the ordinary simple vessels used for the purpose. Although M. Clement, in making this 2 Digitized by Google 10 ABUTMENT. comparison, has unquestionably selected the most unfavorable case, it must be admitted that his absorbing cascade possesses great advantages. To the apparatus thus de- 2. scribed, M. Clement adapts another, which he calls " the Productive Cascade," shown in combination in our diagram. It is intend- ed to produce gas for a considerable period 7 of time, and in a more convenient and less expensive manner than by the ordinary methods. Suppose, for example, it is re- n quired to prepare oxymuriatic acid or chlo- rine; a large vessel h, provided with four openings, is filled with oxide of manganese, broken into large pieces; the opening i is by a tube connected to a leaden vessel k, containing common salt and sulphuric acid. By the tube l, a small stream of water is made to flow from the reservoir above, which gradually moistens the whole surface of the pieces of manganese, and permits the muriatic acid gas to attack and dissolve it b very easily. The chlorine which is produced passes by the tube n, into the absorbing cascade, while the muriate of manganese is carried off as it forms, by the water, through the tube o, into the reservoir p. By this arrangement, there is no occasion to reduce the manganese to powder, and a much larger quantity may be operated on at the same time, without the operator being under the necessity of frequently renewing the charge of materials, and dismounting his apparatus. ABUTMENT is a term commonly ap- plied by engineers to those fixed parts of me- chanism whence a resisting or reacting force is obtained. See RAILWAY ENGINEERING. ABUTMENTS, block, in course and rubble. See RAILWAY ENGINEERING. ACACIA. See WOODS, varieties of. ACCELERATION is the increase of velocity in a moving body, caused by the continued action of the motive force. When bodies in motion pass through equal spaces in equal times, or, in other words, when the velocity of the body is the same during the period that the body is in motion, it is termed uniform motion, of which we have a familiar instance in the motion of the hands of a clock over the face of it; but a more correct illustration is the revolution of the earth on its axis. In the case of a body moving through unequal spaces in equal times, or with a varying velocity, if the velocity increase with the duration of the motion, it is termed accelerated motion; but if it decrease with the duration of the motion, it is termed retarded motion. A stone thrown up in the air, affords an illustration of both these cases, the motion during the ascent being retarded by the force of gravity, and accelerated by the same during the descent of the stone. All bodies have a tendency to preserve their state, either of rest or of motion; so that if a body were set in motion, and the moving force were withdrawn, the body, if unopposed by any force, would continue to move with the same velocity it had acquired at the instant the moving force was withdrawn. And if a body in motion be acted upon by a constant force, (as the force of gravity,) the motion becomes accelerated, the velocity increasing as the times, and the whole spaces passed through increasing as the square of the times whilst the proportional spaces passed through during equal portions of time, will be as the odd numbers, 1, 3, 5, 7, &c.; and the space passed over in any portion of time will be equal to half the velocity acquired at the end of such time: which results will be better brought to view in the following Table: Times. Velocities. Spaces for each Time. Total Space. 1 1 1 1-12 2 2 3 3+1-4-? 3 3 5 5+3+1-9-3² 4 4 7 7+5+3+1-16-4 It has been ascertained by experiment, that a body falling freely by its own weight from a state of rest, will descend through 16 feet 1 inch in the first second of time, and will have acquired a velocity of 321 feet; but from the rapidity with which the velocity increases, cannot extend the experiment, for in only four seconds a body falling freely would pass through -pace of 256 feet. But by an ingenious contrivance of Mr. Atwood, the laws of motion above laid vn may be verified experiment- ally. The machine is called Atwood's machine," after the name of the inventor; and the principle of its action consists in counteracting a portion of the gravitating power of a body, by the gravitating power of a smaller body; so that the absolute velocity, and the spaces passed through, shall be less than in the case of bodies descending freely, whilst, as the force is constant, the same ratio of progres- sion will hold in both cases. The annexed figure represents one of these machines. a a a is a triangular Digitized by Google ACCELERATIONS. 11 frame upon three moveable legs; b, a small platform suspended from it by a universal joint c c, and supporting two upright standards dd, in which the axis of a light brass wheel e revolves with very little friction. Over a groove in the periphery of the wheel passes a very light and pliable silk thread, from the ends of which hang two equal weights f, g. Into the under side of b is screwed a square rod h, descending to the floor, to which it is secured in a perpendicular position by small pins passing through holes in the claws at ii. On the face of the rod is a scale of inches; k is a brass guide, fixed at the upper part of the rod h, so that when the top of the weight g touches the lower side of k, the under side of g is on a level with 3. the top, or commencement of the scale; l is a small stage, moveable along the rod h, and having a hole in it sufficiently large for the weight g to pass: on one side is a tightening screw m: n is another moveable stage, fitted with a tightening screw o, as also a fork p, turning upon a hinge. The experi- ments are conducted as follows small circular weight is placed upon g, which is pulled up to the top of the scale, and the stage n is screwed to the rod h, on a level with the lower part of the weight f, which is held down upon it by the fork p. Upon releasing f from the fork, the weight g descends with a slow, but gradually accelerated motion, and the number of inches the weight has descended, at each successive beat of a pendulum, (suspended from another triangle,) is observed upon the scale; and if the additional weight be such as to cause g to descend through three inches in the first second, then it will cause it to descend through one foot in two seconds, and through 61 feet in five seconds. If the additional weight be removed, and a small bar of equal weight, but of a length exceeding the diameter of the hole in l, be placed upon g, and the stage l be set at any division of the scale, at which the weight would arrive at the end of any number of seconds, the stage will intercept the bar in its descent, and the weight will continue to descend with the velocity it had acquired upon reaching 1. Thus, if the velocity at the end of the second second be two feet, in which case the weight would have descended one foot in that time, if the stage be set at one foot upon the scale, it will intercept the bar at the end of the second second, and the weight g will move with a uniform velocity of two feet per second, through the remaining portion of its descent. If it is required to illustrate the case of retarded motion, the small circular weight is placed upon the weight g, and a similar small weight upon the weight f, so that g, still out- weighing f, will descend; but as soon as the stage l intercepts the bar with the small weight upon it, f becomes the heaviest, and g will descend with a velocity decreasing as the squares of the times, counted from the time of g passing the stage 1. ACCELERATIONS, composition of. See PHORONOMY. ACCELERATIONS, combination of velocity, and See PHORONOMY ACCIDENTS IN BORING. See RAILWAY ENGINEERING. ACID, carbonic, sulphurous. See NUMERICAL DATA and principal laws of the steam-engine. AERIAL PERSPECTIVE, is that which represents objects diminished in size and weakened in tint in proportion to their distance from the eye; but the term relates principally to the color. AFFINITY, a term used in chemistry to denote that kind of attraction by which the particles of different bodies unite, and form a compound possessing properties distinct from any of the substances which compose it. Thus, when an acid and alkali combine, a new substance is formed, called a salt, perfectly different in its chemical properties from either an acid or an alkali and the tendency which these have to unite, is said to be in consequence of affinity. AFRICAN BLACKWOOD. See WOODS, varieties of. AIR ESCAPE, a simple and ingenious contrivance for letting off the air from water-pipes. If a range of water-pipes be led over a rising ground, it will be found that air will collect in the higher parts and obstruct the progress of the water; to remedy which inconvenience the Air Escape is employed. A hollow vessel is attached to the upper part of the pipe, in the top of which vessel there is fixed a ball cock, adjusted in such a way, that when any air collects in the pipe, it will ascend into the vessel, and by displacing the water, cause the ball to descend, and thus open the cock, when the air is allowed to escape. No water, however, can escape, for when that fluid rises in the vessel above a certain height, the ball rises and shuts the cock; new air then collects, displaces the water, lowers the ball, the cock is opened, and it again escapes. AIR-GUN. A machine in which highly-compressed air is substituted for gunpowder to expel the ball, which will be projected forward with greater or less velocity, according to the state of condensa- tion, and the weight of the body projected. The effect will, therefore, be similar to that of a gun charg with gunpowder, for inflamed gunpowder is nothing more than air very greatly condensed, so that the two forces are exactly timilar. There is this important consideration to be attended to, namely, that the velocities with which balls are impelled are directly proportional to the square root of the forces; so that if the air in an air-gun be condensed only ten times, the velocity will be equal to one-tenth of that arising from gunpowder; if condensed twenty times, the velocity would be one- seventh that of gunpowder, and so on. Air-guns, however, project their balls with a much greater velocity than that assigned above, and for this reason, that, as the reservoir or magazine of condensed air is commonly very large in proportion to the tube which contains the ball, its density is very little altered by passing through that narrow tube, and consequently the ball is urged all the way by nearly the same force as at the first instant; whereas the elastic fluid arising from inflamed gunpowder is but very small indeed in proportion to the tube or barrel of the gun, and therefore, by dilating into a com- Digitized by Google 12 AIR-VALVE. paratively large space as it urges the ball along the barrel, its force is proportionally weakened, and it always acts less and less on the ball in the tube. Hence it happens, that air condensed only ten times into a pretty large receiver, will project its ball with a velocity little inferior to that of gunpowder. Having thus explained the principle of the machine, we shall proceed to describe the construction of one. It consists of a lock, stock, barrel, ramrod, &c., of about the size and weight of a common fowling- piece. Under the lock at b is screwed a hollow copper ball c, perfectly air-tight. This ball is fully charged with condensed air, by means of the syringe B, previous to its being applied to the tube at b. Being charged and screwed on as above stated, if a bullet be rammed down in the barrel, and the trigger a be pulled, the pin in b will, by the spring-work in the lock, forcibly strike out into the ball, and thence by pushing it suddenly, a valve within it will let out a portion of the condensed air, which, rushing through the aperture in the lock, will act forcibly against the ball, impelling it to the distance of 60 or 70 yards, or farther if the air be strongly compressed. At every discharge only a portion of the air escapes from the ball; therefore, by re-cocking the piece 4. another discharge may be made, which may be repeated for a num- c ber of times proportioned to the size of the ball. The air in the copper ball is condensed by the syringe B in the following manner. The ball is screwed quite close on the top of the syringe; at the end of the steel-pointed rod a is a stout ring, through which passes the rod k; upon this rod the feet should be firmly set; then the hands are to h be applied to the two handles i i fixed on the side of the barrel of the syringe, when, by moving the bar- k rel B steadily up and down on the rod a, the ball c will become charged with condensed air, and the progress of condensation may be esti- mated by the increasing difficulty in forcing down the syringe. At the end of the rod k is usually a square hole, that the rod may serve as a key for attaching the ball to either the gun or syringe. In the inside of the ball is fixed a valve and spring, which gives way to the admission of the air, but upon its emission, comes close up to the orifice, shutting out the external air. The piston-rod works air-tight by a collar of leather on it, in the barrel B; it is therefore obvious, that when the barrel is drawn up, the air will rush in at the hole h; when`it is pushed down, it will have no other way to pass from the pressure of the piston but into the ball c at the top. The barrel being drawn up, the operation is repeated, until the condensation is so great as to resist the action of the piston. If air be very suddenly compressed into a small compass, the heat given out is 80 considerable as to be sufficient to ignite inflammable sub- stances. This discovery was made, accidentally, by a French soldier, who, in cleaning his musket with some wadding fastened to the ramrod, found, after thrusting the ramrod suddenly down the piece, that the wadding had ignited. The fact he communicated to the National Institute, and repeated the experi- ment in their presence. This property has been turned to advantage in an apparatus denominated, An Instantaneous Light Machine," constructed in a walking-stick, which consists of a piston accurately fitted and worked in a cylinder, by the sudden stroke of which the volume of air contained in the cylinder becomes so much compressed as to give out sufficient heat to set fire to a piece of the substance termed German tinder. AIR-VALVE, a valve commonly applied to steam-boilers for the purpose of preventing the forma- tion of a vacuum when the steam happens to be condensed within the boiler. The mode of action of these valves is very simple. A valve in the top of the boiler opening inwards, is kept shut by a eoun- terweight at the end of a lever; but whenever the steam in the boiler happens to be condensed, a vacuum is formed, and the air-valve is opened by the pressure of the atmosphere, consequently the air enters and destroys the vacuum. The interior of the boiler being allowed to remain in the state of vacuum, the atmospheric pressure from without might cause its sides to collapse, and thus effect the destruction of the boiler. There have been instances of boilers collapsing even though furnished with an air-valve, but in this case the counterweight must have been too great, or the valve itself too small; an error which we fear is pretty common, and ought to be avoided. AIR-VESSEL, a chamber containing air, attached to pumps and other water-works, the use of which is to make the discharge constant, where the supply of water is intermittent. In the forcing- pump for instance, where the water has to be sent up through a long range of pipes, the discharge from the pump being irregular, the impetus of the water at every stroke would jolt the machinery, which, however, may be prevented by an air-vessel. The ejection-pipe of the pump leads into a cham- ber containing air, and this chamber communicates with the pipes through which the water is to flow, the latter being less in diameter than the former. Now, when water by a stroke of the pump is sent into the air-vessel, the air within it will be compressed, and before the pump has made another injection into this vessel, the air will by its elastic power force the water in a constant stream up the pipes, and thus a continuous stream is kept in the rising main. Air-vessels are with great advantage applied to the suction-end of a pump. AIR LEAKS. how to detect. See DETAILS OF ENGINES. AIR IN MOTION, OR WIND AND WINDMILLS. Pure air consists almost entirely of azote or Digitized by Google AIR IN MOTION. 13 nitrogen, and oxygen gases, with a very small portion of carbonic acid gas. Of 100 parts of air, reckon- ing by weight, 75.55 parts are nitrogen, 23.32 oxygen, and 1.13 carbonic acid and watery vapor. Both as respects weight and bulk, nitrogen forms the chief ingredient of the atmosphere. The weight or pressure of the atmosphere is equal to the weight of a column of water 34 feet in height, or to a column of mercury 30 inches in height, or 14.7 lbs. per square inch at a mean temperature. But air and all kinds of gases are rendered lighter by the application of heat, for then the particles of the mass are repelled from each other or rarefied, and occupy a greater space. Rarefied air, being specifi- cally lightest, mounts above that of common density; hence, change of temperature is the principal cause of winds. Some winds occur from the following cause :-When a condensation of vapor in the atmosphere sud- denly takes place, giving rise to clouds, which speedily fall in rain, the temperature of the surrounding air is sensibly altered, and the colder rushing in upon the warmer, gives rise to a sudden gust of wind. The most remarkable winds are those which traverse the ocean steadily in one direction, and are call- ed trade winds, from their use to mercantile navigation. Their external limits are 30 degrees on each side the equator; but each limit diminishes as the sun advances to the opposite tropic. The force of effect and common appellations given to winds at different velocities are exhibited in the following table :- The impulse of wind increases as the Velocity of the Wind. Force or Pressure square of its velocity; and the force or per Sq. Foot, in Common Appellations of the Miles per Feet per Force of the wind. pressure per square foot, in lbs., as the lbs. Avoirdu- Hour. Second. pois. square of the velocity multiplied by .002288. 1 1.47 .005 Hardly perceptible. Windmills are constructed either 80 2 2.93 .020 that the sails shall move in a horizon- 3 4.40 .044 Just perceptible. tal plane, or in a plane nearly vertical 4 5.87 .079 the former are called horizontal, and 5 7.33 .123 Gentle pleasant wind. the latter vertical windmills. 10 14.67 .492 The sails of a windmill may be sup- 15 22.00 1.107 Pleasant brisk gale. posed to intercept a cylinder of wind; 20 29.34 1.968 and it would seem that when the whole 25 36.67 3.075 Very brisk. cylinder is intercepted, the effect of the 30 44.01 4.429 machine is diminished; hence it is con- 35 51.34 6.027 High winds. cluded, from experiments, that the sails 40 58.68 7.873 should not intercept above fths of the 45 66.01 9.963 Very high. cylinder. 50 73.35 12.300 A storm or tempest. The wind does not act perpendicularly 60 88.02 17.715 A great storm. on the sails of a windmill, but at a cer- 80 117.36 31.490 A hurricane. tain angle; and the sail varies in the degree of its inclination at different dis- tances from the centre of motion, in resemblance to the wing of a bird, and which is termed the weath- ering of the sail. The angles of weathering, as recommended by Smeaton, are as follows :-the radius or whip being divided into 6 equal parts, and the first part from the centre being called 1, the last or end of the sail, 6. Deductions from Smeaton's experiments on Wind- Distance from Angle with the Angle with the mills.-1. The velocity of windmill sails, whether the Centre. Axis. Plane of Motion. unloaded or loaded, so as to produce a maximum, is nearly as the velocity of the wind, their shape and 1 72° 18° position being the same. 2 71 19 2. The load at the maximum is nearly, but some- 3 72 18 what less than, as the square of the velocity of the 4 74 16 wind, the shape and position of sails being the same. 5 773 12} 3. The effects of the same sail at a maximum are 6 83 7 nearly, but somewhat less than, as the cubes of the velocity of the wind. 4. The load of the same sails at the maximum is nearly as the squares, and their effect as the cubes of their number of turns in a given time. 5. When sails are loaded, so as to produce a maximum at a given velocity, and the velocity of the wind increases, the load continuing the same :-1st. The increase of effect, when the increase of the ve- locity of the wind is small, will be nearly as the square of those velocities. 2d. When the velocity of the wind is double, the effects will be nearly as 10: ;-and 3d. When the velocities, compared, are more than double of that where the given load produces a maximum, the effects increase nearly in a simple ratio of the velocity of the wind. 6. In sails of a similar figure and position, the number of turns in a given time will be reciprocally as the radius or length of the sail. 7. The load, at a maximum, that sails of a similar figure and position will overcome, at a given dis- tance from the centre of motion, will be as the cube of the radius. 8. The effects of sails of similar figure and position are as the square of the radius. 9. The velocity of the extremities of Dutch sails, as well as of the enlarged sails, in all their usual positions when unloaded, or even loaded to a maximum, is considerably quicker than the velocity of the wind. General Proposition.-That all planes, however situated, that intercept the same section of the wind, and having the same relative velocity in regard to the wind, when reduced into the same direction, have equal powers to produce mechanical effects. Digitized by Google 14 AIR-PUMP. TABLE, containing Nineteen Sets of Experiments on Windmill Sails, of various Structures, Positions, and Quantities of Surface. Ratio of Ratio of greatest Description of Sail No. made use of. Angle at the extremities. Grentest Angle. Turns of the Sails unloaded. Turns of the Sails at the Maximum. Load at Maxi- mum. Greatest Load. Product. Quantity of greatest Ratio of Surface. Velocity Load to Surface to to the Ve- the Load the Pro- locity at at Maxi- duct. Maxi- mum. mum. Plain sails at an an- Deg. Deg. lbs. lbs. Sq. In. gle of 55° with the 1 35 35 66 42 7.56 12.59 318 404 10:7 10:6 10:7.9 axis Plain salls weather- 2 12 12 70 6.3 7.56 441 404 10:8.3 10:10.1 ed according to the 3 15 15 105 69 6.72 8.12 464 404 10:6.6 10:8.3 10:10.15 common practice. 4 18 18 96 66 7.0 9.81 462 404 10:7 10:7.1 10:10.15 Weathered accord- 5 9 261 66 7.0 462 404 10:11.4 ing to Maclaurin's 6 12 291 701 7.35 518 404 10:12.8 theorem 7 15 321 634 8.3 527 404 10:13. 8 0 15 120 93 4.75 5.31 442 404 10:7.7 10:8.9 10:11. Salls weathered in 9 3 18 120 79 7.0 8.12 553 404 10:6.6 10:8.6 10:13.7 the Dutch manner 10 5 20 78 7.5 8.12 585 404 10:0.2 10:14.5 tried in various 11 7f 221 113 77 8.3 9.81 639 404 10:6.8 10:8.5 10:15.8 positions 12 10 25 108 73 8.69 10.37 634 404 10:6.8 10:8.4 10:15.7 13 12 27 100 66 8.41 10.94 580 404 10:6.6 10:7.7 10:14.4 Sails weathered in 14 71 221 123 75 10.65 12.59 799 505 10:6.1 10.8.5 10:15.8 the Dutch manner, 15 10 25 117 74 11.08 13.69 820 505 10:6.3 10:8.1 10:16.2 but enlarged to- 16 12 27 114 66 12.09 14.23 799 505 10:5.8 10:8.4 10:15.8 wards the extremi- 17 15 30 96 63 12.09 14.78 762 505 10:6.6 10:8.2 10:15.1 ties 8 Sails, being sectors 18 12 22 105 641 16.4 27.87 1059 854 10:6.1 10:5.9 10:12.4 of ellipses in their 19 12 22 99 64g 18.06 1165 1146 10:5.9 10:10.1 best positions AIR-PUMP. This instrument has been much improved in form in recent times, but the principle remains the same; its chief use being to extract the air from a vessel, whereby we are said to exhaust it, or to produce a vacuum. The construction and operation of the Air-pump will be understood by a reference to the cut. This is a sectional view of the common form of the Air-pump. R is a bell-shaped glass, ves- sel, open only at the bottom, and whose rim is ground perfectly flat, so that it may rest on every point, on a brass plate SS, which is likewise ground to a flat surface, so that when a little hog's-lard is rubbed upon the edge of the glass vessel, commonly called the receiver, and then the rim placed, by a kind of circular sliding motion, upon the brass plate, no air can pass in or out of the receiver, between its edge and the plate. Through the centre of the brass plate there is drilled an orifice A, from which orifice there is led a pipe AB, forming a communication between the receiver R and the interior of the cylinder BPV, which communication may be opened or closed by means of a stop-cock at G. The cylinder or barrel BPV is furnished with a piston BP accurately fitted to the cylinder, but capable of free motion up and down, which motion is effected by means of a piston-rod DC, which moves through a stuffed or air-tight collar at D. The bottom of the cylinder or barrel is furnished with a valve V opening outwards. This cylinder communicates with another BXPV, constructed and furnished in a similar manner; and the two piston-rods are provided with racks C at the top, the teeth of which are acted upon by those of a neel placed between them, as may be seen in the figure. Let us now attend to the mode of action. Suppose the stop- 5. cock at G open, and the pistons as they are in the figure. The piston BP being at the top, a free communication is formed between the receiver R and the first cylinder, and the piston Y being pushed down past the orifice at B, the air contained in the cylinder or barrel will be forced into less space or com- C pressed, and of course its elastic force increased. In conse- C R quence of this increased elasticity, the valve at V will be open- ed, and the air expelled. When the piston is lifted. this valve will be shut by the pressure of the atmospheric air without; thus a portion of the air which was contained in the receiver, S A S D D communication pipe, and barrel, has been expelled, and that E which remains will consequently be less dense; another stroke B B P of the piston will diminish the density still more; and this pro- G cess may be continued until the density be 80 diminished, that when compressed by the descent of the piston to the bottom of the barrel, its elastic force is only sufficient to open the valve F P V. It will be easily seen, that the exhaustion of the air in the V V receiver depends on the elasticity of the air; for when the pis- ton descends and expels the air contained within the barrel, which it will do completely, if it go to the bottom, and then in returning, the valve V being shut, a vacuum will be formed in the barrel until the piston in its ascent passes the orifice B, when the air within the receiver will expand and fill the whole Digitized by Google AIR-PUMP. 15 cavity. The operation of the second barrel and piston is precisely similar to that of the first, so that when the one is understood, the other requires no explanation. The degree of exhaustion will depend upon the workmanship of the pump, the number of strokes of the piston, and the relative capacities of the receiver and barrels; but perhaps in no case can the vacuum in the receiver be made perfect. For the purpose of determining the degree of exhaustion, a mercurial gauge is employed, which acts on a similar principle with the common barometer. A glass tube EF, rests in a basin of mercury F, and its upper orifice opens into the brass plate SS. When the exhaustion of the receiver has commenced, the pressure of the air in the receiver must be less than that of the atmosphere without. Wherefore, since the air in the receiver presses the mercury down the tube, and the atmosphere pressing on the mercury in the basin forces it up the tube, with the greater force the mercury will rise in the tube, and it will rise the higher according to the difference of the density, and consequently elastic force of the air in the receiver, and that of the atmosphere. AIR-PUMP, Kennedy's Horizontal Double Cylinder. Any modification of, or improvement in this instrument, is a matter of interest not only to the man whose sole pursuit is science, but to all who are engaged in studying or illustrating the simplest truths of experimental philosophy. It is not a little extraordinary, that while nearly every species of apparatus has been improved by modern ingenuity, the Air-pump retains the form given it by Boyle. Probably all users of the common form have been made sensible of its want . stability and porta- bility. These evils were sorely felt by Mr. Kennedy, while engaged during the winter of 1841 and 1842, in lecturing in the northern part of this country. He determined, if possible, to remove them, and before the close of the season invented, and during the following summer constructed, the subject of this article. He employed it the succeeding winter in his course before the Delaware County Institute of Science, where it attracted much attention. It has been in use more than three years, and having received the unqualified approval of several impartial scientific men, and of one of the best makers of philosophical apparatus in the country, it is now for the first time made public. The objections that obtain against the old form arise chiefly from the upright position of the barrels or cylinders. This necessarily throws the pinion twelve, or more, inches above the point of support. The handle placed on the projecting axis has a constant tendency, while the operator is working the pump, w tilt it outwards; so much so, as frequently during rapid exhaustion, to require the steadying hand of an assistant. This leverage outwards, and the consequent instability, are especially annoying whilst using the barometer gauge. Again, the most eligible height of table for the display of appara- tus, by elevating the handle, renders the work of exhaustion an exceedingly laborious one, and the perpendicular cylinders and pump-head form an inconvenient barrier between the operator and the glass receiver, especially if the experiment is performed on the gauge-plate; a footstool but poorly com- pensates for this height. Finally, the Air-pump, always one of the most expensive items of the labora- tory, is rendered so, to some extent, by the cost of the double rack, pump-head, and brass columns that support it. On each of the points named, the horizontal double cylinder pump is believed to possess great superiority. 6. R S DESCRIPTION.-In the figure, L L represent the barrels, the enlarged ends of which are let into the board and bolted through to ensure stability. There is one rack; the two pistons being attached to its extremities. A portion of the rack is exposed at T. The semi-pinion W, works in cast straps, or gudgeons, attached to the bottom of the board by screws, which, passing through, terminate in the rack guides, one of which is seen above. The forward gudgeon is 80 cast as to receive the end of the clamp which secures the pump to the table. The semi-pinion works upwards through a slot cut in the board, and of course between the rack guides. The upper extremities of the guides are perforated to I sceive rollers, against which the back of the rack may work when necessary. None have yet been required. To the axis of the semi-pinion the handle is attached in the usual manner. The piston may be either solid or valved, and the cylinders may communicate with the plates R and B, in the wav most approved by the maker. In the pump from which the sketch is taken, the pistons are solid. The farther extremities of the cylinders bear female screws, which connect with corresponding male screws on the block. On the posterior portion of each block is cut a female screw; the male of which bears the valve V V, of course opening inwards. On those portions of the blocks which project into the board are cut male screws bearing valves opening outwards. Perforated nuts over these secure the blocks to the board, and the valves against injury. At V V is attached the tube leading from the plates. D is the screw for restoring atmospheric pressure. The general stop-cock S, connects this with Digitized by Google 16 AIR-PUMP. the parellel tube which, bearing the gauge-cock S', forms at pleasure a communication between the plates. The original of the figure both exhausts and condenses. The remaining letters refer to the parts used in condensing. This is effected by simply connecting, by means of tubes under the board, the valves F', F, with a third tube passing upward to the stop-cock K. Then the air drawn in at R, will be condensed in a receiver screwed on C. Those familiar with Pneumatic chemistry need not be told of the facilities thus afforded for the transfer of gases. The condensing gauge is borne by the screw G. To the working philosopher, it is unnecessary to amplify the advantages that result from lowering the centre of motion to a level with the points of support, bringing both plates directly under the operator's eye, and pre- senting, at about the cost of an ordinary exhausting pump, an instrument furnished with all the facilities for exhaustion, transfer, and condensation, without any shifting of parts-Philad, Dec. 1845. AIR-PUMP, rules respecting,-diameter of,-rules for part of,-valves of,-canvas valves for,-side valves for,-metallic packing for,-indicator applied to. See DIMENSIONS OF ENGINES, and MANUFACTURE and MANAGEMENT OF ENGINES. AIR-PUMP CROSS-HEAD, table of sizes of. See DIMENSIONS OF ENGINES. AIR-PUMP ROD, table of sizes of,-rules for strength of. See DIMENSIONS OF ENGINES-Materials for. See DETAILS OF ENGINES. AIR-PUMP SIDE RODS, table of sizes of,-rules respecting passages,--area of. See DIMENSIONS OF ENGINES. AIR-PIPES, an invention for clearing the holds of ships and other close places of their foul air. The contrivance is simply this: a long tube, open at both ends, is placed with one end opening into the apartment to be ventilated, and the other out of it. The air in the outer end of the tube is rarefied by heat, and the dense air from the hold comes in to supply the partial vacuum, the escape of the foul air in the hold being supplied by fresh air introduced through an opening above; and this process is carried on until the air becomes everywhere equally elastic. AJUTAGE, a tube fitted to the mouth of a vessel for the purpose of modifying the discharge of water. ALARM-Fire Damp. At the Academic des Sciences, at Paris, M. Chuart's invention was explained it consists of a ball or globe, contained in a chemical solution highly sensitive to any deterioration of the atmosphere, and acting upon a lever, which sets an index in motion, and thus shows the vitiated state of the atmosphere, whether in a mine or elsewhere, long before the common air can be so saturated with gas as to explode on the application of light. M. Chuart has added to his invention an alarum- bell, which is struck by the lever when the ball is thrown off its equilibrium by the vitiated state of the atmosphere. Since M. Chuart first exhibited his apparatus he has made a great improvement. His ball was originally of glass, which was not only too heavy, but also liable to breakage. He now makes it of copper, so very thin that its weight is almost nominal, and yet it is perfect in every part. It is stated that he arrived at this perfection by means of the galvanic process, which gives a thinner substance than any mechanical means could effect consistently with the compactness that is required for the certain operation of the apparatus. 1845. ALARM-WHISTLE The object of this instru- ment is to prevent injury to boilers from the water 7. falling below its proper level. A is a float attached to a stem or rod, which H D passes upwards through a tube, B¹, and a diaphragm, B², fixed within that tube, and terminates in a conical top, which fits into the hollow pipe C, of the steam-whistle D. The lower end of the whistle a a D is passed through an orifice in the top of the boiler, (indicated by the letters a a,) and screwed into the top of the tube, which is thus kept steady, E if in a vertical position. E is a collar attached to K K the stem of the float, near the top, which, catching B against the plate B², on the fall of the stem or rod A, prevents it from descending further. When the water falls below the safety-line, and the float along with it, the descent of the stem of the float opens the pipe C of the whistle, and allows the steam to escape, which, impinging against the bell H at top, B produces the alarm required. KK are orifices in the side of the tube to facilitate the rushing of the steam into the whistle, as soon as the boiler is in danger. ALDER. See Woods, varieties of. ALLOYS. See METALS and ALLOYS. ALLUVIAL DEPOSITES. See RAILWAY EN- GINEERING. ALMOND-TREE See WOODS, varieties of. A ALOES-WOOD. See WOODS, varieties of. AMBOYNA-WOOD. See WOODS, varieties of. AMERICAN STEAM EXCAVATING MA- CHINE. This machine, which is the invention of the late Mr. Ottis, of New York, is an application of steam-power to the purposes of excavation and is edging; and for the former purpose, appears Digitized by Google AMERICAN STEAM EXCAVATING MACHINE. 17 12. 11. o "OT S F 13. R tot 9. c g SCALE.-16 feet-3 inches. greatly superior to any thing which has hitherto been achieved in excavating machinery. The ac- companying engraving presents the principal side elevation (Fig. 8) of the machine, which brings all the working parts sufficiently into view; Fig. 9, a plan of the horse-shoe pulley and crane top. the 3 Digitized by Google 18 ANACLASTICS. dotted lines show the position of the lower framing or stage and boiler; Fig. 10, shows the crunk shaft and gearing; Fig. 11, the main drum; Fig. 12, the main drum for working the excavator; and Fig. 13, a plan of the excavator. The whole of the details of this machine, which are very elaborate and complete, of course cannot be attempted in an article of this nature; we will, however, describe as much of the details and its principal feature as are necessary to a proper understanding of the several movements of the machine, and then describe each of those movements separately. The machine consists of a strong horizontal wooden framing or stage A, mounted upon two pairs of railway wheels b, for locomotion, which run on temporary rails, laid down as may be required; on the one end of the stage is fixed a cylindrical boiler C, and the gearing for turning the crane round. In the middle is placed the gearing for working one of the motions of the excavator D; and, at the other end is placed the wooden crane E, in form similar to an ordinary timber crane, on the diagonal brace of which is placed a platform f, on which an assistant stands; and gearing W, for working another motion of the excavator D. To support the machine laterally, strong brackets or arms project on either side, the ends of which are furnished with screws to adjust the machine to the inequalities of the surface of the ground. The excavator or shovel D, (Figs. 8 and 13,) is formed of stout boiler-plate, and is firmly riveted together; it is of a box shape, having one end open; on the lower edge are four tangs or points, which serve to penetrate and loosen the soil; the other end is hung on swivel hinges, and fastened by a spring d, which may be set at liberty by means of the lever and rods a, Fig. 8. The machine is made to periorm three distinct movements; 1st, the digging movement; 2d, the turning movement; and 3d, the locomotive movement. The Digging Movement consists of two motions, one for drawing the excavator forward, and the other for driving it into the ground, both of which are done simultaneously the first motion is performed in the following manner. On the horizontal stage A, and in front of the boiler C, is placed a small high- pressure engine, (not shown in the engraving,) the connecting rod of which acts upon the crank c, and gives a rotary motion to the shaft L, and with it the pinion l, (Fig. 10,) which works into the large wheel M, mounted on the shaft N, upon which is fixed a large channelled barrel or drum n, (Figs. 8 and 11,) round which the hauling chain O, is coiled; this chain passes upwards through the hollow crane post, over the indented pulley P, to a double pulley fixed at the jib-head, thence round the blocks R, to which the excavator is suspended, as the chain wound up draws the excavator out of the ground both in a forward and upward direction, when driven into the ground by the second motion. This last motion is communicated by the chain traversing over the indented pulley P, to another gearing. On the axle of the indented pulley P, is fixed a bevelled wheel v, (Fig. which works into a similar one v', (Fig. 8,) mounted on to the upper end of the oblique shaft V, on the lower end of which is a corresponding bevelled wheel v", working into another 20, fixed upon the shaft W; upon this shaft is a pinion w', which takes into the large spur wheel u', mounted upon a shaft, upon which is a channelled drum u, round which is coiled the chain s, attached to the diagonal wooden arms S; on the lower end of these arms is fixed an iron yoke, to which is suspended on pivots the excavator. By this arrange- ment, as the main chain o passes over the pulley P, motion is communicated to the shaft for the purpose of forcing downwards in a diagonal direction the arms S, and with them the excavator into the ground. A man stands upon the stage f, for throwing in and out of gear this apparatus, and to regulate the motion for lowering or raising the excavator. The next motion to be described, is for the purpose of turning the crane round either to the right or to the left; this is effected by another gearing in the following manner. On the first crank shaft I, is fixed a bevelled wheel l, (Fig. 10,) which works into a similar wheel g, mounted on to the end of a hori- zontal shaft G, upon which are placed loose two bevelled wheels g'g", either of which can be thrown in or out of gear so as to work, as may be required, into the large bevelled wheel h, mounted upon the shaft H; upon this shaft is a pinion h', which works into the wheel j, fixed on the shaft J; upon this shaft is fixed an indented pulley j', round which the chain r is coiled, and passes upwards over pulleys 8, round either side of the horse-shoe pulley, to the ends of which it is fixed by iron bolts; the horse-shoe pulley is fixed by means of strong iron stays to the crane, and when it is made to revolve, the crane-jib is turned round on the stationary post t, either to the right or to the left as may be required, and empties the contents of the excavator into a wagon or barrow. The Progressing Motion is effected by placing on the hind wheel axle a strong wheel, shown by a circle b, (Fig. 8,) which communicates with a pinion b', on a shaft, as shown by a dotted circle; motion being given to the shaft above by the bevel gearing described in the last motion, a forward or back- ward motion of the machine is obtained. We have no precise data as to the cost of the machine or the quantity of work that can be performed by it, further that a rough estimate, which states that the machine is capable of digging 1000 cubic yards of earth per day, and that a machine complete costs about 6000 dollars. ANACLASTICS. That part of Optics which considers the refraction of light, and is commonly called Dioptrics. ANCHOR. A heavy curved instrument, used for retaining ships in a required position. The forms of anchors, and the materials of which they are made, are various. In many parts of the East Indies the lower part of the anchor is formed of a cross of a very strong and heavy kind of wood, the extrem- ities of which are made pointed. About the middle of each arm of the cross is inserted a long bar of the same wood, the upper ends of which converge to a point, and are secured either by ropes or an iron hoop, and the space between the bars is filled up with stones to make the anchors sink more deeply and readily. In Spain, and in the South Seas, anchors are sometimes formed of copper, but generally in Europe they are made of forged iron. Anchors may be divided into two classes-mooring anchors, and ships' anchors. Mooring anchors are those which are laid down for a permanency in docks and harbors, and are considerably heavier than ships' anchors, from which they differ in form, having sometimes but one arm, and sometimes, instead of arms, having at the extremity a heavy circular mass of iron and no Digitized by Google ANCHOR. 19 stock; these latter are called mushroom anchors, The general form of ships' anchors is shown in the annexed figure. There is a long bar of iron, called the shank, from the lower extremity of which branch two curved arms bb in opposite directions, and forming an angle of d 60° each with the shank. Upon each arm, towards the end, is laid a thick triangular piece of iron cc, termed the Auke. In the upper end of the shank is an eye, through which passes a ring d, to which the cable is attached. The stock e is composed of two strong beams of wood, embracing the shank immediately below the ring, and se- cured together by iron hoops and tree-nails; the stock stands at right angles to the plane of the arms, and serves to guide the anchor in its descent, so as to cause one of the flukes to enter the ground. Ships are generally pro- vided with three large anchors, named the best bower, the small, and the sheet anchor; a smaller anchor, termed the 14. stream anchor; and another, still smaller, named the kedge, which latter has generally an iron stock passing through an eye in the shank, secured thereto by a key, or forelock, which admits of its being readily displaced its principal use is in changing the position of a ship in harbor, and in an operation termed kedging. From the great mass of iron in large anchors, (some weighing from 3 to 4 tons,) b the perfect forging of them becomes a matter of much dif- b ficulty; as from the great heat necessary to weld such mass- es, the iron is liable to become "burnt," as it is termed. Workmen also cannot always observe what is going on in the forge, where the iron is exposed to ignition from the blasts of the bellows, or to the presence of sulphur in quantity among the coals. When the welding of a large mass, like the shank of an anchor, is to be completed by the sledge-hammer, the workmen are subjected to a scorching heat radiating therefrom, which renders it impossible to make a very close inspection, and the consequence frequently is, the beating up of cinders within the body of the iron. To this cause, and to burning, may be often attrib- uted the breaking of anchors, followed too frequently by a distressing loss of lives and property. Many attempts have been made of late years to construct anchors not liable to these defects, by dividing the mass into separate parts, and by a more judicious arrangement. The following is the invention of Mr. Hawkes. He observes, "The anchors at present in use are made by forming the shank and flukes sepa- rately; and by the rapid action of heavy hammers, a they are united or welded into each other, and the cable is fastened to a ring passed through the shank sidewise. The stocks, if of wood, are let or scored over each side, and bolted and hooped over the shank of the anchor; if of iron, the eye or hold for it is formed by punching a hole through the shank of the anchor; the palms are made separately, and welded on to the flukes. The improvement consists in making one fluke and half the shank in one length, and to bend them to the form required, and then hooping the two halves together. This method of making the anchor in separate parts, admits of the forming of a groove up the middle of the shank, for a chain to pass through, and of an eye of great - 15. strength for the reception of a wooden stock, which d is also made in two pieces, and passed into the shank in reverse directions; these having iron shoul ders abutting against the eye, are kept im- move..)ly in that position by being braced to- h gether with an iron hoop at each end. The con- struction is shown in the annexed engraving a the d cable ring b the eye which holds the stock, made out of the whole substance of the shank, by bend- ing each of the halves into a semicircle, in opposite directions. The anchor is shown to be divided into two equal parts, by a line which passes down the middle of the shank, as at 00; c the wooden stock, made also in two equal parts, as before described, and firmly secured in their places by the hoops and shoulders; dd d are four strong hoops which bind the shank together; the upper one is made square, and the others circular; a portion of the shank is supposed to be removed, to exhibit the situation of the chain which passes up the centre, and is con- nected at the upper end to the cable ring, and at the lower end to the buoy ring. f, in the small sep- Digitized by Google 20 ANCHOR. arate figure, gives a transverse section of the shank of the anchor, showing it to be of an oval form, the longest diameter of which is in a line with the flukes; this figure conferring upon it great strength to with- stand the powerful strains to which an anchor is frequently exposed in that direction. hh are the palms, bolted to the respective flukes, each of which is connected in one piece with a brace ii, passing in opposite directions round the shank of the anchor, thereby strengthening the flukes in a great degree, and giving a collateral support to each half of the anchor. k is a strong plate of iron bolted on to the crown; 1 the buoy ring." One differing materially in form and construction from the ordinary anchor was invented by Mr. R. F. Hawkins, and is represented in the subjoined engravings. The shank of the anchor a is forked at the lower part or crown, into two parts or loops b and c, in each of which is formed a hole or eye; between the loops is a block of iron d, termed a crown-piece, having a circular aperture to receive the arms, and a square aperture at right angles to the former, into which is screwed a stout bar of iron e, termed a toggle, projecting equally on each side of the crown-piece; on the end of the crown-piece, op- posite to that in which is inserted the toggle, is a ring f for the buoy rope. The arms g h are formed in one piece, and before the palms ii are attached, one end of the arms must be passed through the eyes in the loops of the shanks, and through the eye of the crown-piece; the palms are then to be put on, and must both lie in the same plane; after which the arms are to be curved in the same plane with the palms. The 16. crown-piece is firmly keyed a to the arms, and the toggle must be of such a length and form as to make it bear firmly against the fore part of the fork in the shank, 80 as to pre- vent the crown-piece and arms from turning round upon it, and to retain them at an angle of 50° with the shank. When the anchor is let go, one end of the toggle will come in contact with the ground, which puts the flukes in a position to en- ter; and when the strain is upon the cable, that end of the toggle which is upwards comes in contact with the throat of the shank, and sets the anchor in the hold- 17. ing position, as shown in perspective at Fig. 17. The advantage of this mode of constructing anchors is, that both arms take the ground, and therefore the weight of metal may be diminished, and yet an equal, if not a greater, effect be obtained also, as there is no stock, and no projecting upper fluke, there is little risk of fouling, as it is termed that is, of the cable entwining round the arms. The only objection which occurs to us, is the probability that, when at single anchor, it might not 80 readily turn in the ground at the turn of the tide, as the ordinary anchor, and therefore might be likely to trip; but for moorings we have no doubt that it would be found very effective. An anchor upon a similar principle, but of a some- what different construction, was invented by Mr. Soames, a front and side elevation of which is ex- hibited in the subjoined cuts. In this anchor there is but one fluke a, which is T-shaped, and works on a pivot in a triangular frame, composed of the two sides b d a d c, forged in one piece, and a stay d, which serves as a stock; ff are loops, or eyes, for the reception of the chains that unite the ring g, to which the cable is 18. to be fastened. For general purposes, this anchor is, perhaps, preferable to the former, it being free from the objection we made to that one, as it admits of de- taching the arm, which renders it more convenient to 19. stow away; also, as the shank is formed in two parts, instead of one of equal area, they are more easily forged soundly, and consequently less liable to break- age. The anchor proposed by W. Rogers is deserving of cotice. Its main peculiarity consists in its having a hollow shank, formed out of six bars of iron, of such a thickness as to ensure the forging of them perfectly sound for anchors of the largest dimensions. The con- struction we shall describe with reference to the sub- joined figures. Fig. 21 represents a side view of the anchor, and Fig. 20 a plan of the stock. The two Digitized by Google ANCHOR. 21 principal pieces a a are bent 80 as to form a part of the arms or flukes; the other four are formed into a hollow tube b b (as shown in section at Fig. 22) for a centre-piece, and the whole are firmly welded together at both ends of the shank. The intermediate parts are secured by strong hoops i i, 80 that every piece must bear its proportion of the entire strain. In place of the usual ring, there is a bolt and shackle c, Figs. 21 and 23, when the anchor is to be used with chain cables; but when hempen cables are to be used, a ring d is connected to the shackle c by an additional shackle and bolt e. The anchor- 23. 22. do b 6 21. a 20. stock f may be formed either of a single piece, or of two pieces hooped together, and is secured in its place as follows: The bolt and shackle c being withdrawn, the small end of the shank is passed through the eye of the stock f, (which is defended by an iron plate g on each side ;) the collar h is then put over, and the stock is keyed up against the hoop i by the forelock key k passing through a hole in the shank; by this means the anchor may be stocked or unstocked without the assistance of a carpenter, which is a great recommendation, as a considerable length of time is required to stock an anchor in the common way. These anchors have been pretty extensively adopted, and several parties who have made trial of them have given satisfactory certificates of their efficiency. In connection with improve- ments on anchors, it may not be altogether out of place to mention some improvements in the method of letting them go. Two improved methods of letting go anchors are described in the Transactions of the Society of Arts. The principle is the same in each, and consists in supporting the end of what is termed the standing part of the cat-head stopper and shank-painter, by bolts turning upon pivots, and retained in a proper position by a catch, which being withdrawn, the bolt turns upon its pivot, and the stopper slips off, by which means all risk of jamming the turns of the stopper (as in the common method of letting go the running end) is avoided; the danger to the men on the forecastle is done away, and the anchor can be let go at a moment's warning. The arrangements in each of these inventions being the same, whether applied to cat-head stoppers or shank-painters, we shall therefore show one invention as applied to cat-head stoppers, and the other to l a shank-painters. The subjoined cuts show Capt. Burton's method of letting B go a cat-head stopper. a i the cat- head; bc a bolt, turning .pon a pivot d; the end c forms an oblique plane, and is held down by the clamp e turning upon a pivot f, the clamp being secured by a hasp g and pin h. The standing end of the stopper, having an eye formed in it, passes over the end b of the bolt bc; the other end of the stopper 25. 94. passes through the ring of the anchor, and over the thumb-cleat k, and is made fast round the timber-head 1. When it is required to let go the anchor, a handspike is inserted be- tween the thumb-cleat k, 80 as to nip the clamp e, and the hasp g is cast off; then, upon withdrawing the handspike, the bolt being no longer held by the clamp e, turns upon its pivot d, by the weight of the anchor on the stopper, and the eye of the stopper slips off the end of the bolt. The following cut represents Mr. Spence's invention for letting go a shank-painter. Fig. 26 is an Digitized by Google 22 ANGICA-WOOD. elevation, and Fig. 27 the plan. a is a cast-iron carriage, bolted through the ship's side, and supporting the hook d by a pin or pivot at b; d e a lever turning upon a centre f, the end d being formed into a hook, which clasps the upper end of the bolt b, the lever being retained in the position shown in the plan, by a pin g h is part of a chain forming the standing part of the shank-painter, and supported by the bolt b. To the other end of the chain is spliced the running part of the shank-painter, which passes round the shank of the anchor, and is made fast to a 26. d b e timber-head. When it is required to let go the a shank-painter, an iron bar is inserted into the end B of the lever d e, which is made hollow for the pur- pose, and the pin g being withdrawn, the lever is turned round its centre until the bolt is released from the hook d, when it falls, and the chain end of the shank-painter slips off. a ANGICA-WOOD. See WOODS, Varieties of. ANEMOMETER. An instrument for measuring 27. b the strength or velocity of the wind. Among various machines which have been constructed for this pur- pose, the following one has been found to answer very well. It consists of an open frame a c, sup- ported by a shaft d, upon which it turns by the action of the wind upon the vane e. f f are sails, fixed to one end of the axis g, and disposed to be influenced by the wind in the usual manner. Upon this axis is also fixed a conical barrel of wood h k, on the smaller end of which k is attached a line l, with a weight appended to it. The wind acting upon the sails, causes the barrel to revolve, and the line to be wound up on its superficies. To prevent any retrograde motion, a ratchet wheel o is fixed to the base or larger end of the cone, having a clicker falling into the notches as it revolves. It is evident that the power of the weight will continually increase as the line advances towards the base of the cone, as the weight acts at a f greater distance from the axis or fulcrum; conse- quently, the variable force of the wind may be readily ascertained by fixing the line at the smallest end, and marking the barrel with spiral lines, as taken up by the coiling of the rope round its superficies, placing g og also between the lines numerals to denote the force of the wind, which may be calculated with tolerable precision upon the principles of the lever. The c a diameter of the cone should be such in comparison with its smallest end, that the force of the strongest wind should have scarcely sufficient force to bring the line on to the base of the cone. Although the instrument de- 29. scribed above gives an accurate idea of the comparative force of 28. the wind at different times, it does not point out the actual force exerted on a given surface, 3 nor can observations made with h. one instrument in a particular place, be compared with obser- 2 1 vations made by another instru- k ment elsewhere. It is also cum- bersome, and not portable. In 1 m d the Philosophical Transactions for 1775, Dr. Lind gives a de- scription of a very ingenious AWY portable wind gauge, which indi- cates the actual force of the wind g by the column of water which it will support. This instrument consists of two glass 1 tubes a b, c d, which should not be less than 8 or 9 inches long, the bore of each being about four-tenths of an inch in diameter, and connected together by a small bent glass tube e, of about only one-ninth of an inch bore, to check the undulations of the 3 water caused by a sudden gust of wind. On the upper end of the tube a b is fitted 6 a thin metal tube f, which is bent at right angles, and has its mouth open to re- ceive the wind blowing into it horizontally. The two branches of the tube are at liberty to turn round a steel spindle g, which passes through two slips of brass h i i near the top and bottom of the instrument. The spindle is fixed into a block of wood by a screw in its bottom. When the instrument is used, a quantity of water is poured in until the tubes are about half full, and the instrument being then held perpendicularly, with its mouth exposed to the wind, the water will be de- pressed in the tube a b, and proportionably elevated in the tube cd; and the dis- tance between the surfaces in the two tubes measured by a sliding scale of inches, and parts k attached to the instrument, will be the height of a column of water which the wind is capable of sustaining at that time; and as a cubic foot of water Digitized by Google ANNEALING. 23 weighs 1000 ounces, or 621 pounds nearly, the Height of Water. Force of Wind. twelfth part of which is 5 5-24 pounds, therefore Velocity per Hour. Inches. lbs. Miles. every inch the surface of the water is raised, the t 1.3 18 force of the wind will be equal to 80 many times Mr 2.6 25.6 5 5-24 pounds on the square foot. This instrument 1 5.2 86 shows the force, but not the velocity, of the wind; 2 10.4 50 but as the force is as the square of the velocity, if 8 15.6 62 the velocity due to a given force be ascertained, a 4 20.8 76 table of the velocities corresponding to each inch 5 26. 80.4 the water is elevated, may be calculated and en- 6 31.25 88 graved upon the scale of equal parts. The table 7 36.5 95.2 at the right, showing the corresponding height of 8 41.7 101.6 water, velocity of the wind, and the force exerted 9 46.9 108 upon a square foot of surface, has been calculated 10 52.1 113.6 from some experiments made by Dr. Hutton. 11 57.3 119.2 ANNEALING. The process by which metallic, 12 62.5 124. and other mineral productions, are converted from a brittle to a comparatively tough quality, presumed to bè caused by a new arrangement of their con- stituent particles. In a considerable number of bodies that will bear ignition, it is found that sudden cooling renders them hard and brittle, while, on the contrary, if they are allowed to cool very gradually, they become softened or annealed. We have, however, noticed several alloys of copper (brass in particular) in which sudden cooling has the reverse effect, that of annealing it. The process of anneal- ing requires some address and experience to perform it in the best manner; and varies in the degree of heat applied, as well as in the period of cooling, according to the nature of the metal or other substance operated upon. In the annealing of steel and iron, the metal is heated to a low redness, and suffered to be gradually reduced in its temperature, covered up, on a hearth. Ovens are constructed for this purpose, wherein the pieces of metal, according to their massiveness, and the quality it is desired they should possess, are placed and retained at a low heat for days, and sometimes weeks together. The annealing of glass is performed precisely in the same manner. ANGLE IRON HOOP, tables of circumferences, for facilitating construction of boilers. See DIMENSIONS OF ENGINES. ANGLE AND SURFACE JOINTS. See JOINING AND WORKING SHEET METAL. ANGLE OF FRICTION. See FRICTION AND RIGIDITY. ANGLE, to be given to double-lock gates. See LOCKS OF CANALS AND RIVERS. ANGLES AND POSITIONS OF TOOLS, as regards the act of cutting. See CUTTING Tools, general remarks upon. ANGLES. See TURNING TOOLS. ANGULAR THREAD SCREWS. See SCREW-CUTTING TOOLS. ANGLE, in Geometry, means nearly the same thing with the word inclination; thus, if two lines drawn on a plane surface are 80 situated that they meet in a point, or would do so, if long enough, they form an opening which is called an angle. The point where the lines which form the angle meet, is called the angular point; and if on this point as a centre, the one point of a compass be placed, while the other is made to describe the arc of a circle, which passes through both of the lines that form the angle, that arc will be the measure of the angle. It is to be observed, however, that it is not the length of the are which determines the magnitude of the angle, but the number of degrees, minutes, and seconds conta in it, 80 that if the arc consists of 20° 80', the angle is said to be one of 20° 30'. Angles are of various kinds, as Right, Obtuse, and Acute. When one line meets another, or stands upon it, and makes the angles on both sides equal to each other, then these angles are each called a right angle, and in this case the one line is said to be perpendicular to the other. In the common language of workmen, the one line is said to be square with the other and if the one line be horizontal the perpendicular is said to be plumb to it. The arc which measures a right angle, is the quarter of the whole circumference, or is a quadrant, and contains 90 degrees; any angle measured by an arc less than this, is said to be acute, (sharp,) and if the arc which measures the angle be greater than a quad- rant, the angle is said to be obtuse, (blunt.) The measurement and formation of angles is of extensive application in the mechanical arts, and it is therefore necessary that the artificer should be familiar with the subject. On this account we will introduce in another place an explanation of the various lines employed for that purpose, which lines, however, are more frequently treated of under the head of Trigonometry. ANIMAL KINGDOM, materials from-used in the mechanical and ornamental arts. Porcelanous and nacreous shells, bones, etc.-The hard solid substances derived from the Animal King- dom, are parts of the external or internal skeletons, as shells and bones or of the instruments of sus- tenance and defence, as horns, hoofs, nails, claws, and teeth these, together with the various coverings of animals, whether hair, feathers, or scales, are alike composed of animal and earthy matters, almost exclusively albumen, gelatine, and lime, combined in various proportions, and with a structure more or less interspersed with animal fibre. Many of these are either formed by the deposition of successive. annual layers, or they are altogether yearly renewed. A brief consideration of the chemical difference between their component parts, and of their respective proportions, in such as are used in the arts, will show the reasons for their various characters, and differ- ent treatment with tools. Albumen, the principal ingredient of these animal substances, and which exists in the purest form in the white of eggs, is hardened by a degree of heat less than the boiling temperature of water, and is msolulde in the same. Gelatine, of which jelly and glue are different examples, is softened by heat, and rendered fluid by the addition of water: both are easily cut and scraped, in all their various stages from Digitized by Google 24 ANIMAL MATTER USED IN THE ARTS. soft to hard, and during this change they contract very materially, but without entirely losing their elas- ticity. The earthy matters of the animal solids, principally the phosphate and carbonate of lime, are widely different from the foregoing, and also from the substances of the woods and metals. They are inelastic, and often crystalline, and therefore incapable of being cut into shreds or shavings; as when they are divided, they become smaller fragments or particles which are always angular: they are comparatively uninfluenced by water or small changes of temperature, and are incapable of contraction. When the earthy and crystalline structures prevail, the animal substances are harsh, incapable of ab- sorbing moisture, or of alteration of size or form; when the animal and fibrous characters prevail, they are easily cut, and they absorb moisture, soften, and swell. Enamel of teeth, the hardest of the class, contains from 2 to 31 per cent of animal matter, (Berzelius.) Porcelanous shells are nearly similar. Nacreous shells, 24 per cent, (Hatchett.) Ivory, 24 per cent, (Ure;) 25 per cent, (Merat Guillot.) Bone, 33 per cent, (Berzelius.) Horn, is coagulated albumen and lime, with 1 per cent of phosphate of lime, (Ure.) Tortoiseshell is nearly the same as horn. The horn of the buck and hart are intermediate between bone and ordinary horn, (Ure.) In some of the shells, the quantity of animal matter is so small, and the lime is in 80 hard and compact a form, that they are very brittle, partially translucent, generally they have smooth surfaces, and are in- capable of being cut with a knife or tools; such shells are called porcelanous, from their resemblance to porcelain, they include most of the univalve shells, such as the whelks, limpets, and cowries. Most of these can only be worked upon after the manner of the lapidary, with emery and other gritty matters harder than themselves, by which means they are cut and polished, as will be explained in speaking of that art; by analysis, porcelanous shells are considered closely to agree with the enamel of the teeth. The nacreous shells, thus named from nacre, the French for mother-of-pearl, are most commonly known in the shells of the pearl-bearing oyster of the Indian Seas, (Ostræa margaritifera,) but they include the generality of the bivalve shells, as the various oysters, muscles, &c. within they are smooth and iridescent, without they have a rough coat or epidermis. These kinds contain a larger proportion of animal matter, which is considered to be arranged in alter- nate layers with the carbonate of lime; and as these shells also are impenetrable to water, they neither shrink nor swell. The pearl shells are less frangible and hard than the porcelanous shells, and they ad- mit of being sawn, scraped, and filed, with ordinary tools; but they are harsh, scratchy, and disagreeble under the operation. The beautiful iridescent appearance of the pearl shells is attributed to their laminated structure, which disposes their surfaces in minute furrows, that decompose and reflect the light; and owing to this lamel- lar structure, they also admit of being split into leaves, for the handles of knives, counters, and the pur- poses of inlaying. As the pieces are very apt to follow, and even to exceed the curvature of the surface, splitting is not much resorted to, but the different parts of the shell are selected to suit the several purposes as nearly as possible; and the excess of thickness is removed upon the grindstone in preference to risking the loss of both parts in the attempt to split them. The usual course in preparing the rough pearl shell for the arts, is to cut out the square and angular pieces with the ordinary brass-back saw, and the circular pieces, such as those for buttons, with the an- nular or crown saw, fixed upon a lathe mandrel. The sides of the pieces are then ground flat upon a wet grindstone, the edge of which is turned with several grooves, as the ridges are considered to cut more quickly than the entire surface, from becoming less clogged with the particles ground off. The pieces are finished upon the flat side of the stone, and are then ready for inlaying, engraving, and polishing, according to the purposes for which they are intended. Cylindrical pieces are cut out of the thick part of the shell, near the joint or hinge, and rounded upon the grindstone, ready for the lathe, in which they may be turned with the ordinary tools used for ivory and the hard woods. The following are considered by an experienced dealer to be the respective qualities of the pearl shells. Th , Chinese, from Manilla, are the best; they are fine, large, and very brilliant, with yellow edges. Singapore, fine large shells, dead-white. Bombay, a common article. Valparaiso, also common, with jet-black edges. South Sea pearl shells, common, with white edges. The very beautiful dark-green pearl shells, are known as ear-shells or sea-ears; they are unlike the others in form, being more concave, and with small holes around the margin, and are the coverings of the Haliotis, found in the Californian, South African, and East Indian Seas. Cameos are cut in the conch- shell, Strombus Gigas, of the southern coast of America, and the West Indian Islands. Mr. E. H. Bond states that he has seen the Chinese work the largest of known shells, the Chama Gigas of Linnæus, the Tridacna Gigas of Lamarck, intò snuff-bottles, tops of walking-sticks, bangles, (a kind of bracelet,) and similar articles, some of which he possesses. The shell is a bivalve and not nacreous, generally white, sometimes pale blue; it may be beautifully polished, and is less readily scratched than mother-of-pearl; its localities are the Indian Seas, New Holland and the Red Sea, but the largest are obtained from Sumatra, one pair from whence, described in Sir Joseph Banks' MSS. Library, is said to weigh, the one valve 285, the other 222 pounds, but the more usual weight is about 100 pounds each/valve. Mr. Bond considers the useful portions of the shell, already prepared, might be obtained from China. In the bones of animals, the earthy and animal matters are more nearly balanced they are therefore less brittle than the shells, but prior to being used they require the oil with which they are largely im- pregnated to be extracted by boiling them in water, and bleaching them in the sun, or otherwise. This process of boiling, in place of softening, robs them of part of their gelatine, and therefore of part of their elasticity and contractibility likewise; they become more brittle, and having a fibrous structure, they break in splinters. The forms of the bones are altogether unfavorable to their extensive or ornamental employment; most of them are very thin and curved, contain large cellular cavities for marrow, are are interspersed with vessels that are visible after they are worked up into brushes, spoons, and articles of common Digitized by Google ANIMAL MATTER USED IN THE ARTS. 25 turnery. The buttock and shin bones of the ox and calf, are almost the only kinds used. To whiten the finished works, they are soaked in turpentine for a day, boiled in water for about an hour, and then polished with whiting and water. Bone is far less disagreeable under the tools than the pearl shell, but it is nevertheless hard, harsh, and chalky; the screws cut on bone are imperfect and soon injured. It is harder, often whiter, but much less pleasant to work than ivory, which beautiful material will be treated of separately. Horn.-In the English language we have only one word to express two quite different substances; namely, the branched bony horns of the stag genus, and the simple laminated horns of the ox genus, and other kindred genera. The bony horns are called in the French bois, from their likeness to the branch of a tree; they are annually renewed. The other sort of horn, to which the French appropriate the term corne, and which is the subject of our present inquiry, is found on the ox, the antelope, the goat, and sheep kinds. These two kinds will be considered separately. The stag-horn closely resembles the ordinary solid bones, both in its chemical characters, and also in structure, as it is spongy and cellular in its central parts. The horn is sawn into pieces, filed to the re- quired shapes, and used without any further preparation, the natural rough exterior of the horn being left in the original state; its appearance is neat and ornamental, and from its uneven surface is very suitable for the handles of knives, and other instruments requiring to be held with a firm grasp. When short pieces of stag-horn are used entire, as for the handles of table-knives, the hollow cellular part is concealed by the addition of the metal cap, and those parts of the white internal substance, which are necessarily exposed, are browned with a hot iron, or the flame of a blowpipe, so as nearly to match the other parts. The horns of the OX tribe are deposited in annual layers upon the bony cores that project from the foreheads of the animals; whence it results, that the general form of the horn, (neglecting its curvature,) is conical, the portion beyond the core is solid, and the other extremity tapers off 80 as to terminate at the base in a single plate, or extremely thin edge. Horn consists almost entirely of animal matter, chiefly membranous-namely, coagulated albumen with a little gelatine, and an inconsiderable portion of phosphate of lime; had the horns much more earth they would be brittle like bones, had they much more gelatine they would be soluble like jelly or glue; as they are constituted, the quantity of gelatine is only sufficient to allow them to be considerably softened by a degree of heat not exceeding that of melted lead, after which they may be cut open with knives or shears, flattened into plates, divided into leaves, and struck between dies like metal. Their gelatine serves as a natural solder, 80 that neighboring surfaces, when perfectly free from greasy matter, may be permanently joined together by moisture, heat, and pressure the union becomes perfect, but horn being a cheap material, the process of joining it is seldom practised. The straight conical horn of the rhinoceros is also occasionally used; it is solid, and formed as of a group of hairs cemented together: the transverse section of the upper part of the horn exhibits small dots. The horns of the chamois and antelope, and those of some other animals, are generally looked upon as natural curiosities, and are only polished exteriorly, without any strictly manufacturing process being applied to them. The first step in operating upon horn is the separation of the bony core, which is effected by macera- ting the horns in water for about a month, when, from the putrefaction of the intermediate membrane, the core may be readily detached; this is not thrown away, but burnt to constitute the bone earth used for the cupels for assaying gold and silver. The solid portion or tip of the horn is usually sawn off, and the remainder, if not cut into short lengths, is softened by immersion for half an hour in boiling water it is then held in the flame of a coal or wood fire, until it acquires nearly the heat of melted lead, when it becomes exceedingly soft, after which it is slit up the side with a strong pointed knife, and opened out by means of two pairs of pincers applied to the edges of the slit; and lastly, the flats" are inserted between iron plates previously heated and greased, which are squeezed tight in a kind of horizontal frame or press by means of wedges; wooden boards may be used. For general purposes, as for combs, the pressure should be moderate, otherwise, in the language of the workman, it breaks the grain, or divides the laminæ, and causes the points of the teeth to split; but great pressure is purposely used in the manufacture of the leaves for lanterns, which are afterwards completely separated with a round-pointed knife, scraped, and polished. The heat and pressure when applied to the light-colored horn render it almost transparent. An improved mode of opening horn" was invented by Mr. J. James, by which the risk of its being scorched or frizzled over the open fire is entirely removed; he employs a solid block of iron with a conical hole, and an iron conical plug: these are heated over a stove to the temperature of melted lead, and the horn, after having been divided lengthwise with a saw or knife, is inserted in the hole, the plug is gradually driven in with a mallet, and in the space of about a minute the horn is softened and ready for being opened in the usual manner. In making drinking-horns, and some few other turned works, the material is cut to the appropriate length, brought to the circular form, and allowed to cool in the mould the process is similar to that just described, although the old methods of the open fire and wooden cones are commonly used. The horn is then fixed in the lathe by its larger end, and turned on its inner and outer surface, and the groove, or chime for the bottom, is cut with an appropriate tool. A thin plate, previously cut out of a flat piece of horn with a crown-saw, is dropped into the horn, and forced into the groove, after the horn has been sufficiently heated before the fire to allow the necessary expansion; in cooling, the contraction fixes the bottom water-tight. As an illustration of the peculiar properties of horn, and a mode of its employment in the lathe, may be mentioned the expanding snake: this toy is well known to consist of a conical piece of horn, the 4 Digitized by Google 26 ANIMAL MATTER USED IN THE ARTS. one end of which is carved to represent the head, and the remainder is cut into a single spiral shred, 80 as to admit of great expansion, in imitation of the body of the reptile. I find the elastic portion of the one before me to measure, when compressed, barely one inch and a quarter in length, and that it expands to upwards of three feet and a half, or thirty-five times: no mean proof of the elasticity of the material. In making this trifle, the material is first turned to a conical form, after which a hole of about one- eighth or one-sixth of an inch diameter, is pierced from the tail almost through the head; the horn is then soaked for about two days in cold water to soften it, and the spiral incision or screw is made at one single cut, by means of a tool extending from the centre to the circumference; the cutter is not required to be very thin, as the shaving will bend away to make room for the same. One of the three following modes of proceeding is recommended in the Manuel du Tourneur. First, by the employment of a sliding rest, adapted to cutting screws, by which the tool is traversed, or guided mechanically along the horn during the rotation of the mandrel of the lathe; and to prevent the fracture of the toy during its construction, a stick of wood, with a button on the end of it, is put up the aperture, to receive and support the spiral as it is produced. Another method is by the employment of a lathe with a traversing or screw-cutting mandrel, upon which latter the horn is fixed, the tool being kept stationary in the slide-rest. Both methods require expensive apparatus, the principles of which will be explained in the article on screw-cutting tools. The third plan is extremely simple; and appears, on inspection, to have been the one pursued in this instance it is ascribed to the German toy-makers. The horn is prepared as before, but the lathe and slide-rest give way to the ordinary carpenter's brace, which carries the piece of horn, as in Fig. 30. A 0 30. mmm 32. 31. small tool is fixed in the vice or bench; it consists of a piece of wood, to which is screwed a hardened steel plate about one-twelfth of an inch thick it has a hole equal to the diameter of that in the horn, for the passage of the supporting wire; the plate is divided radially, the one edge is sharpened very keenly, and bent so much in advance of the other, that their difference of level or agreement, shall be equal to the intended thickness of the continuous shaving of the body of the snake, and therefore the projecting edge assimilates to the mouth of a plane: the last processes, in every case, being to carve the head and to attach a little piece for the end of the tail. It is necessary the coils of the snake should be of a conical form, or dished, as in Fig. 31, instead of being quite flat, as it increases the strength of the toy this is accomplished by making the cutting edge of the tool oblique to the axis of the snake; Fig. 32 shows the tool for the lathe. The several details are too simple to require further explanation. The handles for knives, razors, and other works moulded in horn, are thus made: the horn is first cut into appropriate pieces with the saw, and when heated these are pared with a knife or spokeshave, to the general form and size required in this state horn works as easily as a piece of deal after having been pared, the pieces are pressed into moulds. An idea of the moulds will be conveyed by imagining two dies, or pieces of metal, parallel on their outer surfaces, and with a cavity sunk entirely in the one, or partly in each, according to circumstances the cavities made either straight, curved, twisted, rounded, bevelled, or engraved with any particular device, according to the pattern of the work to be produced. The pressure is applied to the dies, by enclosing them in a kind of clamp, made like a very strong pair of nut-crackers, but with a powerful screw at the end opposite to the joint; the mould, dies, and horn, are dipped into boiling water for a few minutes, and then screwed as fast as possible immediately on removal from the same, and in about twenty minutes the work is ready for finishing some handles are made of two pieces joined together. On referring to French authorities, I find it stated that horn, steeped for a week in a liquor, the active ingredient of which is caustic fixed alkali, becomes so soft that it may be easily moulded into any required shape. Horn shavings subjected to the same process become semi-gelatinous, and may be pressed in a mould in the form of snuff-boxes and other articles. Horn, however, 80 treated, becomes hard and very brittle, probably in consequence of its laminated structure being obliterated by the joint action of the alkali and strong pressure. Horn is easily dyed by boiling it in infusions of various colored ingredients, as we see in the horn lanterns made in China. In Europe it is chiefly colored of a rich red-brown, to imitate tortoiseshell, for combs and inlaid-work. The usual mode of effecting this is to mix together pearlash, quicklime, and litharge, with a sufficient quantity of water and a little pounded dragon's blood, and boil them together for half an hour. The compound is then to be applied hot on the parts that are required to be colored, and is to remain on the surface till the color has struck on those parts where a deeper tinge is required, the composition is to be applied a second time. This process is nearly the same as that employed for giving a brown or black color to white hair; and depends on the combination of the sulphur, (which is Digitized by Google ANIMAL MATTER USED IN THE ARTS. 27 an essential ingredient in albumen,) with the lead dissolved in the alkali, and thus introduced into the substance of the horn. The horn which is naturally black is less brittle than that which is so stained. Tortoiscshell comes next under consideration. The animal which produces this beautiful substance is a marine tortoise, called the Testudo imbricata, or hawk's-bill turtle. The usual size of the full-grown animal is about a yard long and three quarters of a yard wide; its covering consists of thirteen principal plates, five down the centre of the back, and four on each side, and in a tortoise of the above size, the largest, or main-plates, weigh about nine ounces, and measure about thirteen by eight inches, and one quarter of an inch thick at the central parts; but they are thinned away at the edges where they overlap, owing to the deposition of the substance of the shell in annual layers, each extending beyond the previous one. Very rarely, the shells are three-eighths thick and proportionately heavy. Others are very thin, and appear to consist of only one single layer; this is supposed to occur when the animal loses a plate by accident, or that it is stripped and thrown back again into the sea whilst alive; such shells are usually very light-colored and are called yellow belly." There are also twenty-five small pieces of shell which envelop the edge of the animal, but these can only be applied to very small purposes. Some of the tortoiseshell is of very dark-brown tints running into black, and interspersed with light gold-colored dashes and marks, these are considered the best; others are lighter, even to pale red- browns, yellow, and white: the last are not valued, the yellow are used for covering the works of musical snuff-boxes, and the light red and brown shells are manufactured into ladies' combs, for expor- tation to Spain, where they obtain double the price of those made of the darker colored tortoiseshell. The shell of the turtle is also used, but it has not the transparent character of the foregoing; the colors are lighter, less beautifully marked, and it is little valued. The treatment of tortoiseshell is essentially the same as that of horn, but on account of its very much greater expense, it is economized so far as possible. Before the shells are worked they are often dipped in boiling water to temper them; three or four minutes commonly suffice, but they require a longer period when they are either thicker or more brittle than usual: excess of boiling spoils the colors of the shells, renders them darker, and covers the outside with an opaque white film. Others, flatten and temper the shells with hot irons, such as are used by laundresses: the shell is continually dipped in cold water to prevent its being scorched; but as a general rule the less tortoiseshell is subjected to heat, or to being pulled about, the better, as from its apparent want of grain or fibre, it becomes in consequence very brittle. Many of the works in tortoiseshell are made, partly by cutting them out of the shell, and partly by joining or adhesion, called by the French souder. Thus in the Manuel du Tourneur, the artist is directed to form the ring of tortoiseshell for the rebate of a box, by cutting out a long narrow slip of the shell; the ends are then to be filed with a clean rough file to thin feather edges, to the extent of three quarters of an inch of their length, the one on the upper and the other on the lower surface, to constitute the lap or joint; the slip is dipped into boiling water, and when softened it is bent into an oval form with the intended joint on the flat side, the ends are held in firm and accurate contact with the finger and thumb, and the piece is dipped into cold water to make it retain the form. A pair of tongs is required, such as those in Fig. 33, with flat ends measuring about one inch wide and three or four long, and that spring open when left to themselves, but fit perfectly close and even, when compressed; these are made warm. In the mean time the ends of the ring are sprung 33. asunder sidewise, to bring the scarfs or parts to be joined to the inner and outer surfaces respec- tively, that they may be retouched with the file to remove any small portion of grease which may have been accidentally picked up, and the joint is restored to its proper position. A piece of clean linen is then soaked in clean water, squeezed dry with the fingers, folded in ten to twenty thicknesses, to about the size of one and a half inch wide, and three or four long; the ends are now folded together, placed on each side the joint, the whole is inserted between the tongs, and fixed moderately tight in the jaws of an ordinary vice. The softening and consequent adhesion of the shell, will be known by the flexibility of the ring when the loose part is wriggled about with the fingers; the work is either allowed to cool in the vice, or after a time is dipped into cold water. The success of the process will depend on three different circumstances; the parts to be joined must be entirely free from "grease and dirt, on which account the surfaces should not be touched after being filed; the temperature of the tongs should be just sufficient to color writing-paper of a pale orange tint; and moisture or vapor must be present, apparently to liquefy the gelatine of the tortoiseshell at the surfaces of union. The ring, when cold, is pressed with the fingers into the circular form or even into an oval in the opposite direction, which would cause the ends of the joints to start, if the soldering were imperfectly performed; should this happen, the application of the moistened rag and heated tongs must be repeated until the result is perfect; the ring is made circular by warming it in boiling water, and gently forcing it on a wooden cone of small angle. Another mode, the invention of an amateur, is also described; the strip of shell is chamfered off at the ends and bent round a piece of wood, a compress of linen in six or eight folds is put upon the joint, and the whole is tightly bound round with string, and immersed in boiling water for ten minutes. The contraction of the string, and the expansion of the wood, from being wetted, supply the needful pressure, and the process is said to be quite successful. Moulding and soldering tortoiseshell, are also performed under water in various other ways; for Digitized by Google 28 ANIMAL MATTER USED IN THE ARTS. example, in attaching the back of a large comb, to that piece which is formed into the teeth, the two parts are filed to correspond, they are surrounded by pieces of linen and inserted between metal moulds, connected at their extremities by metal screws and nuts; the interval between the halves of the mould, being occasionally curved to the sweep required in the comb. Sometimes also the outer faces of the mould are curved to the particular form of those combs in which the back is curled round, so as to form an angle with the teeth; the joint when properly done cannot be detected either by the want of transparency or polish at the part. Considerable ingenuity is shown in turning to economical account the flexibility of tortoiseshell in its heated state; for example, the teeth of the larger description of combs are parted, or cut one out of the other with a thin frame-saw, when the shell equal in size to two combs with their teeth interlaced as in Fig. 34, is bent like an arch in the direction of the length of the teeth as in Fig. 35. The shell is then flattened, the points are separated with a narrow chisel or pricker, and the two 36. 34. combs are finished whilst flat, with coarse single-cut files, and triangular serapers; and lastly they are warmed, and bent on the knee over a wooden mould, by means of a strap passed 37. round the foot, in the manner a shoe- maker fixes the' shoe-last. Smaller combs of horn and tortoiseshell are 38. parted whilst flat, by an ingenious 35. machine, invented by Mr. Kelly. It has two chisel-formed cutters placed ob- liquely, 80 that every cut produces one tooth, the repetition of which com- pletes the formation of the comb. Ivory and boxwood combs cannot be thus parted; they are cut in the old way, one tooth at a time, by various contrivances of double saws, as will be explained. In making the frames for eye-glasses and spectacles, the apertures for the glasses were formerly cut out to the circular form, with a tool something like a carpenter's centre-bit, or with a crown-saw in the lathe; the disks were in either case preserved, to be used for inlaying in the tops of boxes, and the outside of the frame was then shaped with saws and files. This required a piece of tortoiseshell of the entire size of the front of the spectacles, but a piece of a third that width is made to answer for inferior spectacles, as the eyes are strained, or pulled. A long narrow piece of the material is cut out, and two alits are made in it with a thin saw; the shell is then warmed, the apertures are pulled open, and fashioned upon a taper triblet of the appropriate shape: Figs. 36, 37, and 38, explain this method; the groove for the edge of the glass is cut with a small circular cutter, or sharp-edged saw, about three- eighths or half inch diameter, and the glass is sprung in when the frame is expanded by heat. Tortoiseshell is also manufactured into boxes and a variety of moulded works, but the process calls for extensive preparations, and is not often followed by the amateur. The construction of tortoiseshell boxes requires a copper, with a fireplace beneath; a trough with cold water; and a press and moulds. The former may be compared to the ordinary coining press, or to a strong rectangular frame, usually of wrought-iron, with a screw in the centre of the upper cross-piece; the base of the press is fitted into a square recess in the centre of the bench, fixed so firmly to the floor or wall. as to resist the efforts of two or 39. three men at the end of a lever five or six feet long, whose entire force is sometimes required in tightening the mould. For the convenience of transferring the heavy press, a from the hole in the bench to the hot or cold water, a crane, the centre of which is equally distant from the three, is added to the estab- c lishment. 41. The mould required for a round box con- sists of a thick wrought-iron ring a a, Fig. 39, a turned interiorly to the diameter of the box; a 40. it stands loosely upon a plate b; it is ac- curately fitted with several pieces, common- ly of brass, as c the bottom die, d the top b die for a plain box, e a plain block for flat plates, and f a die engraved with any par- ticular device to be impressed upon the work. e In the Manuel du Tourneur the methods of making four different kinds of boxes are minutely given. Thus in the Boites d feuilles, the best kind, in which the cover and bottom part are each made out of a single leaf of shell the circular pieces are to be cut out of the shell as much larger than the size of the box, as the vertical height in addition to the diameter; so that я box of three inches diameter and one inch deep would require pieces of four and five inches respectively for the cover and bottom. Digitized by Google ANIMAL MATTER USED IN THE ARTS. 29 The round plate of shell is first placed centrally over the edge of the ring, as in Fig. 39 it is slightly squeezed with the small round-edged block g, and the entire press is then lowered into the boiling water; in one quarter, or half an hour, it is transferred to the bench, and g is pressed entirely down, which bends the shell into the shape of a saucer, as at Fig. 40, without cutting or injuring the tortoiseshell, after which the press is cooled in the water-trough. The same processes are repeated with the die d, which has a rebate turned away to the thickness of the shell, and perfects the angle of the box to the section Fig. 41, ready for completion in the lathe; it is however safer to perform each of these processes at twice, with two boilings. When the shell is insufficiently thick, two pieces are joined together, and should they from the nature of the shell be of irregular thickness, the thick and thin parts respectively are placed in contact; for such cases the dies c e, of a larger mould, are used. The piece d is adapted to boxes of various depths, or to the tops or bottoms respectively, by slipping loose rings upon it to contract the length of its smaller part. When the box is required to have a device, an engraved die f is substituted in place of a The s.me tools are also used for horn boxes, and for the embossed wooden boxes, but the latter process is mostly performed in the dry way, the warmth being supplied by heated plates, put above and below the two parts of the mould which are then compressed, and the whole is allowed to cool in the air. The Manuel describes the construction of inferior boxes, " Tabatières de morceaux," in which small pieces of tortoiseshell with bevelled edges are carefully fitted together with the file and arranged along the bottom and up the sides of the mould; or else they are first pressed into a flat plate, and made into a box as a separate process; but the joints, from the manner in which they are made, can scarcely ever escape observation. The Boites de très-petits morceaux" are made of still smaller fragments, which are often cemented on a thin leaf of shell to ensure their better union; and lastly, the Boites de drogues" are made of the fine dust and filings, which are passed through a sieve, and treated in other respects much in the same manner as the foregoing, but these boxes are quite opaque and brittle; a thin hoop of good tortoiseshell is sometimes inserted in the mould, to form the rebate of the box, which alone is then transparent; at other times, the shavings are mixed with mineral coloring matters, to imitate granite, lapis-lasuli, and other stones. After the lapse of ten days or a fortnight, it sometimes happens the box shows a tendency to recover its primary form, that of a flat plate, and from being cylindrical on the edge, it becomes in a slight de- gree conical and larger without. After being again returned to the mould, boiled, and pressed, its figure is in general permanent. This disposition is turned to useful account in restoring the fitting of a box that may have become loose, as by dipping the lower part, or the rebate, into warm water, it will expand and fill out the lid, but it requires care that it be not overdone. The tortoiseshell boxes usually made, are those which are veneered upon a body or fabric of wood, for which purpose the plates are scraped and filed to a uniform thickness, and glued on much the same as veneers of wood; generally fine glue is the only cement used, but various compositions are resorted to by different manufacturers. To improve the appearance of the shell, and to conceal the glue and wood beneath, the back of the veneer is rubbed with a mixture of lampblack, vermilion, green, chrome, or white, in fish glue; the colors are applied over the entire surface, or partially to modify the effect, and thus prepared the veneers are glued upon the boxes. In tortoiseshell works inlaid with mother-of-pearl and gold or silver plates or wire, the substances to be inlaid are first prepared; and for pearl shell a paper is pasted on a thin piece of pearl, the pattern is drawn thereupon, and the small pieces are cut out with a fine buhl-saw gold and silver plates are some- times also thus sawn out. A plain mould similar to Fig. 39, but rectangular, and with plain dies, as c and e, is used; a few shavings of tortoiseshell are first placed on the piece c, to make a bed or cushion, then a piece of paper to prevent them from adhering to the thin leaf of tortoiseshell, which is next inserted in the mould. The small pieces of pearl shell, &c. to constitute the pattern, are then carefully arranged in their intended positions, and the top plate e is very carefully lowered into the mould above the pieces, 80 that it may not misplace any of them. The mould is then slid into the press, slightly squeezed, and plunged into the copper fa an hour, carried to the bench and screwed moderately tight; the work is now examined to see that nothing is misplaced, it is returned to the caldron for a time, and the final squeeze is given by the entire force of three men, after which, whilst still under pressure, the whole is plunged into the cold water. The tablet is then fit to be smoothed and glued on the wooden box. It will be readily conceived, that the force required depends upon the dimensions of the work; pieces of three or four inches square require all the appliances described; whereas the little ornaments upon razors and knives, may be pressed in with much slighter apparatus, such in fact as were previously de- scribed as being used in moulding them. In cutlery, a different method is generally resorted to, which applies equally well to ivory and pearl shell, substances which cannot be submitted to the softening and moulding processes employed for horn and tortoiseshell. The cutlery works which are dotted all over with little studs of gold or silver, are drilled from thin pattern plates of brass or steel in which the series of holes have been carefully made the drill or passer" has an enlargement or stop, which, by encountering the surface of the pattern plate, prevents the point of the drill from penetrating beyond the assigned depth into the handle; the holes in the ivory or pearl shell are then filled with silver or gold wire, which is either filed and polished off level with the general surface, or allowed to project as little studs. For small ornaments they use pattern plates or templets of hardened steel, pierced with the exact form. The cutting tool somewhat resembles an ordinary breast-drill eight or ten inches long, and like it, is used with the breast-plate and drill-bow; but the extremity of the tool is cleft, or made in two branches, which, left to themselves, spring open to the extent of an inch or more; each half of the tool Digitized by Google 30 ANIMAL MATTER USED IN THE ARTS. has a shoulder or stop, which bears upon the surface of the steel guard-plate, as in the drill, and a rectangular cutting part that protrudes through the shield-plate as far as the required depth of the recess, and is sharpened both at the end and side, or at the ends only. When the elastic tool or spring-passer" has been compressed 80 as to enter the guard-plate, it is put in motion, and flounders about in all directions, 80 far as it can expand, and routs or cuts out the shallow recess; the small ornaments are punched out, fixed by two rivets, and smoothed off; these processes are very expeditious, and produce accurate copies of the respective pattern-plates employed. The tortoiseshell, when unnecessarily thick for a single scale for a penknife, is sawn to serve for two; and the colors are brightened up by placing a piece of Dutch leaf beneath the same; they are finally polished on the various wheels used by the cutler. Tortoiseshell has been manufactured into hollow walking-sticks, and even bonnets. Whalebone may be considered as a kind of horn; which latter substance it resembles perfectly, both in its chemical and principal physical properties; and is particularly interesting as forming the transi- tion from horn to hair. It is the substitute for teeth in the Greenland whale, and in the black southern wale; but is not found in any of the cetaceous animals that have tecth. From the roof of the mouth hang down on each side the tongue about three hundred plates of whalebone, all the blades on one side being parallel to each other and at right angles to the jaw-bone. The average length of the middle blades is about nine feet, but they have occasionally occurred of the length of fourteen or fifteen feet. The general color of whalebone is a dusky grayish black, intermixed with thin stripes or layers of a pale color, which are often almost white-very rarely the entire flake is milk-white. The preparation of the whalebone for use is very simple. It is boiled in water for several hours, by which it becomes soft enough to be cut up while hot, in lengths of different dimensions, according to the use to which it is to be applied. Whalebone that has been boiled, and has become cold again, is harder and of a deeper color than at first; but the jet-black whalebone has been dyed, and by the usual processes it takes very bright and durable colors. Whalebone is now principally used for the stretchers for umbrellas, and as a substitute for bristles in common brushes; it is also plaited into whips, and solid pieces of mixed shades are twisted for walking-sticks; but it does not admit of being soldered or joined together like tortoiseshell. Whale- bone also furnishes a very neat and durable covering for pocket-telescopes. Narrow pieces of the material are grooved or made into ribs, by drawing them like wire through a corresponding aperture in a steel plate, after which they are wound round the tube, and tucked under" the rings at the ex- tremities. Broad flat strips of the party-colored whalebone, (the light portions of which absorb the green dye,) are also used these are secured by narrow black barids which overlap the two edges, and other bands are wound around the ends also. Ivory, the tusk or weapon of defence of the male elephant, and of which each animal has two, is placed by the chemists intermediately between bone and horn, and its mechanical characters corrobo- rate the position. It is generally considered that the male elephant alone possesses tusks, commercially known as elephants' teeth, but this appears questionable, as by many the female is reported to have tusks likewise, but of smaller size, and some consider the latter produce the small solid tusks called ball ivory," used for making billiard balls. Ivory has less gelatine than bone; but as it leaves the animal in a state fit for use, without the neces- sity of removing any of its component parts for its purification, its elasticity and strength are not im- paired by such abstraction. Ivory is not therefore so brittle as bone, neither does it splinter so much when broken, but its greater ultimate share of animal matter leaves it more sensible to change of form and size. The shape of the tusk is highly favorable to its use, as it is in general solid for above half its length, and of circular or elliptical section; it is entirely free from the vessels or pores often met with in bone, and although distinctly fibrous, it cannot be torn up in filaments like horn, nor divided into thin flexible leaves, as for miniatures, otherwise than by the saw. Its substance appears very dense, and without visible pores, as if beautifully cemented by oil or wax; and notwith anding that it possesses so large a share of lime, it admits of being worked with exquisite smoothness, and is altogether devoid of the harsh, meager character of bone. It is in all respert; the most suitable material for ornamental turning, as it is capable of receiving the most delicate lines and cutting, and the most slender proportions. The general supply of ivory is obtained from the two present varieties of the animal, the Asiatic and the African: they are considered by physiologists to be distinct species, and to be unlike the extinct animal from which the Russians are said to obtain their supply of this substance; which, although described as fossil ivory, does not appear to have undergone the conversion commonly implied by the first part of the name, but to be as suitable to ordinary use as the ivory recently procured from the living species. An extract from the interesting account of 44 The Elephant of the Lena" is subjoined as a note. " The Mammoth, or Elephant's bones and tusks, are found throughout Russia, and more particularly in Eastern Siberia and the Arctic marshes. The tusks are found in great quantities, and are collected for the sake of profit, being sold to the turners in the place of the living ivory of Africa, and the warmer parts of Asia, to which it is not at all inferior." " Almost the whole of the ivory-turner's work, made in Russia, is from the Siberian fossil ivory; and sometimes the tusks, having hitherto always been found in abundance, are exported from thence, being less in price than the recent. Although, for a lung series of years, very many thousands have been annually obtained, yet they are still collected every year in great numbers on the banks of the larger rivers of the Russian empire, and more particularly those of farther Siberia."- Naturalist's Library, 1836. Mammalia, vol. V., p. 133. The Mammoth terth are but rurely exposed for sale in this country. I only learn of two; the one weighed 186 pounds, was 10 feet long, of fine quality, and except the point, which was cracked, was cut into keys for pianofortes; the other also was large, but very much cracked and uscless. Of the latter I have a specimen: the substance of the Ivory between the Digitized by Google ANIMAL MATTER USED IN THE ARTS. 31 The hippopotamus, or river-horse, supplies the ivory used by the dentist, which is imported from the East Indies and Africa; the animal, in addition to twenty grinders, has twelve front teeth, the whole of which agree in substance with ivory, but not in their size or arrangement. The six in the upper jaw are small, and placed perpendicularly; in the lower jaw of the hippopotamus the two in the centre are long, horizontal, and straight, the two next are similar, but shorter; but the two external semicircular teeth are those 80 highly prized by the dentists on account of their superior size, and are those usually referred to when the "sea-horse" or hippopotamus tooth is spoken of, although the animal is in reality a quadruped inhabiting rivers and marshy places. The circular hippopotamus teeth are covered exteriorly with a thick coat of enamel, which entirely resists steel tools, and will even strike fire with that metal; it is usually removed upon the grindstone* in order to arrive at the beautiful ivory within, which, owing to the peculiarity of its section, is better adapted to the construction of artificial teeth than the purposes of turning; the other teeth are tolera. bly round, and fit for the lathe. The ivory of the hippopotamus is much harder than that of the elephant, and upwards of double the value; in color it is of a purer white, with a slight blue cast, and is almost free from grain. The parts rejected by the dentists are used for small carved and turned works. In texture it seems almost intermediate between the proper ivory and the pearl shell; as when it is turned very thin, it has a slightly curdled, mottled, or damasked appearance, which is very beautiful; the general substance is quite transparent, but apparently interspersed with groups of opaque fibres, like some of the minerals of the chatoyant kind. The teeth of the walrus, sometimes called the sea-cow, which hang perpendicularly from the upper jaw, are also used by the dentists; the outer part, or the true ivory, nearly resembles the above, but the oval centre has more the character of coarse bone; it is brown, and appears quite distinct. The long straight tusks of the sea-unicorn or narwal, which are spirally twisted, also yield ivory; but they are generally preserved as curiosities. These two kinds are principally obtained from the Hudson's Bay Company. The masticating teeth of some of the large animals are occasionally used as ivory; those of the spermaceti whale are of a flattened oval section, and resemble ivory in substance; but they are dark- colored towards the centre, and surrounded by an oval band of white ivory: like that of the aquatic varieties generally, they are not much used. The grinders of the elephant are occasionally worked; but their triple structure of plates of the hard enamel, of softer ivory, and of still softer cement, which do not unite in a perfect manner, render them uneven in texture. Owing to the hardness of the plates of enamel, the grinders are generally worked by the tools of the lapidary; they are but little used, and when divided into thin plates are disposed to separate, from change of atmosphere, the union of their respective parts being somewhat imperfect. They are made into small ornaments, knife-handles, boxes, &c. The tusk of the elephant is, however, of far more importance than all these other kinds of ivory, and appears to have been extensively used by the Greeks and Romans. Amongst the former, Phidias was famous for his statues, thrones, and other works of embellishment, made in ivory combined with gold, an art described as the Toreutic. In reference to the construction of ivory statues, Monsieur Quatremère de Quincy, in his great work on ancient sculpture, advances some curious speculations of their having been formed upon centres or cores of wood, covered with plates of ivory; and also that the ancients were enabled to procure larger elephants' teeth, or possessed the means of softening and flattening out those of ordinary size, from which to obtain the pieces presumed to have been thus employed. These questionable suppositions, particularly the last, scarcely seemed called for, as solid blocks of ivory of the sizes commonly met with, would appear to be sufficient for the construction of colossal figures, in the mode ingeniously demonstrated by M. de Quincy in his plates 26 to 31. It is much to be regretted that none of these statues have descended to our times. One of the constituent parts of ivory being animal matter, we should naturally expect it to be less durable t' an the inorganic materials, in which numerous fine specimens of ancient art still exist in great comparative perfection. Ivory appears not to suffer very rapid decay, in the lengthened deposition in the frozen earth of Siberia, nor when immersed in water; but various specimens in the British Museum, appa- rently less favorably situated, and in contact with the air, exhibit the effect of time, the ivory being decom- posed and divided into flakes and pieces which exhibit its lamellar structure in a very satisfactory manner. Elephants' teeth differ considerably in their size, weight, and appearance. The outsides of the African teeth run through all the transparent tints of light and deep orange, hazel, and brown, and some are almost black. Those from Asia are similar, although generally lighter, and frequently of a kind of opaque fawn, or stone-color; they have seldom the transparent character of the African teeth; and they commonly abound in cracks of inconsiderable depth, from which the others are comparatively free. Some teeth are as long as from eight to ten feet, and as heavy as 150, rarely 180 lbs. each tooth; some- times they are only as many inches long, and about one inch in diameter, and of the weight of five or six ounces, and even lighter; the teeth less than from 10 to 14 lbs. are called "scrivelloes." In section, the tusks are rarely quite circular, sometimes nearly elliptical, seldom exceeding the proportions of four to five, but commonly less exact than either of these forms; Figs. 43, 44, and 45, are accurately reduced from sections of teeth; the largest tusk the author has met with measured eight and a quarter inches the longest, and seven inches the shortest diameter of the irregular oval. cracks appears quite of the ordinary character, although the Interatices are filled with a dry powder resembling chalk. Both teeth were solid unto within six inches of the root. The enamel of the hippopotamus is much thicker, but similar to that of the generality of masticating teeth, which is found upon analysis to agree very nearly with the hard porcelanous shells. The enamel is sometimes scaled off by driving a thin chisel between it and the Ivory; and I learn, the flame of the blowpipe is likewise frequently used for the purpose of separating it. Several of the other teeth have enamel, but the semicircular tooth by far the most abundantly. + Le Jupiter Olympien, ou l'Art de la Sculpture Antique. Paris, 1815. Digitized by Google 32 ANIMAL MATTER USED IN THE ARTS. The curvature of the teeth is sometimes as much as the half-circle, as in Fig. 46, and occasionally even 80 little or less than the sixth, as in Fig. 42; they are sometimes finely tapered off, especially in the African teeth, at other times their ends are very much worn away,-in rare instances, to the extent of a third of their apparent length, and generally more 80 on the one side of the centre than the other. 42. Other teeth end very abruptly, as if they had been broken and repointed before they left the head of the animal, in which they are generally inserted for about one-fourth their length. The teeth are hollow about half-way up, and a speck, sometimes called the nerve, but in reality the apex of the successive hollows, is always visi- 44. ble throughout the length of the tusk to its extreme 43. end, the tooth being formed by layers deposited on a vascular pulp after the manner of teeth gen- erally. The inner and outer surfaces of the teeth are in general tolerably parallel, and exteriorly they are curved in the one direction only, 80 as to lie nearly 45. flat on the ground; but occasionally they are much curved in both directions, as represented in Figs. 47 and 48 the smaller is beautifully formed, and resembles in shape a handsome bullock's horn, the other is furrowed throughout its length, and ap- pears the result of disease or injury. 46. The choice of ivory in the tooth is admitted by the most experienced to be a very uncertain matter; of course, for the purposes of turning, a solid cone would be the most economical figure, but as that form is not to be met with, we must be satisfied with 47, 48. the nearest approach that we can find to it, and select the tooth as nearly straight, solid, and round as possible, provided the other prognostics are equally favorable. The rind should appear smooth and free from cracks, and if the heart should be visible at the tip, the more central it is the better; by the close inspection of the tip, from which the bark is always more or less worn away, it may be in general learned whether the tooth is coarse or fine in the grain, trans- parent or opaque, but the color of the exterior coat prevents a satisfactory judgment as to the tint or complexion of the ivory within. After the most careful scrutiny on the outside of the tooth, however, the first cut is always one of a little anxious expectation. as the prognostics are far from certain, and before proceeding to describe the preparation of ivory, I will say a few words of its internal appearance when exposed by the saw. The African ivory, when in the most perfect condition, should appear, when recently cut, of a mellow. warm, transparent tint, almost as if soaked in oil, and with very little appearance of grain or fibre; it is then called transparent or green ivory, from association with green timber; the oil dries up considerably by exposure, and leaves the material of a delicate, and generally permanent tint, a few shades darker than writing-paper. The Asiatic ivory is of a more opaque dead-white character, apparently from containing less oil, and on being opened it more resembles the ultimate character of the African, but it is the more disposed of the two to become discolored or yellow. The African ivory is generally closer in texture, harder under the tools, and polishes better than the Asiatic, and its compactness also prevents it from 80 readily absorbing oil, or the coloring matter of stains when intentionally applied. The rind is sometimes no more than about one-tenth of an inch in thickness, and nearly of the color Digitized by Google ANIMAL MATTER USED IN THE ARTS. 33 of the inner ivory, but occasionally it is of double that thickness, dark-colored, and partially stains the outer layers. As we do not find all specimens of the most perfect kind, we must be prepared to expect others, especially amongst the larger teeth, in which the grain is more apparent, but it generally dies away towards the centre of the tooth, the outside being the coarser; the regularity of the grain some- times gives it the appearance of the engine-turning on a watch-case. In some teeth, the central part will appear of the transparent character, the outer more nearly white; and the transparent teeth often exhibit, at the solid parts, white opaque patches, which are frequently of a long oval form. Amongst the white ivory, the teeth are often found to be marked in rings alter- nately light and dark colored; these are called 'ringy or cloudy." In those teeth in which there appears to be a deficiency of the animal oil, the intervals between the fibres occasionally assume the chalky character of bone, and are disposed to crumble under the tools unless they are very sharp; in this they resemble the softer parts of woods when worked with blunt tools; sometimes the ivory is not only coarse but dark or brown, and the two defects not unfrequently go together. The cracks occasionally penetrate further than they appear to do when viewed from the outside, and more rarely a very considerable portion of the tooth is injured by a musket-ball, although the gold and silver bullets, said to be used by the Eastern potentates, are exceedingly scarce, or else transmuted into iron, of which metal they are commonly found, and less frequently of lead. The ball generally lacerates the part very much, and a new deposite of bony matter is made that fills up all the interstices, incrusts the hollow, and leaves a dotted mottled mass extending many inches each way from the ball, and which completely spoils that part for any ornamental purpose. Preparation of Ivory.-On account of the great value of ivory it requires considerable judgment to be employed in its preparation, from three conditions observable in the form of the tusk; first, its being curved in the direction of its length; secondly, hollow for about half that extent, and gradually taper from the solid state to a thin feather edge at the root; and thirdly, elliptical or irregular in section. These three peculiarities give rise to as many separate considerations in cutting up the tooth with the requisite economy, as the only waste should be that arising from the passage of the thin blade of the saw: even the outside strips of the rind, called spills, are employed for the handles of penshives, and many other little objects; the scraps are burned in retorts for the manufacture of ivory black, employed for making ink for copperplate printers, and other uses; and the clean sawdust and shavings are some- times used for making jelly. The methods of dividing the tooth either into rectangular pieces, or those of circular figure required for turning, are alike in their early stages until the lathe is resorted to: I propose, therefore, to begin with the former. The ivory saw, Fig. 49, is stretched in a steel frame to keep it very tense; the blade generally measures from fifteen to thirty inches long, from one and a half to three inches wide, and about the fortieth of an inch thick; the teeth are rather coarse, namely, about five or six to the inch, and they are sloped a little forward, that is, between the angle of the common hand-saw tooth and the cross-cut saw. The instrument should be very sharp and but slightly set; it requires to be guided very correctly in entering, and with no more pressure than the weight of its own frame, and it is commonly lubricated with a little lard, tallow, or other solid fat. 49. The cutler generally begins at the hollow, and having fixed that extremity parallel with the vice, with the curvature upwards, he saws off that piece which is too thin for his purpose, and then two or three parallel pieces to the lengths of some particular works, for which the thickness of the tooth at that part is the most suitable; he will then saw off one very wedge-form piece, and afterwards two or three more parallel blocks. In setting out the length of every section, he is guided by the gradually increasing thickness of the tooth; having before him the patterns or gages of his various works, he will in all cases employ the hollow for the thickest work it will make. As the tooth approaches the solid form, the consideration upon this score gradually ceases, and then the blocks are cut off to any required measure, with only a general reference to the distribution of the heel, or the excess arising from the curved nature of the tooth, the cuts being in general directed, as nearly as may be, to the imaginary centre of curvature. The greatest waste occurs in cutting up very long pieces, owing to the difference between the straight line and the curve of the tooth, on which account the blocks are rarely cut more than five or six inches long, unless for some specific object. In subdividing those blocks which are entirely solid, no great difficulty is experienced in those which are nearly solid, as in Fig. 50, the first step is to cut a central slice just thick enough to avoid the hollow, unless the pieces a b are required to have some particular size; c d would serve for leaves for minia- tures or veneering, and the remainder would be cut up of any required sizes, as sketched beyond c d. For square pieces of similar size, the block is cut into parallel slabs; for bevelled pieces, as the taper handles of knives and razors, the slabs are cut out wedge-form, the thick end of one against the thin end of the next, as at e f these slabs are afterwards divided with parallel or inclined cuts, either with the frame or the circular saw. In flat works, such as razor and knife handles, the broad surfaces, if cut radially, would show the edges of the rings or layers of the ivory; but cut parallel with the curve (If as the tangent, the grain is 5 Digitized by Google 34 ANIMAL MATTER USED IN THE ARTS. much less observable, and the ivory appears finer In the keys for pianofortes this is particularly at tended to; the finest broad keys are always cut upon the flat side of the oval, as atf, those upon the long diameter are cut into the narrow pieces called tails, (used between the black keys,) and the inter mediate parts are cut obliquely as at g; this causes much waste. For such pieces as have large hollows, more management is neces- 50. sary, as the thickness and curvatures of the material have to be jointly considered. When the hollows are thin, they are cut into squares or handles as large as the substance will allow; but on account of the circular section of the tooth, some of the pieces, if not all, must neces- sarily be angular or wedge-form; as regards pieces for the lathe, this is of little consequence. In all cases the ent. re division of the block or ring should be deter- mined upon, and carefully marked in pencil upon the end of the piece, before the saw is used. When the tusk is cut up exclusively for turnery-work, the first cut is more generally made where the hollow terminates, which spot is ascertained hy thrusting a small cane or a wire up the tooth; and every cut is directed as nearly as possible at right angles to the curve of the tusk, or to the centre of the circle, as before described. Unless the tooth is very far from circular, it is usual to prepare the principal quantity into cylinders or rings, as large as they will respectively d hold, and the diagrams, Figs. 51, 52, and 53, are intended to explain the b best mode of centreing the pieces, or placing them in the lathe. If, as in preparing an ordinary block of wood, a circle were made at each end, and the work were chucked from the centres of the circles, as at o, Fig. 51, the largest cylinder that could be obtained would 53. 52. 51. c b d be that represented by the four sides of the dotted rectangle within that figure. Very much less waste would result from placing the centres 80 much nearer to the convex side, as to obtain the cylinder rep- resented in Fig. 52, by allowing the waste to be equally divided between the points a, c, and e. It is however more economical, to cut those teeth which are much curved into the shortest blocks, and the Fig. 53, which represents the proportions more commonly adopted, shows the small comparative de- gree of waste that would occur in a piece of half the length of the others, when centred in the most judicious manner. The first process in preparing to rough-turn the block, is to fix it slenderly in the lathe between the prong chuck and the point of the popit-head, and its position is progressively altered by trifling blows upon either end, until when it revolves slowly, and the common rest or support for the tool is applied against the most prominent points a, e, and c, respectively, the vacancies or spaces opposite to each, at d,b, and f, shall be tolerably equal; 80 that, in fact, about a similar quantity may have to be turned away from the parts a, e, and c, for the production of the cylinder, represented by the dotted lines within the figure. The centres having been thus found, they should be made a little deeper with a small drill; and then the one end of the block being fixed upon the prong chuck, the opposite extremity, supported by the centre, is turned for a short distance slightly conical, ready for fixing in a plain boxwood chuck, or a brass chuck lined with wood, to complete the rough preparation, unless indeed it is entirely performed upon the prong chuck. With the decrease in length, less attention is requisite in the centreing, on account of the interference of the curvature of the tooth, and the pieces may be at once rasped to the circular form, and then chucked either in a hollow chuck, or else by cement or glue, against a plain flat surface. When the blocks of ivory are long and much curved, a thin wedge-form plate may be sometimes sawn from the end, in preference to turning the whole into shavings; the end is turned cylindrically for a short distance, just avoiding to encroach on the lower angle of the block, and as soon as practicable, a parting tool is used for cutting a radial notch for the admission of the saw, which may be then employed in re- moving a thin taper slice. The process is at any rate scarcely attended with more trouble than turning the material into shavings, and thin pieces are retained for a future purpose, such in fact as those repre sented beyond the dotted lines at the ends of the figures. The hollow pieces of ivory are treated much in the same manner as those which are solid, and into which latter condition they are sometimes temporarily changed, by rasping a piece of common wood, such as beech, to fit into the hollow, driving it in pretty securely, but so as not to endanger splitting the ivory the work is then centred as recently explained, the chuck and centre being in this case received in the wood. With the hollow pieces, the process of turning must be repeated on their inner surfaces, for which purpose a side cutting tool, with a long handle for a secure grasp, should be used: the toc! should be held very firmly, so as to withstand the jerking intermittent nature of the cut, until the irreg larities are reduced. For this purpose the aliding-rest is very desirable, as the tool is then held perfectly fast without effort Digitized by Google ANIMAL MATTER USED IN THE ARTS. 35 on the part of the individual, and if the chucking be correctly done, the greatest possible economy of the material is attained; the hand tools succeed very well on the outer surface, as the rest or support upon which they are then placed is 80 close to every point of the exterior surface, that they may be held se- curely with less effort, although the sliding-rest is nevertheless desirable there also. When the ivory hollow is thin, and far from circular, the material would be turned entirely into shavings, in attempting to produce a circular ring; the circular dotted lines in Figs. 43 and 44, are in- tended to explain this. Fig. 43 might be turned into an oval ring; but it is more usual to cut such irregular hollows into small square and round pieces, as explained. When thin rings or short tubes are required, they are frequently cut one out of the other in the lathe, in preference to wasting the material in shavings; this is done with the parting tool, as in Fig. 54; an incision being made of uniform diameter from each end, and continued parallel with the axis, until the 55. 54. two cuts meet in the centre; very short pieces may be thus divided from the one end only. When the rings are large and thin, it is desirable to plug them at one or both ends, with a thin piece of dry wood, turned as a plug to fill the diameter, and prevent the ivory from becoming oval in the course of drying. Fig. 55 explains the mode of preparing such an object as a snuff-box out of a solid block; that is, with the ordinary parting tool entered from the front, and the inside parting tool entered from within the incisions of which meet and remove a series of rings. The dotted lines represent the paths of the respective tools, the shaded parts the ring obtained, and the black lines the tools themselves. An apérture must necessarily be made in the centre, of a diameter equal to the extreme width of the tool but after the removal of the first, or central ring, a tool of considerably larger size may be used to ex- tract a much wider ring; and a little tallow or oil applied to the parting tools, will, in a great measure, prevent the shavings of the ivory from sticking to them and impeding their progress. Ivory requires a similar drying, or seasoning, to that recommended for wood; as when the pieces cut out of the tooth are too suddenly exposed to hot dry air, they crack and warp nearly after the same manner as wood, and the risk is the greater the larger the pieces; and on this account ornaments turned out of ivory or wood, especially those composed of many parts, should not be placed upon those chimney-pieces which, from their size, are so close to the fire as to become heated thereby in any sensi- ble manner. Notwithstanding the difference between the component parts of wood and ivory, and that the latter does not absorb water in any material degree, it is subject to all the changes of size and figure experi- enced by the woods, and in one respect it exceeds them, as ivory alters in length as well as width, whereas from the former change wood is comparatively free. The change, however, is very much less in the direction of the length than the width; this is particu- larly experienced in billiard-balls, which soon exhibit a difference in the two diameters, if the air of the apartment in which they are used differ materially from that in which the ivory had been previously kept. The balls are usually roughly turned to the sphere for some months before they are used, to allow the material to become thoroughly dry before being turned truly spherical; and in some of the clubs they even take the precaution of keeping the rough balls in their own billiard-room for a period, to expose them to the identical atmosphere in which they will be used. It may be asked, what means there are of bleaching ivory which has become discolored the author regrets to add that he is unacquainted with any of value. It is recommended in various popular works to scrub the ivory with Trent sand and water, and similar gritty materials; but these would only pro- duce a sensible effect, by the removal of the external surface of the material, which would be fatal to objects delicately carved by hand, or with revolving cutting instruments applied to the lathe. Perhaps it may be truly advanced, that ivory suffers the least change of color when it is exposed to the light, and closely covered with a glass shade. It assumes its most nearly white condition when the oil, with which it is naturally combined, is recently evaporated; and it is the custom in some thin works, such as the keys of pianofortes, to hasten this period, by placing them for a few hours in an oven heated in a very moderate degree, although the more immediate object is to cause the pieces to shrink before they are glued upon the wooden bodies of the keys. Some persons boil the transparent ivory in pearl- ash and water to whiten it; this appears to act by the superficial extraction of the oily matter as in bone, although it is very much better not to resort to the practice, which is principally employed to render that ivory which is partly opaque and partly transparent, of more nearly uniform appearance. It is imagined by some that ivory may be softened 80 as to admit of being moulded like horn or tortoiseshell: its different analysis contradicts this expectation; thick pieces suffer no change in boiling water, thin pieces become a little more flexible, and thin shavings give off their jelly, which substance is occasionally prepared from them. Truly, the caustic alkali will act upon ivory as well as upon most Digitized by Google 36 ANIMAL MATTER USED IN THE ARTS. animal substances, yet it only does 80 by decomposing it; ivory, when exposed to the alkalies, first be- comes unctuous or saponaceous on its outer surface, then soft, if in thin plates, and it may be ultimately dissolved, provided the alkali be concentrated; but it does not in any such case resume its first con dition. Ivory is not in all cases used in solid pieces, to which the foregoing remarks principally apply; but is frequently cut into thin leaves and glued upon fabrics of wood, for the manufacture of small orna- mental boxes, and works of various kinds, after the manner of the veneers of wood, or the plates of tortoiseshell; it is also used in buhl works, combined with ebony. Such thin plates are usually cut out of the solid block, parallel with the axis of the tooth, as at cd, in Fig. 50, with a fine feather-edge veneer saw; but the mode introduced in Russia for cutting veneers spirally from a cylindn al block of wood, with a knife of equal length, (as if the veneer were uncoiled like a piece of silk or cloth from a roller,) has been latterly applied to the preparation of ivory into similar veneers, converting the cylinder of ivory into one ribbon, probably by the action of a reciprocating-saw.* The modes pursued in these veneered works are analogour to those to be described in the article in reference to woods; it is, therefore, only necessary to a. d a few words on the white-fish glue, or " Diamond cement," as it is sometimes called, which is very often used for ivory-work, both in attaching ivory to ivory, and ivory to wood. This cement is made of isinglass, (which is prepared from the sound, or swimming-bladder of the sturgeon,) dissolved in diluted spirits of wine, or more usually in common gin. The two are mixed in a bottle loosely corked, and gently simmered in a vessel containing boiling water: in about an hour the isinglass will be dissolved and ready for use; when cold, it should appear as an opaque, milk-white, hard jelly; it is remelted by immersion in warm water, but the cork should be at the time loosened, and it may be necessary, after a time, to add a little spirit to replace that lost by evaporation. Isin- glass, dissolved in water alone, soon decomposes. Factitious ivory and tortoiseshell have been prepared in France in thin plates or veneers. Having adverted to many animal substances suitable to the mechanical arts, obtained from various inhabitants of the land and water, let me, in conclusion, mention some that are obtained from the feathered tribes-namely, the eggs of birds; which, although of limited application in the arts of em- bellishment, have at all ages served as models or standards of beautiful form. They may be made to answer in a very perfect manner for the bodies of vases, the feet and upper parts of which are turned out of wood or ivory for this purpose the egg-shells have been commonly used in their entire state, a hole having been made at the top and bottom for the extraction of their contents, and the attachment of the remaining parts. I have now the pleasure to bring before the reader a method of cutting the shells of the eggs of our various domestic fowls, and other birds, for the formation of vases with detached covers. In the accompanying drawing is represented the nose of a lathe, with an egg chucked ready for cut- ting. Fig. 56 is the section of a chuck for holding the eggs to prepare them for the chuck represented in Fig. 57. Fig. 56 is what is generally termed a spring chuck, 56. and is made by rolling stout paper, thoroughly moist- ened with glue, upon a metal or hard-wood cylinder, the surface of which has been greased to prevent the paper adhering to it, and upon which it must re- main until perfectly dry, when it may be removed, and cut or turned in the lathe as occasion may re- quire. This sort of chuck is very light, easily made, and well adapted for the brittle material it is intended to hold. Before fixing the egg in it, the inner surface should be rubbed with some adhesive substance, (common diachylon answers exceedingly well ;) when 57. a this is done, the egg should be carefully placed in the chuck, the lathe being slowly kept in motion by one hand, whilst with the other the operator must adjust its position, until he observes that it runs perfectly true; then, with a sharp-pointed tool he must mark the centre, and drill a hole sufficiently large for the wire in the chuck, Fig. 57, to pass freely through. B When this is done, the egg must be reversed, and the same operation repeated on the opposite end; 6 its contents must then be removed by blowing care- fully through it it is now ready for cutting, for which purpose it must be fixed in the chuck shown in Fig. 57, which is made as follows: A is a chuck of box, or other hard wood, having a recess turned in it at a b, into which is fitted a piece of cork, as a soft substance for the egg to rest against. B is a small cup of wood, with a piece of cork fitted into it, serving the same purpose as that in A. A piece of brass, d, is to be firmly screwed into the chuck A, and into that a steel wire, screwed on the outer end. Monsieur H. Pape, of Paris, planoforte manufacturer, has taken out patents for this method of cutting ivory spirally into sheets. A specimen, 17 inches by 38 inches, and about one-thirtieth of an inch thick, glued upon a board, may be seen at the Polytechnic Exhibition in Regent-street, and M. Pape advertises to supply sheets as large as 30 by 150 inches. He has veneered a pianoforte entirely with ivory. Digitized by Google ANTHRACITE COAL. 37 ANTHRAOITE COAL The annexed table, taken Horse Pounds Horse Pounds Horse Pounds from O. E Leonard's valuable work, The Mechanical Power. Coal. Power. Coal. Power. Coal. Principia," shows the usual consumption of coarse an- thracite coal a day, by different-sized engines. The 4 168 38 1596 70 2940 column marked " Horse Power" shows the horse power 6 252 40 1680 72 3024 of the engines, the column marked "Pounds Coal" 8 836 42 1764 74 3108 shows the number of pounds consumed a day of 12 10 420 44 1848 76 3192 hours. Example: the number of pounds of anthracite 12 504 46 1932 78 3276 coal used in a day, to supply an engine working 40 14 588 48 2016 80 3360 horse power, is 1680. Again: let it be required to find 16 672 50 2100 82 3444 the number of pounds of anthracite coal per day, to 18 756 52 2184 84 3528 supply an engine working 100 horse power. Find 100 20 840 54 2268 86 3612 in the column marked Horse Power," opposite to this 22 924 56 2352 88 3696 number in the column marked Pounds Coal," will be 24 1008 58 2436 90 3780 found 4200 pounds. 26 1092 60 2520 92 3864 The following table is calculated principally for the 28 1176 62 2604 94 3948 Southern States, where the Southern Pine is used for 30 1260 64 2688 96 4032 fuel instead of coal; the column marked Horse 32 1344 66 2772 98 4126 Power," shows the number of horse power the engine 84 1428 68 2856 100 4200 is working; the column marked Cords," shows the 36 1512 number of cords that the engine consumes per day (12 hours;) the column marked "Hours," shows the number of hours per day, which the engine is supposed to run. EXAMPLE-Required the number of cords of South- ern Pine to drive three run of 41 feet stones grinding Horse Horse Power. Cords. Hours. Power. Cords. Hours. corn, the number of horse power required being about 45. Find 45 in the column marked Horse Power," 4 t 12 45 opposite to this number in the column marked Cords," 51 12 6 1 " 50 6 " will be found 51 cords. 8 1 " 55 6.1 a EXAMPLE-An engine is working 25 horse power 10 11 " 60 71 66 required the number of cords the engine will consume 12 11 " 65 8 " per day (12 hours.) Find 25 in the column marked 14 14 " 70 81 " Horse Power," opposite to this number in the column 16 2 " 75 91 " marked Cords," will be 3 cords. 18 21 " 80 94 " ANTHRACITE COAL, use of in locomotives. See 20 21 " 85 10} " MANAGEMENT OF LOCOMOTIVES. 25 8 " 90 11 " ANTIMONY. See METALS AND ALLOYS. 30 ANVIL See FORGING. 81 " 95 111 " 35 41 " 100 121 " APPLE-TREE See WOODS, varicties of. 40 44 " APRICOT-TREE See WOODS, varieties of. APS. See WOODS, varieties of. AQUEDUCT WIRE SUSPENSION, over the Allegheny River at Pittsburgh.-This work, recently constructed under the superintendence of John A. Roebling, the designer and contractor, has supplied the place of the old wooden structure which originally was built by the State of Pennsylvania at the west- ern termination of the Pennsylvania Canal. The council of the city of Pittsburgh, by whom, in consequence of an arrangement with the State, the tolls on this aqueduct are of late received, and who are bound to keep the work in repair, decided on re- building, and after considering various plans, adopted that of Mr. Roebling, and entered into contract with him to reconstruct the communication, for the gross sum of $62,000, including the removal of the old ponderous structure and the repair of the pier and abutments; a very small sum indeed for a work of such magnitude. As this work is the first of the kind ever attempted, its construction speaks well for the enterprise of the city of Pittsburgh. The removal of the old work was commenced in September, 1844, and boats were passed through the new aqueduct in May, 1845. This work consists of 7 spans, of 160 feet each, from centre to centre of pier. The trunk is of wood, and 1140 feet long, 14 feet wide at bottom, 16} feet on top, the sides 81 feet deep. These, as well as the bottom, are composed of a double course of 21 inch white-pine plank, laid diagonally, the two courses crossing each other at right angles, 80 as to form a solid lattice-work of great strength and stiffness, suf- ficient to bear its own weight and to resist the effects of the most violent storms. The bottom of the trunk rests upon transverse beams, arranged in pairs, four feet apart; between these, the posts which support the sides of the trunk are let in with dovetailed tenons, secured by bolts. The outside posts, which support the sidewalk and towpath, incline outwards, and are connected with the beams in a sim- ilar manner. Each trunk-post is held by two braces, 21 X 10 inches, and connected with the outside posts by a double joint of 2}X10. The trunk-posts are 7 inches square on top, and 7 X 14 at the heel; the transverse beams are 27 feet long and 16X6 inches the space between two adjoining is 4 inches. It will be observed, that all parts of the framing are double with the exception of the posts, so as to admit the suspension rods. Each pair of beams is supported on each side of the trunk by a double suspension rod of 1 fth inch round iron, bent in the shape of a stirrup, and mounted on a small cast-iron saddle, which rests on the cable. These saddles are connected, on top of the cables, by links, which diminish in size from the pier towards the centre. The sides of the trunk set solid against the bodies of masonry, which are erected on each pier and abutment as bases for the pyramids which support the cables. These pyramids, which are constructed of B blocks of a durable, coarse, hard-grained sandstone, rise 5 feet above the level of the sidewalk and towpath, and measure 3 X 5 feet on top, and 4 X 6f feet at base. Digitized by Google 38 AQUEDUCT, WIRE SUSPENSION. The sidewalk and towpath being 7 feet wide, leave 8 feet space for the passage of the pyramids. The ample width of the tow and foot path is therefore contracted on every pier; but this arrangement proves no inconvenience, and was necessary for the suspension of the cables next to the trunk. The caps which cover the saddles and cables on the pyramids rise 3 feet above the inside or trunk railing, and would obstruct the free passage of the tow-line; but this is obviated by an iron rod which passes over the top of the cap and forms a gradual slope down to the railing on each side of the pyramid. 58. The wire cables, which are the main support of the structure, are suspended next to the trunk, one on each side; each of these two cables is exactly 7 inches in diameter, perfectly solid and compact, and con- structed in one piece from shore to shore, 1175 feet long; it is composed of 1900 wires of fth inch thick- ness, which are laid parallel to each other. Great care has been taken to ensure an equal tension of the wires. Oxidation is guarded against by a varnish applied to each wire separately; their preservation, however, is ensured for certain by a close, compact, and continuous wrapping, made of annealed wire, and laid on by machinery in the most perfect manner. A continuous wrapping is an important improve- ment, which, in this case, has been for the first time successfully applied. A well-constructed and well-wrapped cable presents the appearance of a solid cylinder, which in strength greatly surpasses a chain made of bars of the same aggregate section or weight. It is not only the great relative strength of wire which renders it superior to bar-iron; but its greater elasticity, which ena- bles it to support strong and repeated vibrations, adds still more to its value as a material for bridge building. The extremities of the cables do not extend below ground, but connect with anchor chains, which, in a curved line, pass through large masses of masonry, the last links occupying a vertical position. The bars composing these chains average 11 inches, and are from 4 to 12 feet long; they are manufactured of boiler scrap, and forged in one piece without a weld. The extreme links are anchored to heavy cast-iron plates of 6 feet square, which are held down by the foundations, upon which the weight of 700 perches of masonry rests. The stability of this part of the structure is fully ensured, as the resistance of the an- chorage is twice as great as the greatest strain to which the chains can ever be subjected. The plan of anchorage adopted on the aqueduct varies materially from those methods usually applied to suspension bridges. where an open channel is formed under ground for the passage of the chains. On the aqueduct, the chains below ground are imbedded, and completely surrounded by cement. In the construction of the masonry, this material and common lime-mortar have been abundantly applied. The bars are painted with red-lead. Their preservation is rendered certain by the known quality of calcareous cements to prevent oxidation. If moisture should find its way to the chains, it will be saturated with lime, and add another calcareous coating to the iron. This portion of the work has been executed with scrupu- lous care, so as to render it unnecessary on the part of those who exercise a surveillance over the structure to examine it. The repainting of the cables every 2 or 8 years, will ensure their duration for a long period. Where the cables rest on the saddles, their size is increased at two points by introducing short wires, and thus forming swells, which fit into corresponding recesses of the casting. Between these swells, the cable is forcibly pressed down by three sets of strong iron wedges, driven through openings which are cast in the side of the saddle. When the merits of the suspension bar were discussed previous to the commencement of the structure, doubts were raised as to the stability of the pyramids and the masonry below, when unequal forces should happen to disturb the equilibrium of adjoining spans. It was then proved by a statistical demonstration, that any of the arches with the water in the trunk, could support an extra weight of 120 tons, without disturbance to any part of the work. In this examination, no allowance at all was made for the great resistance of the wood-work, and the stiffness of the trunk itself. During the raising of the frame-work, the several arches were repeatedly subjected to very considerable unequal forces, which never disturbed the balance, and proved the correctness of previous calculations. The stiffness and rigidity of the structure is 80 great, that no doubt is entertained that each of the several arches would sustain itself in case the wood-work of the next one adjoining should be consumed by fire. The wood-work in any of the arches separately may be removed and substituted by new ma- terial, without affecting the equilibrium of the next one. The original idea upon which the plan has been perfected, was to form a wooden trunk strong enough to support its own weight, and stiff enough for an aqueduct or bridge, and to combine this structure with wire cables of a sufficient strength to bear safely the great weight of water. The plan of this work, therefore, is a combination which presents very superior advantages, viz. great strength, stiffness, safety, durability, and economy. Digitized by Google AQUEDUCTS. 39 This system, for the first time successfully carried out on the Pittsburgh aqueduct, may hereafter be applied, with the happiest results, to railroad bridges, which have to resist the powerful weight and great vibrations, which result from the passage of heavy locomotives, and trains of cars. REMARK-The quantities in the following table are calculated for a depth of water of 4 feet, which has been in the aqueduct ever since the opening. The depth contemplated was 31 feet; the greater depth is at present required on account of the raising of the bottom of the canal by bars and sediment, which have to be removed before the level can be lowered. Table of Quantities on Aqueduct. Length of Aqueduct without extensions, 1,140 feet. Length of cables, 1,175 " Length of cables and chains, 1,283 " Diameter of cables, 7 inches. Aggregate weight of both cables, 110 tons. Section of 4 feet of water in trunk, 59 sup. feet. Total weight of water in aqueduct, 2,100 tons. " " " one span, 295 " Weight of one span, including all, 420 " Aggregate number of wires in both cables, 3,800 Aggregate solid section of both cables, 58 sup. inches. " " anchor chains, 72 64 " Deflection of cables, 14 feet 6 inches. Elevation of pyramids above piers, 16 feet 6 inches. Weight of water in 1 span between piers, 275 tons. Tension of cables resulting from this weight, 392 " Tension of one single wire, 206 lbs. Average ultimate strength of one wire, 1,100 lbs. Ultimate strength of cables, 2,090 tons. Tension resulting from weight of water upon 1 solid square inch of wire cable, 14,800 lbs. Tension resulting from weight of water upon 1 square inch of anchor chains, 11,000 lbs. Pressure resulting from weight of water upon one pyramid, 1871 tons. " " " one superficial foot, 18,400 lbs. AQUEDUOTS, MODERN. Of the aqueducts erected within a comparatively modern period, we may mention the following :-The aqueduct of Spoleto, constructed in 741 by Theodoric, king of the Goths. to communicate with the town of Spoleto, situated on the summit of a mountain. It is one of the handsomest structures of the kind, and remains entire to the present day. In crossing the river De La Morgia, the channel-way is supported upon two tiers of Gothic arches, the lower containing ten grand arches, and the latter thirty. The length of this arcade is 800 feet, the breadth 44, and the height 420! The aqueduct of Caserta, built in 1753 by Charles IIL of Naples, is also an expensive and gigantic structure, one of its arcades consisting of three tiers of arches, 1724 feet long, and 190 feet in height. In France, that which conducts the waters of St. Clements and Du Boulidou to Montpelier, is perhaps the must beautiful. It was built under the superintendence of M. Pitot, and required thirteen years for its completion. The principal arcade is 90 feet high, and consists of two tiers-the lowest containing 90, and the upper 210 arches. That of Arcueil deserves next to be noticed. It was originally built by the Emperor Julian, A. D. 360, to bring water to Paris, and supplied the palace and hot-baths, but was destroyed by the Normans. After it had been in disuse for 800 years, it was rebuilt in 1634 again repaired in 1777; and fresh sums have lately been devoted to the same purpose by the city of Paris The arcade over the valley of Arcueil consists of 25 arches, is 72 feet high, and 1200 feet long. Of recent aqueducts, that of Lisbon and that of New York are the only two deserving notice. The former, completed in 1738, is about three leagues in length, and in some parts of its course has been excavated through hills; but near the city it is carried over a deep valley, for a length of 2400 feet, by several bold arches, the largest of which has a height of 250 feet, and a span of 115 feet. AQUEDUCT, CROTON. The Croton river rises in Putnam county in three springs, whose rivulets unite near Owentown; its water is increased by the surplus of several lakes, which collect the water of the country by different small streams above and under ground. The principal branches being united with the river, it receives still more water from a number of small brooks which fall into it from both sides, till after many turns and windings it disembogues into the Hudson river below Tellers Point, 40 miles above New York. It may be useful, in describing the engineering work, to know the geological formation of the ground through which it passes, as well as of the adjoining regions. The predominant rock of the country is gneise, a continuation of the formation which runs through the Northeastern States. Its quality varies from the hardest granite suitable for every building material, down to a loose laminated mica-slate. On the surface of the rock there are various impressions; in some of them large masses of white marble are deposited, from which a superior building material is taken without much labor. The gneiss strati- fication shows clear signs of some very violent revolutions; within the extension of one mile it dips in every direction, and appears to have been forced up in some places through lateral pressure, by violent concussions and shocks, and in some parts the layers are even broken. Here and there the gneiss-rock lies exposed, or is covered in part as high as 50 feet with diluvium and alluvium mixed with boulders of granite and trap, the latter proceeding from the right shore of the Hudson river, where it stands upon red sandstone. The surface of the ground is traversed at short distances by every impediment which can render the construction of an aqueduct difficult hills of 600 feet above the level of the sea rise with every variety of slope, side by side with valleys of little or nothing above sea-level. The great Digitized by Google 40 AQUEDUCT, CROTON. extension of this rock-ground offered excellent foundations, but the cutting it away and driving a number of tunnels increased the expense very much. Two different routes for the conduit-canal were proposed, the inland-route and the Hudson-route the first commenced near the village of Mechanicsville, ran along the valley of Muddy-Brook, traversed the ridge, went through New Castle valley, then the valley of Saw-mill river, and, by means of an aqueduct bridge, crossed Harlem river to the city. From its commencement to the distributing reservoir in 38th street, this line had an extension of 43 miles, retained a head of 117 feet, and a capacity of 27000000 gallons every 24 hours. The Hudson route started from the same point, ran along the left shore (look- ing downward) of the Croton and the left shore of the Hudson river. The length of this line amounted to 47 miles, and the estimate of cost was 4768197 dollars; on both the routes the water was to be conducted in an arched aqueduct. On the 5th of September 1833, the water was gauged by Mr. Douglass at Mechanicsville the produce was 51522480 gallons every 24 hours. From some circumstances and from information collected from persons living in the vicinity, he was induced to deduct one-fifth of this amount, which left 44120924 gallons of daily flow as minimum for all seasons. On the 25th September a gauge was made by the Civil Engineer, Mr. Albert Stein. He found— Gallons. At Pine's bridge 57101068 One mile above Pine's bridge 49971686 Two miles above Pine's bridge 49276080 Three miles above Pine's bridge, at Mechanicaville 47959344 204608178 or 51077044 gallons every 24 hours as average, differing only by a few hundred gallons from the Douglass statement. The observations and information gained, induced him to deduct 4 inches of depth from the surface, in order to meet extraordinary droughts, which reduced the quantity as follows: 28731715 gallons 23186908 83004800 = 32707066 " 117630489 " or 29407622 gallons on an average every 24 hours. During the uncommon drought, prevailing in the summer of 1838-the work of the aqueduct being under construction already-the water in the Croton river was remarkably low. Mr. Horatio Allen having made a gauge of the quantity of water, there was found at one point 26886560 gallons, and at another 28738000 gallons; averaging 27562280 gallons every 24 hours, which came nearest to the Stein estimate. The quality of this water exhibited, above all the waters of the neighborhood, the greatest purity and its mineral contents in the gallon of 10 pounds or 57600 grains weight, were only 2.8 grains of carbonate of lime and magnesia, which amounts not to the 20000th part of the whole; besides an admixture of 2 grains of vegetable matter, which was supposed to fall on the bottom. In company with the engineers Martineau and Stein, the water commissioners re-examined the ground and the plans; in consequence of which, the place for the dam was fixed 6 miles lower than the point proposed by Major Douglass. Difficulties arose between Mr. Douglass and Mr. Stephen Allen, the chairman of the water commissioners, 80 that the friendly relations existing between these gentlemen ceased in consequence; Mr. John B. Jervis was charged with the execution of the work, a practical and experienced engineer, who had been previously engaged in the execution of state canals. The line of the aqueduct was portioned off into 4 divisions of 10 to 11 miles extent each, by Mr. Jervis the chief engineer. 1st division contained the dam, and stretched some distance below Sing-Sing, the 2d to Cook's run, the 3d to Fordham Church, and the 4th to the distributing reservoir. The whole amount of the work was given out in 99 Sections, one after the other, under contract. THE CROTON Dam-At the above-mentioned point, the dam was erected in order to raise the water, and to form the Croton lake. Fig. 61 shows the profile of the river. At first a length of only 90 feet was given for the dam B, and this part was erected after the profile of Fig. 59, with a con- struction similar to that of Fig. 62, extending then only from a to b, Fig. 61, occasion for which was given by the rock lying here affording a good foundation: the remainder of the river profile to d, was to be filled with an earth embankment. A considerable freshet, however, carried away this embankment when partly completed, and it was resolved to extend the stone dam 180 feet further, to c. For the erection of this part, A, Figs. 61 and 62, the bottom of the river was cleared from mud and boulders, and the piers C and D, of 12 inch hemlock timber, successively built up; the walls were connected together by ties, and filled with stone closely packed in; the top was covered with six-inch plank of white pine, and treenailed upon this planking, the timber-piers F and G were erected, but only F covered with plank. While erect- ing those piers, the space E was filled with concrete, and the piers near the top connected with ties. Both these piers, together with their filling of concrete, being the armature of the dam, served at the same time for a coffer-dam against the water above. Against G, another timber pier was in like man- ner constructed, with but one timber wall; in place of the other, anchors of round timber were laid in, and with the ties joggled together. The timber of these piers is of hemlock, 12 inches by 12, the ties of white oak, 7 inches thick at the smaller end, framed with single dovetails 4 inches thick, Fig. 65, and fastened with one-inch treenails, which are placed 10 feet from centre to centre. The pier-timbers, Figs. 63 and 66, are treenailed 80 inches deep, with 2-inch treenails of white oak. These nails are sometimes put nearer together, and the ties likewise. The planking is of white pine. When the timber piers had reached a certain height, the piers KK, of four compartments, were put down, two of which, the nearest to low water, were packed out with stone; the two others were filled with concrete, and formed the coffer- dam against the water below the dam. The courses were of 12 by 12 inch hemlock; the ties of oak, 8 Digitized by Google 41 Granite 1 59. 61. a B c Earthd B Digitized by Google Tunnel puv Alluvium with boulders Aqueduct CROTON LAKE gnelss rook b 55 duct Profile at B Radius of 60. and Original bottom 66. Secondarydam ofCroton-river Fore Embankment Profile at A. Itm AQUEDUCT, CROTON. Elm White oak 6 63. W.oak 2 White W.oak W. elm 64. White clm & 62. oak E W. oak 65. y-ss & Lak embankment Fore of earth Rear of Aprons 67. Top line of Secondary Dam Bond of stone infaceofweir Dead water 3m 35 SCALE.-One inch=20 feet. One inch=8 feet. Natural ground of 24 42 AQUEDUCT, CROTON. inches at the smaller end, and 6 feet apart from centre to centre the treenails of the equared timber the same. The uppermost of them are made of elm and white oak, treenailed every 3 feet, 30 inches deep, 21 inches in diameter. The upper ties, Figs. 64 and 66, are of elm 12 inches square; to this course of ties a bed timber of white elm is joggled and secured by iron screw-bolts, Fig. 66. Across these bed timbers or caps, an apron-planking of 6-inch elm is fastened by 1}-inch locust (robinia pseudo acacia) tree- nails of 13 inches in length. Against the rear of this timber pier the one marked L was erected; against the back-water only, it has a regular timber wall, Fig. 63: the ties are secured by anchora. A part of the apron planking of this pier is laid horizontally in connection with the apron of the pier K; the remainder is put three feet lower, Fig. 62. After the pit had been laid dry by pumps, the ground and the space at f were filled in with concrete and levelled off. On this bed the body of the dam was by degrees erected of hydraulic stone-masonry, according to the bond, Fig. 67, and the courses of face-stone for the weir laid down. This face-work is of granite, cut with such closeness as to allow the stone to be laid with a joint not exceeding three-sixteenths of an inch. The masonry is laid in horizontal courses to 3 feet from the extrados of the face-work, where it is in courses corresponding with the radii. In front of the lip of dam below the head-water, a fore-embankment, Figs. 59, 60, and 62, was formed of earth, and its upper part secured with a dry stone-pavement 2 feet thick. In the part of the dam first erected, B, Fig. 61, at b, and Fig. 60 at b, a waste-weir is constructed, in order to draw off the water of the lake from a greater depth; it consists of a well with culverts having two sets of gates, all of which are protected with a small stone-house, Figs. 60 and 61, at b; which can be reached by the bridge B, Figs. 59 and 61. At a distance of 300 feet from the lip, a secondary dam, Figs. 59 and 60, is constructed it is erected of round timber, filled up with dry stone. The object of this secondary dam is to divide the head of water, and by means of the water-basin formed by it, to break the body of water running over the weir, and to keep the wood-work of the timber-piers K and L, under water. Near the left shore a waste- weir is constructed in this dam, in order to let off the water from the basin when required. By the construction of the Croton dam the water was raised 40 feet, whereby the river passed its shores and formed the Croton lake: this is the collecting-reservoir of the aqueduct, containing in it, at a depth of 6 feet, 500000000 gallons of disposable water, above the level that would allow the aque- duct to discharge 35000000 gallons per day ;-sufficient for 1750000 inhabitants, at the rate of 20 gal- lons daily per head, including manufactories, shipping, watering streets, gardening, baths, &c. The flow of the Croton is about 27000000 gallons in 24 hours, at the lowest stages, which continues, with mode- rate rains, from two to three months in the year. Whenever the wants of the city may require the above-mentioned amount, it will be necessary to draw from those 500000000, daily, 8000000 to make up these 85000000. The amount of the reservoir would thus afford a supply for 621 days. Never has the water in summer been 80 low. The supply of the Croton from its daily flow, aided by the reser- voir, may therefore be taken, with great confidence, at 85000000 gallons; and when the day arrives that will require a larger quantity, it may be obtained by constructing other reservoirs further up the stream, where there are abundant facilities for such purposes. PROFILE OF THE AQUEDUCT.-At the first consideration of the adopted plan, to conduct water from the Croton river, an open trapezoidal canal was proposed. The flow of the water over earth and rock might, however, impregnate the conduit-water therewith;-and as a good deal might sink into the bot- tom, it became necessary to make the bed waterproof; to do this with tight earth seemed insufficient, though brick with concrete under it might answer. The open canal remained, however, exposed to the sun and to evaporation, as well as to the wading of cattle, to bathing, and to being filled up with earth, boulders, and snow washed in; and might, in fine, freeze out in winter; it became necessary, therefore, to cover it, as had been found indispensable already, at deep-cuts, and in the vicinity of villages. A protection with a kind of wooden roof was some time under discussion, (seeming economical,) having the deep-cuts and tunnels arched. This mode of roofing, however, did not seem impenetrable to frost and heat; it was resolved, at last, to arch the whole, notwithstanding the great expense. The artificial Croton lake stretches more than 5 miles on the line of the original bed of the river, which makes the total length of the whole work amount to 50 miles. The regulation of all the measurements in heights and depths was taken from a grade-line or planum which is 7 inches below the intrados of the inverted arch at the bed of the aqueduct, being the base- line or basis-surface of the aqueduct-masonry, in cuttings into the natural ground. LENGTH, INCLINATION, AND GRADE-The fall of the aqueduct on the continent is 0.021 per hundred, or 1.1088 feet per mile. The roofing-arch follows accurately this inclination, except a distance of 2276 feet next the dam, which runs horizontally at the height of the lip of the dam. At the entrance, 2.93 feet were added to the height, which brought this to 11 feet 5 inches in the clear, (Fig. 62.) From the lower intrados the inclination is 0.0118 per 100, or 0.59664 feet per mile, at a distance of 4.949 miles, where it meets the general inclination and the profile of the aqueduct, as shown in Figs. 68, 69, 70 This arrangement, which, in a certain way, can be considered as an extension of the lake. renders it pos- sible to draw water from a depth of 11 feet 5 inches, and to carry it, under influence of its head, with less fall, over this distance. At the level of the lip of the Croton dam the aqueduct has still a capacity to draw off 85000000 gallons every 24 hours, as experiment has shown. Digitized by Google AQUEDUCT, CROTON. 43 Table of Lengths and Inclinations. Distances in Fall in feet. Miles. Feet. From the dam to the meeting of the general inclination 4.9490 26130 2.9507 From here to Harlem river the general inclination 0.021 per 100 or 1.1088 feet per mile of 5280 feet 27.9316 147479 30.9700 At the aqueduct-bridge of Harlem river to the general inclination 2 feet are added, the water being carried over in pipes by a siphon of 12 feet 0.2750 1450 2.3450 To Manhattan valley the general inclination of 1.1088 feet per mile 2.0140 10635 2.2334 Across Manhattan valley the water passes in a siphon of 109 feet head, for that reason 8 feet are added to the general inclination 0.7917 4180 3.7783 From here to the receiving-reservoir 9 inches per mile 2.1727 11471 1.6295 From the influence-gate of this reservoir to its effluence- gate 0.1720 908 0.0000 To the distributing-reservoir the water is carried in a si- phon by pipes; for the entire distance 2.1760 11489 4.0000 Distributing-reservoir 0.0800 420 0.0000 These 47.9069 feet form the fall at the bottom of the aque- 40.5620 47.9069 duct; at the head this bottom is 11.4633 F. below the surface of the lake, but only 8.2000 " at the discharge in the receiving-reservoir which gives 3.2633 64 3.2633 difference, added to the fall at bottom; this makes the entire fall, or the accurate difference between the surface of the Croton lake and that of the distributing-reservoir 51.1702 When to this extension of the aqueduct that of the large mains is added, which is about 4.0000 we have the following as the entire length of aqueduct from its head to the distribution of the water, viz. :- 44.5620 CONSTRUCTION OF AQUEDUOT-CANAL-Where the masonry of the aqueduct is cut in level ground or side- hills, a course of concrete 3 inches high is laid under the whole extent of masonry under the extrados of the inverted arch, as high as the shape of the extrados required. Where water-veins were met, and in loose ground, or where the depressed ground made foundation walls necessary, the concrete bedding was put 12 inches high as broad as the clear width of the aqueduct; but under the side walls only 6 inches. In both cases each of the side walls was carried up 13 inches high perpen- dicularly, by which the spring-line of the inverted arch was reached; after this the inverted arch was turned 1 a brick 4 inches thick, the stone part of the side walls carried up 4 feet high, and on both sides plastered 1 inch thick with hydraulic mortar. When these walls had set, the inner facing, I a brick 4 inches thick, was carried up; at last the roofing-arch, 1 brick 8 inches thick then the span- dril-backing, over which and the upper part of the extrados, plaster of i inch thickness was laid on and smoothed off with the trowel. Where suitable stone was to be had near, the side walls could be car- ried up; also the roofing-arch, which in this case was turned 12 inches thick; this, however, has been carried into execution in but few instances. The courses of masonry were levelled off every 12 inches, and no stone put in which reached through the wall or raised over the course of 12 inches; granite, or gneiss of the most sound quality, was used. The hydraulic mortar at tunnels, deep-cuts in earth and rock, had the proportions of 1 part cement to $ sand upon foundation-walls, however, 1 part cement to 21 sand in volume; the same proportion for concrete. The sand for concrete, containing coarse and fine grains, was first mixed with water, then there was added to it from 2 to 21 broken stone of the size of 11 inch, or the same amount of coarse gravel, and worked till the mass became uniform, and the broken stone completely covered and bedded in the mortar. Immediately after this preparation the concrete was laid and settled with a stamper till the surface had the appearance of an even floor the courses were laid not over 6 inches thick. For brick masonry the proportion of cement to sand was 1 to 2; the mortar for vertical joints was put to the brick before laid, the brick forced into its bed in such a manner, that from horizontal and vertical joints the mortar readily is forced out like sausages; the superfluous mortar was then taken off and the joints smoothed immediately: only bricks of superior quality were admitted, No. 1 for the inverted arch and the facing, No. 2 for the roofing-arch. CULVERTS.-In order to carry off rivers, creeks, and field-waters, underneath the aqueduct, culverts were constructed at a suitable depth. Their fall or inclination was 1 in 20; and where the upper end happened to be below the surface of the ground, generally the case at side-hills, a well was constructed, Figs. 76 and 79. The culvert, Figs. 79, 80, and 81, is one of the smallest dimensions, with bottom and roof of stone alabs; that of Figa. 76, 77, and 78, is a large one, bottom and roofing are of smooth, well- wrought stone, the side-walls only faced with it, while the backing of this face-work is of rough masonry. Digitized by Google 44 AQUEDUCT, CROTON. Tunnel 68. Bulk-head LipolDam a 11'5" * * F 70. ton lake M & * 69. Agreduct & 6 71. Aqueduct & Regulating gates Guard-gates Screen Enzme Tunnel 20 I 180 long 72. SCALE.-1 inch = 40 feet. Digitized by Google AQUEDUCT, CROTON. 45 In the body of the foundation-wall of the aqueduct, an arch of dry stone without mortar was rolled over the extrados of culvert, Fig. 78; after this the foundation carried further up. The fall-well at the arched culverts is round in plan, Fig. 77. THE GATEWAY.-From the effluence of the lake, Figs. 59 and 61, a tunnel is cut through solid rock, 180 feet in length. It has no facing of masonry, and in dimensions is kept somewhat larger than the general aqueduct, only below the gateway, Fig. 70, it takes the dimensions as marked, Fig. 62, except the height, which is here greater. The ground is uncommonly favorable for the construction of the gateway, offering roek-foundations throughout. As shown, Fig. 71, the channel "of the aqueduct is widened, and the water runs through an arch in the bulkhead a a, then passes the screen-frame, a set of guird-gates, and a set of regulating gates. The screen, formed of oak slabs, six inches by one, allowed a quantity of fish to pass through the one-inch spaces into the aqueduct. In order to prevent this, a fine brass netting was put over the screen, through which only very small fish could pass; to prevent which other artificial preparations will be required. Below the wall with the regulating gates, the width of the water-way is reduced to the general width of the aqueduct, by an ogee curve, in order to let the water into the proper aqueduct without any loss of fall. The guard-gates with their frames are of cast-iron, made as shown in Fig. 97 a is the frame lined with metal. The sill is marked here let in stone, but in the case under description it is cut something into the wooden floor; b is the shover with the consols c c through which the wrought-iron rod dd passes-the latter has a screw cut at its upper end ec is a nut, which is let into the caps and screwed. By turning right or left with a key put on the die, the rod rises or lowers, and the gate is opened or shut. On account of the considerable length of the rod, the guides k k, Figs. 69 and 70, are put on they consist of cases of wrought-iron, leaded into the stone of the wall. The regulating gates with their frames are of gun metal, in order to obtain a superior tightness. The caps ff, Fig. 70, are secured upon the saddles by bolts. In turning to the left the female, whereby the shover is raised, the saddles with the caps press upon the base and are kept closer and closer upon their bed; in screwing right, however, they press upward. To prevent their loosening and lifting, the screw-bolts n n n are put in; they reach down through two courses of stone, and there they are bent; some of them are secured to the caps of the screen-frame. In shutting the gates by turning to the right, the bolts n n secure the caps ff to their places and prevent their lifting. The masonry in all parts of the gateway is of rough gneiss in hydraulic mortar, faced with well-hammered stone the partitions between the gates are of cut stone. To keep the gates and utensils secure, a stone house is erected over the gateway. LINE OF AQUEDUCT-Having left the gateway, the aqueduct makes its way upon the left bank of the Croton river. After a course of one mile, it crosses Lounsberry's brook, over a culvert of 6 feet in width, 66 feet in length, the bottom of which lies 44 feet below the top of the back-filling of aqueduct. After crossing some little brooks with small culverts, the line leaves this river, having followed it for 5 miles, turns to the left and crosses the valley of India creek 6 miles from the dam; the culvert for the passage of this stream is 8 feet wide, 142 feet long, and its bottom is 58 feet below the top. A little distance further, the aqueduct is tunnelled through two hills of solid rock. The first passage, called Benvenue farm tunnel, is 720 feet in length; the second, Acker's brook tunnel, is 116 feet long. Half a mile further is another tunnel of 276 feet in length, called Hoag's hill tunnel, cut through rock. From here to Sing-Sing, several small valleys and ravines of from 20 to 32 feet in depth are crossed by the aqueduct. Immediately after the last one, there is another tunnel worked through rock, called Sing-Sing tunnel. SING-SING KILL BRIDGE-Was commonly called, while in construction, the passage of the aqueduct across the valley of the Kill river. Although the Kill is merely an unimportant brook, by frequent freshets it has worn out a large chasm, the depth of which from the top of the aqueduct to the rock bottom is 82 feet; the width measured at the top is 536 feet. Parallel to the river runs a street of the village of Sing-Sing, over which an aqueduct bridge of 20 feet in width was constructed; a little further the line of the aqueduct cut off the dwelling-house from the rest of the farm of Mr. Sing, where a pas- sage-way 7 feet wide was constructed. Across the stream an arch of 88 feet span was required. The abutment walls of this bridge are 20 feet thick, on solid rock-foundation. The arch is constructed over an half oval, 33 feet in height, 4 feet thick at the spring-line, and 3 feet at the keystone; the granite and gneiss for it was cut with much accuracy, not allowing the joints to be over three-sixteenths of an inch thick. The spandrils were carried up solid, sloping upward, thence with hance walls and alternating openings, till 3 inches over the highest point of extrados: these openings were arched over with half a brick. Across those openings, the hance walls were connected together by bond stone. On the top of the small brick arches, a rubble masonry of 6 inches in height was laid, and the whole levelled off; on this the concrete course of 9 inches height to the extrados of the inverted arch of aqueduct. As far as the clear width of the bridge arch and its abutments extended, the construction of the aqueduct was 80 altered, that the side-walls were carried up 5 feet high instead of 4, as in ordinary aqueduct, and the arch was turned over a segment of 7 feet 7 inches long, 2 feet 81 inches high. Bottom and side walls were provided with a lining of cast-iron in form and dimensions, worked in with the masonry whereby the aqueduct was rendered absolutely water-tight above these constructions. The same iron lining was applied also at the before-mentioned street bridge. Between the attic wall and the side wall of the aqueduct, spaces were left, covered over, above the attic wall, carried up in connection with the side walls of the aqueduct, and covered with a coping stone, the whole then filled over with earth. The spaces serve not only for protection against frost from without, but also for carrying off the water falling from the sky on the back-filling, down into the hollows. Upon the extrados of the bridge-arch, the drainage water runs over the tangental surface of the spandril-backing into the dry foundation wall. The surface over which the water drains is well plastered with hydraulic mortar. The exterior masonry of both the bridges is of well-hammered stone. Throughout the structure hydraulic mortar was used. For the distance of aqueduct between the bridges and back of them to the side-hills, the rock bottom was prepared with steps, and a foundation wall of dry stone-masonry carried up The exterior faces of some thickness into the wall were laid in hydraulic mortar, and the joints pointed with the trowel. Digitized by Google 46 AQUEDUCT, CROTON. 76. Grade-line Turnnike / of Aqueduct. Slope 1to road / Natural ground Dectivity 11.20 78. 77. & 79. Slope 3th2 3th2 Grade-line of Aqueduct Natural ground NON 81. 80, 88. 90. 14: 4' Ton of Backlilling 220 Grade line of Aquiduct 91. 89. SCALE.-1 - inch - 40 feet. Digitized by Google AQUEDUCT, CROTON. 47 CONTINUATION OF THE LINE OF AQUE- 73. Ducr.-Below some streets running across Sing-Sing, the aqueduct proceeds further on for a mile, on quite favorable ground, Grade line and when on the land of the State prison of Aqueduct farm, it enters into the great State prison farm tunnel, made 416 feet long, partly in rock, partly in earth. At some distance further, it is met by the small State prison farm tunnel, 375 feet, in earth: 91 miles from the dam, after having passed Hale's brook tunnel of 260 feet in length, the aqueduct crosses the valley of Hale's brook; its culvert is 6 feet in width, 131 feet long, and 49 feet below the top of the back-filling of the aqueduct. One mile further, the line crosses Rider's brook, over a culvert 100 feet long, 6 feet wide, and 74. 34 feet under the top of the aqueduct: 10 miles from the dam, the aqueduct crosses over the highway leading from Sing-Sing to Tarrytown by a bridge of 20 feet span. Grade line Proceeding further on, the aqueduct en- counters some high land, through which a tunnel of 186 feet is driven; it is 11} miles from the dam, designated Austin farm tun- nel From here the ground has various depressions of from 20 to 30 feet under the top of the aqueduct. At Mill river, 18 miles from the dam, the crossing-work is imposing. The de- pression of the valley is 87 feet below the top; the culvert or aqueduct bridge is 25 feet in width and 172 feet in length. In the extension of the next two miles, in the vicinity of Tarrytown, at five valleys in 75. succession, small culverts of various dimen- sions are constructed; then the aqueduct passes a tunnel of 246 feet in length, most- ly through rock, called White Plains tun- nel; then Requa's brook is crossed, over a culvert of 25 feet below the top; and after this the classical ground of Washington Irving's farm and Irving's run, the latter with a small culvert The next structure is at Jewell's brook, and its ravine, 17} miles from the dam; the culvert is 6 feet wide, 148 feet long, 62 feet below the top. A farm-road which could not be removed, was made to run under the aqueduct at a heavy expense; its arch is 14 feet in width, 141 feet long. Across Wilsey's brook, 181 miles from the dam, the culvert is 49 feet below the top, 6 feet wide, and 137 feet long. Half a mile further there is a tunnel near Dobbs' Ferry, 262 feet, driven through earth, and designated Dobbs' Ferry Tunnel. Crossing Storms' brook, the depth of culvert is 40 feet, the clear width 6 feet, and the length 187. From here the aqueduct passes several small valleys of from 10 to 15 feet in depth. At Cook's run the culvert is 4 feet wide, 132 feet long, and its bottom is 42 feet below top of aqueduct. Dyckman's brook, 22 miles from the dam, has a culvert of 8 feet in width, 120 feet in length, and is 35 feet below the top of back-filling. Then the line crosses various unimportant valleys and creeks, with small culverts, and arrives in the vicinity of the village of Yonkers, where, on account of the greater inland extension of low ground, an abrupt curve to the left was required, followed at a short distance by another to the right. The aqueduct passes through the Sawmill river tunnel, which is 684 feet, driven partly through earth, partly through rock; then it crosses the river itself, over which a bridge of two arches of 25 feet each has been erected. Fig. 73 is the cross-section of aqueduct at this point, with the longitudinal section of bridge; Fig. 74 the cross-section of bridge with the longitudinal section of aque- duct; and the last, Fig. 75, is the horizontal projection of one of the flanks; close to it is the passage for the turnpike-road, 20 feet in width, arched over a semicircle. The next work is a culvert over Nodine's run; after which a hill of considerable height is encountered, behind which the valley of Tibbit's brook comes in the way. The tunnel under this hill is 810 feet long, driven through solid rock, and called Tibbit's brook tunnel. The culvert for the brook is 6 feet wide, 107 feet long, and its bed is 40 feet below the top of the aqueduct: it is 26 miles from the dam. At some distance several small brooks are crossed one is O'Brien's run; the largest is Acker's brook, which passes 87 feet below the top of the aqueduct. The last two miles of the line are very nearly straight, the high land offering 80 favorable ground, that the upper filling of the aqueduct just disappears under the surface. Here the aqueduct arrives at the strait which separates Manhattan Island from the continent. HARLEM RIVER BRIDGE-The valley of Harlem river slopes down from the before-mentioned high land, at a point which is 33 miles distant from the Croton dam, first at 20 degrees, to a piece of table- land 25 feet above tide-water, stretching over a distance of 800 feet, whence, by a second slope, it Digitized by Google 48 AQUEDUCT, CROTON. reaches the water's edge. The tide-water has here a width of 620 feet. The bank of the island being of solid gneiss-rock, rises with a slope of 35 degrees to the height of the top of the aqueduct. The slope of this rock below water, as far as it could be examined, is steeper, and disappears under a deposite of mud mixed with sand and boulders. It is supposed this rock has connection with that of the opposite shore. In the basin formed by its depression below the strait is deposited a mass of white marble, Fig. 100, upon which the gneiss and alluvium of sand, mixed with pieces of rock and boulders, are found, upon which mud is deposited, consisting chiefly of vegetable matter. At first it was intended to carry the conduit-water over the valley in a siphon, through iron pipes,-on the side of the continent, following the surface of the ground to the water's edge, across the water of the river upon a stone embankment, from the centre of the river, ascending to that point of the island where the aquelluct starts again. Through the body of that part of the embankment, next the island bank which is sloping up, an arch of 120 feet in width, 60 feet high, was intended, through which a passage was to be kept open for navigation with sloops and schooners of 200 tons burden. The execution of this work was already contracted for, the dredging-machine in operation, when the landholders of both the banks of the river started a lawsuit against the measure; and an act from the legislature of the State was obtained, according to which, the aqueduct was to be carried below the bottom of the sea, or above its surface at such a height, that openings of 100 feet above high-water, 80 feet in width, had to be left in order to carry on the navigation. Notwithstanding estimates and comparisons of the two methods showed a surplus in cost of 200,000 dollars for the latter, its erection was preferred. This bridge has 15 arches, 8 of which are 80 feet in width each, by 100 feet in height above flood-tide, placed in the water, and upon both the shores 7 arches of 50 feet span each the two abutments were founded on the gneiss rock, three upon the marble, seven on piles, the rock being without reach below the latter. With this arrangement, the conduit-water was carried across to the island in a siphon of 12 feet depression. The manner intended of carrying the water below the bottom of the sea should here be mentioned. Following the slopes of the banks and the valley, 4 pipes of 8 feet diameter each, were to be laid 4 feet under the surface of the ground, below the bottom of the Strait; 2 tunnels, parallel to each other, 12 feet wide, 8 feet high each, 12 inches thick at bottom arch, put upon concrete, side walls and centre wall 4 feet thick each, roofing arches 16 inches thick; the extrados of both these arches covered with a course of concrete of 2 feet thickness, and the whole structure, top and sides, covered again with a stone pave- ment 12 inches thick, set in hydraulic mortar; the stone pavement was kept 24 feet below low-water. Each of the tunnels contained 2 pipes; the tunnels were provided with entrances, in order to examine them. It was intended to carry out the work by means of a coffer-dam on each side. The estimated cost was 636738 dollars. In order to reach the foundation of every pier for the high bridge, a coffer-dam was put down, the coffer or box made for each of the piers of such a height as the depth of water at its site required, to- gether with the thickness of the mud-deposite, and 8 feet border above high-water. In order to take the water out of the aqueduct, and let it into the pipes, and after passing over the bridge, re-discharge the same into the aqueduct, 2 gate-chambers, a and b, Fig. 100, are placed. Fig. 113 shows the ground-plan, Fig. 112 the longitudinal section, and Fig. 111 the cross-section of the influence gate-chamber, (entrance into the siphon;) c c is a basin, the bottom of which is level with the deepest line of the in- trados of the inverted arch; dd are the gateways, ee the two pipes; the influx of the water can be regulated by the two cast-iron double gates k k; f h is a waste-weir, whereby the waste water or the whole content of the aqueduct may be let off; f is the gateway, g the waste-weir well, h the sewer. The construction of the latter for the first 80 feet in length, is shown by Fig. 115; following the slope down- ward, it is funnelled into the shape and construction of Fig. 114, which leads to Harlem river. Fig. 111 is the section of gateway for the waste-weir; Fig. 112 the elevation of front with the gates 11. All the gates are of shape and construction as shown at Fig. 69. The rod-caps of waste-weir are connected by the bolts m n, Fig. 111, with the consols n; but the rod-caps of the gateways by the bolts m n, which are kept down and secured in the pier below, by the crosspiece n. Over the entire structure, a stone building is erected, arched with bricks, and covered with 3-inch greywacke slabs. The effluent-gate b, Fig. 111, at the island extremity of the bridge, is of the same arrangement in reversed order, but without waste-weir; it receives the water from the pipes of the siphon, and discharges it again into the aqueduct. Several times the question has been asked, why this bridge, being in a certain way considered a con- struction of luxury, has not been carried up to the full height, reaching the water-line of aqueduct, with the construction of the latter as upon the Sing-Sing Kill bridge 1 The pipes could have been spared the erection of the gate-chambers rendered needless; and what is most important, 2 feet of height had been saved, 117 feet head being left in the city, instead of 115. The reply may be :-a greater height of the structure would have required a larger and more compact model for the piers, or a more careful choice of material, and a more costly workmanship of the same; also a greater height for the attic walls upon the bridge arches; and in fine, the construction of the aqueduct itself with iron lining. All this, with- out doubt, would have accumulated the cost by 75000 dollars, a sum of some moment in the cost of the water-work. Considered as a monument, the bridge, as above constructed, has a sufficient height. The beginning of the construction of this bridge had been greatly delayed. It was desirable to use the aqueduct sooner than the bridge possibly could be finished. Down the descent of the valley, then upon the embankments enclosing the coffer-dams-which by degrees had formed an unbroken embankment across the salt-water strait-then up the island-shore to the aqueduct, a 36-inch pipe was put down, through which the conduit-water provisionally was led across the valley, and the aqueduct opened on the 4th of July, 1842. The construction of the bridge went on but slowly. CONTINUATION OF THE LINE OF AQUEDUCT.-A short distance from the effluence-gate the aqueduct passes over a ravine of 30 feet in depth, immediately after which a tunnel had to be driven 234 feet through solid rock. This lies about 331 miles from the dam, on the land of the deceased Monsieur Etienne Jumell, on that account called Jumell tunnel. Close by this tunnel is a ravine of 38 feet in Digitized by Google b 100. Agreduct MANHAT ISLAND. Mica so 14 20' Earth & Sand Gneiss and CONTINENT slate OF AMERICA Gneiss White Marble 103. 102. B A 101. @ o @ 0 o a D D o a D so, & 109. L 108. Shaft 110. AQUEDUCT, CROTON. Elevation of Scaffold. 105. 107. 106. Stone bond of Base 104. n Stone-bond of Shaft Flood tides Belt Ebb Cen ter line Digitized by Google bridge Base White Marble 49 50 AQUEDUCT, CROTON. 111. m d a g 112. m m f f f d K e 113. I h g f 7:6" c Center line of bridge 26 e d C Center line 115. 114. Digitized by Google AQUEDUCT, CROTON. 51 depth, and another 43 feet deep. Proceeding further 341 miles from the dam, the aqueduct enters into the line of 10th Avenue. Without any obstacles of consequence, it proceeds hence to the vicinity of Man- hattanville, and 35 miles from the dam passes through Manhattan-hill tunnel, the longest of the whole line-worked 1215 feet through rock. MANHATTAN VALLET.-Having left the tunnel, the ground slopes down to a depth of 105 feet, and rises up again to grade-line; measured here, the length amounts to 4180 feet. For conducting the water across this valley, first an aqueduct of arcades was proposed, with arches of brick supported by piere of rough stone-masonry, and the aqueduct upon these in its common shape. This method of crossing would have preserved 3 feet of head-pressure for the conduit-water, but at an expense of $1200000, while the passage in pipes cost only the fifth of that sum; this was a matter of some moment, and it was concluded, therefore, to make use of 4 pipes of 36 inches each. At the end of the last-mentioned tunnel an influent-gate, similar to that of Fig. 112, was erected, only of a greater width of basin-4 pipes being required; otherwise of the same arrangement, leaving out the waste-weir. At the brow of the opposite height, called Asylum-hill, is the effluent-gate, of the same construction entirely with the in- fluent-gate; it receives the conduit-water from the pipes, and lets it into the aqueduct again. Between 83. 8 c Grade line Aqued 85. 84. m Center- Line of. Aqueduct 13 e c c e 86. 87. d those two gates the siphon is placed, the pipes of which are partly laid in the ground; and where de pressions of the ground occur, upon an embankment of earth, throughout covered with earth 4 feet high In order to empty the pipes of the siphon when required, in cases of repair or removing deposites of san at the deepest depression of the valley, here, just in Manhattan-street, provisions were made for a waste weir for that purpose at each pipe; waste-pipes were put in; those pipes pass through the stop-cock vault and discharge into the waste-weir well. When one of the pipes is to be emptied, both of its upper ends are closed first by the respective gates in the gate-houses, then the stop-cock in the stop-cock vault drawn open; the content of the pipe makes now its way through a pipe into a sewer. which about 2000 feet from here discharges into the Hudson river. CONTINUATION OF THE AQUEDUCT-LINE-The declivity of the aqueduct being from here only 9 inches per mile, the water rises back as far as this from the receiving reservoir, which is merely 2.1727 miles off. To the thickness of the side walls of the aqueduct, by degrees, 4 inches have been added, making in all, 3 feet below, and 2 feet 4 inches at the spring-line; in the same way the walls were car- ried higher up to 11 feet above the spring-line of the roofing-arch. A short distance from the effluent- gate the line goes through its last tunnel, called Asylum-hill tunnel; this has a length of 640 feet, mostly broken through rock. Further on, for the grentest part of a mile, it was necessary to construct Digitized by Google 52 AQUEDUCT, CROTON. the aqueduct thus, that its sides and back-filling reached the height of 80 feet; at the end of this, for a little distance, the ground rises again to such a height that the upper-filling of the aqueduct just disap- pears below it, then another valley comes in the way. CLENDENNING VALLEY is the name given to the depression of ground which stretches across the high- lands of the island. The most favorable passage for the aqueduct is offered by in ne drawn 150 feet west from the axis of 9th Avenue, to which the aqueduct-line, coming from the 10th Avenue, is con- nected by an ogee-curve. The valley here has a length, or rather width, of 2000 feet, measured from the commencement of the upper-filling of the aqueduct, at the brow of the hill, to its disappearance on the opposite side; its greatest depth is 50 feet below the upper-filling. Looking on the map, it shows that this part of the island is laid out in streets and blocks. At this place it was designed that the streets, after being cut through and opened, should cross over the aqueduct; but, under such a con- siderable depression of ground as this, it was not practicable; and it was concluded to pass 6 of d 92. 94. i 93. - 95. d d 96. 97. Stone 98. a b 99. Brick Stone o 3 these streets, viz., the 101st, 100th, 99th, 98th, 97th, and 96th, underneath. The first 5 of these streets are 60 feet wide; but 96th, being a principal street, is 100. For their passage aqueduct-bridges were applied, of 3 arches each for the first 5; a main arch 30 feet in width in the centre for the road-way and two side arches, for the sidewalks, of 9 feet span each, over 101st and 97th streets; but of 10} at the bridges over 100th, 99th, and 98th streets. During the construction of those bridges it was thought, by the new Water Commissioners, only some of those bridges might be required for passage for the space of 50 or even 100 years, in consequence of which the passages for 101st, 97th, and 96th streets were beforehand left out; the bridges for 100th, 99th. and 98th streets will then be spoken of here. The dimensions of the different parts of these bridges are the same among all, with exception of the height of the pier-shafts only, which is determined by the various levels of pavement in the streets, but making only a difference of some inches. The foundation of all the piers is placed partly on rock, and partly on alluvial ground ; the piers themselves, as well as the arches, being constructed of gneiss rock; the former of well-hammered stone, the latter of cut-stone. The spandrels of the arches are car- Digitized by Google AQUEDUCT, CROTON. 63 ried up solid to the line tangental to the extrados. From here bance-walls are carried up alternating with openings, the latter being covered over with stone slabs, at a height of 8 inches over the extrados here the whole is levelled off by a rubble-masonry of stone 6 inches thick. Upon this level a course of concrete 9 inches thick is bedded, on which the aqueduct with its iron lining is erected; on the outsides of the side-walls of aqueduct, spaces of 6 inches in width are left, in order to separate the masonry of the aqueduct from the attic-walls, and to carry the water, draining through the earth-filling, over the extrados and the spandrel-backing. The spaces of aqueduct between the various streets, and be- yond them to the extremities of the valley, are supported by a dry stone-wall; stone of large size, to the thickness of 2 feet, were laid upon their broadest beds over the whole course, the interstices filled in with smaller ones, and all levelled off with smaller and smaller broken stone to the height of 2 feet, on which the following course was laid in the same manner; on a width of one foot back from the out- side, this masonry was laid in hydraulic-mortar, and the joints pointed. This part of the aqueduct has a very substantial appearance. THE AQUEDUCT LINE CONTINUED.-Over a distance of seven-eighths of a mile, upon which a curve of 90 degrees is turned to the left, in three various radii, the aqueduct of masonry discharges into the receiving reservoir; upon that curve the ground has a depression of about 40 feet, and the over-filling of the aqueduct is supported by protection-walls. Here then is the termination of the aqueduct as far as it is constructed of masonry; and only some appurtenances still remain to be mentioned. In order to keep the air which is confined in the closed aqueduct, in communication with the atmos- phere, ventilators, Fig. 90, are erected at distances of every mile; buttresses a a, Fig. 91, are carried up on each side of the aqueduct, between which the roofing-arch is carried round 12 inches thick instead of 8 inches. In the centre of the arch thus fortified, a circular opening is left bordered with bricks or stone upon this border the chimney-like ventilator, Fig. 90, is erected, secured at the top by a lattice. The third of those ventilators is always of larger dimensions and provided with a door to pass into the interior, Figs. 89 and 88, in order to facilitate examination and repair of the inner parts of the aque- duct in cases required. The one shown by Fig. 90 is put up before crossing Clendenning valley. The greater number of them are made of white marble, the rest of gneiss. There are of the latter kind 11 in all, and 22 of the former. At suitable points of the aqueduct line waste-weirs are put in to draw out the water when required. There are six on the whole line, with exception of that in the gate-house before Harlem river bridge. A gateway, Figs. 82, 83, 84, and 85, is formed according to the marked dimensions; the waste-water passes ough a pair of gates, bb, falls into the well c c, and discharges over d into the sewer ce. The gates with the gateway are constructed entirely as shown in Fig. 97. and already described. When the water rises higher than 5 feet 9 inches, measured from the deepest point of the intrados of the inverted arch, it runs over the lip of the breast-wall and falls likewise into the well c. By means of timber or planks i i, put against the post h, and slipping in the rabbits g g, provision is made to keep the water in the aqueduct higher at pleasure, consequently over the mentioned 5 feet 9 inches. In the platform at k, an opening, provided with a trap-door, is left, through which the planks ii can be put in and taken out. Above all, a stone house has been erected. From without, the platform can be reached by the door and over a small stair. At m, Figs. 84 and 85, a rabbit is cut in the side-walls of the aqueduct, into which timber may be slid in order to shut off the same. Those waste-weirs at their places serve likewise for ventilators; the one just described is put at 142d street: those on the continent are of the same description, with unimportant differences adapted to locality. THE RECEIVING-RESERVOIR, is built between 7th and 6th avenues, and 86th and 79th streets its area is 87.05 acres, including the top of the embankment, or 31 acres of surface of water. By means of an embankment it is divided into two divisions; the north one has a depth of 24 feet, measured down from the top of the embankment, and is filled with 20 feet of water; the southern division is 29 feet deer below the top of the embankment, 25 feet of which is water. Those depths, however, are not throughout the same; the rock-bottom near the southern embankment lies lower than this-near the northern embankment, higher. The contents of water amount to 150000000 gallons. Each division can be used as a single reservoir for itself, while the other may be emptied for inspection and repair. At the influx of the aqueduct at 85th street, west side of the reservoir, the street-level is equal with the top of the embankment. All the other parts of embankment had to be carried up more or less in order to reach the top, the ground being lower; and at efflux of the reservoir in 80th street, east side of the reservoir, it is 38 feet below the top. All the embankments are of earth, the interior puddled with clayish earth or loam. The sides on the streets and avenues are protected by dry walls of stone, their outside being laid in lime-mortar and the joints pointed, Figs. 127 and 128. The inside slopes of the embankments washed by water, are protected by a dry stone pavement of 15 inches thick. At the bottom of the reservoir the bare rock or earth is left without any artificial contrivance. In order to keep the surface of both the divisions at a level, a connecting or communicating-pipe, Fig. 125, has been placed, of which Fig. 123 is the section; the pipe is bedded upon rock, surrounded and supported by concrete: halfway a stop-cock is put for shutting and opening the pipe; over this cock a circular well is erected, and carried up to the top of the embankment. Upon the top of the well two caps are placed, on which a nut is screwed, like that at Fig. 94, by means of which, in con- nection with the screw-bar, the stop-cock can be drawn and shut. When the water has reached its height in the reservoir-viz. 4 feet below the top of embankment- and the rising still continues, the surplus water falls by itself into the waste-weir well. Through the same way 3 feet more water can be drawn off from the surface when required. by taking out the tim- bene Over the top of this waste-weir well, a bridge with a brick arch is erected, for the passage on the top of the division-embankment The influent-gate, Figs. 120 and 121, receives the water from the aqueduct a, by the gate-chamber b, and lets it either directly by the gateways e e e over the sluice-channel cc into the northern division, or by Digitized by Google 54 AQUEDUCT, CROTON. the gateways fff through that part d d of the aqueduct which is built in the body of the western embank- ment leading into the southern division. The various apertures of the gateways of the two entrances are separated from each other by means of jambs of cut-stone 9 inches thick, covered over at the front, in the gate-chamber, with stone lintels, Figs. 116 and 119, at gg ; in the rear at h h, however, the passages are arched over with half a brick, Fig. 119. The gates, with their frames, are made as shown at Fig. 97 ; the gate-caps rest partly in the walls and partly upon the posts 11. In order to prevent their rising, in screwing the gates, consols n n are projected, to which the gate-caps are secured by the bolts n m. By those two sets of gates, the water-influx to the divisions of the reservoir can be regulated completely. Over the whole a stone building arched with brick has been erected, and covered with flags.of grey wacke. 116. 118. 117. Top bank Top bank Tonwater 3 d d d d 119. TR Top bank. Top water. slore of Bottom Southern Division Centerline Bottom of Northern Division 3to.2. Division -Binbankment Radius 120. Sluice c and Sluice- Channel Northern Division Leading 121. to 122. Gate F a Chamber. Division d b b Main a SCALE.-1 inch 40 feet. The efflux from the reservoir is arranged in such a manner, that the water may be drawn either from the one division or from the other, or from both at once, each division having its own separate outlet. Three pipes, coming out of the northern division, run in the body of the eastern embankment, protected by a vault built in the same. At the southern extremity of the vault, upon the axis of 80th street, the pipes are united to 3 others, leading from the southern division, making 4 after the junction. Nos. 1, 2, and 3, carry the water to the distributing reservoir for the lower part of the city; No. 4 is for the sup- ply of the east side of the upper town. The arrangement of efflux is thus. a a a, 'Figs. 123, 124, 126, 127, and 131, is a tower, erected with sub- stantial stone walls: in the open side, fronting the reservoir, is put the gate-fruming with the screen bb; Digitized by Google AQUEDUCT, CROTON. 55 V a WASTE-WEIR f Coll as f 80 8 £ of Northern Division 123 of Southern Division 124. 2 a C B 0 A 7. A A a 125. DE A a Gate Cha -mber d 126. Top or Plateau of J Ton bank Top water 127. Top bank TopWater Top 5 R E M a 131. AB BC B CD A 16" a 129. ========================= Top Water 130. Ton bank 128. 6th 6th Avenue 6th Avenue N:27 SCALE.-1 inch - 40 feet. Digitized by Google 56 AQUEDUCT, CROTON. the same consists of two frames, of 1.2-inch white pine timber the outer is filled with 1-inch oak slate 6 inches wide, put 1 inch apart, Fig. 131; the upper part is covered with plank; the inner, or 2d frame, is left open as far as the just-mentioned planking reaches. Below this the gate-apertures are left-4 of such are in the tower, Figs. 123 and 127 ; at the tower, Fig. 124, they are of 2-inch pine plank, connected by pieces of plank nailed across and slid in wooden grooves; some of them are opened by sliding down, some by sliding up. Opening and shutting is effected by iron rods reaching up to the gate-caps c cc, Fige. 126, 127, and 131. On the top of each rod a screw is cut, which goes into the nut put upon the gate- caps; the nut and screw are shown by Fig. 93, at d e and i. Above this gate and screen-frame the tower is carried higher up and roofed over. Fig. 131 is the elevation of the tower-pavilion; Fig. 127, its section, and longitudinal section of bridge connecting the tower with the embankment. In the interior of the tower, Fig. 127, some timbers are put for support of the gate and screen-framing when the gates are Division Wall Iop Water Western Division Eastern Division Slope 112 state 4907 132. 133. 76' Bottom drain Bottom drain m Bottam Western Dir. Bottom ofEastern Div. c C Ion of Divi Wall 20' 2 Platform 42. Street. SCALE.-1 inch 40 feet. elosed. At the figure named, f shows the wing-walls of the tower, and g a breast-wall, being carried up against the bottom of the reservoir. Although Fig. 127 here is the section of Fig. 124, just as Fig. 131 is the elevation of Fig. 123, yet the arrangement and construction of the two are alike, except in some dimensions, which at Figs. 123 and 131 are smaller. In the rear-wall of the tower are the mouths of the pipes; the latter for some distance are bedded in and covered over with concrete, Figs. 123, 124, and 130. When the pipes Nos. 2, 3, and 4, coming from the northern division, have passed the line of the waste-weir sewer, D E, Fig. 123, they enter into the pipe-vault, Fig. 129 and Fig. 128; here they join with the pipes Nos. 1, 2, and 4, and so pass on. The letters hh show the stop-cocks; at i is a passage with stairs starting down from the avenue. In order to prevent all sudden opening and shutting of the stop-cocks or aliding-valves, consequently the pushing Digitized by Google AQUEDUCT, CROTON. 57 of the water, and to obtain a water-tight sit, a set of conical wheels and the crank, Fig. 98, were put in connection with the stop-cock. There are for the supply of the upper town, at the west side of the reservoir, two other effluent-gates, of similar description and equal heights with the corresponding ones in the same reservoir-division; yet they have their outlet through one pipe only. They are, together with the towers, of smaller dimensions in length and width. THE AQUEDUCT-LINE CONTINUED.-Prom the mouth of the pipes at the 6th A venue, the aqueduct, consist- ing here of three pipes, 36 inches each, 4 feet under ground, runs along 80th street, bends round the corner into 5th Avenue, proceeds here a distance of 2.176 miles across three depressions of ground and two 134. Pip e ault d a d d a d n n 135. t, t. Pipe area Pipe area 2 3 и u wur b a d vaule a a 50 Radias Drain 50 Rid Seiver Instruct SCALE.-1 inch 40 feet. heights. On the summit of the latter air-cocks are put, to allow the air to escape. At the lowest points of the depressions there are outlets, in order to get rid of the sand which might collect here. THE DISTRIBUTING RESERVOIR is also divided into two divisions, an eastern and a western, by means of a division-wall. Each has a separate inlét and outlet, and may be used as a reservoir for itself, while the other division is emptied. It is erected on the top of Murray hill, the greatest part being above ground; as for instance-the corner marked by x, is 49 feet above the street; y, however, only 39 feet. The outer walls a a of the reservoir, of 4 feet thickness, the inner of 6, connected together with the cross-walls cc,4 feet thick, form the chief mass of the enclosure of the basin. The cellules dd, between the cross-walls, are arched over 12 inches thick with bricks; their spandrels, of some feet in height, 8 Digitized by Google 58 AQUEDUCT, CROTON. backed with stone masonry then filled over and levelled off with concrete to a height of 6 inches above the highest point of the extrados of those brick arches. The division-wall is of concrete, faced with rough stone-masonry, Fig. 146. The bottom of the basin is puddled with earth, over which a course of concrete, 12 inches thick, is laid; the sides are puddled, and slope up 1 foot in 4, horizontally, for 16 feet in width; then 1 to 1 to the coping of the enclosure. The lower part of this slope is covered with a course of concrete, 12 inches thick; the steeper upper part is protected by a pavement 15 inches thick, laid in hydraulic mortar. The slopes of the division-wall have the same protection. The upper-filling of the cellule-arches is likewise of puddle, except 2 feet next the slope-pavement, and 2 feet below the flagging of the platform, Figs. 134, 137, 138, 144, 150, and 151, which will prevent the frost from penetrating into the puddle in parts not covered with water. 136. Centerpilaster in 24 stre Draining 25' Draining pipe Drain. Influent pipes Drain 142. Sewer 137. Section of Influent gate way Ton of Division wall Top Drain 141. M Sewer 140. 139. 138. Upper Waste-weirwell. Conectingnine well Connecting-p & Waste weir Ton-water Sewer 8 SCALE.-1 Inch = 40 feet. The total length of the entire structure, measured at the top of the cornice, (not in its projection,) is 420 feet; 80 the width. The basin is 386 feet square, 42 feet deep, and when filled with water 38 feet, contains 21000000 gallons. In order to collect and drain off any water which might filter down through the embankment i, and through the walls bb, there are left in the cross walls cc, small open- ings nn, Figs. 134, 135, 143, 144, 150, 151, by which the water may drain from cellule to cellule with- out the structure. Out of the northern side, the drain-water runs through the two sewers ff, Figs. 134, 135, 136, 141, 142, through the receiving-sewer gg, to the street-sewer hh. The southern part of the structure makes its drainage in an opposite direction-viz. through the drain-sewer i to the well k, Figs. 134, 135, from which it is carried off by the street-sewer of 40th street. Fig. 140 shows the lon- Digitized by Google AQUEDUCT, CROTON. 59 gitudinal section of the sewer q, the cross-section of the well k, with the mouth of the street-sewer 4 the construction of which is given by Fig. 139; the sewer ii has a like construction as Fig. 142. In order to draw off entirely the water from the bottom of each division, when required for cleansing or repairing them, 2 little wells are put in, m in, Figs. 133, 137, and a slight descent of the bottom towards them, from off all sides, arranged. In those wells the last of the contents collect, and is drawn away by pipes marked o o in the above-mentioned figures. The pipes discharge the water into the receiving- sewer gg; by the stop-cocks pp, those pipes can be opened and closed. In order to keep the water of both divisions on a level, a 36-inch connecting-pipe is put through the division-wall. Fig. 135 shows the ground-plan of the well in dotted lines. Fig. 133 is the top of the well, with a square opening formed by jutting over the coping-stone. Fig. 139 is the longitudinal section of pipe, stop-cock, and well. For letting out from the reservoirs the superfluous water, a waste-weir well, in 2 descents, or for 2 cascades, has been constructed in the body of the division-wall. That water which falls from the open- ing of the bridge 88, Figs. 132, 137, 138, 140, covering the first well, fills the water-bag below, which is 8 feet deep; it passes through the opening s, makes then the second fall down the well 8, fills its water- bag, and is carried off through the sewer 8 h into the street-sewer of 42d street. The construction of the sewer h is shown by Fig. 141; it has here, as well as in g, a bottom and arch of stone. The pipes 1, 2, and 2, 3, having made their curves running parallel with each other, they end in the pipe-areas tt, and the aqueduct itself terminates herewith. The just-mentioned figures show the course of the pipes: Figs. 136 and 140 the cross-section of the course at the entrance into the structure of the reservoir; and Fig. 134 the parts near the stop-cocks. Fig. 137 is their longitudinal section and sec- tion of the pipe-area: the same figure shows also the bedding and wrapping of concrete round the pipes in the embankment; it exhibits also the cut-off wall & For the effluence of the water into the distributing-pipes, an effluent-tower v, with gate-frame to, is erected for each division. Figs. 143, 145, show the ground-plan; Fig. 146, the elevation; Fig. 150, the side-view; and Fig. 151, the section. The gate-frame has a screen at the outside, in the rear of which is the gate-frame itself; both are supported by a breast-wall, over which the water falls upon the interior bottom of the tower, which is 8 feet below the top of that wall In the rear wall of the tower is put the entrance into the city-main. Each of the towers has a pipe x and 2, which are connected in the pipe-vault by the cross-pipe x runs to the eastern part of the town, z to the central part, and tz to the west part, for distribution. The ground-plan shows the way in which all 3 pipes can be supplied by the one set of gates, or the other, or by both together. The arrangement for the outflow of water answers, therefore, completely, the purpose-to empty the one division, entirely, while the other re- mains filled. At the lowest points of the pipes x, y, and z, draining-pipes with stop-cocks are put in, to let out into the sewer-pit k k any sand that may collect here. The way to work the gates from the caps, as well as the upper structure of both the towers, is shown by Figs. 145, 146, 150, and 151. The platform of the reservoir is guarded by an iron railing. At the elevation of 119 feet above the level of the sea, it commands a complete view of the west and east of Manhattan Island, as well as of the south part of the city, with New York bay, and at a greater distance in that direction, the Atlantic ocean. This view is exceedingly beautiful, and is one of the finest in the world. DISTRIBUTION OF THE WATER.-From this reservoir, the distribution of the water is made. The above- mentioned three 36-inch pipes convey it to the lower town, which is built closer and closer the fur- ther down one goes; 134 miles of pipes of all sizes, between 36 and 4 inches, conduct it through the streets, and feed several public and private fountains; these pipes are laid down in the centre of the streets, or as near so as possible. The branchings and crossings are made by means of single or double sleeves cast together with a main-piece. The pipes are put together with faucet and spigot, B inches deep; at the smaller pipes, 4 inches. The pieces have a length of 9 feet, each piece making thus 9 feet run of water-conduit when put together. Before laying down, they were proved with the hydraulic press, with the pressure of 200 to 250 pounds to the square inch. At the corners of streets where crossings and branchings occur, stop-cocks are put in, in order to cut off districts of pipes, when this is required for alteration or repair. Those pipes that run off from the street pipes, leading into the houses, are 1 to 1 inch wide, made of lead, connected to the main-pipes by boring. Such a house-pipe has either a mouth-cock under the outdoor steps, or leads to the kitchen, which in this country is in the basement. To feed bathing-tubs or bathing apparatus, a pipe some- times rises to the upper-story bedrooms. Pipes branching off for the hydrants, placed at convenient distances, are for the most part of cast-iron, branching off from the mains by sleeves; at the larger-sized pipes, by means of boring. The hydrants, as far as they are above ground, are protected by a cast-iron case to keep off frost, heat, and damage. For the extinguishing of fires, the engine-hose is screwed to the muzzle of the hydrants. At the harbor, pipes are branched out, terminating at the bulwarks, in order to supply the ships, and fill the water- casks on board by a hose. The cost of this aqueduct amounts to 8575000 dollars, including purchase of land required, extinguish- ing of water-rights, and some unfinished works. This amount is within 5 per cent of that estimated by the chief engineer, Mr. John B. Jervis, and the percentage occurs chiefly below the estimate. To this is added 1800000 dollars, the cost for the distributing-pipes. The first two millions had to be raised at an interest of 7 per cent, and are payable from 1847 to 1857. For the rest, 5 per cent is paid, and to be redeemed from 1858 to 1880. 647157 dollars was the discount for issuing the loan, which, together with the interest paid already during the construction of the work, brings the total expense to 12500000 dollars. The annual interest for this capital amounts to 665000 dollars, which is collected by a direct water- tax, and some indirect taxes; by means of an existing sinking fund, the capital will be redeemed by degrees. The water-tax amounts to 10 dollars for a house of middle size manufacturers, hotels, bathing- Digitized by Google 147. K : 149. tz Z Pavement of 40 Street Drain Sewer K Street Sewer 148. K !! 143. 145. e Pipe z X e vault tod F 150. C @ V Platform Top of Division wall SCALE-1 inch - 40 feet. b Ion water Top Batter 1in None 101 Store of Div V 151 on a AQUEDUCT, CROTON. Gate 40ust. 461 V Chamber V v V W 151. Ton water 144. Digitized by Google V V d Divis Pip e- V ault d a ion wall n n n TL 40ths: 146. ARCHIMEDEAN STERN-PROPELLER. 61 establishments, distilleries, livery-stables, bakeries, sugar-refineries, breweries, slaughter-houses, etc, and ships, pay according to extension and size. ARBOR VITE See WOODS, varieties of. ARCHES; stone ; brick; backing of ; centering; Pierpont; screw. See RAILWAY ENGINEERING. ARCHIMEDEAN, Boiler-furnace, and Self-acting Stern-Propeller.-Fig. 152 represents part of the stern of a vessel fitted with this improved propeller; Fig. 153, a front view of the instrument detached from its place in the vessel; and Fig. 154, a sectional plan of the propeller and its connections on the line a b of Fig. 152. 152. 153. c n 0 S 4 155. 154. A' A" are the blades of the propeller, which are inserted at their inner or narrow ends into sockets, B' B", in the end of the propeller-shaft S, in which sockets they are free to turn to the extent to be presently defined. To the shank of each propeller-blade there are two toothed segments, C'C', C" C", attached one at top of each socket, and the other at the bottom of it; and the two sets of segments work the one into the other within the limits determined by the stops ff, 80 that the propeller-blades must always move in perfect unison, and can only turn round in their sockets to the extent allowed by the stops. E is a sliding clutch, affixed to the driving-shaft inside of the propeller-blades, which may be moved sternwards, 60 as to lay hold of either of two sets of pins, d d and e e, which project from the back of the wheels of the innermost propeller-blade A". F is a vertical rod, by means of which the dutch E may be worked from the deck of the vessel; this rod terminating at bottom in a screw, which takes into a swivelled nut which is attached to one arm of a bell-crank, G, the other arm of which is forked so as to embrace the clutch E, when brought down upon it. The mode in which the propeller, as thus fitted, acts, is as follows :-Supposing the clutch to be disengaged, and the driving-shaft to be put in motion, the blades are immediately thrown out into the angular positions proper for propelling, and they will continue in these positions as long as the shaft continues to rotate. Should occasion arise Digitized by Google 62 ARCHIMEDEAN STERN-PROPELLER. for backing the vessel, the blades are then secured in their extended positions by interlocking the clutch with the pins dd. at the back of the wheels of the innermost blade, A", as represented in Fig. 154. When the engine is stopped, and the driving-shaft ceases to rotate, and the clutch is withdrawn, the propeller-blades will, by the action of the water upon them, be turned round in their sockets until they come into a line with the course of the vessel, and present their sharp edges only to the water, as 156. W 157. exemplified in Fig. 155; and, for greater security, they may be made fast in this position by interlocking the clutd h E, with the pins ee, at the back of the wheels of the innermost blade. From the manner which this peculiarly fixed screw-propeller can be turned to account, from its never being required to be raised out of the water, and never offering, when in the water and at rest, any Digitized by Google ARTESIAN WELL OF GRENELLE. 63 material obstruction to the steering of the vessel, it seems to possess so far a great superiority over all the screw-propellers hitherto in use; but it promises to be more especially advantageous in the case of vessels going long voyages, with small store of fuel, and employing steam as an auxiliary power only, when the wind is not fair for the use of sails. With a propeller of this description, not a minute need be lost, in charging from sailing to steaming, or from steaming to sailing, and conse- quently, not a pound more of fuel need be expended than is absolutely required. The peculiar feature of this furnace consists in the employment of rotating tubular screw-bars, and hence the name (" Archimedean") by which we have ventured to distinguish it. Fig. 156 is a longitu- dinal section of the furnace; and Fig. 157 a front view. H H, are the fire-bars, which, instead of being as usual, solid fixtures, consist of a series of tubes, which are free to revolve in their bearings, are open from end to end, screw-threaded on the outside, and perforated with air-holes. On the front end of each bar there is a broad flange or shoulder, f, which projects beyond the general line of the furnace, and has a worm-wheel, W, formed upon it. An endless screw-shaft, K, which passes across the front of the furnace, and is worked from the engine through the medium of the bevel-wheels N 0, takes into the whole series of worm-wheels W, and causes thereby the constant rotation of the fire-bars. L is a throttle-valve hopper by which the coals are supplied to the furnace. As the coals drop from the hopper they fall upon an inclined shoot, M, which projects them upon the front end of the furnace-bars, whence they are carried gradually forward to the back, by the rotation of the bars and the action of their screwed surfaces on the mass of fuel. In consequence of the bars being in this constant state of rotation, it is almost impossible that either clinkers or ashes should accumulate upon them. ARENE See RAILWAY ENGINEERING. ARTESIAN WELLS. These have long existed in Italy, in Austria, in the Crimea, Siberia, Sahara, Palmyra, Balbec, Tyre, and Egypt; their modern name arises from their having been immemorially used in Artois, one of the departments in France. Belidor mentions one in 1749 at the monastery of St. André, near to Aire; and in the ancient convent of the Chartreux, at Lillier, in the same neighbor- hood, is another, more than 700 years made. ARTESIAN WELL OF GRENELLE, Boring Apparatus of. About the year 1824, M. Péligot, one of the superintendents of the hospitals at Paris, suggested the idea of sinking a well upon the Arte- sian principle, and workmen were sent from Artois for the purpose; whilst this was being effected, M. Mulot, a smith, became interested in the operation, and turned his attention to the subject; he was consequently employed by the Marchioness de Groslier to sink one at Epinay; success attended his efforts, and he was nominated to attempt one at Grenelle. The primitive soils, according to M. Arago, are but rarely stratified, or are found in regular beds. The fissures in granitic rocks, the crevices sepa- rating the contiguous masses, have but little width or depth, and do not frequently communicate with each other in such soils the waters of filtration have but limited outlets, each film or thread termina- ting its course alone, without receiving any increase from others in their descent. The springs being numerous in the neighborhood, it was not thought probable that any vast quantity of water could be obtained, as the whole of the rain penetrating the earth was supposed to pass off through various open- ings in the sides of the hills. The secondary soils, which are composed of a variety of rocks, in general take the form of immense reservoirs or basins, the centre being considerably depressed, or the extreme boundaries of it greatly elevated. Within this basin, hills, and often mountains, arise, apparently destroying its original charac- ter. The stratification of the secondary formation is in regular beds, some of which are of enormous thickness, composed of sand or grit, and very permeable; these permeable beds, as they rise towards the extremities of the basin, become bare on the sides of the mountains and hills. The rain-water which falls on the earth, after penetrating it, forms one continued sheet, which pursues its course with great rapidity when the beds have a great declivity, and, reaching the lowest point, is accumulated in vast quantities. One chalky or calcareous stratum, which is furrowed out in all directions, and par- ticularly in the upper portion, allows the pluvial water to pass with great facility, and also to circulate through the mass to a great depth: and in this peculiar stratum the wells both of Grenelle and Rouen have been bored. The tertiary soils are stratified, and composed of many beds placed over each other, and separated by clean and well-defined joints, like the secondary, on which they rest; these basins are of less extent, and derive their form from the rectifying of the beds, the elements of which they are constituted being the same as those found on the neighboring hills. The several beds are arranged in a regular manner, and their separation is formed by a layer of sand, through which the water freely percolates; in these several sandy fissures it acquires force as it descends, and at great depths, its pressure being augmented, the flow is rendered constant. These soils are undoubtedly the best for sinking Artesian wells, because they have at their base courses of sand lying on impermeable clays, and are less subject to dislocation or rupture than rocks of the old formation. Such strata are easily examined, and are usually found rising from the centre of the basin, and following an inverse direction to that of the inclination of the water, which, like a sub- terranean river, pursues a downward course till it meets with an outlet. They frequently become bro- ken, when the water they contain weeps into small rivulets and is carried away on the surface. Where the well has been bored at Grenelle, the upper stratum or tertiary deposite is 41 metres in thickness; the next is composed of chalk mixed with flint, 99 metres; then a gray chalk, without any silex, 25 metres; to this succeeded a gray chalk, in which were iron pyrites, 341 metres; then a wealden clay, gray sand, and a sandy clay, in which were found ammonites and other fossils; the whole depth hored through being 548 metres, or about 1798 feet. Before giving the description of the apparatus used in boring this well, we will give a short sketch of the difficulties encountered and overcome by M. Mulot, to whom the direction of this great work had been intrusted. Digitized by Google Digitized by Google 160 " T ,Y k E © 150 k 159. Y ** G L E E a G x g G & G L n M CI G U y M 161. 0 n I U Z 158. 11 o NO S T $ D' A. "FE,S ARTESIAN WELL OF GRENELLE. 40 ARTESIAN WELL OF GRENELLE. 65 M. Mulot commenced boring in 1833 he easily pierced the tertiary sands, which are at Grenelle 180 feet thick, but shortly after having reached the chalk, at the depth of 377 feet, the sides gave way and filled the bored space, which was cleared again, after fifty-seven days' labor; this happened in June. 1834. In May, 1837, the borer had reached 1246 feet, when the valved-spoon, together with a rod 262 feet long, fell to the bottom of the hole and were shattered to fragments; the weight of the mass was 100 cwt. Many contrivances were proposed-some even put in execution-but in vain, till M. Mulot had the idea of wearing the ends of the fragments, and thus extracted them, fifteen months after the accident. In April, 1840, the instruments were wearing out rapidly, while they were making little headway through the hard chalk, when, being raised to a considerable height, the boring-screw fell, and was buried in the compact rock to the depth of 75 feet. It became necessary to bore all round it in order to free it, and after many months of labor this new obstacle was surmounted. In December, 1840, the spoon detached itself from the rod, causing a little delay in the operations of M. Mulot, who bored a hole in the sides of the well and pushed the separated instrument into it. This was the last impediment to overcome, and the 26th of February, 1841, the rod suddenly sunk several feet; immediately a column of warm water 1797 feet high, equal to the pressure of 53 atmospheres, rose from the bosom of the earth, and poured upon its surface 800,000 gallons of water, having a tem- perature of 79 Fahrenheit. But, besides boring, it was necessary to give support to the sides of the well, which would fall in, unless composed of material more consistent than earth. A tube of a certain calibre is first introduced, then another smaller one slipped within the first, and so on; but should the boring be deeper than ex- pected, it would become necessary to withdraw these tubes in order to replace them by larger ones, because the last must be of sufficient calibre to allow the rod to work. At Grenelle it was necessary to draw off five series of tubes, and to bore larger holes to introduce tubes of a greater diameter. The following is a table of the strata bored through. Nature of the Strata. Thickness. Depth beneath the soil. Feet. Feet. 1 Foundation of a basin 7.21 on the surface 2 Alluvial soil, composed of rolled flints and gravel 24.40 7.216 3 Chalk 2.78 31.652 4 Plastic clay, lignites, iron pyrites, and sand, penetrated by sul- phuret of iron 65.69 84.44 5 Marl and calcareous sand, containing nodules of compact lime- stone 36.11 100.13 6 Chalk and silex in lumps 312.89 136.25 7 Hard gray chalk with silex 652.92 449.14 8 Gray chalk, very hard, alternating with more soft chalk 423.18 1104.23 9 Green chalk .98 1524.20 10 Blue chalk with clay 101.73 1526.0 11 Black and blue clay, with strata of green sand, containing iron py- rites and fossils 101.79 1658.51 12 Argillaceous sand 2.30 1780.28 13 Green sand 4.50 1792.57 Water 1797.47 Description-The apparatus consists of a crane with four beams A, iron-bound. At the summit there are four pulleys of cast-iron B, on these the chains C pass; these chains also go through two other moveable pulleys DD'. The chains C, attached by one end to the guide-strap of the pulleys DD', are hooked by the other extremity on the conical drum E E', around which they are wound in opposite directions. By these pulleys the iron bars F, 26.24 feet long, to which are attached the bur- rowing instruments, are lowered and raised. To raise the rods, eight horses are harnessed at G, Figs. 158 and 159, which being set in motion, one of the chains passing through the pulley H coils round E, while the other chain is unrolled. The pulley D, to which the rod F is suspended by means of a hook, is raised, and brings up all the boring apparatus. When this pulley has reached the top of the crane the second pulley D' is made fast; then the bar just raised is taken off by men standing on a; the hook is fixed to the next bar, and the horses are driven in the opposite direction. While the pulleys are exchanged, the top bar is seized by the crank J, placed at the orifice of the well to prevent it from falling. The cranks J are formed of two strong iron plates, between which are set two eccentric chaps J1 J2, which allow the rods to ascend, but prevent their falling back. One man is necessary to lower the rod, which is accomplished by pulling or loosening the break, Figa. 158 and 159, at pleasure. This double break consists of two large hoops K K', surrounding the drum L, which is covered with a thick sheet of iron; one of the extremities of the hoops is fastened to the horizontal beam M, while the other is kept in place by a square placed out of the works, and opened or closed by a lever. The next thing to be considered is how the rod is turned. It is adapted to the wheel N, which is made to communicate with the wheel, Fig. 163. The toothed-wheel N, is for this purpose changed from the position it occupied, Fig. 158, to that represented Fig. 162, corresponding to the axis of the well; a square hole is made in the centre to receive a square bar of iron .2624 of a foot 9 Digitized by Google 66 ARTESIAN WELL OF GRENELLE. T @ 163. 167. 168. to a P R 57 29'6" A B a " N R 16 R R UUCU inn 162. R 164. R N 165. 166. Digitized by Google ARTESIAN WELL OF GRENELLE. 67 square and 18 feet long, which is adapted by one extremity to the boring-rod, and by the other is sus- pended to the hook of the pulley D. When the wheel N is fixed to the rod it is adapted to its inter- mediate toothed-wheel P, fixed to a wooden frame close by the crane. The wheel P is put in connec- tion with the great wheel Q placed over the wheel R, to which two, and sometimes three horses are harnessed. The burrowing-rod is suspended by chains run into a ring g, Fig. 159, and coils round the drum S, Figs. 158 and 163', situated on the other side. The wheel T serves to raise or lower the instrument. When the wheel R is put in motion, the rod receives the movement of rotation imparted to N by the toothed-wheel P. The men at T allow the rod to descend slowly. The pulley D' would be in the way during the operation, it is therefore fixed by a pin to the links of the chain. Explanations of the Figures.-Fig. 158.-A vertical and longitudinal section of the apparatus in a plane passing through the axis of the well, and of the wheel used to lower and raise the borer. Fig. 159.-A horizontal section of the wheel G, made above the breaks; the two conical drums, around which the chains are wound, being omitted. Fig. 160.-A horizontal projection of the drum L, and of the breaks. Fig. 161.-A front view of the two frames U U', placed in the horizontal beam, near the wheel G Within these frames two smaller frames are made to slide; they have wooden rollers, и and u', and are intended to support and guide the chains C, to the drums E'. These chains, when slack, rest on the rollers w'. The frames U and U' have their superior part in contact with the beams V and V', which are fastened by one extremity to the crane, and by the other to the strong bearer, X. The pillow of the axis of the wheel G, rests also on this bearer. A flooring, Z, connects the wheel to the crane, and places within the reach of the workmen the parts just described. Fig. 162.-Vertical and transverse section of the apparatus, whose plane is perpendicular to that of the section, Fig. 158. Fig. 163'.-A view of the drum used for supporting and lowering slowly the borer as it sinks. Fig. 164.-Plan of the wheel R, Fig. 162. Fig. 165.-A profile view of the frame and wheel N. Fig. 166.-A plan of this frame, which slides in grooves made in the beams O, Figs. 158 and 162, on small friction-rollers. The small flooring n, gives passage towards the centre of the wheel N, in order to adapt the rod in it. Fig. 167.-Front view of the wooden support to the toothed-wheel P, Fig. 162. Fig. 168.-A horizontal section of this support, and plan of the wheel. Figs. 169 and 170.-A front and profile view of one of the moveab.e pulleys, D D', with its guide- strap, giving attachment to the hook d, to which is suspended the borer by a ring. Figs. 171 and 172.-An external view of the crank J, with a section following the line 1-2. While the boring goes on, this is set over the orifice of the hole; to this end, two semicircular pieces j are attached to the plates J, and rest on the ground. The rods pass between J and the nippers J1, Jª. As long as the rods are raised the nippers yield; but as soon as they remain motionless, either to change the rods or for any other motive, the arcs through their eccentricity press against the bars and prevent their descent. To secure them further, their other sides are held by the force-screws jª. Fig. 173.-A fragment of galvanized iron tube, 0.016 of a foot thick, used as a conductor to the water. Figs. 174 and 175.-Pincers used for the extraction of fragments of wood or other matters. Fig. 176.-Section of the foregoing, following the line 3-4. Figs. 177 and 178.-Pincers for withdrawing the tubes. Fig. 179.-A horizontal section of a branch in the direction of 5-6. Figs. 180 and 181.-Details of an instrument called Caracol, used to withdraw fragments of the rod when they have penetrated into the parietes of the well. Fig. 182-A plan of the instrument. Figs, 183 and 184.-Screwed rods composing the borer. The superior bar has a hook also vised to it. Figs. 185 and 186.-Rods united by means of pins, the heads of which are buried in the thickness of the bars. The end of one is fissured, in order to receive the end of another rod. Figs. 187 and 188.-A ring which is attached to the rods by three pins. Figs. 189 and 190.-A chisel, called Trepan, used to perforate the hard rocks which it is necessary to break and to crush at the same time. There are three edges, a, b, c. The edge a is double, b and c are turned in opposite directions. This implement will cut the rock and crush it in whatever direction it is turned. Figs. 191 and 192-A valved spoon, used in sands and clays almost rendered liquid by the water in which they are in suspension. It consists of a long cylinder in sheet-iron, open at both extremities, the inferior being strengthened by an iron ring with a sharp edge. A little above this ring there is a disk, at the centre of which a round hole has been perforated. This opening is perfectly closed by an iron ball. When the spoon is lowered into the hole the sand pushes away the ball, which, however, falls back by its weight, closes the orifice b, and allows the extraction of the sand. The ball is prevented from rising too high by the perforated disk c. Figa 193 and 194.-A vertical section and external view of the borer, used to enlarge the hole. It is very solid, and consists of a hollow cylinder, whose inferior extremity is furnished on its circumference with fluted knives, of which there are several of different dimensions. Fig. 195.-A view of the underneath part of the preceding. Fig. 196-Shows the mode of attachment of a knife to the ring, and also a front view of the knife. The knives are firmly attached to the inner ring, and are surrounded by another ring of greater diame- ter. The whole is traversed by a pin. ASH. See WOODS, varieties of. ASPHALTE. See RAILWAY ENGINEERING. Digitized by Google 68 ARTESIAN WELL OF GRENELLE. 174. 175. oo c c c 169. O 177. 176. A 178 179. 000 C 170. A o 183. 193. 184. 185. 195. 196. 186. 180. TOT 189, IF ja " 172. 181. n jt 173. 189. 000 J' . 190. o 1 o J' 191. 6.6. 171. 2 o : in 0 187. J 192. 188. in Digitized by Google AUGERS. 69 ASPEN. See WOODS, varieties of. AUGER, Ship Carpenter's. This is a very ingenious 197. instrument, invented by Richard Coffin, of Haverhill, Mass, and the following explanation will convey an idea ased of its uses. c A is the foot. D is the frame. C is a rod and crank F F attached to the auger H. B is the cup and head. E is the spring. G G are two rods for the purpose of discon- E D necting the catches FF from the rod C. If you wish to bore, pull the spring E by the handle to the left; shove down the left-hand rod G, to disconne t the left-hand catch from the rod C. The right-hand catch holds the spring. and throws its power towards the auger H, and so on; the cup B allows its ball to roll in the frame and auger in any position, and the thumb-screw will hold it in that position; the other thumb-screw is to hold the slide which elevates or depresses the auger. AUGERS. See BORING TOOLS and RAILWAY ENGINEER- ING. AUGER, improved. This is the invention of Mr. Wil- A liam Ash. Its object is to produce holes of various diam- eters by one instrument by having the cutting and gui- ding parts detached, 80 as to change them at pleasure. 204. 203. Figs. 198, 199, 200, and 201, represent the auger in three different positions. Fig. 201 shows its end. A is the spindle; B the conical screw; C the worm fitted on the K spindle. The upper end of the worm is made to bear against the stop D. F is the cutter fitted into a mortise in the spindle, fastened by the wedge-piece G. The cut- ter F, is shown above in four detached positions, Fig. 202. 202. K The lower end of the worm bears against the back of the cutter, and the wedge G rests also in a small notch cut in 201. the face of the worm, as seen in Fig. 200. On taking out the wedge the cutter can be taken out, and also the worm, when another worm or cutter of a different size may be at- tached to the spindle. In this way the cutter can be taken out and sharpened at pleasure. Instead of the worm C, the guides, Figs. 203 and 204, are sometimes substituted. Fig. 203 is a vertical, and Fig. 204 a horizontal, section. 198. This guide consists of a ring, KK, having a slightly conical 209. 199. screw-thread on the outside, from which extend two wings, II, supporting a thimble, L Through this thimble the spindle A passes, and the cutter being applied to bore the wood, the opening of the hole is only to be cut in the first place, then the ring of the guide is firmly screwed c into that orifice; and in boring, the cutter will then be directed by the spindle sliding through the thimble. By the worm the chips are carried up out of the hole. By the guide the chips will rise through the opening K and the thimble L The worm appears to be, by far, the best guide. AUGERS, machinery for making. The object of the inventor, Mr. Palmer, is to manufacture the single-twist" e auger, usually made of a rod of metal, twisted round a cylinder into a helical curve. The auger which the inven- tor's machinery is intended to manufacture, is formed of a long rod of metal, (either of a triangular or other prop- er shape, in its cross-section.) The iron should be rolled c in square bars or rods, of the size required, and be cut into pieces of sufficient length, to make the tool or instru- c ment intended. A small piece of steel of proper size for the cutting-lip, and the conical screw, if it is to be added, is next welded upon one end of each one of the pieces, and the end is next turned or bent down at right angles to the remainder, upon an anvil, so as to fit into the cavity of the lower section of the dies, for forming the lip, or the lip and screw cone. About three-fourths of the length of the rod from the steel knob is next heated to the necessary temperature, to be rolled down by the next portion of the machinery. The next portion of the process of manufacturing the auger, consists in forming the cutting-lip, or the cutting-lip and conical screw-blank, upon its end. For this purpose, dies are employed to form the lip without the conic blank. The head of steel being heated, is placed between the dies, and the upper of them caused to descend, with the force necessary to swedge or compress the metal into the shape required. The knob thus formed, is next bent down to the angle re- quired, to be applied to the machine, by which the rod is twisted in the helical curve. The next operation is, Digitized by Google 70 AUGERS. to give the requisite degree of uniformity to the size and spread of the twist, 905. 906. 207. which is accomplished by hammering in the machine, consisting of a trip- hammer, arranged and operated over a die-anvil or bed-piece, grooved out, 80 as to receive the twisted helix when laid thereon. By turn- ing the auger around, first in one direction and next in the opposite, succes- sively, so as to cause it to pass back and forth between the hammer and bed-piece or anvil, the twist is spread out in a uniform manner. The lower part of the hammer should be curved to correspond with the circumference of the exterior of the twist of the auger. The twisted portion of the auger is again heated, and rolled between heavy iron plates, for the purpose of straightening the twist; during which operation, care should be taken that the cutting of the auger does not come in contact with the plates. The auger is next to be finished by filing, and upon grinding and polishing wheels, or by other proper means, in such manner as may be desirable and when a screw is to be connected with the cutting-lip, it may be cut upon the blank by any contrivance adapted to the purpose. AUGERS, double and single twist. Improvement in single and double twist augers, by Sandford, Newton, and Smith, of Meriden, Conn. :- This improvement consists in what we term a graduated twist, and is effected by 80 constructing the auger as to produce a uniformly decreasing length of twist, with a corresponding gradual tapering of the cavity of the auger, from the shank to the lower or cutting extremity. Any person skilled in the art of making augers can form the graduated double-twist with tongs and hammers, in the ordinary mode of twisting double-twist augers, by exercising due care and attention. A better method is to have the dies in what auger manufacturers call crimp-jaws, 80 constructed as to conform in size, graduated length of twist, and taper of the cavity, to the proposed auger. The auger having been first twisted by the common method, with the tongs and other tools, to about the shortness of a medium in the proposed twist, is, while hot, put into the crimps, which are then brought suddenly together by the usual process, the auger being at the same time turned partially round, backward and forward. The twist is thus made of a gradual increasing length, with a corresponding gradual enlarging cavity from the lower or cutting end to the other extremity of the twist, as is represented in Fig. 205 in the drawing an- nexed. To form single-twist augers with this improvement, see Fig. 206, that part of the rod which is to form the twist, should, before being twisted, be drawn with a graduated taper from the part which is to form the shank, to that which is to form the lower or cutting end. The auger may then be twisted in the usual way, by having the mould upon which it is formed or twisted, made to conform in size, graduated length of twist. and taper of cavity, to the proposed auger. The mould is a machine well known to all makers of single-twist augers. The superiority of augers made with this improvement consists in, that the clogging of the chips or core in the twist, while in the process of boring, is effectually prevented; thereby materially diminishing the fric- tion. And also, that the shortness of the twist at the lower end gives a better opportunity to finish the cutting-lips, 80 that they may bore more smoothly and evenly than when the auger is made in the ordinary way, with a slack or open twist. What the inventors claim as their improvement and invention, are the making or constructing double or single twist augers, with a gradually increasing length of twist, and the consequent gradual enlargement of cavity from the lower or cutting end to the other extremity of the twist. AUGER, double-lipped, convex, and concave. Improvement in the form and construction of concave screw-augers, by N. C. Sandford, Meriden, Conn.-This improvement consists as follows: Instead of having the plate, from which the auger is to be twisted, of concave shape throughout, as is usual in forming concave augers, the lower extremity of the plate is of convex shape, or of even thickness, though the former is preferred. In augers of five-eighths diameter it will be sufficient to have about one inch of the lower extremity of convex shape, or of even thickness, as aforesaid, varying in proportion as the diameter of the auger is increased or diminished. The advantage of this mode of construction consists in, that the work- man, when twisting the auger, which is done in the ordinary mode, is better enabled to give to the plate a short twist at the lower extremity, and finish the cutting-lips or edges in the best and most approved method for easy boring, than when the plate is formed in the usual way, of concave shape throughout. What Mr. Sandford claims as his invention, is the forming of the lower part of the plate of a convex shape, or of even thickness, when this is Digitized by Google AUGER MACHINE 71 combined with the upper part of the plate formed of a concave shape. The whole plate being formed for the purpose of making therefrom a double-lipped, convex, and concave auger. AUGER MACHINE This new and useful improvement in the mode of equalizing and straightening the twist of double and single twist screw augers, invented by Sandford and Smith, of Meriden, Conn., may be described as follows: Set firmly in the ground, or otherwise secure to the floor, two posts, marked a, Fig. 208, about six sr : apart and fifteen inches in diameter, of sufficient length to elevate the machine to a convenient 208, 209. a a distance from the ground. Upon the upper surface of these posts is placed horizontally, and se- cured strongly, a piece of timber b, say of oak, about twenty inches wide on its upper surface, and four inches thick. This we term the bed of the machine. Two straight cast-iron bars c, about two inches thick and two inches wide, of the same length as the bed, and raised about twelve inches therefrom, and then placed about twelve inches apart, parallel to each other and to the bed. Each of these bars is secured to the bed by two vertical posts of iron, D. Fig. 208 shows the machine as thus far construct- ed. We then take a piece of cast-iron, say two feet long, fourteen inches wide, and one inch thick, with its edges raised about one inch, 80 as to form a dovetail on its upper surface. This we call the Digitized by Google 72 AUGER MACHINE. lower stock, and is represented by that portion of Fig. 210 marked h. This stock is placed in the centre of the bed, between the bars; screws passing through the bed and attached to the stock, serve to elevate or depress it at pleasure. Another screw, passing through the centre of the stock and through the bed, enables the operator to confine and hold the stock firmly on the first-named four screws. Another piece of cast-iron, of similar dimensions, but with the dovetail on its under surface, is then placed under the bars, 80 that about one inch of each edge of the upper surface of its entire length shall bear upon the under surface of the bars. This we term the upper stock, and is held to the bars by four hooks, marked g, in Fig. 209, attached to the upper surface of the stock, and resting in the upper surface of the bars, so as to admit a sliding movement of this upper stock. This movement is effected by means of a rack e, and pinion; the rack, to be of sufficient strength, should be formed of a cast-iron bar, about two inches square, and of the same length as the bars, with cogs about two inch- es in length, and is attached lengthwise to the surface of the upper stock. The pinions and shaft should be of corresponding dimensions; and being turned by means of a crank or wrench, give an alternate backward or forward movement to the upper stock. Fig. 209 represents the machine with the upper stock k, and the lower stock h, in their respective places, and the rack e, and pinion at- tached. There are then inserted into these stocks, metallic plates, or dies, of about one inch thickness, which fit into and are securely held by the dovetails above mentioned. To each of these plates, or dies, are secured, by means of rivets or screws, two wales of cast-steel, running parallel to each other in an angular direction across the plates. Fig. 210 shows one of these plates i, partially inserted in the stock h. When the plates are separated from their respective stocks, the wales upon the plate are designed for the lower stock, and vice versa; 80 that when the plates are inserted in their respective stocks, the wales upon the upper plate run in an opposite direction from those upon the lower plate, form- ing an angle with each other. The size of the wales will depend upon the size of the auger to be formed and the angle at which they cross the plate must be governed by the openness or closeness of the proposed twist, so that separate plates, adapted to each size of auger respectively, will be re- quired. If it is desired to form the auger so as to make the graduated twist, it may be effected by slightly curving and also tapering, as shown in Fig. 212, the wales; increasing or diminishing the curve and taper, in proportion to the degree of graduation contemplated. 210. 211. 212. 2 The plates are adjusted at the proper distance from each other, required by the size of the auger to be formed, by means of the screws. To work the machine the crank is turned backward, 80 as to move the upper plate directly over the opposite extremity of the wales upon the lower plate, as shown in Fig. 211. The machine is then ready for operation. The auger being twisted by hand in the usual way, (which can be done with great expedition, as particular nicety in this respect is rendered unnecessary by the use of the ma- chine,) is placed while hot in the machine, with the part nearest the shank on the wales, which being adapted to the size of the auger to be operated upon, will fill the cavity of the twist. The upper plate is then moved forward by turning the crank, and rolls the twist part of the auger between the plates, these giving it an exact and uniform size; while, at the same time, the wales operate upon the cavities of the twist, opening or closing them as may be necessary, and by a single forward move Digitized by Google AUTOMATIC DIVIDING MACHINE. 78 ment of the machine, produces a perfectly even and regular twist. Thus forming a better article, and at less expense, than can be done by any method now in use. Messrs. Sandford and Smith, claim the raising upon and securing to the surface of level metal- lic, or other plates composed of hard substance, wales running either in straight or curved lines, and operated substantially in the manner just specified, for the purpose of forming the twist of double and single twist screw augers. AUTOMATIC DIVIDING MACHINE, arranged for use in the Coast Survey Office, by JOSEPH Sax- TON, assistant in the office of weights and measures, Washington, and constructed by William Würdeman, mechanician, coast-survey office-The dividing machine, which has been rendered automatic by Mr. Sax- ton, was imported for use in the coast-survey office, by the late F. R. Hassler, Esq., superintendent. The graduations made by means of it, by different persons, were unsatisfactory. Many causes were assigna- ble for this, and it was considered by the present superintendent, Professor A. D. Bache, desirable that the most obvious of the causes of error should be got rid of, by render- ing the machine automatic, before the minor causes of irregularity were sought for. This was done by Mr. Saxton, in the manner described in 213. the following pages. The result has B B been very successful, not only in its M first application, but in permitting W the determination and removal of sources of error, previously conceal- ed in the working of the machine. The drawings of the proposed ad- ditions upon a scale necessary for working, were made by Mr. Saxton, and the work was executed by Mr. William Urdeman and his assist- H ant mechanicians in the coast-survey office. Accuracy, beauty of finish, ease of reading, economy of time, and labor in dividing, have all been T gained by the improvements. The machinery for rendering the dividing machine automatic, consists of a brass wheel A, about 20 inches in diameter, mounted on the axis B, Fig. 213. One of the arms of the wheel A has a slit extending from near the cen- tre of the rim ; in this slit is fixed the crank-pin so that it can be placed at any re- quired distance from the centre. On the edge of the wheel is turned a groove, in which runs a cord for driving the wheel. On the other 214. end of the axis is fixed the wheel C, which is geared into the wheel D, on the lower end of the vertical shaft E, Fig. 214. On the upper end of the same shaft, is another wheel F, El geared into the wheel G, on the horizontal shaft H. On the end of the shaft H, is a wheel I, which gears into the wheel J, on the axis K. The wheels CDFGI and J are all bevel wheels, having the same number of teeth, (60,) and work into each other at right angles. H The shaft E has on it a sliding-joint L, for 215. altering its length; the shaft H is turned and ground of uniform thickness, 80 that it may a slide accurately through the socket of the a O wheel G, and also through its bearing at M, in which it turns. The axis K has on it two ec- centrics, N and 0: N to raise the tracing point, and o to move it horizontally. One-half of the U circumference of N is concentric with the axis b on which it turns, so as to keep the point up R e while the crank-wheel moves half a revolution, and is moving the dividing plate. The other is eccentric to the axis about one-tenth of an inch, 80 as to let the point rest on the circle while it is making the division. The eccentric 0 has about fth of its circumference concentric to the axis; the rest is described from a point about fth of an inch from the centre. N and 0 must be fixed on the axis with regard to each other, so that N will raise the point before o begins to move it back, and both with regard to the crank-wheel A, 80 that the point 10 Digitized by Google 74 AUXILIARY EXPANSION. will be raised before the crank begins to move the dividing plate, and keep it up until it is done moving, and o has moved the point back, and then let it down before 0 begins to let it return. The axis K has also on it, near the end, a small cog P, to shift the ratchet-wheel Q one tooth every revolution of K. The ratchet-wheel has 60 teeth, and is kept in its proper position by the detent spring R. In front of the wheel, and fastened to it by two screws, is a circular plate S, Figs. 213 and 215, with 20 notches in its edge, the deepest one for the longest line, or 5°; the next for 30'; and the shallowest for 15'; and the edge of the plate for the 5' lines. The segment T, Figs. 213 and 215, is fixed on the vertical part of the tracing-frame U, and has a pin in the end at V, of such a size that it can drop into the notches in S, as they are brought under it by the revolutions of the ratchet-wheel, and 80 regulate the length of the division lines. The time of raising the ratchet must be when the stop-pin is raised out of the notch, by the motion of the traces backwards. To give motion to the screw, a stout fusee-chain is used, one-eighth of an inch broad, and one-fourteenth of an inch thick, which answers well; one end is attached to the ratchet-barrel W, round which it is wound five or six turns; the other end is attached to the crank-pin X. Near the lower end of the chain, at Y, is a small tube, containing a strong spiral spring, arranged like the common spring weighing-ma- chine, but having a motion of only about fth of an inch; the spring must be 80 strong as not to give by the force required to turn the screw, but only to give a little when the ratchet comes up to the stop, and the crank is just passing the lower centre. Between the spring and the crank-pin is an a. rangement for lengthening or shortening the chain, when it is arranged for making a larger or smaller division; for this purpose, two pieces of brass wire, about six inches long, having a screw cut on them their whole length, and each filed away one-half, and two small milled nuts, tapped with the same thread, are run on each the two wires are laid together, and the nuts screwed up until they embrace both wires, as shown at Z, Fig. 213. The crank-pin is fixed on a slide, projecting beyond the nut which fastens it, 80 that it may be extended, if necessary, beyond the circumference of the wheel, or by reversing, it may be brought quite to the centre. When the divisions are to have the long end towards the centre, a jointed lever, as shown at a, Fig. 215, is used. It is screwed fast to the cross-bar b, Figs. 214 and 215, directly over the eccentric o, and connected to the vertical frame U at c, and the stop-pin V is shifted to the other end of T, and the abutting piece f on U, is to be removed, when the eccentric 0 will act against the lever a, at d, and move the point in an opposite direction. The tracing-frame is made to follow the eccentric, by a weight and cord passing over a pulley and hooked to the vertical part of the tracing frame at ee, Fig. 215. When the adjustment is made for dividing with the long end of the division lines, towards the circum- ference of the circle, all the wheels connecting the axis K with the axis B should be marked with a dot on the tooth and space in which it works, and a line should be drawn on the shafts E and H, and a cor- responding mark on the sockets through which they pass, 80 that they may always be fastened in the same position. The axis K should have two short pins fastened on it, and notches in the ends of the sockets N and O, to fix them in their proper position when the lines are towards the circumference or centre, as the case may require. The slit in the crank-wheel A, in which the crank-pin is fastened, should also be graduated, showing the distance of the pin from the centre, for each degree, minute, and second that may be required in dividing. By marking the position of each part of the machine in this way, much time and trouble will be saved in making the necessary changes for different kinds of dividing, whether it be in the number, or the di- rection in which the long lines are to be extended. The tracing point should be adjusted so as not to be raised more than about the thirtieth of an inch, or it will be liable, in descending, to make a small dot at the commencement of each line, which would injure the appearance. In the drawing, the eccentric N is represented as acting on the tail of the tracing-frame, but it is better to make it act on a steel pin in the side of the tail. By this arrangement of the crank for turning the dividing-screw, the stops of the ratchet are brought in contact when the crank is passing its centres, and the motion of the screw is so slow, that it is not pos- sible for the stops to strike so hard as to do any injury, and the dividing may be done with great ra- pidity. AUXILIARY EXPANSION. Slide-frame and Gearing.-See LOCOMOTIVE ENGINE and TENDER. AWLS, various kinds of. See BORING TOOLS. AXLES, GREASE FOR RAILWAY. Booth's Grease for Railway Axles.-Water 1 gallon, clean tallow 8 lbs., palm oil 6 lbs, common soda f lb.; or tallow 8 lbs., and palm oil 10 lbs. The mixture to be heated to about 210° F., and well stirred till it cools down to about 70°, when it is ready for use. AXLE GREASE; for Railway Carriages. Some mystery has been made on this subject, and patents taken out for various articles, but I believe, from experience, the following is the t:-Take 56 or 60 lbs. of soda; dissolve in about 8 gallons of water in a small boiler; when quite dissolved, to be poured into a large tub or wooden cooler, containing from 80 to 36 gallons of cold water, and well mixed. Tallow to be melted (according to the proportions hereinafter stated) in a 60-gallon boiler. After being thoroughly dissolved, palm oil is to be added, and then the mixture allowed to boil; as socn as it boils the fire to be taken out of the furnace, and the mixture to be cooled gradually, and to be frequently stirred while cooling. When cooled down to blood-heat (98°), it is to be run off through a sieve into the cooler containing the water and soda, and it must be stirred during the whole of the time it is running off, in order that it may be properly mixed. Proportions of Oil and Tallow. Summer Weather. Winter Weather. In open Weather, (Spring or Autumn.) Palm oil 1 cwt. 1 qr. I Palm oil 1 cwt. 3 qrs. " I Palm oil 1 cwt. 2 qrs. Tallow 1 " 3 Tallow 1 " 1 " Tallow 1 " 2 44 } equal quantities. AXLES, for turning Narrow Curves. This is an improvement in the construction of Railroad Car. Axles, invented by Messrs. Morse and Mansfield, Machinists, Canton, Mass. Digitized by Google AXLES. 75 This invention has been effectually tried during the past year on the Boston and Worcester, the Boston and Providence, and several other Railroads in New England, and the valuable practical testimony of the Superintendents and Engineers of these roads is highly favorable-exceedingly 80. The saving of tear and wear of the wheels where it has been used, has far exceeded expectation. The nature of the invention consists in having each axle as it were divided and hung in two middle suspen sion-bearings, which are allowed to swing on pivots, whereby the angles of the wheels can be diverged from the straight line for the better turning of narrow curves, than by extended immoveable axles. 216. A B 6 B B A 217. F E C C K X D D W DESCRIPTION.-Fig. 216 is a view looking down upon the truck, and Fig. 217 an end elevation. The same letters refer to like parts on both figures, therefore we will describe the engraving collectively. A A A A are the wheels. BBBB are the axles. CC are pinion and rack coupling. DD, Fig. 217, are the pivot axis of WW, the suspended axle-bearings. K K K, are the transverse timbers of the truck-frame. E is a pinion-crank, and F F are vertical bolts in the end of the pinion-crank to fit into recesses in the bottom beams of the car. G is an iron socket to receive a vertical bolt fixed on the bottom of the car. H H are friction pulleys to case the friction of the car upon the middle of the truck. The bolts FF, and the bolt in the car to fit into socket G, secure the car. to the truck. E, we call a pinion-crank, from the fact that below its cap-plate it has notches that fit into notches on the upper end of the swing axle-bearings. These notches coincide about one quarter of the circle on each side of the pinion with the notches in the upper part of W W, therefore the top of W W moves in slots in CC, as will be observed in Fig. 216. The operation of these axles is obvious; they prevent torsion, also much wear of the wheels and rails too. To allow the wheels to change with the angle of the axle as seen in Fig. 216, the outside journals of the axles are fixed in their boxes in such a manner that both the shoulders and journals move in their boxes and work very nicely. Digitized by Google 76 AXLES. It will here be observed, in the outeet, that the car acts as a guiding lever to make the axles and wheels conform to the curvature of the road. Fig. 218 is a top view, and represents the position of the wheels, axles, and body of the car passing over a double curvature. LL are the rails, and KK the body of the car. Fig. 221 is an enlarged view of two wheels and axles, and the axle-boxes with part of the car-frame. A A are the wheels. BB are the axles. ZZ are the central pivots of the car-body. Each wheel has a single axle for itself; and it has this advantage over other cars, that if one axle breaks, or one wheel, there is no danger of the car breaking down-the car will run steady upon three wheels to a truck. The inner ends of the axles are hung in suspension oscillating boxes, having cogs on the upper parts. Fig. 219 represents an oscillating box. D is an inside shoulder, and C are the cogs on the upper part. These boxes are at- 218. 221. K oz E c F K K: 219. 220. 00 oz tached by pivots to the central longitudinal beam of the car, and are retained in square plates, firmly secured to the central beam. E is a plate, on the under side of which are teeth to mesh into C, the open part of the axle bearing like pinion and rack coupling, and F is a crank with a bolt or wrist on the end of it, to fit into a slot in the bottom of the car-body KK. To allow the wheels to change with the angle of the axle, as seen in Fig. 219, the outside journals of the axles are fixed in their boxes in such a manner that both the shoulders and journals move in their boxes and work very nicely, as represented in Fig. 220. B is the axle. H, the axle-block; which, from the dimensions of the box, allows the axle at the outer end to move in unison with the other end of the axle in its oscillating bearings. The two crank-plates on each truck, which have wrists projecting into recesses of the bottom of the bar, are of unequal lengths, as seen in Fig. 218, 80 that the front and hind wheels will describe different angles, the whole conforming to the curvature of the road. A mathematical problem is in- volved in the combined motion of the car-body and wheels, which cannot be rendered plain in this de- scription, but its operation in Fig. 218 is correctly represented. The ingenious inventors are Messrs. Jedediah Morse and William Mansfield, both practical men; the former of Sharon, and the latter of Canton, Norfolk Co., Massachusetts. Digitized by Google AXLES. 77 AXLES, Vibrating Box for Locomotives-Invented by Norris & Tull, of Philadelphia. The arrange- ment of this box allows it to revolve in a vertical plane, at the same time that it floats up and down, the journals of the drivers having, at all times, their full bearing upon the box. Let the axle assume any position from a horizontal line, caused by inequalities of the road, or the consequent raising of the outer rail in passing curves, which must necessarily reduce friction in a great degree, and insure the more perfect working of the engine, without producing any undue strain in its several parts; it has 2211 d (4) 223. 222. m A m. m B 225. 224. n n IF SC B b b m m a c only to overcome the friction which is due to the surfaces upon which it works. This evil. has always been overlooked in the construction of locomotives, and which must occur when a box floats vertically in a pedestal. Fig. 221}.-Elevation of pedestal with vibrating-box. Fig. 222.-Cross-section of the same. Digitized by Google 78 AXLE AND WHEEL. Fig. 223.-Ground plan. Fig. 224.-Vibrating-box. Fig. 225.-Bearing of vibrating-box. A A, pedestal forming part of the wrought-iron frame. B, vibrating-box resting with the two pivots b', which are firmly attached to it in openings of the two sliding-pieces c'. Fig. 225 shows an end view of one of the latter, with its flanges m m', and the hole a, which is to receive the pivot b. These sliding-pieces are connected, by means of screws x x, with the cross-piece d, the lower surface of which is cylindrical, and forms a bearing for the upper convex surface n n', of the box B. f, wedge, kept by the set-screw f' in a position which allows the box to slide in the pedestal without being too loose or too firm. g, oil-box. In Fig. 224 this oil-box is omitted. The same parts are marked by the same letters in the different views. AXLE AND WHEEL, or the wheel and axle, is a kind of lever, in which a plane is moveable about an axis perpendicular to that plane, or 80 contrived as to have a continued motion about its fulcrum, or centre of motion, where the power acts at the circumference of the wheel, whose radius may be reckoned one arm of the lever, the length of the other arm being the radius of the axle, on which the weight acts. If the power acts at the end of a handspike fixed in the rim of the wheel, then this increases the lever- age of the power, by the length of the handspike. 22b. The wheel and axle consist of a wheel having a cylindrical axis passing through its centre. The power is applied to the circumference of the wheel, and the weight to the circumference of the axle. In the wheel and axle, an equilibrium takes place when the power multiplied B C by the radius of the wheel, is equal to the weight multiplied by the radius of the axle; or P: W : CB. For the wheel and axle being nothing else but a lever so contrived as to have a continued motion about its fulcrum C, the arms of which may be represented W by A C and BC; therefore, by the property of the lever, P W CA P If the power does not act at right angles to C B, but obliquely, draw CD per- P pendicular to the direction of the power; then, by the property of the lever, P: W CD. It will be easily seen, that if two wheels fastened together and turning round the same centre, be so adjusted, that while they turn round they will coil on their circumferences strings, to which weights are suspended; one of those wheels being larger than the other, the larger wheel will coil up a greater length of the string than the smaller one will do in the same time, and this will de- pend either on the radii or circumferences of the two wheels. The velocity of the weight will be in proportion to the length of string coiled in a given time; therefore, the velocity of the weight will be greater as the wheel is larger. Now, as in the lever, we saw that a small weight required a greater velocity to balance a large weight with a small velocity, we may infer, that the rules given for levers will also apply to the wheel and axle; since the velocity of any body on a lever depends upon its dis- tance from the fulcrum. EXAMPLE-A weight of 13lbs. is to be raised at a velocity of 14 feet per second, by a power whose velocity is 20 feet per second; how great must that power be 1 13 X 14 ÷ = 9.1, the power required. If the velocity of the weight, be to that of the power, as 14 to 20, and the radius of the axle on which the weight is coiled be 7; then, 20 X 7 ÷ 14 = 10, radius of wheel on which the power acts. If a weight of 36lbs. is to be raised by an axle 3 inches diameter; what must be the power applied at the end of a handspike 4 inches long, fixed in the rim of the wheel connected with the axle, the wheel being 6 inches diameter Here the handspike will increase the distance of the power from the fulcrum, and will add to the diameter of the wheel twice its own length; therefore, 8 + = 14 ;-hence, 14 : 3 36 : 7.77, the power required to keep the weight in equilibrio. Wheels acting on each other by teeth or bands, may be easily calculated in the same way. Thus, if a wheel which has 30 teeth, drives another of 10 teeth, it is evident, that as the larger wheel has three times as many teeth as the smaller, the smaller wheel will be turned round three times for once that the larger one is turned round so that the velocities of the wheels will be inversely as their num- ber of teeth. In like manner, it is clear, that if the larger wheel drives the smaller not by teeth but by a band, their revolutions will be inversely as their circumferences. EXAMPLE-The number of teeth in one wheel are 160, and in another driven by it are 20, and the larger wheel makes 12 revolutions in a minute; how many does the smaller one make 1 20 : 160 : : 12 : 96 = the number of turns which the smaller wheel makes in a minute. The larger wheel is usually called the wheel, driver, or leader, and the smaller one is called the pinion, driven wheel, or follower. Let us now see what would be the action of two wheels and a pinion, if the first wheel contains & teeth, the pinion 12 teeth, and second wheel 36 teeth. Place the first wheel and the pinion on the same axis, 80 that they move together, one revolution of the one being in the same time as a revolution of the other, and the pinion drives the second wheel. If the first wheel makes 16 revolutions in a minute, the pinion will do the same, and the pinion drives the second wheel; therefore, 36 12 16 : 5f = the velocity of the second wheel. Place these so, that the teeth of the first wheel act in the teeth of the pinion, and these again act in the teeth of the second wheel. If the first wheel make, as before, 16 turns in a minute, then the pinion will make 12 80 : 16 : = in a minute; consequently, the revolutions of the second wheel will be 36 : 12 35.55 = turns the second wheel in a minute. Digitized by Google AXLE AND WHEEL. 79 When there are a number of wheels ABCD, 227. acting on the respective pinions a bcd, then the c D effect of the whole may be found thus: if the let- ters which represent the wheels and pinions be understood to signify the number of teeth of each, power X AX BX CX D aXbXcXd weight. If the velocity of the first wheel be used instead of the power applied, then this rule will give the resulting velocity instead of the weight. EXAMPLE-If the numbers of the teeth of the wheels are 9, 6, 9, 10, 12, and those of the pinions 6, 6, 6, 6; then if the power applied be 14lba, we have 14X9X 6 X 9 X10X12 6x6X6X6X6 = 105lbe, the weight. And, by the remark under the rule, if the first make 14 revolutions in the minute, the speed of the last will be 105 in the same time. The same rule will apply to the case where the wheels act on each other by ropes or straps, if the circumferences of the wheels and pinions are used for the number of teeth. It often happens, in the construction of machinery, that two shafts must be connected by means of toothed wheels, in such a way, that the velocity of one shaft shall bear a certain proportion to that of the other shaft; and we must determine the number of teeth in each of the connecting wheels and pinions. Take the respective numbers of teeth in the pinions at pleasure, and multiply all these together, and their product again by the number of turns that the one shaft is to make for one turn of the other shaft. Take, now, this product, and find all the numbers which will divide it without a remainder, or divide its divisors without a remainder-always excepting the number 1. Arrange all these in one line, and separate them into parcels or bands, each containing as many numbers, or factors (as they are called) as you please; but observing, that there must be as many bands as there are wheels required; then the product of the numbers in each band will give the number of teeth in the respective wheels. Thus, if one shaft is to turn 720 times for another shaft's once, and there be interposed 4 pinions, one of which is fixed to the end of the one shaft, each pinion having 6 teeth or leaves: then, 6 X 6 6 720; all the divisors or factors of which are 3, 2, 3, 2, 3, 2, 3, 2, 2, 2, 3, 5, 2, 2, 3; these divided into 4 bands at pleasure, give the number of teeth in the wheels. Thus, 2X3X5 =80, 3X8X5 = 45, Either 2X2X2X3=24, Or, '= X x 2X2X3X3=36, { 3X3X2 =18, 2X2X3X3=36, 3X2X2X2 =24, The application of what we laid down may be thus illustrated. In finding the number of teeth in the wheels of an orrery, we extract from Marrat's Mechanical Philosophy. There is considerable difficulty in proportioning the number of teeth in wheels for clocks, orreries, &c., the problem indeed is indeterminate; we shall, however, give an example, that will point out a method by which any inge- nious mechanic may complete a piece of machinery, such as an orrery, so as to show, at all times, in what part of its orbit any planet is. The following example is for Mercury: this planet goes round the sun in 87d. 23h.; now as the hour-hand of a clock goes round twice in 24 hours, it will make 17511 revolutions in 87d. 23h. For the fraction 11, take any multiple of the denominator plus or minus unity, and make it the third term of the proportion; thus say, as 12 : 11 515 472 nearly; for 111 is one unit less in each than a multiple of 1/2 by 473; hence the revolutions become. 175 472 00597. Now the only difficulty remaining, is to find proper factors or divisors that will divide the numerator and denominator without a remainder, in order to determine the number of teeth and leaves in the wheels and pinions. For the numerator, the best method Mr. Grier found is to make trial of the num- bers 2 X 5 or 10, as often as we can, and if we do not succeed, to try successively the prime numbers 3, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, &c. He found by trials the numerator will break into the factors 101 X 39 X 90597, and concluded then that these numbers 101, 39, 23, may be the num- ber of teeth in three wheels. We can easily break the denominator into the numbers 103 and 5; but as 103 is too large for the teeth in a pinion, and being a prime number, another number must be sought for that will answer the purpose better. Again say, as 12: 11 1825 : 1673; the revolutions now become 1751873, or 39104. Hence we find by trial that the numerator (321048) can be broken into the factors 91 X 72 321048, which may be three wheels having that number of teeth in each. Again, the denominator of the fraction, or 1825, is capable of being broken into the factors 73 X 5 X 5 = 1825. Now the product of the number of teeth in all the wheels, divided by the product of the number of teeth in all the pinions, will give the revolutions. For example, 321048- ÷ 1825 = 175 revo- lutions, 11h. Om. 1s. 58 thirds, which does not exceed the 87d. 23h. (or 17511 revolutions) by two seconds. The numbers last found for the wheels and pinions, may be transformed by multiplication into more convenient numbers, as 98 73 X 10 X 5 91 72 = 144 73 10 175r. 11h. Om. 1s. 58th., either of which will be a train of wheel- X work proper for such я motion, and this train may be conveniently attached to the pinion of the hour- wheel of a clock. The reason for finding a new fraction, will appear evident; for if we take the original number, 175H we shall find it impossible to break the numerator into factors without leaving Digitized by Google 80 BACKING OF ARCHES. a fraction, which is inconsistent with wheel-work, as nothing but whole numbers will answer the pur- pose. It is obvious, that the higher we take a multiple of H the nearer we approach to the true time of revolution, provided we can break the numerator and denominator into proper numbers for the teeth and leaves of the wheels and pinions. It is necessary to observe, that there must be either three wheels and three pinions, or, if the numbers when broken be too large, if we can break them into five wheels and five pinions, it will be the same thing; because, as the hands of a clock go round with the sun, that motion would make two wheels and two pinions (attached to the pinion on the hour wheel) go round the contrary way to what they ought; but three or five will answer the intended purpose. BACKING OF ARCHES. See RAILWAY ENGINEERING. BACK LINKS. See DETAILS OF ENGINES. BACKWATER, or SCOURING POWER. The stream of water employed in connection with harbors, to carry away the shingle and prevent its accumulation at the mouth. They are employed where a great quantity of water can be obtained at high tides, large reservoirs being filled at such times, and the water is afterwards discharged on the bar at low-water. BALANCE-GATES. A certain description of floodgate, much 228. used in Holland, acting upon the following principle: the gates are fixed on a vertical shaft as a centre, and are kept closed by the pres- sure of the water against them, one side of each being larger than the other and in order to open them, when requisite, a sluice is con- structed in the largest side, which, upon being opened, reduces the area of this side of the gate to less than that of the other side upon which the water consequently acts upon the gates, and opens them. BALKS. A term applied to long pieces of timber, from about 5 to 12 inches square. BALANCE-VALVES. See VARIETIES OF STEAM-ENGINES. BALLAST-WAGON. The wagon employ- ed in removing earth in excavations, and the 229. like, the which hold about 2 cubic yards, or 21 or 8 yards at the utmost. even by piling up. If they are filled too full they are apt to tilt. They are usually used without springs, but they are better with them, particularly for those working on permanent rails, as the former in- creases the wear and tear of the rails, and adds to the expense of maintaining the way. The cut shows an improved form of ballast-wagon. See EARTHWORK. BALLASTING, or METALLING, (sometimes called Bottoming.) A term applied to the covering of roads generally, and to the filling-in material, above, below, and between the several stone blocks and sleepers upon railways, dc. it is laid for the purpose of keeping the road dry, as in the event of water lying upon it, the rails invariably sink, as it causes them to rest unequally. Ballasting is mostly composed of gravel, broken stone, or the like, and is laid about two feet thick on railways, the finished surface of it being usually rather more than one inch below the level of the rails, and it is generally from 6 to 12 inches thick on roads. A longitudinal drain, six inches square, is sometimes laid within railway ballasting, having cross drains, 15 feet apart, communicating with the same, to convey the water into the side ditches. These drains should invariably be used in excavations and when employed in embankments, the water is led down the slopes by drains. BALUSTRADE A series of balusters situated and fixed under the coping of the parapet of a bridge, &c., which are not employed in engineering works so frequently as formerly. BALL VALVES OF LOCOMOTIVES. See DETAILS OF ENGINES. BANDING PLANES. See CHISELS AND PLANES. BAR. A piece of timber or metal placed horizontally, and running across from one part of any framework to another. BAR, (in navigation.) An accumulation of sand or shingle at the commencement or mouths of rivers, harbors, &c, being formed by the action of the tides. BARBERY-WOOD. See Woods, varieties of. LAROMETER, or VACUUM GAGE. See DIMENSIONS OF STEAM-ENGINES. BAR-WOOD. See WOODS, varieties of. BARREL, (of a drum-wheel.) The cylindrical body or axle round which the rope is rolled. BARREL (of a pump.) The cylinder, or hollow part of the pump, in which the piston works. BARROW. A machine generally used for carrying soil in the formation of excavations and other works at their commencement, before a road is formed. BASE LINES, (in surveying.) The main lines of a survey, upon which the correctness of the whole depends; it is therefore necessary to proceed with the utmost care in the laying out of the several base lines of a survey. BAT. The name given to a half, or other portion of a brick. BATH-STONE. A very serviceable sandstone, almost wholly calcareous, although some of it is more silicious. It is extremely soft when taken out of the quarry, but afterwards becomes hard. In setting the stones, it is very essential to lay them in their natural or quarry bed, which remark may be applied to every description of stone, although not in the same degree as with Bath-stone. BATTER. The face of a retaining, or other wall, when built in a leaning position, the top part fall- Digitized by Google BEETLING MACHINE. 81 ing back within the line of base; walls of this description are sometimes termed tallue walls. The bat- ter of a wall is either straight or curved; the latter are also generally commenced straight from the top, the greatest degree of curvature being given to the bottom of the wall. BAY-TREE. See WOODS, varieties of. BEAM. Of Land Engines, to find the vibration of studs; depth at centre; the total depth is equal to the diameter of the cylinder; depth of beam at ends; thickness of beam; studs of beam; when of cast-iron; when of wrought-iron. See DETAILS OF ENGINES, and DIMENSIONS OF ENGINES. BEARINGS. Management of; spherical advantages of. See MANAGEMENT OF ENGINES, and DETAILS OF ENGINES. BEARINGS, as applied to carriages, &c. The chairs supporting the framework of the carriage, which merely rest on the axles and upon the outside of the wheels of railway-carriages; but they are fixed to the axles of all common road-carriages. BEECH. See WOODS, varieties of. BEEF-WOOD. See Woons, varieties of. BEETLE A wooden instrument, or mallet, for driving piles, being raised by the help of ropes and pulleys: the term is also applied to the rammer used for driving stones into the ground. BENCH, or BERM. A ledge left on the face of a cutting to strengthen the same. Steep cuttings should always have ledges to support them, particularly in canal work, to prevent the mould from the upper part falling down into the water; chalk may also be executed at a very steep inclination by their assistance. Ledges are likewise generally made at a change of slope, occasioned by meeting with a different soil. BEETLING MACHINE. This invention relates to improvements in producing various kinds of or- namental and other figured fabrics, by pressure from corrugated or indented surface-rollers, of various patterns; and consists, first, in the peculiar construction and arrangement of suitable machinery called beetles, in which one or more grooved or indented roller, or rollers, form the principal feature of these improvements; the said rollers being employed for the purpose of giving to woven fabrics a glossy finish, similar to that which is now produced by the ordinary stamps used in the machines called beetles. Also, for improvements in arranging and applying steam or fluids to such purposes, thereby giving a certain pressure to the rollers employed in the improved beetle; and, further, for a combina- tion of mechanical arrangements necessary for the construction of a roller-mangle, with a sufficient pressure to produce, when required, the operation of beetling. The accompanying engravings represent, at Fig. 230, a front elevation, and at Fig. 231, an end elevation of the above-mentioned machine, with the samé letters of reference applying to similar parts. A A are cast-iron stand- ard frames, having side-claw projecting bearings BB, Fig. 231, with two central horn-shaped ones A¹, carrying the pressure-lever links; CC are bush-bearings for the journals of the beetling-rollers D and E, which rotate horizontally with each other in opposite directions; F F is the roller upon which the cot- ton fabrics, about to undergo the beetling process, are wound; G G is the pressure-roller, mounted in the lever-link motion-head H H, upon the central horn-standard in a manner subsequently explained; I is the shaft upon which the pressure-roller revolves; K K two connecting-rods on each side of the machine, attached in vertical positions at the top to the links HH, and at their lower ends to the weighted levers L; M is the centre stud, upon which the levers L L radiate; N N are two spherical- shaped balls or weights, for giving pressure to the roller G. through the medium of the levers LL, as- sisted by their own gravity; o is the bearing on which the connecting-rods KK move; P is an inter- mediate crank motion-rod, coupling the two way link-shafts V R, and giving motion horizontally to the longitudinal rest-bars TT, through the quarter-way links SS, in gear with the same; U U are two spur-wheels, mounted upon the beetling roller-shafts D and E, in gear with a pinion V, on the driving- shaft; W X is a long hand-lever, the object of which is to raise the different- rollers from their beds by it in the manner hereafter explained. Having thus far described the various arrangements and parts of which this invention consists, it is necessary to explain its mode of working, and the numerous advan- tages that may result from its application to the various purposes for which it is intended. Steam, or other motive power, is in the usual manner first applied to the driving-shaft W, which is mounted in a bracket bearing against the standard-framing, as represented in the engraving; whilst the other end is similarly mounted against a wall or other convenient place, and when driven by the action of steam, it causes the pinion V, on the end, which takes into the spur-wheels UU, to propel the same, and thereby give the required motion to the machine or apparatus during the process of beetling. It must be observed, that the cotton fabrics about to be mangled or beetled, are first wound upon the roller F; to accomplish which, the roller has to be removed or taken out of its place, which is performed in the manner hereafter explained. Having completed the operation of winding the cotton on the rollers, it is then passed between the beetling-rollers D and E, which are furnished with periph- eries, such as are seen in the two smaller engravings annexed; these are embossed. or checkered in different patterns corresponding to the rollers employed. The fabries are then taken from the rollers and replaced by others, during the working of the machine, and the operations effected. The pressure to which the fabrics are exposed by the constant rotation of the rollers between F hich they pass, is produced and carried into effect as follows roller G G, with its moveable link- bearings on each side, centred on the horn-shaped standards, are caused, through the medium of the side connecting-rods KK, to receive the entire weight of the levers LL, in addition to the weights H H on the ends, and consequently offer a sustaining pressure to the fabrics during the process of beetling. On the other hand, when it becomes necessary to supply the apparatus with plain cotton fab- rics, and remove those already beetled, the levers L L. which are represented as having holes at one end for the employment of any suitable or convenient tackle, are to be by such means raised, the action of which will have the effect of raising also the head-links and pressure-roller, and thus, by removing the weight, enable the roller beneath to be lifted out of its seat, and placed in one of the end claw- bearings BB, as represented by the dotted lines. The mode of effecting this part of the operations will 11 Digitized by Google 82 BEETLING MACHINE. be readily comprehended by reference to the engraving, Fig. 231, where TT shows a bar of iron hori- sontally placed on each side, beneath the journals of the roller F, forming a rail or table upon which they are to be moved. When a downward motion of the lever handle is given by the operator, it causes the coupling-rod P, through the medium links P R, in connection with others on the same shaft, in gear with the rest-bar TT, to move upwards horizontally, similar to the action of a parallel rule, and raise the rollers F or B out of, or into their respective places, by enabling the rollers to be rolled along them, when disengaged from their bearings or seats, and carefully lowered into their places, in readi- ness for the next operation. From these observations it will be seen that, first, the levers LL are to be raised in the manner which will cause the roller GG to be also raised, through the medium of 230. H H G B B U X D R W N L V 231. A A H I J K X B B I T A s E A B M N L the connecting-rods KK, when the pressure will be removed from the lower rollers, and which will enable them to be raised to the required height, 80 as to transfer them from one seat or bearing to another, and thus allow the fabrics to be changed by removing those already having undergone the process, and supplying the other roller with plain ones. The patentee, although he describes and sets forth the employment of the side-levers, yet does not confine himself exclusively, as other and equally effectual means may be applied with the same advantages, such as steam pressure, liquids, or other wise; and in many cases the weight of the rollers themselves might be found sufficient to give the re- quired pressure without the intervention of additional pressure. The next object to which the patentee directs attention, is to the improved mode of construct- ing roller-manglea, which consists of very nearly the same arrangement of rollers, the only apparent difference being, the introduction of a flexible lever or spring, firmly fixed to the standards upon which Digitized by Google BELTING. 88 the pressure-roller is mounted, being brought to act upon 232. the same to any degree of force, by the application of a hand-wheel and screw-spindle, supported in bearings, suit- ably arranged. To the end of the screw-spindle two fixed studs are attached, between which the lower end of the flexible lever or spring is introduced, 80 that when the spindle is screwed to or from the centre of such stand- ard, carrying the roller, the pressure is applied by rea- son of the standard moving from a centre with the rol- ler under an elastic pressure thus given by the forward or backward application of the screw hand-wheel spindle. The patentee states that cast-iron rollers may be employed for dry articles, but for damp ones, bell-metal would be found better adapted. One of the advantages derived from this system of mangling is the small space the ma- 233. chine occupies, together with the accommodation which it offers by being placed within a piece of furniture having drawers for the purpose of disposing of the various articles when 80 mangled, and thus forming a very useful piece of furniture, and which may, if necessary, be rendered high- ly ornamental in place of the present incommodious ma- chine now in use. The same principle also extends to a portable description of mangle, which the patentee states may be temporarily set up on a table or dresser, and made to answer all the purposes for which it is in- tended, motion being given to it by hand-levers in the usual manner, but employing, as a means of giving pres- sure, a lever, as in the first-mentioned instance; but with this difference, that the connecting-rod K, in the beetling apparatus, has in this instance a rack and pinion as a means of adjusting it, so as to obtain the requisite pressure. The patentee, after describing the peculiar forms given to the several rollers comprising a series of different patterns, and the best means of constructing them and forming the corrugations or indentations upon them, would wish it to be distinctly understood, that he claims as new and of his invention :-First, the employment of rollers having indented, grooved, checkered, or undulated surfaces or peripheries, for producing by pressure corresponding marks or impressions there- with upon cotton or other fabrics. Secondly, for the general arrangement of parts constituting the action and construction of the said improved machinery. Thirdly, for the employment of water or other fluids within the aforesaid rollers, to act independently of other pressure apparatus, such as the long levers in Figs. 230 and 231, of the annexed engravings; also for the application of steam to such purposes, causing, in the usual manner by its expansion within a cylinder, a pressure to be exerted upon the rollers, and at the same time that such application should be available for the purposes of taking off and removing the pressure when required, the same means employed for the one shall be found effectual in performing the other. Fourthly, and lastly, for the use of the numerous patterns as applied to cylinders employed in the process of beetling, or to other like machines or apparatus, either for mangling, or otherwise, as hereinbefore fully detailed. See CALENDERS. BELL-METAL See DETAILS OF ENGINES. BELLS. See CASTING AND FOUNDING. BENCH MARKS, (in surveying.) Fixed points left on the line of survey for reference at any future time. consisting of cuts in trees, pegs driven in the ground, and the like. BETON. A French concrete or mortar, used in the foundation of hydraulic works: it consists of twelve parts of puzzolana, nine of quicklime, six of sand, thirteen of stone scablings, none exceeding the size of an egg, and three parts of iron scales from the smith's forge; after being well mixed and indurated together, it is broken in pieces, and a coffer having been previously prepared, it is dropped by & proper box into the same, and laid in alternate layers with rubble stones, until sufficiently elevated to receive the masonry. BELTING. We have taken this article from C. E. Leonard's valuable book, "The Mechanical Principia." The following table shows the velocity of belts: the column marked Revolutions Shaft," shows the number of revolutions which the line or driven shaft is supposed to make per minute; the column marked 44 Diameter Drum," shows the diameter of the drum on the line or driven shaft. EXAMPLE:- The line shaft is required to make 120 turns per minute, and it is desired to have the belt run 1800 feet per minute; required, the diameter of the driven drum. Find 120 in the column marked " Revolu- tions Shaft;" opposite to this number in the table find 1800, or the nearest to it, which is 1884 feet ; over this number in the column marked Diameter Drum," will be found 5 feet, the diameter of the drum- EXAMPLE-The line shaft makes 100 turns a minute, the diameter of the driven drum is 4 feet required, the number of feet the belt moves a minute. Find 100 in the column marked Revolutions Shaft," opposite to the number in the table, and under 4 in the column marked Diameter Drum," will be found 1256 feet. Digitized by Google 84 BELTING. No. 1. Revolu- DIAMETER DRUM. tions Shaft. 2 21 3 31 4 41 5 51 B 100 628 785 942 1099 1256 1413 1570 1727 1884 110 690 863 1036 1208 1381 1554 1727 1899 2072 120 753 942 1130 1318 1507 1695 1884 2072 2260 130 816 1020 1224 1428 1632 1836 2041 2245 2449 140 879 1099 1318 1538 1758 1978 2198 2417 2637 150 942 1177 1413 1648 1884 2119 2355 2590 2826 160 1004 1256 1507 1758 2009 2260 2512 2763 3014 170 1067 1334 1601 1868 2135 2402 2669 2935 3202 180 1130 1413 1695 1978 2260 2543 2826 3108 3391 190 1193 1491 1789 2088 2386 2684 2983 3281 3579 200 1256 1570 1884 2198 2512 2826 3140 3454 3768 The following table shows the required width of belts to transmit different number of horse power. The apparent degree of accuracy in this table is not obtained for any practical use, but to show the theoretical power of belts; when the belts exceed 12 inches in width the fractions may be omitted. This table is calculated upon the velocity of the belts being from 25 to 30 feet per second, which is the ordinary velocity; if the power to be transmitted exceeds 20 horse, and circumstances will not allow the centre of the drums to be over 15 feet apart, the power should be transmitted by gearing. EXAMPLE-Required the width of a belt to transmit 20 horse power from a water-wheel, the diame- ter of the smallest drum being 6 feet. Find 20 in the column marked " Horse Power opposite to this number in the table, and under 6 in the column marked Diameter," will be found 12 inches, the width of the belt. EXAMPLE-Required the width of a be! in transmit 100 horse power from an engine, the diameter of the smallest drum being 5 feet. Find 100 in the column marked Horse Power;" opposite to this number in the table, and under 5 in the column marked 'Diameter," will be found 72 inches, which can be divided into four 18-inch belts, or any desired width. No. 2. DIAMETER. Horse Power. 2 3 4 5 6 7 8 9 10 1 1.8 1.2 0.9 0.72 0.6 0.514 0.45 0.4 0.36 2 3.6 2.4 1.8 1.44 1.2 1.028 0.90 0.8 0.72 3 5.4 3.6 2.7 2.16 1.8 1.542 1.35 1.2 1.08 4 7.2 4.8 3.6 4.88 2.4 2.056 1.80 1.6 1.44 5 9.0 6.0 4.5 3.60 3.0 2.570 2.25 2.0 1.80 6 10.8 7.2 5.4 4.32 3.6 3.084 2.70 2.4 2.16 7 12.6 8.4 6.3 5.04 4.2 3.598 3.15 2.8 2.52 8 14.4 9.6 7.2 5.76 4.8 4.112 3.60 3.2 2.88 9 16.2 10.8 8.1 6.48 5.4 4.626 4.05 3.6 3.24 10 18.0 12.0 9.0 7.20 6.0 5.140 4.50 4.0 3.60 12 21.6 14.4 10.8 8.64 7.2 6.168 5.40 4.8 4.32 14 25.2 16.8 12.6 10.08 8.4 7.196 6.30 5.6 5.04 16 28.8 19.2 14.4 11.52 9.6 8.224 7.20 6.4 5.76 18 32 4 21.6 16.2 12.96 10.8 9.252 8.10 7.2 6.48 20 36.0 24.0 18.0 14.40 12.0 10.280 9.00 8.0 7.20 25 45.0 30.0 22.5 18.00 15.0 12.850 11.25 10.0 9.00 30 54.0 36.0 27.0 21.66 18.0 15.420 13.50 12.0 10.80 35 63.0 42.0 31.5 25.20 21.0 17.990 15.75 14.0 12.60 40 72.0 48.0 36.0 28 80 24.0 20.560 18.00 16.0 14.40 45 81.0 54.0 40.5 32.40 27.0 23.130 20.25 18.0 16.20 50 90.0 60.0 45.0 36.00 30.0 25.700 22.50 20.0 18.00 55 99.0 66.0 49.5 39 60 33.0 28.270 24.75 22.0 19.80 60 108.0 72.0 54.0 43.20 36.0 30.840 27.00 24.0 21.60 65 117.0 78.0 58.5 46.80 39.0 33.410 29.25 26.0 23.40 70 126.0 84.0 63.0 50.40 42.0 35.980 31.50 28.0 25.20 75 135.0 90.0 67.5 54.00 45.0 38.550 33.75 30.0 27.00 80 144.0 96.0 72.0 57.60 48.0 41.120 36.00 32.0 28.80 85 153.0 102.0 76.5 61.20 51.0 43.690 38.25 34.0 30.60 90 162.0 108.0 81.0 64.80 54.0 46.260 40.50 36.0 32.40 95 171.0 114.0 85.5 68.40 57.0 48.830 42.75 38.0 34.20 100 180.0 120.0 90.0 72.00 60.0 51.400 45.00 40.0 36.00 Digitized by Google BELTING. 85 It is immaterial whether the smaller drum is the driving or the driven drum; if the diameter of the smaller drum remains constant, the width of the belt will remain constant, if the diameter of the other drum should be increased indefinitely. The following table shows the required width of large belts to drive different numbers and kinds of spindles with looms-the columns marked Mules," Mules and Frames," and Frames," show the number and kind of spindles to be driven, the column marked No. Yarn," shows the number of yarn which the spindles are supposed to spin, the column marked Diameter," shows the diameter of the smaller drum. No. 3. smallest drum being 6 feet. Find 5000 in the col- umn marked Frame Spindles;" opposite to this DIAMETER. number in the table, and under 6 in the column marked Diameter," will be found 32 inches, or Frame Spindles. No. Yam. 34 5 6 7 8 two belts 16 inches wide. 1000 30 to 40 13 10 8 61 5f 49 No. 8. 2000 44 64 26 20 16 13 11 9 3000 " " 39 30 24 19 16 14 4000 44 " 52 40 32 26 22 18 Spindles DIAMETER. 5000 46 " 65 50 40 32 27 23 Mule 48 39 33 28 and 6000 - " 78 60 Frame. No. Yarn. 3 4 5 6 7 8 No. 4. 1000 20 to 30 13 10 8 6f 5f 5 2000 66 66 26 20 16 13 11 10 3000 " " 39 29 24 20 17 15 DIAMETER. 4000 " " 52 39 31 26 22 20 5000 " " 65 49 39 33 28 25 Mule 6000 " " 78 58 47 39 33 30 Spindles. No. Yarn. 3 4 5 6 7 8 1000 10 to 20 13 10 8 7 6 5 No. 9. 9000 " " 27 20 16 13 11 10 3000 " # 40 30 24 20 17 15 4000 - 66 54 40 32 27 23 20 Spindles DIAMETER. 5009 & " 67 50 40 34 28 25 Mule 6000 $ 66 81 61 49 40 34 30 and Frame. No. Yarn. 3 4 5 6 7 8 No. 5. 1000 30 to 40 12 9 7 6 5 4f 2000 " " 94 18 14 12 10 9 3000 " " 36 27 21 18 15 13 DIAMETER. 4000 " " 48 36 29 24 20 18 5000 " " 60 45 36 30 25 22 Mule 6000 F " 72 36 31 27 Spindles. No. Yarn. 3 4 5 6 7 8 54 43 1000 20 to 30 12 91 If 6 5 41 No. 10. 9000 & - 25 19 15 12 10 91 3000 be to 38 28 23 19 16 14 4000 " 44 50 38 30 25 21 19 DIAMETER. 5000 F 66 63 47 38 31 26 23 6800 $4 & 76 57 45 38 32 28 Frame Spindles. No. Yarn. 3 4 5 6 7 8 No. 6. 1000 10 to 20 16 12 10 8 7 6 2000 " 66 32 24 19 16 14 12 DIAMETER. 3000 " " 48 36 29 24 21 18 4000 " " 65 48 39 32 27 24 Mule 5000 " " 81 61 48 40 34 30 Spindles. No. Yarn. 3 4 5 6 7 8 6000 " " 97 73 58 49 41 36 1000 30 to 40 111 9 7 51 47 41 2989 # " 234 17 14 11 If 81 EXAMPLE-Required the width of a belt to 3000 66 to 35 26 21 17 14 13 drive 2000 mule spindles with looms, the number 4000 4. " 47 35 28 23 19 17 of the yarn being 28, and the diameter of the 5000 $ 06 58 44 35 29 24 21 70 52 42 35 29 26 smallest drum being 3 feet. Find 2000 in the col- 6000 " " umn marked 'Mule Spindles;" opposite to this number in the table, and under 3 in the column No. 7. marked Diameter," will be found 25 inches, or two belts 12h inches wide. Spindles DIAMETER. Mule and No. 11. Frame. No. Yarn. 3 4 5 6 7 8 1000 10 to 20 15 12 11 8 64 6 DIAMETER. 2000 " & 30 24 21 15 13 11f 3000 66 " 45 36 32 23 20 17 Frame 4000 66 66 60 48 43 30 26 23 Spindles. No. Yarn. 3 4 5 6 7 8 5000 " " 75 60 54 38 33 29 6000 64 " 90 72 64 45 40 35 1000 20 to 30 14 11 81 7 6 5 2000 " 64 29 21 17 14 12 11 3000 " " 43 32 26 21 18 16 EXAMPLE-Required the width of я belt to 4000 " " 57 43 34 29 24 21 drive 5000 frame spindles with looms, the number 5000 " " 72 54 43 36 31 27 6000 « " of the yarn being 35, and the diameter of the 86 65 58 43 37 32 Digitized by Google 86 BELTING. The following table shows the required width No. 16. of counter-belts to drive the counter-shafts which MULE SPINDLES. drive the different machines represented in the following table. DIAMETER. No. 12. Mule. PICKERS. 10 12 14 16 18 20 22 24 26 28 30 600 12, 101 81 71 61 6 5f 5 41 41, 4 DIAMETER. 900 18 151 121 111 91 91 81 71 62 61 6 Beaters. 1200 241 20! 17½ 14) 13 124 10 101 94 81 81 1500 307 251 211 184 16 15 13 12 111 101 10. 10 12 14 16 18 20 22 24 26 28 30 EXAMPLE-Required the width of a counter- 1 6f 5f 4f 41 3) 34 3 2 13 11 9 81 71 6f 6 54 5 41 4 belt to drive a picker with two beaters, the diam- 3 18 16 13 121 11 9f 9 74 71 7 61 eter of the smallest pulley being 18 inches. Find 2 in the column marked "Beaters;" opposite to No. 13. this number in the table, and under 18 in the column marked Diameter," will be found 7 inches, 30-INCH CARDS. the width of the required belt. DIAMETER. No. 17. Cards. FRAMES, (LIVE AND DEAD) SPINDLES. 10 12 14 16 18 20 22 24 26 28 30 2 51 41 3] 31 3 21 DIAMETER. 3 78 6s 51 43 41 4 34 34 3 4 104 81 71 61 6 51 48 41 41 31 34 Frame. 5 13 10 9 8 7t 64 6 51 51 43 44 10 12 14 16 18 20 22 24 26 28 30 6 151 13 11 94 82 8 7 6 61 51 5 7 18 154 123 114 10 9 81 7% 71 61 6 100 8 61 51 5 41 4 31 31 3 8 20 17, 141 121 111 101 91 9 81 74 7 200 161 134 111 101 81 81 74 61 61 51 51 9 231 19 16 141 134 12 10 10 9 81 71 300 241 191 171 151 131 12f 102 91 91 81 71 10 26 211 18 16 14½ 13 12 11 104 94 81 400 321 261 221 201 17 16 141 13 12. 111 10 500 401 331 281 251 22. 201 181 16 15 14 13. No. 14. No. 18. DRAWING FRAMES, (3 HEADS EACH.) DRESSERS, (8 FANS TO EACH DRESSER.) Drawing. DIAMETER. DIAMETER. 10 12 14 16 18 20 22 24 26 28 30 Dressers. 10 12 14 16 18 20 22 24 26 28 30 1 4 34 3 21 2 8 64 6 5 41 4 3t 34 3 1 74 51 5½ 41 31 31 34 3 3 12 91 9 71 61 6 54 41 41 41 4 2 14} 111 101 81 71 7 6½ 51 54 5 41 3 211 17 15 124 111 10, 91 81 81 71 61 No. 15. 4 281 23½ 201 17½ 13 14. 121 101 10 91 TWIST SPEEDERS. No. 19. Looms. DIAMETER. Speeder. DIAMETER. 10 12 14 16 18 20 22 24 26 28 30 Looms. 48 61 51 41 31 3f 3 10 12 14 16 18 20 22 24 26 28 30 72 91 71 6f 51 54 41 41 4 3ᵢ 3. 3 96 12, 10÷ 8% 71 6% 6 5¥ 5½ 41 41 41 2 51 41 31 31 3 120 151 13 11± 91 81 71 7 6} 6 51 5 4 10. 81 71 6½ 53 51 51 41 41 41 31 144 184 15 13 11} 10÷ 9 81 74 74 61 61 6 15 13 11± 91 81 72 74 61 6 51 51 168 211 181 15 13. 12 10f 91 9 81 71 61 8 201 17, 141 121 111 10t 9f 81 84 71 7 192 24] 201 171 15 13 12 114 101 91 81 81 10 261 211 171 16 14. 13, 111 10] 101 91 BI 216 29 23f 191 17 15 13 121 111 104 10 9 12 311 26 221 191 174 15 14 13÷ 12% 114 10f EXAMPLE-Required the width of a counter-belt to drive 6 cards, No. 20. the diameter of the smallest pulley being 20 inches. Find B in the column marked Cards;" opposite to this number in the table, and under 20 in the column marked " Diameter," will be found 8 inches. EXAMPLE-Required the width of a counter-belt to drive 1500 Pulleys. No. MACHINES. 1 2 3 4 mule spindles, the diameter of the smallest pulley being 20 inches. Find 1500 in the column marked "Mules;" opposite to this number 12 71 15 221 30 in the table, and under 20 in the column marked " Diameter," will 14 6f 13 194 26 16 51 111 161 22f be found 15 inches, the required width, (or two belts 7 and 8 inches 18 5 10 15 20 wide.) 20 4f 9 13f 18 Table 20 shows the width of the counter-belt that drives the coun- 22 4 81 121 16f 24 31 it 111 15 ter-shaft, from which any number of large size board-planing machines 26 " 7 10+ 134 from one to four may be driven. The column marked Pulleys," 28 " 6f If 124 shows the diameter of the smallest of the two pulleys on:which the 30 " 6 9 12 32 " 51 counter-belt runs; the column marked 'No. Machines," shows the 81 11t 34 " 51 8 10f number of machines to be driven. 36 = 5 71 10 Digitized by Google BIRAM'S TELL-TALE. 87 KEAMPLE-Required the width of a belt to drive two board-planing machines, the diameter of the smallest pulley being 20 inches. Find 20 in the column marked " Pulleys;" opposite to this number in the table, and under 2 in the column marked No. Machines," will be found 9 inches, the required width of a counter-belt that drives a counter-shaft, which drives two large size board-planing machines. EXAMPLE-Required the width of a counter-belt to drive a counter-shaft, which is to drive one board- planing machine, the smallest pulley being 12 inches in diameter. Find 12 in the column marked Pulleys;" opposite to this number in the table, and under 1 in the column marked No. Machines," will be found 71 inches, the width of the belt. The following statement shows the surplus power of the belts in the table which refers to this note. The width of the belt was 18 inches, which run 1500 feet per minute; the angle of the belt was about 45 degrees; the distance between the centres of the drums was 25 feet; the diameter of the driving drum was 8 feet; the diameter of the driven drum was 4 feet. When the belt transmitted 20 horse power, it worked quite freely; when the power was increased to 25 horse, it was necessary to make the belt quite tight; when the power was increased to 28 horse power, it was necessary to apply a tight- ening pulley, which caused the journals on the driven shaft to heat this statement shows that the velocity of the belts in the table which refers to this note must not be less than 1500 feet per minute. From a great number of observations it appears that a belt will last longer when it does not run over 2000 feet per minute. BENCH-PLANES. See CHISELS AND PLANES. BENCHES AND BENCH STROPS. See CHISELS AND PLANES. BENDING AND JOINING. See JOINING AND WORKING, sheet b 234 metal. BEVIL AND PARTING TOOLS. See TURNING Todis. BEVIL, mortice, whoel, and pin- 103. See GEARING. D BIRAM'S TELL-TALE. De- H scription.-Fig. 234 is a side eleva- tion in section, and Fig. 235, a plan of the apparatus, (on a scale a lit- tle less than half size.) A A is the frame, supposed to contain the works of a portable timepiece, of which B is the fusee F C is a hollow screw, fixed upon the frame A, through which the axle of the fusee is prolonged, being supported by, and turning in a cir- cular opening at a, above which the axle is square, the diagonal of the square being equal to the diameter at a; D is a hollow tube, having a female screw fitted into the bot- tom, to turn easily upon the male- screw C; the top of the tube D B has a square opening to fit easily upon the square end of the axle of the fusee; which axle should pro- ject about half an inch beyond the tube D, when in the position shown in the figure, to receive the key or e handle used in winding up the timepiece E is the barrel or cyl- inder, round which the registering K paper is placed, which should be made to fit upon the tube D, suffi- ciently tight to retain its position wherever placed, but capable of L being easily turned round upon the tube, or slightly elevated or de- g OF G pressed, for the purpose of adjust- mg it to the index F, to show the time of the day, and also to adjust the registering lines with the prick- er G. F, the index showing the time, is a fine wire, placed verti- X 4 K cally as near as possible to the cyl- inder, the ends being secured in a 4 frame attached to A. The top of Θ the frame also carries the pricker G, placed exactly over the wire F, which is acted upon, and makes an 235 Digitized by Google 88 BIRAM'S TELL-TALE. impression upon the registering paper, when a finger is pressed upon the stud H; I shows a slight spring, intended to return the pricker and stud to their position when the finger is removed ; L is a piece of glass in front of the timepiece, the horizontal section of which is that of a double convex lens, but the sides vertically are parallel with each other this magnifies the parallel and diagonal lines upon the paper which show the minutes, horizontally only, showing the time more distinctly to the fraction of a minute; K K are two pieces of plane glass, on each side of L, for the purpose of throwing more light upon the barrel. Fig. 236 shows a portion of the registering paper, of the full size, with the shaded lines upon it in- dicating the days of the week; this paper is of exactly the circumference of the cylinder, and is put upon a strip of leather, gutta percha, or other flexible material, also of the length and width of the barrel, to each end of which is riveted a strip of brass, having a projection on each side to catch into a notch in the projecting flanges of the barrel. When the registering paper is changed, the barrel may be taken off from the tube D, and the leather and paper from the cylinder; and then a new paper put on, the ends of the paper being turned underneath the leather, and retained by any adhesive applica- tion, such as that made use of in postage stamps. The registering paper is divided vertically by twelve equidistant parallel lines, representing the hours, and again subdivided between each of the above lines by other finer lines into ten minutes. On the lower edge of the paper are five parallel lines crossed by two diagonal lines between each of the above sub- division or ten-minute lines, by which each subdivision is again divided into minutes, the time of the day being shown by the point when the index wire F intersects these small parallel and diagonal lines. The shaded lines representing the days of the week are not drawn parallel with the edge of the paper, but in such a manner that when the paper is fixed round the barrel the shaded lines at one end of the paper fit opposite the intervals at the other end, these shaded lines and intervals being each ex- actly equal in width to the pitch of the screw C. Now, suppose the timepiece newly wound up, and a new registering paper placed upon the barrel at midnight on Sunday (of course this untimely hour is not necessary, as the operation may be done at any time of the day.) The barrel will then have been removed from the position shown by the dotted lines in Fig. 234, to the shaded part above in the same figure, and the pricker G would then be oppo- 236. M Su So E Th Tu M 12 site the commencement of the underside of the line M, (Fig. 236,) and every part of the underside of that line would by 12 at noon have passed under the point of the pricker; when the barrel having made one revolution would also have descended one thread of the screw, and during the next revolu- tion the upper side of the line M, representing the afternoon hours of Monday, would have passed un- der the pricker, and so on through the week; the lower side of the line representing each day passing under the pricker during the forenoon, and the upper side on the afternoon of such day. It is therefore obvious, that any impression made upon the paper by the pricker, would show the day and the exact time of day when such impression was made, and when the paper was removed from the barrel the punctures remaining upon it would be an enduring testimony, to be consulted and checked at leisure, of the operations recorded upon it during the week. The uses to which this tell-tale might be applied are various. If as a watchman's clock, it may be used by several people who are required to be at a certain spot at certain or uncertain intervals. When erson presses upon the stud, he should be required to make a memorandum of the time by the clock; Digitized by Google BLASTING UNDER WATER. 89 these memoranda he would give up to the inspector at the end the week, who would compare whether the punctures upon the paper corresponded with the return; and if not, the writer would of course be detected making a false statement. In an establishment where there are a number of individuals, and it is desirable to ascertain the time of their attendance, they might be required to write their names, and the time of their arriving, in a book, at the same time pressing the tell-tale; when, although sev- eral might arrive and sign so near together that the punctures upon the paper might run one into an- other, yet the time between the first and last would be distinct, and if the names were written in suc- cession, it would be evident that they had been written during the time between the first and last puncture. Again: any individual leaving an establishment during the day, might be required to write his name in the same way, with the time of his leaving and returning, at each time pressing upon the tell-tale, which would be a great check against a person absenting himself improperly, or being absent too long. It might also readily be applied to registering the performance of a steam-engine, or other machinery, by so connecting it with the machinery that the pricker should puncture the paper after a certain number of strokes of the engine, or otherwise. The tell-tale, as in the engravings, is shown attached to a portable timepiece, regulated by a balance escapement; but it is applicable also to a common eight-day clock, with slight modifications. BIRCH. See WOODS, varieties of. BISMUTH. See MINERAL KINGDOM, materials from used in the mechanical and useful arts. BITS AND BRACES. See BORING Tools. BITTERNUT-WOOD. See WOODS, varieties of. BLACK BOTANY-BAY WOOD. See WOODS, varieties of. BLASTING UNDER WATER. Paper on the application of Gunpowder as an instrument of engi- neering operations, exemplified by its use in blasting marl rocks in the River Severn.-The object of the proposed works was to increase the depth to 6 feet of navigable water during all seasons. Above Wor- cester, the additional depth is obtained partly by dredging, but chiefly by a series of four weirs, varying between 300 and 400 feet in length, with side-locks for the traffic. Between Worcester and Gloucester (a distance of 29 miles) it is proposed to obtain the required depth, partly by contracting the channel by embankments of fascines, and partly by dredging. The shoals to be removed by dredging are gen- erally isolated, varying from 100 yards to half a mile in length, and they require excavating to a depth of from 3 to 5 feet. A large portion of these shoals consists of alluvial gravel, without flints, but prin- cipally of quartzose and granitic pebbles, varieties of porphyry and of compact and granular sandstone. This material, although very hard in some places, offered no engineering difficulties. Other shoals con- sist of denuded beds of hard red marl; this material being found in every instance, when the river im- pinges upon the eastern or western limits of its valley. In most places it was so hard, as to render its removal by the dredging machine quite impracticable. That part of the river Severn, above described, traverses nearly north and south the great plain of red marl of the new red sandstone formation, the bed of the river from Stourport to about a mile below Holt bridge, near Ombersley, being formed through the upper strata of the new red sandstone; upon this lies the great bed of red marl, (in places saliferous,) dipping at a small angle, but irregularly, to the south- east. The river traverses the whole of this strata, which is probably more than 1000 feet in thickness, passing through the upper strata, and entering the lias formation above Gloucester. The red marl is generally considered by geologists to be formed from the debris of older rocks, and it appears to be totally devoid of organic remains. It lies generally in beds, rarely exceeding 15 inches in depth, and often much less. It is divided occasionally by strata of greenish gray marl, and near the upper part of the formation by thin, but very hard, beds of shaly or imperfect lias. It is difficult to describe the comparative hardness of materials, but when it is stated, that in many places it was impossible to cause a steel chisel-pointed boring tool to enter it by any ordinary exertion, by Is and, from a boat, it will be conceived that it could not be readily raised by dredging. After exposure to the action of the air it breaks up into small fragments, almost like the slaking of lime, so that solid blocks, which could only be broken by the application of considerable force into sharp-edged fragments, would, in the course of a few days, fall to pieces and afford no criterion of its hardness in an undisturbed state. When the dredging machine was tried upon one of these marl shoals, it was found impossible to raise above 50 or 60 tons per day, and that with constant risk and repeated accidents to the machine; but such rate of progress was totally incompatible with the required progress of the work. Attempts were first made to break it up by driving iron bars into it, and prizing it up, but this plan did not answer. A second attempt was made to loosen it with a very strong plough, something like a 'subsoil" plough, which was proposed to be pulled through the marl by a powerful crab fixed on a barge, the plough being guided by a strong pole; the effect produced was, however, 80 superficial, and the expense of labor was so great, that this method was also abandoned, and experiments were made to ascertain the effect and probable cost of using gunpowder. These were 80 satisfactory, that it was determined to blast all the marl shoals, previous to dredging them. In January, 1845, as soon as the requisite materials and estab- lishment could be prepared, this operation was commenced, and has since been carried on with no other interruptions than those occasioned by freshes in the river; the total length of blasting required (about a mile and a half) being now completed, and a considerable portion of the marl since dredged up, at the rate of 200 or 300 tons per day, with perfect facility. The most economical method of using powder, to break up a depth of rock like that described, would probably be to obtain a face of the required depth at one end of the work, to put in a row of shots at the back of it, and after each discharge to remove the loosened marl; continually repeating the process but this method would have been open to many serious objections. The dredging machine and the blasting gang would have been constantly waiting for each other, and having but two dredging machines to perform the work, it was of great importance to economize their time in every possible way. By such proceedings also, a constant obstruction to the navigation would have been created, equal to the whole width of the new channel. The number of men that could have been employed in blauting would also 12 Digitized by Google 90 BLASTING UNDER WATER. have been very limited. These objections, in this particular instance, far outbalanced any little saving of gunpowder. It was therefore determined to put in perpendicular shots, throughout the site of the channel, at such distances as experience might prove to be best, and proceedings were commenced with spaces of 6 feet from centre to centre of the shot-holes. Six rafts were used as stages to work from they were each formed of four baulks of timber, about 40 feet long; the baulks, placed in pairs, were secured at a distance of 4 feet apart, by cross-pieces, 6 inches square, well spiked to the baulks at intervals of 6 feet; these were covered with deals 3 inches thick, laid lengthwise of the raft, a space of 12 inches in width being left open along the centre. The ends of the rafts were provided with strong ring-bolts to moor by. These rafts were confined to one bank of the river by ropes, and retained at the required distance from it by a series of "sets," or booms, abutting against the bank. At the up-stream end of the raft was a large barge, fitted up as a black- smith's shop, for the necessary repair of the tools, with dwellings for the watchman, &c. The bows of the barge were strongly fortified, and a strong oblique boom of large baulks reached from it to the shore, 80 as to protect the whole fleet from the craft coming down the river. At the down-stream end was another barge, fitted up as a powder magazine, and as a shop, furnished with every necessary for the manufacture of the cartridges, and for the storing of their material. The first operation consisted in placing and securing in their proper positions, the pipes through which the holes were to be bored. Small stakes, painted with a series of numbers, were first driven into the bank, parallel to the work, at distances of 6 feet apart; as far behind them as the slope would allow, was another row of stakes parallel with the first, 80 that a line drawn through two stakes would be at right angles with the river, and a person standing behind the two stakes could readily direct the workman when to lower the charge-pipe, which was then secured in its place, in the opening of the raft, by a timber dog," driven into the raft on each side of it. The pipes were of wrought-iron; they were 31 inches in diameter, three-sixteenths of an inch thick, and 9 feet long. Where the marl was so deep as to require 8 or more pounds of powder, it was found that the cartridges of such diameter as could be used in these small bores were so long as to lose part of the effect of the gunpowder; subsequently, pipes of 4 inches diameter were used with advantage. Two collars, half an inch square, were shrunk on them near the upper 237. 23d end, for the purpose of retaining a rope, by which they were secured when the charge was fired. When the depth of the water increased, these pipes could be lengthened 4 feet by an additional piece, prepared for that purpose; this joint was made by shrinking on a collar, 6 inches long, over the joint. The pipe being in its place, was driven through any gravel that might remain, and a few inches into the marl The gravel was generally so thick upon the marl, that it was requisite first to remove it by means of the dredging machine. To protect the thin edges of the pipes whilst being driven, a cast-iron cap, or plug. was used, which received the blows from a heavy wooden beetle; the interior of the pipe was next cleared of any sand, or gravel, that might have entered while putting them down. The principal tool used for this purpose was an iron bucket or cylindrical tube, 2 feet in length, of as large a diameter as would pass down the whole; it was furnished at the bottom with a valve opening inwards, and was jointed to a round rod, of the requisite length, half an inch in diameter, and when used with a pumping motion, quickly brought up whatever could not enter at the valve. Digitized by Google BLASTING UNDER WATER. 91 The boring then commenced a gang of three men being stationed at each pipe. The first operation was that of the jumper, which was made with a single steel edge, a little rounded. The jumpers were of round iron, 11 inch diameter, except 2 feet in length at the lower end, which was 11 inch diameter. For general use they were 15 feet long, and weighed about 52lb. each; after working them till they were nearly set fast, an auger was inserted to raise the plug of loosened marl and to render the hole true. The shell of the auger was 20 inches long and nearly closed up, the better to retain the loosened borings. The shot-holes were bored two feet below the proposed bottom of the dredging, as it was expected that each shot would dislocate, or break into small pieces, a mass of marl of a conical or parabolic form, of which the bore-hole would be the centre, and its bottom the apex, 80 that four adjoining shots would leave between them a pyramidical piece of marl, where the powder would have produced little or no effect. By carrying the shot-holes lower than the bottom of the intended dredging, the apex only of this pyramid was left to be removed, and in practice this was found to form but a small impediment, Figa. 237 and 238. A second reason was, that if the removal of the shoals should cause the level of the sum- mer water to fall lower than was expected, the marl might still be found sufficiently broken to enable a greater depth to be obtained without further blasting. The cartridges, or charges, were formed of strong duck or canvas bags, somewhat tapered at the bottom these were filled with the required charge of powder, varying from 2lb. to 4lb., according to the depth of the marl; the weights of powder used for depths of 4 feet, 4 feet 6 inches, and 5 feet, were respect- ively about 2lb, 3lb,, and 4lb. The end of a coil of Bickford's patent fuse was inserted to the centre of the powder, and the neck of the bag was carefully gathered up round the fuse, and well tied with small twine. If the cartridge was small, it was then dipped into melted pitch, which had about one-fourth of tallow melted with it, or otherwise the melted pitch was ladled over it, till it was uniformly coated; in this state, the cartridges were hung to drain and stiffen. When hard, they were well rubbed over with tallow, and lastly powdered over with dry whiting. The tallow, whilst it ensured the stopping of any little cracks in the pitch, facilitated the passage of the cartridge down the hole; the whiting also pre- vented the pitch from adhering to any thing. It has already been stated, that the powder was ignited by means of Bickford's patent fuse; but as this material is never made in lengths exceeding 48 feet, it was found expedient, in order to save waste, to use the whole coil, cutting it off at the requisite length when absolutely in the hole, and using the remainder in the same way till the whole was used up. The charge was carefully pushed down into the hole by a wooden ramrod of suitable diameter, with the end rounded; the same instrument was used for ramming down the tamping. The material found to answer best for this purpose, was the small fragments of hard marl, separated by the action of the weather from the lofty escarpment at each of these shoals; this was gradually filled into the holes, and rammed solidly, till the bore was full up to the surface; the timber-dogs which held the pipes were then removed, the pipes were loosened from the marl, ropes were attached to the pipes and to the raft, or to some loose pieces of timber, and the shots were fired. Generally there was little external effect beyond the pipes being lifted a few inches, though sometimes they would be blown up several feet, and occa- sionally the water would be forced up through the pipe to a height of 40 or 50 feet. All the gangs commenced their holes in the morning, and they were generally all ready to fire at the same time, which was always done, as it caused least interruption to the work. It was a rare occurrence for a shot to miss fire-probably not once in a hundred shots the failure arising generally from a leak at the joint between the fuse and the bag. If the leak was not very serious, the shots were often saved by the following somewhat singular expedient. An iron bar, five-eighths of an inch in di- smeter, and of sufficient length, pointed at the end, was kept in readiness, and when required the end was heated red hot, put quickly through the water into the tamping, through which it was driven as rapidly as possible into the powder, which in nine cases out of ten it was still hot enough to ignite. The result of the whole work being invisible, great care was necessary in order to prevent mistakes and omissions. As each shot was ignited, a red mark was laid against its corresponding stake upon the bank; when it had gone off, each shot was carefully examined with a steel chisel-pointed searcher, to prove that the required effect had been produced to the determined depth; when so found, the red mark was insurted into the top of the stake, as a certificate of that shot having passed examination: the numbers so certified were then transferred to a book kept for that purpose, and if a shot was found in- effective, another was put in the same place. To afford space for the workmen, every alternate hole was first made, and afterwards those which had been left between them; one line being completed, the whole line of raft was moved 6 feet outwards to the next line, and so on till the required width was obtained. The whole establishment was then dropped down the length of the rafts, and the process was repeated. When the men had become used to the work, each gang would sometimes get down four shots per day 80 that with fifteen gangs, sixty shots have been fired per day. It may be objected to the use of the patent fuse, that the ignition of a number of charges simultane- ously by the galvanic battery would have produced better effect, at less cost, and in a more scientific manner. The author commenced the work under a different impression, and subsequent experience with the battery has not altered his opinion. When it is required to separate a large stone from its bed in the quarry without breaking it, nothing can be better than the numerous simultaneous discharges, which can only be obtained by the use of the battery but the object in this work, on the contrary, was to break the mass to pieces as much as possible, which it is conceived would be more likely to be effected by distinct discharges. Then as regards cost: the patent fuse No. 8, carriage included, cost six-tenths of a penny per foot; if the average length is taken at 15 feet, that is just nine-pence per shot, a sum which would barely pay for making the arrangement of wires necessary for the galvanic ignition. It was also found, from the compressible nature of the canvas cartridges, that the arrangement of the wires was very liable to be disturbed, during the insertion of the cartridge into the hole, or by the subsequent ramming of the tamping. Digitized by Google 92 BLAST-FURNACE After considerable experience, therefore, and the use of nearly 100,000 fect of the patent fuse, it has been found satisfactory. There now only remains to be given the cost of the operation above described. The first cost of the establishment or plant, sufficient for 6 months' work, was $1500. This includes the waste and use of timber, in the raft, stages, booms, &c., hire of barges, and cost of fitting them up for the work, cost of pipes for boring, iron and steel for tools, deducting estimated value when done with, sundry ironmongery, waste and loss of ropes and other small stores. More than ten thousand shots have been fired. This number gives just one shilling per shot, as the proportionate share per shot of the cost of the plant; this would of course be much less if the work was to be continued. BLAST-FURNACE This invention relates to the construction of blast-furnaces, and to various other arrangements connected therewith. Heretofore, it has been the custom, during the process of smelting iron-stone or ore, to allow the charge to remain some days in the furnace for the purpose of cementing, as it is termed; such being understood to mean the distribution of metal over the surface of the material, so that it may receive the full force of caloric evolved by the reverberation in the smelting-furnace. The present means, however, employed by the patentee for more effectually carry- ing into operation his improvements hereafter explained, constituting the novelty of this invention, consists in the numerous advantages resulting from the more perfect combination of certain parts, by reducing the height of the furnace very considerably, and arching in and producing a better arrange- ment at the top, so that the unconsumed smoke, which would otherwise pass off, is prevented, gener- ating thereby greater heat than hitherto. Fig. 239 of the engravings annexed, represents a sectional 240. 241. 239. d 7 d d c h c b b 244. 242. 243. d elevation of an old furnace, such as is now in use; the construction of which will be readily under- stood by reference to the engraving; a is the hearth; b, the commencement of the boshes, and c the shaft d is the crown for supplying the furnace; e is the lining of the furnace, composed of fire-brick; and f, the outer casing of stone or other suitable material; g g are the tuyeres, surrounding the base in the figure just referred to; the materials are thrown in from the top, which is open to the passage of the flame and unconsumed gases, instead of arresting their progress, for the production of greater heat during the smelting process. Fig. 240 represents a modification of the former arrangements, consisting only in the dome or arched top placed just above the landing h; the object of which is to deflect down the rays of heat, and the unconsumed gases evolved; d shows two dampers, for the purpose of regula- ting the draft, by opening or closing the crown of the dome; i i are slots or apertures, passing trans- versely down by the sides of the landing, for supplying the furnace. Fig. 241 represents a sectional elevation of a blast-furnace of the improved construction, the form of which the patentee considers an essential feature, being greatly diminished in height, rendering, thereby, the operation of raising the materials for forming the products .less troublesome than hitherto; the mode of working, and the Digitized by Google BLASTING. 93 arrangements generally, are the same, from the hearth upwards, with the exception of the boshes; the sides are nearly vertical, with a slight curve at the shoulder or bending; the form of the dome or cover, as before described, for concentrating and retaining the heat, is of such a material and construction, that the effect produced during the process of smelting iron-ore, or other metallic substances, causes a quicker deposite of the products, enabling such to be entirely withdrawn at shorter intervals, by the increased intensity of the caloric. Fig. 242 shows a sectional plan view of Fig. 241, taken through the dotted line at b; g g, as in the former instance, denote the tuyeres, passing through the lining e e, the outer stone-work ff allowing any communication being. to them by means of the recesses formed in the masonry j is described as the tapping-hole. The chief novelties in these arrangements relate, first, to the improved form, which is considerably less in height, and greater in width, employing a proportionate number more of tuyeres, as well as offering facilities for feeding the furnace, by de- creasing the rise to the landing, as also for an apparatus employed for that purpose, shown at Fig. 243; 6 is the receptacle for the materials; b a couically-shaped bottom, mounted on a centre, having a weight, e, placed upon the end of the arm or lever to which it is attached, for the purpose of keep- ing it closed, and counteracting the weight of the trap or moving bottom; c is another, of a large description, situated immediately beneath it, with a weight f, and lever, as in the other instance; d is the crown of the furnace. The action is as follows: the materials to be placed in the blast. furnace, are directed through the chamber a, which, by the use of the conically-formed trap or bottom, are deflected off from the surface in an outward direction, and by falling on the larger one, beneath, caused to descend, and be deposited around the sides of the furnace, where a greater degree of caloric is given off. Fig. 244, represents a blowing-apparatus, which consists of an upright frame-work, to the top portion of which the blowing-apparatus is fixed, the other end having a sliding-bar working on the side-rods b; c is a small cylinder, fixed to the bed-frame, with piston and connecting-rod attached vertically to the lower portion of the blowing-apparatus; d is the steam or ingress pipe; e, the blast branch-pipe, communicating to the tuyeres. In putting the machine into operation, it is first ne- cessary, by suitable valves, to admit the steam below the cylinder g, the effect of which upon the blowing-apparatus, will be to cause it to move upward, and impel the air from within, through the tube e, into the furnace; ff are springs for bringing down the apparatus in readiness to be again raised by the steam-piston. The patentee describes an improved tuyere, capable of passing into the furnace, and being kept cool without the application of water-passages through them, using for such means currents of air instead; also for combining and arranging blowing-cylinders having steam- engines attached; the novelty of which consists in uniting two air-pump cylinders, with inlet and outlet valves, communicating to the tuyeres, and working the same backwards and forwards by the up and down stroke of the piston, as heretofore, the rod of which is attached to the pistons of the air-pumps, which are so constructed, having buffers of elastic substances, such as Indian-rubber, that when the piston completes each alternate stroke, it shall be prevented striking the ends of the cylinder by the interposition of such means, whereby a pressure of air is maintained of uniform strength without the employment of fly-wheels. Lastly, for the mode of applying two or more fans placed on the same shaft, and made to revolve by a rotary steam-engine in such a manner that the air or blast from the first shall enter into the second, and from the second into the third, and so on, if desirable, thus accumulating by such means a more powerful blast to be passed into the furnace than yet employed. The patentee, after describing the object of his invention, and the manner in which the same is to be carried into effect, states, that he does not confine himself to the whole of the particulars, so long as the important peculiarities of his invention be retained; but he claims, first, the mode of constructing bla-t-furnaces in the peculiar manner set forth; secondly, for improvements in the con- struction of tuyeres, so as to keep them cool by the passage of air through them; thirdly, for the mode of arranging and combining blowing-cylinders having steam-engines attached, whereby the pressure of air is kept uniform, without the employment of fly-wheels; fourthly, for the means of regulating blasts of air to blast-furnaces, by the pressure of steam and springs; fifthly and lastly, for the appli- cation of two or more fans on the same shaft, when receiving motion from a rotary steam-engine placed on teb shaft. BLAST-FURNACES. See CASTING AND FOUNDING. BLAST-PIPE A pipe employed in locomotive engines to convey the waste steam from the cylin- ders up the chinney, and to urge the fire. Its invention is generally ascribed to Mr. George Stephenson, and it IS supposed to have doubled the power of the engines at the period of its introduction. BLASTING. The operation of detaching and separating blocks of stone or earth from their natural or quarry beds, which was usually performed in former times by the following process:-Long wooden wedge were driven, in a very dry state, into holes prepared for them, and previously well heated; a quantity of cold water was then poured over the wedges, which, upon becoming thoroughly saturated, swelled and caused a fracture of the rocks. The same effects are now generally produced by the exploding force of gunpowder, which was first used for that purpose about the year 1820. A hole is first driven into the earth by a jumper, or chisel, which is held in a proper direction by one man while another strikes it with a hammer, the former turning his instrument at every blow, by which it is soon made; and it is formed of various depths, from 1 to 3 feet, according to circumstances. If water appears in the hole, some stiff clay is crammed in, by which it is absorbed, and the fissures through which it entered filled up. When the hole is of some considerable size, and of great depth, a long jumper succeeds the first, which is 6 or 8 feet long, and pointed at both ends, with a projecting bulb in the middle, which serves as a handle for the men to lift it up, upon which it is dropped into the hole, and being heavy, perforates the rock. A hole of 5 feet depth may be formed without much difficulty by a succession of these falls. The gunpowder, enclosed in paper, is then introduced into the bottom of the hole, which is properly adapted for it. A thin copper rod is now connected with it, and some soft impervious substance crammed into the remaining part of the hole when the rod is withdrawn, by which a vent is obtained, connecting the charge with the touch-hole, into which a fusee is dropped Digitized by G ogle 94 BLOCK MACHINERY. and lighted, which completes the operation, when the men retire. Crooked pieces of iron are also semetimes introduced into the bottom of the hole to assist in detaching the masses of rock. The natural stratification of the rock is of course attended to, as a horizontal blast will frequently bring down ten times as much as a vertical one. The blasting of rock under water is usually performed by the diving-bell, the communication with the gunpowder being effected by means of a tin tube. A galvanio battery has also been lately employed for that purpose, and with considerable success. A much greater degree of safety is insured by this system of explosion. BLOCK IN COURSE. See RAILWAY ENGINEERING. BLOCK MACHINERY. The machinery at the dock-yard, at Portsmouth, invented by Mr. Brunel, for manufacturing blocks, is deservedly celebrated. The following is a concise account of it:-The machines are separated into four classes.-1. The sawing-machine, for converting the large timber into proper dimensions for the small machines to operate upon. 2. The machinery to form the shell. 3. The sheave-forming machines. And 4. The pin-forming machines. The machinery is capable of completing three sets of blocks of different sizes at the same time, and is worked by two steam-engines of 30-horse power each. The order of the process is this: The elm-trees are first cut into short lengths, proper to form the various sizes of the blocks, by two large sawing-machines, one a reciprocating, and the other a circular saw. These lengths of trees are next cut into squares, and ripped or split up into proper sizes by four sawing-benches, with circular saws, and one very large reciprocating saw, which is employed in cutting up the pieces for very large blocks. The scantlings of the blocks being thus prepared, the next process is that of Making the Shells. The centre hole for the pin of the sheave is first bored by a centre-bit in the boring-machine, whilst a number of others, corresponding to the number of sheaves which the block is 245. 0 in 2 q re 1 4 W b b W y I to contain, is bored at right angles to the former, to admit the first stroke of the chisel, and, at the same time, form the head of the mortises. The blocks are then removed to the mortising-machine; here they are firmly fixed to a moveable carriage, beneath cutting chisels, set in a frame moving up and down with extreme rapidity. Each time that the chisel-frame ascends, the moving carriage advances a small space, bringing a fresh portion of wood under the chisel, until the mortise is cut to the proper length. when the machine is stopped with the chisel-frame at its highest elevation. The chips cut are thrust out of the mortise by small pieces of steel projecting from the back of the chisels, which are also armed with two cutters, called scribes, placed at right angles to the chisels, which mark out the breadth of the chip to be cut at each stroke, and at the same time leave the sides of the mortise so true as to require no further trimming. The corners of the block are next taken off at a circular saw table, and it is then removed to the shaping-machine; here the blocks are fixed in grooves in the peripheries of two equal wheels fixed upon the same axis, the distance between them admitting of regulation to suit various Digitized by Google BLOCK MACHINERY. 95 sizes of blocks, each wheel having ten grooves, 80 that ten blocks are shaping at once. These wheels are made to revolve with great velocity against a cutter set in a slide-rest, which, moving in a curved direction to the line of the axis, cuts those outward faces of the block to their required figure. As soon as the tool has traversed the whole length of the block, the machine is thrown out of gear, and the blocks are (without removing them) each turned one-fourth part round, and another fourth-part of their surface is exposed to the cutter. When the remaining portions of the surface are shaped, the ten blocks are removed, and the last operation is performed by the scoring-machine, which, by means of a cutter, scoops out a groove round the longest diameter of the block deepest at the ends, and vanishing at the central hole for the pin. There only remains to remove any little roughness, and give the surface a kind of polish, which is done by hand, and the shell is then complete. of the Sheaves. These are mostly made of lignumvitæ, which is cut into slabs of a proper thickness by circular-saws, and then removed to a crown-saw, which bores the centre hole, and at the same time reduces the circumference to a circular figure. The abeave is then placed in the coaking-machine, which forms a recess on each side of the block to receive the bush or coak, which is a triangular form, with the ends rounded off. The machinery for effecting this is extremely ingenious, and acts with such accuracy, and the coaks are cast 80 true, that a single tap with a hammer is sufficient to fix the coak in its place. Three holes are then drilled through the two coaks and the intervening wood, and pins being inserted in the holes, they are placed under the riveting hammer, which strikes the pins with a velocity proportioned to the pressure which the workman exerts upon the treadle. The centres of the coaks are next broached by a steel drill, and the sheave being removed to a lathe, which cuts the groove on the periphery whilst it faces the sides, the sheave is completed. There remains now only the iron pin, which, passing through the two sides of the shell, serves as the axis on which the sheave turns. These pins are also made, turned, and polished, by a machine for the purpose; so that, with the exception of strapping by rope or iron, the block is now complete. Although the foregoing account of the operation of the several machines will convey to the intelligent reader a sufficiently clear idea of the whole process by which the blocks are made, we doubt not that a representation of some of the principal machines will be acceptable to our readers. To give engravings of the whole of them would cause us to extend this article to too great a length; as, independently of the various saws by which the trees are cut up into blocks and slabs of the proper dimensions, (which saws may be considered as applicable to other purposes,) there are a great variety of machines employed in the subsequent operations. These may be said to constitute the block-making machinery, properly so called; and from these we have selected two of the principal, to form the subject of the accompanying engravings. Fig. 245 is a side elevation of the mortising-machine, in which the mortises for the sheaves are cut. a a the bed of the machine; b a sliding carriage c the block to be mortised, securely held in the sliding carriage by the screw e; f one of the cutters, the number of which depends on the number of sheaves the block is to contain; g the cutter-frame, moving vertically in guides fastened to the two front pillars of the machine, one of which pillars is removed in the figure, in order to show the cutter-frame; h a guide-rod attached to the upper part of the cutter-frame, and moving in a collar j; k connecting-rod, attached at the upper end to the cutter-frame, and at the crank 1 fixed upon the shaft m, which is driven by a strap from the steam-engine passing round the drum n, which is bolted to the fly-wheel O. The fly-wheel is loose upon the shaft, which is attached to, or detached from, the fly-wheel, by a friction-clutch p, which enters the conical interior of the drum n, and which is moved by the levers qq; r is a double-threaded screw, by which the sliding carriage is advanced it works in a nut 8, which turns in a bearing t; to this nut are attached the ratchet-wheel v and the cog-wheel to ; = a pinion acting upon 10, and turned by the handle y, and only used to bring the blocks under the cutters for the first cut, after which the carriage is advanced by the machine in the following manner Upon the shaft m is an eccentric 1, which acts upon a roller 2, in a vertical lever 3, to the lower end of which is jointed a horizontal bar 4, which has a tooth acting upon the teeth of the ratchet-wheel, 80 that - each revolution of the axis the eccentric thrusting out the upper end of the lever 3, moves in an opposite direction the ratchet-wheel v, which, by means of the nut 8, turns the screw, and advances the sliding carríage, 80 as to bring a fresh portion of the block under the cutters. When the whole length of the mortise is cut, the advance of the carriage further is prevented as follows: The extremity of the bar 4 is prolonged beyond the ratchet-wheel, and rests upon the lever 5, which turns upon a pin in one of the upright columns of the frame. The lever 5 is supported by the curved end of the lever 6, the other end of which rests upon an adjustable slide 7, which is screwed to the sliding carriage, and which is 80 fixed, that when the mortise is completed, the long arm of the lever 6 is no longer supported by the slide; the long arm of the lever consequently descends. and, by its descent, raises the lever 5, which lifts the bar 4 clear of the teeth of the ratchet-wheel Fig. 246 is a side elevation of the shaping- machine a is a large circular rim, or chuck, firmly keyed upon the shaft b; a similar chuck c, (which cannot be shown in the drawing,) is placed upon the shaft behind a. This chuck is not made fast, but may be set upon the shaft at any required distance from a to suit the different sizes of the blocks; dd are stay-bolts passing through the chucks a and c, and having nuts at the back of c to retain it at the requisite distance from a; ee are the blocks which are to be shaped; they are retained between the two chucks a and c, as follows ff are a number of short maundrils, set in the chuck a, and each carrying on the farther end a small cross, the extremities of which have two sharp steel rings; in the chuck c is a screw, opposite to, and concentric with, the maundrils ff; the inner end of these screws having a -harp steel ring loosely fitted upon them. Each block, in the operation of boring the holes previous to passing to the mortising-machine, has had the line of its axis determined, by the marks of two steel rings impressed on one end, and of a single ring upon the other. The marks of the two rings are applied to the steel ring on the cross, and the ring on the screw is advanced by the screw to the single mark on the other end of the block g is a slide-rest, supported upon the bed h, and attached to the radial bar j, which turns upon a centre directly beneath the line of the axis of the shaft b; k is the bar carrying the cutter I, and sliding in a mortise; in a steel spindle, passing through a socket in k, and Digitized by Google 96 BLOCKS. having a small horizontal roller n fitted upon its lower end o one of two pillars supporting two curved bars P q, called shapes; the curve on one bar determining the shape of the faces of the blocks, and that of the other bar the shapes of the sides of the blocks. r is a lever by which the cutter-bar is moved along its mortise, 80 as to cause the roller n to press against one of the shapes p or q; 8 is a bar attached to the slide-rest, by which the rest is made to traverse the bed h, describing a portion of a circle of which the pivot of the radial bar is the centre. The operation of the machine is as follows The chucks being filled with a number of blocks corresponding to the number of maundrils, the chucks are set in motion by a strap from the engine passing round the drum t, keyed upon the shaft b. The cutter l being previously adjusted to the proper distance, the attendant holding the bar 8 in his right hand, causes the slide-rest slowly to traverse the bed h, whilst, by the lever r, held in his left hand, he keeps the roller n in contact with the shape p or q. and consequently causes the cutter I to describe a curve similar to that of the shape; and that face of the blocks which is exposed to the cutter revolving with extreme rapidity against the cutter, is cut to a corresponding shape. When the first side 18 completed, the blocks and the chucks are stopped, and the blocks are turned one-lourth round, so as to present the next line to the cutter. This is effected by the following means: On the outer end of each maundril is fixed a worm-wheel v, upon which an endless screw upon the outer end of the spindle W acts; upon the other end of each spindle is fixed a bevelled pinion y, gearing with a bevelled wheel = fitted loose upon the axis. When it is required to turn the block, the wheel x is locked to the frame by 246. od 6 C LTV. a catch-pawl, (not shown,) and the attendant turns round the chucks a and c four times, and the bevelled pinions revolving round the wheel x cause the spindles on which the endless screw is cut to turn the worm-wheels one-quarter round. The roller n is then by a simple movement pushed down, so as to act against the lower shape; the chucks are again set in motion, and the slide-rest being made to traverse back over the bed, the second face is shaped, and the operation is repeated for the other two sides. BLOCKS, in the Navy, and Marine Architecture, a species of pulley very extensively used for moving heavy weights, by means of ropes or chains passing over the pulleys; also occasionally in architectural and other works. A block consists of one or more pulleys, called sheaves, which are generally formed of lignumvitæ, or some hard wood inserted between cheek pieces, forming hat is called the shell of the block, and turning upon a pin passing through the shell and the centres of the sheaves. Blocks are of various forms, each having a particular name; the following cut represents a common single block a is the shell, b the sheave, c the pin. Blocks are suspended by straps, either of rope or iron; the latter are called iron-strapped blocks, and have frequently a swivel-hook. A combination of two blocks, one of which is attached to the load to be raised, is called a tackle, and the power is to be esti- mated by the space through which the fall (which is that part of the rope to which the power is applied) passes, compared with the space through which the load is raised, deducting for friction, which is great, owing to the rigidity of the ropes, and the small diameter of the sheaves; these, for nautical pur- poses, are necessarily limited by considerations as to weight and space. The friction is also consid erably increased, in certain circumstances, under which blocks are applied. When there is more than one sheave in the same block, the fall comes last over the outside sheave; and that sheave, if the exertion of power be in a line nearly parallel to the direction in which the load is drawn, always endeavors to get in'o a line with the point of suspension; for the great friction to be overcome pre- ven ing the equal transmission of the power throughout the combination, and the outside sheave having to sustain not only the pressure of its own share of the load, but also the additional strain Digitized by Google BLOCKS. 97 sufficient to overcome the friction of the other sheaves, and the vis inertise of the entire load; it must therefore, be con- 248. 247. siderably depressed, and in consequence of this oblique di- rection of the block, the lateral friction of the sheaves be- comes so great, as in some cases nearly to equal the power. Figa 247 and 248 represent blocks so constructed as to al- low the fall to pass over the middle sheave, by which means it will be immediately beneath the point of suspension. Fig. a 247 is the invention of the celebrated Smeaton, who em- a ployed blocks of this description in erecting the Eddystone Lighthouse. The upper block a contains six sheaves ranged in two tiers, and the lower block b contains also six sheaves, also ranged in two tiers; the lower tier of sheaves in a, and the upper tier of sheaves in b, being more than two diameters of the rope smaller than the other sheaves, the mode of reev- l ing the rope is as follows: Beginning in the middle, the rope is reeved over the large sheaves as far as it will go; thence going to the first of the smaller sheaves, they are reeved throughout; thence again to the outer one of the remaining large sheaves, and ending upon the middle sheave of the up- per block. The principal objection to this method is, that it requires a combination of at least twelve sheaves, and is not therefore applicable to general purposes. The construction " shown in Fig. 248 can be applied to any number of sheaves from four upwards. The cut represents a pair of blocks of two sheaves each. To the upper block, a, is attached another block b, the sheave of which stands at right angles to the former, and is called the cross-sheave; the lower block c contains two sheaves abreast, (shown diverging,) in order that the cross- sheave may not be of a very small diameter. The method of reeving is to begin upon the middle upper sheave, and when arrived at the outer sheave, to pass to the cross-sheave, which carries the rope over to the outer sheave, on the opposite side, and then proceed again in the order of the sheaves. The annexed figure represents an improved cat-block. The advan- tages which this block possesses over those in common use, may be 249. thus stated In all large class ships, the unwieldy nature of the usual cat- block requires that two men should be sent out on the anchor, a most perilous service in rough weather; whereas this only requires one man at any time, because he has not to sustain the whole weight of the block, as in the former case, but only that of the hook. And in vessels smaller than line-of-battle ships, in blowing weather, when the ship pitches heavily, the anchor may be hooked without a man going on it, by his standing on the head, and guiding the hook of the block to the anchor, by a staff and hook, similar to a boat-hook. This facility is gained by the mobility of the swivel in its socket, 80 that the man has not the weight of the block to turn, in order to insert the hook in the ring of the anchor. Should the anchor, when hooked in the dark, or otherwise, cause a turn in the fall, the hook being on a swivel-joint, the turn will come out before the strain comes on the block and when the anchor is foul, it can also be hooked with great facil- ity. In service I have seen the wooden cat-blocks swell 80 much in cold climates, that the sheaves have become immoveable; this being of metal, is liable to no such inconvenience. By merely having a spare socket or two fitted with hooks of various sizes, it may take a strap for gear-blocks, or it may be converted into a lashing-block with- out the hook and socket, but with the socket-bolt. In the figure, which represents a perspective view of the block, it will be seen that the hook, instead of being formed in one with the strap, turns with a swivel-head, in a socket which hangs from a pin passing through the lower end of the shell Although entirely formed of metal, they are lighter than wooden ones with their iron bindings, and capable of the same service. There is another species of blocks, which are termed " Dead-eyes," and are used for tightening or setting up, as it is called. the standing rigging of ships. It consists merely of a circular block of wood, with a groove on its circumference, round which the lower end of the shroud, or an iron strap, is fast- ened three holes passing through the face, (ranged in a triangle,) to receive the laniard or smaller rope, which forms a species of tackle for tightening the shrouds. There are no sheaves in the dead-eye, but the edges of the holes are rounded off to prevent cutting the laniard, but this very imperfectly answers the purpose as from the roughness of the grain of the wood, which is usually elm, and from the stiff- ness of the rope, the laniard renders with difficulty; and from the great strain to which it is subjected, it is frequently broken. A very simple and effectual improvement has been made in this respect, by inserting a half-sheave of lignumvitæ into each of the holes, which causes the laniard to render with greater facility, and the shroud to be set up in half the usual time. Fig. 250 shows the dead-eye; Fig. 18 Digitized by Google 98 BLOW-PIPE-ANALYSER. 251 a section of the same and Fig. 252 one of the half-sheaves. It will be seen, from the manner of inserting the half-sheaves, as shown in Fig. 251, that they cannot fall out, for the more pressure there is on them, the faster they will be. 253. Fig. 253 represents a block of a peculiar description, intended for form- ing a kind of rope-road to a stranded ship. When a vessel thus circumstanced has had a rope thrown over, considerable difficulty has been found in reeving an ordinary pulley for the conveyance of the crew to the shore. In the figure, it will be seen that the pulley divides at the hook, or shackle, into two equal parts, so that it may be instantaneously passed on to a stretched rope, and, by means of a cord from the ship, persons may pass securely and quickly backwards and for- wards. The little bar which traverses the opening is fixed at one end by a joint, and fits into a mortise, as shown; the use of it being to confine the rope to its place, when any vehicle, or other apparatus, is slung or suspended to it. 251. 250 252. BLOOD. The principal use of blood in the arts is for making Prussian blue, or sometimes for clarifying certain liquors. It is also recommended in agriculture, as an excellent manure for fruit- trees. A mixture of blood with lime makes an exceedingly strong cement; and hence its use in the preparation of some chemical lutes, the making floors, dc. BLOOM. A mass of iron after having undergone the first hammering, called bloomary. It requires many subsequent hammerings or rollings to render it fit for smiths' use. BLOW-PIPE-ANALYSER. This simple instrument for finding the weight of any very minute metallic globules without a balance, was invented by (Prof. O. Byrne,) the editor of the present work, in 1844, and communicated to " THE LONDON CHEMIST," for June in that year. Dr. Sheridan Muspratt, of Liverpool, has introduced it, in an Appendix to his English translation of Plattner's excellent work on the Blow-pipe; and it is now much used by European Analysts. Let A BCD, and A B FG, Fig. 254, be two pieces of very finely polished plate-glass, joined together at A B, forming with each other a very acute angle. The figure is distorted, and the necessary mounting omitted, for the purpose of exhibiting the parts more distinctly. A C and B D represent scales of equal parts, of a greater or less degree of fineness, according to the exactness required; they may be drawn on paper, and pasted to the glass. X Y is a cylindrical piece of wire of any convenient length, or of any sort of metal, placed between the plates of glass, near the top, parallel to A B: the planes are tangent planes to the cylindrical wire. This wire must have a fixed position while experimenting. The diameter of this cylinder can be calculated with very great accuracy, by weighing a pound, or a half-pound, of the wire from which it is cut; this weight divided by the length of X Y will give its weight, and, from knowing the specific gravity of the metal, the diameter of the wire can be thus accurately determined; this diameter will be the diameter of the globe n, the greatest possible that can be made out of the cylinder XY. The solidity of this globe can be also readily ascertained, and would stand in the same position, subtending the same acute angle, if the cylinder were removed. Suppose the inch and the ounce to be the units of measure and weight respectively, L the length of a piece of wire weighing q ounces, from which X Y=1 is supposed to be taken, then the weight of XY. Then say as, S L LS the solidity of XY in cubic inches, S being the specific gravity of the motal, or the numbers of ounces in 1728 (=c) cubic inches:- area of the circular cross-section of XY. =3.14159, &c. »LS = the diameter of this section, or of the globe n, the solidity of which ÷ an expression well adapted to logarithmic computa- tion, which is independent of the length of XY. Digitized by Google BLOW-PIPE-ANALYSER. 99 EXAMPLE-Suppose a piece of copper wire 3765 inches long, to weigh 5 ounces, what is its diameter? And what is the solidity of the greatest globe that can be taken out of its cross-section 1 Let L = 3765, S = 9008, c = 1728, q =5, and K = 3.14159, dc. Then log. 4. = 0-6020600 log. q. = 0.6989700 log. c. = 32375437 Sub. log. T. = 9.5028501 Sub. log. L = 74242350 Sub. log. S = 60458716 Reject 30 27-5110304 2) 8-5110304 The diameter of the wire = 0569528 = 27555152 8 42665456 Log. = 1-7189986 Log. 00009672622 = 5.9855442 So that the diameter and solidity of a globe, placed in the position of any wire X Y, can be determined to any degree of accuracy required. If the part X Y be taken from such a wire as the one given in the example, the diameter would be 0569528 inches, and the solidity of n, 00009672622 cubic inches. 254. C n X Y a b c d e g oh ok I m B The solidity of any other globule, a, b, c, or d, &c., suspended between the planes of glass, can be readily found, from knowing the distance of its centre from the line A B, where the planes meet and the distance of the axis of the cylinder from the same line. These distances may be measured in a alant line by the scales A C, BD, and will answer as well as the perpendicular distances between the axis and centres. If very great accuracy be required, two distances are necessary-the one above, and the other below the globule: for instance, let us take the globule d, the distance c' the lower limb Digitized by Google 100 BLOWING-MACHINES. from A B is 49, according to the design of our woodcut, and the distance of the upper limb is 54; there- fore its centre may be said to be 49+54 2 515 parts from the line AB. It is convenient, but not necessary, to have the wire X Y so placed, that the distance of its axis from A B may correspond with 10, 100, 1000, &c., on the scales A C, BD. Suppose the wire n to be 80 placed that 8' t' reads on the scale A C and BD, referring to the first figure at 1002, and w' v' to read 998; then 1002 + 998 2 = 1000, the best position for the wire which keeps the planes apart. Let m' n' be at 645, and p' q' at 643, then the globule may be said to stand at 645-2643-644. 255 Indeed, if the globules were read off all above, or all below, it would answer the same purpose, observing to keep the lines s' t', m' n', or w' v', p' q', dic., parallel. s Then 1000 : 644" :: S : S4; S and S. being the solid contents of n and d respec- tively. n :. 1000' : 644" W : W.; W and W. being the weights of n and d respectively. Hence W.= 1000000000 The weights and solidities, or volumes of the small globules a, b, c, d, e, f, g, h, i, &c., supposing them to stand at 947, 895, 763, 644, 602, 533, &c, respectively, will be in like manner expressed by- 1000000000 And S₁ 1000000000 The co-efficient, { 1000000000 } or similar ones, can be de- termined with great ease by a table of the cubes of numbers; in fact, they may be ascertained by addition. If It is evident, if the weights W1, W,, W,, &c., of a great number of globules, a, b, c, d, &c., of any sort of metal, be taken together with a very fine balance, and the co-efficient f, determined by a table of cubes, the weight W, of the globe n, can be determined with the greatest possible accuracy, no matter what the specific gravity of the globules may be. Thus, having found the volume and weight of n-and this may be done to any degree of accuracy- the weight and volume of any other globule or number of globules may be at once determined from- w 1000000000 S,+S,+S,+S,+dc:=f; or It may be remarked, that a detached scale of box or ivory will answer the same purpose as the attached scales A C, BD. BLOWING-MACHINES. Machines employed for producing a rapid combustion of fuel, by furnishing a more copious supply of air than can be obtained by the mere draft of the ordinary chin- neys. Although the common bellows is undoubtedly a blowing-machine, yet the term is generally restricted in its application to those machines which are employed at large furnaces, as in foundries, forges, &c. Blowing-machines are constructed of various forms, the great object in all being, that the blast should be as continuous and uniform as possible. The method of producing such blast by a Digitized by Google BLOWING-MACHINES. 101 centrifugal force has long been known, but the first blowing-machine on this principle, of which we have a distinct account, is that invented by Mr. Tyrrell, in 1729. It consists of a number of vanes or fanners, radiating from a horizontal shaft, and enclosed within a cylindrical box, having two aper- tures at opposite sides of the cylinder, to one of which is fitted a conical pipe leading to the furnace, whilst the air enters by the other aperture, and the shaft being turned with great rapidity, a copious and uniform current of air may be impelled through the conical pipe to the furnace. From the great sim- plicity and cheapness of these machines, they have recently been coming into more general notice. Another kind of blowmg-machine, and which is very extensively used for smiths' forges, is the double bellows. This machine in form resembles an ordinary single bellows, but is divided into two parts by a middle board, similar to the bottom board, and like it furnished with a valve opening upwards. The upper and under boards are each loaded with weights, which compress the upper and distend the lower compartments, and the middle board is supported in a horizontal position upon a frame. The pipe or nozzle of the bellows communicates with the upper compartment of the bellows only whilst the air is admitted by the valve in the lower compartment. The action of the machine is as follows: The lower board being raised by the brake or handle, the air contained in the lower compartment is driven through the valve in the middle board into the upper compartment, and not escaping from it through the nozzle as fast as it is forced into it, it elevates the upper board, and thus distends the upper compartment. Upon the descent of the lower board, the valve in the middle board closes, and the upper board de- scending by the pressure of the weights upon it, the air beneath it is urged through the nozzle in a con- tinuous current. During the descent of the lower board, the air enters by the valve in the board, and fills the lower chamber of the bellows; and upon the rise of the board it is forced into the upper chamber as before, and thus a continuous blast is maintained. But although continuous, it is not quite equal, or of a uniform force; for during the up-stroke the air is compressed by a force exceeding that of the weights on the upper board, since it causes the upper board to ascend; but upon the descent of the lower board, the air is expelled by the pressure of the weights alone, which, being at all times the same, the current is then nearly uniform. Another species of blowing-machine is the water-bellows. The nature of these machines will be readily understood by the help of the following diagram. The side figure is a vertical section of the machine. a is the fulcrum of the lever or beam, with two inverted vessels, b and c, suspended from its ex- 256. tremities; these vessels are open underneath, but air-tight above. d and e are two larger vessels, filled with water to the same level, in which the vessels b and c rise and fall alternately. g h i is b a tube or pipe, which passes through the vessels d and e, and reaches above the surface of the water; c at the extremities are two valves, which respect- ively open outwards into the inverted vessels, with a pipe at h open to the atmosphere. k and l are pipes d E passing through the bottom of d and e, and extending a little above the surface of the water; they are open at top, and have valves at bottom opening into the trunk o, to which the pipe is fitted which con- o o ducts the blast to the furnace. An alternating mo- tion being imparted to the beam by a steam-engine or other first mover, the air passes up the tubes g hi, and fills each inverted vessel as they are successively drawn up out of the water the descent of the inverted vessel closes the valves at g and i, and opens those at the bottom of the tubes k and l, through which the air is driven forward by the trunk o, and thus by the reciprocation of the beam, a continual blast is maintained through the trunk o and the tuyere of the furnace. But the most perfect blowing-machines are those in which the blast is produced by the motion of pistons in a cylinder. The annexed engraving represents a blowing-machine of this description. It consists of two double-acting force-pumps, placed at right angles to each other, to equalize the draft, they are driven by a water-wheel of 5-horse power. a is the vertical cylinder; b the horizontal cylin- 257. e h, c a g c b der ; cc two connecting rods united to the crank d; e the working-beam f the parallel motion; g the pipe for conveying the blast to the cupola or furnace h; i a small wheel, running in a groove in a cast- ron plate j frame supporting the vertical cylinder, between which the lowermost connecting rod, c, passes. Atkk are placed valves, to admit the air into the vertical cylinder; similar valves are placed at the ends of the horizontal cylinder into it. The operation is simply this By the revolution of the crank the air is drawn in at each end alternately of both cylinders. and at the same time it is forced out at the opposite extremity along the pipe g into the furnace; and the cylinders being placed at right Digitized by Google 102 BLOWING-MACHINE angles, one piston will be moving with its greatest velocity whilst the other is moving with its least velocity, by which means the blast is rendered nearly uniform, and an air-chamber or reservoir rendered unnecessary. The first cylinders of magnitude used as blowing-machines, were erected by Mr. Smeat- on, in 1760, at the Carron Iron Works, the cylinders being four in number, 4 feet 6 inches in diameter, and the piston making a stroke of 4 feet 6 inches in length. BLOWING-MACHINE, or Air Fan. Description.-Fig. 258 gives an elevation and section of the apparatus, which is composed of an undershot wheel, and of a box containing it. D a d d' 274. 273. 266. 0 258. 264. 265. H of 269. O 267. M Y 270. 271. 260. K I De, 268. K M H K Fy alo 261. P D o Pa) R x a I 263. 259. e 262. À I The box is supported by a brick wall A, Figs. 258, 259, and 260; a strong cast-iron plate is fixed to this wall by the tive pins b. The two cheek-pieces B', also of cast-iron, are similar to each other; they are circular at the part b', b, 6" of their circumference, and have an edge projecting outwards, by which Digitized by Google BLOW-PIPE. 10$ they are solidly adapted to the plates B by screws. The internal surface of the cheek-pieces must be level. Their centre has a circular opening Bᵃ, Fig. 262, concentric in this there is a beam to which sup- porters C of the axle are fixed by wedges; they must be carefully set, in order that the centre of the axle will be at the centre of the cheek-pieces. The sides of the box are composed of thin sheet-iron; the cheek-pieces touch it on all the points of their circumference it must be cylindrical, in order that the wheel may not be impeded in its rotation; and since it is necessary that the air compressed by the motion of the wheel should find no exit, lead sheets are nailed between the table and the projection of the cheeks, the sheet-iron being itself closely adapted by an iron band; pins closely set, strengthen the whole. The only apertures to the box are at B²; through these it takes in the air; through the lateral open- ings D, the compressed air is conveyed to the furnace. The axle E, made of wrought-iron, traverses the box in its breadth, and bears a pulley F which rotates it. The arms G are of wrought-iron, and adapted to the axle by the two disks H, riveted together; the arms are twisted at g to receive the paddles 1, made of sheet-iron 0.0984 ft. thick. Their breadth is about equal to the distance of the internal surfaces of the cheeks, and their length is such, that their extreme circumference is always at a little distance from the interior surface of the box. On account of the rapidity of the rotation, the arms G are connected by a circle K of iron riveted to them. The wheel makes 1200 revolutions per minute, so that the extremity of the paddles travels 1640 feet in the same space of time. The air in contact with them receives their speed, and when it attains the free space D, Fig. 259, it rushes into it, tangentally obeying the impulsion it has received. The air thus forced has a speed of nearly 3280 feet per minute. The spout D', which receives the air at its exit from the ventilator, is represented in Figs. 271 and 272, in transverse and horizontal section. This principal channel distributes the air through secondary pipes d, by which it is conveyed to the furnaces; the quantity of air is regulated by registers d¹. The orifices have a diameter of from 0.00328 feet to 0.008 feet, according to the size of the piece to be wrought. Fourteen furnaces can be ventilated by this apparatus: a power of four horses is estimated sufficient to set it in motion. Fig. 258.-An external view of the ventilator fixed on the brick wall. Fig. 259.-Longitudinal section. Fig. 260.-Transverse section through the axle of the wheel Fig. 261.-Plan of the cast-iron plate B. Figs. 262 and 263.-Elevation and horizontal section of one of the cheek-pieces B'. Figs. 264 and 265.-Details of the supporter C. Fig. 266.-The oil reservoir, with the siphon. Figs. 267 and 268.-Projection of the wheel. Figs. 269 and 270-The disk H. Fig. 271.-The axle E, of wrought-iron. Fig. 272.-Projection of the pulley F. Fig. 273.-Main channel D', and one of the lateral pipes d distributing the air. Fig. 274.-A horizontal section of one of these pipes, and of the register d¹, by which the quantity of air forced out is regulated.* BLOWING OFF. Amount of heat lost in See DETAILS OF ENGINES. BLOW-OFF COCKS AND PIPES. See DETAILS OF ENGINES. BLOW-PIPE An instrument for exciting intense combustion upon a small scale; it is extensively used in many branches of the arts, and also in philosophical experiments upon metallic substances. In its simplest form it is merely a conical brass tube, curved at the small end, in which is a very minute aperture; and a stream of air being urged through it by the mouth against the flame of a lamp or candle, a heat equal to that of the most violent furnaces may be produced. The body intended to be operated upon should not exceed the size of a peppercorn, and should be supported upon a piece of well-burned, close-grained charcoal, unless it be of such nature as to sink into the pores of the charcoal, or to have its properties affected by its inflammable quality. Such bodies may be placed in a small spoon made of pure gold, silver, or platinum. Many advantages may be derived from the use of this simple and valuable instrument. It is portable; the most expensive materials, and the minutest speci- mens of bodies, may be used in the experiments; and the whole process is under the eye of the observer. In the blow-pipes used by enamellers, glass-blowers, and others, the current of air is main- tained by a small pair of double bellows. Early in the present century, Dr. Hare, of Philadelphia, made a most important improvement in the blow-pipe, by substituting for the flame of a lamp that arising from a mingled current of oxygen and hydrogen, of which we shall treat presently. The Hydrostatic Blow-pipe consists of a cask, divided by a horizontal diaphragm into two parts DD. From the upper apartment, a pipe of about 3 inches diameter (its axis coincident with that of the cask) descends, until within about 6 inches of the bottom. On this is fastened by screws, a hollow cylinder of wood B B, externally 12 inches in diameter, and internally 8 inches. Around the rim of this cylinder a piece of leather is nailed, 80 as to be air-tight. On one side a small groove In a blast apparatus employed at the Cyfartha Works, moved by a 90-horse steam-power, the piston-rod of the blowing-cylinder is connected by 8 parallelogram mechanism with the opposite end of the working-beam of the steam- engine. The cylinder is 9 feet 4 inches diameter, and 8 feet 4 inches high. The piston has a stroke 8 feet long, and # rises 13 times In the minute. By calculating the sum of the spaces percurred by the piston in a minute, and supposing that the volume of the air expelled is equal to only 98 per cent. of that sum, which must be admitted to hold with ma- chines executed with 80 much precision, we find that 12,583 cubic feet of air are propelled every minute. Hence a herse- power applied to blowing-machines of this nature gives, on an average, 137 cubic feet of air per minute. The pressure on the air, as it issues, rarely exceeds two pounds on the square inch in the Welsh works. Digitized by Google 104 BLOW-PIPE. is made in the upper surface of the block, 80 that 275. a lateral passage may be left when nailed on each side of the groove. This lateral passage com- municates with a hole bored vertically into the wood by a centre-bit; and a small strip of leather being extended 80 as to cover this hole, is made, with the addition of some disks of metal, to con- stitute a valve opening upwards. In the bottom of the cask there is another valve opening up- wards. A piston-rod, passing perpendicularly G through the pipe from the handle H, is fastened near its lower extremity to a hemispherical mass of lead L The portion of the rod beyond this proceeds through the centre of the leather which covers the cavity of the wooden cylinder; also through another mass of lead like the first, which, being forced up by a screw and nut, subjects the leather between it and the upper leaden hemis- D phere to a pres ure sufficient to render the junc- D ture air-tight. From the partition, an eduction- pipe E is carried under the table, where it is fastened by means of a screw to a cock which carries a blow-pipe, so attached by a small swivel- joint as to be adjusted in any required direction. A suction-pipe passes from the opening covered by L the lower valve, under the bottom of the cask, and rises vertically close to it on the outside, terminating c B in a union-joint for the attachment of any flexible tube which may be necessary. The apparatus being thus arranged, and the cask supplied with water until the partition is covered to about the depth of 2 inches, if the piston be lifted, the leather will be bulged up, and will remove in some degree the atmospheric pressure from the cavity beneath it; con- sequently the air must enter through the lower cavity to restore the equilibrium. When the piston is depressed, the leather being bulged in an opposite direction, the cavity beneath it is diminished, and the air being thus compressed, forces its way through the lateral valve into the lower compartment of the cask, which compartment being previously full of water, a portion of the fluid is pressed up through the pipe into the upper apartment. The same result ensues each time that the stroke is repeated, so that the lower compartment soon becomes filled with air, which is retained by the cock until its dis- charge by the blow-pipe is necessary. Dr. Hare, in his oxy-hydrogen blow-pipe, did not mix the gases in his gas reservoir, but supported the flame of the hydrogen by a current of oxygen issuing from different jets. Subsequently, it was found that the heat produced was materially affected by the proportions in which the gases were mixed, and that the greatest intensity of heat was obtained by two volumes of hydrogen united with one of oxygen; and various attempts were made to mix and burn the gases in their due proportion, but with little success, until the important improvement effected in the instrument by Dr. Clarke, Professor at Cambridge. This improvement consisted in first mixing the gases in a bladder, in the exact proportions to form water, and afterwards condensing them in a strong iron chest, by means of a condensing syringe. To an opening at the end of this chest he attached a great number of layers of fine wire gauze, through which the mixed gases were driven by their elastic force into a small tube, at the end of which they were inflamed. By this arrangement he ob- tained a much greater heat than had been effected by Dr. Hare's invention, and was enabled to make a great number of experiments highly interesting to science. Unfortunately, however, for the general adoption of his plan, it was soon found that his instrument was unsafe to use; that the wire gauze would not prevent the explosion of the gases, that in several cases, when used by the most experienced and cautious operators, the instruments were burst. The explosions were tremendous, and resembled the bursting of a bomb, the fragments of the iron chest being scattered with great force in all direc- tions. After trying various plans to render the invention safe, the Doctor, as a protection, had the iron chest placed behind a brick wall at the back of the operator, the gases being conveyed through a tube passing through the wall. In this state the instrument remained, until Mr. Goldsworthy Gurney applied himself to its improvement, and after numerous experiments, which are highly interesting, and are fully detailed in his published lectures, he succeeded in producing an instrument unattended with the elightest danger in its use, and admirably adapted both for scientific investigation, and for various operations in the arts. The annexed engraving is a representation of the instrument. A is the safety- chamber; B a water-trough, through which the gas is made to pass from the gasometer D by the cock C, through a tube which reaches to the bottom of the water-trough; E is a cock fitted into the neck of the same, from which it is thrown out should an explosion take place on the surface of the water. F is a gage, to indicate the necessary height of the column of water in the trough. G is a transferring bladder, which is made to screw and unscrew to and from the stop-cock H, for the purpose of supply ing the gasometer with gases, which may be charged and recharged at pleasure, by an assistant, during its action, 80 as to keep up the most intense flame for any length of time. A valve is placed between the gasometer and the transferring bladder, which prevents the return of the gas. II is a light wooden or stiff pasteboard cap, which combines sufficient strength with great lightness, so that in case an explosion of the gasometer should happen, it is merely thrown a short height into the air, by the force breaking the strings which connect the cap to the press-board. To these strings are attached Digitized by Google BLOW-PIPE. 105 276. I D o L Q = H N small wires which pass through the table of the instrument, as at L, into the press-board below, where they are secured; this press-board is kept in a horizontal position by the stand, so that when the re- quisite pressure is given to it, the cap 1 1 is brought to bear equally on the gasometer D. The gas- ometer bladder (or silk bag) is tied to a piece of bladder, which screws into a long tube laid into and across the table, which permits it to be unscrewed at pleasure from the body of the instrument, and immersed in water when it requires softening, affording also the means of fixing on another bladder, if any accident should render it necessary. The stop-cock of the charging bladder G is fixed to one end of the tube just described, and the stop-cock of the water-trough on the other end. To operate with this instrument, pressure by the hand is applied to the press-board, which draws down the cap I I on the gasometer D, and forces the gas which it contains through the stop-cock C, and through the water- tube and safety-chamber A, to the jet at the end, where it is burned. When the pressure on the press- board is too slight, or when the hand is taken off, the flame returns into the safety-chainber, and is extinguished. When it is required to suspend the operation, the hand need only be taken off the pressing-board; the water in the trough acts as a self acting valve in preventing the escape of gas from the instrument, and saves the necessity of turning the stop-cock. A silk tube is attached to the end of the tube before described, in the water-trough, which prevents the splashing of the water, sometimes occasioned by unskilful management. We omitted to state that the safety-chamber A is filled with numerous disks of very fine wire gauze closely packed, and should the flame be driven in, which will sometimes happen, it will not enter the bag or reservoir D, but will explode above the surface of the water in the chamber B, merely driving out the cork. An improvement has, how- ever, been since introduced in the construction of the safety-chamber, by Mr. Wilkinson, by which the retrograde motion of the flame appears to be effectually prevented. and a much larger jet may be employed than heretofore with perfect safety. This improvement consists in filling the chamber A with alternate layers of wire gauze and of asbestos, previously beaten with a mallet, and pulled out to resemble floss silk. Mr. Wilkinson received from the Society of Arts a silver medal for his com- munication on the subject, and we understand that Mr. Hemming has recently made some further im- provements in the construction of the instrument. We must here advert to the wonderful effects produced by the oxy-hydrogen blow-pipe, which almost instantaneously reduces the hardest and most refractory substances. Gun-flints are instantly fused by it, and formed into a transparent glass; china melts into a perfect crystal. All kinds of porcelain are readily fused, previously assuming a beautiful crystallized appearance. Rock crystal is quickly melted, giving out a beautiful light. Emerald, sap- phire, topaz, and all the other precious stones, melt before it into transparent glassy substances. Barytes, strontian, lime, and alumina, exhibit very striking and beautiful phenomena. Magnesia fuses into hard granular particles, which will scratch glass. The metals, even platina, are all quickly fused by it: and all descriptions of stones, slates, and minerals, are melted, sublimed, or volatilized, by its all-subduing power. BLOW-PIPE. DR. HARE'S HYDRO-OXYGEN; On certain improvements in the Construction and Sup- ply of the Hydro-oxygen Blow-p.,e, by which Rhodium, Iridium, or the Osmiuret of Iridium, also Plati- num in the large way, have been fused. By Robert Hare, M. D,, Professor of Chemistry in the University of Pennsylvania. While a pupil of my predecessor, Dr. Woodhouse, in the year 1801, having observed that a jet of hydrogen when inflamed in atmospheric air, of which only one-fifth is oxygen, was productive of a heat of pre-eminent intensity, I was led to infer that in combining with pure oxygen, the gas in question ought to produce a temperature at least five times as great. This led to the contrivance of two modes of producing a jet consisting of a mixture of hydrogen with oxygen. Agreeably to one mode, the gaseous currents, meeting like the branches of a river, were made analogously to form a common stream. This object was accomplished by means of perforations drilled in a conical frustrum of pure silver, so as to converge until met by another shorter perforation, commencing at the opposite surface, and so extended as to join them at the point of their meeting. The other mode was that of causing one tube to be within another, so as to be concen'ric, the outer tube being a little the longer of the two; the latter being employed for hydrogen, the former for oxygen. In the year 1814, this last-men ioned mode was improved, so as to have the means of securing, by adjusting screws, the concentricity of the tubes, and varying the distance of the orifice of efflux of the inner tube from that of the other. The constructions employed in 1801, were described and published in a pamphlet, and afterwards 14 Digitized by Google 106 BLOW-PIPE. republished m Tillock's Philosophical Magazine, vol. xiv., and in Annals de Chymie, vol. xiv. At the same time an account was given of the fusion of pure lime and magnesia, and of the fusion of platinum. Subsequently, in a paper published in the Transactions of the American Philosophical Society, it was mentioned that I had volatilized platinum. About the year 1811, Professor Silliman, in a memoir read before the Connecticut Academy of Sciences, gave an account of a series of experiments, in which the experiments which I had performed were repeated, and many additional fusions made. I had adverted to the intensity of the light pro- duced during the exposure of lime to the flame. Alluding to the heat and light, my words were, the eyes could not sustain the one, nor the most refractory substances resist the other." The intensity of the light was still more insisted upon by Silliman. My experiments were also repeated by Mr. Rubens Peale, during many successive years, at the Philadelphia Museum, for the amusement of visiters. About the year 1813-14, it was ascertained, at the laboratory of Dr. Parrish, that a bladder being supplied with a mixture of hydrogen and oxygen, in due proportion, and punctured by a pin, while subjected to compression, on igniting the resulting jet, the gas within the bladder did not explode. Of course, a burning jet of flame thus created was found competent to produce, while it lasted, the same effect as when otherwise generated by the same gaseous mixture. Soon after this result was obtained, Sir Humphrey Davy discovered, that if a lamp flame be com- pletely surrounded by a gauze of fine wire, it may be introduced into an inflammable gaseous mixture without causing it to explode. This was ascribed to the refrigerating influence of the metal, keeping the gaseous mixture below the temperature requisite for inflammation. Hence it was inferred, that if a mixture of hydrogen and oxygen, while condensed within a suitable receiver, was allowed to escape through a capillary metallic tube, 80 as to form a jet, this might be made to burn without communica- ting ignition to the portion remaining in the receiver. By means of an apparatus contrived agreeably to this idea, Dr. Clark, of Cambridge, England, re- peated the experiments, made many years before by Silliman and myself, without any other reference to ours, than such as was of a nature to do injustice. An exposition of the invalidity of Dr. Clark's pretensions to originality was made in Silliman's Journal for 1820, vol. ii., and in Tillock's Philosophi- cal Magazine for 1821, vol. lvii. The light produced by the hydro-oxygen flame with lime having been observed by Lieutenant Drum- mond, of the British Navy, was ingeniously proposed by him as the means of illumination in light- houses, and has been, in consequence, subsequently used as a substitute for the solar rays, in an instru- ment known as the hydro-oxygen microscope, which is a modification of that which has been called the solar microscope. The name of Drummond light has consequently been given to a mode of illumination, which I originally produced as above stated. The instrument which was used by Professor Silliman and by Rubens Peale, was that above described as having two perforations meeting in one. In this form it was, I believe, employed by Dr. Hope, of Edinburgh, and Dr. Thompson, of Glasgow, who both treated it as my contrivance, anteriorly to the publication of Dr. Clark's memoir. The other form, consisting of two concentric pipes, was modified by a Mr. Mangham, with the view of producing a lime light for the microscope above alluded to. When I saw Mr. Mangham at the Adelaide gallery in 1836, he treated this instrument as mine, in another form. I was surprised after wards to learn that he had obtained a premium for this modification from the British Society for the Encouragement of Arts, without any allusion to the original inventor. After my return from Europe in 1836, I was very much in want of a piece of platinum of a certain weight, while many more scraps than were adequate to form such a piece were in my possession. This induced new efforts to extend the power of my blow-pipe; and after many experiments, I suc- ceeded so as to fuse twenty-eight ounces of platinum into one mass. Although small lumps of platinum had been fused by many operators, with the hydro-oxygen blow- pipe, as well as myself, it had not, up to the year 1837, been found sufficiently competent to enable artists to resort to this process. I am informed by Mr. Saxton, that some efforts which were made while he was in London were 80 little successful, that the project was abandoned. There was an impression that the metal was rendered less malleable when fused upon charcoal, as in the experiments alluded to. This is contradicted by my experiments, agreeably to which fused platinum is as malleable as the best specimens obtained by the Wollaston process, and is less liable to flake. The celebrated Dr. Ure, on seeing the platinum in the forms of wire, of leaf, and plate, said that there was no one in Europe who could fuse platinum in such masses. He also alleged that it had been found so difficult to weld platinum, that no resort was had to that process. In this I concur, having had the welding tried by a skilful smith, both with a forge heat, and with a heat given by the hydro-oxygen blow-pipe. An incorporation of two ingots was effected on their being hammered together, when heated nearly to fusion; but on hammering the resulting mass cold, a separation took place along the joint by which the ingots were united. The difficulty seems to arise from the rapidity with which the platinum becomes refrigerated. It seems to have a less capacity for heat than iron, and, not burning in the air as iron does, has not the benefit of the heat acquired by iron from its own combustion with atmospheric oxygen. Latterly, by means of the instrument and process which it is my object here to describe, I have been enabled to obtain malleable platinum from the ore directly, by the continued application of the flame. From some specimens of platinum I have procured as much as ninety per cent. of malleable metal The malleability is not inferior to that of the best specimens obtained, by reducing it to the state of sponge, through the agency of aqua regia and sal ammoniac. There is, however, a greater liability to tarnish, arising, probably, from the presence of a minute portion of palladium. Of the fusion of iridium and rhodium, I have already given an account in the Bulletin of the Society, which was subsequently embodied in an article prepared for Silliman's Journal for October last, 1846. Digitized by Google BLOW-PIPE. 107 It remains now to give an account of the apparatus employed in the fusion of platina on a large scale. Fig. 277 represents the association of fifteen jet-pipes of platina with one large pipe, D B, at their upper ends, 80 that their bores communicate, by means of an appropriate brass casting, with that of the large pipe, the joints secured by hard solder. Their lower extremities are made to protrude about half an inch from a box A, of cast brass, their junctures, with the appropriate perforations severally made for them, being secured by silver solder. They come out obliquely in a line along one corner of the box, an interval of about a quarter of an inch alternating with each orifice. By means of flanges, the brass box is secured to a conical frustum of copper, Fig. 278, 80 as to form the bottom thereof, while the pipe, extending above the copper case, is screwed to a hollow cylinder of brass, A, Fig. 279, pro- vided with two nozzles and gallows screws gg for the attachment of appropriate hollow knobs, to which pipes are soldered, proceeding from the reservoirs of oxygen and hydrogen. Cocks are interposed by which to regulate the emission of the gases in due proportion. 277. D 279. 278. A g B g D B c E 280. In connecting the pipes conveying the gases with the brass cylinder, A, Fig. 279, care should be taken to attach that conveying oxygen to the upper nozzle, while the other, conveying hydrogen, should be attached to the lower nozzle; since, by these means, their great difference in density tends to pro- mote admixture, which, evidently, it must be advantageous to effect. The object of surrounding the jet-pipes with water, by means of the copper box,* is to secure them against being heated to such a degree as to cause the flame to retrocede and burn within them, 80 as finally to explode within the cylinder, A, gg, Fig. 279. It is preferable to add ice or snow to the water, in order to prevent undue heat. Fig. 280 represents a moveable platform, A, of cast-iron, wholly supported upon the point of the iron lever D B, which is curved towards the extremity under the platform, 80 as to point upwards, and to enter a small central conical cavity made for its reception. The lever is supported by a universal joint upon the fulcrum C, so that by means of the sliding-weight at one end, the platform and its appurte- nances are counterpoised at the other. The platform is kept in a horizontal position by the cannon- ball, supported in a sort of iron stirrup terminating in a ring, in which the ball is placed. Upon the platform is situated an iron pan with a handle, holding the brick, on a cavity in which, as already . Since the engraving was made, I have preferred to use water-tight boxes, with gallows screws and nozzles. situated one near the bottom on one side, the other on the opposite side near the top. By means of the lower nozzle, a pipe is attached, communicating with a head of cold water, the other being 80 situated as to carry the water into a waste pipe, or large tub: a circulation may be kept up during the whole time that the operation is going on. As a support, a brick of kaolin is used, having an oblong elipeoidal depression on the upper face for the reception of the metal to be fused. Digitized by Google 108 BLOW-PIPE. mentioned, the metal is supported. The apparatus being duly prepared, and connected with the supply pipes, the hydrogen is first allowed to escape, and then the oxygen, until the ignition has attained apparently a maximum. The accomplishment of this object may, of course, require the adjustment of either cock several times; especially where there is any decline in the pressure either of the one or the other gas in its appropriate reservoir. By means of the handles of the lever and of the pan, the operator is enabled to bring the metal into the position most favorable for the influence of the heat, while his hands and face are sufficiently re- mote to render the process supportable. In fusing any quantity, not being more than four ounces, the platform may be dispensed with, the handle of the pan being held in one hand of the operator, while by the other the cocks may be adjusted. When the blow-pipe of fifteen jets, or any larger, may be employed, and the platform is necessarily resorted to, the cocks must be adjusted by an assistant. Fig. 281 represents a cask made of boiler-iron, three-sixteenths of an inch thick, so as to resist an enormous pressure. The joints are secured by riveting, as in constructing high-pressure boilers. 282. H 281. B M HH L E A N T D C E F This cask communicates with the hydrant-pipes, so called, by which our city is supplied with water, of which the pressure varies from a half to more than two atmospheres, say from seven to thirty pounds per square inch, according to the number and bore of the cocks from which the water may be flowing at the time, for the consumption of the community. Hence, experiments, while using this head, are best made towards bedtime, or between that time and sunrise. The vessel is filled with water by opening a cock F on one side of the pipe C, and allowing the air to escape through the valve-cocks B. Being thus supplied, the cock F closed, and a communication with a bell-glass, into which oxygen is proceeding from a generating apparatus, being made by means of a flexible leaden tube, on opening the valve-cock B and the cock E the water will run out, and be replaced by gas from the bell. This process being continued till the iron cask is sufficiently supplied with gas, the cock E must be shut. Whenever the gas is wanted for the supply of the blow-pipe, it is only necessary to establish я communication between the valve-cock B and the upper gallows-screw, Fig. 279, of the cylinder A, and to open the cock F 80 as to admit the water to press upon the gas, the efflux being regulated by B, or preferably by a cock of the ordinary construction, one of which kind should be interposed at a con- venient position between the valve-cock B and cylinder A. T represents a glass tube, which, by due communication with the interior, shows the height of the water. and consequently the quantity of gas in the vessel. G H represents a gaging apparatus, consisting of a cast-iron flask, of about a half a pint in con- tent, and a glass tube of about a quarter of an inch in bore, which should be at least five feet in height. The tube is secured air-tight into the neck of the flask, so as to reach nearly to the bottom within. The flask is nearly full of mercury. Under these circumstances, when a communication is made, by a leaden pipe between the cavity of the flask and that of the reservoir, an equilibrium of pressure re- sulting, the extent of the pressure is indicated by the rise of the mercury in the tube. Digitized by Google BLOW-PIPE. 109 In order to generate hydrogen for the supply of a reservoir like that represented by the preceding figure, I have employed the vessel represented by Fig. 282. This vessel, by means of a suitable aperture, susceptible of being closed by a screw-plug, is half filled with diluted sulphuric acid. Being furnished with a tray of sheet copper D, punctured like a coal-sieve, and supported by a copper sliding-rod E, strips of zinc are introduced in quantity equal to the capacity of the tray. The sliding-rod passes through a stuffing-box F, at top of the reservoir, so that the operator may, by lowering or raising the tray, regulate or suspend the reaction between the zinc and its solvent, accordingly as the supply of hydrogen is to be produced, suspended, increased, or diminished. The communication with the reservoir is opened and regulated by means of the cock P, furnished with a gallows-screw G for the attachment of a leaden pipe, as above described, in the process for supplying the reservoir with oxygen. Another apparatus for producing a supply of hydrogen, is represented in Fig. 000. It consists of two 283. M L H K c SE 3 B C N E c P ci2 D A. o similar vessels of boiler-iron, each capable of holding forty gallons. They are lined internally with copper, being situated upon a wooden frame, 80 that the bottom of one is two-thirds as high as the top of the other. The upper portion of these vessels communicate by a leaden pipe B, of about half an inch bore, furnished with a cock, while the lower portions communicate by another leaden pipe of a bore of 11 inches. The upper vessel is surmounted by a globular copper vessel, of about twelve inches in diameter, which, from its construction, renders it possible to introduce an additional supply of concentrated acid while the apparatus is in operation, without reducing the pressure within the reservoir, by permitting the excess above the pressure of the atmosphere to escape. This object is accomplished as follows :- Digitized by Google 110 BOBBINET MACHINERY. The valve at the end of the rod, attached to the lever L, being kept shut by the catch M, the screw- plug H removed, the acid is introduced through the aperture thus opened. In the next place, the plug being replaced, and the valve depressed by means of the lever and rod, 80 as no longer to close the opening, which it had occupied, the acid descends from the chamber into the cavity of the vessel beneath it. The valve is of course restored to its previous position as soon as the acid has effected its descen⁴. The lowermost vessel is furnished with a perforated copper tray, supported by a copper sliding-rod, in a way quite analogous to that already described in the case of the copper reservoir. It is also sup- plied with zinc and its solvent in like manner, being made half full of the diluted sulphuric acid. Of course, on contact being produced between the zinc and its solvent, the generation of hydrogen will take place. So long as the communication between the upper portions of the two vessels is open, the gas will extend itself into both, occupying the whole of the upper vessel, and that half of the lower one which is unoccupied by the liquid. But if, in this way, the pressure reaches to two atmospheres, as indicated by the gage, on shutting the communication through the pipe B, the pressure in the in- ferior vessel will augment, that in the superior vessel remaining as before, but the liquid will conse- quently begin to pass out of the inferior vessel through the pipe A, and thus may lessen the contact between the acid and zinc, and finally suspend it altogether. Meanwhile the gas in the upper vessel being condensed to nearly half its previous bulk, the pressure will be nearly four atmospheres. It will, in fact, always be nearly double that which existed before the pipe B was closed. In order that nearly the whole of the acid shall be expelled from the inferior vessel, the tray must be depressed till it touches the bottom of that vessel. The pressure being four atmospheres at commencement, as soon as, by means of a pipe attached to the valve-cock N, an escape of gas is allowed, the acid is forced again upon the zinc, and thus prevents a decline of pressure to any extent sufficiently to interfere with the process. The gases may be used from a receiver in which they exist, in due proportion, safely by the following means. Two safety-tubes are to be made, not by Hemming's process exactly, but as follows :-A cop- per tube, silver soldered, of which the metal is about the eighth of an inch in thickness, is stuffed with the finest copper wire, great care being taken to have the filaments straight and parallel. The tube is then to be subjected to the wire-drawing apparatus, so as to compress the tube on its contents until the draught becomes so hard, as that it cannot be pushed farther without annealing. The stuffed tube thus made is to be cut into segments, in lengths about equal to the diameter, by a fine saw. The surfaces of the sections are to be filed gently with a smooth file. By these means, they appear to the naked eye like the superfices of a solid metallic cylinder. Brass caps being fitted on these sections, they are to be interposed by soldering, at the distance of a foot or more, into the pipe for supplying the jet. Under these circumstances, the posterior section, becoming hot, may allow the frame to retrocede; but the anterior section being beyond the reach of any possible combustion, and remaining cold, will not allow of the retrocession; and as soon as the flame passes the first section, the operator, being warned, will of course close the cock, and subject the posterior section to refrigeration before proceeding again. But this plan of operating may be rendered still more secure by interposing a mercury bottle, or other suitable iron vessel, half full of oil of turpentine, between the reservoir and safety-tubes, as in the arrangement of a Woulfe's bottle. A leaden pipe proceeding from the reservoir is, by a gallows-screw, attached to an iron tube which descends into the bottle, 80 as that its orifice may be near the bottom. The leaden pipe communicating through the safety-tubes with the jet-pipe, is attached to the neck of the bottle. Thus the gaseous mixture has to bubble through the oil of turpentine in order to proceed through the safety-tubes to the jet-pipe. If, while this process is going on, the flame should, by retrocession, reach the cavity of the bottle, exploding in contact with the turpentine, a compound is formed, which is, per se, inexplosive from the excess of carbonaceous matter. Meanwhile the shock, acting on the surface of the oil, drives it into the bore of the iron tube, and thus, both by its chemical and mechanical influence, renders it utterly impossible that the flame should reach the cavity of the reservoir. BOBBINET MACHINERY, is the name of machines which are intended for manufacturing a peculiar net-like texture, whose constructure is inferred from that of the pillow-made or bo 'e-lace, and which, in its most simple intertwisting. is known by the name of plain bobbinet and quillings. The simple intertwisting of the plain bobbinet has been altered in various manners, and thus have been produced new kinds of texture, partly very different in appearance from that of the plain bobbinet and in recent time furnishing very fine fancy articles, much in demand. They are termed figured bobbinet in the following description, which treats chiefly of the most common and most recent systems of bobbinet machines. The machines for manufacturing quillings, and which are known by the term stripe-machines, work quillings or edgings from to to 4 and 6 inches in breadth, and of considerable length. A great many edgings, connected with and by the side of each other, thus forming one broad piece, are worked simultaneously, and are subsequently separated. As the quillings are, as it were, to be edged at both borders, for the sake of fastness and durability, this edging and intertwisting of the several quillings require particular contrivances in the machines, which thus, according to the different systems applied to them, are more or less complicated. Those for manufacturing the figured bobbinet are in general narrow; that is to say, there can be worked only pieces of inconsiderable breadth by them. This is owing partly to the circumstance, that older machines, originally intended for manufacturing pieces six or eight quarters of a yard wide, have been arranged for figured bobbinet, to make them still fit for use in any way and partly to the fact that the making of figured bobbinet is by far more difficult than that of plain bobbinet, and that it requires the most eager attention and skilfulness of the operative. To the latter it would be almost impossible to overlook broad pieces of this kind, or the work would go on so slowly that such an arrangement could be of no great avail. Digitized by Google BOBBINET MACHINERY. 111 Alphabetical Survey and Explanation of the Letters in the Figs. 284 to 394. A, right side-frame, Figs. 285 and 286. A1, left side-frame, Figs. 284, 286, and 287. B, fore front-frame, Figs. 284, 303, 317. B1, back front-frame, Figs. 284, 303, 317. C, joist joining the uppermost parts of the side-frames, Fig. 286. C, pillars screwed on C, and bearing the sockets of the lace-beam A, Fig. 286. D, rounded iron bars across which the texture passes on its way to the lace-beam, Fig. 286. D₁, D2, cross-beams at the right and left sides of the frame, Figs. 284 and 285. E, front pusher-bar, Figs. 284, 288, and 289. E₁, back pusher-ba Figs. 284, 288, and 289. F, a kind of reed composed of perforated brasses for the warp-threads, Figs. 284 and 286. F1. steel springs of the hold-fast contrivance, Fig. 357. (+, warp-beam, Fig. 284. G,, } lever-arms of the point-bars, Figs. 284, 285, 288, and 289. G1, H, lever bearing the weight-stone R, Figs. 284, 286, and 287. H,, lever moving the front point-bar, Fig. 287. H2, lever moving the back point-bar, Figs. 287, 288, and 289. I, cradle-arms, Figs. 284, 285, and 286. I,, cradle-pieces, Figs. 284, 285, and 286. K, front bolt-bar, Figs. 286, 288, 289, 300, and 303. K., back bolt-bar, Figs. 287, 288, 289, and 303. L, front comb, Figs. 284, 288, and 289. L₁, back comb, Figs. 284, 288, and 289. M, front point-bar, Figs. 284, 285, 288, 289. N, back point-bar, Figs. 284, 285, 288, and 289. N, crowbar of the front point-bar, Figs. 286 and 287. N2, crowbar of the back point-bar, Figs. 288 and 289. o, socket-frame in the midst of the machine. 1 Both are fastened to B and Bt, and bear the sockets P, socket-frame at the side of the machine. 1 of the lockers, Figs. 315 and 317. P1, forked bars for both point-bars, Figs. 287, 288. and 289. Q, weight-stone for the tension of the warp, Figs. 284, 285, 286, and 287. Q1, lifting-thumb acting on the forked bar P1, Figs. 288 and 289. R, grooved disks for the cords or strings S, Fig. 286. R1, large rowels, Fig. 284. Rr. shell-wheel of the front point-bar, Fig. 286. Rn, shell-wheel of the back point-bar, Figs. 286, 288, and 289. 8, cords or strings for the tension of the warp, Figs. 284, 285, 286, and 287. S1, support of the front point-bar, Fig. 287. S, support of the back point-bar, Figs. 287, 288, and 289. T. T,, shafts to which the lever-arms G₁ and G₂ are fastened, Figs. 284, 288, and 289. U, large heart-shaped disk to bring about the swinging movement of the pusher-bars, Figs. 284, 288, 289, and 290. Un similar disk in Figs. 358 and 859. V. great spur-wheel with 48 cogs at the principal axis W, Figs. 285 and 286. W, principal axis of the machine, Figs. 284, 286, 288, and 289. W', driving axis of the machinery for the thong-disk Y, Figs. 284, 285, and 287. X, dented wheel at the axis W₁, with 36 cogs, Fig. 285. Y, thong-disk at the axis W1, Fig. 286. Y1, thong of the disk Y, Fig. 286. Z, the lace-beam, Fig. 284. a, front guide-bar, Figs. 284, 331, 332, 303, 317, &c a,, adjusting screw for the lateral movement of the front guide-bar, Figs. 331, 332, and 333. a, adjusting screw for the lateral movement of the back guide-bar, Fig. 333. b, back guide-bar, Figs. 284, 303, 815, 317, and 333. b1, by } curved stays through which the adjusting screws a and a₂ pass, Figs. 331 and 338. bn common pivot of the levers H and H2 and of the crowbar N and N2 Figs. 287, 288, and 289. c, front series of guides, Fig. 284. C1, projecting bolt, through which the supporting screws d and d₂ pass, Figs. 331 and 833. cm cm } adjusting screws of the levers H₁ and H₁, Fig. 287. d, back series of guides, Fig. 284. d₁, d, } supporting screws of the guide-bars, Figs. 331, 833. e, middle stay of the bolt-bars. Figs. 300, 301, 302. f, warp-threads, Figs. 284, 335, 336. and 360. Digitized by Google 112 BOBBINET MACHINERY. f1, steel springs for pushing back the guide-bars, Figs. 285, 295. f2, pivots on which the point-bars turn. Figs. 285, 288, 289. g, socket-irons of the warp-beam, Fig. 284. I₁, Is } lever-bars for the lockers, Figs. 285, 288, and 289. 4, lever-arm at the midst of the axis m, Figs. 358 and 359. k₁, lever-arms at the ends of the axis w, Figs. 358, 359, and 284, 285, 288, 289. h₂, i, pivot of the lever-bars I₁ and In Figs. 284, 285, 288, 289. k; k₁, weft-threads, Fig. 360. k₂, curved arms, to which the pivots f2 of the point-bars are fixed, Figs. 285, 288, 289. 1, front carriage-line, Figs. 284, 288. 289. l₁, back carriage-line, Figs. 284, 288, 289. l₂, sockets of the shafts T and T1, Firs. 285, 286. l₃, sockets of the shafts w in Figs. 358, 359. m, drawer-bars of the lever-arms h₁ and hr Figs. 358, 359, and 284, 285, 286, 288. m₁, m₂, adjusting screw for the lateral movement of the front comb, Figs. 286, 300, 301. mr adjusting screw for fixing the back comb, Figs. 286, 288, 300, 301. n, point-pieces, Figs. 284, 286, 288, 289. n., split sockets of the guide-bars, Figs. 304, 305 a, in the midst of D₁ and D2, and of the machine. R n₁, spiral-spring of the point-bars, Fig. 285. o, comb-shifting disk at the shaft t, Fig. 286. o,, ratchet-wheel of the front guide-bar, Fig. 286, left side. on ratchet-wheel of the back guide-bar, Figs. 285. 286. On, comb-shifting disk at the shaft t, right side, Fig. 286. p, locker-bar, Figs. 284, 288, 289, 309. P., bolts or rails to which the adjusting screws m, and ms are fixed, Figs. 300, 301, 286. P₂ socket-pieces at D₁ and Dr Figs. 284, 285, 286. q. locker, Figs. 284, 288, 289, 309. qn supporting arms or stays of the bolt-bars, Figs. 284, 285, 287, 300, 301, 302, 303. q₁, screws for supporting the bolt-bars, Fig. 317. r, sliding roller of the large heart-shaped disk U, Figs. 284, 288, 289 (r,) sliding roller of the large heart-shaped disk U,, in Figs. 358 and 359. r1, roller of the locker-disk v₁, Fig. 286. T2, roller of the locker-disk U₂, Fig. 286. T3, rowels at the bar D, Fig. 286. r4, sliding roller of the shell-wheels R2 and R₃, Figs. 288 and 289. 8, arms by which the point-bars are connected with the supporting bars S, and S2, Figs. 287, 288, 285 81, 82, dented wheels at the axis W, Fig. 286. t, shafts to which are fixed all ratchet-wheels and disks, Figs. 285, 286, 288, 289. & t1, } dented wheels at the axis t, Fig. 286. u, pivot on which the pushing levers x₁ and x₂ move, Fig. 285. us, angular lever of the front guide-bars, Fig. 295. 262, angular lever of the back guide-bars, Fig. 295. us, pushing lever of the front comb, to the right, Fig. 286. u,, pushing lever of the front comb, to the left, v, motive power or quarter-wheel of the lockers, Figs. 284, 311, 312. v₁, locker-disk for the back locker, at the axis W, Fig. 286. v₂, locker-disk for the front locker, at the same axis, Figs. 284, 286, 288, 289. w, shafts to which the lever-arms h, h₁ and h2, are fixed, Figs. 386, 289, 358 and 359. so,, shafts to which the cradle-arms I, and cradle-pieces I, are fixed, Figs. 284, 285, 286, 287. 20₂, dented wheel of the lace-beam, Fig. 285. x, socket of the shaft 10, Fig. 284. I1, pushing lever of the front guide-bar, ~ Figs. 286 and 295. xq. pushing lever of the back guide-bar, xₙ x3, angular levers for pushing the bolt-bars, Figs. 285 and 287. y, bolt or rail, through which the common peg of the angular levers u₁ and Ug are put, Fig. 295. y, adjusting screw of the point-bar, on which the upper fork of the bar S₁ is acting, Figs. 288, 289. Yr adjusting screws of the point-bar, which strike against the side-frame A and A1, Fig. 285. 2, a trigger, Fig. 286. : 5 } dented bars for the lockers, Figs. 284, 287, 311, 312, 314. a, foot-screws of the bolt-bars, Figs. 284, 285, 286, 287, 300, 303. B, notch in which the middle stays e are running, Fig. 317. I. d, } iron pegs at the lower fork of the bar S1, Figs. 288 and 239. Digitized by Google BOBBINET MACHINERY. 113 a Bs 84 © G X Sr. R 293. z R x S 8 K, S A, D2 B 16 B - 10 & its 8 K R3 e k 03 K 70 Is 290. me a 2 $ its K 201, 2411 6 a K, 292. . p 844 A. Я (o) XI Xrn A u o, THE 768 or O. x 15 Digitized by Google 114 BOBBINET MACHINERY. Y Y / HIL eRs 4 Y₂ D 5 N R 2 B 12 D 00 6/0 010 00 010 2010 00 OG 286. 6/0 00 0/0 00 010 910 00 00 B N R O y, K 5 2 296. 297, 298. a 299. D, 2 295. 183 : Digitized by Google Digitized by Google 308. . o 311. to to 314. 7 312. 302. 301. S 302. 0 313. '6 & 9. all 781 W 307. A 0 HE & 320. Я 305 304. M38 I "U - 72, 303. Я HB q b X 317. De q R q 318. I N y 0 302. 301. Q.2 300. B. B B 310. 306. 309. 316. il 315. B e 6 a $ + in HE 26 'd # or ½ 319. d D, A,g % FOIR 20 © N0211117 to 10 9 ÷ I S2 or R₂ u 4, S 287. 91 R ON Z EN 01 G2 0.0 A. K. III D₂ of " O 911 BOBBINET MACHINERY. Digitized by Google 344. * C 329. I 343. a 334. I 342. F 335. 336. 0 337 327. b q à a 333. # 2 327. 341. a * CI 340. E D a a - - 327. W B 326. 322. 321. F Fo t 340. 339. 332. 331. W 330. B 20 " a * Hollc + 325. R è 324. ; , à 8 è 323. a w & 338. BOBBINET MACHINERY. OII BOBBINET MACHINERY. 117 O 12 23 22 12 28 IS 21 23 22 12 B = 8 * 347. 18 345. 348. 22 22, 346. 13 20 20 14 2 20 14 U.S. 2 CN 349. 15 of 15 19 16 t = 16 IG IS SI 19 SI 19 I (5) (9) 5 n (4) (8) o A B s feet. S (3) 356. K cmo h (7) 350. F (r) o I, R H T Da 2 (2) (6) 358. D G K A (1) m © 350. Ru m a 0 >I A LO D ЧШП o = 1 359. U 712 7 S il is TP N 12 y It 10 © B e 12 351. K W 352. 353. 14 D F 368. & 357. o o F 357. Digitized by Google 118 BOBBINET MACHINERY. II kVIII 369. 360. & D of of III VII IX XI 12 369. 370. 371. a 372. 376. # & 363. " 377. 373. a w 361. 362. 363. 364. I # 365. 375. 374. Digitized by Google BOBBINET MACHINERY. 119 378. N M N n E J₁ 7 1 l F B q k k 1 P q P P₃ P, e E d LAJ 4 e, 384. 383. or b : H M/ / 382. k h G l i 1 L c q k 380. P 1 P G₃ Ti n k 1, l " k 1 q 4 Fe P3 379. E TV, TU 381. 1; b a E k W E L I L 1 L 1 K 1 k₁ q k = 4 % P P 3 q P p q p 3 3 p b и 12 to statement Digitized by Google 120 BOBBINET MACHINERY. E L 386. o & J 390. L @ & c . ,H ,K 388. 3N L P . X' E 2 af 77 391. 49 is sh 4h C d OR <0 D 385. 387. 389. d A K A 7 E at R 392. 393. R J 394. R Digitized by Google BOBBINET MACHINERY. 121 Machines for manufacturing broad plain Bobbinet. The latest and most approved construction of these machines is according to the double-locker sys- tem. Machines of this system can be arranged for any breadth of the piece, and are working for weeks, and even months, with great precision and quickness, without any interruption which might be produced by irregularity in the mechanism. Being commonly of considerable breadth, the motive power must be very strong; therefore it is driven either by water or steam. In the following, we give a description of a machine for webs 8 quarters wide, constructed according to the double-locker system, and illustrated by Figs. 284 to 375, in the most careful manner. The illus- trations are given with all particulars required, which may enable the mechanic to draw upon a large scale from them. The machine for manufacturing plain bobbinet, though being the most simple of all bobbinet machines, belongs, however, by its construction to the most complicated ones. Its web is represented by Fig. 360 on a large scale. One and the same thread is marked along its way by the same letter. The threads f are extended up and down, or proceed downwards in serpentine lines, while the two other sets of threads k and k₁ proceed from the right to the left, and from the left to the right in slanting directions. By this, the twisting and interlacing of the threads is produced. The perpendicular threads in the figure, which are parallel to the border, may be regarded as the warp, and the two sets of slanting threads as the weft, in comparing bobbinet with a common web. The straight warp- threads receive their twist from the tension of the weft-threads, twisted obliquely round them alter- nately to the right and left. This seemingly simple union of the threads requires, however, a very complicated mechanism, which must be understood before the operation of the machines can be comprehended, and their result ex- amined more closely. At the chief frame A A, B B, C, are shown all parts of the machine. (See Figs. 284 to 287.) Fig. 284 shows the machine near its centre in transverse section Fig. 285 gives an end view of the right side of the machine, before which the operative has his ordinary place. Fig. 286 gives a front view of the fore side, and Fig. 287 an end view of the left side. Two and two opposite sides of the frame are completely equal to each other, viz: A and A1, B and B1; all four are united by screw-bolts. The joist C, Figs. 284 and 286, binds the upper ends of A, A1 together. The warp of the web consists, as has already been mentioned, of parallel running warp-threads, which are coiled round the warp-beam. In proportion to the proceeding of the fabrication, the warp is unwound, while at the same time the finished lace is wound upon the lace-beam. The lace-beam is placed above the warp-beam, as may be seen by Z and G in Fig. 284, where they are shown in trans- verse section. The ends of the warp-beam (represented in Fig. 284, in transverse section, and with the warp wound upon it) are provided with strong rollers or disks; and its pivots run in iron sockets, which are fastened to B1, and in the figure marked by g. The disks R are grooved to receive the cord S, one end of which is fastened at B, while the other end runs vertically downwards, and is fastened to the lever H. This lever turns on a pivot at the post B1, and its fore end bears the weight Q. This contrivance serves to keep the warp in due tension while being wound off the warp-beam. This unwinding takes place in four rows of warp-threads, (see Fig. 284,) for which purpose the single threads pass the eyes of a kind of reed F. Figs. 284. 286, and 350, 351, consisting of single pieces of latten-plate, called brasses, and placed one by one into the grooves of two long staves, bound together at the ends and in the midst. The brasses are regularly perforated in four rows. The reed is oblique, and close above the warp- beam loosely fastened, (see Figs. 284 and 351,) that it (if required) may be lifted a little, and not slip down. The warp-threads are marked with f. Fig. 350 gives the view of a brass; Fig. 350 a trans- verse section of a row of eyes; and Fig. 351. The fourfold divided warp passes vertically upwards between two parallel guide-bars, and unites close above them into two series of warp-threads, two and two series of the warp being drawn into two series of guides. The guide-bars (see Figs. 284, 286, 330, 331, 332, 333, 334, 335, 336, 337) are placed along the whole machine and supported at both ends and in the centre, that they may retain their parallel situation and their relative position. They are in all figures marked with a and b-a marking the front and b the back guide-bar. Both guide-bars are liable to lateral movement, by which a lateral shifting of the warp is effected. The series of guides c and d consist, like the reed F, of single pieces put together lengthwise. The number of the pieces, which are to be of entirely equal breadth, depends upon the number of the warp-threads, or of the breadth of the texture. Every single piece, consisting of a mixture of lead and zinc, is provided with an equal number of guides, being made of iron or steel wire, and cast together with the pieces in uniform distance from each other. Fig. 334 gives a front view of a single lead-piece in its position when screwed to the guide- bar Fig. 335 a side view of it; Fig. 336 represents a single guide; and Fig. 337 an ear. Guides are almost exclusively used, as by them the drawing in of the warp-threads is considerably facilitated. The two series of guides c and d divide the warp into two opposite equal parts, of which the texture is to be made. At the point where the texture begins both unite in one warp and are placed in one plane. Each half extends over the whole breadth of the texture, the threads of each series having double the distance between themselves, apparent in the texture. This arrangemcnt is of the greatest importance. The lace-weaving is facilitated by it, and at the same time some parts can be made stronger, which is of great avail regarding durability and quickness of operation. Moreover, the inconvenience of entangling and tearing the threads is removed. The texture begins near MN, where the interlacing and twisting of the warp and weft threads is accomplished. Fig. 360 shows the formation of the regular holes or meshes, completed by the round points of the point-bars M and N, after the intertwisting of the warp and weft threads having been accomplished 16 Digitized by Google 122 BOBBINET MACHINERY. below. The formation of the meshes is effected round the points of the point-bars, and simultaneously across the whole breadth of the warp in horizontal lines. For the formation of one row of meshes only one point-bar is required. Both alternate in this operation, 80 that one point-bar holds the finished row. of meshes, while the other takes up the next following, and thus they relieve each other continually. In proportion to the proceeding of the formation of the rows of meshes, the texture is wound upon the lace-beam. Figs. 284, 285, 286, 287,-288, 289, 321, 322, 328, and 329, will illustrate what is said here. The point-bars are marked with M and N,-the front bar with M, and the back point-bar with N. Both are provided with points which are adapted to each other. The points are cast in lead-pieces which are fixed to the point-bars by screws, (see Figs. 321, 322, and 328, 329;) the last-mentioned figure shows a point-piece N separately. Every point-piece must have exactly the same breadth as the lead-pieces of the series of guides c and d, whose number is equal to that of the point-pieces. The number of points in each point-piece is likewise equal to that of the guides in each lead-piece. By Fig. 328, it will be perceived that between the single points there is room enough not only for the opposite points, but also for the intertwisting threads. Z represents the lace-beam, running parallel with the warp-beam, and being of equal length, and of equal or smaller diameter. It turns on pivots, whose sockets are placed in similar manner to those of the warp-beam. See Fig. 286. The successive turning of the lace-beam is effected by a regulator, moved by the machinery. The finished lace passes on its way from the point-bars to the lace-beam across the rounded iron bar D, Figs. 284, 286, 352, 353, and 354, which serves to support the texture. At both ends of it are rowels r₃ (355) turning on small pivots. The pricks of these rowels enter the meshes close by the borders of the texture, thus preventing its running together. The larger rowels R1, close above the smaller ones, are intended for the same purpose. The lace is, by its winding upon the lace-beam, on account of its tension, somewhat less broad than it is when lying on the point-bars. The union of the warp and weft takes place below MN, and is effected by two rows of weft-threads, each of which is wound round a small bobbin, that passes between two and two warp-threads. Thus there are two rows of bobbins which are moved round the warps; and in this way the intertwisting is effected. The bobbin-rows stand parallel with the breadth of the warp, and either both rows before or behind it; or one row before and one behind it. That the bobbins may occupy these respective positions, they are pushed from one side to the other on carriages and bolts. Each bobbin has its separate carriage and bolt; and two and two bobbins are with their carriages behind each other, on one bolt. The whole series of bolts is called a comb. The bobbins, carriages, and bolts, are of a peculiar shape, as may be seen by Figs. 284, 286, 288, 289 296, 297, 298, 306, 307, 308, 326, 338, 339. Fig. 296, gives the side view of a carriage with inserted bobbin. Fig. 297, section of a bobbin. Fig. 298, carriage viewed from the other side, and without the bobbin. Fig. 299, section. Figs. 306, 307., and 308b, show a bolt. Fig. 306, gives a side view of the bolt, when placed in the machine. Fig. 307, represents its lower edge turned towards the warp. Fig. 308, gives a section of the bolt at its opposite end. The single bolts are, like the points and guides, cast in lead-pieces, each of which contains as many bolts as there are points and guides in one lead-piece. The breadth of the comb-pieces is exactly equal to that of the other lead-pieces. Figs. 338, (view from behind,) 339, (front view,) and 326, (side view,) represent a comb-piece. The small interstices between the single bolts receive the carriages, which thus, with their grooves, are placed upon the bolts. See Figs. 298, 299, 306, 326, 338, and 339. The bolt-pieces are by the side of each other screwed on a bar, and thus form together the comb. One of such combs is placed before, and one behind the warp, and the distance between both is not greater than required for the easy passage of the double row of warp-threads. The bolts of both combs are exactly opposite each other, that the carriages may be pushed from one comb to the other without obstruction. The bolts are circular, to keep the bobbin-threads at an equal tension, while the carriages are pushed to and fro. The width of the carriages, compared with the inconsiderable distance by which their bolts stand off, on both sides of the warp, permits this pushing from one comb to the other without any difficulty. Both combs have their correct mutual position with reference to the centre of the circular line. In the figures, the front comb is marked with L, and the back comb with L₁; the bars on which the tembs are screwed, and which are called bolt-bars, are marked with K and K,, and the carriage-lines 1 th l and l₁. The carriage-line l, which is always nearest to the operative, is called the front, and l₁ the back line. For this reason they use to say front and back carriage-thread series, or briefly front and back carriage-threads, instead of bobbin-thread series, etc. The unwinding of the threads and turning motion of the bobbins, is to be seen by Figs. 296, 297, 298, and 299. The swinging movement of the carriages on their circular bolts is not a continual one, but is made in short regular intervals. The pauses occur as soon as the carriage-lines, coming from the one or the other side, have passed the warp-threads and stand completely on their bolts. Meanwhile the shifting of the warp-threads (not being hindered now by the carriages) to the right or to the left takes place. As soon as the carriages pass the warp-threads, the regular twisting and crossing is accomplished, and at the same time the mesh of net completed. Digitized by Google BOBBINET MACHINERY. 123 The swinging movement of the carriages is effected in the following manner. See Figs. 284, 288, and 289. E and E1 are two bars, parallel to the carriage-lines, but somewhat longer, and their oblique side turned towards them. Both bars are, with their ends, placed so that they cannot shift their places. Figs. 284, 288, and 289 show the different positions which they occupy. They are close above the comb, seize the carriages, and push them from one comb to the other, as soon as put in a swinging motion. This motion is in consequence of. their moveable sockets being put in the rifts of the cradle-pieces I,, which are moved backwards and forwards like a pendulum. See Figs. 284, 285, 286, 287, 340 to 344. By Figs. 284 and 289, it may be seen that these pusher-bars never can pass the centre, but stop at some distance from the warp before they make their retrograde motion. Thus the pushing of the car- riages beyond the midst, cannot be effected by them; this must be done by the drawer-bars, or the blades of the locker, (here called double-locker.) These are marked with q, and the locker-bar on which they are screwed, with P. Fig. 294 gives a transverse section of the double locker-blades. The locker-bars P are placed at both sides of the warps below the comb, towards the bolts of the carriages. The locker- blades may be cast either each separately, or, more properly, both together, and then fastened to the locker-bar by screws. Their material is brass, but the bars are made of wrought-iron. The length of the combined locker-blades is somewhat exceeding that of the comb, and they therefore can seize a whole carriage-line at the pointed ends of the carriages projecting from beneath the comb. See Figs. 284, 288, 289, 296, and 298. By a slight angular movement of the blades, the carriages, pushed to them by the pusher-bars, are seized at their feet, and drawn across the midst of the machine through the warp-threads. The movements of the pusher-bars and lockers are thus supporting each other, and by this, the swinging of the carriages is completely effected. The lockers serve at the same time to keep back the carriage- lines during the above-mentioned pauses, thus prevent them getting into the centre, and bringing the warp-threads out of order during their shifting. The periodic angular movement of the locker is effected by motive power, dented bars and eccentric disks acting upon the axis of the locker-bars. Figs. 284, 288, and 289 will more distinctly explain the operations of the single locker-blades. In Fig. 284, both carriage-lines stand on the back comb. The front blade of the back locker holds the hind-feet of the front carriage-line, and thus retains also the back carriage-line. The front locker is com- pletely turned over, so that its blades by no means hinder the carriages from sliding on the front comb. In Fig. 285, the front blade of the front locker has already drawn over the front carriage-line, and keeps it on the comb. The back carriage-line is on the back comb, and is retained there by a blade of the back locker. In Fig. 286, both carriage-lines are on the front comb, and the back line, together with the front car- riage-line, is retained by the back locker-blade. The figures also show the counter-movement of both lockers, the necessity of the removal and height. of the locker-blades, etc. This highly ingenious con- trivance is invented by Mr. Morley. The chief parts of the machine, their movements and functions in general, are now known, and it will hereafter not be difficult more to follow the movements, operations, and connection. But first, a stand- point must be afforded, from which the whole progress of the machine can be overlooked. For this pur- pose, it will be suitable to commence with the moment when a row of meshes is completed and seized by the point-bars, and at the same time to notice the particulars concerning the rotation of the shafts, wheels, and disks. The great dented wheel V (with 48 cogs) at the principal axis W, makes three rotations during the two movement-periods, in which two rows of meshes are completed. It is the same with the two dented wheels 8, and Sq. The large heart-shaped disk U, and the two small locker-disks v₁ and v₂ make likewise three rotations in this time. Each rotation of these disks brings about four interrupted movements of the pushing and locker bars. Every such movement causes a carriage-line to cross a comb. Consequently, for completing one row of meshes, six movements of carriage-lines are required. The dented wheels t₁ and t₂, (of the axis t,) which are turned by 8₁ and 82 have thrice as many cogs as the latter dented wheels, and, for this reason, they make only one rotation, while the principal axis W makes three. It is the same with the shafts t, and the pushing-wheels and lifting-thumbs connected with them. The notches and elevations of the pushing or notched wheels, occupy nearly one-twelfth of the pe- riphery, if taken together. In Figs. 345, 346, 347, and 348, their mutual position with reference to their notches and elevations is shown, as they must be put on the shafts. This position corresponds to the moment which is represented in the figure of the machines, in Figs. 284, 285, 286, and 287. The disks move in the direction of the arrows. The pushing-points of the levers are in a vertical plane going through the axis of the shafts t. Equally marked points of the periphery of the pushing or ratchet wheels are during the movement entering this vertical plane, and acting upon their levers simultaneously. The ratchet wheels in Figs. 345 and 346, are, during a total rotation of the axis, (or during the com+ pletion of two rows of meshes,) pushing the front comb twice to the right and twice to the left; the notched wheel 0,, Fig. 347, pushes in the same time the front guide-bar, and with it the front half of the warp, thrice to the right and to the left, and the notched wheel 0₂ Fig. 348, does the same with the back guide-bar and the back half of the warp. The shell-wheel R₂ of the front point-bar (represented in Fig. 287, but omitted in Figs. 288 and 289) has a position entirely opposed to that of R,, so that the indenture of the shell-wheel R₂ stands deepest while that of R, stands highest. (See Fig. 289.) The points 9, 10, and 11, of the lifting-thumb Q₁, (sec Figs. 288 and 289,) are, with reference to the Digitized by Google 124 BOBBINET MACHINERY. simultaneous pushing of the ratchet-wheels, corresponding about the points 20, 22, and 12; that is to say, as soon as the points 9, 10, and 11 are active, the points 20, 22, and 12 follow this movement in succession. On the other hand, the edge of the indenture in the shell-wheel R, corresponds respectively with 10 and about 16, its centre with 11 and 18, and its opposite edge with 19. The corresponding points of Rs are respectively 10, and about 22, then 11, 12, and 13. The relative position of all parts being thus correctly stated, we shall follow the various movements from the moment when a row of meshes has just been completed, and the points are falling or catching in the meshes. Fig. 289 shows the positions of most of the chief parts in this movement; and there we see what follows :- The back point-bar is about to fall off. Both carriage-lines are on the front comb. The front half of the warp assumes its usual position, (that is to say, its most frequent position.) Point 12 on 0₁ is under the point of the lever x₁, (see Fig. 286.) The back half of the warp has just now shifted from the left to the right, the lever x₂ being fallen off from 12 on Or The movement ensues. The back point-bar N lifts the row of meshes. The back carriage-line 1, goes up to the back comb. After the shafts t and W have made respectively one-twelfth and a quarter of rotation, a pause ensues. The point-bars have lifted up their rows of meshes almost entirely. The back carriage-line is on the back comb. All carriages have made a comb-movement. The front half of the warp retains its usual position, (see above;) the point 13 on 0₁ is advanced until beneath the point of the lever. The back half of the warp has shifted from the right to the left, (the pushing-lever x₂ has risen above the prominence at 13 on 02) and assumes its usual position, (see above.) The first movement is accomplished; and the different parts are in the position of Fig. 288. The second movement begins. The point-bars are at rest. The front carriage-line goes up to the back comb, where the back carriage-line moves higher up. The shafts t and W make, respectively, one-twelfth and a quarter of rotation, and a pause ensues. Both carriage-lines are on the back comb. The front comb is pushed from the right to the left, the points 14 of o and O₂, being advanced to be- neath the points of the levers. The front half of the warp has shifted from the right to the left. The back half of the warp retains its usual position. The point-bars are at rest. The second movement is accomplished. The positions of the different parts represented in the figures, (with the exception of Figs. 288 and 289,) are corresponding to this moment. - The third movement begins. The front carriage-line l returns to the front comb. The front point-bar begins to leave its row of meshes. This curve from 9 to 10 of the lifting-thumb acts upon the pin of the fork. The shafts t make again one-twelfth of their rotation, and the pause ensues. The front carriage-line is on the front comb, and has moved from the left to the right. The back carriage-line is on the back comb. The front half of the warp has shifted from the left to the right, and is in its usual position, as is the back half also. The front point-bar is lifted almost entirely out of the meshes. The third movement is accomplished. The fourth movement begins. The back carriage-line goes up to the front comb. The front point-bar is lifted out. The shafts t make their fourth twelfth of the rotation, and the pause ensues. Both carriage-lines are on the front comb, and move from the right to the left. The front and back parts of the warp are in their usual position. The front point-bar is about to lower. The fourth movement is accomplished. The fifth movement begins. The back carriage-line returns to the back comb. The point-bar lowers. The fifth twelfth of the rotation of the shafts t is made, and the pause ensues. The back carriage-line is on the back comb. The front carriage-line is on the front comb, and has moved from the left to the right. The front half of the warp is in its usual position, and the back half has shifted from the left to the right. The fifth movement is accomplished. The sixth movement begins. The front carriage-line goes up to the back comb. The front point-bar is lowering, and six-twelfths or one-half of rotation of the shafts t ensues. Both carriage-lines are on the back comb. The interchange or traversing of the carriages is accomplished. The carriages have advanced to the right by one station. The front half of the warp is in its usual position. The back half of the warp has shifted from the right to the left. Digitized by Google BOBBINET MACHINERY. 125 The front point-bar has lowered. It is now exactly in the same position as the back point-bar was in the beginning of the first movement, (see Fig. 289,) and is nearly about to fall off. The sixth movement is accomplished, and therewith a row of meshes completed. These six movements constitute the first period of operations. The next, or second period, comprises almost the same movements, with the exception of the comb- shiftings, as will be perceived by the following explanation:- The seventh movement begins. The front carriage-line goes up to the front comb. The front point-bar falls off, and lifts the seized row of meshes. The shafts t make the seventh twelfth of their rotation. The front carriage-line is on the front comb, and the back one on the back comb. The front half of the warp has shifted from the right to the left; the back half is in its usual position. The front point-bar is lifted almost entirely. The seventh movement is accomplished. The eighth movement begins. The back carriage-line comes up to the front comb. The front point-bar is lifted. The shafts t make the eighth twelfth of their rotation. Both carriages are on the front comb. The front half of the warp having shifted from the left to the right, assumes its usual position. The back half of the warp retains its usual position. Both point-bars are at rest. The eighth movement is accomplished. The ninth movement begins. The back carriage-line goes up to the back comb. The back point-bar begins to leave the meshes, and nine-twelfths of rotation of the shafts t are made. The back carriage-line is on the back comb, and the front line on the front comb. The front half of the warp is in its usual position. The back half of the warp shifts from the left to the right. The back point-bar has nearly left the meshes. The ninth movement is accomplished. The tenth movement begins. The front carriage-line goes up to the back comb. The back point-bar is entirely taken out. The tenth twelfth of rotation of the shafts t ensues. Both carriage-lines are on the back comb. The front half of the warp shifts from the right to the left, and the back half shifts from the left to the right. The back point-bar is about to lower. The tenth movement is accomplished. The eleventh movement begins. The front carriage-line returns to the front comb. The back point-bar lowers, and the eleventh twelfth of rotation of the shafts t ensues. The front carriage-line is on the front comb. and the back line on the back comb. The front half of the warp shifts from the left to the right, and the back half retains its usual position. The back point-bar is near its deepest standing. The eleventh movement is accomplished. The twelfth movement begins. The back carriage-line goes up to the front comb. The back point-bar attains its deepest standing. The last twelfth or a total rotation of the shafts t is accomplished. Both carriage-lines are on the front comb. The front half of the warp is in its usual position, and the back half shifts from the left to the right. The back point-bar is in its deepest standing, and about to fall off. The twelfth movement is accomplished. A fresh row of meshes is completed, and is forthwith taken up by the back point-bar. With the twelfth movement the second period of operations is accomplished, and all is in the posi- tion of Fig. 289. Hereupon the same circulation of movements and functions of the different parts begins, and 80 on. The following table will serve to render the just-described periods of movements still more con- spicuous. The superscriptions of the columns will prove to be sufficient to explain the signification of the letters; and it may only be remarked, that A signifies the front carriage-line, and B the back car- riage-line. Each column contains two lines, filled either with points or letters, thus indicating the mutual position of the concerning threads and carriages after every lateral movement. The asterisks (*) in the column superseribed " Front comb," serve to direct the attention on the shifting of the comb. Digitized by Google 126 BOBBINET MACHINERY. TABLE of the Periods of Movements. First Period of Movements. Front half Back half Movements. Front comb. of the of the Back comb. Movement of the point-bar. warp. warp. End of the 12th or beginning The back point-bar is about to of the 1st B a b fall off. End of the 1st or beginning b The back point-bar has taken up of the 2d B the row of meshes. End of the 2d or beginning a b of the 3d B Both point-bars at rest. End of the 3d or beginning b The front point-bar is lifted ot , of the 4th a B of the meshes. End of the 4th or beginning B b The front point-bar is about to of the 5th a lower. End of the 5th or beginning The front point-bar is lowering of the 6th b B deeper. End of the 6th or beginning b The front point-bar has lowered of the 7th B deepest and is about to fall off. Second Period of Movements. End of the 7th or beginning a b The front point-bar has lifted the of the 8th B row of meshes. End of the 8th or beginning b of the 9th B Both point-bars at rest. End of the 9th or beginning The back point-bar is lifted out of the 10th a b B of the meshes. End of the 10th or beginning a b The back point-bar is about to of the 11th B lower. End of the 11th or beginning b The back point-bar lowers of the 12th B deeper. End of the 12th or beginning The back point-bar is about to of the 1st A B b fall off. A comparison of this detailed statement, with the illustration given in Fig. 360, will afford a still clearer view of the intertwisting and crossing of the warp and weft or carriage-threads. In Fig. 360 the warp-threads are marked with f. They proceed downwards in serpentine lines, and receive their contorsion from the tension of the weft-threads twisted obliquely round them alternately to the right and the left hand. Before this union, and beneath the point-bars, the warp-threads are tentered vertically. So that the front half of the warp may be better distinguished from the back half, the threads of the former are hatched. The front carriage-threads are marked with k, and the back threads with k₁. The figure shows the texture on a very large scale. The web consists of nine warp and nine weft threads. Five threads belong to the back half of the warp, and four threads to the front half. Each (horizontally directed) row of meshes contains four holes or meshes. The hatched circles within the meshes represent the points of the two point-bars, and are marked with M and N. Description of an eight-quarters stripe machine.-Machines of this kind furnish bobbinet stripes or quillings, forming one broad piece during the fabrication, but which afterwards are separated from each other. As these quillings or edgings, for the sake of beauty and solidity, must be, as it were, without a seam, this manufacturing requires a particular contrivance in the bobbinet machines. The above-described double-locker machine may easily be arranged for manufacturing quillings; and the most practical and suitable contrivances for this purpose are those invented by Mr. Croft. In Fig. 369 are represented two stripes of equal breadth, and united in such manner as they appear in the whole piece on the lace-beam. The borders or selvages are hatched and marked with fs and for Digitized by Google BOBBINET MACHINERY. 127 The connecting thread, running in zigzag from one mesh to the other, is marked with k₂, and the other warp and carriage threads respectively with f and kk₁. Each stripe being a plain narrow lace in itself, and the carriage-threads proceeding in their slanting directions, separately in the one and in the other, of course a contrivance is required in order that the carriages may turn back at the two inner selvages as well as at the two outer ones. This and all other required arrangements are illustrated by Figs. 361 to 394. Fig. 378 represents a double-locker stripe machine in transverse section, in which latter Figs. 385, 386, 387, 388, and 889, are also given. The most essential parts of the machine are to be seen in Fig. 378. Beginning from below, there will be perceived two warp-beams, G and G, Round the larger one is wound the warp for the plain texture, and round the other are twisted the commonly somewhat stronger selvages fs and for In case the latter should be of equal thickness as the other warp-threads, one beam would be sufficient. The warp-threads are to be drawn through the kind of reed F, and thence through the series of guides c and d, which are fastened to the guide-bars a and b. The selvage-threads are only laid over the wooden framing-staves of the reed F, (see Fig. 878,) and then (on account of their peculiar lateral movement) drawn through particular iron or brass ears, (one of which is represented by Figs. 391 and 392,) called selvage-guides, which are fastened to the guide-bars as and b. The selvage guide-bars are provided with similar sockets, supports, adjusting screws, levers, and springs, as a and b. The warp is not divided into two equal parts as in the machine described above, but is drawn through the front and back guides c and d unequally divided, and this in such a manner, that in the front warp. half one, and in back half two, warp-threads are omitted at every border of the stripe. The corre- sponding guides, in the series of guides, are broken off as superfluous. The selvage-threads, on the other hand, are equally divided, drawn through the series of guides cs and d₃, yet those marked with fo (see Fig. 369) exclusively through the front, and those marked with fs through the back series. Between the combs L and L₁ all warp and selvage threads are drawn up in two rows, and led to the points n of the point-bars M and N, beneath which the texture is formed, after which it proceeds to the lace-beam. The comb and the lockers, and locker-bars p and q, are set up in the usual manner. The carriages are likewise put in with two lines, odd carriage, etc., as has been described above. Yet in the back line, right opposite to the selvage-threads, there are also the turn-again and whipping carriages, briefly called whipper-carriages, with the thick and strong connecting threads kg, (see Fig. 309.) The whipper-carriages make upon the whole the same movements as the other carriages, with the only difference that they do not shift their places, but are running to and fro in the same bolts. During the shifting, they remain in the back comb, while the other carriages change their places in each stripè-section. Before their peculiar movement, (illustrated by the figures from 378 to 382,) during the shifting, can be explained, some parts and contrivances connected with it must be viewed. Close beneath the locker-bars p are parallel with them the so-called picker-bars, to which the pickers p, are fastened by screws. The picker-bars have exactly such sockets and supports as the locker-bara. At the one end is fixed a short arm e₁, moved by the drawer-bar o, by which the picker-bar, with the pickers, can be put in a slight angular movement. The pickers, made of stiff hammered iron or brass, Figs. 392 and 393, are performing here the func- tions of the locker blades in the above-described machine, as they, like them, seize the heels or catches of the carriages and push the latter onward, or respectively set them in their places. They, more- over, serve to regulate the movements of the whipper-carriages, and are to be advanced as far as possible towards the midst, yet in such manner that they may not impede the series of guides in their lateral movements. To retain the whipper-carriages on the back bolt-bar, the back pusher-bar E1 must be placed by a particular contrivance, which is illustrated by Figs. 378 and 381, and especially by Figs. 885 and 389. The pusher-bar E1, made of strong iron or spring steel plates, is at its long outsides strengthened by a rib of wrought-iron and provided with a pivot, by means of which the bar is placed in the sockets of the cradle-pieces I₁ in Figs. 284, 285, 286, etc. The bar has narrow but deep notches, intended to receive the whipper-carriages while the other carriages are shifting their places; but as soon as this shifting is accomplished, the whipper-carriages are let out, and the notches are closed by the covers d₄, which are fixed to the guide-bar ga, and represented in Figs. 388 and 389. The covers are made of thin iron plate. The guide-bar I' is, by means of iron pieces en fixed to the above-mentioned rib in such manner that it is easily to be moved sidewise, and keeps the covers close upon the notches. The bar is con- stantly attracted or drawn by a small but sufficiently strong spiral spring, fixed with its end to the pusher-bar E₁. The iron pieces e₂ and the slits of the guide-bar Is, are squared thus, that the covers are exactly upon the notches as long as the spring is acting. Fig. 385 represents this movement The uncovering of the notches is effected by a lateral movement of the guide-bar g, to the right, and this movement is brought on by the action of a lever on the pivot or tenon a, at the bar. Figs. 390 (giving a side view) and 391 (horizontal section close above the comb) serve to illustrate this movement. K is the front bolt, which, in the moment of the shifting, moves from the right to the left with the comb L At its lower edge is applied the trigger hs which grasps the short one of the two arms of the lever F, The turning takes place on the pivot 8₂ fixed at a suitable place in the frame. The long lever-arm, bent exactly in conformity with the curve of the comb, and placed in such manner that it is tight beneath the bar E₁, lies close to the left side of the tenon a. Thus as soon as the bolt-bar K is moving to the left, the long arm of the lever F,, moving to the right, presses against the tenon a,, overcomes the power of the spiral spring, pushes the guide-bar g₃ to the right, and opens the notches of the pusher-bar. Digitized by Google 128 BOBBINET MACHINERY. The notches must be kept open until the shifting is accomplished. But the bolt-bar turning again from the left to the right, after the first quarter of the shifting movement, and, consequently, the long arm of the lever F, making the inverse movement, the covers would close the notches again and bring about confusion, if there had not been made a contrivance for preventing it. The chief instrument of this contrivance is the parrying-ledge h₄, screwed on the back bolt-bar. Its position relative to the lever F, and the tenon a, is shown by the Figs. 390 and 391. The tenon a, leans against the parrying- ledge as soon as it is pressed by the lever F2, and does not give way until the shifting is accomplished. The positions of the tenon a+ marked with dotted points in Figs. 390 and 391, will sufficiently illustrate this statement. We shall now take a view of the peculiar movements of the whipper-carriages in the moment of the shifting. Fig. 378 represents the concurring parts in the movement when the shifting of the front comb begins. Both carriage lines are on the back comb. In the next movement the comb makes its lateral movement; the lever F, acts upon a+ and the notches of the pusher-bar E, are opened. Simultaneously the back pickers are, by the angular move- ment of the picker-bars, moved upwards. They now seize the shifted carriages at their beels or catches and push them onward, see Fig. 379, while the other carriages remain at their places, and the whipper- carriages (marked with k₂) pass into the notches of the pusher-bar E1. Now the movement of the pusher-bar and locker begins; E, pushing onward those carriages, which are not retained by the pickers, and the back locker lowering. As soon as the outer locker-blade is within the back heels of the retained carriages, the pickers move downwards, the just-mentioned carriages are seized by the outer blade of the back locker, and the carriage-movement ensues in the usual manner. The front locker draws the carriages, pushed to it by the pusher-bar E1, up to the front comb, where, opposite to each whipper-carriage, one common carriage is lacking, (which may appear a matter of course by the above given statement,) and is instead of this in the back line of it. The back carriage-line on the back comb is complete, and has behind itself the line of the whipper-carriages which had been retained in the notches of the pusher-bar E1. (See Fig. 380.) The comb moves back; the carriage-movement ensues; the back pusher-bar causes all carriages, without any exception, to move onward; the back locker falls off and the front locker seizes the carriages presented to it and draws them up to the front comb. But just before the front locker seizes the heels of the carriages, the back pickers move upwards again, and consequently retain the whipper- carriages on the back comb. Meanwhile the other carriages have been drawn up to the front comb, where now two lines are, of which the inner one is complete, while in the outer one as many carriages are lacking as there are whipper-carriages on the opposite side. The position of the concurring parts in this movement is represented by Fig. 381. The back pickers are thus, in this period of movements, performing the function of the back locker, which (as is shown by Fig. 381) has completely turned round, and cannot, for this reason, retain the whipper-carriages. As soon as now the front comb has moved again from the right to the left, the front pickers spring up, and, seizing the (not in pairs) standing carriages on the front comb at their heels, press them upwards until their back heels or catches are beyond the outer blade of the front locker. (See Fig. 382.) The back pickers remain in their position represented by Fig. 381. Then the usual carriage-movement begins, and before the front comb moves from the left to the right, the front as well as the back pickers fall off. The comb-shifting ensues, and now both carriage-lines on the front and on the back comb are complete. The interchange or traversing of the carriages throughout the whole width of each texture- stripe has occurred, and the movement of the carriages of the complete lines continues in the usual manner until the shifting takes place anew. This shifting, i. e,, the interchange or traversing of the carriages in the texture-stripes, is indeed not easily to be understood; however, the following statement will prove adapted to render the matter pretty clear. The common carriages are marked with a, b, c, d, e, f, g, h, k, and the whipper-carriages with kg; their number is in conformity to the pattern in Fig. 369. The position of the carriages and combs is, according to Fig. 378, the following: k, back comb. First Position after the first shifting of the front comb. Commencement. front comb. The big points represent the concurring places for the carriages. As soon as the carriages are on the front comb, their position is the following: kg back comb. First Position. End. front comb. Digitized by Google BOBBINET MACHINERY. 129 After the comb's lateral movement to the right, the carriages stand thus: k₃ k₃ abedeabed } back coml. Second Position. - Beginning. k h g f khgf } front comb. This 1- saition corresponds to Fig. 380; yet as soon as the back carriage-lines have passed the front comb, the position is the following: kg kg } back comb. Second Position. - End. abed abcde khgf } front comb. khgf The comb moves to the left, and now the carriages stand thus: k₃ k₃ } back comb. Third Position. - Beginning. a b c d e 3 c d e } front comb. k h f k h g f This position corresponds to Fig. 381. The carriages move up to the back comb, and their position is now the following: } back comb. bcdekbedek Third Position. - End. akhgfakhgf } front comb. The comb moves back, and the shifting of the carriages is now accomplished; for the position is thus: bcdekbcdek } back comb. Fourth Position. a khgfakhgf } front comb. &c, &c., &c. This statement shows at the same time clearly, that all carriages, as for instance, e in the first posi- tion, or as after the shifting f in the fourth position, which are with the whipper-carriages in one and the same bolt, are doing the business of whipper-carriages. At the ends of the carriage-lines no whipper-carriages nor pickers are required, because the hold- fast contrivance, applied here, together with the notches of the lockers, supply the action of the pickers. The above explained interchange or traversing of the carriages is rendered necessary by the men- tioned order of the warp-threads, and that the stripes of the texture may be provided with seams. In manufacturing plain broad pieces, the front half of the warp containing one thread less than the back half, there must be in a pattern like that of Fig. 369, four front and five back warp-threads in each stripe. Further, the borders or selvages of plain broad pieces being made of the end- threads of the back warp-threads, consequently the seam-threads of the stripes must likewise be contained in the back half of the warp. But as here, on account of the connecting thread, (running in zigzag,) the left seam-thread of a stripe must alternately pass over two bolts, these threads are to be drawn through particular guides adapted for this movement. 17 Digitized by Google 130 BOBBINET MACHINERY. The lateral movements of the guide-bars are in the usual manner prepared by ratchet-wheels, levers and angular pieces, or swing-bars. But for effecting the just-mentioned movement for the particular guiding of the seam-threads, the stripe-machine must be provided with two ratchet-wheels more, which are fastened at the axis t, to the right of the machine. Besides these, there are required two other ratchet-wheels for the movement of the pickers, which are fastened at the same axis within the dented wheels t₁ and t₂ (See Fig. 286.) Sometimes the last-named wheels are arranged for this pur- pose in the manner illustrated by 81 in Fig. 390. The figures from 370 to 377 represent all ratchet-wheels of the double-locker stripe-machine. The directions of the arrows indicate those of the movements. The various acting points in the twelve different movements of the concurring parts are marked with ciphers. Equal marked points are simul- taneously acting. Point 1 corresponds to the acting point indicated by Fig. 378. Fig. 370 represents the right ratchet-wheel for the lateral movement of the comb; Fig. 371 the left one of this description; Fig. 372 the front ratchet-wheel for the warp-threads, and Fig. 374 the back ratchet-wheel for the same purpose. (These four wheels, already known by the description and illus- trations of the broad plain bobbinet machine, are delineated here once more, in order to facilitate the view of the whole.) Fig. 373 represents the front ratchet-wheel for the seam-threads; Fig. 375 the back ratchet-wheel for the same purpose; Fig. 376 the back ratchet-wheel for the pickers, and Fig. 377 the front one of this description. Following in the order of numbers the indentments of the ratchet-whecls, it becomes apparent that during the twelve different movements of the two principal movement-periods, (in which two rows of meshes are completed,) the shiftings of the warp-threads occur simultaneously, and in a successive order. Still more perspicuous the simultaneous operations of the ratchet-wheels will appear by sup- posing their peripheries to be stretched out into a straight line, as has been done in the following sketch. By the lateral shiftings of the warp-threads, and by the interchange or traversing of the carriages, the formation of the web is effected; and all the intertwistings and decussations of the threads follow each other in the same order, as has been sufficiently explained above. The connection of the seam- threads with the connecting thread his, (Fig. 369,) is not brought on by perhaps a lateral movement of the latter, but only by the lateral movements of the seam-threads. Thus the intertwisting of ks and f (in the midst of the figure) is effected by a single shifting of the latter towards the former thread, (ex plained by Fig. 373,) while the intertwisting of the left seam-thread fo is effected by its double-shifting (See Fig. 375.) The positions of the warp-threads towards each other and towards the carriages in the two principal movement-periods, are exposed in the following statement. In this a, b, c, d, e, f, g, h, k signify the common carriages, k₂ the whipper-carriages; the asterisks (*) signify the back seam-threads; the simple crosses (+) the front seam-threads; the large points (.) the common front and back warp- threads; and the vertical dashes (1) the void places for the carriages. The statement corresponds to the texture of Fig. 369. First Movement. Acting point 12. b d k₁ a b c d his back comb. back seam-threads. back warp-threads. front warp-threads. + + front seam-threads. g g front comb. Second Movement. Acting point 1. (Position as in Fig. 378.) b c h₃ a b c his back comb, h: 1, g lc 1 g back seam-threads, warp-threads, Shifting. + + front seam-threads, front comb, Third Movement. Acting pc: it 2. k₃ k₃ b d b c d back comb, back seam-threads, warp-threads, Shifting. + + front seam-threads, h front comb, Digitized by Google BOBBINET MACHINERY. 131 Fourth Movement. Acting point 8. kg h₃ back comb, back seam-threads, warp-threads, Shifting. + + front seam-threads, e d a h g k 1a front comb, g Fifth Movement. Acting point 4. b c kg b c d k₃ back comb, c back seam-threads, warp-threads, Shifting. + + front seam-threads, a g k h g front comb, Sixth Movement. Acting point 5. b c kg b c d e k₃ a k h g k back comb. h g back seam-threads. warp-threads. + + front seam-threads. ~ front comb. Now the first principal movement-period is finished, and one row of meshes is completed. The point-bars take up the completed row. Seventh Movement. Acting point 6. b k₃ b c d k₃ back comb. back seam-threads. + + g h g front comb. Eighth Movement. Acting point 7. back comb. * back seam-threads. warp-threads. + + front seam-threads. b k₃ b d e h₃ h front comb. g h g Ninth Movement. Acting point 8. b d kg b c d e ~ back comb. k₃ back seam-threads, warp-threads. + + front seam-threads. g k h g front comb. Digitized by Google 132 BOBBINET MACHINERY. Tenth Movement. Acting point 9. b kg b c d c k₃ back comb. I h h g back seam-threads. warp-threads. + + front seam-threada. front comb. Eleventh Movement. Acting point 10. b d back COL b. his c kg back seam-threads. warp-threads. + + front seam-threads. a h g front comb. Twelfth Movement. Acting point 11. back comb. back seam-threads. warp-threads. + + front seam-threads. b c kg k₂ back comb. a h g h g Now the second principal movement-period has finished, a fresh row of meshes is completed, and forth- with taken up by the back point-bar, and in this manner the cycle of movements is continuing. The points of the point-bars take up the completed meshes in the usual manner, only two points in the midst are somewhat bent sidewise to give room for the connecting thread. (See Fig. 394.) The breadth of the stripes is commonly fixed in conformity with numbers which coincide with the number of meshes running diagonally. Thus, for instance, the stripes in Fig. 369 would be marked with No. 8. Figured bobbinet (or design bobbinet) is manufactured in three different ways :- The common plain bobbinet is interwoven with embroidering or twisting threads. This inter- weaving can be done at single spots, as well as in continued lines. The first manner produces points or spots regulated by groups and figures of various descriptions; and the second manner produces orna- mental stripes either in serpentine lines, or in zigzag, or otherwise arranged. The ornamental or embroidering threads consist usually of thick or colored yarn, in order that the pattern may have a better relief. Machines for manufacturing bobbinet of this description, are: Sneath's improved single-locker ma- chine; Heathcoate's patent machine; Summer's lever machine; Sewell's roller machine; Draper's ma- chine, and White's improved machine.-The arrangements of these machines are very different, and it would lead us too far, to give any description whatever of them here. Heathcoate's machine is connected with a so-called tatting machine, by which the interweaving of ornamental threads is performed. The simple intertwisting of threads in the plain bobbinet is altered in such manner, that at certain points of the web. larger holes or meshes are made, surrounded by common smaller ones. Some pat- terns of this description are called grecian net, the honey-comb open work, and the roseau tull. The manufacturing of these webs requires, of course, more or less complicated arrangements in the machinery. Their chief peculiarity is, that the warp is to be divided in more than two parts, which have their lateral movements independent of each other. Frequently the movement of the carriages is in certain movement-periods somewhat altered too, similar to the case of the stripe-machine, which may indeed be considered as producing figured or design bobbinet, if the zigzag connection be regarded as a figure. The arrangements of the first and second systems are combined, by which we obtain patterns with larger, and meshes with ornamental threads. Draper's machine is partly adapted to them. Upon the whole, the machinery is very complicated; and for this reason, almost everywhere the lever and single- locker systems are applied, because machines of this description can be more conveniently arranged and altered than double-locker machines. BOILER PLATES, Machine for punching. Fig. 395 is an elevation, Fig. 396 a plan, and Fig. 397 a side view of a punching-machine on a very improved principle, whereby the plates required for boilers Digitized by Google BOILER PLATES. 133 and other purposes may be punched with the greatest possible accuracy, insuring at the same time very superior workmanship and great dispatch. It is usual in all ordinary punching-machines, first of all to mark out the rivet-holes in the plate, by a template, with white paint, and then to place it as near as the eye will permit under the punch; by the contrivance of this machine, this operation is entirely dispensed with, it being only necessary to fix the plate to a travelling table, and then to adjust the various parts of the machine to the proper distance required between the rivets. The large cast-iron frame P carries the several parts of the machinery, and also the two plummer- blocks for supporting the bearings of the lying shaft a, running the whole length of the building, for the purpose of working other machines; this frame is securely bolted to the wall, which, added to its own weight. gives it great stability. On the shafts a, connected together by the two coupling-boxes, is placed the crank b, the motion being communicated through the crank-pin to a connecting-rod c, to which is attached the upper lever d, being always at work, while the shaft a is revolving; the fulcrum of this lever is on the frame p. A lower lever e for raising and depressing the punching frame f has also its fulcrum on the same frame; this last lever working only when the punching operation is being performed. On the top of the frame P is a lever and long rods e' for engaging and disengaging the machinery. The side view epre- sented by Fig. 397, shows the machine at work, and by drawing down the lever e', connected by the rods to the counterbalance weight, which will allow it to remain steady in any position, they are disengaged from the pin on the lever d, which at once ceases to communicate the motion to the lower or punching lever e; thus it will easily be understood that those parts of the machine constantly at work, are the lying shaft a, the crank b, the connecting-rod c, and the upper lever d. The slide f for carrying the punches, works between V's, Fig. 396; one is fixed to the frame p by adjusting-screws, both on its face and sides, and by the curious shape given to the end of the lever e, this slide is made to rise and fall, the counterbalance weight and lever g being connected by two short links; on the bottom of the slide is screwed a small frame for carrying the punches, which may be taken out and replaced by others. The dies i, in which the punches work, are placed in a frame bolted to the frame p, and by unscrewing the small adjusting-screws, these may be taken out and replaced by others suitable to the different-sized punches that may be required. On the under side of the frame p is screwed a small stop, by which the circle punched from the plate is forced out as the slide rises. In the front of the machine is placed a long table, supported by the carriages o, consisting of two columns and diagonal frame, having bolted to them two long bars, upon which the moveable table is made to slide; this table, as will be seen by Fig. 396, has a number of holes by which the plate to be punched is secured by clamps; it is advanced by the rope or chain n passing under the pulley, Figs. 395 and 396, and over a second one hung from the ceiling of the building, to which is connected a weight sufficiently heavy to draw forward the table and plate fixed to it; after travelling the length of the table o, it may be brought back by turning the winch-handle and spindle l, on which is a pinion for working the rack, fixed to the under side of the moveable table m. By a very ingenious contrivance, forming part of this machine, the rivet-holes of boilers may be punched to very different pitches, a thing very much wanted in such cases as the repairing of old boilers, or replacing an old plate by a new one, where it is of the utmost importance to have the rivet-holes coinciding with the greatest accuracy, which may be better understood by supposing that in the length of a plate, one, two, or three additional rivet-holes may be required, which distance would have to be equally divided in the whole length of the plate. A description of this part of the machine will fully show how this operation is performed. On the end of the punching-lever e is screwed a small plate with a pin j', adjustable by a screw working in the short mortise, Fig. 397 on the frame p is bolted a fulcrum piece for the lever and counterbalance weight j to this lever a long rod is connected at its lower end, passing under the table in, and the lever r is fixed to it, as will be seen by the dotted lines in Fig. 396; it has also two stops or projecting pieces r' r' on its surface. A second lever 8 has its fulcrum fixed to the table o, one end of this lever being connected to the lever r, while the opposite end has on its surface two small pins 8' 8'; the fulcrum 8" of this lever is adjustable by the two small screws shown in the plan, Fig. 396. A long notched bar k is fixed to the under side of the table m by screws, and the bar t has its fulcrum t' also fixed to it; this latter bar t is moveable on its centre, and may be placed at any angle by an adjusting-screw working in a mortise t", where it may be fixed in any required position, as will be seen; it is by the angle given to this bar, that the regular increase of distance is obtained between the rivets. This is effected in the following manner :-As the lever c works on its centre, the pin j' to which it is fixed, strikes as it descends on the end of the lever j; its motion is then communicated to the long rod, passing under the table, for working the lever r back- wards and forwards, it being fixed to the rod; as the latter lever moves, it alternately engages and disengages the stop or projecting pieces r' qu' from the notched bar, allowing it at the same time to slide forward the distance between the rivets; while the bar t placed at the required angle, and working between the pins s' 8' on the lever 8, immediately effects the distance travelled by the lever r, which it shortens; by this arrangement the machine is made quite self-acting, but it may also be worked by the handle on the end of the rod j. When it is required to change the punches 1. for different-sized holes, it is necessary, when replaced, to adjust them to the greatest possible accuracy in the dies i; this could not be done without stopping the whole line of shaft a, were it not for a provision made for that purpose; in such a case, the key in the upper part of the connecting-rod c is withdrawn, a block of wood is then placed between the frame and the lever d, whose fulcrum is on the side of the frame p, upon which it rests. It is of course under- stood that the punching-lever d is at rest, being disengaged from the pin é; the result of this is the working of the long mortise of the connecting-rod up and down on the pin, without communicating any inotion whatever; and by the lever q, worked gently by hand, and shown dotted in Figs. 396 and 397, the punching-lever e can be raised and lowered, communicating its alternate motion to the slide-frame, by which means the punches are with great facility adjusted in the dies i. Digitized by Google 134 BOILER PLATES. a Shaft running through building. b Crank. c Connecting-rod. d Upper lever worked by connecting- 395. rod c. B Lower or punching lever engaged or disengaged by means of rods, levers, and pin é. Punching-frame raised or depressed I 9 by lever a and counterbalance weight g. Lever and counterbalance weight. Punches. e i Die-frame. j Self-acting rods, levers, and counter- balance weight, for engaging and disengaging notched bar from 0 7 stops r' r', worked by pin j. m k Notched bar fixed to table and stopped by projecting stops k alternately on either side for each rivet. I Handle, pinion, and rack, for ad- vancing table by hand. Moveable table for carrying plate to be punched, drawn along by rope or chain running over put ley R. Fixed tables supported by columns. P Frame for carrying machinery. 396. q Lever for raising punching-lever when the punch is required to be changed without stopping the length of shaft. the n m m 8 l 397. 6 a j Selfacting rods, levers, and counterbalance a Shaft running through building. b Crank. weight, for engaging and disengaging c Connecting-rod. J notched bar from stops r' r', worked by pin d Upper lever worked by connecting-rod c. k Notched bar fixed to table and stopped by e Lower or punching lever engaged or disen- projecting stops k alternately on either gaged by means of rods, levers, and pin é. side for each rivet. f Punching-frame raised or depressed by lever 21 / Handle, pinion, and rack, for advancing e, and counterbalance weight g. table by hand. Lever and counterbalance weight. m Moveable table for carrying plate to be h Punches & Die-frame. punched, drawn along by rope or chain running over pulley n. 0 0 o q 1 m m 0-0 n K 0 21 7 of 5 3 9.1 A E 0 n Rope and pulley for drawing along changed without stopping the a moveable centre at s". table m. length of shaft. t Bar for regulating the pitch of rivet- Fixed table supported by columns. Lever fixed at one end to rod j; on holes, working between pins s' s'; P Frame for carrying machinery. this lever is fixed two small pro- it has a fixed centre at i. and 9 Lever for raising punching-lever jecting pieces r'r'. may be placed at any angle by when the punch is required to be Lever with two guide-pins having sliding in groove t". Digitized by Google BOILERS. 135 The jaws in the frame p are much strengthened by placing a square wrought-iron bar between them, in places provided for the purpose. From the above description, it will be seen that the advantages possessed by this machine, more than compensate for the increased number of its parts, which are but few when compared with its superiority over those of ordinary construction. BOILERS. Varieties of, and circumstances attending their use and construction. Before proceeding to give tabulated computations of the fire and flue surface of boilers, the per- formance of the different varieties with respect to consumption of fuel, and such other particulars rel- ative to their performance as will be a guide to the engineer, and show forth the best methods of construction, we think it expedient to give drawings of some of the boilers of which these particulars are to be determined, both to render our tabulated results clearer than they could otherwise be, and to furnish the engineer with examples to avoid or imitate. These delineations are all made to a scale, and on the more important of them the sizes are also marked; so that these wood-cuts may serve all the purposes of working drawings-half an inch either in excess or defect in the length of a boiler being a thing of no importance. Subjoined are given two scales, the one or the other of which is No. 1. Scale 3 inches = 11 feet. No. 2. Scale 3 inches = 16 feet. applicable to such of the boilers rep=ented as are not measurable by any of the scales in common use. A notification will be given of each case in which either of these scales is to be applied. Fig. 398 is 3 transverse section of a 30-horse power wagon boiler of the kind employed by Messrs. Boulton and Watt. This boiler will serve as a type of its class. We shall hereafter give the length, breadth, height, and surface for the different powers Figs. 399 and 400 represent a land boiler of a very good description constructed by Messrs. Caird & Co. for a blast-engine of small size. This kind of boiler is common enough; but it has generally only one tube for conducting the smoke through the boiler, instead of the number here represented. Figs. 401 and 402 represent the boiler introduced by Messrs. Caird & Co. into some iron tug-boats made by them. Cylinder, 32 inches in diameter-length of stroke, 3 ft. 6 inches. We shall not, in general, append the size of the engines or the number of the boilers to the drawings, as all this information will be given in a more commodious form in our tables. 398. 399. 400. SCALE.-1-20th inch = 1 foot. SCALE.-1-20th in. = 1 foot. Longitudinal Section. Transverse Section. 401. 402. 10 2 50 SCALE.-1-12th inch = 1 foot. Transverse Section. Figs. 403, 404, 405, and 406 are different views of the boilers of the steamer Phoenix, a steamer con- structed by Messrs. Scott, Sinclair, & Co., for plying between Cape Town and Algoa Bay, at the Cape of Good Hope. This vessel was provided with collecting vessels within the boiler for obviating the deposition of scale; an expedient of much efficacy, and of which at the right place we shall furnish our readers with full information. Digitized by Google 136 BOILERS. 405. 404. 403. : SCALE.-1-16th inch = 1 foot. SCALE.-1-16th inch = 1 foot. SCALE.-1-16th inch = 1 foot. 407. 406. 200 30 210 SCALE.-1-16th inch = 1 foot. SCALE.-1-16th inch = 1 foot. Longitudinal Section. Elevation and Transverse Section. Figs. 407, 408, and 409 represent the boilers of the Achilles steamer, constructed by Messrs. Caird & Co. This vessel plies between Liverpool and Glasgow, and is well known for her numerous excel- lencies. 409. 10 10" " 408. 60 20 SCALE.-1-16th inch = 1 foot. SCALE.-1-16th inch= 1 foot. Longitudinal Section and Exterior. Horizontal Sections and Bird's-Eye View. Fig. 410 represents the boilers of the sister ship, the Eagle, also by the same makers. There is nothing of peculiar excellence in these plans; and, for steam vessels, we believe boilers of this kind will be superseded by the tubular plan of boiler, of which we shall give all the best specimens. But a good number of boilers upon the common flue plan are still made, so that some specimens of them are indispensable; and, indeed, there are still far more flue-boilers in use than there are of any other de- scription. In most of these boilers it is a fault that the furnaces are made too long and narrow, and the consequence is, that it is impossible to fire them on a long sea-voyage, especially in stormy weather. It is much preferable to restrict the furnaces to a moderate length, and give the bars a considerable clevation, so that they may always be well covered with coal at the after ends. When the furnaces are very long, a good deal of air generally escapes into the flues at the after end of the bars, the effect of which is materially to lessen the generation of steam. Figs. 411, 412, and 413 represent the boilers of the Thames and Medway, two vessels of large size, constructed by Messrs. Maudslay & Field for the Mail Steam Packet Company. The boilers of these vessels have been very successful, and are among the best specimens of the flue-boiler as applicable to Digitized by Google BOILERS. 137 410. marine engines hitherto produced. We do not know 411. of any boiler of this kind that engineers may imi- tate with greater safety, ás regards their power of generating steam, though there are many speci- mens distinguished by a greater durability. In some of the boilers recently introduced in the Mail Steamers, the furnaces stand athwartships, and the plan is attended with the material advantage that the coals trim more easily; for the coal reserve in this arrangement situated behind the boilers, and Scate.-3-20th inch 2 fect.-Elevation and Horizontal Section. another depot standing between the boilers and the t engines, communicate immediately with the stoke- holes, whereby an easy transfer of the coal becomes accomplishable. Figs. 414 and 415 are also views of the boilers of Horizontal Section through the Thames and Medway, These views are per- Flues. pendicular sections through the lines A B and C D, shown in the horizontal section through the furnaces, 412. and the horizontal section through the flues. The dotted sweeps at the two upper corners represent the ascent of the flue into the funnel. The flue narrows in width and rises in height as it approaches the chimney, for the same area is not required for the transmission of the smoke after its volume has been contracted by the communication of heat to the water, and a less depth of water above the flue suffices after the heat of the smoke traversing it has been well-nigh expended. The bridges are water bridges, and their superior ridges do not run in a horizontal, but in an oblique direction, the design of which is to facilitate the extrication of the steam. There are four boilers in all, and the Horizontal Section through boilers are fired from both ends. Furnaces. In furnaces with two lengths of furnace-bars, it is a good plan to make the centre-bearer double, so that the ends of the bars may have a space between them through which the ashes will be precipi- tated; the space thus left enables the bars to expand without injury on the application of heat, whereas, without some such provision, the bars are very liable to get burned out by their centres bending up into the furnace, or else the lugs which carry the bearer-bars will be perpetually being carried away. A similar space should be left between the fore end of the bars and the dead plate at the furnace mouth, and care should be taken that not only the ends of the bars do not touch, but that the heels of the bars do not rest against the furnace-bearers. 513. 514. 415. Longitudinal Section. Scals.-1-8th inch = 1 foot. SCALE.-1-8th inch = 1 foot. Section through A B. Section through CD. The bridges of these boilers are, it will be observed, of brick, and come tolerably close to the fur- nace top. In such cases it is expedient to make the upper part of the bridge consist of one or two fire- brick blocks, which may be lifted off when a person requires to enter the flues to sweep or repair them. The continual knocking down and building up of bridges becomes otherwise very expensive. In boilers of this construction it is difficult to light one tier of fires after the others have been thoroughly kindled, as the fires first lighted keep the lead in the draught. It might be anticipated that by firing the tiers of fires alternately, the smoke would be burned, but such is not found to be the effect. 18 Digitized by Google 138 BOILERS. Provision has been made in these boilers for the introduction of a fan-blast, which would at once cure the evil of a defective draught. The furnaces would, in this plan, be made close, and the blast would be introduced into a chamber at the back of the ashpit A, Fig. 418, from whence it would pass into the ashpits by necks A A A, Fig. 416. One inconvenience, however, of a fan-blast thus applied is, that the smoke comes out of the furnace-doors very much when they are opened. Almost every engineer has made tubular boilers that were short of steam, but we never before met with one who acknowledged it. The original boilers of the Great Western contained of flue surface 2950 square feet, and of furnace surface 890 square feet, making 3840 square feet of heating surface; area of fire-grate 202 square (eet; capacity of steam-room 1150 cubic feet weight of boilers and steam-pipes 202 tons weight of water 80 tons; average consumption of coal 1000 tons per voyage, out and home, of 27 or 28 days. In the tubular boilers, Figs. 416 to 418, the tube surface is 5900 square feet, smoke-box surface 830 square feet; furnaces 420 square feet; making 7150 square feet of heating surface; area of fire-grate 145 square feet weight of boilers 56 tons; weight of water 52 tons capacity of steam-room 1320 cubic feet average consumption of coal per voyage out and home, of 29 days, 696 tons. The speed of the vessel, it will be observed, has somewhat declined with the new boilers, but there is a greater econ- omy in fuel upon the same distance. The horse power of the Great Western is about 400; the par- ticulars of the two boilers will therefore stand as follows :- Old Boiler. New Boiler. Heating surface per horse power 96 17875 Fire-grate per horse power 5 3625 Steam-room per horse power 2.875 33 Coal per hour per horse power 8-333 5.6 The consumption of fuel, as here set down, it must be borne in mind is that of the old beiler in its super- annuated state, and of the new boiler in its best state. The old boiler, when new, did not consume more than 6 lbs. of coal per horse power per hour. The tubes of these tubular boilers are of iron of 3 inches internal diameter, and 8 feet in length. The furnaces are 8 feet 3 inches in length, which is, in our judgment, a greater length than can be fired effectually on so long a voyage as the Great Western has to perform. The water within the boiler rises some distance above the top tubes. It would be better, we think, to let the return tubes go through the steam, which would dry it very effectually, and surcharge it in some degree with heat. This could easily be done by lowering the water-level, and the hot air will be sufficiently cooled, after passing through the lower tier of tubes, to prevent any injury to the upper tier from an excess of heat. One of the advantages of iron tubes is, that they can be subjected to a degree of heat, with impunity, that would be unsafe to apply in the case of brass tubes. It is said, however, that the scale adheres to them with greater tenacity than to brass, but this objection is not likely to prove of much weight if the boilers be well blown out, for in that case very little scale will be formed at all. Figs. 419 and 420 represent the boilers of the British Queen steamer, constructed to ply between London and New York. There is nothing very peculiar in this kind of boiler; and, indeed, it is nothing more than the common marine boiler, as used for the ordinary coasting vessels, constructed upon a larger scale. There are four boilers in the vessel, ranging athwartships, containing in all fourteen furnaces, the wing boilers containing four furnaces each, and the midship boilers three furnaces each. The pro- jection of the water-space into the flues at the after-end of the wing boiler is to obviate a back-draught in the furnaces, in cousequence of the currents of hot air meeting one another in a direct antagonism at the point where they coalesce, and which they would do but for this protuberance, which deflects each of them sufficiently to make it enter, without conflict, the longitudinal flue. These boilers were kept supplied with fresh water, as the engines are fitted with Hall's condensers, which return the condensed steam to the boiler to maintain the water-level This species of condenser is now discontinued in most vessels, as its weight and expense are formidable objections, and it does not act as a preservative of the iron of the boiler from corrosion. One government vessel, some time since, fitted with Hall's condenser, had no less than 22 miles of copper pipe for accomplishing the condensation of the steam. The use of salt water in boilers is attended with very little inconvenience if they be often blown out, and their durability is little, if at all, increased by the employment of fresh water. Figs. 421 and 422 represent the boilers of the City of London steamer, a vessel lately con- structed by Mr. Napier, of Glasgow, to ply between Aberdeen and London. These boilers are much upon the plan of the boilers of the Thames and Medway, and are fired from both ends instead of from one end, as in the boilers of the British Queen. There is a hanging water-bridge, it will be observed, at the end of the furnace, Fig. 421, beneath which the flame has to descend before it can enter the flues. This arrangement we look upon as very judicious. The hot air, by virtue of its specific levity, ascends into the upper part of the furnace-chamber, where it remains until it has given out a considerable por- tion of its heat, and it is only after its specific gravity has been increased by the extraction of heat that it can overflow into the flues. It is also a good practice to place a hanging bridge of sheet-iron at the after-end of the flue, where it enters the chimney. Figs. 423, 424, and 425, represent the original boilers of the steamer Tagus, constructed by Messrs. Scott, Sinclair & Co. The following are some of the dimensions of the original boilers :-Length 24 feet 3 inches, height 10 feet; breadth of each boiler 7 feet 6 inches, making the total breadth of the boilers about 22 feet 8 inches, with projections of rivet-heads. Length of under furnaces 8 feet; length of upper furnaces 7 feet 6 inches. Breadth of furnaces 3 feet; total number of turnaces 12. Each boiler contains 14 iron pipes of about 10 inches in diameter, and 10 feet in length, through which the smoke passes on its way to the chimney. These pipes are formed of boiler-plate, with turned rings or collars attached to each end, which are inserted into holes in the smoke-box plates, and then riveted over. These rivets are liable to get burned away by the action of the flame, as the collars within pre- Digitized by Google BOILERS. 139 416. : 417. 18 feet 6 inches. SCALE.-9-122th inch = ) foot. - 24 feet. - A-A-A- a. Horizontal Section through Furnaces. SCALE.-0-198th inch = 1 foot, b. Horizontal Section above Furnaces. Transverse Section. c. Horizontal Section above Tubes. 418. 420. 410 A a - 12 feet. SCALE.-9-128th inch = 1 foot. Longitudinal Section. 421. e Scale.--075 inch = 1 foot. Horizonal Section. Perpendicular Section. Longitudinal Section. 423. 422. 10 feet. 0000000 7 feet 6 in. 7 feet 6 in. SCALE.-075 inch = 1 foot. SCALE.-9-128th inch = I foot. Through Flues. Horizontal Section. Through Furnaces. Transverse Section. Elevation. Digitized by Google 140 BOILERS. vent the water from getting access to the angle, and the plates into which they are fixed then get pressed out by the force of the steam. It would be a good plan to cover these rivets with another perforated plate placed above them, the holes in which should be of a somewhat smaller diameter than that of the tubes. Figs. 426, 427, 428, and 429, represent a marine boiler with upright tubes, a kind of boiler to which we have already made several allusions, and which we are persuaded will, before long, come into ex- tensive use. This boiler, it will be remarked, has the water outside of the tubes, and the upper portion of the tubes does not pass through the water, but only through the steam, by which the steam is thor- oughly dried, and any inconvenience from priming counteracted. We have another specimen of this boiler to give, and shall reserve what we have to say about the plan until we come to it. Figs. 430, 431, 432, 433, 434, and 435, represent the boilers of the Queen steamer, a river vessel, con- structed by Messrs. Rennie, and well known for her swiftness and efficiency. The object this boiler 424. 425. 10 feet. 3ft. 3 ft. 2. 24 feet 3 inches. 24 feet 3 inches. SCALE.-9-198th inch = 1 foot. SCALE.-9-128th inch = 1 foot. Longitudinal Section. Horizontal Section. 426. 427. 428. 429. 60 Section through Ashpit, showing Section through Tubes. stays of bottom water space. 430. 431. 52 R SCALE.-1-8th inch = 1 foot. No. 1. E/ vation. Perpendicular Section. SCALE.-1-16th inch = 1 foot. Transverse Section. Elevation. 434. 435. 432. 433. SCALE.-1-16th inch = 1 foot. SCALE.-1-16th inch = 1 foot. Longitudinal Section. Elevation. Plan. Horizontal Section. seeks to attain is lightness, and it is therefore made so as to hold very little water. It does not, how- ever, appear to be well calculated to sustain any considerable pressure, though this is an object of im- portance in vessels intended to go fast. The following are some of the principal dimensions -Length 13' 8"; breadth 12' 8"; height 6' 0"; length of furnaces 5' 2"; length of tubes 5'7"; breadth of fur- naces 2' 8"; diameter of tubes 2' 6"; material of tubes brass. Total number of tubes 228. Diameter of cylinder of engines 29'3"; length of stroke 4' 6". There are two engines on the direct action plan. Collective power 76 horses. If any considerable pressure of steam he employed in this boiler, it will be necessary to stay down Digitized by Google BOILERS. 141 the boiler-top very firmly, both to the tops of the furnaces and the bottom of the boiler; for the force acting against the boiler-top, and tending to raise it upwards, will be immense, if a high pressure be adopted. To stay the boiler-top to the tops of the furnaces alone would not be sufficient, for the tops of the furnaces might alter their form, and the stays would then be of very little avail. The stays to the bottom of the boiler, however, if carried in the usual way, would have to be attached to the bottoms of the water spaces, and there they would be much in the way when the boilers are being cleaned. Indeed, it would be almost impossible to clean out the water legs effectually with stays so situated, and the best method, therefore, appears to be either to stay the boiler-top to a strong inverted arch spanning the water spaces, or to place a succession of iron arches over the furnace tops, to keep them in shape, after the fashion practised in Stephenson's locomotives, and to stay the boiler-top to these. Figs. 436 and 437 represent another boiler with upright tubes, (having the wa- 436. ter outside of them,) the design of Messrs. Rennie. This boiler is intended to supply steam to an engine on land, and its exterior is therefore composed of a cyl- inder of brickwork, between which and the boiler-shell the smoke is made to cir- culate on its way to the chimney. This brick cylinder is surmounted by a cast- iron dome, the edge of which fits into a groove containing sand, and access can readily be had to the ends of the tubes by raising up this dome by the tackle ap- plied to the eye fixed in its centre. This kind of boiler is identical in all its im- portant features with that represented in Figs. 426, 427, 428, and 429. That boiler, however, is intended for a steam vessel, and is, indeed, the boiler of one of the tug vessels working upon the Thames. As we happen to have a very high opinion of this variety of boiler, we must consider its merits in some detail, and therefore refer back our readers to Figs. 426, 427, 428, and 429, as it is to that specimen our remarks chiefly apply. The diameter of that boiler is 6 feet; height, 11 feet 6 inches; diameter of fire- box, 5 feet 2 inches distance from top of bars to lower tube-plate, 1 foot 6 inches distance from top of bars to ashpit bottom, 1 foot 7 inches length of tubes, 8 feet SCALE.-1-8th inch=1 ft. Perpendicular Section. diameter of tubes, 2 inches; distance from centre to centre of tubes, 3 inches; di- ameter of tube-plate, 3 feet 10 inches. There is a clear space of 1 foot 2 inches all 437. round, between the tubes and the boiler-shell. The height to which the water rises along the tubes is 5 feet, leaving 3 feet of the tubes to traverse the steam space. There are 145 tubes in all, and, reckoning their effective length at 5 feet, the effective tube surface is 881.53 feet. The fire-box surface is 20.96 feet, ma- king a total of 412.03 square feet of effective heating surface. The area of the fire- grate is 20.96, and the proportion of fire to heating surface is 1 to 20 nearly. One of these boilers supplies the engine of the vessel with steam, the cylinder of which is 26 inches in diameter, and the length of stroke 38 inches, the number of SCALE.-1-8th inch=1 ft. strokes per minute, 35 light, 26 to 30 when towing. The consumption of fuel is a a Furnace Doors. 10 cwt. of coal per four hours, including getting up steam. The tubes are of iron, Transverse Section. and show no symptoms of injury from the application of heat above the water-level. In some of the boilers constructed on this plan the lower tube-plate has cracked between the tubes, andwe think the breadth of an inch of iron between the tubes is insufficient in most cases. It would be an improvement, we think, to zigzag the tubes, which would leave more iron between the tubes, and, at the same time, would not prevent the introduction of an instrument to scrape them when necessary, at least diagonally. It would be very expedient, too, to defend the tube-plate from the heat of the fire by a fire-brick dome perfo- rated opposite to each tube. In that case, however, it would be necessary to give an additional tube surface, as more heat would then pass into the tubes than if such a dome were not employed. It is one drawback to the merits of this boiler, that it will be liable, we fear, to corrode internally more rapidly than common boilers. One of the most influential causes of internal corrosion appears to be the exist- ence of surcharged steam within the boiler, and in this kind of boiler the steam is almost necessarily surcharged to some extent. The surcharging, however, will be less considerable if there be a large heating surface, which may easily be given. It will be necessary in applying boilers of this construc- tion to steam vessels to adopt means of blowing out the supersalted water very effectually, else the scales may fall from the tubes upon the tube-plate, and occasion injury. One very obvious objection to this plan of boiler will present itself to our practical readers, which is, that a deposite either of silt or scale will be liable to take place on the top of the tube-plate, which will, in consequence, very soon burn out. This evil is to a great extent met by our suggestion to inter- pose a firebrick dome between the tube-plate and the fire; but we have not been able to discover that any sensible inconvenience has arisen from such depositures in boilers of this construction, even without the expedient we have just described. The agitation of the water, caused by the ascent of the steam up through it, is a powerful antidote to any settlement where it is going on, and the particles of matter mingled with the water, and out of which scale is fabricated, find their way by degrees to the sides of the boiler, where the water is tranquil, and there they finally settle. It is expedient, however, in boil- ers of this kind, either to blow off very frequently, or to have brine-pumps, which change the water in the boiler rather faster than usual. It would be a further improvement to place a collecting vessel within each boiler. Instruments of this kind have hitherto been very little used in steam vessels, but in land boilers they have long been employed with advantage, though in that case the advantage is of less account. We shall at a more advanced stage of our progress give some specimens of collecting vessels as applicable to marine boilers, but may here, for the sake of making our recommendation in- telligible, explain the simplest form of collecting vessel as applied to wagon boilers. We must first, however, premise that the addition of particles of extraneous matter to boiling water facilitates the extrication of the steam, and, in many cases, lowers the temperature at which ebullition carried on. The generation of steam is most active in those situations where those particles exist, Digitized by Google 142 BOILERS. 80 that, indeed, the steam appears as if it came out of them, and the particles are continually buoyed up by the steam in its ascent, and prevented from settling where the ebullition is active. If a vessel with a narrow mouth be immerged in a boiler under such circumstances as to preserve the water within it in a tranquil state, the vessel will speedily become filled with depositure resembling mortar, which, could it have settled, would have been indurated into scale. Of this circumstance advantage is taken in the construction of collecting vessels, for if the whole of the water in a boiler be in a state of ebulli- tion except a portion contained in an internal vessel, into that vessel the depositure will find its way and from thence it may be removed by blowing out. The remarks which we have already made respecting this species of boiler are sufficient, we con ceive, to show that the objections which might be brought against it are not of an insuperable character Its recommendations, however, are not of a negative kind, and it possesses two of weight enough, we conceive, to entitle it to a preference over most kinds bitherto projected. The first is, that if the steam be taken off by a perforated pipe there will be but little priming; and the second, that the construction facilitates the introduction of the revolving grate, and which, we anticipate, will come into general use for steam vessels. There is nothing in the revolving grate too complicated for such an application and it would be a matter of great importance to have the furnaces of steam vessels feeding themselves, which they would do much more effectually, and much more cheaply, than can be done by hand Boilers on this upright plan might be arranged across the vessel thus: Ship's side. Ship's side. with a crucial passage between them, and the athwartship passage need only be of a width cufficient to enable the attendants to light and clean the fires. We cannot here enter into the details of the ap- plication, but may remark that in those cases in which it may be inconvenient to drop the coal upon the fire through a slit from the top of the boiler, it will probably be found the best way to combine the boil- ers, so that one revolving grate will suffice for two sets of tubes, and the coals may then be introduced between the tube cylinders, and immediately over the fire. One material advantage of this 438. 439. arrangement is, that there will be no smoke-a virtue often claimed for the Cornish plan of boiler, but without any title thereto, farther than what arises from slow combustion and the use of Welsh coal, and both of these points may be attained in any boiler. Figs. 438 and 439 represent a small tubular boiler constructed by Messrs. Horton & Son for a coasting steamer called the Zephyr. This boil- er has been found to perform well, and is, in every respect, satisfactory. The tubes are of iron, 3 inches in diameter, and 6 feet long. Length of furnace 6 feet, number of tubes 168. 2 engines. Consumption of coal per hour, about SCALE.-1-10th inch=1 foot. SCALE-1-10th inch=1 foot. 6 cwt. The pressure of steam is about 5 lbs. Front View and Transverse Section. Longitudinal Section. on the square inch. Figs. 440, 441, and 442, represent another boiler, by Messrs. Miller, Ravenhill & Co., of the tubular kind. It is identical in all its main features with the boilers of the Tagus, already described, and the same remarks apply to it. It has been found expedient to introduce a jet of steam into the chimney of this vessel to quicken the draught. The tubes are of brass, 34 inches in diameter, and the tube- plates are of iron. A galvanic action between the brass and the iron has been found to arise in some boilers, which shows itself, not at the ends of the tubes, but at the ends of the athwartship stays which bind the sides of the boiler together and the iron plate around these stays very soon acquires the ap- pearance of having been scooped out by a knife; but in other boilers no action of this kind has been found to take place, and it has been doubted whether a leakage caused by the inadequate fastening of the stays has not had something to do with its production; nevertheless, in several cases of brass-tubed boilers which have come under our observation, the action has been very remarkable in the situation we have mentioned. The evil would probably be obviated by the application of a washer of zinc. Ex- perience in the use of tubular boilers certainly shows that brass tubes are on the whole the most eligi- ble. Iron tubes are speedily eaten into holes by corrosion, and it is remarkable that the corrosion chiefly takes place upon the under side. Brass tubes, on the contrary, are found to last many years. It ap- pears to be the best plan to refrain from attempts at scaling brass tubes, but they may be withdrawn once a year, cleaned, and reinserted. Figs. 443, 444, and 445, represent the boilers of the steam vessel Ocean. The tubes of these boilers are of iron 31 inches in diameter and 9 feet long furnaces 7 feet long and 2' 1" wide. There are three boilers in all the centre one with three furnaces, and the two wing ones with two furnaces each. Total breadth of boilers 19} feet; total length 14 feet; total number of tubes 378; two engines-diameter of cylinder 56 inches; length of stroke 51 feet; pressure of steam about 4} lbs.; consumption of coal about 18 cwt. per hour. In ordinary coasting vessels we do not approve of the plan of firing from each end, as the length in the vessel occupied by an additional firing space is a manifest waste of room; and there will be no difficulty in short voyages. about maintaining the trim of the ship on account of the stowage of so evanescent a cargo as coal in the wake of the furnaces. The object should, we conceive, Digitized by Google BOILERS. 143 be to obtain the requisite number of furnaces in the breadth of the ship, and then to add a sufficient number of tubes above the furnaces to extract the heat given out in them. In cases where this cannot be altogether, and yet can be nearly done, it is a less evil, we conceive, to put a few furnaces in a sec- ond tier into the midship boiler, rather than change the whole plan of the boiler by firing from both ends. In most cases we believe it will be possible to get sufficient room for the furnaces in the breadth of the ship if the engines be wrought expansively ; and this may be done, without affecting the power, either by applying high-pressure steam to the existing size of cylinders, or by introducing larger cylin- ders, and retaining the steam at a moderate pressure-that is, under 10 lbs. The latter plan in the case 440. 441. 442. 11 feet. SCALE.-3-20th Inch = 1 foot. SCALE.-3-20th inch = 1 foot. SCALE.-3-20th inch = 1 foot. Front View one-half in Section. Back View one-half in Section. Perpendicular Section. of new vessels is, in our judgment, greatly the preferable one; and we should recommend all new steam vessels to be made with the cylinders very large, while the boilers remain of the same dimensions as at present, except in the case of vessels impelled by the screw, where the engines may be worked at a very high speed-an increase in the speed being equivalent to an enlargement of the cylinder. A great force is thus available for the propulsion of the vessel when necessary, whether from adverse circumstances of wind and water, or otherwise, merely by diminishing the degree of expansion; while, in fair winds and smooth water, it becomes necessary to work with a very high measure of expansion to keep the engines supplied with steam, thus securing a moderate and uniform consumption. To make the engines light, while the power is kept undiminished, they must be worked with a fast piston; and to make the boilers light, with unimpaired efficacy, they must be provided with an artificial draught, unless the calo- rimeter or sectional area of flue be made larger than is at present usual in boilers forced in the manner of locomotive boilers. It is doubtful whether the tubes of tubular boilers intended for low-pressure en- gines are not still made longer than is expedient. 444. 445. 443. SCALE.-3-29th inch = 1 foot. SCALE.-3-28th inch = 1 foot. SCALE.-3-28th inch = 1 foot. Longitudinal Section. Horizontal Section through Tubes of Wing Transverse Section. Bollers and Furnaces of Centre Boller. Digitized by Google 144 BOILERS. Figs. 446, 447, and 448, are different views of the boilers of the steamer Forth, belonging to the English Mail Steam-Packet Company. These boilers are well worthy of the attention of the engineer, as they have approved themselves more economical than any of the other boilers employed in those vessels, at the same time that there is an abundance of steam, and the speed of the vessel is well maintained. The following are some of the more important particulars: There are four 447. 446. SCALE.-1-11th inch = 1 foot. SCALE.-1-11th inch = 1 foot. Longitudinal Sections. Transverse Section. Front View. 448. 449- 9/10" 2.0" 6484 181 816 NB2 95 16 9.26 SCALE.-1-11th inch = 1 foot. SCALE.-1-11th inch = 1 foot. Horizontal Section through Furnaces. Horizontal Section through Flues. Transverse Section. Elevation. 451. 450. 46 " 8 SCALE.-1-11th inch = 1 foot. SCALE.-1-11th inch = 1 foot. Horizon Section through Horizontal Section through Transverse Sections. Furnaces. Flues. Digitized by Google BOILERS. 145 boilers, with three furnaces in each, making 12 furnaces in all. Length of each boiler, 13' 6" breadth, 9' 10"; height, 14' 11". There is a fore-and-aft passage between the boilers, 2 feet wide, and an athwart passage 18 inches wide. Length of furnace, 7' 4"; breadth of furnace, 313 inches; diameter. of chimney, 67 inches; height of flues, 5 feet. Figs. 449, 450, and 451, represent two sets of boilers constructed by Messrs. Bury, Curtis & Kennedy, for the two steam vessels Wladimir and Der Greuss Adler, the one belonging to the Russian and the other to the Prussian government, and both of the power of 320 horses. These examples are of much interest, apart from all consideration of the general success of the constructors, the boilers for the Russian vessel being of the tubular variety, while those for the Prussian vessel are on the common flue plan; and we shall thus have a fair comparison of the merits of the two varieties. The shape and dimensions of the tubular boiler are shown in the figures by means of dotted lines; and a just conception may thus be arrived at of the amount of space occupied by a tubular and a flue boiler of the same efficacy in raising steam. The tubular boiler, of which the outline is here given, is almost identical with the boiler of the Braganza steamer, already given, and it is therefore needless here to repeat the delineation. Figs. 452, 453, and 454, represent the boilers of the Retribution, a steamer of 800-horse power; the engines being on the double cylinder plan of Messrs. Maudslay. There is nothing very pe- 452. 453. SCALE.-1-8th inch = 1 foot. SCALE.-1-8th inch= 1 foot. a. Horizontal Section through Furnaces. a. Side View. b. Horizontal Section through Flues. b. Longitudinal Section. enliar in these boilers except their size; in other respects they very much resemble the boilers of the Great Western, and of the Thames and Medway, also by Messrs. Maudslay and Field, of which we have already given delineations. Figs. 455, 456, 457, 458, 459, and 460, are different views of a sediment-collector, as made by Mr. Armstrong, of Manchester, for marine boilers. The manner in which this contrivance acts has already been explained, and all that we have here to do, is to give such forms of the machine as have been found the most convenient in practice. The sediment-vessell are generally made of thin sheet-iron, and an agitator with a handle extending through a stuffing-box to the outside of the boller, is usually added to facilitate the blowing out of the silt and other foreign matters caught by the collectors. In the manu- 454. facturing districts, the main purpose for which collecting-vessels are employed is the prevention of priming. Priming arises from insufficient steam room, an inadequate area of water-level, or the use of dirty water in the boiler the last of these instigations may be remedied by the use of collecting ves- sels, but the other defects are only to be correct- ed either by a suitable enlargement of the boiler, or by increasing the pressure and working more expansively. Closing the throttle-valves of an engine partially will generally diminish the amount of priming, and opening the safety-valve suddenly will generally set it astir. A steam vessel coming from salt into fresh water is much SCALE.-1-8th inch = 1 foot. SCALE.-1-Sth inch = 1 foot. more liable to prime than if she had remained Transverse Section. Elevation 19 Digitized by Google 146 BOILERS. in salt water, or never ventured out of fresh. This is to be accounted for by the higher heat at which salt water boils, so that casting fresh water among it is in some measure like casting water among molten metal, and the priming is in this case the effect of the rapid production of steam. One of the best palliatives of priming appears to be the interposition of a perforated plate between the steam space and the water. The water appears to be broken up by dashing against a plate of this description, and the steam is liberated from its embrace. In cases in which an addition is made to a boiler or steam-chest, it will be the best way not to cut out a large hole in the boiler-shell for establish- ing a communication with the new chamber, but to bore a number of small holes for this purpose, so as to form a kind of sieve, through which a rush of water cannot ascend. In locomotives the same end is attained by the use of a perforated steam-pipe extending from end to end of the boiler. Such a contrivance draws the steam off equally from the surface, instead of taking it from any one part; and boilers provided with it are enabled to work with SO small a steam-space that the steam-domes are now being taken away from locomotives altogether. This expedient has not yet been adopted in steam vessels, though it appears to be applicable to them also with advantage. In some boilers priming appears to be mainly caused by a malformation which prevents the water from circulating freely, and the steam has therefore to pass up through the water, occasioning a great agitation, instead of the water being enabled to circulate with the ascending steam. The evil may be mitigated in such cases by the addition of pipes to the exterior of the boiler, which will permit a descending current to be established, to replace the water carried upward by the steam. 455. SCALE.-11 inch = I foot. Front View of Bollers. 456. SCALE.-11 inch = 1 foot. Longitudinal Section of Boilers. We cannot afford to surrender any more space to these specimens of boilers, and must now proceed to dispatch what we have still to say on the subject of boilers in as few words as possible. We have already stated that a cubic foot of water raised into steam is reckoned equivalent to a horse power, and that to generate the steam with sufficient rapidity, an allowance of one square foot of fire-bars, and one square yard of effective heating surface, are very commonly made in practice, at least in land engines. These proportions, however, greatly vary in different cases; and in some of the best marine engine boilers, where the area of fire-grate is restricted by the breadth of the vessel, and the impossi- bility of firing long furnaces effectually at sea, half a square foot of fire-grate per horse power is a very common proportion. Ten cubic feet of water in the boiler per horse power, and ten cubic feet of steam- room per horse power, have been assigned as the average proportion of these elements; but the fact is, no general rule can be formed upon the subject, for the proportions which would be suitable for a wagon- boiler would be inapplicable to a tubular-boiler, whether marine or locomotive; and good examples will in such cases be found a safer guide than rules, which must often give a false result. A capacity of three cubic feet per horse power is a common enough proportion of furnace-room, and it is a good Digitized by Google BOILERS. 147 'plan to make the furnaces of a considerable width, as they can then be fired more effectually, and do not produce so much smoke as if they are made narrow. As regards the question of draught, there is a great difference of opinion among engineers upon the subject, some preferring a very slow draught, and others a rapid one. It is obvious that the question of draught is virtually that of the area of fire-grate, or of the quantity of fuel consumed upon a given area of grate-surface, and the weight of fuel burned on a foot of fire-grate per hour varies in different cases in practice from 31 to 80 lbs. Upon the quick- ness of the draught again hinges the question of the proper thickness of the stratum of incandescent fuel upon the grate; for if the draught be very strong, and the fire at the same time be thin, a great deal of uncombined oxygen will escape up through the fire, and a needless refrigeration of the contents of the flues will be thereby occasioned whereas, if the fire be thick, and the draught be sluggish, much of the useful effect of the coal will be lost by the formation of carbonic oxide. The length of the circuit made by the smoke varies in almost every boiler, and the same may be said of the area of the flue in its cross-section, through which the smoke has to pass. As an average, about one-fifth of the area of-fire- grate for the area of the flue behind the bridge, diminished to half that amount for the area of the chimney, has been given as a good proportion, but the examples which we have given, and the average flue-area of the boilers which we shall describe, may be taken as a safer guide than any such loose statements. When the flue is too long, or its sectional area is insufficient, the draught becomes insufficient to furnish the requisite quantity of steam whereas if the flue be too short or too large in its area, a large quantity of the heat escapes up the chimney, and a deposition of soot in the flues also takes place. This last fault is one of material consequence in the case of tubular boilers consuming bitumin- ous coal, though, indeed, the evil might be remedied by blocking some of the tubes up. The area of water-level is usually about 5 feet per horse power in land boilers. In many caser, however, it is much less; but it is always desirable to make the area of the water-level as large as possible, as when it is contracted, not only is the water-level subject to sudden and dangerous fluctuations, but water is almost sure to be carried into the cylinder with the steam, in consequence of the violent agitation of the water, caused by the ascent of a large volume of steam through a small superficies. It would be an improvement in boilers, we think, to place over each furnace an in- 457. SCALE.-3-16th inch = 1 foot. Horizontal Section and Bird's-eye View. 458. 459. 460. AAD Plan of Collecting Vessel from Bottom. Plan of Collecting Vessel from top. Plan of upper Collecting Vessel verted vessel immerged in the water, which might catch the steam in its ascent, and deliver it quietly by a pipe rising above the water-level. The water-level would thus be preserved from any inconve- nient agitation, and the weight of water within the boiler would be diminished at the same time that the original depth of water over the furnaces was preserved. It would also be an improvement to make the sides of the furnaces of marine boilers sloping, instead of vertical, as is the common practice, for the steam could then ascend freely at the instant of its formation, instead of being entangled among the rivets and landings of the plates, and superinducing an overheating of the plates by preventing a free access of the water to the metal. In the Transactions of the Institution of Civil Engineers, several papers are given by Mr. Parkes and others, descriptive of experiments made by them on steam boilers. We have, in Table 1, collected a few of the principal results exhibited in Mr. Parkes' very voluminous tables, and we have added the two columns on the right-hand side of the table, to show at the same time the evaporative economy of the boilers in use at the East London Water Works. One of these boilers is on the Cornish plan, and attached to the Cornish engine there. The other is a wagon boiler, with an internal flue, for supplying steam to a Boulton and Watt pumping-engine. The Cornish boilers are cylindrical, with an internal flue; and, as they are generally used with steam of from 15 lbs. to 35 lbs. above the atmosphere, they are made of plates half an inch thick. The left-hand column in the table gives the mean results of ex- periments made on the boilers at the Huel, Towan, and United Mines in Cornwall. The second column Digitized by Google 148 BOILERS. from the left is devoted to Mr. Parkes' experiments at Warwick; and, according to him, about one-sixth of the evaporation there given is due to his smoke-consuming apparatus. The third column exhibits the mean of eight experiments on wagon boilers, at the different places indicated at the head of the column, which were all (except the Albion Mills experiments) conducted by Mr. Parkes. The fourth column from the left contains the results of Mr. Smeaton's experiments on his atmospheric engine at Long Benton; and the fifth column gives the mean of eleven experiments on locomotives by M. de Pam- bour. Referring to the sixth line, it will be seen that the mean evaporative economy of the Cornish boilers is about the same as that of the Warwick boilers; but, if we exclude the East London Water Works boiler, the other Cornish boilers will show a decided superiority over all the rest. Lines five and eight show two of the principal peculiarities in the proportions of the Cornish boilers. It will be observed that the extent of their surface exposed to the heat, for each cubic foot of water evaporated, is about seven times as great as in any of the others. The combustion in their furnaces also is carried on at a very slow rate, there being only about 31 lbs. of coals burned on each square foot of grate. The only boiler that makes any approach to them in slowness of combustion is the one at Warwick. Mr. Parkes is a great advocate for slow combustion; and he founds his opinions principally on its effect in the Warwick boilers-at least it is from his experiments on them that he derives his opinion, that the principle should be carried so far as it was in that case. We conceive that in this instance he has over- looked one very material circumstance. It will be observed in the table, that the heated surface bears very nearly the same proportion to the water evaporated in these boilers as in the other wagon boilers; but, before Mr. Parkes altered his furnaces, much more water was evaporated per boiler, and, conse- quently, the heating-surface must then have been very small in proportion to the evaporation. We are, therefore, rather inclined to attribute the increased duty of the fuel to the increase of the heating- surface of the boiler, than to the diminution of the rate of combustion. Nevertheless, from other ex- 461. SCALE.-2th inch = 1 foot. Longitudinal Section and Elevation of Collectors. periments of Mr. Parkes, we are disposed to think that, for economy of fuel, the combustion in the gen- - erality of wagon-boiler furnaces is rather too rapid. The very large proportion that the heating-surface in the Cornish boilers bears to the weight of water evaporated, is, no doubt, to a considerable extent, rendered necessary by the thickness of the plates which the heat has to penetrate, and the high tem- perature of the water within them-both circumstances that retard the transmission of the heat. The Cornish practice, too, is universally, 80 far as we have been able to ascertain, in favor of this great ex- tent of surface; yet we can hardly think that a small diminution of it would produce any injurious effect on the economical properties of the boiler, while it would save a considerable part of the original cost. It will be seen, from what we have already advanced, that but a small part of the superior duty of the Cornish engines can be derived from the boilers; we must therefore look to the engines for the principal sources of their superiority, which may be comprised under these three heads:- 1st. The use of high-pressure steam cut off when a very small part of the stroke has been performed, and working expansively over the remainder. 2d. The careful clothing of every part of the engine where heat can escape. The cylinder is usually encased with a steam-jacket; and the steam-jacket itself, and all the steam-pipes, top of the boiler, &c, are protected from the cold air by being covered with a layer of three or four inches thick of ashes, saw-dust, or other good non-conductor of heat. The amount of saving effected in this way may be conceived to be very considerable. We have not met with any experiments to ascertain the amount of the saving by clothing the whole engine; but Mr. Wicksteed found that clothing the top of the boilers alone produced a saving of 101 per cent. in the fuel consumed. 3d. The third main source of the great duty of the Cornish engines is to be found in the excellent Digitized by Google BOILERS. 149 system of registering and publishing the duty of each engine, which has for many years been prevalent in Cornwall. It has made both the proprietors and engineers much more careful than they otherwise would have been of a host of details that have elsewhere been considered too trifling to require notice; but which, nevertheless, in the aggrégate, are of no small importance. TABLE L Mean of Huel, Towan, and United Mines boilers, in Cornwall. Mr. Parkes' boiler, at War- Mean of 8 experiments at the Albion Mills, Clithero, Preston, and New River Water Com., of London. Atmospheric Smeaton's Engine, at Long Benton, Noneumberland, 1778. of of M. Pambour's experiments on the Loco- motives of the Liverpool and Manchester Railway. wick. Cornish boiler at East Lou- don Water Works, 1839. Boulton and Watt boiler the Ban London Water Works, 1839. Cylindri- Circular Cylindri. Wagon Nature of the Bollers used. cal with Locomo- internal Wagon. Wagon. or Hay- cal with with in- stack. Live internal termal flue. flue. flue. Total area of heated surface in square feet 962 152 342.8 459 334.6 798 588 Length of circuit made by the heat in feet 155 50.66 72.5 52.8 7.0 83.1 78 Area of fire-grates in iguare feet 23.66 23.33 96.09 35-10 7.03 14-25 37.26 Weight of fuel burned on each square foot of grate, 3.46 4.00 10.75 20.34 79.33 46.82 13.31 per hour, in lbs Cabic feet of water evaporated from initial tempera- 18.87 16.44 13.91 14.11 11.14 ture by 112 lbs. of fuel Cubic feet of water evaporated per hour from initial 13.81 13.79 34.40 90.7 55-18 temperature Square feet of heated surface for each cubic foot of 69.58 11.00 9.96 5.06 6.06 17.17 water evaporated per hour Square feet of heated surface for each square foot of 40.65 6.51 13.13 13.08 47.59 56.0 15.78 grate. Pressure of steam above the atmosphere in lbs 42-2 2.5 3.68 1.5 50 15-45 Kind of coal used* W. S. L.&N. N. Coke. N. N. W. Welsh.-S. Staffordshire.-L. Lancashire.-N. Newcastle. The grand secret, however, of the economy of the Cornish engines lies in the large application of the principle of expansion, and the results there obtained are very little aided by any peculiar excellence in the boiler. Upon the merits of expansion, however, or the pitch to which it may be beneficially carried in particular cases, this is not the place to enlarge, but we may here give a table which shows the relative efficacy of different engines with different degrees of expansion. Holmbush, Cornish con- densing En- Smeaton's At- Boulton and Watt's gine, single Noncondensing mospheric non-expansive ro- acting, for double-acting Cornish En- Boulton and TABLE IL Engine,Long tative condensing pumpingwa- Engine, non- gine, East Watt's Pump- Benton,Nor- Engine, Albion ter. Steam London Wa- ing Engine at expensive, thumerland, Mills, acts expan- Congleton, ter Works. East London London, Water Works. date 1772. date 1786. sively after Cheshire,1828. the first sixth of the stroke, 1836. Diameter of cylinder in Inches. 52 34 50 13 794 594 Length of stroke in feet 7 8 9.1 4 10 7.91 Number of strokes per minute. 12 16 4.63 27.5 7 11.5 Pressure on the piston, above or below the atmosphere, in lbs. Estimated at +30 +20 +5.17 +2.15 2.5 per square inch Weight in lbs. raised one foot by 112 lbs. of coals 12,600,000 25,756,752 140,484,848 12,418,560 105,664,118 46,602,333 Weight in lbs. raised one foot by one pound of water. as steam. 14,280 28,489 119,097 15,840 110,716 53,369 Effective power of the engine at time of experiment in horse 40.5 50.0 26.48 12.0 power Efficiency of the steam, its offi- ciency in the Albion Mills .501 1·000 4-180 .556 3.89 1.87 being unity Efficiency of the fuel, its effi- ciency in the Albion Mills .480 1.000 5.454 -482 4.1 1.81 being unity Distance of the piston from the end of its stroke when the 0 0 833 0 687 -5 steam is cut off in parts of the length of stroke The first column on the left exhibits the performance of Smeaton's atmospheric engine at Long Benton. In the second column will be found similar particulars of Boulton and Watt's condensing rotative engine at the Albion Mills. In the third column we have put down the same data for the Holmbush Cornish engine; and, in the fourth, for a high-pressure non-condensing engine, whose duty was determined by Mr. Wicksteed. The last two columns supply the same data for a Cornish engine and Boulton and Watt pumping-engine, at the East London Water Works. The economical effects of expansion will be found to be very clearly exhibited in this table. The duties are recorded in the fifth line from the top, and the degree of expansion in the bottom line. It will be observed, that the order Digitized by Google 150 BOILERS. in which the different engines stand in respect of superiority of duty is the same as in respect of amount of expansion. The Holmbush engine has a duty of 140,484,848 lbs. raised 1 foot by 1 cwt. of coals, and the steam acts expansively over 830 of the whole stroke; while the water-works' Cornish engine has only a duty of 105,664,118 lhs, and expands the steam over only 687 of the whole stroke. Again, comparing the two Boulton and Watt engines together, the Albion Mills engine has a duty of 25,756,752 lbs., and no expansive action. The water-works' Boulton and Watt engine, again, acts expansively over one-half of its stroke, and has an increased duty of 4,660,333 lbs. Other causes, of course, may influence these comparisons, especially the last, where one engine is a double-acting rotative engine, and the other a single-acting pumping one; but there can be no doubt that the expansive action in the latter is the principal cause of its more economical performance. The heating service per horse power allowed by Boulton and Watt is about 9 square feet in wagon boilers, reckoning the total surface as effective surface, if the boilers be of a considerable size; but in the case of small boilers, the proportion is larger. The total heating-surface of a two-horse power wagon boiler is, according to Boulton and Watt's proportions, 30 square feet, or 15 ft. per horse e power; whereas, in the case of a 45-horse power boiler the total heating-surface is 438 square feet, or 96 ft. per horse power. The capacity of steam-room is 84 cubic feet per horse power, in the two-horse power boiler, and 51 cubic feet in the 20-horse power boiler; and in the larger class of boilers, such as those suitable for 30 and 45 horse power engines, the capacity of the steam-room does not fall below this amount, and indeed is nearer 6 than 54 cubic feet per horse power. The content of water is 18, cubic feet per horse power in the two-horse power boiler. and 15 cubic feet per horse power in the 20- horse power boiler. In marine boilers about the same proportions obtain in most particulars. The original boilers of the Great Western" steamer, by Messrs. Maudslay, were proportioned with about half a square foot of fire-grate per horse power, and 10 square feet of flue and furnace surface, reekoning the total amount as effective; but in the boilers of the "Retribution," by the same ma- kers, a somewhat smaller proportion of heating-surface was adopted. Boulton and Watt have found that in their marine flue-boilers 9 square feet of flue and furnace surface are requisite to boil off a cubic foot of water per hour, which is the proportion that obtains in their land boilers; but in- asmuch as in modern engines the nominal considerably exceeds the actual power, they allow 11 square feet of heating-surface per nominal horse power in their marine boilers, and they reckon as effective heating-surface, the tops of the flues, and the whole of the sides of the flues, but not the bottoms. They have been in the habit of allowing for the capacity of the steam space in marine boilers 16 times the content of the cylinder; but as there are two cylinders this is equivalent to 8 times the content of both cylinders, which is the proportion commonly followed in land engines, and which agrees very nearly with the proportion of between 5 and 6 cubic feet of steam-room per horse power. Taking, for example, an engine with 23 inches diameter of cylinder and 4 feet stroke, which will be 184 horse power-the area of the cylinder will be 415476 square inches, which multiplied by 48, the number of inches in the stroke, will give 19942-848 for the capacity of the cylinder in cubic inches; 8 times this is 159542-784 cubic inches, or 923 cubic feet; 92.3 divided by 184 is rather more than 5 cubic feet per horse power. There is less necessity, however, that the steam space should be large when the flow of steam from the boiler is very uniform, as it will be where there are two engines attached to the boiler at right angles with one another, or where the engines work at a great speed, as in the case of locomotive engines. A high steam-chest too, by rendering boiling over into the steam-pipes, or priming, as it is called, more difficult, obviates the necessity for so large a steam space; and the use of steam of a high pressure, worked expansively, has the same operation; so that in modern marine boilers, of the tubular construction, where the whole of these modifying circumstances exist, there is no necessity for so large a proportion of steam-room as 5 or 6 cubic feet per horse power, and about half that amount more nearly represents the general practice. Boulton and Watt allow 0.64 of a square foot per nominal horse power of grate-bars in their marine boilers, and a good effect arises from this proportion; but sometimes so large an area of fire-grate cannot be conveniently got, and the proportion of half a square foot per horse power seems to answer very well in engines working with some expansion, and is now very widely adopted. With this allowance, there will be about 22 square feet of heating-surface per square foot of fire-grate, and if the consumption of fuel be taken at 6 lbs. per nominal horse power per hour there will be 12 lbs. of coal consumed per hour on each square foot of grate. The flues of all flue boilers diminish in their calorimeter as they approach the chimney some very satisfactory boilers have been made by allowing a proportion of 06 of a square foot of fire-grate per nominal horse power, and making the sectional area of the flue at the largest part one-seventh of the area of fire-grate, and the smallest part where it enters the chimney one-eleventh of the area of the fire-grate; but in some of the "boilers proportioned on this plan the maximum sectional area is only 7:3 or g'3, according to the purposes of the boiler. These proportions are retained whether the boiler is flue or tubular, and from 14 to 16 square feet of tube surface is allowed per nominal horse power; but such boilers, although they may give abundance of steam, are generally, perhaps needlessly, bulky. We must now, however, dismiss these speculations, and with them the whole subject of the efficacy of different kinds of boilers, upon which we have already expatiated sufficiently we shall therefore conclude our remarks upon the subject by introducing a table of the comparative evaporative power of different kinds of coal, which we have derived from Mr. Wicksteed's experiments, and which will prove useful, by affording data for the comparison of experiments upon different boilers when different kinds of coal are used. Without this means of reduction, experiments would be useless for comparison, unless the fuel employed was in every case of equal evaporative power; but when the relation between the evaporative power of different kinds of coals is ascertained, the results of experiments can be easily reduced so as to render them comparable with one another. Digitized by Google BOILERS. 151 TABLE of the Comparative Evaporative Power of different kinds of Coal. Water evapor- No. Description of Coals. ated per lb. Value per Ton in the Pool. of Coals. Lbs. 8. d. 1 The best Welsh 9.493 17 11 2 Anthracite 9.014 17 0 3 The best small Newcastle 8.524 16 1 4 Average small Newcastle 8.074 15 21 5 Average Welsh 8.045 15 21 6 Coke from Gas-works 7.908 14 11 7 Coke and Newcastle, small, half and half 7.897 14 101 8 Welsh and Newcastle, mixed half and half 7.865 14 10 9 Derbyshire and small Newcastle, half and half 7.710 14 61 10 Average large Newcastle 7.658 14 53 11 Derbyshire 6.772 12 94 12 Blythe Main, Northumberland 6.600 12 53 Strength of Boilers.-The extension of the expansive method of employing steam to boilers of every denomination, and the gradual introduction in connection therewith of a higher pressure than formerly, makes the question of the strength of boilers one of great and increasing importance. This topic was very successfully elucidated a few years ago by a committee of the Franklin Institute, and we shall here recapitulate a few of the more important of the conclusions at which they arrived. Iron boiler- plate was found to increase in tenacity as its temperature was raised until it reached a temperature of 550° above the freezing point, at which point its tenacity began to diminish. The following table exhibits the cohesive strength at different temperatures:- At 32° to 80° the tenacity was = 56,000 lbs., or 1-7th below its maximum. At 570° " " " = 66,500 lbs., the maximum. At 720° " " " = 55,000 lbs., the same nearly as at 32°. At 1050° " « " = 32,000 lbs, nearly 1 of the maximum. At 1240° a " " = 22,000 lbs, nearly 1 of the maximum. At 1317° " " " = 9,000 lbs., nearly 1-7th of the maximum, At 3000° iron becomes fluid. The difference in strength between strips of iron cut in the direction of the fibre, and strips cut across the grain was found to be about 6 per cent. in favor of the former. Repeated piling and welding was found to increase the tenacity and closeness of the iron, but welding together different kinds of iron was found to give an unfavorable result riveting plates was found to occasion a diminution in their strength, to the extent of about one-third. The accidental overheating of a boiler was found to reduce its strength from 65,000 lbs. to 45,000 lbs. per square inch. Taking into account all these contingencies, it appears expedient to limit the tensile force upon boilers in actual use to about 3000 lbs. per square inch of iron. Copper follows a different law, and appears to diminish in strength by every addition of heat, reckoning from the freezing point. The square of the diminution of strength seems to keep pace with the cube of the temperature, as appears by the following table :- TABLE showing the Diminution of Strength of COPPER Boiler-Plates by additions to the Temperature, the Cohesion at 32° being 32,800 lbs. per Square Inch. Temperature Diminution of Temperature Diminution of No. No. above 32°. Strength. above 32°. Strength. 1 90° 0.0175 9 660° 0.3425 2 180 -0.0540 10 769 0.4398 8 270 0.0926 11 812 0.4944 4 360 0.1518 12 880 0.5581 5 450 0.2046 13 984 0.6691 6 460 0.2133 14 1000 0.6741 7 513 0.2446 15 1200 0.8861 8 529 0.2558 16 1300 1·0000 Digitized by Google 152 BOILERS. In the case of iron, the following are the results when tabulated after a similar fashion. TABLE of Experiments on IRON Boiler-Plate at High Temperatures; the Mean Maximum Tenacity being at 550°65,000 lbs. per Square Inch. Temperature Diminution of Tena- Temperature Diminution of Tena- observed. city observed. observed. city observed. 550° 0.0000 824° 0-2010 570 0-0869 932 03324 596 0-0899 947 0-3593 600 0-0964 1030 0.4478 630 0.1047 1111 0.5514 662 0-1155 1155 0-6000 722 0-1436 1159 06011 732 0-1491 1187 0.6352 734 0-1535 1237 06622 766 0.1589 1245 0.6715 770 0.1627 1317 0-7001 The application of stays to marine boilers, especially in those parts of the water spaces which lie in the wake of the furnace bars, has given engineers much trouble; the f-plate, of which ordinary boilers are composed, is hardly thick enough to retain a stay with security by merely tapping the plate, whereas, if the stay be riveted, the head of the rivet will in all probability be soon burnt away. The best practice appears to be to run the stays used for the water spaces in this situation, in a line some- what beneath the level of the bars, so that they may be shielded as much as possible from the fire, while those which are required above the level of the bars should be kept as nearly as possible towards the crown of the furnace, 80 as to be removed from the immediate contact of the fire. Screw-bolts with a fine thread tapped into the plate, and with a thin head upon the one side, and a thin nut made of a piece of boiler-plate on the other, appear to be the best description of stay that has yet been contrived. The stays between the sides of the boiler-shell, or the bottom of the boiler and the top, present little difficulty in their application, and the chief thing that is to be attended to is to take care that there be plenty of them; but we may here remark that we think it an indispensable thing, when there is any high pressure of steam to be employed, that the furnace-crown be stayed to the top of the boiler. This, it will be observed, is done in the boilers of the Tagus and Infernal, constructed by Messrs. Miller, Raven- hill and Co.; and we know of no better specimen of staying than is afforded by those boilers. Explosion.-This subject has been investigated with much care by the committee of the Franklin Institute, whose experiments on the strength of boilers we have already mentioned with commendation. We are unable, however, to follow these experimentalists in their researches, and have only room to remark that we believe most explosions will be found to have arisen either from an undue pressure of the steam, or from the overheating of the plates composing the boiler. The plates of the boiler may become overheated either in consequence of a want of water in the boiler. or from such a configuration of the internal parts of the boiler that the steam when formed cannot escape freely to the surface. The bottoms of large flues upon which the flame beats down are very liable to injury from this cause and the iron in such a case will probably be softened by the heat, and in all probability will collapse upwards. Lightning, the sudden disengagement of large portions of scale, and other similar accidents have, we believe, caused explosions sometimes. But these causes are of very unfrequent occurrence in comparison with those that we have indicated, and which would be oftener recognised as the real causes of explosions, were it not that people think they show their cleverness best by clearing up a difficulty with a new hypothesis that has been coined for the purpose in fancy's mint. The plugs of fusible metal sometimes introduced into boilers to obviate explosions by melting out before the steam can reach any high temperature, are found in practice to be of but little avail. The compound metal is not homogeneous, and the more fusible of the metals is melted first, and is forced by the pressure of the steam out of the interstices of the less fusible metal, leaving its place to be supplied by the debris which all water supplies. The consequence is that the plug ceases to be fusible metal of the kind originally introduced, and cannot be melted by the steam even at a pressure and temperature much above that fixed as the requisite fusing point. Plugs of fusible metal should, therefore, we think, be discarded, as they are only calculated to mislead by pretending to do what they cannot accomplish. In tubular boilers, however, it is, we think, a good plan to introduce lead plugs in the tops of the fire- boxes-not with the idea that they will be melted by the steam where its pressure gets high, but to be melted out, and give notice of danger should the water fall too low. Every boiler should be furnished with a steam-gage, which may give indication of danger should the pressure become too great, and the passages leading to the safety-valves should have no connection with the pipes leading to the stop-valves. In some cases stop-valves have been lifted from their seats, and forced into the mouth of the pipe, 80 that no steam could escape thereby; and in consequence of the safety-valve pipe springing from the pipe connecting the boilers, the boiler thus blocked up was in great danger of bursting, and would have burst if the fires had not been immediately drawn. "In the case of any derangement of the safety-valve, or of the cone in the waste steam-pipe of a steam-vessel getting loose, and blocking up the mouth of the pipe, the pressure in the boiler may be eased by open- ing the blow-through valves of the engines, and the steam-gage will in all cases tell whether any undue pressure exists. Incrustation.-The incrustation of boilers by saline deposites was a much more important subject at Digitized by Google BOILERS. 153 one time than it is now, as nothing has been more clearly established, of late years, than that boilers may be preserved effectually from any injurious incrustation by abundant blowing off. Brine-pumps are now in extensive use for withdrawing a certain quantity of water at every stroke of the engine; and the water so withdrawn has to pass through or among pipes carrying the feed-water to the boiler, 80 that some interchange of heat is there effected. These refrigerators, however, as they are grotesquely called, are in some respects bad things: the quantity of heat they save is, we believe, inappreciable; and the small pipes of which they are built up are liable to get choked, thereby endangering the boiler by the unconscious concentration of its contents. To guard against this danger, every engine fitted with brine-pumps should be provided with an hydrometer for telling the specific gravity of the water in the boiler, 80 that the engineer may not be cheated by the defective action of the pumps, or suppose that they are operating when they are really inert. In the case of blowing out a boiler in the usual way, the engineer looks at his glass gage-tube, and keeps the blow-off cock open until the water-level has descended through the required distance, 80 that, under these circumstances, no doubt can arise that the boiler has been emptied of a certain quantity of water; but there is no such assurance in the case of the continuous extraction of the water, either by brine-pumps or by a continuous blow-off; and all boilers using either of these expedients should be fitted with hydrometer gages as a precaution against the contents of the boiler being suffered to reach an injurious concentration. Numerous prescriptions have at various times been given as antidotes to incrustation; such as putting potatoes and other vege- table matters in the boiler, or, in the case of a steam-vessel, taking the feed-water from the bilge. The application of oil to the flues has also been recommended; and some boilers are fitted with a contri- vance to inject oil into them just before the steam is let down. We look upon all such expedients, how- ever. as needless, and are confident that boilers require no other preservation from incrustation than effectual blowing off. Collecting vessels, however, are advantageous, as they enable a less amount of blowing off to suffice; and, in the case of the feed supplied to the boiler being muddy water, they con- duce to convenience and save fuel by obviating priming. The prevailing fault among engineers, how- ever, is that they do not blow off enough, the idea probably being that a considerable check is given to the generation of the steam by the introduction of colder water in lieu of the water abstracted; but the waste of heat by effectual blowing off is very inconsiderable-much less, indeed, than is occasioned by the difficulty of getting steam from brine, or of transmitting heat to the water through flues covered with incrustation, much of which heat, in consequence, ascends the chimney. There is no gain, there- fore, in any respect, by penuriousness in blowing off; and there is much injury to the boiler, for incrusted plates become overheated; they blister, crack, and get burned out, and make expensive repairs indis. pensable. Proprietors of engines should accept of no excuse for the accumulation of salt or incrustation within their boilers; for such deposites arise altogether from insufficient blowing off. The best method of scaling boilers appears to be by lighting a train of shavings in the furnaces and flues after the boilers have been emptied of water. The rapid expansion of the metal, thus occasioned, causes the scale to crack off; and, if the flues be then washed down with a hose, the scale will fall to the bottom of the boiler, and will issue out with the water on taking off the mud-hole doors. This plan of scaling, however, is one that the engineer must execute himself, and must not intrust to firemen or other subordinates, as the metal of the boiler might be damaged if the heat were made too great. The safety- valve should, obviously, be kept open while the boiler is being heated and cooled, to obviate any pres- sure or exhaustion within it. This plan of scaling, however, will seldom be necessary if due attention be paid to blowing off by the engineer; and if the quantity of scale be inconsiderable, or partial in its attachment, the best plan will be to chip it off with a hatchet-faced hammer, and then wash down the flues with the hose, as before described. Corrosion.-The corrosion of boilers is one of the most obscure subjects in the whole range of engi- neering. Marine boilers seldom last more than four or five years, whereas land boilers, made of the same quality of iron, often last eighteen or twenty years; yet the difference in durability is not the effect of any chemical action upon the iron by the contact of sea-water, for the flues of marine boilers rarely show any deterioration from this cause, and, even in worn-out marine boilers, the hammer-marks on the flues are as conspicuous as at the time of their formation. The thin film of scale spread over the internal parts of the boiler would, of itself, preserve that part of the iron from corrosion which is situated below the water-level; but, whatever be the cause, it is a rare thing to find any internal cor- rosion of a boiler using salt water in those parts of the boiler with which the water comes in contact. The cause, therefore, of the rapid wearing out of marine boilers is not traceable to the chemical action of salt water, and steamers provided with Hall's condensers, which supply the boilers with fresh wa- ter, have not reaped much benefit in the durability of their boilers. The operations of the steam in corroding the interior of the boiler is most capricious-the parts which are most rapidly worn away in one boiler being untouched in another, and in some cases one side of a steam-chest will be very much wasted away while the opposite side remains uninjured. Sometimes the iron exfoliates in the shape of a black oxide which comes away in flakes like the leaves of a book, while in other cases the iron appears as if eaten away by a strong acid which had a solvent action upon it. The application of felt to the outside of a boiler, has in several cases been found to accelerate sensibly its internal corro- sion. Boilers in which there is a large accumulation of scale appear to be more corroded than where there is no such deposite, and where the funnel passes through the steam-chest the iron of the steam- chest is invariably much more corroded than where the funnel does not pass through it. These facts appear to indicate that the internal corrosion of marine boilers is attributable chiefly to the existence of surcharged steam within them, which is steam to which an additional quantity of heat has been com- municated subsequently to its generation, so that its temperature is greater than is due to its elastic force; and on this hypothesis the observed facts relative to corrosion become easily explicable. Felt applied to the outside of a boiler may accelerate its internal corrosion by keeping the steam in a sur- charged state, when by the dispersion of a part of the heat it would cease to be in that state. Boilers in which there is a large accumulation of scale must have worked with the water very salt, which 20 Digitized by Google 154 BOLTING-MILL. necessarily produces surcharged steam; for the temperature of steam cannot be less than that of the water from which it is generated, and inasmuch as the boiling point of water, under any given pressure, rises with the saltness of the water, the temperature of the steam must rise with the saltness of the water, the pressure remaining the same; or in other words the steam must have a higher temperature than is due to its elastic force, or be in the state of surcharged steam. The circumstance of the chim- ney-flue passing through the steam will manifestly surcharge the steam with heat, so that all the cir- cumstances which are found to accelerate corrosion are, it appears, such as would also induce the formation of surcharged steam. Besides, the natural effect of surcharged steam is to oxidate the iron with which it is in contact, as is illustrated by the familiar process for making hydrogen gas by sending steam through a red-hot tube filled with pieces of iron; and although the action of the surcharged steam in a boiler is necessarily very much weaker than where the iron is red-hot, it manifestly must have some oxidizing effect, and the amount of corrosion produced may be very material where the action is perpetual. Boilers with a large extent of heating-surface, or with descending flues circulating through the cooler water in the bottom of the boiler before ascending the chimney, will be less corroded internally than boilers in which a large quantity of the heat passes away in the smoke. If these views be correct, then to prevent the internal corrosion of marine boilers it is only necessary to take care that the water in the boiler shall be as fresh as possible, and that the root of the chimney shall either be lined with fire-brick, or not go through the steam at all. 463. steam Pips 462. D S P These boilers, which have now been in use by the Lowell Manufacturing Company at Lowell for two years, were constructed, from directions by Dr. A. A. Hayes, of Boston, by Messrs. Bancroft, Nightin- gale & Co., of Providence. One row of four boilers are set perpendicularly above another row of the same number, the fires being under the lower tier. The boilers are plain cylinders, 40 feet long and 33 inches diameter, having a surface exposed to the fires of 2,000 square feet, and containing about 1,200 cubic feet of water. The grates are in two heights of 3 feet 2 inches each, with a width of 12, feet, giving a fire surface of about 80 square feet. Each grate is 11 inch thick, having between it and the next one a space of a quarter of an inch wide, giving the whole of the space for the passage of the air to the fires equal to about 101 square feet. The dampers at the back end of the boilers are usually kept open about four inches, giving an area of four and one-sixth square feet for the exit of the smoke. The upper and lower tiers are connected by thimbles in four places in each boiler between their ends, while at the ends are a number of connections, as shown. The thimbles are of cast-iron, having a socket turned in its upper part, into which a tube is set, reaching to within eight inches of the top of the upper boiler. The connections at the ends are of cast composition metal, and notwithstanding their number no leakages have occurred. A steam drum, 11 feet long and 33 inches diameter, is connected with each of the upper boilers, and is placed above them; from this drum steam is taken to the engines. Accurate measurements and accounts have been kept of the amount of coal used, and of the water evaporated by it, which show that for the last year together, the average amount of water evaporated to one pound of coal consumed was 9.66 lbs. The amount of coal consumed under each nest of eight boilers per day is about 21 tons. and by com- paring the weekly averages of effect, it appears that, even with this large amount of boiler compared to the fire surface, that the less the amount of coal consumed per day the better the effect. For example: the amount of coal consumed under two nests of these boilers during the week ending Feb. 18th, 1848, was 65 tons, which evaporated 8.72 lbs. of water for each pound of coal consumed, and during the week ending July 14th, 1849, 21 tons of coal only were burned, and 10.44 lbs. of water were evaporated for each pound of coal consumed. The best result from a week's working was obtained du- ring the week ending May 7th, 1849, when 11.62 lbs. of water were evaporated by each pound of coal consumed. The steam from two nests of these boilers is used at a pressure of 65 lbs. per square inch, by a double high-pressure engine of 200-horse power, and a single engine of 40-horse power, both of which exhaust into pipes under a pressure of five pounds per square inch, from which it is used for dying, dry- ing, and heating. BOLTING-MILL for flour. A bolting-mill is the general name of a place where meal is sifted. But here the subject in question is particularly a dressing or bolting machine in common mills, by which either the bran is separated from the flour or meal, or the ground grain, ore, &c., is refined. The bolting- machines most in use are-1st. The common bolter; 2d. The rotative cylindric or prismatic bolter; and 3d. The brush-bolter. Though they differ from each other in structure, the substantial arrangement consists in a kind of sieve of wire or horsehair, or of cotton or silk texture, of bolting-cloth or of silk- gauze, either of which stuff is used according to the fineness of the meal required; the meshes or per- forations of the one being smaller than those of another. The peculiarity of the common bolter is, that the sifting is effected by its shaking motion that of the cylindrical or prismatic bolter is, that the sifting is produced by its rotative motion, either alone, or by co-operation of the centrifugal power, or of beaters or similar apparatus. Digitized by Google BOLTING-MILL. 155 The peculiarity of the brush-bolter is, that the sifting is effected by brushes placed in the interior of the bolter itself, which latter discharges its coarser contents into the bran-chest; while the meal or flour is taken up in the bolting-hutch. The common bolter is still most in use, at least in Germany, and other countries of the European continent, because it is the most simple; although in recent times the cylindric and prismatic bolter have here and there been introduced and applied successfully. The arrangement of the improved bolter in general use, will be perceived by Figs. 463, 464, 465, and 466, where Fig. 463 represents the bolting-machine in longitudinal section; Fig. 464 ground-plan, (but without the lid of the bolting-hutch;) Fig. 465 front, and Fig. 466 side-view of the hind part, together with the mechanism for effecting the shaking motion. The oblong and closed bolting-hutch, marked by a a, is fastened to the meal-bench b; and in its in- terior, at an angle of 15, or, at the most, 30 degrees, is placed the bolter or sifter c c, whose upper end is fastened to the scuttle d, Figs. 463 and 464, and whose lower end discharges its contents at the fore side of the hutch a a. The bolter consists commonly of bolting-cloth or silk-gauze, of which two strips from 6 to 7 feet in length, and from 14 to 16 inches in breadth each, are sewed together lengthwise. The seams are edged, two inches broad; and the two ends of the bolter are likewise bordered with leather, for the purpose of fixing iron rings. The ring at the upper end is quadrangular, yet with rounded corners it is 8 inches broad, and from 5 to 6 inches diameter. At about 2 feet down from the upper end of the bolter, two handles, (called bolter-ears, and marked by the letter e,) of strong sole-leather, are sewed to the sides, to serve for the reception of two arms ff, of the apparatus for effecting the shaking mo- tion. The lower end of the tight-stretched bolter is placed in the aperture cut out in the slide g on the outside of the bolting-hutch; the shaking-arms ff, which are either covered with tin-plate, or with ends of cast-iron, are to be put through the two bolter-ears e; and the upper end of the sifter is to be placed on the outside of the scuttle d, in the notch of the wooden ledge h, Fig. 463, and fixed by the iron cramp i. At the lower end the screws k k of the slide g are designed to stretch the bolter as required. The motion of the bolter may either be horizontal or perpendicular. The former is most general, as the bolter is more worn by the perpendicular motion. But it may be asserted that the case is almost entirely the reverse. For by the lateral motion the sides of the bolter are very much tossed, and 80 their threads too much stretched, especially when the shaking-arms ff stand out straight from the shaking-axis, forming thus an acute angle with the bolter. By the perpendicular motion the bolter is also violently tossed; however, this inconvenience may be removed by using curved arms, (like that marked by f in Fig. 463,) instead of rectilinear ones, and made either of timber or iron. The vertical shaking motion of the bolter is produced in the following simple way: At the axis l, placed horizontally beneath the sifter, are fixed the two shaking-arms ff; also at its projection the bent arm m, called the bolter, in which the bolter-tongue is, by means of a peg, fastened in a manner which allows of its turning. The bolter-tongue is pressed against the horizontal arm o of a vertical axis p, by the wooden or steel spring q, 80 firmly and continually that a retrograde motion results from the re- bounding of this spring, while the advancing motion is effected by a second arm r of the axis p, which beats against three tenons t, and is pushed off again by them. The power of this shaking motion can be modified according to the required fineness of the flour, or to the more or less fine bolting-cloth; and this is effected by displacing the bolter-tongue n in the wheel-scissors m, for which purpose both are perforated. However, the bolter is not suffered to move more than 3 inches up and down, as this is sufficient even for the coarsest grit, while a more vigorous movement would wear the bolter too much. The upper millstone in a common mill, of 3 feet in diameter, making from 140 to 180 rotations a minute, each bolter, brought in connection with a set of such stones, will be moved up and down thrice 80 often, or 420 to 540 times in a minute. In order to be enabled to look frequently at the bolter, there is made in one of the side partitions of the bolting-hutch a large square aperture и 26, commonly covered with a linen cloth v, Fig. 464. Another aperture w, about 6 inches high and wide, at the bottom of the hutch, is provided with a slide of wood or tin-plate, and serves as an outlet for the flour. Beneath the lower end, or mouth of the bolter, is a small gutter x, made of wood or tin-plate, in order to facilitate the emptying of the grit or bran into the bran-chest below. The mouth of the bolter is covered with a cloth y, Fig. 465, pressed towards the mouth of the bow x, to prevent the flour-dust, joined to the grit and bran, from dusting away. Should the under side of the bolter become defective, it is commonly mended by putting in a new piece of cloth; or, should this be of no avail, the upper side of the bolter may be turned down. The apparatus used for bolting ores containing silver or gold, after they have been ronsted with salt and ground, is somewhat different from the bolting-machinery in corn-mills. At Freiberg (a celebrated mining town in Saxony) a similar bolter as the above-described is used, with the only difference that it is made of double bolting-cloth, whose threads are twined, to make it stronger. The ore-dust being very warm, and for this reason easily brought to rise, the bolting-hutch is made of very dry timber, and its boards are not only joined together carefully, but also grooved and glued. The aperture in the side- partition, Fig. 463, uu, is beside the curtain, Fig. 464, v, closed with a door or slide, while on the other hand, the bran-chest is 11 feet in length, and closed tightly. The bolting-cloth used in bolting-mills consists generally of woollen, more seldom of silk texture, and is glued or gummed in a particular manner. According to the species of corn to be bolted, and to the fineness of the flour, the cloth is coarse or fine, both in the threads and the size of its perforations or meshes. There are more than a dozen sorts of cloth, which are selected according to the quantity of meshes in an inch square. The cloth is commonly from 14 to 16 inches broad, thus being adapted for the use of bolters from 10 to 12 inches in diameter. The English manufacture bolting-cloth noted for its good quality and durability; there are also in Germany superior manufacturers of this article, especially at Lins, Berlin, and Breslau. The best quality bolting-cloth and silk-gauze is fabricated by Digitized by Google 156 BOLTING-MILL. Dufour & Co., at Thal, in the Swiss canton of St. Gall, by Hennecart, at St. Quentin, in France, and by Harlem Star, in Holland. We shall now describe those bolting-mills where the cylindrical bolter is used. Formerly, in England and the United States, a bolting-mill of this description was used, in which the cylindrical bolter, put in circular motion with great celerity, consists of a kind of reel, framed in the following manner :-From a somewhat inclined axis, like radii, six arms or spokes project, which are con- nected with each other by six laths running parallel with the axis. This cylindrical frame is commonly, at the upper end, 221 inches diameter, but at the lower end only 201 inches, (in this case it is called taper-reel;) sometimes it is at both ends 221 inches diameter, in which case it is called an equal-reel. The wider cylindrical bolter encloses the frame, and is at both ends (which are lined with leather) fastened to it. In the bolting-hutch are placed six wooden beaters, whose points stand off half an inch from those of the spokes. Now, as soon as the bolting-cloth is swelled by the rotation and centrifugal power, it strikes violently upon these beaters, and thus the finer elements of the flour are forced through the sides of the bolter, while the grit and bran proceed along the whole bolter into the bran- chest at the outside of the bolting-hutch. Yet this bolting apparatus was not much adapted to the purpose, because the ends of the bolter could not be fixed firmly enough to prevent its unsteady, swinging motion, and its too violent striking upon the beaters, by which the bolting cloth soon became defective. However, at present this bolting- mill is substantially improved by James Ayton. Fig. 467 gives a side view of this improved machine, without the bolter, and without the front of the hutch. In the frame of the bolting-hutch a a, the apparatus is placed obliquely. By the axis bb, (made of forged iron,) and the disk c, the bolting-machine is brought in rotation. At the axis b b are fixed the two naves d and e, in a proper manner, and into both are placed four spokes ff, at right angles with each other. From each spoke to the corresponding opposite one, or from f to is distended a strip of bolting-cloth or duck g, 5 to 6 inches broad, fixed at the extremities of the spokes. The strips in the interior of the bolter form a kind of fanning-machine of about 20 inches diameter. Above the nave d is another one h, from which project six iron spokes, bent upwards, and connected with each other at their points by the wooden ring k, whose diameter is equal to that of the fanning-machine. Below the board partition 11, that separates the flour-hutch m from the bran-chest n, is a third nave o, from which project six steel springs p, whose points are bent into hooks, carefully rounded off and pol- ished, that the handles of the bolter (which are fixed to them) may be spared as much as possible. This nave, which by Fig. 468 is twice represented on a larger scale, consists of three hoops o qr, of which the inner q is fastened to the square axis bb; the middle o revolves round the hoop q, and the outer r is fastened to the hoop q by four screws. The bolter surrounding the fan-shaped reel is, by means of its handles at the lower end, fixed at the hooks of the six steel springs p; while its upper end, above the wooden ring k, is simply drawn to- gether by a cord or string. As soon as the reel is in rapid rotation, the pressure of the air, produced by the fans and the centrifugal power, will swell the bolter, which at the same time is kept at a uni- form concentric tension by the elasticity of the steel springs p. Another substantial improvement of Ayton's bolting-mill is, that the six beaters 8, lying round the bolter may, according to circumstances, be placed more or less near to it, even during the rotation. The manner of this arrangement may be perceived by Fig. 469, where the machinery, Fig. 467, is repre- sented in a view from behind or before. On the outside of each of the partitions 11 and tt, Fig. 467, is a broad iron ring 16, Fig. 469, revolving round the axis b, in the small furrows of the six cramps marked with v. In both of these rings (on the front and back) are cut six eccentric slits w w, behind which, in the board partitions, there are cut out as many other slits, like radii of the axis bb, so that both kinds of slits are crossing each other. The beaters 88, Fig. 467, are (by means of screws x) brought into con- nection with the slits in such a manner, that they are moved to and fro in the slits of the partitions 11 and tt, and thus approach and turn off from the bolter, as soon as the outside rings и (which are not connected with the axis bb itself) are turned round by the dented wheels y, Fig. 469. The whole perimeter of the rings is dented; only a part of it is shown in Fig. 469. The dented wheels are con- nected with another axis different from that marked with bb. Through the hopper 2, Fig. 467, is constantly running the ground grain as required for bolting; 80 that from the other end of the bolting-hutch only grit or bran, without mixture of flour, runs out. This improved bolting-mill has this substantial advantage over the older one-that the movement of the air within the bolter is produced by the fans instead of the reel, and drives the flour towards the periphery in a more complete manner. Thus the flour gets easily through the perforations of the bolting-cloth, whose obstruction is almost entirely prevented by the trembling motion of the steel springs p. The beaters are also arranged 80 that they cannot much wear out the bolter. While by the older machinery (with 170 to 200 rotations a minute) only two and a half to three sacks (measuring three bushels each) of grit are said to have been bolted in an hour, Ayton's improved mill bolts four sacks in the same time. Notwithstanding this favorable result, the improved bolting-mill is not much used, for the reason that the bolter (as the weakest and most expensive part) is yet damaged by the beaters. The cylindrical bolter has recently been supplanted by a hexagonal or octagonal one, with great success. Figs. 470 and 471 show the frame of this bolting-machine (which is in very general use in this coun- try) in longitudinal section and front view. The front partition is omitted, to get a better view of the interior. These bolters are made exclusively of silk bolting-cloth, manufactured by Harlem Star, in Holland. For two sets of five-feet millstones there are generally made bolters of 28 inches in diameter and of 90 feet in length, and of three different sorts of cloth that is, 60 feet of the finest sort, No. 10 or 11 24 feet of the middling sort, No. 5 or 9; and the remaining 6 feet (60+24+6=90) of the third or coarsest sort, No. 2, which latter is intended for separating the finer bran from the coarser. Digitized by Google BOLTING-MILL. 157 The cloth is tentered round wooden frames similar to the above-described reels, of hexagonal or oc- tagonal form, 20 inches in diameter, and from 18 to 20 feet in length. The cloth is fastened with pins to the wooden rings at both ends of the frame, and to six or eight laths running parallel with the axis, and resting on spokes. Such bolters, as a a, Figs. 470 and 471, are commonly placed four in one hutch bb, that is, two above and two below, as in Figs. 470 and 471. They are placed somewhat obliquely, and, by means of the mo- tive power cc, revolved all together by the wheel d of the axis, which also turns the wheel c. Each bolter makes generally 25 rotations in a minute. The flour-conveyers, f and g, are commonly put in motion by straps, (like the strap h, in Fig. 470,) they being highly adapted to the purpose, and more- over simple and cheap. The conveyers are intended to remove immediately the bolted flour from the butch of each pair of bolters without opening the hutch. The ground grain passes through the common plate-iron gutters ii into the two superior bolters, (where the cloth is of finer quality,) in such quantity as may be easily bolted by them. The mechan- ism applied for this purpose will be described below. The flour bolted in the upper half of these two bolters is somewhat finer than that bolted in their lower half, the former therefore being called extra- superfine, and the latter superfine. All this flour falls through the oblique partitions kk, Fig. 471, into the trough l of the upper conveyer. The wheels m n, Fig. 470, moving this conveyer, are covered by the roof o. The coarser parts, or the grit and bran, issuing from the mouth of the bolter, fall into the partition p of the bolting-hutch, and then, by means of the oblique board partition q, into the two lower bolters of coarser cloth a₁. Thence the bolted flour goes into the trough of the lower conveyers g, and the bran goes from the bolter's mouth through the gutter 8, Fig. 470, The above-mentioned extra-superfine flour is, by means of the conveyer f, pushed to the wooden chan- nel t, through which it then goes off into the flour-box, while the superfine flour is, by the channel и, conveyed into the upper partition of the hutch, enclosing the two lower bolters a₁ a₁. Hence, mixed with the flour of these bolters, it is by the lower conveyer g pushed to the channel v, through which it goes off into the meal-elevator, that brings it back to the hopper-boy. Thence, having been mingled with grit, it is conveyed once more into the bolter. In the case when the middling flour (or seconds) is ground for the second time, the flour bolted by the upper and lower bolters is intermixed and not reconveyed into the hopper-boy; but the gutter or channel v is shut, and the strap h (moving the conveyer crossed, which has the effect of conveying the flour to the gutter or channel w, (which then is to be shut up,) from whence it goes, together with the flour coming from the upper bolters down the gutter x, into the flour-box. The mechanism by which the ground grain or meal is conveyed into each of the two superior bolt- ers, is to be seen in Fig. 472, longitudinal section, and Fig. 473, front view, on a larger scale. The letter y marks a funnel, into which the ground mass falls down from a hopper-boy in a higher story, and thence upon the moveable spout a, resting on the axis 2. The channel i, Fig. 471, is connected with this spout. At the fore part of the spout's side-boards are the cross-rails ßB, by which, and by wedges, the sha- king-bolt r is fastened. At the upper mouth of the bolters is a cast-iron cross δ, Figs. 470 and 471, fastened to the axis, whose points are provided with heads, the forms of which may be seen by Figs. 471 and 472. During the rotation of the bolters, these heads touch upon the end point of the shaking- bolt γ, Fig. 472, which lifts the spout a up and down. Thus the spout is constantly in a shaking mo- tion, and the mass heaped in the funnel y is conveyed by the gutter i into the bolter a. By means of the shutter & the aperture at the bottom of the front partition of the funnel y can be widened or nar- rowed, according to circumstances. The conveyers f and g consist of a screw, as may be perceived by Fig. 474, where they are repre- sented on a larger scale. The chief part is commonly an octagonal strong wooden axis 1, round which, in a helix, are put small wooden square tables 2, 2, at right angles to the axis. These tables are generally 21 inches high and broad, and at the foot end half an inch thick, while the back lessens to a sharp edge. The front sides (which retain their right angle with the axis) take hold of the flour contained in the trough 3, and push it gradually on to the respective gutters. Beside the slides, shutting the gutters u, x, t, v, w, there are in the bottom of the conveyer-trough as many alides as possible, in order to prevent its obstruction during the movement of the conveyer. In the above-described bolters the pushing of the flour through the perforations of the bolting-cloth is produced in such a manner that the contents of the bolter are during its rotation cast up, and then by their own weight fall upon the under side of the bolter; whereas, in the following rotative bolters (which in all other respects are arranged like the other just mentioned) the bolting is effected by beaters or other similar instruments. By this arrangement, the obstruction of the perforations is prevented with more success. Figa 482 and 483 represent a bolter of this kind and its hutch in longitudinal and transverse sec- tions: and Figs. 484 and 485 represent the bolter in transverse section, and in a side view. The hex- agonal wooden axis is marked by a a. From each of its six flat sides project six cylindrical staves b, of hard timber, and one inch in diameter, and placed at the distance of two or three feet from each other. The staves of every row are at their points connected with each other by a lath c, over which the bolting-cloth is tentered, and to which it is fastened with pins. Upon each staff is put a little tube of east-iron, 11 to 2 pounds weight, 3 to 4 inches long, 2 inches in the outer diameter, and called beaters. During the rotation of the bolter, produced by the wheels e and f, Fig. 482, these beaters run up and down the staves, Fig. 484, and by their beating against the hard-wood supports g, Fig. 484, underneath the laths c, they prevent the obstruction of the perforations of the bolter. That the laths may not be knocked of by this beating, there are commonly laid round bands either of leather or thin hoop-iron, see hh, Fig. 485. While the lower end of the bolter is left open to let out the grit or bran, the upper end is provided with a wooden crown i, Figa. 482 and 483, whose interior diameter leaves only as much room as is re- quired for the plate-iron gutter k, Fig. 482, by which the ground mass goes into the bolter. The crown Digitized by Google 158 BOLTING-MILL. & 20 466. 463. 464. 8 100 KS 22 5 © 465. 474. 0 469. 468. 470. 472. 467. 21 473. 471. Digitized by Google. BOLTING-MILL. 159 i is provided with a funnel l of tin-plate, for the purpose of retaining the grit or flour within the bolter. A bolter of this kind is commonly from 16 to 26 feet long, and 24 to 30 inches diameter, and inclines in the ratio of one-fifteenth to one-eighth of its length. Its silk bolting-oloth is selected out of two to five, and even still more numbers. The first sort covers the greatest pat of the bolter from above, and then follow in succession the coarser qualities. According to the variety of the flour to be obtained, there are brought into connection with a set of 4 or 5 feet millstones, either one, or two, or more bolters, which are placed in the above manner, (see Figs. 470 and 471.) The most proper arrangement is, that the upper parts of the bolter (covered with the finer sorts of bolting-cloth) furnish the flour at once completely bolted, while the less fine grit of the other parts is to be ground and again bolted. The different qualities of flour or grit are taken up in separate partitions of the bolting-hutch, of which a simple arrangement is represented by Figs. 482 and 483. The partitions n separate the lower part of the bolting-hutch m m into the partitions 1, 2, 3, and 4, of which the first three take up three differ- ent sorts of flour, while the partition 4 takes up the grit or bran issuing from the mouth of the bolter, and has on its outside a hole (with the slide 0) through which the grit or bran comes out. The oblique tables pp. Fig. 483, leave below an opening from 6 to 12 inches wide, through which the bolted flour falls into the partitions. Each of the latter, 1, 2, and 3, is provided with a valve, consisting of a frame covered with cloth, (see q, Fig. 482,) and whose hinges are marked by rr. The valve may be kept open by fastening it to the buttons 8 8, Fig. 483. Another proper arrangement for taking up the flour or grit, is shown by Figs. 486 and 487. Here the bottom b of thesbolting-hutch a a, (which contains the same partitions as the other ones just described,) runs out in a slope sidewise, through which the flour falling from the bolter accumulates at the side- wall cc, Fig. 487, and thus runs easily through the opening d, into the bag f, as soon as the slide e is shut up. As many as convenient are placed before a flour-partition, Fig. 486. They are put up and taken away in the following simple manner At the sack-mouth i, beneath the opening d, on which rests the sloping bottom b, are put in two screws hh. Their ends are crooked into hooks which grasp the leather rim i of the sack. (See h beneath the opening d, Fig. 487.) About 3 or 5 feet above each sack projects a rafter k, from which hangs down a thong l, with forceps m and n, to take hold of the rim of the sack. It may be finally remarked, that it has been tried to supplant the beaters above described, (see Fig. 484,) by another contrivance represented by Figs. 488 and 489 in side and front views. The chief part consists of a thick steel button marked b, Fig. 488, fixed at the upper pivot of the bolter's axis b, Fig. 488. The steel button turns round on a strong and well-polished steel plate c, inserted into the pivot- base d. Now the axis in turning round is by the three protuberances lifted up and down, and thus constantly kept in a shaking motion. In this way the obstruction of the perforations of the bolting- cloth is prevented as well as by the beaters. The brush-bolter, or cylindrical dressing-machine, as it is styled, is in many mills used conjointly with Ayton's improved bolting-machine, into which latter the grit and bran is brought after they have been bolted in the dressing-machine. Fig. 475 gives a side view of the common brush-bolter, while Figs. 476 and 477 represent an im- proved machine of this kind in transverse and longitudinal section, several parts of which are illustrated by Figs. 478 and 479, (on a large scale,) and 480 and 481. The bolter, both of the common and improved machine, is cylindrical, covered by a bolting-cloth made of wire-texture, and placed obliquely in the bolting-hutch. (See Figs. 475, 476, and 477.) The bolting- cloth in Fig. 475 is directly fixed to the bolting-frame; but in Figs. 476 and 477 it is kept suspended by long screw-bolts qq, fixed at the roof of the bolting-hutch. (See Figs. 476, 477, 480, and 481.) The cylindrical sieve-frame of the common machine, Fig. 475, consists of staves bb, fixed round the disks ec and at the felloes d. The interior periphery of this frame is covered with wire-gauze of different fineness-the first number fixed at the upper end, and the less fine sorts following in succession, just in the same way as has been mentioned. The sieve-frame of the improved machine consists of two semi-cylinders, (see Figs. 477, 480, and 481,) whose side-boards e e are laid and screwed together, thus forming a full cylinder. Within this cylindrical sieve is, exactly in its axis, placed the shaft ff, (made of wrought-iron in the machines represented in Figs. 475 and 476,) which is provided with three disk-wheels g Fig. 477. On the periphery of these wheels are put in eight brushes of hog's bristles h, (see Figs. 478 and 479,) in the manner illustrated, not only by Fig. 477, but also by Fig. 478, where the wheel-periphery is marked by gg, and the brushes by hh; while the outer circle signifies the inner periphery of the cylindrical seve. The shaft ff. Fig. 477, is turned by the disk i, and during its rotation the brushes touch the inner periphery of the cylindrical sieve as much as required, to prevent the obstruction of the perforations by flour. In case the brushes should be worn, they can be screwed more forward by boxes k k, Fig. 478. At the upper and lower end of the cylindrical sieve are the wooden rings l and m, Fig. 477, fastened by means of screws. They are in the periphery somewhat notched, as may be seen by m, Fig. 481. To the upper ring 1, Fig. 477 is tied, by means of a cord, the leather strip n, which is glued or nailed on the bolting-hutch aa. By this arrangement the ground mass, coming out by the spout o, is taken up here, and conveyed to the cylinder. The ring m, at the lower end, serves as a link between the parti- tion-boards pp. In order to establish equality in the brushing of the sieve, this latter, or the cylindrical bolter, is, by means of four screw-bolts qq, kept in suspension, and may, according to circumstances, be wound up and lowered, for which purpose the nuts are winged. The screw-bolts are at their ends provided with hooks rr, Figa. 480 and 481, which take hold of two side-laths bb, Fig. 481, of the cylindrical frame of the sieve. On the other hand the brush-cylinder, whose shaft ff rests on the sliding-rail 8, can also be displaced, either up or down, by the nut of the screw t. The hopper, which holds the ground grain, is marked by u, Fig. 477, and the moveable spout con- Digitized by Google 160 BOLTING-MILL. m 72 a 484. 475. M 482. 485. + m a R B u e 480. S - 476. a m & 483. 70 m 12 0 481. a 20. R 19 Y - 3 = 17 h 477. 16 a 15 488. 486. $ h N 13 h 12 = a = A N $ + ⑉⑈ 479. h ** a 489. 487. 478. 28 Digitized by Google BOND. 161 nected with it by o. This spout is shaken by a nave v, fixed at the shaft ff, which beats during the rotation against a tack at the bottom of the shoe. By the slide at w, the quantity of ground grain in the shoe can be increased or decreased. The slide x, which in Fig. 477 is closed, is shut up in Fig. 476. A cylindrical sieve or bolter of this kind is commonly covered with four or five different numbers of wire-texture, through which the different qualities are bolted, and taken up by the corresponding par- titions 1, 2, 3, 4, and 5, whence the flour is easily taken out through the side-openings, until then closed by slides. The bran falls into the partition 6. The fineness of the texture is commonly in the ratio of 64, 60, 56, 38, and 16 meshes to the square inch. Experience has taught, that the best arrangement is to cover the frame from above, first with gauze or texture of 60 meshes, and to follow in succession that of 64, 56, 38, and 16 meshes. The gauze of 60 meshes furnishes as fine flour as that of 64, which is owing to the circumstance that the fleur in the uppermost part of the bolter is not 80 much exposed to the influence of the brushes, and that the finest quality of flour is more sticky or viscous than the coarser qualities. By the rotation in one and the same direction, the bristles of the brushes must at last be bent to one side, and thus lose their efficacy. To remedy this, an arrangement is made by which the brush-reel turns alternately to the right and left. This is easily effected by double wheels or thong-disks. A small brush-cylinder has been invented by James Murphy, of Zanesville, O, which is to be placed at the outside of the above-described cylindrical sieve, that is, everywhere on its periphery brushed by it. By this operation the obstruction of the meshes is completely prevented. Mr. Murphy uses thin hoops and ribs of cast-iron for constructing the sieve-frames, instead of the above-described wooden felloes and laths. BOLTS, (iron.) The pieces of iron used for securing framing together, and much employed in timber- work; they are formed of wrought-iron, either square or cylindrical, with a square head at one end, and a screw and nut at the other; a plate of iron, termed a washer, being interposed between the surface of the wood and the head and nut, to protect the former from damage during the process of screwing up. BOLSTERS. The pieces of timber used in the construction of the centres of arches, and running across from one rib to another, for the purpose of supporting the voussoirs. A piece of timber, em- ployed in a somewhat similar manner to a corbel, is also termed a bolster; which are much employed in timber bridges. BOND. The union or tie of the several stones or bricks forming a wall. The great principle in all bond is to provide against settlements: the vertical joints of a course should, therefore, be exactly midway between those below-in other words, break joint with them; and in no case should the joints of one course be carried up over those of the one below it. The bricks or stones lying lengthwise, in the longitudinal direction of the wall, are called stretchers; and those placed lengthwise across the wall, headers. 490 491. Old English Rond, or Block-bond. Flemish Bond. Bond may be described generally to be of three kinds. In English bond the courses are alternately all headers and all stretchers, and when the backs of each course are laid alternately header and stretcher it is called Flemish Bond; this description of tie is also known by the name of header and stretcher, particularly in stone-work. 493. 492. Cross-bond. Combined Cross and Block bond. The cross-bond-mostly used in Germany by bricklayers-differs from the old English or block bond, by the change of the second stretcher-line, 80 that the joints of the second come in the middle of the first, and the same position of stretchers comes back only every fifth line. This bond gives besides a very neat appearance, and is therefore used wherever a nice building is to be erected. The strongest tie is given to a wall by combining the block and cross-bond, so that the extrados is put up in cross- bond, the intrados in block bond, as shown in the figure. The reason of it is, if a settling of the wall happens, so that the joints open, all other bonds give only in the vertical, a crooked breaking line; but this combined-bond requires a crooked breaking-line in the horizontal direction besidec ; it is therefore applied where a neat appearance and great strength are required. 21 Digitized by Google 162 BORING MACHINE. BONES. See ANIMAL KINGDOM, materials from used in the mechanical and ornamental arts. BORING MACHINE, Vertical: by Messrs. Nasmyth, Gaskell & Co. The many advantages derived by this arrangement of a vertical boring machine over those where the work is placed in a horizontal position, may perhaps be unknown to persons unacquainted with the general character of machinery it may not be unadvisable to point out a few of the principal features showing the superiority of this machire. In the first place, the arrangements of its parts; the manner in which the cylinder is placed, namely, its vertical position, thereby doing away entirely with all the injurious effects produced by the weight of the body being planed or bored; thus obviating all tendency to distort its figure, which is the case where the operation is performed by the horizontal system, and where the sides are bulged out from the weight of the upper part; this may be better understood by forming a cylinder of thin paper, which will be found to widen in the middle and assume an oval form from its own weight. This alteration of form is found to be quite sensible when the cylinders are of large diameters. Another great advantage of this system of vertical boring, is avoiding all risk of flexure in the boring- bar, upon which the cutter wheel or head is fixed for carrying the boring-tools; this bar has a tendency to bend down in the centre to a curve, instead of keeping a perfectly straight line, transferring the figure assumed by the bar to the surface of the cylinder; but this will much depend both on its length and diameter. Another advantage of this machine is, that the cutters are kept clear of the borings, which fall to the bottom of the cylinder as fast as they are cut. By this superior arrangement all these objections are entirely removed, thus avoiding all the tendency gravity has in altering the trueness of the cylinder or the bar; added to these, the power requisite to bore the cylinder is found to be much less than in those placed horizontally, a very desirable object in a large establishment. A short description of its several parts will enable the reader more fully to understand the advanta- ges already alluded to. Fig. 494 represents a cross-section of this machine, and Fig. 497 a plan showing its position in a corner of the building where it is placed. In these two views it will be seen that the driving part of the machinery is situated below the ground-line on suitably strong foundations, in which it is enclosed. These parts are rendered accessible by the steps t, which are found to be necessary in cases where the machinery is likely to get out of order, a precaution never to be neglected. The two riggers k k receive their motion from the main shaft by means of a leather strap: one of these runs loose on the shaft, and the strap is thrown on it when the machine is not at work; this is done at pleasure with the greatest possible facility; by a bevel-wheel and pinion j, it is then conveyed through the shaft i to the endless worm n, working in a large worm-wheel o, which is fixed on the great vertical boring-bar a, whereby a very easy motion is obtained, and all jerks avoided. It will be seen by the series of wheels in Fig. 497, how much the speed of the boring-bar is reduced. The shaft i is placed at an angle, and works in a bearing or plummer block and a step h, both of these being made of brass. The vertical bar is made in two parts a and c, the upper one a for carrying the cutter-head or boring- wheel r, while to the lower one is connected the driving apparatus; they are coupled together by the upper one resting, as is shown in Fig. 496, in a socket on the top of the lower one; a steel key l is then driven in, which entirely prevents it from turning; the toe of the bar c rests in a step or socket shown by Fig. 498; the entire weight of this bar and its appendages is thrown on the hardened cast-steel disks s, which are constantly kept supplied with oil. Both extremities of the bar c are rendered ad- justable to the greatest possible accuracy by means of the small set-screws qq, Figs. 496 and 498, which, by being tightened, press against the conical brass segments, the upper one forming part of the great base or floor-plate b, which is materially strengthened by six strong ribs on its under side. The cross-beam g is well fitted to the sockets f, built into the wall of the building, where they are bolted by strong bolts, Figs. 494, 495, and 497. It has an additional stay in the bolt u. There are four standards or supports, dd, Fig. 494, for carrying the cylinder to be bored, which can be altered to any convenient position by unscrewing the bolts which fix them to the base-plate. After the cylinder has been properly placed in its right position, it is fixed to these supports by clamps e and bolts; and thus rendered quite immoveable. In the boring-bar a is a deep socket m, Fig. 494, which allows the bar to slide up and down by means of the screw P and the nut 1; upon the lower side of this socket is a flange m, upon which the cutter-head or wheel r rests, receiving its motion from the bar by means of a nut, answering both the purpose of nut and key. By the different arrangements of the sun and planet motion of the wheels on the upper part of the bar, any degree of motion can be given to the screw for the descent of the cutter- wheel. After the cylinder has been once bored through, the cutter-wheel is raised by means of a small crane, and the chains, Fig. 495, and by the peculiar arrangement of the nut l in the socket m, the cutter- wheel can be drawn up the cylinder without turning the screw p, as it leaves the nut behind, which is afterwards screwed up, there being no other weight to raise but that of the nut. The cutters are then set afresh to the new or finishing cut, after which the cylinder may be considered perfectly true. The position occupied by the crane enables the cylinder to be placed, and the bar lifted in and out with most perfect case; while the space occupied by this machine is very small compared with those where the work is performed horizontally it is, however, important that the base-plate b should be well secured to the foundations by strong bolts. The speed of this machine may very easily be varied, by having different-sized riggers or pulleys on the driving-shaft which conveys the motion to the riggers kk, Figs. 494 and 497. BORING MACHINE, Great. By Messrs. Nasmyth, Gaskell and Co. The machine represented by Fig. 499 is, with few exceptions, the same as that last described, where the cylinder to be bored is placed in a vertical position, whereby numerous advantages are derived, as already explained. The motion is communicated by the driving-pulley c to a bevel pinion working the bevel-wheel d; Digitized by Google BORING MACHINE. 163 495. 494. 9 I Elevation Plan 496. Section m 20 m T a c d 410 c Section 498. 2 a ###### 497. # nn Lo un 6 1 . Boring-bar. Cross-beam. R Screw working in wheel a b Foundation or base plate. Step or bearing for driving-shaft. 0 Screw-wheel. c Socket and lower part of upright i Driving-shaft. P Screw for regulating drilling-bar. bar. Bevel-wheel and pinion. q Adjusting-screws. d Movemble supports for carrying cyl- 7 Driving riggers. r Boring-wheel. inder to be bored. 1 Keys and nut. 8 Steel disks or pivots. e Clamps. 17. Socket upon which the cutter-wheel t Steps. f Socket for carrying the beam 8. rests. M Tie bar. Digitized by Google 164 BORING MACHINE. the shaft on which this wheel is fixed, has on its opposite end a worm for communicating the motion through the worm-wheel to the upright shaft f and boring-bar a, having on its circumference the grooves a' in which the cutter-head is moveable, sliding up and down according to the progress of the work k is a tool-carrier fixed to the cutter-head. The foundation plate h forms a bearing for the upright shaft, the lower end of which rests in the step g, while the cylinder l is secured by the clamps jj to the supports ii fixed to the foundation plate. These parts are in every respect similar to the boring ma- chine shown by Fig. 494, by which they are more fully described. Two strong piers of masonry m' support the entablature m, (for carrying the self-acting apparatus for raising and lowering the cutter-head b,) to which it is bolted by strong holding-down bolts m'. This apparatus consists of a rack n worked by a pinion, the motion being transmitted from a trullion-wheel through two spur-wheels and pinions o. The whole of this upper machinery revolves with the boring- bar, with the exception of the internal wheel or screwed hoop p; the consequence of which is, the small trullion-wheel is made to turn on its axis by the thread of the wheel p in which it works, and thereby ultimately raises the cutter-head b, the two side-slings connecting it to the upper frame q', to which is fixed the rack n. This machine is of the largest dimensions, and was made for the purpose of boring the large cylin- ders, 10 feet in diameter, for the Great Western Steam Navigation Company's vessel the Mammoth, at their works at Bristol 499. i l a Upright boring-bar. i Supports for carrying the cylinder to P Internal screw-wheel on the upper Ь Cutter-head working up and down be bored. [ports i. part of cutter-head conveying the in the three V's a'. j Clamps for fixing cylinder to sup- self-acting raising motion to it, by c Driving-pulleys fixed on shaft c'. k Tool-carrier fixed to cutter-head. the trullion-wheel and spur-wheels d Bevel-wheel and pinion for convey- 1 Cylinder being bored. and pinions #. ing the motion at right angles. Entablature for guiding the upper 9 Side-slings which convey the eleva- e Worm-wheel. part of bar, boll 1 to walls m by ting or cut-feeding motion from the Upright shaft for working boring-bar. bolts m". rack n down to the cutter-head b. Step for shaft. R Rack and pinion for raising the cut- All revolves with the boring-bar Foundation plate and boring-box ter-head, worked by spur-wheels except the internal screw-wheel or bearing, tightened by conical pieces and pinions o. screwed hoop p, which is stationa- and scrows k'. 0 Spur-wheels and pinions. ry, being bolted to the entablature. BORING MACHINE, Vertical. By Messrs. Benjamin Hick and Son, Bolton. By this combination of three distinct machines, the following different operations may be performed, viz. boring, drilling, and face-grinding: it is so contrived that the entablature b, supported by the four columns a a a a, carries Digitized by Google BORING MACHINE. 165 500. 6 3 B A C W 0 22 n n a Columns for supporting the entabla- to be bored moveable in grooves cutters) for giving it the feod or b Entablature. [ture b. in the foundation plate n. advancing motion. c Boring-bar of large machine. i Clamps or Caps for securing the cyl- I Second floor of the building, and on d Driving-pulleys worked by leather inder to the supports h. which is placed 8 crane for raising strap d. j Circular frame or ring for steadying or lowering the boring-bar when a e Bevel-wheel and pinion conveying the cylinder, which is adjusted to cylinder has to be placed or re- the motion to the upright shaft f its proper place by the set-screws moved. through the column a. this frame can be raised or lowered, - Footstep for boring-bar. f Upright shaft working in footstep f'. and is secured by bolts fitted into n Foundation plate. 8 Spur pinion and wheel for working grooves in the back of columns a. o Framing and beds of the side ma- the boring-bar c. k Racks and wheels attached to the chines on which the V slides o' h Supports for carrying the cylinder boring-block (containing the steel move. 501. O PO P Travelling tables for carrying the t Guide-frame for boring-bar of ma- ported by the two bracket car- work to be bored, &c. chine B, fixed between the two riages x" u". 9 Driving-pulleys for machines B and columns a a. D Chain pulleys and weight for raising C, worked by straps d. a Reversed cones, strap-shaft, and bev- the boring-bar u' supported by the r Cross-shaft, levers, and links, for oc- el-wheels, for giving the feeding two brackets o' v'. casionally raising the grinding-plate motion to the upright boring-bar % to Cylinder being bored. r, of machine C. by means of the screw x" attached x Crank being bored. s Cross-frame for carrying the brackets to its upper end. The shaft is sup- y Piston having its face ground. ' s' for supporting the shaft T. Digitized by Google 166 BORING TOOLS. the upper parts of the three different machines, consisting of the requisite driving machinery for com- municating to them their respective motions. That in the centre, A, is a vertical boring machine for boring cylinders of large diameters, which are fixed in the usual way on the six moveable supports h by the clamps i; in addition to which it is ren- dered perfectly steady by the circular frame or ring j, sliding up and down in grooves on the back of the two middle columns, the adjusting-screws j being tightened when the cylinder is properly placed under the centre of the boring-bar c, which receives its motion from the leather strap and pulleys d, whence it is conveyed through the bevel pinion and wheel e on the upright shaft f, upon which is also keyed the spur-pinion for driving the wheel g fixed to the lower part of the boring-bar c, and working in the step m; the rack and wheel k gives the cutter-head the requisite feed while boring out the cylinder. The six supports h are made to slide in grooves on the foundation plate n, according to the different diameters of the cylinders being operated upon; these, when properly placed, are bolted to the plate n. The second machine, B, is a vertical drilling and boring machine for work of smaller dimensions than the machine A. It is shown in the drawing boring out the centre of a crank x, fixed to the travelling table p, and slides on V's on the frame o', which has also a motion at right angles, on the bed o fixed to the foundation plate. The drilling-bar u' is lowered by the screw u" according to the feed, its mo- tion being conveyed to it from the pulley q and strap q' to a spur-wheel and pinion not shown in the drawing; the pinion is on the same spindle as the pulley, and the wheel on that of the reversed cone u, by which it is carried to the square-threaded screw 14" by two pairs of small bevel-wheels u, fixed on a horizontal spindle and working in suitable bearings on the carriages 26" u". The apparatus for raising the drilling-bar, Fig. 500, consists simply of two small chains fixed to the bar 26' and working round the pulleys, its opposite end being attached to a weight v. The third machine C, is for the purpose of grinding up the faces of rings for metallic pistons, conical valves, &c.; the travelling table p of this machine is in every respect similar to that of B, and upon it is placed the piston y to be ground; the upright rod, receiving its motion from the pulley and strap q', is kept in a vertical position by the cross-frame 8, while the shaft r and grinding-plate are connected to the lower end of the rod, and are occasionally raised for examining the surface being ground. The different motions given to these machines are quite independent the one of the other, by which means any one of them can be worked separately. The whole is placed on a suitable strong founda- tion of stone. After the large cylinder is bored, it is raised from its position by a crane placed on the floor above. BORING : and extraction of winding tools -Jumpers Widening -Lengthening of extraction of broken rods ;-accidents;-spring-bar;-head-piece;-clan;--plaform. See RAILWAY ENGINEERING. BORING TOOLS. The process of boring holes may be viewed as an inversion of that of turning: generally the work remains at rest, and the tool is revolved and advanced. Many of the boring and drilling tools have angular points, which serve alike for the removal of the material, and the guidance of the instrument; others have blunt guides of various kinds for directing them, whilst the cutting is performed by the end of the tool. Commencing as usual with the tools for wood, the brad-awl, Fig. 502, may be noticed as the most simple of its kind; it is a cylindrical wire with a chisel edge, which rather displaces than removes the material; it is sometimes sharpened with three facets as a triangular prism. The awl, Fig. 503, used by the wire-workers, is less disposed to split the wood; it is square and sharp on all four edges, and tapers off very gradually until near the point, where the sides meet rather more abruptly. The generality of the boring instruments used in carpentry are fluted, like reeds split in two parts, to give room for the shavings, and they are sharpened in various ways, as shown by Figs. 504 to 508. Fig. 504 is known as the shell-bit, and also as the gouge-bit, or quill-bit; it is sharpened at the end like 502. 503. 504. 505. 506. 507. 508. a gouge, and when revolved it shears the fibres around the margin of the hole, and removes the wood almost as a solid core. The shell-bits are in very general use, and when made very small, they are used for boring the holes in some brushes. Fig. 505, the spoon-bit, is generally bent up at the end to make a taper point, terminating on the diametrical line; it acts something after the manner of a common pointed drill, except that it possesses the keen edge suitable for wood. The spoon-bit is in very common use; the coopers' dowel-bit, and the table-bit, for making the holes for the wooden joints of tables, are of this kind. Occasionally the end is bent in a semicircular form; such are called duck- nose-bits from their resemblance, and also brush- bits from their use; the diameter of the hole con- tinues undiminished for a greater depth than with the pointed spoon-bit. The nose-bit, Fig. 506, called also the slit-nose-bit, and auger-bit, is slit up a small distance near the centre, and the larger piece of the end is then bent up nearly at right angles to the shaft, so as to act like a paring-chisel; and the corner of the reed. near the nose, also cuts slightly. The form of the nose-bit, which is very nearly a diminutive of the shell-auger, Fig. 507, is better seen in the latter instrument, in which the transverse cutter lies still more nearly at right angles, and is distinctly curved on the edge instead of radial. The augers are sometimes made three inches diameter, and upwards, Digitized by Google BORING TOOLS. 167 and with long removeable shanks, for the purpose of boring wooden pump-barrels; they are then called pump-bits. There is some little uncertainty of the nose-bits entering exactly at any required spot, unless a small commencement is previously made with another instrument, as a spoon-bit, a gouge, a brad-awl, a centre-punch, or some other tool; with augers a preparatory hole is invariably made, either with a gouge, or with a centre-bit exactly of the size of the auger. When the nose-bits are used for making the holes in sash bars, for the wooden pins or dowels, the bit is made exactly parallel, and it has a square brass socket which fits the bit; so that the work and socket being fixed in their respective situations, the guide-principle is perfectly applied. A "guide-tube" built up as a tripod, which the workman steadies with his foot, has been recently applied by Mr. Charles May, of Ipswich, for boring the auger-holes in railway sleepers exactly perpendicular. The gimlet, Fig. 508, is also a fluted tool, but it terminates in a sharp worm or screw, beginning as a point and extending to the full diameter of the tool, which is drawn by the screw into the wood. The principal part of the cutting is done by the angular corner intermediate between the worm and shell, which acts much like the auger. The gimlet is worked until the shell is full of wood, when it is unwound and withdrawn to empty it. The centre-bit, Fig. 509, shown in three views, is a very beautiful instrument; it consists of three parts, a centre-point or pin, filed triangularly, which serves as a guide for position; a thin shearing- point or nicker, that cuts through the fibres like the point of a knife; and a broad chisel-edge or cutter, placed obliquely to pare up the wood within the circle marked out by the point. The cutter shoul 1 have both a little less radius and less length than the nicker, upon the keen edge of which last the correct action of the tool principally depends. Many variations are made from the ordinary centre-bit, Fig. 509. 510. 11. 509; sometimes the centre-point is enlarged into a stout cylin- drical plug, so that it may exactly fill a hole previously made, and cut out a cylindrical countersink around the same, as for the head of a screw-bolt. This tool, known as the plug centre bit, is much used in making frames and furniture, held together a by screw-bolts. Similar tools, but with loose cutters inserted in a diametrical mortise, in a stout shaft, are also used in ship- building for inlaying the heads of bolts and washers, in the timbers and planking. b The wine-cooper's centre-bit is very short, and is enlarged behind into a cone, 80 that immediately a full cask has been bored, the cone plugs up the hole until the tap is inserted. The centre-bit deprived of its chisel-edge, or possessing only the pin and nicker, is called a button-tool; it is used for boring and cutting out, at one process, the little leather disks or buttons, which serve as nuts for the screwed wires in the mechanism connected with the keys of the organ and pianoforte. The expanding centre-bit, shown on a much smaller scale in Fig. 512, is a very useful instrument; it has a central stem with a conical point, and across the end of the stem is fitted a transverse bar adjustable for radius. When the latter carries only a lancet-shaped cutter it is used for making the margins of circular recesses, and also for cutting out disks of wood and thin materials generally; when, as in Mr. James Stone's modification, the 512. expanding centre-bit has two shearing-points or nickers, and one chisel-formed cutter, it serves for making grooves for inlaying rings of metal or wood in cabinet- work, and other purposes. The above twols being generally used for woods of the softer kinds, and the plankway of the grain, the shearing-point and oblique chisel of the centre-bit, Fig. 509, are constantly retained, but the corresponding tools used for the hard woods assume the characters of the hard-wood tools generally. For instance, a, Fig. 510, has a square point, also two cutting edges, which are nearly diametrical, and sharpened with a single chamfer at about 60 degrees; this is the ordinary drill used for boring the finger-holes in flutes an 1 clarionets, which are afterwards chamfered on the inner side with a stout knife, the edge of which measures about 50 degrees. The key-holes are first scored with the cup-key tool, b, and then drilled, the tools a and b being represented of corresponding sizes, and forming between them the annular ridge which indents the leather of the valve or key. When a, Fig. 510, is made exactly parallel and sharpened up the sides, it cuts hard mahogany very cleanly in all directions of the grain, and is used for drilling the various holes in the small machinery of pianofortes; this drill (and also the last two) is put in motion in the lathe; and in Fig. 511, the lathe- drill for hard woods, called by the French langue de carpe, the centre-point and the two sides melt into an easy curve, which is sharpened all the way round and a little beyond its largest part. Various tools for boring wood have been made with spiral stems, in order that the shavings may be enabled to ascend the hollow worm, and thereby save the trouble of so frequently withdrawing the bit. For example, the shaft of Fig. 513, the single-lip auger, is forged as a half-round bar, nearly as in the section above; it is then coiled into an open spiral with the flat side outwards, to constitute the cylin- drical surface, and the end is formed almost the same as that of the shell-auger, Fig. 507. The tristed gimlet, Fig. 514, is made with a conical shaft, around which is filed a half-round groove, the one edge of which becomes thereby sharpened, SO as gradually to enlarge the hole after the first penetration of the worm, which, from being smaller than in the common gimlet, acts with less risk of splitting. The ordinary screw-auger, Fig. 515, is forged as a parallel blade of steel, (seen in Fig. 516, which also refers to 515 and 517;) it is twisted red-hot, the end terminates in a worm by which the auger IS Digitized by Google 168 BORING TOOLS. gradually drawn into the work, as in the gimlet, and the two angles or lips are sharpened to cut at the extreme ends, and a little up the sides also. The same kind of shaft is sometimes made as in Fig. 516, with a plain conical point, with two scoring cutters and two chisel edges, which receive their obliquity from the slope of the worm it is as it were a double centre-bit, or one with two lips grafted on a spiral shaft. The same shaft has been also made, as in Fig. 517. with a common drill-point, and proposed for metal, but this seems scarcely called for ; 513. 514. 515. 516. 517. 518. 519. 520. but it is in this form very effective in Hunter's patent stone-boring machine, intended for stones not harder than sandstones; the drill is worked by a cross, guided by a tube, and forced in by a screw cut upon the shaft carrying the drill; so that the stone is not ground to powder, but cast off in flakes with very little injury to the drill. Another screw-auger, which is perhaps the most general after the double-lipped screw-auger, Fig. 515, is known as the American screw-auger, and is shown in Fig. 518; this has a cylindrical shaft, around which is brazed a single fin or rib; the end is filed into a worm as usual, and immediately be- hind the worm a small diametrical mortise is formed for the reception of a detached cutter, which ex- actly resembles the nicking-point and chisel-edge of the centre-bit; it may be called a centre-bit for deep holes. The parts are shown detached in Fig. 519. The loose cutter is kept central by its square notch, embracing the central shaft of the auger; it is fixed by a wedge driven in behind, and the chisel-edge rests against the spiral worm. Spare cutters are added in case of accident, and should the screw be broken off, a new screw and mortise may be made by depriving the instrument of 80 much of its length. This instrument will be found on trial extremely effective; and on account of the great space allowed for the shavings, they are delivered perfectly, until the worm is buried a small distance beneath the surface of the hole. The Americans have also invented an auger, thoroughly applicable to producing square holes, and those of other forms: the tool consists of a steel tube, of the width of the hole, the end of the tube is sharpened from within, with the corners in advance, or with four hollowed edges. In the centre of the square tube works a screw-auger, the thread of which projects a little beyond the end of the tube. 80 as first to penetrate the wood, and then to drag after it the sheath, and thus complete the hole at one process; the removed shavings making their escape up the worm and through the tube. For boring long mortises, two or more square augers are to be placed side by side, but they must necessarily be worked one at a time. The tools Figs. 513 to 520 are American. The screw-auger acts as a hollow taper-bit or rimmer, and the screw-form point and shaft assist in drawing it into the wood; but the instrument must pass entirely through for making cylin- drical holes. The most usual of the modes of giving motion to the various kinds of boring bits, is by the ordinary carpenter's brace with a crank-formed shaft. The instrument is made in wood or metal, and at the one extremity has a metal socket called the pad, with a taper square hole, and a spring catch used for retaining the drills in the brace when they are withdrawn from the work; and at the other it has a swiv- elled head or shield, which is pressed forward horizontally by the chest of the workman; or when used vertically, by the left hand, which is then commonly placed against the forehead. The ordinary carpenter's brace is too familiarly known to 521. require further description, but it sometimes happens, that in (orners and other places there is not room to swing round the handle; the angle brace, Fig. 521, is then convenient. It is made entirely of metal, with a pair of bevel pinions, and a winch-handle that is placed on the axis of one of these, at various distances from the centre, according to the power or velocity required. Sometimes the bevel-wheel attached to the winch-handle is three or four times the diameter of the pinion on the drill; this gives greater speed, but less power. Digitized by Google BORING TOOLS. 169 The augers, which from their increased size require more power, are moved by transverse handles some augers are made with shanks, and are riveted into the handles just like the gimlet; occasionally the handle has a socket or pad, for receiving several augers, but the most common mode is to form the end of the shaft into a ring or eye, through which the transverse handle is tightly driven. The brad- awls, and occasionally the other tools requiring but slight force, are fitted in straight handles; many of the smaller tools are attached to the lathe-mandrel by means of chucks, and the work is pressed against them, either by the hand, or by a screw, a slide, or other contrivance; Figs. 510 and 511 are always thus applied. Drills for metal, used by hand-The frequent necessity in metal works, for the operation of drilling holes, which are required of all sizes and various degrees of accuracy, has led to so very great a variety of modes of performing the process, that it is difficult to arrange with much order the more important of these methods and apparatus. The ordinary piercing drills for metal do not present quite so much variety as the wood drills ra- cently described. The drills for metal are mostly pointed; they consequently make conical holes, which cause the point of the drill to pursue the original line, and eventually to produce the cylindrical hole. The comparative feebleness of the drill-bow limits the size of the drills employed with it to about one- quarter of an inch in diameter; but as some of the tools used with the bow, agree in kind with those of much larger dimensions, it will be convenient to consider as one group, the forms of the edges of those drills which cut when moved in either direction. Figs. 522, 523, and 524, represent, of their largest sizes, the usual forms of drills proper for the re- ciprocating motion of the drill-bow, because their cutting edges being situated on the line of the axis, and chamfered on each side, they cut, or rather scrape, with equal facility in both directions of motion. 522. 523. 524. 525. 526. 527. Fig. 522 is the ordinary double-cutting drill; the two facets forming each edge meet at an angle of about 50 to 70 degrees, and the two edges forming the point meet at about 80 to 100; but the watch- makers, who constantly employ this kind of drill, sometimes make the end as obtuse as an angle of about 120 degrees; the point does not then protrude through their thin works, long before the comple- tion of the hole. Fig. 523, with two circular chamfers, bores cast-iron more rapidly than any other re- ciprocating drill, but it requires an entry to be first made with a pointed drill; by some, this kind is also preferred for wrought-iron and steel. The flat-ended drill, Fig. 524, is used for flattening the bottoms of holes. Fig. 525 is a duplex expanding drill, used by the cutlers for inlaying the little plates of metal in knife-handles; the ends are drawn full size. Fig. 526 is also a double-cutting drill; the cylindrical wire is filed to the diametrical line, and the end is formed with two facets. This tool has the advantage of retaining the same diameter when it is sharp- ened; it is sometimes called the Swiss drill, and was employed by M. Le Rivière, for making the nu- merous small holes in the delicate punching machinery for manufacturing perforated sheets of metal and pasteboard; these drills are sometimes made either semicircular or flat at the extremity, and as they are commonly employed in the lathe, they will be hereafter further noticed. The square countersink, Fig. 527, is also used with the drill-bow; it is made cylindrical, and pierced for the reception of a small central pin, after which it is sharpened to a chisel-edge, as shown. This countersink is in some measure a diminutive of the pin-drills, Figs. 534 to 537, and occasionally circular collars are fitted on the pin for its temporary enlargement, or around the larger part to serve as a stop, and limit the depth to which the countersink is allowed to penetrate, for inlaying the heads of screws. The pin is removed when the instrument is sharpened. By way of comparison with the double-cutting drills, the ordinary forms of those which only cut in one direction, are shown in Figs. 528, 529, and 530. Fig. 528 is the common single-cutting drill, for the drill-bow, brace, and lathe; the point, as usual, is nearly a rectangle, but is formed by only two facets, which meet the sides at about 80° to 85° and therefore lie very nearly in contact with the extremity of the hole operated upon, thus strictly agreeing with the form of the turning tools for brass. Fig. 529 is a similar drill, particularly suitable for horn, tortoise-shell, and substances liable to agglutinate and clog the drill; the chamfers are rather more acute, and are continued around the edge behind its largest diameter, so that if needful, the drill may also cut its way out of the hole. Fig. 530, although never used with the drill-bow, nor of so small a size as in the wood-cut, is added to show how completely the drill proper for iron, follows the character of the turning tools for that metal; the flute or hollow filed behind the edge, gives the hook-formed acute edge required in this tool, which is in other respects like Fig. 528; the form proper for the cutting edge is shown more distinctly in the diagram a, Fig. 534. 22 Digitized by Google 170 BORING TOOLS. Care should always be taken to have a proportional degree of strength in the shafts of the drills, otherwise they tremble and chatter when at work, or they occasionally twist off in the neck; the point should be also ground exactly central, 80 that both edges may be cut. As a guide for the proportional thickness of the point, it may measure at b, Fig. 531, the base of the cone, about one-fifth the diameter of the hole; and at p, the point, about one-cighth, for easier penetration: but the fluted drills are made nearly of the same thickness at the point and base. 528. 529. 530. 531. 532. 533. B p In all the drills previously described, except Fig. 526, the size of the point is lessened each time of sharpening; but to avoid this loss of size, a small part is often made parallel, as shown in Fig. 531. In Fig. 532, this mode is extended by making the drill with a cylindrical lump, SO as to fill the hole; this is called the recentering-drill. It is used for commencing a small hole in a flat-bottomed cylindrical cavity or else, in rotation with the common piercing-drill, and the half-round bit, in drilling small and very deep holes in the lathe. Fig. 532 may be also considered to resemble the stop-drill, upon which a solid lump or shoulder is formed, or a collar is temporarily attached by a side-screw, for limiting the depth to which the tool can penetrate the work. Fig. 533, the cone-countersink, may be viewed as a multiplication of the common single-cutting drill Sometimes, however, the tool is filed with four equidistant radial furrows, directly upon the axis, and with several intermediate parallel furrows sweeping at an angle around the cone. This makes a more even distribution of the teeth than when all are radial as in the figure, and it is always used in the spherical cutters or countersinks known as cherries, which are used in making bullet-moulds. On comparison, it may be said, the single-chamfered drill, Fig. 528, cuts more quickly than the double- chamfered, Fig. 522, but that the former is also more disposed of the two to swerve or run from its intended position. In using the double-cutting drills, it is also necessary to drill the holes at once to their full sizes, as otherwise the thin edges of these tools stick abruptly into the metal, and are liable 534. 535. 536. 537. a to produce jagged or groovy surfaces, which destroy the circularity of the holes; the necessity for drill- ing the entire hole at once, joined to the feebleness of the drill-bow, limits the size of these drills. In using the single-chamfered drills it is customary, and on several accounts desirable, to make large holes by a series of two or more drills; first the run of the drill is in a measure proportioned to its diameter, therefore the small tool departs less from its intended path, and a central hole once obtained, it is followed, with little after-risk, by the single-cutting drill, which is less penetrative. This mode likewise throws out of action the less favorable part of the drill near the point, and which in large drills is necessarily thick and obtuse the subdivision of the work enables a comparatively small power to be used for drilling large holes, and also presents the choice of the velocity best suited to each progressive diameter operated upon. But where sufficient power can be obtained, it is generally more judicious to enlarge the holes previously made with the pointed-drills, by some of the group of pin-drills, Figs. 534 to 537, in which the guide-principle is very perfectly employed: they present a close analogy to the plug centre-bit and the expanding centre bit used in carpentry. The ordinary pin-drill, Fig. 534, is employed for making countersinks for the heads of screw-bolts in laid flush with the surface, and also for enlarging holes commenced with pointed drills, by a cut parallel with the surface; the pin-drill is also particularly suited to thin materials, as the point of the ordinary Digitized by Google BORING TOOLS. 171 drill would soon pierce through, and leave the guidance less certain. When this tool is used for iron it is fluted as usual, and a represents the form of the one edge separately. Fig. 535 is a pin-drill, principally used for cutting out large holes in cast-iron and other plates. In this case the narrow cutter removes a ring of metal, which is, of course, a less laborious process than cutting the hole into shavings. When this drill is applied from both sides it may be used for plates half an inch and upwards in thickness; as, should not the tool penetrate the whole of the way through, the piece may be broken out, and the rough edges cleaned with a file or a broach. Fig. 536 is a tool commonly used for drilling the tube-plates for receiving the tubes of locomotive- boilers: the material is about t inch thick, and the holes 14 diameter. The loose cutter a is fitted in a transverse mortise, and secured by a wedge; it admits of being several times ground before the notch which guides the blade for centrality is obliterated. Fig. 587 is somewhat similar to the last two, but is principally intended for sinking grooves and when the tool is figured, as shown by the dotted line, it may be used for cutting bosses and mouldings on parts of work not otherwise accessible. Many ingenious contrivances have been made to insure the dimensions and angles of tools being ex- actly retained. In this class may be placed Mr. Roberts' pin-drill, Figs. 538 and 539; in action it re- sembles the fluted pin-drill, Fig. 534, but the iron stock is much heavier, and 538. 539. is attached to the drilling-machine by the square tang; the stock has two grooves at an angle of about 10 de- grees with the axis, and rather deeper behind than in front. Two steel cut- ters, or nearly parallel blades, repre- sented black. are laid in the groves; they are fixed by the ring and two set- screws 88, and are advanced, as they become worn away, by two adjusting-screws aa, (only one seen,) placed at the angle of 10 degrees through the second ring; which, for the convenience of construction, is screwed upon the drill-shaft just beyond the square tang whereby it is attached to the drilling- machine. The cutters are ground at the extreme ends, but they also require an occasional touch on the oilstone to restore the keenness of the outer angles, which become somewhat rounded by the friction. The diminution from the trifling exterior sharpening, is allowed for by the slightly taper form of the blades. The process of drilling generally gives rise to more friction than that of turning, and the same meth- ods of lubrication are used, but rather more commonly and plentifully; thus oil is used for the generality of metals-or from economy, soap and water; milk is the most proper for copper, gold, and silver; and cast-iron and brass are usually drilled without lubrication. For all the above-named metals, and for alloys of similar degrees of hardness, the common-pointed steel drills are generally used but for lead and very soft alloys, the carpenters' spoon-bits and nose-bits are usually employed, with water. For hardened steel, and hard crystalline substances, copper or soft-iron drills, such as Figs. 529 or 530, sup- plied with emery-powder and oil, are needed; or the diamond drill-points, Figs. 531, 532, and 533, are used for hardened steel, with oil alone. Having considered the most general forms of the cutting parts of drills, we will proceed to explain the modes in which they are put in action by hand-power, beginning with those for the smallest diame- ters, and proceeding gradually to the largest. Methods of Working Drills by Hand smallest holes are those required in watch-work, and the general form of the drill is shown on a large scale in Fig. 540; it is made of a piece of steel wire, which is tapered off at the one end, flattened with the hammer, and then filed 540. up in the form shown at large in Fig. 522; lastly, it is hardened in the candle. The re urse end of the instrument is made into a conical point, and is also hardened; near this end is attached a little brass sheave for the line of the drill-bow, which, in watchmaking, is sometimes a fine horsehair, stretched by a piece of whalebone of about the size of a goose's quill stripped of its feather. The watchmaker holds most of his works in the fingers, both for fear of crushing them with the table-vice, and also that he may the more sensibly feel his operations; drilling is likewise performed by him in the same manner. Having passed the bowstring around the pulley in a single loop, (or with a round turn.) the centre of the drill is inserted in one of the small centre-holes in the sides of the table- vice, and the point of the drill is placed in the mark or cavity made in the work by the centre-punch; the object is then pressed forward with the right hand, whilst the bow is moved with the left. Clockmakers, and artisans in works of similar scale, fix the object in the tail-vice, and use drills, such as Fig. 540, but often larger and longer; they are pressed forward by the chest, which is defended from injury by the breastplate, namely, a piece of wood or metal about the size of the hand. in the middle of which is a plate of steel, with centre holes for the drill. The breastplate is sometimes strapped round the waist, but is more usually supported with the left hand, the fingers of which are ready to catch the drill should it accidentally slip out of the centre. As the drill gets larger the bow is proportionably increased in stiffness, and eventually becomes the half of a solid cone, about one inch in diameter at the larger end, and 30 inches long; the catgut string is sometimes nearly an eighth of an inch in diameter, or is replaced by a leather thong. The string is attached to the smaller end of the bow by a loop and notch, much the same as in the archery- bow, and is passed through a hole at the larger end, and made fast with a knot; the surplus length is wound round the cane, and the cord finally passes through a notch at the end, which prevents it from uncoiling. Digitized by Google 172 BORING TOOLS. Steel bows are also occasionally used these are made something like a fencing-foil, but with a hook at the end for the knot or loop of the cord, and with a ferrule or a ratchet, around which the spare cord is wound. Some variations also are made in the sheaves of the large drills; sometimes they are cylin- drical with a fillet at each end; this is desirable, as the cord necessarily lies on the sheave at an angle, in fact in the path of a screw; it pursues that path, and with the reciprocation of the drill-bow the cord traverses, or screws backwards and forwards upon the sheave, but is prevented from sliding off by the fillet. Occasionally, indeed, the cylindrical sheave is cut with a screw coarse enough to receive the cord, which may then make three or four coils for increased purchase, and have its natural screw-like run without any fretting whatever; but this is only desirable when the holes are large and the drill is almost constantly used, as it is tedious to wind on the cord for each individual hole. The structure of the bows, breastplates, and pulleys, although often varied, is sufficiently familiar to be understood without figures. When the shaft of the drill is moderately long, the workman can readily observe if the drill is square with the work as regards the horizontal plane; and to remove the necessity for the observation of an assistant as to the vertical plane, a trifling weight is sometimes suspended from the drill-shaft by a metal ring or hook; the joggling motion shifts the weight to the lower extremity the tool is only hori- zontal when the weight remains central. In many cases, the necessity for repeating the shaft and pulley of the drill is avoided, by the em- ployment of holders of various kinds, or drill-stocks, which serve to carry any required number of drill- points. The most simple of the drill- stocks is shown in Fig. 541; it has a 541. the centre and pulley of the ordinary drill, but the opposite end is pierced with a nearly cylindrical hole, just at the inner extremity of which a dia- 542. metrical notch is filed. The drill is shown separately at a; its shank is made cylindrical, or exactly to fit the hole, and a short portion is nicked down also to the diametrical line, so as to slide into the gap in the drill-stock, by which the drill is prevented from revolving; the end serves also as an abutment whereby it may be thrust out with a lever. Sometimes a diametrical transverse mortise, narrower than the hole, is made through the drill-stock, and the drill is nicked in on both sides; the cylindrical hole of 541, should be continued to the bottom of the notch, the end of the drill should be filed off obliquely, and it should be prevented from rotating, by a pin inserted through the cylindri- cal hole parallel with the notch; the taper end of the drill would then wedge fast beneath the pin. Drills are also frequently used in the drilling-lathe; this is a miniature lathe-head, the frame of which is fixed in the table-vice; the mandrel is pierced for the drilla, and has a pulley for the bow, therein resembling Fig. 542, except that it is used as a fixture. The Fig. 542 just referred to, represents one variety of another common form of the drill-stock, in which the revolving spindle is fitted in a handle, so that it may be held in any position, without the necessity for the breastplate; the handle is hollowed out to serve for containing the drills, and is fluted to assist the grasp. Fig. 543 represents the socket of a universal drill-stock," invented by Sir John Robinson it is pierced with a hole as large as the largest 543. of the wires of which the drills are formed, and the hole terminates in an acute hollow cone. The end of the drill-stock is tapped with two holes, placed on a diameter; the one screw, a, is of a very fine thread, and has at the end two shallow diametrica' notches; the other, b, is of a coarser thread and quite flat at the extremity. The wire-drill is placed against the bottom of the hole, and allowed to lean against the adjusting-screw a, and if the drill be not central, this screw is moved one or several quarter-turns, until it is adjusted for centrality; after which the tool is strongly fixed by the plain set-screw b. Fig. 544 is a drill-stock, contrived by Mr. William Allen: it consists of a tube, the one end of which has a fixed centre and pulley much the same as usual; the opposite end of the tube has a piece of steel fixed into it, which is first drilled with a central hole, and then turned as a conical screw, to which is fitted a corresponding screw-nut n; the socket is then sawn down with two diametrical notches, to make four internal angles, and lastly, the socket is hardened. When the four sections are compressed by the nut, their edges stick into the drill and retain it fast, and provided the instrument is itself con- centric, and the four parts are of equal strength, the centrality of the drill is at once ensured. The out- side of the nut, and the square hole in the key k, are each taper, for more ready application; and the drills are of the most simple kind, namely, lengths of wire pointed at each end, as in Fig. 545. The sketch, Fig. 544, is also intended to explain another useful application of this drill-stock, as an up- right or pump drill, a tool little employed in this country, (except in drilling the rivet-holes for mending china and glass, with diamond drill,) but as well known among the oriental nations as the breast-drill. Digitized by Google BORING TOOLS. 173 Holes that are too large to be drilled solely by the breast-drill and drill-bow, are frequently com- menced with those useful instruments, and are then enlarged by means of the hand-brace, which is very similar to that used in carpentry, except that it is more commonly made of iron instead of wood, is somewhat larger, and generally made without the spring-catch. Holes may be extended to about half an inch diameter, with the hand-brace; but it is much more expeditious to employ still larger and stronger braces, and to press them into the work in various ways by weights, levers, and screws, instead of by the muscular effort alone. Fig. 546 represents the old smith's press-drill, which although cumbrous, and much less used than formerly, is nevertheless simple and effective. It consists of two pairs of wooden standards, between which works the beam a b; the pin near a is placed at any height, but the weight to is not usually changed, as the greater or less pressure for large and small drills, is obtained by placing the brace more or less near to the fulcrum a; and this part of the beam is shod with an iron plate, full of small centre- holes for the brace. The weight is raised by the second lever cd, the two being united by a chain, and a light chain or rope is also suspended from d, to be within reach of the one or two men engaged in moving the brace. It is necessary to relieve the weight when the drill is nearly through the hole, otherwise it might suddenly break through, and the drill becoming fixed, might be twisted off in the neck. 546. d 547. a 0 R 0 8 The inconveniences in this machine are, that the upper point of the brace moves in an arc instead of a right line the limited path when strong pressures are used, which makes it necessary to shift the fulcrum a; and also the necessity for readjusting the work under the drill for each different hole, which in awkwardly-shaped pieces is often troublesome. A portable contrivance of similar date, is an iron bow-frame or clamp, shown in Fig. 547 the pressure is applied by a screw, but in almost all cases, whilst the one individual drills the hole, the assistance of another is required to hold the frame; Fig. 547 only applies to comparatively thin parallel works, and does not present the necessary choice of position. Another tool of this kind, used for boring the side-holes in cast-iron pipes for water and gas, is doubtless familiarly known; the cramp or frame divides into two branches about two feet apart, and these terminate like hooks, which loosely embrace the pipe, 80 that the tool retains its position without constraint, and it may be used with great facility by one individual. Fig 548 will serve to show the general character of various con- 548. structions of more modern apparatus, to be used for supplying the pressure in drilling holes with hand-braces. It consists of a cylin- drical bar a, upon which the horizontal rectangular rod b is fitted z 0 with a socket, so that it may be fixed at any height, or in any angular position, by the set-screw c. Upon b slides a socket, which d is fixed at all distances from a, by its set-screw d; and lastly, this socket has a long vertical screw e, by which the brace is thrust into the work. d The object to be drilled having been placed level, either upon the ground, on trestles, on the work-bench, or in the vice, according to circumstances, the screws c and d are loosened, and the brace is put in position for work. The perpendicularity of the brace is then examined with a plumb-line, applied in two positions, (the eye being first directed as it were along the north and south line, and then along the east and west,) after which the whole is made fast by the screws c and d. The one hole having been drilled, the socket and screws present great facility in readjusting the instru- ment for subsequent holes, without the necessity for shifting the work, which would generally be attended with more trouble than altering the drill-frame by its screws. Sometimes the rod a is rectangular, and extends from the floor to the ceiling; it then traverses in fixed sockets, the lower of which has a set-screw for retaining any required position. In the tool represented, the rod a terminates in a cast-iron base, by which it may be grasped in the tail-vice, or when required it may be fixed upon the bench. In this case the nut on a is unscrewed; the cast-iron plate, when reversed and placed on the bench, serves as a pedestal; the stem is passed through a hole in the bench, and the nut and Digitized by Google 174 BORING TOOLS. washer, when screwed on the stem beneath, secure all very strongly together. Even in establishments where the most complete drilling machines driven by power are at hand, modifications of the press-drill are among the indispensable tools: many are contrived with screws and clamps, by which they are attached directly to such works as are sufficiently large and massive to serve as a foundation. Various useful drilling tools for engineering works, are fitted with left-hand screws, the unwinding of which elongate the tools; so that for these instruments which supply their own pressure, it is only necessary to find a solid support for the centre. They apply very readily in drilling holes within boxes and panels, and the abutment is often similarly provided by projecting parts of the castings; or other- wise the fixed support is derived from the wall or ceiling, by aid of props arranged in the most conve. nient manner that presents itself. Fig. 549 is the common brace, which only differs from that in Fig. 548 in the left-hand screw ; a right- hand screw would be unwound in the act of drilling a hole when the brace is moved round in the usual direction, which agrees with the path of a left-hand screw. The cutting motion produces no change in the length of the instrument, and the screw being held at rest for a moment during the revolutic n, sets in the cut but towards the last, the feed is discontinued, as the elasticity of the brace and work suffice for the reduced pressure required when the drill is nearly through, and sometimes the screw is unwound still more to reduce it. 549. 550. 551. 553. The lever-drill, Fig. 550, differs from the latter figure in many respects; it is much stronger, and ap- plicable to larger holes; the drill-socket is sufficiently long to be cut into the left-hand screw, and the piece serving as the screwed nut, is a loop terminating in the centre point. The increased length of the lever gives much greater purchase than in the crank-form brace, and in addition the lever-brace may be applied close against a surface where the crank-brace cannot be turned round; in this case the lever is only moved a half circle at a time, and is then slid through for a new purchase, or sometimes a span- ner or wrench is applied directly upon the square drill-socket. The same end is more conveniently fulfilled by the ratchet-drill, Fig. 551, apparently derived from the last; it is made by cutting ratchet-teeth in the drill-shaft, or putting on the ratchet as a separate piece, and fixing a pall or detent to the handle; the latter may then be moved backward to gather up the teeth, and forward to thrust round the tool, with less delay than the lever in Fig. 550, and with the same power, the two being of equal length. This tool is also peculiarly applicable to reaching into angles and places in which neither the crank- form brace nor the lever-drill will 554. apply. Fig. 552, the ratchet-lever, in part resembles the ratchet-drill, but the pressure screw of the latter in- strument must be sought in some of the other contrivances referred to, as the ratchet-lever has simply a square WAS aperture to fit on the tang of the drill d, which latter must be pressed forward by some independent means. Fig. 553, which is a simple but 555. necessary addition to the braces and drill tools, is a socket having at the one end a square hole to receive the drills, and at the opposite, a square tang to fit the brace; by this con- trivance the length of the drill can be temporarily extended for reaching deeply-seated holes. The sockets are made of various lengths, and sometimes two or three are used together, to extend the length of the brace to suit the position of the prop; but it must be remembered, that with the additional length the tortion becomes much increased, Digitized by Google BORING TOOLS. 175 and the resistance to end-long pressure much diminished, therefore the sockets should have a bulk proportionate to their length. The French brace, Fig. 521, is also constructed in iron, with a pair of equal bevel-pinions, and a left- hand centre-screw like the tools, Figs. 549, 550, and 551 ; it is then called the corner-drill. Sometimes, also, as in the succeeding Figs. 554 and 555, the bevel-wheels are made with a hollow square or axis, as in the ratchet-lever, Fig. 552 the driver then hangs loosely on the square shank of the drill-tool, or cutter-bar, and when the pinion on the handle is only one-third or fourth of the size of the bevel-wheel with the square hole, it is an effective driver for various uses; the long tail or lever serves to prevent the rotation of the driver, by resting against some part of the work or of the work-bench. All the before-mentioned tools are commonly found in a variety of shapes in the hands of the engineer, but it will be observed they are all driven by hand-power, and are carried to the work. I shall conclude this section with the description of a more recent drill-tool of the same kind. This instrument is represented of one-eighth size, in the side view, Fig. 556, in the front view, 557, and in the section, 558; it is about twice as powerful as Fig. 555, and has the advantage of feeding the 556. 557 558. 8 B cut by a difforential motion. The tangent-screw moves at the same time the two worm-wheels a and b; the former has fifteen teeth, and serves to revolve the drill; the latter has 16 teeth, and by the difference between the two, or the odd tooth, advances the drill slowly and continually, which may be thus explained. The lower wheel a, of 15 teeth, is fixed on the drill-shaft, and this is tapped to receive the centre- screw c, of four threads per inch. The upper wheel of 16 teeth is at the end of a socket d, (which is represented black in the section Fig. 558,) and is connected with the centre-screw c, by a collar and internal key, which last fits a longitudinal groove cut up the side of the screw c; now therefore the internal and external screws travel constantly round, and nearly at the same rate, the difference of one tooth in the wheels serving continually and slowly to project the screw c, for feeding the cut. To shorten or lengthen the instrument rapidly, the side-screw e is loosened; this sets the collar and key free from the 16 wheel, and the centre-screw may for the time be moved independently by a spanner. The differential screw-drill, having a double thread in the large worm, shown detached at f, requires if turns of the handle to move the drill once round, and the feed is one 64th of an inch for each turn of the drill; that being the sum of 16 by 4. Drilling and Boring Machines.-The motion of the lathe-mandrel is particularly proper for giving action to the various single-cutting drills referred to; they are then fixed in square or round hole drill- chucks which screw upon the lathe-mandrel. The motion of the lathe is more uniform than that of the hand- nols, and the popit-head, with its flat boring-flange and pressure-screw, form a most convenient arrangement, as the works are then carried to the drill exactly at right angles to the face. But in drilling very small holes in the lathe, there is some risk of unconsciously employing a greater pressure with the screw, than the slender drills will bear. Sometimes the cylinder is pressed forward by a horizontal lever fixed on a fulcrum; at other times the cylinder is pressed forward by a spring, by a rack and pinion motion, or by a simple lever, and the best arrangement of this latter kind is that next to be described. In the manufacture of harps there is a vast quantity of small drilling, and the pressure of the cylinder popit-head is given by means of a long, straight, double-ended lever, which moves horizontally, (at about one-third from the back extremity,) upon a fixed post or fulcrum erected upon the backboard of the lathe. The front of the lever is connected with the sliding cylinder by a link or connecting rod, and the back of the lever is pulled towards the right extremity of the lathe, by a cord which passes over a pulley at the edge of the backboard, and then supports a weight of about twenty pounds. Both the weight and the connecting-rod may be attached at various distances from the fixed fulcrunn between them. When they are fixed at equal distances from the axis of the lever, the weight, if twenty pounds, presses forward the drill with twenty pounds, less a little friction; if the weight be two inches from the fulcrum and the connecting-rod eight inches, the effect of the weight is reduced to five pounds; if, on the other hand, the weight be at eight and the connecting-rod at two inches, the pressure is fourfold, or eighty pounds. The connecting-rod is full of holes, 80 that the lever may be adjusted exactly to reach the body of the workman, who, standing with his face to the mandrel, moves the lever with his back, and has therefore both hands at liberty for managing the work. Sometimes a stop is fixed on the cylinder, for drilling holes to one fixed depth; gages are attached to the flange for drilling numbers of similar pieces Digitized by Google 176 BORING TOOLS. at any fixed distance from the edge: in fact, this very useful apparatus admits of many little additions to facilitate the use of drills and revolving cutters. Great numbers of circular objects, such as wheels and pulleys, are chucked to revolve truly upon the lathe-mandrel, whilst a stationary drill is thrust forward against them, by which means the concentricity between the hole and the edge is ensured. The drills employed for boring works chucked on the lathe, have mostly long shafts, some parts of which are rectangular or parallel, so that they may be prevented from revolving by a hook-wrench, a spanner, or a hand-vice, applied as a radius, or by other means. The ends of the drill-shafts are pierced with small centre-holes, in order that they may be thrust forward by the screw of the popit-head, either by hand or by self-acting motion; namely, a connection between either the mandrel or the prime mover of the lathe, and the screw of the popit-head, by cords and pulleys, by wheels and pinions, or other contrivances. The drills, Figs. 528 and 530, are used for boring ordinary holes; but for those requiring greater accuracy, or a more exact repetition of the same diameter, the lathe-drills, Figs. 559 to 562, are commonly selected. Fig. 559, which is drawn in three views and to the same scale as the former examples, is called the half-round bit, or the cylinder-bit. The extremity is ground a little inclined to the right angle, both horizontally and vertically, to about the extent of three to five degrees. It is necessary to turn out a shallow recess exactly to the diameter of the end of the bit as a commencement, the circular part of the bit fills the hole, and is thereby retained central, whilst the left angle removes the shaving. This tool should never be sharpened on its diametrical face, or it would soon cease to deserve its appellation of half-round bit: some indeed give it about one-thirtieth more of the circum- ference. It is generally made very slightly smaller behind, to lessen the friction; and the angle, not intended to cut, is a little blunted half-way round the curve, that it may not scratch the hole from the pressure of the cutting edge. It is lubricated with oil for the metals generally, but is used dry for hard woods and ivory, and sometimes for brass. 559. 560. 561. 562. 563. The rose-bit, Fig. 560, is also very much used for light finishing cuts, in brass, iron, and steel the extremity is cylindrical, or in the smallest degree less behind, and the end is cut into teeth like a countersink; the rose-bit, when it has plenty of oil, and but very little to remove, will be found to act beautifully, but this tool is less fit for cast-iron than the bit next to be described. The rose-bit may be used without oil for the hard woods and ivory, in which it makes a very clean hole; but as the end of the tool is chamfered, it does not leave a flat-bottomed recess the same as the half-round bit, and is therefore only used for thoroughfare holes. The drill, Fig. 561, is much employed, but especially for cast-iron work; the end of the blade is made very nearly parallel; the two front corners are ground slightly rounding, and are chamfered; the chamfer is continued at a reduced angle along the two sides, to the extent of about two diameters in length; this portion is not strictly parallel, but is very slightly largest in the middle, or barrel-shaped: this drill is used dry for cast-iron. Fig. 561, in common with all drills that cut on the side, may, by improper direction, cut sidewise, making the hole above the intended diameter; but when the hole has been roughly bored with a common fluted drill, the end of the latter is used as a turning tool, to make an accurate chamfer; the bit 561 is then placed through the stay as shown in Fig. 562, and is lightly supported between the chamfer upon the work and the centre of the popit-head: the moment any pressure comes on the drill, its opposite edges stick into the inner sides of the loop, which thus restrains its position; much the same as the point and edges of the turning tools for iron dig into the rest, and secure the position of those tools. It is requisite the drill and the loop should be exactly central. Fig. 562 shows the common form of the stay when fitted to the lathe-rest, but it is sometimes made as a swing-gate, to turn aside, whilst the piece which has been drilled is removed, and the next piece to be operated upon is fixed in the lathe. Sometimes also the drill 561, has blocks of hard wood attached above and below it, to com- plete the circle; this is usual for wrought-iron and steel, and oil is then employed. These three varieties are exclusively lathe-drills, and are intended for the exact repetition of a number of holes of the particular sizes of the bits, and which, on that account, should remove only a thin shaving to save the tools from wear. The cylinder bits, however, may be used for enlarging holes below half an inch, to the extent of about one-third their diameter at one cut; and for holes from half an inch to one inch, about one-fourth their Digitized by Google BORING TOOLS. 177 diameter or less; and as the bits increase in size, the proportion of the cut to the diameter should decrease. The cylinder bit is not intended to be used for drilling holes in the solid material, and as the piercing drills are apt to swerve in drilling small and very deep holes, the following rotation in the tools is sometimes resorted to. A drill, Fig. 531, say three-sixteenths diameter, is first sent in to the depth of an inch or upwards, and the h de is enlarged by a cylinder bit of one-quarter inch diameter. The centre at the end of the hole is then restored to exact truth, by Fig. 532, a recentering drill, the plug of which exactly fits the hole made by the cylinder bit; the extremity of the recentering drill then acts as n fixed turning-tool; and should the first drill have run out of its position, 532 corrects the centre at the end of the hole. Another short portion is then drilled with 528. enlarged with the half-round bit, and the conical extremity is again corrected with the recentering drill; the three tools are thus used in ro- tation until the hole is completed, and which may be then cleaned out with one continued cut, made with a half-round bit a little larger than that previously used. Some of the large half-round bits are 80 made, that the one stock will serve for several cutters of different diameters. In the bit used for boring out ordnance, the parallel shaft of the boring-bar slides accurately in a groove, exactly parallel with the bore of the gun; the cutting blade is a small piece of steel affixed to the end of the half-round block, which is either entirely of iron, or partly of wood; and the cut is advanced by a rack and pinion movement, actuated either by the descent of a constant weight, or by a self-acting motion derived from the prime mover. For making the spherical, parabolical, or other termination to the bore, cutters of corresponding forms are fixed to the bar.* There are very many works which, from their weight or size, cannot be drilled in the lathe in its or- dinary position, as it is scarcely possible to support them steadily against the drill; but these works are readily pierced in the drilling-machine, which may be viewed as a lathe with a vertical mandrel, and with the flange of the popit-head enlarged into a table for the work, which then lies in the hori- zontal position simply by gravity, or is occasionally fixed on the table by screws and clamps. The structure of these important machines admits of almost endless diversity, and in nearly every manufac- tory some peculiarity of construction may be observed. Figs. 564 and 565 exhibit Nasmyth's Portable Hand-drill, which is introduced as a simple and effi- cient example, that may serve to convey the general characters of the drilling-machines. The spindle 564. 565. is driven by a pair of bevel-pinions; the one is attached to the axis of the vertical fly-wheel, the other to the drill-shaft, which is depressed by a screw moved by a small hand-wheel. Sometimes, as in the lathe, the drilling-spindle revolves without endlong motion, and the table is raised by a treadle or by a hand-lever; but more generally the drill-shaft is cylindrical and revolves in, and also slides through, fixed cylindrical bearings. The drill-spindle is then depressed in a variety of ways; sometimes by a simple lever, at other times, by a treadle which either lowers the shaft only one single sweep, or by a ratchet that biings it down by several small successive steps, through a greater distance; and mostly a counterpoise weight restores the parts to their first position when the hand or foot is removed. Friction-clutches, trains of differential wheels, and other modes, are also used in de- pressing the drill-spindle, or in elevating the table by self-acting motion. Frequently also the platform admits of an adjustment independent of that of the spindle, for the sake of admitting larger pieces; the horizontal position of the platform is then retained by a slide, to which a rack and pinion move- ment, or an elevating screw, is added. Drilling-machines of these kinds are generally used with the ordinary piercing-drills, and occasion- ally with pin-drills; the latter instrument appears to be the type of another class of boring tools, namely, cutter-bars, which are used for works requiring holes of greater dimensions, or of superior acc'i- racy, than can be attained by the ordinary pointed drills. The small application of this principle, or of cutter-bars, is shown on the same scale as the former drills, in Fig. 566; the cutter c, is placed in a diametrical mortise in a cylindrical boring-bar, and is fixed by a wedge; the cutter c extends equally on both sides, as the two projections or ears embrace the sides of the bar, which is slightly flattened near the mortises. Cutter-bars of the same kind, are occasionally employed with cutters of a variety of forms, for The outside of the gun is usually turned, whilst the boring is going on, by the hand-tools. A plug of copper is acrewed into the brass guns to be perforated for the touch-hole, copper being less injured by repeated discharges than the alloy of 9 parts copper and 1 part tin, used for the general substance of the gun; the curved bit smooths off the end of the plug. 23 Digitized by Google 178 BORING TOOLS. making grooves, recesses, mouldings, and even screws, upon parts of heavy works, and those which can- not be conveniently fixed in the ordinary lathe. Fig. 567 represents one of these. c 566. 568. 567. The larger application of this principle is shown in Fig. 568, in which a cast-iron cutter-block IS keyed fast upon a cylindrical bar; the block has four, six, or more grooves in its periphery. Sometimes the work is done with only one cutter, and should the bar vibrate, the remainder of the grooves are filled with pieces of hard wood, so as to complete the bearing at 80 many points of the circle occasionally cutters are placed in all the grooves, and carefully adjusted to act in succession-that is, the first stands a little nearer to the axis than the second, and so on throughout, in order that each may do its share of the work but the last of the series takes only a light finishing cut, that its keen edge may be the longer preserved. In all these cutters the one face is radial, the other differs only four or five degrees from the right angle, and the corners of the tools are slightly rounded. These cutter-bars, like the rest of the drilling and boring machinery, are employed in a great variety of ways, but which resolve themselves into three principal modes: First. The cutter-bar revolves without endlong motion, in fixed centres or bearings-in fact, as a spindle in the lathe; the work is traversed. or made to pass the revolving cutter in a right line, for which end the work is often fixed to a traversing slide-rest. This mode requires the bar to measure, between the supports, twice the length of the work to be bored, and the cutter to be in the middle of the bar it is therefore unfit for long objects. Secondly. The cutter-bar revolves, and also slides with endlong motion, the work being at rest; the bearings of the bar are then frequently attached in some temporary manner to the work to be bored, and are often of wood.* In another common arrangement, the boring-bar is mounted in headstocks, much the same as a trav- ersing mandrel, the work is fixed to the bearers carrying the headstocks, and the cutter-bar is advanced by a screw. The screw is then moved either by the hand of the workman, by a star-wheel, or a ratch- et-wheel, one tooth only in each revolution, or else by a system of differential wheels, in which the ex- ternal screw has a wheel, say of 50 teeth, the internal screw a wheel of 51 teeth, and a pair of equal wheels or pinions drives these two screws continually, so that the advance of the one-fiftieth of a turn of the screw, or their difference, is equally divided over each revolution of the cutter-bar, much the same as in the differential motion of the screw-drill, Fig. 556. This second method only requires the interval between the fixed bearings of the cutter-bar to be as much longer than the work, as the length of the cutter-block; but the bar itself must have more than twice the length of the work, and requires to slide through the supports. Cutter-bars of this kind are likewise used in the lathe; in the act of boring, the end of the bar then slides like a piston into the mandrel. Such bars are commonly applied to the vertical boring-machines of the larger kinds, which are usually fitted with a differential apparatus, for determining the progress of the cut; the bar then slides through a collar fixed in the bed of the machine. In some of the large boring-machines either one or two horizontal slides are added, and by their aid, series of holes may be bored in any required arrangement. For instance, the several holes in the beams, or side-lerers, and cranks of steam-engines are bored exactly perpendicular, in a line, and at any precise distances, by shifting the work beneath the revolving spindle upon the guide or railway; in pieces of other kinds, the work is moved laterally during the revolution of the cutters, for the formation of elon- gated countersinks and grooves. Thirdly. In the largest applications of this principle, the boring-bar revolves upon fixed bearings without traversing and it is only needful that the boring-bar should exceed the length of the work, by the thickness of the cutter-block, of which it has commonly several of different diameters. The cutter- block, now sometimes ten feet diameter, traverses as a slide down a huge boring-bar, whose diameter is about thirty inches. There is a groove and key to couple them together, and the traverse of the cutter-block down the bar is caused by a side screw, upon the end of which is a large wheel, that en- gages in a small pinion, fixed to the stationary centre or pedestal of the machine. With every revolu- tion of the cutter-bar, the great wheel is carried around the fixed pinion, and supposing these be as 10 to 1, the great wheel is moved one-tenth of a turn, and therefore moves the screw one-tenth of a turn also, and slowly traverses the cutter-block. The contrivance may be viewed as a huge, self-acting, and revolving sliding-rest; the cutter-bars are equally applicable to portions of circles, such as the D-valves of steam-engines, as well as to the enormous interior of the cylinder itself. All the preceding boring tools cut almost exclusively upon the end alone. They are passed entirely through the objects, and leave each part of their own particular diameter, and therefore cylindrical; but I now proceed to describe other boring tools, that cut only on their sides, go but partly through the . Cylinders of 40 inches diameter for steam-engines have been thus bored by attaching a cast-iron cross to each end of the cylinder: the crosses are bored exactly to fit the boring-bar. one of them carries the driving-gear, and the bar is thrust endlong by means of a screw, moved by a ratchet or star wheel. Digitized by Google BORING TOOLS. 179 work, and leave its section a counterpart of the instrument. These tools are generally conical, and serve for the enlargement of holes to sizes intermediate between the gradations of the drills, and also for the formation of conical holes, as for valves, stopcocks, and other works. The common pointed drill, or its multiplication in the rose countersink, is the type of the series but in general the broaches have sides which are much more nearly parallel. Broaches for making taper holes.-The tools for making taper holes, are much less varied than the drills and boring tools for cylindrical holes. Thus the carpenter employs only the rimer, which is a fluted tool like the generality of his bits; it is sharpened from within, as shown in Fig. 569, so as to act like a paring tool. Flutes and clarionets are first perforated with the nose-bit, and then broached with taper holes, by means of tools of this kind, which are very carefully graduated as to their dimen- sions. Fig. 570 represents a German rimer, used by wheelwrights for inlaying the boxes of axletrees; the loose blade is separated from the shell of the instrument, by introducing slips of leather or wood between the two; the detached cutter fits on a pin at the front, and is fixed by a ring or collar against the shaft. 569. 571. 572. 573. 574. 575. 576. 577. 570. 578. A curious rimer for the use of wine-coopers, by which the holes were made more truly circular, and the shavings were prevented from dropping into the cask. The stock of the instrument consists of a hollow brass cone, seen in section in Fig. 571; down one side there was a slit for containing a narrow blade or cutter, fixed by three or four screws placed diametrically. The tube was thus converted into a conical plane; the shavings entered within the tube, and were removed by taking out a cork from the small end of the cone. The broaches for metal are made solid, and of various sections; as half-round, like Fig. 572: the edges are then rectangular. But more commonly the broaches are polygonal, as in Fig. 573, except that they have 3, 4, 5, 6, and 8 sides, and their edges measure respectively 60, 90, 108, 120, and 135 degrees. The four, five, and six-sided broaches are the most general, and the watchmakers employ a round broach in which no angle exists, and the tool is therefore only a burnisher, which compresses the metal and rounds the hole. Ordinary broaches are very acute, and Fig. 574 may be considered to represent the general angle at which their sides meet-namely, less than one or two degrees; the end is usually chamfered off with as many facets as there are sides, to make a penetrating point, and the opposite extremity ends in a square tang, or shank, by which the instrument is worked. Square broaches, after having been filed up, are sometimes twisted whilst red-hot. Fig. 577 shows one of these; the rectangular section is but little disturbed, although the faces become slightly concave. The advantage of the tool appears to exist in its screw form: when it is turned in the direction of the spiral, it cuts with avidity and requires but little pressure, as it is almost disposed to dig too forcibly into the metal: when turned the reverse way, as in unscrewing, it requires as much or more pressure than similar broaches not twisted. This instrument, if bent in the direction of its length, either in the act of twisting or hardening, does not admit of correction by grinding, like those broaches having plane faces It is not much used, and is almost restricted to wrought-iron and steel. Large countersinks that do not terminate in a point, are sometimes made as solid cones; a groove is then formed up one side, and deepest towards the base of the cone, for the insertion of a cutter, (see Fig. 574.) As the blade is narrowed by sharpening, it is set a little forward in the direction of its length, to cause its edge to continue slightly in advance of the general surface, like the iron of a plane for cutting metal Fig. 579 represents Mr. Richard Roberts' broach, in which four detached blades are introduced, for the sake of retaining the cone or angle of the broach with greater facility. The bar or stock has four 579. shallow longitudinal grooves, which are nearly radial on the cutting face, and slightly undercut on the other The grooves are also rather deeper behind, and the blades are a little wedge-form both in sec- tion and in length, to constitute the cone, and the cutting edges. In restoring the edges of the blades, they are removed from the stock, and their angles are then more easily tested: when replaced, they are set nearer to the point, to compensate for their loss of thickness. Broaches are also used for perfecting cylindrical holes, as well as for making those which are taper. The broaches are then made almost parallel, or a very little the highest in the middle; they are filed, with two or three planes at angles of 90 degrees, as in Fig. 575 or 576. The circular part net being able to cut, serves as a more certain base for foundation, than when the tool is a complete polygon; and the stems are commonly made small enough to pass entirely through the holes, which then agree very exactly as to size. Such tools are therefore rather entitled to the name of finishing drills, than broaches Digitized by Google 180 BRAN SEPARATOR. The size of the parallel broaches is often slightly increased, by placing a piece or two of paper at the convex part; leather and thin metal are also used for the same purpose. Gun-barrels are broached with square broaches, the cutting parts of which are about eight to ten inches long they are packed on the four sides with slips or spills of wood, to complete the circle, as in Fig. 577, in which the tool is supposed to be at work. The size of the bit is progressively enlarged by introducing slips of thin paper, piece by piece between two of the spills of wood and the broach; the paper throws the one angle more towards the centre of the hole, and causes a corresponding advance in the opposite or the cutting angle. Sometimes, however, only one spill of wood is employed. A broach used by the philosophical instrument makers in finishing the barrels of air-pumps, consisted of a thin plate of steel inserted diametrically between two blocks of wood, the whole constituting a cylinder with a scraping edge slightly in advance of the wood; slips of paper were also added. According to the size of the broaches, they are fixed in handles like brad-awls; they are used in the brace, or the tap-wrench-námely, a double-ended lever with square central holes. Sometimes also broaches are used in the lathe just like drills, and for large works, broaching machines are employed; these are little more than driving-gear terminating in a simple kind of universal joint, to lead the power of the steam-engine to the tool, which is generally left under the guidance of its own edges, according to the common principle of the instrument. In drills and broaches, the penetrating angles are commonly more obtuse than in turning tools; thus in drills of limited dimensions, the hook-form of the turning tool for iron is inapplicable, and in the larger examples, the permanence of the tool is of more consequence than the increased friction. But on account of the additional friction excited by the nearly rectangular edges, it is commonly necessary to employ a smaller velocity in boring than in turning corresponding diameters, in order to avoid soften- ing the tool by the heat generated; and in the ductile fibrous metals, as wrought-iron, steel, copper, and others, lubrication with oil, water, &c., becomes more necessary than in turning. The drills and broaches form together a complete series. First the cylinder-bit, the pin-drills, and others with blunt sides, produce cylindrical holes by means of cutters at right angles to the axis; then the cutter becomes inclined at about 45 degrees, as in the common piercing-drill and cone countersink; the angle becomes much less in the common taper broaches; and finally disappears in the parallel broaches, by which we again produce the cylindrical hole, but with cutters parallel with the axis of the hole. Still considering the drills and broaches as one group. the drills have comparatively thin edges, always less than 90 degrees, yet they require to be urged forward by a screw or otherwise, the resistance being sustained in the line of their axes. The broaches have much more obtuse edges, never less than 90, and sometimes extending to 135 degrees; and yet the greater force required to cause the penetration of their obtuse edges into the material, is supplied without any screw, because the pressure in all these varied tools is at right angles to the cutting edge. Thus supposing the sides of the broach extended until they meet in a point, as in Fig. 578, we shall find the length will very many times exceed the diameter, and by that number will the force employed to thrust forward the tool be multiplied, the same as in the wedge, whether employed in splitting timber or otherwise; and the broach being confined in a hole, it cannot make its escape, but acts with great lateral pressure, directed radially from each cutting edge; and the broach under proper management leaves the holes very smooth and of true figure. BOW-STRING BRIDGE, OR TENSION BRIDGE, a kind of suspension bridge, the roadway being suspended from wrought-iron rods; but, instead of the usual suspension chains, cast-iron segments are thrown across the ravine, or river, as the case may be, which are rested on proper abutments upon each side. 580. Bridge at Howslett. The span of the Monk Bridge is 112 feet; that erected at Howslett, has a span of 152 feet, and the rise of the arch is 33 feet; the total height above the level of the water is 43 feet, the width of the bridge is 33 feet. BOX-WOOD. See WOODS, varieties of. BRACKETS AND PILLOW-BLOCKS. See GEARING. BRAKE, OR CONVOY, the drag applied generally to the wheels of carriages to check their velocity in passing down hills, by means of friction. The brake attached to railway carriages consists of a piece of wood, which is pressed upon the rim of the wheels of the carriages by a hand-lever, worked by the brakeman. The brake of the tender alone affords a sufficient resistance to stop a train under ordinary circumstances. The term is also used in reference to the contrivance for arresting the motion of machinery. BRAN SEPARATOR. This is the invention of E. R. Benton, of Milwaukie, Wisconsin, and it has been deemed one of no minor importance. The following description of its construction and operation, in connection with the accompanying engravings, will enable our readers fully to understand it. Fig. 581 is a sectional view, and Fig. 582 a sectional plan, with the top parts removed in order more plainly to show the parts represented in Fig. 581. A, is the shaft. B, the cylinder. C, the inner re- Digitized by Google BRAN SEPARATOR. 181 volving shell and D, the outer or stationary shell. The cylinder is made by framing staves of the form, and in the position represented at 1, 2, 3, &c., Fig. 582, into corresponding cast heads. The staves thus forming the longitudinal and working surface, and which may be covered with any kind of material that will make it rough and durable. Air is let into the cylinder, the best at the lower end, through equidistant holes around the centre, and the quantity gaged by a circular revolving slide, and spaces between the staves emit it to carry the flour and other stuffs through the several qualities of wire-cloth with which the inner surface of the revolving shell is covered. The cylinder is driven by a belt and 581. il e 583. Y 6 M 0 a a e D D Q E B A G K L M P 2 582. S U R T F DL H pulleys, as is represented at the bottom of Fig. 581 ; and the bridge and oilpot for the point and step, and the fixture for supporting the upper journal-box of the shaft, are cast in a piece with their respec- tive heads of the outer shell, thus rendering this part of the machine perfect. The inner surface of the revolving shell is covered with the above-named wire-cloth. Thus, the space between the top and the bevelled dividing ring E, Fig. 581, is covered with a quality that will let through little else but pure flour, which falls, and by the dividing ring is conducted into an endless trough I, attached to the inner and sheet-iron or zinc-lined surface of the stationary shell, and by the sweepers F, attached to the revolving shell, is brought around and discharged at the spout G. The space between the divi- ding rings E and H is covered with a quality that will discharge an inferior quality to the above, which falls, as above into the endless trough J, and by the sweepers K, is brought around and discharged at the spout L The space between the dividing rings H and M is covered with a quality that will take out the fine particles of the bran, called dusting, which falls, as above, into the endless trough N, and by the sweepers O, is discharged at the spout P. The space between the dividing ring M and the bottom, is covered with a quality that will separate the shorts from the bran, the shorts falling to the bottom, or into the endless trough R, and by the sweepers S is discharged at the spout T, the bran passing down inside of the revolving shell, and by the arms U, of its cast head, is swept around to, and discharged Digitized by Google 182 BREAKWATER. at the spout V. The revolving shell is driven by a combination of gear-wheels, thus: The pinion above, on the principal shaft A, Fig. 581, drives the wheel X, on the small or centre shaft Y, and the pinion Z, on the last-named shaft, drives the projecting cogged-wheel rim a, cast in a piece with the top head, which will turn it the same way with the cylinder; and to turn it the contrary way, the project- ing rim a must be so large as to circumscribe and be driven by the pinion Z, working into cogs upon its inner periphery, as seen by the figures W, of pitch circles, the figures denoting the corresponding pitch circles of the wheels and pinions in Fig. 581. b, is a circular inclined plane, so calculated as to lift a mallet or hammer to strike upon the end of the revolving shell to keep the cloth from clog- ging, the blow to be struck upon a block resting upon its upper rim, and projecting up through a cor- responding hole in the stationary head, as at C. d, is a set of cams on the shaft Y, which shake a wire sieve e, that receives the uncleaned and unseparated bran, shorts, and dustings from the bolts, as through the spout f, the sieve carrying off all coarse extraneous stuff that might injure the machine, the bran falling through the sieve and entering the machine passing between the arms of the upper head of the revolving shell on to the head of the cylinder. BRASS, (see SOLDERING :) Yellow; tough for engine work; for heavy bearings. See DETAILS OF ENGINES. BRASS-TURNING TOOLS. See TURNING TOOLS. BRAZING COPPER. See SOLDERING. BRAZING SOLDERS. See DETAILS OF ENGINES. BRAZILETTO. See WOODS, varieties of. BRAZIL-WOOD. See WOODS, varieties of. BREAKWATER. A kind of artificial embankment, dike, or rampart, formed of large stones, and erected for the purpose of protecting the entrances of harbors, also roadsteads, from the effects of violent winds, by breaking the force of the waves of the sea; the shipping, moored behind them, lying perfectly secure. The most celebrated works of this description are those of Cherbourg, in France, and Plymouth, in England. That of Cherbourg was the first executed, having been begun in the year 1783: the building of the wall was commenced upon upright cones of timber, and each cone was intended to have been about 150 feet diameter at the base, 60 feet at the top, and about 60 or 70 feet high, the depth of water at spring-tides, in the line in which they were sunk, varying from 56 to 70 feet; they were also intended to have been filled with stones to the top, and after allowing some time for settling, the masonry was intended to have been commenced upon them but a few of these cones only were constructed, when, in consequence of the difficulty of the undertaking, the whole was covered with large stones, thrown in at random. This breakwater is 10 feet above the highest tides, and has a roadway or platform 20 feet wide on the side next the shore, a parapet-wall being built upon it on that next the sea. The Plymouth breakwater was commenced in 1812. It is composed of blocks of stone, 1} to 2 and 3 tons weight, and consists of a central part, 1000 yards long; and two wings, each 350 yards long, 584. Plan of Plymouth Breakwater. directed towards the sea, and forming angles of 158° with the centre portion. A transverse section taken through the breakwater shows an average base of 290 feet, and the breadth at the top is 48 feet, with an average depth of water, at low spring-tides, of 36 feet; the side next the sea is sloped in the 585. A D B B Section of Plymouth Breakwater.-A A, high-water spring tides. B B, low-water spring tides. D, the fore-shore. proportion of 1 perpendicular to 7 horizontal, and the side next the land is 1 to 5; these sides were not intended, originally, to have had so great a slope, but, in consequence of the violence of the waves during its construction, it was thought proper to increase them, as executed. The stone was raised in large blocks, some of which contained 10 tons, and were thrown into the sea, in the direction set out for the breakwater, care being taken that the greater nunber were de- posited upon the outer slope. After a number of these large masses had been lowered, A smaller class of stones, quarry rubbish, rubble, and lime-screenings, were thrown in to fill up the interstices, and close all the cavities; these found their position, by the action of the sea, and the great mass be- came, as it advanced, perfectly wedged together. Digitized by Google BRICK-MAKING. 183 BREAKWATER GLACIS, (sometimes termed stone-pave- ment.) The stone pavings next the sea, in pier erections they 586. are mostly laid upon a slope, or curved, the stones being of sufficient weight to resist the action of the sea. BREASTS. The name given to the bushes connected with small shafts or spindles. BREAST-WALL A wall built up breast-high, as a para- pet-wall, or a retaining-wall, placed at the foot only of a slope. BRICK. An artificial preparation of clay, sand, and ashes, Section showing the Breakwater Glacis. burnt in a kiln, or clamp, and used for building, and for other purposes good brick-earth is also sometimes found in a natural state. A good brick is about 84 inches long, 41 inches wide, and 21 inches thick, when burnt. BRICK-MACHINE Among the machines which have been produced by the inventors of our sister city of Philadelphia is that of Stephen Ustick's, for Moulding and Pressing Bricks from untempered clay, a representation of which is given below. It will readily be seen that it is simple in its construc- tion, as all the motions to the pistons and fillers are given by stationary cams as the wheel of the moulds rotates. The pressing cams give a powerful progressive pressure-the same in effect as that given by toggle-joint levers. 587. M H B A A, frames, between which the cams G, the pinion on the driving-shaft. ing the brick with it, by a projection BC and the centre shaft D are firmly G, revolving wheel on the shaft D, hav- of the cam-wheel E. bolted. ing pairs of parallel arms to which N, a perpendicular cam which operates BC, cams which give the pressure to the moulds are bolted, and between the plunger 0, to discharge the bricks the outer pistons. which the pistons slide. from the pistons. D, centre shaft on which the wheel of H, the moulds. P P, cams which bring the pistons into moulds revolves. 11, pistons which condense the clay. the moulds. E, cam-wheel on the centre shaft D, K, the fillers which supply the moulds Q, annular receiver, into which the clay which gives the pressure to the inner with clay. falls from the pulverizer. pistons. L, the hoppers above the fillers. R, openings in the bottom of the re- F, cam-wheel on side shaft, above the M, a light cam, which brings the outer ceiver communicating with the hop- cam-wheel E. which gives motion to piston out of the mould after the pers L. the fillers. The view of this cam- brick is pressed, while the inner one S, scraper which fills the hoppers. wheel is obstructed by the receiver. is thrust through the mould, carry- After the first pressure is given to the clay, which commences when the outer piston is at the front end of the cam B, the air is let off of the brick by the filler, (the front end of which is a false top to the mould,) moving inwards, leaving the upper part of the brick bare for the condensed air to escape it then moves back to its place before the piston reaches the back end of the cam C, and then the second pressure is given to the brick, without any loss of time, as a brick is made in each mould in every revolution of the wheel. BRICK-MAKING. Brick is a kind of factitious stone, made of a fatty earth formed into a parallelopiped, about 4 inches broad by 8 or 9 inches in length, by a wooden mould, and then baked or burnt either in a kiln or a clamp, to serve the purposes of building. Bricks appear to have been used for architectural purposes at a very remote period, as we learn from the Scriptures that the Israelites were employed to make bricks in Egypt; and some of the most durable of the Greek and Roman monuments which have come down to us, are wholly, or in great part, constructed of this material. In the East they bake their bricks in the sun; the Romans used them crude, only leaving them a long time in the air to dry, about four or five years. In modern times, brick-making is nowhere carried to greater perfection than in Holland, where most of the floors of the houses, and frequently the streets. are paved with excellent and very durable bricks. Loam and marl are in England considered the best materials for bricks. The former is a natura! mixture of sand and clay, which may be converted at once into bricks; marl is a mixture of limestone and clay in various proportions. The neighborhood of London is remarkably Digitized by Google 184 BRICK-MAKING. adapted for the making of bricks, the soil of the whole surrounding country being clay at a certain depth, generally below a bed of gravel, and the bottom of the Thames yielding the sand which is used in this manufacture; but great practical carelessness seems to pervade the whole business as conducted there. The following is a description of the process as it is usually conducted around the me- tropolis: The earth is dug up in the autumn, and suffered to remain in a heap until the next spring, that it may be well penetrated by the air, and particularly by the winter frosts, which, by pulverizing the more tenacious particles, greatly assists the operations of mixing and tempering. In making up this heap for the season, the soil and ashes, or sand, are laid in alternate layers or strata, each stratum containing such a thickness as the stiffness of the soil may admit or require. In temper- ing the earth, much judgment is required as to the quantity of sand to be thrown into the mass, for too much renders the bricks heavy and brittle, and too little leaves them liable to shrink and crack in the burning. The addition of sea-coal ashes, as practised about London, not only makes it work easy, but saves fuel, as when the mixture is afterwards sufficiently heated these bricks are chiefly burned by the fuel contained in the clay. When the brick making season arrives, the heap is dug up, the stony parti- cles carefully removed, and the mass properly tempered by a thorough incorporation and intermixture of the materials, with the addition of as little water as possible, 80 as to form a tough viscous paste. If, in this operation, too much water be used, the paste will become almost as dry and brittle as the soil of which it is composed. In order more effectually and regularly to mix the loam and ashes, it is now generally performed in A sort of mill, named a pug-mill This consists of a large tub or tun, fixed perpendicularly in the ground, and having an upright bar, fitted with knives, placed obliquely. The upright bar is turned by a horizontal lever, to which a horse is attached, and the soil being put in at top, is, by the revolution of the knives, forced through a hole in the side of the tub near the bottom, whence it is removed to the mould-table, which is placed under a moveable shed, and is strewed with dry sand. A girl rolls out a lump somewhat larger than the mould will contain. The moulder receives this lump from the girl, throws it into his mould previously dipped in dry sand, and with a flat smooth stick about 8 inches long, kept for the purpose in a pan of water, he strikes off the overplus of the soil; he then turns the brick out of the mould upon a thin board rather larger than the brick, upen which it is removed by a boy, who places it on a light barrow of a particular construction, which being loaded with a certain number of bricks, they are sprinkled with sand, and wheeled to the hacks. The hacks for drying are each wide enough for two bricks to be placed edgewise across, with a passage between the heads for the admission of the air, to facilitate the circulation of which the bricks are usually laid in an angular direction. The hacks are usually carried eight bricks high; the bottom bricks at the ends are usually old ones. In showery weather the hacks must be carefully covered with wheat or rye straw, unless sheds or roofs be built over the hacks, as is done in some parts of the country, but in London this is impracticable, from the very great extent of the grounds. In fine weather the bricks will be ready for turning in a few days, in doing which they are reset more open than at first, and in six or eight days more they will be ready for burning. In the vicinity of London bricks are commonly burned in clamps. In building the clamps, the bricks are laid after the manner of arches in the kilns, with a vacancy between every two bricks for the fire to play through. The flue is about the width of a brick, carried straight up on both sides for about three feet; it is then nearly filled with dry bavins or wood, on which is laid a covering of sea-coal and cinders, (or, as they are termed, breeze;) the arch is then overspanned, and layers of breeze are strewed over the clamp, as well as between the rows of bricks. When the clamp is about six feet wide, another flue is made in every respect similar to the first. This is repeated at every distance of six feet throughout the clamp, which, when completed, is surrounded with old bricks, if there be any on the grounds, if not, with some of the driest of the unbaked ones reserved for the purpose; on the top of all, a thick layer of breeze is laid. The wood is then kindled, which sets fire to the coal and when all is consumed, which will be in about twenty or thirty days if the weather be tolerable, the bricks are concluded to be sufficiently burned. To prevent the fire burning too furiously, the mouths of the flues are stopped with old bricks, and the outside of the whole clamp plastered with clay and against any side particularly exposed to the rain, &c., screens are laid, made of reeds worked into frames about six feet high. and of a width to admit of being moved about with ease. This is the mode of manufacturing the ordinary descriptions of bricks; but the superior sort, termed washed malms or marls, are tempered with greater care and attention. For this purpose a circular recess is built about four feet high, and from ten to twelve feet diameter, paved at bottom, with a horse-wheel placed in its centre, from which a beam extends to the outside for the horse to turn it by. The earth is then raised to a level with the top of the recess, and forms a platform for the horse to walk upon. Contiguous to the recess a. well is formed for supplying the recess with water, which is raised by a pump worked by the horse-wheel A harrow made to fit the interior of the recess, thick set with long iron teeth, and well loaded, is chained to the beam of the wheel to which the horse is harnessed. The soil prepared in the heap in the usual manner is brought in barrows, and distributed regularly round the recess, and a quantity of chalk is added, and a certain portion of water; and the horse being set in motion, drags the harrow, which forces its way into the soil, admits the water into it, and by tearing and separating the particles, not only mixes the ingredients, but also affords an opportunity for stones and other heavy matters to fall to the bottom. Fresh clay, chalk, and water, continue to be added until the recess is full. On one side of the recess, and as near it as possible, several hollow square pits are prepared about 18 inches or 2 feet deep. The soil, reduced to a kind of liquid paste, is discharged from the recess by a sluice, and conveyed by wooden troughs to the pits. In these pits the fluid soil diffuses itself, settling of an equal thickness, and remains until wanted for use, the superfluous moisture being drained or evaporated away by exposure to the atmosphere. The remainder of the process is the same as for the common sort of bricks. In the country, bricks are always burned in kilns, whereby much waste is prevented, less fuel is consumed, and the bricks are more expeditiously burned. A kiln is usually 13 feet long by 10 feet 6 inches wide, about 12 feet in height, and will burn 20,000 bricks at a time. The walls are about 14 inches square, and incline inwards towards the top. The bricks are set on flat arches, having holes Digitized by Google BRICK-MAKING. 185 left between them resembling lattice-work. The bricks being set in the kilnf, and covered with pieces of broken bricks or tiles, some wood is put in and kindled to dry them gradually; this is continued till the bricks are pretty dry, which is known by the smoke turning from a darkish to a transparent color. The burning then takes place, and is effected by putting in brushwood, furze, heath, fagots, &c.; but before these are put in, the mouths of the kiln are stopped with pieces of brick called shinlog, piled one upon another, and closed over with wet brick-earth This shinlog is carried just high enough to leave room sufficient to thrust in a fagot at a time; the fire is then made up, and continued till the arches assume a whitish appearance, and the flames appear through the top of the kiln, upon which the fire is slackened, and the kiln cooled by degrees. This process is continued, alternately heating and slackening, till the bricks are thoroughly burned, which is usually in the space of forty-eight hours. Many attempts have been made of late years to supersede, by the aid of machinery, a portion of the manual labor now employed in the manufacture of bricks; and although only the most recent of the machines invented for this urpose have been found to answer in practice, several of them are worthy of notice. The engraving below represents Messrs. Choice & Gibson's brick-making machine. a a a a is an upright frame, with cross-beams at top and bottom; bc are two vertical shafts, carrying two horizontal spur-wheels d and e, the teeth of which take into one another; these are put in motion by the horse-shaft f, or any other convenient power. Near the bottom of the shaft b is fixed a large cast-iron collar g, having three deep mortises; into each of these the end of an iron arm h is fitted, with a belt 588. 9. m passing through them to form a centre, as in a hinge-joint. To the other extremity of each of the arms h is firmly fixed, by screw-bolts, a cast-iron mould-box i, having three divisions for three bricks, in which work three stocks or false bottoms, having upright bolts passing through holes in the top. By the rev- olution of the shaft, these mould-boxes, with their arms, are successively carried up and over the recrs k k k; which form circular curves in the plan, and appear EO in the perspective, but are in reality 24 Digitized by Google 186 BRICK-MAKING. inclined planes. At l, near the bottom of the shaft, is a small bevelled wheel, which actuates a pinior. fixed on the spindle of the drum-wheel m that passes under the floor of the machine; an endless strap passing round the drum m, and another placed at the required distance, continually carries the bricks forward to their destination as fast as they are made, and deposited upon it. o is a crank or lever, attached by a joint to the framing, as shown, at the upper end of which is fixed a roller; by the revolution of the wheel above the three circular bars or cams, rrr, attached to the wheel, successively act upon the roller, and depress the crank o, which first raises the rod and weight q, and afterwards, as soon as the crank is relieved of the pressure, allows it to drop and strike the mould-boxes, by which the bricks are discharged out of them. 8 is a box of cast-iron, containing water, into which the mould-boxes dip; t is a cushion, upon which they next fall in succession, by which the superfluous water is taken off; and is a box of dry sand, into which the mould-boxes afterwards fall, their surfaces tecoming in consequence slightly coated with sand previous to becoming charged with clay. The horizontal wheel e worked by d actuates the shaft c bearing the knives in the pug-mill. At the lower end of the shaft c is fixed the large circular revolving bottom-plate и, the periphery of which being furnished with teeth or cogs, as shown, take into the teeth of a circular revolving plate ", over which, as the mould-box passes, the lower surface of the bricks becomes smoothed. At x is a small frame, working up and down in a casing, with a pulley and counterbalance weight, like a sash window; it is raised by the crank y as each mould-box passes, when three little boards are placed across the frame by a boy, for the reception of the bricks. When these are deposited by the means described, the frame drops below the level of the endless strap n; the latter then receives them, and carries them off to their destination. At z is fixed a flat box, which acts as a gage to regulate the thickness of the stratum of clay revolving upon the bottom plate n of the pug-mill. The operation of this machine is as follows: the clay being worked in the ordinary manner through the pug-mill, it passes out at the mouth, (not shown, being on the opposite side,) from thence under a flap which partly regulates the quantity on the bottom plate, and next under the gage, which determines it precisely. A mould-box having passed over the highest inclined plane or riser k, first falls on the stratum of clay, and chops out three bricks, filling the moulds therewith by the false bottoms rising up to the determined point from the pressure of the clay against them; the moulds, with the bricks in them, then slide over the polishing plate r, (which is kept wet by water constantly dripping upon it from a tub;) from thence the moulds pass on to the frame x, when the weight q strikes against the protruded bolts of the false bottoms, and pushes out the bricks upon the boards on the frame; the frame then descends two or three inches by their weight, and delivers the boards upon the endless strap, which, being constantly in motion, carries the bricks away to be deposited on the hacks. The mould-box being discharged, is then carried upon its roller up the first riser k, drops into the water, thence rises again, falls upon the cushion, next into the sand-box, whence ascending again, the highest inclined plane being duly prepared, it, falls again upon the bottom plate of the pug-mill, and chops out three more bricks, during which period each mould-box has operated in a similar manner. We shall now proceed to describe the brick-making machinery invented by Mr. Leahy, and erected by him for the Patent Brick Company; it is represented in the succeeding figure. a is the main horizontal shaft in direct communication with the steam-engine or other first mover; b is a hopper- formed vessel, technically termed the pug-mill, in which the clay and other materials are tempered and mixed up: it is for this purpose furnished with cross iron bars, or blades of steel; part of these are firmly fixed to the hollow vertical shaft c, and the remainder bolted to the sides of the pug-mill, and they are so arranged, that those fixed to the shaft cut in as they revolve between the others. The clay is delivered into the hopper or pug-mill by an endless chain of buckets, (in the same man- ner as ballast is raised;) it is then cut up and tempered by the knives and bars in the pug-mill, and gradually descending, it falls, or rather is forced by the superincumbent pressure upon the circular inclined plane d, which consists of a single thread or spiral turn of a very large screw, occupying the whole internal space of the lower cylindrical end of the mill, where it is exhibited in section. This screw or circular inclined plane is fixed to the central shaft passing longitudinally the hollow shaft, and a slow reversed motion is given to it, by means of an intermediate wheel acting upon pinions in the upper part of the frame. The blades on the hollow shaft revolve in the pug-mill at the rate of fifteen turns in a minute, grinding and dividing the materials much more completely than in the ordinary mode of brick-making. In this attenuated state the materials are forced upon the circular inclined plane of the screw, and as this slowly revolves in a contrary direction at the rate of five turns in a minute, it takes hold of the clay, (by a peculiar adaptation not easily described,) and forces it out of the mill in a very compact state, into a receptacle below: of this. one side is always in immediate contact with the moulds, and those two sides which are at right angles to the former side are closed by iron cheeks, between which the lever or forcing flap n acts by pressure, and fitting closely, prevents the escape of the clay, so that it can only pass into the moulds. These moulds are placed round the periphery of a circular frame e, made of flat iron rings, fixed upon bars or spokes, and turning upon a fixed shaft. There are twenty-five of these moulding-boxes in one circle; but as the frame e may be of any breadth, it may contain twice twenty-five or thrice twenty-five on the circumference of the cylinder, provided that the engine is capable of affording sufficient power or force to cut or mould so many bricks at each revolution. Each moulding-box is furnished with a false or moveable bottom, to which rods are attached, for the purpose of pushing out the brick when moulded, and drawing back the bottom to its place to receive a fresh portion of the clay. The manner in which these operations are performed is extremely simple and ingenious. The ends of each of the moulding-box rods are bent at right angles, and an eccentric piece f is so fixed, that, as the moulds revolve, and at the moment that the surface of each is covered by being in contact with the clay, it gradually draws back the false bottom, and with it the clay, which is also urged on by the circular inclined plane d; and to render the bricks solid and compact, a powerful pressure is applied to them by means of the flap forcer n, to which a backward and forward motion is given by the thrusting of a rod attached to a revolving crank. The moulding- boxes, immediately they are thus filled, are subjected alternately to the action of a steel scraper, which Digitized by Google BRICK-MAKING. 187 levels and smooths their surface, and is made to operate by the pressure of springs. The bricks, now completely formed and fast in their moulds, pass downwards in their revolution, which brings the ends of the rods under the operation of a cylindrical rolter, with grooves made round it at equal distances; into these grooves the ends of the rods successively pass, which, in their revolution, force out the rods, and thereby push out the bricks from the moulds on to boards placed underneath to receive them. The bricks thus made are carried forward to the hacks or drying-house, upon an endless web or chain ii, to which a continued motion is communicated by the revolution of the two polygonal drums or wheels k k, placed at the requisite distance asunder. The upper part of the engraving shows a side elevation of the machine, and the lower part a section of it; and although these views serve to give a general idea of the construction of the apparatus, it has been impracticable to show the gearing by which the 589. 590. % h name several motions are produced we will therefore attempt to describe it as follows :-Upon the horizontal shaft a. (which makes 21 revolutions per minute,) is fixed a toothed, bevelled wheel, which drives a bevelled pinion on an upright shaft, (not shown; ;) nearly at the top of this a spur-wheel is fixed, which works into a pinion fixed upon the upper end of the hollow shaft c, which carries' the knives or blades in the pug-mill. Upon the upper end of this upright shaft is also fixed a pinion, which works into an intermediate pinion turning upon an axis. This intermediate pinion acts upon another pinion affixed to the internal shaft, communicating a slow and reversed motion to it, and also the circular inclined plane affixed to it; at the lower end, on the main horizontal shaft, is fixed a spur-wheel m, which gives motion to the crank and to the flap forcer connected to it. o, in the separate figure, gives the form of the shelves comprising the drying apparatus,-Mr. Leahy proposing to dry bricks either by flues or by steam, instead of ranging them in hacks exposed to the variations and inclemencies of the weather,-by which means it is presumed that the bricks will be rendered dry enough for burning, either in kilns or clamps, in a much shorter time than in the common method, and the process may be carried on in winter as well as in summer. If drying by flues be resorted to. a drying-house must be furnished with proper stages, and shelves must be provided. Around and across the lower part of these, flues framed Digitized by Google 188 BRICK-MAKING. either of bricks or cast-iron are to be placed, through which flame or heated air is to be conveyed. In drying by steam, the vapor is conveyed from the boiler through cast-iron pipes throughout the drying- house, and boards are arranged upon stages, (similar to those in Fig. 590.) so as to leave intervals between the rows of bricks, and to prevent their touching one another. Nash's Patent Brick-making Machinery. This invention, which we have now to describe, is not the only one, we believe, that has been brought into successful operation. The leading features of Mr. Nash's mechanism consist in the application of 591. b Z I h II 2 3 1 3 1 m m o 12 o 12 2 g h o 8 5 6 11 IV t 11 & III 6 10 m 10 m u 7 9 7 9 8 8 10 V separate or detached moulds of a particular construction to a series of mould-boxes, which are consecu- tively brought into action; in the employment of heaters, placed in contact with, or contiguous to, the fresh bricks, during the process of their being moulded; and in lieu of sand, which is generally used to prevent the adhesion of the bricks to the moulds, employing elastic absorbent substances, such as cloth saturated with water. In the subjoined engravings, Fig. 591 represents a front elevation, and Fig. 592 an end elevation of the principal parts of the machine. A vertical shaft a is made to revolve in the cylinder or pug-mill b, by any adequate force acting upon the bevelled wheel c. A number of broad Digitized by Google BRICK-MAKING. 189 steel or iron blades d d d are attached to the shaft a, their surfaces being set at such an angle as will cause them, during their revolution, to pass nearly in contact with the edges of two other sets of knives c e, fixed on opposite sides of the cylinder, by which means the clay and other materials with which the mill is charged are tempered and amalgamated, and then forced into the hopper f, fixed to the lower extremity of the pug-mill. This hopper is divided into two equal chambers by a vertical blade or knife, which separates the materials into equal portions, which are supplied to the moulds in a compact state. The moulds are lodged in rectangular cavities at equal distances in the periphery of two polygonal drums g h; these cavities are marked 1 to 12. To one face or side of the drums are attached two toothed wheels, gearing into each other so as to revolve in opposite directions when motion is communicated to one of them. These wheels lying at the back of Fig. 591 592. cannot be seen, but one of them is shown at i in Fig. 592. The moulds, after being filled with the plastic material, are pushed out nom their recesses by means of pistons at m m, easily fitting the recesses, and sliding upon parallel rods fixed to the rims of each drum. To each piston is attached, by a short rod, a cross-head, sliding upon the parallel rods, and having at each end small anti-friction wheels pp, which, by the motion given to the machinery, come in contact with a larger wheel q, placed ec- a centrically, which thus raises the pistons, and the moulds which lie upon them are d then removed by hand and emptied. Dur- ing this latter process the emptied mould- - receiver will have passed over the centre of the eccentric wheel q, and the piston - will be descending when the attendant places the emptied mould in its former sit- uation, to be filled again from the hopper as it passes under it. Between each of 0 the rectangular mould-boxes are formed a a series of wedge-shaped boxes, termed by the patentees hollow sectors," into each of which is placed a red-hot iron, the object of which is to expel the superfluous moist- ure from the newly-formed brick, &c., in order that the manufacture may be con- ducted in the winter as well as the sum- mer. These irons are heated in the kiln- II fires. The axis of the polygonal drums re- volve in plummer-blocks, supported upon a strong frame s; but as the polygonal drums revolve in close contact, the plummer- blocks are free to slide in grooves in the frame, and the wheels are kept in contact by the action of strong helical springs t, which press against the plummer-blocks, the other end of the springs abutting against a regulating screw. In the middle h of, and underneath the horizontal frame 8, is fixed a knife u, (supported in its place by a spiral spring,) which separates the whole or a portion of the superfluous ma- III terials from each mould, as the latter passes over the edge of the former. As some re- dundancy of material may still be left after the operation of the knife и, the exposed surface of the moulds in motion undergoes a similar treatment from two other knives vv, fixed to the foundation plate 10 of the y machine. A trough or cistern k k, contain- ing water, is placed under each of the drums, the lowest sides of which come in contact with a cylinder y, covered with strong coarse cloth or other suitable absorbent substance, which, as it revolves, takes up the water and delivers it to the moulds, as before mentioned. These cylinders are mounted on elastic bearings, and derive their motion from pinions on their axes, actuated by the toothed wheels on the drums. In the centre of the foundation plate there is a cavity, or pit,' for the reception of the superfluous clay or other materials, which are removed at pleasure. The pug-mill has a door in it, for the convenience of cleaning it out when requisite; and the whole of the upper part of the machine is supported by three columns Digitized by Google 190 BRICK-MAKING. 222. The polygonal drums are driven by a set of wheels lying at the back of Fig. 591, and therefore in that figure shown by dotted circles. No. L is a band-wheel, which drives, by a pinicn II, the two whecls III and IV, on the axes of the driving gearing, into each other, and turning in opposite directions. Those two wheels must have involute teeth, as their point of contact becomes variable by the move- ment of the axes of the drums. In case of negligence on the part of the boys, or other attendants of the machine, in not removing the bricks or tiles after the moulds containing them have passed the centre of the eccentric wheel, they fall back into their former position, and pass round to the place of delivery, as before, without any damage whatever being done to the machine. Having explained the general arrangement and operation of the machine, there remains to be described the construction of the detached moulds. Fig. 598 represents a side view, and Fig. 594 an end view of one of these. The ends of the mould 18, 18, are made of 593. 594. wood, plated at the edges with iron, o 0 and fastened on by screws, as seen 18 18 in Fig. 593. The bottom 19, is also of wood, but cased in a strong frame 0 © 18 of cast-iron, and its two extremi- ties are jointed to the ends 18, 18, o 22 1 so as to open only a little way, for 19 allowing the brick to separate freely 21 21 from it upon inverting the mould This effect is facilitated by lining the interior of the mould with cloth, which, although constantly in a wet state, admits air to pass through its interstices when the clay is forced into the mould, 80 that when the brick is afterwards forced out, the moisture of the cloth, and the spring of the confined air, delivers the brick uniformly clean, without the adhesion of any clay. It will be observed that the two ends 18 of the mould have each a cavity; these cavities receive the fingers of the workman when he takes hold of the mould, which he afterwards inverts, drawing back the ends 18 at the instant, and pressing with his thumb upon the screw-heads 21, 21, the other ends of which are attached to a plate 22 underneath the cloth lining of the bottom, as shown by dots, causing the brick to be immediately disengaged. The two sides of the brick not included in the detached mould are formed by the par- tition between the mould-boxes and the hollow sectors. The forms and dimensions of the detached moulds are varied according to the nature of the articles to be produced therefrom. For adapting the machine to make tiles, or other articles of a greater length than a brick, two moveable blocks, which usually lie inside the hopper, to contract its lower dimensions, are taken out. In the making of drain tiles, and other articles having cavities within them, jointed horses or cores are employed; the plastic matter is forced around them by the action of the machine in the same manner as in forming a brick, and the subsequent operations are also the same, except that in the removal or delivery of such tiles from their moulds, suitable adaptations are made to prevent their being pressed or even touched by the hand. The annexed Fig. 595 exhibits another arrangement employed by Mr. 595. Nash for making flat tiles, flooring tiles, &c., of any required breadth and thick- ness. This cut only represents the b lower part of the machine, the upper being the same as in the previously- described apparatus. To the bottom of the pug-mill is fixed a funnel-shaped z hopper 23, the materials in which, after 23 being forced through a mouth 24, formed of the required shape, are re- 25 ceived upon boards 25, and when cut 27 to the proper length, are removed to 24 26 sheds for drying. In order to equalize the surface of the clay after it has come out of the hopper, a roller 26, turning in bearings on a curved arm, which is fixed to a hinge-joint, gives to the ma- 27 terial any pressure that may be re- S S quired, by loading it accordingly. The dotted lines 27, 27, in the same figure, exhibit another funnel-shaped hopper, for the purpose of making pipes or 28 tubes, by means of a centre core 28, between which and the cylindrical con- tinuation of the hopper, the material is forced by the action of the pug-mill, and produces a tube, which, after having made a certain length of, is cut off, the tube being turned round, to render the inside smooth previously to its being removed. The patentee states that this machine may be used with either one or two horse power; that when used with one horse power, the product is about 700 per hour, or 8000 per day to do which requires the services of two men and eight boys, occasioning an expense not exceeding two shillings and Digitized by Google BRICK-MAKING. 101 sixpence per 1000. With two horse power employed, the production is double, or 16,000 per day; but the quality of the bricks, which the editor has seen, is equal to those which are usually finished by grinding the surfaces by hand. The saving of labor in the production is about two shillings per 1000; but the quality rendering them worth five shillings per 1000 more in the market, the advantage of making by the machine, where good bricks are required, is equal to seven shillings per 1000. BRICKS AND TILES, Machinery for the manufacture of. The application of machinery to the fabrication of bricks has met with considerable opposition in the diversity of physical and chemical con- ditions of the earths used. Thus, in some localities the clay has more tenacity and aluminous properties than in others; the mechanical powers sufficient for the last would be useless in the first. As early as 1835, M. Terrasson had constructed a machine surpassing all previous ones in simplicity A frame, having wires stretched across, cuts into bricks the earth which has been compressed between a roller and planks. M. Carville has invented a machine which simultaneously bruises and divides the earth, moulds and throws off the bricks; it may be applied to the fabrication of tiles and other earthen ware. Description of M. Carville's Machine, Figs. 596 to 604. DIVISION AND KNEADING OF THE EARTHS-The earths used are clays, requiring sometimes sand or aluminous compounds. The mixture is the most difficult part in all the process of brick-making. To this end M. Carville uses a cylindrical barrel A, with a flat bottom; its upper part is opened in order to introduce the material. An axis B, also vertical, to which a rotary motion is imparted by a horse har- nessed to the beam C, through the medium of the cast-iron socket a, (see Fig. 596, which is a vertical section through the middle of the machine.) This axis rests against two pillows, one adapted to a beam b, which unites the opposite sides of the machine, and the other upon an inferior cross-beam. This axis is provided with several flat iron branches d, which being fixed perpendicularly to the axis, their fuces have an inclination of 45°. On these there are sharp-edged knives, to divide and knead the clay during their rotation; thus the earth is well divided before reaching the inferior part of the barrel. The branches ef, stouter than the former, but without knives, are attached at the very extremity of the axis, and receive from it a rotary motion, during which they press against the earth, forcing it out through the orifice g. The size of this orifice depends on the quantity needed to fill the moulds; the iron sliding- door h regulates this orifice. This method for dividing and kneading is applied to the fabrication of earthen ware, porcelains, etc. MOULDING AND CASTING OFF THE BRICKS.-It is specially in these functions that M. Carville's machine excels all others. He uses a series of moulds in cast-iron, forming an endless chain D, constantly moving these moulds successively pass beneath the aperture through which the moistened earth is pressed, in order to receive it. Each link forms a rectangular frame, composed of four moulds, which have the precise dimensions of the bricks. Figs. 597, 598, 599, show a plan and transverse section of this chain. Two wheels, with each four arms E, are situated on either side at the extremity of the apparatus. The iron bars i support the limbs and impart to them the movement of rotation communicated by the spur-wheel F; the arrows indicate the direction in which they are to move Fig. 596, so that the moulds are carried under the roller G after they are filled with earth. This roller is of cast-iron, turning round a horizontal iron axis, set in motion by the beam C. Its office is to compress the earth in the moulds as it is received from the barrel. But as these moulds have nc bottom, a moveable flooring is adapted to them to serve as such; it is made of strong sheet-iron j, the pieces approaching each other at distances proportional to the length of the bricks, and hooked to an endless chain passing over the rollers k; one of these rotates, giving to the chain a motion equal to the speed of the moulds. These must be nearly horizontal, when they pass beneath the barrel to give them this direction, a number of wooden rollers H support the iron plates. The axes of these rollers are of iron, freely turning on pillows, Fig. 600. The clay being thus moulded and pressed, soon meets the blades l, made of steel or cast-iron, which shave the two horizontal and parallel faces of the moulds, levelling and polishing the bricks. The clay is prevented from adhering to the surface of the rollers by the water slowly falling from the vessel I. A wooden hopper J, containing fine and dry sand, sprinkles the bricks as they pass beneath l; a small fluted cylinder m, is adapted to the base of the hopper to allow the sand to come out-but in small quantity this cylinder is rotated by means of a pulley and strap, or a small endless chain. As soon as the bricks have passed the polishing blades, they are taken out of the moulds. This is ingeniously done by the simple process of M. Carville. Two pieces of cast-iron K, having a superficial dimension equal to that of the section of the mould, which they completely fill, are attached to a single vertical beam L, which is suspended to another beam M, the other extremity of which being balanced by a counterpoise, this is prevented from falling by a board N. To the axis of the beam M a vertical branch n is adapted this receives a movement of oscillation, depending on the speed of the endless chain of moulds. To this end, this last is provided with little knobs o, Fig. 598, which meet and push successively a horizontal lever r, Fig. 599, fixed to the vertical axis g. To the superior part of this axis is attached the pulley r, Fig. 596, to the circumference of which is hooked the small chain O, whose other extremity is fastened to the pulley r', freely rotating round the iron pin P. Thus when one of the knobs o is in contact with the inferior lever p, it pushes it in the direction of the chain, causing the vertical axis q to turn; the pulley attached to q turns also, carrying along the chain O, and since the extremity of the vertical branch " is engaged in one of its links, it is drawn by it: therefore the axis carrying it oscillates, and also the beam M; L descends, pushing the lumps K into the two corresponding moulds, thrusting the bricks on a moveable floor j'. The weight attached to the beam M causes L to rise, as soon as the lever is no longer acted on by the eminence o. Digitized by Google a CI "309 a b Б b Vo 72 W " 598. 1 f 1 f Digitized by Google " a σ 10 a WS E 8 a b 597. 209 '009 903 *909 BRICK-MAKING. of H 0 60s + Y to X 8 I A a the 7 d *009 % *109 u MV M. a a 9 o 9 a A A L 22 604. 605. J 192 596. BRIDGE. 193 To bring back to its original position the beam L, a cord is attached to its lower extremity, passing through the pulleys 8 s', and having a small counterpoise fastened to its other end. The chain, going all the time, plunges into a reservoir of water Q, which extends its whole length, to wash the moulds. Following the direction indicated by the arrows, it passes under the hopper R, where the moulds are sprinkled with sand before reaching the barrel. The second moveable flooring j', which receives the bricks, is composed of small plates forming an endless chain; parallel rollers, such as H', placed in a different direction from the first, support this chain. Their iron axes are moveable in pillows resting against oak beams S. This flooring moves only when the beam L rises. The teeth o raise successively a short lever p', which is attached about the middle of the short vertical axis q' ; to this is adapted a second lever n', fixed to a small horizontal beam t, which communicates through a rope with the pulley 26. Thus, as soon as a tooth acts on p', its axis oscillates, and its inferior lever n forces the flooring j' to advance a distance equal to the breadth of the two bricks. The small rope passing through u has a counterpoise to bring back the levers to their original position. The bricks being taken off without any handling, are put up to dry. The plates are set back to the chain j', on the side opposite to that on which the bricks were. Description of the Machine of M. Capouillet, Figs. 605, 606, 607. This machine consists of two cast-iron cylinders, performing the office of rollers; one is perfectly smooth, the other is pierced over all its surface with cavities, the dimension of which depends on the size of the bricks to be made: pistons are made to fit into these cavities. These pistons receive an alternative movement equal to the thickness of a brick. CONSTRUCTION OF THE CYLLNDERS-The first cylinder A is solid and smooth; its diameter is 7.31 feet, and its breadth is 7.47 feet. It has an axis of wrought-iron B, turning in pillows with screws a. It receives its motion from the second cylinder, through a straight-toothed wheel C, whose inner diameter is precisely that of the external cylinder. The second cylinder A'is of the same dimensions with the first, but whose circumference contains a great number of rectangular cavities, having only 0-039 feet between each, and of sufficient depth to contain each the thickness of a brick and of a metallic piston b. It has also a horizontal axis of wrought-iron B', of equal length with the preceding. It also is provided with an axis C' of equal diameter with C, with which it is engaged; the pinion M communicates motion to it. The pistons b are rectangular, their dimensions in length and breadth being equal to the bricks; they are free in the cavities, but closely fitting a cylindrical rod is attached to them. MOULDING THE BRICKS.-The clay being prepared, is brought into a rectangular box D, extending as far as the two cylinders, between which the earth falls and is carried away by them. The quantity is regulated by a slide adapted to the box, whose height must not be less than 6.50 feet. By its side is placed a hopper E, containing dry fine sand to be sprinkled on the cylinder A' before the earth enters its cavities. The spout F regulates the direction of the sand; to it an oscillating motion is imparted by the spokes c. The clay, falling between the two cylinders from the box D, is pressed into the cavities of A', filling them in succession with so much more ease as the pistons are pushed in. These pistons had previously been forced in by the cog, which is furnished with the circumference of a strong cast-iron disk G, situated at the right of the cylinder, and having an iron axis. These cogs are disposed as in a cog-wheel, and engaging into the cavities of the cylinder, they push the pistons within the cylinder. An eccentric of cast-iron H is contained within A', freely turning round on its axis, in order to force the pistons from within out, thus forcing the bricks away. The curve of this eccentric must be calcu- lated to give the pistons play only the thickness of a brick. Fig. 605 gives an external elevation of the apparatus, and also a part of the vertical section, showing the disposition of the pistons. Two scrapers dd, adapted to iron levers, which oscillate round the common axis f, and which have counterpoise e', serve to keep the surface of the cylinders smooth and clean. TRANSPORTATION OF THE BRICKS-The horizontal boards I, receive the bricks as they are forced out of the moulding cylinder; they are moved with a speed somewhat greater than the cylinders, in order to leave a small space between the bricks. Their direction is from left to right. These boards are carried by small cylindrical rollers J of cast-iron, the axes of which rest on collars g', pinned on the sleepers, as seen in the horizontal section, Fig. 607. The toothed-wheel k, in which an endless chain h is engaged. transmits to them the motion communicated to it by the wheel which is placed on one of the rollers, to which the small pinion L is adapted. This last is engaged in the prin- cipal pinion M, whose axis is turned by the prime mover which may be a hydraulic wheel, a steam- engine, or a horizontal beam turned by a horse. 608. BRIDGE. A very common engineer- ing expedient employed for passing over rivers, canals, and roads. Rivers of great width were not often crossed by bridges formerly, but ferries were usually estab- lished, at convenient spots, for the pur- poses of communication, (the sites of most river bridges were formerly occupied by ferries,) and shallow streams were com- monly forded. The erection of a bridge over a river occasions a great increase of traffic in the line of route, as may be natu- rally anticipated, in common with all Elevation of the Rialto Bridge. schemes for facilitating conveyance. 25 Digitized by Google 194 BRIDGE. The bridges employed in modern times are constructed after various methods, but arches are mostly used. In most cases the road is carried over at once by stone or brick arches, or by iron or wood beams thrown across and trussed, according to the span; the road is sometimes suspended from inverted bows 609. Details of one of the arches and centreing of Waterloo Bridge. by rods, being usually formed of iron, which are supported upon stone piers at each end, and from thence carried down and secured in the ground, which are called iron suspension bridges. Among modern bridges may be mentioned the Rialto Bridge, over the Grand Canal, at Venice, which was commenced in 1588, by Michael Angelo, and is considered to be a very beautiful structure. The bridge across the Seine, at Neuilly, built between the years 1768 and 1780, by Péronett, is a very celebrated structure; it is a level bridge, consisting of five elliptic arches, each of 128 feet span, and 32 feet rise. Waterloo Bridge, London, by Rennie, is considered a masterpiece. It was commenced in 1810, and is also a level bridge, having nine arches, each 120 feet span, and 35 feet rise, and it is 42 feet 4 inches wide between the parapets. 610. Elevation of one of the arches of Neuilly Bridge. London Bridge, by the same engineer, is a fine work; and, together with the last, form excellent specimens of masonry, being constructed of granite. Timber bridges have been much more generally employed since the introduction of the many inven- tions for preserving timber, as the material offers very great advantages. In wooden bridges of small span the pieces running from pier to pier are termed sleepers, or string-pieces, which support the cross- joists, on which the planking is laid small pieces of wood are sometimes introduced under the string- pieces to shorten the bearing, which are termed bolsters, or corbels. The American system of forming bridges and viaducts by laminating timber arches, has been lately introduced into England. The Ouse-burn Viaduct is 108 feet high, and consists of five arches, each 116 611. Transverse section of Neuilly Bridge. feet span, with two stone arches at each end, 45 feet span; and the Wellington Dean consists of seven arches, each 120 feet span, the height up to the roadway being 82 feet. The piers and abutments are of stone, and each arch consists of three segmental ribs, each rib being composed of thirty 3-inch deck- deals, being two deals in width and fifteen in height; they vary in length from 20 to 45 feet the first course is formed of two deals in width, as before stated, bent over a light centre; the next course consists of one deal and two half ones, and 80 on until the whole rib is formed, the ends breaking joint with each other; and they are connected together by 3-inch oak-trenails, each passing through three of Digitized by Google 612. Elevation of Schuylkill Bridge. Longitudinal Section. BRIDGE. 613. Digitized by Google Elevation of the Upper Schuylkill Bridge. Longitudinal Section. 195 196 BUFFING APPARATUS. the deals: a layer of brown paper, dipped in boiling tar, is placed between the joints to prevent the wet from injuring them, and the timbers are bedded tightly on it; the ends of each rib are let into cast-iron shoes, which are fixed to the springing-stones of the masonry, and are secured with four long iron bolts and run with lead, and the three ribs are connected together by diagonal braces and iron ties the spandrels are framed as shown in the cut, and the whole of the timber is prepared to prevent decay. 614. Elevation of centre arch of the Wellington Dean Viaduct. There have been several arches of large span executed with timber, in Germany and in America-as the Schuylkill Bridge, at Philadelphia, of three arches, the centre one of which is 195 feet span, and the side ones 150 feet; also, the upper Schuylkill Bridge, of the same city, consisting of one arch, 340 feet span, the rise being only 20 feet-the largest arch in the world. The floods form the principal difficulties to guard against in bridges connected with rivers and canals; and their effect upon the nearest adjacent bridges and arches should be carefully ascertained previous to deciding upon the width of the arches or openings of the intended works. The traffic should be con- sidered next, and sufficient width left for it between the parapets. BRINE-PUMPS. See VARIETIES OF BOILERS and DETAILS OF ENGINES. BRINE, Boiling Point of. See DETAILS OF ENGINES. BRONZING. Improvements in the Brassing and Bronzing the surfaces of steel, iron, dc., by Charles de la Salzede, of Paris. This invention consists in coating cast-iron, steel, lead, zinc, and tin, with brass or bronze, by means of a galvanic battery. The solution to be used consists of 5,000 parts, by weight, of distilled water, 610 parts subcarbonate of potass, 25 parts chloride of copper, 48 parts of sulphate of zinc, 805 parts of nitrate of ammonia, and 12 parts of cyanide of potassium. The cyanide of po- tassium is dissolved by itself, in about 120 parts of distilled water taken from the above quantity. The other salts above mentioned (except the nitrate of ammonia) are then added to the remainder of the water, and the mixture is heated to from 144° to 172° Fahrenheit; when they are entirely dis- solved the nitrate of ammonia is added, and the solution allowed to stand 24 hours; the solution of the cyanide of potassium is then added, and the whole allowed to stand till it is quite clear; the clear solution is then to be drawn off with a siphon, and put in the decomposing-trough. The subject to be covered with brass is then to be attached to the zinc-pole of a battery; and to the other pole of the battery a large plate of brass is to be attached, which must be also immersed in the solution. The bat- tery must, the patentee says, be a powerful one; he advises to use Bunsen's, or Grove's. When it is in- tended to bronze, instead of the 48 parts of sulphate of zinc, 25 parts of chloride of tin must be used the other ingredients are to remain the same. Another solution, recommended by the patentee, consists of 5,000 parts of distilled water, 15 parts of chloride of copper, 35 parts of sulphate of zinc, 500 parts of subcarbonate of potass, and 50 parts of cyanide of potassium, for brassing; and for bronzing, 12 parts of chloride of tin, instead of the 35 parts of sulphate of zinc; this solution, the patentee says, must be used at a temperature of from 25° to 36° cent. The proportions, the patentee says, may be varied within certain limits. BUCKET-LADDER. See VARIETIES OF STEAM-ENGINE. BUCKET-WHEELS. See CONSTRUCTION OF WATER-WHEELS. BUFFING APPARATUS. A contrivance for receiving the shock of a coalition between railway- carriages, consisting of powerful springs and framing. The buffing apparatus first used upon the Liverpool and Manchester Railway consisted of elliptic iron springs, or bows, of several thicknesses, placed transversely across the middle of the frame-work of the carriage which received the shock of whatever blows or jerks the buffer-heads might receive, by the aid of rods communicating with the same, to which method the following has been considered an objection :-If the several carriages are not loaded equally, the frames do not range upon the same level with each other and when this is the case, the buffer-heads consequently do not strike each other in the centre, whereby the rods become bent, and the whole apparatus is liable to get twisted: to remedy which Mr. Bergin, of Dublin, contrived an improved buffing apparatus for the carriages of the Dublin and Kingstown Railway. It is supported upon the axles of the wheels, and is totally unconnected with the frame of the car- riage, whereby it does not partake of the rise and fall of the latter, according to the weight acting Digitized by Google BUNG-CUTTING MACHINE. 197 615. upon the vertical springs; and two strong iron rods are passod through the whole length of the carriage, which rest upon small rollers, to which the buffer-heads are attached, spiral springs being wound round them, which re- ceive the effect of all shocks, by the help of collars formed upon the rods, and the introduction of stops to the springs. Fig. 619 represents a cross-section of the first model made by Mr. Tucker, under the direction of Mr. Ray, in the summer of 1844, and to which Mr. Tucker, Mr. Bradley, and Mr. Bannester, testify as being the model marked of B;" Fig. 617, the model made in 1845, to which Mr. Osgood, Bradley, and Gen. Thos. W. Harvey have testified Fig. 618, a rough sketch made by Mr. 616. 617. 619. © 618. Fowler M. Ray's Metallic India-rubber Car-Springs and Buffing Apparatus. Ray, in 1844, which he gave to a man about departing for England to take out some patents, who promised to write to Ray after his arrival in that country-which promise he has probably forgotten. Mr. W. C. Fuller, of England, patented the above spring, in that country, on the 23d October, 1845. He filed his enrolment April 23d, 1846, and on the 22d October, 1846, he took out a patent in the United States, under the title, " For Improvement in Railway Carriages," when the improvement consisted in the spring, and not in the carriage. By the above detail it seems clear to our minds that the invention, though claimed by an Englishman, (Mr. Fuller,) belongs to the American, (F. M. Section of Bergin's Buffing Ray.) Apparatus. BUHL WORK. See PUNCHES. BULLETS, manufacture of by rolling. At the Arsenal, at Woolwich, in England, they now manufacture leaden bullets by drawing and compression. These bullets have the advantage of being without blows or air cavities, and are rolled out of round bars of lead, which are passed between rolls formed like the roulettes used for ornamental work on the lathe. The rolls are constructed with hemispherical cavities, each one of which forms one-half of the ball, whilst the correspondent cavity forms the other half; the bullets are then finished by removing the extra metal, and being rolled together in a barrel. BULLET WOOD. See WOODS, varieties of. BUNG-CUTTING MACHINE. We here present two views of a machine invented by Messrs. Dowdy & Sweet, No. 35 Cross-street, of this city. Fig. 620 is a side elevation, and Fig. 621 a view of the cutter-stock and cutters. A is a stout table. H is a strong upright-post in the middle of the table. To this post the cutter-shaft C is secured by proper bearings DD, to allow it to revolve. F is a screw which passes through a bearing G, into an opening in the head of N. J is an elevating bed or rest for the plank that is to be cut into bungs. It is fixed on a treadle J, by a foot-spring K; when pressed upon towards L, the bung-bed is elevated through an opening in the middle of the Digitized by Google 198 BUTTON MACHINERY. 020. F . D H c D B & H K I o table, and as the foot presses K, so is the plank fed up to the cutter till the bung is cut, when the foot being released, the bung is driven out by a spiral spring, which will be better understood by Fig. 621. A is the cutter-stock. It is of a cylindrical form, with an opening through the 621. centre, and a thread a short distance at the upper end to screw in the shaft C. In the centre of the cutter-stock is a spindle with a spiral spring on it, represented by D. The spring does not reach to the ends of the spindle. By an open- ing in C, the shaft is allowed to pass into it, when the plank is fed into the c cutters; but when the bung is cut, this spiral spring in the centre of the cutter- stock recoils as the feed-table is lowered, and throws out the cut bung. This is the object and use of the interior spiral spring and spindle. GFH are the cut- ters. Each is a distinct piece, and each performs a different office. They are all set on to the cutter-stock, which is turned on the outside, leaving them to sit around it like a ring, where they are covered with a snug collar B, and a screw E E, for each cutter, secures them to the cutter-stock. The inside of the cutters is like a cup, and they are arranged almost like screws of different pitch. F has two little spurs on it; one on the inner side, and the other on the outer. These cut the cresses of the groove in the plank for the bung, when H follows after and scoops it out, cutting on the outside of the bung. Both of these cut straight with- out any taper. G is the taper cutter. It is graduated in the edge to the bottom of the cutter-stock; therefore it gradually planes the taper of the bung, after the B OF other two cutters have done the rough work. This makes the work easy on the machine, which cuts out about 20 bungs per minute, hand fed, with great ease. On the bottom of the stock, in the inside of the cutters, there is a small knife G H that rims off the edge of the bung. This machine has been in operation suc- cessfully for some time. BUSH. A piece of metal, usually made of hard brass, and fitted into a 622. plumber-block, in which the journal turns; they are also sometimes termed pillows, and the blocks, pillow-blocks. The guide of a sliding-rod is also term- ed a bush. Thus, in Fig. 622, A is the piston-rod, B B the bush. B BUSHES, metal for lining. See DETAILS OF ENGINES. A BUTTON MACHINERY. Buttons may be divided into two general classes,-those with shanks, or loops of metal, for the purpose of attaching B them to garments, and those without shanks; and each class is manu- factured from a great variety of materials, and by a variety of methods. Of buttons with shanks the greater number are composed of metal, although glass and mother-of-pearl are also employed for the purpose. Metal buttons are formed in two different ways, the blanks or bases of the buttons being either cast in a mould, or stamped out of a sheet of metal; the former method is gen rally employed for making white metal-buttons, and the latter for plated and gilt buttons. To cast Digitized by Google BUTTON MACHINERY. 199 buttons, a great number of impressions of the pattern of the button are taken in sand, and in the cen- tre of each impression is inserted a shank, the ends of which project a little above the surface of the sand, and fused metal is poured over the mould. When cool, the buttons are taken from the moulds, and after being cleansed from sand by brushing, are placed in lathes, the edges are turned, the face and back smoothed, and the projecting part of the shank also turned. The buttons are then polished by rubbing the faces upon a board spread with rotten-stone of different degrees of fineness, and afterwards by being held against a revolving board covered with leather, upon which is spread a very fine powder of the same material; finally, they are arranged on a sieve or grating of wire, and immersed in a boiling solution of granulated tin and cream of tartar, by which means their surfaces become covered with a thin layer or wash of the metal, which improves their whiteness without injuring their polish. The blanks of plated buttons are cut by a fly-press out of copperplate, coated on one side with silver. They are then annealed in a furnace, and afterwards stamped by the descent of a weight, as in a pile- driving machine, the die being fixed in the lower surface of the weight. The soldering of the shank is performed on each button separately, by the flame of a lamp and a blowpipe: the edges of plain but- tons are next filed smooth in a lathe, and the buttons are afterwards boiled in a solution of cream of tartar and silver; they are then placed in a lathe, and the backs brushed, and afterwards burnished with blood-stone. The metal used for gilt buttons is an alloy of copper and zinc. This metal is rolled out into sheets, and the blanks stamped out, which are then planished, if intended for plain buttons; but if for figured buttons, the impression is now given. The shanks are next attached, which is effected as follows each blank is furnished with a pair of small spring tweezers, which hold the shank down upon it on the proper place, and a small quantity of solder and resin is applied to each. They are then ex- posed upon an iron plate to a heat sufficient to melt the solder, by which the shank becomes fixed to the button; and whilst still warm they are plunged into nitric acid, to remove the oxide formed on the surface by the heat employed in soldering the shanks. They are then placed in a lathe, the edges rounded, and the surfaces rough-burnished, which renders them ready for gilding. Five grains of gold are fixed by act of parliament, in England, as the least quantity to be employed in gilding a gross of buttons of one inch in diameter. An amalgam is formed of gold and mercury, and the buttons are placed in an earth- en vessel along with the amalgam, together with as much aquafortis as will moisten the whole, and the mixture is stirred with a brush until the buttons are completely whitened. To dissipate the quicksilver the buttons are shaken in an iron pan, placed over a fire, until the quicksilver begins to melt, when they are thrown into a felt cap, and stirred with a brush, to spread the amalgam equally over their surfaces; after which, they are returned to the pan, and the mercury volatilized completely by the increased heat, leaving the gold evenly spread in a thin film over the surface of the buttons; they are then burnished in a lathe, which completes the operation. The better sort of buttons undergo the gilding process twice or thrice, and are distinguished accordingly as "double" or treble gilt." Glass buttons are formed of glass compressed, while in the fluid state, in moulds, in which the shank is inserted, and when the glass becomes cold, the shank is firmly retained in its place. In mother-of-pearl buttons the meth- od of inserting the shank is extremely ingenious: a hole is drilled at the back, and undercut-that is, larger at the bottom than at top; and the shank being driven in by a steady stroke, its extremity ex- pands; on striking against the bottom of the hole, it becomes firmly riveted into the button, forming a kind of dove-tail joint. Buttons without shanks are of two kinds; the first are simply disks of horn, bone, wood, or other material, with four holes drilled through the face, for the purpose of sewing them to the garment. Horn buttons of this description are made from cow-hoofs by pressing them into heated moulds. The hoofs having been boiled in water until they are soft, are first cut into plates of the requisite thickness, and after into squares of the size of the diameter of the button, and afterwards reduced to an octag- onal form by cutting off the corners. They are then dyed black by immersing them in a caldron of logwood and copperas mixed. A quantity of moulds somewhat resembling bullet-moulds, and each furnished with a number of steel dies, are then heated a little above the point of boiling water, and one of the octagonal pieces of horn is placed between each pair of dies, and the mould being shut is compressed in a small screw-press, and in a few minutes, the horn becoming softened by the heat, receives the impression of the die, after which the edges are clipped off by shears, and then rounded in a lathe. The holes in buttons of this description are drilled by means of a lathe, represented in the annexed engraving. Four spindles, of which two only, a a, can be seen, are supported in bearings at b, 623. c a D h b g 0 a D= d and by the centre points cc are made to revolve with great velocity by means of two bands d d passing over pulleys e e fixed upon each of the spindles, each band driving two spindles, and receiving motion from a wheel worked by a treadle. At the end of each of the spindles a, is a hook uniting them to four other spindles ff by similar hooks at one end, the other end of the spindles passing through four small holes in the plate g, and the projecting points being formed into small drills. The button is placed in a concave rest h, and pushed forward against the drills by a piece of wood. The standard g can be Digitized by Google 200 BYRNEGRAPH. exchanged for another with holes more or less apart, and the rest h can be set at any height to suit different-sized buttons. As the spindle-holes in the plate g are nearer together than the holes in the standard b, the spindles ff converge; the hooks in the spindles are therefore necessary to form a uni- versal joint. The second description of buttons without shanks consists of thin disks of wood or bone, called moulds, covered with silk, cloth, or other similar materials. The bone for the moulds is made from refuse chips of bone sawed into thin flakes, and brought into a circular form by two operations, illustrated by the accompanying engraving. On one end of the spindle a, which revolves in bearings 624. a d b 6 l m g at b b, is screwed a tool c, and on the other are two collars dd, between which a forked lever e embraces the shaft, the fulcrum of which is at f. The spindle a is put in rapid motion by a band g passing over the pulley h, and over a band-wheel worked by a treadle; and the workman, holding the material i for the mould in his right hand, against a piece of wood k firmly held down in the iron standard I by two screws, by means of the lever held in his left hand, he advances the tool c against the material i of the mould the central pin of the tool drills a hole through the centre of the intended mould, whilst the other two points describe a deep circle cutting half through the thickness of the material, and the flat surface is cut smooth by the intermediate parts of the tool. The tool is then drawn back a little by the lever e, and the material shifted to bring a fresh portion of the surface opposite the tool, and when as many moulds as the plate of the material will afford, are thus half cut through, the other side is presented to the tool, and the central point of it being inserted in the hole made in the first part of the operation, the other two teeth cut another deep circle exactly opposite the former one through the remaining substance of the material, and the mould is left sticking on the tool; by drawing back the lever e the tool recedes, and the mould, meeting a fixed iron plate, is pushed off the tool, and falls into a small box m. Covered buttons having come into very general use, various improvements have been introduced in the manufacture of them, and patents for this purpose 625. have been granted to various parties. The following is Mr. Sanders' method of making covered buttons: a piece of the material with which the mould is to be covered is cut of a a circular shape, somewhat larger than the intended button; upon this is placed a disk of card of the exact size of the button, and b b next a disk of paper coated with an adhesive composition, which c will become soft and sticky by heat and upon these is laid a button-mould e, having four holes, through which threads or a a strings have been passed to form the flexible shank. These circular disks being put together, are then laid over a cylindrical hole in a metal block a; this hole being exactly the size of the intended button, and the covering of the button being larger than the hole, when the disks are pushed down into the hole, the material of the covering will wrinkle up on the edges round the other disks. The tube bb is then introduced into the cylindrical hole, and its lower edge being bevelled inwards, will, as it is pressed down, gather the plaits of the cloth on the edge of the button; towards the centre is a metal ring or collar c, having teeth round its edge, some- what like a crown-saw, which is now passed down the tube b, and driven with considerable force by the punch d, and the block a having been previously heated, the adhesive matter will be softened, and cause the several disks to stick together, which, when taken out and become cold, will be very firm and retain its shape. BUTTON-WOOD. See WOODS, varieties of. BUTTS OF CROSS-TAIL, Rules for proportioning. See DIMENSIONS OF ENGINES. BYRNEGRAPH, OR NEW PROPORTIONAL COMPASSES: Invented by Oliver Byrne, the Editor of this Dictionary. Proportional Compasses have been very defective and expensive instru- ments, easily disarranged and almost impossible to be repaired. If the points of a proportional com- pass were disturbed in the least by constant use, sharpening, or accident, it was rendered wholely useless. Besides, each of these instruments was constructed from a number of experiments, and not by rule or on mathematical principles: 80 that no two proportional compasses were divided alike; or in other words, there has been no certain rule to determine the positions of the several divisions of the lines on the instrument. Mathematical instrument-makers in this, as in many other instances, determined the divisions by guess, or what is commonly called the rule of thumb," circumstances that not only left the dividing inaccurate and subject to change, but also made the number of divisions very few, merely Digitized by Google BYRNEGRAPH. 201 those answering to the whole numbers 1, 2, 3, 4, dc., which were intended to correspond with 80 many times the length, surface, or solidity of some particular unit of magnitude. The new proportional compasses, or as it has been termed, The Byrnegraph," not only remedies the defects of the old proportional compasses, but also extends the application of an instrument of 80 much importance to the engineer, the artist, the architect, and the amateur, in every department of applied mathematics, when its results can be relied on with confidence. The fact is, this mathematical instru- ment, from being one of the most uncertain, scarcely deserving the appellation mathematical," from the principles upon which it has been constructed, and the limited range of its application, by one or two simple contrivances, will now be found based on principles purely mathematical, and quite as cer- tain and as extensive in its results as the Sextant or Theodolite. The framework of this instrument may be made to assume different proportions and forms for the sake of ornament, compactness, or convenience, according to the fancy or design of the maker; the first completed was constructed by Cary, 181 Strand, London, and explained at York, before the British Association, in 1844. A view of the instrument, which we shall describe, is given in Fig. 626 it differs but little from that constructed, according to the directions of the inventor, by Désiré Lebrun of Paris. 626. 24 A B 8 The two boxes E pq, F pq, are 80 adapted to the beams A B, CD, that they may be moved together by sliding to any part, and fixed in that position by tightening the clamp-screws E and F. When the moveable centre E q F, is clamped in any position, the instrument turns on an imaginary line or axis passing through EF, perpendicular to a plane passing through P q, the junction of the boxes E pq, F Pq the friction of the planes meeting at pq renders the motion uniform. Connected with the brass boxes at K and L are two points of the instrument meeting at x: at K and L there are two clamp- screws to fix the boxes, which must be moved together. When the points are in their proper places, the proportions of the instrument that we are describing are these :-Suppose st = 1, then tu = 24, and uv = 5. The points at x are represented in proper adjustment, but those at y must be moved till y comes up to the line w, and then made fast by the clamp-screws at Q and R. When the points are worn or broken, the boxes QR, LK, must be moved accordingly, so that the equal beams, A B, CD, exceed the 24 equal parts, in order to give the instrument sufficient range. It is also advisable that the lengths of the points should exceed rather than fall short of the designed proportions. We shall now show how to determine the lengths and proper positions of the points at any time; an adjustment upon which the accuracy of the instrument very much depends. Let the boxes Q, R, Fig. 627, be moved together until the points y just touch a straight-edge appended at BD; then BR, the length of the points, 627. is determined from a scale on the upper side of AB. Or the length may 24 be more accurately found by moving the centre-piece in conjunction with R QR, and taking the difference of the numbers pointed out by the same B vernier, when Q R is at BD, and when the points y fall within BD. If this length be greater than five or any other number of equal parts allotted Q to the longer points, then Q R must take its fixed position accordingly; so that not more than the designed number of equal parts may extend beyond W, where the 24 divisions are supposed to terminate on the beam AB. In the present case the differ- ence between 5, 50, or 500, and RB, will give the difference of Q R from W. A similar operation, will be required to adjust the points at x. Figs. 628 and 629 show the instrument when closed and open, viewed directly over K E R, Fig. 626; it must be always closed as in Fig. 628 while sliding, and fixing the moveable centre EF to any required proportion, and when being used the moveable centre must be firmly clamped. 628. 629. For the purpose of ascertaining with great exactness the position of the moveable centre EF, Fig. 628, there may be four verniers or reading-plates, two at each side of the instrument, fixed in openings, as m, n. From opening and shutting the instrument from time to time, the motion will require some 26 Digitized by Google 202 BYRNEGRAPH. adjustment to render it uniformly smooth, to move stiffer or easier at pleasure, and to keep steady in any position that may be given to it, 80 that the motion may be similar to that of an ordinary pair of compasses. This adjustment is performed by the application of a windlass turn-screw to the clamp at one side of pq; thus the pressure on the planes that meet at pq is increased or diminished. On the faces of the limbs of this instrument there are in general four sets of lines and divisions; the first de- nominated the line of lines;" the second, the line of circles;" the third, the line of surfaces;" and the fourth, the line of solids." With the assistance of the accompanying table, one or two lines of equal parts with verniers attached will answer every purpose. Before entering upon the use of this instrument, it may be necessary here to explain the nature of verniers generally; which is very simple, and can be shown as follows: (see Byrne's Practical, Com- plete, and Correct Gager, page 52.) Any straight line or circular arc divided equally, can again be subdivided by a vernier with little trouble, to very great minuteness: for example-let the line B be taken of any number of equal parts whatever, and a moveable scale or vernier, V, that contains on the bevelled edge of d, 9 of the equal parts of A B divided into 10-i. e. the 10 equal parts or spaces on the vernier are equal to 9 on the line A B; this vernier will divide each of the former divisions into 10 equal parts. 630. A 0 1 2 3 B d 7 v Let the vernier a b d or V, be moved to V', then 0 or zero, the point commencing the scale on the vernier, has moved over 15 divisions on A b and something more, which is three-tenths-found on the vernier by seeking where the divisions on it coincide with those on the line A B: in this case they coincide at 3; therefore the distance on the line A B, from 0, to where 0, on the vernier rests at V', is represented by 15:3-also from a to a', or from b to b', is 15:3: and in fact, every point of the vernier has moved 15.3 of the divisions on A B, from its position at V to its position again at V'. Again, let the vernier be moved along the line A B, to the position V", then we find that 0, or the first division on the vernier, has moved 28 divisions and part of another, which is seven-tenths of it, as the division on the vernier at 7 coincides with one on the line B; therefore, from 0, on the line AB, to where 0 on the vernier rests at V", is 28.7, and from a to a", or from b to b", &c., is 287; as before shown with 15.3, when the vernier rested at V'. The distance on the line A B, between 0 on the vernier at V', and 0 on the vernier at V", is 287-15-3=13;4, and the distance between a' and a", or b' and b", is 13.4. Sup- pose 11 of the equal spaces on any line, as AB, be taken, and divided into 12, for a vernier; or in other words, to have 12 divisions on the vernier, equal to 11 on the scale upon which it moves: this vernier divides each of the divisions upon such a scale as A B, into 12 equal parts; or, as it is said, it reads off 12ths. Again, if we take 19 equal parts on any scale, equal to 20 on a vernier, such vernier reads off 20ths; if 49 on the scale be equal to 50 on the vernier, the vernier reads off 50ths, and so on. "The line of lines" on the instrument that we are describing, is divided into 3000 equal parts by one of the verniers attached to the moveable centre. The reckoning commences at the extremity of the shorter points; therefore the division marked 150 and may be read 1500, is in the middle of the line that is, the division marked 150 is equally distant from the points at x and those at y. There may be another set of divisions on this line marked 1, 2, 3, 4, 5, &c., and represent the ratios 1 : 1, 2 : 1, 3 : 1, 4: 1, 5: 1, &c., respectively. The division marked 1 coincides with the one marked 150. When the division on the vernier marked zero is set to 1, or 150 on the line of lines, any opening of the compasses will be equal at both extremities. When the vernier zero is in like manner set at 2 or 100 on this line, then any line between the longer points (y, y', Fig. 629) will be twice as great as the one between the shorter points x x'; the angle of opening remaining constant: consequently any line taken between the longer points may be accurately divided into two equal parts by the distance be- tween the shorter points. Further, when the zero of the vernier belonging to this line is set to the division marked 3 or 75, the ratio of x x' to y y', at any opening will be as 1: 3, or the line between the shorter points will be one-third of the line between the longer points. The same may be said of the remaining continuous divisions. The positions of the integral divisions 1, 2, 3, &c., among those marked 10, 20, 30, &c., can be readily ascertained for instance, if it were required to find the position of the moveable centre 80 that the distances between the points may be in the ratio of 1 to 7, we have only to divide 8000 into two parts in the ratio of 1 : 7, thus: 875 7 3000 2625 Therefore 7 on the line of lines must stand at 375 or 2625 on that line; for it will be found that 375 + 2625 = 3000 and 375 : 2625 1 : 7 This and the like proportions may be found at once by the succeeding table: the decimal of 1-7th = 142857, opposite which in the table we find 875, the division at which we find the zero of the vernier must be set. 2625 represents the same position as 375, for one tells the distance from the shorter points and the other from the longer; the distance between the points, as we have before observed, is supposed to be divided into 3000 equal parts. It may be inconvenient from the space occupied by the centre to continue this aliquot series of divi- Digitized by Google BYRNEGRAPH. 203 "ions beyond 9 or 10, so that if 1-20th of a line be required, we must have recourse to the following means; take 19-20ths of the line, and the remainder must be 1-20th: thus- 19 + 20 : 3000 20 19 1462 1538 If zero be set at 1462, or its supplement 1538, on the line of equal parts marked 10, 20, 30, &c., then the distances between the points, in any position at one side, is 19-20ths of the distance between the points at the other side, the compasses retaining the same angle of opening. The position of the centre can be immediately determined by the table before alluded to: opposite the nearest decimal to that of = -950000, we find 1462, which was before determined. We have called 1538 the supplement of 1462, because 1462 + 1538 = 3000. Some of these supplemental ali- quot divisions might be laid down between 100 and 150, and others of them between 150 and 90, and marked in a contrary position to the numbers on this line which express the direct aliquot parts: thus 8 might signify 7; hence 6 signifies s; 13 signifies 13; and 80 on. However, unless for these very large portions, it is better to calculate the position of the moveable centre for each as it may be re- quired, the operation in all cases being so simple, especially with the table. By reading off the vernier in any position and taking the result from 3000, we have the ratio between the lines at any angle of opening; for example, suppose the vernier, when the centre is fixed, to show 1693, then the openings will be as 1693 : 1807, for 1693 + 1807 = 3000. The position of the moveable centre for the greater aliquot and supplemental divisions, may be im- mediately determined by the following table:- Ratios. Centre at Ratios. Centre at Ratios. Centre at Ratios. Centre at Ratios. Centre at 1 1 1500 .1 7 375 12 13 1440 18 19 1459 24 25 1469 5 1 2 1000 1 8 333 13 14 1445 19 20 1462 25 26 1471 1 3 750 1 9 300 14 15 1448 20 21 1464 26 27 1472 1 4 600 1 10 273 15 16 1452 21 22 1465 27 28 1473 1 5 500 10 11 1428.5 16 17 1455 22 23 1467 28 29 1474 1 6 429 11 12 1435 17 18 1457 23 24 1468 29 30 1475 Thus, if the centre be set at 600, lines may be divided into four equal parts; if set at 1455, any given line can be divided so that the whole is to one of its parts in the ratio of 17 to 16 or the whole to the other part as 17 to 1. L Let it be required to take 13 of any given line A B. = decimal 136843 % = decimal 863157 1. 1.000000 A C B Opposite 136843 in Table III, we find 361 or rather, opposite 136794, which is the nearest to 136843 in the table, we find 361: and opposite to the nearest to 863157 we find 1390. If the centre be set at 1390, and the line A B taken between the longer points, then the shorter points will extend from A to C, or %? of A B; hence CB will be 13 of AB. But this can be taken between the lesser points if the centre be fixed at 361, and the line A B placed between the longer points. Or, by the Rule of Three: To lay off A B and A 0 between the points, say, As 82 + 95 8000 82 1889.8 nearly = 1390 95 1610'2 = 1610 To lay off A B and BC between the points, say, As 95 + 13 = 108 3000 13 361.1 nearly = 361 95 2638. = 2639 II. Let it be required to take the to of a given line m p. to = .025000 18 = 975000 m n p 18 1.000000 Opposite 974982, which is the nearest to .975000 in Table III, we find 1481; therefore if the centre be set to 1481 or to 1519, its supplement, and m p taken between the longer points, m n = 39 of m p will be the distance between the shorter: by laying off m n we also lay off 76 P the 1-40th of m p. By the Rule of Three: 39 1481 As 39 + 40 = 79 3000 40 1519 The Line of Circles-The line marked " circles," may also be furnished with a double set of divi- sions; one set for polygons, and the other for laying off any portion of a circle in degrees, minutes, and decimals of a minute. When zero on the index is set to any number on the line of polygons, the points will open in the proportion of the radius of a circle to the side of an inscribed polygon of that number of sides; thus, if it be set to the division marked 7, and the points yy' opened to the radius Digitized by Google 204 BYRNEGRAPH. of any circle, the opening of the points at x x' will divide the circumference into seven equal parts. Or, the position of the centre, for any polygon from 3 to 20 sides, is given in the annexed table. Sides. Centre at Sides. Centre at Sides. Centre at Sides. Centre at Sides. Centre at Sides. Centre at 8 1902 6 1500 9 1219 12 1023 15 881 18 773 4 1757 7 1394 10 1146 13 971 16 842 19 741 5 1621 8 1301 11 1081 14 923 17 804 20 715 The use of this table is obvious, for if the vernier be set at 1394, and the radius taken between one pair of points, the side of the required heptagon will be between the other points; and so of other polygons. The other equal divisions are like those already described on the line of lines, only the numbering runs in a contrary direction, commencing to count from the extremities of the longer points. To lay off any number of degrees, minutes, dc. find the division from the following table, opposite the natu- ral sine of half the given angle, and set the vernier to that division; then if the diameter be taken with the wider opening, the other opening will be the chord of the given angle, which is easily applied to lay it off. III. It is required to lay off an angle in the semicircle A B o 631. equal to 136° 323 = 136° 17' 19" 88. 2)136° 17'·323 C Nat. sine 68° 8'·6615 = 928126 The nearest number to 928126 is 928020, which is opposite to 1444; therefore if the moveable centre be set to 1444, and A B taken between the shorter points, which is the greater open- ing, then BC will be the distance between the longer points, A o B and the angle B = 136° 17'·323. It may be necessary to remark, that the lines are numbered from the shorter points, 10, 20, 30 250 and from the longer points 50, 60, 70, 290, 80 that 144·4, on the line of circles, which is numbered 50, 60, 70, &c., may be represented by 1556, as both are equally distant from the centre, for 1556 as far exceeds 1500 as 1444 falls short of it. If the centre be fixed at 1556, and A B taken between the longer points, then B C, the chord of 136° 17' 19". = 186° 17'·323, will be the distance between the shorter points. The only alteration that takes place by changing the centre from 1444 to 1556 is a change in the application of the points; the diameter was taken between the longer points when the centre was fixed at 1444, and between the shorter points when it was fixed at 1556 ; 1444 + 1556 = 3000. Table III, containing nearly 5000 ratios, calculated to 6 places of decimals, is given in a pamphlet which accompanies the instrument. Opposite 24 and under 6, or answering to 246, we find 089324, showing that 246 is to 8000 less 246, or to 2754, as 089324 : 1. A vernier that subdivides a line into 10ths may also be made to read 20ths, by making the spaces on the vernier coincide with those on the line; or rather, by making two consecutive divisions on the vernier fall just inside of two consecutive divisions on the line. For example-suppose that 0 on the vernier has passed over 140 and 7 of the smaller divisions, and a little more, so that the space between 5 and 6 on the vernier falls opposite a space on the line, then the centre is at 14751 or 14755. Hence the length of the instrument is divided into 6000 equal parts, and Table III. will answer for 6000 as well as 8000. For instance: Opposite 1475, in the table, we find 967212 and 1476 968502 2) 1290 = diff. 645 967212 opposite 14755, in the table, should be 967857 The converse of this operation is simple. Any number of degrees, minutes, &c., may be laid off by setting the vernier at the number corres- ponding to that which is nearest to double the natural sine of half the given angle: the remainder of the operation is the same as that just described, only the radius is taken instead of the diameter. IV. Let it be required to lay off an angle of 37° 34''646, or 37° 34' 632. 88"76. 2)87° 34''646 Nat. sine of 18 47323 = 322072 2 644144 Opposite .643888, which is the nearest to 644144 in the table, we find 1175. If the centre be fixed at 1175, or 1825 its supplement, and the radius 0 A taken between the greater opening, then will the lesser opening be A B the chord of 37° 34' 88"76 = 37° 34''646; that is, OA : AB 1-000000 644144 Digitized by Google BYRNEGRAPH. 205 an accuracy is thus attained in laying off angles never before arrived at, by a contrivance so simple. Although a sextant, theodolite, and other complicated mathematical instruments give angular distances with as much exactness as can be required, yet we were unable to transfer them to our constructions with the same accuracy, for want of a simple instrument like the one which we are describing. It must, at the same time, be admitted that it requires more time to lay off an angle with the proportional com- passes than with the protractor; yet, where any thing like accuracy is required, the additional trouble is more than compensated for. To lay down 'an angle with the proportional compasses that is small, or not greater than 10 degrees, it is better to lay down an angle equal to 60° plus or minus the given one, thus: V. In the circumference of the circle ABB' it is required to lay off an arc equal to 8° 39'621 = 89' 37"26. 60° O' 8 39621 2)56 20379 Nat. sine of 28 10-1895 = 472088 2 944176 Opposite 944264 in the table we find 1457, the nearest to 944176; therefore if the centre be set at 1457, and o A, the radius, taken between the greater opening, the lesser opening will extend from A to m, and the angle m o A 56° 20'379 and if the angle B'OA = 60°, the chord of which equal the radius, then the angle B'O m equal 3° 39'621 = 3° 39' 87"26 hence B m is an arc subtending this angle. Without changing the centre the same may be done with any other circle, whose radius can be taken between the greater opening. In this example, OA : A m : 1*000000 : 944176 or, which is the same proportion, o A: A m 1543 : 1457. By this simple means an angle may be laid down to the decimal of a second, and that, too, with as much accuracy, be the circle large or small. 954176 falls between 943005 and 944264 in the table. We have selected the number indicated by the latter, for although it is greater than 944176, yet it is nearer to it than 943005. The lines of surfaces or of squares, show the 633. ratios between the areas of similar plane figures, and like the other lines may have a double set of divisions. The integral divisions marked 1, 2, 3, 4, &c. The fractional divisions are common to the four lines; the numbering of this line is the same as that of the line of lines, 10, 20, 30, 40, B c D dc., reckoning from the shorter points to the longer. If zero be set to 2073 or 927, which is found opposite 5, in Table IV., (see pamphlet,) and the radius A B of any circle measured with the greater opening, then if a circle be described with CD the lesser opening, this circle will contain 1-5th the area of the other. The same may be said of squares, triangles, or any other plane figures that are similar. 634. 3 VI. Let it be required to describe a figure abcde, similar to ABCDE, whose area will be 17 of it, or, which is the same, Area ABCDE area a 37 17. = 677834, c which can be readily determined by logarithms, as follows D Log. 17 1.2304489 Log. 37 15682017 6622472 Log. 677834 18311236 Opposite 677852, which is the nearest to 677834 in Table III, we find 1212. Hence, if the move- able centre be fixed at 1212 or at 1788, and the lines AB, AC, A D, &c., taken within the greater opening, the lesser opening will give a b, ac, ad, &cm, to form the figure ab de similar to ABCDE, whose area will be in the proportion required. VII. On two maps of the same place, say America, the distance between New York and Baltimore stands between the greater opening of the proportional compasses on one, while the distance between the same places stands between the lesser opening on the other map; the centre is found to be at 1234: required the number of times one of these maps is greater than the other. 8000 1766 2 1234 1766 1234 20481 times nearly. Digitized by Google 206 BYRNEGRAPH. By logarithms. Log. 1766 32469907 Log. 1234 30913152 1556755 2 3113510 = Log. of 20481. The use of Table IV. is obvious, for if the zero be set at 1309 on the line of surfaces, lines similarly placed in similar surfaces or figures will exactly fit between the openings of the instrument, when the area of one of the surfaces or plane figures is 6-10ths of the other; if the zero be set at 2145, the open- ings will coincide with lines similarly placed in similar figures when the area of one is 6 and 3-10ths the area of the other; and again, if the centre be set at 2561, the openings of the points will coincide with similar lines in similar figures, the area of one being 34 times the area of the other. Line of Solids.-The arrangement of this line resembles the arrangement of the Line of Surfaces; with this line similar solids are compared, by taking between the points of the instrument lines that are similarly placed in them, in the same manner that similar surfaces were compared bv the line of surfaces. VIII. At what division on the line of solids must the vernier be set, so that if the side of a cube be taken between one pair of points, the side of a cube 78 times as large will fit between the other pair of points, with the same angle of opening! : 1 = : 6 = 283714 By logarithms. Log. 6 7781518 Log. 47 1-6720978 8)11060585 1.3686845 log. of 233714. Opposite 568 we find 233552, the nearest number in Table I. to 238714; if the centre be clamped at 568, then the cubes whose sides fall between each pair of points will be to one another as 47 : 6, or the solidity of one of them will be 7g the solidity of the other. IX. In two animals of the same species, which may be taken as similar solids, it was found that the lengths of similar parts at the same time coincided between each pair of points, with the centre fixed at 855 how many times larger is one of these similar solids than the other ? From 3000 Take 855 = 15-79 times. 2145 By logarithms. Log. 2145 33314273 Log. 855 2.9319661 3994612 3 1.1983836 So that one of these animals is nearly 16 times the size of the other. Like the table for the line of surfaces, the use of this is at once apparent; for if zero be set at 1272 on the line for comparing solids, lines similarly placed in similar solids will exactly fit between the open- ings of the instrument when the solidity of one of the bodies is 4-10ths (T4 or 4) of the solidity of the other. If the zero be set at 1980, the openings will coincide with lines similarly placed in similar solids, when the solidity of one is 733 times (7.3) that of the other. Again, if the centre be set at 2325, the openings of the points will coincide with similar lines in similar bodies, the solidity of the one being 41 times the solidity of the other; that is, the solid between the longer points, or rather applied to the longer points, will be 41 times the solidity of a similar solid similarly applied to the shorter points, when zero on the vernier is set to 2325 on the line of solids; for in Tables IV. and V. the unit is sup- posed to be placed between the shorter points. X. Given a circle A BCD, to lay off a line equal to its circum- 635. ference. c The diameter of a circle is to its circumference as 1 : 81416, nearly opposite 3.1416 we find 2276 in Table III. to be the near- est, but by proportion 3.1416 will be found to correspond more A nearly with 22757. Set the index of the moveable centre to 7243, or to its supple- E M ment 22757, then if any diameter A B be taken between the less- er opening of the instrument, the greater opening will extend from E to F = the circumference of t] circle A BCD; this will not be more or less than the circumference 100'000 part of the radius. Digitized by Google BYRNEGRAPH. 207 XL Let it be required to construct a parallelogram, whose area 636. shall be equal to that of a given circle BC. B As in the last example, set the index to 7243 or 22757 then take the radius D A between the lesser opening, and it will be one of the sides of the parallelogram E H; the opening of the other points will C be the other side EF, forming a parallelogram EG, equal in area to D the circle A B C. XII. Let it be required to make a square equal in area to a given circle A B. H G When the side of a square equal 8862, and the diameter of a circle equal 1; these areas are very nearly equal opposite 8862 in Table III, we find by proportion 14095. Set the index to 14095 or 15905, then 'if the diameter A B of the circle be taken between the greater opening, the side DE of the 637. square, equal in area to that of the circle, will be given by the lesser opening; 80 that while the centre is thus fixed we can instantly make A squares equal to circles, or circles equal to squares, large or small, ac- c cording to the range of the instrument. It may be remarked, that when the space on the vernier between 0 and 1 falls evenly between B one of the divisions on the limb, and the zero of the vernier beyond to 1490, then the zero is said to stand between 1490 and 1491, or at 14905. This reading may require another example: Suppose the space on the vernier between 7 and 8 falls evenly between one of the divisions on the limb, and that the zero on the vernier is beyond 154, then the zero of the vernier is said to stand half way between 1547 and 1548, or at 15475. XIII Describe a circle whose circumference will be 111 inches. Set the index to 22757 or to 7243, its supplement; then if the half of 111 inches, or 57 inches, be taken between the points of the greater opening, the lesser opening will be the radius of a circle whose circumference will be 111 inches. XIV. To divide an arc or angle of any number of degrees, minutes, &c., say of 84° 36'-25, into any number of equal parts, say 3. 638. It may be first necessary to make an angle of 84° 36'-25; this may be done as before shown: 84° 36'-25 ÷ 2 = 42° 18'125 nat. sine of 42° 18'-125 = 673090, and 673090 X 2 = 1-346180, opposite which, in Table III, we find 17215, to which, if the index be set, and the radius taken between the lesser opening, the greater B will extend from A to C, and subtend an angle 00 = 84° 36'-25. Again, 84° 36'-25 ÷ 3 = 28° 12'083 ÷ 2 = 14° 6'047, nat. sine = 248630 X 2 = 487260, oppo- site which, in Table III., we find 983, to which, or to its supplement 2017, the centre must be set; then if the radius be taken between the greater opening, the lesser will o extend from A to B, and divide the angle CO A into three equal parts. XV. Given the diameter of a globe A B to find the side 639. 640. of a cube whose solidity will be equal to that of the globe. When the diameter of a globe is 1; the side of a cube equal in solidity to it is 805996, opposite which, in Table III, 1338 is found, to which if the centre be set, and the A B diameter of any globe A B taken between the greater opening, the opening of the other points will give CD, the c D side of a cube whose solidity is equal to that of the globe. XVI. To describe a regular polygon, (e. g. hexagon,) whose area will be equal to that of another regular figure, (decagon.) The area of a decagon whose side is unity = 7694209 the area of a hexagon whose side is unity = 7694209 2.598076 then = the side of a hexagon of equal area to a decagon whose side is unity 2.598076 this is readily found by logarithms to be 1-720902, opposite which, in Table III, we find 18975, to which, if the index be set at any opening, one pair of points gives the side of a regular hexagon, whose area is equal to that of a decagon, the side of which is found between the other pair of points, at the same angle of opening. 641. 642. F With the index set at 18975, A B will be o D given by one pair of k points, while a b is given by the other. 1 R bl XVII. In a certain construction the square root of 33 equal parts is required with great accuracy; at what point must the centre be set to effect this object! Opposite 5-74456 = 88 in Table III, we find 2555, to which, if the index be set, and any line Digitized by Google 208 CALENDER. supposed to be divided into 33 equal parts taken between one of the openings of the compasses, the other opening will give the square root of 33, and will not be in error 10000 part of a unit. XVIII. It is required to lay off a line whose length is represented by the cube root of 7. The cube root of 7 : 7 :: 1: 3.6593, or 7: 7 : : 1 : 3.6593. Opposite to 3-6593, in Table III, we find 23565, to which if the index be set, the cube root of any line supposed to be divided into 7 equal parts will be given in the lesser opening of the instrument, when the line stands between the points of the greater opening. CALENDER WITH FIVE ROLLERS, Designed and Constructed by Messrs. A. More and Son, Glasgow. Fig. 644, an end view; Fig. 643, a side elevation; the same letters of reference denote the same parts in each view. A A A, three cylinders or rollers made of paper, the construction of which will be noticed afterwards. BB, two cast-iron cylinders, made hollow to allow of the introduction of hot bolts of iron within them; or of steam, when it is required or preferred. 644. H H H 643. D D G D E < B I B C C C A A C F F SCALE.-1-4th inch = 1 foot. 645. 646. C G D ID D A A Q 0 A 0 C c B B F SCALE.-1-5th inch = 1 foot. 00, the two side-frames or cheeks, into which are fitted the several brass bushes for the cylinders to turn upon. DD, top guides, into which the cross-head G, and elevating screws H H, work. EE, top-pressure levers, connected by a strong rod of iron with the under-pressure lever F. This Digitized by Google CALENDER. 209 system of levers is connected with the cross-head G, by two strong links of iron. The elevating screws H H pass through the cross-head, and rest upon a strong cast-iron block, into which is fitted the brass bush of the top paper roller. By means of the screws, the cross-head and levers can be raised or depressed as required, and when the calender is working warm and requires to be stopped, the elevating screws are screwed up for the purpose of lifting the paper rollers off the hot cylinders, to prevent their being injured by the heat. The construction of the paper rollers or cylinders is as follows: Upon each end of an arbor of malle- able iron, of sufficient strength to withstand the necessary pressure without yielding, is fastened a strong plate of cast-iron, of the same diameter as the roller to be made; the plate is secured in its proper place by a ring of iron, cut in two, and let into a groove or check turned in the arbor. When the roller is finished, the annular pieces are kept in their groove by a hot hoop put upon the outside of them, and allowed to cool. A plate is fitted on the other end, of exactly the same size, and in the same manner. In building the rollers, one of the plates is taken off the arbor, but the other is allowed to remain in its place. The paper sheets of which the rollers are to be made, have each a circular hole cut in the centre of it, of exactly the same diameter as the arbor. The sheets are then put upon the arbor, and pressed hard against the fixed plate. When the arbor is filled with paper, it is put into a strong hydraulic-press, and pressed together,-always adding more paper to make up the deficiency caused by the compression, until the mass will press it no harder. The half rings are then put in their place, to prevent the plate from being pressed back by the elasticity of the paper. The roller is now to be dried sufficiently in a stove, the heat of which causes the paper to contract so as to be quite loose. The roller is then again taken to the press, and the unfixed plate being removed, more paper is added, and the whole again compressed, until the roller is hard enough for the purpose to which it is to be applied. It is next turned truly in the lathe till it acquires a very smooth surface. The wood-cut, Fig. 647, shows the manner in which the calender is geered to make it a glazing calender. In this cut, a marks the top cylinder of the calender, upon which is keyed a spur-wheel b; and c is the under cylinder, upon which is also keyed a spur-wheel d. The intermediate or carrier- wheel e, when drawn into geer, reduces the speed of the under cylinder c, one-fourth. Now, the cylinder a, being the one that gives motion to all the rollers, and revolving always at the same speed, the cloth 647. 648, b h in its passage through all the rollers below the cylinder a, is carried through at a speed one-fourth less than if it passed only below the cylinder a; consequently, when it comes into contact with a, it is rubbed, and thereby glazed, in consequence of the cylinder a moving one-fourth quicker than the cloth, as above stated. The wood-cut, Fig. 648, shows the manner in which the rollers are lifted clear of each other when the machine is stopped. In this, e.e are two rods of iron, attached to the block or seat of the top roller bfg, three bridges of malleable iron, capable of sliding upon the rods ee; but held fast upon the rods when once they are adjusted to their proper places by pinching screws. The bridge b is placed half an inch clear of the bearing of the cylinder a, when all the rollers are resting upon each other; the bridge f is placed one inch below the bearing of the paper roller h; and the bridge g is placed one inch and a half below the bearing of the cylinder c. When the pressure screws of the calender are lifted, the blocks of the top roller being attached to them, the rods ee are lifted also, and along with them the different rollers as the bridges successively come into contact with their respective bearings. The manner of passing the cloth through the calender varies very much, according to the amount of finish required upon it. The various methods are accomplished by different arrangements of the geering, so that a calender calculated to do all the different kinds of finishing becomes a very compli- cated machine, on account of the quantity of geering required. For common finishing, the method of passing the cloth through the calender is as follows :-The cloth is passed alternately over and under a series of rails placed in front of the machine, so as to remove any creases that may be in it, and is then introduced between the lower roller A and cylinder B; returns between the lower cylinder B and the centre roller A; passes again between the central A and the upper B, and again returns between the top pair A, B, where it is wound off on a small roller, (hid in the drawings by the framing of the machine,) pressing against the surface of the top roller A. When this small roller is filled with cloth it is removed, and its place supplied by another, to be in succession filled as the motion of the machine progresses. 27 Digitized by Google 210 CALENDER. Water-Mangle with two copper, and three wooden rollers; designed and constructed by Messrs. A. More and Son.-This machine, Figs. 645 and 646, differs nothing in principle, and little in general construction, from the five-rollered calender above described, except in this-that it is intended for wet goods. It is drawn to a scale slightly less, but the views given and the lettering of the parts correspond to those of the preceding figures. A A A, the three wooden rollers, and BB, the two copper rollers of the mangle. These last consist of a copper cover upon a cast-iron body, through which passes a wrought-iron arbor, differing from those of the wooden rollers in being round, whereas these are square between the bearings. The smaller of the two copper rollers, namely, the third in order, is in this arrangement the driver, the mangle being driven like the calender, by a system of reversing geer not shown in the drawings. The pressure in the mangle is brought on by a system of levers, which differ slightly from that described. In this, indeed, there are strictly two distinct pressures: that brought on the axis of the middle roller by the lever E, which is connected by a link with the weighted lever F; and that transmitted through the whole system of rollers by the single-weighted lever D. The weight of this last is regulated by means of a set-screw, which turns in a nut in the jaws of the lever D, and bears upon the set-block which rests upon the arbor of the top roller. This pressure is thus transmitted downwards from the top roller throughout the whole set, and at the middle roller B is added to the pressure obtained by the lever E. By this arrangement, the pressure between the three under rollers is greater by the pressure of E, than it is between the upper pair; but, for very high pressure the lever D may be locked by set-pins and the set-screws turned down by the hand-wheel G, until the requisite degree of pressure is obtained. The manner of passing the cloth through this machine is the same as that already described in the calender, with this single exception, that before the cloth enters between the lowest roller A, and the small cylinder B, jets of water from a pipe, perforated with small holes, extending the whole width of the machine, are allowed to play upon the cloth, 80 as to impart to it sufficient moisture for causing it to receive the requisite degree of smoothness preparatory to the starching process, and at the same time allow the cylinder B to free it from any impurities that may be remaining in it, by forcing them back with the expressed water. CALEMBEG. See WOODS, varieties of. CALENDER. Description. A, two cast-iron frames. BCD, three cylinders. EFG, thrce cog- wheels. HI, two force-screws. KL, two fly-wheels with handles. 649. 1 E The cylinder B, which is in cast-iron, and hollow, is heated by another iron cylinder heated red hot. The material of the cylinder C is pasteboard, its axle is of wrought-iron. These three cylinders must be perfectly round and parallel. The wheel F forms the communication between E and G, which rest upon the cylinders B and D. The relation of F to the circumference of the cylinders is such, that when the machine is set to work Digitized by Google CALICO MACHINE. 211 these cylinders slide, causing friction, and thus give a gloss to the cloth. The friction is variable, ac- cording to the nature of the tissue. 650. K H E F R G In order to set the machine in motion, the fly-wheels K and L being turned in order to press the screws H and I against the pillows of the first cylinder B, the cloth is placed between the rollers in the direction indicated by the arrows. CALICO: Machine for printing in four colors. In this machine the pressure is normal, in all the engraved rollers, by the means of the levers P. These rollers are turned by a belt communicating with the prime mover. The regulators are adjusted by screws, to which are attached hands, indicating, upon dials, the space to be run by the rollers in order to reach the regulators: this is known without stopping the works. The engraved rollers can be brought up to the pressing cylinder, or withdrawn from it, without changing the places of the color-vessels or of the scrapers, for all the different pieces fixed against the pillows on the turning pieces of the engraved rollers, move with these last. Finally, there is an appa- ratus placed behind the under cloth, the intermediate cloth, and the stuff to be engraved, by which the workman governs these three pieces at will. The engraved rollers are sometimes made of copper, sometimes of brass, or of copper and tin. The first are to be preferred, being less apt to be injured; with such a cylinder 30,000 pieces can be printed with the most delicate patterns. The brass cylinders will be injured in proportion to the acidity of the printing-mixture, the zinc being attacked Those in whose composition tin is introduced are more hard, but also more difficult to en- grave. Some of these cylinders are hollow, others are massive: either may be used. The diameter of the cylinders varies from 0.23 to 0.82 feet, according to the option of the manufac- turer, and also to the dimensions of the pattern. The dimensions of the pressing-rollers make no difference in the impression : the lesser ones should, on certain considerations, be preferred, for the engraved rollers always yield under the pressure of the first, so that it becomes necessary to give a curve to the pressing-roller equal to that of the engraved ; and as the pressure it exercises is inversely to the augmentation of its diameter, it becomes necessary to increase the weight on the subterraneous levers, thus giving still more chance to the engraved cylinders to bend. M. Huguenin thinks that a pressing-roller having only a diameter of 0.856 feet, for machines printing only one color, and that of those printing several colors, the smallest possible must be used. In some manufactures these rollers are wrapped with a band of a tissue, the warp of which is flax, and the weft of worsted, having the property of not lengthening under pressure; at the centre of the roller, this envelope is 0.062 feet thick, at the extremities 0.032 feet. The most modern improvement in this respect is the introduction of a tissue of cotton and caoutchouc. The furnishing rollers have their circumference enveloped in a woollen cloth; their speed is inferior to that of the engraved cylinders; their diameter is generally about 0.328 fect. The vessels in which the rollers dip are made of copper or wood. It is necessary to keep them sup- Digitized by Google 212 CALICO MACHINE. plied with a constant quantity of printing material, for the rollers would soon only skim over the sur- face of the fluid and leave but a feeble impression; to this end a reservoir pours a continual supply. A partition is placed in a position which enables it to clear the roller of the froth with which its surface may be covered. 651. R a T S S G B H D H H H D H G G N M L 0 D K P P a P A A, frame-work. I, a shaft communicating with the PPPP, levers which are loaded with BBBB, pressing cylinder. moving power. weights in proportion with the cccc, engraved cylinder. KKKK, wheels adapted to the fe- pressure required: they are situ- DDDD, scrapers. male screws LLLL, which put ated beneath the floor. EEEE, vessels containing the color- the levers in communication with Q, the cylinder round which the cloth ing matter: they are raised and the pillows of the rollers. to be printed is rolled. lowered at pleasure, by the screws M, a wheel communicating with the R, the cylinder round which the in- FFFF. driving power, whose office is to termediate cloth is wound. GGGG, endless screw, guiding the press the rollers; it also moves the S, a weight which keeps the cloth regulators. wheel N, and the endless screws stretched on the cylinders QR. HHHH, pinions and wheels which 0000, which are engaged with T, a roller used to give an inclination turn all the machinery. the wheels KKKK. to the cloth when printed, and reg ulate the speed. Digitized by Google CANDLES. 213 CAMWOOD. See WOODS, varieties of. CANARY-WOOD. See WOODS, varieties of. CANGICA WOOD. See WOODS, varieties of. CANDLES, Wax. Next to tallow, the substance most employed in the manufacture of candles is wax. Wax candles are made either by the hand or with a ladle. In the former case, the wax being kept soft in hot water, is applied bit by bit to the wick, which is hung from a hook in the wall in the latter, the wicks are hung round an iron circle, placed immediately over a large copper-tinned basin full of melted wax, which is poured upon their tops, one after another, by means of a large ladle. When the candles have, by either process, acquired the proper size, they are taken from the hooks, and rolled upon a table, usually of walnut-tree, with a long square instrument of box, smooth at the bottom. CANDLES, Stearic-Manufacture of. Among the tallows which are best adapted for the prepara- tion of stearic candles, are those of beef and mutton All other fatty matter is poor in solid acid, or of too considerable a price. It is, then, the quantity of acid, stearic or margaric, which is found in a given weight of beef or mutton, and the facility in working the same, which ought to determine in giving preference to this or that quality of tallow. The mutton tallow contains the greater quantity of solid acid, and is the more easily worked. That of beef is, generally speaking, to be procured a little cheaper. The manufacturers of stearic candles, to free themselves from the inconvenience of melting, are gen- erally in the habit of buying from the butchers fat already melted. This method is far from being the best, as it is almost impossible to judge the purity of the tallow when it has been melted, and at the same time gives an opening for imposition to a considerable extent. Thus it would be most im- portant to the manufacturer to purchase the tallow in lumps, in such manner as it is taken from the animal, covered with its membranes, and bound in its cellular tissue, and to melt it himself. This operation of melting is performed in the slaughter-houses of Paris in a very simple manner. They have a great copper, from 6.56 feet to 7.21 feet diameter, and from 3.28 feet to 3.93 feet in depth, swelling at the bottom as in a stewpan, and widening at the top, so as to be enabled to rest upon a circular oven. This is constructed in such manner that the hearth, of a breadth of 1.32 feet, is exactly under the copper, from its circumference to its centre. The flame and hot air heat at first the whole of the bottom surface, and then circulate twice round the cylindrical part of the copper before passing up the chimney. They throw the fat in this copper by an inclined plane, which proceeds from the upper story, and during the melting they stir it with a long rod. When they have reached a proper degree of fusion, which is generally obtained in about four or six hours, according to the nature of the fat, they turn it out, first into a large iron-plate reservoir, of the same size as the copper, and which is furnished with two cocks, from which it is drawn off into slightly conical vessels, SO as to form large lumps of a conical shape. It is well to place under the copper a large funnel, the same as in a forge, to conduct the gas which escapes from the fat during the operation to the chimney. There should be also in the same fac- tory a screw-press, for compressing the membranous part, in order that no portion of fat may be lost. The different operations in general use for the manufacture of such candles are generally divided as follows: 1st. The formation of soap; the object of which is to combine the acidulated fat with the lime, to produce the glycerine, and obtain the stearate, margarate, and oleate of lime. The glycerine dissolves itself in the water necessary for this preparation. 2d. The pulverizing of the lime soaps. 3d. The decomposition of these same soaps by sulphuric acid diluted with water. 4th. The cleansing of these stearic, margaric, and oleic acids-first, by water slightly acidulated, and secondly, by pure water. 5th. The moulding and crystallization of the now obtained acid fats. 6th. The melting of the crystalline masses into small layers instead of large rolls. 7th. The cold-pressure of the acids thus formed into layers. 8th. The hot-pressure of these layers now reduced. 9th. The purification of the solid acids by water slightly acidulated at first, and secondly by pure water. 10th. The melting and moulding of the solid acids into moulds; then the clipping of the candles. 11th. The bleaching of the candles. 12th. The polishing, packing, &cm for removal. Description of the Machinery.-Fig. 652 represents the general plan of a manufactory, indicating the utensils which are employed. Fig. 653 is a sectional view of this manufactory, vertically and longitudinally; and the figures 654, 655, 656, and 657, represent in elevation, or sectionally, the details of the principal utensils, and the means of communicating the movement. The Formation of Soap.-This operation is performed in a large vat, generally constructed of wood, slightly conical in form, and provided with several frets all the way up. The bottom and the lid are of wood, and its capacity is sufficiently great to contain, easily, more than 7058 cubic feet. They gen- erally place about 1100 lbs. of tallow, with a proportion of water rather more than enough to easily dissolve the same, and which would be about 200 gallons. This is heated by steam from a leaden pipe g, winding in a serpentine manner, and placed at the bottom of this trough. This pipe is per- forated with a number of small holes, across which the steam passes as it proceeds from the coppers A or A', with which it is in communication. When this is melted, they add, by degrees, 165 lbs. of lime well mixed; and they allow this preparation time to mingle, taking, at the same time, great care to stir it by means of an agitator p, composed of many branches united by a cross-piece, and having a Digitized by Google 214 CANDLES. kind of knife fixed at each of the four arms. This contrivance is mounted upon a vertical beam o, to which is given a rotary movement by the wheel n fixed to the upper part of the beam. This wheel is acted upon by a pinion n' adjusted upon the horizontal beam, which communicates with the prime mover by the two pair of cog-wheels 11' and jj, mounted on one part upon the vertical beam k, and on the other part upon the horizontal beam F, as seen in Figs. 652 and 653. An energetic stir- ring is most important, because it more fully completes the formation of soap, and economizes, conse- quently, the sulphuric acid. Generally, in the greater part of the manufactories, says Mons. Dumas, they use, perhaps, 33 lbs., and sometimes more, of sulphuric acid, to the 220 lbs. of tallow, while they ought only to use from 19 to 22 lbs. to 220 lbs. of tallow. It is often, then, a third too much, and an experienced manufacturer would do well to pay attention to this. They had proposed to give the movement to this agitator by means of a cord, but they found they were obliged to give up this, as they could not obtain a regular movement-during one part of the operation the matter, being very compact, would present a great resistance, and the rope would give. The time for the formation of soap is generally from 6 to 8 hours. At the end of this period they draw off, by means of a tap q' placed in the bottom of the trough, the liquid part which has absorbed the glycerine, and they take from the trough all the solid which remains there, which is now a forma- tion of stearate, margarate, and oleate of lime, in the form of a very hard soap; this they throw upon the floor, upon which rests the trough J. Pulverizing.-To pulverize the soap, they use, in many manufactories, a roller of cast-iron K, which they pass to and fro in an alternate movement, and generally by manual labor. Mons. Dumas proposes to have the soap pass between two cylinders moistened by a stream of cold water, which should bathe it; a precaution most indispensable, because the soap, heated by the pressure, would soften, and render itself more often in cakes than in powder. Troughs for Decomposition.-The two troughs J1 and Jª, into which is conveyed the solid matter after it has been broken, are designed for the decomposition of these matters by the action of sulphuric acid much diluted with water. Like the former, in shape they are slightly conical, and nearly of the same dimensions, heated by steam by a serpentine pipe q'. They ought, also, as with the former troughs for the formation of soap, to be cased with lead, so as to be protected from the action of the sulphuric acid. It would be quite as well to fit up both with a mechanical agitator, though in many manufac- tories they are not SO. These troughs are generally on a lower floor, under the trough for the forma- tion of soap, so that they can easily dispose of the matter. The quantity of sulphuric acid necessary for the decomposition of these lime soaps can be easily de- termined. For 1100 lbs. of tallow, according to Mons. Dumas, they would use 165 lbs. of lime; or for 220 lbs. of lime the equivalent in sulphuric acid is equal to 367 lbs., at 66° centigrade. Consequently, for 165 lbs. of lime will be necessary 275 lbs. of this acid. In practice they add from 10 to 15 per cent. to this quantity, and the acid being, we suppose, at 66°, they dilute it by twenty times its quan- tity of water. At the end of about three hours the decomposition of these soaps is effected. They then displace the mass. The fat acid comes to the surface, and the sulphate of lime is precipitated to the bottom. Cleansing the Acids.-For this purpose they withdraw, by means of a tap q', which is placed un- derneath, and which, like the preceding ones, is cased in lead, and equally heated by steam by a ser- pentine pipe placed in the bottom. It is as well to have a second trough L, similar to the preceding one, to complete the cleansing, in which they work only with pure water. The passages R, inserted in the interior of the roof, serve to establish a communication with the two troughs of decomposition J J', and with those of cleansing L', and to carry the liquid off or into the lower reservoirs. As much as possible of sulphuric acid and lime are drawn off into a series of zinc moulds M, which are arranged in rows along the entire length of the workshop, in such manner, that in drawing it off into the first mould it flows gently into the adjoining moulds, which is easily done by attaching to each brim of the moulds a gutter, which carries off the superfluous matter at its proper height. These moulds present the form of a rectangular prism from 27 to 39 inches in length, from 61 to 7 inches in breadth, and about 161 feet only in height. Thus are formed layers of solidified acid, which are taken away (after being wrapped in woollen serge) to the vertical hydraulic press N, which is con- structed exactly similar to the ordinary presses, of which it is easy to see the construction by reference to the design, Fig. 653, where it is shown in vertical section. The drawing off into these moulds, such as we have endeavored to show, is only a modern application. Previously the acids were drawn off into larger moulds, which could contain about 7 gallons, and which were a little wider at the top, so that the matter could be the more easily extracted. These rolls were broken into smaller pieces by the action of a knife with an alternate movement, similar to a knife for cutting straw into small parts. Since the use of these newly-invented moulds, they economize nearly one-horse power in the impelling force. Cold Pressure.-The vertical hydraulic press ought to be constructed to obtain a pressure of 440,000 lbs. A great part of the oleic acid flows cool to the action of this press, but, however, the lat- ter portions can only be extracted by the aid of a certain temperature. Other presses of horizontal construction, and which are heated by steam, are employed. Such is the press represented in PP, upon the plan, Fig. 652, and upon the vertical section, Fig. 653. Hot Pressure.-This press is heated; also the wrought-iron plates P', between which are placed the links which proceed from the vertical press, and which, in issuing from this press, are enveloped in horse-hair material, in place of woollen serge. On the opposite side to the piston of the press is a cast-iron rectangular chest Pª, airtight, in which is enclosed a similar action of plates. The steam proceeding from the generators A or A', passes by the pipes e, e¹, e², t, finds its way into the double sides, as also into the double bottom of the press, to heat it. It afterwards passes by the pipes t', which carry it into the chest Pª, where there is a full Digitized by Google CANDLES. 215 652. in S 8 : .a ? = R or to H M X M F X Digitized by Google 216 CANDLES. action of plates Pª to be employed as soon as the press will have ceased to work, and where they may take away those that they have used. They can still heat these plates by boiling water in a trough, also in cast-iron. It is shown by Fig. 653 in what manner these plates can be raised to furnish heat to the press, or reciprocally. They have provided for this purpose, in the upper part of each of them, an eye, which permits the introduction of a hook fixed to the extremity of the cord u, which passes into a throat of cast-iron to the pulley. The upper part of the locket of this pulley ends with an elongated eye, to enable it to glide easily the entire length of an iron way fixed to the plank, and below the press, lengthwise-so that one of the plates being raised, they can advance the locket in a perpendicular line. They can transport them in succession either from the press to the chest, (which serves as a heater,) or from the chest to the press. The pressure of the piston of the press often ranges from 880,000 lbs. to 1,100,000. Some, after a certain time of working, have had the bottom of the cylinder carried away by the pressure; and, in cer- tain factories, others have been destroyed by the rupture of the long braces, which connect the heads of these presses, and which were not sufficiently strong in themselves. The oleic acid which flows from the vertical press, or from the horizontal one, into a lower receptacle O, by the pipes S' Sª, from which it is drawn for the receiver into the flat vessels, by the cooling, de- posites the stearic acid that it had absorbed in consequence of the increased temperature which it underwent during the action of the horizontal press. The two pressures completed, the oleic acid is regarded as sufficiently separated, and the residual matter, formed by the stearic and margaric acids, is of brilliant whiteness; they only equal about 45 to 50 per cent. of the tallow employed. The injecting-pumps are shown by H and H, Figs. 652 and 653, which clear the two horizontal and vertical presses. They are put into action by the horizontal beam F, which communicates with the impelling power, which is an engine of about 4-horse power-a power more than sufficient to put in motion the necessary apparatus of this manufactory. Upon the horizontal beam E is a cast-iron upright wheel f, which commands the wheel f1, fixed upon the horizontal beam g. This has, at its extremity, two small winches, which, by the accession of two rods h, impart to the pistons of the injection-pumps il the movement for casting the water that they draw into the great bodies of the presses N, P. The heads of the vertical press are supported at a convenient distance by four cast-iron columns, interlaced by large iron bolts all the way up, and the liquid matter falls upon the lower plate, which unites with the piston, and upon which they have adjusted a small trench or gutter, to allow it to flow by the pipe s¹, finished in its upper part in form of a funnel, and which conducts it into the reservoir O. Purification of the Solid Acids.-The lumps of stearic and margaric acids which are taken from the horizontal press, are carried to the trough R, to be there purified by dilute sulphuric acid. This trough is constructed exactly similar to the preceding-cased in lead, and heated by steam, by the pipe q3, which conducts the same in the serpentine q, which liquefies the acids. It must be under- stood that this cleansing has for its object to disengage the fat acids from the remotest trace of lime that they may contain. After this operation, it only remains to free them also from the acid itself, by purifying with water. They then allow this to remain, or decant it into another trough R¹, situated upon a lower floor, and which only contains pure water, and which should be occasionally replenished. They then allow it to cool, draw it off into moulds, and at length is obtained rolls perfectly fit for work- ing into candles. Melting and Moulding the White Solid Acids.-They use for this purpose a copper, T, (see Figs. 652, 654, 655,) which are in the interior silver-plated, to prevent the discoloration of the acids. This copper is double-bottomed, to be heated by steam at a temperature which should not ordinarily exceed 100 degrees. The steam proceeds from the generators into the double bottom by the pipe v, and this, condensed, flows off by a pipe v¹. A tap v³, attached to the pipe which issues from the bottom of the copper, serves to empty it completely. It is surrounded by a coat of wooden staves U, to prevent the cooling of the trough. By the side of this copper they have placed a table V, upon which rests the vessel T, which serves to receive the melted matter to be carried into the moulds. In order to make the candles and the stalactites which form upon them less powdery, they generally add 10 per cent. of sulphuric acid, when they throw in this copper the rolls of stearine. They cool these candles in moulds similar to those represented in plar. and in section, Figs. 658 and 659. These moulds are formed of an alloy, composed of one-third pewter and two-thirds lead. It will be perceived that they are slightly conical, and terminated by a kind of funnel. They fix the wick to the upper part by a bent pin y', and to the lower by a little wooden peg y, which closes against the sides of the orifice. These wicks are matted, which prevents the necessity of constantly snuffing the candles; for this purpose, says Mons. Dumas, it will be necessary to dip them in a solution of borax, which forms with the lime a borate which fixes itself in the wick, and serves to consume it. To fix the wicks, the moulds are placed vertically in the holes of the wooden tables S, conveniently arranged in the workshop, and upon which they allow the candles to cool, after they are drawn off. For this purpose, after the wicks are fixed in the centre of the moulds, they carry them to the hot- water basins, which are brought up to the temperature of boiling water. This system of heating is brought about by several basins V, represented in plan and section, (see Figa 656, 657, and 652.) They are entirely surrounded by water, heated by a current of steam com- ing from the generators by the pipe x in the serpentine x¹, placed in the bottom of the apparatus. When the moulds are sufficiently hot, they are filled by the aid of a small vessel T1, which they plunge in the copper T. It should be first ascertained that the acid has commenced to crystallize. This precaution, as much as that of heating the moulds, is very essential to neutralize the crystalli- Digitized by Google CANDLES. 217 655. 654. di at a 5 657. 656. of 9 659. 658. x N 10 4 to 8 Fig. 653: SCALE.-5 33 inches=33 feet. Figa. 654 to 659: SCALE.-8 inches= 13 feet. II : J J 653. M K M Digitized by Google 218 CANDLES. zation of the fat acids-a crystallization which would give to the candles a very disagreeable appear- ance. After the cooling of the moulds, they remove the small wooden peg which holds the wick, and by means of a punch, they extract the candle. The roll must also be cut, and the candles be put length- wise. For this purpose many mechanical means have been tried, and which have not produced very satisfactory results; the difficulty to avoid breaking the candle being so great. However, they are at this moment trying the effect of a certain mechanical knife or circular saw, from which much is expected. For this process we believe it is most important that the cutting-blade should possess great rapidity and very little pressure. Bleaching the Candles.-When the candles are moulded, they should be exposed for some time to the air, to the light, and to a humid atmosphere, that they may possess as white an appearance as possible. This is generally done upon the roof of the workshop itself, which should be constructed in the form of a terrace, where the candles z can be arranged upon the trays Y. Space should be econo- mized as much as possible. Polishing the Candles.-The last two processes which the candles have to undergo, after they have been exposed to the air some time, are the polishing and the packing. The polishing is done by rub- bing the candle briskly with a piece of cloth, damped with alcohol or ammonia; and this is generally done by women or children. They have also tried to produce the polish by a mechanical process, having a kind of cylindrical plug or bung of wool or cloth, to which was imparted a regular to-and-fro movement, whilst the candles were immediately placed under the same, and by the means of endless chains, which advanced gradually upon a horizontal table, the candles rested and turned equally at the same time. This process is the invention of a Mons. Davison, of Paris, who has taken a patent out for it for five years. The packing consists in arranging them to form packets of one pound, and they are carefully and neatly secured ready for use. Boilers, or Steam-coppers of the Machine.-The two boilers A and A', represented in Fig. 652, are for the purpose of feeding not only the engine, (of 4-horse power,) but also for heating the dif- ferent troughs; for the formation of soap; for decomposition and cleansing the horizontal press; the copper for melting, and the warmer. These boilers are of 16-horse power. There are some factories which have them as large as 20-horse power. Fig. 652 represents a horizontal projection seen from the top, and shows the disposition of these boilers, with their safety-valves, and also the pipes for conducting steam. In B will be perceived the brick furnace, in which the boilers are imbedded; in b the safety-valves; and in b' the floats c shows the pipe communications with alimentary pump; e' e' the pipes for conducting the steam to the different apparatus of the machine; and d d' the pipes which furnish the steam-engine. All these pipes are of copper, and provided with taps. Application of the Oleic Acid-This acid, for a long time in the different factories for the manufac- ture of stearic candles, was regarded as a superfluous residue, and you may say completely lost, with respect to any advantage that could be derived from it. Messrs. Pelicot & Alcan have been success- ful in applying it to the purpose of greasing the wool employed in silk-yarn manufactories, or in scour- ing it. It is well known, in the picking or combing of wool, that a nap as homogeneous as possible is neces- sary. It is first prepared with a certain quantity of fat matter. This preparation is so far necessary, that without it the twisting and stretching of the wool would only be accomplished indifferently, and the loss would be greater. The thread thus obtained would be more unequal, and would not possess, for weaving, the quality required for the production of stuffs. Until within the last few years they have employed, for this purpose, vegetable oils, in most of the principal factories at Rheims, Sedan, Elbeuf, &c. In the factories of the south, olive oil was almost always used, whilst in the suburbs of Paris they have given the preference to the oil from grains, which was cheaper, and in some cases a mixture of water and oil is used, brought to a state of emulsion by the addition of a small quantity of potass. The oil with which wool is impregnated should only remain until immediately after the spinning or weaving. Scouring should commence at that period. The process of scouring varies with the nature of the stuff they propose to manufacture. For cloths and felt stuffs it is done after the weaving, and be- fore fulling. For light and rasé stuffs it is generally done upon the thread, and before the weaving. At Elbeuf, Louviers, and other places, scouring is accomplished by means of potters' clay saturated with water. The thread being impregnated with this substance, they pass it between two compressing cylinders, which brings it in contact with the greasy matter; this is consequently displaced, mechan- ically, and is drawn off by the water, which flows in great quantities. This process will take from eight to twelve hours, and it will affect the soundness and color of the tissue; besides, the accidental presence of any small stone in the clay will occasion a rent or imperfection in the same. It is also very uncertain; and if in the first process there is a failure, it becomes more difficult again in the second, in consequence of the deposite of insoluble salts, arising from the application of water. An imperfect scouring prevents the stuff receiving the color as effectively as it should. The oil which has been used for the greasing becomes entirely unfit for any other purpose; for, on reference to experienced men upon the subject, the result is nearly as follows: 88 lbs. of woollen cloth will imbibe 18 lbs. of oil, and they are diluted by 2843 gallons of water. In the south, where they manufacture large quantities of common cloth for troops, or for exportation, the vegetable is not always entirely lost in the scouring. To extract this, they employ water mixed with soap and alkali: this is absorbed by heat, and then employed in the fulling of the stuff already scoured. This scouring, although very imperfect, still is, however, more economical than the former. In Sedan, for the manufacture of black cloths, &c., the greasing and the fulling are generally done at the same time. For this purpose they use a solution of soap or urine, and sometimes a combination of both. When they wish to scour the wool in thread, they use soap solution sufficiently powerful. Messrs. Peligot and Alcan, to remove many of the inconveniences attending these processes, thought Digitized by Google CANNONS. 219 to remedy them by the use of the acid stearic, instead of the vegetable oils. We have seen that the tallow formed into soap is transformed into two fat acids, the one solid and the other liquid. The first is the acid stearic for the manufacture of candles, and the second is the acid oleic. This last, until within the last three years, was not employed for any special purpose. These chemists, in applying it to the woollen factory, have not only rendered a great service to this last, but also to the manufacturer of stearic candles, in augmenting the value of a portion of their residue. The employment of the acid oleic, besides economizing the actual price of purchase upon that of olive oil, or that from grain, offers this very important advantage-that it is immediately soluble in the carbonate of potash, with which it combines in the formation of soap. The scouring becomes a chemi- cal process-for it consists in immerging the stuff for some instants in an alkaline water, and then washing it in an ordinary apparatus. The scouring of the threads by this process has a still greater advantage, because it can be effected simply by an alkaline solution, instead of the more costly employment of a considerable quantity of soap, and equally in employing the fresh residues as in former ones. This process is again very economical, as it furnishes itself the soap to be employed in the fulling, an operation which generally follows the scouring. The oleic acid having the direct property of a true soap, by its combination with carbonate of potash, a property that none of the vegetable oils pos- sess in any degree or shape whatsoever, (and of which an exclusive use was made,) they now obtain, as a consequent residue from the scouring, a liquid combining the properties of soap and alkali, which before they had to provide for the fulling of the stuffs. Besides the waste in picking, of little moment when they employ the ordinary oils, this is completely saved by the facility of scouring offered by the use of the acid oleic. From numberless experiments it is proved, that the wool greased by the acid oleic does not become heated, neither does it ignite even when placed in circumstances most favorable for combustion. The acid oleic, such as is left by many factories of candles, could not be employed for the purpose of greasing wool until it has undergone a complete purification, or been brought into a homogeneous sub- stance possessing all the above-mentioned characteristics. That which they employ at this time in the cloth factories can only be compared, by its clearness and color, to the finest olive oil employed in the same factories. In certain factories of the stearic candles they manufacture with the acid oleic a hard soap, which is sold to the dealers in large lumps. Apparatus necessary for the manufacture of Stearic Candles.-Horizontal press, or hot press, as rep- resented in Fig. 653, including injecting-pump. Vertical, or cold press, with iron columns and injecting-pump. Cast-iron chest, as in Fig. 655, for the heating of the plates. Each plate weighs about 100 lbs. cast-iron. The troughs (deal) for cleansing and decomposing, with the iron frets which surround them. The pipes and lead casing-the agitators and their movement. Steam-engine, high-pressure, 4-horse power. Two boilers, each from 16 to 18 horse power. Also many other indispensable accessories, such as moulds, heaters, transmitters of movements, and pipes. CANNONS OR GREAT GUNS; the machinery for the boring of. The manufacture of cannons is divided into two branches, the founding and the boring. Here we only treat of the latter branch, and restrict ourselves, concerning the founding, to the remark, that formerly the cannons were founded over the core, (as it is called,) or with the bore, which then was perfectly regulated by means of the borer; while at present they are generally founded massive, and afterwards bored in boring-mills. These boring-mills work either vertically or horizontally. The former were exclusively used until the middle of the last century; the boring consisted only in the enlargement of the founded bore conforma- ble to the calibre, and the opinion prevailed that brass cannons could be bored in no other manner than this. But since then the advantages of the horizontally-working boring-mills have become 80 apparent, that but few of those working vertically are still extant. A short description of the three principal systems of the latter will therefore be sufficient here. In the machines constructed according to the oldest and most imperfect system, the cannon rests vertically, and with the grape upwards, in a wooden sledge which runs in the furrows of two side- beams, and can be moved up and down by means of long tackles. Beneath the cannon, and in the direction of its axis, is the borer running in a steel pan and crossed by a beam, by means of which it is turned round by horses. The pressure required while boring, is effected by the weight of the sledge and cannon, and can be regulated by counterbalances. But as the borer is to have some scope, the borer can easily be brought out of its vertical position, and thus the boring assume a false direction without its being noticed instantly. According to the second system, the cannon rests with its muzzle-face on rollers, while its grape is inserted into the shaft of a dented wheel connected with a moving power, and thus the cannon is turned round its axis. The vertically standing borer is fastened at a aledge, which runs in the furrows of two beams, and can be pressed onwards against the cannon during the operation of the boring, by a lever drawn upwards by a string provided with weight-stones, and passing over a pulley. Both the exact direction of the borer and its uniform pressure against the cannon is hard to be effected yet the ad- vantage is here, that a false direction of the borer can instantly be noticed by the trembling motion of the cannon and borer. The third and best system of boring-mills working vertically, is represented by Figs. 660 and 661, in front view, and section through the axis of the cannon and boring-bar. Here the borer is fixed, while the cannon turns round its axis, and moves up and down in a sledge, and by its weight the required constant pressure against the borer is effected. The square piece of the cannon's grape is clamped into the maif marked with T, and which at the same time takes up the lower square part of the boring- Digitized by Google Digitized by Google W b 667. V y S = d d 668, d V UVU D y P P 666. M. www a 2 a E c @ & N D . O @ D a 663. c 662. 10 : 00 8 my WILL Hmar B 665. E P S of y D C E or R n @ D @ 0 I M H H 661. 00000000 N II by 664. I L 660. a CANNONS. 220 CANNONS. 221 spindle S. The latter is, together with the cannon, turned round their common axis by a motive power between the fixed rails C₁ and C2, by means of the cog-wheel U, the spring-wheel V, and a cog-wheel at the vertical shaft W. The boring-spindle is provided with a bell-shaped runner of brass, whose feet turn on a steel plate inserted into the rail G. In order to secure the position of the boring-spindle, the latter has at its upper end an indentation for receiving the steel point of the bolt F. The cannon is kept in a vertical direction by the slides of the rails E1 and En provided with adjusting screws. The hitherto described contrivance moves, with the exception of the moving power between the side-beams A, right up and down, the directing-beams I, together with the rails F, G, E1 and E, forming a sledge, which by means of the drawing-machines N, the disks L, their shaft F, and the long tackles fastened to the upper bolt B, can be lifted or lowered at pleasure. Fig. 664 shows the rail E1 in the upper view, and illus- trates the working of the directing and running beams one into the other, and at the same time the fastening of the rails to the directing-beams. The boring-bar is fixed in the sill D, and is kept in its vertical position by the rails C, and C4 The upper rail C, is taken off, as soon as the cannon sinks down into its vicinity. The drawing-machine is, during the boring, slackened, so as to allow the weight of the cannon to act freely. With larger calibres, counterbalances may be applied to decrease the pressure. The first horizontally working machine was constructed in 1744 at Strasburg, by Maritz, inspector- general of the foundries in France; and since these were constructed, other machines on the same principle in Spain, Sweden, and England. The boring-mill at Chaillot, in France, is the first where the power of stean. was applied; and that of Liege, in Belgium, is the most extensive, comprising twelve horizontal boring-benches put in motion by four steam-engines. In both, the system is that of the can- non turning round its axis, while the borer presses straight onwards against it. Another system pre- vails in English boring-mills, according to which the borer is not only pressing against the cannon, but at the same time rotating in a direction opposed to that of the cannon. Machines constructed on this system are called cylindrical boring-machines. A third system unites with the contrivance for the movement of the boring-sledge a uniformly advancing support for turning off the cannon. We shall first describe the machinery according to the above-mentioned system, applied in the boring- mills of Chaillot and Liege. Figa. 669 to 677 represent a boring-bench and its single parts. In the mill of Liege three of such benches are placed by the side of each other, and are put in motion by a steam-engine, which is directly connected with the shaft of the middle boring-bench, while the dented wheels B are acting upon those of the side-benches. If two boring-benches be placed at the end of each other, BO as to have one common axis, they form what is called a boring-road that is connected with the prime mover in the way of running boring-machines, which shall be described below. Each bench, Figs. 669 and 670, consists of two long beams joined by cross-beams. The first two cross-beams bear the sockets A and C of the axis, the next following two bear the saddles for the grape and the mouth of the cannon, and the fifth and sixth serve as supports for the dented bar of the boring- sledge, so that the beams can be placed and kept exactly in the same level the timber must be com- pletely dry. The cross-beams are firm with the exception of the fourth one, which by double springs moves in the furrows of the side-beams, as the different length of the cannons requires a corresponding position of the saddle for the mouth. For connecting the cannon with the axis, the square adjoined piece of the grape is to be put, together with the square of the axis, in the muff D, which is fastened by small metallic wedges, driven in at both sides. The cannon rests horizontally in two collars E and F, which in Figs. 673 and 676 are represented in double scale. The socket of the grape E supports the latter only on the lower side, and can be moved forwards and backwards on the beam. The socket F of the mouth embraces the cannon entirely near its head-moulding, and allows it no other movement than the rotation round its axis. The con- struction of these sockets (which are to be provided with copper standard-disks a, conformable to the calibre) may easily be comprehended by the figures. The iron boring-bar a, (Fig. 670,) is put with its back-squared end through the bow G of the carriage-frame, and held fast by a peg. The dented bar H is fastened in similar way to the carriage, being put through the bow b to G, and held fast by a fore- lock-bolt. The carriage-frame (Fig. 674) is made of cast-iron, and is moved by means of four wheels, run- ning on the rails c of the long beams. The carriage must be of such weight, that it is not subjected to vacillation; while the boring-bars are made as light as possible, yet at the same time strong enough to prevent them from bending. The means for the movement of the boring-sledge are very various. In the first boring-mills working horizontally a dented bar was applied, put in motion by an endless screw or winch; then by means of chains passing over rollers, and moved by a lever and weight-stones; and by a screw-spindle, whose box was fixed in a wheel. Yet all these means of movement require either an experienced operative, or they do not produce a uniform pressure. For this reason the manner of movement represented in the delineation was applied in the boring-mills of Chaillot and Liege. It consists of a dented bar F, moved onwards by the moving power I, at the axis of the dented wheel R, and by the action of the lever K, charged with weight-stones. The lever K is at both ends provided with the segments N and o, in whose grooves the string of the weight-stone P (which brings about the pressure) and the chain of the iron hinge M are placed. The hinge (Fig. 677) consists of two parallel iron bars joined below by two tenons, which latter stand asunder at equal distance, as two cogs of the obliquely dented wheel R do. By this contrivance a uniform pressure of the borer against the cannon is brought on, but at the same time it has the inconvenience of frequent shifting of the hinge. For this purpose, first the lever L is to be laid in to prevent the retrogression of the dented wheel, and then the weight-stone P is to be drawn up by means of the rope fixed at the segment 0, and passing over the roller Q to the axis T; a catch V preventing the retrogression of this axis, turned by the moving power U. As soon as the hinge M is shifted, and the catch V lifted, the weight-stone P begins its action again. In order to cause less inter- ruption, in the most modern French boring-mills, the dented wheel is provided with a barrel, over which Digitized by Google 222 CANNONS. passes a string with a weight-stone at its end. The string must also pass over a roller, which is to be fixed as high as possible, to prevent a frequent hanging of the weights. It is well to provide the string with rings, one foot asunder, so as to be enabled either to increase or decrease the pressure, by hang- ing several weights one above the other. The movement of the boring-carriage must above all be uni- form, without any start or pull. For this reason the screw-spindle is to be preferred to the dented bar but the difficulty to make it exactly in these dimensions, and its expense, have prevented its general application. Fig. 675 represents the frame forming the socket for the moving power of the dented bar, and at the same time holding in its lower part a roller with projecting edges, to facilitate the movement of the dented bar, and to keep the latter in the direction of the cannon-axis, conjointly with the notch in the back cross-beam. A boring-bench arranged in this manner is adapted to great guns of every calibre however, in more extensive boring-mills, there are several benches of inferior length for the boring of howitzers and mortars. The second system of the horizontally working machines is an imitation of the above-mentioned cylin- drical boring machines. Two boring-benches at the side of each other are represented in Figs. 662, 663, and 665, plan and side view. The prime mover being here either the power of steam, water, or animal power, the toothed wheel of the principal axis m grasps the cog.wheels A of the two shafts n, which belong to the boring-benches, and puts the whole boring contrivance in motion. Sometimes each of the shafts n is arranged for two boring-benches, in which case the second ones are placed in the king-pieces of the represented boring-benches, at the other side of the spring-wheels. The cast-iron sockets of these shafts rest on a foundation X, made of square stones, and covered with plates of cast-iron. These plates Y are firmly fixed to the foundation by screw-bolts, and are kept together at the edges by other bolts. At each boring-bench in the socket-plates are two long and well-polished grooves p, for receiving the screw-bolts of the cast-iron saddles and tressels T, U, V, W, Z, as well as the support for the turning off. Along the grooves are cut out in the foundation, channels for the reception of the bolt-heads which are wider than the grooves. By this contrivance the tressels can be moved'and adjusted by the screws. The screw-bolts are altogether of the same dimensions, and can be taken out at proper places, which enlargements of the grooves are to be closed by stops of iron. By taking down a tressel from the boring-bench, the female screws need only be unscrewed, and the tressel to be lifted a little, to free it from the bolt. The socket of the shafts is formed of six iron posts, resting on a strong cast-iron plate, fixed by means of screws. The two middle posts enclose the spring-wheel of the principal axis, while the other, R and S, leave sufficient room for the wheels A, the pinion B, and the pillow-block a. The pinions B are screwed on the wheels A, and grasp in the cogs of the moving power g. C may be in equal direction with the wheels A. The cannon is, with its grape, connected with the shaft n by a muff; it turns round its axis, and is at its mouth supported by the saddle U. The squared shaft f of the lower wheel C passes through the post S and the saddle U, between which it is supported by a tressel T, and is im- mediately behind the resting tressel V and the winding tressel Z, provided with the cog-wheels E and G, which are fixed by means of wedges. The cog-wheel E grasps in D, placed above it, and causes the boring-bar c and its screw-spindle d, to turn on their axis in a reverse direction to the rotation of the cannon, by which the acting of the borer is strengthened. In order to produce a uniform and properly measured advance of the boring-bar, the system of the screw with moveable box is applied, the cog- wheel G working in the teeth of another one F, which contains the box of the screw-spindle d, and turns round this latter with somewhat less celerity than the screw-spindle itself, by the working of the cog- wheel D upon it. In this manner a slow, but uniform advance of the boring-bar is effected. The extent of the pressure of the borer against the cannon depends upon the number of the wheel-teeth, as well as upon the length of a screw-worm of the spindle, and may consequently be altered by a shifting of the wheels. In order to afford a clearer idea of the whole machine, we shall give a more circumstantial description of its several parts, in whose construction various alterations can be made. The shafts n and f are provided with moving-out apparatus, which are not constructed like the com- mon claw-boxes; one of them is represented in Figs. 680 and 681. The shaft n n₁, is cut through at x, and consists of two parts, of which the front one bears the spring-wheel, while the back one, 921, passes through the post S, and terminates in a square for the connection with the cannon. Both shaft-parts are connected with each other by a case, embraced at its front collar by a barnacle-ring f, which presses against the knobs dd of the wheel, and causes a simultaneous rotation of the box and shaft. The front part of the shaft n₁ is squared, and thus put in motion directly by the box, while the part of the shaft n, inserted in the box, must be cylindrical, 80 that the box be put in again, by means of the fork a, at every movement of the rotation. Suppose both shaft-ends inserted in the box were square, it would be not only difficult to watch the moment when both shafts are in congruity, but also impossible to pre- vent a shaking movement. The fork a moving round the support b c, fixed to the post S, embraces the box at the groove of its weaker back-part, and leans against the projecting edges. Thus, if the handle of the fork be pressed to the left, the box is moved out to the right, i. e. the barnacle-ring f leaves the knobs d, and the movement of the shaft n is not connected with its other half n₁. The saddle U is represented in Figs. 684 and 685 it has, like all other tressels, in its lower part a socket for the shaft f. The slide o, forming the holder for the cannon-mouth, is adapted to every length and diameter of the cannon, and is provided with adjusting disks polished with emery. The lower part of the slide is cut off obliquely, and in conformity with the inclination of the wedge, moved by the screws m n. Consequently by drawing the female screw m, the cannon can be lifted exactly to the required height. The supporting tressel T of the shaft f is represented in Fig. 686; it contains the semicircular socket in its upper part. The squared shaft f is at all points, where it rests on the tressels, provided with Digitized by Google CANNONS. 223 brass boxes, which are circular at their outsides, and fastened at the shaft by means of small metallic wedges. Figs. 666 and 667 represent the resting tressel V, whose upper part contains the holder of the boring- bar c. The latter being squared, it is provided with a box pp, Fig. 668, circular at its outside, and turning round in the holder, together with the bar, yet not advancing like this. To the projecting squared part of the box the toothed wheel D is fixed, which puts the boring-bar and screw-spindle in a rotative movement. To the lower shaft f is fixed the wheel E, which can be kept in constant gear- ing with the wheel D by the edge 00; otherwise the box might, together with the upper wheel, slip out of the socket. The tressel W, Figs. 682 and 683, supporting the spindle and lower shaft, has at its upper part the slide b, and is cut out conformable to the diameter of the screw-spindle. The hindmost part of the machine is formed by the tressel Z, Figs. 678 and 679, which allows a free passage to the screw-spindle, and is for this reason perforated according to its widest diameter. Above, the tressel contains the holder for the shaft of the wheel e, which allows to draw back the boring-bar by means of the winch x, and at the same time to increase or decrease the pressure against the cannon, if required. The wheel e works in the teeth of the cog-wheel F, which contains the female screw of the screw-spindle, and is kept in constant gearing with the wheel G, by the edge pp. Thus, whenever the boring-bar is to be drawn back, the wheel G is drawn off, and the lower shaft moved out. Should it seem preferable to allow a spring-like movement to the boring-bar, the tressel V may be entirely removed, and then the wheel D is to be fastened at the square end of the screw-spindle, which now, together with the boring-bar, is moving onwards against the cannon. The third system of the horizontally-working machines is a combination of the two other ones. The arrangement of the wheel-work and shaft-sockets A and B is in substance the same as the above de- scribed. The boring-shafts are provided with apparatus to move them out and in; yet the connection of the cannon with the principal axis is arranged in an improved manner. The adjoined piece of the grape has the shape of a regular prism, and is inserted into a box cylindrical at its outside at the end of the axis is fastened a ring. In the cylindrical excavation, D, the inserted box, has a play of some few lines. Three strong adjusting screws pass through the adjoined piece into the box, and by means of them the cannon can be centred, if required. In general the cannon is only supported at its mouth by the saddle G with the disk a; with great calibres, however, a second saddle G, may be applied at the bottom piece or grape. The saddles are made of cast-iron, and moveable in the grooves of the iron plates. The sledge L, made of brass, terminates below in a guide, which is advancing in the excavation Y, and cut out in such manner that it forms beneath the screw-spindles, two feet armed at the edges with steel rails. At the middlemost and higher part of the sledge, the boring-bar is fixed either by means of a bow and pin, or of two steel rails R, that are to be screwed on, and between which the square of the bar is pressed fast by the screw d. The shifting of the borers and the taking out of the bore-chips is so facilitated. The sledge is pressed against the cannon by two screw-spindles E and E1, passing through the side projections of the sledge, and having their sockets in the iron posts B and N. The fe- male screws are cut out in the brass of the sledge, and at both ends provided with steel armaments. The back ends of the spindles, terminating in squares, bear the toothed wheels o and O₁, being in gear- ing with each other by the equal wheel O2 and thus turning in the same direction, and with the same celerity. The spindle E passes through the post N, and is provided with a handspike-wheel P, for the movement of the machine. Simultaneously with the sledge, a support K, for the turning off, moves along the cannon, and is pro- vided with a female screw for the spindle. It has, like the sledge, a guide sliding on the iron plates or special bolts, and through the upper part of which a brass wing H is moving, and terminates in a foot gliding on the steel rails c c of the iron plate Q. The latter is, according to the various descriptions and calibres of the cannon, fixed at the screw-holes x x, so that the rails cc run parallel with the cannon, while the turner's chisel is always kept in a proper distance from the cannon's axis during the move- ment of the support. At the front end of the wing H is a moveable rail or peg, for supporting the turner's chisel; by means of an endless screw it can be put back or forward, and an index at its upper side indicates the extent of the change. At Douai, in France, a steam-engine, 12-horse power, moves four boring-benches, whose shafts make 10 or 12 revolutions a minute; at Toulouse, a water-wheel, 12 or 13-horse power, moves four boring- benches; and at Strasbourg, one boring-bench is put in motion by four horses. The movement of the cannon on the boring-bench, and the pressure required against the borer, de- pend generally upon the material and calibre of the cannon. Is the rotation decreased, the pressure may be increased, as otherwise the bit might generate a too great heat, and thus become weak. Iron cannon and wide calibres must revolve more slowly than brass cannon and smaller calibres. In the boring-mill of Liege, the cannon revolves once in 8 seconds, and in that of Douai it revolves at the rate of 10 or 12 times a minute. It seems that 12 times a minute is considered as the maximum. The pressure, depending chiefly upon the hardness of the metal, cannot be indicated precisely. In the second of the horizontally-working machines, above described, the advance of the boring-bar de- pends upon the number of teeth of the several wheels. If, for instance, the wheels B, C, D, E, and F, have 36 teeth each, while the wheel G has only 34 teeth, the wheel F, together with the female screw of the spindle, will make 34 of one complete rotation of the spindle; and thus the boring-bar will ad- vance only by 1.20 of that distance, by which it would have moved onwards, if the female screw were fixed. If the length of a screw-worm be half an inch, the spindle will advance by 3 X 1/08 = 3'8 inch. Should the wheels B, C, E, and F have 36 teeth each, while the wheel D has 35, and G only 34, the spindle will revolve at the rate of 36, and the female screw at that of 34 of one complete rotation of the cannon, while the boring-bar is advancing by 30 X 30 X 1/2 = 0.0286 inch. The following table gives the number of teeth both of the spring-wheels and of the wheels E and F. Digitized by Google 681. 680. 224 672. 671. W. The B x W. T y = NOT 6 OF H 27 679. 678. a a X 683. 682. 677. 8 WWW 3 N DE 676. a K % 12 o a c P T G © G a % M W R If a of " G 669. D 0 II 0 0 R N 685. 684. CANNONS. P 3 a 674. G 2. - c c 1 лл. E uu 670. R a 2 © a E . II B Digitized by Google a (CED) 686. " el B é # R T CANNONS. 225 The middle wheel of the lower axis, and that with the female screw, are at all events provided with 36 teeth; by inserting a fresh boring-bar, the proportion of the advance can be altered without much trouble. Number of teeth Advance of the bo- of the wheels. ring bar by inches. The Material, Description, and Calibre of the Borer. Cannon. B,C, During one Remarks. Eand D. G. rotation of In an hour. F. the cannon. From 48 to 24 pound cannon, mortars, Brass cannon. carronades, and howitzers, of wide 36 35 34 0.0286 10.29 The length calibre of a screw- Plain borer and widening From 18 to 12 pound cannon and howitzers of small calibre 36 35 33 0.0428 15.41 worm is I an inch. borer. From 6 to 4 pound cannon 36 84 33 0.0441 15.88 From 48 to 24 pound cannon, mortars, The cannon Iron cannon. and howitzers of wide calibre 36 36 33 0.0416 14.97 revolvesat From 18 to 12 pound cannon and the rate of howitzers of small calibre 36 34 33 0.0441 15.88 6 times a From 6 to 4 pound cannon 36 36 32 0.0554 19.44 minute. Fly-borer of the mortar-pieces and Auger or forehand- auger of the carronades, and from 36 36 35 0.0139 5.00 borer. 48 to 24 pound iron cannon Chamber-auger of the howitzers, and 36 36 34 0.0277 9.97 auger for all other great guns Bottom-borer of the cannon, chamber Bottom- borer. bottom-borer of the mortar-pieces, and vault-borer for the holes of the 36 35 35 0.0148 5.148 mortar-pieces To convey the cannon from the foundry to the boring-mill, a crane-carriage can be applied in case of their being connected with each other by a railway; which, of course, is to be held aloft by supporting- posts, that the cannon can be lowered down to the boring-bench. The carriage runs on four cast-iron wheels X, on the rail a. (See Figs. 671 and 672.) Its upper frame, made of solid timber, bears two shafts W, and W. T1 and T2 moved by winches Y. The shaft W, serves to move the carriage onward, and the end of the rope cast round it is fixed to a hook in the intended direction of the carriage. Sometimes this shaft is left out entirely, and the carriage provided at both ends with hooks to hang ropes, which either are fastened to windlasses at both sides of the railway, or are connected with the principal axis of the boring-mill by rollers. To the ropes of the second shaft is attached the draw-beam Z by means of strong iron hooks, to which the cannon is fixed with ropes. The axle T1 is provided with double ratchets. By means of this crane-carriage the cannon is lifted from the pit, freed from the mould, and then conveyed to the boring-bench, on which it is placed horizontally. In a similar manner it can be removed as soon as the boring operation is accomplished. Before the cannon is encased on the boring-bench, its eccentricity must be examined; for which purpose it is to be placed on two separate saddles, where it is, by means of the trunnions, turned round its axis and meanwhile examined. If the eccentricity nowhere exceeds four lines, the cannon may forthwith be encased; but in the contrary case its centre must previously be precisely regulated. For the purpose of severing or turning off the lost head, the lever A, Fig. 676, centred on a pin at the front saddle or tressel F, or at a particular post, moves in a plane vertical to the cannon, and has in its lower part a hole, into which is inserted the chisel-shaped blade C. At the lever's end is the weight P, and above it a moveable ear or handle, serving as box for the support T. which, at its upper part is provided with screw-threads. By means of this screw the chisel can be approached to the axis of the cannon, while the weight prevents the rising of the apparatus. The boring-mill being put in motion, the lost head is turned off to a minute remnant, whereupon a stroke completes the severing. For the purpose of the cannon being centered, near the cannon a cross-piece of timber is put beneath the boring-bar, which is then, by means of small wedges, to be brought to the required height and direction. This done, and the front face of the cannon having been chalked, the borer is slightly pressed against it, while the cannon revolves. If no shaking of the boring-bar be perceived, even by increasing the pressure, the borer is correctly centred; but if it be the case, the boring-bar must, by the wedges, be adjusted till no shaking is perceivable. Now the boring may commence. The shape of the borer has in the course of time greatly varied. Formerly a hollow borer or wimble was used for boring massively founded cannon over the core, as it was called. Having bored to a certain depth, the core was, by a peculiar contrivance, pushed off, and upon this the boring operation completed with borers. This was performed in boring-mills, working vertically. At present there are chiefly four descriptions of borers in use, viz :-The auger, the bottom-borer, the plain or calibre borer, and the widening-borer. The terms of cross-borer, disk-borer, bore-knife, chamber and Ay borer, vult-borer, &c., have relation 29 Digitized by Google 226 CANNONS. partly to peculiar positions and shapes of the bits, partly to the place and manner of their application, and can be ranged in the above-named descriptions. The auger consists commonly of a bit of steel as broad as the first boring requires. Frequently hardened iron is used instead of steel. This auger is used in the boring-mill of Liege. It has two edges and an angular form in the fore part. The angle must be the more obtuse, the greater the motive power, the pressure, and the hardness of the metal By this bit the first boring is preserved to the dis- tance of four lines from the cannon's bottom, where it ends in a conical form. With middle calibres the bore of the cannon is now only to be somewhat widened and polished, by means of the plain borer, while with larger calibres one or more widening borers are still to be applied. The older French auger, here and there still in use, consists of three blades, the first of which hav- ing the form of the auger and widening the bore to two-thirds of the whole boring diameter. Behind it, in the bit-head, is a hole, through which the second blade is put, that cuts onward and sidewise, and widens the bore by eight lines. Behind, and in a right angle with this blade, is a third, which widens the bore to the diameter required for its being polished. In German boring-mills, augers are used; they leave four lines of the bore, and penetrate to near the bottom of the cannon or howitzer. In recent time the form of a saw, like that of the bore-knives, has been adapted to the auger; and thus, by one single boring, the operation can be completed so far that only the plain borer is still to be applied. In Vienna the augers have not only this form, but are also provided with shovel-edges. In order to be assured of the correctness of the first boring, a strong wooden rule as broad as the bore, is to be put in; and in case it can penetrate to the bottom, and be turned without any obstacle, the boring is faultless and can be pursued. The boring with the auger is immediately followed by that with the bottom-borer, though with larger calibres, an application of some widening borers is to be made previously. The bottom-borer is intended to widen the cone made by the auger, and give the required shape to the bottom. Its boring-blade is three or four lines thick, and forms a rectangle, rounded off in the fore part, which at the same time is the cutting part. The frame or head of the borer is, by means of its tail and by two screws, fixed to the boring-bar. The next is a bottom-borer, as constructed in France: and another one intended for giving a hemi- spherical form to the bottom. The latter can be forthwith applied, in which case it consists of a metallic head provided with two side-blades, and an upper rounded edge; four wooden prisms secure the run of the borer. Frequently the head receives a cylindrical form, and the boring-blade is inserted, in the way of a plane-iron; in which case the borer is called a disk-borer. The bottom-borer is followed by the polishing or plain borer, which commonly only takes away the two last lines of metal and polishes the bore, by freeing it from boring-rings. Its head forms a cylin- der, a quarter of which is cut out, and on the level of its edge an oblique steel blade is screwed fast. The screw-holes in the blade are elliptically formed, as the boring is to be repeated several times, and meanwhile the discharge of the blades is gradually. increased until the normal calibre is at- tained. The plain borer is used in the boring-mill of Liege. It consists of two small boring-blades, which, in the fore part, have exactly the form of the bottom, and are fixed to the tongue of the boring-head by means of three screw-bolts. The discharge of the blades is effected by strips of tin-plate inserted behind their back. The boring of the howitzers and mortars is in general done in the same manner as that of the cannon, with the only exception that a greater number of borers is applied. The auger is succeeded by the calibre-borer of the chamber; it is intended to polish the chamber; and as its blades are crossing each other, it is also called the cross-borer. The third and fourth borers have the same frame, into which the blades are inserted one after the other. At last follows a polishing-borer. The gradual discharge of its two blades is effected by inserted small strips of tin-plate. Field-howitzers, with spherical chambers, are in France bored with borers of the following descrip- tion :-A common auger makes a bore, which is by two lines less wide than the chamber. Next fol- lows the borer which bores out the fly or middle part of the bore to two lines of its diameter: a cylin- der of the same diameter as the first bore serves as guide to it. The third borer has a similar guide, and is intended for boring out the spherical chamber. Then follow the polishing-borers The mortars are, in the boring-mill of Liege, bored in the following manner:-First is applied the small auger, which makes the bore by four lines less wide than the chamber. Next follows the great auger, which is inserted into a particular boring-bar, and penetrates to the fore part of the chamber. Its blade can either be formed single, or be composed of three blades; the joined piece of the boring-head serves as support. After this the chamber-borers are applied. In case the chamber is to be conically formed, the bore-knives are commonly used, which are con- structed in the following manner:-At the boring-bar is a long groove for receiving the dented iron rail, which is held by the bands. The bar is moved by the axle, and by means of the lever, and at its front end is a notch, into which the boring-blade is inserted after the plate has been removed. The lever is worked by an operative. The first bore-knife to be inserted is in the form of a saw, and brings about an undulatory surface in the chamber; yet with the advantage of taking away much metal. The second one is plain, and cuts away all elevations completely. Another instrument for boring conical chambers is represented by Figs. 687 and 688. The blade a is, by means of the bar b, moved onwards in grooves formed by the lists p, and is, like the bar b. screwed in the plates m and n. The surface of the instrument is plain, whereas the lower base is rounded according to the form of the chamber, (see Fig. 691.) The boring of spherical chambers is very different; it requires a great number of borers. To show their contrivance and application, we will shortly describe the boring of a French foot-mortar. First an auger is applied, whose diameter is by 4 lines less than the neck of the chamber. Next follows the Digitized by Google CANNONS. 227 o 699. a "П b 0 8 a 8 697. B 0 es 700. 687. 0 0 689, Rq й 688, 690. 0 0 701. 0 0 702. 0 0 THE 72 6 R A 698. u 703. 691. 704. 715. 707. E # 711. A 708. d R 709. 712. R 713. A 710. - 705. 714. . 696. 716. o o 692. B 694. 11 8 a 717. 706. i o A 8 718. . A R 719. - 0 . 0 8 693. 695. L 00 M © y 720. 721. 722. 723. 724. 725. 726. 727. 728. Digitized by Google 228 CANNONS. blade, together with another rounded in accordance with the form of the chamber. Fig. 699 illustrates the shape of the borings, which are marked with ciphers in their order of succession. All these blades are inserted into the head of a particular boring-bar. The chief part of the head is provided with a tongue, and a cover or moveable lip B, on which all blades are screwed. The grooves of the blades are adjusted to the lists. Now as soon as they have attained the bottom of the chamber, they glide backwards in consequence of the pressure, and commence at the same time the operation of boring out the chamber. First, the blades C, then the blades D, and at last the blades E, are applied, and thus the parts 4, 5, and 6 of the chamber, (see Fig. 699,) are successively cut away. Finally, to complete the boring, the blades and the polishing-borer are applied. Figs. 689, 690, and 691 represent a borer for giving to the chamber the form of a pear. It is applied after a bore as wide as the chamber-neck having been made. The boring-head has a groeve q to let out the bore-chips; and in another groove, partly covered by the rails p, run the plates m and n, round which the blade a, and the bar b are fixed. It may finally be remarked that the pear-formed chambers are at present out of use. The turning off is at present commonly done conjointly with the boring of the cannons. Only in boring-mills working vertically, a separate turning-lathe is required, which consists of two long beams 6 or 8 inches asunder, and short cross-beams. In the inside grooves of the long beams are inserted two moveable strong oak blocks, provided with knobs or bunchings at the front, to be inserted into holes of the front and back pieces of the cannon. Near the trunnions is a disk, consisting of two halves, fixed and connected by an endless thong, with a fly-wheel of five or six times greater diameter. In this way the cannon is turned on its axis. The turning off can be done either off hand, or by clamped chisels. The first method has many ad- vantages, yet requires great labor, and an experienced operative; and the apparatus for working by clamped chisels on moveable supports is very expensive, however applied to brass cannons. The common method is the working off hand combined with fast supports. The turner's chisels are provided with long wooden handles, and are either crooked (as the French) or straight, (as the English.) The French chisels are dented at the back of the incurvation, to prevent their slipping from the support. There are especially two descriptions of them, the one intended to rough-turn with, and the other for planing, (see Figs. 701, 702, 703, and 704.) The English chisels are straight, and mounted with either triangular or quadrangular pommels; the handles are fastened to them in right-angular direction. A moveable support according to the old French system is represented by Figs. 692 to 695, and worthy of description here, as it can yet be applied with some modifications. The chisels, Fig. 696, are by means of a bolt fixed in the iron rail A, which in the wings of the brass support N can be moved on- wards and backwards by the screw B. The latter passes through the back part of the support, strengthened by the steel plates q. To prevent the rail A from lifting, the two cross-pieces a a on the support, are provided with female screws for the pressing-screws C. The support N rests on the brass plate M, and is moved on it by the screw-spindle D, which passes through its midst, where the two ends of the screw-worm are armed with the steel plates Y. The lowest part of the support consists of a foot running in a furrow of the plate, and regulating the progress. For the purpose of facilitating the movement, and maintaining a uniform and easy progress, the steel rails z z are inserted along the plate. At one end the screw-spindle is provided with a toothed wheel in gearing with the winch P, by means of the endless screw L According to the older system, the plate was fixed to the boring-bench by two screw-bolts passing through the cuts X X; but at present one single bolt is applied, and passes through the middle of the plate. The chisels used with the moveable supports are in general shaped as is shown by Fig. 696, a and b. For turning off the moulding and grape of the cannon, particular chisels are used, such as represented by Fig. 696, b and k. Before the turning off begins, the cannon is placed so that the trunnions lie exactly in a horizontal plane, and then, by means of the instrument, the middle line of the cannon's surface is to be as- certained. Upon this the moulding, edge-rings, and vent are pointed out and marked, so as to prevent the chisel from planing these points. In turning off hand, the beginning is commonly made with the bottom moulding, next follows the edge-ring, and then the grape, and thus the opera- tion proceeds to the head-moulding, while successively the chisels c, d, e, f, g, a, b, h, and i, Fig. 696, are applied. The trunnions are to be rounded off, either off hand, or by a particular contrivance of the machine, illustrated by Figs. 735 to 739. The cannon rests in cross-blocks or standards, and the machinery in the frames B. The spindle m consists of two parts, one of which bears the roller r, round which the string d of the weight Q is coiled. The screw of the spindle is adapted to the female screw in the capsule P, to which is fixed the fly-wheel D. Another machine is represented by Figs. 731, 732, 733, and 734, and all its parts are made of cast-iron or steel. The sockets D and E for the cannon are by screw-bolts fixed in slits of the iron plates of the boring-bench. Each of the standards E, Fig. 733, consists of two parts, whose projections v and t grasp one into the other. The screw g serves for ad- justing the required height of the upper part. The standards A A are, like the tressels of the boring- bench, fixed by screw-bolts in the long slits pp, (see Fig. 663.) Through the lower part of both stand- ards passes the squared axis f of the boring-bench, bearing the round boxes d d, and the wheels C. Through the upper part of the standards passes the spindle m, on which are screwed the blade-baskets n, and which bears at the same time the wheels B, that, conjointly with the wheels C, bring about the simultaneous movement of both spindles. Each spindle is perforated in its axis for the reception of the steel rod q, which at its back end is provided with a screw-turn, and at its front end with a small female screw. The pressure against the cannon is effected by a strong spring 2. The basket n con- tains four blades b, (see Fig. 734,) which by the pressing-screws 8 are pressed against the trunnions. Those parts of the the cannon which cannot be turned off in the above-described manner, because the trunnions and handles hinder it, are elaborated by the chaser or engraver. The instruments he makes use of are represented by Figs. 720 to 727. First, he applies the gouge, (Fig. 723,) carving furrows, whose Digitized by Google CANNONS. 220 g d 8 9 0 0 & a 799. I 730. 734. 733. I a E a E b A 8 746. D a A 0 O 731. 000 25 B O o A A 747. I R H 732. a a a R a D 735. o B a of 0 745. & A c K 4 R P a 45 R a B 748. & R 736. 742. E 8 a . a 0 B 740. A 744. A R 741. i F B B 737. 738. de I o 743. 739. 749. e Digitized by Google 230 CANNONS. edges he then takes away by the plain chisels, (Figs. 720 and 721,) upon which the surface is freed from all inequalities by means of the vaulted mallet, (Fig. 728,) and of the instruments represented by Figs. 724 and 726. The elaboration of the angles and ornaments is accomplished by means of the burin, (Fig. 722.) Finally, the chaser elaborates the written characters, using the instrument, Fig. 727, called in French traçoir, and the common gravers. Fig. 725 represents a scalper or raspatory for dim- ming the metal between letters working in relievo. We will give here some statements about the difference in time between the older and modern boring systems. Formerly it was computed that the boring of a 24-pounder might take up 8 or 10 days, its turning off the same space of time, and the transport from one machine to the other 4 days; conse- quently in total from 20 to 24 days, or from 200 to 240 hours. At present a 24-pounder is bored in 50 hours, the simultaneous turning off prolongs this time to 60 hours at the most, and the transport takes scarcely 10 hours; thus the whole work is done in 70 hours. The boring of smaller calibres is at present completed in 14 hours, and that of the mortar-pieces in from 20 to 60 hours. In the French boring-mills the auger advances t of an inch in an hour; the bottom-borer completes its work in an hour, and the plain borer advances one inch in an hour, as also the widening borer. In the modern German boring-mills the borers advance 11 inches in an hour.* To make the cannon completely ready for service, the boring of the vent, the placing of the aiming ruler, and the fixing of the priming contrivance remain to be done. For placing the aiming ruler, either a deepening is made in the back edge-ring, or a hole bored in the bottom-piece of the cannon, in the performance of which is used the borer represented by Fig. 744. The frame required for this opera- tion consists of a standard A, of whose four feet C, only the two back ones are to be seen in the figure. The cannon rests on this standard in a horizontal position, is at its ends supported by the wedges C, and at the trunnions by the blocks b and wedges a, and is fixed by means of the bands f and cross- pieces g. Between the posts O, P, Q, and R, is the beam D, serving as a lever, having its fulcrum at m, and being pressed down by the weight P, by which its front end with the blade G lifts the guide I. Between the cross-rails of the bench F, the guide I can only move vertically up and down at its upper end it is armed with an iron frame o, which can be adjusted by the screws ii. It is at the same time provided with a steel plate, through the conical deepening of which the borer T is put. The boring of the vent of the cannon is performed either by a drill (which is turned to the right and left alternately) or by the borer T, (see Fig. 744,) which latter is turned in one and the same direction. Commonly the former is used, especially in the boring-mill of Liege, where the machine for this pur- pose, represented by Figs. 729 and 730, comprises two frames, one for the cannon, and the other for the drill. The frame for the cannon consists of two cross-beams a a, united by a long beam b; in the former the iron rails v are inserted and fastened by the wedges r; the cross-pieces c are moveable. The tressels m m, with the disks o o, are supporting the cannon at and can be moved aside, if required, on the cross-pieces c. The cannon is placed in such a manner, that while the axis of the bore lays horizontally, that of the trunnions is vertical. The boring-apparatus consists of a bench d, fixed, by means of the bolt e, to a plate, which rests on the posts q and p, and on which the bench turns on the bolt e. The drill f is moved onwards against the cannon by a spindle, or by a dented bar and winch, and is turned by means of a bow, Fig. 740, made of bamboo or old steel blades, and whose string (of catgut or horsehair) is coiled round the boring-roll. By moving the bow to and fro, the borer turns alternately to the right and left. For adjusting the bench, the ruler, Fig. 748, is applied. The line a b marks the axis of the vent, and the line c d indicates the length of the cannon's bore. To this latter line the notch x extends. The line fg corresponds to the notch y. By means of this ruler the point for the vent can be exactly fixed. As regards the borers, in Liege first the auger C (Fig. 747) is applied, then the plain borer B, and finally the borer C. The bits are of the best steel. To prevent the deterioration of the vent by the violent discharge of gas from it in the moment of the explosion, there must be inserted in it a pipe of iron, or of refined copper, which is replaced by a fresh one as soon as it is worn out. For this purpose the pipe has on its outside a male, and the vent is pro- vided with a female screw. On the lathe the pipe receives the form a in Fig. 697. The lower part is made conical, the next following cylindrical, and the upper part squared. The boring out of the vent in the French foundries is performed by means of a machine represented by Figs. 697 and 698. The cheeks B, resting on two standards A, receive the rails C, D, and E, of which the two latter are fixed by the wedges n n. The pressure of the drill p is effected by the pressing-screw Q The cutting of the screw- worm is performed on the block x, Fig. 700, by means of barnacles or pincers, Figs. 741, 742, and 743. The pipe or core a is clamped in the vice b, fixed to the block x, which in its lower part is firmly im- mured. The fork-shaped body A of the pincers runs out in a long arm the cheeks D and E are inserted into the furrows of the arms F; the cross-piece B is held fast by the screws x x, and forms the female screw for the end of the lever C. The pincers are turned horizontally round the pipe by two operatives, while a third one is watching the operation. To form the female screw in the vent, Field-guns cannot be conveniently served when they have less than one hundred and fifty pounds of metal to each pound of shot, and battering-guns require at least two hundred pounds of metal to each pound of the shot. With any less weight the service of the gun is very difficult, from its excessive recoll; therefore. lightness is not a desirable point in the construction of cannon. Strength is always desirable; it should be secured, but not at the expense of any other important point. If it were pos- sible to fabricate sound and strong guns of wrought-iron, they would be found deficient in hardness. The projectiles used are of cast-iron, a material much harder than wrought-iron consequently, the wrought-iron gun is soon indented and worn so much as to prevent all accuracy in firing, and it then is worth little or nothing. Leaden balls are used in small-arms but they are Inadmissible in cannon, as the great heat of the exploded gunpowder melts the lead, more or less, and changes the form of the ball, thereby reducing its range; besides, lead has not sufficient tenacity to enter hard substances, and therefore is not a suitable material to be used against ships and batteries. Wrought- iron is also more liable to injury from rust, than bronze, or cast-iron and the smallest crack admitting moisture, would, of itself. in time, seriously injure the gun. The first cost of wrought-iron cannon is the same as that of bronze, and more than six times that of cast-iron. Bronze guns, it may be remarked, after being too much worn for service, can be easily recast, whereas the old wrought-iron is useless for refabrication, and of little value, in such large masses, for any purpose. Digitized by Google Digitized by Google D 777. c 1 1 774. R B 767. # OR & 776. a 768. E © N X (i) 772. K 6 4 K EO M R 0 18. us n O 766. 765. 775. C 771. K " a o o in 769. R to F 1 a 764. A 759. 757. 756. m 763. 0 p 0 m D 773. b O 770. B & 9 b D x y x y H V 762. e BO B © 5 761. 760. 758. S of R a 10 8 755. 754. 751. 9 Д I . + B be , a w 753. & Mini 1 . e e a a - of DC x a to C Ets E18 a 750. v ***** 752. 8 bo Ets ENG & y y & B 183 CANNONS. 232 CARDING ENGINES. the horizontally-working boring-bench, represented by Fig. 719, formerly was used, and is in some places still in use. But at present the vertically-working machine (Fig. 745) prevails. It consists of the frame A, B, C, D, E, a screw-spindle T, (whose female screws are in A and C,) and the borer S. The cannon rests on the beam E. The borers commonly applied are, first the auger, (Fig. 715,) then some widening borers, and a pol- ishing-borer of the shape in Fig. 712. With old battering trains, or cannon of fortresses, in which the pipes are inserted in a heated state, a greater number of borers are required. In France, first an auger is applied, and then six others in the ensuing order of succession : Figs. 708, 709, 710, 711, 712, and 713. CARDING-ENGINES. BREAKER AND FINISHER.-These very effective machines, Figa 778 to 783, are manufactured at the machine-shop, Lowell, Mass. Figs. 778, 779, and 780 represent the Card- Breaker, with 14 tops or flats; and Figs. 781, 782, and 783 represent the Finisher, which has 22 topa. 778. ⑉ Front View. SCALE.-5 inches = 8 feet. 779. 2 o 0 Driving-end. SCALE.-5 inches = 8 feet. Digitized by Google CARDING ENGINES. 233 There are but few mills in the United States that use single carding ; the greater part use Breakers and Finishers, even those that manufacture the coarsest goods. In the Eastern district the general breadth of the cards is 37 inches, and diameter of main cylinder 36"; doffing cylinder 18"; feeding rollers 14". The main cylinders are made of cast-iron, and covered with broad filleting, instead of sheets. The average speed of the main cylinders is about 100 revolutions per minute. In the Rhode Island district the cards are made of various breadths, from 18 to 36 inches, and are principally wooden 780. o . Gear-end. SCALE.-5 inches = 8 feet. cylinders, covered with sheets. In the Southern district the general breadth of the cards is 24" to 80". There are some cast-iron cylinders covered with sheets. The average speed of the cylinders in the two latter districts is 110 revolutions a minute, and diameter 36 inches. In order to make smooth, level 781. D D Back View. SCALE.-5 inches: = 8 feet. # yarn, it is absolutely necessary to have the cotton well cleaned and carded; if the tufts or knots of cot- ton are not perfectly teased out, and the fibres well separated at the latter process, the fleece delivered from the doffing cylinder will exhibit inequalities, or appear what is technically termed clouded ; and from card-ends of that texture, it is impossible to make good yarn. The stripping is performed by two persons one, the top-stripper, begins at the first card in the series, and strips every second top all over ; 30 Digitized by Google 234 CARDING ENGINES. that is, the 1st, 3d, 5th, 7th, 9th, 11th, &c., until the whole of the tops are stripped in two or three courses. The cylinder is also stripped by the cylinder-stripper, thus keeping up a contsant system of stripping all the time the machinery is in motion. For the purpose of sharpening the teeth, when a carding-engine is first clothed with new sheets, fillets, &c., the cylinders are put in motion the right way, and a light emery-board, about 4 inches broad, is traversed over the top of the cylinders, with a very delicate hand; this is called facing up the teeth, because the points of the wires are running against the board, and is intended to cut down any single 782. alli C Driving-end. SCALE.-5 inches = 8 feet. wires that may be too long. After running the cylinders in this way for about fifteen minutes, their motions are reversed, and small cast-iron cylinders, coated with emery, (Fig. 781,) are mounted on the main and doffing cylinders; these are denominated fast-grindera, and which, after being properly set, are caused to revolve in an opposite direction to the card cylinders. This operation is continued until 783. 6 B 9 Gear-end. SCAL inches = 8 feet. the whole of the teeth on both cylinders are ground down to one uniform length; but during the process of grinding, the emery cylinders are made to traverse a little each way, so as to grind the wires to a round point, and prevent them from being hooked. The cards are then dressed up-first with a brush dusted with chalk, and then with emery-boards, called strickles; this latter process is called sharpen- Digitized by Google CASK-GAGING. 285 ing, and is continued daily to the Breakers, and every second day to the Finishers. The fast-grinders are not applied above once a year, or only when the cylinders on some parts of the surface have become higher than on the other parts, or, technically, of the truth." By this method of grinding the cards when necessary, and sharpening them every working day, they are always in good order, and conse- quently produce more perfect work also, when the practice of sharpening is continued daily, it can be done in much less time two men can easily sharpen thirty carding-engines in the space of four hours The card-belts being all fitted with buckles, no time is lost in making them long or short, for the pur- pose of reversing the motion of the cylinders. The tops are also brushed out and sharpened once a week. Fig. 778 is a front elevation of the Card-breaker. Fig. 779 represents the driving-end; and Fig. 780 the gear-end. Fig. 781 is a back elevation of the Card-finisher. Fig. 782, the end elevation, (driving-end.) Fig. 783 represents the gear-end. CAMPHOR WOOD. See WOODS, varieties of. CASE HARDENING. See DETAILS OF ENGINES, and HARDENING AND TEMPERING. CASK-GAGING. The rules hitherto given and used for gaging casks are either erroneous, imprac- ticable, or uncertain; so much so, that at best they can only be counted mere guess-work: first the gager has to determine by observation the variety of the cask; when he has made up his mind as to the variety, he commences to calculate its contents by an erroneous rule, if brevity be required, thus heaping error upon error; or by some long calculation or other, which he is told is correct, of the working of which he is not sure, and thus uncertain as much as before of the quantity it contains. If he performs the calculations on his slide rule, again he has to guess at what the result is: 80 he guesses the variety of the cask, prepares its dimensions, before applying them to the slide rule, by an erroneous calculation, and then the result is uncertain, even if he has hit upon the right form and prepared the dimensions correctly. The following were the vague directions given to the gager, to determine the form or variety of a cask :- "1. When the staves of the cask are much curved or arched, it is supposed to be the middle frustum of a spheroid, and is called the first variety. "2. Where the staves are not quite so much curved, the cask is taken for the middle frustum of a parabolic spindle, or the second variety. Where the curvature of the staves is very little, it is supposed to be of the form of the frustums of two equal parabolic conoids, and is termed the third variety. "4. If the staves be straight from the bung to the head, the cask is taken for the frustums of two equal cones abutting or joining upon their greater bases, which is the fourth variety." From these directions it is impossible to determine the variety of the cask, excepting the fourth, and that rarely occurs. Without depreciating the rules hitherto given any further at present, we shall give one which is at once simple in practice and certain in its results, let the variety be what it may; after which, we shall point out the absurdity and uncertainty of using the former rules. Before we lay down the principles upon which casks ought to be gaged, it is necessary to explain a new instrument, which is a tape, and may be added to those already in use: viz. the cross-callipers, long-callipers, the head and bung-rods, which require little or no description, and may be less in use than they formerly were. The tape here referred to is a box-tape, and may be of any given length, with two lines on it, one on the face, and one on the back; the line on the face is not a line of inches, but expressed in mean diameters, each principal division being 3-14159, &c., inches, so that when any utensil is girted with this tape it gives the mean diameter at once, instead of the circumference; and the line on the back points out the area in gallons for such a mean diameter. Therefore, any circular vessel girted with this tape gives the mean diameter in inches, and the area in gallons, of that section of the vessel where the measurement is applied. For instance, suppose the circumference of a circle taken with this tape to be 45.7 divisions, (which is the mean diameter in inches,) opposite this number on the other side will be 5-916 gallons, the area of the circle. In gaging, where the area is computed in gallons or bushels, 784. &c., we consider the depth or thickness one inch. Thus, if we C say the area of a figure is 100 gallons, it is understood if liquor or any other substance be placed on the surface of that B A figure one inch in depth, it will measure 100 gallons; and 80 of bushels, &c. To take the dimensions of a cask standing.-The thickness F E of the staves is the first thing to be ascertained, whether the cask be standing or lying; this may be found from the pro- jecting chimbs very accurately. When the cask is standing, the external length may be found thus -Lay any straight rod H G across the centre of the head, as AB, of sufficient length to extend beyond the bulge; then set another straight rod or inches upright, touching the bulge, as CD, and intersecting K 1 the rod across the head, observing that the upright rod is at an equal distance from the chimbs at bottom and top; then A M is the external length required. The internal length of a cask is easily found if there be a hole in the head, which note down, M as well as the external length. Next take the internal length N D from the external, and divide the remainder by two, which set Digitized by Google 236 CASK-GAGING. off from m to A; then opposite to a, and as nearly perpendicular to CD as possible, mark the cask; to m A add one-fourth of the internal length, which set off from m to E, opposite, as before; mark the cask opposite E; and 80 on at c', d, and é, increasing the distance one-fourth the internal length each time. In two or three places mark the cask in like manner, in order that the tape may pass round the cask in circles parallel at the places marked, viz. the surface of the liquor at top and bottom, at the centre of the cask or bung, and in the middle, between the head and bung and between the bot- tom and bung. When the diameters at the head and bottom are equal and the bulge uniform, we only require three girths, viz. at the head and bung, and in the middle between the head and bung, F E and HG. On the tape, opposite any circumference taken in mean diameters, we find the area in gallons cor- responding to such a circumference, as before observed; but as the diameter found includes twice the thickness of the stave, this must be deducted: on the face of the tape then opposite to the remainder, we find the area of the internal circle corresponding to this internal mean diameter, and may be set down as the girts are taken. To find the content, when the cask is regular; or rather, when the diameters of the heads at bottom and top are equal, and the bulge uniform and central Add together the area at the head, four times the area of the circle in the middle between the head and bung, and the area of the circle at the bung or centre of the cask; the sum multiplied by one-sixth the length is the contents. When the cask appears of an irregular shape.-Add together half the sum of the areas at top and bottom, the area at the bung, and twice the sum of the areas in the middle between each head and the bung; the sum multiplied by one-sixth the length is the contents. Suppose the internal length of a hogshead is 42.25 inches, and the girts at the head, bung, and in the middle between them, (after allowing for thickness of the staves,) to be 1742, 2.992, and 2.494 gallons respectively; what is the content Area of head = 1742 Area of middle = 2.494, and 2.494 X 4 = 9-976 Bung = 2-992 14710 14.71 X 42-25 = 621-4975 hence 6214975 ÷ 6 = 103.5829 gallons, Ans. By the Slide Rule.Set 6 on B to 1471 on A; then will 103.583 be found on A, against 42.25 on B. It is worthy of remark, that in using the tape it matters not what shape or variety the vessel is of, providing it has a tendency to be round; for out of the many examples given in the above-named work, comprising the different varieties, there is only one in which it differs from the strict mathematical rule, and that a mere fraction of a gallon; while in the others it agrees to two and three places of decimals, and in many cases farther: it also appears of no consequence whether the bung diameter exceeds the head diameter by more or less than six inches, on which so much has been built in previous works on gaging. There is an irregular standing cask that girts in five different places, as follows:- At the upper end = 1.714 gal. half-way between the top and bung = 2.415 at the bung = 2-918- half-way between the bung and the other end = 2.549 at the lower end = 1828 How many gallons does it contain, the length being 42 inches 1 Area at top = 1714 Area at bottom = 1.828 2 ) 3.542 1771 Area of bung = 2.918 2.415 X 2 = 4830 and 2.549 X 2 = 5-098 14617 42÷6= II 7=f = the length. Ans. 102.319 To take the dimensions of a cask lying.Girt it round the end with the tape, as far from the end as will be equal to the thickness of the head and projecting chimb; this will give the area of the head in- side,* (when the thickness of the stave is allowed for ;) then take the circumference at the bung and between the head and bung, as directed in treating of the standing cask; but if the cask lie in a position that renders it difficult to be measured with the tape, the diameter must be taken with the rod, taking care that the rod meets the stave opposite to the bung-stave, and that the bunghole is in the middle of the cask, and to allow for the thickness of the wood at the bung:-with this diameter find the area on the tape,-or, by the instrument-See SLIDE RULE. Next take the length of the cask, which is best done with a pair of callipers; but if those be not con- venient, the following method may be adopted: Apply any straight rod to the bulge of the cask, as HB, in such a position that each chimb of the It was usual to take the distance from the inside of the chimb to the outermost sloped edge of the opposite stave, and count it the head diameter of the cask inside; but this cannot be relied on. Digitized by Google CASK-GAGING. 237 cask shall be equally distant from the rod, and two other straight rods being put across the ends of the cask, as G H and BA; then will the distance HB, be the external length of the cask; from which subtract as much as the staves project over the heads, together with the thickness of the heads, and 785. the remainder will be the internal length. Care should H F D B be always taken to know whether the ends of a cask are equal or not; if not, it should be treated as in the last example. Let HA represent a cask whose chimbs project 1.25 inches, and the thickness of the head 1 inch, also the ex- ternal length or distance IB=82: how many gallons K will it contain, the three girts being as follows:- at either end 11 inches from the chimb 25. at H, the centre or bung 285 and in the middle at OP 27.4 inches. G C These being the gross dimensions, when we move two E inches back along the tape for the thickness of the staves, we have the area of the head = 1.498 gallons. the area of the bung = 1.989 - and of the middle section 1828 - Inches. Again, the external length = 32.8 the projection of the two chimbs = (1-25 X 2) = } = 45 and the thickness of the heads = X 2 = 2-0 Hence the internal length = 28.3 Then to find the content, Area of head = 1.498 Area of bung = 1.989 4 times area of middle section = 7.312 10-799 10-799 X 28.8 (the length) = 509353 gallons. 6 Thus far we have shown methods sufficient to find the contents of any cask, let its form be what it may, and also the mode of taking the dimensions whether the cask be lying or standing; we shall now revert to the rules heretofore practised by the (English) Officers of Excise, in order to show how near they come to the truth, and with what certainty they can be depended on. The usual custom for ascertaining the content of a cask was to find a mean between the head and bung diameters, 80 that this mean diameter would be the diameter of a cylinder the same length as the proposed cask, and nearly the same capacity. To reduce each variety to a mean diameter, the following factors or multipliers have been adopted:- for the first variety 68, for the second 62, for the third 55, and for the fourth 5; 80 that if the differ- ence between the bung and head diameters be multiplied by each of those for their respective variety, and added to the head diameter, it will give the mean diameter, when the difference between the bung and head diameters is 6 inches or less. Let the following diagram represent the four varieties of 786. casks, each of whose bung diameters AB is 26.5 inches, their A head diameters = E inches, and the length being o E 28.3 inches; how many gallons will each contain For the first variety.-From the (bung diameter)-(head diameter) = = then 3.5 X (fac- tor) = 3.5 X 68 = 2.38, and this added to the head diameter will be 23- + 2.38 = 25.38 the mean diameter. Again, (2538)* = 644'1444, and 644.1444 X (283) the length, gives 18229-28652. 1822928652 ÷ 353-035 = 51636 gallons, the content. For the second variety.-As the difference between the head D F and bung is 3.5, and the factor for the second variety .62, we have 35X62=217, and 2.17 +23=25.17 the mean diame- B ter; then as above, (25-17)* X 283 = 6335289 283 = 17928-86787. 17928-86787 ÷ 353-035 = 50.785 gallons, the content. For the third variety.-(Difference of diameter) (factor) + (head diameter)=(3.5X5 + 23=24'925 the mean diameter; and 24-925 X 24-925 X 283 = 17581.5342, which divided by 353035 gives 498 gallons, the content. For the fourth variety.-(3.5 X 5) + 23-24'75 the mean diameter .. 24.75 X 24-75 X 28.3 = 1738551875, and 17335-51875 353-035 49104 gallons. Where the divisor 353-035 is used, the factor or multiplier 002832 may be substituted; thus, 1733551875 X 002832 = 4909, nearly the same as above. If the bung diameter exceeds the head by more than 6 inches, the following factors must be Digitized by Google 238 CASK-GAGING. used :-7 for the 1st variety; ·64 for the 2d; .57 for the 3d; and 52 for the 4th. But even were there any certainty of determining the variety of the cask, much reliance could not be placed on these rules; however, they may often serve as a check upon other methods, and with the assistance of tables can be used with much expedition; for let us take the mean diameter of the first variety in the last example at 25.4, and opposite 25 inches and under 4 in the table, we find the area = 1.8275. .. 18275 X 283 = 51-7 gallons, very nearly the same as before; thus we see if the area of the mean diameter of any variety be found, and multiplied by the length of the cask, the product will be the content. The nearest method to the truth that has hitherto been practised is, by taking the diameter at an equal distance from the head and bung; but to determine this diameter before the introduction of the tape was attended with some trouble, though the following mode seems easy enough in practice. Lay a straight-edge touching the bulge of the cask in the middle, as HB at F, Fig. 785, the internal length and bung diameter being known; set off on HB from the centre F of the cask towards either end one-quarter the internal length, as at D; then the distance from D to the stave, added to the thick- ness of the stave and doubled, will give the excess of the middle diameter above the bung, and this taken from the bung diameter will give the middle diameter. Let the bung be 32 inches, the distance from D=1 inch, and the thickness of the stave= 75 of an inch; what is the middle diameter 1+75=175, and 175 = .. 32 - 3.5 = 285 the middle diameter o P. When this diameter is obtained, and having the head diameter, the bung, and internal length of the cask, observe the following rule: To four times the square of the middle diameter, (or to twice the middle diameter squared. which is the same,) add the squares of the head and bung diameters; the sum mul- tiplied by one-sixth the length, and the product divided by 353035, will give the content in gallons. Taking the middle diameter as found above at 285 inches, the head 24, the bung = 32, and the internal length = 42 inches respectively; what is the content 280 and 57" = 3249 = square of twice the middle diameter, or (28.5)²X = 3249 = the same. Then (head diameter): (24)' = 576 Also (bung diameter) = (32)2 = 1024 4849 1/6 of the length = of 42 = 7 353-035)33943(961463 gallons. This rule is as near the truth as any numerical one that can be applied, when the middle diameter is taken correctly; nor need there be any attention paid to what variety the cask belongs. The above rule is similar to the one given with the tape, for if the area of each diameter be used instead of their squares, the rule will become thus :- To four times the area of the middle diameter, add the 787. areas of the bung and head diameters; the sum multiplied by one-sixth the length, will be the content. C Another method of finding the diameter in the middle between the head and bung diameters, is by putting the ga- ging-rod CE into the bung at C, (when the axis A B is hori- zontal;) let a ring be fixed at O, in the middle of CE, t o 8 through which the plumbline COP moves freely: in this B A q manner OP is determined, and is always greater than half the diam ster in the middle between the head and bung; but $ E this diameter can be found when OP is known, thus: m Because OC=0E, and the triangles cot and .OE are equiangular, Ot=08, or Af=fQ, or En =nm. D P Em :: m 0; but Em is the double of En, consequently m C is the double of n O; and as m C is known, n is also known. But since n P (or and half the head diameter, are known, Pf half the middle di- ameter is known, for Let m D, half the difference between the head and bung diameters the bung diameter = L=Af=fQ=En or n m, t the length of the cask; h=AE=fn or Qm half the head diameter; P=0P, the length taken with the plumbline; and =fP, half the middle diameter. Then 2 L: L : b-a 2 =0n; hence P = n P, and 2 = 2 h + b, the middle diameter sought. Find the content of a cask, whose bung and head diameters and length are 36, 28, and 44 inches re- spectively also the length taken with a plumb= 18.12 inches. P=18.12 2P=1812 X 2= 8624 = (head diameter) = 2800 36- 28 = 400 .2P+ 2h +a=6824 and b = (bung diam.) = 36.00 32:24 = 2 x, the middle diameter. Then we have the content = 1295697 gallons. Digitized by Google CASTING AND FOUNDING. 239 Notwithstanding the apparent simplicity of this mode of finding the contents of casks, in practice it becomes in some degree troublesome, and its accuracy depends much on the manner in which the dis- tance 0 P is taken. But if OP be obtained correctly, (at the same time observing that the cask lies level, that is, when the axis A B is horizontal,) it approaches very near the truth. If the cask be spheroidal, the content may be obtained by taking the length of a diagonal with a rule commonly called Branan's, without having the head, bung, or length: apply the rule or rod from the centre of the bung to where the end meets the stave at the opposite side-as from C to E in the last figure; then the number on the rule in the centre of the bung will be the content in gallons. The rule or diagonal rod here spoken of, is constructed for the middle frustum of a spheroid, there- fore it will not give the true content unless the cask be of that particular form; and here it falls under the objection that we have too many of the old methods, for we have no criterion whereby to judge whether a cask is spheroidal or not. Other diagonal rods can be constructed for casks of other varieties, as solids are to each other as the cube of their like dimensions but these rods would be subject to the same objection as the one in use. If the diagonal rod be applied to the head diameter of a cask, twice the diagonal number which measures that diameter will be the content in gallons. There are many other rules given in works on gaging besides those here treated of, several of them depending on the construction of tables, such as the proportions of the bung dividea y the head diam- eter, &c., but even before the introduction of the Patent SLIDING RULE and tape they were of very little practical utility; we shall therefore refrain from giving them, and conclude with a general rule that may be applied to casks promiscuously, without any respect to variety, and in all cases is a near approxi- mation to the truth. It may be necessary to add, that the PATENT SLIDING RULE and TAPE were in- vented by the editor, Mr. OLIVER BYRNE. To 39 times the square of the bung diameter, add 25 times the square of the head diameter, and 26 times the product of the two diameters; then multiply the sum by the length, the product again by 000031473 will give the content in gallons; of 277-274 cubic inches each. CAST-IRON, its manufacture. See MINERAL KINGDOM. Strength of various mixtures of, strength of affected by mode of casting. See DETAILS OF ENGINES. CASTINGS, how to make fine. See DETAILS OF ENGINES, and CASTING AND FOUNDING. CASTING AND FOUNDING. We are indebted to the fusibility of the metals for the power of giving them, with great facility and perfection, any required form, by pouring them, whilst in the fluid state, into moulds of various kinds, of which the castings become, in general, the exact counterparts. This property is of great value. Some few objects are cast in open moulds, 80 that the upper surface of the fluid metal assumes the horizontal position the same as other liquids, as in casting ingots, flat plates, and some few other ob- jects; but in general the metals are cast in close moulds, 80 that it becomes necessary to provide one or more apertures or ingates for pouring in the metal, and for allowing the escape of the air which previously filled the moulds. When these moulds are made of metal, they must be sufficiently hot not to chill or solidify the fluid metal before it has time to adapt itself thoroughly to every part of the mould; and when the moulds are made of earthy matters, although moisture is essential to their formation, little or none should remain at the time they are filled. The earthen moulds must be also sufficiently pervious to air, that any vapor or gases which may be formed, either at the moment of pouring in the metal or during its solidification, may have free vent to escape; otherwise, if these gases are rapidly formed, there is great danger of the metal being driven out of the mould with a violent explosion, or when more slowly formed and locked up without sufficient freedom for escape, the casting will be said to be blown, as some of the bubbles of air will displace the fluid metal and render it spongy or porous. It not unfrequently happens that castings which appear externally good and sound, are full of hidden defects, because the surface 788. being first cooled, the bubbles of air will at. c b tempt to break their way through the cen- tral and still soft parts of the casting. The explanatory diagram, Fig. 788, is in- tended to elucidate some of the circumstances concerning the construction of moulds, which in the greater number of cases are made only B in two parts, but in other cases are divided into several. The figure to be moulded is supposed to be a rod of elliptical section, the d mould for which might be divided into two parts through the line A B, because no part F of the figure projects beyond the lines a b, D drawn from the margin of the model at right angles to the line of division, and in which direction the half of the mould would be removed or lifted; the model could be afterwards drawn out from the second half of the mould in a similar manner. The mould could be also parted upon the line D, because in that direction likewise, no part of the model extends beyond the lines d, which show the direction in which the mould would be then lifted. The mould, however complex, could be also parted either upon A B or upon CD, provided no part of the model outstepped the rectangle formed by the dotted lines b c, or was undercut. But, considering the figure 788 to be turned bottom upwards, and with the line EF horizontal, the Digitized by Google 240 CASTING AND FOUNDING. removal of the entire half of the mould upon the lines e f would be impossible, because in raising the mould perpendicularly to EF, that portion of the mould situated within the one perpendicular e, would catch against the overhanging part of the oval towards A. Were the mould of metal, and therefore rigid, it would be entirely locked fast, or it would not " deliver were the mould of sand, and there- fore yielding, it would break and leave behind that part between A and E which caused the obstruc- tion. Consequently, in such a case, the mould would be made with a small loose part between A and E, so that when the principal portion, from A to F, had been lifted perpendicularly or in the direction of the line e, the small undercut piece A to E might be withdrawn sidewise, on which account it would be designated by the iron-founder a drawback, by the brass-founder a false core. All the patterns in the mould, Fig. 789, could be extracted from each half of the mould, because none of them encroach beyond the perpendicular line, or that in which the mould is lifted a and b could be laid in exactly upon the diagonal, or upon one flat side, or partly imbedded; and in like man- ner fg h might be sunk more or less into the mould, their sides being perpendicular; but the patterns 789. d c b a 790. in Fig. 790 being undercut, the division of the mould into two parts only would be impracticable, and false cores or subdivisions would be required in the manner represented, the construction of which will be hereafter detailed. Extending these same views to a more complex object, such as a bust, it will be conceived that the mould must be divided into 80 many pieces, that none of them will be required to embrace any 795. 796. 792. 791. t t b b s 794. t 793. c s 6 overhanging part of the figure. For instance, were it attempted to mould a human head so that the parting might pass through the central line of the face and down the back ; the two halves could not be separated if they were made each in a single piece, as the inner angles of the eyes, the spaces behind the ears, and the curls of the hair would obstruct it, and the head could be only thus moulded Digitized by Google CASTING AND FOUNDING. 241 by making false cores or loose pieces at these particular places, in the manner illustrated by the former figures. These would require to be accurately adapted to the surrounding parts by pins, or contrivances to ensure their retaking their true positions. These remarks, however, are only advanced by way of general illustration, as figure-casting is the most refined part of the art of moulding. Metal moulds are employed for many works in the easily-fused metals, which are required to be produced in large quantities, and with great similitude and economy the examination of which moulds will serve to demonstrate many of the points of construction and proceeding. Thus the common bullet-mould is made like a pair of pliers, the jaws of which are conjointly pierced with a hole or passage leading into a spherical cavity; the aperture is equally divided between the two halves of the mould, so that in fact the division is truly upon the diametrical line both of the sphere and the runner, or the largest part of each; otherwise the pliers could not be opened to remove the bullet when cast. Iron shot for great guns are likewise cast in iron moulds, by which they also possess great accuracy of form and size. Figs. 791 to 794 represent the moulds for casting pewter inkstands. These moulds are a little more complex, and are each made in four parts; the black portions represent the sections of the inkstands to be cast. The moulds each consist of a top-piece or cap t, a bottom or core b, and two sides or cottles 8 & In Fig. 794 the one side is removed, in order to expose the castings, and the top-piece t is supposed to be sawn through to make the whole more distinct. It will be seen the top and bottom parts have each a rebate like the lid of a snuffbox, which embrace the external edges of the two side-pieces 3 8, and the latter divide, as in the bullet-mould, exactly upon the diametrical line of the inkstand, which in a circular object is, of course, the largest part; the positions of the parts are therefore strictly main- tained. When the mould has been put together, laid upon its side, and filled through x the ingate, or as it is technically called, the tedge, it is allowed to stand about a minute or two, and then the top t is knocked off by one or two light blows of a pewter mallet; the mould is then held in the hand, and the bottom part or core is knocked out of the casting by the edge; lastly, the two sides are pulled asunder by their handles, and the casting is removed from the one in which it happens to stick fast; but it requires cautious handling not to break it. The face of the mould is slightly coated with red ochre and white of egg, to prevent the casting adhering to the saine, and to give the works a better face. The first few castings are generally spoiled, until in fact the mould becomes properly warmed. 799. 798. 797. P 3 a 800. Most of the works made in the very useful material, pewter, are cast in gun-metal moulds, which re- quire much skill in their construction thus, a pewter tankard, with a hinged cover and spout, consists of six pieces, every one of which requires a different mould. Thus:- 1. The body has a mould in four parts, like that for the inkstand, but it is filled in the erect position through two ingates, which are made through the top-piece t of the mould. 2. The bottom requires a mould in two parts, and is poured at the edge. 3. The cover is cast in the same manner; and thus far the moulds are all made in the lathe, in which useful machine these castings are also finished before being soldered together. 4. The spout requires a mould in two parts. 5. The piece, Fig. 796, by which the cover is hinged to the handle, requires a much more complex mould, which divides in four parts, as shown in Fig. 795, and much resembles, except in external form, the remaining mould namely, 6. For the handle, which mould, like the last, consists of four pieces, fitted together with various ears and projections. They are represented in their relative positions in Fig. 798, with the exception of the piece a, Fig. 799, which is detached and shown bottom upwards. Fig. 797 shows the pewter handle separately, with the three knuckles for joining on the cover; and on reference to Fig. 798, of the five parts through which the pin p is thrust, the two external pieces belong respectively to the sides c and d of the mould the others are parts of the casting, and the two hollows are formed by the two solid knuckles fixed to the detached piece of the mould a, Fig. 799. At the time of pouring, the pin P serves 31 Digitized by Google 242 CASTING AND FOUNDING. to connect the three parts a c d together, and also to form the hole in the casting for the pin of the joint. Fig. 800 shows the section of the mould upon the dotted line & By this it will be seen the handle is cast hollow, as almost immediately the mould has been filled through t, all but the thin external shell is poured out again, and the weight is reduced to less than half. To extract the handle, the pin P is first twisted out; then the joint-piece a is removed next the back-piece b; and lastly, the two sides c d are pulled asunder. Tin or pewter bearings for locomotive carriages have been cast in appropriate metal moulds and such materials are very useful to the mechanist for many temporary purposes, such as collars, bearings, screws, and nuts, either for difficult positions, or where no screw-tap is at hand and the resistance is moderate; in such cases the parts of the machine constitute one portion of the mould, the apertures being closed with moist loam. The processes are most successful when the parts can be made warm and the clay is nearly dry. The most important, exact, and interesting example of casting in metallic moulds is that of type- founding, the description of which, as well as drawings of the mould, have been repeatedly given; some of the peculiarities only of this art, will be therefore noticed. Each complete set of types consists of five alphabets, A, A, a, A, a, besides many other characters, in all about two hundred, and which are re- quired to be most strictly alike in every respect, except in device and width; the width is the greatest for the W and M, and the least for the i and !. Every required measure of the types, (represented on an enlarged scale in Fig. 801,) is determined by the mould alone, and not by any after correction. TYPE-FOUNDING. 806. 801. 802 a 803. 8 c a 804. 803. If the moulds for the rectangular shafts of the types were made as in Figs. 802 or 803, the usual forms of square moulds, they would not admit of alteration in width, as shifting a, Fig. 802, would pro- duce no change, and Fig. 803 would thereby produce the form b. The mould which is used, is made in two L-formed parts, as in Fig. 804; whence it follows that shifting the part a to the right or left, in- creases or decreases the width of the type without interfering with its thickness, or as it is technically called, its body, (B, Fig. 801 ;) the width, W, is adjusted by a piece called the register, fixed at the bottom of the mould. The device is changed by placing across the bottom of the mould one of the two hundred little pieces of copper, Fig. 805, called matrices, into which the face of the letter is impressed by very beautifully- formed punches. The length of the letter is determined by a contraction at the upper part of the mould, as shown at c, Fig. 806, which represents the type as it leaves the mould the metal is poured with a jerk, to make a sharp impression of the matrix,-the mould, which is held in the left hand, and the ladle in the right, being jerked simultaneously upwards, at the moment of filling the mould, and without which the face of the type would be rounded and quite imperfect. The breaks c, or the run- ners of the types are first broken off, and after a slight correction of the sides, the hollows or channels in the feet are planed out of a whole column of them, fixed between bars of wood, without touching the square shoulders which determine the lengths of the types, and are left as originally cast. In some types with a large face and much detail, such as the illustrations given above, the motion of the hand is barely sufficient to give the momentum required to throw the metal into the matrix, and produce a clean. sharp impression. A machine is then used, which may be compared to a small forcing-pump, by which the mould is filled with the fluid metal; but from the greater difficulty of allowing the air to escape, such types are in general considerably more unsound in the shaft or body 80 that an equal bulk of them only weigh about three-fourths as much as types cast in the ordinary way by hand, and which for general purposes is preferable and more economical. Some other variations are resorted to in type-founding; sometimes the mould is filled at twice, at other times the faces of the types are dabbed, (the clichée process;) many of the large types and orna- ments are stereotyped, and either soldered to metal bodies, or fixed by nails to those of wood. The music type, and ornamental borders and dashes, display much very curious power of combination. The clichée process is rather stamping than casting. The melted alloy is placed in a paper tray, and Digitized by Google CASTING AND FOUNDING. 243 stirred with a card until it assumes the pasty condition. The metal die, or mould, is then "dabbed" upon the soft metal, as in sealing a letter, but with a little more of sluggish force. Plaster of Paris Moulds, and Sand Moulds.-Other examples of metallic moulds might be given, but there are far more frequent cases in which one single casting is alone required; or else the number is so small, or the pieces themselves are so large or peculiar, that the construction of metal moulds would be found almost or quite impracticable, even without reference to an equally fatal barrier, the expense. In making these single copies in the metals of considerable fusibility, plaster of Paris is sometimes employed: thus, after the printer has arranged the loose types into a page, and the requisite correc- tions have been made, a stereotype, or solid type, is taken of the whole as a thin sheet of metal, which serves to be printed from almost as well as the original letters; and its small cost enables the printer to retain it for future use, after the types themselves have served perhaps for a hundred similar regen- erations, and are ultimately worn out. The stereotype-founder takes a copy of the entire mass of type in plaster of Paris; this is dried in an oven, and placed face downwards within a cast-iron mould, like a covered box, open at the four top- corners. The mould and plaster-cast are heated to the fusing temperature of the type-metal, and gradually lowered into a pan or bath of the same by means of a crane; the hot fluid metal runs in at the corners of the mould. and raises the inverted plaster, which latter would rise entirely to the surface but for the restraint of the cover of the mould. Type-metal is about eleven times as heavy as water; and if the mould be immersed four inches be- low the surface, it is subjected to a pressure equal to that of a column of water forty-four inches high, or of above two pounds upon every square inch. The necessity of this arrangement is shown when a few ounces of type-metal are poured from a ladle on the face of the plaster; the metal looks like a dump, almost without any mark of the letters, where- as the stereotype-cast is nearly as sharp as the original type. The immersion fulfils the same end as the jerk of the hand-caster, or of the pump occasionally employed; and the long continuance of the mould in the fluid metal allows ample time for the air to escape in bubbles to the surface; after which the mould is raised and cooled in a vessel of water, and the plaster is mostly destroyed in its removal. Plaster of Paris, although it may be, and frequently is used for the fusible metals, such as lead, tin, and pewter, cannot be employed alone for iron, copper, brass, and many other metals, the intense melting heats of which would calcine the material, and cause it to crumble; even the soft metals should not be very hot, or they will make the plaster of Paris blister off in flakes or dust. We must there- fore seek a substitute better capable of enduring the heat, and likewise susceptible of receiving definite forms; for which purpose damp sand, with a small natural or subsequent admixture of clay or loam, is found to be perfectly adapted. The moulding-sand cannot, however, be used without external support, and which is given by shal- low iron frames, without tops or bottoms, called flasks, represented in Figs. 807 and 808. The bottom part, 4, 5, is supposed to have been rammed full of sand, and to stand upon a flat board, 6. The model of the plain flat bar which is to be cast, is now laid on the surface of the sand, that of the round bar is imbedded half way in the same, and the mould is dusted with dry parting sand. 807. 808. 2 3 4 5 6 The top part of the flask 2, 3, is shown still empty, and in the act of being attached to 4, 5 by its pins, which enter corresponding holes in the latter, easily but without shake: 2, 3 is also rammed full of sand, and covered with a top board, 1, not represented to avoid confusion. The mould is now opened, the models are removed, and channels are scooped out from the ends of the cavities left by the models, to the hollows or pouring-holes at the end of the flask; the parts are all replaced in the order 1 to 6, represented in Fig. 808, and the whole are fixed together by screw-clamp3, 80 as to assume the condition of Fig. 807. The flask is now placed almost perpendicularly beside the pouring-trough, and the metal is poured into it from the crucible; but the flask, if small, is put on the surface of the pouring or spill trough, and propped up with a short bar. This brief ketch of the entire process of moulding and casting in sand moulds, will be now followed by some remarks in greater detail: first, on the patterns of the objects to be cast; secondly, on the conditions required in the sand; and thirdly, the process of moulding simple and solid bodies. The Digitized by Google 244 CASTING AND FOUNDING. section then following will be devoted to moulding cored works and figures, after which a few lines will be given upon the subject of filling the moulds. Patterns, Moulds, and moulding simple objects.-The perfection of castings depends much on the skill of the pattern-maker, who should thoroughly understand the practice of the moulder, or he is liable to make the patterns in such a manner that they cannot be used, or at any rate be well used. Straight-grained deal, pine, and mahogany, are the best woods for making patterns, as they stand the best: screws should be used in preference to nails, as alterations are then more easily made in the models; and glue joints, such as dovetails, tenons, and dowels, are also good as regards the after use of the saw and plane for corrections and alterations. Foundry patterns should be always made a little taper in the parts which enter most deeply into the sand, in order to assist their removal from the same, when their purposes will not be materially inter- fered with by such tapering. The pattern-maker, therefore, works most of the thicknesses, and the sides or edges, both internal and external, a little out of parallel or square-perhaps as much as about one--ixteenth to one-eighth of an inch in the foot, sometimes much more. When foundry patterns are exactly parallel, the friction of the sand against their sides is so great when they penetrate deeply, that it requires considerable force to extract them; and which violence tears down the sand, unless the patterns are much knocked about in the mould, to enlarge the space around them. This rough usage frequently injures the patterns, and causes the castings to become irregularly larger than intended, and also defective in point of shape, from the mischief sustained by the moulds; all which evils are much lessened when the patterns are made consistently taper and very smooth. It must be distinctly and constantly borne in mind, that although patterns require all the methods, care, and skill, of good joinery or cabinet-making, they must not, like such works, be made quite square and parallel, for the reasons stated. Sharp internal angles should in general be also avoided, as they leave a sharp edge or arris in the sand, which is liable to be broken down in the removal of the pat- tern, or to be washed down on the entry of the metal into the mould. Either the angle of the model should be filled with wood, wax, or putty, or the sharp edges of the sand should be chamfered off with the knife or trowel. Sharp internal angles are very injudicious in respect also to the strength of cast- ings, as they seem to denote where they will be likely to break; and more resemble carpentry than goo metallic construction. Before the patterns reach the founder's hands, all the glue that may have been used in their con- struction should be carefully scraped off, or it will adhere to and pull down the sand. The best way is to paint or varnish wooden patterns, so as to prevent them from absorbing moisture, as they will then hang to the sand much less, and will retain their forms much better. Whether painted or not, they deliver more freely from the mould when they are well brushed with black-lead, like a stove. In patterns made in the lathe, exactly the same conditions are required; the parts which enter deeply into the sand should be neither exactly cylindrical nor plane surfaces, but either a little coned, or rounding, as the case may be; and the internal angles should not be turned exactly to their ultimate form, but rather filled in, or rounded, to save the breaking down of the sharp edges of the mould. Foundry patterns are also made in metal; these are very excellent, as they are permanent and when very small are less apt to be blown away by the bellows used for removing the loose sand and dust from the moulds. To preserve iron patterns from rusting, and to make them deliver more easily, they should be allowed to get slightly rusty, by lying one night on the damp sand next, they should be warmed sufficiently to melt bees'-wax, which is then rubbed all over them, and in great part re- moved. and then polished with a hard brush when cold. Wax is also used by the founder for stopping up any little holes in the wooden patterns; whitening is likewise employed, as a quicker but less care- ful expedient; and very rough patterns are seared with a hot iron. The good workman, however, leaves no necessity for these corrections, and the perfection of the pattern is well repaid by the supe- rior character of the castings. Metal patterns frequently require to have holes tapped into them, for receiving screwed wires, by way of h indles for lifting them out of the sand; and in like manner, large wooden patterns should have screwed metal plates let into them for the same purpose, or the founder is compelled to drive pointed wires into them, to serve as handles, which is an injurious practice. The flasks or casting-boxes for containing the sand, are made of various sizes; each side is about 2 to 3 inches deep. They are poured at the edge when placed nearly vertical but for large brass works the practice of the iron-founder is generally followed, who mostly pours his work horizontally, through a hole in the top, as will be explained. The pins of the flask should fit easily but without shake, or the two halves will -hift about and cause a disagreement or slip in the casting. The tools used in making the moulds are few and simple; namely, a sieve, shovel, rammer, strike, mallet, a knife, and two or three loo-ening wires and little trowels, which it is unnecessary to describe. The principal materials for making foundry-moulds are very fine sand and loam they are found mixed in various proportions, SO that the respective quantities proper for different uses cannot be well defined but it is always judicious to employ the least quantity of loam that will suffice.* These materials are seldom used in their new or recent states for brass castings, although more 80 for :ron; and the moulds made of fre-h sand are always dried, as will be explained. The ordinary moulds are made of the old damp sand, and they are generally poured immediately or whilst they are green sometimes they are more or less dried upon the face. The old working sand is con-iderably less adhesive than the new, and of a dark-brown color; this arises from the brickdust, flour, and charcoal-dust, used in moulding, becoming mixed with the general stock, which therefore requires occasional additions of new sand or loam, 80 that when slightly moist and pressed firmly in the hand, it may form a moderately hard compact lump. * The iron and brass founders' sand and loam used in this city are principally obtained from Long Island and are found in great abundance in almost every state of the Union. Digitized by Google CASTING AND FOUNDING. 245 Red brickdust is generally used to make the partings of the mould, or to prevent the damp sand in the separate parts of the flask from adhering together. The face of the mould which receives the metal, is generally dusted with meal-dust, or waste flour; but in large works, powdered chalk, and also wood or tan ashes, are used, from being cheaper. The moulds for the finest brass castings are faced either with charcoal, loamstone, rottenstone, or a mixture of the same the moulds are frequently inverted and dried over a dull fire of cork shavings; or when dried, they are smoked over pitch or black resin lighted in an iron ladle.* The cores or loose internal parts of the moulds for forming holes and recesses, are made of various proportions of new sand, loam, and horse-dung, as will be explained in treating of cored works. They all require to be thoroughly dried, and those containing horse-dung must be well burned at a red heat; this consumes the straw, and makes them porous and of a brick-red. In making the various moulds, it becomes necessary to pursue a medium course between the conditions best suited to the formation of the mould, and those best suited to filling them with the red-hot metal, without risk of failure or accident. Thus, within certain limits, the more loam and moisture the sand contains, and the more closely it is rammed, the better will be the impression of the model; but at the same time, the moist and impervious condition of the mould would then incur the greater risk of acci- dent, both from the moisture and from the non-escape of the air; therefore the policy, on the score of safety, is to use the sand as dry as practicable, so as to avoid the delay of after-drying, and also to keep the mould porous. The founder, therefore, compromises the matter by using : little facing sand containing rather more loam, for the face of the green moulds for general work; and in those cases where much loam is used, the moulds are thoroughly dried by heat, which is not generally necessary with ordinary sand moulds. The power of conducting heat is considerably less in red-hot iron than in copper and brass, and there- fore the moulds for the latter require to be in a drier condition than those which may be used for iron; but in either case the presence of superfluous moisture is always attended with some danger to the individual as well as to the work.t Another point has also to be considered: as castings contract considerably in cooling, in moulding large and slight works the face of the mould must not be too strongly rammed, nor too much dried, or its strength may exceed that of the red-hot metal, whilst in the act of shrinking. The result would be, that in contracting, the casting would be rent or torn asunder from the restraint of the mould whereas it should have the preponderance of strength, 80 as to pull down the face of the sand instead of being itself destroyed. But the exact condition both of the mould and of the melted metal, must be determined by the nature of the object to be cast; matters which can be only referred to with the development of the practice of the foundry, and upon which we shall now commence. The sand having been prepared, and the appropriate flask and boards selected, the moulder first examines every pattern separately, to determine the most appropriate way of inserting it in the flask, as explained by Fig. 789; also to see that patterns, such as f and h, therein shown, are smallest at the parts entering the most deeply into the sand, in order that they may deliver well. It should also be noticed whether they are perfectly smooth, and that there is no glue hanging about them, which would cause them to adhere and to pull down the moist sand. The bottom flask, 4 and 5, Fig. 808, is placed on a board not less than an inch or two longer and wider than itself, with the face 4 downwards, and it is filled from the side 5. A small portion of the strong facing- sand is rubbed through a fine sieve; the remainder is thrown in from the trough with the shovel, and the moulder drives the whole moderately hard into the flask, either with a mallet, the handle of the spade, or other rammer; or else he jumps up by aid of the rope suspended from the ceiling, and treads the sand in with his feet. The surface is then struck off level with a straight metal bar or scraper, a little loose sand is sprinkled on the surface, upon which another board is placed, and rubbed down close. The two boards and the flask contained between them, are then all three turned over together; this requires them to be brought to the front of the moulding-trough, so that the individual may rest his chest against them, and his fore-arms upon the edges of the top board; he then grasps the three together at the back part with his outstretched hands, and thus retained in contact, the whole are quickly turned over upon the front edge of the moulding-trough, and then slid back upon the transverse bearers or blocks, to the usual position. The top board is afterwards taken off; the clean surface of moist sand, then exposed, is well dusted over with red brickdust crushed fine, and contained in a linen bag; the mouth of the bag is held in the right hand, and the bottom corner in the left, and both hands are shaken up and down together, to scatter the dry powder uniformly over the flask; a part of the loose powder is removed with the hand-bellows, and the bottom half of the mould is then ready for receiving the patterns. The models are next arranged upon the face of the sand at 4, 80 as to leave space enough to prevent the parts breaking one into the other, and also for the passages by which the metal is to be introduced, and the air allowed to escape. When there are only two or three pieces to be cast, a separate runner is often made to each of them from one of the holes in the end of the flask when several small patterns are to be moulded, they are arranged on both sides a central runner, or ridge, from which small passages The gold and silver casters frequently use a lighted link for facing their sand-moulds, and some of the type-founders' metallic moulds are smoked over a lamp: all these modes deposite a fine layer of soot upon the moulds. t The above is the reason generally assigned for the fact, that the iron-founders may and do use their moulds with safety when sensibly more moist than is admissible for brass and copper castings. It is confirmatory of the fact, that the more dense the mould, the drier it must be; as the sand used by iron-founders is also coarser and therefore more porous than that employed by brass-founders. Digitized by Google 246 CASTING AND FOUNDING. lead into every section of the mould. The whole mass when poured has been compared to a great fern- leaf with its leaflets, and is usually called a spray. Those patterns which are cylindrical or thick, are partly sunk in the sand, by scraping out hollow recesses with the bowl of an old copper spoon, and knocking the model into the sand with a mallet; afterwards the general surface is repaired to agreement with the diametrical line of the model, or its largest section, as the case may be, by means of a knife or a little piece of sheet steel, something like the worn-out blade of a dessert-knife bent up a little at the end, or else with very small trowels. After the sand is made good to the edges of the patterns, the brickdust is again shaken over them, so that the patterns may receive a slight share as well as the general surface of the sand. The upper part of the flask 2, 3, is then fitted to the lower, or 4, 5, by the pins, and this half likewise is made up: first a little strong sand is sifted in; it is then filled up from the trough, rammed down, and struck off as before, the dry powder serving to prevent the two halves from sticking together. In order to open the mould for the extraction of the models, a board is placed on the top of flask 2, 3, and struck smartly at different parts with the mallet; the tool is then laid aside, and the upper part of the flask and its board are lifted up very gently and quite level; after which it is inverted on its board, and now each of the inner faces of the mould is exposed. Should it happen that any considera- ble portion of the mould, say a part as large as a cent, is broken down in one piece, the cavity is moistened with the end of the knife, the mould is again carefully closed, and lightly struck before the removal of the patterns; it is probable on the second lifting such piece will be picked up. The breaks are carefully repaired before the extraction of the patterns, to effect which they are driven slightly sidewise with blows of the mallet, given on a short wire or punch, 80 as to loosen them by enlarging the space around them; the patterns are then lifted out very carefully with the finger-nails, or sometimes a pointed wire is driven a little way into the pattern to serve as a handle to lift it by :* this process requires some delicacy not to tear away the sand, which accident must be carefully re- paired, sometimes by replacing the loose pieces, at other times with a little new sand picked out of any unused part of the mould. Should the flask only contain one or two objects, the ingate or runner is now scooped out of the sand, 80 as to lead from the object to the pouring-hole; and when several objects are contained, a large central channel, and lesser passages sidewise, are made as before mentioned. The entrance round about the pouring-hole is smoothed and compressed with the thumb, that it may not break down when the metal is poured and all the loose sand is carefully blown out of the mould, both parts of which may be placed edgewise for the more convenient application of the bellows, if necessary. The succeeding processes are to dust the faces of both halves of the mould with meal-dust or waste flour, as explained with regard to the brickdust, and to replace the mould and boards: the whole of them are then carried to the spill-trough, upon the edge of which they are rested whilst the one board is placed exactly level with the end of the flask; but the board on the side from which the crucible will be poured, is placed about two inches below, as in Fig. 807, and the hand-screws are fixed on as shown. The mould is now held mouth downwards, that any sand loosened in the screwing down may be allowed to fall out, and the flask. according to its size, is supported either on the ground or on the surface of the trough by aid of a little bar resting against the clamp: it is now quite ready to be filled, the particulars of which process will be described when the remarks on moulding are concluded. In works that require the first side, or 3, 4, to be cut away for imbedding the models, it is usual when the second part, or 2, 3. has been made, to destroy the first or false side, (which is only hastily made,) and to repeat it in a more careful manner by inverting the lower flask upon 2, 3, proceeding in all other respects as before, by which means a much more accurate and sound mould is produced. When many copies of the same patterns are required, an odd side is prepared; that is, a flask is chosen to which there are two bottom sides, 4, 5. One of these latter is very carefully arranged with all the patterns, but which are only imbedded barely half way, 80 that when 2, 3 is filled, and both are turned over, the whole of the patterns are left in the new side; a second side, 4, 5, is moulded to serve for receiving the metal, as the mould is destroyed every time the metal is poured in. By this plan the trouble of rearranging the patterns for every separate mould is saved, as they are merely replaced in the odd side, and the routine of forming the two working sides is repeated. Moulding Cored Works.-If the objects to be cast require to be 80 moulded that when they leave the sand they may contain one or several holes, they are said to be cored, and in such cases, a variety of methods are practised for introducing internal moulds or cores, which shall intercept the flow of the metal, and prevent it from forming one solid mass at those respective parts. For example, the pins inserted in the pewterers' moulds, Figs. 795 and 798, for producing the holes in the joints, are essentially cores. Various other methods are pursued, the three most usual of which are represented in Figs. 809, 810, and 811; the upper figures show the exact sections of the three models or casting patterns; the lower figure represents the two halves of the mould, which are respectively shaded with perpendicular and horizontal lines, the cores are shaded obliquely; and the white open spaces show the hollows to be occupied by the metal when it is poured in. First. Many works are said to deliver their own cores; of such kind is Fig. 809, in which the cavity extends through the model, and exactly represents that which is required in the casting; the hole is either made quite parallel, or a little larger one side than the other, and gradually taper between the two. In some cases, when the hole is sufficiently taper, it delivers its own core as a continuation of the general mass of sand filling the one side of the flask; but in many or most cases, the space in the model is rammed full of strong sand at first, and it is then moulded as if to produce a plain solid casting. Before the mould is finally closed for pouring, the sand core is pushed carefully out of the pattern, and A steel ire, pointed and hardened, is convenient as a picker-out ; and when fixed in the pattern and struck sidewise, it scrves as a loosening bar likewise. Digitized by Google CASTING AND FOUNDING. 247 inserted in the mould; to denote its precise position, one side of the core is scored with one or two deep marks in the first instance, which cause similar ridges or guides in the mould. Secondly. When the hole extends only part way through, the hole of the pattern, Fig. 810, is fitted with a solid plug, sawn and filed out of soft unburnt brick, principally sand, (or the common Flanders brick; the core is made long enough to project about as much as its own diameter, and the work is moulded as if to be cast with a solid pin, instead of a hole. The last step is to extract the filed core, and to insert it into the hollow formed by itself in the flask. 811. 810. 809. Thirdly. The patterns for iron-work and some others are mostly made with prints instead of holes, as in Fig. 811; that is, the pattern-maker places square or round pieces on one or both sides of the pattern, where the square or round holes are respectively required; and the founder has moulds for forming cores of corresponding diameters or sections, and in lengths of about two to twelve inches, short pieces of which are cut off as may be required. For example, some core-boxes are made like Fig. 812, for cylindrical cores; these divide through the axis, and are kept in position by pins; at the time when they are rammed they are fixed together by wood or iron staples, embracing three sides of the mould, or else by screw-clamps. For straight cores, say one inch wide, twelve inches long, and half-inch thick, the pieces of wood, Fig. 813, are also one inch thick, with an opening between them of twelve inches long and half-inch wide. This core-box is laid on a flat board; it is also held together with clamps, but without pins in the core-box, as the projection at the one end gives the position; it is rammed flush with both sides, and the two parts can be then separated obliquely. If it is preferred to make the cores to the precise lengths instead of cutting them off, this core-box admits of contraction in length, in the manner of the type-mould, Fig. 804; and by placing thin slips between the two halves it may be temporarily increased in width, but not in thick- ness. Fig. 814 is a similar core-box for a casting with circular mortises; this requires either pins or projections at each end, as it cannot be opened obliquely. Core-boxes are sometimes made of plaster of Paris; wood is much better, and metal the best of all. 813. 812. 815. 814. 816. 817. 819. Many works require core-boxes to be made expressly for them; thus the dotted line in Fig. 812 shows an enlargement in the centre for coring a hole of that particular section. Figs. 815 and 816 represent the two halves of a brass or lead core-box suitable to the stop-cock, Fig. 817; and Fig. 819 shows the core itself after its removal from the part 816, in which it is also figured. In 817, the model from which the object is moulded, the shaded parts represent the projections, or core-prints, which imprint within the mould the places where the extremities of the core, Fig. 819, are supported when placed therein. The various kinds of core-boxes are rammed full of new sand, sometimes with extra loam; the long cores are strengthened by wires they are carefully removed from the boxes, and thoroughly dried before use, in the oven prepared for the purpose. Fig. 820 represents several examples of coring: in this view the works are represented of their ulti- mate forms, that is, with the holes in them; in Fig. 821, the models are arranged in the flask, with the runners all prepared, the prints of the cores being in every case shaded for distinction. Thus a is the . Others prefer sand, horse-dung, and a very little loam, for making cores; these are dried, and then well burned, for which purpose they are put into an empty crucible within the fire, the last thing at night, and allowed to remain until the morning. This consumes the small particles of straw. and renders them more porous, in consequence of which the works become sounder from the free escape of air, the necessity of which was adverted to in the earlier part of this subject, and can- not be too much insisted upon. Digitized by Google 248 CASTING AND FOUNDING. stop-cock, of which explanation has been already given; b has a straight and a circular mortise; this pattern delivers its own core, in the manner referred to in Fig. 809, as the model is made with mortises like the finished work: c only requires a perpendicular square core; d a round core parallel with the face of the flask, and in this manner all tubes and sockets are cast, whether of uniform or irregular bore, see Fig. 812; e has two rectangular cores crossing each other at right angles; and f is the cap of a double-acting pump, the core for which is shown in section by the white part of Fig. 822, the shaded portions being the metal; the great aperture leads to the piston, the two smaller are for valves opening inwards and outwards; this of course requires a metal core-box capable of division in two parts, and made exactly to the particular form. 820. b 822. € d c 821. In addition to the cores used for making holes and mortises, much ingenious contrivance is displayed in the cores employed for other works of every-day occurrence, the undercut parts of which WC uld retain them in the sand but for the employment of these and analogous contrivances. It will now be readily understood that if, in the Fig. 790, the parts shaded obliquely were separate, there would be no difficulty in removing first the upper half of the flask, then the false cores, after which the patterns would be quite free.* By such a method, however, the circular edge of a sheave would require at least three such pieces; but Fig. 823 shows a different way of accomplishing the same thing, when the pattern is made in two parts in the manner represented. The entire model is first knocked into the side A, the sand is cut away to the inner margin of the pattern which terminates upon the dotted line a, and the side A of the mould is then well dusted; a layer of sand is now thrown on, and rammed tolerably firm to form an annular core, which is made exactly level with the inner margin b of the pattern, and the core is well dusted; lastly, the side B is put on and rammed as usual. To extract the model, the side B is first lifted, the half pattern b, b, (which is shaded,) is removed, and the ingate is cut in the side B, to the edge of the pulley ; the mould is well dusted with flour and replaced. 823. B 8 8 b a a The entire mould is now turned over A is first removed, then the remaining half pattern a, a, which must be touched very tenderly or it will brenk down the core; and the runner (which divides in two branches around the core) is also scooped out in the side A, which is dusted with flour and replaced, ready for pouring. Common patterns not requiring cores, are frequently divided into two parts in the above manner, so that when the mould is opened the pattern may divide and remain half in each side; this lessens the risk of breaking down the mould and the attendant trouble of afterwards repairing it. Reversing and Figure Casting.Supposing that an ornament, represented in section in Fig. 824, has been modelled in relief, either in clay or wax upon a flat board, from which a thin casting in brass is wanted without the tablet, the process is called reversing, and is to be accomplished in any of three ways. . The term false-core is employed by the brase-founder to express the same thing as the drawback of the iron-founder. The former calls every loose piece of the mould not intended for holes, a false-core. Digitized by Google CASTING AND FOUNDING. 249 First, an empty flask is placed upon the board, 824, and rammed full of sand; it assumes the appearance of 825; the second part of the flask is attached to 825, and filled to make the part 826, which is called the back-mould; some clay is then rolled out to the intended thickness of the casting, with a cylindrical roller running on two slips of wood or on two wires, and a 824. narrow band of this clay is placed on 826, around the figure, that it may separate 825 and 826, exactly to the required distance, ready for receiving the metal. By the second mode, 825 is first made, then 826, and from 825. the latter 827 is moulded, which is a counterpart of 825. A thin sheet of clay is then pressed all over 827, into every cavity, and cut off flush with the plane surface of the mould, by which it assumes the appearance denoted by the double line in 827. After this 826 is destroyed, and made over again in 827, but 826. 80 much smaller than before as the thickness of the clay lining; when the new back-mould 826 is placed in contact with 825, it leaves the required space for the intended casting. This 827. mode is only preferable to the first, when many parts of the work are nearly perpendicular in which case, if the first mode be adopted, a portion of the back-mould 825, must be pared away at the perpendicular parts, and if incautiously performed there will be a risk of irregularity of thickness, or even of holes in the casting. The third mode, is to take a casting of 824 in plaster of Paris; when this is thoroughly dry it is oiled, and poured full of a cement of wax, grease, and red ochre, which is poured out again when partially set, leaving a thin crust behind, (as in the pewter handle.) A second, a third, or more layers of wax are thus added until the whole is sufficiently thick, when the wax shell is extracted, and then moulded from in the ordinary manner; the first brass casting is finished and chased to serve as the permanent pattern. The management of the wax requires practice. In constructing such moulds additional care is given to every part of the work; for example, the sand is sifted much finer, the parting is made with fine charcoal dust, and the facing with charcoal and rottenstone mixed together in about equal parts, the mixture being of a slaty color; sometimes the loamstone, which is found in the pits where clay for making tiles is dug, is used instead of rottenstone. The moulds are well dried in an oven, or over the mouth of the furnace, and the faces are afterwards smoked over a dull fire of cork shavings; this deposites a very fine layer of soot over the face of the mould, which greatly assists the running of the metal; when this additional care is taken the works are known as fine-castings. In casting figures, such as busts, animals, and ornaments consisting of branches and foliage, consider- ably more skill is required the originals are generally solid, but the moulds necessarily divide into very many parts. Most persons will have had the opportunity of judging of the complexity of these moulds, from similar works in plaster of Paris, which are frequently purchased by artists and the virtuosi before the seams of the mould are removed. A glance at these plaster-casts, at the complex and undercut form of many of these ornamental works, and at the explanatory diagram, Fig. 788, will convey some notion of the method to be pursued as well as of the trouble attending them. It is shown, for example, by the diagram just referred to, that all figured works approaching to the circular or elliptical section, require that the mould should be divided into at least three parts, except under most favorable circumstances. In the human figure and quad- rupeds, the four limbs and the trunk require at least three parts each, and often many more; it will be easily conceived, therefore, that such moulded works require considerable skill and patience. Piece after piece of the mould is successively produced, just as in making the core, Fig. 823, every piece embracing only so much of the figure, as in no part to require any core to overhang the line in which it is withdrawn. The side of the mould in which the figure is partly imbedded is first dusted with charcoal, and then the first core is very carefully rammed into the nook, and pared down to the new line of division; the green or wet sand-core is then dusted, and the second core is made, and after- wards dusted, when the moulder proceeds with the third core, and so on; every one being carefully adapted to its neighbor and withdrawn, to see that all is right, before the succeeding core is proceeded with. The relative positions of the cores amongst themselves are readily recognised and maintained by the irregularity of their forms, as in a child's dissected map, or by making a notch or two here and there, which are faithfully copied in the succeeding piece. It is frequently necessary to thrust two or more broken needles through the green cores into the neighboring parts to connect them together, in imitation of the pins in the flasks. All the parts of the mould are dried in the oven, and the facings are smoked over a cork fire as be- fore explained; the perfection of the casting is augmented by pouring whilst the mould is still slightly warm, as otherwise on cooling it has an increased affinity for damp; but the mould when hot is more or less filled with aqueous vapor, which is equally prejudicial. When a figure, such as a bust, is required to be cast hollow from a solid model, it is first moulded exactly as above. The core is now produced as follows: At the foot of the bust a large space, nearly equal in length and bulk to the bust, is cut away in the sand, to serve for fixing the core in the mould, or for the balance, as it is called, as the core cannot be propped up at both ends. The entire hollow, that is, for the bust and the balance, is filled with a composition of about one part of plaster of Paris and two of sand or fine brickdust, mixed with a little water and poured in fluid, a few wires being placed amidst the same for additional support. The mould is now taken to pieces to extract the core, which is then dried, thoroughly burned, and allowed to cool slowly, (which the founder calls annealing, from a similar method being employed in 32 Digitized by Google 250 CASTING AND FOUNDING. annealing or softening the metals and glass:) the core is then returned to the mould, to see that it has not become distorted. If needful, the fitting around the balance is made good to suit the reduced magnitude of the core, which latter is then so far pared away as to leave room for the thickness of metal; this is frequently regulated by boring holes at many parts of the core with a stop-drill, having a collar to prevent its penetrating beyond the determined depth; the surface of the core is now pared down to the bottoms of the holes, as uniformly a3 possible. When the mould has been faced, dried, and smoked, the whole is put together for pouring, for which purpose the figure is inverted and filled from the pedestal. Equestrian and other figures are sometimes cast in two, three, or more pieces, and joined together by solder, screws, or wires; but in all such works the aim of the founder is to leave little or nothing for the finisher or chaser to do. Some objects which are either exceedingly complex in their form, or soft and flexible in their sub- stance, and which do not therefore admit of being moulded in sand, in the ordinary manner of figure- casting, may be moulded for a single copy, provided the originals consist of 8. bstances which may be either readily melted or burned into ashes. A cavity is made in the sand of the moulding-trough, a little larger and longer than the object, or else a wooden box of appropriate size is procured, in the midst of which the wax model may be placed to the end of the model is added a piece to represent the runner, which will be required for introducing the metal. The composition of one-third plaster of Paris and two-thirds brickdust, mixed with water, the same as for the core of the bust, is then poured in, entirely to surround the model. The mould is first slowly dried; it is then inverted and made warm to allow the wax to run out, after which it is an- nealed, or burned to redness; and lastly, when cooled, it is buried in sand and filled with metal. The method necessarily throws the chance of success upon a single trial, as the model is destroyed. Should the face of the casting be required to be particularly smooth, a small quantity of brickdust is washed, (in the manner practised with emery, and to be explained,) and mixed with very fine plas- ter a coat of this is brushed over the model, which excludes air-bubbles, the model is quickly placed in its cavity, and the coarser mixture is poured in as before. The above method exactly corroborates a mode long since described as being suitable to casting copies of small animals or insects, parts of vegetables. and similar objects these are to be fixed in the centre of a small box, by means of a few threads attached to any convenient parts, one or two wires being added to make air-holes and ingates for the metal. A small quantity of river silt or mud, which had been carefully washed, was first thrown in and spread around the object by swinging the box about; and when partly dry, successive but coarser coats were thrown in. 80 as ultimately to fill up the box. When it had become thoroughly dry, the wires were first removed from the earthy mould; it was then burned to reduce the object to ashes, and when every particle of the model had been blown out, it was ready to be filled with metal. Filling the moulds.-Having traced the formation of various kinds of moulds for brass work, we must now return to the furnace to see if the metal is in condition to be poured, which is indicated by the slight wasting of the zinc from its surface with a lambent flame. When this condition is observed, the large cokes are first removed from the mouth of the pot. and a long pair of crucible tongs are thrust down beside the same to embrace it securely, after which a coupler is dropped upon the handles of the tongs; the pot is now lifted out with both hands and carried to the skimming-place, where the loose dross is skimmed off with an iron rod, and the pot is rested upon the spill-trough, against or upon which the flasks are arranged. The temperature at which the metal is poured must be proportioned to the magnitude of the works; thus large, straggling, and thin castings, require the metal to be very hot, otherwise it will be chilled from coming in contact with the extended surface of sand before having entirely filled the mould thick massive castings if filled with such hot metal would be sand-burned, as the long continuance of the heat would destroy the face of the mould before the metal would be solidified. The line of policy seems therefore to be, to pour the metals at that period when they shall be suffi- ciently fluid to fill the moulds perfectly and produce distinct and sharp impressions, but that the metal shall become externally congealed as soon as possible afterwards. For slight moulds the carbonaceous facings, whether meal-dust, charcoal, or soot, are good, as these substances are bad conductors of heat, and rather aid than otherwise by their ignition; it is also proper to air these moulds for thin works, or slightly warm them before a grate containing a coke fire. But in massive works these precautions are less required, and the facing of common brickdust, which is in- combustible and more binding, succeeds better. The founder therefore fills the moulds having the slightest works first, and gradually proceeds to the heaviest; if needful, he will wait a little to cool the metal, or will effect the same purpose by stirring it with one of the ridges or waste runners, which thereby becomes partially melted. He judges of the temperature of the melted brass principally by the eye. as when out of the furnace and very hot, the surface emits a brilliant bluish white flame, and gives off clouds of the white oxide of zinc, a consid- erable portion of which floats in the air like snow; the light decreases with the temperature, and but little zinc is then fumed away. Gun-metal and pot-metal, do not flare away in the manner of brass, the tin and lead being far less volatile than zinc; neither should they be poured so hot or fluid as yellow brass, or they will become sand-burned in a greater degree, or rather the tin and lead will strike to the surface. Gun-metal and the much-used alloys of copper, tin, and zinc, are sometimes mixed at the time of pouring the alloy of lead and copper is never so treated, but always contains old metal and copper is seldom When the founder is in doubt as to the quality of the metal. from its containing old metal of unknown character, or that he desires to be very exact, he will either pour a sample from the pot into an ingot mould, or extract a little with a long rod terminating in a spoon heated to redness. The lump is cooled and tried with the file, saw, hammer, or drill, to learn its quality. Digitized by Google CASTING AND FOUNDING. 251 cast alone, but a trifling portion of zinc is added to it, otherwise the work becomes nearly full of little air-bubbles throughout its surface.* Some persons judge of the heat proper for pouring, by applying the skimmer to the surface of the metal, which when very hot has a motion like that of boiling water; this dies away and becomes more languid as the metal cools. Many works are spoiled from being poured too hot, and the management of the heat is much more difficult when the quantity of metal is small. The mixture and temperature of the metal being found to be proper, it is poured in the manner represented in Fig. 788; the tongs are gradually lowered from the shoulder down the left arm, and the right hand is employed in keeping back the dross from the lip of the melting-pot. A crucible contain- ing the general quantity of 40 or 50 lbs. of metal, can be very conveniently managed by one individual; but for larger quantities, sometimes amounting to one hundred weight, an assistant aids in supporting the crucible, by catching hold of the shoulder of the tongs with a grunter, an iron rod bent like a hook. Whilst the mould is being filled, there is a rushing or hissing sound from the flow of the metal and the escape of the air; the effect is less violent when there are two or more passages, as in heavy pieces, and then the jet can be kept entirely full, which is desirable. Immediately after the mould is filled, there are generally small but harmless explosions of the gases, which escape through the seams of the mould they ignite from the runners, and burn quietly; but when the metal blows, from the after-escape of any confined air, it makes a gurgling, bubbling noise, like the boiling of water, but much louder, and it will sometimes throw the fluid metal out of the runner in three or four separate spirts. This effect, which mostly spoils the castings, is much the most likely to occur with cored works, and with such an are rammed injudiciously hard, without being, like the moulds for fine castings, subsequently well dried. The moulds are generally opened before the castings are cold, and the founder's duty is ended when be has sawn off the ingates or ridges, and filed away the ragged edges where the metal has entered the seams of the mould; small works are additionally cleaned in a rumble, or revolving cask, where they soon scrub each other clean. Nearly all small brass works are poured vertically, and the runners must be proportioned to the size of the castings, that they may serve to fill the mould quickly. and supply at the top a mass of still fluid metal, to serve as a head or pressure for compressing that which is beneath, to increase the density and soundness of the casting. Most large works in brass, and the greater part of those in iron, are moulded and poured horizontally, and the process being exactly alike for both metals, we must refer the reader to the following. Iron-Founders' Flasks, and Sand-moulds.-The process of moulding works in sand is essentially the same both for brass and iron castings; but the very great magnitude of many of the latter give rise to several differences in the methods it will suffice, however, to advert to the more important points in which the two practices differ, or to those which have not been already noticed I shall therefore com- mence with a few remarks upon the flasks and the sand. In the greater number of cases, the iron-founder moulds and casts his works horizontally, with the flasks lying upon the ground; frequently the top part only is lifted and in the largest works the lower part of the flask is altogether omitted, such pieces being moulded in the sand constituting the floor of the foundry; in these cases the position of the upper flask is denoted by driving a few iron stakes into the earth, in contact with the internal angles of the lugs, or projecting ears of the flasks. The sand would drop out of such large flasks, if only supported around the margin they are con- sequently made with cross-bars, or wooden stays, a few inches asunder, which, unless the entire flask is made of wood, are fixed by little fillets cast in the solid with the sides of the iron flasks. A great number of hooks in the form of the letter S, but less crooked at the ends, are driven into the bars, and both the bars and hooks are wetted with thick clay-water, 80 that the sand becomes entangled amidst them, and is sustained when the flask is lifted. Some flasks require the force of either two or several men, who raise them up by iron pins or handles projecting from the sides of the flask; they are then placed upon one edge, and allowed to rest against any convenient support whilst they are repaired, or they are sustained by a prop. The very heavy flasks are lifted with the crane, by means of a transverse beam and two long hang- ers, called clutches, which take hold of two gudgeons in the centres of the ends of the flask; it can be then turned round in the slings, just the same as a dressing-glass, to enable it to be repaired. The modern iron-founders' flasks are entirely of iron, and do not require the wooden stays, as they are made full of cross-ribs nearly as deep as the flask itself, and which divide its entire surface into compartments four or five inches wide, and one to two feet long. On the sides of every compart- ment are little fillets, sloping opposite ways, so as to lock in the small bodies of sand very effectually. When these top flasks are placed upon middle flasks without ribs, as in moulding thick objects, the two parts are cottered or keyed together. by transverse wedges fixed in the steady pins of the flask; lifters or gaggers are then placed amidst the sand these are light T-shaped pieces of iron, wetted and placed head downwards, the tails of which are largest at top, so as to hold themselves in the sand, the same as the keystone of an arch is supported. The gaggers are placed at various parts to combine the sand in the two flasks, and they fulfil the same end as the iron hooks and nails driven into the wooden stays of the old-fashioned flasks. The bottom flask, or drag, has sometimes plain flat cross-ribs, two inches wide, (like a flat bottom with square holes,) that it may be turned over without a bottom-board and unless the flasks have swivels for the crane, they have two cast-iron pins at each end, and one or more large wrought-iron handles at each side, by which they may be lifted and turned over by a proportionate number of men. The engraved cylinders for calico-printing are required to be of pure copper, and their unsoundness when cast in the usual way was found to be so serious an evil, that it gave rise, in 1819, to Holingrake's patent for casting the metals un- der pressure. Digitized by Google 252 CASTING AND FOUNDING. The sand of the iron-founder is coarser and less adhesive than that used by the brass-founder. The parting-sand is the burned sand which is scraped off the castings it loses its sharp, crystalline character from being exposed to the red heat. The facing-sand is sometimes only about equal parts of coal-dust and charcoal-dust, ground very fine; at other times, either old or new sand is added, and for large, thick works a little road-drift is introduced. All these substances get largely mixed with the sand of the floor, and lessen its binding quality, which is compensated for by occasional additions of new sand, and by using more moisture with the sand, as before extracting the patterns, the iron-founder wets the edges of the sand with a sponge, which has sometimes a nail tied to it to direct the water in a fine stream; for heavy works a watering-pot is used. The green-sand moulds are made as in the brass-foundry, of the ordinary stock of old moist sand these are often filled as soon as they have been made. The dry-sand moulds are made in the same manner, but with new sand containing its full proportion of loam; these moulds are thoroughly dried in a large oven or stove, and then blackwashed or painted, with thin clay-water containing finely-ground charcoal; this facing is also thoroughly dried before the moulds are poured. The loam-moulds, which are much used for iron-castings, and somewhat also for those of brass, are made of wet loam with a little sand, ground together in a mill to the consistence of mortar the moulds are made partly after the manner of the bricklayer and plasterer, as will be explained; the loam moulds also are thoroughly dried, blackwashed, and again dried, as from their greater compactness they allow less efficient escape for the vapor or air, and therefore they must be put into the condition not to gener- ate much vapor when they are filled. Iron moulds are also employed for a small proportional number of works which are then called chilled castings; and occasionally the methods of sand-casting and chilling are combined, as in some axletree-boxes. which are moulded from wooden patterns in sand, and are cast upon an iron core. To form the annular recess for oil, a ring of sand, made in an appropriate core-box, is slipped upon the iron mandrel, and is left behind when the latter is driven out of the casting. It would be a useless repetition to enter into the details of moulding ordinary iron-works; but from the horizontal position of the flasks, it is necessary that the part of the work which is required to be the soundest, and most free from defects, should be placed downwards, as the metal is more condensed at the lower part, and free from the scoria or sullage which sometimes renders the upper surface very rough and full of minute holes. As the flasks almost always lie on the ground, it is also found the most convenient to retain them in contact by placing heavy weights upon them; the foundry should in consequence have an abundant supply of these. The flasks require to be poured through a hole in the upper half, as seen at r, Fig. 837, which hole is formed by placing a wooden runner-stick in the top part A, whilst it is being rammed and a small channel is afterwards cut sidewise into the mould. Sometimes two, three, or even half-a-dozen or more runners are put to one single casting, either when it requires a great weight of metal, or when it is large but slight, as in trellis-work, in which case the metal might cool before filling the mould, if only intro- duced at one single runner. When the runners are required to be lofty, either to supply pressure to the metal, or as a reserve to fill up the space left by its contraction in cooling, iron rings of six or eight inches diameter are piled up to the required height, to support the tube of sand contained within them. Small objects that are poured from one hole, are frequently moulded with two runners, that the metal may flow through the mould, and that there may be a sufficient supply to meet the shrinkage, and also to supply head or pressure; another advantage also results, as it assists in carrying off the scoria or sullage. The iron-founder employs all the methods of coring explained at pages 246 to 248, and also others of an entirely different kind but little required in brass-works; namely, for lateral holes in the parts of the castings buried beneath the general surface of the mould, and which are explained by the Figs. 828 to 831. Thus, 828 represents the finished casting, 829 the model of the same, 830 the ap- pearance of the bottom flask or drag when the pattern is first removed, and 831 the flask and cores when closed ready for pouring; the moulds are inverted, and the same letters of reference refer to similar parts of all these figures. 831. 830. 820. 828. a 3 a d 3 a a The core-print a would deliver from the sand, and leave the cavity at a, Fig. 830, to be afterwards filled by the core shown in Fig. 831, the same as formerly explained at Fig. 811. But the core-print b, Fig. 829, (which has reference to the stud b, Fig. 831,) would tear away the sand above it in with- drawing the pattern therefore the print b should, like d, Fig. 829, extend to the face of the pattern, or the parting line, represented by e, Fig. 831. This being the case, the pattern would leave the space denoted at d, Fig. 830; the core is put down sidewise to the bottom of the recess, and extends entirely across the same the small open space above is made good with the general surface, as shown by the shade lines in Fig. 831, and this filling in, at the same time fixes the core precisely where denoted by the print d, which latter has a mark to show to the moulder where the core is to end. The circular Digitized by Google CASTING AND FOUNDING. 253 hole requires the core-print shown at c, Fig. 829 the cores themselves are made in the core-boxes, 812 and 813, before explained. Fig. 832 represents the model and core-print, from which the finished casting shown at Fig. 832 might be made from a solid pattern in a two-part flask; it would be inverted, and the parting would be made 832. 833. x a a upon the line x. The prints for the four holes a a, would be placed in the top flask, and those for the great apertures or panels d, would be made in a core-box of the express form, and as thick as the pat- tern and core-print measured together. The core would be deposited edgewise into the core-print, and the upper corners of the mould will be made good, as explained in Fig. 831. By the same method, a mortise-wheel, or one with spaces around its edge, as at m m, Fig. 833, to be filled with wooden cogs, might be made with a series of core-prints, as at c, brought up flush with the parting of the mould; if every print were filled with a core such as Fig. 833, made in an appropriate core-box, the matter would be accomplished with great facility and truth. The iron-founder makes frequent use of flasks which divide in three or four parts; this is done in many cases simply to increase the depth of the contained space in which case, when wooden flasks were employed, they admitted of being temporarily fixed together by dogs, or large iron staples, driven a little way into the neighboring flasks, but the modern iron flasks are fixed by cotters. The following examples will show the nature of some other uses to which the flasks with several partings are applied. 835. c 834. 1 1 B 2 2 A ' A casting, such as Fig. 834, which represents the top of a sliding-rest for a lathe, might be moulded in a very deep two-part flask, if the parting were made upon the dotted line a a; but there would be very great risk of tearing down the mould in drawing out the pattern and from the depth, there would be scarcely a po-sibility of repairing it, and the metal would probably be strained. It would be also possible to mould it with the joining upon the line b, provided several cores were employed; but the mode adopted is more convenient than either of these, when the pattern is made in two parts, and the flask in three, as in Fig. 835. A and B are first united and partly filled with sand, the pattern is knocked in as represented, and the whole well rammed, especially in the groove, the parting being made on the line 11, and dusted. C is now put on, filled, and struck off level; a board is put above it, and ABC are all turned over together, A becoming the top. A is now removed, and the sand is cut away to make the second parting on the line 22, after which A is replaced, and the runner-stick is inserted to make the runner r. On removing the pattern, the runner-stick r is first taken out, A, or the top part of the flask, is lifted off, and the white part of the pattern is drawn out; B. or the middle part, is then lifted, and the last or shaded piece of the pattern is drawn out of the mould, which is now put together again, and poured through r; 80 that the top- surface of the pattern, as seen in both views, becomes the face, from being cast downwards, or upon the lowest piece C, of the flask, called the drag. The part c, Fig. 834, might be cast with a chamfer in three different ways; although, in small cast- ings, it is more usual to cast it square and plane it out of the solid. First, the pattern might be moulded square, and the top A, after removal, might be worked to the angle by aid of the trowel and a cham- fered slip of wood, used as a gage; or secondly, by the employment of a core, the print of which is represented by the dotted lines terminating at the angle d, Fig. 834; or thirdly, by having a loose slip on the pattern sliding on the line c, Fig. 834, so as to be drawn off when the top A had been lifted. Digitized by Google 254 CASTING AND FOUNDING. This last method is analogous to that represented in Fig. 836, also intended for a sliding-rest, and which might be cast in a two-part flask, if the two chamfers cc were fitted loosely upon slides, as shown; but a three-part flask is more convenient, as explained by Fig. 837, in which the pattern is inverted. 837. 836. m m 2 2 B 1 1 c m The lowest piece C, or the drag, is parted upon the line 11, but its sand extends upwards between the two sides of the pattern, as shown by the shade lines. The middle piece B is parted through the line 22; and lastly A, the top, is filled up level, the runner-stick at r being inserted at the time; A is first lifted, and all the pattern is then removed, excepting the chamfered bars and their slides, which are represented black this pattern delivers its own cores for the circular mortises m m, the sand form- ing them being a part of that in B, or the middle flask; lastly, B is lifted, and the chamfer-slips are picked off from C. This pattern may consequently be moulded without turning over the flask, and every part of the mould is quite accessible for repair. The pedestal of the swage-block, is another good example of moulding in a three-part flask. The model is made with the upper fillet loose, also with the sides solid, or without the holes, and the object is moulded as it stands. The top part of the flask opens at the upper moulding, and which latter is then removed from the pattern; the middle flask divides at the plinth or flange, so that when this has been lifted, the pattern also may be withdrawn, leaving a square pedestal of sand, as large as the interior of the model, standing upon the bottom part or drag, as in Fig. 837. The panels are made by means of a core-box, of the kind Fig. 814: the box is exactly as thick as the metal to be cast; and the circular cores are then fixed upon the pedestal of sand by means of a few wires or nails, after which the flask is put together: ready for pouring. If the casting here referred to, had four fluted columns at the four angles, either with a large cap to each, or with a square entablature connecting the whole of them, the object might be also cast in one piece, if moulded in a three-part flask. After removing the top flask, the entablature and capitals would be first withdrawn, the columns being divided through their smallest diameters the mould would be then turned over, and upon lifting off the drag, or bottom piece, the remainder of the pattern could be drawn, either in one single piece, or if the pillars were loose, the five parts could be more safely extracted the three-part mould would be put together again, and reversed for pouring. In this general manner, by making either the mould or the pattern, or both, in different pieces, and by the judicious employment of cores and drawbacks, objects apparently the most untractable are cast with very great perfection. The iron-founders are likewise very dexterous in making castings in some respects different from the patterns from which they are moulded thus, if the pattern be too long, or that it be temporarily desired to obliterate some few parts, the mould is made of the full size and stopped-off, additional sand being worked into the mould, by aid of the trowel and some temporary piece of wood, to represent the imagined termination of the pattern. On the other hand, any simple enlargement or addition is not always added to the pattern, but it is frequently cut out of the mould with the trowel, in a similar manner. Many common works, such as plates. gratings, parts of ordinary stoves, and simple objects, are made to written measures, and without pattern3, as a few parallel slips of wood to represent the margin of the casting are arranged for the purpose upon a flat body of sand, which is modelled up almost entirely by hand but for all accurate purposes and for machinery, good and well-made patterns are indispen- sable, and to some particulars of which a little attention will be now devoted. Remarks on Patterns for Iron Castings.-The construction of patterns for iron castings requires not only the observance of all the particulars conveyed, but in addition, the large size of the models, the peculiar methods employed in moulding them, and the nearly inflexible nature of the iron castings when produced, call for some other and important considerations; and which should not be entirely overlooked. even in works of comparatively small size. or it may lead to failure and disappointment. Thus, it becomes necessary to make patterns in some degree larger than the intended iron castings, to allow for their contraction in cooling, which equals from about the ninety-fifth to the ninety-eighth part of their length, or nearly one per cent. This allowance is very easily and correctly managed by the employment of a contraction-ru'e, which is made like a surveyor's rod, but one-eighth of an inch longer in every foot than ordinary standard measure. By the employment of such contraction-rules, every measurement of the pattern is made proportionally larger without any trouble of calculation. When a wood pattern is made, from which an iron pattern is to be cast. the latter being intended to serve as the permanent foundry pattern, as there are two shrinkages to allow for, a double contraction- rule is employed, or one the length of which is one quarter of an inch in excess in every foot. These rules are particularly important in setting out alterations in, or additions to, existing machinery the Digitized by Google CASTING AND FOUNDING. 255 latter is measured with the common rule, and the new patterns are set out, to the same nominal measures, with a single or double contraction-rule as the case may be, the three being made in some re- spects dissimilar to avoid confusion in their use the entire neglect of contraction-rules incurs ad- ditional trouble and uncertainty.* Patterns for iron castings are much more frequently divided into several parts than those for brass; for instance, the division into two equal parts, after the manner of Fig. 823, (but without reference to the under-cutting,) is very common, as both the pattern and flask separate when the top part is lifted, and the halves of the pattern can then be drawn out from the halves of the flask with much less risk of tearing down the sand. Fig. 790, if small, would be moulded as represented, with false cores or drawbacks; but if it were a large fluted column, the iron-founder would employ a solid two-part flask; the shaded parts would together represent the body of sand in the drag, and the pattern would be made in three parts, something like a boot-tree. When the top flask had been lifted, the central slice of the pattern, ex- tending from the two upper to the two lower angles, would be withdrawn vertically, and the two outer pieces would be released sidewise. The general rule is to divide the circumference of the pattern into six equal parts, and to let the central slice equal one of them in width. The figures 835 and 837, representing two parts of a slide-rest, and the pedestal, are some amongst many of the common examples of the division of the patterns; and with which may be asso- ciated the numerous subdivisions of the mould instead of the pattern, by the employment of cores, many applications of which have been also explained. All these matters display much interesting and ingenious contrivance, resorted to either to render possible the operation of moulding, or to facilitate its performance. To lessen the distortion of castings from their unequal contraction in cooling, it is important that the models should be nearly symmetrical. For example, bars or rods of all the sections in Fig. 789 may be expected to remain straight; perhaps g is the most uncertain, but if the lower fins of 6 and h were removed, their flat surfaces then exposed to the sand would become rounding or convex in length, from the contraction of the upper rib being unopposed by that of a similar piece on the under side. Bars and beams, the sections of which resemble the letter I, are of the most favorable kind for general permanence, and also for strength, and large panels may be cut out from their central plates to diminish their weight without materially reducing their stability. They are much used, not only in building, but also in the framing of machinery, which is in a great measure based upon the same general rules. It is also of great importance, especially in castings of large size, that the thickness of the metal should be nearly alike throughout, 80 that it may cool at all parts in about the same time. Should it happen that one part is set or rigid, whilst another is semi-fluid, or in the act of crystallizing, there is great risk of the one part being altogether torn from the other and producing fracture. Or should the disturbing force be insufficient to break the casting, it may strain the metal nearly to its limit of tenacity or elasticity; so that a force far below that which the casting should properly bear may break it in pieces. An example of this is seen in wheels with very light arms and heavy rims or bosses. The arms sometimes cool so quickly as to tear themselves away from the still hot rim or nave or when the arms are solidified without fracture, the contraction of the rim may so compress the spokes endwise as to dish the wheel, (in the manner of an ordinary carriage-wheel,) and thereby strain the casting nearly or quite to the point of fracture. The arms are sometimes curved like the letter s, instead of being straight and radial; the contraction then increases their curvature with less risk of accident than to straight arms.t A more elegant way of avoiding the mischief was invented by Mr. Isaac Dodd, of the Horsley Iron Works, by placing the spokes as tangents to the central boss, in which case the con- traction of the rim makes a small angular change of position in the boss for the rim in thrusting the spokes inwards, causes the boss to twist round a little way with far less risk of fracture. The destructive irregularity of thick and thin works is partly averted by uncovering the thick parts of the casting, or even cooling them still more hastily, by throwing on water from watering-pots. In wheels this has been done by a hose, the axis of which is concentric with the wheel, the arms being all the time surrounded by the sand to retard their cooling; but it is the most judicious in all patterns, to make the substance for the metal as nearly uniform throughout as circumstances will admit, so as not to require these modes of partial treatment, which often compromise the ultimate strength of the casting. Another mode sometimes adopted for avoiding the fracture of wheels, from the great dissimilarity of their proportions, is by inserting wrought-iron arms in the mould, but they do not always unite indly with the iron of the rim and the nave. The same inconvenience occurs when iron pins are in- serted in the ends of either iron or brass castings, to serve for their attachment to their respective places. In iron castings it frequently produces the effect of chill casting, 80 as to render the works difficult to be turned or filed at the junction, and there is risk of the casting becoming blown or un- The contraction of brass is nearly three-sixteenths of an inch in every foot, but from the small size of brass castings the contraction-rule is less required for them, as the differences may be easily allowed for without it. Iron castings weigh about fourteen times as much as the ordinary deal and fir patterns from which they are made, that being nearly the ratio of the specific gravities of those materials. All these matters are entered into in the pam- phiet, A New System of Scales of Equal Parts," and the paper On a Scale of Geometrical Equivalents for Engineer- Ing and other Purposes," Lond. and Edin. Philos. Mag., July, 1838, wherein are described numerous applications of scales of equal parts to the purposes of drawing and calculation, and to the comparison and conversion of all kinds of measures, weights, and other quantities. t It appears to be often desirable to supersede the straight diagonal braces of iron castings by curved lines, which are both more ornamental, and better disposed to yield to compression or extension by a slight alteration in their curvature. 1 Mr. Dodd had to contend with the shrinking of the nave, which was the last to cool the accidents therefore occurred from the tension. instead of the compression of the spokes; this equally fatal effect was completely remedied by placing the arms as tangents.-Trans. Soc. of Arts, vol. li. p. 66. Digitized by Google 256 CASTING AND FOUNDING. sound in either case. When the pins are heated before being placed in the mould, they become nearly cold before the metal can be poured, and they also endanger the presence of a little steam or vapor, which is detrimental; therefore they are more generally put in cold, notwithstanding the sudden check they then give to the fluid metal. The patterns for iron castings of large size are necessarily very expensive, especially those for hol- low cylinders and pans, many of which are 80 large that it would be impossible to find solid pieces of wood from which the patterns could be made; either with sufficient strength for present use, or with the necessary permanence or form for a subsequent period, as they would be almost sure either to break, or to become distorted from the effects of unequal shrinking. Such patterns, therefore, require to be made of a great many thin layers or rings of wood, each consisting of 6, 8, or 12 pieces, like the felloes of wheels, 80 that in all parts the grain may be nearly in the direction of a tangent. As they are glued up, every succeeding layer is connected with the former, by glue and wooden pins or dowels, and the whole is afterwards turned to the tubular or hemispherical form, as the case may be. As the castings are generally required to be rather thin, such models are not only very expensive, but also very liable to accident; and besides, it frequently occurs that only one or two castings of a kind may be required, which makes the proportional cost of the patterns excessive. It fortunately happens, however, that this case, which is one of the most costly and uncertain by the employment of ordinary wood or metal patterns, becomes exceedingly manageable by a peculiar and simple application of the art of turning, (the one great centre of the constructive arts, to which these pages are intended immediately and collaterally to apply;) and by which process, or one branch of loam moulding, to be explained in the following section, patterns are not generally required. Loam Moulding.-Figs. 838, 839, and 840, are intended to illustrate this process as regards a steam cylinder. Fig. 838 is the entire section of the mould in its first stage; Figs. 839 and 840 are the half sections of the second and third stages, preparatory to burying the mould in the pit in which it is to be filled. The inner part of the loam-mould is called the core when small, but the nowel when large; the outer is called the case or the cope. Each part is built upon an iron loam-plate, or a ring cast rough on the face, and with four ears by which it may be lifted. The mould is occasionally erected upon four shal- low pedestals of bricks for the convenience of making a fire beneath it to dry the loam; at other times it is made upon a low truck upon which it may be wheeled into the loam-stove, which is heated to about the temperature of 300 to 400 degrees Fahrenheit. A vertical axis a, is mounted in any convenient manner, frequently in two holes in the truck itself, or as shown in Fig. 838, in a pedestal or socket erected upon the truck; at other times the axis is mounted in a hole in the loam-plate, and in any bearing attached either to the building, or its roof. 840. 839. 838. a 8 c a o c b The first step is to fix upon the spindle the templet b b, at the distance of the radius of the cylinder, either by one or two clutches, with various binding screws. An inner cylinder of brickwork is then built up, plastered by the hands with soft loam, (which is represented black in all the figures,) and scraped into the cylindrical form by the radius board, which is moved round on its axis by a boy. When the surface is smooth and fair it is thoroughly dried, after which it is brushed over with black- wash, and again dried. The charcoal-dust in the blackwash serves as a parting, to prevent the sue- ceeding portions of the loam-mould from adhering to the first. The templet c c, Fig. 839, cut exactly to the external form of the cylinder, is now attached to the axis at the distance from the core required for the thickness of the metal some additional loam is thrown on to form the thickness, which is smoothed in the same careful manner as the centre, after which the templet and spindle are dismounted, and the thickness, which is represented white in Figs. 839 and 840, is also dried and blackwashed. The ring for the outer case or cope is now laid down, and its position is denoted either by fixed studs or by marks; and the outer case represented in Fig. 840, is built up of bricks and loam, with an inner facing of loam worked very accurately to the turned thickness. The new work or the cope is also thoroughly dried, and afterwards lifted off very carefully by means of the crane and a cross-beam with four chains. This process likewise drags off the thickness, which usually breaks in the removal; its Digitized by Google CASTING AND FOUNDING. 257 remains are carefully picked out of the cope, both parts of the mould are repaired, and again black- washed and dried. When the cylinder requires ports at the ends, or the short tubes with flanges for attaching the steam passages, models of the tubes are worked into the cope, and are afterwards withdrawn; the cores are made in core-boxes, and are partly supported by the outer extremity, and partly upon grains, or two little plates of sheet-iron connected by a central wire, the whole being equal to the thickness of the metal at the part. When steam passages are wanted, either along the side, or around the cylinder they are worked up in clay upon the thickness, and duly covered in by the cope; their cores are sup- ported, partly by their loose ends, and partly by grains, which become entirely surrounded by, and fixed in the metal, when it is poured.* The mould is now put together in a pit sunk in the floor of the foundry, and the two iron plates are screwed together; the surrounding space being rammed hard to prevent the mould from bursting open, but the inner part is left much more loose for the escape of the air. The top edges of the mould are covered over with a loam-cake, (which has been previously made and dried,) or a ring three or four inches thick, strengthened with iron bars amidst the clay, the joining being made air-tight by a little cow's hair, and by the pressure of a quantity of iron weights; the loam-cake is generally perforated with many holes, as shown at d, for the entry of the metal and the escape of the air. But provision must always be made in casting thin cylinders, boxes, and such like forms, for the breaking up of the core as soon as the metal is set, to prevent the metal scoring or rending from its contraction upon a rigid, unyielding centre.4 Large pans, and various other circular works, are moulded precisely in the same way as cylinders, except that curved templets are used, and that towards the conclusion, the apertures through which the spindle passed are filled in and worked by hand to the general surface. Water-pipes are made much in the same mode, but the cores for these are turned upon an iron tube pierced full of holes, which is laid horizontally across two iron trestles with notches, and is kept in rota- tion by a winch-handle at the end; there is also a shaper-board or scraper fixed parallel with the axis: this primitive apparatus is called a founder's lathe. The perforated tube (serving as the mandrel) is first wound round with haybands, then covered with loam, and the core is turned, dried, and blackwashed; the thickness is now laid on and also black- washed, after which the object is moulded in sand. The thickness is next removed from the core, which latter is inserted in the mould, and supported therein by the two prints at the extremities, and by grains with long wires, the positions of which may be seen by the little bosses on the pipe, the metal being there made purposely thicker to avoid any accidental leakage at those parts. When pipes are cast in large quantities, they are moulded from wooden patterns in halves, so that it only becomes necessary to turn the core; and this, when made in the above manner, is sufficiently porous for the escape of the air. The moulds for crooked pipes and branches are frequently made in halves, upon a flat iron plate. An iron bar or templet of the curve required is fixed down, and a semicircular piece of wood, called a strickle, is used for working and smoothing the half core; next a larger strickle is used for laying on the thickness, the two halves are then fixed together by wires, and moulded from in the sand-flask; the thickness is now stripped off the core, which is fixed in the mould by its extremities, and if needful, is supported also upon grains. By the employment of these means, although the loam-work requires time for the drying, yet with ordinary care an equality of thickness may be maintained, notwithstanding the complexity of the out- line, and without the necessity for wooden patterns. Very many of the large works in brass are also moulded in loam, the management being in most respects exactly the same as for iron, except that in some ornamental works wax is more or less em- ployed, and is melted out of the moulds before the entry of the metal; a very slight view of the methods will serve as a sequel to the subject of brass-founding. Large bells are turned in almost the same manner as iron cylinders or pans, by means of wooden templets, edged with metal, and shaped to the inner and outer contour of the core and thickness. The inscription and ornaments are either impressed within the cope, the clay of which is partially softened for the purpose, or the ornaments are moulded in wax, and fixed on the clay thickness before making the cope. Less generally the whole exterior face of the bell, or indeed its entire substance, is modelled in wax, and melted out before pouring. In any case, the concluding steps in filling up the apertures where the spindle passed, are to attach a dissected wooden pattern of the central stem and of the six cannons or ears by which the bell is slung, which parts are moulded in soft loam; and then, the parts There is always some uncertainty of the sound union of the grains, or other pieces of iron, with the cast-metal. Some cast them in iron and file them quite bright; others also tin them, apparently to preserve them from rust, as the tin must be instantly dissipated by the hot metal. Grains should always present clean metallic surfaces, and when used for very thin castings, to prevent them from dropping out, the wires are nicked with a file that they may be keyed in the metal. It is, however, better to avoid the use of grains, which may be generally done by giving the core sand bearings, and after- wards plugging up the holes in the casting. + The largest cylinders, such as those of the Cornish pumping-engines, of 80, 90, and 95 inches bore, and 12 or 14 feet in length, and the blowing cylinders of blast furnaces, sometimes 105 inches bore, are made without the employment of the thickness. The case or cope is built up in the pit, and turned inside, with a radius bar, and the core is erected on a plate on the floor, and turned outside to a gage; when dried, it is lowered into the other by the crane. The cylinders are cast one foot or upwards longer than required, to serve as a head of metal and make the top edge sound, and thus much is cut off before they are bored. To enable the mould to resist the great pressure of the lofty column of fluid metal. (equal at the base to near 60 pounds on every square inch,) the core is strengthened by diametrical iron bars entering slightly into the brickwork: the outer cylinder is surrounded at a small distance by iron rings piled one on the other, the Interval being rammed with sand; and stays are placed in all directions from the rings to the sides of the pit. which is either lined with brickwork, or when liable to be inundated with water, it is made of Iron like a water-tight caisson. Small cylinders are moulded in sand from wooden models, and only the cores are turned in loam; for cylinders of the smallest size the cores are made of sand in core-boxes, as already explained. 33 Digitized by Google 258 CASTING AND FOUNDING. having been dried and replaced, and the iron ring for the clapper inserted, the whole is ready for the pouring-pit. The heaviest bells are moulded within the pit the same as huge cylinders. Brass guns are also moulded in loam, and in a somewhat peculiar manner; a taper rod of wood, much longer than the gun, is wound round with a peculiar kind of soft rope, upon which the loam is put for making the rough casting-model of the gun, which is turned to a templet; the work is executed over a long fire, to dry it as it proceeds, and the model is made about one-third longer than the gun itself. The model, when dried and blackwashed all over, is covered with a shell of loam, not less than three inches thick, secured by iron bands; the shell is also carefully dried; after this the taper bar is cau- tiously driven out from its small end, the coil of rope is pulled out, and so likewise is every piece of the clay model of the gun. The parts for the cascable and trunnions, which should have been worked separately upon appropri- ate wooden models, are then attached to the shell. Should the gun have dolphins, or any other orna- mental figures, they are modelled in wax and fixed on the clay model before the shell is formed, and are then melted out to make the required space for the metal. When all is ready and dried, six, eight, or more of these loam cases, or shells, are sunk perpendicu- larly in a pit at the mouth of the reverberatory furnace, and the earth is carefully rammed around them; at the same time a vertical runner is made to every mould, to enter either at the bottom or not higher than the trunnion: the upper ends of the runners terminate in the bottom of a long trough or gutter, at the far end of which is a square hole, to receive the excess of metal. In casting brass guns, tapping the furnace is rather a ceremony, and certainly an imposing sight: the middle and the end of the trough are each stopped by a shovel or gate held across the same; and the runners are all stopped by long iron rods, held by as many men. When all is pronounced to be ready, the stopper of the furnace is driven inwards with a long heavy bar swung horizontally by two or three men, and the metal quickly fills the trough; on the word of command, number one, draw," the metal flows into the first mould, and fills it quickly but quietly from the bottom; the mould being open at the top, no air can be accidentally enclosed. Numbers two, three, and four are successively ordered to draw. The first shovel is then removed from the great channel, and now the guns, five to eight or ten, as the case may be, are similarly poured and filled to the level of the trough; after which the last shovel is withdrawn, and the residue of the metal is allowed to run into the square bed or pit prepared for it. The flow of metal from the furnace is regulated by the tapping-bar, the end of which is taper, and is thrust more or less into the mouth of the furnace as required; the trough and runners are thus kept exactly full, which is an important point in most cases of pouring, as it prevents a current of air being carried down along with the metal. Large bells are poured much in the same manner, except that the runners are at the top, and the metal runs from the great channel, through smaller gutters, to every sunk mould, the stoppers for which are successively drawn. For quantities of brass intermediate between the charge of an ordinary crucible, and such as require the reverberatory furnace, the large ladles or shanks of the iron-founder are used; the contents of four or six crucibles being poured into the shank as quickly as possible, and thence in one stream into the mould. The author of the article Founding, in the Encyclopedia Metropolitana, minutely describes three ways of casting large hollow statues, which are briefly as follows: First; a rough model of the figure is made in clay, but somewhat smaller than its intended size; it is covered over with wax, which is modelled to the required form, or the wax is worked up in separate pieces and afterwards attached various rods or cylinders of wax to make the apertures for the runners and air-holes, are fixed about the figure and led upwards. The whole is now surrounded with a coating of loam and similar materials, the inner portion of which is ground very fine and laid on with a brush, like paint; and the outer part is secured with iron bands. When all has been partially dried, a fire is lighted beneath the grating on which the figure is built, to cause the wax to run out through one or more apertures at the base, which are afterwards stopped, and all is thoroughly dried and secured in the pit, after which the charge of the furnace is let into the cavity left by the wax. Secondly ; the finished figure is modelled in clay, and stuck full of brass pins just flush with its sur- face, which surface is now scraped away as much as the thickness required in the metal; the reduced figure is now covered with wax mixed with pitch or rosin, which is worked to the original size with all the exactness possible. The other stages are the same as in the foregoing; the metal studs or pins prevent the mould and core from falling together, and they afterwards melt, becoming a part of the metal constituting the figure. Thirdly the finished figure is modelled in plaster, and a piece-mould is made around it, the blocks of which consist internally of a layer of sand and loam, 11 inch thick, and externally of plaster one foot thick. The mould when completed is taken to pieces, dried, and rebuilt in the casting pit; it is now poured full of a composition suitable for the core, the mould is again taken to pieces, the core is dried and scraped to leave room for the metal, and all is then put together for the last time, secured in the pit, and the statue is cast. The first plan is the most wasteful of metal; the third, the least so, although it is the most costly when the time occupied is also taken into account; but it has the advantage of saving the original work of the artist. Melting and Pouring Iron.-Iron is usually melted in a blast-furnace, or, as it is more commonly called, a cupola; although the cupola or dome leading to the chimney, from which it would appear to have derived its name, is frequently omitted, the two or three furnaces being often built side by side in the open foundry. At the basement there is a pedestal of brickwork about 20 to 30 inches high, upon which stands a cast-iron cylinder from 30 to 40 inches diameter, and 5 to 8 feet high; this is lined with road-drift, which contracts its internal diameter to 18 or 24 inches. The furnace is open at the top for the escape of the flame and gases, and for the admission of the charge, consisting of pig-iron, waste or old metal, coke and Digitized by Google CASTING AND FOUNDING. 259 lime, in due proportion. The lime acts as a flux, and much assists the fusion; chalk is considered to answer the best, but oyster shells are very commonly used where they are abundant. At the back of the furnace there are three or four holes one above the other for the blast, which is urged by bellows or by a revolving fan. No crucible is used, and as the fluid metal collects at the bottom of the furnace, the blast-pipe is successively removed to a higher hole, and the lower blast-hole is stopped with sand, which partly fuses and secures the blast-hole very effectually. The front aperture of the furnace through which the metal is allowed to flow into the ladles or trough, is usually made sufficiently large for the purpose of clearing or raking out rapidly the fuel and slag, as the process is most laborious, owing to the excessive heat. This aperture is closed by a guard- plate, fixed on by staples attached to the iron-case of the furnace, in the centre of which plate the tapping-hole is made: during the time the metal is fusing, the tap-hole is closed by sand well rammed in, and this if well done is never found to fail. Many iron furnaces are made octangular, and in separate parts bound together by hoops, 80 that in the event of the charge becoming accidentally solidified in the cupola, the latter may be taken to pieces for its removal, and thus avoid the necessity of destroying the furnace. There is frequently a light framing or grating above the furnace, upon which the small cores are placed that require to be dried. In some foundries the cupolas are built just outside the moulding shop, beneath one or more chimneys or shafts, which carry off the fumes; in such cases the fronts of the furnaces are accessible through an aperture in the foundry wall, with which they are nearly flush; when the furnaces are lofty there is a feeding stage at the back, from which the charge is thrown in. For heavy iron castings, which sometimes amount to thirty tons and upwards in one piece, rever- beratory or air furnaces are also commonly used; the ordinary charge for these is four to six tons of iron, and five or six furnaces are commonly built close together, 80 that they may be simultaneously tapped in the production of such enormous works.* For melting iron in the small way, good air-furnaces may be used, and also some of the blacklead furnaces, which are blown with bellows, but this is one of the processes that is not successful upon a limited scale. Considerable judgment is required in proportioning the charge for the iron furnace, which always consists of at least two, and often of half-a-dozen kinds of new pig-iron mixed together, and to which new iron, a small proportion of old cast-iron is usually added. The kinds and quantities used are greatly influenced by local and other circumstances, so that nothing can be said beyond a few general remarks. When the principal object is to obtain sound castings with a very smooth face, as for ornamental works not afterwards wrought, the soft kinds of iron containing most carbon, which are most fusible and flow easily, are principally used. But such metal would neither possess sufficient hardness, durability, nor strength, for many of the castings employed in the construction of edifices and machinery. If the cupola contained a little bard pig-iron, but were in great measure filled with old cast-iron, which had been repeatedly melted, and had become successively harder from the loss of carbon at every fusion, such castings would be brittle, and sometimes so hard as scarcely to admit of being cut; these would be equally unfit for the generality of machinery from the opposite causes. But the same mixture of iron will be found to differ very much according to the size of the objects in which it is cast; iron, which in a plate one-fourth of an inch thick, may be quite brittle and hard, will mostly be of good, soft, and useful quality, in a stout bar or plate of two or three inches thick. Thick castings are necessarily slow in cooling, and are seldom very hard. unless intentionally made SO. Between the extremes, (say three parts of pig-iron to one of old, or three parts of old iron to one of pig-iron.) various qualities may be selected; in castings for machinery the general aim is to obtain a strong, sound, and tough iron; mixtures of this nature which are used for iron ordnance, are called gun- metal amongst the gun-founders. The fireman, or the individual having the management of the furnace, therefore always employs the scales in mingling the different kinds of iron, according to the magnitude and character of the works to be cast; and until the sorts in use are familiarly known, it is partly a matter of trial, and requires the same attention as the making of alloys properly so considered.+ A few of the modern cupolas greatly exceed the air-furnaces in effect, as they are calculated to contain upwards of twelve tons of melted iron. One of these, at the works of Messrs. Nasmyths, near Manchester, is six feet two inches diameter externally, and lined with Stourbridge bricks. It has three sheet-iron tuyeres, nine inches diameter at the mouth, the blasts from which enter the furnace at three points of the circle, and they may be slid like telescope-tubes to either of the four series of holes, as the furnace becomes gradually filled. There are three other furnaces progressively smaller, arranged beside the first; all of which may be used separately or in combination, according to circumstances. The blast, which is under corresponding control, is obtained from two revolving fans, five feet diameter, making above 1000 revolutions per minute. Messrs. Acramans, of Bristol, have likewise enormous cupola power; they have a series of four cupolas, in which collectively from forty to forty-five tons of iron may be melted at one time. In some cupolas the top is contracted by a cone made of iron plate; in Yates's patent, a brick trunk is built upon the cupola, with narrow arches crussing the trunk at right angles: this economizes the heat by causing the flame and gaseous matters to be retarded, from pursuing a serpentine course in their escape. + When the management of cast-iron was less efficiently understood, it was occasionally alloyed with five or six per cent. of shreds of copper, thrown into the Indle full of iron to produce a close, sound, strong metal, suitable to three-throw cranks for pumping machinery. and other purposes. It is said that ten per cent. of copper renders cast-iron malleable, and that alloyed with copper or tin it is less disposed to rust: all these alloys may be now viewed as matters of experiment alone. It is much to be regretted that no protection has yet been found to prevent the conversion of cast-iron into plumbago, or the carburet of iron, from long immersion in sea-water, or the water of copper-mines, sewers, and other places. This, which is a most serious inconvenience in dock-works, sea-walls, and mines, arises, says Dr. Faraday, from the circumstance that the protoxide of iron, formed beneath salt-water, is soluble, and becomes washed away, thus robbing the original mass of its iron; whereas the peroxide, or ordinary rust formed by exposure to the air, is insoluble, and serves partly as a Digitized by Google 260 CASTING AND FOUNDING. When enough iron is melted, (the common charge being two and a half to four cwt., but sometimes above twelve tons,) the cupola is tapped in front, at a hole close to the bottom, which allows the whole contents to run out, either into ladles, or, in very large works, into channels leading directly to the moulds.* In pouring iron, the means of conveying the melted metal to the flasks, differ with the quantity. One man will carry from fifty to seventy pounds in a hand-ladle; three to five men will carry from two to four cwt. in a double hand-ladle, or a shank; larger quantities, amounting sometimes from three to six tons, are carried in the crane-ladle. These all possess one feature in common, namely, their handles or pivots are placed but slightly above the centre of gravity of the ladles; they may therefore be tilted very readily, as their fluid contents, in obeying the law of gravitation, are almost neutral in the operation of tilting, which they scarcely assist or retard, unless by mismanagement the ladle is over-filled, and thus rendered top-heavy. All these ladles are coated with a thin layer of loam, and every time before use, they are brushed over with blackwash, and carefully dried. The hand-ladle has a handle three or four feet long, with a crutch or cross-piece at the end, which is mostly held in the left hand frequently the contents of half a dozen or more hand-ladles are poured simultaneously into the same flask. The shank has a single handle on the one side, and one made in two branches at the other, and together they measure six to eight feet in length; the tilting is completely under the command of the one or two men at the double handle. The crane-ladle is carried from the furnace to 'the mould by the swinging and traversing motions of the crane, which is similar to those used at the iron-forges, &c., and in very large foundries, the plan of the building is divided into imaginary squares with a crane in the centre of every square, 80 that the ladle is walked from one to the other, even to the far end of the shop, with great facility and expedition. The bail, or handle of the crane-ladle, is fixed in its perpendicular position by the guard, a simple bolt which prevents the ladle from being overset by accident until it has reached its destination. Two long handles, terminating in forked branches, are now fitted by their square sockets upon the swivels or pivots of the crane-ladle, and secured by transverse keys, after which the guard is withdrawn; and then two men at the ladle, two others at the crane, and one to skim the dross from the lip of the ladle, commonly suffice to manage two or three tons and upwards of fluid iron, with great ease and dexterity. The observations offered on page 250, respecting the temperature of the metal suitable to different brass works, might be here in a great measure repeated namely, that the smallest castings require very hot metal, and a gradually lower temperature is more suitable to works progressively heavier, to avoid their becoming sand-burned or rough on the face, from the partial destruction of the mould. When cast-iron is very hot, the metal scintillates most beautifully. far more vividly than a mass of wrought-iron raised above the welding heat; as the metal cools, the sparks become intermittent, and at last the metal remains entirely quiet, excepting a multitude of lines vibrating in all directions, as if the surface were covered with thousands of wire-worms in great activity; this effect lessens until the metal solidifies. The softest iron shows most of this play of lines, or is said to break the best. Iron castings are generally much heavier than those of brass, and the melting heat of the metal being considerably higher, the quantity of gas generated is very much greater; additional care is consequently required to provide for its escape, or the explosions are much more violent. The sand is punctured at many places with a fine wire, before the removal of the patterns; sometimes also more coarsely as soon as the metal has become solidified. The gases issuing from the filled moulds are often lighted, either by the red-hot skimmer, or by a torch of straw with which the moulds are flogged this lessens the accumulation of gas and the consequent risk of accident. The pouring of very large objects in open moulds, such as plates, beams, and girders, is a very beautiful and grand sight. The metal is led from the furnace, through a gutter lined with sand, into a large trough or sow, the end of which is closed with a shuttle; when the SOW is full, the shuttle is raised; this allows the metal to flow very quickly into the mould, but enables it to be kept back should it be unnecessarily hot; the castings made in open moulds are generally covered up with sand as soon as the metal is set. The above, an ' the casting of smaller objects, such as flat plates in open moulds, may appear amongst the most certain modes of procuring sound castings; but unless the air be well drawn from the lower surfaces, they will become honey-combed or full of air-bubbles. This defect is avoided by making the sand-bed sufficiently porous, and pricking it with many holes just below the surface, to serve as horizontal air-drains. defence to the metal beneath. When first raised from the sea-water, the plumbago becomes exceedingly hot from the action of the atmosphere; it may be cut with a knife like an ordinary pencll.-Minutes of Conversation, Inst. Civ. Engineers, 8th Feb. 1842. . The furnace is not unfrequently tapped whilst the charge of metal is being melted, and in such cases when the required quantity has been removed into the ladles, the fireman restops the tap-hole by a conical plug of clay on the ond of a wooden bar; the process is called botting, and requires a dexterous hand, or the whole contents of the furnace may escape. t Mr. Nasmyth has added to the pivot of the large crane-handle, a tangent-screw and worm-wheel, by which it may be gradually tilted by one man standing directly in front at any convenient distance; and another man skims the metal by a kind of throttle-valve coated with clay, which sweeps into the lip of the ladle, and keeps back the sullage: the axis of the skimmer is continued as a long rod, at right angles to the first, and also terminating in a cruss. By these arrangements any precise quantity of metal can be delivered, and the risk of accident scarcely exists. # In casting lead, tin, &c. on a flat metallic plate, the formation of air-bubbles is lessened by placing a sheet of dry paper on the plate; it appears to keep down any little bubbles of air or vapor, and to provide a thin channel for their escape. But the most perfect example of a porous mould is that invented by Lord Rosse, to avoid the formation of air- bubbles in those speculums which are cast in open moulds. The plate, or bed of the mould, consists of a great number of slips of hoop-iron placed edgewise and in contact; they are screwed tight within a frame, and are then turned in a Digitized by Google CASTING AND FOUNDING. 261 A far greater number of works are cast in close moulds, and in the horizontal position; the propor- tionate quantity of metal is carried to them in ladles: skimmers are held to the lips of the moulds at the time of pouring, to keep back all the sullage or dross. The number, position, and height of the runners, are determined by circumstances generally not less than two apertures are provided, the first for the entry of the metal, the second for the escape of the air, and to allow the metal to flow through the mould and carry off the sullage. Sometimes in heavy castings, in addition to the runners, one or more large heads or feeds are made at the upper part, to supply fluid iron as the metal shrinks in the act of solidifying; and in some such cases the feed is pumped, by moving an iron rod up and down in the feed to keep the metal in motion, so that for a time the metal may freely enter and the air escape, to increase the general soundness of the mass. The pumping should, however, be discontinued the moment the metal begins to stiffen and clog the iron rod, or in other words to crystallize, otherwise mischief instead of benefit will accrue. Works which are required to be particularly sound, as some cylinders, pipes, shafts, and plungers, are cast vertically; the moulds are sunk in the earth, and well rammed to enable them to withstand the great pressure of the fluid column, without becoming strained or bursting open. Such objects are moulded and poured with a head, or an additional portion about one-third the length of the finished casting, as mentioned in respect to brass guns. In pouring cylinders of tolerably large size, the metal is conducted from the sow through two sunk passages with side branches, entering the mould in the direction of tangents about one-third from the bottom; these keep the metal in circulation, and assist the rise of the sullage. Cylinders are also poured through holes in the loam-cake, other apertures being always provided in it for the escape of the air. Beneath the iron plate upon which the mould is built, is placed a central mass of haybands, in order that the air may have free passage to collect, and then to escape upwards to the surface of the earth, through one, two, three, or more internal or external tubes, as the case may be. The thick cylinders for hydrostatic presses are closed at one end, and those cast with the mouth downwards require an air-tube bent at each end, to lead from the core beneath the casting to the surface of the earth; the gas drives out in a stream, and is immediately ignited like a great torch: others prefer casting them with the mouth upwards, in order that less risk may exist of locking up air within the casting. For the very heaviest works, the three or four furnaces are usually tapped at the same moment; the stream from every one is conducted through a sand-trough, and they all unite in one great trunk leading to the mould. In pouring some of the largest cylinders, the trough is led entirely round the top of the loam-mould; and from the circular channel, sometimes as many as thirty runners, every one of which is stopped by a shovel held by a man or a boy, descend to the mould, and as many air-holes are made between the ingates. When the foreman that all the furnaces are in full run, and that the channels are well supplied, he gives the word, up shovels;" they rise at the instant, and allow the molten stream to deposite itself in its temporary resting-place. At the time the cylinder is poured, all the precautions explained in the note, p. 257, are necessary to give the mould sufficient strength to resist the pressure of the fluid metal; but as soon as it becomes set, the conditions are altered, and this resistance must be removed from the inner surface, that the cylinder may shrink, in cooling, without restraint or fracture. Accordingly, after three or four hours' time, all the diametrical iron stays are knocked away by a vertical weight or monkey, and men descend by iron ladders into the cylinder, to break down the brick core. The heat is 80 terrific, that they can only endure it for a minute or 80 at a time, but still the precaution is imperative: and even in com- paratively small castings of hollow objects, such as cylinders, pans, and boxes, it is desirable to break down the cores, to prevent the castings from scoring or breaking. Although some iron castings employed for bridges, girders, and even for machinery, require the enormous quantities of iron referred to, on the other hand this useful metal is employed for exceedingly light and beautiful castings, abundant examples of which may be seen in the Berlin ornaments and chains.* The links of most of the Berlin chains are connected with wrought-iron wire, but Figs. 841, 842, represent a chain made entirely by the process of casting. lathe to the required curve by this arrangement interstices exist at nearly every point through which the air may escape downwards. Speculum metal is perhaps the most untractable of any of the alloys, and it serves to illustrate in a most striking manner many of the effects that occur in castings generally. Small speculums are cast in sand; as soon as they are set. the sand- core is pushed out of the aperture, in such as are intended for Gregorian telescopes, to enable them to contract without fracture, and the red-hot disk is surrounded by ignited wood-ashes or any very bad conductor, to delay the cooling. These precautions entirely fail with large speculums, as their margins solidify the first, and from the absence of ductility, the central parts tear away in the act of contraction, and the mass becomes rent or flawed. Lord Rosse considered this fracture would be avoided by cooling the speculums in uniform layers from below upwards, or as it were in infinitely thin laminse, and he therefore first employed iron moulds which were cooled by a stream of water projected against their under surfaces this partially answered with small speculums, but with those of 18 inches diameter it almost always failed, as the mould cracked before the metal was congealed. A general source of failure was the non-escape of air; this caused the lower surface to be full of air-bubbles, which it was tedious to grind out. The plan ultimately adopted was the porous hoop-iron mould, with a marginal ring of sand; the mould was heated to about 2120 F.; it was filled very quickly, and the moment the metal was solidified, it was drawn into an annealing oven previously heated to about the same temperature as the casting; so that for small reflectors of nine inches diameter, the cooling might be extended over about three days, and for large ones of thirty-six inches diameter, over about fourteen days with these precautions the process was uniformly successful.-See Trans. Royal Soc., 1840, pp. 510, 11. The whole of the paper On the Reflecting Telescope," pp. 503 to 527, is quite a study for those interested in the construction of telescopes, and possesses nearly the same interest for the general mechanist. * We have seen some of these gems of art in the condition in which they left the moulder's hands, and also a portion of the and employed: notwithstanding the minute size of the castings, some of them are quite hollow, as if stamped out of thin steel metal. Professor Ehrenberg says, that the iron employed for them is made from a bog-iron ore, and that the sand is a kind of tripoli, also containing iron: both are entirely constituted of various kinds of animalcules, several of which are found, Digitized by Google 262 CENTRE OF GRAVITY. Its length is 4 feet 10 inches, it consists of about 180 links, and weighs 11 OZ. avoirdupois. It was thus made: the larger links a a were first cast separately; a solid model of the chain about eight inches long, with core prints, as in Fig. 842, was then moulded; the links a, previously smoked to prevent the 842. b b 841. c a c a z adhesion of the metal, were first laid in the mould, and afterwards the sand-cores bb, and a separate runner was made to every one of the small links c c, 80 as to unite the whole when poured. CENTRES, main strength of, to find the distance from main centre to centre of cylinder, when length of beam is given; to find length of beam when distance between main centre and centre of cylinder is given: how to find centres in erecting Engines. See DIMENSIONS OF ENGINES; and DETAILS OF EN- GINES; VARIETIES OF PARTS OF STEAM-ENGINES. CENTRE OF CUTTING. See Locks OF CANALS. CENTRE OF GRAVITY. The weights of the parts of a heavy body form a system of parallel forces, whose resultant is the weight of the whole, and whose centre may be determined from the formulse. This middle point of a body or system of bodies is called the centre of gravity, and also the centre of the mass of the body or system of bodies. If a body be turned about its centre of gravity, this point does not cease to be the central point of gravity; for if the three planes, to which the points of application of the separate weights are referred, revolve at the same time with the body, the position of the directions of force to these planes alone changes by this revolution; the dis- tances of the points of application from these planes remain invariable. The centre of gravity is, therefore, that point of a body in which its weight acts vertically downwards, and which must, therefore, be supported and fixed, in order that in every position the body may remain at rest. Every vertical straight line in which this point lies is called the line of gravity; and every plane passing through the centre of gravity, a plane of gravity. The centre of gravity is determined by the intersection of two lines of gravity, or that of a line of gravity and a plane of gravity, or by the inter- section of the planes of gravity. Since the point of application may be displaced at will in the direction of force, without changing the action of the force, so a body is in any position in equilibrium if a point in the vertical line passing through the centre of 80° gravity is fixed. 843, If a body M, Fig. 843, be suspended by a thread C A, in its prolongation A B we have a line of gravity; and if it be similarly suspended by a second line, we get a second line A of gravity DE. The intersection S of both lines is the cen- tre of gravity of the body. If the body be suspended upon D an axis, or be brought upon a sharp edge (knife-edge) into a state of equilibrium, we shall obtain in the vertical plane A passing through the axis, or through the knife-edge, a plane of gravity, &c. Experimental determinations of the centre B M of gravity, as just pointed out, are rarely applicable; we have generally to make use of geometrical rules, which will El B presently be given for the determination of this point with accuracy. In many bodies-for example, in rings-the centre of gravity falls without the mass of the body. If such a body is to be fixed in its centre of gravity, it is necessary to connect a second body with the first, in such a manner that the centres of gravity of both may coincide. Determination of the Centre of Gravity.-If x₁, x₂, x₈, Y, Y2, Yrs 21, 2₂, 23, &c., be the distances of the parts of a heavy body from the three planes xz, yx, xy, and the weights of these parts be Pₗ P₂ P₂ &c we then have the distances of the centre of gravity from these three planes, P,x,+P,x,+ Px,+ x P₁+P₁+P,+ y P,+P,+P,+ P,z,+P,z,+P,x,+ z P₁+P₁+P,+ both in the fossil and recent states, in the neighborhood of Berlin. Vide Paper read by Prof. Ehreuberg, at the Royal Academy of Sciences, Borlin, July 7, 1836; and also Scientific Memoirs, Vol. 1,, part 3. (Wilkinson's Engines of War, p. 219.) Digitized by Google CENTRE OF GRAVITY. 263 If the volumes of these parts be V₁, V2 Vₙ &c., and their densities y₁, y₂ Y₂, &c, we may put, there fore, x = V₁γ₁x₁ If the body be homogeneous, i. e. all parts of the same density γ, then: x = or since the common factor γ above and below is cancelled: 1. x = V₁ + 2. y V₁ 3. z = V1 V2 We may also, instead of the weights, substitute the volumes of the separate parts, and thereby make the determination of the centre of gravity a problem of pure geometry. When bodies are a little extended in one or in two dimensions, as thin plates, fine wires, &c., they may be regarded as surfaces or lines, and their centres of gravity likewise determined with the help of the three last formula, if for the volumes V1, V₂, the arms or lengths be substituted. In regular figures the centre of gravity coincides with the centre of figure, as in dice, cubes, spheres, equilateral triangles, circles, dc. Symmetric figures have their centre of gravity in the plane or axis of symmetry. The plane of symmetry A BCD, divides a body A DFE, D Fig. 844, into two congruent halves; the portions on both sides of this plane 844. are equal; the moments also on the one side are equal to those on the other, and, consequently, the centre of gravity falls within this plane. Be- A cause the axis of symmetry EF, cuts the plane surface A BCD, Fig. 845, into two congruent parts, here the portions on the one side are equal to those on the other; the moments, also, on both sides, are equal, and the centre of gravity of the whole lies in this line. Lastly, the axis of sym- metry KL, of a body ABGH, Fig. 846, is its line of gravity, because it arises from the intersection of two planes of symmetry, A BCD, and E FGH. For this reason, the centre of gravity of a cylinder, of a cone, and C of a surface of revolution, or of a rotating body formed on the potter's wheel, lies in the axis of these bodies. E B F 846. D H K 847 C M 845 G P D E C Q S R D E A B A L B A F B F X X F N C Centre of Gravity of Lines.-The centre of gravity of a straight line lies in its middle. The centre of gravity of a circular arc A B = b, Fig. 847, lies in the diameter C M, and passes through the middle M of the arc, for this diameter is the axis of symmetry of this arc. But in order to find the distance CS=x of the centre of gravity S from the middle point, or centre of the circle, the arc must be divided into many elementary parts, and statical moments of these, with reference to an axis XX, passing through the centre C, and parallel to the chord AB=8, be determined. If be a part of the arc, and PN be its distance from XX, then the statical moment of this portion of the aru=PQ.PN. If now the radius PC=MC=r be drawn, and QR parallel to AB, we obtain the two similar 4" PQR and CPN, for which: PQ:QR=CP:PN, from which the statical moment of the elementary arc PQ.PN=QR.CP=QR. is determined. Now, for the statical moments of all the remaining arcs, the radius r is a common factor, and the sum of all the projections QR of the elementary arcs is equal to the chord corresponding to the pro- jection of the whole arc; it follows, therefore, that the moment of the whole arc is also = the chord (s) times the radius r. If this moment be put equal to the arc (b) times the distance x, and therefore bx we then obtain: Digitized by Google 264 CENTRE OF GRAVITY. So that the distance of the centre of gravity, from the middle point is to the radius, in the ratio of the arc to the chord. If the angle at the centre A BC of the are b be=ß°, the are corresponding to the diameter 1 is ß = 180° ß° W. We have then b=ßr, and s=2 r sin. 2/2 whence it follows, that x = 2 sin. B For the semicircle ß=- and sin. therefore, = 0.6366 nearly. To find the centre of gravity of a polygon, or a connection of lines Y BCD, Fig. 848, we must seek the distances of the middle points 848. H, K, M, of the lines = L₁, = La, = LA, &c, from two D axes OX and O Y, viz. y1, H, K, M M C x2, &c.; the distances of the centre of gravity sought from these axes K 2 K are then: B S 2 S , H 8 H A 0 M1 SIKI H: X For example, the distance of the centre of gravity S of a wire bent into the form of a A ABC, Fig. 849, from the base is: NS=x fah+flh a+b 2' h a+b+c a+b+c if the sides opposite to the angles A, B, C be designated by a, b, c, and the height CG by h. If the middle points H, K, M, of the sides of the triangle be connected with each other, and in the triangle 80 ob- 848 tained a circle be described, its centre will coincide with the C centre of gravity S, for the distance SD from one side HKis =DN-SN K D H ABC S = the distances SE and SF from the other sides. a+b+c E F Centre of Gravity of Plane Figures.-The centre of gravity B A MN G of a parallelogram A BCD, Fig. 850, lies in the point of in- tersection of its diagonals, for all strips, such as KL, which are formed by drawing lines parallel to one of its diagonals BD, are bisected by the other diagonals AC; each of the diagonals, therefore, is a line of gravity. C 850. D In a plane A A BC, Fig. 851, every line CD from one angle to the middle D of the opposite side AB, is a line of gravity, for the same bisects all the elements KL of the A which are given when lines S K M parallel to A B are drawn. If from a second angle A a second line of gravity be drawn to the middle E of the opposite side BC, the point of intersection of the two will give the centre of gravity of the B A L whole 4. Because BD=1 BA and = BC, DE is parallel to AC and = 1 A C, and A D ES similar to the A CAS, and lastly, CS=2SD. If, further, we add SD, it follows that CS+SD, or CD= 3 DS, and, therefore, inversely, DS=} CD. The centre of gravity S lies at 1 of the line CD from the middle point D of the base, and at ! of the same from the angle C. If CH and SN be drawn perpendicular to the base, we have also SN=1 CH; the centre of gravity S is at s of the height from the base of the A. 852. C 851. C S B L K D E M A S) B A X X DN H BI D1 SI Cl AI The distance SS₁ of the centre of gravity of a A ABC, Fig. 852, from an axis x X is = DD+1 Digitized by Google CENTRE OF GRAVITY. 265 (CC₁-DD₁), but consequently, = AA₁+BB₁+CC₁ 3 , i.e., the arithmetical mean of the distances of the three angular points. Since the distance of the centre of gravity is determined in the same manner by three equal weights at the angular points of a 4, so the centre of gravity of a plane triangle coincides with the centre of gravity of these three equal weights. 853. The determination of the centre of gravity G C N D S of a trapezium ABCD,Fig. 853, may be made in the following manner. The straight line MN, which connects the middle points St of the two bases AB and CD with each other, is a line of gravity of the trapezium; 8 for lines drawn parallel to the bases decom- pose the trapezium into elementary parts, whose middle points or centres of gravity lie B EMH F A in MN. Now to determine completely the centre of gravity S, we have only, therefore, to find its distance E H from a base AB. Let B represent the one, and b the other of the parallel sides AB and CD of the trapezium, h the height or the normal distance of these sides. Let D E be now drawn parallel to the side BC, we shall then obtain a parallelogram BCDE of the area bh, and whose centre of gravity is S1, and distance from AB=4, and a A of the area 2 and centre of gravity S, and whose distance from AB=Å The statical moment of the trapezium, about the line AB, is therefore but the area of the trapezium is = it follows, therefore, that the normal distance of the centre of gravity S from the base is 854. D = 0 3 To find the centre of gravity by construction, let the two bases be prolong- SI ed, the prolongations CG made = B and F=b, and the two extreme E points obtained, F and G, connected by a straight line: the point of inter- M section S with the middle line MN will be the centre of gravity sought; F for, from HS= B+26 B+b . h it follows that = B+26 B+6'8 . MN and NS Ss 2B+_MN____MS__B+26_JB+6_MA+AF__MF B A = B+b 3 ; and NS = 2B+b = B+Lb which actually arises from the similarity of the triangles MSF and NSG. To find the centre of gravity of any other four-sided figure ABCD, Fig. 855, we may decompose it by the diagonal AC into two triangles, and from the foregoing, determine their centres of gravity S, and S, and thereby a line of gravity S₁S₂ If now the four-sided figures be decomposed into two other tri- angles by the diagonal BD, and their centres of gravity determined, we obtain another line of gravity, whose intersection with the first will give the centre of gravity of the whole figure. We may effect this more simply if we bisect the diagonal AC in M. apply the 855. greater part BE of the second diagonal Y to the less, 80 that DF=BE, join FM and divide it into three equal parts; the B₂ B centre of gravity lies in the first point S from M, as may be proved in the follow- c C₂ ing manner. MS,=} MD and MS,= As A }MB, consequently S,S, are parallel to BD, but SS, times A ACD=SS, times A or DE=SS, BE; there- Si fore, SS,: Now, BE X X =DF and DE=BF, consequently SS, C1 D1 SIBI Et A1 0 SS,=DF:BF. The straight line MF intersects, therefore, the line of gravity D2 S,S, in the centre of gravity of the figure. D Es If it be required to find the centre of E gravity S of a polygon ABCDE, Fig. 855, we must decompose the polygon into Y triangles, and determine their statical mo- ments with reference to two rectangular axes XX and YY. If the co-ordinates 0B₁=₂, OB₂=y₂ &c., of the extremities are given, the 34 Digitized by Google 266 CENTRE OF GRAVITY. statical moments of the triangles ABO, BCO, COD, &c., may be determined simply in the following manner. The area of A ABO, from the remark below, = D₁ of the following A D, yr), &c., the distance of the centre of gravity of A ABO from YY=m= x₁+x₂+0 3 = 3 from of the centre of gravity of A = us = xg+x, 2 and &c. If these distances are multiplied by the areas of the triangles, the moments of these last are obtained; and if the values so obtained are substituted in the formulae: = D₁+D₁+... v= D₁+D₁+... we have the distances и and v of the centre of gravity from the axes YY and XX. Example.-A pentagon A BCDE, Fig. 855, is given by the following co-ordinates of its extremities A, B, C, dc.: to find the co-ordinates of its centre of gravity: Co-ordinates given. Triple co-ordinates of Six times the statical Twice the area centre of gravity. moments. of triangles. x y 3 un 3 V" 6D,u" BD.v. 24 11 24 21 - 11 = 31 32 13237 13664 7 21 7 15 + 21 16 = 441 - 9 36 - 3969 15876 -16 15 16. 9 + 12 15 = 324 -28 6 9072 1944 12 - 9 12 12 + 18 9 = 306 +6 -21 1836 -6426 18 12 18 11 + 24 12 = 486 42 1 20412 - 486 Sum: 1984 22444 24572 The distance of the centre of gravity from the axis YY is: 22444 1984 and from the axis XX: Remark.-If CA₂=y₁, and the co-ordinates of the two angles of a tri- 856. angle BC, Fig. 856, whose third angle C coincides A2 with the point of application of the system of co-ordi- B₂ B nates, we have the area of the same: = trapezium B₁ A1 triangle CBB,-tri- angle CAA= C X B. A1 The area of this triangle is the difference of two other triangles, CB, A1 and CA, B1, and the one co-ordinate of a point is the base of the one, and the other co-ordinate the height of the other triangle, and inversely. 857. The centre of gravity of the sector of a circle A C B, Fig. 857, coin- M cides with that of a circular arc A, B₁ which has the same angle with the sector, and whose radius C A, is two-thirds of the radius CA of the M1 sector; for the sector may be divided by an infinity of radii into very A B small triangles, whose centres of gravity are distant two-thirds of the S radius from the centre C, and these form by their continuity the arc A, B1 A1 M, B₁. The centre of gravity S of the sector lies in the radius CM, bisecting the surface, and at the distance = chord 2 -CA= o arc 3 4 sin. JB 3 ß r; r representing the radius CA of the sector, and ß the arc which measures the angle at the centre A C B. For the semicircle ß = R, sin. = sin. 90° = 1, therefore == 0,4244 r, or about 14 For a quadrant x 4 3 Vⱼ R r = 4√₂ 3 r = 0,6002 r, and for a sixth part x = 4 3 r = 0,6366 Digitized by Google CENTRE OF GRAVITY. 267 The centre of gravity of a segment of a circle A B M, Fig. 858, is given, if we put the moment of the sector CBM equal to the sum of the moments of the segment and the moment of the triangle A C B. If r be the radius C A, 8 the chord A B, 858. and A the area of the segment BM, the moment of the sector = the M sector X r 2 arc chord arc 2 3 1 r²; further, the moment of the S A S1 B triangle = triangle X 8 4 3 2 r2 4 = 3 12' 12 S₂ and from this the moment of the segment: A. CS = A x = 3 1 0 consequently the distance sought is 12 For the semicircle s=2 r and hence x = 8 * 4r as found above. 2 In like manner we may find the centre of gravity S of a portion of 850. a ring ABDE, Fig. 859, which is the difference of two sectors A CB M and DCE If the radii be CA=r and CD=n, and the chords AB=s and DE=8₁, the statical moments of the sectors are: B 8 8 and 8 therefore the statical moments of the portion of ring = A E 8 , or But the area 0 2 (2), provided that ß represents the arc corresponding to the angle at the centre A CB; the centre of gravity, therefore, of the portion follows from the distance moment area r³—r₁³ Example.-The radii of the surfaces of a dome are: r=5 ft., r₁ = 31 ft., and the angle at the centre, = 130°, then is the distance of the centre of gravity of these surfaces from their central point: 4 sin. 65° 5°-3,5" 4.0,9063 125-42,875 3,6252 X 82,125 == 8 are 130° 5'-3,5' 3.2,2689 25-12,25 6,8067 X 12,75 =3,480 feet. 860. Centre of Gravity of Curved Surfaces.-The centre of gravity of a curved surface (envelope) of a cylinder ABCD, Fig. 860, lies in the middle S of C N the axis MN of this body, for all the annular elements of the cylindrical en- D velope which are obtained by sections drawn through the body parallel to the base, are equal, and their centres of gravity lie in the axis; these centres of gravity form a uniform line of gravity. For the same reason, the centre S of gravity of the surfaces of a prism lies in the middle point of the straight lines connecting the centres of gravity of both the bases. The centre of gravity of the envelope of a right cone A BC, Fig. 861, lies B in th. axis of the cone, and is one-third of this line from the base, or two- M thirds from the vertex; for this curved surface may be decomposed into an infinite number of small triangles by straight lines, which are called the sides of the cone whose centres of gravity form a circle HK, which is distant two-thirds of the axis from the vertex, and whose centre of gravity or centre S lies in the axis C M. 861 c 862. H D N E K S H S H G M F A B C 0 M The centre of gravity of a spherical zone A BDE, Fig. 862, and likewise that of a spherical cup, lies in the centre S of its height MN; for from the rules of geometry, the zone has the same surface as Digitized by Google 268 CENTRE OF GRAVITY. a cylindrical envelope FGHK, whose height is equal to that of MN, and whose radius is equal to that of the radius CO of the spherical zone; and this equality also exists in the annular elements, which are obtained by carrying an infinite number of planes parallel to the circular bases through the same: according to this, the centre of gravity of the zone coincides with that of the cylindrical envelope. Remark.-The centre of gravity of the surface of an oblique come or oblique pyramid lies at about one-third of the height from the base; but not in the straight line passing from the vertex to the centre of gravity of the base, because slices parallel to the base decompose the surface into rings, which vary in breadth at different parts of their surface. Centre of Gravity of Bodies.-The centre of gravity of a prism A K, Fig. 863, is the centre S of the straight line which connects the centres of 863. gravity M and N of both bases AD and GK, for the prism may be de- L composed by sections parallel to the base into exactly congruent slices, K whose centres of gravity lie in MN, and by their superposition make the N G line MN a uniform line of gravity. For the same reason, the centre of gravity of a cylinder lies in the middle of its axis. S The centre of gravity of a pyramid DF, Fig. 864, lies in the straight line M F from the vertex F to the centre of gravity M of the base, for all slices as NOPQR, have from their similarity with the base, their centres D A of gravity in this line. c B If the pyramid be triangular, as ABCD, Fig. 865, each of the four angular points may be considered as vertices, and the opposite surfaces as bases; the centre of gravity S is determined by the intersection of two straight lines drawn from D and A to the centres of gravity M and N of the opposite surfaces A and BCD. F D 865. 864. N 0 D N So S c A C M HGM E A B B If the straight lines EA and ED be given, we then have EM=}EA and = 1 ED there- fore M N is paraller to A D and = AD, and the A MNS similar to A DAS. Again, from this similarity we have MS=1 DS, or DS=3MS, also MD=SD+ MS = 4 and inversely MS=+MD. Hence the centre of gravity is found to be one-fourth of the line joining the centre of gravity M of the base with the vertex D. Further, if the heights DH and SG be given, and HM be drawn, we then obtain the two similar 4° DHM and M, in which from the foregoing SG=1 We may, therefore, say that the dis- tance of the centre of gravity S of a triangular pyramid from the base is equal to one-fourth, and that from the vertex three-fourths of the height of the pyramid. As every pyramid, and also every cone, is made up of 866. an infinite number of three-sided pyramids of the saine height, the centre of gravity of every pyramid and cone is a fourth of the height from the base and three-fourths from the vertex. We may, therefore, find the centre of gravity.of a pyramid or cone, if a plane be drawn paral- lel to the base at a distance one-fourth from the base, and S the centre of gravity of the section or its intersection with DA the line joining the vertex and the centre of gravity of the base be determined. co If the distances A A1, BB,, of the four angles of a tri- angular pyramid A BCD. Fig. 866, from a plane HK be B A. known, the distance of the centre of gravity S from this plane is found from the mean value M H K 4 The distance of the centre of gravity M of the base ABC B from this plane is: 8 and that of the pyramid S is: SS,=MM+(DD,-MM,), where DD₁ is the distance of the vertex: hence it fullows by combining the two last equations, that: 4 Digitized by Google CENTRE OF GRAVITY. 269 The distance of the centre of gravity of four equal weights Z c applied to the angles of a triangular pyramid, is equivalent 867. to the arithmetical mean AA,+BB,+CC,+DD, A , 4 B consequently the centre of gravity of the pyramid corre- sponds with that of the system of weights. Remark.-The determination of the volume of a triangu- lar pyramid, from the co-ordinates of its angles, is simple. o If we draw planes XY, XZ, YZ, through the vextex 0 of C Y such a pyramid A BCO, Fig. 867, and represent the dis- tances of the angles ABC from these planes by 21, 20 23, Yu yrs Yrs and x₁, In In the volume of the pyramid will be X B A which will be given, if the pyramid be considered as an aggregate of four oblique prisms. The distances of the centre of gravity of these pyramids from the three planes are: = x₁+x,+x, 4 , y₁+y₃+y₂ 4 , and z = 4 Since every polyhedron, as A BCDO, Fig. 868, may be decomposed into triangular pyramids : BCO, BCDO, we may also find its centre of gravity Z A S if we calculate the volumes, and the statical moments of the single pyramids. 868. If the distances of the angles A, B, C, &c., from the co-ordinate planes passing through the common vertex o of all the pyramids, are x₁, x₂, 0 ats, &c., y1, Y2, Yr, &c., 21, 20 Z₂₀ &c., the volumes of the single pyramids are: D 0 and the distances of their centres of gravity: Y A 26, = 4 4 s so, , 4 4 X D B' statz From these values the distances of the centre of gravity of the whole body may be finally calculated by the formulæ: = V₁+V₁+ v = V₁+V₁+ w = V,+V,+.. V, Example.-A body bounded by six triangles A DO, Fig. 000, is determined by the following values for the co-ordinates of angles; whence the co-ordinates of its centre of gravity may be found. Four times the co-ordi- Given co- nates of Twenty-four times the statical ordinates. Six times the area of the triangular centre of moments. pyramids. gravity. 4 % s 4 w, S x y z 4v. 24 V.u. 24V.v. vn 24 Va 20n 20 23 41 20.29.28 20.40.30 6 V₁= 41.45.40 45.35.28 12 6 V₂ &BL 23.28.45 31072 77 92 45 29 30 99 2392544 2858624 3076128 23.30.12 41.12.29 45.40.20 40 29.20.12 29.28.38 17204 95 104 78 1634380 1789216 1341912 38 35 20 30.38.40 30.12.35 Sum: 48276 4026924 4647840 4418040 From the results of this calculation, the distances of the centres of gravity from the three planes YZ, XZ, and XY follow. 1 4026924 1 4647840 1 4418040 = = . = 20,853, v = 24,069, 22,879. 4 48276 4 48276 48.76 Digitized by Google 270 CENTRE OF. GRAVITY. The centre of gravity of a truncated pyramid A DQN, Fig. 000, lies in the line MG, which connects the centres of gravity of the two parallel bases: in order to determine the distance of this point from one of the bases, we must determine the volumes and moments of the entire pyramid A DF, and the supplementary pyramid NQF. If the areas of the bases AD and NQ=G and g, and the normal distance of both = h, the height of the supplementary pyramid will be given from the formulæ: g = = and x = as also h+ = hVĞ The moment of the whole pyramid with reference to the base G is now: 8 4 = 12 1 hᵃ that of the supplementary pyramid = (4) = 3 1 VG-VI h'VI' + 12 1 (G-₉) h²g² ; hence it follows that the moment of the truncated pyramid: Now the solid contents of the truncated pyramid are: hence it follows, finally, that the distance of its centre of gravity S from the base is G+2VGg+3g The radii of the bases of a truncated cone are R and r, and therefore G=, Rª and K rs; we have then for this R'+2Rr+8r 867. R'+Rr+r D₁ A Example.-The centre of gravity of a truncated cone of the height = :N 20 inches, and radius R=12 and r=8 inches, always lies in the line C B1 joining the centres of the two circular bases, and is distant from the great- er by 20 4 2.12.8 + 3.8' 5.528 304 = 2640 8,684 inches. D SIG 4 A pontoon is a body enclosed by two dissimilar rectangular bases and Fx E four trapeziums ACC,A,, Fig. 867, and may be decomposed into a paral- lelopiped AFC₁A₁, two triangular prisms EHC₁B₁, GKC,D₁, and a B quadrangular pyramid HKC,; we may, therefore, with the help of these C H constituents, find the centre of gravity of the body. It is easy to see that the line from the one base to the other is the line of gravity of this body; there remains only to determine the distance of the centre of gravity from either base. If we represent the length BC and breadth A B of one base by 1 and b, and that of A1 B₁ and B₁ C₁ of the other base by 1₁ and b₁, and the height of the body by h, then the volume of the parallelopiped = b₁l₁h, and its moment b₁ l₁ 2 2 1 b₁ 1₁ h²: further, the volumes of the two triangular prisms ([b-b₁] l₁ + [l-l₁] h 2' and their moment = ([b-b₁] [L-4] lastly, the volume of the pyramid (b-b₁) (1-1) h 8' and its moment (b-b₁) (l-l₁) h The volume of the whole body is, therefore: V = (6b₁ 6 (2bl + 2b, 1, bl, + and its moment Vy = (6b₁ l₁ + + (3b, l₁ + + bl, + b₁ Hence it follows that the distance of the centre of gravity from the base bl is: 2b1+ 2b,4 +b₁ +,l2 Remark.-This formula is also applicable to bodies with elliptical bases. The axes of the one base are a and b, and of the other a₁ and b₁; the volume of such a body, therefore, is: V=nh = 24 ab₁ and the distance of the centre of gravity: ab+3a,b+ab₁+a;b.h Digitized by Google CENTRE OF GRAVITY. 271 Example.-A dam, A CC₁ A1, Fig. 868, is of the height 20 feet, 250 feet long at the bottom, and 40 feet wide; at the top 400 feet long and 15 wide: to find the distance of its centre of gravity from the base. Here 40, = b₁ = 15, l₁ = 400, h=20, therefore the vertical distance sought is: 20 M2.40.250 +2.15.400+40.400+15.2502 - 868. B N C B1, A1 M 5 D1 If the sector of a circle A CD, Fig. 869, revolves about its radius CD, there is generated the spherical sector A CB, whose centre of gravity we 869. wish to determine. We may represent the body as containing infinitely D many and infinitely thin pyramids, whose common vertex is the centre C, B M and whose base forms the spherical surface ADB. The centres of gravity of all these pyramids are at t of the radius of the sphere from the centre IN C; they therefore form a second spherical surface A, D₁ B₁ of the radius B1 A1 CA=CA. But the centre of gravity S of this curved surface is the centre of gravity of the spherical sectors; because the weights of the ele- mentary pyramids are uniformly distributed over this surface, and therefore it is uniformly heavy. If we now put the radius CA=CD=r and the height DM of the outer surface = h, we get for the inner CD₁=1 r, and M1 D₁ = consequently D₁ = M, D₁ = h, and the distance of the centre of gravity of the C sector from the centre: For the semicircle, for example, h=r, therefore the distance of its centre of gravity 6 from the centre C is : 870. D The centre of gravity S of the segment of a sphere ABD, Fig. 870, is obtained when its moment is put equal to the difference of the moments of the sector ADBC and that of the cone A BC. Again, if we put the radius of the cone CD B A BI M =, and the height DM=h, the moment of the sector= = and that of the cone = F moment of the segment of the sphere is therefore C E1 E volume of the segment * (3r-h); hence, the distance in question is: If, again, we put h=r, the segment becomes a semicircle, and as above, CS=ir. This formula holds good for the segment of a spheroid A₁ B₁, which is generated by the revolution of an elliptical arc DA' about its major semi-axis CD=r; for both segments may be divided into thin alices by planes parallel to the base AB, 80 that the ratio of any two is constant and MA CE,' 6' CE2 if b represent the semi-axis minor of the ellipse. The volume, as well as the moment of the segment of the sphere, must be multiplied in order to give the volume and moment of the segment of the spheroid, and thereby the quotient volume will remain unchanged. Digitized by Google 272 CENTRE OF GRAVITY. 871. To find the centre of gravity of an irregular body ABCD, Fig. 871, C we must decompose it into thin slices, by planes equidistant from each N F D other, determine the solid contents of each slice, their moments with reference to the first parallel plane A B serving for the base, and finally F3 connect them together by Thos. Simpson's rule. The contents of these slices are F₀, F1, F2, F3, F4, and the whole F' height or distance of the outermost parallel plane is=h; the volume S of the body, therefore, according to Simpson's rule, (approximately,) is: E' B M If we multiply in this formula each of these volumes by their distance, we obtain the moment: lastly, by dividing one expression by the other, we get the distance required: F+4,+2,+,+ 4 If the number of elementary slices = 6, we have: 6 It is easy to understand how this formula may be altered when the number of slices is different from the above. This rule requires only that the number of the slices should be even, and, therefore, that of the surfaces uneven. In most cases of application, the determination of one distance is enough, because, besides this, a line of gravity is known. The bodies commonly met with in practice are solids of rotation, generated in a lathe whose axis of rotation is the line of gravity. This formula, lastly, is applicable to the determination of the centre of gravity of a surface, in which case the sections F°, F1, F2, become lines. Example.-1. For the parabolic conoid A BC, Fig. 872, which is generated by the revolution of a parabola ABM about its axis A M, we obtain by making the section DNE, the following: The height AM=h, the radius BM=r, AN=NM=₄, and hence the radius DN=, 1/2 The area of the section through A is F₀=0, of that through = F1 = W 2 and of that through M=F,=.r. Hence the volume of this body is: v=+++= 5) on the other hand, the moment is r2 r²) = = 23 = lastly, the distance of the centre of gravity S from the vertex, is 872. 873. R B M ro A A "1 M SN S A T2 rg E N T4 c D C Example 2.-A vessel ABCD, Fig. 873, has its mean half breadths, r₀=1 inch, r₁=1,1 inch, r₂ = 0,9 inch, r₃=0.7 inch. r₄=0,4 inch, with a height M N = 2,5 inch. The sections are F₀=1.π, F₁=1,21.π. F₂=0,81.π, F₁=0,49.π, F4=0,16.x; hence, the distance of the centre of gravity from the horizontal plane A B, is: 1 +4.1,21 x+2.0,81 x +4.0,49 * +0,16* 4 14,60 9,58 2,5 36,50 0,9502 inches. The capacity, therefore, cubic inches. Digitized by Google CENTRE OF GRAVITY. 273 An interesting and sometimes very useful application of the laws of the centre of gravity is the properties of Guldinus, or the barocentric method. According to these, the volume of a body of revo- lution (or of a surface of revolution) is equal to the product of the generating surface, (or generating line,) and the space described by its centre of gravity during the generation of the body or surface of revolution. The correctness of this proposition may be made evident in the following manner. Guldinus' Properties.-If the plane area ABC, Fig. 874, revolve about an axis XX, each element F, F1, &c, of the same will describe an annulus; if the distances F₁ G,, F, G, &c., of these elements from the axis of revolution XX, be rg, &c., and the angle of revolution therefore the are corresponding to the radius 1=a, the circular paths of the ele- ments will be r₂ &c. The spaces described by the ele- 874. ments F1, F₂ &c., may be considered as curved prisms having the XI bases F1, F₂ &c., and the heights &c., and the volumes F1 a, F, &c., and therefore the volume of the whole body If MS = x be the distance of the centre of gravity S of the genera- " M.O ting surface from the axis of revolution, we have also (F₁+F₁+...) 8, consequently the volume of the whole body V =(F,+ F,+...) x But F,+F,+. are the contents M - of the whole surface F, and x a the circular arc 10 S,, described by 875. the centre of gravity S; consequently, V = Fw, as above enunci- X ated. This formula holds good also for the revolution of a line, because it may be considered as a surface made up of infinitely small breadths; F is namely =Lw: i. e. the surface of revolution ,A A is a product of the generating line (L) and the path (w) of its centre of gravity. Example.-1. In a half ring of an elliptical section ABED, Fig. B P -) 10 B 875, let the semi-axis of the section be CA=a and CB=b, and let the distance CM of the centre C from the axis X =r ; then x the elliptical generating surface F = π ab, and the path of the centre of gravity (C) hence the volume of this half ring V = x2 and that of the whole ring = If the dimensions be, a=5 inches, b=3 inches, r=6 inches, the volume of one- fourth of the ring = = = 444,132 cubic inches. Example.-2. For a ring with a semicircular section A BD, Fig. 876, if CA=CB=q represent the radius of this section, and MC=r that of the hollow space or neck, the volume is V (+) 877. 876. D X A' 1B C M S JD X IN Example.-3. To find the surface and volume of a cupola ADB of a dome, Fig. 877, half the width MA=MB=a, and the height MD=h, are given. From both dimensions it follows that the radius CA=CD of the generating circle =r= 2a + and the angle ACD subtended at the centre by AD=a, if we put the sin. a=, a The centre of gravity S of an arc DAD,=2AD = is determined by the distance CS=r chord arc A D MD sin. ; further, CM=r cos.a, consequently a the distance MS of the centre of gravity S from the axis MD and the path described by the centre of gravity in the generation of the surface ADB=2xr. sin. The generating line DAD₁= 2 r e, and since it only is required to determine the half ADB, this line = a, and consequently we must put the whole surface 0=ra.2xr 35 Digitized by Google 274 CIDER-MILL AND PRESS. Very commonly a°=60°; therefore, sin. a = JV3, and the cosa=}; hence it follows that mo= = For the segment DAD₁ = A = sin. 2 a) the distance of the centre of gravity from the centre is = sin. hence the distance from the axis MS = CS - CM = finally, the path of this centre of gravity described in one revolution is: The volume of the whole body generated by the segment D A D₁, is given if this path be multiplied by A. and the volume of the dome found by taking the half of this: therefore, V = * sin. sin. COS. a). For example, and COS. a = hence: Remark.-Guldinus' properties find their application in those bodies which arise when the generating surface 80 moves that in every position it remains perpendicular to the path of its centre of gravity, because we may assume every small part of a curvilinear motion to be circular. From this we may find the solid contents of the threads of screws, and sometimes also calculate the masses of earth, heaped up or removed, as in the case of canals, roads, railroads, dc. CHALK See RAILWAY ENGINEER- ING. CHAMBERS OF LOCKS, form to be given to. See LOCKS OF CANALS. CHEESE-PRESS. Dick's Anti- 878. Friction Cheese-Press.-In the annexed cut is represented the method of apply- ing Dick's anti-friction power to the pressing of cheese. By the use of this press the whey is entirely removed, and half the labor usually required in the manufacture of cheese is saved, it being ready for market or transportation as it comes from the press, without risk or loss to the purchaser, and the consequent vexation 80 frequent in the case of the method originally pursued. The press- ing may be carried to any extent deemed requisite, without danger to the press, the working portions of the press being made of iron, and capable of sustaining the force that may be applied. Attached to this press is the platform scale; so that the cheese can be accurately weighed before it is removed from the press-a matter of great convenience and importance to the manufacturer and vender of these articles, as well as to the purchaser, who can depend upon the weight marked upon it as strictly accurate. In fact, the advantages of this press, above others, must be at first view apparent, and the power such that it will come into general use. CHIMNEYS, OF LOCOMOTIVES. See DETAILS OF ENGINES: what to do if carried away. See MANAGEMENT OF EN- GINES. CHISELS. See PLANES AND CHIS- ELS. CIDER-MILL AND PRESS. Chapin's Portable Cider-mill and Press-This machine is arranged in one compact body, upon a set of heavy wagon-wheels; and including these, the whole weighs but about 2,700 lbs. It may be drawn from one orchard to another by a single pair of horses, and is put in operation while standing on the wheels. With the power of one horse and the labor of two men and a boy, it is capable of expressing from twelve to twenty barrels of cider per day. The apples are ground by four fluted cylinders or nuts, which mesh into each other, and are within the mill, as at E; Digitized by Google CIRCULAR SAW. 275 these are driven by a horse attached to the sweep C. Below the cylinders is the press crib, made of perforated plank and grates, and when the falling poinace has formed a sufficient cheese in this, the follower-planks and block F are introduced upon the upper surface; the sweep C is transferred to the heads of the screws; and the pressing is performed either by hand or horse power. A channel on the margin of the platform 0, conducts the cider which issues through the sides of the crib, into the tubs. When the pressing is finished, the platform is lowered to the ground, the tubs and rear grate B are removed. and the cheese is drawn out in a mass upon a separate side platform, by a horse, to any con- venient distance from the mill. The sweep is then placed upon the shaft H of one of the cylinders, and the grinding is again commenced. A band of iron on each side, shown at D, confines the press- beam to the platform during the pressure of the screws. They are manufactured by Nathan Chapin, Syracuse, N. Y. 879. E CIRCULAR SAWS. See SAWS. CIRCULAR SAW for Cutting Veneers. The object of this machine is to cut up logs of fine wood into slices or leaves for purposes of veneering. From ten to sixteen of these slices may be cut from an inch of wood; and considering that the logs are from 9 to 36 inches broad, some idea may be formed of the nicety of the operation, and of the steadiness and rigidity of parts required in the machine for the efficient discharge of its functions. The principal feature of the machine is a circular saw, marked bb in the cuts, which is built in seg- ments upon a strong, rigid, cast-iron frame A, which, it will be observed from the sections and the plan, consists of a series of arms radiating from a central eye, dished in form, like an ordinary carriage- Digitized by Google 276 CIRCULAR SAW. wheel, and flanged on the hollow side, to secure rigidity; these arms terminate in a broad, flat ring, upon which the segments of the saw are fastened by means of short countersunk screws, as exhibited in Fig. 882. The saw-frame, as it may be termed, is hung upon a strong shaft P, which runs in bear- ings located on wall-plates, secured to a foundation by holding-down bolts. Upon the same shaft are hung the driving-pulleys BB, whence the motion of the machine is derived. While the axis of the saw-frame remains stationary during the operation of the machine. the log of wood C. which is being cut up, is urged forward against the saw by a gradual progressive motion, being fixed for the purpose on a sliding carriage D E G, moved by a self-acting apparatus. First of all, the carriage runs upon two parallel rails T R, bedded on two longitudinal square tim- 880. c R E B B 0 M v P K N bers, and firmly bolted down to them. The lower part of the carriage G, slides on these rails at three surfaces of contact on each rail, as may be seen in Fig. 882. The upper part of the carriage E is held down to the part G by means of dovetail bevel surfaces, where a broad piece of metal is introduced between the snug cast on the end of the piece G and the bevel edge of the piece E. and bolted down to G, thereby holding down the piece E to G-admitting also of a transverse sliding motion of the piece E; (see Fig. 882.) From the piece E, three flanged arms are erected, to which is bolted the timber frame D, on which is immediately sustained the log C. The frame D consists of two longitudinal square timbers, the lower one of which, as shown in Fig. 880, rests upon short flanges projecting from the faces of the arms of the piece E, and is thus prevented from sliding down; these timbers are connected by a series of spars, checked at both ends into the timbers. The spars are finished flush on their exterior surface, on which they receive the log C, which adheres to them by means of a film of glue interposed. The spars are set at an inclination backwards, as they are thus more directly in the line in which the strain comes upon them. The self-acting motion for moving the sliding carriage, and thereby feeding the saw, is driven from the main shaft. A rack H fixed on the under side of the carriage, is driven by a pinion on the end of the horizontal shaft T, Fig. 880, upon which the triple-grooved pulleys M 0 run loose, ready to be catched alternately by the sliding-clutch V. The pulleys M are driven by the pulleys K on the end of the main shaft, the motion being reduced by means of the intermediate pulleys L The pulleys 0 are driven directly by the pulleys N on the main shaft. The pulleys K L M are those which feed the saw, the band K L crossing itself, and LM being an open band. The pulleys N 0 reverse the motion Digitized by Google circular SAW. 277 of the log-frame, and carry back the log to prepare it for a succeeding cut. Three different speeds are provided in these pulleys. The motion for feeding the saw transversely-that is, for shifting the log in the direction of its breadth, in setting it for another cut-is effected by the screws SS, the bearings of which are fixed on the sole G, and their screwed parts working in nuts fixed on the piece E. On these screws, worm- wheels are fixed, driven by worms on a horizontal shaft, which again is driven by hand, by means of a pair of small meter wheels-all which is represented in the plan, Fig. 881. The lateral motion of the piece E is directed by the bevel surfaces between which it is confined. 881. @ 00 0 00 M L H 0 C D E B B C H A @ 6 Action of the Machine-The log being fixed to the frame DE, and the end of it adjusted in contact with the edge of the saw, by means of the longitudinal and transverse sliding-surfaces already described, the clutch V is geered with the pulleys M, the driving-bands being shifted to the proper speeds. The driving-belt is then shifted to the driving-pulley B, and the saw is caused to revolve at a high speed, the self-acting motion at the same time urging forward the log. The veneer, as it separates, glides off the back of the saw-frame, as shown at F in Fig. 881, and, when cut off, is carried away. The clutch v is then reversed into geer with the pulleys O: thus the motion of the sliding-carriage is reversed, and the log is returned to its first position in front of the saw. The clutch is then entirely disengaged, and the transverse motion is applied to the frame DE, by which the log is shifted in front of the saw, in readiness for the next cut. The clutch V is now engaged with the pulleys M, and the process is re- peated as already described. Digitized by Google 278 CIRCULAR SAW. The speed at which the saw is driven is about 180 revolutions per minute, which with a diameter of twelve feet, gives a velocity of 6784 feet in that unit of time. The feed-motion for that velocity is about t inch for every revolution of the saw, making 111 feet per minute of veneer cut. The feed- motion is, however, modified according to the quality of the log under operation: often it does not exceed a half of that stated; and in some mills the velocity of the saw is also less. 5 as H a Y A X A Transverse Section. X G Plan of the Lower Carriage. A H E1 M M R Literal References.-A. the saw-frame, with the saw bb attached to it. BB, the fast and loose pulleys on the saw-frame shaft. C, the log which is to be cut into veneers. D, the timber-frame to which the log is attached. E, the cast-iron frame to which D is bolted. which slides laterally under dovetail surfaces. F, the veneer as it comes from the saw, gliding off the saw-frame. G, the lower part of the sliding-carriage, which slides longitudinally on rails laid on tim bers. H, the rack attached to the sliding-carriage, and driven by a pinion on the shaft of the feeding apparatus. Digitized by Google CLOTH-SHEARING MACHINE. 279 K, grooved pulleys on the end of the main shaft, for driving the feed-motion. a L, intermediate pulleys, driven by the pulleys K. M, pulleys loose on the pinion shaft, driven by the pulleys L N, pulleys on the main shaft, for reversing the motion of the log. 0, pulleys loose on the pinion shaft, driven by the pulleys N. P, the saw-frame shaft. RT, longitudinal slides on which the sliding- frame is moved. - S, screw and wheel motion for shifting the log- frame laterally. V, the clutch carried round with the shaft on which it slides, so that it may be put in geer S with the loose pulleys MO, alternately. A Saw-mill Rollers for Planks.-Fig. 883 repre- A sents an arrangement for steadying the planks or logs as they are moved forward in saw-mills. G R H A A, are adjusting-screws, working in nuts fixed on the frame of the machine, for setting the roller-frame against the logs. B B, are adjusting-screws for setting the plank- frame HS. C C, pinching-screws, acting by the intervention of levers upon the rollers. S DD, levers jointed to the roller-frame, trans- 883. mitting the pressure of the screws CC to the rollers. E E, spring-levers intermediate between the S screws C and the levers D. F G, F G, the soles of the roller-frames, guided in their traverse motion by dovetail surfaces upon R HH. H H, the plank-frames, into the ends of which a H are inserted the screws B B. II, clutch-frames, through which the journals A of the rollers pass; they transmit the pressure of the levers D D to the rollers. R R, the rollers which press the planks against the uprights SS, and steady their motion; the ends of their journals move in grooves in the framing F G, FG. SS, uprights rising from the plank-frames H H, against which the planks are held by the rollers. CLOTHING BOILERS AND CYLINDERS, saving fuel from. See MANAGEMENT OF ENGINES. CLOTH-SHEARING MACHINE Invented by Milton D. Whipple, of Lowell, Mass., for shearing cotton cloth, or preparing it for being printed. Fig. 884 denotes a top view of the machine; B Fig. 885 is an elevation of one side of it; Fig. 886 is an elevation of the other side of it; Fig. 887 is a central vertical and longitudinal section of it; Fig. 888 is an elevation of the front end; and Fig. 889 is an elevation of the rear end. The machine to be described is calculated to remove from the surface of calico or cotton cloth the furze, nap, knots, or other matters which are usually taken off by the process of picking by hand, and singeing by hot rolls or plates, or the flame of gas. Mr. Whipple does not confine his invention to the shearing of cotton cloth alone, as it may often be used to good advantage on many other thin cloths, such as mouslin de laine, for instance. In the drawing, A denotes the frame-work of the machine constructed of iron, wood, or any other suitable material; B is the driving-shaft extending across the frame, and made to run in proper boxes C is a fast pulley, and D a loose pulley arranged on the shaft, motion being given to said shaft by the belt, from the driving power being made to operate on the fast pulley EF G H are four series of revolving helical shearing-cutters applied to, or arranged respectively on horizontal shafts IKLM, whose journals are supported in boxes N N N, &c. Beneath each of these series of cutters is one of a series of blades or horizontal knives 000, &c, which is attached to a head-piece or holder P. The ends of the said head-piece have adjusting-screws Q R, Q R, applied to them in such manner as to admit of the correct adjustment of the holder P, and blade O, with respect to the rotating helical cutters over and in advance of them. At some distance in front of each of the blades 00, is a rule or ledge S, whose Digitized by Google 280 CLOTH-SHEARING MACHINE. upper edge is placed somewhat above the under surface of the knife or blade 0; the position of said rule S, and the top of it with respect to the cutters and blades, being as seen in the drawings. Each of the series of revolving cutters has a pulley T fixed on it. There is a driving-pulley V on the driving- shaft. A belt V passes arounl the said pulley V, and the two middle pulleys TT, as seen in Fig. 885. It is by means of the said pulleys and belts, that the several series of helical cutters are put in revolution. A cylindrical brush X is placed in advance of the first rule S, and so as to bear against the cloth Y, 884. R 885. n T T T T NO 20 KO 60 k o A A B as it passes from the under surface of a friction-roll on cylinder Z to the top of the first rule S; the said brush is revolved by a belt, which passes around two pulleys bc, the former of which is fixed on the driving-shaft, and the latter on the shaft of the brush x. In the rear of each blade O, and between it and the rule or ledge S, directly in rear of it, is a long transverse horizontal brush z, which rests on the cloth, and removes any superfluous lint, and lays the nap of the cloth as it passes underneath in the proper direction to be acted upon by the cutters in rear of it; e and f are a pair of drawing-rollers arranged at the rear end of the machine, as seen in Fig. 887. The lower one has its journals sustained Digitized by Google CLOTH-SHEARING MACHINE. 281 in boxes, applied to the ends of two weighted levers g, H, by the action of which it is pressed against or towards the upper roller. The upper roller has a geer-wheel i fixed on its shaft; the said geer-wheel is made to engage with a toothed pmion K fixed on a shaft i; on said shaft i is a pulley m, around which a band n passes to a pulley 0 fixed on the driving-shaft. By means of the pulley, belt, and geers, the upper drawing- roller receives the motion. A stretching-bar P is arranged at the front end of the machine, and directly over the roller z. The upper edge or surface of the bar has grooves or flutes made diagonally across it, those on the side of the centre of the bar being caused to run in a direction opposite to those on the other, as seen in the figures, the object of this bar being to stretch the cloth in lateral directions. When the cloth first enters the machine, it passes over a cylindrical rocking-bar q, (see Fig. 888,) which is supported so as to rock or vibrate laterally on a post r, made to rise upwards from a trans- verse bar S. From the centre part of each end of the bar, one of two rods or journals i u projects, as seen in Fig. 890, which denotes a vertical and longitudinal section of the bar, and parts connected with it. On each of the journals one of two pulleys v w is placed, and revolves; each of said pulleys being of a diameter corresponding to that of the cylindric bar q. The external curved surfaces of the pulleys are made rough by having sand-paper, or sand or emery glued to them, and each of said pulleys has a neck or hollow shaft x extending from it, and through a vertical groove y, made in one of two plates or standards 2 a. A small geer-wheel b is fixed on each hollow shaft x; the said geer-wheel being made to engage with a vertical toothed rack c, affixed to the standard, as seen in Figs. 885 and 886. The pecu- liar object of the said rocking-bar and mechanism applied to it, is to cause the cloth, as it rises up from the pile on the floor, to be delivered centrally upon the front series of helical cutters; or in other words, 80 that one of its selvages shall be at the saine distance from the adjacent end of the series of cutters as the opposite selvage is from the end thereof adjacent to it. The length of the rocking-bar is made equal to, or somewhat greater than the width of the piece of cloth: when the piece is drawn through the machine by the action of the drawing-rollers, it is made to pass over the rocking-bar. If either selvage or edge of the piece, while 80 in motion, should happen to project at any time beyond the contiguous end of the rocking-bar, and upon the surface of the adja- cent pulley v or to, it will cause said pulley to turn on its journal; the consequence of which will be, that the toothed pinion b will be made to revolve by it; which motion of the pinion will cause it, by its connection with the rack into which it goes, to rise upwards and tilt the rocking-bar into an inclination to the horizon, thereby inducing the cloth to move laterally on the rocking-bar, or towards the pulley at its opposite end. Should it by chance run over the last pulley, a contrary action will occur, and the rocking-bar will be tilted in an opposite direction, and so as to induce the cloth to slide or move towards the other pulley. The apparatus is thus self-acting, and operates with all the desired regu- larity and precision to introduce the cloth centrally into the machine. Directly over each of the series EFGH of revolving helical cutters is an oiling apparatus, which consists of a strip of cloth d, affixed to a long bar e, whose ends have journals which are supported and move in the tops of posts or standards f G. One of the journals of each of the bars e' c¹, &c., has an arm h extending downwards from it, and passing through one of a series of staples i, &c., driven into a long slide-bar K. This slide-bar is sustained by bearings l m, fastened to the side of the frame A, and its rear end rests against a cam n, fixed on the shaft of the upper driving-roller. The said cam during part of its rota- tion forces the slide-bar forward, and longitudinally, in such manner as to move all the arms h h simul- taneously, and thereby cause all the strips of cloth to rise above their respective series of cutters. The retraction of the bar may be effected by a spring properly applied to it, the said retraction causing all the stripe of cloth to descend upon the cutters. Each strip being saturated with oil, will, when it is carried in contact with the knives or cutters, lubricate their edges. The next portion of the machine to be described is that by which the lint and extraneous matter, removed from the surface of the cloth by the helical cutters, are taken from the machine. For this purpose is placed above the frame A, a large pipe or hollow cylinder or vessel n, one end of which should be stopped up while the other should connect with an air-exhausting apparatus of some proper kind. From this pipe others, 0 0, &c., extend downwards, and open respectively in vertical, triangular, or other proper-shaped vessels PP, each of which is placed respectively just in rear of the cutters and rotary brush, an! is open at bottom, and shaped and made as seen in the drawings. Each of the bars to which the blades 00, &c., are attached is curved upwards, as seen at q, 80 as to direct the lint and the conductors PP. Now when air is drawn out of the pipe 72 by the exhausting apparatus, an atmospheric current will rush up each of the vessels and pipes extending downwards from it. In the passages of said currents into the adjutages of the conductors PP, and through the same, and pipe O, they will carry with them the lint and extraneous matters removed by the cutters and rotary brush. In order that the cutters may perform their operation on the cloth in a proper manner, a reciprocating lateral movement as well as a rotary movement may be given to them: this is effected in the following manner. On each cutter-shaft is a grooved pulley r1, into the groove of which the upper end of one of four vertical plates SS, dc., is inserted, the said plates being secured to a horizontal slide-bar t, which is arranged and operated by a cam, and a retracting spring, in substantially the same manner as is the slide-bar K, hereinbefore described. The upper end of each of the plates S is bent out of parallelism with the side of the frame A, as seen in Fig. 884. Now when a reciprocating rectilinear movement in a longitudinal direction is imparted to the slide-bar v, and plates SS, the pressure of the plates on the slides of the grooves of the pulleys rr, &c., will cause the various series of cutters during their revolu- tions to move back and forward laterally. 36 Digitized by Google 282 887. 886. n n mmmmy A e m 0 CLOTH-SHEARING MACHINE. r A A OR A Digitized by Google CLOTH-SHEARING MACHINE. 283 8 888. R 890. 3 Do r 889. R D Digitized by Google 284 CONDENSING ENGINE. Two straight bars d' er are arranged at the front end of, and transversely across the machine, and parallel to one another; one of them, viz. d³, being fixed firmly in position while the other is made adjustable, or has adjusting-screws or other proper contrivances applied to it for the purpose of regula- ting its distance from the other bar. The cloth is passed and moves between these bars, they being adjusted at such a small distance asunder, as will be just sufficient to allow the cloth to pass between them, while no knot or picker-wires or other extraneous substances which would be likely to injure the cutters, present themselves in the cloth. When such matters exist on the cloth, and are carried in contact with the bars, they will either be removed by the draft on the cloth, or they will stop the motion of the cloth until they can be removed by an attendant. The next and last portion of the machine to be described is the folding apparatus, which consists of a platform V, supported on two rails X X, by four or any other suitable number of wheels W W. The said platform or carriage should have a reciprocating rectilinear motion imparted to it in a longitudinal direction by suitable mechanism. That employed is as follows: The carriage has a long plate of metal W secured transversely to its under side; through the plate a long slot X is cut, into which one end of a crank J is inserted, the crank being made to project from the top of a vertical shaft 2. which turns in proper bearings of a post or standard a³, supported on the floor on which the machine rests. On the shaft is a bevelled geer a³, which engages with a bevelled pinion b⁸, which is fixed on a horizontal shaft c3, which has a pulley d' secured to its outer end around this pulley, and a pulley e2 fixed on the shaft of the upper draw.roller to the carriage V, by said pulleys e², d², belt f2, shaft c², geers b², a3, and crank y and slot x acting together. The constant fore and back movements of the carriage causes the cloth, as it passes from between the draw-rollers, to be laid on it in regular folds. The manner in which the cloth is passed through the mechanism is seen in b 3 at Fig. 887. It has been found from experience that the cloth is much better sheared when subject to the action of several series of rotating helical cutters, arranged and operating together as above, than it is when successively subjected to the action of one revolving series of such cutters. The process of shearing, besides being performed much quicker by two or more series of rotary cutters and their adjuncts, as above specified, is more easily performed, and with less liability of injury to the texture or thread of the cloth. By reference to the drawing, it will be seen that the position of the top edge of each of the ledges S, with regard to the bottom of the cutters or cutting-blade O, is such that the cloth, after passing over the top of said ledge, is by the ledge borne up against the under side or edge of the blade O, and so that the fur or nap which is to be removed is carried against the edge of the plate, and is cut off by the action of the revolving cutters. Consequently, should there be any knots, motes, or foreign substances projecting from the upper surface of the cloth, they will be removed by the upper surface and blade, and without injury to the cloth. If the cloth passed directly over a ledge or rest placed under the cutters, as in machines for shearing broadcloths, cassimeres, &c., or thick and long-napped cloths of like character, it would be constantly liable to be cut into strips or otherwise injured. By doing away with the rest, the cloth has the opportunity of falling, moving, or springing away from the blade when any very large knot or extraneous substance is presented to it and the cutters. The manner in which the cloth is borne against the under surface of each of the blades O, viz. by means of a ledge or rule S. or any equivalent in rear of each blade, we may dispense with the swing-bar which is used in the machine of Courlier to bring the cloth up to the blade, it being subject to the same objections as in the rest. The machine of Courlier is described at page 8 of Traité Théorique et Pratique de l'impression des Tissus, par J. Persoz, tome deuxieme, Paris, 1846. Mr. Whipple claims for his invention the manner of supporting the cloth during the performance of the cutting operation, viz. by the under side of the blade o of each of the series of cutters in combination with two ledges SS, or other mechanical equivalents whose upper edges shall be arranged in a plane with or a little above the said blade; the same enabling him not only to dispense with a rest such as in common shearing machines, but with the swing-bar used in the machine of Courlier. He also claims the combination of two or more series of helical cutters E F G H, blades 0, dc guide-rules SS, &c., and drawing-rollers as arranged, and operating together substantially as above specified. Mr. Whipple also claims the apparatus by which the cloth is received at the front end of the machine, and caused to pass centrally into it or towards the cutters. Said apparatus being a combi- nation of a rocking-bar, two pulleys, and two great pinions and racks or any mechanical substitute, the whole being arranged and made to operate together substantially as described. Mr. Whipple further claims in the machine's combinations with the shearing machinery, the apparatus arranged over it for the purpose of removing the lint by upward currents of air as described; and the reciprocating carriage or moving platform for folding the cloth. in combination with the shearing machinery, the same being arranged and made to operate substantially as above explained; and the set of parallel bars dᵃ, e$, as combined with and applied to the shearing mechanism in manner and for the purpose before described. COCKS, proportions of. See DETAILS OF ENGINES. CONDENSING ENGINE of thirty-horse power, by Neilson and Mitchell, Glasgow. This form of beam-engine, in which the frame is composed of six fluted columns, supporting an entablature for carrying the main centre pedestals, has a very light and handsome appearance, and besides possesses the maximum capability of resisting severe working strains. It belongs, indeed, to the most economical class of engines, as respects durability and expense of maintenance for repair. Fig. 891 is a side elevation of the engine, with a portion of one of the columns at the steam-cylinder Digitized by Google CONDENSING ENGINE. 285 ERIE Gilling Ad B 802. H of B x B K N C M 991. a m и Digitized by Google 286 COINING MACHINE. end removed to allow the internal arrangements of the cylinder and nozzles to be shown in section. The section is taken in the plane of the axis of the cylinder, and is continued through the air-pump, condenser, and hot-water pump. Fig. 892 is an end elevation taken upon the cylinder end of the engine. General Description.-The sole-plate A consists of a single casting, with three shoes in each of the side-pieces, which are bored to receive the turned feet of the columns. The entablature C consists likewise of a single casting, with corresponding recesses bored to the diameter of the projecting ends of the columns, which are firmly secured at top and bottom by strong cotters. The main centre pedestals D D, are bolted to the entablature immediately above the middle columns. The steam-cylinder consists, as usual, of a separate casting from the valve-casing, which is joined to the cylinder with red lead cement, both faces being previously planed and fitted; and has two packing- ports c c, fitted with doors, which can be removed to admit of the packings on the back of the valve being examined and renewed when necessary. The valve is of the long-D kind, and is worked by a spindle passing through a tube at the lower end of the casing, and connected to a sliding stuffing-box 20, which is provided with two projecting pins for connecting it to the links of the rocking-shaft v. This shaft receives its motion from the eccentric t, upon the crank-shaft U, by means of the rod и. The cold-water cistern N is placed, as usual, in the masonry of the foundation, and contains the condenser K and air-pump M. These communicate by the passage L, in which is the foot-valve f, opening towards the air-pump. The condenser is slightly conical in shape, and the upper and narrower end is provided with an internal projecting collar, for the purpose of receiving the extremity of the exhaust-pipe J, which being made tight with hemp packing, thus forms an expansion joint of the simplest kind, and quite sufficient for the purpose. The lower end of the condenser enters slightly into the passage L, through a hole cast in the upper surface of the latter, and is supported upon it by a flange cast round the condenser for that purpose. The air-pump is attached to the foot-valve passage in a similar manner, but projects downwards considerably more, for the purpose of giving the pump a better hold of the water. The valve of the air-pump bucket g is of the perpendicular-lift, or pot-lid kind, as is also the discharging valve h. Action of the Engine.-To exemplify the action of the engine, let it be supposed that the throttle- valve is open, and occupies a position parallel with the axis of the steam-pipe I, thereby allowing a passage for the steam from the boiler to the valve-casing; although the piston is, in the present instance, at half-stroke, still, on account of the lap of the valve, the steam cannot enter the cylinder to start the engine, for both of the steam-ports e e are shut, as represented in the section. But the steam being thus admitted into the valve-casing, if the blow-through-valve b be now open, (as shown,) the steam will immediately flow into the condenser, and opening the foot-valve f, will expel the air, with which we may suppose it to be filled, through the air-pump bucket and delivery valves. When the air is expelled,-which is known to be the case as soon as pure steam is seen to issue from a small valve, called the snifting-valve,the blow-through-valve is shut, and the injection-cock opened to admit a shower of cold water from the cistern into the condenser, which, immediately condensing the steam in the latter, and in the passage L, forms of course a vacuum in them. The rocking-shaft v must now be moved by a portable lever which fits into a socket on the shaft, (seen in Fig. 892,) until the pin in the fork of the working-lever comes beneath the gab of the eccentric-rod u; this motion will place the slide- valve d in the proper position for opening a communication between the valve-casing and the lower part of the cylinder, and between the upper part and the condenser. The atmospheric pressure being thus in great measure removed by the expansion of the air above the piston, into the condenser, and the steam being made to act upon the piston underneath, will cause motion of the piston in an upward direction, which will be transmitted through the piston-rod o to the beam R, and thence by the con- necting-rod S to the crank T, upon the fly-wheel shaft U. Motion being thus induced, when the piston arrives at the end of its stroke, the momentum of the fly-wheel will carry the crank over the lower centre, by which time the eccentric will have reversed the position of the slide-valve; a communication will now be opened between the condenser and the lower part of the cylinder, and between the boiler and the upper end, thereby producing a downward motion of the piston, and consequently continuous revolution of the fly-wheel shaft. The injection water, together with that resulting from the con- densation of the steam, meantime flows along the passage L, through the foot-valve f. and is pumped away by the ai *-pump M, into the hot-well O, from which it flows back to the cold water reservoir. It is also from the hot-well that the boiler is supplied with water, by means of the hot water or feed- pump, shown in section in Fig. 891. The plunger of this pump receives its motion from the main beam, to which it is attached by the rod s.-The inlet valve of the pump is connected by the horizontal pipe j, with the hot-well, and through this pipe the water is drawn by the ascent of the plunger. which, in its return stroke, discharges the water which had passed into the pump through the outlet valve at P, into the supply pipe k. The supply of cold water is maintained in the cistern by the pump Q, which com- municates with the cistern by the pipe m. The governor W consists of a vertical spindle revolving in bearings within the column E, and is driven by a pair of bevel-wheels from the fly-wheel shaft. The upper end of this spindle is hollow, and, at that part upon which the sliding collar works, is slotted through to allow of a connection between the collar and the rod, which passes down through it. The divergence or collapse of the balls, as the engine moves with greater or less velocity, produces a vertical motion in this rod, which, by means of a system of rods and levers z, is conveyed to the throttle-valve, and thus the speed of the engine is regulated. COG-WHEELS. See DETAILS OF ENGINES. COINING MACHINE. This machine for stamping money was invented by M. Thonnelier, and com bines economy with perfection of workmanship. durability of the machine, and safety to the operatives. The moving power applied to a winch, or rather a steam power, turns я fly-wheel which governs it, and sums up all its powers at the moment the piece is stamped. To the axle of this fly-wheel a spiral Digitized by Google COINING MACHINE. 287 893. 894. P P N C o L & E J R. I J H O Q 896. 897. e 895. X 898. P 899. C c Flz. 893, lateral elevation of the ma- a lever G, fork-shaped, bearing the two tremity an instrument to take the coin chine. balls H, hold the case against D. The off, should it be attached to the supe- A, principal axle turned by a winch supporter and the lever of the case re- rior. or moving power. volve round an axle in d. This portion of the machine com- B, connecting-rod giving to the lever I, an iron lever receiving from an- prises several pieces; viz. the side- C the movement of the winch adapted other lever concealed by the machine, plates of the ferrule; the ferrule, &c. to the axle A. an impulsion transmitted by the eccen- L, a tube which receives the metal C, lever whose centre of movement tric fixed to the plate o of the fly- about to be coined. is at a, in the interior of the cast-iron f wheel N these two levers are fixed to M, a passage through which the coin P: it makes the second cylinder b re- the axle J, which is the means of pla- passes to fall into the basket. volve the are of a circle. cing the metal, and of drawing it off N, fly-wheel. D, a force column of steel. It moves when stamped. o, a cast-iron plate attached to the at its lower part, in the box E. Its up- i, a lath communicating with the axle of the fly-wheel. per portion is joined to the lever by lever I, and destined to raise the point P, cast-iron case of the machine. the intervention of the steel cylin- c on a level with the side-plate of the QQ, four cast-iron columns giving der b. ferrule. support to the frame of the machine E, a sliding-case leaning against c. e'. inferior stamp. R, likewise made of cast-iron. It is maintained by a double beam F; K, placing hand. It has at its ex- Digitized by Google 288 COINING MACHINE. curve is adapted to direct the movements of a connecting-rod, which transmits to the moving parts the mechanism of placing and taking off the metal between the stamps, and withdrawing it from the ferrule after the money is stamped. The power accumulated by the fly-wheel, is transmitted through its axle to a winch, which acts upon two arms joined to each other by a hinge at their extremities, and forming a very obtuse angle, which can be opened or closed a little. When this angle is opened, the two other extremities of the arms or levers become more distant, and as the superior meets a buttress, it is the inferior one which moves; it is properly a funicular lever or mechanical knee. Thus the lower part of the inferior lever is drawn towards it resisting plane, when the angle of the two arms widens, but on the contrary it is carried away from the plane when the angle closes; the movements are produced by the connecting-rod and the winch fixed to the fly-wheel. The two stamps are placed, the one at the moveable end of the lever, above the metal to be coined the other is situated beneath, the two planes being parallel. The pieces to be coined are piled up in an iron cylindrical vessel, and at every turn of the fly-wheel, the nether piece is taken away, and pushed under the press, being contained within a ferrule which limits its circular diameter. When the lever rises, the coin spontaneously leaves the ferrule. Cylinders.-The principle of this press consists in two cylinders having their axes parallel, and turning in opposite directions. These cylinders have on their outer surface engraved matrices, smooth and fluted ferrules, as well as ferrules with inscriptions. Fig. 900 presents a transversal section of the machine perpendicular to the axis of the cylinders. Fig. 901 is a vertical section made through this axis. The cylinder A receives the movement of the moving power; its axle has length enough out of the case to have cogs B engaged into the pinion B', on the axle C. This axle has a fly-wheel C', and can be set to work by any moving power through the pulleys D'. The second cylinder A' is constructed almost like the first, and of equal diameter, having the same number of matrices. Two wheels E E' are connected with one of the extremities of the cylinders in order that they may receive motion. In the swollen centre of the second cylinder A', and on its surface, there are excavations to receive the matrices a, Fig. 902 they are cylindrical metallic disks e support the matrices, whose distance from the centre, or from the circumference of the cylinder, is thus governed. Buttresses b placed on each side of the matrices are inserted into the cylinders, to push the matrices outwards. This forces the iron out; which, when effected, the buttresses are sent back to their original position by the spring d. At the central part of the outer surface of the cylinder A, grooves are made to receive the ferrule matrices a', the form of which is hemispherical, Fig. 903, 80 that they can oscillate through the rotary motion of the cylinders. The plane surface which terminates each matrice, and which is engraved, passes through the centre of the sphere, but the outer circumference of this surface should be some- what eccentric, to the surface of the sphere. Pillows can be placed within the groove under the matrices; they are of steel, and can be regulated by a screw. The matrices are by this means secured from oscillations. Steel springs e, Fig. 900, act upon the sloped edges of the ferrule matrices, to forrce back these last to the place they should occupy, as soon as they are no more opposite the matrices a. A tube F. containing the pieces about to be coined, furnishes them to the matrices. The circumference of the second cylinder A is surrounded with steel plates f, which have at their centre a cylindrical hole of equal diameter with the matrices a; these plates serve to stamp the circumference of the coin. When the cylinders are placed as represented in Fig. 900, the lowest piece in the tube F is in contact with the surface of the plate; as soon as the matrice comes to the orifice of the tube, the piece falls into the vacuum formed by the plate, and comes in contact with the engraved surface of the matrice. The cylinder continuing its rotation brings the metal within reach of the ferrule matrice, and the coin is stamped on both sides at once. It is then pushed out of the matrice by b, assisted by the scraper g, which has a counterpoise. The turning-pieces of the cylinders are received in pillows which allow them no lengthwise displace- ment; and in order that the matrices may be retained in the same plane, perpendicular to the axis of the cylinders, these are exactly clamped between the two cheek-pieces of the cases which contain their pillows. Wedges pressed by screws h, hold the pillows firmly fixed. The coins, as they fall, receive no shock, and are received in a box enclosed within J, the frame-work of the machine. Such a machine coins more than 100 pieces in a minute, or 60,000 pieces in a day of 10 hours' continual labor. The moving power required is but slight. This press performs its functions without noise, and is not liable to be put out of order; its construction is simple, and it occupies little room. The work- man who attends it is perfectly safe during his labor. Should any accident or obstacle occur, the machine is so arranged that it stops spontaneously; the fly-wheel C' is maintained on the axle by a species of break, Fig. 901, which allows it to turn back without turning the axle, when a greater resistance than usual is experienced by the matrices, so that the attendant is made aware of the accident. New Method proposed by M. Béguin to stamp Money, Medals, and Jewelry.-This consists in placing within the matrices a certain number of steel stamps. These matrices being piled one upon the other, are enclosed in a rectangular box, and made to pass between two cylinders. This pressing is performed rapidly, and many pieces are worked in a short while. The stamps are placed within the matrices, and are of a slightly conical shape; in order that they may be retained at the same level, a strong plate covers the matrices. A thin plate is interposed between the two matrices, and is pierced with a number of holes equal to that of the stamps; its use Digitized by Google COINING MACHINE. 289 is to keep the pieces to be stamped in connection with the stamps; this plate is made of steel, having its surfaces even, and an equal thickness in all its points. The system is carefully fixed into a rectangular frame, which is of iron, and holds the different parts 80 firmly fixed, that they are not deranged while between the rolling cylinders. B F A 900. B a H A B J 903. B B 901. H J A É D 902. A COLD WATER PUMP, content of. See DIMENSIONS OF ENGINES, and DETAILS OF ENGINES. COLLECTING VESSELS: applicability of, to Locomotives. See MANAGEMENT OF ENGINES COLLAR FOR PIPES, in boring. See RAILWAY ENGINEERING. COMPARATIVE DIMENSIONS, of flue and tubular marine boilers. See BOILERS, VARIETIES OF. 37 Digitized by Google 290 CONWAY TUBULAR BRIDGE. CONDENSER, usually made of the same capacity as the air-pump, but the larger the better advantage of high condenser to enable the air-pump to drain it. See DETAILS OF ENGINES. Disadvantage of put- ting the main centre through the condenser. CONDENSING AND HIGH-PRESSURE ENGINES, difference between. See VARIETIES OF THE STEAM-ENGINE. CONNECTING-CRANK This machinery, or apparatus, for connecting two shafts so as to cause the same to revolve at different velocities, is illustrated somewhat in the following manner:- Let a b, Fig. 904, represent the pitch- 906. line of two wheels, the wheel a being twice the diameter of the wheel b; then for every revolution of the wheel a, the c wheel b will make two revolutions, and if a tracing point be attached at b', it g d will describe the straight line a a' upon the face of the larger wheel, and if an- I a other tracing point be attached at the opposite side of the small wheel b, such points will describe straight lines at right angles to one another during the revolu- tion of such wheels. In Fig. 904, is shown an elevation of the arrangement of levers for connecting two shafts together, so that they may re- volve at different velocities. Fig. 905, is a plan of one of the shafts which is pro- vided with a crank forming a portion of 904. the apparatus. In Fig. 906, a is a crank, 905. fixed upon the end of a shaft b, supported by suitable bearings; c is the crank-pin which supports the triangular arm d, through each end of which there are pins e e, in the same plane with the aforesaid shaft these pins support two connecting- f a rods f g, the lower end of the connecting- rod f being attached to the crank f', shown in the plan, the lower end of the k connecting-rod g being attached to the crank-pin g' of the plan; b is a pin fixed into the end of the shaft which carries one end of the connecting-link i, the oppo- site end being attached to the centre, or middle of the connecting-rod e, by the b pinj ; k is the axis of the shaft which is to receive motion from the shaft b, or vice versa ; consequently, if g be double the length of the connecting-link i, the point g' will describe a straight line 11, and if we suppose g to be attached at its lower end to the crank- pin g'. and also the rod f to the crank-pin f', and that the axes b and k revolve in suitable bearings, Ic will make two revolutions whilst b makes one revolution. There are other modifications of the above apparatus shown, for which the inventor claims machinery described for connecting axes or shafts, to revolve in connection at different velocities. CONWAY TUBULAR BRIDGE. The great engineering event for 1848 is the raising of the Conway Tubular Bridge, and which, after so much fear and anxiety, has been effected with great success. This work derives its importance not so much from its greatness, as from its opening the way for the adoption of a new system of bridge building, whereby the resources of engineering are very much extended. To build a bridge greater than those which have been made before, to make a railway longer than those which have yet been opened, or to construct a more powerful locomotive, is a great work; but it is of much greater importance to execute something entirely new. The engineer who has constructed the greatest lighthouse or the greatest dock in his day, may be overcome by some one else, and then his claim is at an end; whereas, the engineer who extends the resources of his art, has a clear and unique claim to distinction. Mr. Robert Stephenson has the merit of carrying out this system of tubular bridge building, and it will be a special event in his career, beyond the many works of con- structive skill he has already produced. The success of the Conway Bridge is none the less important, because it settles the practicability of that greater undertaking, the Menai Tubular Bridge. Thus progress in any one direction leads most certainly to greater exertion; and it is peculiarly necessary to give every encouragement to all attempts, which open a new career for the engineer, and give him greater means of exertion. We have thus given engravings of the tube and the lifting apparatus, and shall lay before our readers drawings of the ingenious Jacquard machinery, invented by Messrs. Roberts, for punching the plates. (See Jacquard Punching Machine.) The construction, when finished, is to consist of two tubular bridges, formed of wrought-iron plates, each tube being for one line of rails. We shall now confine ourselves to the description of one of the tubes, which was fixed in its place in March, 1847, and is shown in the accompanying engravings. Digitized by Google CONWAY TUBULAR BRIDGE. 291 Fig. 907 exhibits a transverse section of one of the tubes and the masonry of the pier, together with the lifting apparatus. Fig. 908 is a side elevation of 19 feet in length of the tube, resting on the masonry, and the lifting apparatus. Fig. 909 is a section through 12 feet in length of the tube, and section of the lifting apparatus. Fig. 910 is a plan of the top of the tube to the extent of 20 feet in length, 910. and plan of the hydraulic press. Fig. 911 is a front view of one end of the suspension girder, and Fig. 912 a side view. The tube consists of a shell or external casing, a a, of wrought-iron plates, from 4 to 8 feet long, and 2 feet wide by half an inch thick in the centre, and five- eighths of an inch thick towards the end of the tube, riveted together to T-angle-iron ribs, placed on both sides of the joints, and angle-gussets at the feet of the ribs to stiffen them; a ceiling, composed of 8 cellular tubes b, each 204 inches wide, and 21 high; and a floor containing 6 cellular tubes c, 271 inches wide, and 21 inches high. The whole length of the tube is 412 feet, and 22 feet sh inches high at the ends, and 25 feet 6 In m inches high in the centre, including the cellular tubes F at the top and bottom, running the whole length, and 14 feet wide to the outside of the side-plates. The upper cells are formed of wrought-iron plates, three- fourths of an inch thick in the middle, and half an inch thick towards the ends of the tube, put together with m m angle-iron in each angle of the cells; and over the upper joints is riveted a slip of half-inch iron, 41 inches wide. The lower cells consist of three-quarter- inch iron plates for the divisions, and the top and bot- tom of two thicknesses of plates, each 12 feet long, 2 feet 4 inches broad, and half an inch thick in the centre, and one-fourth of an inch thick at the ends, and 80 arranged as to break joint; and a covering plate of half-inch iron, 3 feet long, is placed over every joint on the underside of the tube. The external casing is united to the top and bottom cells by angle-iron, on both the inside and outside of the tube, as shown in Fig. 912. The ends of the tube, where it rests on the masonry, are strengthened by cast-iron frames d, to the extent of 8 feet of the lower cells; 6 cast-iron transverse I-shaped girders e, on the floor; 6 similar girders f, above; and upright cast-iron stanchions g, on each side of the tube, to which are bolted the ends of the girders, top and bottom, and also the cross-lifting girders h. In order to allow of the free expansion and contraction of the tube, the ends rest on 24 pairs of iron rollers i, connected together by a wrought-iron frame, and placed between two cast-iron plates j k, 12 feet long by 6 feet wide, and 4 inches thick. The lower plate is laid on a flooring of three-inch planks i, bedded on the stonework; and the tube is also suspended to 6 cast-iron beams m, the ends resting on longitudinal bearers n, 12 feet long, with a circular groove on the under side, supported by 12 gun- metal balls o, 6 inches diameter, standing upon an iron bed p, and supported on the ends of the cast-iron bearers q. The tubes are suspended to the beam m, by wrought-iron bolts r, and spade-pieces riveted on to the sides of the tube, as shown in Figs. 911 and 912. The lifting apparatus for raising this enormous weight was intrusted by Mr. Stephenson, to Messrs. Easton and Amos, engineers of the Grove, Southwark, to whom great credit is due for the very successful manner the tube was lifted. The machinery consisted of two steam-engines, erected in the recesses B of the corresponding tube, one on each side of the river; and each engine has a horizontal cylinder, 17 inches diameter and 16 inches stroke, with piston-rods working through stuffing-boxes at each end of the cylinder; each piston-rod has a cross-head, and gives motion by side-rods and cranks to two fly-wheels; and the ends of the two piston-rods work two forcing-pumps with plungers, 111/7 inch diameter, and 16 inches stroke. These pumps inject the water into the hydraulic press C, shown in the engraving, through the small tube 3. The press was erected on a stage constructed above the level of the top of the tube, and consisted of two cross-girders of cast-iron, each in two heights D, D', the lower one 4 feet high, and the upper one 2 feet 6 inches high; the ends resting upon cast-iron bearers E, imbedded in the masonry of the piers. Upon the cross-girders was fixed the casing F of the ram, which is 5 feet 2 inches long, by 3 feet 9 inches wide, cast with ribs; and on the top of the cylinder are fixed two vertical guide-rods G, G, 6 inches diameter, passing upwards through the cross-head of the ram, and a cast-iron girder H, nearly at the top of the tower, and 18 feet above the girders D'. The press consists of a cylinder, 1, firmly fixed in the casing, 371 inches diameter externally, and 20 inches internally; and the ram 2, 18} inches diameter, with a vacuity nearly seven-eighths of an inch all round, to receive the water injected from the pumps already described, through the tube 3, the orifice of which is three-eighths of an inch diameter; this tube is furnished with a lever-valve close to the cylinder, for safety, in case the pipes should burst. In the event of such a casualty, by an ingenious contrivance the lever-valve would be instantly closed, and the weight supported by the water in the cylinder. On the top of the ram is a cross-head 4, of solid castiron, 9 feet 10 inches long, 1 foot 10 inches deep, and 2 feet 4 inches thick, with two apertures, 2 feet 1 inch long, by 1 foot 11 inch wide, through which the lifting chains pass: and on the top of this cross-head are fixed two clipping vices or clams, 5, 5, each consisting of & pair of wrought-iron jaws, 3 feet long, 11 inches deep, and 6 inches thick, Digitized by Google 202 CONWAY TUBULAR BRIDGE. 907. H of to of to H G c & ! 0 C H of D D D D E T m m 3 6 3 8 b b b i q q h h 15 N h h Digitized by Google CONWAY TUBULAR BRIDGE. 295 909. 908. G G 5 8 8 4 3 3 c C " 9 9 F F D 12 D 12 D D D E E 13 The m THE 777 TTE 772 772 m III 777 772 22 b F 14 h 13 a h 16 h 0 05 d IIO 0 5 Digitized by Google 294 COP-SPINNER. and a winch which turns a small pinion 6, that takes into two cog-wheels 7, 7', fixed upon the heads of two horizontal screws, (8, 8', left and right handed,) passing through nuts in the two jaws of the clams. Thus it will be perceived, that as the winch is turned, the jaws are made to open or close, for the purpose of clipping the heads of the lifting chains; below these clams are two others 9, 9', for clipping the heads of the lower links. The two lifting chains consist of wrought-iron flat bars, in lengths of 6 feet from centre of bolt-eye to entre, and each bar is 7 inches wide and 11, 11, and 11 inch thick, with heads having shoulders 911. fitted to the jaws of the clams. Each chain contained nine links of eight and nine bars alternately, besides the two lower links, each consisting of five and four bars. The heads of the first or upper links passed through the m m m upper lifting clams, fixed on the top of the cross- head of the ram, and there secured by the jaws of the clams being screwed up taut; the second links passed through the lower clam, the jaws n of which were left open, and the heads of the two lower links were made to abut against the O under side of the lifting girders g h. When the pumps were set to work, the ram was lifted 6 feet, its full range; when it had attained this elevation the jaws of the lower clams 9, 9' were screwed up close and clipped the heads of the 912. T third links 11, and there held the chain firm; the jaws of the upper clams were then opened, and the ram lowered down to its original posi- tion, when the bars of the top links 10 were m removed. When this had been done, the jaws of the upper clams 5, 5' were again brought under the heads of the second links, and screwed up taut, so as firmly to clip the shoulders of the links, the jaws of the lower vice 9, 9' opened, and the ram was then set in motion to lift the tube another six feet, when the second links were removed as before described, and the b operation repeated as above, until the tube had been lifted the height required, about 22 feet to 24 feet. The power of the presses may be thus cal- q culated: the area of the ram being equal to 337.64 circular inches, and the force acting upon the plunger equal to 2.14 tons per circular inch, the two being multiplied together give 7221 tons, which is the force of one of the presses, and of the two presses 1445 tons. The actual weight lifted was estimated at 1,300 tons. The quantity of water used for each press is about 66 gallons. The tube was constructed on a platform erected on the shore of the river, close to where it was to cross and when finished, six pontoons, something similar to the large coal-lighters on the river Thames, were placed under the tube at low water, and which at high water lifted the tube off the piles upon which the stage was erected. It was then floated to its destination, and placed between the two towers, part of the masonry being left undone until the tube was put into its proper position, and as it was raised the masonry was built up under the tube. The time occupied in raising the tube and building up the masonry occupied four days; the actual space lifted per hour was 13 feet. COP-SPINNER. George H. Dodye's Improvements in Machinery for Spinning and Winding Yarn-This is a combination of the self acting mule and throstle, and has many advantages over the common method of spinning, and is equally applicable for filling and warp yarn. In the room usually occupied for 1,000 mule spindles, 1,500 may be placed, which will do the work of 3,000 spindles. It occupies the usual space required for warp spinning, but will spin 50 per cent. more yarn to the spindle than the best ring-bobbin spinning known to us in use, and with a saving of two-fifths of the power. It will spin 100 per cent. more yarn than the flyer spindle, and with one-half the power, compared to the quantity. There is a great saving in expense, by dispensing with bobbins. The spindle is more durable than the common one in use, being tapered to the top; and there being no bobbins or check-pins used, it maintains its balance at any speed required. It is not liable to get out of order. It is much more convenient to piece up the ends when broken, than the bobbin-frame. One cent per spindle is paid for tending warp-frames. and 1f cent for filling-frames, and twelve dollars extra for doffers, per week. The proprietors, Messrs. John C. Dodge & Sons, of Dodgeville, Attleborough, Mass., have their entire mill upon this method of spinning, and from 29 years' practical experience with other spinning, believe it to be the best in use. The following table exhibits the comparative product and cost of their old plan of spinning with that of their present improved cop-spinner:- Digitized by Google COP-SPINNER. 295 Bobbin throstles and mules, 4,600 spindles. 1847, 19 weeks product 25,775 lbs. warp, 23,831 " filling, cost, $1,116 69 u 25,974 " 1848, " u warp, " 24,523 " filling, 1,051 78 2)100,103 2)2,168 47 Average, " " " 50,051$ " " $1,084 23 Cop-spinner, 2,320 spindles. 1849, 19 weeks product 32,704 lbs. warp, 28,5741 " filling, 61,278₫ " at a cost of $845 50. The yarn was No. 30, and the average skeins per spindle daily, was seven, no allowance being made for stoppage. The specification of the patent states, that the peculiar object of the improvements which are applied to a throstle spinning-frame, is to wind the yarn, as fast as twisted, or when properly twisted, upon each of the spindles in a regular or proper shaped cop, which shall have a binding-thread between each two adjacent layers of yarn, in order to prevent the cop from falling apart when removed, or while being removed from the spindle. Fig. 913 exhibits a front elevation of the improved throstle-frame. Fig. 914 is an end elevation. Fig. 915 is a horizontal section, taken through the axis of the main drum, which drives the spindles and scroll-shaft; the other parts below the plane of the section being represented in top view. Fig. 916 is a rear elevation of the frame, with the exception of those parts of the mechanism which are situated above the tops of the spindles, and which are like those'in common use in throstle-frames. Fig. 917 is a vertical section of the scroll-shaft and parts connected with it. In the several figures, A A denote the cast-iron ends of a throstle-frame; B B are the step-rails of the spindles; C C, the upper bearing rails of the spindles; D D D, &c., are the spindles; E, the main drum by which they are driven; F, on each side of the frame, is the copping or ring-rail; G G, &c, are the guides to the threads in their passage from the front pair of drawing-rollers to the spindles; H is a series of drawing-rollers, such as are in use in other throstle-frames; I is the bobbin-frame or creel; K is the main driving-shaft, from which the drawing-rollers and other parts receive their motions; L is termed the scroll-shaft-it is situated beneath the main shaft, and extends transversely across the machine, and revolves in bearings a a, fastened to the step-rails B B. It is also supported by, and revolves in, a third box or bearing b, secured to a sustaining bar c, ends of which are respectively fastened to one end A of the main frame, and a transverse beam d extending from one lower girt e, on one side of the frame, to the other f. The scroll-shaft has a reciprocating partial rotary motion imparted to it; it being made to move first in one direction, viz. forwards, with a slow motion, and next in the other direction or backwards, with a much faster one. A dog or clutch wheel g is fixed upon a hollow shaft It, made to run loosely upon the scroll-shaft, in the position as seen in Figs. 915 and 917. The said shaft h has a worm-geer i fixed upon it, which is made to engage with an endless screw or worm k, attached to the lower end of a vertical shaft l, sup- ported by and made to revolve in suitable bearings. On the upper part of the said shaft 1 is a spur- geer m fixed upon it, which is made to engage with, and is turned by a pinion n, fixed on another vertical shaft o: see Fig. 914. The said shaft 0 turns in proper bearings and has a spur-geer p fixed upon it, which geer is made to engage with a spur-geer q fixed upon a third vertical shaft r, put in motion by two bevelled wheels s t, the former of which is placed upon it, and the latter upon the main driving-shaft k. Consequently, when the main shaft is put in revolution in the direction denoted by the arrow u, in Fig. 914, motion will be given to the clutch or dog wheel g, in the direction denoted by the arrow v. The clutch-wheel g consists of a circular plate, having a series of projections w w, &c., disposed at equal distances, as seen in Fig. 918, which is a side elevation of the dog-wheel, as removed from the scroll-shaft. The teeth w w, &c., project over the periphery of a circular plate y, which is fixed upon a hollow tube b', screwed to the scroll-shaft, and has a recess z cut in it, (as seen in Fig. 919, which is a side view of the plate y,) for the reception of a spring-dog a', the spring of which is secured to the hollow hub b'. A bent lever c' is made to turn upon a screw-pin d', inserted in the face of the plate y. The said lever should be so curved as to rest against the spring of the dog a', and when its outer end is elevated, to press against the spring of the dog, and move it and the dog inwards, or out of one of the spaces x of the dog-wheel and into its recess 2. A standard e' is fixed to the side of the frame for the lever s' to rest on. From the above it will be seen, that while the dog remains in any one of the spaces x x, &c, of the dog-wheel, the said dog-wheel will be so clutched to the scroll-shaft as to put the shaft in motion when the dog-wheel is rotated. When thus put in motion the shaft will continue to move until the lever c' is so borne against the stud e' as to press the spring-dog inwards, and out of the space x, in which it may happen to be. The scroll-shaft will be then unclutched from the dog-wheel, and left free to move in an opposite direction, and will drag the spring-dog around with it until it meets the succeeding notch x, and springs into it, and by so doing, again clutches the dog-wheel to the scroll-shaft. On the scroll-shaft is a cam or scroll f', Fig. 920, made to move freely on the shaft. This cam has a chain g' attached to it, Figs. 920 and 915. The chain is carried horizontally over a guide-pulley h', and thence downwards, and is connected to an arm i', which projects from a horizontal transverse rocker. Digitized by Google 296 COP-SPINNER. shaft k'. A similar transverse rocker-shaft l' is arranged parallel to the shaft k'. From each of the shafts h' l' an arm m' extends upwards, and is jointed to a horizontal connecting-rod n'. Each of these shafts has also two other arms o' o', or p'p', extending from it, Fig. 915. To each of these last-men- tioned arms one of four vertical rods q' q'q' q' is jointed. Each ring-rail F is indirectly supported on two of the rods q' q'; that is to say, small studs r' r', from its vertical guide-rods s' 8', rest upon the tops of said rods. H a V2 913. A Ф D r A 0 2 2 914. E SCALE.-1 foot=1 inch. no f From the above it will be seen, that when the chain g' is drawn forward, or in a direction towards the right-hand end of the main frame, each ring-rail will be raised upwards. So when the chain is suffered to move backwards, the ring-rails will be left free to fall down by their own weight. The scroll f is fixed upon a hollow shaft t', which revolves freely on the scroll-shaft L. A worm-geer 26' is fixed on the said hollow shaft t', and engages with an endless screw v', fixed on a shaft 20', which revolves in bearings in the tops of a frame x' which is fastened firmly to the scroll-shaft L. The said shaft 20' has a ratchet-wheel y fastened upon its forward end. The shaft 20' extends through one end of a vibrating lever a⁸, which is made to play loosely upon the shaft. The said lever carries upon its other end an impelling pawl b², which engages with the ratchet- whecl Over the ratchet-wheel is a retaining pawl c2, which is jointed to an arm d' extending upwards Digitized by Google COP-SPINNER. 297 from the frame x'. The ratchet-wheel y' has a small crank-handle b' projecting from its side to turn the whole back and lower the ring-rail when the pawls are thrown up, and when desirable. Directly under the rear end of the lever a² is a bent lever e⁹, which turns upon the scroll-shaft as a fulcrum. Its outer end rests, when in its lowest po- sition, on the top of a stationary standard f2, affixed to the lower girt of the cast-iron end of the main frame. The inner arm of the said lever 2 extends 917. directly under a horizontal projection g² applied to a vertical rod h², extending downwards from the adjacent ring-rail F. The said projection gª should be so adapted to the rod h² that it may be elevated or depressed by adjusting-screws and nuts, in order that its position may be regulated as circumstances F may require. The scroll-shaft has a cam i2 fixed firmly to it. The said cam is seen in Fig. 921, which represents a section of it, and the lever beneath it. It also exhibits the chain g', and various parts adjacent thereto. The cam i' is made to act upon and depress a lever k², whose fulcrum is at P. The said lever carries a roll m², applied to the side of its inner end, and resting on the chain g³. Now in order that the ring-rail may not fall so suddenly as to break the yarns, or not put on the cop a sufficient quantity of binding-thread, some kind of mechanism becomes necessary to cause it to fall with the required velocity. 915. D B Уг m SCALE.-1 foot=1 inch. A A An arm n², fixed to the scroll-shaft L projects downwards from it, and carries a small fly-wheel 02 on an axle p', extending horizontally from it. Said fly-wheel has a small pinion q2 affixed to it, which engages with a spur-geer 73 fixed to a tubular shaft 5², which runs loosely upon the scroll-shaft. On the said shaft 82 is a worm-geer t² which engages with an endless screw u², placed on the vertical shaft o, before men- tioned. The said endless screw u² should 80 revolve the geer-wheel t2 as to turn the shaft 8² and the geer-wheel nº in the direction of the arrow on said wheel r³. The wheel 73 will then act on the pinion, and put the fly-wheel 02 in rapid revolution in the direction of the arrow; this taking place while the ring-rail is being raised, will cause a considerable momentum to be generated in the fly-wheel, which rises upwards with the arm n³, which will be carried up by the forward movement of the scroll-shaft. Now when the ring-rail falls, the momeutum so generated in the fly-whoel will be brought into action in such manner as to cause the pinion q2 to so operate against its geer 7ˢ, as to counterbalance in a certain degree the tendency of the ring-rail to fall too suddenly. The ring-rail will thus be eased down, so as not to break the threads, and with the degree of velocity necessary to insure the laying of a due quantity of binding-thread on the cops. The ring-rail may be further counterbalanced by an adjustable weight v³, applied to an arm 202 ex- tending from the rocker-shaft k'. By means of the scroll f', the length of each successive layer of yarn composing the cop is regulated. The elevation of the ring-rail is gradually increased by the peculiar shape given to the scroll f', and the gradually turning said cam on the shaft. Fig. 922 represents a longitudinal and central section of a cop, placed on a spindle 1. The part a be def of the cop, is termed the bottom part, and all above, the top part. The first layer of yarn is wound on the spindle a distance an, equal to about one half of the length b c of the last layer composing the bottom part of the cop. From the above, it will readily be understood why the scroll or cam f' must be gradually turned on the scroll-shaft, so as to increase the length of each successive layer of yarn composing the bottom part of the cop. It is the purpose of the worm u', endless screw t', shaft 20', frame x', ratchet-wheel y, vibrating lever 38 Digitized by Google 298 COP-SPINNER. a², impelling pawl bª, lever e2, standard f2, projection g², and rod h², as before described, to produce the gradual rotation of the cam, both to form the bottom and top part of the cop. When the scroll- shaft is moved forward, the lever a² will be moved against the lever e2, and thereby cause the impell- ing pawl b², to turn the ratchet-wheel y' a short distance, 80 as to create a movement of the scroll or cam f' on the scroll-shaft. The movement of the ratchet-wheel is increased by elevating the outer end of the lever e², which may be effected by depressing the adjustable projection gª of the rod h². Owing to the manner in which the scroll f' is made, it becomes necessary to turn it somewhat faster on the scroll-shaft at first, while forming the lower portion of the bottom part of the cop, than it does as the winding of the said bottom part continues to progress. In winding the top part of the cop, the scroll has a regular progressive motion upon its scroll-shaft, and the portion b c d, Fig. 920, of its peri- phery is then receiving and acting on the chain g'; while the bottom part of the cop is being made, the portion a b, Fig. 920. is in action upon the chain. In order to cause the ring-rail to rise upwards with the increased velocity necessary to prevent the yarn from piling too much in one place, aid thereby destroying the conical form of each layer of yarn, the cam i², lever k², and roll m², are used, the cam being 80 formed as to properly depress the lever kª, to the extent required, to cause the roll m² to bear down upon the chain g', so as to produce the gradual increased rise of the ring-rail 922. 3 919. h L c I 921. a 918. 916. 2 D D 6 D IS A Vª q SCALE.-1 foot=1 inch. As it is very important that but very little yarn should be wound at the nose or upper part of each layer of the cop, the cam i² has an angular projection x². (see Fig. 921,) which as soon as the cam has completed its action in the lever h², shall in its turn depress the lever so as to cause a very sudden rise of the ring-rail sufficient to produce the effect required. A friction-spring 1/2, at the end A of the main frame, acts as a stop to gradually check the motion of the arm n², when it falls down. It often happens that the ring of the ring-rail may render it difficult to get hold of the end of the thread wound on the cop. In order to overcome this difficulty, the spindle, for about one inch and a half below its upper bearing, is made of the same size or diameter as the part which runs in the bear- ing, as seen at 2ˢ, in Figs. 913 and 922. By taking hold of the spindle when so made, it may be readily raised upwards, so as to carry the broken end of the thread above the ring of the ring-rail, and into such a position as will readily enable the operative to join the ends of the yarn when broken. In order to obtain the advantages of a small spindle, and with a diameter at bottom large enough to start the traveller without danger of rupture of the yarn, the part a³ of the spindle directly below that on which the cop is formed, is made of a diameter large enough to produce the lateral drag upon the traveller, required to overcome its inertia when first started, and give to it a velocity that will pre- vent the thread from breaking; and, before commencing the cop, a few turns of yarn are wound on the said part of the spindle. That part of the spindle on which the cop is formed, (viz. the part 63 c³,) is made of as small a size as will be allowable and admit of its possessing the necessary strength. The spindle 80 constructed is seen in the drawings. By this mode of making it, cops can be doffed without first being obliged to raise them upwards on the spindles by the hand far enough to allow of a Digitized by Google CORN-MILL. 299 few turns of yarn to be laid on that part of each spindle on which the cop is first commenced, as is generally done in mule spinning. A convenient velocity for the spur-geer rˢ, is one revolution to sixteen of the front drawing-roller; and for the clutch g, at the rate of sixty-four one-hundredths of a revolution to eighty revolutions of the front drawing-roller. The patentee mentions these proportions, but does not confine his invention to such. Mr. Dodge claims the combination of mechanism by which the scroll-shaft has a partial rotary for- ward motion imparted to it, and is allowed to fall or move backwards, the same consisting of the stand- ard e¹, or any equivalent, the bent lever c', the spring-dog a¹, the clutch or dog wheel g, or their me- chanical substitutes; the whole being arranged, applied to the scroll-shaft, and operated and made to operate together substantially. And in combination with the shaft, and machinery for imparting to it its rotative motion or motions, he claims the cam, and chain, and machinery connecting the shaft with the ring-rails. He further claims the combination of mechanism by which he is enabled to regulate the length of each successive layer of yarn composing the cop; the same consisting of the cam f¹, and made to rotate on the scroll-shaft; the worm-geer u', endless screw t', shaft w', frame x', ratchet-wheel y', vibrating lever a², impelling pawl b⁹, lever e³, standard f2, projection g², and rod h², extending down- wards from the ring-rail, or their mechanical equivalents; the whole being combined and made to operate. Further, in its application to the scroll-shaft, the combination of mechanism by which the fall of the ring-rail is regulated in such a manner as to prevent it from descending too suddenly so as to break any of the yarns; the mechanism consisting of the fly-wheel o², and machinery for turning it, as applied to the scroll-shaft, and made to operate in connection with it. And for the purpose of causing the ring-rail to rise upwards with the increased velocity necessary to prevent the yarn from piling too much in any one place, and thereby destroying the conical form of such layer of yarn composing the cop, Mr. Dodge claims the cam i², lever k², and roll m², as combined with the scroll-shaft, and the chain g'. And in combination with the machinery, he claims the projection x3, applied to the cam is, for the purpose of producing a very quick rise of the ring-rail, in order to finish the nose or upper extremity of each layer of yarn composing the cop. And he also claims the above-described manner of making each of the spindles, in order that it may be elevated so as to carry a broken end of yarn above the ring-rail, so that an attendant may readily seize it to piece up or join it to the thread proceeding from the draw-rollers, without being obliged to wait for the ring-rail to full downwards. He further claims the construction of the spindle directly beneath that part of it on which the cop is formed of a diameter proper to produce the lateral drag on the traveller, sufficient to overcome its in- ertia, and impart to it a velocity necessary to prevent the yarn from being broken in combination with making that part of the spindle on which the cop is formed smaller in diameter. COPPER BOILERS, Faults of. See BOILERS. CORNISH BOILERS. See BOILERS. CORNISH ENGINE, Causes of the economy of-See BOILERS. Structure of-See VARIETIES OF THE STEAM-ENGINE. Particulars of, Performances of-See DETAILS OF ENGINES. Lantern brass to cover the cylinders of-See DETAILS OF ENGINES. CORN-MILL By William Fairbairn, Manchester. Among the mechanicians who have contributed to the improvement of that description of machinery now under consideration, Mr. Fairbairn, of Man- chester, occupies a most distinguished position, and accordingly, we find that he is most extensively em- ployed in the erection of corn-mills throughout all parts of the continent of Europe. The exam- ple which we have chosen for detailed illustration is a small mill of three pairs of stones, erected by him for His Excellency the Seraskier Halil Pacha, of Constantinople. It is interesting, as exhibiting, within a small compass, an epitome of all the processes carried on in larger establishments, and thereby enabling us to show the mechanism by which these processes are effected on a larger scale than we could otherwise do. Enumeration of the Figures.-Fig. 923 is a sectional elevation of the mill, the line of section being taken in a longitudinal direction, and exhibiting the position of the stones, the engine, and driving geer- ing, and of such portions of the subordinate apparatus as are visible on the side of the mill which is exposed to view. Fig. 924 is a sectional plan corresponding to the above, and taken on a horizontal line passing through the lower story of the mill. Fig. 925 is a transverse section of the entire mill, in which are shown the garners for undressed and dressed wheat, the mechanism by which it is cleaned and conveyed from the former into the latter, the sack-tackle, &c. Fig. 926 is a sectional plan corresponding with the plan Fig. 924, the line of section being taken through the second story of the mill. General Description.-The house in which this mill is contained consists of an assemblage of plates of sheet-iron, A A A, of a suitable thickness, consolidated and bound together by the cast-iron columns B BB, and by the strong cast-iron girders CCC, situated at such a height as to oppose and neutralize the strain of the principal working parts. It is surmounted by an arched roof DD, formed of plates of corrugated sheet-iron. A wall of masonry EE is erected in the interior, for the purpose of affording a foundation for the bearings of the heavier geering of the mill. The motive power is supplied by a high- pressure steam-engine F, of 12-horse power, its principal working parts are wholly inclosed within a large cast-iron column. By this arrangement great firmness and stability is imparted to the engine, while the space which it occupies is reduced to the smallest possible dimensions. The boilers GG are situated in an adjoining part of the house, and their flues H H are formed, in the usual manner, of brick- work, abutting on the one hand against the wall E, and on the other against the side of the house itself. Thus the engine and boilers occupy nearly the entire half of the lower story of the mill. The whole erection is strengtheued and bound together by the cast-iron beams III, which pass transversely through the interior of the house, and are supported, in the middle of their length, by the columns J J. On these beams, also, the flooring of the lower and upper flats is disposed. Digitized by Google 300 CORN-MILL. The fly-wheel KK of the steam-engine, is formed with teeth on the exterior of the rim, thus serving at once to regulate the velocity and to transmit the power of the steam-engine to which they are at- tached. The spur fly-wheel KK, the diameter of which is 9 feet 34 inches, geers with the pinion L of 4 feet 10} inches diameter; consequently, the velocity of the crank-shaft is nearly doubled upon the horizontal shaft MM, to which the latter is fixed, and which, by means of the bevel wheels and pinions N NN, gives motion to the stones contained within the stone-cases PPP. The shaft MM has a bear- ing upon the wall E, close to the back of the pinion L, and one in each of the standards 000, to which the mechanism necessary for impelling and regulating the action of the stones is attached. N a I B 923. a B SCALE.-20 feet=3 inches. The corn to be ground is deposited in the upper floor of the mill in the large garner QQ, from which it is conducted through the spout R, into the acreening-machine SS, where it is cleansed of the dust and other extraneous matter which is found more or less combined with it. This machine consists of a species of cylindrical sieve, formed of wire-cloth, and partitioned inside 80 as to resemble an Archime- dean screw. It is mounted upon an axis, and revolves with a considerable velocity in the interior of a close box, in which it is set at an angle with the horizon. The corn enters at its upper extremity, and, after being thoroughly agitated by its passage through the partitions in the interior of the screen, and thereby divested of the greater portion of the refuse with which it was mixed, falls into a spout U, at Digitized by Google CORN-MILL. 301 its lower end, which conducts it to the elevator V; being subjected, in its passage through this spout, to the action of a blast from the fan T, by which the remaining portion of the sand and dust that escapes with the grain is carried off by a passage leading to the exterior of the house. The grain, after being. thus cleansed, is caught up by the elevator V, and raised nearly to the summit of the mill, where it is delivered, through an inclined spout X, into the creeper-box YY, by which it is distributed into the feeding-garners ZZZ 924. SCALE.-20 feet=3 inches. R M K - H The elevator consists of a long endless chain of small buckets formed of tin-plate and mounted, at regular distances, upon a leather band passing over two pulleys inclosed within the cast-iron frames VV. The uppermost of these pulleys is driven at a moderate velocity by a belt, and the buckets, passing in succession the opening by which the grain is delivered from the screen, become each charged with a small portion of it; this they convey through the wooden pipes or boxes W W, in which they are inclosed, to the upper extremity of the chain, where they deliver their contents into the spout X. The contrivance just described is applicable only to the raising of the grain or flour from a lower level to a higher. For horizontal transport, modern millwrights make use of an apparatus called the creeper, a long endless screw with a wide pitch and thin threads, inclosed in a wooden box or trough, of dimensions slightly greater than its own diameter. It is made to revolve upon its axis, by means of a belt and pulleys, at a velocity corresponding with that of the elevators, and, being restricted from moving longitudinally, the threads, or rather leaves, of the screw, force the grain introduced at one end Digitized by Google 302 CORN-MILL. of the trough to the other. The action of the screw in the case of the creeper is identical in its nature with that of the endless screw in giving motion to a worm-wheel. The corn which is supplied to the garners ZZZ, falls through the feeding pipes A' A' A', into the hoppers, by which the grinding apparatus is surmounted. After being reduced into flour, it falls through the pipes B' B' B', into the creeper-box Y' Y'Y', by which it is transferred to the elevator V.- By this elevator it is again raised to the summit of the house, and carried by means of the creeper Y' to the dressing-machine S'. It may be remarked that, besides the great saving in manual labor effected by the use of these contrivances for transporting the flour from one part of the mill to another, they are attended by another very important advantage: by exposing the flour liberally to contact with the air, the heat evolved during the process of grinding is abstracted, and the moisture evaporated; an operation which it is of essential importance that it should undergo previous to the process of dressing. 5 925. as Q I $ A U P C I B If SCALE.-20 feet=3 inches. This machine, which is very similar in external appearance to the screening-machine already de- scribed, consists of a hollow cylinder covered with wire-cloth of different degrees of fineness, the finest being at the end which is most elevated. Within the cylinder, which is stationary, a circular brush re- volves, in contact with the wire-cloth of which it is composed. The flour which is fed into the cylinder is, by the motion of the brush, sifted or rubbed through the wire, the finest through the upper end, the second through the next division, and so on, till the bran falls through the end of the cylinder, being too coarse to pass through any of the wires.* The different products thus separated are then stored in sacks, or otherwise disposed of as may be rhost convenient. The sack-tackle is very simple, and will be readily understood from the drawing. It consists of a barrel H, provided with a rope of sufficient length to reach to the lower floor of the mill, and fitted to . On the processes undergone by the corn both previously and subsequently to the grinding. much of the success of the whole operation depends. In place of the wheat-screen, an apparatus called a sheeling-mill is employed in some establish- ments. This consists of a pair of ungrooved millstones working at such a distance apart that the grain is merely rubbed between them, but not cut or broken. From the stones it is received upon an Inclined sleve, where the heavier parts of the refuse fall from it. and is then exposed to the blast of a fan which deprives it of the remaining lighter portions. For dress- ing the flour, bolting-machines are very generally used either in combination with, or in place of, the dressing-machines described above. These contrivances, however, come more within the province of the miller than of the millwright. Digitized by Google CORN-MILL. 303 $ 9 926. M. SCALE.-20 feet=3 inches. M K E 8 131 Literal References. ions by which the millstone spin- as bevel wheel and pinion giving mo- dies are driven. tion to A A A, the sheet-iron sides of the 000, the standards or framework of CC, the vertical shaft of the mill. house in which the mill is erected. the grinding machinery. b, bevel wheel and pinion giving mo- BB B, the columns for supporting and PPP, the millstone cases. tion to strengthening the sides of the house. QQ, the large garner for uncleaned E' E', transverse horizontal shaft. CC, horizontal beams passing all round wheat. cc, a set of small bevel geering giving the house at the level of the first R, spout leading from the garner Q to motion to floor. S, the screening-machine. F F, the longitudinal horizontal shaft. DD, the roof formed of corrugated S, the dressing-machine. d, pulley on the transverse shaft for iron. T, a fan attached to the wheat-screen. driving the screen. EE, a wall of mason-work affording a U, a spout leading from the wheat- c, pulley on the transverse shaft for foundation for the bearings of the screen to driving the dressing-machine. driving geering, &c. V W, the first elevator. f, pulley on the longitudinal shaft for F, the steam-engine by which the mill X, passage conducting the grain from driving the fan. is driven. the first elevator to 8, pulley on the longitudinal shaft for GG. the boilers. Y YY, the creeper by which it is dis- driving the elevators and creepers. H H, the flues and seat of the boilers. tributed into h, pulley on the longitudinal shaft for III, transverse cast-iron beams for fur- ZZZ, the garners for feeding the driving the intermediate shaft. ther strengthening the house. stones. i, pulley on the intermediate shaft for JJ, columns for supporting the beams A' A' A', the feeding pipes made of tin driving the sack-tackle. III. plate. G', the intermediate shaft for convey- KK, the spur fly-wheel of the engine. B' B' B', the pipes by which the flour ing motion to L, pinion working into the above, and is withdrawn from the stone-cases H' H', the sack-tackle. fast upon into I', a lever for starting and stopping the M M, the main horizontal shaft of the Y' Y'Y', the second creeper-box, con- sack-tackle. mill. ducting it to K' K', hatchways by which the sacks NNN, bevel mortise-wheels and pin- V' W', the second elevator. are admitted or withdrawn. Digitized by Google 304 CORN-MILL. revolve in bearings attached to the roof; it receives motion, when required, from a belt connecting the pulley on its axis with a shaft G' worked by the engine. The length of this belt is 80 adjusted that the sack-tackle may remain at rest, or be set in motion, according as the long lever I', (the action of which is to tighten or relax the belt as may be required,) is drawn to the right or left. The geering by which the subordinate machinery of the mill is driven consists, first, of an upright shaft C'C', set in motion by a pair of bevel wheels a, from the main horizontal shaft MM. This shaft has its lower bearing in an arched standard embracing the shaft M, and at its upper extremity it is supported by a plummer-block bolted to a double bracket D', imbedded in the wall E. Its motion is here transferred by means of another pair of bevel wheels b, to the horizontal shaft E', passing trans- versely across the mill. On this shaft are fixed the pulleys d and e, which drive the screening and dress- ing machines; and a set of small bevel wheels c c, serve to transmit the motion to the longitudinal shafts F' F', by which the elevators, creepers, &c., are propelled; as also the short shaft G', by which the sack-tackle is driven. The dimensions of the various wheels, pinions, and pulleys, employed in this mill, and the velocities imparted by them to the machines driven by them respectively, are given in a tabular form below. Steam-engine F, 12-Horse Power, makes 40 Revolutions of Crank-shaft per Minute. Driver. Driven. Result. Description of Geering. Diameter. Revolu- Diameter. Revolutions per Minute. Feet. In. tions. Feet. In. Spur Pair K L 9 34 40 4 10} 76 on horizontal shaft M. Bevel Pairs NNN 3 6 76 1 10 140 on the stones. Bevel Pair a 3 6 76 1 10 140 on upright shaft C'. Bevel Pair b 3 0 140 1 9 242 on transverse shaft E'. Bevel Pairs cc 1 1} 242 1 111 140 on longitudinal shafts F' F'. Pulley d 1 6 242 1 0 363 on screening-machine S'. Pulley e 1 6 242 1 0 363 on dressing-machine S'. Pulley f 2 0 140 0 6 560 on fan T. Pulley g 0 8 140 2 0 46.6 on elevators and creepers. Pulley h 1 0 140 2 0 70 on intermediate shaft G'. Pulley i 1 6 70 2 0 47 on sack-tackle H'. Details of Corn-Mill.-The figures exhibit the constructive details of the grinding apparatus, and of some of the subordinate machinery employed by Mr. Fairbairn in all his most recently erected mills, whatever may be their extent and the number of stones they contain. The height of the stone floor (or level at which the mill-stones are situated) from the foundation varies slightly in different mills, and the diameter of the driving-shaft must be increased or diminished in proportion to the num- ber of pairs of stones to be driven, and to the distance of each individual pair from the prime mover. The only deviations from the form and dimensions here given, are, in the former case, to alter the length of that part of the framing called the cone B B, and in the latter to increase or diminish the diameter of the bearings in the plummer-block G G. Enumeration of the Plates.Fig. 927 is a front elevation of the grinding machinery, exhibiting the external appearance of the whole. Fig. 928 is a general section taken on a vertical plane at right angles to that of the elevation, Fig. 929. In this view the millstones and the whole grinding apparatus are shown in combination. Fig. 929 represents a plan of the cone, showing the number and disposition of the adjusting screws of the lower stone. Fig. 930, an enlarged external view of the feeding tube; Fig. 931, an enlarged elevation, and Fig. 932, a plan of the lever for regulating the supply of grain admitted to the stones. Fig. 933, a plan of the ring forming the top of the tripod on which the feeding hopper is supported. Fig. 934, a plan of the ring by which the adjusting wedges of the upper bearing of the mill-spindle are regulated. Fig. 935, an enlarged view of the mill-spindle. Fig. 936, an external elevation; Fig. 937, a vertical section; and Fig. 938, a plan of the Ryne, or crosshead by which the upper stone is connected to the spindle, and the grain supplied to the stones. Fig. 939 is a face view, and Fig. 940, a plan of the sockets in which the ryne works. Fig. 941 is a plan of one of the millstones, showing the disposition and mode of drawing the grooves on its surface. Fig. 942 is a plan of the cast-iron socket inserted into the lower stone, and forming the upper bearing of the mill-spindle Fig. 943, an edge view, and Fig. 944, a front view of the brass bushes fitted into this socket. Fig. 945, a face view, and Fig. 946, an edge view of one of the wedges by which the brasses of the mill-spindle are adjusted. Fig. 947 is a sectional plan of the principal standard or frame of the mill, showing the mode of ad- justing the lower end of the mill-spindle. The line of section is taken on the dotted line 1-2 in the general section, Fig. 928. Fig. 948 is a sectional plan of the standard taken on the line 3-4, Fig. 928, and exhibiting the mech- anism for disengaging the driving pinion when necessary. Digitized by Google CORN-MILL. 805 Fig. 949 is a partial section of the standard and attached mechanism. This section is taken on a plane corresponding with that of Fig. 927. Fig. 950 is a side elevation, and Fig. 951, a plan of the plummer-block of the driving-shaft. Fig. 952 is an external elevation, and Fig. 958, a plan of the driving pinion of the mill. Fig. 954 is a side view, and Fig. 955, a plan of the lever for adjusting the lever of the upper stone. Fig. 956 is an edge view ; Fig. 957, a front view of the screw and nut by which the adjusting lever is regulated. Fig. 958 is an edge view ; Fig. 959 a plan of the key used for working the above adjusting ap- paratus. b 6 E 928. D D D E D 927. 0 0 P 0 C L B B A I I I N M M F H A SCALE.-16 feet=7 inches. The figures 960 to 965 represent the different subordinate parts of the mechanism by which the lower end of the mill-spindle is supported, and its position adjusted. Figs. 966 to 970. These figures represent the details of the mechanism employed for raising the dri- ving pinion out of geer with the wheel. Fig. 971 is an external elevation; Fig. 972, a vertical section; and Fig. 973, a plan, on an enlarged вся'е, of the small apparatus used for regulating the feeding of the mills. Figs. 974 to 977. These figures give a representation, on a large scale, of the various adjusting 39 Digitized by Google 306 CORN-MILL. screws required in this grinding machinery the first two are for adjusting the lower end of the mill- spindle the third for centering, and the fourth for levelling the lower or fixed stone. Figs. 978 to 982. These figures represent general and detailed views of a species of small portable crane or jack, employed for the purpose of raising and replacing the upper millstones when they re- quire to be redressed. Fig. 983 is a side elevation, and 984, an edge view of the lower elevator framing. Figs. 985 to 990. These figures give minute representations of the construction of the creeper. Figs. 985 and 986 are a section and external view combined to show the mode of junction of the differ- ent lengths; Fig. 987 is a transverse section of the creeper-box; Fig. 988, a plan of the plug or con- necting block; Fig. 989, a view of the stud or journal which terminates the range, and Fig. 990, of that which commences it, and on which the driving-pulley is keyed. 929. 934. -0 B D 0 B 935. 931. J 945. f 930. 936. 946. 948. 939. 937. 2-91 J 947. 938. d; X 940. 939. General Description. The Framing.-A strong cast-iron standard or framing A A, securely bolted to a stone foundation by two holding-down bolts, incloses the principal part of the driving and adjusting geering for each pair of stones. It is made somewhat in the form of an oblong box, and is traversed by two horizontal diaphragms or partitions, cast of a piece with it, the upper one for sustaining the lower bearings of the mill-spindle, and the under, the plummer-block of the driving-shaft. It is surmounted by a large bell-shaped casting BB, called the Cone, firmly bolted, by a flange at its lower end, to the standard, while the upper extremity is expanded, and terminates in a cylinder, of a diameter somewhat greater than that of the millstones, the lower of which rests, and is secured, within it. Two straight and broad flanges are cast at the opposite sides of the cylindrical part, for the purpose of bolting the cone to the beams of the mill, or to the same parts of the framing of the contiguous pairs of stones, while another circular flange passes all round, for sustaining the flooring. Three large openings are left in the upper part of the cone to give access to the interior, and it is provided with suitable arrange- ments for the reception of the several adjusting screws required for the setting of the lower stone. The Stone-Case and Feeding Hopper.-Above the cone, and of the same diameter with the cylindrical part of it, is placed the stone-case C, which surrounds the upper stone, and serves to confine the flour which is the result of the grinding. This is simply a cylinder of thin sheet-iron, resting upon the stone floor, and having affixed to the top of it a ring of wood, on which the tripod for supporting the feeding apparatus is set. This cover is made open in order to admit the air freely between and around the stones during the process of grinding. A cast-iron ring D, supported by three malleable-iron legs a a a, forms a sort of tripod in which is placed the hopper E, which receives the grain from the garners above, Digitized by Google CORN-MILL. 307 through the feeding pipe b, and supplies it to the stones by means of the feeding apparatus to be here- after described. A piece of coarse wire gauze is placed in the hopper E to intercept any foreign body that may descend with the grain. The Driving Geer.-The driving shaft F is part of the line of horizontal shafting which is common to the whole range, and which receives its motion from the prime mover, generally through the inter- vention of a single wheel and pinion. The velocity of this line of shafting is usually from 70 to 80 revolutions per minute, with stones of the diameter of those in our examples. The different lengths of which it is composed are connected together by couplings of the same description as that described and represented at Figs. 950 and 951. The shaft F revolves in brass bearings, fitted into a plummer-block G, bolted to a sole formed, as before noticed, in the standard A. The strain of the shaft being en- tirely in a downward direction, this plummer-block requires no cover, the journal being simply protected from injury by a slight brass cap. A large bevel mortise-wheel H, working into the pinion I, on the mill-spindle, serves to transmit the motion of the shaft F to the latter. The pinion is not fixed immoveably upon the spindle, but is capa- ble of sliding vertically upon it by means of a sunk feather. The Mill-Spindle and its Appendages.-The mill-spindle JJ is made of the best forged-iron, accu- rately turned over its entire length, and rises perpendicularly through the standard A, the cone B, and the lower millstone. It is attached to the upper, or running stone by means of a cast-iron piece K, called the Ryne, which combines this function with that of regulating and delivering the supply of grain to the stones. It is in the form given to this very important part that Mr. Fairbairn's most recent im- provement in grinding machinery consists. It will be observed by the drawings, Figs. 936 to 940, that it forms a species of universal joint; the small steel crosshead c c on the top of the mill-spindle fitting into corresponding bearings in the ryne, while the projecting tails dd, cast upon it at right angles to the former, work in similar bearings formed of small cast-iron pieces sunk into the stone. By this arrangement it will be observed, that the connection between the mill-spindle and the upper stone is complete, while at the same time it admits of the free and unconstrained action of the latter against the grinding surface of the lower stone. The lower, or fixed stone is perforated by a large square hole in its centre, into which the cast-iron block L, Fig. 942, is firmly fixed by slips of wood and wedges. Into this block are fitted the three brass bushes e e e, which form the upper bearing of the mill-spindle. These are adjusted by means of the wedges fff, the screwed tails of which pass downwards through the cast-iron ring g, and are regulated by thumb-screws on each side of it. The large openings in the cone, before alluded to, afford access for the working of these screws. Small semicircular chambers are formed in the socket L, be- tween each bush, and filled with hemp and tallow, for the lubrication of the mill-spindle; and the whole is carefully protected from dust by slips of sheet-iron screwed over it, Fig. 941. 941. a 933. 943. L L J 942. 944. The Millstoner-The diameter of the millstones most in use at the present day is 4 feet, and their thickness about 12 inches one-half of this thickness is composed of French burr, a very hard, though porous mineral, of a silicious nature: the other half is made up of plaster of Paris. In consequence of the difficulty of obtaining sufficiently large masses of the French stone, it is usual to construct the millstones in segments, which are cemented together, and the whole firmly bound by iron hoops passing round the circumference. The lower stone is, in the first instance, carefully dressed into a perfectly flat, plane surface, but the upper one is made slightly hollow for a small distance from the central aperture, 80 as to allow the grain to be freely admitted between the stones. Being thus prepared, grooves are then cut on the rubbing surfaces of both, in the manner indicated in Fig. 941. The circumference of the stone is first divided into eleven equal parts; lines are drawn from each division to the centre these radii determine the limits of the grooves in each compartment. A chord b' c' is then drawn, joining the bounding radii of any two compartments; this chord is, of course, bisected by the intermediate radius J a', in d'. Divide the line d' c' into four equal parts in the points e' f' g' and from these points mark off, on the line d' c', distances equal to the width of the groove to be cut; then draw through all these . The number of channels formed in the stones, and consequently the number of compartments, or quarters into which they are primarily divided, are varied by different millers, but the mode of drawing the lines, as here given, is applicable in all cases. Digitized by Google 308 CORN-MILL. Literal References. A A, the standard or lower framing of the grinding machinery. B B, the cone or upper framing. C, the stone-case, of sheet-iron. D, a cast-iron ring forming the sup- 949. port of the feeding hopper, and carried upon aaa, three malleable-iron legs, rest- ing upon the top of the stone-case. E, the feeding hopper. b, a pipe made of thin sheet-iron, supplying grain to the feeding hop- per from the garners above. F, the main driving-shaft. G, the plummer-block in which the shaft F revolves. H, the bevel mortise-wheel, com- municating the motion of the shaft F, to m I, the pinion of the mill-spindle. J, the mill-spindle. K, the ryne of cast-iron, by which m the mill-spindle is connected with the upper stone, and the feeding is regu- lated. cd, the bearings of the universal joint formed by the ryne. H H L, the cast-iron socket for the upper bearings of the mill-spindle. e f, bushes and wedges for adjusting # the upper bearing of the mill-spindle. J 8, a thin cast-iron plate, by means of 960. which the wedges ff are tightened and 950. 951. retained in their places. hhh, pinching-screws for adjusting o a the level of, and 961. iiii, pinching-screws for centering R the lower mill-stone. i, a large brass nut, with jam-nut, for retaining the pinion I constantly in its 962. proper position with regard to the driv- ing wheel. k, the footstep of the mill-spindle, of 963. brass or gun-metal. 21 952. 1, cast-iron socket for the footstep k. 959. 958. 953. M m, pinching-screws for adjusting the socket 1. m, the saddle or link connecting the footstep k with M, the great lever for supporting and regulating the position of the mill- spindle. 971. N, the screwed rod for working the lever M. 964. 965. e, cast-iron screw-key for the same. o, the moveable feeding-pipe of 973. cast-iron. P, lever for regulating the position of the feeding-pipe O. p, small column forming the centre 972. of motion of the lever P. 975. Q 9, apparatus for working the feed- ing mechanism. R, a cast-iron ring for raising the 974. driving pinion out of geer with the o 956. wheel. S, a cast-iron crosshoad, being part of the same apparatus. 957. rr, upright rods connecting the cross- head S, with the ring R. ss, a hand-wheel for working the disengaging geer. ? 4 a screw working through the eye 977. 976. of the hand-wheel 8. T U V W, the several parts of which the stone lifting machine is composed. ur, the centres of motion on which it rotates. X, the lower elevator-frame, of cast- iron. Y Y, the creeper, of cast-iron. to =, blocks and stude for connecting the adjacent lengths of the creeper. 1/2 the brackets in which it revolves. Z, the creeper-box, of wood. Digitized by Google CORN-MILL. 309 points of division lines parallel to the radius J a', terminating them in the radius J c'. These are the outlines of the grooves, which are then to be cut into the stone, perpendicularly on one side and ob- liquely on the other, so that each furrow shall have a sharp edge. The direction of the grooves being the same in both upper and lower stones as they lie on their backs in the position proper for being cut, RD a 978. 981. o W o o V 982. W T 979. b U T T U 980. U E 954. M o M 955. M 984. 983. X X X it is obvious that when the former is reversed and set in motion, their sharp edges will meet each other after the manner of a pair of scissors, (as partially shown by the dotted lines in Fig. 941,) and thus grind the corn more effectually when it is subjected to the action of the unbroken surfaces between the channels. Digitized by Google 310 CORN-MILL. Adjustment of Lower Stone.-It is of the most essential importance to the proper working of any pair of stones, that the grinding surface of the lower stone should be perfectly level, and that its centre should be exactly perpendicular above that of the lower bearing of the mill-spindle. To secure the former of these conditions, three pinching-screws h h h, are fitted into the cone, (that number being greatly preferable to four in adjusting the level of any surface;) and, bearing against small slips of iron sunk into the stone, it can be raised or depressed by them to any required extent. The centering of the stone is effected by means of four pinching-screws i i ii, acting horizontally upon it. To secure it against deviating from the truth after having been properly adjusted, all these screws are provided with jam-nuts. Adjustment of Mill-Spindle.-The lower bearing or footstep of the spindle J is also made capable of nice adjustment, both horizontally and vertically. The former is necessary in order to ensure the accurate working of the driving wheel and pinion, and the latter to regulate the pressure of the upper upon the lower stone, and to compensate for the changes produced upon both by the frequent dressings which their grinding surfaces have to undergo. 970. 969. 966. 968. R R R 966. 985. 987. 23 989. 988. 990. The footstep k, which is of gun-metal, is turned and fitted accurately into a cast-iron socket l, resting on the upper diaphragm of the standard A; the hole into which it is inserted and the annular recess by which it is surrounded being made of somewhat greater diameter than the corresponding parts of the socket itself. Its exact position is determined and secured by the four lateral pinching-screws m m, passing through the ring and working in nuts fitted into recesses cast upon its interior surface. (See Figs. 947 and 975.) The footstep k is not fixed immoveably into the socket l, but is capable of sliding vertically in it. Its proper position, in this direction, is regulated by means of a strong malleable-iron lever M, having its centre of motion in the back of the standard A, while its opposite end projects through a slot, and is raised or depressed by means of a screwed rod N, joined to it and passing through a projecting shelf cast upon the front of the standard. A small link or saddle n, serves to connect the lever with the footstep k; the saddle being provided with a square tail which is inserted into a similar recess in the under side of the footstep; by which means the latter is prevented from turning in its socket. Thus it will be seen that the entire weight of the upper stone and mill-spindle rests upon the lever M, and that the miller is enabled to vary at pleasure the pressure upon the grain between the stones, and consequently, the degree of fineness of the flour produced, by simply turning the nut of the screw N by means of the key O. The Feeding Apparatus.-The supply of grain admitted between the stones is regulated by means of a cast-iron pipe O, open at both ends, the lower end being brought into close proximity with the ryne, while the upper part incloses the pipe in which the feeding hopper E terminates. It is suspended by means of a cast-iron lever P, which has its fulcrum in the small column p, depending from the tripod D. A small chain attached to the end of the lever, and passing over a friction-pulley at the bottom of the stone-case, serves to connect this feeding apparatus with an ingenious little piece of mechanism Q attached to the standard, by which the miller is enabled to regulate the supply with the greatest nicety. This contrivance (which is represented on a large scale at Fig. 971) consists of a small hand-wheel q, working between the cheeks of a double bracket bolted to the standard A. A small screwed pin forms the axis of this wheel; it passes freely through the cheeks of the bracket, but is screwed into the eye of the hand-wheel, and is prevented from turning with it by means of a feather inserted into the former and fitting into a groove cut throughout the entire length of the pin, to the upper end of which the chain is attached. By this arrangement it is obvious that by turning the hand-wheel q to the right or left the small pin will be raised or depressed, and, through the intervening mechanism, the size of the open- ing between the mouth of the feeding-pipe o and the ryne will be increased or diminished. The form given to the upper surface of the ryne may be looked upon as the highest point of perfection to which this important part of grinding machinery can be carried. We have been at great pains to give an accurate representation of it in our various views, (see Figs. 928, 936, 987, 938, 939, and 940.) The principle by which its form is determined is, that the centrifugal force of the running stone shall be employed in the most effectual manner to distribute the corn equally over every point of its surface, while at the same time, the supply admitted shall be susceptible of the nicest possible adjustment. Digitized by Google CORN-MILLS. 311 The Disengaging Apparatus.-The driving pinion I is fitted upon the mill-spindle 80 as to be capable of sliding up and down upon a sunk feather. When fully in geer with the wheel H, it rests upon a collar formed on the upper surface of a large brass nut j, by which the miller is enabled to keep the pinion invariably in its proper position with regard to the wheel, independently of the position of the spindle, which, as we have before had occasion to remark, requires to be slightly lowered every time the stones are dressed. When properly adjusted, the pinion is secured to the spindle by a tapered key. It is, however, necessary to throw each pair of stones, periodically, out of geer with the general range, to admit of their being dressed, dc. For this purpose the tapered key is removed and the pinion raised out of contact with the teeth of its driving-wheel by means of a species of small jack or lifting apparatus attached to the standard, the component parts of which we shall now briefly enumerate. A cast-iron ring R, supported upon two upright rods r r, is brought into contact with the under surface of the pinion by turning the hand-wheel 8, which is screwed upon its axis t, and carries with it in its ascent, the cross- head S, into the ends of which the lower extremities of the rods r r are inserted. The screw t is fixed into a socket cast upon the under surface of the lower diaphragm of the standard, and the connecting rods r r pass through holes formed for their reception in both diaphragms; being set in a diagonal direc- tion in order to clear the lever M, and other important parts of the machinery. On turning the hand-wheel in the contrary direction, the weight of the pinion again brings it into its working position. The Stone-lifting Machine.-Fig. 978 is a representation of a portable lifting apparatus, for raising the upper stones from their beds and depositing them on the floor of the mill, when they require to undergo the process of dressing. It consists of a strong malleable-iron arm TT, bent into a form nearly approaching to a quadrant; the lower end works in a cast-iron step v, inserted into the stone floor, while its upper extremity is supported by a strong rod U, fitted to rotate upon a stud 26, fixed into a cast- iron plate (Fig. 981) bolted to the beams which support the floor above. The fixed centres 26 and v are so situated that the machine shall command two contiguous pairs of stones, and the end of the rod U is made of such a form as to admit of its being easily disengaged from the stud; when the entire machine may be removed. A strong screw V, passing through the arm T, and worked by means of a nut formed into a double handle, carries at its lower end the two connecting links W W, which are attached to the stone by two studs temporarily inserted into it at points diametrically opposite. The links W W are bent so as to admit of the stone being inverted while it is suspended in the lifting machine. The running stone is retained in its place in the mill simply by its own weight; it is, therefore, only necessary to raise it out of its bearings when the grinding surfaces require examination or repair. The Elevators and Creepers.-Figs. 983 and 984 are a representation of the form given to the lower elevator-frame; the nature and construction of this machine having been fully noticed in our previous description, it is not necessary further to advert to them. The creeper, however, Fig. 985, is an object of greater interest. The material employed is cast-iron; the creeper is made in six feet lengths; each length being in the form of a tube, 31 inches in diameter, and about 1 of an inch thick, with broad leaves or threads cast round it in the form of an Archimedean screw. The thickness of the threads does not exceed 3 of an inch at the outer extremity. The different lengths of which the entire creeper is composed, are joined together by short malleable iron studs x x, forming also the journals on which it revolves. These are made with square tails fitted into similar holes formed in the centre of the small cylindrical blocks w w, which are carefully turned on their exterior surfaces, and driven into the open ends of the pipes Y Y, previously bored to the same diameter. This construction at once insures a strictly rectilinear axis for the entire range, what- ever may be its length. Minor details will be understood by a simple reference to the figures. The arrow indicates the direction in which a creeper, constructed in the manner shown in the general view, would propel the grain. CORN-MILLS of MM. Cartier and Armengaud, Sen. The corn-mills after the American system, have undergone useful and important alterations since their introduction into France, though but recently introduced. This system was followed but slowly from the difference in its operation from that of the French mills. The owners of the old mills were satisfied with the work done, with little care on their part respecting improvements. It is only since the importation of the American process that this industry has received a new impulse, and that a new era has commenced; for this system has driven before it the routine with which the old system was encumbered. The new system was already well known all over England when it made its appearance in France, where it received great amelioration. The old method required a large number of hands, while the new supplies their place, or rather their work, by the ingenious motions imparted to the different parts of the mills by the machinery. The construction of the different pieces, as well as their disposition, are not always similar; the mill of Cartier and Armengaud appears to us the most worthy of notice; there are ten couples of millstones set in motion by the same hydraulic wheel. Explanation of the Figures. Fig. 991, front exterior view of the mechanism of the mill, (first system.) Fig. 992, a vertical section of the axis on the line 1-2, of the plan, Fig. 997, (second system.) Fig. 993, a vertical section, perpendicular to the preceding, on the line 3-4, Fig. 996. Fig. 994, a section through the axis of a stone and of a pillar, on the line 5-6, Fig. 995. Fig. 995, a horizontal section above the platform, parallel to the line 7-8, of the preceding Fig. Fig. 996, the general plan of the first system, showing the disposition of the millstones. This plan exhibits the work at different heights, in order to bring under observation the covers of the stones, the inferior stones and their flooring, the triangles and frames which contain them. Fig. 997, the general plan of the second system, with disposition altogether similar to the first. The Digitized by Google 312 CORN-MILLS. horizontal sections are here represented at different depths underneath the frame-work of the stones, exhibiting the pinions of the stones and the horizontal wheel commanding them, the pedestals into which are inserted the ends of the axles of the stones, the pillars and circular platform which gives support to the whole. H A U U R 992. a SCALE.-66 feet=13 inchea. B at A 4 991. S T 0 Figs. 998 and 999, a vertical section and plan of the iron axle of a mill-stone. Figs. 1000 and 1001, a vertical section and plan of the superior portion of one of the cast-iron pedes- tals. Fig. 1002, a steel socket on which the iron axle of the mill turns. Digitized by Google CORN-MILLS. 313 R b A a L G H и a J x C Y P J d P Q. B R 2 R 993. D S X C N ON J U L H o B A M m m SCALE.-66 feet=13 inches. N n 50 7 A A 0 C L L 6 B 5 994. I G 3 e J J L V U 8 x 6 B Digitized by Google 314 CORN-MILLS. a HOB ПОП M V€ a 8 vo GO 996. USE X D % R 3 8 a X x x A . and D at 1002. of E'll 999. WWW.T 1000. 1001. SCALE.-66 feet=13 inches. G 0 H "- H B nj K k A. R² R S 998. x Et Or o mL H N S 72 E N L RNS 997. R' M 4 R 2 K Digitized by Google CORN-MILLS. 315 References to Figs. from 991 to 1002. A, circular stone-work, on which the whole system, com- m, cast-iron fulcrum, having brass pillows, on which the posed of six couple of stones rest. turning pieces of the two shafts N rest; their plates B, the circular platform of cast-iron placed on the stone are set in a groove made in the stones supporting them. frame-work. o, bevel with wooden coga, and fitted to the shafts N. C, six iron pillars of equal height, fixed to the platform by P, cast-iron pinions. pins which penetrate them their whole length, and also Q, vertical shafts in cast-iron, turned their whole length, the stone circle. bearing the pinions P. D, the cast-iron rim, made of one solid piece; the pine of Q, iron shaft, fitted to the summit of the preceding axles, the pillars also penetrate it, thus fixing them firmly to and going towards the upper stories to work the clean- this rim. ing bolting apparatus. a, six long pins traversing the rim, the pillars, the platform, R, a horizontal wheel, with six arms, ending in ears pinned and all the thickness of the stone-work, thus firmly bind- to the boxes of the millstones; its centre has three brass ing the different parts to each other. flat pillows, which keep the axle in a vertical position E, six cast-iron cases resting on the cornice, in which the force-screws press them at will. lower millstone is contained. o, keys, which maintain the pinions and the wheels S at the F, cast-iron triangles, placed at the bottom of the cases, in height determined for them, to prevent their fall, in case order to give the position required to the under mill- the screws which keep them fixed to their axle should stones. become loose. b, screws adapted to the triangles, to govern them. p, steel extremity of every vertical shaft to which it is a iron plate fixed to the rim, into which the resting-rods L adapted, having a conical shape; the contact suffices are screwed, receiving the pressure exercised by the nuts to keep them connected. of the pine a. R', great chair in cast-iron; the basis of which is solidly & Fig. 996, square-headed screws binding the cases to the pinned to the stone R2. rim. R2, a large stone placed at the centre of the works, so die- a round-headed screws holding the immoveable stones. posed as to bear both systems. F, immoveable stones, of the diameter of 4-26 feet, iron- q, rest-rod of the vertical axle; it is made of iron, flanged bound, and borne upon the triangles F; they are fur- at its inferior portion, which goes through a nut in rowed, as indicated in Fig. 996. iron T. Fa, running wheel, of the same diameter, revolving above r, nut, in iron, with square fianges, placed upon the centre the former. They are also 4.26 feet diameter. of the base of R'. G, vertical axles in cast-iron of the running wheels moving r, brass socket, adapted to a cast-iron muff, and containing them. a steel bed, similar to that of the milistone axles: it re- f, cast-iron bushing of a conical shape, adapted to the ceives the point of the vertical shaft, and is governed by axle G. four screws. 8, cast-iron chuck, having two arms contained within f, 8, a horizontal wheel, having fine wooden teeth, and fitted attached by their extremities to the moveable stone, and to the vertical shafts. held in equilibrio upon steel disks, adapted to the axle of T, straight pinions, made of cast-iron, adapted to the axles the stones, and having a spherical part, which serves as of the stones, and to which the rotatory motion is given a pivot to the centre of the chuck. by the horizontal wheel S. H, cast-iron cylinder fixed to the nether millstones, Figs. U, wooden box surrounding the millstones it is placed 997 and 998. upon the flooring of the first story. 4, flat pillow in bronze, contained within H, and bearing V, brass hopper, distributing the grain to the stones. against the iron axles of the millstones. s, zinc pipe, communicating with the hopper, which is N, braces; they are of cast-iron, placed in the bottom of placed in the second story. Valves open and close it. the drums, and fixed to them; they serve to keep the 4 brass tube, fitted into the lower part of the hoppers, and pillows firmly fixed. descending as far as a. 42, cast-iron wedges, pressing the pillows against each other. t, small tube, enclosed within the last, when its opening is i, steel pins, adapted to the inferior portion of the iron to be leasened before grinding the corn. axles connected with the stones. & cross iron bar, the extremities of which are supported a Fig. 1002, steel socket, in which the ends of the axle 8" by screws; their office is to keep the tubes & at the rest. desired height. I, vertical rods of iron, by which the axles and consequently v, small cast-iron supports, attached to the lids of the mill- the millstones are raised. stone box. J, cast-iron pedestals, mostly round, and pinned by their X, a great circular shoot, in wood or sheet-iron, in which base to the circular platform. the ground corn is received at its exit from the stones; is cast-iron sockets, placed in the superior part of the pedes- it rests upon the wheel R. tals; their shape is seen in Fig. 1000. Y, spur-wheel, of cast-iron ; it turns upon the vertical shaft, j, brass socket made to be adapted to the cups j; they and gives attachment to the moveable branches of the rest upon the summit of the vertical rods I, to rise and shoot. descend with them, and receive the sockets 13. I, six iron branches, attached with pins to the ears of the f, a screw to set the sockets in the centre, and consequently wheel Y, which rotates them very slowly. the axles of the millstones. x, wooden plates, fixed to the extremities of the branches I K, cast-iron balance-beam, connected with the resting-rods. they turn with them within the shoot, carrying forward 4, iron bolts, serving to rest one end of the beam K a nut the meal to the box of the endless screw. maintains each of the bolts fixed to the platform. y, pinion, commanding the wheel Y. L, long rod, connected to the beam K, but allowed to re- y, strait wheel, cast with the preceding pinion, and fixed volve round its own axis. with it to an iron gudgeon, adapted to one of the arms 4 a portion of L, of a greater diameter than the rest, and of R. tapped at the height of the rim. re, a similar wheel on the vertical shaft, and transmitting its r, cast-iron fly-wheel, at the summit of each rod L, in order movement to y. to turn them by the hand. Z, an endless screw, made of wood, having an iron axis M. large cast-iron cog-wheels, communicating with the and a wooden screw it is inclosed within a rectangular moving wheel M', and transmitting their movement to box of wood, into which the meal from the shoot is re- the two systems. ceived. M', vertical moving wheel in cast-iron, in two pieces, and z', an oaken box, in which the ground grain falls. adapted to the axle of a hydraulic wheel. 4 a double pulley, mounted upon the extremity of the end- m, cast-iron bushing round each axle of the pinions; they less screw, and free on this axle. can slide on It laterally. z', an endless chain, with tin buckets, fixed at intervals, in m', screw, by which the bushing is made to engage with its order to raise the meal from the box Z to the room pinion; it is disengaged at will, when it is to put in or where it is allowed to cool. out of geer. 22, a small pulley, commanding the endless screw. N, two cast-iron shafts, bearing the pinions M, and the bevel wheels O. Digitized by Google 316 CORN-MILL. CORN ELEVATOR, Steam: Pagin's Patent. In the new warehouses attached to the Atlantic Docks, Brooklyn, there are several of these very useful engines erected. Also one on the river for dis- charging grain-laden ships in the stream or alongside the piers: the latter is called the floating eleva- tor. The extremity of the shoot C is inserted in the hold of the vessel about to be discharged, its height being regulated by the guide-frame and pulleys, Fig. 1003. The machine is put in motion by means of the prime mover A and band-wheel B, when by means of a series of tin dippers attached to a belt of gutta percha or leather, tightly stretched over the wheels at B and C, the corn is brought up to a height 1003. of 76 feet, and discharged by means of the small spout attached to the elevator into the weighing ma- chine; from thence, by a repetition of the same contrivance, it is taken through the building to a shoot on the roof, containing an Archimedean screw, by the use of which and the elevator the grain may not only be placed on any particular floor in the warehouse, but may be transhipped (having been weighed in its passage) either wholly or partially for Europe, or any other destination. This apparatus was erected by Barton, of Buffalo, and by means of a small high-pressure engine, 10-horse power, will raise 2600 bushels of grain 76 feet high per hour, and distribute or tranship as described. CORN-MILL, Old Union. In order to render our series of Corn-Mill drawings complete, we have given in Fig. 1004 a representation of the arrangement of the stones, garners, &c., in an extensive estab- lishment fitted by Mr. Fairbairn with machinery identical, in all important particulars, with that which we have detailed in the preceding figures and descriptions. This mill contains seventeen pairs of stones. The whole are disposed in one straight line, close to the wall of the mill-which arrangement, on account of its undoubted superiority to any other, has Digitized by Google CORN-MILL. 317 induced us to select this example. The flour produced is, for the most part, consumed by an extensive baking establishment adjoining the premises, and belonging to the same proprietors. For our present purposes, we have deemed it necessary to give only a sectional elevation, on a small scale, and of a somewhat sketchy nature. The line of section must not be supposed to be taken in one vertical plane, but to vary in order to exhibit most distinctly the different parts. Description-Two powerful steam-engines are employed to drive the machinery of this mill; one of these communicates its motion to the line of horizontal shafting, near the end of the range, by means of a great bevel-wheel A, keyed to the crank-shaft, and working into the bevel mortise-pinion B upon the mill-shaft; the other, by means of a spur fly-wheel working into the mortise-pinion C, situated towards the centre of the range. By thus applying the power at two points, the weight of shafting and conse- quent loss from friction, &cm is materially diminished. From the driving-shaft DDD, the power is communicated by the bevel pairs a a a, to the mill-spin- dles, which are provided with suitable bearings and adjusting geer, in all respects identical with that we have already described. Between the first and second pairs of stones, one of the standards E is employed for the purpose at once of giving great stability and firmness to the shaft D at the point where it receives the strain of the first engine, and of affording the means of transmitting its motion to the upright shaft driving the lighter machinery of the mill. A strong cast-iron bracket b, bolted through the wall of the mill, abuts against the framing, and the intermediate stays c c bind all three together laterally. Each of the feeding hoppers ddd is supported by a light cast-iron framing e, resting upon slender columns; the tripodal form is, however, preferable to this. The feeding-pipes HHH are of tinned plate, 80 constructed as to be easily withdrawn from their con- nection with the wheat-garners when the stones are taken up; and at the top of each is a small valve or slide h, to shut off the supply of wheat. Above these points the passage of the grain from the cleaned wheat-garners is effected by means of wooden spouts III, converging to and communicating with them. The cleaned wheat-garners J JJ are three in number, and are situated on the top floor of the mill, immediately over the stones. Between, and in front of these, are the garners K K, which receive the wheat as it is first brought to the mill, and deliver it, by means of numerous spouts or openings in the floor, to the great uncleaned wheat-garners LL, situated on the machine flat. From these the un- dressed wheat is conveyed, by means of a creeper and elevator, into the screen M, whence it falls through the spout P into an elevator on the stone floor, by which it is again raised to the upper story and distributed, by another creeper, into the cleaned wheat-garners J JJ. The vertical shaft ii is continued upwards till it terminates near the roof of the machine floor. Then its motion is transferred by means of a short transverse shaft, (which we have purposely omitted in our drawing for the sake of simplicity,) and two pairs of bevel wheels, to the long horizontal range of shaft- ing k k, on which are fixed numerous pulleys for driving the various subordinate machinery of the mill. The pulley l drives the lower creeper. The pulley p drives the second elevator. " " m " the upper creeper. " " " q the fan (belt working over " " n " the sack-tackle. guide pulleys.) " " " o the first elevator. " " " r the wheat-screen. The dressing and bolting machines are driven by pulleys on the transverse shaft. The apparatus Q for raising the stones is shown here in action; it may be remarked that it is found necessary, in this mill, to keep a couple of stone-dressers in constant employment; each pair of stones being, in success- sion, thrown out of geer for twenty-four hours, to undergo the process of redressing. Calculation of Velocities. 1st Steam-engine makes 48 Revolutions of Crank-shaft per Minute. 9d do. 22 do. do. do. DRIVER. DRIVEN. RESULT. Description of geering. Revolu- Revolutions per Minute. Diameter. Diameter. tions. Ft. In. Ft. In. Bevel pair A B 6 81 48 4 6 18 21 22 5 7 } 71.57 on horizontal shaft D. Spur fly-wheel into C Bevel pairs a a a 8 6 71.57 1 10,1 132 on the millstones and upright i. 1st pair of small bevels 3 0 132 2 11 184 on the transverse shaft. 2d do. do 1 6 184 1 10 149 on the longitudinal shaft k. Diameter of the millstones, 4 feet. Literal References to Fig. 1004. A, the great bevel-wheel on the crank-shaft of first engine. B, the pinion on the mill-shaft working into the above. C, a spur cog-pinion on the mill-shaft driven by the spur fly-wheel of the second engine. DDD, the range of mill shafting. EEE, the standards or lower framing of the mills. FFF, the cones or upper framing of the mill. GGG, the stone-cases. Digitized by Google 318 CORN-MILL. A - B H E J K H H g - a i 26 1004. a C J + SCALE.-11 feet==1 inch. L K L H d G E D J T il M Digitized by Google COAL, ANTHRACITE. 319 aaa, the bevel wheels and pinions for driving the mill-spindles. b, a strong bracket for strengthening the bearing of the pinion B. c c, two cast-iron cross-stays for the same purpose. ddd, the feeding hoppers. ece, the frames supporting the feeding hoppers. fff, the cast-iron moveable feeding-pipes. ggg, the small screw and hand-wheel for working the feeding apparatus. HHH, sheet-iron feeding-pipes from the machine floor to the hoppers. hhh, slides for shutting off the supply of wheat when necessary. III, wooden spouts or square pipes for leading the grain to the feeding-pipes HHH from JJJ, the cleaned wheat-garners on the top floor of the mill. KK, the first uncleaned wheat-garners emptying their contents into LLL, the great uncleaned wheat-garners on the machine floor. M, the brusher or wheat-screen. N, the fan attached to the wheat-screen. 0, passage of the blast, carrying the dust, &c., outside of the mill. P, passage of the cleaned wheat to the second elevator. ii, the upright shaft for driving the light machinery of the mill. j, a pair of bevels between the upright shaft and k, the range of longitudinal shafting down the mill. lmnopqrs, pulleys for driving the various light machinery. Q, the stone-lifting machine shown in operation. ttt, studs affixed to the beams supporting the machine floor, affording fixed centres for the working of the lifting machine Q. COAL, ANTHRACITE It is useful to state that the anthracite coal is broken and screened into three different sizes; viz. egg size, nut size, and pea size. The dust and pea-coal mixed, that is to say, the screenings from nut-coal, are most commonly in use for small stationary engines. It costs about one-half the price only of the larger coal and, with proper care, can be made to generate almost as much steam. The grate bars are thin and deep: the depth is generally nearly 5 inches in the centre for bars 4 feet long. By these means a large surface is provided for the radiation of heat from the bars to the cur- rent of air passing between them; and thus, the space between the bars being necessarily small, a suf- ficient supply of air is admitted into the furnace. The fire is usually ignited with a little pine wood kept for that purpose. The fan or blower is.set to work, and the fire is then fed by the shovel in the ordinary way. Care must be taken that too much coal be not put on at one time, nor any faster than it is consumed. It must be equally distributed over the surface; by these means the stoker is enabled to get a body of fuel on the grate of about 6 inches thick, the fire being all the time brisk and equal, and the combus- tion perfect; but, if these rules are neglected, the grate becomes clogged, and the necessary current of air is excluded. It is a common phrase among the firemen that they must keep the surface of the fire always dancing. The rapid supply of oxygen from the fan is essentially necessary for the proper com- bustion of the small coal; but by its agency the mere sweepings, the refuse coal, answer all the pur- poses of large coal, at half the cost; and it is quite extraordinary how small an amount of combustible matter is permitted to escape. Analysis of Coals.-Pennsylvania. Coal from Nesquehoning mines, from the tenth feet veins, east drift, Northampton county. Structure irregularly columnar; fracture irregularly conchoidal; color grayish black; lustre splendent.-Volatile matter, 6.40; Carbon, 86.60; Ashes, white, 7.00: Total, 100. Coal from Summit mines of the Lehigh Company, from a vein said to be 14 feet thick, Northampton county. Structure massive, compact; color black; metallic lustre brilliant.-Volatile matter, 7.50; Carbon, 88.50; Ashes, dull white, 4.00. Coal from Summit mines, Lehigh Company, Northampton county, hardest variety. Structure dense, laminated; fracture smooth, somewhat conchoidal; color metallic, black; lustre splendent.-Volatile matter, 6.60; Carbon, 87.70; Ashes, white, 5.70. Coal from Tamaqua mines, on east side of the river, called vein D, east, Schuylkill county. Texture nearly compact, somewhat slaty; fracture conchoidal; grayish or iron black; lustre splendent; specific gravity 1.57.-Volatile matter, 5.03; Carbon, 92.07 Ashes, white, 2.90. Coal from Tamaqua mines, vein E, east, Schuylkill county. Texture compact; fracture conchoidal; grayish black; lustre splendent; specific gravity 1.60.-Volatile matter, 4.54; Carbon, 89.20; Ashes, very white, 6.26. Coal from Tamaqua mines, R vein, in the Sharp Mountain. Texture compact; tendency to lamina- tion; grayish black; lustre metallic, splendent. Specific gravity, 1.55.-Volatile matter, 7.55; Carbon, 87.45; Ashes, white, 5.10. Coal from Fuscurora mines, from second drift, south of Jackson's mine, Schuylkill county. Structure slightly laminated, tolerably compact; irregular conchoidal fracture; color black; lustre splendent.- Volatile matter, 7.50; Carbon, 88.20; Ashes, pink brown, 4.30. Coal from the Schenoweth vein, Pottsville, Schuylkill county. Structure compact; irregular fracture; color black; lustre splendent; specific gravity, 1.50.-Volatile matter, 1.40; Carbon, 94.10; Ashes, light brown, 4.50. Coal from Neeley's tunnel, third vein, Schuylkill county. Texture compact; iron black; fracture conchoidal lustre splendent specific gravity, 1.55.-Volatile matter, 5.40; Carbon, 89.20; Ashes, light yellow, 5.40. Coal from Sharp Mountain, Pine Grove. Texture laminated; gray black; fracture splintery lustre splendent; specific gravity 1.54-Volatile matter, 7.15; Carbon, 80.57 Ashes, 8.28. Digitized by Google 320 COAL. ANTHRACITE. Coal from Black Spring Gap, Dauphin county, twenty-five miles east of the river. Massive, friable; fracture irregular; color iron black; lustre somewhat splendent; specific gravity, 1.44.-Volatile mat- ter, 9.53; Carbon, 82.47 Ashes, yellow white, 8.00. Coal from Lea vein, 7 feet thick, near Black Spring Gap, Dauphin county. Structure laminated; brittle, black, shining; specific gravity, 1.35.-Volatile matter, 8.96; Carbon, 85.84; Ashes, cream color, 5.20. Coal from Grey vein, 16.7 feet thick, near Black Spring Gap. Massive; fracture irregular; color black considerable lustre; specific gravity, 1.44.-Volatile matter, 9.78; Carbon, 81.02; Ashes, light orange, 9.20. Coal from Grey vein, near Black Spring Gap; included gray band. Structure somewhat fibrous; brittle; color gray-black, smutty dull metallic lustre; specific gravity, 1.33.-Volatile matter, 11.40; Carbon, 81.40; Ashes, pale ochreous, 7.20. Coal from Peacock vein, Gold Mine Gap, Dauphin Co., 25 miles east of the river. Structure massive, with a tendency to columnar fracture angular; color black; shining, irised specific gravity, 1.41.- Volatile matter, 10.95 Carbon, 82.15; Ashes, light orange, 6.90. Coal from the Heister vein, Gold Mine Gap, Dauphin Co. Structure massive; strive distinct; color jet black; lustre shining; specific gravity, 1.41.-Volatile matter, 10.43; Carbon, 81.47 Ashes, pale yellow, 8.10. Coal from vein supposed to be the Peacock vein, west side of Raush Gap, Dauphin Co., twenty-one miles east of the river. Structure massive; friable; small columnar; fracture irregular; color black iridescent; specific gravity, 1.45.-Volatile matter, 10.57 Carbon, 77.23; Ashes, pale orange, 12.30. Coal from Yellow Spring Gap, Dauphin Co., sixteen miles east of the Susquehanna. Structure slaty, somewhat brittle; fracture irregular; black; lustre shining specific gravity, 1.41.-Volatile matter, 10.95 Carbon, 79.55; Ashes, pale yellow, 9.50. Coal from Ruttling vein, Dauphin Co., thirteen miles east of the river. Massive, regular fracture, tendency to lamination; cross fracture shining black between the laminæ lustre feeble; coke light and spongy.-Volatile matter, 13.75; Carbon, 74.55; Ashes, 11.70. Coal from big flats, Dauphin Co., nine miles east of the river from the shaft. Massive; irregularly laminated; fracture irregular; striæ small and distinct jet black; and considerable lustre; makes good coke.-Volatile matter, 15.06; Carbon, 76.94; Ashes, orange, 8.00. Coal from Lyken's Valley, third bed, Dauphin county. Texture laminated, brittle; fracture fibrous; color jet black, shining.-Volatile matter, 8.85; Carbon, 88.25; Ashes, 2.90. Coal from Shamohin coal mines, Snyder's mine. Structure massive, compact; fracture laminated beautifully iridescent.-Volatile matter, 6.10; Carbon, 89.90; Ashes, 4.00. Coal from Wilkesbarre, Luzerne county, Warden's vein. Texture compact; iron black; lustre splen dent; fracture conchoidal; specific gravity, 1.403.-Volatile matter, 7.68; Carbon, 88.90; Ashes, 3.49. Coal from Wilkesbarre coal basin, Carbondale mines, Luzerne county. Texture laminated, laminse compact; iron black; fracture somewhat irregular; lustre brilliant metallic; specific gravity, 1.404.- Volatile matter, 7.07 Carbon, 90.23; Ashes, grayish, 2.70. These analyses will exhibit the average composition of the coal in the different parts of the first or great southern anthracite basin; the specimens which were selected with this view having been chosen from various localities, at tolerably regular intervals from near its eastern extremity to within a few miles of its western termination. The public are already familiar with the fact of the general increase of softness in the coal of this basin as we proceed westward. The above results will display a similar augmentation in the quantity of the volatile materials in the coal, though it does not follow that these two features are in exact proportion to each other, as a single neighborhood will show beds of coal differing considerably in both these particulars-the hardness and volatile matter-and when no such dependence of the one upon the other can be remarked. From the Lehigh westward, as far as Swatara, we rarely find the volatile matter to amount to more than about 71 per cent. in the coal; while its average quantity of anthracite generally may be stated at about 6 per cent. Nearly the whole of this appears to be water. Advancing a few miles west of Swatara, we enter a section of the basin where the coal acquires a decided increase in the amount of its volatility. At Black Spring Gap, twenty-six miles east of the Susquehanna, this is first distinctly manifested the quantity there being about 10 per cent. A portion of this is probably free gaseous matter, not bitumen or, if this is present, the quantity is too small to impart to the coal any tendency to melt or make a coke. But about ten miles westward we meet with coal in the prolongation of the same veins, having as much as from 10 to 15 per cent. of volatile matter, and a part of this obviously bitu- minous. From the Yellow Spring Gap to the western extremity of the basin, the largest proportion of volatile matter which we have yet noticed in the coal is about 15 per cent. Where it possesses this amount, it has all the properties of a true bituminous coal, burning with a brilliant though not very enduring blaze; and yielding, when properly treated, a good spongy coke, well adapted to manufacturing purposes. Bituminous Coals.-Coal from Hopwell Furnace mines, Broad top mountain, Bedford county. Massive; strixe distinct, somewhat columnar; shining jet black, in parts iridescent. Ashes in the coal, 4.00. Coke spongy, but hard-Volatile matter, 11.20; Coke, 88.80. The coal of the broad-top basin exhibits an interesting confirmation of the general law, that as we advance towards the northwest the coals acquire more and more bitumen. This coalfield occupying a position intermediate between the range of the anthracite basins on the one hand, and the bituminous basins beyond the Alleghany Mountain on the other, its coal displays a corresponding or intermediate proportion of bitumen. First basin, N. W. of the Alleghany Mountain-Coal from bed of Lick Run, Lycoming Co. Laminated; Digitized by Google COAL, ANTHRACITE. 321 somewhat brittle; shining, black; between laminse, dull black. Ashes in the coal, 13.07 ; grayish pink. -Volatile matter, 20.72; Coke, 79.28. Coal from Queen's Run, two miles below Farrand's Ville, Clinton Co. Irregularly columnar; brittle; color jet black, shining; with thin films of charcoal. Ashes in the coal, 4.60.-Volatile matter, 21.50; Coke, 78.28. Coal from Snow Shoe Mine, Centre Co. Massive; brittle; irregular fracture; tendency to columnar structure; lustre shining, jet black. Ashes in the coal, 2.07. Coke highly intumescent and spongy.- Volatile matter, 21.20; Coke, 78.80. Coal from Moshannon Creek, near Philipsburgh, Clearfield Co. Structure small columnar, somewhat fibrous; striæ distinct; lustre jet black and shining. Ashes in the coal, 6.10.-Volatile matter, 29.50 Coke, 70.50. Coal from Steed's Mine, sixteen miles from Philipsburgh, Centre county. Friable, irregularly colum- nar; striæ distinct; jet black, with considerable lustre. Ashes in the coal, 11.20. Coke, compact; ashes, light cream color.-Volatile matter, 20.40; Coke, 79,60. Coal from Leech's Mine, 171 miles from Philipsburgh, Centre county. Friable; structure columnar; jet black, with much lustre. Ashes in the coal, 11.75.-Volatile matter, 20.32 Coke, 79.68. Second basin, N. W. of the Alleghany Mountain.-Coal from upper part of large bed, Ralston, Ly- coming county. Columnar; irregular cubical; fracture irregular; color shining; black, in parts dull. Ashes in the coal, 5.00.-Volatile matter, 20.50; Coke, 79.50. Coal from Karthaus, upper seam, Clearfield county. Structure columnar; cubical; friable; fracture irregular; color jet black; lustre considerable. Ashes in the coal, 8.80; brownish yellow.-Volatile matter, 13.00; Coke, 87.00. Coal from Karthaus, lower seam; external character similar to the above. Ashes in the coal, 4.70; brownish yellow.-Volatile matter, 24.80; Coke, 75.20. Coal from Reed's, six feet vein, Curwinsville, Clearfield county. Columnar; cubical; brittle; fracture irregular; color jet black, with great lustre. Ashes in the coal, 5.80.-Volatile matter, 27.00; Coke, 78.00. Third Basin, northwest of the Alleghany range.-Coal from the bed now worked at Bear Creek, Blossburg, Tioga county. Columnar; somewhat compact; containing occasional thin seams of char- coal lustre jet black, and very considerable. Ashes in the coal, 5.20.-Volatile matter, 32.00; Coke, 68.00. Coal from five feet vein, Warner's Caledonia, Clearfield county. Structure laminated; cubical; brit- tle; fracture irregular; color jet black, and shining. Ashes in the coal, 8.50.-Volatile matter, 37.00; Coke, 63.00. Coal from three feet seam, Warner's Caledonia, Clearfield county. Soft columnar; lustre jet black, and very considerable; fracture irregular. Ashes in the coal, 7.20.-Volatile matter, 38.20; Coke, 61.80. Coal from Blairsville, large bed, Westmoreland county. Structure laminated; columnar, somewhat hard and compact; color shining and black. Ashes in the coal, 4.00.-Volatile matter, 31.00; Coke, 69.00. Fourth or Great Western Basin.-Coal from Sandy Ridge, four miles from Shippensville, Clarion county. Massive; striæ indistinct; fracture cubical; black; lustre feebly shining. Ashes in the coal, 7.00; light gray.-Volatile matter, 43.20 Coke, 56.80. Cannel coal from six miles east of Franklin, Venango county. Composed of laminae; breaks with a uniform clearage; cross fracture conchoidal; surface smooth; dull black; with little lustre. Ashes in the coal, 17.68.-Volatile matter, 52.78; Coke, 47.22. Cannel coal from Greensburg, Beaver county. Composed of thick regular laminse; cross fracture conchoidal; surface smooth; dull black Ashes in the coal, 83.88.-Volatile matter, 36.00 Coke, 64.00. Coal from Conneant Lake, Crawford county. Slaty; laminated; fracture irregular; somewhat brit- tle; color jet black, shining. Ashes in the coal, 1.80; reddish brown-Volatile matter, 38.75; Coke, 61.25. Coal from near Greenville, Mercer county. Laminated; slaty; cross fracture splintery; brittle shining, jet black. Ashes in the coal, 1.7; brownish yellow.-Volatile matter, 40.50 Coke, 59.50. Coal from near Orangeville, Mercer county. Structure, laminated; somewhat rusty between laminae; fracture regular; color black, sometimes shining and iridescent. Ashes in the coal, 2.80; dark brown. -Volatile, 43.75; Coke. 56.25. A comparison of the foregoing analysis of the bituminous coals, from the several basins northwest of the Alleghany Mountain, discloses the highly interesting general fact of the progressive increase in the quantity of their bitumen, as we advance northwestward. Thus, the first group of coals, selected from various parts of the basin nearest the Alleghany Mountain, shows an average proportion of bitumen of about twenty-one per cent.; the second, or next basin to the northwest, A somewhat higher proportion the third basin, or range of basins, gives as much as thirty-four per cent.; and the fourth, or great western basin of the Alleghany and Monongahela, nearly forty per cent. This remarkable change in the composition of the coal, as we proceed from the southeast to the northwest, is not confined only to the basins of Pennsylvania, but prevails, it is believed, throughout the whole length of the vast bituminous coal field, which ranges from the state of Pennsylvania to the northern boundary of Ala- bama. All the varieties of coal contain more or less sulphur, no doubt in combination with iron, under the form of iron pirites, disseminated throughout the coal. From numerous chemical examinations, the fol- lowing results are selected :- Anthracite coal from Pottsville; average specimen of white ash. Contains in 100 parts, sulphur 0.60. Anthracite coal from Peach Mountain; average specimen of red ash. Contains in 100 parts sul- phur 0.48. 41 Digitized by Google 322 CORN-SHELLER. 'Anthracite coal from Lehigh, (hard coal ;) average specimen of white ash. Contains in 100 parts, sulphur 0.91. Bituminous coal from Karthaus ; highly bituminous. Contains in 100 parts, sulphur 2.70. Bituminous coal from Blairsville, Westmoreland county. Contains in 100 parts, sulphur 2.60. The limited use of anthracite in England may be attributed to the greater facility of working bitu- minous coal, and to the fact that the latter is nearer the great markets of its consumption. An un- founded prejudice existed against it, excited, probably, by the circumstance that it kindles less readily than the other, and it was thought unadapted to any other purposes than those above-mentioned. The rapid increase of steam navigation, the high price and growing scarcity of wood in the northern states, directed attention to the vast beds of coal with which various parts of the United States abound, and particularly the state of Pennsylvania. Anthracite being nearest the seaboard was the first to come into the market, and to the people of Pennsylvania must be attributed whatever of merit belongs to its successful introduction. In the course of the year 1831, anthracite began to be used in many of the cupolas of the iron-found- ries of Philadelphia, but only in combination with an equal quantity of charcoal; the prejudice I have mentioned not being confined to England. Thus it continued for some years after, during which period it had come into general use for domestic purposes, by the entire population of the towns and cities on the coast; it had also been adopted for the generating of steam for stationary, locomotive, and marine engines, for the smelting of copper, the manufacture of glass, and for all the processes of the iron manufacture, as smelting, puddling, heating the blooms, lumping, also for the smith's forge. In all these operations the fuel now in use is anthracite anthracite only. Its introduction has given a sensible impulse to steam navigation in the northern lakes and rivers. In respect of economy of space, indeed, it is now determined, that anthracite has an advantage over bituminous coals; an advantage of great importance in ocean steamers. One of the most remarkable facts to be noticed in relation to the consumption of anthracite is its cleanliness; it burns without smoke. The contrast it makes in this respect with bituminous coal is strikingly apparent to travellers. 1005. R M H A S CORN-SHELLER. This machine is the invention of L M. Whitman, and is now the property of S.G. Wise, of Weedsport, Cayuga Co., N.Y. It possesses the property of shelling corn with wonderful rapidity, and cleans the grain by removing all dust, &c., by a blower at one operation. Digitized by Google COUNTER PROPORTIONAL 323 Fig. 1005 is a perspective view, and Fig. 1006 is a vertical section, that is, as viewed looking down upon the top of the machine, only the frame P in Fig. 1005 is omitted in Fig. 1006, to show the parts to better advantage. The same letters in both figures refer to like parts, and the reader must refer to both in perusing this description. A is a frame made in the usual form, or of any other more suitable. B is a concave bed made of cast-iron plates, with projections on their inside surfaces. D is a cast-iron cylinder having projections cast on its outside surface, and by the ears of corn being fed in between the roller and the concave bed through M, on the other side of the lid R, and the cylinder set in motion, the ears will be carried round between the cylinder and concave bed, and all the corn removed from the cob in a most excellent man- ner; and when it is carried round to the rake-teeth seen above DD, the cob is thrown over the frame P, and falls over the side of the machine. The concave bed is hung on strong springs EE, which allow it to spring to the various sizes of the ears of corn-making it flexible for that purpose. The plates C, which form the concave bed, are placed a small distance apart from one another, so that the corn falls down between them into an inclined conduit, which carries the corn below H, a revolving set of fans, where the grain is perfectly cleaned; the dust, &c, being blown out through an opening below S, and the corn being heavier passes into the granary or receptacle out of the opening T. 1006. M E E H L A Operation.-The ears of corn are placed in the hopper M, best seen in Fig. 1006, and the master wheel K is turned, which driving the small cog wheel I, turns the revolving cog-surface cylinder D, and carries the ears of corn between it (the cylinder) and the concave bed B, when, by the action of the rough surface of the cylinder and concave bed upon the ear of corn, the grain is effectually removed from the cob, as the ear is carried from one side to the other of the concave bed. And by the concave bed being attached to springs, it will be observed, that according as the ears are great or small, and also as they get smaller in their progress of shelling, the exact relative distance to remove the corn from the cob will be maintained between the revolving iron cylinder and the concave bed. This is a very important and valuable part of the invention. It shells the corn rapidly, and its work is both clean and satisfactory. COROSOS, or nut ivory. See WOODS, varieties of. COTTON, quantities of tabulated. See QUANTITIES. COUNTER See DIMENSIONS OF STEAM-ENGINES. COUNTER PROPORTIONAL by W.H. Lindsay. The construction and operation of this instru- ment will, with the aid of the drawing, be readily understood. Whatever distance or quantity a space from point to point, as from 3 to 4 on the outer circle of the dial-plate, is intended to represent, is attained by proportioning the arm " 2, and the segment of toothed- Digitized by Google 324 COUNTER PROPORTIONAL. wheel v, to the length of the stroke made by the rack r. To facilitate the adjustment with the greatest accuracy, the radius of the counter-arm 76 2 can be lengthened or shortened by means of the pin W, which can be shifted up or down in the slot; and when the proper distance is obtained, made fast by a nut on the back side of the arm. The ratchet-wheel c, and centre pin e, which passes through an eye in the shoulder of the cross-piece k, on the frame b, give motion to the dial hands. The ratchet-wheel is moved in proportion to the length of stroke communicated to the counter-arm n 2, by means of four or five pawls or catches f, each a little longer than the other: for instance, if the space between two teeth on the ratchet-wheel be divided into four equal parts, and four or five pawls are used, they are each longer than the other by that distance; by which means, one or more of the set are always in contact with the tooth nearest their points, thereby obtaining a continuous bearing or hold of the ratchet-wheel, without the possibility of the least slip or play. The moveable pawls f all work on the same centre or pin on the arm d, which works on the same centre as the ratchet-wheel The pawls are made of steel; their points are kept in contact with the tooth nearest to them, by means of the curved elongation of each pressing against the pin h1 on the off-side of the arm, to prevent the least slip or return of the ratchet-wheel during the back travel of the arm with the pawls, or whilst the pawls are moving back over the teeth. Catches g, of the same construction and number as those on the arm, are placed on the frame b, working on a pin in it, so that their ends are pressed into the space between the two nearest teeth on the ratchet-wheel, to render the stop-catches more effective. The ends of the spring i, which is a piece of brass bent or curved, and slit into as many pieces as there are catches for it to act on, presses against the curved part of the catches. The guard 1 crosses the arm d, keeping the arm and catches steady when moving. The pin m, in the centre of the arm, passes through the alot in the back of the counter, to which the counter-arm is made fast by a nut. 1007. 1008. do The counter's operation requires but little explanation: the length of stroke of the rack being deter- mined, say 12 inches, and the pin in the slot adjusted by that length of travel, 50 that the hand on the outer circle of the dial-plate exactly makes a space, as from 3 to 4. Whatever distance within 12 inches the rack moves forward, say 3, 5, 8, or 10 inches, it will give motion to the ratchet-wheel and hand only in that proportion, the stop-catches allowing the ratchet-wheel to move round during the forward motion of the rack; but on the back travel of the rack-arm and catches, they being pressed by their own as well as the springs i into the space between the teeth nearest their ends, prevents not only the return of the ratchet-wheel, but also the least slip or return, by which means the face hands remain where they were carriod to during the forward motion of the rack; from which it will be seen Digitized by Google CRACKER AND BISCUIT MACHINE. 325 that whatever the index, or from point to point on the outer circle represents, whether distance or quan- tity, by communicating motion to the rack a given distance, it will, on inspection of the dial-plate at any time, be found what has been performed. COUNTERFORTS. See RAILWAY ENGINEERING. CORROSION OF BOILERS. See BOILERS, and DETAILS OF ENGINES. COVER ON SLIDE-VALVE, required to produce a given expansion. See PROPORTIONS and PROP- ERTIES OF THE STEAM-ENGINE CRACKER AND BISCUIT MACHINE. It is highly important where large quantities of biscuit are made for sea, either for the commercial or war marine, that there should be some machine for the speedy preparing of such kind of provisions, so as to preserve the flavor and quality of the flour, which we well know is not the case with all kinds of bread, as some will not keep fresh longer than two or three days. The machine represented in the engraving was patented some years ago by W. R. Nevins; and although there have been a number of machines built for the same purpose, yet good judges have pronounced it to be the best machine of the kind in existence, and in its present im- proved condition, without a rival. One of these machines was put up at St. Augustine during the Florida war, and it was of great benefit to the troops there. It has been examined by commissioners of the British navy, and has met their entire approbation. The Brazilian government has also requested one to be sent them, and there are others in use at Norfolk, Va., and Louisville, Ky. 1009. R L Description.-A A A A is the frame. B B are two feeding-rollers, the dough being fed into them on the board C. DD is an endless band the same width as the feed-rollers. This band is for carrying the dough from the feed-rollers to the cutters and forward off the cutters on the band-frame Y, to be taken off after the dough is cut into the desired size and form. The frame Y, on which the band D runs over the roller C, can slide under the machine when the machine is not in operation, 80 as to occupy as little room as possible. P is a crank for working the machine, and on the crank-shaft is a cog-wheel O, meshing into a larger cog-wheel N. The cog-wheel N moves the cutters, not in a rotary motion, but up and down, cutting the biscuit clean by the reciprocating motion ingeniously combined with the rotary by two eccentrics on the shaft, which will be observed between N and the larger, or fly-wheel, on the other side of the frame. While the cutters are moved by N, the shaft of o gives motion to the cog- wheels on the other side of the frame, and by the accumulation of power on the fly-wheel the whole apparatus is very easily worked. The cog-wheel G meshes into the cog-wheel R, for the purpose of giving the feed-rollers a uniform speed, something very necessary, as bakers know, so that there may not be too much friction by the rollers, in which case crackers and biscuits are afterwards apt to split open, and in warm latitudes soon spoil. The endless band is made to bring forward the dough by two cranks, one seen on the opposite side of the frame, inside of the fly-wheel, which works a pendulum shaft below the handle P, on which is a cord passing over a pulley at the end of the feed-board C; on the end of this cord is a weight which works by the pendulum the toothed pulley, on which is a clamp to slip and cut the exact distance the band is wanted to move for every cut of the cutters, for the band D passes over the roller of the toothed pulley, on which is the cord, and round by C. There is a slot in the pendulum shaft, 80 that the pin can be moved up or down, for a long or short cut, and by the shifting or changing the tooth-wheels o and N, the speed of the cutters will be increased while the rest of the machine keeps a uniform motion. It will be observed that the cutters do not fall or press down upon the canvas direct from the shaft, there is a plate between the canvas and the cutters, so that a fine clean cut is made through the dough. One of these machines with cutters only for three biscuit in the breadth of the frame, has cut as fast as one in use in the British navy with fifty cutters, thus showing a great superiority. But the best recommendation comes from those who have them in operation, Mr. Stratton, of Brooklyn, and Mr. Wilson, of this city. who speak in the highest terms of their qualities. This machine is the invention of Mr. W. R Nevins, No. 609 Greenwich-street, New York, who manufactures them. Digitized by Google 326 CRANE, MOVEABLE. CRANE, MOVEABLE. Arranged and used for laying the voussoirs in the inverted arches of the United States Dry Dock at Brooklyn, New York, by Wm. J. McAlpine, predecessor to Mr. Stewart, the present Chief Engineer. 1010. 18 X 76 186 279 $ THE Degrees. TOX15 AT % 194 Ii I'' $1525 13x12 20ft 12x13 1011. T3 172 5.7 54 27.9 16ft 12x13 17% 20 ft SCALE.-8 feet=1 inch. This crane has been used for hoisting stone weighing from ten to fifteen thousand pounds, at the extremity of the arm, which describes a circle of fifty feet diameter. It has also been used with an out- rigger, by which stones from three to five tons weight were hoisted ten feet beyond the extremity of the arm. A similar crane was used by the same engineer in the construction of the locks of the enlarged Erie Canal A moveable sheave traversed along the arm of the crane, which was laid on an inclination Digitized by Google ORANE, FOUNDRY. 327 towards the mast of twenty degrees. By the use of the "Siamese blocks," the stone is moved towards or from the mast, and hoisted or lowered with the accuracy requisite for setting fine-cut stone. CRANE, Foundry. The accompanying engraving exhibits the best description of foundry-crane yet invented. It is manufactured by W. A. Burke, of the Lowell Machine-Shop, Massachusctts. Fig. 1012 is a side elevation, and Fig. 1013 an end elevation. & 1012. J H B 8 K M 10. N H 1013. C R CRANK: theory of,-Supposed loss of power from use of ; strength of malleable-iron cranks,-Ta- bles of strength of cast-iron cranks,-Rules for strength of malleable-iron cranks,-Rules for strength of cast-iron cranks. See MECHANICAL POWER OF STEAM. CROSS-HEAD. See DETAILS OF ENGINES. CULVERTS. See RAILWAY ENGINEERING. CURVES. See RAILWAY ENGINEERING. CURVILINEAR TOOLS: Simple and Complex, for mouldings both external and internal. See TURNING TOOLS. CUTTER-BARS. See BORING TOOLS. Digitized by Google 328 CUTTING AND CARVING MACHINERY. CUTTING AND CARVING MACHINERY. Machinery and Apparatus for Cutting and Carving Substances to be applied for Inlaying and other purposes.-This invention consists in certain improved constructions or arrangements of machinery, having a revolving cutter, by means of which, in conjunc- tion with a moveable table, tablets of wood and other materials can be cut away, carved, countersunk, and perforated, in various ornamental forms, with great facility, for the production of inlaid devices, gothic tracery work, and other kinds of ornaments hitherto usually wrought by hand. 1014. c U s 1015. 1017. 1019. 1021. 1020. 1018. K . 1016. H II 8 Fig. 1014 represents a side elevation; Fig. 1015, an end elevation; and Fig. 1016, a horizontal view of the machinery. AA is a bench or table, for supporting the several parts of the machine; BB is a standard or bracket-frame, firmly fixed to the said bench; which frame is provided with plummer- blocks and bearings CC, to receive a spindle D. E is a forked frame or swinging arm, firmly fixed upon the spindle D; and the other end of the arm E is furnished with suitable bearings, which carry, in a vertical position, a spindle F. The lower end of this spindle F is formed to receive a chuck V, or other suitable contrivance, for attaching and holding securely the tool, drill, or cutter X, or such other cutter as may be required; and upon the spindle F, near its upper end, is fixed a conical pulley G, having grooves of different diameters, for the purpose of determining the velocity with which the spindle shall be made to revolve. This pulley is designed to receive an endless band or cord H, which passes round the lower part of a similar pulley I, running loosely upon the spindle D; the upper groove of the pulley I is made to receive another endless band or cord K, that passes around a wheel or drum L, supported by a standard or frame N, which is connected by a similar frame M, to the standard B; but the band K may be driven by any other means. o is a horizontal moveable table, mounted upon a vertical shaft R, which passes through the bench A; its lower end being supported by, and turning freely upon a step or bearing S, in the arch Z, fixed to the framing of the bench. The tablet or slab of wood, or other material intended to be wrought by the cutter X, is to be placed upon the turning- table as at P, and made fast thereon by screwed clamps. At the left-hand end of the bench A, there Digitized by Google CUTTING-ENGINE. 329 is a vertical bar J made fast to the wood framing, in which there is a fulcrum-pin for the lever W to turn upon; one end of this lever W is formed into a concave socket to receive, as a step, the lower end of the spindle D before mentioned, and the other end of the lever is connected by a joint with a treadle-rod T. This treadle-rod and lever are for the purpose of raising, when required, the spindle D, with the forked frame E, carrying the drill. U is an adjustable screw set in the leg of the bench as a stop to the lever, intended to regulate the descent of the spindle D with the frame E, in order that the cutter X shall not penetrate deeper into the material or substance P than may be desired. Fig. 1021, and the part dotted in Fig. 1015, represent another arrangement for raising and lowering the spindle D with the forked frame and drill, instead of the lever and treadle-rod before described: this arrangement is used when the carving of variable relief, such as foliage, figures, &c., is required to be executed. Upon any convenient part of the standard B is fixed a frame a, with bearings b b to receive and support the axle of a quadrant c, which has a lever d attached to its centre. From the periphery of the quadrant c is suspended by a chain e, or other suitable contrivance, the spindle D, carrying the forked frame E with the drill. To the lever d a weight f is suspended by a rod, or other convenient means, hung in any of the notches provided in the lever for that purpose; which weighted rod acts as a counter-balance to the spindle D and the several parts attached thereto, thus enabling the cutter X to be raised or lowered with the greatest facility and precision; all the other parts of the machine, and their action, being the same as hereinbefore described. Fig. 1017 is an elevation, and Fig. 1018 an under-side or end view, of a tool or cutter for cutting or carving a semi-circular or quarter-round hollow, for mouldings, gothic tracery, dic. Fig. 1019 is an ele- vation, and Fig. 1020 an under-side or end view, of a tool or cutter for cutting or carving a bed and fillet, or astragal. These are only two examples of cutters, but of course a great variety may be employed, and these must depend upon the form of the edge of the recess intended to be cut or formed as any and every variety of rounds and hollows, ovolos, agees, &c., separately or combined, may be executed, not only in straight lengths, but to the form of any regular or irregular curve that may be desired. The mode of cutting or carving with this machine is as follows:-Upon the revolving table O, the tablet, slab, or piece of wood, or other material P to be cut or carved, is fixed and on its upper surface, when desired, is placed a template or pattern Q, (formed of iron, brass, or other approved material,) of the design required to be cut or carved; and the two are firmly held upon the table o, by cramps or cramping-bars, as shown. Motion being given by any convenient power to the wheel or drum L, or communicated by any other means to the band or cord K, the pulley I will be made to turn rapidly upon the spindle D; by which means the band or cord H passed round the pulley G will cause the spindle F carrying the cutter X to revolve with great speed, the velocity of the cutter being deter- mined by the proportions which the diameters of the pulleys G and I bear to each other, and the speed of the driving power. The cutter X being set to the depth of cut required by adjusting the stop U, the workman passes down the treadle-rod T with his foot, which causes the lever W to raise the spindle D with the cutter X, and the several parts attached thereto: thus the forked arm E is raised, and being moved around the cutter X, may be passed over the tablet P in an arc; at the same time the moveable table o must be turned, 80 that the cutter may be perpendicularly pendent over the part of the tablet where the work is to commence. The revolving cutter X is then let down, by removing the pressure from the treadle-rod T, and it immediately penetrates into the tablet. The form in which the cutter moves over the tablet is now to be determined by guiding the shaft of the cutter against the edges of the template or pattern; the table O, with the tablet P upon it, being moved at the same time, in order to keep the edge of the template always close to the shaft of the cutter. By thus moving the swing- ing-frame E and the table O, various arcs of circles that are constantly tangental to each other may be traced upon the tablet under operation; thereby enabling every possible variety of regular and irregular, curved, and straight forms to be cut or carved in the material acted upon; and this combined or simultaneous action forms the principal novelty of the invention. The patentee claims the combination and application of the several parts as herein shown and de- scribed, and any variation of that combination or application for effecting the principle of his invention provided the swinging-frame which carries the cutter, and also the table on which the article to be wrought is placed, have both the means of circular motion. CUTTING-ENGINE Mr. Joseph Gaume, of Cincinnati, Hamilton County, Ohio, has invented a new and useful improvement in the Cutting-Engine, or machine for dividing and cutting the teeth of cog- wheels. In the accompanying engravings, Fig. 1022 is a plan. Fig. 1023 a side elevation, and Fig. 1024 a front view. The same letters indicate like parts in all the figures. The leading object of this invention is to adapt the common lathe, by the addition of certain parts, to the cutting of cog-wheels, chiefly for the use of small shops and manufactories where a lathe and cutting- engine are only required occasionally. And the nature of the first part of his invention consists in add- ing to a lathe, and in combination with the mandrel thereof, a puppet made in two parts for carrying the cutter, the lower half to be attached in the usual manner to the bench, and connected with the upper one by an inclined plane, that the upper part may slide on the lower one at an angle of forty-five or any other number of degrees, for the purpose of carrying the cutter or curr over the wheel in the oper- ation of cutting the cogs of bevel-wheels. The second part of his invention consists in combining with this puppet the cutter-frame, which carries the spindle of the cutter or curr by means of an adjustable horizontal slide, on which the cutter-frame moves to and fro to carry the cutter over the wheel in which the cogs are to be cut; the said slide being a plate with dove-tail or other formed edges, em- braced by or embracing the cutter-frame, and attached at one end by a fixed bolt to the top plate of the puppet, and at the other by a screw bolt that passes through a curved slot, whereby the cutter-frame may be made to carry the cutter in its horizontal motion diagonally with the axis of the mandrel for the cutting of diagonal cogs: the spindle of the cutter or curr having its bearings in an adjustable slide 42 Digitized by Google 330 CUTTING-ENGINE that moves at right angles to the mandrel, to bring the cutter over the axis of the mandrel, (the bed of the slide being connected with a vertical side in the cutter-frame to adapt the cutter to wheels of differ- ent diameters,) by means of a fixed bolt on one side and a screw-bolt passing through a curved slot on the other, that the axis of the cutter may be placed at any angle with a vertical line. The third part of the invention relates to the method of dividing the cogs, and consists in placing the index-wheel on a slide, that it may be adjusted to a wheel of any desired number of cogs on an arbor that communicates by a screw or its equivalent to the mandrel which carries the wheel to be cut, 80 that, by merely chang- ing the wheel on this arbor, a single division index may be used for the cutting of any desired number of cogs. The fourth part of the invention consists in combining the dividing apparatus with the mandrel of a lathe, by means of cogs on the pulley of the mandrel or on the mandrel, the dividing apparatus be- ing 80 arranged that it can be thrown in and out of geer. In the accompanying drawings a represents the bench of the lathe, and C the mandrel with its set of cone pulleys c, the face of the larger one of which is a crown cog-wheel d, the cogs of which engage with the threads of an endless screw on arbor e ; the threads of the screw are shown by dotted lines in the plan, Fig. 1022. One end of the arbor runs on the point of a pivot-screw f, and the other has a long journal that runs in a box in a standard g attached to the bench or the puppet head of the mandrel, 80 that when the rear end is liberated from the pivot-screw, the arbor can be moved far enough in the standard g to carry the ends of the screw out of the cogs of the crown-wheel, that the mandrel may be used for turning the cog-wheel: in this way the wheel can be made with great accuracy, for it is turned and cut on the same mandrel, and therefore there is no danger of not having the wheel properly centered. When the wheel is to be cut, the acour e is properly mounted, and its outer end is adapted by a collar and nut to receive a spur-wheel j of any desired number of cogs, which take into the cogs of the wheel K, one face of which is provided with the division plate or index b, and the other end with a handle m for turning it. This wheel is fitted to and turns on a stud-pin n, projecting from plate o, that slides on an arm p of the standard g, that it may be set to the proper pitch line of a wheel of any desired size on the arbor e, and there held by a screw q. A spring point or catch T is used to catch in the notches of the index or division plate b. From the foregoing it will be seen that with any given size of wheel on the arbor e, the number of cogs to be cut may be varied by the motions of the dividing or index wheel, as in the ordinary dividing- engine, and that, by changing the wheel on the arbor e, any variation can be given to these divisions. The wheel having been turned and the dividing apparatus put in connection, the centering puppet head 8 of the lathe is thrown back, and the extra puppet t is secured in place on the bench. This puppet is made in two parts, (tt,) connected together by a dove-tail or other slide и at an angle of 45°, or any other number of degrees with the plane of the bench. The lower half t is secured to the bench, and the other (t) can be made to slide on it by means of a handle or lever v that turns on a fulcrum-pin W attached to the lower half, and connected with the upper half by a pin X that passes through a slotted hole in a well-known manner. The top plate of the upper half is in a plane parallel with the mandrel, and has a dove-tail slide y connected with it at the forward end by a fixed bolt z, (see Fig. 1025, which is a plain view of this part,) and at the other end by a screw bolt (a) that passes through a curved slot (see the dotted line) in the top plate, so that any horizontal inclination desired may be given to this slide which is embraced by the bottom plate H of the cutter-frame, (c,) and which can be made to slide thereon by a handle or lever (d) that turns on a fulcrum-pin attached to the puppet and connected with the cut- ter-frame by a joint-link, (e,) so that by the motion of this lever the attendant carries the cutter to and fro horizontally over the edge of the wheel to be cut, for cutting spur cogs in a direction parallel with the axis of the mandrel, or inclined therewith as the slide may be set, to be indicated by a pointer (f) on the cutter-frame, and an index (g) on the top plate of the puppet. But when the machine is used for cutting the cogs on bevel-wheels, then the cutter-frame is carried by sliding the upper part (t) of the puppet head on the lower part Fig. 1025; the inclination of this slide determining the bevel of the cogs cut. The forward part of the cutter-frame has a plate, (h,) that alides in it vertically by means of a screw, (h,) to adapt the cutter to any desired diameter of wheel to be cut; to this is connected another plate (j) that turns on a bolt, and further secured by a screw-bolt (k) that passes through a curved slot, (1,) by means of which the plate (j) may be turned on the fixed bolt as a centre to give any desired in- clination to the axis of the cutter; and this last-named plate is provided with dove-tail ways in which alides the cutter-carrier (m,) which is a frame in which are the bearings of the spindle (n) of the cutter, (o,) so that this may be regulated endwise by a set screw (p.) The cutter is rotated by a belt (q) that passes from any first mover over a pulley (r) on the spindle. From the foregoing it will be seen that the cutter can be adjusted in any direction relatively to the axis of the mandrel that carries the wheel to be cut, and that, by means of one of the handles or levers, the cutter-frame can be moved to and fro to cut the cogs by sliding the cutter-carriage on the puppet in a horizontal plane parallel with the axis of the mandrel, which, by the adjustment of the ways or slide on the puppet, may be adjusted to move in a vertical plane projected from the axis of the mandrel or at any inclination therewith to cut oblique cogs; or, by means of the other handle, that the cutter-frame may be made to move with the upper part of the puppet on an inclined plane to cut the cogs of bevel cog-wheels. It will be obvious, from the above, that the plan of the junction of the two halves of the puppet may be made at any in- clination desired to suit the bevel of the wheel intended to be cut. What he claims as his invention and has secured by letters patent, is making the puppet which car- ries the cutter-frame in two parts, separated by an inclined plane, that one may slide on the other for cutting the cogs of bevel-wheels, in combination with the cutter-frame that slides thereon; and also the cutter-frame and double puppet combined together in combination with the mandrel of the lathe. He also claims the method of adapting the index or division plate that has but one set of divisions, to any division of cogs desired to be cut, by means of shifting the wheel on the arbor that communicates motion to the mandrel, in combination with the sliding connection of the index or division wheel, whereby nu- merous divisions on the index plate are avoided. And further, he claims the dividing apparatus in combination with the mandrel of a lathe by means of the cog-wheel and pulleys put on one end of the Digitized by Google CUTTING-ENGINE. 331' a is 3 m 1023. 0000000 j M a b D 1025. C - a d m n b K 110 D jo C In & ИО P P 1024. 1022. 7 a y H H e $10 S S Digitized by Google 332 CUTTING TOOLS. same mandrel, whereby the wheels to be cut can be turned and cut on the same mandrel without being removed therefrom to insure good work, and whereby also the turning-lathe may be used for a cutting- engine. This machine may be composed either of a single lathe, or of a complicated one, of any desired dimen- sions, and nothing need be added to it but a side-coupling, to form the division. First. Its advantages are: turning the wheel on its points; it is thus cut on these same points, with the axis, the length which may be placed on the lathe; likewise, by turning the wheel on the flat side, the hole in the centre and the circumference are cut without its being removed. Second. This machine can cut a wheel on the circumference obliquely, to the right or left, with any desired inclination; and also the same with regard to the wheel on the side. Third. The wheel can be cut at an angle of forty-five degrees. This machine can take the place of, and even offers more advantages than the Great Platform." It can be constructed of any dimension, always being able to cut the wheel which can be turned on the lathe, even should it be fifteen feet in diameter. This machine can be adapted to a lathe placed upon a wooden bench, with only one hun- dred and fifty pounds additional weight of castings. This cutting machine may be obtained, with all the above-mentioned advantages, from one inch in diameter to two feet. The cast-iron lathe offers more solidity, and with a little additional expense. The division extends to all numbers with the greatest precision. CUTTING AND PUNCHING MACHINE See PUNCHING AND CUTTING MACHINE. CUTTING TOOLS, general remarks upon. Cutting tools may be included in three groups, namely, Paring Tools, Scraping Tools, and Shearing Tools. First. Paring or splitting tools, with thin edges, the angles of which do not exceed sixty degrees; one plane of the edge being nearly coincident with the plane of the work produced, (or with the tangent, in circular work.) These tools remove the fibres principally in the direction of their length, or longitudi- nally; and they produce large coarse chips or shavings, by acting like the common wedge applied as a mechanical power. Secondly. Scraping tools with thick edges, that measure from sixty to one hundred and twenty de- grees. The planes of the edges form nearly equal angles with the surface produced; or else the one plane is nearly or quite perpendicular to the face of the work, (or becomes as a radius to the circle.) These tools remove the fibres in all directions with nearly equal facility, and they produce fine dust-like shavings by acting superficially. Thirdly. Shearing or separating tools, with edges of from sixty to ninety degrees, generally duplex, and then applied on opposite sides of the substances; one plane of each tool, or of the single tool, coincident with the plane produced. In explanation of these views, the diagram, Fig. 1026, is supposed to represent seven different tools, the bevels or edges of which are all at the angle of sixty degrees; this may be considered as the medium angle of the paring, scraping, and shearing tools. The cutting and scraping tools are supposed to be moving from A to B, which line represents the face of the work; or the tools may be considered to be at rest, and the work to be moving from B to A. Or, in turning, the tool may be supposed to remain fixed, and the circle to represent the moving sur- face of the work; one plane of the tool then becomes a tangent or radius. The shearing tools, if in pairs, are proceeding towards each other on the line CD, whilst A B still represents the face of the work. The single tools act on the same principle, but the body of the mate- rial, or the surface of the bench or support, supplies the resistance otherwise offered by the second tool. The tools a f are bevelled or chamfered on both sides, the others from one side only; in these lat- ter, the general face of the tool forms the second side of the angle, and allowing for exaggeration, both as to excess and deficiency, the diagram may be considered to represent the edges of the following tools. [a bcd, Splitting and Paring Tools, proceeding from A to B.] a, The axe, or the cleaver for splitting. b, The side hatchet, adze, paring and drawing knives, paring chisels and gouges, the razor, penknife, spokeshave, the engraver's graver, and most of the engineer's cutting, turning, and planing tools for metal C 1026. g f e d c b a A B g D c, The turning chisel for soft wood, the chipping chisels for iron, stone, &c. d, The joiner's chisels and carving tools, used with the bevels downwards, the joiner's planes, the cross-cut chisel for metal, and some other metal tools. [ef. Scraping Tools, proceeding from A to B.] e, When single, the scraping tools for turning the hardwoods, ivory, and brass, the hand-plane for metal: and when multiplied, the various saws and files. f, When single, a triangular scraper for metal; and when multiplied, the cross-cut saw for wood, and also polygonal broaches or rimers with any number of sides, for metal [e Shearing Tools, proceeding from C to D.] e, When duplex, shears with edges from eighty to ninety degrees, commencing with delicate lace Digitized by Google CUTTING TOOLS. 338 scismors for single threads, and ending with the engineer's shears for cutting iron bars and plates up- wards of one inch thick; also duplex punches with rectangular edges, for punching engines and fly- presses. e, When single, the carpenter's firmer and mortise-chisels, the paring-knife moving on a hinge, and cutting punches for gun-wadding and thin materials. f, When duplex, common nippers for wire; more generally, however, the blades are inclined 80 that one bevel of each blade lies in one and the same plane, and which is vertical to A B, as at g g. f, When single, the smith's cutting-off chisel. In practice, the tools differ from the constant angle of sixty degrees, assumed in the diagram for the convenience of explanation, as the angles of all tools are determined by the hardness and the peculiar- ity of fibre or structure of the several substances upon which they are employed. The woods and soft fibrous materials require more acute angles than the metals and hard bodies; and the greater or less degree of violence to which the tools are subjected, greatly influences likewise the angles adopted for them. Thus, under the guidance of a little mechanism, the thin edge of a razor, which is sharpened at an angle of about 15 degrees, is used to cut minute slices or sections of woods, in all directions of the grain, for the purpose of the microscope. But the carpenter and others require more expeditious practice, and the first change is to thicken the edges of the tools to range from about 20 to 45 degrees, to meet the rough usage to which they are then exposed, whether arising from the knots and hard places in the woods or the violence applied. In tools for iron and steel from 60 to 70 will be found a very common angle, in those for brass 80 to 90, in hexagonal broaches for metal it increases to 120, and in the octagonal broach sometimes employed the angle is still greater; in the circular broach required by clock and watch makers, the angle disap- pears and the tool ceases either to cut or scrape, it resolves itself into an instrument acting by pressure, or becomes a burnisher. To a certain extent, every different material may be considered to demand tools of a particular angle, and again the angle is somewhat modified by the specific mode of employment: these conditions jointly determine the practical angles suited to every case, or the angles of greatest economy or most pro- ductive effect. The diagram shows that, independently of the measure of the angle of the tool, we have to consider its position as regards the surface of the work, the broad distinction being that, in the paring tools, the one face of the wedge or tool is applied nearly parallel with the face of the work; and in the scraping tools, it is applied nearly at right angles, as explained in the foregoing definitions. Indeed the paring tools, if left to themselves, will in some cases assume the position named; thus, for example, if we place a penknife at an elevated angle upon a cedar pencil, and attempt to carry it along as a carpenter's plane, the penknife, if held stiffly, will follow the line of its lower side and dig into the wood; but if it be held slenderly, it will swing round in the hand until its blade lies flat on the pencil, and it will even require a little twisting or raising to cause it to penetrate the wood at all. This disposition appears to be equally true in the thin edges of the penknife or razor, and in the thick edges of the strong paring tools for metal. The action of a cutting tool in motion is two-fold. The moving force is first exerted on the point of the wedge, to sever or divide the substance particle from particle; the cohesion of the mass now directly opposes the entry of the tool, and keeps it back. But the primary motion impressed on the tool having severed a shaving, proceeds to bend or curl it out of the way; the shaving ascends the slope of the wedge, and the elasticity of the shaving confines the tool in the cleft, presses it against the lower side, disposes it to pursue that line, and therefore to dig into the substance. The Forms and Motions of Tools, as regards the production of Lines, Superficies, and Solids.-The principles of action of all cutting tools, and of some others, whether guided by hand or by machinery, resolve themselves into the simple condition, that the work is the combined copy of the form of the tool, and of the motion employed. Or in other words, that we exactly put into practice the geometrical definitions employed to convey to us the primary ideas of lines, superficies, and solids; namely, that the line results from the motion of a point, the superficies from the motion of a line, and the solid from the motion of a superficies. It therefore follows, as will be shown, that when the tool is a point having no measurable magnitude, that two motions must be impressed upon it, one equivalent to the breadth, and another equivalent to the length of the superficies. When the tool is wide, so as to represent the one dimension of the super- ficies, say its breadth, then only one motion is to be impressed, say a motion equivalent to the length of the superficies; and these two are either rectilinear or curvilinear, accordingly as straight or curved superficies are to be produced. To illustrate this in a more familiar way than by the ideal mathematical conceptions-that a point is without magnitude, a line is without breadth, and a superficies without thickness-we will suppose these to be materialized, and to become pieces of wood, and that the several results are formed through their agency on soft clay. Thus supposing g g to be two boards, the edges of which are parallel and exactly in one plane, and that the interval between them is filled with clay; by sliding the board p along the edges of gg, the point in p would produce a line, and if 80 many lines were ploughed that every part of the clay were acted upon by the point, a level surface would at length result. The line 1, such as a string or wire, carried along g y, would at one process reduce the clay to the level of the edges of the box. Either the point or the line might be applied in any direction whatever, and still they would equally produce the plane, provided that every part of the material were acted upon; and this, because the section of a plane is everywhere a right line, and which conditions are fulfilled in the elementary apparatus, as the edges of gg are straight and give in every case the longitudinal guide, and with 1 the second line is formed at once, either with a string, a wire, or a straight board; but in P the point Digitized by Google 334 CUTTING TOOLS. requires a second or transverse guide, and which is furnished by the straight parts of the board P rubbing on the edges of g g, and therefore the point obtains both a longitudinal and a transverse guide, which were stated to be essential. The board c, with a circular edge, and m, with a moulding, would respectively produce circular and moulded pieces, which would be straight in point of length in virtue of gg the line of motion, and curved in width in virtue of c or m the lines of the tools. But now c and m must always advance parallel with their starting positions, or the width of the moulding would vary and this is true, whenever curved guides or curved tools are employed, as the angular relation of the tool must be then constantly main- tained, which it is supposed to be by the external piece or guide attached to m. I 1027. I 9 g a Supposing g g each to have circular edges, as represented by the dotted arc a a, or to be curved into any arbitrary moulding, the same boards p, i, c, m would produce results of the former transverse sections, but the clay would in each case present, longitudinally, the curved figure of the curved longi- tudinal boards a a; here also the line of the tool and the line of the motion would obtain in the result. If, to carry out the supposition, we conceive the board a a to be continued until it produced the entire circle, we should obtain a cylinder at one single sweep, if the wire 1 were carried round at right angles to a a. But to produce the same result with the point p, it must be done either by sweeping it round to make circular furrows very near together, or by traversing the point from side to side, to make a multi- tude of contiguous lines parallel with the axis of the cylinder. In either case we should apply the point to every part of the surface of the cylinder, which is the object to be obtained, as we copy the circle of a a (which is supposed to be complete) and the line l, or the transverse motion of p, which is equivalent to a line. But it is obvious that, in every case referred to, there is the choice of moving either the clay or the tool, without variation in the effect. If in respect to the circular guide a a, we set the clay to rotate upon its centre, we should produce all the results without the necessity for the guide-boards a a, as the axis being fixed, and the tool also fixed, the distance from the circumference to the centre would be everywhere alike, and we should obtain the condition of the circle by motion alone, instead of by the guide; and such, in effect, is turning. An every-day example of this identical supposition is seen in the potter's wheel; and the potter also, instead of always describing the lines of his works with his hands, as in sketching, occasionally resorts to curved boards or templets, as for making the mouldings for the base of a column, or any other circular ornament. But here, as also in ordinary turning, we have choice either to employ a figured tool, or to impress on a pointed tool a path identical with the one section; for example, the sphere is turned either by a semicircular tool applied parallel with the axis, or else by sweeping a narrow or pointed tool around the sphere in the same semicircular path. Having shown that in every case the superficies is a copy of the tool and of the one motion, or of the point and the two motions, it will be easily conceived that the numerous superficies and solids, emana- ting from the diagonal, spiral, oval, cycloid, epicycloid, and other acknowledged lines, which are mostly themselves the compositions of right lines and of circles, may be often mechanically produced in three different ways. First, by the employment of tools figured to the various shapes, and used with only one motion or traverse; secondly, by the use of figured guides, cams, or shaper-plates, by which the motion is con- strained, just the same as p makes a right or a curved line, in virtue of its straight or curved guide; and thirdly, by the employment of a point actuated by two motions, by the composition of which most geometric lines are expressed. Thus when uniform motions are employed, two rectilinear motions produce a diagonal to themselves; one circular and one continued right-line motion, give the spiral, the screw, and the cycloid also if, dur- ing one circular revolution, either the circle or the point make one oscillation in a right line, we obtain the oval by two circular movements we obtain the epicycloid, by three motions the compound or dou- ble epicycloid, and 80 on. And when one or both of the rectilinear or circular generating motions are variable as to velocity, we obtain many different kinds of curves, as the parabola, hyperbola, and others; an 1 thence the solids, arising from the revolutions of some of these curves upon an axis. We produce the practical composition of any two lines or movements, whether regular or irregular, by impressing these movements on the opposite extremities of an inflexible line or rod from which rod we obtain a compounded line if we trace the motion of a point inserted in any part of the rod, and we obtain a compounded superficies if we copy the motion of the entire line. This may need explanation. Supposing that in Fig. 1027, the back guide gg to remain a straight line, the front to become the Digitized by Google CUTTING TOOLS. 335 circular arc a a, the board p being now traversed in contact both with the straight and curved edges, the point p would describe a line if it were close against the line gg, or an arc if close against the arc a a; midway it would describe an arc of about half the original curvature. On the other hand, the line b would cut off the clay in a superficies, possessing at the three parts these same conditions, and merging gradually from the right line to the arc a a. But a similar composition of the two lines or motions would occur, were the lines g g, a a to be ex- changed for any others, similar or dissimilar, parallel or oblique, or irregular in two directions; and in mechanical practice we combine, in like manner, two motions to produce a compound line or a com- pound superficies. Indeed in many cases there is no alternative but to impart to two edges g a of a block the marginal outlines of the superficies, and then, generally by hand-labor, to reduce all the inter- mediate portions under the guidance of a straight edge applied at short intervals upon the two edges, which thus become compounded or melted together in the superficies. Numbers of irregular surfaces can be produced by this mode alone. In fine, in mechanical processes, we translate the mathematical conceptions of the rectilinear, circular, and mixed motions of points and lines, into the mechanical realities of rectilinear, circular, and mixed motions of pointed or linear tools. It is not imperative, however, that the tools should have but one fixed point or edge, as without change of principle a succession of similar points may be arranged in a circle, to constitute a revolving cutter, which by its motions will continually present a new point, and multiply the rapidity of the effect. In most cases, the introduction of a tool with a figured outline, cancels the necessity for the means otherwise required to generate such figured line by the motion of a point; and a tool with a figured superficies, cancels also the remaining motion required to produce the superficies, and the tool is .imply impressed as a stamp or die. In tracing the method of applying these theoretical views to the explanation of the general employ- ment of cutting tools, or the practice of the workshop, we may safely abandon all apprehension of com- plexity, notwithstanding the almost boundless variety of the elements of machinery, and other works of cutting tools. For although all the regular figures and solids referred to are in reality met with, besides a still greater number of others of an irregular or arbitrary character, still by far the greater majority of pieces resolve themselves into very few and simple parts, namely, solids with plane superficies, such as prisms, pyramids, and wedges, and solids with circular superficies, such as cylinders, cones, and spheres. These are frequently, as it were, strung together in groups, either in their entire or dissected states; but as they are only wrought one surface at a time, the whole inquiry may be considered to resolve itself into the production of superficies. The guide principle is to be traced in most of our tools. In the joiner's plane it exists in the form of the stock or sole of the plane, which commonly possesses the same superficies as it is desired to pro- duce. For instance, the carpenter's plane used for flat surfaces is itself flat, both in length and width, and therefore furnishes a double guide. The flat file is somewhat under the same circumstances, but as it cuts at every part of its surface, from thousands of points being grouped together, it is more treacherous than the plane as regards the surface from which it derives its guidance, and from this and other reasons it is far more difficult to manage than the carpenter's plane. In many other cases the cutting instrument and the guide are entirely detached; this is strictly the case in ordinary turning, in which the circular guide is given by the revolution of the lathe mandrel which carries the work, the surface of which becomes the copy of the tool, or of the motion impressed upon the tool, either by the hand of the workman under the guidance of his eye alone, or by appropri- ate mechanism. When the lathe is employed under the most advantageous circumstances to produce the various geometrical solids or figures, the tool is placed under the guidance of a ruler, or rather of a slide, by which its path is strictly limited to a rectilinear motion. Thus, for a cylinder the slide is placed exactly parallel with the rotary axis of the mandrel, and for a plain flat surface the tool is moved on a slide at right angles to the axis. Generally two slides fixed in these positions are attached to the lathe to carry and guide the tool, the machine being known as the sliding-rest; but mostly the one slide only is used as a traversing or directional slide for guiding the tool, the other as an adjusting or position slide for regulating the penetration of the tool into the work. Sometimes the two slides are moved simultaneously for the production of cones, but more generally the one slide is placed oblique and used alone. The lathe is employed with great effect in producing plane surfaces, but the more modern engine, the planing-machine, the offspring of the slide or traversing lathe recently adverted to, is now also very much employed for all kinds of rectilinear works. The planing-machine being intended principally for rectilinear solids of all kinds, its movements are all rectilinear, and these are in general restricted to three, which are in the same relation to each other as the sides of a cube; namely. two are horizontal and at right angles to each other, and the third is vertical, and therefore perpendicular to the other two. The general outline of the machine will be con- ceived by imagining a horizontal railway to take the place of the revolving axis of the lathe, and the slide-rest of the lathe to be fixed vertically against the face of a bridge stretching over the railway. In the general structure of this most invaluable machine, the railway is the cutting slide, upon which the work is slid to and fro. For producing a horizontal surface, the horizontal slide is employed for traversing the tool across the face of the work, which is thus reduced by ploughing a series of parallel grooves, not exceeding in distance the width of the pointed tool, so that first the line, and then the sur- face arise, exactly as in the geometrical suppositions. For vertical planes, the vertical is the traversing slide, the horizontal, the adjusting and for oblique planes, the vertical slide is swivelled round to the assigned angle, the imaginary railway being employed in all cases to give the cutting motion. When we examine into almost any machine employed in cutting, it will be found that the end to be obtained is always a superficies, either plane or curved, and which superficies reduced to its elementary condition, presents length and breadth. Digitized by Google 336 DEAL SAWING-MACHINE. When therefore we have put on one side the mechanism required for connecting and disconnecting the engine with the prime mover, whether animal, steam, or other power, it will be found that when the superficies is produced by a pointed tool, the primary motions resolve themselves into two, which may be considered representative of length and breadth. The velocity of the one primary motion is suited to the speed proper for cutting the material with the most productive effect, which for the metals is sometimes as low as ten or twenty feet per minute, measured at the tool, and for the woods the speed is above ten or twenty times as great. The principal limit of velocity in cutting machines, appears to be the greatest speed the tool will safely endure, without becoming so heated by the friction of separating the fibres as to lose its temper or proper degree of hardness. The cohesion of iron being very considerable, a velocity materially exceeding ten to twenty feet per minute would soften and discolor the tool, whereas in general the tools for iron are left nearly or quite hard. Brass, having much less cohesion than iron, allows a greater velocity to be used lead and tin admit of still more speed; and the fibrous cohesion of the soft woods is so small, that when the angles of the tools are favorable, there is hardly a limit to the velocity which may be used. Water, soap and water, oil, milk, and other fluids, are in many cases employed, and especially with the more fibrous metals, for the purpose of lubricating the cutting edges of the tools to keep down the temperature, the fluids reduce the friction of separating the fibres and cool both the tool and work, thereby allowing an increase of velocity and at the same time they lessen the deterioration of the instrument, which when blunted excites far more friction, and is likewise more exposed to being softened, than when keen and in perfect working order. There are, however, various objections to the constant use of lubricating fluids with cutting tools. The velocity of the other prinfary motion is generally very small, and often intermittent; and it be- comes a mere creep or traverse motion, by which the pointed tool is gradually moved in the second direction of the superficies under formation. In producing circular bodies, one of these primary motions becomes circulating or rotary, and in com- plex or irregular forms an additional movement, making in all three, or sometimes four, are compounded; and lastly, when linear or figured tools are employed, one of the motions is generally expunged. CYLINDER See DETAILS OF ENGINES. CYLINDER COVER. See DETAILS OF ENGINES. DAGUERREAN TYPE See PHOTOGRAPHY. DEAL SAWING-MACHINE, by J. Macdowall. This machine differs from the common saw-mill frame in having the motive power included in it, and consequently also in the arrangement of several of its working parts. By this arrangement each sawing-frame is converted into a separate engine, perfectly distinct from the adjoining sawing-frames, and capable of being worked or stopped at the pleasure of the attendant, without affecting any other of the frames contiguous to it. This allows also of any frame being driven faster or slower than the others, as the qualities or natures of the various kinds of timber under opera- tion may require. The machinery may also be constructed without the steam cylinder and piston, and driven by an ordinary stationary steam-engine, there being a fast and loose pulley mounted upon the main shaft, upon which a belt from the actuating part of the stationary engine may be passed. Fig. 1028 shows a front elevation of the machine, looking to the face of the saws. Fig. 1029 is a side elevation, taken at the left of Fig. 1028. Fig. 1030 is a section, taken vertically through Fig. 1029. In all the figures the same letters of reference are used to denote the same parts. A A. the standards or main upright framings of the machine are bolted to the foundation, and otherwise firmly secured in their places by flanges: they are also bolted to the main beams that sup- port the flooring B B, thus dividing the machinery between the upper and lower apartments; the one of which contains the engine or driving power, while the other is occupied by the saw-frame machinery strictly so called. The cylinder of the steam-engine, by the agency of which the sawing machinery is driven, is shown at C: it is supplied with steam in the usual manner, through slide-valves contained in the valve-casing a, which receives the steam from the boiler through the main steam-pipe D and the induction pipe E. Having served its purpose in the cylinder, the steam is discharged by the eduction pipe F into the waste-steam pipe G. H H, the main driving-shaft is mounted upon bearings fixed upon the top of the standards A A. This shaft carries two fly-wheels II, two eccentrics J K, and also the two crank plants LL In these last are fixed the crank-pins b b, which are connected by the rods to the shaft carrying the frame of saws dd. This frame travels in the parallel slides or guide pieces e e attached to the cheeks of the framing A A. It will be seen that while the eccentric J is working the slide-valves, which admit and discharge the steam to and from the cylinder C, that the eccentric K is imparting motion to the spur- wheels ff, for the purpose of feeding or leading forward the timber by means of the link or rod g and ratchet or click h, which drives the ratchet-wheel i and pinion these being keyed upon the same carrying-stud. These spur-wheels ff, which are of rather a fine pitch, give a slight progressive motion to the timber under operation, by means of the system of meter-wheels and shafts III; and it will be perceived that of those wheels the four lower pairs are so mounted as to communicate their motion to the shaft carry- ing the intended iron feeding-rollers kk, which, by this arrangement of the geering, all receive an equal progressive motion simultaneously, and thus feed-in the timber shown at TT. By these means, the timber in its progress through the machine is gradually advanced and Digitized by Google DEAL SAWING-MACHINE. 337 presented to the teeth of the saws, as they are driven up and down by the reciprocating action of the piston-rod 1. It will also be understood that the extent of progressive motion given to the feeding-rollers through the agency of the system of geering, just described, may be varied and adjusted by the click or ratchet h being caused in its receding movements to escape over a greater or less number of teeth of the ratchet-wheel i, and thus produce a quicker or slower advance of the timber according to the nature of its grain, or the number of saws which are acting upon it. 1028. 1029. L K I H 3 B 8 A c m F E B B B B c G D M j d I 7 u и N W W A SCALE.-10 feet=3 inches. The governor, by which the supply of steam to the valve-box is regulated, is placed at the top of the machine, and is of the ordinary construction; the working parts of the governor being attached to the circular plate or disk of metal n, which is driven by the friction of the periphery of the revolving collar o keyed upon the main shaft. This mode of driving the governor simply by friction is preferred, because it admits of ready adjustment by sliding the collar nearer to, or farther from, the centre of the plate n, thereby regulating the speed of the governor, as may be desired by the attendant, whenever it is necessary to vary the speed of the engine to suit the different qualities of the timber to be operated upon. 48 Digitized by Google 338 DEAL SAWING-MACHINE. Having now described the general construction of the sawing-frame, it remains to show the mode of putting it into operation. Let it be understood that the engine for communicating the power is upon the high-pressure principle, and that the engine shown in the drawings is supposed to represent one of that construction of about seven horse power, which will be generally found sufficient for 1030. ordinary timber. Let it also be observed that this engine is shown in the position of half-stroke. The engine being first started in the or- dinary way, by opening the throttle-valve which is placed in the induction pipe E, and thus admitting the steam, its expansive force will cause the piston 1 to rise, and by the crosshead m and side links m' m', will draw up the shaft M, carrying the frame L of saws dd, and thus, through the connect- ing-rods c c, will drive the crank-plates LL round, and thereby communicate rotary mo- tion to the main shaft H, which will impart I its impetus to the fly-wheels II, and, at the same time, cause the eccentrics J K to re- volve; the eccentric J giving a reciprocating motion to the slide-valves through the rod p, the links r, and shaft q; and thus, as the piston works up and down in the cylinder in the ordinary manner, it will clearly be 5 perceived that the necessary reciprocating E a F action will be given to the frames containing the system of saws dd. These saws are of course adjustable in their respective frames so that any number may be employed, and B B also set at any required distance apart. It has been before stated that the engine being in operation, the other eccentric K will meanwhile cause the timber to ad- A vance to the teeth of the saws as required, D G by the system of geering which works the four indented feeding-rollers kkkk. It will also be perceived by reference to Fig. 1028, that each of the vertical shafts j has a feather or raised key upon its surface, in order to carry the two wheels j'j' round with them, and at the same time to allow these wheels to slide upon their respective shafts while in motion, in case of any in- equalities upon the surface of the timber k d K causing the upper feeding-rollers k k to rise or fall. To keep the wheels in geer the boss of the pair of horizontal wheels is T elongated, and has a groove turned upon it in order to embrace the end of the shaft * of the feeding-rollers, as shown in Fig. 1028. N @ Ordinary feeding tables with delivering rollers are placed in front and behind the sawing-frame, to conduct the deals and e timber to be cut on to the plates N N, upon W W which they are supported while under the A operation of cutting; and upon this plate, at the feeding end or front of the machine, there is placed a central guide-piece, or fence SCALE.-10 feet=3 inches. S, against which the deals are to be pressed by the springs tt, having friction-rollers at their ends for that purpose. These springs are adjusted to the tightness of the pinch required by the small winch and screw 26. The tables placed behind the machines to receive the timber after it has been cut into boards are, in other respects, similar to the front tables. It will be seen that there are two weights W W, suspended from the shafts of the upper pair of feeding-rollers kk by the rods vv, in order to keep them down upon the top edge of the timber with sufficient pressure to resist the upward lift of the saws when cutting. These weights are also suspended in the centre by a small chain and pulley from the shaft w, and at one end of this shaft is a ratchet-wheel x, the boss of which has mortises cut in it for the purpose of receiving a small crow-bar, in order to lift the weight and ease the top rollers when required. DENSITY. See FORCE. DENSITY. See PHORONOMY. Digitized by Google DERRICK. 339 1031. V o Top lik. N2 E a Boom 67 67.6 caty PEX SCALE.- 16 feet=1 inch. 5 Oil Whole lengthet mast 69 fest. 0 8ft Guy 162 own Platfor Bx15ft DERRICK, Stone Laying. Used at the United States Dry Dock, Brooklyn. Savage's Derrick: improved by W. J. McAlpine, Engineer. Digitized by Google 340 DERRICK. 1032. Mast so SCALE.-6 feet=1 inch. DERRICK, plan of a small. Used for setting small stone on the United States Dry Dock, Brooklyn. Digitized by Google DISTILLATION. 341 DISTILLATION. Improved Stills used in the distillation of rum-By pursuing the mode of manu- facturing sugar recommended, extremely little molasses will accrue; and the same also applies in re- gard to the skimmings; consequently there will be no more of the latter, than will suffice to give a desirable tone to the former: hence it is evident that the operations in the distil-house will be reduced to a very small scale. This, indeed, is as it should be every thing is converted into sugar that can be; and it is only the remnant that ought to find its way into the distil-house for conversion into rum. Cleanliness is particularly required in every department, from the mill-house to the rum-store: it is of as much importance in the distil-house as in the milling, boiling, and curing departments; and the planter who aims at perfect success in distillation, must be nice and clean even to a fault. Every vessel should be constantly washed and scrubbed, and also well limed down to prevent acidity and by these means the distil-house, and every thing that is in it, should always be perfectly sweet and clean. 1033. = de R NO A The apparatus used in separating the alcohol from the wash, is generally called a still ; bu. well descriptions of stills have 80 multiplied of late years, that some 300 or 400 patents might be mentioned, if it were of any utility doing 80. The first, which is one of the earliest improved stills, is that invented by Corty, and afterwards much simplified by Messrs. Shears & Sons. Fig. 1033 is a representation of this still A being the body of the still into which the wash is put; B is the still-head; CCC are three plates of copper, fitted into the upper part of the boxes D DD, which are kept at a regulated temperature by water being conducted over their outer surface, by means of the pipe E and the distributing-pipes G G G. The spirit-vapor then, rising from the body of the still, meets a check at the lowest plate C, by reason of the coolness occasioned by the water; this condenses Digitized by Google 342 DISTILLATION. the grosser part of the vapor and throws it back, whilst the lighter proceeds on to the second plate C, where a further coolness condenses another portion of the vapor, leaving a much purer spirit to encoun- ter the increased coolness at the third plate C. Here the last separation takes place; the aqueous and oleaginous particles being unable to sustain the temperature maintained, fall back condensed, and only a very strong spirit passes over in the gooseneck. By means of the cock F, in the pipe E, the supply of water to the boxes D can be very exactly regulated; and, as a natural consequence, the temperature can be very accurately adjusted. If the temperature of the upper box be kept at 174°, for example, the alcoholic vapor which passes over will be comprised of 90 per cent. of pure alcohol, or 65 over proof; but with a temperature of 194° Fahr. the vapor will contain only 66 per cent. pure alcohol, or 30 per cent. over proof. a is a screw-cap, through which a jet of steam or water may be sent to clear away the deposite, which otherwise will more or less accumulate on the upper surfaces of the plates C. At the lower end of the worm-pipe is affixed, by means of the brass swivel-joint screw H, a gas ap- paratus. The peculiar form of the pipe I into which the spirit runs from the worm, causes it to be filled shortly after the still commences working; whilst the other branch pipe K rises to some height, then returns, and is immersed in the small box L to the extent of about two inches in water. The gas from the still escapes by this pipe through the water, as the pressure can be but trifling. It is held, that by means of this gas apparatus the distillation proceeds in a partial vacuum, and that thereby there is a great economy in fuel. As the spirit enters the worm at 80 much lower a tempera- ture than in the old stills, that quantity of water is not required to cool the spirit vapor as would be otherwise. A still of 400 gallons is said to work off four to five charges in the day of twelve hours; yielding a spirit on an average of 35 per cent. over proof: which, for rum, is considered the most advantageous strength to run it at. Fig. 1034 is another arrangement of the same kind of still; being the addition of the common still A to the patent still B. In this case the contents of B are drawn down from time to time into A, and that of A run off as dunder; the spirit from A being conducted into B. One fire heats both stills; and it is stated that by the general adaptation and arrangement, a very large quantity of fine spirit is produced by the consumption of a very inconsiderable amount of fuel. L 1034. c M B H b a A I I a I The stills of Blumenthal, Laugier, and Coffey, though very excellent, and no doubt very efficient, are, notwithstanding, much better adapted for European distilleries than for sugar estates. I have seen many of them, as well as modifications of them, working on estates in India and the Straits; but I never knew them to afford satisfaction to their possessors: probably from not having such careful and skilful workmen to intrust them with, as are obtainable in Europe. From what I have already said, it will be seen that I entertain a very good opinion of the stills represented in Figs. 1033 and 1034, and consider them well adapted to the requirements of a sugar estate. But of all the different arrange- ments, I have never known any to surpass the common still and double retorts. As a distilling apparatus peculiarly suited by its simplicity, durability, economy, and efficiency, to the wants of the planter, I consider that it stands unrivalled. Digitized by Google DIVING-BELL. 343 Fig. 1085 represents the appara- tus as it is commonly used; but, if 1035. provided with a wash-heater, the pipe from the second retort, instead of passing directly to the worm- tank, would first run through the charger containing the wash, impart to it a large portion of its heat, and then enter the worm-tank. A still of 1,000 gallons, so provided, should run off 500 gallons of rum, avera- ging 30 to 40 per cent. over proof, between five o'clock in the morning and eight o'clock P.M. In working the apparatus, the still itself is load- ed with wash, and the two retorts with a few gallons of low-wines, or even water, sufficient to cover the bottom of the vapor-pipe : say about 15 or 20 gallons of low-wines in each. The fire is then applied under the still, and rum of 40 to 45 over proof commences to flow into the can placed ready to receive it. When the still begins to boil, the loud rumbling of the retorts gives in- timation of the fact, and warns the attendant distillermen to prepare for the spirit in the can-pit. I M J 1036. D D E c M J c E R I R G Q B B M D N T.I. H 0 DIVING-BELL This diving-bell was invented and patented by Dr. J. Rutherford Worster, of Bal- timore, Maryland. This diving bell need not be made very heavy-it can be lowered perfectly steady Digitized by Google 344 DOCKING SHIPS. in the most rapid currents-the water does not rise above an inch or two within, when immersed. It can sit perfectly steady on the most uneven bottom, as it does not depend on that to sustain it. It is lighted with artificial light, and is abundantly provided with fresh air. The invention consists of a per- pendicular stationary scaffold, erected on a scow, or between two, and a sliding frame to which the bell is attached below, which runs in grooves in the side of the scaffold, operated by rack and pinion, to apply an unlimited power to force the bell steadily downwards into the water, and raise it in the same manner. Fig. 1036 is a front elevation; Fig. 1037 is a vertical section of the bell showing its interior and Fig. 1038 is a top view, looking down upon the frame and scaffold. The same letters indicate like parts. A A are the floats; BB, transverse beams of the scaffold; and DD are uprights of the moveable frame, made secure by diagonal braces EE The uprights D D move in guide grooves formed by two or four upright posts connected by ties. On the edges of DD are racks, indicated in front by F. G are pinions on the scaffold, which are operated by cranks, and by biting into the racks elevate and lower the bell and moveable platform. RR are two diagonal braces of the scaffold. II are tubes to "carry off the smoke from the lamps HH. These lamps have oil reservoirs SS, which regulate the supply by two 1037. 1038. D I M J I IN a a H H a 0 P cocks, and the air to the lamp can be regulated by another cock below. J is the speaking tube with a mouthpiece L. M is the air-tube; and T, the air-pump. These tubes are made of metal above the bell, but connected with the flexible tubes K N inside. o is the bell-platform. VV, the water line. This apparatus is all made in sections, and can be taken to pieces and packed in a very small compass. DIVISION OF FORCES. See PHORONOMY. DOCKING SHIPS, Apparatus for. The slip, Figs. 1039 to 1042, consists of three timber-ways, one central and two lateral, laid down on piles or on the firm beach, and running into deep water. These ways carry a rail, on which work the trucks or rollers of the carriage or frame DD. This carriage or frame consists of three strong longitudinal trucks, secured together by six, seven, or more moveable cross-pieces, the carriage being hauled upon the ways by means of a wheel and pinion, capstan, or other purchase. On the keel-beam D of the carriage, blocks are laid to such a height that the keel of the vessel may clear the ends of the cross-pieces, and each block carries four rollers. On the cross-pieces, on each side, are laid sliding or chock-blocks F F, which are made to suit the rising of the ship's bottom, and are worked backwards and forwards on the cross-pieces by tackle. They are also secured on the cross- pieces by a rack and pawl. On the aftermost cross-pieces are also two shores II, which turn upon a joint, and are prevented from falling outwards, when the vessel is floating on, by means of a small chain. A vessel having floated on to the slip, the sliding-blocks are adjusted by the tackle under her keel, the tackle being taken on board the ship, and hauled tight. By this means the sliding-blocks are brought into the proper place, and the pawls fall into the racks on the cross-pieces, and wedge the vessel firmly in. The iron guides at her forefoot and at her stern are also hauled up, so that she is well secured to the carriage. Of course, the carriage being inclined, the vessel takes first the foremost blocks, but the others are gradually adjusted, and as the carriage is hauled up the slip, the vessel takes the remaining slide-blocks in succession. When duly prepared, the vessel and carriage are hauled up the slip at the rate of from 21 to 5 feet per minute. The power employed is in about the proportion of six men to every hundred tons. When hauled up, the vessel is shored from the ground, and the keel-beam being relieved from the weight can be run back so as to be used again. It should be observed, that during the hauling up the carriage is prevented from falling back by means of three or more pawls at different parts of the framing, working on the rack on the midway. The launching of a vessel from the slip takes place very easily, by putting the cross-pieces and chock- blocks under her and the keel-beam. This slip admits of more than one vessel being on the slip at the same time, as the carriage or cradle is moveable, and the vessel, when ashore, can be shored up in the usual way. Digitized by Google DOCKING SHIPS. 345 The expense of this slip, exclusive of the cost of preparing the foundation and laying down, expenses varying of course according to locality, is stated thus :- For vessels of 100 tons $2178 " " 200 " 2904 " " 800 " 3872 " " 400 " 4840 " " 500 " 5324 And for vessels of greater burden in proportion. In case of voyages of discovery, or expeditions to distant countries, a slip for hauling up the ship might be carried out in framing as cargo, and erected at any convenient place. It has been objected to this slip, that the side blocks or wedges being drawn under her bottom upon the cross timbers can have no other support than those timbers; and should only one, two, or three of them along midships have taken the weight, and yielded however little, the inclining pressure of the ship at the same time must be augmented by the leverage of all that part thereof overhanging the side blocks, which are thus converted into fulcra, and the superincumbent weight to an active force. The danger that the cross-timbers will break down, or the ship break in, and thus fall over, becomes immi- nent, and an accident of this nature did actually happen. 1041. 1042. k K X & ***** 1039. b 1040. E N E D.4 0 E N ID B m The American Marine Railway, as it is commonly called, or the Railway Dock, as it is styled in the patent, was brought forward about twenty years ago. The marine railway laid down at New York is said to have cost between 70,000 and 80,000 dollars; and to be only capable of taking one ship at a time. The charge for docking is 25 cents per ton. The plan of proceeding is thus described by Mr. J. L Sullivan, C. E:- "The process of constructing the railway dock requires, first, the regulation of the bottom, if 80 shoal as to interfere with the intended slope of the work; or it may be excavated within the shore with the proper slope, if a channel should prevent its extension. 'The foundation piles are to be driven in four lines; the two inner rows near to each other, in order to support the keel the two outer rows to come under the shores. " The distance between the piles will be determined by the size of the timbers which bear the iron rails. "The size of the timber will depend on the burden of the largest ship which it is contemplated to haul up. Four feet apart in the centre line will be generally sufficient; in the side lines eight feet. 44 The piles to be cut off under water must be cut off in the exact inclination of the plane, and level 44 Digitized by Google 346 DOCKING SHIPS. with each other transversely. The necessity of previously marking each pile separately, on every side, in accordance with the intended inclination of the ways, led to the invention of instruments re- quisite to the occasion. " An aerial inclined plane parallel to that intended to be established under water is obtained by first fixing a true level across the head of the railway, and denoting each station by a target, the staff of which is so much above the line of plane as will bring the lower end of the aerial plane above water targets, having each a staff of the same length, being next applied, and nailed to the outer, and some few to the intermediate piles, will exactly indicate the aerial inclined plane, while the point of the staff attached to the pile will indicate a point on one side thereof in the intended plane of the foundation. The level and bevel is an instrument by which to ascertain every other point on the sides of the pile which will be in the intended inclined plane. Fig. 1043. "The diving-bell may now be supposed to be brought over the pile, and as much of this as it will take in cut off, together with the target staff, still leaving the lower end. This cutting is repeated till the workmen arrive in the bell to the bottom of the staff, which remains a little below the last rough cutting. The level and bevel is then set on: this consists of a base-board, with a post arising from its centre to support a plumb-line playing in a cant piece having a centre notch, to determine whether the base is level transversely and as this base is at the same angle with its post that the intended plane is to a perpendicular line, and the base being equally thick, its under side also indicates a parallel plane, 80 that, being secured in its place, the distance is measured by compasses from the ascertained point to the base-board, and thence to every point in the circumference of the pile that is also in the intended plane, thus marking it with accuracy for cutting. This operation being the same for each pile, it results that every one must be truly in the intended inclined plane, ready to receive the frames of the railway, which are floated over, and sunk down to their places; or a plank is first secured upon the head of the piles, upon which the frames are successively slid down. The iron rails will, in point of size, depend upon the weight they are to bear. They must of course spread a sufficient base to prevent being indented into the wood by a heavy load. The two middle rails, and the rack piece for the pawls, are generally cast in one; but if the rails are to be of rolled iron, the rack will be separate. The pawls prevent the ship from accidentally running back. "The pressure of the load will, in merchant ships, be greater forward and aft than at midships, because they generally become a little hogged; provision must therefore be made for this contingency, and it will be safe to suppose cases in which the largest class of ships to be received will bear all their weight on the first 10 feet forward and the last 10 feet aft. "The weight of a ship is often erroneously stated to be as many tons as she measures tons. The fact is, that when laden she displaces a quantity of water that would precisely weigh her whole weight, cargo included; and, as she generally carries as many tons as her measurement, she cannot, when light, weigh as many tons as she measures; she weighs only as much as the water she then displaces, and that will be in accordance with the weight of her materials, oak, pine, or cedar. Wherefore, for explanation, I shall suppose the positive weight of ships to be one half of their nominal tonnage. is A ship of war will be received upon a railway carriage with the precautions to be subsequently explained, and its weight distributed equally over it and the foundation. The tendency of all ships being to acquire some curvature of keel, it will generally be injudicious to straighten them on the dock, as they will resume their lines on being again put afloat, opening thereby the upper seams or butts. To keep the ship, when taken out of the water, in precisely the same shape she has in it, the curve of the keel must be ascertained, and the keel-blocks be made to conform thereto. " To measure the curvature of the keel we have devised an instrument, consisting simply of a bar, suspended at each end by a graduated chain. This bar, being long enough to reach across the ship, is passed under and across her centre at every five or ten feet, when the graduations on the chains will show the difference of depth at every point of contact from stem to stern. For merchantmen this precaution will not generally be necessary. A ship of 500 tons measurement will exert a pressure of 250 tons, and we have supposed the whole of this may have to be borne by the two extremities of the carriage, or by 10 feet at each end. The axles, therefore, are at the extremities, but nearest to each other. But as steamboats will bear heaviest in the middle, the axles must be near in the centre also, for their support. The axles will be two feet apart in the first 10 feet. Five axles will have to bear 125 tons, or 25 tons each; the bearings and wheels 12} tons. The axles of the New York Dock are 3 inches diameter, and the square of the section is 7,071 inches. The bearings are close to the wheels in which the axles are fixed. " The strength of the rail is deduced from experiments, from which it resulted that a rail of 1 square inch would be ample; but a rail of 1 inch is too narrow to be favorable to the duration of the wheels. The central axles of the New York Dock weigh but about 1 ton, and would together suspend 9,300 tons. The friction of the axles should be relieved by the intervention of brass bearings, as usual in machinery. 44 The side axles will sometimes have a proportionate share of the ship's weight to sustain; though she will ordinarily be prevented from inclining on one side or the other by the adjusting-screw placed at the angles of the shear-shores; yet it is necessary to guard against the force of high winds, and the weight which a hogged ship may sometimes throw on the centre shores, before she is eased down at midships by the screws, if intended to be straightened. (Fig. 1045 i.) " The carriage is combined in a very strong manner, though it appears to be rather a light structure for the purpose. In its construction the implement called the dowelling-bit is of great and essential use. (See Fig. 1048.) Digitized by Google DOCKING SHIPS. 347 " The dowell is a cylinder of some hard wood, generally lignum-vitæ, which is one half inserted into one, the other half into the other timber, where a joint is to be made of their surfaces, which the dowell prevents from moving or sliding on each other. The gouge and the screw, perceived on reference to Fig. 1055, are also improvements. An auger hole, a little smaller than the screw of the bit, being first bored, the thread will cause the bit to advance as fast as the chisel and gouge can conveniently cut, and thus the whole labor is confined to turning it. " The instrument now makes it easy to dowell the frames of a ship, the knees to the timbers, the waterways to the beams, the thick stuff of the wales to each other, and generally to bind the ship by a solid connection of wood. 1043. A. 1044. 1046. 1045. c 9 1047. h 1 b 1048. a m m d d 1050. 1049. coll 1051. 1053. 1058. 3 h 1057. 1052. I a c 1054. 1056. 1055. 1059. " By means of irons and the dowell, the cross-ties are secured to the sills in such a manner as to make it impossible that the carriage should spread; and by thus tying the sides to the centre, the cross-tim- bers convert the oblique force of the shores into vertical pressure; and care is taken in every instance that a wheel shall stand directly under the base of every shore. "The shear-shores (Fig. 1045) have a form which gives them great stability in their places, and an- swers other purposes to be mentioned; they are bases in hollow coin blocks, either of wood or iron, divided across the middle of the hollow by a partition, which serves to hinge the two legs of contiguous shears. There is thus a continuity of solid material from the side of the ship to the foundation, from the moment she ceases to float till she is high and dry. "The shear-shore screws will sometimes have the important office, when ships are old and tender, of taking a good share of the weight of the ship's side, and distributing it along the carriage side, taking it off from the floor timber-heads, futtocks, and beam-ends, where ships are most liable to be weak. "The bilge levers (Fig. 1045) are levers of the second class. One end is lodged fixedly on the centre sill of the carriage, while the other end is hove up between the legs of the shear-shores by a windlass placed within them. The moving end is guided in a slot of the prop, and sustained, when up to contact with the bilge, by means of an iron pin passing through the cheeks of the prop. Digitized by Google 348 DOCKING SHIPS. The cradle thus formed by the bilge levers it is evident will fit every successive vessel equally well, and may thus be removed singly, and replaced as the work progresses; and as they require to be hauled up with considerable force, nothing can be desired more convenient than these sheara. 'The common keel-blocks are of course placed between the cross-ties, and are of such height as to allow ample room for the shipwright to work under the flat of the bottom, standing between and on the cross-timbers. But the bottoms of the keel will sometimes have to be repaired. To accomplish this end, the instrument called the lifting-plane has been devised, (Fig. 1046.) In the operation of this ma- chine, two wedges are forced on by percussion; blows from opposite sides being simultaneously given, with the combined strength of a considerable number of men, when the resistance renders it requisite. "The lifting-planes are composed of six pieces of timber, and for the navy may be made of cast-iron, or of wood faced with iron. To make them, let us suppose a block 4 feet long, and 16 inches square, halved horizontally, and each face of the cut marked lengthwise, and then shaped into two similar planes inclined in opposite directions. The two planes are then divided from each other by a bar of iron, let in edgewise till its edge is flush with the upper ends of the two planes, in order to guide the wedges. Now let the upper half be placed in its original relation to the under one, (over it,) and there will be space for two wedges, pointing in opposite directions parallel to each other, separated by the bar of iron before mentioned. The planes being eight, all at the same angle of inclination, the upper block, with whatever may be upon it, will be lifted perpendicularly by driving the wedges. These re- quire heavy blows, and for this purpose battering-rams, swung each between two files of men, are necessary. (Fig. 1046.) In practice, one of these machines placed near a keel-block is easily made to take the pressure from it by the least degree of lifting, and thus several machines may be applied, 80 as even to take away all the common blocks, and they themselves may be readily withdrawn and shifted in position, 80 as to allow the bottom of the keel to be got at for coppering, shoeing, or renewing; and when done, the com- mon blocks are to be replaced. To do this, when'a ship is hove down, her keel must be hove com- pletely out of water. 'The chain and compound windlass by which the ship is hauled out is an expensive and essential part of the machine. The power to draw up a ship of 500 tons, weighing, as before assumed, one half the same number of tons, is now to be considered. From the experiments made in different places, the weight which the chain must bear is 40,320 lbs, or 18 tons. The chain of a marine railway must be, however, exposed to accidental stress beyond this calcula- tion. It has to ply around a ratchet-wheel, and animal force is often irregular. A steam-engine would therefore be the best. "The shape of the chain, in order to give it a degree of strength proportionate to the material, is of importance, as it has to bear the stress of turning around the ratchet-wheel of the windlass. " The windlass is also 80 geered as to adapt it to the power of a few horses. When they travel in a walk the ship moves up the plane about 8 feet a minute, and she is completely up in less than two hours. Four horses are a sufficient force for a ship of 500 tons. The horses work in the second story of a small building; they are attached to bars 14 feet in length, proceeding from an upright shaft, on the lower part of which is a bevel-wheel communicating with the rest of the geer. The end of the chain is strongly fastened to the centre of the carriage, with branches passing obliquely to the sides, so that the whole must move equally, and at once. The reversal of the draught at will is an essential provision, in order to draw the carriage out to the extremity of the ways, to which its own gravity would not certainly carry it, because to be able to give the carriage such a position as to afford just water enough for the ship to ground on the upper blocks is indispensable. To be able to refloat the ship, should she happen by bad management to ground other- wise than on the centre of the carriage, may, if on a falling tide, be of great consequence; we must therefore have the readiest means of drawing the carriage down the ways. With this view, the chain, after passing the haul-up wheel, is led to another ratchet with reversed teeth, and thence down along in a trunk by the centre timber of the ways till near their extremity; there it turns around a large and strong shiver, and fastens about 20 feet from the end of the carriage, which the chain follows, when drawn up, it being supported on rollers. The reversed movement, of course, draws the carriage down till it touches the stop-block at the outer end of the railway. The chain is thus disposed of without manual labor. The connection of the second ratchet with the first is by intervening geer, 80 that they move alike. The ship in descending requires a controlling power, that she may not acquire momentum, and injure the carriage by velocity. The friction for this purpose is produced by means of an iron wheel on the upright shaft, placed just below the floor. An iron band is made to clasp this wheel by the aid of a powerful lever. This is found to be quite sufficient, and very convenient. The manner of receiving a ship is this:-she is brought between the wharfs of the dock, head on the carriage is drawn down under her, and perhaps up a little, till her forefoot grounds on the forward block, and as ships generally draw more water aft than forward, she is nearly aground aft also; the head-shores are applied, she is then moored up a few feet, until she is ascertained to touch aft also; the shores are now all applied and secured, and the bilge levers are hove up to their bearing; she is now ready to rise into the light and air. The wheels or sheaves running on the rails are made small, because it is an object to keep the carriage low, that we may not have to extend the ways further than is necessary to get the desired depth of water on the carriage. This structure, it is to be observed, is only accessible for repairs by the diving-bell. In all places exposed to the worms the timber must be coppered, unless the white gum tree is found to be unassaila- ble, as some have represented." At New York there is also a company called the New-York SCREW-DOCK Company, to whom belong Digitized by Google DOCKING SHIPS. 349 the screw-dock, and the hydro- static screw-dock, which is an im- 40 proved form of the invention, and with hydrostatic power brought to bear as the lifting force. 66 The screw-dock in general principle and form is the same as the hydraulic screw-dock. The vessel in the screw-dock is float- ed on to a timber platform, which platform is suspended from strong mainway pieces of beams on each side, laid on the quay walls, by eight suspending screws four and a half inches in diameter. The platform is capable of being sunk about ten feet below the surface of the water, to receive the ship. This platform has several shores on its surface, which were brought to bear equally on the vessel's bottom, to prevent her from cant- ing over on being raised out of the water. About thirty men were employed in working this apparatus, who, by the combined power of the lever, wheel and pinion, and screw, succeeded, in the course of half an hour, in raising the platform, laden with a vessel of 200 tons burden, to the surface of the water, where she remained high and dry, sus- pended between the wooden frames. In a dock at Baltimore, of this kind, the platform is suspended 1060. by forty screws of about five inches in diameter. The Hydrostatic Screw-Dock is a slip abutting on the shore, with a suspended keel, allowing the vessel to be raised up vertically, instead of being drawn up on an incline, as in the slip and the ma- rine railway. It consists of two outer and parallel ranges of piling, each bearing a way at the top, from which are suspended chains, to which are alung transverse bearers or swing beams, over which the vessel to be docked floats; and having arrived over this moveable platform or grating, DD the chains are raised by means of a hydrostatic press, and the ves- sel brought to the level of the permanent way. The means by which the apparatus is worked are ingenious, and constitute the chief merit of the application. The dimensions of the dock are about 165 feet long internally, and 35 feet wide. The distance from the outside of one mainway to the outside of the other is 51 feet. The mainways abut on the land, and run about 38 feet be- yond the head of the dock on to the land, resting on a solid quay of masonry, to which they are bolted down, and which supports the machinery. Digitized by Google 350 DOCKING SHIPS. We shall first describe the construction of the two parallel mainways. These ways (B B, Figs. 1060 to 1069) are placed 35 feet apart, and each consists of a row of double piles A A, with every pair placed obliquely; thus, A. The piles are of the best Georgia pine, 56 feet long and 20 inches square, with iron shoes, and with their heads mortised into the mainway pieces, and bolted together with 14-inch bolts. The divergence of the double piles from the perpendicular is about 3 feet at the lowest extremity. The piles in the longitudinal direction of the ways are placed 4 feet 8 inches apart. The depth of water at the site of the dock is 40 feet, needing no excavation; and the piles are driven into the foundation soil about 84 feet. Some of the piles are further apart than others, depending upon circumstances and contingencies, but the general distance is about 4 feet 8 inches. The total number of pairs of piles in each way is about 29, making a total of 116 piles. (Fig. 1060.) The mainways B B are, as already mentioned, scarfed or mortised on to the top of the double piles, and secured by iron 14-inch bolts, Figs. 1060, and 1061. Each mainway is 182 feet in length, and is formed of Georgia pine logs, placed five together A , and bolted together by the same bolts which secure the heads of the piles. These ways are about 4 feet 10 inches broad and 2 feet 10 inches thick. Through the mainways, passages are left for the suspending chains. At the end of the mainways are chocks Z to prevent vessels from slipping off. On each mainway, again, are mainside straps EE, Fig. 1060, being double, and each composed of three pieces of Georgia pine, the centre about a foot thick, and the others about 8 inches, making a total height of 2 feet 4 inches, and a breadth of about a foot. The mainside straps stand about 10 inches apart, and are secured together by strong bolts and square trenails of locust-wood z The straps are 124 feet in length. The side straps are secured to the cylinder C, by side straps of wrought-iron, 32 feet in length and a foot broad, bolted in, and fastened to the side rods h of the cylinder by a large gib i, Fig. 1062. On each mainside strap are two ratchet-plates and pawls, hereafter to be described. At every 6 feet 4 inches in the mainside straps, a wrought-iron cross-bar or distance piece 1 is fixed in, which is an eye or box u, to receive the head of the suspending chain k. This head consists of a screw m, secured by a nut, which regulates the height of each swinging beam 80 as to fit the keel of the vessel. From the screw m a chain k descends, passing between the mainside straps, mainways, and the spaces between the piles, and terminating in a wrought-iron linkhead and cross-bar o, sustaining the transverse bearers or swinging beams p. The chains are each about 24 feet long. Between the two mainways B, Fig. 1061, hangs the platform of swinging beams, suspended by the chains k, which run over the sheaves n. The mainways are 35 feet apart, and the swinging beams p 44 feet long, consisting each of a double beam about 7 inches apart. The beam is of a flat triangular form, made up of large logs, fastened together by six iron straps. The pairs of swinging beams are twenty in number, and each single beam is of oak, about 15 inches broad, 3 feet 3 inches deep in the centre, and 18 inches at the ends. Each pair of swinging beams is suspended by a chain k at each end. On the centre of the swinging beam is a keel-block to, 8 feet long, 2 feet broad, and 10 inches deep, to re- ceive the keel of the vessel. In it are boltheads also to receive blocks-tackle y, for managing the chock- blocks t. On every second swinging beam is a traverse frame q, raised on six short bearers. On this traverse frame is a ratchet-plate x, into which a pawl falls from the chock-blocks. On the ratchet-plate rests the chock-block t, 5 feet 3 inches high, 4 feet 10 inches broad, and 18 inches thick. These chock- blocks support the sides of the vessel, and are moved backwards and forwards on the swinging beam by blocks and tackle yz. This tackle it will be seen works both ways, and is also affixed to the pawl x. On the quay or landside is the engine-house and pump-room, in which is the machinery of a 6-horse power steam-engine for working the hydrostatic press. In it is a tubular boiler A *, much like a loco- motive boiler, 15 feet long, 3 feet broad, and 6 feet 3 inches high, with steam-pipe B* communicating with the horizontal cylinder C and valve-box B*, which lie parallel to the boiler. This piston carries a connecting rod E*, which sets in motion the mainshaft F at right angles, and in the direction of the mainways, by which four cranks G* G* are worked, each of which has a pair of pumps attached. Each pair of pumps has a separate cistern in the tank N*, which, instead of water, is filled with a fluid com- posed of equal parts of water and alcohol, to prevent freezing in the winter months. These are the pumps which produce the pressure within the hydrostatic cylinders CC. The diameter of the smaller pumps is 1 inch, and of the larger pumps 2 inches, and each set of pumps has its respective stop-valves for letting on and off to the hydrostatic cylinders C C, 80 that one or more may be worked at pleasure. From the main-shaft power is also obtained for fleeting back the ram, by means of a pinion H set in geer on the wheel J * by a clutch I*. The wheel J is on a parallel shaft k *, carrying a pinion K *, from which a bevel-wheel M takes the motion at right angles to another shaft M*, on which are the two pinions LL, Fig. 1062, which turn the bevel-wheels I of the parallel screws jj of the hydrosta- tic ram, so that the power is brought to the back of the hydrostatic cylinders. A hydrostatic cylinder C, Figs. 1060 and 1061, is attached to each mainway, secured, as already mentioned, by its side rods h through a strong gib i to the mainside rods E. The apparatus consists of two strong wrought-iron parallel side rods hh, 44 feet long and 6 inches diameter, united by a cross- head d, 4 feet 8 inches long and 2 feet broad, at the upper end. Within this framing is the cylinder C and ram D. The cylinder, including the glands, is 18 feet long, 18 inches internal diameter, and 2 feet 3 inches external diameter. On the top of each cylinder, Fig. 1061, are pipes o communicating with the pump-room. The ram or plunger is 1 foot 2 inches diameter, and made sufficiently long to admit of a direct motion forward of 15 feet. The outer end is fitted with a collar x into the crosshead d. The crosshead d, Fig. 1061, travels backwards and forwards by means of rollers e on a cast-iron way f, laid on the mainways B. At the dock end the mainside rod h is crossed by the fleeting shaft M * from the engine-room, already mentioned, and the pinions L, on which work the wheels I of screws j, secured by a box K to each of the side rods h, Fig. 1062. At the extremity the side rod h carries a roller M and handle N. We shall now proceed to describe the process of taking a vessel into the dock. The hydrostatic Digitized by Google 1061. B > * x B B 10 0 30 DOCKING SHIPS. 1064. 1062. h / Is E c M E h M Digitized by Google 5 10 20 1063. 0 h 351 a 11107 Digitized by Google a 1069. V 1068. R DOCKING SHIPS. 7 a 3 n " 1066. W v Y v & 3 a 1065. 1067. 352 DOCKING SHIPS. 353 engines are charged with water, and the rams D forced out to the full extent of their stroke. By this means the mainstraps E are drawn towards the head of the dock, and the cradle of swinging beams lifted up, 80 as to allow of the adjustment of the keel-blocks w w and chock-blocks t, and of the swinging beams, by means of the adjusting-screws m, to the suspending chains. The cylinders are then dis- charged, the rams fleeted back, the pawls loosed, and the cradle of swinging beams sunk again by its own weight, the mainstraps being checked from running over the mainways by the chocks Z*. It will be observed that the cradle may be stopped at any required depth by closing the escape-valves, and by lowering the pawls-bars 8 on the ratchet-frames r. 3 39 1070. 1071. R 10 *M The vessel to be repaired is then floated into the dock, brought over the keel-blocks, and the hydro- static engines and pumps set to work until sufficient pressure is created to raise the swing beams up to the keel. The motion is then stopped, and the traverse frames q and chock-blocks t hauled in by the tackle towards the centre of the cradle, so as to take a uniform bearing under the body of the vessel. When they have done so, the pawls x are let fall on the rack 80 as to fix them in their places, Fig. 1066. The vessel is now shored up and the engines again started, when by the hydrostatic pressure the rams are forced in a few minutes out of the cylinders, dragging the mainstraps E, which take the chains along with them, and the vesscl is raised on the cradle of swing beams, as represented in Fig. 1060, high and dry above water, so as to allow of the inspection by the shipwrights of every part of her bot- tom. The cradle is supported on the platform by the pawls and racks 8 r. 45 Digitized by Google 354 DOCKING SHIPS. When the vessel is to be released, pressure is again put upon the cylinders, and then, the escape- valves being opened, and the pawls and racks sr released, the cradle sinks as the water escapes from the cylinders; the traverse frames and side chock-blocks are removed, and the vessel allowed to float out. The mode of fleeting back the rams, Fig. 1062, is to detach the side rods h, by drawing out the gib ii, and turning round the roller M, by the handle N, which supports the end of the side rod h. The side rod having a little play on the crosshead d, allows it to be passed back with ease. The clamps and boxes KK are then attached to the side rods, and the screws j turned by means of the bevel-wheel and pinions I and L, the motion of which is taken from the mainshaft F* of the pump-room, Fig. 1070, by putting on a clutch I*. Another dock company at New York, is that called the Sectional Floating Dock Company. The docks of this company are the most powerful, being capable of lift- ing vessels of 2000 tons burden. This dock is executed at a comparatively small cost, being chiefly of timber, and being more powerful and efficient, is esteemed preferable to all the others. The entire safety of this system is another advantage, as it is scarcely possible that an accident can arise either to the vessel raised or to the workmen employed in the repairs. The dock, also, instead of being fixed, and in one position, like the marine railway and screw-docks, may be towed to any vessel within a convenient distance. Suppose that a ship is sunk, say in 5 fathoms water, it may be raised to the surface by hogsheads, or slung by any of the usual modes; and once got up to the surface, the sectional floating dock can be readily introduced be- neath it, and the whole towed together to the landing or shipwright's wharf. Although this dock has many facilities, it has, however, some of the inconveniences of dry-docks, as the vessel is hidden between the towering sides and the machine sheds on them; and the whole forms a damp structure of wood. 1072. The sectional floating-dock derives its name from its consisting of distinct sections of timber framing in the form of a floating-dock, into which ships can enter. In the sections on each side are balance-tanks, raised and lowered by means of a rack and pinion, and also tanks, which, by being filled with water, cause the dock to sink, and by na ,the water being pumped out, enable it to be raised to any required height out of the water, the ship resting on the platform within. On the top of the sections is ma- chinery for working the racks and pinions and pump- work. x B Such is the general principle of the contrivance. Now to detail the construction. According to the size of the vessel to be raised, any number of sections, more or less, may be used, as convenience suggests. Each section is 92 feet broad externally, and 64 feet internally, and 23 feet long the total length of the seven sections being 165 feet. The section is 38 feet high externally, exclusive of engine- house, and 28 feet high internally to the top of the stand- ards. The dock, it will be seen, is neither more nor less than a large floating timber vessel, and is constructed of beams strongly bolted together. Each section may be considered as consisting of three parts-two lateral scaffoldings or framings of standards within which the balance-tanks run, and a central plat- form connecting them. The object of the lateral framing is to enable the balance-tanks B to be run up and down, and to prevent the machines from coming in contact with the water. Each lateral portion consists of two external standards 36 feet high and 12 inches square, and of four internal standards 37} feet high and 12 inches square. These standards are at the bottom secured to the outside truss-girders, and on their tops carry a platform on which the engine apparatus is placed. The standards are bound together by proper tie-pieces, and are further secured to the outside truss-girders by a 12-inch beam, 44 feet long. At the bottom of each lateral framing is a flooring on which rests a balance-tank B, 191 feet long, 10 feet broad, and 8 feet deep, being of a capacity of about 1,500 cubic feet. The total capacities of the fourteen tanks would therefore be 21,000 cubic feet. Besides these are water tanks within the plat- form in which the pump-rods work. The platform is about 10 feet deep, and on the upper surface consists of two outside truas-girders Digitized by Google DOCKING SHIPS. 355 being about 70 feet long and 17 inches across, composed of two beams scarped together. Between these are a cross-beam, 7 inches square in the centre. secured to the keel-beam; and a cross-beam on each side 9 inches square, for carrying the chock-blocks, and secured to the keel-beams. These cross- beams rest on joists or tie-pieces 10 inches square. In the centre across are the two keel-beams, 241 feet long and 12 inches square, and which carry five keel-blocks. This upper platform rests on the foundation truss-girders, by means of posts and timbers scarfed in. and is further secured by four stout iron ties. The bottom truss-girder is 93 feet long, and formed in three portions, well scarped, tied, and bolted together. These bottom truss-girders extend under the lateral framings, knitting to- gether the whole structure. The sections are connected together, in case of need, by the double tie-beams, which can be readily slipped out, by withdrawing the nuts and screws by which they are secured. On the cross-beams on each side is a rack and pawl, enabling the chock-blocks to be readily moved, and secured by means of tackle. The chock-blocks are 4 feet high and 3 feet 9 inches wide. These receive the bottom of the ship; but in order to steady the sides there are side supports on each side, worked by block and pawl. so as to make the ship firm to the inner standards. The object of the balance-tanks is to keep the dock steady and in an upright position. They con- tain no water, and it is only necessary to keep them depressed to the level of the water, either in sinking or raising the dock, and their resistance keeps the whole dock, with the ship, perfectly steady. The lateral framings are furnished with two station- ary spuds 34 feet high and 7 inches square, provided, on one side, for 273 feet, Shut 1073. with a rack-plate. This spud is secured into the framing at top and bottom, I and is for the purpose of working the tank up and down by machinery. subse. quently to be explained, and part of which is seated on 1074. the top of the tank B. Each D lateral framing is also pro- C vided with a ladder, and an J 1 upper stage for the work- men. On each side of the centre section is an engine-house, which contains the machi- nery for working the thrust- Open 1075. ing and pumping apparatus, and from which shafts run along the sections on each D side. It should be observed that the machinery on all the sections is covered in. The engine-house contains a tub da. boder like a locomotive boiler, with steam-pipe and exhaust pipe, cylinder and valve-box. From the piston a crosshead carries a connecting-rod working on the crank, which drives the main-shaft, on which is the balance-wheel. From the main-shaft a pinion and bevel-wheel carry the motion to the shaft, which is the longitudinal driving-shaft, continued, as here- after explained, along the sections for a length of 140 feet. From this longitudinal driving-shaft a wheel, working by a belt on the wheel, communicates the power to the pumping geer on the shaft, crank, and pump-rod, running down the water-tanks. This geering can be thrown in and out by means of the moveable pulley, which by being raised or let fall tightens or loosens the belt. The longitudinal shaft also works the shaft, by which the thrusting-geer is moved, and which, by means of the wheels and pinions, put on or off by the clutch, works the tank and pinion either upwards or downwards as may be required. The shaft is connected at each end by means of the universal joint, and by the small circular shaft, with the longitudinal shafting on the end sections. By this means the different sec- tions may be placed at such distance from each other as the length of any ship may render necessary. It is to be observed, that a necessity constantly occurs for sinking one or more sections lower than the others. This is also provided for by the slip and universal joints. The thrusting-geer for raising and lowering the tank takes its motion, as mentioned, from the shaft, by means of the bevel-wheel, which moves the pinion, the head of the square vertical shaft. On this shaft is a moveable socket, with a square hole in it, and four friction rollers, so that the vertical shaft may easily pass through it. Beneath the friction rollers is a pinion working into the bevel-wheel. This bevel-wheel is on the horizontal shaft, secured into a framing on the top of the platform of the tank. The horizontal shaft carries a worm, working into the worm-wheel, the shaft of which car- ries a pinion at each end, working into the spud, which is kept in geer by the friction roller. The number of spuds is twenty-eight, four on each section, or two for each tank. On the end sections the machinery consists merely of the longitudinal shaft, the thrusting and pumping geer. The process of taking a ship into the sectional floating-dock is as flollows:-The dock is sunk to any required depth by opening the gates or valves with which each water-tank is furnished, and the dock recessarily sinks. The dock sill being at the required depth, the ship is then introduced between the Digitized by Google 356 DOCKING SHIPS. vertical side-framing, rests on the keel blocks, and when supported on the sides by the chock-blocks and side-supports is ready for lifting. The valves which have previously admitted the water into the water-tanks are now closed, the water is pumped out, and the air again fills the tanks, and they rise, bringing with them the vessel to the height necessary for repairs. The vessel is taken out of dock by a repetition of the process of admitting water into the tanks. The patent is for the general arrangement in the construction of the side-balance tanks. Besides these several kinds of dock apparatus in actual working at New York, many plans have been proposed in the United States, and nearly fifty patents taken out within the last twenty years, for the invention and improvement of slips, marine railways, floating, and other docks. In 1826, Captain Thomas Cald- well proposed a system of dock D 1076. D without pumping power. He pro- posed to construct a dry-dock of T T about twice the usual length; to be divided into two compartments T V c I' by gates situated near the centre of the structure; an additional pair of gates being placed at the extremi- $ s ty, opening a communication with the harbor. The vessel was to en- B B k c 0 ter the first compartment, the ex- K ternal gates being closed, and the A internal gates being opened. The bottom of the second compartment 1077. would be above the level of the D D water in the first or outer compart- ment, and consequently at this pe- riod dry. The water was then to S be permitted to flow from an ele- vated reservoir, through a pipe, A H into the dock. When by this means the surface was sufficiently a elevated, the vessel was to be D D hauled into the second compart- ment, constructed in all respects similar to a common dry-dock. The central gates being closed and secured, the water was to be dis- B charged into the adjacent harbor, Fig. 1073. In 1826, Commodore Barron, of the United States Navy, invented a floating dock in the form of a large scow. (See Fig. 1076.) It will be seen that it is a large flat- bottomed boat, furnished at one end with a pair of gates, and having on each side two air-tight trunks TT, to preserve the buoyancy of the dock when filled with water. In the sides are port-holes, like those of a man-of-war, 80 as to allow of being opened when the dock is above water, and admitting light and air, and the introduction of materials. In case of being used in salt-water, it was proposed to copper the outside of the dock as high as the float-line of the dock when it contained no water. As the dock would not be exposed to much friction, the Commodore was of opinion that very thin sheets of copper might be used. When the gates are open the dock fills with water, and sinks to a depth sufficient to allow vessels to enter therein, and of course to displace their weight of water from the dock, when the gates are closed and secured. The vessel is then shored, and secured by the shores N and S in the usual way. The water is next to be removed from the docks by common pumps, the Archimedean screw, or by a pump forcing the water out through the bottom, which latter plan was preferred. Letters D DD, Fig. 1077, represent the floating dock containing the vessel S. HA is the surface of the water in the harbor, which would coincide with the surface of the dock, supposing it to be sunk to the dotted line, which is its situation when full of water. This depth is also supposed to be 20 feet, or equal to A B. At the commencement of the operation of pumping the water from the floating dock, it resembles the common dock, in not requiring any power to exhaust it; but as the pumping proceeds the dock becomes lighter, and of course the bottom does not remain in the same relative position to the surface of the water in the harbor, but rises in proportion to its buoyancy. In the figure the dock is represented as having risen. It is now immersed to the depth of about 5 feet. It is not necessary to remove the water from the space occupied by the ballasting, shaded dark in the lower part of the figure. As the water is forced out through an aperture in the bottom, the greatest resistance to be overcome is equal only to the pressure of a column of water equal in height to the line A B, (5 feet ;) half of this, or A x = 21 feet, will be the average resistance during the whole operation. Therefore, the power required to remove the water from the floating dock by a forcing- pump, will be to the power required to remove the water from a common dry-dock on the usual plan, as, 21 : 10, or as 1 : 4; viz. as A x Fig. 1077 = to 2f feet is to A x dry-dock = 10 feet. If, however, Digitized by Google DOCKING SHIPS. 357 lifting or forcing pumps be employed to pump the water up, and discharge it over the sides, then, of course, the same power will be required for Barron's dock as for the fixed dock. Commodore Barron's dock was proposed to be moored in a slip between two wharves or breakwaters, to flank and protect it from injury, and with a raft or floating breakwater moored in front of the dock- gate, to preserve it from storms. Literal References. The Patent Slip. 1. The bilge lever. Fig. 1039. Elevation of the slip. m. The prop for supporting the bilge lever. 1040. Ground plan of the slip. Fig. 1046. Side view of the bilge levers and shear- shores. 1041. Section on sea side. 1042. Section on land side, Figs. 1047 to 1053. The lifting-planes, shown in detail. A. Ground line. B. Sidewise, laid on piles, C C. a. The ship's keel. C. Midway, with rack a and pawl b. b. The upper block of the lifting-planes. DDD. Carriage cradle, or frame of timber. c. The under block of the lifting-planes. D*. Keel beam. dd. The wedges. EE Cross-pieces of timber, with rack and pawl. e f. The block in different points of view. The cross-pieces are moveable. Fig. 1054. The battering-rams. FF. Sliding or chock-blocks, working on the rack gg. The battering-rama of the cross-pieces EE, and provided with a Fig. 1055. The improved dowelling-bit. a. The chisel, as in the old implement. rope m. G G. Oast-iron rollers, running on a rail on the ways b. The cutter, as in the old implement. BBC. c. The gouge, improved. h. Block hooking on to carriage DD. d. The screw, improved. i. Chain attached to block, and working on Fig. 1056. The New York chain. H. Capstan-wheel and pinion, or other purchase, Figs. 1056 and 1057. The under-water implements and works. firmly bedded on a large stone. aaaa Piles. IL Shores. jj. Iron guides turning upon a pivot, and made by b. Pile standing out of water. means of the tackle k to fit under the ship's C C. Piles cut off to the line of the plane. stern. d. Pile in the process of cutting off in the diving- k k. Ropes for hauling up guides or crutches. bell, Fig. 1058. 11. Iron guides and oblique braces for the forefoot 6. The level and bevel in the diving-bell. of the vessel f. The batten and target. KK. Vessel on the slip. g g. The aerial plane, parallel to the intended m m. Ropes of the sliding-blocks, which are taken plane. h. The water-line. on board the ship for the purpose of being hauled in. i. Compasses. k. The ground-line. 1. The intended plane. The Marine Railway, New York. Fig. 1059. Tucker's improved chain. Fig. 1043. Elevation of railway, with vessel on the slip. Elevation of Platform of Hydrostatic Dry Dock A A. Piles. without the Hydraulic Engines. a. Windlass loft. A A. Piles in pairs, 56 feet long and 20 inches b. Hauling-up geer. square, of best Georgia pine, shod with iron, c. Chain attached to the carriage. placed 4 feet 8 inches apart, supporting the C. Vessel supported by the shear-shores on the cradle. carriage. BB. Mainway pieces, shown in detail in Fig. 1066. dd Shear-shores. C. Cylinder of the hydrostatic engine. Fig. 1044. End view of railway. D. Ram or plunger-pole working in C, and attached AA. Piles. at the outer ends to aaa Midway and sidewise. d. Crossheads, shown in detail in Fig. 1062. 366. Cast-iron sheaves or trucks, flanged, and run- 6. Friction rollers supporting d, and travelling on f. ning on cast-iron rails. f. Cast-iron way on which the crossheads d run. c c. Timber framing or sill of the carriage. E. Mainstraps of wood constituting the moving or dd Cross-piece of timber. draught-frame from which the cradle is suspended, e e. Bilge levers. (shown in detail in Fig. 1068.) ff. Shear-shores. h. Mainside-rods from the crossheads d to the main- g g. Scaffold posts. straps E, (shown in detail, Fig. 1063.)- Fig. 1045. View of the bilge levers and shear- ii. The gib securing the mainside-rods h, and main- shores. straps E, (shown in detail, Fig. 1068.) a The ways. J. Wrought-iron straps bolted along the main- b. The rail. straps E. c c. The cast-iron sheaves or trucks. k k. The suspending chains. dd The sill of the framing. n n. Cast-iron rollers for carrying the suspending- e. The plank. chains k to the cradle pp. f. The cross-tie or piece. 00. Wrought-iron linkheads and crossbars, support- g g. The hollow coin-blocks or side-blocks. ing the transverse bearers pp. h. The shear-shore. pp. The swinging-beams or transverse bearers of i. The screw. the cradle, (shown in detail in Fig. 1069.) k. The windlass. r r. Ratchet-plates on the mainstraps E. Digitized by Google 358 DOCKING SHIPS. 88. Wrought-iron pawl-bars, (shown in detail in Fig. A A. Piles. 1067.) BB. Mainway piece. 2*. End chock of timber to prevent the vessel from EE Mainside straps. slipping riverwards. kk. The suspending chain to the transverse bear- A steamer is shown in the dock. ers pp. 1. Iron crossbar or distance-piece, in which eyes are Fig. 1061.-Plan of the Hydrostatic Dry D ock, formed to receive the adjusting-screw and nut New York. m of the suspending-chain k. BB. Mainway pieces. m. Wrought-iron adjusting nut and screw. C C. Cylinders of the hydrostatic engine. 98. Cast-iron sheave for carrying the chain. D. Ram of ditto. o. Wrought-iron linkhead and crossbar supporting d. Crossheads to which the ram D is attached. the transverse bearers or swinging-beams p e. Friction rollers supporting d and travelling on f. pp. Transverse bearers or swinging-beams of the f. Cast-iron way on which the crossheads d run. cradle. EE. Mainstraps of wood from which the cradle is rr. Ratchet plate on the mainside strap E. suspended. 88. Wrought-iron pawl-bar. h. Mainside-rods from d to E. 16. Box in the crosshead, at the back of which is the ii. Gib securing the mainside-rods h h, and the nut m. mainstraps EE Fig. 1066. Enlarged plan of mainside strap E and J J. Wrought-iron straps on E. pawl-bar 8. k. The suspending chains to the transverse bearers Fig. 1067. Enlarged section of mainside strap E, pawl-bar 8, mainway piece B, and piles A. 11. Wrought-iron crossbars or distance-pieces be- A A. Pair of piles, each 56 feet long and 20 inches tween the timbers of the mainstraps E, and in square, of best Georgia pine, with iron shoes, which eyes are formed to receive the adjusting- diverging from the perpendicular, at the lowest screws and nuts m of each suspending-chain k. extremity, about 3 feet. m m. Adjusting-screws and nuts of the suspending- a* a*. 14-inch bolts to secure piles. chains k k. B. Mainway pieces of five logs of Georgia pine, n n. Cast-iron sheaves or rollers for carrying the 182 feet in length by 2 feet 10 inches in thick- suspending-chains k k. ness and 4 feet 10 inches in breadth, with piles pp. The swinging-frames or transverse bearers of A A mortised in. the cradle carried by the suspending-chains k k. E E. Mainside straps, constructed of three pieces qq. The traverse-frames. of Georgia pine. rr. Ratchet-plates on the mainstraps E, on which r. Ratchet-plate or rack on the mainside strap. the pawl-bars 8 work. 8. Wrought-iron pawl-bar. 88. Wrought-iron pawl-bara. x*. Trenails of locust wood. 0*. Pipes communicating with the pump-room. Fig. 1068. Elevation of swinging-beams or trans to 10. Keel blocks of timber. verse bearers pp. xx. Iron rack and pawl for keeping the chock-blocks k k. Suspension-chains of iron. in their places. pp. Swinging-beam or transverse bearer of oak, y*. Balks bearing the trasverse-frames q. strapped together by the wrought-iron straps v. 2*. End chock of timber. qq. The traverse-beams of timber for supporting the chock-blocks t. Hydrostatic Dry Dock. t t. Chock-blocks of timber for supporting the sides of the vessel. Fig. 1062. Enlarged plan of hydrostatic cylinder, v v. Wrought-iron straps. with the fleeting apparatus. w 10. Keel-block of timber. C. Hydrostatic cylinder 18 feet long. x x. Iron rack and pawl for keeping the chock D. Ram secured to the crosshead d by the collar blocks in their place. x*. yy. z 2. Blocks and tackle for working the chock d. Crosshead. blocks. E. Mainstraps. Fig. 1069. Plan of the swinging-beams p. h h. Mainside-rods. i. The gib securing the mainstraps E and mainside Fig. 1072.-Hydrostatic Dry Dock. Front Eleva rods h tion of the Pump-Room. jj. Screws for fleeting back the ram D. A*. Tubular boiler. KK. Clamp and box attached to the side-rods hh IL Bevel-wheel working on the pinion L B*. Steam-pipe. LL Pinion to the wheel I. C*. Cylinder. D*. Valve-box. M*. Shaft from the engine-room turning the pin- ions L E*. Connecting-rod from cylinder C* to shaft F*. MM. Roller moved by the handle N. F* F*. Mainshaft working the geering. N. Handle supporting the end of the mainside- G* G*. Cranks from shaft k* to the pump-rods rod h. each crank working two pairs of pumps. H*. Pinion on shaft F*. x*. Collar connecting the ram D and crosshead d. Fig. 1063.-Elevation of the mainside-rod h, with I*. Clutch for putting pinion H* in geer with wheel J*. the roller M, and handle N. Fig. 1064-Cross section through the cylinder, side- J*. Wheel on shaft k*, for transferring motion to rods, and mainways. the geering for fleeting back the ram. k*. Shaft bearing the wheel J* and pinion K*. Hydrostatic Dry Dock. K*. Pinion on shaft k* working with the wheel L*. Fig. 1065. Enlarged longitudinal section of one of L*. Wheel for transferring the power at right angles the mainside straps E to the shaft M*. Digitized by Google DRAWING MACHINE. 359 M*. Shaft turning the pinions LL F*. Main shaft. N*. Tank. P*. Balance-wheel. G*. Crank for working the pump-rods. p*. Pump-rods. Hydrostatic Dry Dock. Fig. 1070. Plan of the pump-room. Barron's Floating Dock. A*. Tubular boiler. B*. Steam-pipe. Fig. 1076. Barron's floating dock. DD. Dock. C*. Cylinder. D*. Valve-box. kk. Knees at the angles bolted firmly to the hori- E*. Connecting-rod. F* F*. Main shaft. zontal or upright timber DD. G* G*. Cranks working the pump-rods p* p* ccc. Horizontal or inclined slips of ceiling, running H*. Pinion on shaft F*. fore and aft, into which the timbers DD are in- I*. Clutch for putting fleeting apparatus in geer. serted. J*. Wheel on shaft k* for transferring motion. TTT. Air-tight trunks. V. Vessel in dock. k*. Shaft bearing the wheel J* and pinion K*. SS. Waleshore supporting the ship V. K*. Pinion. L*. Wheel on shaft M*. hh. Horizontal shores. BB. Keel-blocks. M*. Shaft turning the pinions LL Fig. 1077. Barron's floating dock raised out of the LL Pinions working in geer with the wheels IL water. IL Wheels on the spindles of the screws jj. ij. Screws for fleeting back the ram D of the hy- Caldwell's proposed Dry Dock. drostatic cylinder. Figs. 1073, 1074, and 1075. The dock, with vessel N*. Tank. 0*. Chimney-flue. entering, floating, and lying. A. Reservoir. P*. Balance-wheel 10 feet diameter. B. Pipe communicating with the inner-dock C. 0*. Pipes communicating between the tank and C. Inner-dock. D. Inner-gate. E. Vessel. the hydrostatic cylinder CC; each set of pumps F. Outer-gate. G. Outer-dock. H. Ground level. provided with separate stop-cocks. I. Level of the water in the harbor. Fig. 1071. Side elevation of the pumping apparatus. J. Level of the water in the dock. DOCK. See FLOATING SECTIONAL DRAWING MACHINE-Lowell Machine-Shop. Fig. 1106 is a front elevation, with c cans A removed. Fig. 1107 is an end elevation, show- 1107. ing geered end of rolls. x Fig. 1108 is an end elevation, show- ing pulley end of rolls. o A is the tin cans into which the slivre is deposited. 3 T B is cast-iron end, or support for frame. C is the plungers or crowders that press the alivre into the tin cans A A, after it has passed through the rolls. I Des D is an upright shaft for driving- cam b¹, and giving a rotary motion to R the cans AA. B 5" E is a stand attached to r for sup- port to upright shaft D. c a E' is a pair of calender-rolls, rest- ing upon the table D₁, by means of A stands J, through which the slivre passes before entering the tin cans. G is a bushing or bearing-in floor, to guide lower end of upright shaft to I plungers. G' G' and W are weights for weighting top rolls. 1.1 D' is a table of iron, sometimes of wood, to support calender-rolls. A ZZZZ are steel rolls fluted there are three and four, and sometimes five rolls, which increase in velocity from the first to last sets, making the draft. S' are stands to support rolls ZZ, dc. B B A' is a stand to support the end of driving-roll. XX are stands to hold belt ship- ping-bar, which is wood, sliding in the stands. X', bevel-geers on cam-shaft. A b¹, cam for producing up and down motion on the crowders CC. o Digitized by Google 360 DRAWING MACHINE. 1106. X Y A GI 4 H F и ? D b/ e X K/ d fl N DI B/ A/ EA N H Y2 Digitized by Google DREDGING, AND DREDGING-MACHINES 361 V A c X 0 W X V 1108. no 3 E 1 z 1010 B K' is a mangle-wheel, which gives an alternate circular motion to the cams A, which are driven by я pulley and shaft fl, which has a pinion on the lower end geering into the mangle-wheel. The pulley fl is driven by a belt from the upright D. i is a friction-roll attached to a lever g, which raises and falls the crowders ccc. Y, Fig. 1106, represents the edge view of roll-geers. 00, wooden clearers. which are covered with cloth for clearing top rolls from waste cotton. P are driving-pulleys, tight and loose. Q, geers on back roll. S is an arm operated by a stop-motion RT, which moves arm W. that is attached to shipper-bar in stands XX. T is a light tin trumpet, over which the slivre passes in en- tering the rolls. In case the slivre breaks or runs out, this trumpet falls back, which throws out a ratch, and lets the slide, by means of a spiral spring, press against arm S, which works arm W, and stops the machine. The roll-geers are made to vary in size to suit the operator on No. of yarn which may be required. DREDGING, AND DREDGING-MACHINES. The dredging-machine, since the application of steam-power, has sufficiently proved, in many parts of the world, the most efficient expedient towards the advancement of commerce and commercial interests, not only as the means by which accumulated obstructions have been removed, but also as the means by which rivers have been enlarged to a suffi- cient extent for the transit of commodities by navigable means; but to enumerate all of even the most conspicuous of those places that have thus been benefited, would much exceed our limits, and not materially, as regards the present purpose, add to any important advantage;-however as reference may be required by individuals for further information, a few places shall be named at which dredging-ma- chines have been, and are now, advantageously employed. In the North River, New York, dredging-machines have been and continue to be extensively em- ployed, and the merits of the great improvements in that river are entirely due to their successful operations. At the time when the value of steam, as a moving-power, began to be appreciated by parties interested in navigation, many rivers could offer but small inducement to enterprising speculators, on account of their extremely contracted breadths, and the want of sufficient depth of water to admit vessels with an advantageous cargo. Dredging forms a very important part of the work of the civil engineer, and is effected in various ways; either by drags or scoops, or rakes, or machines. There are two sorts of hand-drags, one for raising mud, the other sand the first consists of an iron box pierced with holes, open in front as well as at the top to this is attached a slightly flexible handle, of a length proportionate to the depth it is to work in when this is made use of, the men in a boat make the iron box enter the sand, sustaining the handle on the shoulder, and when it is filled they raise it, and if there be any large stones they are disengaged by means of hooks a man will raise in this manner, where the depth is not more than 4 or 5 feet, a cubic yard in the course of a day, and sometimes more. The Drag for Mud is differently formed it is an iron ring, to which a canvas bag is attached, by passing a cord through holes made in the ring purposely to receive it that point of the iron rim which is intended to touch the ground and enter the mud must be sufficiently strong two men in a boat or punt are required to manœuvre it, and in the course of a day they will raise from 12 to 14 cubic yards, if the depth does not exceed 6 feet when the boat is made use of, it is first moored in such a manner that it cannot drift such a drag allows the water to flow out of it, and retains only the solid matter. The Louchette, a kind of spade, or a collection of them, is used for cutting or extracting turf under water, without the necessity of first pumping it dry : this consists of a light iron frame, which is armed all round with a cutting-blade, in length about 3 feet; the part between it and the handle is open, being formed of four horizontal rods, and two vertical ones these receive the turf after it is cut and detached, and enable the workmen, by means of a rope and windlass, to pull it up; these cutting instru- ments have a variety of forms given them to adapt them to the peculiar work they may have to perform. The Box Shovel consists of an open box fixed at the end of a long handle, usually made of iron; the cutter traverses in a groove, and is worked by another handle; by this the turf is cut and detached, and each successive piece falls into the box: as many as four turfs may be thus drawn up at one time. 46 Digitized by Google 362 DREDGING, AND DREDGING-MACHINES. Dredging-machines have been constructed in various ways, and of iron or wood, according to the nature of the service. Some machines have been arranged 80 that the system of chain and buckets should work through a channel in the middle of the vessel; others with one system on each side; and others with the buckets working over the extremity of the vessel. But, in general, the modern practice is to place the machinery towards one extremity of the vessel, to allow of the working of the ladder (which holds the buckets) freely on either side of the vessel. By this arrangement barges can be laid along both sides of the vessel, and the material raised by the machine be taken away more easily. The machinery consists of upright and horizontal shafts, on which bevel-wheels, together with the reels or barrels, are fixed for working the chain and buckets, which latter, by being pointed with steel, dig into the soil, which is raised to the upper reels, whence it falls down an inclined board or shoot into the barges. These reels or barrels are made to disconnect by means of friction-clutches, 80 that either or both sets of buckets may be stopped at pleasure, or in case of any obstacle, such as an anchor or a stone intervening, the friction-clutch allows the reels to slip, and thus prevents the machine from breaking. The ladder containing the chains and buckets can be raised or lowered to suit any required depth, and the feeding of the buckets can be regulated by means of a windlass, which is worked by the engine. 1078 The buckets, which are now made with boiler-plates, hold from five to six cwt. of material. The dredging-machine has been employed very advantageously in raising mud, sand, gravel, and even chalk, from different harbors and rivers, both at home and abroad. A good dredging-machine ought to raise from a depth of 25 feet, from 150 to 200 tons of gravel per hour when properly worked, or a ten-horse power will raise from 90 to 100 tons per hour about thirty- four feet in height, or 700 to 800 tons per day, being at the rate of 10 tons of materials per horse power per hour. Description of the 25-horse power Engine and Dredging machinery constructed by Bury, Curtis, and Kennedy, Liverpool, for deepening the Bay of Santander, in Spain-The Figs. 1080 to 1083 represent an elevation, plan, and sections of the boat and machinery. The engine A is a side-lever low-pressure condensing marine-engine of 25-horse power, having a cylin- der 28 inches diameter, and 3 feet stroke, (crank making twenty-eight revolutions per minute:) the cylinder is fitted with short D-valves of brass. The air-pump B is 18 inches diameter, lined with brass 5-16ths of an inch thick, with a brass bucket, brass discharging and foot valves; rod of wrought-iron, cased with brass. The engine is fixed on a cast-iron bed-plate C, 11, inches thick, secured to the keelsons of vessel by sixteen 14-inch bolts; the condenser D is cast solid on the bed-plate. The side-levers EE are 9 feet 34 inches long, 19 inches broad in the middle, and 11 inches thick in the plate; the main centres are keyed into the condenser on each side. There are two fly-wheels FF on the crank-shaft, each 13 feet 6 inches diameter, rim 9 inches deep by 5 inches broad on the edge. The crank-shafts are made of cast-iron, 7 inches diameter in the jour- nals, and supported at the ends by brackets fixed to the side of the boat. Digitized by Google DREDGING, AND DREDGING-MACHINES. 363 The engine is provided with a governor G, which is driven from the crank-shaft by a belt and pulleys. The framing H, columns, and crank-pedestals are cast in one piece. The boiler 1 is 11 feet long, 8 feet wide, and 6 feet high, with steam-chest 5 feet long, 4 feet 6 inches wide, and 1 foot 8 inches high. Dredging-machinery.-The spur-wheel J on the fly-wheel shaft, which connects the engine and other wheels for working the machine, is 4 feet 6 inches diameter to the pitch line, 24 inches pitch, and 8 inches broad on the edge, which wheel works into another wheel K, 9 feet 4 inches diameter, 21 inches pitch, and 8 inches broad on the edge; and on the shaft of this last-mentioned wheel there is fixed a wheel L, of 4 feet 5,1 inches diameter, 31, 1-16th inches pitch, and 10 inches broad on the edge, which works into a wheel M keyed on the bucket-shaft, 8 feet diameter, 31 1-16th inches pitch, and 10 inches broad on the edge. 1079. a SCALE.-1 inch=10 feet. n The main or bucket shaft N, on which the 8-feet wheel is keyed, is of cast-iron as far as the coupling- boxes on each side; the ends of this shaft rest on pins 3 inches diameter, fixed into the tumbler-shafts 00, which are made of wrought-iron, and turned to receive the tumblers PP. The shaft for lower tumblers QQ is also of wrought-iron, and works in chilled cast-iron bushes. The upper tumblers PP are square, with hoops of wrought-iron 4 inches by 11 inches, (steeled on the corners ;) the flange on one end is made loose for the purpose of putting the hoops on. The lower tumblers QQ are square also; the part under the bucket-link is chilled. There are four steel knives in each flange for the purpose of cutting the soil before the bucket. The hangers RRRR for carrying the bucket-frames are of cast-iron, the inner one firmly bolted to the side-framing; the outer one is fixed on the end of the transverse beam S. The bucket-frames or ladders TT are 48 feet long between the centre of the upper and centre of the Digitized by Google 364 DREDGING, AND DREDGING-MACHINES 1080. -3 SCALE-3 inches=25 feet. I Digitized by Google DREDGING, AND DREDGING-MACHINES. 365 1081. ? SCALE.-3 inches=95 feet. Digitized by Google 366 DREDGING, AND DREDGING-MACHINES. lower tumblers; they are made of the best English oak, each side in two pieces 12 inches by 6 inches, and bolted to the cast-iron brackets at each end with 11 inch bolts. The buckets U are made of boiler-plate I inch thick, and welded at the corners. Each bucket has a steeled mouthpiece riveted to the bucket. The bucket-links V are of wrought-iron, with a ring of steel 11 inch thick, welded into the eye of each link; they are 221 inches long between centre and centre. The pins in the joints are also steeled and case-hardened. The rollers W on the bucket-frame for carrying the buckets are 9 inches diameter. The coupling-boxes X on the bucket-shaft are for the purpose of disengaging the tumbling-shaft when only one row of buckets is required to work. These coupling-boxes are also fitted with a friction- strap to prevent accidents to the machinery if the buckets should meet with any obstruction. The mitre-wheel Y on the bucket-shaft, 2 feet 31 inches diameter, works into a mitre-wheel a, keyed on the end of the upright shaft Z, and on the lower end of this shaft there is another mitre-wheel b, 1082. S SCALE.-8 feet=1 inch. S R T which works into a mitre-wheel c, keyed on the chain-barrel shaft. The barrels for hoisting the end of bucket-frames are of cast-iron, with a brake-wheel fixed on the end for lowering the frame when the barrel is disconnected from the intermediate shaft by the coupling-box; the handles of the coupling-box, and also the brake-handle, are placed on deck. The lower end of bucket-frame is suspended by a f-inch chain, and two three-sheaved blocks; the lower block is connected to the bucket-frame by a bow of wrought-iron. The rope geering for hauling the boat forward receives motion from the upright shaft Z in the follow- ing manner. A mitre-wheel d, 1 foot 10 inches diameter, is fixed on the upright shaft, working into another mitre-wheel e on the intermediate shaft; and on this shaft there is a spur pinion f, 111 inches diameter, which works into a wheel g, 3 feet diameter, on the capstan-head shaft. The capstan heads h are of cast-iron, fixed on each end of shaft; on the middle of this shaft is fixed a fuzee pulley. The slack-rope barrels ii are of cast-iron, with a coupling-box and friction-wheel, the handles of which Digitized by Google DREDGING, AND DREDGING-MACHINES. 367 are placed on deck: there is a pulley j, 2 feet diameter, on this shaft which is driven by a belt from the fuzee pulley before mentioned. The construction of dredging-machines is both necessarily and optionally of various designs. Necessarily, because machines with two sets of buckets, or buckets on each side of the vessel, are not at all adapted to narrow rivers, on account of their unavoidable breadth and consequent obstruction and optionally, because the arrangement of the machinery is at the entire discretionary judgment of the constructor. Hence, two different modifications of most approved machines are annexed; the one by Messrs. Summers, Groves, and Day, of Southampton, and the other by Messrs. Girdwood and Co., of Glas- gow; and although they differ materially in design, are each equally efficient in their proper situations. a S N N 1083. SCALE.-8 feet=1 inch. S M R The best adapted boilers and engines for dredging purposes, are those upon the marine principle, as in them compactness and stability are combined; and for which reasons, they of that description are invariably applied; but in practice it is found disadvantageous to the profitable working of the machine, if the engine be not of a proportionate power to the depth of water, the buckets of a suitable number, and the bucket-frame of sufficient length to lie at a proper angle. Hence, the following arranged pro- portions are annexed as the best adapted for working at or about the various specified depths from which the material is to be raised :- Nominal Power Length of Number of Depth of Water of Engine. Bucket-Frame. Buckets. in feet. 20 591 34 18 25 68 36 20 30 781 45 25 The boat requires little or no peculiarity of form, otherwise than that of proper stability ; it must be strong and well put together, or a constant tremulous motion is created by the action of the machinery, and the proper effect of the machine in a measure destroyed. It must also be of magnitude Digitized by Google 368 DREDGING, AND DREDGING-MACHINES. sufficient for the receiving of the machinery with a proper clearance for the buckets, according to the depth of water, and different positions in which, on that account, they are 80 frequently required. That portion of the construction in which is required the greatest degree of attention, is the judicious selection and application of proper materials ; also, in the proper proportional exactitude of the parts of which the machinery is composed. Description of the Machinery in the Dredging Vessel constructed by Summers, Groves, and Day.- The objects which were chiefly kept in view in arranging the machinery of this dredging-engine, were simplicity of construction with efficiency and facility in adapting it to the work it would have to perform: and after some consideration, it appeared to the makers that a marine steam-engine, with side- beams, was the best kind of engine for this purpose, as it enabled them to convey motion to the buckets with less wheelwork, shafting, and machinery than is generally required in dredging-engines, whose works are frequently complex, and require considerable skill in their management. 1085. , 1084. P 1086. SCALE.-3 feet=1 inch. 1087. P Figs. 1090 to 1099, show an elevation, plan, and section of the vessel and machinery.-a is the boiler, constructed with internal fireplaces and flues similar to boilers commonly used for marine-engines. b, steam-pipe leading from the steam-chest on the boiler to the engine. c is a condensing-engine of 20- horse power, the cylinder being 27 inches diameter, and the length of stroke of piston 2 feet 9 inches. The engine is constructed with side-beams on the marine principle, and the motion is communicated to the fly-wheel shaft d, by a connecting-rod in the usual way. e is the fly-wheel. p is a friction-hoop, which fits lightly around a drum or sheave keyed fast on to the fly-wheel shaft. The use of this contrivance being to prevent accidents to the machinery, in case the buckets should get entangled with any thing during the process of dredging, as when the resistance increases beyond what is necessary for raising the soil, the drum or sheave slips round inside the hoop, and the buckets cease to work, whilst at the same time the steam-engine may continue its motion without injuring the machinery. g is a pinion bored to fit the fly-wheel shaft, (but not keyed fast to it,) having two strong stops or carries cast on one Digitized by Google DREDGING, AND DREDGING-MACHINES 369 side of it, which come in contact with corresponding stops on the wrought-iron ring or hoop. h is a spur-wheel, which is driven by the pinion g. 2 is a pinion keyed on the intermediate shaft, which drives the spur wheel j, keyed on the tumbler-shaft. 11 are clutch couplings for the purpose of connecting one or both sets of buckets to the steam-engine, or disengaging them when required. m m m m are cast-iron carriages, forming joints or hinges for supporting the bucket-ladders independent of the tumbler-shafts. n n n n are the tumblers over which the chain and buckets work. 9999, &c., are the buckets, made of boiler-plate, and bolted securely to the links of the chain in a peculiar way, more clearly described in Figs. 1094 to 1096, where the buckets and links are shown on an enlarged scale, and in which, on the front of the buckets, will be observed a kind of spade that is of steel, and attached to the bucket by rivets, consequently easily renewed at any time when worn away; the bucket-chain runs on cast-iron rollers p p. 1088. " 1089. 0 0 SOALE.-3 fect=1 inch. The bucket-ladders are made partly of wood, having wooden sides with cast-iron king-posts and trans verse trusses; with wooden struts and wrought-iron tie-bolts, with screws at the ends, so that they may be tightened up when required. These ladders are remarkably strong, with comparatively light materials. The spout g is of wood, lined with sheet-iron, and has a joint at r to allow of the punts or barges being equally loaded on both sides without turning them round. As when the outer end of the spout is raised by means of the purchase z, the soil will escape at r, near to the side of the barge which is close to the dredging-machine, on lowering down the outer end of the spout, the soil will be carried over to the other side of the barge, thus insuring its being equally loaded. The bevel-wheels tttttt and shafts и и и, Figs. 1091 and 1092, convey the motion from the steam-engine to the apparatus on deck for propelling the vessel to and fro, raising or lowering the bucket-ladders, &c. The ladders are raised by chains passing round the barrels v ", and working in the sheaved blocks bb, which are suspended from the timber framing. The operation of raising the ladders is effected by connecting the barrels to the shafts by the clutches w 10, which are worked to and fro by levers that pass through the deck of the vessel. When the ladders require lowering, the clutches are drawn back and the ladders run down of themselves to any depth which is desired, being regulated by a brake attached to the drums at x x, as shown in Figs. 1091 and 1093. The apparatus for propelling the vessel to and fro is fixed on the deck. yy are two curved cast-iron barrels. By taking two or three turns of a rope or chain round these barrels, one under and the other over, one of the ropes will draw the vessel ahead, whilst the other pays off the slack, and vice versa : 47 Digitized by Google 370 DREDGING, AND DREDGING-MACHINES. SCALE.-8 feet=1 inch. 1090. B A > Digitized by Google 1091. o © (o) of (·) DREDGING, AND DREDGING-MACHINES. - % Digitized by Google SCALE.-8 feet=1 inch. 371 372 DREDGING, AND DREDGING-MACHINES. or by putting both ropes or chains the same way round these barrels, they will both act in pulling the vessel in the same direction. It should be named that there is a friction-sheave placed between the propelling machinery and the steam-engine, similar to that which is fixed upon the fly-wheel shaft, to prevent the chains or ropes being broken in case of any obstructions. The bucket-ladder, Fig. 1090, is composed partly of timber framing; the main timber M (which runs the whole length) being eighteen inches deep and eight inches broad, connected by strong cast-iron crosses, (not shown in the drawing, as it was thought they would only confuse the adjacent parts.) To give it strength to bear the weight of the buckets with their contents, it is furnished with a cast-iron king-post k, having two inch tie-bolts 88 connected to its lower extremity by a single and double forked joint, through which joints and the king-post a pin passes, thus firmly uniting them at this point. The other ends of the tie-bolts pass through snugs, cast on the top and bottom carriages at ends of ladder, and are 1092. T 0 I M M SCALE.-8 feet= 1 inch n n. furnished with a screw for the purpose of setting them up, by means of a nut, should they at any time become slack. There are also two wooden trusses ww, which take the strain of the framing, midway between its centre and either end. This ladder is found sufficiently strong, and well adapted for sustaining a heavy weight; at the same time it is extremely light in appearance. The buckets are made of boiler-plate, the back being half an inch thick. The back plate rises con- siderably above the other parts of the bucket, and slopes forward at an angle of about 25° towards the front or lip of bucket, for the purpose of retaining the soil and preventing its being spilled during its progress, after receiving it from the excavation, until it deposites the same in the barges alongside. The form of this back plate prevents a grent loss of mud or other material, which would otherwise be the result, and consequently a loss of time would follow, and the quantity of soil delivered would not be adequate to the power of the steam-engine. All the other parts of bucket, (exclusive of the back plate before mentioned,) are three-eighths of an inch thick. The buckets at present dig to a depth of 24 feet, but greater depths may be obtained by merely lengthening the timber framing of ladder, and adding a greater number of buckets and links, proportionate to the extended length. As the bucket-links are given in the same drawing with the bucket, further description is deemed superfluous; it may, however, be remarked, that the links pass over the tumblers with perfect ease, and without noise, owing to there being no projections on their lower sides, as the requisite strength round the pins is carried above the centre of the link, and not on each side, as is frequently the case. Digitized by Google DREDGING, AND DREDGING-MACHINES. 373 The upper or tumbler shaft 8 8 8, Fig. 1092, is in three lengths, having two coupling-boxes 11 fitted to them, for the purpose of working either one set of buckets or two sets simultaneously; the bearings or journals of the shafts are four in number, seven inches in diameter and nine inches in length, and working in plummer-blocks, resting on four timber frames ffff. The intermediate or middle shaft ii has bearings five inches and three-quarters diameter and eight inches in length, working also in plummer-blocks, which rest on wooden framing ff; and the lower or fly-wheel shaft d, has bearings five inches and three-quarters diameter and eight inches in length, one bearing of which rests on the engine-frame, and the other on the timber framing. These timber frames are severally connected at their tops by a strong transverse beam TT, 20 inches deep and 18 inches broad, the outer ends of which support carriages (to be hereafter described) for carrying the ladders, &c. By this arrangement, and by being securely fastened at their bases, the four upright timber frames are firmly kept in their perpendicular position. The form of these frames will be clearly understood by reference to the eleva- tion, Fig. 1090. It will be seen that the outer or hanging carriages m m, Fig. 1092, are connected to the ends of the trans- verse beam in rather a novel manner ; the hanging part, or part beneath the beam, being attached to the 1095. 1096. 1094 SCALE.-4 feet=3 inches. cap or top plate by means of twelve 14-inch bolts, by which method it can be securely fastened to the before-mentioned beam, and adjusted 80 as to accommodate the tumbler-shaft, by means of pack- ings being introduced between the cap and top of timber, and which can easily be removed at any time when required. Figs. 1097 to 1099 consist of a detailed plan and section of top and bottom tumblers; they being of essential consequence to the efficient working of the machine, are therefore minutely delineated in an extended scale, thereby rendering the design more easily understood than by a lengthened description, which it would otherwise require. It may be observed, however, that they are of cast-iron, and the corners only being liable to derangement, are separate pieces, consequently easily removed when required. The engine with its machinery has raised 160 tons of soil per hour, upon an average one set of Digitized by Google 374 DREDGING, AND DREDGING-MACHINES. 1093. m SCALE.-8 feet=1 inch. B 1099. 1097. - 1098. SCALE.-4 feet=3 inches. Digitized by Google DREDGING, AND DREDGING-MACHINES 375 buckets only having been employed in the performance, with a weight of three pounds and a half per square inch upon the safety-valve of the boiler. It may be remarked, in conclusion, that the boat is supplied with a bilge-pump for discharging the bilge-water, and a deck-winch for moving the boat by hand when the engine is not working. The chain for raising the lower end of the ladder, is five-eighths of an inch in diameter, of the description called " short link." The draught of water is three feet six inches, with every thing on board, and the bottom is perfectly flat, and both ends are of the same form. Specification for a Dredging Vessel of the following dimensions. Ft. In. Ft. In. Length of deck 80 6 Depth in hold 5 4 Breadth, extreme 22 1 Tonnage 16931. The scantlings as follows:- in. In. Chine, elm, or beech 12 by 14 Floor timbers, elm or birch 91 10 Kelson timbers, elm or birch 12 - 11 Stems, oak, sided 8 inches, moulded 9 inches. 1 deck hook, oak, at each end sided 9 inches. Aprons, " 8 " " 8 " 1 breast hook, = " " Timbers, " 6 " head 6 " Stancheons, " " 5 a Stemson knee, at each end sided 7 " Winch-bits " " 6 X 71 " Deck beams, oak, sided 71, moulded 81 u Propelling gear-bits, oak 9 X 111 " Deck knees, " 5 Plank :- Bottom 34 inch elm. Deck 24 inch yellow pine. Outside 21 64 " Bulwark 11 " " Clamps 41 " " Roughtree rail 4 X 21 " oak. Plank-sheer 21 " " Iron work Butt bolts in bottom and sides 1 inch. Stemson knees and breast hooks 1 inch. 6 pair of iron knees in the wake of boiler and engine t cwt, each fastened with 1-inch iron. Deck, 5-inch spikes. Deck fastenings all of iron. The vessel to have both ends alike, with a break in the deck both fore and abaft. The platform of 2-inch yellow pine round the boiler for the stowage of coals, and 14-inch yellow pine in the engine-room and cabins. Description and specification of a Dredging-machine, constructed by Messrs. Girdwood and Co., of Glasgow, for the excavation of the River Clyde. Figs. 1100 to 1103, exhibit an elevation, plan, and section of the engine and dredging apparatus, the letters of reference corresponding in each figure or separate view of the design. The timbers of this vessel are all exactly similar in specified variety and dimensions to that by Messrs. Summers and Co., as already minutely detailed, but the external dimensions of the vessel are a little different, viz. entire length on deck 90 feet; extreme breadth 22 feet; height from ceiling to ceil- ing seven feet; and when all is on board and in complete working condition, the draught of water is about four feet. Six is the number of men employed on board. A, Figs. 1100 and 1101, represents the boiler, and B the engine; both of which are of the usual construc- tion adapted to marine purposes. The cylinder of the engine is 26 inches diameter; length of stroke 21 feet number of strokes per minute 44; and requires about 2 cwt. of good coal per hour for the generating of a sufficient supply of steam. In effect, the engine will lift, from a depth of 18 feet, about 110 tons of mud or clay per hour, or 160 tons of sand or gravel in the same time; but in very hard ground, and inter- mixed with stones, no proper data can be given. The vessel is moved forward by the power of the engine, through means of the bevel-wheels, shafting, pitch-chain, &c., as shown in each design, and which communicates motion (when required) to, and by means of the double-acting winch R, and when the buckets are working in mud or clay, the vessel is caused to advance at the rate of about four feet per minute, when in gravel or sand at 21 feet per minute, and the number of buckets delivered is 14 in that space of time. With regard to the movement of the buckets, motion is given to the wheels C and D by the crank- shaft S of the engine, and communicated by the line of shafting eec, &c., to the wheels F and G; from thence to the buckets by the barrel or tumbler T, that being made fast upon the spindle I, which is of malleable-iron, eight inches diameter, and on which the wheel G is fixed. The small wheel C is three feet three inches in diameter; the cog-wheel D is seven feet diameter; the shafts ce, &c. are of cast- iron, 61 inches diameter in the bearings; the bevel-pinion F is two feet three inches diameter, and the bevel-wheel G is six feet, and makes seven revolutions per minute; the top or upper tumbler T has four sides, and the bottom tumbler V five; as when they are thus formed, the motion of the buckets is found in practice to work more steady, and, consequently, the effects rendered more complete. The bucket-frame H, acting upon I as a centre, is also regulated to a proper depth of water by the power of the engine; the bevel-wheel K upon the crank-shaft S gives motion by means of the wheels 1 m n, to the barrel r, and round which the chain of the tackle passes, as shown distinctly in the elevation. Digitized by Google 376 DREDGING, AND DREDGING-MACHINES. Feet. 1100. 89 STATE INSURANCE Digitized by Google DREDGING, AND DREDGING-MACHINES 377 The wheels K and I are each two feet four inches diameter; the pinion m on the bottom of the shaft t is 10 inches diameter, and the wheel n four feet two inches. On the same shaft with the bevel-wheel n is fixed a spur-pinion g, of one foot seven inches diameter, which gives motion to the wheel o, of three feet three inches; the motion is communicated (when required) by means of the clutch c c, and, when the frame H is raised to a sufficient height, and placed at the requisite depth of water, farther motion of the barrel is prevented through disengaging the clutch by means of the lever W, and the barrel rendered stationary by the lever and friction-pulley yy. The clutch is two feet four inches diameter; the friction-pulley is three feet eight inches diameter, and its breadth of strap 31 inches. The length of the chain-barrel r is 41 feet, and its diameter two feet. The shaft t is 41 inches diameter, and the barrel-shaft 51 inches, each being of cast-iron. The following is the number of teeth that each of the preceding named wheels contains, also the pitch and breadth upon the face: Wheel or Pinion. Number of Teeth. Pitch. Breadth. Spur-pinion on crank-shaft C 49 21 in. 81 in. Cog-wheel on end of laying-shaft D 112 21 81 Bevel-pinion, marked F 27 31 8 Bevel-wheel " G 72 31 8 Mitre-wheels " Kand / 44 2 41 Bevel-pinion " m 15 21 4, Bevel-wheel " n 75 21 41 Spur-pinion g on shaft with и 35 21 5 Spur-wheel o on chain barrel-shaft 51 5 A o o o 0 o o o 00 III III B 1102. 1103. o C o a go D The Bucket-Frame, Buckets, Links, dcc.-The bucket-frame is of the best red pine, strongly trussed, and strapped with iron, and in form and dimensions similar to the bucket-frame already described in the preceding machine; in length it is 55 feet 4 inches, and the number of buckets thirty-four, each' bucket being 261 inches wide, 16 inches broad, 17 inches deep, and formed of the best plate-iron I inch in thickness; on the back or sole plate p, of each bucket, and immediately beyond its formation, is an attached piece or continuation of the plate, so as to form a covering to the joints of the links, and so prevent any injurious effects from the constant liability of contact with the excavated materials; also 48 Digitized by Google 378 DREDGING, AND DREDGING-MACHINES. on the front of the buckets are fixed pieces of iron shod or edged with 1101. steel, for the purpose of increasing the strength of that portion of the bucket, and the better adapting of the same for coming in contact with hard materials; likewise that of being easi- ly removed when required for repair. The links x x x, &c., that connect the buckets, are of wrought-iron, each link being 21 inches from centre to centre of joint; flanges are formed on the double links, as shown in the de- sign, 21 by fths of an inch, and to which the buckets are fixed by fths of an inch rivets; the diameter of the joints is 34 inches with & inch project- ing on each side, to increase the sur- face of bearing for the pins: all the joints and pins are cased with steel and properly hardened. The rollers rrr, &c., are for the proper conducting of the buckets along the frame H, and are of cast- iron 8 inches in diameter, with axles or bearings of wrought-iron, 11 inch diameter, and which revolve in cast- iron receptacles or bushes. The ends of the tumblers also revolve in cast- iron bushes, that metal being found TO more durable, for this purpose, than any hitherto tried. It may not be out of place here, as being through the means of the action of the buckets and bucket-frame, to remark an idea or system given by a correspondent in the " Civil Engineer Feet. and Architect's Journal," which he calls radius cutting, in distinction to that of the common practice called trench cutting, and which no doubt in various instances must be of con- siderable advantage. In the ordinary method called trench cutting, the power applied to lead the machine ahead into the cutting, has also to re- sist the reaction of the buckets. Now, in radius cutting. the chain from the bow of the vessel is not wound up while it is cutting, but is only shorten- ed at each return of the machine, and which causes a swinging motion of the 0 vessel to take place, the machine 0 0 being led laterally to the cutting by 0 the side chains; and which are com- paratively easy to work. as the reae- H tion of the buckets is mostly against the bow or radius chain. In respect to any inconvenience at- tending the use of these lateral chains, in a harbor or narrow navigation, it is no more than in the ordinary method, as corresponding chains are then re- quired to keep the machine in line, and these are necessarily used on both sides at once; whereas, in the other system. these lateral chains are only tightened on one side, namely, that on which the machine may hap- pen to be traversing; and where it is required to lower them, to allow ves- sels to pass, they only again require to be tightened up sufficiently to let the buckets fill. Digitized by Google DREDGING AND RAISING MACHINE. 379 It may be contended that, to cut or trench a bank in the proper current, will, by changing the currents and eddies, remove it by a natural process; but, as this is a point 80 difficult to hit upon, it is generally allowed that, to get large stones and rocks taken up, and to cut the surface fair, is the surest way of reducing a bank, and of leaving it in the condition least liable to "slit up." The difference of construction in the machine is trifling, 80 as to adapt it to the radius principle, being only the doing away with the flanges on the bottom tumbler, and substituting in their stead "snugs" on the tumbler between the chains or links, to prevent their getting off. But it must be borne in mind in the constructing of dredging-machines for whatever kind of cutting, that a proper means be effected for preserving the chains employed in taking the vessel ahead, when the power of the engine is applied; and the best method that I am at present aware of is that of "conical friction." The excavated material from the dredging-machines is carried away by punts, or large rectangular boxes of plate-iron. In dimensions, they are each 32 feet in length, 14 in breadth, and 3 in depth through the deck of which is an opening 27 feet 8 inches by 10 feet 4, and around this opening is a cooming 10 inches in height, as a prevention to the stuff getting over upon the deck; each punt carries on an average 20 to 22 tons, and a small steam-tug of 70-horse power takes from 18 to 20 loaded punts at one time. Literal References-Figs. 1078 and 1079.-Machine for raising mud out of Messrs. Perry & Well's Dock at Blackwall. a. Horse-bar. b. First motion bevel-wheel for transferring the vertical motion given by the horse-bar to the horizontal one required. c. Corresponding bevel-wheel on horizontal shaft. d. Horizontal shaft, on which is fixed c. A spur-wheel. fg. Are two spur-wheels, by means of which motion is given to h. Reel-shaft. i. The reels are at each end of the ladder round which the buckets pass. k. The ladder, which can be raised or lowered by the tackle to the required depth l. The buckets for raising the mud. m. A shoot for delivering the mud from the buckets into n. A barge alongside. o. A trap-door at the bottom of the bridge for discharging the mud. p. A pinion on horizontal shaft for working the windlass, by means of which, as the dredging pro- gresses, the machine is hauled ahead. DREDGING AND RAISING MACHINE, by J. Hart, of Middletown, Connecticut. Fig. 1104 is a horizontal plan of the mud dredging-machine. Fig. 1105 is a vertical section. A is a large flat vessel for receiving the boilers, fuel, engine, and principal parts of the machinery. B is a small vessel for stores, &c., strongly connected to the larger one with the vibrating ways c for the buckets, strongly hung between the two vessels in a gallows-frame. A is a crank, by which the power is to work the whole machinery, fixed on one end of the shaft b, which is strongly mounted in framing c. On the shaft b is the fly-wheel e, and between that and opposite bearing is the clutch f, sliding on the shaft b, into or out of the clutch part of the driving pinion g, which geers into the larger tooth-wheel h mounted on that end of the bucket-shaft i; on this the chain-wheels k k are fitted, each wheel made with four shifting-studs to lock into the long links of the bucket-chain. This chain is made so that each flat link has a curve to fit the wheels kk. The edge link has a strong iron brace [' put in given lengths. A connecting link is inserted, made with an open side turned up to receive a doubled-eyed collar. In this mode of making a chain in sections, and using only four spurs or teeth, a chain can be worn one inch at each end, and not ride or turn on the teeth or spurs; each end of the links is lined with steel. When worn or broken a section can be taken out to be repaired and replaced by another. The chain-wheel h k is a skeleton cast wheel to receive a shifting sectional stud or spur, with bolts to hold them in, which takes the strain off the chain, and allows them to be taken out and replaced by others when worn. The friction rollers and water chain-wheel run on sleeves. The raising and lowering of the buckets is effected by the slings and yoke in i, Fig. 1105, and chain h½, which goes over the sheeve o, mounted on the double davit P. thence under the chain-wheel g to a sheeve at the head of the gallows-frame, and having at its inner end a counter-weight. The chain-wheel g, fitted with a groove and studs to match the chain h½, is mounted on a shaft fitted in bearings, and having the tooth-wheel w on one end, where it geers into the pinion x, which is fitted to a shaft mounted on bearings, and carrying on it the raising or lowering wheel E; this is made so that it serves as a hand-wheel by the spokes 41, and as a drum by the flanged rim x¹, and through it the ways are regulated by the directing workman, who stands on the deck. Immediately over the fly-wheel e, Fig. 1104, a frame i, Fig. 1105, is laid, to receive the bearing of the shaft " on one part, forming a winch h1, Fig. 1104. Digitized by Google 380 DREDGING AND RAISING MACHINE. 1104. X X X X SCALE.-25 feet=3 inches. X A Digitized by Google DREDGING AND RAISING MACHINE. 381 OF 1105. SCALE.-25 feet=3 inches. Digitized by Google 382 DRESSING-MACHINES. At the other end, the drum sl is mounted, and over this is placed the belt, so that it hangs loosely around and below the fly-wheel e, and is kept from contact with it by the small rollers q¹ q², mounted below the drum 8¹, when not required in use in the pit. Formed by the frame which carries the drum s¹, are the two tightening drums p'p' shown in Fig. 1104, as set over the fly-wheel these are hung in the swing-frames 0¹ 0ª. The upper part of each of these frames terminates in arms u³, and at one end of the frame x1 is the vertical davit and sheeve m²; a rope 11 goes from the arm u² round the sheeve m2 and returns and fastens to the arm u³, and thence leads to the frame over the deck w¹. The winch k¹, Fig. 1104, receives one end of rope i¹, the other end of the rope being attached to the drum x¹ on the wheel E; and the tooth-wheel is fitted with a pawl h1 to retain it in its place as wanted. This part of the apparatus is to be used as follows: when the buckets are to be lowered, the attending laborer lifts the pawl h' back and turns the ways-wheel E in the direction of the arrow 1 by the spokes y'; this lowers the ways, and at the same time is winding the rope il off the windlass k': the belt r being slack does not hinder the operation of lowering. When the bucket and ways are to be raised, the attendant laborer leaves the wheel E and simply hauls on the rope l¹, which pulls the arms u" and u³ outwards, and forces the drums p¹ inwards against the belt below in contact with the rim of the fly-wheel e, whose motion round drives the rais- ing-wheel E round in the direction of k¹, raising the ways and buckets easily and rapidly. Near the machinery in the smaller vessel B, projecting over the end, is a frame forming a slide, carrying the anchor-post. This is raised by a chain running through sheeves; then by taking a turn around the end of the bucket-shaft i, the end forms a windlass barrel for that purpose. This anchor- post holds one end of the machine; the other end is moved the width of the buckets at a time by a pawl, windlass, and lines. This machine, working with a ten-horse power engine, will excavate, on an average, 600 yards a day. It delivers ten buckets of nine cubic feet a minute. The one now at work in the New York slips has worked four years, and has not lost three days in the year by being out of repair. DRESSING-MACHINES. The dressing-machines used in this country are made upon an entirely different construction from those used in England. Fig. 1109 represents a side view of the dressing-machines used at Lowell and its vicinity. A A is the centre-frame, supporting the centre-beam a, containing the dressed yarn. The wheel E, on the centre-beam, is fastened with a set-screw, so as to be easily taken off when a full beam is to be removed, and put on the empty beam which is to replace it. BBB to the right and left are the section-frames, all made of wood, containing the section-beams HHHH. The ends of the section-beams are of cast-iron, with a square groove for receiving a friction-strap, and a weight represented at The sizing-rollers are represented at The yarn as it leaves the section-beams, passes through a raddle or ravel, made of small pieces of hard wood, and represented at u u,-from that, through between the sizing-rollers,-again, through a brass wire reed at o,-through a copperplate supported by b,-through another brass wire reed at dd-and under the measuring-rollers N N,-at which place the yarn from the four beams on each section are, for the first time, brought all into one horizontal plane. From the rollers NN, the two sections of dressed yarn pass up through heddles at k, called the lease- harness; from that it is wound on to the centre-beam a, at the top. The lease-harness may be shifted to either side of the frame by means of a screw at k, and only one section of the dressed yarn goes through heddle-eyes in the lease-harness; 80 that when a full beam is to be removed, a lease-rod is introduced between the two sections of yarn above the harness; then, by drawing the harness to one side, another lease is formed, into which a rod is introduced. The different operations of the machine are effected in the following manner. F are the fast and loose belt-pulleys, driven by a belt from the room below; n n are two cones, that to the right being driven from the one to the left, by the cross-belt R. On the axis of the cone to the right hand, there is a small bevel-wheel working into another on the bottom of the upright shaft rr. On the top of the upright shaft there is a small bevel-wheel working into the wheel c; and on the axis of the wheel c, there is a small spur-geer, not seen in the engraving, working into the wheel E, on the centre-beam a. Motion being thus given to the cone on the left hand, (by the belt-pulley F which is fastened on the same shaft,) it is next communicated by the belt R to that on the right, and from it to the beam on the top, containing the dressed yarn; hence the speed of the centre-beam a, on the top of the centre- frame, may be increased or decreased, by shifting the belt R, on the cones n n. The brush-motion is next to be considered. DDD are the brush-racks, or brush-fraines; they are not fastened to the section-beam frames BBB, but are fitted so as to move up and down, short spears z 2 being fixed to the top and bottom of each side of the brush-frames, which slide into the eyes of studs, and serve to keep them in their proper position, as well as to let them move freely up and down 8 8 8 8 are small blocks of cast-iron, which are fitted to slide freely on the polished steel-rods hhhh; the dotted lines represent straps or belts passing over small pulleys on each side, and descending down to the large wooden pulleys G G, to the surface of which the belts are fastened: the blocks 8 8 8 8 are fastened to the belts by a small nut and screw on the under side, whilst the brushes rest on the blocks above. The feathers represented on the blocks at 8 8 8, fit into slits in the ends of the brushes. W W represent two beams of wood, (one at each side of the machine,) about four inches broad, and three inches thick, called sweeps; these are supported in the centre at f, and at the end towards the left hand, they are attached to the lever PP, the under point of which supports the whole brush-frame the other end of the sweeps being attached to the block i, towards the right hand: the block i is a Digitized by Google DRESSING-MACHINES. 383 projection from a shaft, extending across the machine at each section, the axis of which is seen at x, and the pulleys G G are fastened on each end of this shaft. By carefully examining the engraving of the various parts of the machine, the reciprocating motion of the brushes, together with the up and down motion of the brush-frames, will now be easily understood. The lever J is connected with a aliding-crank on the axis of the cone n, towards the left hand; consequently, the revolving of the crank moves the sweeps alternately, from section to section; and the end of the sweeps to the right hand, being attached to the block i by a strap of belt leather, the alternate motion of the sweeps moves the shaft x, and with it the pulleys G G, about one-fourth of a revolution each way this reciprocating motion of the pulleys, draws each end of the straps represented by the dotted lines, and thereby pro- duces the necessary reciprocating movements of the brushes upon the yarn; while, at the same time, the other end of the sweeps towards the left hand, H by means of the lever PP, raises the brush-frame, and with it the brushes, up and down at every alter- B nate stroke. Thus, when the brushes are at hhhh, 2 the frame is down, and they are then in a proper position for moving along the surface of the yarn, B B (which has just been coated with size, in passing through between the sizing-rollers,) and having made one full stroke, they are then at the opposite side of the frame, which is immediately raised by the lever PP, connected with the sweeps; and in raising the frame, the brushes are lifted out of the yarn, until they return to their former position at hhhh. The whole movements of the machine com- mence at the cone n towards the left hand. From it, motion is communicated by the belt R, to the opposite cone, and from it, to the centre-beam a at the top; and from it, (the cone n,) motion is also communicated by the sliding-crank, and the con- necting-lever J, to the sweeps W W, of which there are two, and the one end of each moves the brushes alternately from side to side, whilst the other end produces the up and down motion of the brush- frame. The whole machine is extremely simple, and all its different movements 80 contrived, that they can easily be adjusted so as to operate with 1109. A the most perfect accuracy. SCALE.-4 feet=1 inch. LL represent the fanners enclosed in wooden boxes, open only at the centres for admitting a cur- rent of air, and at the mouths QQ, for throwing it out: by this method of confining the air, it rushes X out with much greater force, and the mouths Q Q are made so as to direct it right up amongst the dressed yarn. The fanners here represented have four wings each, but some have only two or three that to the left hand, is driven by a belt from the room below, and from it, a cross-belt communicates motion to the one on the right. X is a hot-air pipe, with a branch extending up to the hot-air box M, placed between the two rollers NN. The cover of this box extends till within one half-inch of each side, which leaves a small opening for the escape of the e air, which issues out at each side upon the yarn, and wing entirely hot air, it has a peculiar effect in ab- sorbing any remaining moisture upon the yarn, be- fore it is wound on to the centre-beam a, on the top. Instead of the hot-air box M, some dressing-frames have a centre fanner, similar to those used about H I Manchester. The sizing-rollers yyyy, are generally made of soapstone, with an iron axis; the under roller only is covered with cloth: one of these rollers, when finished, costs about eight dollars. The two sections of these dressing-machines may be extended out as far as may be thought necessary. In order to diminish the size of the plate, the distance from the centre of the section-beams to the centre of the frame, is represented as only 91 feet; some, however, extend to 17 or 18 feet. As the greater the distance from the sizing-rollers to the centre-beam containing the dressed yarn, more time will be gained for drying; but when the section-beams are stretched out too far, the yarn is more liable to break with the drag of the centre-beam. On one end of the axis of the measuring-rollers N N, there is a screw or worm working into geers, connected with an index which points out the number of yards of dressed yarn on the centre-beam; every 33 yards is marked with paint, which allows 30 yards of cloth to each piece, the 8 yards (equal to 10 per cent.) being allowed for shrinkage in the weaving, &c. Digitized by Google 384 DRESSING MILLSTONES. The measuring-rollers, in general, are common wooden cylinders, about eight inches in diameter some are revolving steam-cylinders, which, when properly packed at the journals so as to prevent the steam from escaping, has the best effect of any thing that has yet been tried for drying the yarn speedily. The average produce of these machines is very variable. In some factories, their average produce will be about 14 pieces per day to suit a 900 reed; yarn, Nos. 14's to 18's. In other factories, on the same kind of work, these machines will dress 20, in others 80, 40, 50, and 60 pieces per day. Some of those fitted up with revolving steam-cylinders, are said to produce even 70 pieces on the same kind of work, viz., coarse 900s, yarn No. 14's. One great cause of this difference in the quantity produced from the dressing-machines, arises from the different temperatures in the apartments where they are in opera- tion, as well as from the mode of applying the heat to the dressed yarn. In some factories the dressing- machines are in the same room with the looms, where the temperature seldom exceeds 75°. Those mounted with steam-cylinders, in place of wooden measuring-rollers, generally produce the grentest quantity of work; next to these, are those with the hot-air pipes; and next to the latter, are those with three fanners, that is, one at each side, and one in the centre. Those with only two fanners, produce the least quantity of work. The size used for dressing is generally made of potato starch for all coarse work; and of flour for the finer goods, or such as are intended for printing. The mode of preparing the starch for size requires particular attention; and although different places may have different methods, the two following have been found to suit the purpose remarkably well. 1. Method of making Size from Potato Starch for coarse Goods.-2} gallons of yeast, and 2 quarts of vinegar, to be well mixed with about 9 gallons of water, which has been previously heated to 120°, or as hot as the hand will bear to work in it. To these are added 125 lbs. of potato starch. The whole is then allowed to stand in a warm place about 10 or 12 days, or until it is perfectly fermented; then 81 lbs. of common clean tallow is dissolved in 75 gallons of water, heated to 160°, to which are added 75 lbs. of the fermented starch. The whole is well stirred until all the ingredients are perfectly incorpo- rated. The size is then to be used immediately before, or after it is perfectly cooled down. To the above some add about 21 lbs. of the sulphate of copper, to prevent mould. The above makes a very superior size. It is smooth, clean, and entirely free from any offensive smell; and although about the same price as flour, it is found to answer the purpose much better for coarse goods; very little of it adheres to the yarn, yet quite enough to make it weave well. 2. Method of making Size from Flour for the finer Goods.300 lbs. of flour mixed in 45 gallons of water, and allowed to stand for four or five days at blood-heat, until it is perfectly fermented; this is called yeast. To the above are added about 140 gallons of water heated to 180°. The whole is then boiled by steam from 30 to 45 minutes. At first it boils thick, but by continued boiling it becomes thin in the middle, when it is considered done; after which it should stand over one week, and be reduced with cold water when used. The following mode of making Size from Flour is practised in Glasgow for various kinds of Goods :- One barrel of flour is soaked in water which had been previously heated a little over 120°, and allowed to stand in this state about a week, or until it ferment thoroughly. It is then mixed with about 110 gallons of water in a copper boiler, with a cast-iron casing; and by introducing steam into the boiler, as well as into the vacant space between the casing and the boiler, it is gradually heated until it boils; after which the steam may be admitted at any pressure, and the boiling process continued about an hour; during which an agitator, driven by the engine, moves round with a slow motion, until all the concretions or lumps are completely dissolved, when a wooden roller being dipped into it, if the small portion which adheres to the roller has a thick, smooth, glutinous appearance, it is then ready to be emptied out into narrow deep vessels to cool, in which it is allowed to stand for three or four days before using it. Besides the kind of dressing-frame just described, there is another made at Providence, Rhode Island, and generally used throughout that part of the country, known by the name of Pitcher and Gay's dressing-frame. The principal difference between it and the one already described, is, that the former has four pairs of sizing-rollers on each section, while the latter has only two; that is, the yarn from the two upper beams passes through between one pair of sizing-rollers, and that from the two under beams through another pair. DRESSING MILLSTONES, Machine for. We have had occasion to notice, in our descriptions of corn-grinding machinery, the frequency with which it is found necessary to renew the grinding surfaces of the stones, and the great care and accuracy to be observed in thus preparing them for their work. The operation consists in roughening the surface of the stone, when worn smooth, by cutting delicate and very regular furrows between each of the radial grooves and parallel to them, and depressing the latter to a degree corresponding with the amount of the grinding surface removed. Skilful and expe- rienced workmen are employed for this service, which they accomplish by the help of hammers, pro- vided with chisel-edges, of well-tempered cast-steel. Simple as this operation may appear, the attempts bitherto made to perform it entirely by machinery have proved abortive; and we need not be surprised at this, when we consider the various degrees of hardness and compactness presented by different parts of the same stone, as well as the differences in the nature of the grain which is to come under its action. To accommodate itself efficiently to such circumstances, a machine would almost require of itself to possess intelligence. But although it may safely be pronounced impossible to dispense with manual labor in this process, it may be accomplished with much greater dispatch and precision by the use of the simple machine, or more properly instrument, which we have represented in Figs. 1110 to 1121. This instrument serves simply to guide the hand of the workman. and to restrict the cutting edge of the hammer into a perfectly parallel and rectilinear course; the force and number of the blows being left entirely to the discretion of the workman. By a simple contrivance, it is also made available for Digitized by Google DRESSING MILLSTONES. 385 regulating with the greatest nicety the degree of fineness, or in other words, the distance between the furrows, of the grinding surface of the stones, according to the nature of the work on which they are to be employed. Fig. 1110 is a side elevation; Fig. 1111 an end view ; and Fig. 1112 a plan of the entire machine. Figs. 1113 and 1114 are views of the hammers and cutting tool detached from the machine. Figs. 1115 and 1117, a sectional view and corresponding plan of the axis E, and its screw and nut. Figs. 1116 and 1118, detached views of the saddle or guide for the hammer. Figs. 1119, 1120, and 1121, represent the various handles used for varying the distance between the cuts; the first having five, the second six, and the third four rays or points. 1110. 1112 - 0) SCALE.-1 foot=1 inch. 1119. 1120. 1121. 1113. 1115. 1117. 1111. 1116. 1118. 1114. The base of this machine, which simply rests, without being fixed, upon the dressed surface of the millstone A, consists of a narrow cast-iron plate B, also dressed on its under surface. and of sufficient weight to retain it in the position in which it is set, without at the same time impairing its portable character. On this sole-plate a carriage C is fitted to traverse longitudinally; being supported at one side by a smooth cylindrical rod D, bolted to the sole-plate, and passing through the brass-mounted sockets aa; while, at the other side, it is provided with small friction-rollers bb, resting on the sole- plate. At right angles to the direction of this motion, an axis E is fitted to slide on bearings cast upon the carriage C; the outer extremity of this axis is formed into a screw, worked by the nut F; and the opposite end, which is cranked, carries the saddle G, into which the hammer-handle H is inserted, and which guides the action of the cutting-tool. The nut F is elongated so as entirely to enclose the screw and protect it from injury it is also provided with a set of star-handles cc'c", either of which may be affixed to it according to the degree of fineness which it is required to give to the stone. The first has 49 Digitized by Google 386 DRILLING-MACHINE six rays, and gives the greatest degree of fineness, the distance between the cuts being only one-sixth of the pitch of the screw; the others, having fewer rays, give correspondingly increased roughness to the stone. A species of index d, fixed to the carriage, serves to regulate the exact amount of motion given to the nut. The cranked form given to the axis E is for the purpose of adapting the machine to the length of the cutting-tool I. The manner in which this adjustment is accomplished will be obvious from Inspection of the drawings. Action of the Machine.-This instrument being laid upon the surface of the stone, with the edge of its sole-plate exactly parallel to one of the great radial grooves, the carriage C is pushed by the hand of the workman towards the circumference of the stone, until the cutting-tool I reaches it. He then begins his strokes, varying the number and intensity of them according to the hardness of the stone, and the depth he wishes to give to the furrows; and drawing the carriage C slowly with his left hand towards the centre of the stone, until the whole grinding surface is traversed by the tool. The hammer is then set into the position for making the next adjacent furrow, by turning the handle c through another of its divisions; the carriage is again slid towards the circumference, and the operation continued as before. Thus the requisite straightness, regularity, and parallelism of the grooves is en- sured and the operation of dressing materially facilitated. A, the millstone to be re-cut. B, the base-plate of the machine. C, the carriage or support of the working parts of the machine. a a, straps of iron binding the carriage to the cylindrical rod D. bb, friction-rollers between the carriage and sole-plate. D D, a cylindrical horizontal rod, turned smooth, for guiding the carriage C into a rectilinear move- ment. E, an axis sliding transversely in bearings, and carrying the guide for the hammer. F, nut by which the position and motions of the axis E are determined. c c c, star-handles for regulating the fineness of the cut; the first having six, the second five, and the third four rays. d, an index for regulating the exact amount of travel given to the nut F. G, a cast-iron saddle fitting to the cranked end of the axis E, and serving as a guide to the hammer. H, the wooden handle of the hammer. I, the chisel or cutting-tool inserted into the head of the hammer. DRILLING-MACHINE, by Messrs. Joseph Whitworth & Co., Manchester. This machine answers all the purposes for which tools of this kind are intended, and is made self-acting in all its motions. Fig. 1122 is a vertical section in the plane of the axis of the driving-cone and work-table. Fig. 1123 is a front view of the machine, agreeing in its letters of reference with Fig. 1122. The other figures are drawings of the parts of the machine, which are necessary to a full description of its construction and motions, and have the same letters of reference. A A A A indicate the form of the cast-iron framing of the machine, upon which all the working parts are carried, as also the work-table and its motions. This framing is formed of a single casting, and is fixed by three strong bolts upon the sole-plate TT, intended to rest solidly, and without any fastening, upon the floor of the workshop. On the upper portion of the main frame a strong bracket is cast, which serves to carry the outer ends of the cone spindle b, and back-speed spindle of the machine. Upon the spindle b is the driving-cone B of three speeds, the spur-wheel C, and the bevel-pinion D. The speed-cone B is loose upon the shaft, and only communicates motion to it by means of the spur-wheel C, which is keyed upon the spindle, and to which the cone can be attached by a stud-pin and nut at c. This wheel geers with the pinion E, on the same spindle which carries the wheel M; this in turn geers with the pinion N, which is fast upon the end of the cone B, but runs loose upon the cone-spindle b. This arrangement is in every respect the same as the ordinary back-speed of a lathe, and serves the same purpose. Supposing the back-speed removed, the cone being driven by its belt causes the spindle b to revolve, in consequence of its attachment to the fast-wheel C, and at the same time gives motion directly to the bevel-pinion D on the end of the spindle. This again geers with the bevel-wheel F, on the dríll-spindle G G, which is free to slide vertically in the eye of the wheel, while at the same time it is prevented from revolving in it by a sunk feather. By this means three different degrees of quick speed may be communicated to the drill. But let the back-speed be in geer, as represented in the drawing, Fig. 1122, and let the stud-pin c be removed, and the cone thereby loosened from its attach- ment with the wheel C, the motion being communicated to it will not drive the shaft b, directly as be- fore, but the pinion N being fast upon it will give motion to the wheel M, upon the same spindle with the pinion E. This last will therefore make the same number of revolutions as M, but being less in diameter will convey a proportionally less velocity to the wheel C, with which it geers, and which it consequently drives with a speed diminished in the ratio of the geering pairs. Now the wheel C being fast on the shaft b, conveys through it to the bevel-pinion D the same diminished speed, and this again to the drill-spindle G G. This reduced speed may, of course, be varied as before, by placing the belt on one pulley or other of the speed cone. Behind the pinion E there is a recess cast in the framing, to allow it to enter when the back-speed wheels are to be thrown out of geer; and it may be remarked that this speed-geer is only required to be in action when the machine is employed in boring holes of upwards of an inch and a half in diameter. The wheel F is cast with a long hollow boss, which is turned and fitted into a brass collar in the lower branch of the carrying-bracket, as seen in Fig. 1122. This collar is kept in its place by a cover bolted over it, as shown in Fig. 1123. As already observed, the drill-spindle passes through the wheel F. which thus serves as its lower guide. The upper end of the spindle is at the same time guided in a collar similarly fitted into the Digitized by Google DRILLING-MACHINE 387 upper branch of the bracket at a, and is thus guided vertically in ascending and descending. (In the drawings it is shown at the lowest limit of its travel.) To the top of the drill-spindle is attached the back-weight H by a jointed lever and guide link, which embraces the top of the spindle and moves upon a vertical guide-rod, kept firm in its place by having its lower end held by a screw-nut, in a socket cast in the bracket, in the manner of a bolt, a ruff forged upon the lower end of the rod answering to the head of the bolt. a 1122. M by J c B N L A 1130. SCALE.-12 fect=7 inches. The drill-spindle is itself screwed towards the middle of its length; it is there embraced by two screw-wheels JJ between which it turns, and which serve the purpose of a nut to feed down the spindle in the operation of drilling, by an arrangement which will presently be described. K, is the table upon which the article to be bored rests, and to which it can be firmly held down and adjusted by T-headed bolts and glands in the usual way, when thought necessary. The table, it will be observed, is recessed and grooved to receive and retain the T-heads of the holding bolts, as fully shown in the horizontal section, Fig. 1124, and the side view, Fig. 1125. When the article is much smaller in area than the surface of the table, the fixing bolt-head can be entered at any convenient point Digitized by Google 388 DRILLING-MACHINE of the surface by the recesses k h; and slid forward until it passes below the projecting ledges of the recess, where it is retained. The common mode of running two sets of inverted dovetail-grooves at right angles to each other, lengthwise and across the table, seems, however, preferable to this mode of partially recessing the surface. The table is itself supported upon the sole of the large carriage-bracket L, which is strength- H ened by two strong ribs cast on its under side. This bracket is attached to the framing A A by two pieces YY, which are bolted upon it and planed true to the angle of the inverted bevel edges of the broad face-rib of the main frame. These edges are also planed where they meet 1123. the oblique faces of the pieces YY. By this means a joint is formed which allows of a sliding motion vertically, but does not admit of any de- viation laterally. When the slides become loose G by wearing of their surfaces, the pieces Y Y ad- mit of being tightened by means of pinching screws fitted against them through continuous snugs cast on the bracket. This arrangement is fully explained by Figs. 1124 and 1125. This bracket is raised and depressed by means of a hand-crank applied at u. Upon this spindle is fixed the spur-pinion U, (shown in combination by Figs. 1122 and 1123, and separately by Figs. 1132 and 1133.) This pinion geers with the spur-wheel V, (partially seen in Figs. 1122 and 1123,) on the same spindle with the pinion W, Fig. 1122, which geers in turn with the rack 10 set into the frame A A of the machine. so as to form an integral part of it. By turning the hand- G crank on 26, it is thus manifest that the motion will be transmitted to the bracket, which will either be raised or lowered according as the crank is turned in one direction or the other. The table K has a double movement upon the sole of the carriage-bracket; one movement is Y Y circular and the other is in the direction of the length of the table. The circular movement is K effected by means of the hand-crank P upon the L spindle y, carried in bearings formed on the box R X, which thus serves as a centre of rotation. On the spindle y is formed a worm, which, geering with the worm-wheel P on a stud projecting downwards from the table K, conveys the motion of the handle P to the table. This arrangement is well shown separately by the plan Fig. 1127, and the elevation Fig. 1126. This last corre- sponds to the view given in Fig. 1123. Opposite views of it are also given in Figs. 1122 and 1125, the last on an enlarged scale. It will be observed that the stud on which the worm-wheel P is fixed, is cast hollow, and is fitted into the table K by a key at o, shown in Fig. 1124. The lateral movement of the table is effected by a different arrangement. A recess in the 1133. 1132. form of a parallelogram is cast in the sole of the 1131. carriage-bracket L, with projecting ribs ee on its under side to serve the double purpose of giving strength to the sole-plate and of forming guides against which the cover of the travelling-box X SCALE.-12 feet=7 inches. may slide, the surfaces in contact being planed true for that purpose. The motion is communicated by means of the handle q, (Figs. 1122 and 1123,) upon the spindle which carries the bevel-wheel Q, (seen in Fig. 1123, and partially in Fig. 1122; also separately in Fig. 1131;) this spindle has its bearings attached to the bracket L, and its wheel-geers with the equal wheel R upon the end of the screwed spindle d, which has its bearings r also attached to the sole-plate of the carriage-bracket, and works in a long nut or internal screw formed in the cover of the travelling-box X, (see Fig. 1123 for the general arrangement, also Figs. 1125, 1127, and 1130.) By turning the handle q it is thus clear that the piece which serves the purpose of a nut on the screw d, will be carried along in the direction of the length of the screw; but the nut being attached to the table K, the whole will be moved simultaneously in that direction. Digitized by Google DRILLING-MACHINE. 389 By means of these two motions any point of the table K can be brought under the axis of the drill; and by means of the vertical motion it can be placed at any convenient height. The feed of the tool during the operation of boring is obtained, as before stated, by means of the two screw-wheels J J, by an arrangement of parts which forms the chief novelty of this machine. On the axes of these wheels are placed two pulleys, the circumferences of which are embraced by the friction collars SS, (shown in combination in Figs. 1122 and 1123, and separately by Figs. 1128 and 1129.) The bearings of the axis being at- tached to the framing A A of the 1128. machine, it is obvious that the ma- chine being in motion, if the pulleys @@@@ be prevented from revolving, the wheels JJ will likewise remain at 1126. rest; but the screwed part of the drill- 0 spindle revolving between them, they P 1127. S will act as a stationary nut, and cause the spindle to descend through a space equal to one thread of its screw during every revolution. Again, sup- pose the pulleys and wheels free, the screw of the spindle, instead of de- X P scending will simply cause the wheels JJ to revolve on their axes through 1129. a space equal to one tooth during every revolution of the screw. Now, between these extremes any amount of feed or downward motion of the drill-spindle may be obtained by 1125. K simply retarding the motion of the wheels, by means of the friction-col- lars SS, which embrace the small pulleys on their axes; for the fric- tion of the collars being less than to prevent entirely the motion of the L wheels, and, at the same time, greater X than to allow a tooth to pass during a revolution of the spindle, a down- P y ward motion of the spindle must thus be produced equal to the re- tardation of the pulleys produced by 1124. the friction-collars. Thus, any degree of feed can be produced at pleasure by the contrivance of the friction- collars shown separately in Figs. 1128 and 1129. These collars are formed in two halves S and S, with Y L bosses joining the segments, pair k k and pair; these bosses are reverse screwed internally, the thread of the one to the right, and that of the other A to the left; and being placed on a rod o 8 8 correspondingly screwed right and left, they are made to approach or recede according as this rod is turned to the right or left, and to embrace A more or less closely the surface of K the pulleys upon which they are Y L placed. This screwed rod is pro- longed, and has a handle placed on its under end, by which the required b k degree of friction can be adjusted at pleasure, (see Fig. 1123.) The fric- tion-collars are lined with copper, SCALE.-1 foot=1 inch. -for the purpose of increasing the friction; for it is manifestly of advantage to obtain as much friction on the pulleys as possible with the least amount of pressure. This arrangement has also the advantage of allowing the tool to be speedily withdrawn; for on slacking the friction-collars the balance-weight H will raise the spindle in ordinary cases; and when the tool has a hold in the hole which is being bored, the balance-weight can be assisted in its office by the hand-wheel placed on the axis of one of the wheels J; the wheel and screw will thus for the time be converted into a pinion and rack. DRILLING-MACHINES. See BORING-TOOLS. DRILLING-MAC-INE, Vertical. By W. A. BURKE, Lowell Machine-Shop. From the description already given of V. nitworth's drilling-machine, it is neodless to enter minutely into a detailed descrip- Digitized by Google 890 DRILLING-MACHINE tion of this very complete machine. Fig. 1134 is a front view of the machine. Fig. 1135 is a side ele- vation in the plane of the axis of the driving-cone and work-table. The frame of this machine is of iron, cast in one piece, having a broad base or sole-plate at the bottom, by which it can be properly fastened to a stone or other suitable foundation. Fig. 1185. N is the loose and fast driving-pulleys. D, on the same shaft, is a set of cone-pulleys which communicate the power by a belt to a corresponding set of cone-pulleys. T, near the top of the frame rr and hh, are geers for decreasing the motion of the drill, similar to the back geering of turn- ing-lathes. Upon the shaft which carries the cone-pulleys T is a bevel geer, which drives another bevel geer made fast on the spindle-tube B. This tube runs loose in gun-metal bearings, and carries round the steel spindle to which the drilling-tool A is attached, by means of a long splice in the spindle and a corresponding groove in the tube. 1134. 0 I h k S b o E F F n n The machine IS adapted to feed the drill down by hand, or it can be made self-acting. When feeding the drill by hand, by turning the hand-wheel a, Fig. 1134, motion is communicated through the geer d to the geer f, which is fastened to a revolving nut which moves the feeding-screw up or down as wanted. The screw is prevented from turning round by means of a coupling which connects the screw to the spindle, and slides on a parallel rod lying back of the screw. When the feeding is to be self- acting, the geer k, which is fastened to the tube B, drives the geer c, fastened on its shaft by a splice and groove. This shaft admits a motion upward sufficient to raise the geer g on its upper end from driving c. When the feeding is done by hand, this upward motion is produced by moving the handle b, which is on the end of a bell-crank lever jointed to the end of the shaft. By means of friction-collars each side of pinion-geer g, pressure to which is given by a small hand-wheel, the quantity of feed can be raised 80 as to suit the size of the hole to be drilled. The circular table FF on which the work to be Digitized by Google DRILLING-MACHINE 391 drilled is laid, is prevented from turning round by means of a stop which alides on a rib cast on the frame. n n are handles projecting from a nut, which, on being turned, elevates or depresses the table F as may be required. E, Fig. 1135, is the handle to the shipper. C 1135. h T B r h b a m E A F F m A N TO 71. SCALE.-2 fect=1 inch. A machine of gigantic dimensions has been constructed by Nasmyth for the Great Western Steam- Navigation Company. In this machine, the entablature carrying the upper end of the boring-bar is supported on two massive pillars of masonry, placed one on each side of the boring-bar. The feed motion of the cutters 18 novel and ingenious in the extreme; it consists, primarily, of an internal screwed collar fixed on the upper surface of the entablature, and surrounding the boring-bar. A train of geering, terminating in a pinion working into a rack running down the side of the boring-bar, is attached to the latter and revolves with it. The first wheel of the train is a species of crown-wheel, its teeth being set at right angles to its axis of motion; this geers with the internal threads of the screwed collar before-mentioned, 80 that by this means the train is set in motion by the revolution of the bar, and the cutter-boss, which is attached to the lower end of the rack, is raised and lowered at pleasure. Mr. Walton, of Leeds, has introduced a highly effective boring-machine, with columnar framing intended principally for boring the apertures in the tube-plates of locomotive-engines. The machine is capable of drilling a series of parallel holes on a surface of five feet square, without refixing the object under operations, the tool-holder and the table being moveable at right angles to each other. This boring- machine may be considered as a magnified drill, as the spindle is fed longitudinally, no cutter-boss being attached. The framing consists of two plain columns, coupled at the top by a suitable entabla- ture, and carrying two other transverse beams for the support of the drill-spindle and driving-goer. The self-feeding motion may be worked by hand. Digitized by Google 392 DRY-DOCK. 1136. n n C a b 17.6 <7. 6 E E m G G H p P Section on b. DRY-DOCK, U. S., BROOKLYN. History of the Commencement and Progress of the U. S. Dry-Dock at the Navy Yard, Brooklyn. New York was originally selected in 1794, as one of the points for the establishment of a naval depot. In 1826, COL. LOAMMI BALDWIN, a civil engineer of great skill and science, examined the harbor of New York, to ascertain the feasibility of constructing a dry-dock of sufficient size to receive a ship- of-the-line. Locations for a similar purpose were examined at Boston and Norfolk, which led to the commence- ment of dry-docks at both of those places in 1832, and their completion in 1836. In March, 1835, Congress authorized an examination for a site for a dry-dock at New York, and appropriated $100,000 for commencing it. In the following June, Col. Baldwin examined the vicinity of the Navy Yard, and reported very favorably upon the facility for constructing such a work, nearly on the site where the present dock has been built. In March, 1841, Congress made an appropriation of $50,000 for commencing a dry-dock at New York, and in August, EDWARD H. COURTENAY, professor of Civil Engineering at the National Academy at West Point, was appointed chief engineer of the work. Mr. Courtenay remained in charge of the work one year, during which time there was expended the sum of $35,264.75 on the coffer-dam, and erecting workshops, and providing tools, &c., for carrying on the work. The succeeding Congress failed to make a further appropriation for the dock, and all operations were suspended in August, 1842. At the close of this session Congress appropriated $100,000 for the construction of a floating dry- dock at New York, if the plan should be approved of by the Secretary of the Navy. A commission was formed of naval officers and engineers, to investigate the merits of the different plans of floating-docks, as compared with the walled stone-dock, and also to determine the best plan of a floating-dock. They reported in favor of the walled stone-dock as the best, and the balance" as the best of the floating-docks. In the naval appropriation bill of 1843, Congress directed an examination of a project for construct- ing a dry-dock in the city of New York, on the plan of using the Croton water as an elevating power, and an investigation of the best plan of a floating-dock. W. P. S. SANGER, the Engineer of the Bureau of Yards and Docks, was directed to examine and re- port on these subjects, which he did adversely to the project of using the Croton, and the "Sectional" as the best plan of a floating-dock. In February, 1844, Hon. HENRY C. MURPHY, a member of Congress from Kings Co., N. Y., took up the subject with great interest and energy, and presented the matter to Congress in a very able report. To his exertions at this time may be mainly attributed a law that was passed in June following, Digitized by Google DRY-DOCK. 393 directing a resumption of the work on the site and plan previously determined upon, appropriating the unexpended balance of a former appropriation, amounting to $129,100. In August, 1844, Gen. WM. GIBBS MONEIL, formerly an officer of the army, and then a distinguished civil engineer, was appointed chief engineer, and the works were resumed in October following. Under this gentleman's direction considerable progress was made in the construction of the coffer- dam, and the removal of the excavation, and in preparing the plans and arrangements for conducting the work. In March, 1845, Congress appropriated $150,000 for continuing the work, and it was placed under the direction of the Engineer of the Bureau, MR. SANGER, until February, 1846, when WM. J. MCALPINE was appointed engineer in chief. Congress has made the following appropriations :- March, 1835 $100,000 Do. 1841 50,000 Do. 1845 150,000 August, 1846 250,000 March, 1847 275,000 July, 1848 350,000 March, 1849 490,000 Total, $1,665,000 The progress of the work has been much retarded in consequence of the frequency with which its officers have been changed. In 1835, Col. Baldwin expended the sum of $5,000. From August, 1841, to August, 1842, Mr. Courtenay expended $35,264.75 From August, 1844, to March, 1845, Gen. McNeil expended $114,675.83. From March, 1845, to February, 1846, Mr. Sanger expended $115,951.81 and from February, 1846, to the present date, (October 1st, 1849,) Mr. McAlpine has expended $1,147,310.39-making the whole amount of expenditure $1,418,198.78; and contracts have been made amounting to about $250,000 more. A description of the LOCATION and CONSTRUCTION of the Dry-Dock.-The dry or graving dock is a walled basin sunk below the level of the sea, to allow vessels to float in and remain while undergoing repairs. The water is removed from the basin, and the vessel is supported by shores resting on the bottom and sides. In many parts of the world the rise and fall of the tide is sufficient to allow the vessels to float in at high, and become dry at low tide. When the tide is not sufficient for this purpose, it is necessary to remove the water by pumping. The tide in the harbor of New York rises four feet seven and a half inches above mean low-water. The highest tides during the heaviest gales do not exceed eight feet above this mark, and the greatest range between low and high tide does not exceed ten feet. The government dock-yard occupies the Wallabout bay, an arm of the East River, between the cities of Brooklyn and Williamsburg, on Long Island, and directly opposite the private dock-yards in the city of New York. The bay forms a fine harbor of sufficient capacity and depth of water to receive a large navy. The dry-dock which is just being finished, and which it is now proposed to describe, is situated on the convex side of the channel of the Wallabout, near the northwest corner of the Navy Yard. It has been chiefly excavated, but the lower end of the dock was built on the edge of the channel. This part of Long Island is a diluvial formation, composed of a coarse, sharp, red, and yellow sand and gravel, interspersed with boulders of trap and greenstone rock, some of which are of an enormous size, and will weigh several thousand tons. The site selected for the dock is of more recent formation. The superstratum is formed chiefly by vegetable decomposition; below this, for a depth exceeding one hundred feet below tide, is a quick- sand formed by the debris of the rocks in the vicinity, brought down and deposited with alluvial matter by the East River, which at this place is expanded to three times the width it has above and below, and the velocity of the water correspondingly reduced. This material is an almost impalpable sand, containing a large proportion of mica. When confined and undisturbed, and not mixed with water, it is very firm and unyielding, and presents a strong resistance to penetration. When saturated with water, it becomes a semi-fluid, and is moved by the slightest current of water passing over or through it. Borings were made to a depth of sixty feet below the level of the foundation, and the same material was found to extend to that depth. Small veins of coarse sand were occasionally encountered, through which flowed springs of fresh water. It was on this material that the coffer-dam was to be constructed, to exclude the tide-waters, and a foundation prepared to sustain the enormous weight of the superstructure. The work will now be described under the following general heads, viz:- Dimensions of the structure The gates. The coffer-dam. The pumping engines. The earth-work. The pump-well, culverts, and engine-house. The bottom springs. The machine and tools used ; and The foundation, apron, and pile-driving. The cost of the work. The masonry. Dimensions of the Structure.-The pit which was excavated covered an area of over two acres at the top, and over one acre at the bottom. It was sunk about forty-two feet below the surface of the ground, and thirty-seven feet below mean high-water. 50 Digitized by Google 394 DRY-DOCK. N S 59.7 16 8.4 19 18.5 : as or A(s 18.0 A as A 24 16.20 X " a * 23.20 % 15.9 10.0 18 A A " d! 21' 30 21.6 B 2 1137. e 220 220.0 is 210 3' be If 22.8. 11 * V 24.9. 21. 2.9 12.0 X 6 105 Digitized by Google DRY-DOCK. 395 The coffer-dam in front was four hundred and seventy feet long, and from sixty to one hundred feet wide. The wings were one hundred and seventy-five feet long, and from fifteen to thirty feet wide. A double row of sheet piling protection-timbers were extended entirely around that part of the pit which was not protected by the coffer-dam. The foundation is three hundred and ninety-two feet long, and one hundred and sixteen feet wide. The main chamber is two hundred and eighty-six feet long, and thirty feet wide on the bottom, and three hundred and seven feet long, and ninety-eight feet wide on the top; and by using the floating-gate instead of the folding-gates, an additional length of fifty-two feet may be obtained. The least width is at the hollow quoine, where the walls are sixty-six feet apart at mean high-water line. The least depth of the dock is over the mitre-sills, where there is twenty-six feet of water at mean high-tide. The whole height of the walls is thirty-six feet. The Coffer-Dam-Before the excavation could be extended below the surface of the water of the bay, it was necessary to exclude the tide, and to provide for the removal of the water which would collect in the pit. As the excavation was required to be carried to a great depth, (thirty-seven feet below mean high- tide,) it became necessary to provide a strong and tight barrier to resist the pressure and percolations of the tide-water. The original dam was built as follows:- Three rows of contiguous square piles were driven entirely around the lower end of the proposed excavation, leaving two intervals of ten and twelve feet between them. These piles were secured at the top, and at the level of low-water, by horizontal wales and iron tie-bolts. The dams were filled with the silt which was taken from the excavation. The piles were of yellow-pine timber, thirty-five to forty feet long, fifteen inches square, and sawed to parallel sides. A portion were tongued and grooved but on examination it was found that from the difficulty experienced in driving, the piles swerved aside, and fractured or drew out from the tongues. The wales were of oak, twelve inches square, bolted once in ten feet, with bolts two inches in diameter. On the first trial of this dam, (in February, 1846,) it was forced inwards by a pressure of less than ten feet head of water, and by the time the excavation was taken down, so as to bring a head of thirty feet of water against the dam, the water of the bay forced its way through the sand beneath the piles, and burst into, and filled the pit. This breach occurred in July, 1846, at the northeast angle of the dam. It was repaired, and in September following, a similar breach occurred at the northwest angle of the dam. The first breach occurred without warning, after the workmen had left. The first indication of the September breach, was an increased flow of water in one of the bottom springs, which was situated fifty feet from the nearest part of the coffer-dam. The water flowing from this spring had previously been fresh; it was observed to change alternately from fresh to salt, several times within a few minutes, and in less than an hour had increased to five times its former quantity, and soon after brought up volumes of the black mud which overlays the quicksand in the channel of the bay. The direction of the breach was soon developed by the sinking of the coffer-dam, some of the piles in which settled down vertically from five to six feet. After the occurrence of these breaches, it became necessary to reconstruct a dam. This was done with piles from ten to fifteen feet longer than had been before used. The new dam which was placed on the outside of the old one, was made from thirty to forty feet wide, so that the weight of the earth would break down into any passages which the water might form through the loose soil on which the dam rested. In the narrow dams it was found that the earth adhered to the timber on the sides, and that the cavities formed by the filtering of the water, became very large before any of the earth broke down to fill them. The new dam was filled with gravel, containing loam, sand, and coarse stone. The gravel was filled in water thirty feet deep, and to prevent the stone from separating from the other materials in the descent, it was discharged in large quantities from boats with drop bottoms which contained one hundred tons. A row of piles was driven on the inside of the original dam, to a depth from twelve to fifteen feet below the proposed level of the foundation. A heavy bank of coarse gravel was filled on the inside of the dam, extending up to the lines of the foundation. The material on which the dam rested, was so unstable, that although the piles penetrated it from fifteen to twenty-five feet, yet the dam continued to yield to the pressure, and was only sustained by the closest watchfulness, and the most prompt application of remedies. As long as the excavation was in progress, there was no opportunity to obtain any support from the inside, and whenever it could be done, chain cables were attached to the dam, and secured to mooring blocks on the shore. These cables, made of iron two inches in diameter, were repeatedly broken. On one occasion six of them broke during one night. The removal of the excavation adjoining the dam was not effected any faster than it could be fol- lowed up by the foundation piling, and this was done in trenches, leaving abutments of earth on each side. Timber shores were extended from the foundation to the dam, before the intermediate sections of earth were removed. In like manner the rear work of the masonry on the foundation was at first laid in sections, and braces extended from it to secure the dam. The thrust upon these braces at one time was 80 great, that it moved a mass of masonry exceeding two hundred and fifty tons weight. The earth in the dam was subject to a continued waste on the side adjoining the bay, by the action Digitized by Google 396 DRY-DOCK. G G A 31.6 a d 3.6 18 17.6 A 30.0 Y 3.6 31.0 > A S 1139. 72 72.0 30.0 n 9.8% 22. 31/8 i ^ 33% <35 &r F G B d 1138. δ G d 2 E/5 d X I 1140. 59 59.6 29.8 30. 20 I 27.0 X 22.0 24.3 26.6 % J 20.6 20 d 3 y < 30.0 A 2 G Digitized by Google DRY-DOCK. 397 of the water flowing through the joints of the piling but this waste gradually decreased, until it be- came of but little importance. The whole number of piles driven for the coffer-dam is 3,504. Earth Work.-That part of the excavation of the pit which was above the level of low-water was taken out before the coffer-dam was constructed. There was also about ten feet of the earth below the water dredged. The semi-fluid state in which the material was found after the water had been pumped out of the pit, rendered its removal very difficult and tedious. When the excavation had been extended to a depth within about six feet of the level proposed for the foundation, springs of fresh water burst up through the crust, and discharged very copiously. It was found necessary to use tight vessels in removing the earth, because when the water mixed with the sand, it became 80 fluid, that it would escape almost wherever water would flow. Boom derricks were used to some extent in the removal of the excavation from the pit. Dumping tubs were suspended from the end of the boom, which, when filled, were hoisted to the level of the ground by steam-power. The chief part of the excavation, however, was taken out in cars, which, when loaded, were hauled up the inclined planes by steam-power. These cars possess an advantage over the earth- cars commonly used for this purpose, as they were hung very low, not above thirty inches from the top of the ground to the top of the box. This saves the labor of shovelling the earth twice to load the cars. They dumped between the axles and between the rails. The walls were backed up with gravel, as fast as the masonry was laid. Puddle walls were extended from the sides of the masonry to cut off the passage of water along the walls. The Bottom Springs.-These were met with, as before stated, when the excavation had nearly reached the level proposed for the foundation, and were the cause of the greatest difficulty which was encountered in laying down the foundation. The water which flowed from them was entirely fresh, and evidently came from a source higher than the tide-water. The temperature was 58° in January, and 55° in August. The temperature of the water in the bay at the same time was 43° and 46°, and that of the atmosphere was 40° and 90° at the same dates. The flow was not affected by the rise and fall of the tides. The strata through which the springs flowed, were evidently at a great depth (not less than thirty feet) below the foundation, and the veins of water of the different springs, even those contiguous, had no connection with each other. The difficulties caused by these springs did not proceed from the mere flowing of the water; but this, as it came up, brought with it large quantities of sand, so fine and impalpable, that it would in- sinuate itself through the smallest interstices, and if allowed to flow in this manner, would soon have endangered the surrounding works. Nor could the water be checked with safety, as the pressure was sufficient to raise the foundation, however heavily it could be loaded. It became necessary, therefore, to provide for the flow of the water, and at the same time check the removal of the sand. After repeated trials, it was found that the level of the outlet of the springs could be raised to a height which would not disturb the foundation, and would yet be sufficient to check the velocity of the water so much, that it would not disturb the sand through which it flowed. The largest spring discharged (in 1848) ten gallons per minute. When the water was allowed to flow at a level, twenty-six feet below low-water, it discharged thirty-eight gallons per minute, which contained twenty-seven ounces of fine sand at a level twenty-two feet below it discharged thirty- three gallons, containing seventeen ounces of sand; at a level nineteen feet below, it discharged twenty- two gallons, containing four ounces of sand; and at a level seventeen feet below low-water, the water flowed unmixed with sand. One of the most troublesome and refractory springs was encountered at, and near the pump-well, at the northeast corner of the dock. The first evidence of its effect was the undermining and settling of the piles driven to support the pumps and engine, and rendered it necessary to change the pump-well; but the spring followed, and compelled another change of the well. The spring was driven out of the old well by filling it with piles, but it immediately burst up among the foundation piles of the dock near by. In a single day it made a cavity in which a pole was run down to the depth of fifteen or twenty feet below the foundation; one hundred and fifty cubic feet of cobble-stone were thrown into this hole, which settled ten feet through the night, and fifty cubic feet were thrown in the following day, which drove the spring to another place, where it undermined and burst up through a body of concrete two feet thick. This new cavity was repeatedly filled with concrete, leaving a tube for the water to flow through, but in a few days it burst up in a new place, where it soon undermined the concrete, and even the foundation piles, so that they settled from one to three inches. These piles were thirty-three feet long, and had been well driven by an average of seventy-six blows from a bammer weighing two thousand two hundred pounds, falling thirty-five feet at the last blow, which did not move the pile over half an inch. These alarming results rendered paramount the adoption of the most thorough and speedy measures to prevent any further injury from this source. Accordingly, as many additional piles as could then be put in the space were driven, and those put in before were then driven from eight to twelve feet lower, by means of followers. The old concrete was removed to a depth twenty inches below the top of the piles. An area of about one thousand square feet around the spring was planked a floor of brick was laid in dry cement; and on that another, also of brick, was set in mortar, made of Roman cement; the space was next filled with concrete, and the foundation completed over all in the usual manner, and with the greatest dispatch. Several vent-holes were left through the floors and foundation. After a few days' interval, when the cement had become well set, the spring was forced up about ten feet, at which level it ever after ran clear, and without discharging sand, and gave no further trouble. Digitized by Google 398 DRY-DOCK. The other bottom springs, some forty in number, have been of a like character, but the successful result obtained in the treatment of that above described, led to the adoption of the same plan with each, and with similar results. Two of the springs were accidentally closed by freezing in 1848, and forced up, in one case eight hundred, and in the other twelve hundred square feet of the foundation. The rising took place between the lower timbers and the planking, lifting also the first course of the stone floor, which was from twelve to fifteen inches thick. None of the springs were closed until the inverted arches of masonry and side walls had been laid, and the cement had become well set. The pressure on the bottom of the floor is 80 great that the water sweated through the joints, but did not disturb the stone. The arrangement proposed to be accomplished, was to bring up all of the springs through the foun- dation, and have no pressure upon it, until the masonry was laid, and the cement had become well set; but there were many minute veins of water that were unnoticed when the foundation was laid, which exerted a force upon the cement jointe, and rendered its setting very slow and tedious. These joints will require a twelvemonth or more to become impervious to the water. The whole amount of water which came into the pit for the last year was from these springs; none leaked through the dam. The quantity which flowed in was seven hundred cubic feet per hour. The water was removed from the pit by a steam-engine of twenty-five horse power, driving two plunger pumps of fifteen inches diameter, and five feet stroke, which discharged six hundred cubic feet per minute. Foundation, Apron, and Pile-Driving.-In 1835, Col. Baldwin examined the proposed site of the dock by borings, which he extended in several places to a depth exceeding eighty feet below tide. These borings brought up sand and clay, and also fresh water, but touched no rock. Col. Baldwin remarks, Upon careful examination of these circumstances, I have no doubt a dry-dock may be safely founded at Wallabout bay. Should piling for the foundation be thought necessary, which can best be determined in the process of excavating, the piles cannot be driven deep in such soil, and will have similar or better resisting materials than those hitherto used The construction of a dock in the yard, however, will be more difficult than either of those built before, (at Charleston and Norfolk.") In 1842, Mr. Courtenay commenced driving the piles for the coffer-dam, and remarks, During the progress of the work we were enabled to form a very satisfactory opinion, as to the character of the soil upon which the dock was to have been founded, and the frequent examinations then made resulted in the conviction, not only that the substratum was sufficiently firm to resist, without danger, the pressure arising from the weight of the contemplated structure, but that the nature of the soil was far better adapted than had been supposed, to resist the percolation of water through the dam." A deposite of clay mixed with a large proportion of very fine sand, which covered the northeast portion of the pit, for several feet in depth, probably led to the favorable conclusions of these gentle- men. The soil, as was developed by the excavation, is as has been previously described, and there is but a very small portion of clay in any part of it. The borings which were made during the progress of the work extended to a depth forty feet below the foundation. Specimens have been preserved of the soil taken from various parts of the dock, and at every change in depth, including that which was brought up by the borings. Sets of these specimens have been deposited in various public institutions through the country. A trial-pile was driven in June, 1846, to the depth of forty-five feet below the foundation. It was a round stick of spruce, twenty inches diameter at one end, and fourteen at the other, and forty-nine feet long. It was shod with iron, and was driven by a hammer weighing two thousand and twenty- four pounds, falling from its greatest elevation, thirty-five feet. For the first hundred blows the hammer fell but a few inches; the next two hundred and sixty blows drove the pile thirty inches in forty-six minutes; the next two hundred and sixty-five blows occu- pied an hour, and drove the pile from half an inch to one and a half inches at each blow; the next one hundred and ten blows in an hour, averaged one and a quarter inches at each blow, the hammer falling at the last blow thirty-four feet. The pile subsequently received about two hundred blows through the medium of a follower, which drove it an average of half an inch to each blow. In June, 1847, a pile was driven forty-three feet by Nasmyth's steam pile-driver and then another pile fifteen feet long, driven on top of the first, making a total depth driven into the earth of about fifty- seven feet. The first pile was driven forty-two feet, by three hundred and seventy-three blows in seven minutes, as follows: Four blows, four inches each eight blows, three and a half inches each twenty-two blows, three inches each twenty-five blows, two inches each; forty blows, one and three quarters inches each; fifty-six blows, one and a half inches each; thirty-two blows, one and a quarter inches each sixty-four blows, one and an eighth inches each; seventy-three blows, one inch each; the last forty- nine blows, half an inch each blow. The second pile was driven fifteen feet by two thousand four hundred blows in forty-three minutes, as follows: Thirty-three blows, three-eighths of an inch at each blow seventy-three blows, one-fourth of an inch each; one hundred blows, one-eighth of an inch each eight hundred blows drove it together eighty-eight inches; three hundred blows, twenty-four inches; three hundred blows, twelve inches; four hundred and fifty blows, eleven inches, and the last three hundred and forty blows together drove the pile five and a half inches. The movements of these piles indicated the continuance of the same material to the depth which they reached and the uniformly increasing resistance, as the pile penetrated the earth, gives very favorable evidence of the support which the piles afford, when they are thus driven to the point of absolute resistance. Digitized by Google DRY-DOOK. 399 The soil required very hard driving to force the pile into it, and as long as the material was undis- turbed, the subsidence of the sand around it added greatly to the firmness of the foundation. Yet the springs were liable to disturb and loosen the soil around the piles, and, as has been previously stated, destroy their value as supports. To prevent the wasting effects of the springs, it became necessary to put down the foundation in small detached pieces, and frequently to drive the piles at a level, sometimes to the extent of six feet above the proper plane. When one of these pieces was taken in hand, the earth was removed, and the concrete, timber, &c., put in without a moment's cessation; for the springs would in a few hours render the earth semi-fluid, which had before been compressed to great firmness by the insertion of the piles. It was originally supposed that piles driven at distances of three feet from centre to centre, and twenty to twenty-five feet long, would afford a sufficient foundation to the superstructure; but from the fear that changes might take place after the foundation was put down, it was determined to drive as many piles as could be forced into the earth. The chief part of the piles were driven to the point of absolute resistance, and whenever a hammer of two thousand pounds weight, falling thirty-five feet, drove the pile for the last few blows exceeding three inches per blow, another and longer pile was driven alongside. Great care was taken in registering the performance of all the piling engines used in constructing the foundation of the dock the depth driven by every blow that has been given to every pile was recorded, and from these data the following averages have been made. The average number of blows received by the piles was seventy-three the average depth driven by the first five blows is eight inches each; by the middle five blows, six inches each; and by the last five blows, one inch each blow. The whole number of bearing-piles in the foundation is 6,539, besides 1,744 sheeting-piles, which serve also as bearing-piles. The piles are chiefly round spruce timber, from twenty-five to forty-five feet long, averaging fourteen inches diameter at the head. The average length of the piles as driven, is thirty-two feet. The sheeting-piles were yellow-pine planks, five inches thick, and from twelve to twenty-five feet long. They averaged fifteen and a quarter feet long. They were tongued and grooved, and were driven entirely around the foundation, and four rows across the pit. The piles were protected at the head by a band of wrought-iron, three by one inch, made of the toughest iron that could be procured. One ring would generally drive two piles before it burst, and by welding it could be used three times. Occasionally the point was shod with iron, but this did not increase the facility of driving, as the resistance was caused by the friction on the sides of the pile. The hammers which were used were generally about twenty-two hundred pounds weight. Several were used from three thousand to four thousand five hundred pounds, with economy and effect. The larger hammer did not injure the pile as much, and it was driven in less time, and with a less number of blows, and the same power as was applied to the smaller hammer. The leaders of the machines were from thirty-five to fifty feet long. The hammers were hoisted by men working with a crank, and on a treadwheel, and with horses, but chiefly by steam-power. The expense of these several methods of driving piles are in the order in which they have been stated above. A contract was made for the use of one of Nasmyth's steam pile-drivers, and one of his best machines was imported. Unfortunately, however, the machine was constructed too light to perform the severe labor to which it was here subjected. When in order, it produced the most astonishing results-driving the piles in less than one-third the time or expense of any other known method. Its principle consisted in very rapid short blows, with a very heavy hammer. The steam cylinder was inverted over the hammer, to which it was connected directly by the piston-rod; and the hammer, which weighed two and a half tons, was hoisted by the stroke of the engine at every revolution. Both the cylinder and the hammer, were supported by the pile itself, to which it was loosely attached by a deep cap or band. The cylinder moved up and down, alongside a spar, and the steam was conveyed to it by a flexible tube leading from the boiler on the frame below. The hammer made about sixty blows per minute. The concrete masonry which was used in the foundation was made as follows: A soft mortar was made of one part of hydraulic cement, and two parts of clean sharp sand into this was thrown five parts of stone, broken, not to exceed one and a half inches in diameter. The mass was thoroughly mixed, and immediately thrown into the place where it was required for use. The foundation was put down in the following manner: The bearing-piles were sawed off at a level thirty-three and a half feet below mean high tide. The earth was removed to a depth two and a half feet lower, which space was filled with concrete masoury. The piles were capped with yellow-pine timber, twelve by fifteen inches scantling, trenailed and bolted to the piles, and laid transversely to the axis of the dock. The spaces between the timbers were filled with concrete. Yellow-pine plank three inches thick were jointed, and closely laid on and spiked to the timbers. On the top of the plank another set of timbers of the same size were laid, breaking joints with those below. The spaces were filled with concrete, and covered with plank in the same manner as the first floor. At the foot of the dock an apron is extended for thirty feet in front, to protect the lower end of the foundation from undermining. It is composed of timber and plank, and supported on piles, with concrete masonry between and below the timbers, in the same manner as the foundation of the dock. It is prevented from floating by trenailing and bolting to the piles, and by inserting dovetailed stone between the ranges of timbers. Digitized by Google 400 DRY-DOCK. The tide tables which had been kept for several years at this station, showed that the level of the foundation should be placed six inches lower than had at first been supposed to be necessary. It was accordingly assumed at a level which would give twenty-five feet of water on the mitre-sills at high tide, for two-thirds of the days in the year. The Masonry.-It is believed that no modern structure in the world surpasses this, in the size of the stone, in the accuracy of their workmanship, and their durability. The quantity of masonry which has been laid to form the walls of the dock is 23,375 cubic yards, and in the draining and discharging culverts, and the engine-house, and other masonry connected with the dock, there is 5,250 cubic yards. All of the facing-stone has come from the Sullivan and Frankfort quarries in Maine, and New Lon- don in Connecticut. The interior stone was chiefly obtained from the Staten Island and the Highland quarries in New York. A system of inverted arches occupies the whole extent of the lower part of the structure, and serves not only to distribute the weight of the walls over the whole surface of the foundation, but to resist the immense hydraulic pressure from beneath. The floor of the main chamber is first formed of a tapering course of cut-stone, twenty-seven inches thick at the head, and twelve inches thick at near the mitre-sill; the second course of stone is uniformly three feet thick, and the arches are extended to a height nine feet above the floor on each side. The floor of other parts of the dock is made in a similar manner. The mitre-sills are immense blocks of granite; the key-stone is estimated to have weighed about fifty tons before it was cut; its weight is now 43,300 pounds; sixteen similar stones form the mitre- sills, and the smallest stone weighs 13,300 pounds. The floor of the chamber is level on the bottom for thirty feet wide, and the sides are carried up in steps or altars for the convenience of shoreing the vessel and working under her bottom, as represented in Fig. 1136, where the Ohio, ship-of-the-line, is shown in dock," sustained by the keel-blocks and shores. The side walls are laid up with English bond, alternate courses of stretchers and headers the stones in the alternate courses are of the same length which gives what is termed 'plumb-bond," although the stones in the same course differ in length, a variety of lengths having been previously determined upon to facilitate the quarrying of the stone. These lengths have, however, been 80 arranged as that adjoining stone do not differ to exceed three inches, and increase and diminish gradually from the shortest to the longest stone. The difference in length is therefore imperceptible. The courses are chiefly twenty-four inches thick, a few near the bottom being twenty-seven inches thick. The beds of the stone in the stretcher courses are from three to three and a half feet broad. and in the header courses are from four to five feet broad. The length of the headers is from three to four feet, and of the stretchers from six to eight feet. The headers are in all cases one-half of the length of the stretchers. The smallest stone in the face exceeds three thousand pounds, and the average is about six thousand pounds. Many of the coping and other large stones exceed fifteen thousand pounds. The interior stones are also large, and will average upwards of fifteen hundred pounds. The facing stones are all laid to a joint not exceeding three-sixteenths of an inch, and the joints are kept up full to the lines for the full depth of the stone. The facing stones have been backed up with a course of scabbled stone cut to the same thickness, and laid to joints not exceeding half an inch. The interior and rear of the wall has been laid up with coursed rubble, which has been so selected that either one or two courses made up the thickness of the facing course. The following extract is taken from the contract for the granite facing: " All of the stone must be of the most durable description of granite, entirely free from sap, stains, or seams, and obtained from quarries which may be approved of, by the Engineer in charge of the work; all of the stone which show in the chamber must be of the same color and general appearance. " Patterns for quarrying and cutting the stone will be furnished by the government; on all the arch-stones full corners and edges will be required on the back lines of the stone; all of the stone will be delivered cut, except such stone as may be directed to be delivered unwrought, in which case they shall be quarried out without any unnecessary excess of stone, but of sufficient size to fill the patterns. The cut-stone designed for the facing of the work must be delivered with perfect edges on the show-lines, and none will be received which are in any way marred or nicked. The stone must be delivered in the order in which they are required for use, as far as practicable. " In the courses of the chamber above the inverted arch, and in the other walls where an additional width of bed is permitted, the minimum size will be given in the bills, but stone of greater width will be received. Suitable 'lewis' holes shall be drilled in the bed, or such other surface as may be directed, to receive a lewis of sufficient size to suspend the stone with safety. Such cranes, machinery, and assistance as may be required for discharging the stone from the vessels at the Navy Yard, will be furnished by the government. " The cutting which is required to be done on the face of the stone which shows, and also on the builds of the outer stone, shall be as hereinafter described as first-class work; that required on the beds, builds, and joints, shall be as hereinafter described as second-class work; that required on the rear of the front and interior stone, shall be as hereinafter described as third-class work. The beds and joints must be dressed up full to the square, and no slack joints will in any case be permitted. The cutting will be required to be done in the following manner, to wit: " First-class work.-The arris must be kept clean and sharp, with fine-cut drafts run around the sur- faces to be dressed. Within these lines the surfaces must be taken down fair and even with a patent hammer of eight plates. No holes or depressions of any kind that will show in the face will be per- Digitized by Google DRY-DOCK. 401 mitted; and the dressing with the hammer must be level and square, 80 as to present a smooth fair appearance. 44 Second-class work.-A good arris must be kept; clean draft-lines must be run around the surfaces to be dressed. Within these lines the stone must be dressed down to a fair even level surface, with a common pean hammer. No depressions of any kind will be allowed within six inches of the face; none which exceed six inches in diameter, or one inch in depth, or where they shall together exceed one- fourth of the surface in which they occur. " Third-class work-Draft-lines shall be run around the surfaces to be dressed. Within these lines, they shall be pointed down to a fair even surface and finished with a pean hammer, 80 as to make good close work, of not exceeding half an inch joint. No cavities or depressions will be allowed which exceed eight inches in diameter, or one and one-half inches in depth, or when they shall together exceed one- fourth of the surface in which they occur." The following extract is taken from the contract for the backing-stone. "They shall be of a sound durable description of granite or gneiss, free from sap or seams, split out by wedges in blocks, with parallel beds and sides; at least three-fourths of the bed, and one-half of the build, must have a fair level bearing-surface; the vertical joints must be split down at right angles to the bearing surface of the stone; the stone must all be drilled on the top bed to receive a lewis of such size and form as shall be directed. The dimensions of the stone must in no case be less than the fol- lowing viz., length, two and one-half feet; width, one and one-half feet; thickness, eight inches. and no stone larger than the following will be received viz, length, eight feet; width, four feet; thickness, two feet and the stone must average not less than twelve cubic feet." The whole of the masonry was laid in mortar made of one part of Hydraulic cement and two parts of clean sharp sand; the cement used was from the celebrated Lawrence and Newark" manufactories, at Rosendale, New York. It was required to be fresh ground, very fine and lively, and transported under cover in barrels, con- taining about three hundred pounds; the barrels to be made of seasoned air-tight staves. and to have twelve hickory hoops, and each barrel to be well papered. Every tenth cask was subjected to the following tests: first, mixed up in flat cakes of two inches diameter, the moisture carefully dried from the surface by means of blotting paper, until it was set enough to bear one-fourth of a pound weight on a wire of one-twelfth of an inch diameter, and then put in water, where, after the lapse of not exceeding five minutes, it should bear one pound on a wire of one-twenty-fourth of an inch diameter. Second, a similar-sized cake, after the lapse of five days' insertion in water, was required to bear a wire of one-twenty-fourth of an inch, loaded with fifty pounds. Third, two bricks united by cement and put in water five days, must resist one hundred pounds before separating. No cement was used until after it had stood the above tests. They were made with water at a tem- perature of 70°. The mean of a large number of these tests is as follows: The time to dry in air, to bear one-fourth pound on a wire one-twelfth inch diameter, was 8 minutes. The time to set in water, to bear one pound on a wire one-twenty-fourth inch diameter, was three and one-fifth minutes. Force required to thrust a wire one-twenty-fourth inch diameter, through cakes of cement two inches diameter, and three-fourths of an inch thick, after being immersed in water 24 hours, 65 pounds. do. do. 48 " 70 " do. do. 72 " 75 " do. do. 15 days, 155 " do. do. 50 " 390 " The joints of the whole masonry have been pointed up in the following manner Cement and sand were put in an iron mortar slightly moist and made nearly into an impalpable powder; this was driven into the joint to the depth of an inch by an iron caulking tool, and the upper surface rubbed with a steel tool until it became very hard; in a few days this pointing was nearly as hard as the adjoining stones. The masonry of the dock was laid up in an unprecedented short time. The first stone was laid May 12, 1847, but the foundation was not entirely completed until June, 1848. The first coping-stone was laid July 4, 1849, and the whole work completed during that season. This dispatch was owing to the systematic arrangements of the vàrious operations, and to the number and capacity of the machines used in the construction. On the completion of the work it was found that there were no stone left on hand. The prices which have been paid for the stone used in this work are as follows: For the granite coping, hollow quoins, and other expensive stone, sixteen dollars per cubic yard. For the plain facing-stone, ten dollars; for the second class, nine dollars; and for the rubble stone, five dollars per cubic yard. For the fine cutting on the hollow quoins, checks, etc., one dollar per super- ficial foot: on the facing stone, forty cents; for the second class of cutting on the beds and joints of the facing stone, twenty cents; and for the third class of dressing on the interior stone, twelve cents per superficial foot. The weight of a cubic foot of the several kinds of granite, sienite, and gneiss, used on this work is as follows: Sullivan, Frankfort, and Seal Harbor, 168 pounds; Blue Hill, 165; Quincy, 169; Millstone Point, 170; Breakneck, 169; Staten Island, 186; and Kips' Bay, 172. The Gates.-The folding gates are similar to those used in canal locks, though of much greater dimen- sions. Such gates have usually been built of wood, though a few docks in Great Britain have them made with cast-iron frames, and covered with oak or sheet-iron. The low temperature of the atmosphere in this climate renders the use of cast-iron dangerous where it is subject to violent concussions; to avoid this objection, Mr. McAlpine was induced to arrange a gate 51 Digitized by Google 402 DRY-DOCK. made of wrought-iron, on an entirely original plan; they are the first iron gates which have been built in this country. They are made as follows: Two leaves are to be erected 80 as to turn on the quoin posts, and secured to the masonry of the dock by steps and straps, and arranged to be worked by capstans in the walls, from which chains are extended to open and close the gates. The frame of each leaf is composed of a series of horizontal curved bars of wrought-iron, bolted to the quoin and mitre posts, and covered on the outer side by a sheathing of boiler-plate, riveted and secured together by angle-iron. The outer extremity of each leaf is supported by two rollers traversing on circular tram-plates, laid on and secured to the floor of the masonry. The quoin-post is a cylinder of cast-iron. The mitre-post is made of wrought-iron, and a buffer of oak inserted where the two leaves come in contact. A similar buffer is inserted at the bottom of each gate where it comes in contact with the mitre-silla. There are two valves in each leaf for the passage of water to and from the chamber of the dock. Each leaf is thirty-eight feet three inches long, and thirty-one feet high, curved on a radius of seventy- six feet seven inches on the outside of the gate. The gate is twenty-six inches wide at the quoin-post, and twenty-two inches wide at the mitre-post. The quoin-post is turned and planed to fit the quoins and collar-straps. The horizontal bars are made of plates of wrought-iron, twenty-two inches wide and three-fourths of an inch thick, curved to suit the form of the gate, and made up alternately of three and four plates to each bar, and secured at the joints by splicing-plates. The sheathing is made of boiler-plates, from ten to fourteen feet long, and two to four feet wide. The bottom courses are five-eighths of an inch thick, and they gradually decrease in thickness, and are one-quarter of an inch thick at the top of the gate; they are secured to the horizontal plates by means of angle-iron riveted to each. The horizontal joints are lapped, and the vertical joints are butted, and riveted, and chipped, and caulked, so as to be water-tight. The mitre-post is made up of a plate of iron (welded) thirty-one feet long, twenty-two inches wide and one inch thick, set upright, with side pieces secured by angle-iron; the whole secured to the hori sontal bare by shelf pieces of angle-iron. The valves are made of cast-iron and set in a cast-iron frame, bolted to the bars of the gate. The valves are opened by screws placed on top of the gate. The rollers are of cast-iron, eighteen inches in diameter, and set in a frame with a long rod and screw, by means of which the extremity of the gate may be raised at pleasure. On the top of the gate is placed a foot-walk, supported by iron bars, and a hand-rail of wrought-iron. The capstans are geered, and the chain drum is provided with an ingenious arrangement for laying the chains which are extended to open and shut the gates. India Rubber is inserted in the buffers. The whole surface of the gates is painted, to protect it from corrosion. The horizontal bars were originally designed to be welded in one bar and to be made of iron one inch thick, and the bars at the bottom of the gate placed twelve inches apart. Some doubt having been expressed whether such a bar contained the requisite strength, a model bar of the same form and length proposed was made of four plates of iron, twenty-two inches wide and three-fourths of an inch thick, with lapping plates over the joints three feet long. This bar was first tested by loading it, with the ends secured and resting against abutments. A weight of 92,000 pounds was put on the middle of the bar, which deflected it two inches; the yielding of the frame prevented any further weight being applied, but it was subsequently tried with- out abutments, and deflected three inches with 50,000 pounds; six inches with 65,000 pounds; ten inches with 71,000 pounds, and broke with 75,299 pounds; the fracture being a rent near the middle, extending up from the lower edge six inches. The floating gate is a vessel sixty-six feet long, sixteen feet beam, and thirty feet hold. The keel and stems are made to fit grooves in the masonry, at the lower end of the dock; by admitting water into the vessel it sinks into these grooves and forms a barrier against the sea. It is removed from its place by pumping out water sufficient to float the vessel clear of the grooves. Means are provided for passing water through this vessel also, into or from the chamber of the dock. This gate or caisson is built as follows: The frame is made of vertical ribs of iron bent to the form of the vessel and covered with boiler- plates, and stiffened with cast-iron tubes. The keel and stems are made of plates of iron, two feet wide and five-eighths of an inch thick, with side plates of similar-sized iron, secured together and to the sheathing by angle-iron riveted to each. There are three decks; the beams are made of angle-iron four by two inches, and half an inch thick, split at the ends to form braces; they are covered with sheets of iron one-fourth of an inch thick. The stiffening tubes are sixteen inches diameter and one inch thick, and secured to the sides of the vessel. The centre tier are open at both ends, and provided with valves to pass water through and into the vessel. The ribs are made of iron six by one inch, set edgewise, and secured to the sheathing by angle pieces four by four inches, riveted to each. The upper part of the ribe is formed by welding on bars of angle- iron three by three inches. The sheathing is formed of plates, laid horizontally, about ten feet long and two feet wide. The bottom courses are five-eighths of an inch thick and gradually decrease in thickness, and at the top are three-sixteenths of an inch thick and four feet wide. Below the water-line the joints are lapped, and above they are butted. The bulwarks are carried up in a similar manner to the sides, and are lined. The kcel is stiffened by the insertion of cast-iron plates longitudinally and transversely, and the keel Digitized by Google DRY-DOCK. 403 is braced from and suspended to the sides, by a trussing of hollow cast-iron pipes five inches diameter, through which are passed rods of wrought-iron, two and a half inches diameter. Two windlasses are provided for warping. Hand-pumps are provided for emptying the vessel. The joints of the sheathing and stems are chipped and caulked 80 as to be water-tight, and the whole surface is painted to prevent corrosion. The gates and the caisson were designed by Mr. McAlpine, and constructed by Mr. H. R. Dunham, at the Archimedes Works, New York. The dock is filled by means of culvert passages through the lower ends of the walls, which discharge into the galleries leading into the main chamber. The Pumping Engines-The tides are but about five feet, which renders it necessary to provide the means of pumping out the chamber of the dock. For this purpose there has been constructed a steam- engine of great power, and pumps of great capacity. The duty required is the removal of 610,000 cubic feet of water in from two to three hours, as follows: 110,000 cubic feet to be raised an average height of 21 feet. 125,000 " " u " " 71 " 115,000 " " " " " 121 " 110,000 " " " u 46 17} " 110,000 " u of u " 221 « 40,000 " " " " " 26 " The following are the specifications and dimensions of the engine and pumps: A condensing vertical beam-engine, with a cylinder of fifty inches diameter, and a stroke of piston of twelve feet. The piston-rod of the cylinder is attached to one end of the beam, and from the opposite end the connecting-rod is attached and extended to the crank. The beam is of cast-iron, thirty-two feet long, with suitable bearings provided for attaching the draining and air pumps. The crank-shaft is of wrought-iron, turned and polished the crank is of wrought-iron, finished up. The fly-wheel is placed on the crank-shaft and is twenty-four feet diameter, with a cross-section of eighty square inches. The condenser is fifty-two inches diameter and five feet high. The air-pump is made of cast-iron and lined with a staving of composition metal; it is forty-four inches diameter and forty-two inches length of stroke, and is fitted with a floating top. The air-pump, bucket, foot-valve, seat, and rod are of composition metal. The cylinder has double balance-valves, made of compo- sition, with valve-stem of cast-steel. The side-pipes are of cast-iron, turned and polished, and provided with an expansion-piece. The cut-off motion is self-adjusting, 80 as to admit an increased quantity of steam to the cylinder, as the duty on the engine increases by lifting the water to a greater height. All of the connections of the engine are of wrought-iron, and those above the bed-plate are finished and polished. The piston of the steam-cylinder has metallic packings moved by steel springs. All of the boxes of the journals are of composition and lined with Babbet's metal. Automaton oil- cups are fitted to the principal journals. The engine is fitted up with a register, a steam and vacuum gage, and an indicator. The engine-frame is of cast-iron, with a bed-plate set upon a granite foundation raised eighteen inches above the floor of the engine-room. Upon the bed-plate are five gothic columns, and two pilasters on each side. The columns sustain gothic arches of ten feet span and an entablature, all of cast-iron. The engine-frame is surrounded with an iron railing. All of the work which is not finished or polished is painted and bronzed. The space for three feet entirely around the engine is covered with a cast-iron flooring figured in relief. In the boiler-room are placed three marine boilers, made of the best Pennsylvania piled boiler-plate, seventy-eight inches diameter and thirty feet long, with six hundred and fifty feet of fire surface in each. The boilers are so arranged that one or all may be used, as occasion may require. Each has a steam-drum, and cast-iron doors to the furnace and ash-pit. One of Worthington's feed-pumps is attached to each boiler. The boilers are warranted safe to be used with a pressure of fifty pounds to the square inch. All of the steam, feed, connecting, and injecting pipes are of copper. All the cocks and valves are of composition metal. All the joints are faced metal and metal. Steam and water gages, and safety, feed, and blow valves are put on each boiler. The steam-drums, pipes, and steam-cylinder are covered with hair felting; that on the cylinder is cased with mahogany staving, reeded and banded with brass bands. The felting on the drums and pipes is covered with hemp canvas, and painted. All of the wrought-iron is hammered charcoal-iron, and the cast-iron cold-blast of the best, quality. There are two draining-pumps, each of sixty-three inches diameter and eight feet length of stroke, 80 placed that one pump is driven by each arm of the beam. Each pump is provided with a suction-pipe and valve-chamber, and valve, and floating-top. The two suction-pipes are connected, by a pipe, to an air-vessel which is common to each. The draining-pumps, air-pump, and condenser are placed on a bed-plate eleven feet below the bed- plate of the engine. Between the bed-plates is a cast-iron reservoir, with hinge-valves to exclude the tide-water, but which will open at every stroke of the pumps. The chamber of the pumps is lined with a staving of composition; the bucket, rod, and valve, and valve-seats are of composition; the valves are covered with vulcanized india-rubber. All the joints of the pumps, pipes, and bonnets are faced metal and metal; all the connections which extend above the bed-plate of the engine are finished and polished. The engine and pumps were designed by Mr. McAlpine, and constructed by Messrs. Kemble, at the West Point Foundry. The Pump-well, Culverts, and Engine-house.-When the dock is to be emptied, the water passes from the chamber, through the galleries, into vaulted passages in each wall, which unite at the head of Digitized by Google 404 DRY-DOCK. the dock, and it is thence carried to the pump-well by a large culvert of cut-stone. The pump-well is placed under the east end of the engine-house, and is built in an oval form, the two interior diameters being thirty and twenty feet. The foundation of this well and culvert being carried to the same depth as the foundation of the dock, rendered its construction equally tedious, and the same difficulties were encountered, but its limited area permitted the use of shores and braces, extending across the pit. The disturbance which was caused to the ground in the vicinity, rendered it necessary to bring up a stone foundation for the engine-house, from the same depth as the well, by a series of arches. Leading from the pump-well is a culvert of cut-stone extending from the bay near the entrance of the dock. for the purpose of carrying off the water which is discharged by the draining-pumps. The engine-house is of fine-cut granite, three hundred feet long, sixty feet wide, and three stories high. The part not occupied for the engines and pumps is to be used for a machine-shop for repairs. The Machines and Tools used-A steam-engine, with a cylinder of fifteen inches diameter, and four feet stroke, was erected to drive the temporary pumps used for draining the work during its progress. These pumps were two forcing, of fifteen inches diameter and five feet stroke, capable of discharging six hundred cubic feet per minute. Duplicate pumps and an engine were provided to prevent delay and injury to the works by the temporary failure of the main engine. After the dam had been repaired, the quantity of water which flowed into the pit did not consume the whole of the power of the engine for its removal, and the surplus was applied in various ways to facilitate the progress of the work. Two other steam-engines, one of twelve and the other of five horse power, were used at times during the construction of the work. These engines were all fitted up with winding-drums, by which power was conveyed to the several machines. The mud was hoisted out by tubs suspended from the booms of the derricks and by cars moving on inclined planes. which were elevated by means of a rope leading to the winding-drums of the engines. In a like manner the hammers of the piling-machines were elevated, and heavy stone were hoisted and lowered on the cranes and derricks. Grindstones, saws, planing and grooving and screw-cutting machines were also driven by the surplus power of the engine. The edges of the flooring-plank, and the grooving and tonguing of the sheet-piles were all done by machines driven by steam-power. The drawings of some of the most useful of these machines will be found under the several heads of stone-setting machines," lewis," "crane," "derrick," piling-machine," stone-jack," pumping-engine," " iron gates and caisson," where a full description of them will also be found. It remains only to state how these machines were applied. The stone were chiefly transported on cars; lines of railroad encircled the pit, from which branches led to within reach of each of the laying- derricks, the piling-derricks, and the discharging-cranes. Of the latter there were seven, placed along the wharves and coffer-dam, by means of which an equal number of vessels could be discharged daily. This number was necessary, as in most cases the stone vessels arrived in fleets. The stone were hoisted out of the vessels with the cranes, worked by steam-power, and loaded on cars and transported to the stone-cutters' sheds or piling-derricks, where they were assorted and stowed away. Thence they were taken as required to the laying-derricks placed around the margin of the pit. The discharging-cranes were cheap machines. The piling-derricks were chiefly the old excavation-derricks refitted. The limited area of ground assigned by the officers of the yard to the use of the dock ren- dered it necessary to pile up the stone. Under the head of lewis" are described a variety of tools used on this work for securing stone for hoisting. Among them is a side-lewis, the invention of Mr. Lidgerwood, the master of masonry, which deserves particular notice, as being the first instrument of the kind which has been got up to suspend cut-stone without marring the upper surface; such as coping, altars, and steps. The Cost of the Work.-The amount which has been expended to the 1st of October, 1849, is $1,418,198.78. This sum has been classified under the following heads of expenditures, viz: Offices $69,418 17 Culverts and well 32,485 74 Coffer-dam 206,378 36 Temporary drainage and steam- Earthwork 149,802 58 engine 105,139 07 Foundation 127,250 03 Workshops 104,293 23 Masonry 600,569 84 Miscellaneous 6,566 41 Gates 16,295 35 $1,418,198 78 It is estimated that the sum of $420,000 will be required to finish the work; but in these amounts are included the value of machines and tools, the cost of constructing a machine-shop, and grading and levelling the Navy Yard, which are inappropriately charged to the dock, and which, if deducted, would make the cost $1,750,000. This great cost has arisen from the frequent changes which have been made in the officers of the work, and by the failure of the original coffer-dam, and by the unfavorable nature of the soil, and the difficulties experienced in getting down the foundations, and by the great en- largement of the structure beyond the size originally contemplated. Description of the Drawings.-Fig. 1137 shows a plan of the masonry. The entrance to the dock is at SZ; near by is shown the groove into which the caisson or floating-gate is sunk. DDDD represent the four capstans which open and close the two folding-gates. GB is a drain sunk below the level of the floor of the chamber. Fig. 1138 represents an elevation of the walls, and also of the timber and pile foundation. The entrance to the dock is at f, the groove for the floating-gate. At A is the recess to receive the wing of the folding-gate when open. B to y represents the chamber in which the vessel is received. At K is the gallery leading to the exhaust culverts running through the walls, a section of which is shown at J. PPPP represent the piles which support the structure, on the top of which are shown the Digitized by Google DYNAMOMETRIC CRANE. 405 timbers and plank. In Fig. 1139 is shown a section of the walls through the point marked A on the plan and elevation, being the recess to receive the folding-gates when they are open. The culvert passages which are used to fill the dock are shown at F. Fig. 1140 is an elevation of the entrance wall, showing the filling culverts at F, and the slides at the head of the dock for lowering timber by I. Fig. 1136 represents a section of the dock in the receiving-chamber, with a line-of-battle-ship resting on the keel-blocks and shores. The exhaust culverts are shown at E. In all of these drawings the most im- portant dimensions are marked in feet and inches, which obviates the necessity of any further description. DYNAMOMETRIC CRANE: of Messrs. Lasseron and Le Grand. This machine, for which inven- tors have taken out a patent for 15 years, dated 13th April, 1843, and for improvement dated 31st October, 1843, combines the two great qualities- First, That of indicating the weight of objects raised. Second, That of retaining its equilibrium of itself, whether placed upon a moveable wagon or railroad. Its first condition is obtained by means of a horizontal lever having at one end, together with a pulley, the chain by which the weight is suspended. The other end communicates with a scale to which are fixed proportional weights. The action is merely that of a steelyard operating in the interior of the crane at the same time as the crane itself, and is sure of indicating an exact weight whatever may be its extent. To obtain an equilibrium the crane has two beams, forming in its upper part a horizontal line, upon which runs an iron-way of which the incline is determined. A counterbalance, sliding upon this iron- way, represents half the maximum of the weight that the crane is destined to raise. When the crane is inactive the counterbalance is at the end of the beam which raises the weight: in this state it finds its own equilibrium; since the opposite beam is charged with a weight exactly equal to its counterbalance. The equilibrium of the crane will not cease if in the action of raising a given weight-the counter- weight falls in proportion-thus giving a like amount of weight upon each beam. The chain for raising the weight passes and presses at the same time upon a lever marked at one of its extremities. The other extremity, drawn by the movement of the pulley, has a rope or chain which winds upon a conical cylinder. Upon the axis of the cylinder is fixed a pulley which communicates with the counterweight in such manner that this pulley revolving as the marked lever, describes a greater arc; that is to say, as the weight raised is heavier, so will the counterweight retire in such pro- portion that the equilibrium will not be lost. In the same ratio as the chain distends and the weight raised is discharged, the counterweight resumes of its own accord its normal position. By the system of balancing, making all weight rest upon the pivot, the adjustment of the crane is rendered easy, and the weight suspended to the beam can be placed upon any point between the two tangent lines, within the circles of rotation of the crane, and parallel with the iron-way. A machine constructed upon such principles would be of infinite use in the working of railroads, as it can be re- moved to wherever its service may be required, which is often more economical than to bring the goods or merchandise before a stationary crane. It might with equal advantage be worked in factories, &c., or for the removal of large pieces of foundry-work. Description in detail of the Crane.-Fig. 1141 is a representation of its longitudinal elevation section- ally. or supposing one side to be removed in order that its mechanism may be more fully developed. Fig. 1142 is a side elevation. Fig. 1143 is a horizontal projection or a section of its upper works complete. Fig. 1144 is equally a horizontal one, but taken from one side at the line indicated in Figs. 1144, by 1-2. The other figures represent more in detail the principal pieces of which this crane is composed. Body of the Crane.-In order that this machine should maintain a constant equilibrium, it is con- structed with a double arm, which makes it exactly symmetrical on both sides of its axis. The arms are each composed of two side-pieces A in cast-iron, parallel and in form of a triangle, of which one side is vertical, the second horizontal, and the third is a curve. These side pieces are applied on the inside of the mountings B in cast-iron, to which they are bolted at equal distances, Fig. 1144. These mountings form a kind of pilaster, and are strengthened by a strong cast-iron square C, and by many trusses or bolts which maintain them in their position. Upon the horizontal sides of these side pieces are inserted plates of iron b, which serve as adjusting-screws. They are surmounted with a rectangular balustrade D in cast-iron, which serves for ornament, and at the same time conceals and restrains the moving counterweight, which should always balance the weight raised In the centre of the square plate C, a cavity or kind of cup is hollowed out hemispherically to receive the steel-pivot c, fixed upon the summit of the conical column E, upon which rests all the machine. This column is cast with a square platform F, which serves as base to the machine, and upon which the men can stand as occasions may demand. To make the crane capable of being removed, four supports G are inserted in cast-iron, which are screwed on underneath, and in which are adjusted brackets dd, Fig. 1145, for the purpose of receiving two wrought-iron axes of the wheels H in cast-iron. To make the transport more easy, the wheels are made to rest upon two iron bands I, arranged in the direction required for use, and upon which they can roll in the same manner as upon a railway. In order to have all four wheels bearing on the rails with equal weight, through the upper bed-plate d are adjusting-screws e, which being screwed into the thickness of the platform, permit the apparatus to be placed perfectly horizontal. It is also necessary to have the whole mounting perfectly in equili- brium upon the pivot c. round which it should freely turn, 80 that the equilibrium should not be broken. The lower sockets d only serve to maintain the axes of the wheels in their position, and can easily be held in their place by a simple bolt or linchpin. The handle by which the winch is turned is not directly placed upon its axis, but upon a lower shaft, with a pinion g in cast-iron, of 5 inch pitch diameter, and which works within an intermediate wheel K. The diameter of this is 8 feet 6} inches; its axis h works upon pillows. The sides of the check-pieces Digitized by Google 406 DYNAMOMETRIC CRANE. have another pinion of the same diameter as the first, but more strongly dented, and which works within the large wheel L, mounted upon the axis of the winch. M is a cast-iron cylinder, upon the surface of which are grooves wormed spirally, so as to receive the thickness of the rings of the chain o which bears the load. A second similar cylinder N, but smaller than the preceding one, is brought against this upon the same axis to receive a smaller chain i, which is intended to balance the weight of the former. At the end of the large chain is a swivel-hook j, to which the weight about to be raised is attached. All this mechanism is concealed by the two side-pieces of the crane, with the exception of the handle of the windlass. a E 25 1153. IL u 12 1154. 1155. z N 701,0 an 1147. 9 1156. 7) É M H 1141. at 19 5 3 1143. a of O 1157. 1152. 1144. N 1158. R 0 & 1145. 1151. 11 38 b 26" 9 o P per 1142 4 A of - F B I 16 4 a 5 4 F s 1146. 8 a R 4 1150. 1148. 1149. 9 Equilibrium of the Crane-This machine is the more interesting, by reason that its inventors have made it capable of always finding its own equilibrium without care or inspection, without reference to the weight it may be about to raise. To arrive at this, at the extremity of one of the arms of the crane a weight Q of cast-iron is fixed to the two cheeks by bolts or screws. This weight alone would evi- dently cause the machine to fall over, but it is counterbalanced by another, R, capable of advancing or retiring, like a wagon, over the entire length of the beam. So long as the crane is inactive, without a Digitized by Google DYNAMOMETRIC CRANE. 407 weight to raise, the counterweight R remains naturally at the extremity of the right-hand shaft and coun- terbalances Q. But from the moment they commence to raise a given weight, the counterweight must displace itself and advance from right to left, to enable the machine to retain its balance. It has for this purpose four cast-iron wheels C, which allow it a free action, passing upon two iron rails S, and to which is given from the first a slight incline that can be regulated at pleasure by the adjusting-screws K. The motion of the counterbalance weight is effected, not by the workman, but by the load this crane is raising. The counterweight, or moveable wagon R, is attached to an endless chain, which, passing over the guide-wheel T, of which the axis is at the extremity of the two inclined rails, is attached to a point of the circumference of the large grooved pulley U. This is cast with two smaller pulleys, Fig. 1147, on one of which a second chain m is attached, which is fixed at the end of a wrought-iron lever V. It is evident that if this end of the lever descend, the pulleys turn as indicated by the arrows, and the chain m is wound upon the greater pulley, and of necessity the counterweight is drawn from right to left. It is already perceived that to effect a displacement of the counterweight, it is only necessary to attach the load to the lever V. Having given the levers the form of a fork twice bent, as indicated in Fig. 1142, it is suspended to the arms of the crane by means of an iron axis n, which traverses them at their extremity; then at some distance from this axis is placed between the same branches a pulley V, over which passes the chain which bears the load, Fig. 1141. It is evident from this, that the more the weight, the more the pulley is pressed; consequently the more the forked lever tends to descend, the more of necessity the counterweight R advances to the left of the machine. This arrangement, so simple in itself, could, without difficulty, be applied to any kind of crane, moveable and with double beams, by the addition of a counterweight in the upper part. And it is entirely independent of the dynamometric system, neither would it embarrass the same in any manner. It is hardly necessary to remark, that from the moment the crane is relieved of its load the lever is free; the counterweight passes upon its inclined plane to recover itself at the extreme left of the machine; and that it may do 80 conveniently, the extremity of the two rails S are slightly bent. Dynamometric Mechanism.-The mechanism added by Messrs. Lasseron and Le Grand, to indicate the weight of the burden raised, is very simple in its arrangement, and the more curious that it does not interfere with the original construction of the machine. It is merely an addition that can be applied to any description of crane. This mechanism consists in a large wrought-iron beam X traversing as a steelyard by a steel axis o, carefully cut in the form of a knife, that it may act only upon any sudden jerk of the two steel cushions, which are adjusted upon two iron cross-pieces p, bolted in the interior of the side-pieces of the crane. This disposition will be more intelligible on reference to Fig. 1148, which represents a vertical section, following the indicated line 5-6 of Fig. 1141, and by Fig. 1149, which gives in elevation and plan the details of a cushion or pillow and cross-piece. The beam is divided by the axis o in two different parts to form two arms of unequal length, of which the shorter should carry the load, and of which the longer should communicate with the balance-scale. At the extremity of the shortest arm of this lever are suspended two iron checks q bound between them by a clamp, Fig. 1150, and reunited at their lower end by a horizontal axis v. They are furnished at their summit with two guard-plates, which hide the knives, by which they come in contact with the beam. The axis r has at its middle the grooved pul- ley Y, Fig. 1151, on which passes the principal chain O. The lateral movement of Y is prevented by the small checks S, (in detail Fig. 1152,) one end attached to the lower end of the checks Q, the other to the frame at t. The axis r is extended beyond the two external ends of its knives, to form pivots, which, when the machine only acts as an ordinary crane, carry the two supports v, bolted on the inside of the side- pieces, so as not to wear needlessly the knives; but these pivots are quite free when the crane acts as an indicator of weights. From knife edges at the extremity of the longest arm of the lever, a rod u, Fig. 1153, is suspended, whose length can be adjusted, and of which the lower end, also forked, affords a support for the knife edges 2, Figs. 1154 and 1155, of the lower lever x. At the extremity of the longest arm of the steelyard, is suspended a long bar u; to this effect it forms a fork at its upper part, as well as its lower, but this is brought opposite, Fig. 1153, to allow you to regulate the exact length of the bar, according to the distance which should exist between the beam and the lower lever a, which it serves to unite. This union takes place at both extremities by the introduction of steel knives 2, which destroy the friction, Fig. 1154, and yet permit all the freedom of action desirable. The lever = is at one end in the form of a horse-shoe, (see the details, Figs. 1154 and 1155,) 80 as to give it more firmness upon the axis Y. The other end of the lever is in form of a hook to receive the scale Z, placed as those of an ordinary balance to receive the weights. It can be understood, that in the con- struction of a like machine, the lengths of the lever, and of the great beam, can be combined, as is done upon the steelyards, or in the ordinary scales. Thus for machines of a small kind, in most cases, it would suffice to allow 1 to 10 lbs, that is to say, that a given weight of 1 lb. should balance 10 lbs, suspended at the extremity of the chain O. With cranes of an intermediate or larger size, they might allow 1 upon 20, or 1 upon 30. That is nearly about the allowance for the machine here represented. It will be perceived that the knife x, Fig. 1154, is at some distance from the point of rest y, equal to 0.270, and the total length of the lever is 0.880; consequently the proportion is 0-27 : 0.88 :: 1 3-25. The smallest arm of the steelyard X has for length 0·440, and the longest 3.82, which gives 0.44 3.82 1 : 8.68. Consequently the product of the two gives 1 : 3.25. X 8.68 = 282. Digitized by Google 408 DYNAMOMETER. If the differences of the two pieces be added to enable them to be in equilibrium, it will be seen, that the ratio between the power and the weight placed upon the platform Z is to the resistance or weight added to the end of the chain as 1 30. With the lower lever x is forged a vertical branch a', Fig. 1154, joined at right angles, and terminated in form of a knife acting as indicator, and corresponding with the point of a similar piece b', fixed against the cast-iron cross-piece C. When the load is in equilibrium with the weight on the platform, the sharp edges of these knives ought exactly to coincide, as they do at a' b', Fig. 1141. Therefore, weights must be put into, or taken from the scale, until this end is obtained. Equilibrium of the Weight of the Chain-With such disposal of the mechanism as adopted by the inventors, it was indispensable for the exactitude of the machine to make an allowance for the differ- ence of the weight of the chain O. To overcome such, Messrs. Lasseron & Le Grand have cast a second roller N, of much smaller diameter, alongside that which bears the chain, and upon which the small chain i can wind itself, which, passing as the chain o upon the throat or neck of the pulley V', passes on still to a guide pulley c', placed in the upper part of the crane, and from there to another pulley d', carried by the extremity of the steelyard near the point of suspension of the long rod u. A small counterweight e' is attached to the extremity of the small chain to balance the exposed portion of the chain O. Or when this winds itself upon the winch, and passes upon the pulleys Y and V', and besides upon the guide pulley A', which causes it to take the proper direction, the small chain winds itself equally and in proportion upon its own small windlass N, and so diminishes as much the load at the end of the steelyard. In like manner, as the thickness of this smal lchain has been calcu- lated beforehand, 80 that a given length acting upon the steelyard balances, with an equal length given of the chain o, by reason of the difference of circumference of the two winches, and of the arms of the steelyard, a conclusion as nearly correct as possible is immediately arrived at. Equilibrium of the Weight of the Steelyards.-The inventors have also endeavored to balance the weight of the steelyards; fearing that in the cranes of large dimensions this difference of weight might be considerable. In a certain point of the larger beam X, they adapt by means of a knife a double forked piece of iron, detailed, Fig. 1157, which in its lower part rests upon the extremity of a counteracting lever g', which also moves upon two knives, that carry the steel bolsters dovetailed on the iron way h'. This one represented in elevation, Fig. 1158, is fixed between the two side-pieces of the right arm of the crane, and has two square blades which serve to preserve the bolsters and knives. At the ex- tremity of the lever f' is a counterweight, either in lead or cast-iron, to overcome the weight of the great arm of the lever of the steelyard. DYNAMOMETER, invented by S. Brown, of Lowell : the principle of which consists in measuring the power used by weighing the strain on an intermediate geer. 1159. y B A c E Description-A is a pulley, Fig. 1159, which receives the power from the driving-pulley, which is trans- mitted through the geers CD and E to the pulley B, thence to the driving-machine. The pulleys are out- side of the frame, the geers CE inside of the frame, and supported by it; the intermediate geer D hangs in a stirrup, supported by the beam F, which is a steelyard, whose fulcrum is f. But it must be remarked, that the strain on the centre of the intermediate geer (since the pilot line of the geer on one side is the point of application of the power and on the opposite side is the fulcrum) is double the power transmit- ted by the machine. G is a cylinder filled with water, in which a piston, fitting loosely, is attached to the beam F, and is used as a regulator to prevent sudden oscillations in the beam, which invariably oc- cur in such machines. Digitized by Google DYNAMOMETER. 409 DYNAMOMETER. Figs. 1160 and 1161 are two views of a dynamometer constructed on the prin- ciple of what is called the differential-box," and consists of two pair of belt-pulleys A A, BB, mounted on the shaft CC: one of these pulleys on each side is loose, while the other is fast. The fast pulley on the side A A, and the bevel-wheel D, are both fastened to the shaft C C. The bevel-wheel F is fastened on a small tube connected with the pulley B. The wheels EE are connected by G, which is constructed 80 as to revolve round the shaft C C. To apply this simple machine, a belt from a druni on the main driving-shaft is brought to the pulleys AA, whilst another belt is carried from the pulleys BB, to the machine or machinery, the weight of which is to be ascertained. And it is plain, that if the pulleys A A, and the wheel D, are once put in motion, the wheels EE will also revolve on their axis, and at the same time the connection-shaft G will revolve round the shaft CC, thus leaving the wheel F and the pulleys BB, standing still; but, if the wheels EE are kept in their present horizontal position, and prevented from revolving round the shaft C C, it is equally obvious, that the wheel F and the pulleys BB will then be moved at the same speed as the wheel D and the pulleys A A; hence the weight required to keep the wheels EE in their present position, is equal to the weight required to move the pulleys BB. The weight thus required, is found by means of the lever HJ. The arm H is attached to the centre of the wheels EE, by the straps aa, Fig. 1160. The arm J is divided upon the principle of the Roman steelyard. The weight M is merely intended to balance the arm J, and being 1160. 1161. J J 16 1% n 8 8 4 1 N 1 a E E G H C D F E E a A B P M M H fastened with a set-screw, can easily be shifted on the arm H, as may be found requisite. Therefore, when the wheels EE are kept in their present position by means of the lever J H, it is evident that a weight of 20 lbs. acting upon the pulleys A A at P, will balance another of the same weight at N, of the pulleys BB. Now the distance from the centre of the shaft CC to the division on the lever J marked 1, is equal to the radius of the belt-pulleys; hence a weight of 20 lbs. at 1 will counterbalance the same weight at P,-that is, making no allowance for friction, the amount of which is ascertained by the additional weight required to balance the given weight at P; and having once ascertained the proper allowance for friction, the machine is put in motion by shifting both belts on to the fast pulleys, and moving the balance weight along the lever J from 1 to 4, 8, 12. or to whatever number will balance the wheels E: and the weight thus indicated on J, is the weight required to move the machine or machines, from which deduct the allowance for friction. A worm at y on the end of the shaft C C, works into a wheel with an index and pointer, in order to show the speed at which the machine is driven, and also to determine the difference of the weight of any machine at different speeds. From the above description it is presumed that the principle upon which this dynamometer is constructed, as well as the mode of applying it, will be easily understood. An improvement has been made on this machine by J. B. Francis, Esq,, of Lowell, by which the 52 Digitized by Google 410 DYNAMOMETER. power is transmitted to and from the dynamometer in the same line; thus, instead of the pulleys B B, a geer is employed, which works in an equal geer fixed to the end of an extra shaft parallel to CC, on the opposite end of which, and on a line with A A, is a pulley of the same size as A A, from which power is transmitted to the machine to be driven. The beam is balanced without the use of a moveable weight M, and to this end a regulating pump is attached, as in Brown's machine. A clock is driven by an endless-screw on the extra shaft, which registers the revolutions of the shaft, and a bell strikes at every 50th revolution. The beam J is 80 graduated, that the power used, or weight raised 1 foot high per second, is obtained directly, by dividing the weight as shown on the beam, by the number of seconds occupied by the shaft in making 50 revolutions. The friction of the machine was taken by the use of Prony's friction break, placed on the extra pulley, and was ascertained exactly by a course of experiments, on different speeds and weights. DYNAMOMETER. Regnier's Dynamometer resembles a common graphometer, the principal part of which instrument is a steel spring bent in the form of an ellipsis; it should be properly tempered, and well welded, and covered with leather, to prevent injury to the hands when used. This spring is represented by A A', B', formed by two equal plates united at the ends by rounded half-rings. The dimensions of this spring vary according to the tension required, or the weight to which it is applied. The dynamometer used to ascertain human strength weighs little more than two pounds, and serves to measure a thousand times that weight; its total length is about 12 or 13 inches, and its greatest breadth, as measured in the middle of the two arcs, is 2.2 inches, and the least breadth at the extremity of these arcs is t of an inch. The thickness of the arcs at their centres is nearly 2 inches, and its height, which decreases from the centre towards its ends, from I's to I'o of an inch; the chords of the two ares are 6·4 inches. This length, added to that of the two demi-rings, gives for the total length of the dynamometer 12 or 13 inches. The distance between the parallel chords is about t of an inch, and the perpendicular of the arcs are each 10 of an inch, giving about 2-2 inches for the total distance between the centres of the arcs. 1162. L I A' E B D T B o & BU N/ L d M ODPY H N B There are two methods of stretching the spring, by pressing it in the direction of the perpendicular of the two arcs which form it, or by drawing it with the two rings at right angles to that perpendicular these two limits of tension are indicated by two scales drawn on the same limb, called scales of pressure and tension : the first gives the pressure of weight from zero to 264 pounds avoirdupois. The greatest pressure brings the centres within 04 of an inch of each other, each perpendicular, which is 07 of an inch when there is no pressure, is reduced to 0.5 of an inch. The brass limb on which the scales are drawn is fixed on the centre of the arc A' B' of the spring, and the opposite arc A B carries a counterpoise a b, 3.1 inches long the extremity b of this counterpoise acts on a small branch b H, 0.3 of an inch of a bent-lever, b Hc, whose other branch H c is a needle, 2.4 inches long, from the centre H of rotation to the index c. Below this index is a small cylindrical thread, 01 of an inch, which is fixed to the needle Hc, and serves as a foot when it turns on the centre H, parallel to the limb. This first needle by turning communicates a rotatory movement round the centre K to another needle K dd which rolls on Digitized by Google DYNAMOMETER. 411 the smooth portion of the screw K, and leans on the limb by a foot G furnished with a washer to re- duce friction. This second needle has two indices d and d, to mark the pressure and traction; it is moved by the first needle H c; the divisions of the arcs described by the two indices are numbered in pounds, which indicate the weight brought by the needle to these divisions: as long as the spring is not stretched, the needle H c preserves its primitive position, and the needle dd' of the scales remains on the divisions to which it is drawn by the tension of the spring; whence it is seen that the system of two needles gives us the power of preserving the measure of a tension, when the force which produced this tension no longer acts. The greatest arc which the needle H c can describe is determined by the course of the counterpoise a b, which is 039 of an inch. The points b and c of the bent-lever GHc describe arcs of the same number of degrees: with regard to the positions of the two needles Hc, Kd d' to the right line HK L of their centres, the angle which the second needle makes with this right line, is equal to the angle c HL of the first with the same right line, increased by the vertical angle H c K of the two needles, for in the triangle H c K, whose sides H c and HK are constant, the angle c K H is the supplement of the angle c KL, and of the sum of the two angles c and H c K. The distance HK of the centres H and K is about 0·46 of an inch, and it results that the total arc de- scribed by the needle <dd is nearly one-third of the circumference. To preserve from injury the system of these three pieces, viz., the counterpiece a b, the bent-lever bHc, and the needle with two indices dd', the limb is covered by a plate NNN, which rests on the three pillars, 0.39 of an inch high. If the axis of rotation of the bent-lever were prolonged, it would meet this plate in the point H', the centre of the arc of a circle m' m" which terminates it, and whose radius is equal to the length of the needle Hc. The divisions of the arc m' m" are figured, and the figures indicate the same tensions as those on the scale of traction. The dynamometer just described indicates on the scale of traction a tension of a ton weight, which is greater than the most powerful effort of a horse, but nevertheless too small to measure the ordinary effort of a power applied to a screw. M. Regnier constructed a dynamometer on the same principles, which measures a traction of 6,600 lbs. the spring was of the same power and length as the old one, but the two arcs or plates of which it was composed were longer, thicker, and further apart in their centres; their distance from each other was 45 inches; by the greatest traction it was only diminished 04 of an inch; these arcs had in the middle a breadth of 1.8 inches, and a thickness of 02 of an inch; the total weight of the instru- ment was 53 lbs. By placing the machine between the two ends of a cord passing over two or more pulleys, the ratio of the force which separates the extreme pulleys to the tension of the cord will be known, and by this disposition we can measure a traction much more considerable than that which is indicated by the scale of the dynamometer. Fig. 1162 shows the arrangement with two pulleys. Details of the Construction of the Dynamometer.-Two supports DD' of steel, are adjusted solidly on the two opposite branches of the spring in the direction of the perpendicular of the axis. The first support D, cut in a fork, carries a screw on which the extremity a of the counterpoise a b rolls; it is about 14 inches high, and 0.59 wide; it is retained on the centre of the arc A B by a strong screw, whose head is marked T on the convex part of the arc. The second support D is also retained by a screw, the extremity of which, t, is seen on the concave part of the arc A' B'; the upper face E E of this support is about 4 inches long: on the opposite face EF, which is of the same length, is a brass plate I L, fixed by a single screw g, which is level with EF in the plate, hardened to make a spring, carries at its extremity a pivot I, which passes through the support and the limb; this pivot, like that of a compass- needle, serves as a centre to the bent-lever b H the limb is applied to the face EF of the support D', and is fixed there by two screws e f. The plate IL being a spring, the pivot I yields to a pressure of the counterpoise, and prevents any rupture of the mechanism which turns the needles of the scales. The covering plate OPQ is voided at K' in a small circle of a diameter nearly equal to that of the head of the screw K, round which the needle K d d works, with a slight friction on the limb: if this friction be too slight, a turn-screw which passes through the circular opening K' will tighten the pressure. The lower pivot of the bent-lever b H c rolls on the pin I'; its upper pivot rolls on the side H', which is riveted to the covering plate OPQ Spring-Balance and Eprouvette. The spring-balance most used in commerce is formed of two steel branches A C, CB, bent at an angle of 45°; each of the arcs D pq E, I H G, is fixed to one of the branches and traverses the other. By drawing the rings EG, which terminate the ares in opposite directions, we bring the branch AC 1163. near BC; a circular scale figured from 5 to 40 indicates the respec- tive positions of these two branches. The branch AC pushes before it a small cursor k of card or leather, which slides easily on the C metalic wire fg, attached to the branch CB of the balance. To graduate the scale, suspend the balance by a ring E fixed to the branch A C, and attach weights to the ring G, which is at the ex- tremity of the scale. The numbers on the scale indicate the tension of the spring. Regnier has made an excellent instrument of this spring-balance for trying the strength of powder. The length of the branches A C a and CB is about 48 inches, and their breadth about an inch; a small L brass cannon, whose breech H is on the branch CB of the balance, and whose mouth I is closed by the fuse I L of the obturation DILE 1 fixed on the other branch A C of the balance, contains a given weight of the powder to be tried; it is primed by a little powder put in the pan F: the powder within the cannon is fired and drives it away; after the ignition the two branches Digitized by Google 412 DYNAMOMETER. of the balance approach, and the cursor k indicates on the scale the tension of the spring at the moment of the explosion. The iron DE, and the brass arc G H on which the scale is drawn, pass through openings pq, r 8 made in the middle of the plates CB and CA. A dynamometer for measuring animal force was invented by Mr. Graham, and afterwards improved by Desaguliers, but it was found to be inconvenient for the purpose, as it was made of wood. Leroy afterwards formed one in a metal tube 10 or 12 inches in length, with a spring within it placed vertically on a stand. This, however, was not found so useful as Regnier's, where the sides of the spring are made to approach each other, and move an index, which marks the degree of approximation on a semicircu- lar scale: a man can ascertain by it the mean force he exerts with either hand, or with both together it was with this kind of dynamometer that M. Quetelet, of Brussels, made his experiments upon the strength of men of different statures and ages. Another kind of Spring-Balance.-The spring of this balance is bent in a curve CKD, terminated by two braces, C B, DE, one of which supports the pinion I, and the other a rack D EGH, of which the toothed portion GH catches the pinion L This pinion and the needle which marks the tension of the spring turn on the same axis. The face is a circle whose centre is on the axis of the pinion I, and is fixed by two 1164. screws t and t', on the plane T V, which is soldered to the upper brace AB, which carries the pinion. To graduate the scale, suspend the balance by the ring A, and attach known weights to F by the hook d c. The rack G H will work the pinion I, and the needle fixed on the axis of this pinion & V takes up successively the positions figured V from 0 to 100; these numbers express the t' d 20 force of tension on the spring in pounds. The index of the needle describes about 1 of the inch as the maximum tension of the spring, or for the greatest distance between the extremities C and D of the spring, a which is about 11 inch. M L K The plane of the balance being supposed 5 vertical, as in the projection, on another H' vertical plane passing through the axis of the pinion; the face of the brace A B, per- 3 pendicular to the plane of the limb, is B drawn parallel to itself in A'B'; we see D on this face in the parallelogram 1 2 3 4, the projection of an opening made in the thickness of the brace AB, to make way for the toothed part GH of the rack; the breadth, 12 or 34, of this opening is 4 inches; LM is the projection of the axis E of the pinion I; the spring CKD is pro- jected in CD; the plane on which the face is screwed has for its projection TV. The spring is 0·11 of an inch thick, and 12 inches broad. To render this balance more con- venient, a needle is added, which turns freely on the face round the axis of the pinion I, and may be employed as the dynamometer; it is even preferable for measuring the ordinary strength of men. Of the Dynamometric Machine, and the Measurement of the Tangential Force of an Axletree.-Let A B, Fig. 1165, be the section of an axle moved by water or any other power; an unknown but con- stant resistance acts tangentially to this axle, and we require to measure it. To resolve this question, suppose we fix on the axle A B of a wheel DEFGH, of any number of rays CD, CE, CF, &c.; this wheel turns with the axle. Another wheel having the same number of spokes, C d, Cc, Cf, turns freely on the same axle; springs Dd, Ee are attached to the couples of the spokes, D, Cd, CE, Ce of the two wheels, 80 that the points of attachment D and d of the extremities of the springs are in a plane perpendicular to the axis of rotation C of the axle A B, and at an equal distance from this axle. Having disposed the power or mover so that it shall turn the wheel freely in the direction of the arrow X, it is evident that the extremities de,fg of the springs fixed to this wheel, would swerve from the points of attachment DEF, &c.; that the equal angles D d, Fce, Ecf, &c., whose sides pass through the extremity of the springs, considered in their primitive position, would become other equal angles Ded, Ece, Ecf, &c., and all the other springs would be stretched, if not equally, at least at the same angle: when the total tension of the springs is equivalent to the resistance applied tangentially to the axle, the system of the two wheels will turn on the axis A B as one and the same wheel. Now suppose that the axis turns, and that we can measure one of the angles D d', at which all the springs are stretched, we shall have in the triangle DCd the angle C, the equal sides CD, Cd, and conse- quently the perpendicular let fall from the centre C on the side Dd, or the radius of the circle to which the force which stretches the spring is tangential. We may, besides, observe the number of turns of an axis in a given time, whence we may deduce the velocity of the point at which the force Digitized by Google EARTHWORK. 413 that stretches each spring is applied. Multiply this velocity by the sum of the tension of the springs, the product will be the dynamic effect of an axis in a unity of time, for example 1". To measure the angle D c d, which moves in a plane perpendicular to the axis of rotation C of the axis AB, we fix on the lines Cd, CD, the middle of the radii, two small hammers a b, coupled by a spring Dd, which each moves in a plane perpendicular to the axis of rotation C, and at equal or unequal distances from this axis, but greater than the radii of the wheels. These hammers strike two bells placed beyond on circles described through a and b. This being arranged, we can with a seconds watch measure the time which elapses between the two consecutive sounds resulting from the blow of each of the hammers on the bells, and knowing besides the time of the entire revolution of the hammers, these two portions of time will be in the ratio of the arc which measures the angle of the right lines passing through the extremity of each spring to the entire circumference. This angle being known, we can easily measure the weight which stretches each spring at a known angle, and the sum of these weights will be the total tension of the dynamometric machine. 1165. By this description it will be seen that simple springs without needles or scales, whose force of tension for the same lengthening may be sensibly unequal, give exactly the measurement of a tangential force applied to axes: by taking springs capable only of a tension of a ton, we may place eight on a circle of 3937 inches radius, and eight others on a concentric circle of 8 decimetres, supposing the axle makes four turns per minute; the dynamometric machine will show, on this hypothesis, that the dynamic effect produced by a force applied to an axle is nearly equivalent to that obtained from 80 horses. Another dynamometer deserves to be mentioned: a vessel containing water should have a cylinder, made of some heavier substance than the water, suspended in it by a rope passing over a pulley: when the upper surface of the cylinder is on a level with the surface of the water, the weight of the cylinder, or the force which it exerts upon the rope, will be equal to the absolute weight of the cylinder in air diminished by the weight of a quantity of water of the same magnitude as the cylinder: a horse or a man pulling at the rope to raise the cylinder above the fluid surface, the weight of the cylinder will gradually increase; and if the magnitude and specific gravity of the cylinder are duly adjusted to the force, there will be a particular position of the cylinder at which its weight will exactly balance that applied. The forces in equilibrio, or those required to be measured, will be equal to the absolute weight of the cylinder, diminished by the weight of a quantity of water equal to the magnitude of the immersed part of the cylinder: a scale attached may be so set out, that it will accurately measure the force ap- plied, and the cylinder can be increased to any length by diminishing its diameter, so that a very lengthened division may be adopted. EARTHWORK, wagons for executing. Figs. 1166 to 1169, a wagon generally employed on railways; this wagon is tipped at the end. Figs. 1170 to 1173, a form of wagon much in use; this wagon is tipped at the side. Figs. 1174 to 1177, wagon tipped at the end. Figs. 1178 to 1181, wagon tipped at the side. The flanch of the wheels is about 1 inch deep, slightly bevelled off from the inner side to the outer, so that when the wheel is running in a straight direction, the edge of the flanch is kept about an inch clear of the rail, or from coming in direct contact with it: this is effected by making the tire, which is 4 inches broad, slightly conical, the inclination being about one part in seven or eight. Where the flanches are not bevelled or are too shallow, the carriages are very apt to run off the rails, and should they come in contact with a defective joint in a rail the same evil islikely to occur. Wagons 6 feet in length and 2 feet deep, are found convenient on railways for carrying earth and ballast, as well as the other materials required whilst the works are in progress. The plans, Figa. 1169, 1173, 1177, 1181, show the under side of the framing, consisting of two stout longitudinal timbers to receive the iron axles, upon which the wheels turn. The bottom of the wagon is further strengthened by iron plates, and a three-quarter round iron bar passes from one side of the frame to the Digitized by Google 414 ELECTRICITY. other, to hold them together in the middle, and to aesist in supporting the load at the bottom. The uprights at the sides are mortised into the bearer at bottom as well as the top rail, and at each angle is an iron bolt that screws the whole together in the direction of its height. The ends are moveable, some- times sliding in grooves, at others merely pinned in their place. 1167. 1166. 1171. 1168. 1169. 1173. B 1170. 1175. 1174. 1177. 1172. 1176. 1179. 1178. 1181. 1180. a In the construction of all kinds of railway carriages, great attention should be paid to the centre of gravity of the load, for if too high, their oscillation is considerably increased, which frequently occasions them to be thrown off the rails, even where the wheels have the proper depth of flanch: the revolving parts of the machinery in a carriage should be always so balanced that a smooth and equable motion can always be maintained. ECCENTRICS. See ENGINES. details of. ECCENTRICS AND VALVE GEER See LOCOMOTIVE. ELECTRICITY. All substances are susceptible in a greater or less degree of electrical excitation, but according to their readiness to evince electric properties by friction, they are classed as electric or non-electric. Electric substances have not only the property of electrical excitation, but also the power of confining, or imprisoning, as it were, the communicated electricity upon other bodies, in which it could not under the same circumstances be 80 excited while on the other hand, the non-electric substances al- low the electricity to pass off. Non-electric substances, therefore, have been called conductors, and electric substances, non-conductors or insulators. These expressions are merely relative, yet the difference in conducting powers in certain bodies is enormous; that of iron, for instance, being estimated at 400,000,000 times greater than that of water. Digitized by Google ELECTRICITY. 415 The following Table gives in an approximate way the order of precedence in conductive power. Conductors. Non-conductors or Insulators. All known metals. Ice at 0° of Fahrenheit. Most perfect. Well-burned charcoal. Dried vegetable substances. Plumbago. Smoke. Less perfect. Dried animal substances, generally. Burning gaseous matter, as flame. Parchment, leather, feathers. Baked wood. Concentrated acids. Oils and fatty substances. Dilute acids. Silk. Saline fluids. Fur and hair. Less perfect. Living animals. Dry gases, including air. Living vegetables. Pure steam of high elasticity. Wood, in its ordinary state. Glass and all vitrefactions. Snow, and ice from 32° to 0°. Water. Aqueous vapor. Common earth and stone. Imperfect. Most perfect. Diamond and transparent gems. Talc. Amber. All resins and resinous bodies. Dry chalk and lime. Brimstone. Marble and porcelain. Shell-lac. Paper. Alkaline matter. The effect of the electrical discharge on metallic bodies is to raise their temperature to a less or greater degree, according to their conducting power. The ratios of heat evolved, and of those of conducting power, are shown as follows: Heat evolved. Conducting power. Silver 6 120 Copper 6 120 Gold 9 80 Zinc 18 40 Platinum 30 24 Iron 30 24 Tin 36 20 Lead 72 12 Vitreous and Resinous, or Positive and Negative Electricity-There are two opposite electrical or elementary states of excitation, in which forces are developed attractive of each other. These forces were, by more early inquirers, supposed to depend on two different kinds of electricity, termed vitreous and resinous, as being derived the one from excited vitreous bodies, the other from excited resinous bodies. Subsequent investigations have shown that both these electrical elements may be obtained from the same substance; bence it has been agreed to designate these opposite states by the common positive and negative signs of arithmetic and algebra, calling the vitreous excitation, as developed in the friction of glass by silk, positive or +, and the resinous, developed similarly by the friction of resinous bodies, negative or - Substances in dissimilar states of electricity, that is, the one + and the other -, attract each other; those in similar states, that is, both + or both -, repel each other. If an insulated body A, charged, for example, positively, be placed near another body B, insulated, but in its natural state, this latter body B, while in this position, will be found in an electrified state; the portion nearest the charged body A showing a negative electricity, and the portion most remote a positive; or vice versa, if A be charged negatively. This influence has been termed Electrical Induction, and the resulting effect Induced Electricity. The expressions of the most important electric laws are as follows: The attractive force between two opposed surfaces varies— If between a charged and a neu- directly, as the square of the quantity of electricity, tral free conductor, inversely, as the square of the distance, 64 " " " surface, If between an unchangeable posi- directly, as the square of the quantity of electricity, tive and negative surface, inversely, as the distance. The conducting powers of different rods of the same metal vary therefore in a higher ratio, apparently, than as the surfaces, though they are not asserted to do so as the squares. They vary inversely as the length; and directly as the square of the diameter of the solid rod. The heating effect (referring to solidity) varies directly, as the square of the quantity of electricity inversely, as the area of the transverse section; inversely as the length of conduction. Having thus briefly stated the general principles and laws of electrical action, omitting electric- machines, electroscopes, &c., as being connected rather with scientific investigation and experiment, we proceed to the practical applications or examples of power which electrical knowledge has supplied. Lightning-conductor-1 first and most obvious practical result of Franklin's discoveries was the lightning-conductor for the protection of buildings and ships from the violent effects of the disruptive discharge. The first lightning-conductors consisted merely of metallic rods or chains proceeding from the highest point of the building or the ship, in a direct line to the earth or to the sea; but this was not found in all cases sufficient. Instances have occurred in which the conductors have been fused or Digitized by Google 416 ELECTRICITY. shattered, and hence arose a prejudice against their use, under the idea that they did more harm than good, by inviting the destruction they were intended to prevent. An attentive examination, however, of numerous cases of damage from lightning has shown that the path of discharge from the cloud to the earth is always in the line of least resistance. This line may not be the shortest lineal distance, but it is in all cases the shortest electrical distance; that is, the lightning picks out the best conductors in its transit to the earth, selecting with the nicest discrimination metal cramps and fastenings, and by its expansive power shattering and destroying inferior conducting substances, such as wood, brick-work, and stone. The following diagrams from experiment, illustrate this principle fully: Figs. 1182 and 1183. The shaded part shows the direct track a a 1183. 1182. taken by the electric fluid along a line of metallic conduction, disregarding every thing but its own course. Fig. 1182 may a represent the conducting masses in a building. Fig. 1183, the passage of the fluid across the bight of a wire-rope, or of a chain. Hence the principal danger in using chain or wire conductors in the upper masts of shipping, as when these last are lowered they are apt to leave the chain or wire-rope hanging loosely; and when handling this as a bight, the seaman's body becomes the shortest course (a' a', Fig. 1183) for the electric action, on the very same principle that a metallic rod-conductor of proper dimen- sions may be passed through a barrel of gunpowder with perfect safety, though a chain would ignite it at once. To guard effectually a structure from the stroke of lightning.- First: The conductor should be of metal, and one of the best con- ducting metals should be selected. Second: The conductor should be capacious. Third: The conductor should consist of several branches with pointed rods projecting freely into the air from distant summits of the building, and connected by horizontal branches passing along the ridges, and from these sending off other branches to the ground. 1. Copper is the best conductor the rods should not be less than half an inch diameter, if solid; three-fourths of an inch is preferable, and generally ample. If hollow, they may be from 1 to 2 inches in diameter, and about one-fifth of an inch thick. If iron rods be used, they should not be less than three-fourths of an inch diameter when solid it hollow, not less than 2 inches diameter and three-tenths of an inch thick, and jointed. The hollow conductor (if sufficiently thick for stability) is better than the solid rod of equal length and weight, because the metal should display as much surface (in lateral dimensions) as possible con- sistently with strength, to reduce the intensity of action on surface, and heating effect in transverse sectional area but unnecessary length should be avoided. The conductor should involve in its course the principal detached masses of metal in or on the actual walls and framing of the building or ship: if not allowed this course freely, it will be apt to take it in a summary and violent manner. Figs. 1188 to 1192. It should be placed as close as possible to the walls, &c., which are to be defended,-not at a distance from them and should be carried down at once directly into the ground; and when below the surface, it should then divide into two or more pointed branches a a a, Fig. 1187, slanting away from the building. If circumstances permit, the lower end should pass into a well, or a stream, or a drain, or at all events into earth that can generally be kept moist from any neighboring gutter. It is a useless precaution to pass condctors through glass linings and holdfasts, as has been recommended, since the lightning will always take the direct course down the rod until interrupted; on which last account chain conductors are very inferior to those of rod, being a series of interrupted conductions from which the lightning is ready to turn aside at any point of contact of the links,-provided that at such point a freer and easier line of conduction be offered by some neighboring body than what the chain itself affords. The conductor should be attached to the most prominent points of the building, Fig. 1190: if its length be very considerable, its transverse dimensions must be increased; and in doing this, the provision for a sufficient conducting surface insures that for the heating effect. In ornamental buildings, such as honorary columns, &c., for the sake of appearance, the conductor may pass down withinside; it must, however, be firmly fixed, and the line of conduction made and kept complete and undisturbed. In extensive ranges of buildings, all the most prominent points should have long pointed rods pro- jecting freely into the air, at least 4 or 5 feet above the building; and the larger the range the higher they should be. Fig. 1190. It does not appear that any single conductor hitherto made can insure beyond a horizontal radius of 40 feet hence, in practice, less should be taken; though a wider range may be allowed if the roofs be of zinc, lead, copper, or any other metal in well-connected sheets or if the ridges and hips only be thus guarded, and the whole well joined to the conductor, and to iron gutters and pipes, now coinmonly used, and a free passage be provided to the ground at different places. The points of contact must be numerous, to reduce the heating effect (or chance of fire) at such points, as the whole electric action will condense there, having still to pass through them on its way down. There is no reason why lightning conductors should not be painted or lacquered. In addition to the diagrams given in Figs. 1184, 1185, and 1186, showing the construction of hollow conductors for buildings,-those for the protection of shipping, Figs. 1189 to 1192, are likewise noticed, as probably providing for the most complicated cases that are likely to occur in the most extreme cases on land. Digitized by Google ELECTRICITY. 417 Fig. 1184, the mode of joining two lengths of copper tube ab by means of a double screw c with a shouldered collar d. Fig. 1185, the staple a, by which the conductor is supported at the joints and fixed to the wall. Fig. 1186, the head of the conductor. Fig. 1187, conductor complete, showing the lower termination a a a as buried in the ground. or re- ceived in water. Fig. 1188, application of conductors; the points 1184. 1188. abcde, &c., connected by bands of metal dt b k, &c., into one general whole. 1185. Fig. 1189, ships' conductors, consisting of two strips of sheet-copper, from 1.5 to 5 inches n wide, and from 1-8th to 1-16th inch thick, in 1186. lengths of 4 feet. They are let double into a d groove in the mast, 80 as to insure continuity of conduction by breaking joint, as shown in the figure: these strips are kept in thorough con- tact, and are secured to the mast by copper nails, 6 inches apart, in the drilled and countersunk 1189. holes a a. The upper surface of the upper piece 1187. A A is slightly rounded, so as to conform to the surface of the mast in transverse section. Fig. 1190, the cap a b and the hole b through which the moveable mast x slides, are furnished with similar plates; these are led from the square 1190. hole at a, by which the cap ab is fixed to the head of the mast D, into the round hole at b; 1192. and there is a lining of copper in this part of the hole next to the conductor at b, by which the D metallic line is continued to the next mast D. Figs. 1191, 1192, the bolts a passing through the ship, and in which the general line of conduction terminates, are clenched upon me- 1191. tallic rings and plates, in connection with the copper sheathing; and there are additional bands mn, Fig. 1191, leading from the fore-inast and mizen-mast directly to the stem or stern under A the decks; other bands gh, Fig. 1192, traverse the beams, and they all terminate in the sea by bolts clenched on the copper sheathing. Fig. 1192 is a section suited to the beams abaft each mast. Voltaic blasting.-The property of the electric current to raise the temperature of the metal through which it passes, has been turned to account in promoting the efficacy and lessening the danger of blast- ing on land and under water. Voltaic electricity is transmitted through a complete circuit, either wholly or in part of metallic wire, and such an arrangement is adopted that a small portion of the circuit may be rendered red-hot within the powder composing the charge. The object is attained by employing a voltaic battery of sufficient intensity to heat a short length of fine steel or platinum wire fixed across the disconnected ends of the conducting wires within the powder. Upon the area of the section of the conducting wires and the intensity of the battery, depends the power of the electric current to travel the required distance and produce the proper effect. The principle of voltaic action may be thus stated let Fig. 1194 be a glass vessel containing a liquid and a plate of copper C connected with a plate of zinc z, constituting a pair of a voltaic pile. When the liquid is water alone, there is scarcely any electrical action. When salt is added, the ac- tion becomes evident; but when sulphuric acid is added, it is very greatly increased a decomposition of the fluid in this case takes place; the oxygen is taken up by the zinc, which has the greater affinity for oxygen, and is therefore called the positive metal; the hydrogen is evolved at the negative metal, copper. A current of electricity is thus generated. Several positive and negative plates immersed in an acid solution, and connected one with the other in a series, constitute a voltaic battery, which is more or less intense, according to the number of plates. Various forms have been given to the voltaic battery, and modifications made from time to time, ac- cording to the purposes to which it was to be applied. Description of batteries that may be employed in blasting.-The common copper and zinc plate bat- tery may be thus described. The pairs or sets of plates composing the series are each composed of a zinc plate 3-16th inch thick in the centre of a rectangular case of sheet-copper, without top or bottom, a convenient size for which may be 10 inches long, 1f inch wide, and 8 inches deep. The zinc plates must be about 4 inch shorter than the copper case, so that the edges of the metals may not be in con- tact: two slips of wood with grooves in them should be fixed, one down the inside of each end of the copper case, and nailed by small copper nails: the zinc plates will then slide up and down in these grooves, which will be found convenient in withdrawing them for cleaning, and will keep them separate from the copper. The connections may be formed by bands or strips of stout sheet-copper 1 to 4 inch wide, riveted to the zinc plate, and soldered to the copper case: there should be two connections to each set of plates, fixed at a few inches from their ends. Binding-screws should be used for connecting the strips of metal in sequence above the plates thus: let the 1st zinc form the terminal plate or nega- 43 Digitized by Google 418 ELECTRICITY. tive pole of the battery: this must be disconnected from any other the two strips of metal on the 1st copper case will then be turned over, and connected with the two on the 2d zinc plate, the two on the 2d copper with the two on the 3d zinc, the two on the 3d copper with the two on the 4th zinc, and 80 on up to a series of ten or twelve, which will be found sufficient for any common mining purposes. The last copper case will then be found to stand free as a terminal plate or positive pole. Two stout cop- per wires, let into these terminal plates, will form the poles, on connecting which the circuit is complete. The sets of plates must all be let into a stout frame 2 inches X 11 inch, for the purpose of immersing the whole simultaneously into the trough or cells containing the acidulated solution, which should con- sist of dilute sulphuric acid, in the proportion of 1 of acid to 10 or 12 of water. This trough should be either of oak or elm baked, as it then becomes a very imperfect conductor of electricity. There must be as many cells as sets of plates, which should be from 11 inch to 2 inches wide, and 9 inches deep. The partitions separating them should be about f inch thick; the whole made water-tight by being coated with a cement, for which the following ingredients have been found by trial to answer the best, viz.: Spirits of wine I gal. Gum Sandarach 2 OZ. Shell-lac 1 lb. Vermilion t lb. The above quantities and proportions will be found sufficient for covering the inside of the trough of a battery of 10 cells with 2 coats, containing about 23 superficial feet each. The partitions to the cells are necessary in a battery of this form, to keep each set of plates separate, otherwise the fluid acting as a conductor would cause a cross play of electricity between every positive and negative plate in metallic connection, and much power would be lost. In lieu of the connections by bands or strips of sheet-copper, a convenient form of uniting the copper case and zinc plate will be by leaving a tongue or flap projecting from one of the upper edges of the former, and extending its whole length, sufficiently broad to be turned over at right angles, and again bent upwards 80 as to come in contact with the adjoining zinc plate the whole of the upper edges of the two metals will thus be in metallic contact, by which increased contact some additional power will be gained: in this arrangement the zinc plate must stand higher than the copper case by about the of an inch, so that the flap of copper may be quite clear of the case next to it: the end or terminal plates may be finished with triangular flaps, and the wires for forming the poles may be connected to the apex of each triangle. This constitutes a common plate battery, which, for mining operations, will be found sufficiently pow- erful from the very short time required to keep it in action for heating platinum wire. But it has many defects. The acid speedily becomes saturated with oxide of zinc, by which its conducting power is reduced. The hydrogen which is set free at the negative copper plate adheres with great tenacity to its surface, and throws a considerable portion out of action: it reduces the zinc from the solution, and deposites it on the copper plate, by which a zinc plate is virtually opposed to a zinc, and a counter- action is thus produced; and in addition to this, the zinc of commerce, being exceedingly impure, con- tains many particles of foreign matter which unite in consuming the zinc, and in causing what is called local action this latter evil is however somewhat obviated by the amalgamation of the zinc plates with mercury. Daniell's battery.-A single cell of this battery consists of a copper cylinder, an amalgamated zinc rod, and a porous diaphragm, which may be composed of various materials, such as paper, plaster of Paris, sail-cloth, porous earth, or animal membrane. In this arrangement two fluids are used, separated by the diaphragm, containing dilute sulphuric acid in the proportion of 1 of acid to 8 of water, in which the zinc rod is immersed on the outside of the diaphragm, next the copper cylinder, is a saturated so- lution of sulphate of copper, containing a little sulphuric acid binding-screws and stout wires are used to connect the respective metals with each other. The zinc being well amalgamated, and the apparatus in perfect order, no electrical action will take place until the circuit is completed by the wires, when it will be indicated by a sharp and clear spark emitted at the poles: this action, however, takes place without the evolution of hydrogen at the negative metal; in lieu of this, copper will be released from its sulphate, and deposited on the copper cylinder; the strength of the solution must therefore be kept up by a supply of the crystals of the sulphate of copper, which should be continually dropped in for the purpose of being dissolved. The advantages of this arrangement are, that the hydrogen, not being evolved at the copper cylinder, the formation of the film or coating of this gas is avoided, which has been shown to be so prejudicial to constancy of action in common plate batteries: on the contrary, a deposite of pure copper is formed, and the deposition of zinc upon the copper is avoided. The limits of the duration of the action are, the exhaustion of the copper solution, and the saturation of the acid solu- tion within the diaphragm, joined to the consumption of zinc. The action may be prolonged for a very long period, (8 or 10 hours.) Zinc and iron plate battery.-Within the last few years, iron has been much used as the negative metal for plate batteries. Its being more economical than copper was probably the principal reason for its being first adopted, but it is also superior in other respects. When the battery is in action, the hydrogen of the decomposed fluid does not adhere to the surface of iron as it does to copper, which has already been shown to cause great loss of power. The arrangement of a battery of this form would be similar to the common one, viz. a single zinc between two iron plates: ten or twelve of these sets would be sufficient for a battery for common pur- poses. The iron plates should be cast as thin as possible, to diminish the weight; 3-16ths of an inch is a good thickness. The connections of the battery may be formed by strips or bands of sheet copper, 1 to 1 inch wide, riveted to the iron and zinc plates, one on each of the former, and two on the latter, connected by binding-screws: to observe regularity in forming the connections down the series, and to avoid confusion, the width of the battery should be divided into five equal parts; then the connections of the first set of plates may be riveted to them, at the first and third divisions; of the second Digitized by Google ELECTRICITY. 419 the second and fourth divisions; of the third, at the first and third; and so on alternately this will preserve regularity, and keep all connections clear of each other. This difference in connecting the cop- per and iron plate batteries is caused by the former being one single case, the latter two separate plates, each of which has to be connected to its adjacent zinc. A convenient dimension for the plates will be about 10" X 8"; they should all slide in grooves, cut out of upright pieces of wood let into the frame: any plate may thus readily be withdrawn, if required. The plates should be supported by leaving about 1 an inch at the bottom of each groove solid or uncut, which will form a shoulder for them to rest upon, and they will thus be about 1 an inch clear of the bottom of the trough. The acid solution should be of the same strength as for the copper plate battery already mentioned. The dimensions of the trough for a battery of ten sets of plates will be about 2' 2" X l' 1" X 10", each cell being 111 inches long, 2 inches broad, and 9 inches deep. A plate battery should always be raised or suspended above its trough when not in action, to allow the acid solution to drip from the plates into the trough; and this may be done in various ways, either by having ends or handles projecting beyond the frame for lifting the battery in and out, or by stand- ards attached to the ends of the trough, carrying a windlass, with handles for winding the battery up and down by means of a cord attached to each end of the frame; and which may be rendered still easier to work, by having weights to counterbalance the battery suspended over small pulleys on the standards; or, lastly, by having a cog-wheel and rack inserted in each end of the frame, with handles for turning the wheels. A plan for constructing the iron and zinc battery has lately been adopted in Scotland, which possesses some advantages over the one above described, in which the trough is simply a box without partitions: a battery on this principle becomes very compact, as the plates may be much closer to each other than in any other arrangement: the action of both sides of the plates is also thus obtained. In this construc- tion the zinc and iron plates are placed alternately, in lieu of having one of the former between every two of the latter: supposing the series to commence with iron, let the first and second iron plates be connected together as a double terminal plate, with a wire attached to form the positive end or pole; then join the first zinc and third iron, the second zinc and the fourth iron, the third zinc and the fifth iron, and so on to the end of the series, which may consist of twenty plates of zinc and twenty-one of iron; then it will be found that the twentieth or last zinc will be disconnected from any other, and a wire attached to this will form the negative end or pole. In this construction the plates may be very close to each other, about t of an inch apart; they should be separated by slips of wood of this thickness, placed between each plate, the whole being kept to- gether by two pieces of board at the ends, connected by cross-bars at the sides, and with one at the bottom to prevent the plates from falling out: this arrangement will be found simple and expeditious, and therefore well calculated for common blasting operations. The partitions in the trough may be dis- pensed with, because by the method of connection, two plates intervene between every pair in metallic connection; there is thus no cross play of electricity. The action of both sides of the plates is also thus obtained. A battery of twenty pairs, or of forty-one single plates, may be readily got into a space of 20 inches in length, or even less. This last mode of arrangement is recommended for blasting operations in the field, from its compact- ness and simplicity of construction: the power of a battery of this form would be about on an equality with one of a similar number of plates on the common principle, and a single battery would be sufficient - to fire charges at the distance of 500 feet if more power should be required, then two of them may be combined. Grove's battery.-Its peculiarity consists in the use of two acids-concentrated nitric and dilute sul- phuric or muriatic the former is contained in an inner porous cell in contact with platinum, the nega- tive metal; the latter in an outer vessel with zinc, the positive metal. As soon as the electric current is established by completion of the circuit, both acids are decomposed; the hydrogen of the muriatic unites with the oxygen of the nitric, and the chlorine attacks the zinc. The hydrogen is thus removed without being evolved at the negative plate. This battery is remarkable for its power: a series of four cells in good order will give a cubic inch of mixed gases per minute for every square inch of platinum in each cell, and all the other effects in pro- portion. It has also the advantage of occupying very little space. It is remarkably constant, and, from its great intensity, very economical, as a smaller series may be employed than in any of the other com- binations. For mining and blasting operations on a large scale, its great intensity would make it valuable, par- ticularly in firing a number of charges simultaneously; but for common purposes of this kind it would perhaps not be 80 practically useful as the simpler form of the zinc and iron battery already mentioned, the porous cells being fragile and delicate, and the nitric acid destructive to clothing. Smee's battery.-Another battery of great practical utility has also been invented by Mr. Smee, who has taken advantage of the property which roughened surfaces possess of evolving the hydrogen, by covering the negative element, either silver or platinum, (generally the former for practical purposes,) with the finely divided black powder of platinum it is not, however, considered necessary to enter more fully into the construction of this battery. The relative power of batteries is indicated by the number of degrees of deflection of the galvanometer. The principles of several kinds of batteries which may be usefully employed in blasting having been given, it should be again remarked that the cast-iron and zinc battery will be found the most practically useful, and the simplest form will be that in which the zinc and iron plates are placed alternately, and the action of both their sides is obtained; the trough being simply a box, without being divided into cells. Of the conducting wire to be used in blasting.-The best conducting wire consists of several fine copper wires twisted together like a hempen rope: as it is very flexible, less liable to break than a solid wire Digitized by Google 420 ELECTRICITY. of equal dimensions, and the junctions of the several lengths may be very securely united by splicing, as in a common rope. The conducting power of wires varies with their thickness, or with the area of their section this should not be less than one-fifth or one-sixth inch in diameter, and in forming the wire- rope as many fine wires must be twisted together as will make up this size. During the operations on the wreck of the Royal George, the wire-rope was prepared in the rope-house at Portsmouth Dockyard, out of wire 1-10th inch in diameter, or No. 14 gage; three strands or threads being a little more than equivalent in area to one solid wire one-sixth inch in diameter: 30 lbs. in weight of this size, or 1000 feet in length, made 300 feet of conducting wire when completed. To insulate the two conducting wires from each other,-which for the sake of convenience and porta- bility should, in land operations, be laid close together, 80 as to form, as it were, one rope,-they must be carefully coated with a water-proof composition, and then bound over with layers of tape, twine, &c., making them, when thus prepared, about fth inch in thickness. The composition which has been hitherto generally used for this purpose consists of beeswax, pitch, and tallow, in the proportion of 8 pints of pitch to 1 of each of the other ingredients, laid on while hot. In forming conducting wires, they have hitherto generally been separated or insulated by being laid on each side of a 4-inch rope placed between them. This rope may, however, be dispensed with, and for land operations, the wires having been carefully coated in the manner described, may be laid close together, side by side, and then bound over or connected by coarse tape or twine. The double conduct- or thus becomes small and of convenient size. For subaqueous operations, in using a double wire it will be better that the two wires thus prepared should be employed separately or singly rather than joined together as one; for, in working under wa- ter, much inconvenience and loss of power result from the covering becoming gradually worn off by damp and friction, leaving the wires exposed in one or more places and in contact with the water, and failures are frequently caused from the wires being brought together at an improper place, causing the circuit to be completed before arriving at the charge. The two separate single lines may each be con- nected to one of the priming wires of the charge at one end, and to the poles of the battery at the other, and a large space left between them intermediately; then all risk of a failure from improper metallic contact would be obviated. But in subaqueous operations, a complete metallic circuit is not required a portion of one of the con- ducting wires may be dispensed with, and the depth of water intervening between the charge at the bottom and the surface of the sea or other piece of water in which the operations are being carried on, may be used for completing the circuit. In this case, on account of water being a more imperfect con- ductor than that portion of the wire for which it is substituted, it becomes necessary to use a larger surface of metal at each extremity of the water conductor, that is to say, (in the case of submarine oper- ations,) at the bottom and surface of the sea, to lead the electric fluid through it. At Spithead, in the summer of 1843, we used zinc plates at the surface, and the case of tin or iron in which the charge was usually contained served as the metal required at the bottom. At the depth of 18 fathoms it was as- certained that about 3 square feet of surface of the zinc or positive metal was required, but in respect to the other, or negative metal, a much smaller surface was apparently sufficient. This surface of zinc should be divided into three or more plates, connected with each other and suspended from a copper wire passed through a hole in the top of each plate, and immersed into the water at the surface the other end of this wire goes to the battery. The long single wire extending from the battery to the charge is connected to one of the priming or short wires inserted in the bursting tube, and the other priming wire is turned down on the metallic surface of the case enclosing the charge, and connected with it. The charge having been taken down by a diver, and placed in its proper position at the bot- tom, the ends of the long single wire above water, and of the short length attached to the plates, are led to the voltaic battery on forming contact at which, the intercepted portion of the circuit from the zinc plates at the top to the metal case at the bottom of the sea is completed by the depth of water between them the electric current is thus passed through the piece of fine platinum wire fixed across the priming wires of the bursting charge, which also forms a part of the circuit, and is instantaneously ignited. This method will serve when the charge is contained in a vessel of tin, iron, &c.; but in the case of wooden casks it would be necessary to attach a sheet of tin or copper to the surfaces of the cask, to which the second priming wire would be attached. Description of the charges usually employed in voltaic blasting.-It has already been stated that igni- tion is communicated to the charge by having a small portion of the circuit within the powder composed of fine steel or platinum wire, (about 1 inch in length,) which, being made red-hot during the transmis- sion of the voltaic current, fires the charge as soon as contact is made at the battery. From the rapidity with which the fine wire is fuzed, it is necessary that the powder immediately in contact with it should be of a finer quality and more thoroughly dried than the main body of powder composing the charge. On this account, and for the sake of convenience in attaching the main or con- ducting wires, it is usual to have small bursting charges, or cartridges, holding a few ounces of the finest sporting powder, (their size varying according to that of the mass of powder to be ignited,) which should be thoroughly dried by being placed and shaken on a plate which has been moderately heated at the fire. These bursting charges may be contained in cylinders or cases of tin or paper; if in the former, great care is required to prevent the wires within the case from touching the tin, on account of its being a conductor. For land operations, it will merely be necessary to close the top and bottom of the burst- ing charge with bungs of cork; before fixing which, the priming wires (so called to distinguish them from the main or conducting wires) should be introduced, from a foot to 18 inches long, the ends pro- jecting 9 or 12 inches from the top of the case, the ends within it passing through grooves cut into the sides of the upper cork, and clenched against a thin piece of wood near the bottom of the bursting charge, but not occupying the whole of its interior space. The platinum wire should be fixed across the copper wires about the centre of the bursting charge, which should then be filled from the bottom with the finest sporting powder, and closed by the lower bung of cork. The top and bottom of the Digitized by Google ELECTRICITY. 421 bursting charge should then be sealed with any good cement, which does not crack in cooling, and will keep out damp. In firing a mine on land, it will be necessary to place a bursting charge, prepared as above, in the centre of the mass of powder to be ignited; the ends of the main conducting wires must then be con- nected with those of its priming wires by placing a few inches of each, side by side, and frapping round them with fine bell-wire, and then covering them with tape dipped in water-proof composition. The length of the conducting wire must of course vary according to the nature of the mass to be removed by the explosion, the splinters from which, if of rock, might endanger the operator at the battery, unless at a considerable distance from the charge. In mining operations on a moderate scale, a length of from 300 to 500 feet will generally be found sufficient for conducting wires, and for which the battery of ten sets of plates will possess sufficient energy. Contact may then be made at the battery by hand and from the rapidity with which electricity travels, the firing of the mine takes place at the instant the cir- cuit is completed: should it be feared, however, that at this distance splinters might injure the person firing, a self-acting apparatus may easily be contrived by which he may retire to a place of safety, after having made the arrangements at the battery to insure the circuit being completed a minute or two after he has left it. Such a self-acting apparatus may be formed by means of mercury in a cup or vessel, having one end of the conducting wire dipped into it while the pole of the battery to which it is to be connected is suspended above it, and held by a string; (the end of the other conducting wire and pole of the battery having been previously connected.) If such an arrangement therefore is adopted as to cause this string to be burned asunder in a given interval after the operator has left the battery, so that the pole of the battery may drop into the same cup of mercury as that in which the end of the conducting wire to which it is to be connected is already immersed, the object is gained; for by means of mercury as good a connection is formed as if the ends of the wires actually touched each other. Another method by the agency of mercury has been recommended by Professor O'Shaughnessy, thus. Fig. 1193 c c'. Conducting wires. P W. Platinum wire. 1193. pp'. Poles of battery B. e. V. Vessel filled with mercury, and with a cock at bottom for emptying it: the conducting wires c c' pass through holes in the sides of the vessel. As long as the vessel is full, the circuit of the conducting wires will be completed by the mercury, and the electric current will thus be stopped from passing through the piece of platinum wire, P W; but on opening the cock below, the mercury will descend, and as soon as a sufficient quantity has run out to leave the conducting wires clear, the current will no longer be stopped, but will pass through the secondary wire P W and ignite it. Therefore a sufficient quantity of mercury should be left above the level of wires c' to allow a person time to get out of danger, after having turned the cock and made the arrangements for firing the charge. In preparing the blasts for being fired by the voltaic battery, wooden cones may be used immediately above the charge; the priming wires should be let through a groove cut on each side of the cone, their ends turned down on the bottom of it, and connected by a piece of fine platinum wire from 1 inch to 11 inch long. If in a dry soil, the powder may then be enclosed in a canvas bag, tied round a projecting collar on the bottom cone; the come and the charge with its priming wires may thus be let down to the bottom of the hole, and the tamping of broken stone made over it. The priming wires will, of course, vary in length according to the depth of hole; they should project about 12 inches above the top of it, and the conducting wires may then be connected to them, as above described. If in a damp or wet situation, the bag must be coated and made water-proof, or the charge may be contained in a case of brown paper or pasteboard, pitched over. For mines of a moderate size, which do not contain more than from 50 to 200 pounds of powder, the bursting charges may be small; the cartridge being altogether about 4 inches long and 1 inch in diameter, and holding about'l ounce of fine powder. In operations on a larger scale, these secondary charges may be proportionably increased in size, and even two may be used on each conducting wire, to be fired simultaneously, so as to ignite a large mass of powder in two places at the same instant: this was successfully adopted in firing the great mines at the Round Down Cliff, Dover, in January, 1843, where for the three charges (two of 5,500 pounds, and one of 7,500 pounds) there were two bursting charges on each conducting wire, 9 inches long and 2 inches diameter, which were extended to a distance of about 3 feet apart in the chambers, and buried in the centre tier of loose powder. In this operation the powder was contained in loose bags, holding about 50 pounds each, the mouths left open, and uppermost in the. tiers below the centre, while those above it had the mouths downwards the interstices were filled in with loose powder. This will be found a convenient mode of charging mines, and will insure the ignition of the whole of the powder when in large masses. On the preparation of charges for subaqueous operations.-The preparation of these charges requires the greatest care, particularly when the operations are carried on at any great depth. In working against a wreck, the general system will be to employ large charges at first to break it up into detached masses, which if necessary may again be subdivided by using charges of a smaller size, until at length very small quantities of powder will be sufficient to break up or detach the pieces still remaining. Hence the sizes of the charges will vary according to the objects for which they are required. For containing the larger charges, which are supposed not to exceed 600 or 700 pounds, wine or spirit casks will be found convenient and economical; and if the depth does not exceed 30 or 40 feet, they need not be stronger than those commonly used in the navy, excepting that the heads will require some additional 8 curity, as being the part most liable to be forced in by the pressure of the water. Digitized by Google 422 ELECTRICITY. Beyond that depth, however, the whole cask should be more strongly made than would be usual for common purposes. A convenient size of cask for the larger charges will be the 72-gallon puncheon; for the medium size, the 18-gallon cask; and for the small ones, tin cans or oil-bottles, of sizes varying from 2 to 5 gallons. The puncheon for the larger charges, when sunk to depths of from 10 to 12 or 13 fathoms, should be prepared as shown in Figs. 1228 to 1230; the body or staves to be 11 inch thick, and the heads formed in two thicknesses of 11 inch each, the lower one placed transversely to the upper, and resting on a circular groove or shoulder cut out all round the inside of the ends of the staves, equal in depth to about half their thickness. This lower head should be additionally secured, both at top and bottom, against external pressure, by the support of four cleats, to be let at equal distances round the circle about 1 inch into the thickness of the body. The upper head should be fixed close over the lower one, and secured to it by strong 3-inch screws; it should come flush with the outside of the cask, and a broad iron hoop passed round outside the top and bottom, screwed to each of the heads, will secure and connect the whole firmly together. Where these or similar precautions are not adopted, there will be every probability of the heads being forced in by the pressure of water above, which, on a head 2 feet in diameter, at the depth of 13 fathoms, would be about 7 tons. In altering common puncheons for subaqueous explosions, it would be necessary to saw off so much of the top and bottom as would include the triangular groove or mortise into which the common form of head is usually let; then the rebate or shoulder for the new head should be commenced from that level. The most difficult and troublesome part of the operation will be that of making the cask water-proof; for when sunk to a great depth, the pressure of the water would cause it to penetrate at the most minute hole or imperfection in the covering. The cask is first to be payed over with a coat of the composition above mentioned, consisting of beeswax, pitch, and tallow, which will fill up the pores of the wood, and, with the addition of strips of canvas laid between the hoops, will bring the whole surface level, and prevent their edges from chafing the coats of canvas to be next laid on, which should consist of strips (No. 6, good old worn canvas will do) laid on lengthwise, from end to end, having been pre- viously coated with composition on the under side only; the ends, projecting 5 or 6 inches beyond those of the cask, should be notched for the purpose of folding or plaiting down upon the circular heads: the joints of the canvas should not lap over each other, but merely touch; 5-inch slips are to be laid over each joint previous to the second coating, in which the canvas should be laid in a transverse direction to the first, encircling the cask with one joint round the centre or bung diameter, and projecting 4 inches over the ends, which projections should be notched and plaited down on the heads as before. A 5-inch strip must then be laid over the central meeting-joint, and each head covered with a circular piece equal to its own diameter. In both first and second coats, the composition should be laid on the under side of the canvas only, and drawn through to the upper one by a hot flat iron; by this means the interstices and pores of the canvas are entirely filled, and made water-proof. A coating of the composition should also be put over the whole on completion When in this state, the puncheon should be lowered empty to the depth at which the charge is intended to be fired, and kept there half an hour, in order to test its strength and water-proof qualities; and if proper precautions have been taken, the cask will not admit the smallest particle of water. In lowering, it will be necessary to protect the canvas covering from friction of the slings in which it is held, by fixing six or eight staves of casks tightly round the outside, lashing them at equal distances by yarn, for the reception of which grooves should be cut in the staves, about 2 inches wide and I inch deep, at about 6 inches from each end. The slings may then be passed over the staves, and kept quite clear of the water-proof covering, and they should also be connected by rope-yarn to keep them from slipping. After the cask has been drawn up, if found to be water-tight, it will be ready for loading and for the insertion of the bursting tube, which may be conveniently formed out of lead pipe, with the bottom closed, and a circular collar or flange formed on the top, projecting about } inch, for the purpose of nailing on to the cask. The length of the tube should be a little more than half the bung diameter, so as to enter the cask to about half its depth. For the 72-gallon puncheon a convenient size of tube will be l' 6" long and 2 inches diameter; and for the 18-gallon cask, 12 inches long and If inch diameter: a circular hole must be cut out of the cask, at its bung diameter, of sufficient size to receive the tube which will be inserted, and the projecting collar nailed down on the surface by small clout- nails. The operation of loading may then be commenced; the loading hole will be cut out of the centre of one of the heads, tapering from the top to the bottom, where it should be about 2 inches diameter; a cleat 20 inches long and 4 inches broad having been previously nailed on over the centre of the head, which will thus make the thickness of wood at the loading hole about 31 inches. The puncheon should be filled by inverting the small powder-barrels over the loading hole. As each barrelful is poured in, the puncheon must be continually shaken, in order that the powder may be properly distributed over the whole surface, and it should at the same time be rammed by a copper rammer. Nearly 10 pounds of I owder per gallon may thus be got into the puncheon. As soon as it is full, a small wooden plug, about an inch thick, should be dropped into the bottom of the loading hole, and the water-proof compo- sition poured in above it, until nearly on a level with the top of the upper surface of the head. The remainder of the hole within the cleat will then be closed by a dovetailed wooden plug, with a circular head projecting about 1 inch all round, firmly driven in with composition, and just entering the upper part of that already poured in; the whole should then be carefully payed over with the same. The preparation of the bursting charge will be similar in principle to that described for land operations, though differing somewhat as to its details. It is shown in Figs. 1227, 1228, 1231, 1232, 1233, where 1232 and 1233 represent a collar and plug, turned out of oak, elm, or beach. The collar is for closing the top of the tube, into which its lower half should enter about half an inch, being made a little smaller than the diameter of the tube, while the upper half lies on the surface of the cask, consisting of a flanch or shoulder projecting half an inch all round. A circular hole is left in the centre of the collar, about 11 Digitized by Google ELECTRICITY. 425 inch diameter, through which the two priming wires pass, and their ends are received by the plug below, which should be of a cylindrical form, varying in size according to that of the bursting charge. For the 2-inch tube the plug should be about 11 inch diameter and 7 inches long, with two grooves I inch square, cut in it opposite to each other, in which the wires are laid. The lower part of the plug should swell out about half an inch for 1 inch in length, to give a projection for attaching the mouth of the canvas bag containing the bursting powder. The ends of the priming wires are turned up and flattened against that of the plug, and nailed to it with small copper nails. Two pieces of fine platinum wire are then to be laid across the ends in small notches previously cut into them with a chisel, which should be closed and hammered lightly down over the fine wire to retain it in place. This operation requires great care from the delicacy of the platinum wire, two pieces of which are used as a precaution in the event of one breaking. By means of the plug the priming wires will be kept firmly in their position, and not be liable to move, which might cause a fracture in the fine wire connecting their ends. The end of the plug should have a circular hole left in it, on each side of which the flattened ends of the priming wires will lie, and being filled with fine powder in contact with the platinum wire, the ignition of the latter and of the bursting charges will be insured. The canvas bag containing it will be about 7 inches long, occupying the remaining length of the lead tube, and the vacant spaces round the sides and bottom should then be filled with the composition, and circular layers of canvas, well coated and payed over with the same, passed over the collar to cover the joint between it and the surface of the cask, and carried up a few inches on the priming wires above the collar. The ends of these wires should project about a foot beyond the top of the tube for connecting with the conducting wires, carefully insulated with tape, yarn, and composition, as above described. In order to relieve the junction of the priming and conducting wires from all strain, they should, when connected, be turned down upon the surface of the cask, and fixed there by a lashing of rope-yarn, passed round it. In working in a tide-way, or in a heavy sea, the strain would sometimes be considerable, and might be sufficient to cause the separation or derangement of the wires, unless this precaution were adopted. It may here be stated, that by having a bursting tube, the risk of the whole of the powder being spoiled in the event of the cask leaking, is obviated; for as the water, if it penetrated at all, would most probably find its way through at the joint which must necessarily be left round the collar and tube, and for securing which the greatest precautions should be taken, the powder contained in the small charge only would, in such a case, be damaged, the main body of powder still remaining dry and fit for use; the cask would therefore, in the event of a failure from this cause, have to be drawn up again, and a fresh bursting charge inserted. In lowering a cask containing a charge of the larger size (650 pounds) to be fired against a wreck, a small tackle must first be used to raise it from the deck of the vessel in which the operations are being carried on. After it is in the water it will be so well supported as only to require a line passed round a bollard, and attached to the slings to lower away upon gently. To the end of this line a buoy should be attached, to be thrown into the water for marking the position of the charge, so that on heaving the vessel or vessels out of the way, they may be placed at a proper distance. Previous to the explosion, in working at a depth of 13 fathoms, a horizontal distance of 80 to 100 feet will be sufficient for safety in firing the larger charges, and about one-half that distance in firing the medium ones, while for charges not exceeding 50 or 60 pounds, the vessels need not be moved away at all, but may remain immediately over them. It should be remembered, however, that the effects will be much greater when working at less depths, and the distances should be increased accordingly. The 72-gallon puncheon will, when filled with powder, require a weight of 4 or 5 cwt. to sink it, which may be conveniently given by attaching canvas bags filled with ballast, weighing about 1 cwt. each. The description given for the preparation of bursting charges for casks will hold good for any description or size of charge, the rule being that the bursting charge should be equal in length to half the diameter of the vessel containing the powder; and the size of the collars, plugs, and canvas bags will therefore be varied according to that of the main charge. Where the diameter of the plug becomes small, as in the case of bursting charges for tin cases, its end should be cut obliquely, 80 as to offer n greater surface for receiving the flattened ends of the priming wires, and to insure a length of 1 inch of platinum wire, which should be its minimum length. For the tin cans, tubes of the same metal should be used for the bursting charges, soldered into the cans, at about the centre of their height. It may be remarked, that in working at such depths as 12 or 13 fathoms, the depth or height of water above the charge becomes a very efficient tamping, and a considerable effect will be produced where charges are merely laid on the surface at the bottom, for the purpose of forming a hole or crater below them, which would be frequently required where the timber or other material to be removed is buried in a mass of mud or shingle, which there is no other means of dispersing. On firing a number of charges simultaneously.-This operation will be found of great use on land, as well as in working under water, and more particularly in blasting rock in quarrying, where it is fre- quently an object to throw down a long face of stone, and where a much greater effect may be produced by the judicious disposition of several small charges in line with each other, than if the whole of the powder were concentrated in one mass. The simplest and most economical mode of firing several small charges or blasts on land, will be to have a main conductor consisting of the double insulated wire laid parallel to the blast-holes, but several feet in rear of the face intended to be thrown down, so that the wires may not be injured by the fragments falling after the explosion. To this main conductor will be attached at the several intervals branch wires leading to the charges, its end being used for connecting with the extreme charge. The connections should be very carefully formed by opening the main wires at each point, and attaching the ends of the branch wires either by means of bell-wire or binding-screws, (the latter mode will be most expeditious,) and taking care that the wires are well cleaned and brightened at the several points of connection. At short intervals of 10 or 12 feet, and with branches, which for small blasts need not exceed 20 feet in length, a battery of moderate power would be sufficient for firing eight or ten charges simultaneously; but it will be prudent in the first instance to fire a set of small cartridges in the same positions as those Digitized by Google 424 ELECTRICITY. of the intended charges, to ascertain the requisite strength of battery, which may be increased to any sufficient amount by combining two or three together. It is believed, however, that when the length of the main conductor does not exceed 400 feet, and of the branches 20 or 30 feet, two batteries of ten sets of plates each will be sufficient for a number of charges not exceeding ten or twelve. By this mode of arrangement the charges may all be said to be fired at the same instant. Several interesting experi- ments have been tried on this subject, which prove that each secondary wire becomes ignited, as it were, at the same moment of time, and that no part of the effect is dependent upon their being consecutively broken, as has been supposed; also that in the case of the non-ignition of one of the secondary wires, (which might happen if the powder in one of the charges were accidentally damp,) yet all the others would be ignited and their charges fired as usual. Again, if improper metallic contact of the copper wires exists anywhere, either in the conductor or branches, the electric fluid would be stopped from passing through any of the charges, but would return to the battery from the point of improper contact without any effect; hence the greatest care will be required in connecting, to keep all main wires clear of each other. The above description applies chiefly to cases of common blasting, where the length of the branches and their distances apart on the main wire would be small; but in operations on a larger scale, where it may be necessary from local circumstances to have a great length of wire communicating with each charge, it would be imprudent to attempt firing several charges simultaneously by a single combination of batteries. A safer plan will be to have a battery for every two charges, or in some cases it might even be better to have one for every charge; the circuit being completed either by hand or mechanically by the mercurial igniter already noticed. In forming the simultaneous contact of a number of separate wires, the mercurial igniter will be found very convenient, which should consist of two parts. A stand or stool, about 18 inches high, with a front frame containing as many cups or receptacles for mercury as there are wires, and an arm or cross-piece hinged to the back of the stand, with a corresponding number of short pieces of stout copper wire let into it, and suspended over the frame in such a manner that on being let down each piece of wire will enter a cup of mercury below it; one pole of each battery, and the end of one side of each conducting wire, being then connected to each other either by screws or bell-wire. The second pole of the battery may be let into a mercury cup, and fixed there, while the other end of the conductor to which it is to be connected will be attached to the piece of copper in the arm immediately above it. The same arrange- ment being made for all the wires and batteries, it will only remain to let the arm fall down upon the cups, when, the circuit being completed at the same instant by the upper wires entering the mercury, the whole of the charges will be simultaneously fired. Before attaching bursting charges to a conductor, it will be essential to prove that the circuit is complete, and the platinum wire perfect; for being extremely delicate, this secondary wire is occasionally liable to be broken in spite of all precaution. The readiest mode of doing so will be by means of the instrument called the "galvanometer," the principle of which is founded on the well-known influence of voltaic electricity on the magnetic needle. Another mode of proving the completeness of a circuit by means of the water-test apparatus," or the power of the electric circuit to decompose water, may also be used, but it will require a more powerful battery, and not be 80 quickly performed as by the galvanometer, by which 100 cartridges may be proved in less than half an hour. In carrying on operations of this kind, it will also be occasionally useful and interesting to try the relative power of different kinds of batteries and lengths of wire, for which purpose the voltameter or decomposition apparatus may be employed, which is constructed 80 as to measure off the quantity of gas emitted when water is decomposed, and thus to indicate the amount of electricity passing in a circuit. There are various forms of voltameter, but the one most commonly employed, and which would give the most accurate results, is that in which the water (slightly acidulated) is contained in a glass vessel of moderate size, closed at the top, into or near the bottom of which are fixed two pieces of platinum wire about one-quarter of an inch apart. A glass tube, whose interior diameter may be half an inch, graduated to cubic inches and parts, is supported over these poles, entering the water to some depth. The tube being also filled by inverting the vessel, the mixed gases will be collected in it on connecting the ends of the wires or poles of the battery with those of the voltameter, and by keeping a record of the quantities of gas delivered per minute, or per half minute, using different kinds of batteries and lengths of conducting wire, we may arrive very nearly at the relative powers of the former, and the proportional resistances offered by the latter. Another form of voltameter is that in which two tubes are used over each pole, to collect the gases which may be evolved, separately or singly. Zinc and Copper Battery. Fig. 1194. Diagram of the galvanic principle. Fig. 1195. Isometrical view of a zinc plate and copper case, with a portion of the copper removed. Fig. 1196. Three sets of plates connected. Fig. 1197. Portion of a copper case and zinc plate on an enlarged scale, showing the connecting band and screw. Fig. 1198. Isometrical view of a battery of ten sets of plates connected. Fig. 1199. Trough containing the acidulated solution, in which the battery is immersed. h. Orifice for discharging the solution. Fig. 1200. Section of three sets of plates, showing a method of connection by leaving a tongue or flap projecting on one side of the copper case, to be turned up against the adjoining zinc plate, and connected with it. Digitized by Google ELECTRICITY. 425 Fig. 1201. Plan of ditto. ccc, show the projecting flaps. Fig. 1202. Clamp-screw to be used for this method of connection. Figs. 1195, 1196, 1198, and 1199, are on a scale 2's full size. Figs. 1197 and 1202 " " 1/8 a Figs. 1200 and 1201 « " 1 « T6 1196. 1194. 1195. 1204. c 2 1198. 1197. r 1200. c P of 06 1206. 1205. 1202. 1199. 1201. c 1203. Cast-iron and zinc battery of 10 cells, represented in Figs. 1203, 1204, 1205, and 1206. Fig. 1203. Plan of trough. Fig. 1204. Isometrical view of the battery raised above its trough. Figs. 1203 and 1204 are on a scale 1½ full size. 1211. 1210. 1207. the 1209. 1208. RG / Z z Fig. 1207. Isometrical view of battery of alternate plates of cast-iron and zinc, the trough without partitions. The battery is shown supported above the trough, by the wood pins pp, which are to be removed before lowering it. The plates are supported by a piece of board at the bottom, let into the ends of the frame, similar to the pieces 8 at the sides. The bottom piece is not seen in this view. 54 Digitized by Google 426 ELECTRICITY. Fig. 1208. Section showing nine of the plates on an enlarged scale, with the method of connection. The iron plates are shaded and marked ¿¹ is is, &c.; the zinc plates are marked 2' 23 z³, &c. Fig. 1210. Transverse section through A, Fig. 1203. c c. Circular orifices, t inch diameter, at the bottom of each partition, at contrary ends, for passing the fluid through the cells. Fig. 1211. Transverse section through C or D, Fig. 1204. 1217. 1213. 1218. 1214. 1212. 1215. 1216. 1219. 1222. 1220. 1221. 1923. Fig. 1212. Section through a 5-gallon tin can, holding about 50 pounds of powder, showing it prepared as a charge for submarine operations. 1. Loading-hole. b. Bursting charge. The priming wires are shown lashed to the handle and surface of can, so as to relieve the platinum wire within the bursting charge from all strain. Fig. 1213. Section through the bursting charge of Fig. 1212, showing the collar C, plug P, and canvas bag containing the powder. Figs. 1214 and 1215. Collar and plug for bursting charge, Fig. 1213, showing the neck of plug for tying round the canvas bag. Fig. 1216. Plan or end view of plug, showing the ends of the priming wires turned down against the surface, and the platinum wire lying across them. The spherical hole is left for being filled with fine powder in contact with the platinum wire. Fig. 1217. Pointed charge to be used in clearing away mud or soft ground. When forced down to about three-fourths of its depth, the effect of the explosion will be very great. Fig. 1218. A mode of lashing two cans together G 1224. to form one large charge, if required, with the method of connecting the two inside priming wires of each bursting charge, 80 that the platinum wires of both charges may be included in the same vol- taic circuit and fired together. This arrangement has answered well on several occasions. Fig. 1219. Section of a blast-hole in rock pre- pared for firing by the voltaic battery. The tamp- ing is formed by a cone of hard wood, to the bottom of which is attached the canvas bag holding the A powder, and the hole filled up with small broken B stone. Figs. 1220, 1221, and 1222. Section, plan, and elevation of a bursting charge or cartridge, to be used for voltaic operations on land, where the quan- tity of powder to be fired exceeds 200 or 300 pounds. A 1225. Fig. 1223. Small cartridge for experiments, and which may also be used for firing small mines. The cases of these may either be formed of tin or pasteboard; if the former, care must be taken to keep the wires from touching it. P 1226. Figs. 1212, 1217, and 1218, are on a scale 3/5 full size. Figs. 1213 to 1215, and 1219 to 1223, are on a P scale 1 full size. C Fig. 1216 is on a scale t full size Fig. 1224. The copper and zinc plates being im- mersed in water, and their surfaces connected by the wire w w, it will be found, on placing a gal- vanoineter G within the circuit, that a voltaic cur- Digitized by Google. ELECTRICITY. 427 rent of considerable intensity is passing through the water from the zinc to the copper, and returning by the wire. The distance between the copper and zinc plates may be considerable-a mile or more. Fig. 1225. Showing the method of firing submarine charges by a single wire, making the sea or other depth of water complete the circuit. The ends of wire A and B are led to a voltaic battery. Wire A goes to the negative or zinc pole. Wire B goes to the positive or iron (or copper) pole. pp'. Priming wires of bursting charge. C. Point of contact of priming wire p', with surface of charge, attached by a lashing of rope-yarn. The greatest length or depth of water-conductor known to have been used hitherto for firing charges in submarine operations does not exceed 100 feet, but it is presumed that the same principle may be extended to much greater depths. 1230. 1227. 1228. 1229. s 1233. & 1231. 1235. 1232. 1234. 2 Fig. 1227. Enlarged section of loading-hole. PP. Wood plugs. C. Composition. Fig. 1228. Longitudinal section through a 72-gallon puncheon, prepared for a submarine explosion by the voltaic battery, showing the double thickness of head with the loading-hole l through it, and the lead tube t for the bursting charge. Size of charge about 720 pounds. Fig. 1229. End view of head, showing the cleat and plug closing loading-hole, the staves 8 lashed round the surface to guard it from friction, and ballast bags to weight the charge in lowering it to the bottom. Fig. 1230. Side view of cask prepared for lowering, showing the slings, staves, &c. The priming wires are relieved from strain by being secured by the lashing round the cask at X. Fig. 1231. Section through bursting tube and charge on an enlarged scale, showing the collar, plug, canvas bag containing the powder, &c. The vacant spaces are filled with composition. The tube may be made of lead pipe, with a bottom soldered on and the top beaten out to form flanch for screwing to the cask. Fig. 1232. Section through collar on an enlarged scale. The circular orifice is left to pass the priming wires through. Fig. 1233, side view, and Fig. 1234, plan of bottom of plug, showing the grooves for the wires, with the ends flattened and connected by the two pieces of platinum wire. Fig. 1235 shows an arrangement for firing several small charges or blasts on land simultaneously, by a powerful battery applied at one end of the main wire. Figs. 1227 and 1221 are on a scale 110 full size. Figs. 1228, 1229, and 1230 " t in. = 1 foot. Figs. 1232, 1233, and 1234 " 1 full size. Fig. 1236. Isometrical view of a mercurial apparatus or igniter for forming the simultaneous ignition of several mines. The upright A is hinged to the inside of the frame, and on being unhooked falls down upon the front piece containing the six cups C filled with mercury. The pieces of wire, let through the arm B, numbered from 1 to 6, enter the similarly numbered cups at the same instant, the connections being completed by the wires 1' 2' 3ª, &c., which enter the bottom of the cups, and are turned up against the front part of the frame. The two extreme batteries, 1 and 6, are here only shown connected with their conducting wires and the apparatus. The intermediate batteries would be conducted in the same manner, but are not shown, to avoid confusion. Fig. 1237. Section through front of frame, and mercury cup on an enlarged scale, showing the arm down upon the frame, with the connection complete. Fig. 1238. Isometrical view of cylinder battery connected. Fig. 1239. Battery in plan. Fig. 1240. Box in plan. Fig. 1241. Section through A BCD, Fig. 1239. c c. Copper cylinder. 88. Sulphuric acid, water, and sulphate of copper. z 2. Zinc rods, within ox-gullets, containing dilute sulphuric acid only. Digitized by Google 428 ELECTRICITY. 1236. 1237. A 1239. 1238. A, B 1941. Di 0 i) 0 1242. 1244. X B C A T s 1243. Z C A P P Digitized by Google ELECTRICITY. 429 Figs. 1242 and 1243. Galvanometer. C. Single cell of a Daniell's battery. Copper cylinder 21 inches diameter, and 2f inches high. Z. Zinc rod, } inch diameter. D. Rectangular coil of insulated wire, one-sixteenth of an inch diameter, surrounding the needle in a vertical direction. One end of the wire is connected to the cylinder at X; the other end forms the positive pole of the galvanometer. In testing the completeness of an electric circuit, the two ends of the wire forming that circuit must be brought in contact with the poles P' of the galvanometer, when the needle will be instantly deflected if the circuit is perfect. Fig. 1244. Voltameter. A. Glass vessel closed at top, containing acidulated water. T. Graduated glass tube entering the liquid in the vessel. pp. Platinum wires, hermetically sealed into the tube. &. Stopper for closing the second orifice, while the vessel is inverted for filling the tube. Fig. 1242 is on a scale } in. If 1 foot. Fig. 1243 " 1 full size. Fig. 1244 " « " The following is from the report of Alexander Parris, C. E., conducting the works at the Navy Yard, Portsmouth, N. H., dated November 9th, 1840. This report was addressed to Col. S. Thayer, Boston. "Our operations during the past season were confined chiefly to the construction of quay walls and the foundations of two launching ways, the whole of which are built of stone. The character of the bottom of the river where the work was laid, rendered blasting or other means necessary, before a pro- per surface for the foundation could be obtained it was desirable to give it a slight inclination inward, so that the face of each course of stone should lie somewhat higher than the inside, thus preserving a proper bottom for the walls and rendering them perfectly secure. This bottom is a hard slate-rock, and, with the exception of some level portions, extremely uneven, with slopes of almost every grade, gener- ally in an outward direction from the shore. The depth of water in the line of the walls varies from fifteen to twenty feet at low water, and from twenty-five to thirty below the high tides. The depth of water added to a strong and variable current, caused me to anticipate much difficulty and great expense in all operations below its surface. 'But we were fortunately provided with a fine diving-apparatus, consisting of a cast-iron diving-bell and a powerful air-pump attached. This apparatus was worked from a vessel of strong construction and light draught, fitted expressly for the purpose. A system of signals and messengers was established for communication between the workmen in the bell and those on board the vessel; by these means, every want was speedily made known and answered. Four workmen, divided in two gangs, were em- ployed for working in the bell, which made four descents per day, occupying at each time two and a half hours, the two gangs alternately relieving each other. The bell was amply supplied with a con- stant stream of fresh air, and but two or three inches of water remained in at its greatest depth, so that the men worked in a comfortable state, perfectly dry, and with no more difficulty of respiration than on dry land. In deciding upon the best means for preparing the bottom for the reception of the foundation of the walls, I was greatly at a loss which to adopt. It appeared to me that in adopting the method prac- tised by other engineers, great expense and difficulty would be incurred; and as it did not appear that their method had been employed in blasting the solid rock at the bottom of a river, in any of their ex- periments, I was somewhat apprehensive of their utility for operations of this kind, and whether the cost would justify the trial. In order to satisfy myself with regard to the expense of an experiment with the galvanic battery, I applied to Mr. Daniel Davis, jr., philosophical instrument maker of Bos- ton, for the necessary information, when I was convinced that a very trifling expense would procure such a trial as would satisfactorily decide the merits of the apparatus. Mr. Davis kindly assisted me in making the experiments, which were tried at the Navy Yard, at Charlestown, and I had the pleasure of witnessing the most satisfactory results, and without hesitation determined to apply the means to the work in hand. "The galvanic battery, which was constructed by Mr. Davis, was one of Doctor Hare's invention, of Philadelphia. It consists of two vessels or jars, each formed by two concentric cylinders of copper, ad- mitting of a cylinder of zinc between. Two copper wires, termed the conducting wires, formed the medium by which the electrical fluid was communicated to the charge from the battery. These wires were closely wound with thread in order to prevent their coming in contact with each other, and both covered tightly with tape, and afterwards served round with twine, thus forming a single coil. At each extremity of the coil, the wires were separated for a few inches like a fork. This form of the galvanic battery, termed by Doctor Hare the 'Calorimeter,' is the most simple and portable of any that I have seen its power for blasting gunpowder may be increased to any required degree; either by enlarging the size of the jars or increasing their number. We had in addition to this apparatus, a simple con- trivance for proving the charges of powder, which is termed the Electrometer.' "The charges used in blasting consisted of various quantities of gunpowder, according to the effect required, from four ounces to a pound. They were enclosed in perfectly air-tight tin canisters, the smallest being an inch and a quarter in diameter, and the diameter of the largest about two inches the lengths of the canisters were eight or nine inches. Two copper wires were introduced into the canister about half way down, with the extremities connected by a fine platinum wire; the other ends of the wires projected twenty or twenty-five inches beyond the mouth of the canister, which after being filled with powder, was closed and effectually secured with a water-proof composition. It will be ob- served in thus preparing the charges that the whole is completely air and water tight, and that no vent to the powder remains, an advantage of which I shall further speak. "The operation of blasting is carried on in the following manner: The hole in the rock for the recep- tion of the charge, is drilled to a proper depth by the workmen in the bell; the canister is then inserted with the ends of the copper wires extended outside of the hole, which is then filled up or tamped with coarse sand. The ends of the conducting wires are then connected by means of clamps to the wires Digitized by Google 430 ELECTRICITY. leading from the charge; the other end of the coil is then led up, as the bell is hoisted to the surface, to the battery, which in all our experiments was placed on a floating stage directly over the charge. The jars forming the battery are brought near each other, and their whole power concentrated by connecting them together with a short copper wire the end of one of the conducting wires is then brought in con- tact with one pole of the battery, and the end of the remaining wire similarly disposed with the other pole, when the explosion instantly follows by the platinum wire in the charge becoming intensely heated as the electrical current passes through the conducting wires. " We made during the past season nine blasts, with but one failure, which was caused by the platinum wire in the charge becoming accidentally broken, so as to render the electrical circle incomplete this probably occurred in tamping, an operation which must be conducted with care, as this accident is most liable to be incurred, of all others, owing to the extreme delicacy of the wire. The object of the elec- trometer is to detect whether this has taken place before the charge is inserted in the rock, and may always be ascertained by a simple trial. It must be obvious to every one, at all experienced in blasting rocks, that this method has advan- tages in many respects over the old methods, both under and out of water. The danger of accidental I explosion is entirely prevented; these occur for the most part in the old practice by carelessness, while in this, great care and nicety are required to produce the explosion. There is very little time required in charging, as the canister is simply inserted in the hole and tamped with sand; the whole time occu- pied in this operation, and making the connection with the conducting wires, in the present cases rarely exceeded twenty minutes. There is great expense and trouble saved in the absence of the train or fuse, which was indispensable in the old methods, especially under water, where was always required a water-tight hose or tube leading to the surface, which was always destroyed by the explosion. Here nothing is lost or injured except the canister containing the charge. The explosion of the charge is re- duced almost to certainty, and should cases of failure occur, it can be approached with safety, without the suspicion that fire may be near it. The most important advantage in an economical view, is that the effect of the charges is much greater than in the old way, in consequence of there being no vent- hole; the whole explosive force of the powder is thus gained, while by the old methods much of it 18 lost. Our smallest charges displaced a much greater quantity of rock than the same amount of powder by the old means, which we had opportunities of experiencing. With these advantages, this method of blasting places in our hands the most ample means of clearing harbors and rivers, of rocks, &c., in any reasonable depth of water. " In using Dr. Hare's apparatus, it appeared that an important advantage was gained over that of Daniell's, employed by some operators, inasmuch as a very troublesome arrangement, indispensable in the latter, was avoided. This consisted in not being obliged to insulate the conducting wires from the water, as in such a case the connection of the conducting wires with the charge must be made before the canisters are placed in the rock; every portion then of the wires, where the connection is made, must be covered with the water-proof composition. By Daniell's apparatus, it appeared that water was a con- ductor, thus destroying the electrical circle, if any part of the conducting wires came in contact with it." Electricity applied as a moving power.-The operation of voltaic electricity in magnetizing iron, and the disappearance of the excited magnetism directly its action is suspended, or nearly so, has furnished a means of obtaining to a certain extent a considerable moving force applicable to the purposes of ma- chinery and although in all the attempts hitherto made, engines of great practical value have not been obtained, yet very considerable advances have been made and are still making in electrical machines. The general principles resorted to in the construction of electro-magnetic engines are these,-either a rapid change of polarity in masses of iron surrounded by spiral coils, 80 as to cause them to alternately attract and repel other electro-magnets brought within their influence, or otherwise a rapid magnetizing and demagnetizing of masses of iron in a similar way, without any change of polarity by which an attractive force is brought to act upon other masses of iron, so long as the attraction is operative in pull- ing them onward, and no longer. In both these cases a rotary motion is obtained by fixing the at- tracted masses on the circumference of a wheel, and placing the wheel so as to admit of the operation of the electro-magnets upon the extremities of its radii, as in any other similar case of the application of a moving force to the circumference. Mr. Cook, of Saratoga, made an interesting exhibition of an electro-magnetic machine, in the year 1838, in Barclay-street, New York. The whole apparatus was of the most simple construction, con- sisting of two sets of magnets, one revolving within the other. The external magnets being excited by the fluid generated by the action of an ordinary galvanic battery, while the polarity of each inagnet was constantly and regularly changing, a perfectly uniform motion was communicated to the cylinder, which might be increased indefinitely as additional force is applied. The machine was thirty inches in diame- ter, and contained seventy-eight magnets, each weighing four pounds. The machine, in full operation, made eighty revolutions per minute-considerably more than can be obtained by the force of one man. Mr. Cook states that the power of the machine may be greatly increased by adding to the number of magnets, without enlarging the battery. Professor Jacobi, of St. Petersburg, by means of an engine on this principle, succeeded, in the years 1838 and 1839, in propelling a boat upon the Neva at the rate of 4 miles an hour. This boat was 28 feet in length, about 7 feet wide, and drew nearly 3 feet water. It contained ten persons; the engine was worked by a voltaic battery of sixty-four pairs of platinum plates, excited with nitric and sulphuric açid, and propelled the vessel through the medium of paddle-wheels. In 1842, Mr. Davidson constructed an electro-magnetic locomotive engine, which was tried on the Edinburgh and Glasgow railway, the carriage of which was 16 feet in length and 6 feet wide, weighing above five tons, including batteries and magnets. It was propelled at the rate of about 4 miles an hour. A new suggestion in the application of Electricity as a moving power will be found under the head of ELECTRO-MOTIVE ENGINE: but as yet the only practical machines, that we know of, driven by elec- tricity, are the electric clocks used on many of the European railways. Digitized by Google ELECTRIC LIGHT. 481 Amongst other applications of electricity to useful purposes, the application of magneto-electrical action in arresting the oscillations of the compass-card on board ship is not the least important. Elec- trical currents are excited in non-magnetic metals, such as copper, zinc, &c., when placed near a magnet in motion, or when themselves set in motion near a magnet; and these currents 80 tend to arrest the motion, that if an ordinary magnetic needle be caused to oscillate within a ring of copper, the amplitude of the oscillations rapidly diminishes, and the needle is speedily reduced to rest. On this principle, the common compass-card employed at sea is placed within a dense ring of copper,-the poles or extremi- ties of the magnet being near the interior of the ring; this, with some valuable and judicious improve- ments in the construction and mounting of the needle, so fetters the vibrations, that even although the instrument be extremely sensible of the least motion, and of the action of the magnetic force of the earth, yet the compass-card is found steady in the heaviest sea, and under the violent motion of steamboats when struggling with a gale. For further and still more important applications of electricity to the improvement of the arts, and the conveniences of life, see Electro-Metallurgy, Electro-Magnetic Ore Separator, and Telegraph ELECTRIC LIGHT. The improvements in the construction of galvanic batteries consist in making them on what is termed the "perfluent" system of supply and discharge, to contradistinguish it from the 64 percolating" system, which has recently come into extensive use. According to the percolating system, the liquid employed (usually sulphuric acid) is supplied to and discharged from each of the cells of the battery, in separate and distinct streams or series of drops; the liquid, as it becomes exhausted, though not entirely so, dropping out through an oritice in the bottom of the cell, and being then allowed to run to waste, and the place of the discharged liquid being supplied by fresh drops descending from above into each cell. But, according to the new system, the liquid is supplied in one stream only, which passes continuously through the entire series of cells, entering by the first cell of the series, and passing off through the last. No diminution of electric intensity is observed to take place in the perfluent battery, from bringing the cells into communication with one another, owing to the circuitous course which the fluid is made to take between cell and cell. In proportion, of course, as the duration of the transit through each cell is shortened, the chance must be proportionally lessened of each portion of the liquid coming into contact with the acting metal or element in that cell; yet, as no drop of the fresh liquid supplied to the battery can make its way to the final discharge outlet without going through the whole of the cells, what it misses in the first cell, it is sure to encounter in one or other of the remaining cells. The cells last in order of a perfluent battery necessarily act less power- fully than the earlier cells of the series; as, for example, the last six cells of a series as compared with the first six. The diminution of power, that is to say, the quantity of electricity which the cells are capable of circulating, does not appear, however, to follow exactly in the ratio of the strength of the exciting liquids; for the difference in power between the middle and initial cells of a series is propor- tionally not so great as the difference between the middle and the terminal cells. When it is desirable to obtain intensity in the electric current rather than great quantity, the terminal cells should be made about equal to the quantitative power of the others, by uniting the similar conducting wires of several cells together, and using them as if proceeding from one cell. Thus, as it would be technically expressed, the last three cells in a fifteen-cell battery (say the 15th, 14th, and 13th) might be connected for quantity, and the two next preceding pairs (say the 12th and 11th, and 10th and 9th) be connected also for quantity, and the first eight cells might be worked singly, in the usual manner of a series. But, how- ever great may be the differences in power between the initial, middle, and terminal cells of a series in each cell, regarded by itself apart from the others, the degree of exhaustion, and consequently of electric action, is always very nearly uniform throughout every part of the cell. The details of a battery constructed on this perfluent principle are represented in Figs. 1245, 1246, 1247, and 1248 of the drawings annexed. Fig. 1245 is a view of the battery, as seen from above; Fig. 1246 is a vertical longitudinal section; Fig. 1247 is a view of the trough from beneath; and Fig. 1248 is a vertical cross-section. A is a wooden trough, the parts of which are firmly bolted together; a a are slate partitions, the edges of which fit closely into the sides and bottom of the trough, and are about two and a half inches apart; bb are thicker partitions of wood, which are inserted at short intervals, say every six cells, and made fast to the sides by screws and nuts ; c¹ are two parallel rows of holes made in the bottoms of the cells, two in each; dd' are two corresponding rows of wooden covers, which are made fast to the bottom of the trough, Fig. 1247, one underneath each adjoining pair of holes, as c c or c' c¹, with the exception of the two end ones, which cover one cell only; e is a groove cut out in the upper surface of each cover, and made just of width enough to embrace two of the cell holes, as cc or c1 c¹, and 80 establish a channel of communication between them; f is an aperture made in the bottom of the end cover of the series of holes; d and f', similar apertures in the bottom of the opposite end of the same series of holes, into each of which apertures there is inserted a piece of copper tubing, to which there is attached one end of a flexible hose, g or g¹, (made of vulcanized caoutchouc, gutta percha, or any other suitable substance or combination of substances,) which terminates at the other end in a funnel h or h¹; and i i' are eye-bolts affixed to the ends of the trough on the outside, which respectively sustain in an upright position the funnels h and h¹, there being a slit or opening in the eye of such bolt, to admit the neck of the funnel. The whole of the inside of the trough is well coated with marine glue. The mode of operation with this apparatus is as follows: The liquid is poured in at the funnel h, and passes into the first cell through the hole o of that cell; from the first cell it goes out through the hole B into the first of the grooved covers of the series d, whence it flows into the second cell through the hole c' of that cell; from the second cell it next passes through the hole c of that cell into the second of the grooved covers of the series d; and 80 on to the end of the series, (as indicated by the arrows in Fig. 1245,) when it discharges itself through the flexible hose g' and h' into a receiving vessel K. The arrangement just described is, however, chiefly suitable for those batteries which use but one sort of exciting liquid, but in batteries where two fluids are used it may be expedient to adopt the modifi- Digitized by Google 432 ELECTRIC LIGHT. cation of the perfluent system represented in Figs. 1249 to 1254. The internal cells in this case are supposed to be made of earthenware or some other porous material. Fig. 1249 is A side view of one of these cells, and Fig. 1250 a vertical section across the middle. A hole Q is made in the bottom of this cell, and into this hole a varnished copper tube r, with a collar and washer of vulcanized caoutchouc at top, is dropped. The tube is pulled tightly down upon the washer, in order to prevent any of the liquid escaping between the washer and the bottom of the cell. Or, instead of this arrangement, one of the description represented in Figs. 1251 and 1252 may he substituted. S is a cradle which is cemented on 1259. N < A 1245. 1261. 3 1962. no K 1249. σ 1251. 1253. 1248. V 1250. 1252. 1246. d. 1257. & 1258. 00006000000000 0000 1254. < 1247. 1255. 1256. to the under end of the cell by marine glue, and encloses it completely. The tube r is screwed on to the bottom of this cradle, and through it up to the hole in the cell. In both cases the tube has an oval aperture w cut transversely through it, and terminates at its under end in a solid screw-point. The trough for the reception of porous cells of this description is made in the manner represented in Figs. 1253 and 1254; the former being a transverse vertical section of the trough through the centre of one of the cells, and the latter a longitudinal vertical section. Q is the internal porous cell, and Y the zinc plate suspended therein. X X are the plates of negative surface, say copper, placed outside of the porous Digitized by Google ELECTRIC LIGHT. 433 cell. ZZZ are the sides and bottom of the trough, the spaces m m between which and the porous cell form the external cell, which contains the second fluid, (say sulphate of copper.) A is an open channel for the discharge of the second fluid, which runs along the outside of one wall of the trough, near to the top, and communicates by lateral apertures pp in the wall, with the spaces inside m m, appropriated to that fluid. V is a grooved or channelled under-cover, which extends along the bottom of the trough from end to end, and comes immediately under the line of holes in the porous cells Q. The lower end of the tube r, which is attached as aforesaid to the bottom of each porous cell, and enclosed by the cradle, is passed downwards through an orifice in the bottom of the trough, and also through another orifice in the bottom of the under-cover V, till the oval aperture w in the tube coincides with the groove l in the bottom of V; so that when the whole of the cells are fixed in their places, the channel t forms through the medium of the apertures w w a common channel of communication between all the cells. U is a nut which takes on to the end of the solid screw-point of the tube r, and by turning which the parts S, r, V, and Z are all screwed tightly together. For the sake of greater security against leakage, and against the intermixture of one of the fluids with the other, washers of vulcanized caoutchouc are inserted between the crade S and the bottom of the trough, and between the bottom of the grooved channel V and the shoulder of the nut U. E is a second under-cover which runs parallel to V, (on one or either side of it;) the groove e, in which the second cover communicates by a series of holes n n with the external cells above, containing the second fluid, serves as a common channel through which these cells may be supplied from a flexible hose. The second fluid is, after passing through the external cells, discharged from the end of the channel A. The perfluent system may be also carried into effect by employing siphons instead of the grooved under-covers dd', V, and E, before described, to transmit the liquid from cell to cell successively, as shown in Fig. 1255, which represents two adjacent cells of a battery. The long end A of the siphon descends to near the bottom of one cell, in order that it may carry over the densest portion of the liquid therein, and deliver it through the short end B into the next cell. Or, if the liquid employed is of such a nature that it becomes lighter as it becomes exhausted, (sulphate of copper, for instance,) then the legs of the siphon are reversed, the liquid entering it by the short end, and being carried over by the long end. Part of the invention consists in attaching to all galvanic batteries in which a gradual change of liquid is required, an equilibrated hydraulic cistern and graduated meter, such as represented in Figs. 1256 and 1257. A is a cask, closed at top, so as to prevent the action of the atmospheric pressure on the surface of the liquid contained in it; and b is an orifice near to the bottom, which opens into a small outer cistern c. This arrangement ensures that the liquid flowing through any channel from the little cistern c will always flow at the same rate, whether the cistern be full or nearly empty. From this little cistern a loose piece of vulcanized caoutchouc tubing d proceeds, and is connected with the glass tube e, from which is suspended the meter f, having a small hole at the bottom, 80 that the rate of flow out of this hole is indicated by the height at which the surface of the liquid stands. The meter is graduated to units, which shows the amount of flow requisite to supply the chemical action which is going on in the battery when the electric current is circulating at a rate indicated by corresponding units on the galvan- ometer described in Fig. 1258, which is included in the circuit. The meter, with its tube d, is suspended so as to enable the rate of flow to be adjusted by hanging it at an altered level in relation to the cistern, according as the galvanometer may indicate to be necessary. The parts d e form in fact a siphon, which only requires to be filled with liquid when the apparatus is first set in action, after the cistern is charged. The liquid issuing from the meter is received by a funnel h, or otherwise led to the battery. Also the employment in galvanic batteries, having copper or mercury for the negative element, of a liquid amalgam of zinc and mercury, enclosed in a bag or case of lawn or horse-hair cloth, or any other finely reticulated fabric, but not made of metal, which allows of the acid passing freely through its meshes to act on the bottom and sides of the zinc amalgam, while the bag or case retains the amalgam itself. Again, the employment of lead as the positive element in galvanic batteries, (instead of the zinc which is now commonly used,) combined with a solution of nitric acid or of acetic acid, in some one or other of the forms best calculated to act on the lead. The new galvanometer is such that it can be made a permanent adjunct to, or part of the battery, 80 as to be always indicating what amount of electricity is circulating when any sort of duty is being performed by it, and the weights of materials combining or used per minute at any particular time. This improved galvanometer consists of a thick piece of insulated copper wire A wound round a wooden or brass cylindrical centre, fitted with ends C C. One end of this coil is in metallic connection with the positive or negative pole of the battery, and the other extremity is placed in connection with the part of the lamp, (or other piece of mechanism for actuating which the battery is used,) which would receive the conductor from the said pole of the battery. In the hollow cylindrical centre of the coil there is placed a rod of soft iron d, as shown in the figure, which moves loosely up and down in it, and is pro- longed by a short brass stem or index e. A graduated scale f is fixed to, and rises from, the upper end of the coil, 80 as to show the height at which the electric influence causes the index to stand. The graduations are represented in the figure as marked on a glass tube, within which the index and rod d slide. These graduations are 80 made as to indicate the number of grains of pure zinc consumed per minute in each cell of the galvanic series, the current produced by which causes the index to stand at each such division of the scale. Any galvanometer of this kind can be graduated from a standard one. The standard can be graduated by ascertaining experimentally the weight of zinc consumed per minute, but a less tedious process is to graduate it from a Petrie's Galvanometer, which indicates all the required units of electricity and their fractions, by means of weights; the accuracy of that instrument being first tested by one such direct experiment on the zinc consumed. This improved galvanometer may be made of a shorter and thicker wire, making fewer coils, if the iron rod is partially counterpoised by a spring or weights, or hydrostatically with mercury. 55 Digitized by Google 434 ELECTRIC LIGHT. Figs. 1259 and 1260 are representations of a lamp embodying this improvement. The skeleton of this lamp is composed of a foundation-plate of wood A, a sole-plate B of brass, firmly connected by pillars C and a three-legged stand K rising vertically from the sole-plate B, the feet of which are fastened to B by nuts beneath, but insulated by circular washers of dry hard wood (of the form shown in section i.) A hole is bored vertically down through the centre of the top of the stand K, into which hole the upper electrode N is fixed by three 1260. metal wedges jambed into key-ways or channels, sloping upwards and outwards, so as to keep the inner faces of the wedges parallel to the central axis. A glass shade is fixed to the sole-plate B 80 as to cover K. H G is a shaft which slides vertically into the central axis of the lamp, through holes in A and B, and has a socket at top which carries the lower electrode M. The lower part G is cut with teeth which work into a pinion F, which turns on a spindle in fixed supports. A barrel F' is attached to the pinion F. and a weight W is suspended by a string which passes round F' and is fixed to it, 80 as to counterpoise the weight of HG. On the spindle of the pinion F is fixed a wheel E, having square teeth. A lever T turns loosely on the same spindle as a fulcrum, and carries a double pawl U V, which turns on a pin which projects from the side of T, so that this pawl U V can lock into the teeth of the wheel E in either direction. A long horizontal lever Q passes over this pawl from a joint or fulcrum a, and this lever carries a light spring or tongue l close beneath it, the end of which is kept from springing away from the lever by resting in a step in a little stirrup or fork d, which is attached to the lever Q. and embraces the wheel E and the end V of the pawl. The pawl and its lever T are kept in a state of slow vibration from side to side by means of a crank S, which works in a fork at the end of T, the crank S being made to revolve by an ordinary train of wheel-work, furnished with an escapement or fly-wheel A', and driven by spring power or weights. When the lever Q is turned a little downwards its tongue I presses V into the teeth of the wheel E, and the vibratory motion of T causes V to drive the wheel round, notch by notch. The wheel does not follow the pawl in its back motion at every stroke, for this is better ensured by having a spring n (Fig. 1260) fixed to A, and pressing against the side of G. This motion of the wheel causes the pinion to elevate the rack G slowly, 80 as to raise its electrode M towards N. But when the lever Q is raised or turned upwards, the notch in the stirrup lifts the tongue l off V, and allows U, the heaviest end of the pawl, to drop into the teeth of the wheel E. This drives it round in a contrary direction, so as to lower the rack G and draw its electrode M further from N. Whenever the lever Q is raised, the lower step in the stirrup d catches the sides of V and draws it (V) up out of the teeth of the wheel, in case v should have become jambed or hitched in the teeth, 80 that the counter-weight of U might be unable to release it. The means by which the end of the lever Q is raised or lowered are these: R is a regulator coil, one end of its wire is connected with the binding-screw e, and the other end, L, is brought up and fixed in contact with K. An iron rod 0 moves freely up and down in the central hole of the coil, and is prolonged upwards by a stem of wood p, by which it hangs to the end of the lever Q in the manner shown in Figs. 1259 and 1260. The rod o passes through a hole in the centre of a cup y, which screws into the bottom of the coil-case. Around o there is a circular weight X which rests on a small step in 0. when o is raised. When o sinks below its medium position it is left behind, resting on the edge or rim of y. The object of this arrangement is, that when o is actuated by a force equal to its own weight, added to half the weight of X, then it will have a tendency to return to its medium position, with a force of half the weight of X, whether it be raised higher or sunk lower than that position. The mode of action is as follows: The end of the negative wire from the battery is set in the binding-screw f, and is conducted thence by a metal connection to the supports of the spindle of the pinion, and to the spring n. The current passes through these into the rack; thence to the lower electrode M, from which it passes to the upper one, N, producing the light between them. From N it proceeds through the stand K to the wire L, of the regulator; thence to the clamp e, which is in con- nection with the other end of the regulator wire, and into which the positive wire from the battery is clamped to complete the electric circuit. The current, in passing through the regulator, tends to raise the iron centre o, which being connected to the lever Q, is counterpoised by the weight W¹, which screws along an extension of the lever beyond the fulcrum a. To put the lamp into adjustment, the driving geer being wound up, and the battery being in a state of activity fit for the permanent action intended to produce the light, and its wires connected with e and f, as described, the lever Q is raised by hand until the electrodes have separated to the greatest extent compatible with obtaining a perma- nent light from them. The screwed weight W' is turned backwards or forwards until it keeps o balanced, just so as not to sink below its medium position, when the electrodes are separated as afore- said. When in this position, the shoulder of o touches the weight X, which is resting on the rim of y. The lever Q carries a little projecting piece or catch g, which meets the bent arms attached to the crank- spindle S, and thus arrests the motion of the crank, when the lever lies so that o is in its medium position; but whenever it rises above or sinks below that point, the catch g allows h h to pass beneath or over it accordingly, 80 that the crank can revolve freely and work the ratchet U V. A front view of a lamp on this plan is given in Fig. 1261, and a side or edge view in Fig. 1262. A' is the disk, which, as shown in section, Fig. 1262, resembles in its form two cones, placed base to base, so that there is always one sharp or feather-edge in sight of the negative electrode, which is of the ordinary single-cone form. B' is the scraper; B2 is a frame which carries the shaft C², to which the disk electrode A' is attached. Dª and E2 are a bevelled wheel and pinion, which geer into one another, the latter being fixed to the shaft G2. At the bottom of this shaft there is another wheel H2, to which the clock-work or other apparatus for giving motion is attached. The shaft G' may be insulated in various ways, either by the interposition of plates of ivory or wood, J K, screwed together, or by gutta- percha or india-rubber rings. Digitized by Google ELECTRIC LIGHT. 435 To increase the temperature of the metallic electrode A¹, the operator sometimes passes the metallic holders BB through a block of glass DDD, or some other similar bad conductor of heat, as repre- sented in Fig. 1263, so that the heat and radiant light may be developed with as little loss of the former as possible by radiation. An elevation of a small iridium bracket lamp is given in Figs. 1264 and 1265. A' is the electrode of iridium, which is fused on or otherwise fixed to two pieces of platinum B B, which are fixed into two copper or other metallic holders C C. These holders are insulated by means of ivory, wood, or vul- canized india-rubber washers DD, or some other suitable non-conducting substances, 80 as to prevent contact with the bottom metal plate of the lamp E. To one of the metallic holders a copper wire a¹, passing through the hollow tube B', is connected with one pole of the battery, and the electric circuit is completed, and the current made to pass through the brass-work of the lamp to the electrode, by turn- ing the ivory knob X, which is attached to a screw-shank Z, making a metallic communication with the other holder. W Y is a ring of brass, which is screwed into the bottom of the lamp. A glass shade, of any shape or form, may be placed on the plate E. Fig. 1266 represents a triple electrode suspending-lamp. A A A are three ivory knobs, with metallic shanks, for making the necessary communication, as before described. An apparatus embodying the chief of these arrangements is represented in Fig. 1267. The parts in this apparatus which are similar to those in the permanent light apparatus, Figs. 1259 and 1260, before described, are indicated by similar letters. A helix coil of insulated copper wire A, is employed for the purpose of producing the prime-moving force which actuates the sliding shaft which holds the electrode. This helix is fixed to the bottom of the framework CC'C". A cylinder of soft iron, B, moves freely up and down in it; to the top of B is fixed the rack E, which slides through the hole at c", and carries the electrode M, fixed in a socket, 80 that this shaft can move the electrode M to or from the lower end of the electrode N, which is fixed in the top of the tripod K by wedges or screws. K is fixed and fur- 1267. 1266. 1270. 1271. K 1269. b 1268. a b R 1265. B 1264. d. 1263. D D B B nished in the same manner as that shown in Fig. 1259, and before described. The weight of the shaft BE is rather overbalanced by the weight Q, which is attached by a string passing over a pulley R to B. A pinion F works into the rack E, and fits it loosely with a back lash of about a tenth of an inch. The pinion F is connected with an ordinary train of multiplying wheel-work (concealed behind the brass plate c"") and terminating by any well-known sort of fly or escapement motion of such kind, that FY will be prevented from revolving quickly, but will at the same time yield with a slow motion to any slight force from the rack E. 80 as to prevent the rack E from moving up or down too quickly. The negative wire from the galvanic battery is connected with one end of the helix coil A, and the other end of it is soldered to the brass case, 80 that the current passes through the helix wire to its case, and thence by means of the springs D which are fixed to the case, and are in contact with the iron cylinder B, up the shaft DE, to the electrode M, whence it flows through N, down K, and returns to the positive pole of the battery, by means of the wire y. But when the current thus passes the helix, A causes the shaft B to be drawn downwards, which motion separates the two electrodes MN, and light is evolved until the electrodes become too far separated, when the current suddenly ceases, the light becomes ex- tinguished, and the helix ceases to draw B downwards, when the weight Q begins to draw it upwards again, until the electrodes touch one another, whereby the electric current is re-established, and the light is repeated as before. The apparatus which has been described, Fig. 1267, may be modified in manner following: Fix a regulating coil with a properly weighted iron centre, &c., just like that described in Fig. 1259, (at R, o, Digitized by Google 436 ELECTRIC LIGHT. ?, x, y.) This coil is fixed to c, Fig. 1267, and its wire is permanently included in the electric current and 0, instead of P, moving a ratchet VV; when it drops, it presses a spring or lever in connection with the negative wire from the battery in contact with the shaft B, so that most of the electric current passes from the negative wire through the lever to B direct, and B is no longer drawn down by the action of A, but begins to rise by the force of the weight Q, which in this modification of the apparatus is made to overbalance the shaft as it does in Fig. 1267. The apparatus employed, Fig. 1267, in any of the preceding modifications may be made to act by substituting the arrangement shown in Fig. 1268, for the parts A and B, which gives a greater moving power, and allows the electrode shaft to move through a long space not limited by the length of the coil A. A', Fig. 1268, is a helix coil, similar in construction to A, but differing in form, as is indicated in the sectional view, Fig. 1268. A short hollow cylinder B' is substituted for B; a brass rod B" (or a bar feather edged," for the sake of lightness) passes freely through B', and ratchet teeth are cut in it as shown, by which a spring ratchet g suspends B', in the position shown in the engraving. An end H, which screws on to the top of the central tube of the coil A, carries the conducting springs D D, and guides the shaft B"; when the shaft B" rises (carrying B' with it) it brings the projecting end of the ratchet g against the slanting side of H, the pressure of which pushes the ratchet out of the teeth and lets B' descend for the space of one notch or tooth, 80 that B' is always ready when the current in A' acts to draw the shaft B' a fraction of an inch lower, and yet does not prevent the shaft from gradually moving upwards to any extent to supply the waste of the electrode, while B' never follows the shaft higher than H. The helix coil last described, Fig. 1268, may have its action on B' augmented by making certain parts of the case in which the coil is wound, to be of soft iron in place of brass, as shown by the section of the case in Fig. 1269, the parts marked a being iron, and those b brass. An electro-magnet may be used in place of the helix coil surrounding the moving piece of iron B'; the poles of the electro-magnet being presented obliquely or directly beneath B¹, the form being altered so as to be the better suited to be attracted by both poles of the electro-magnet. Reflectors may be adapted to electric lighthouse lamps as well as to electric lamps of all surts. The intensity of the electric current (whatever may be the nature of the lamp or apparatus used for producing the light) is effected by including in the electric circuit a long coil of insulated copper ribbon wound in an iron case, as shown in section, Fig. 1270, and part side view with cover removed at Fig. 1271. The coil may be made in pieces separately wound on, and their ends joined in succession, the two extreme ends A e of the first and last coils being made to pass through the holes Pq in the case. A hollow cylinder of iron, or a number of bits of flat iron bar gh, are placed around the coil like the staves of a cask, and are held together by elastic bands of vulcanized caoutchouc. A good proportion for the substance of the coil is one-hundredth of a square inch of copper in section to every 40 yards ot length. The ends of each coil are held from slipping back or unwinding, while the next coil is being wound, by being bent round and backwards over a pin K K'. screwed into the side of the iron case. The numbers annexed to the arrows indicate the succession of the different portions of the coil on which they are placed. The letters ABCDE indicate the commencement of each of the coils, and a bcde their several terminations. The solid electrodes employed in electric lamps in supporting tubes, are represented in Figs. 1272, 1273, and 1274. A tube e, serves to guard the electrodes, to hold them steady, and to conduct the electricity freely up to the top part of the electrode, the current being passed into the tube through the sole- 1272. plate c", which is put in metallic connection with the negative wire. D"D" (Figa. 1272, 1273, and 1274) are spring conductors (they may be of iron) fixed on the 1274. 1273. # tube e, the tips of which embrace the electrode near the point where the light is developed. The electricity has by this means a free passage from the tube into the electrode. The tube may be fixed mechanically to the B framework c c", and yet insulated electrically from it, as shown in Fig. 1273, by means of collars of dry hard wood 22, on the same principle as the legs of the up- c per electrode-stand K, are insulated from the sole- plate c". The electrode may be composed of many pieces slightly joined together, end to end, and placed in a tube, Fig. 1274, of any required length. To obviate the necessity of joining the parts firmly, the following arrangement, Fig. 1274, has been contrived, wherein the electrodes need never be drawn backwards in the tube: c" is a piece of the supporting framework of the lamp, made for the purpose of holding the tube steady. The tube has a free sliding motion for a short space, that is, upwards, until the nut f touches the under side of z³, and downwards, until the collar f1 touches the upper side of z³, or rather until it touches the part q which rests on 2³. The weight of the tube is nearly counterpoised by the elasticity of the spring q', which is attached to an arm projecting from the tube, as shown, and has an arm q fixed to its other end, the further end q being forked 80 as to embrace the tube, and to rest the pressure of the spring upon the top of z³. The weight of the tube being thus supported, it rises with the electrode, when it is pushed upwards by E', until f touches 23, and after that the electrode rises by passing through the tube. The parts of the fixed supports c and c", through which the tube passes, may be insulated from the rest of the framework by collars of wood, as represented by 22 and z³. Digitized by Google ELECTRIC LIGHT. 437 The following are improved modes of preparing the materials for electrodes: take the powder of various carbonaceous matters, which make electrodes of different qualities as to illuminating power and resistance to abrasion by the electric current. The materials preferred are; first, plumbago powder, having its iron, &c., extracted by washing and warming in acids; second, lamp-black; third, charcoal powder of sundry kinds of wood; fourth, the powder of the carbonaceous concrete which becomes de- posited in gas retorts; or, fifth, grains of this latter substance sifted so as to obtain a somewhat uniform size of grain: any one of these materials mixed with a quantity of brown sugar, in such proportions as are requisite to form a free paste with the powder when the mixture is melted by heat, a much larger proportion being sometimes employed for making the product cohere better. This mixture is melted and boiled (without water) until it becomes stiff; it is then pressed (while hot) into iron moulds of suitable shapes, the inside being lined with paper, or chalk, or plaster of Paris, to prevent the mixture from adhering to the mould, and to form a porous envelope through which the gases, &c., can slowly escape. The moulds have numerous small crevices or holes for the purpose of letting the gases and steam escape from the material when baked. The moulds when charged and closed tightly are heated very gradually, so as to allow sufficient time for drying and dispelling the gases without their destroy- ing the compactness of the material. When a red heat is thus obtained, it is after a time allowed to subside, when the contents of the moulds are carefully taken out and placed upright in a 1275. crucible, which is filled with sand luted down and gradually raised to a white heat. At this high temperature they may be kept for some time, to give them greater mechanical hardness and strength; they are then covered up and allowed to cool gently, and being cleaned if they retain a coating of any other substance, they are put into close-fitting tin cases for use. ELECTRIC LIGHT Apparatus-Straités patent. Figs. 1275 and 1276. A, copper coil. B, soft iron bar for raising or depressing" the bal- ance-lever. C, regulating balance-lever. D, ratchet-wheel for raising or depressing rack. E, rack carrying the lower electrode. F, eccentric- wheel moved by clock-work, for giving motion, by means of the lever G, to the ratchet-wheel D. H, end of coil, communicating with the upper electrode. II, Carbon electrodes. K, clock- work movement. The light was produced from a galvanic battery of moderate size, embracing in its construction and elements several improve- ments, so as to render the battery constant, continuous, and regular in its action, and eco- nomical in cost. By means of solid copper wires the electric fluid is conveyed to the lamp, which may be placed on a table or sus- pended from the ceiling. In this lamp are two sticks of carbon or carbonaceous material, between which the light is developed; and these sticks are moved by a clock-work ar- rangement, in proportion as they are con- sumed, at a speed which is regulated by the current. To render the light continuous, it is necessary that these two pieces of carbon should first be brought into actual contact, that the current may pass, and then be sep- arated to a short distance apart. This is ac- complished by means of the current itself, without manual aid. As the carbon grad- ually wears away, (about half an inch an hour,) the same regulated distance between the two electrodes is ensured by like means. The apparatus to effect this self-regulation is an electro-magnetic instrument, placed im- mediately under the plate of the lamp, and through which the current of electricity is made to pass. The principle of this instrument is extremely ingenious, and in some degree resombles a galvanometer: the galvanic current passing through a coil of wire, magnetizes a bar of soft iron which is passed through the coil; and, in proportion as the current is strong or feeble, the magnetized bar rises or falls. When the current is in excess, it actuates an escapement, and the two electrodes are drawn to the required distance apart; and when the current passing is less than the regulated quan- tity, the motion is reversed, and the electrodes are drawn closer together. By these means, not only is the light rendered steady and constant, but only 80 much of the generated fluid is allowed to pass as is developed in light-effecting an economy of the battery power never before approached. Digitized by Google 438 ELECTRIC CLOCK. The light equalled between 800 and 900 standard wax candles and when it was thrown by means of a glass lens on some pictures, the most delicate tints of color, the grays, greens, and blues, were as clearly defined as by daylight. The prismatic rays were as vivid and bright as those from a sunbeam, and perfectly identical in color, showing the light to be, in purity, equal to the sun. The light was also exhibited immersed in a bowl of water; and as an illustration of the fact that the light, strictly speak- ing, was not the result of combustion, (in the ordinary sense of the term,) but was a pure incandescent light, not dependent upon oxygen for its support. When in action in a room, it nei- 1276. ther takes from nor adds to the surrounding air any property whatever-an important fact in large and crowded assemblies. The inventor is preparing modifications of his lamps, with a view to show the applicability of the discovery to every pur- pose of illumination, from a single candle power upwards. The cost of the light he stated to be about one-twelfth that of gas; that it was perfectly safe and harmless and easily man- aged, and that accidents from explosion or from fire were im- possible. 1277. B ELECTRIC CLOCK. Fig. 1277 is a view of the electric clock in the telegraph office of the Eastern Counties Railway, Eng. CZ are plates of copper and zinc buried in the earth (with a quantity of coke) a depth of nine feet this is termed an earth battery It is compu- ted that the electricity derived from the earth with the two plates is sufficient to work thirty clocks, and will last a number of years with- out being disturbed; EE the pendulum, made of wood, to the lower end of which is fastened a coil of wire enclosed in a brass case F; A A are two permanent magnets; B the balance weight for regulating the pendulum; M M a stand supporting N a steel spring by which the pendulum is suspended; K a spring to which the wire coming from z is attached V a piece of wood for insulating the wire from the stand ; hh two small pieces of wood; tt two metal pins passing through the wood hh. one of the pins t is joined to a brass plate, the other pin has a small gold head, brought level with a piece of agate S; n the break for making and breaking the con- tact; R two arms projecting from the pendu- lum; pr brackets supporting hh; suppose the pendulum is set in motion by moving it to the left, one of the arms R would be brought in contact with the break, pushing the point which did rest on the agate S on to the metal t, the other end of the break would still rest on the brass plate; the current of electricity would then pass from 2 up the wire (as indicated by the arrows) to the C spring K, (down one of the wires at the back Z F. o of the pendulum shown dotted,) through the coil in box F up the other wire to spring N, then down the wire to pin t along the break to the other pin, and terminating at C, the circuit would then be complete; when in the EARTH position described, the coil F would become a magnet, and be attracted back by the mag- net A, the other arm would then push the break on the agate, the pendulum would then Digitized by Google ELECTRO-METALLURGY. 439 fall back again, making the contact, thus a constant motion of the pendulum is kept up. To complete the clock, a few wheels are necessary for the proper working of the hour, minute, and second hands. ELECTRO-METALLURGY. Electro-metallurgy, depending essentially on galvanic agency, is sub- ject to the operation of the same principles, and governed by the same laws laid down in the books which treat of galvanism and galvanic batteries; the successful reduction, therefore, of the metals, must depend entirely upon a thorough knowledge of galvanism, and galvanic apparatus. Independently, however, of these general galvanic properties, there are certain particular ones apper- taining either to the different metals, or to the different qualites of the same metals, which have to be considered in detail, as well as the apparatus to be employed for precipitations. The substance best adapted for the complete separation of the solutions, in a single-cell apparatus, is animal membrane. Of this there are various kinds; bladders of different textures, the lining membrane of the intestine of the ox, fine gold-beaters' skin, or bladders of various animals may be used. Animal membrane separates solutions better than any other diaphragm, but, for most purposes, it affords too much resistance to the passage of the current. Brown paper, and cartridge-paper, are frequently of value for the electro-metallurgist, and they last for a considerable period without renewal. Of late, earthenware tubes have been very extensively employed. The following is the order in which different substances stand with regard to their capabilities of admitting the passage of electricity: Brown paper, Bladders of various thickness. Thin plaster of Paris, Thick plaster of Paris, Porous earthenware, Capillary tube. Gold-beaters' skin, Of the various forms of apparatus, which may be used for the precipitation of the metals, the most simple is that having a porous earthenware tube, to contain the acid and zinc, whilst the negative metal, which is usually a mould, is placed externally to this, and connected by a piece of wire to the zinc. Thus, for instance, take a pound pot, Fig. 1278, and half fill it with a solution of sulphate of 1278. copper, S; in this, place the earthen vessel P, with the dilute acid A and zinc Z, and this constitutes the whole of the present form of apparatus; for, when we desire to make an electro-medallion, it is only necessary to place one or more casts in the outer vessel m m connected by a wire with the zinc, and then action will immediately commence. Any number of moulds may be placed in the outer vessel, provided they can radiate to the zinc. Saturation of the liquid may be preserved by suspending some of the salt in a linen bag over the mould. This form is objectionable, because the salt of zinc speedily passes through to the outer vessel; but it has the advantage of allowing the mould to be placed vertically, in which position it is much less liable to have particles of dust settling upon it. There is no limit to the size of this outer vessel; for a water-butt, a tank, or even a lake naturally impregnated with sulphate of copper, would answer. There is another form, where bladder takes the place of the earthen vessel, and where the position of the cast is horizontal. Here, the outer vessel, Fig. 1279, which is square, is made of wood, coated internally with cement; on one part of the edge of which, a piece of brass b is fixed in which are two holes, one for connection with the wire of the cast m, the other with that of the zinc. In the interior of the trough, a moveable shelf of mahogany is placed, on which is supported a glass containing a zinc plate Z and crystals of sul- phate of copper to be dissolved. The glass has a piece of blad- 1279. der tied over the rim, and this forms an outer vessel similar to the porous tube in the former apparatus. It, in like manner, contains the acid and zinc; the latter being connected by a screw to a wire, in such a way that it can be readily removed. In every single-cell apparatus, the solution of metallic salt should be maintained in the required degree of concentration, by keeping some crystals of the salt undissolved in the solu- tion. If these crystals are allowed to sink to the bottom of the vessel, they will not answer the intended purpose of maintain- ing a saturated solution; for the portions of the fluid which have been deprived of their metallic salt rise to the surface, whilst the saturated parts remain in con- tact with the crystals at the bottom, thus preventing their solution. This difficulty may, however, be readily overcome, by placing the crystals to be dissolved in a little bag, on a shelf at the top of the liquid, by which means the saturation of the fluid will be ensured. The only circumstance to be observed is, that the zinc be equidistant at every place from the metal on which the reduction of the new metal is to be effected, 80 that the deposite may be everywhere equally thick. There are other metals besides zinc and iron that might be used to generate electricity thus, lead will reduce copper, silver, gold, and various other metals. When it is employed for electro-metallur- gical experiments we must form a soluble salt, of which the acetate and nitrate are most conspicuous. If we use nitrate of potash in the outer side with the lead, and a solution of metallic salt, say of copper, in the inner side, with the negative plate, the reduction will take place. It is vain to attempt to reduce a sulphate by this salt, for the sulphate of lead is absolutely insoluble. Its equivalent number is very high, one hundred and four of lead being equal to thirty-two of zinc, which is one serious objection to its use. Tin may be used to generate electricity, it being soluble in muriatic, sulphuric, acetic, oxalic acids, &c. It has a feeble force, requires a large plate, and thin porous tube. It is best used with dilute sul- phuric acid on one side, and the metallic salt, which should be a sulphate, on the other. It reduces Digitized by Google 440 ELECTRO-METALLURGY. several metals, but, unfortunately, has a high combining number, requiring fifty-eight grains to generate as much power as thirty-two grains of zinc. A solution of a salt of copper is to be placed in a convenient vessel, Fig. 1280, and the object N, on which the precipitation is to take place, is to be connected with the zinc of the battery Z, whilst a piece of sheet copper is connected with the silver S. As soon as action commences, water is decomposed, oxygen passes to the copper pole and oxydizes it, and the hydrogen passes to the negative plate. Whilst the decomposition is taking place, oxide of copper is passing to the negative pole, and the acid to the positive pole; the hydrogen reduces the oxide of copper at the negative plate, whilst the acid combines with oxide of copper at the positive end, and thus the saturation is continued. 1280. 1281. S N S Z S S A series of precipitating troughs, arranged like a compound battery, may be employed occasionally with only one battery. In this case, we should have one generating cell in the battery, and six, eight, or ten decomposition cells; therefore, by the fundamental laws to which the action of the galvanic fluid is obedient, we should have six, eight, or ten equivalents of metal reduced for one equivalent of zinc. Theoretically, this apparatus, Fig. 1281, exceeds every other in economy-practically, it has not been so much employed as it ought to be, particularly in the reduction of plain copper plates. The galvanic su- ries is made by alternating the metal C to be dissolved with the object m to receive the precipitate, the last mould being joined to the zinc Z of the battery, and the last copper with the silver S; the positive plates should be large, and the liquid rendered as conducting as possible to lessen resistance. It is im- portant in this apparatus that every positive and negative plate should possess nearly the same surface, and the solution the same strength, in order that the metal of the same quality should be reduced in each cell. Description of Fig. 1282.-A, the battery cell, M extending downwards 2 feet under the floor, and terminating in a point, in which a stop-cock is fixed, to draw off the saturated solution of sul- phate of zinc, which is formed there. The bot- h tom is reached by a trap-door and steps. 1282. B, the decomposing trough, resting on a keel, D which, for the purpose of agitating the solution, enables a rocking motion to be given to the S g trough, by means of a coupling shaft a connected with the truck b on which the trough is moved to any part of the room, for cleaning or changing the plate. K CC, conductors from the battery plates, each formed of five lengths of copper wire 1-10th of an inch in diameter, twisted together, and covered with water-proof tape, the one leading to the pos- h itive or dissolving plate c, the other to the nega- tive or receiving plate d, the latter being placed C on a board, with small feet or wedges, to keep it A at the proper distance from, and parallel to, the positive plate. D, a water-tight box containing a solution of sulphuric acid in the proportion of 1 to 4 water, by which the battery cell (having been originally charged with solution of the requisite strength, 1 to 30) is constantly supplied with renewed acid, through a lead pipe e which extends downwards into the cell about 2 feet, and is turned horizon- b tally 80 as to cause a circulating movement in the solution. The box is provided with a float f to indicate the height of the acid solution in it, and the quantity which has passed into the battery. In Fig. 1282 the acid box is placed near the battery cell for the sake of bringing it within the margin lines. It is nearly close to the ceiling, in Digitized by Google ELECTRO-METALLURGY. 441 reality, so as to afford by its height a considerable force to the solution issuing from the pipe, that it may circulate freely around the battery plates. For want of height in this Figure, it has also been necessary to omit a beam which passes along the side of the room nearly close to the ceiling, on which a small carriage and pulley travel, for the purpose of raising the plates and moving them to any part of the battery range. E, a gasometer, or gas collector, formed of thin copper, suspended by the wires g and the cord 12, which passes over the pulleys i i, and terminates in a counterpoise k, intended to balance in part the collector. which is placed immediately over the plates in the battery, and dips into the solution. It is furnished with a stop-cock I, through which the gas passes by the flexible tube m and copper pipe n to a gas meter o. F G, levers-the former, F, being attached to the plug of the stop-cock, having at one end a weight p and at the other a chain q fastened to the battery cell; the latter, G, turning in the same centre, and brought by a screw r at one end into contact with the under part of the former, F, and kept in con- tact with it by the pressing of the weight p. To its other end a small block of wood s is attached, dip ping into a waste-box t, and acting as a weight when the box t is empty, and as a float when the box is filled by overflow from the battery cell. H I, levers, drawn downwards by the weight of the collector, with which they are connected by the cord и. The former, H, turns on a pivot at the end of the latter, having at its other end a cord carrying a weight v which acts in the same manner as 8; the latter, I, carrying, as before mentioned, the lever H at one end, and having at the other end a spring w screwed to it, from which a wire, passing through the lever, deseends to the valve x for the purpose of raising the valve suddenly, being first closed upon the lever, until the adhesion of the valve to its seat is overcome, when the spring returns to its former position with a jerk, carrying up the valve, and opening the aperture at once to its greatest extent. K, a lever fixed to the bottom of the box D, having at one end a small hole through which the cord / passes, until checked by a knob y, when the other end rises and lifts a valve 2 in the bottom of the box t. Working of the apparatus.-The operation proceeds in the following manner. The aperture of the stop-cock 1 must be 80 adjusted by the screw r as to allow the gas evolved from the plates of the bat- tery to escape at the same rate as that at which it is generated, allowing a slight excess to resist the uncounterpoised portion of the weight of the collector, or its tendency to sink down. Then, when the quantity evolved is greater than can pass through the aperture, the collector will ascend till the lever F is restrained by the chain q, when the aperture will be enlarged till equivalent to the quantity evolved. On the contrary, when the quantity evolved is less than that for which the adjustment has been made, the collector will descend and pull down the levers H and I; the weight v will resist the end of the lever H, and the end of the lever I carrying the spring w will rise, and with it the valve x of the acid cistern, with a jerk; a quantity of the strong acid solution will then rush into the battery cell by the pipe e, with sufficient force to circulate round the plates, displacing a portion of the lighter or less acid solution, which will run off by the overflow pipe o into the box t, which thus becomes a meas- ure of the quantity of acid thrown into the cell. When the lever H then becomes released from the weight of the float v, the acid valve x preponderates, falls into its seat, and stops the supply. At the same time, the lever G of the collector is also released by the floating of the weight 2, and the aperture of the stop-cock completely closed by the weight p. The gas collector in this condition rises rapidly, till the knob y comes into contact with the lever K, when the valve 2 opens, and the solution in the waste-box t runs into a vessel placed for its reception, where its deficiency of acid is supplied, and it again returned to the cistern D. The waste-box t being emptied, the floats 8 and v again descend to the bottom of the box 8, carrying down the lever G, by which the aperture of the stop-cock is opened, and the apparatus is again in a position to throw in a greater supply of acid, if the energy of the bat- tery is not sufficient to evolve the quantity of hydrogen for which the aperture has been adjusted. Thus the power of the battery depends on the stop-cock, whose normal position is adjusted in the first instance to the required openness by the screw r; and the state of its working is ascertained by the quantities of gas which pass through the meter in equal times. The voltaic deposite of metal may take place upon any conducting substance, which is capable of acting the part of the negative metal, in the arrangement. The laws which relate to this, are the same which regulate, in a similar manner, the plates of the battery. The deposite may be effected upon most metals, except the earthy and alkaline, and upon any alloy or compound of them. It may, likewise, take place upon charcoal and plumbago. The following is a short list of substances which may be used to receive the deposite of metal Carbon In all metallic solutions, acid, Lead In all alkaline, in all but the neutral, or alkaline. preceding, saline and acid. Platinum do. do. do. Bismuth do. do. do. Gold do. do. do Antimony do. do. do. Palladium do. do. do. Tin do. do. do. Silver In all alkaline, in all but the Iron do. do. do. preceding, saline and acid. Zinc In some alkaline do. Copper do. do. do. Non-metallic substances. Sealing-wax In all saline or acid solutions; not in alkaline. White wax do. do. do. Beeswax and rosin do. do. do. Stearine do. do. do. Spermaceti do. do. do. Plaster of Paris, prepared do. do. do. Some animal substances do. do. do. Most vegetable substances do. do. do. 56 Digitized by Google 442 ELECTRO-METALLURGY. Now by the preceding table we perceive that some substances may be immersed in one solution with impunity, while others would be destroyed by its action on them. It is, therefore, important to know, when we have a substance which is acted upon by any metallic solution, how to make a reverse from it that shall not be injured. For convenience a table is appended, showing at one view the modes of preparing moulds of different substances. The perpendicular row is a list of the objects to be copied, the horizontal the means of multiplying them. Suppose the operator had a valuable silver medal, of which he was desirous of making a fac-simile, he would look in the table against silver, and would there find that he could make a mould, or reverse, in copper, by electro-metallurgy; but to this he would doubtless object. He would then see by what other methods he could also make a mould, and he would find that he could succeed with each of the processes given, and perhaps he would prefer plaster of Paris, as least likely to be injurious to his medal. Having made the mould in plaster, he would see from the former table, that when prepared it might be placed in any saline or acid solution of copper, to form the fac-simile. LIST OF THE PRINCIPAL MODES OF MAKING MOULDS OR REVERSES OF VARIOUS OBJECTS. STEARINE, SEALING- SPERMACETI, PLASTER OF METALS. COPPER. LEAD. ALLOYS OF LEAD. SULPHUR. WAX. WAX AND PARIS. COMPOUNDS. Copper by Electro- by percussion, Metallurgy. rolling. by clichee. by fusion. by fusion. by fusion. by mixture with water. Silver do. do. do. do. do. do. do. Gold do. do. do. do. do. do. do. Platinum do. do. do. do. do. do. do. Lead do. do. do. do. do. Alloys of do. by clichée. do. do. do. Tin do. do. do. do. Iron do. by Per- by percussion, cussion. rolling. by clichée. do. do. by fusion. do. Other Metals by Electro- do. do. do. Metallurgy. Sealing-Wax do. by percussion. do. do. Beeswax and Com- do. do. pounds Stearine do. do. Spermaceti do. do. Sulphur by clichée. by fusion. by fusion. do. Bread-crumbs by fusion. do. Plaster of Paris by Electro- Metallurgy. by clichee. by fusion. by fusion. do. Glue and whitening not. do. do. do. Animal subs by Electro- Metallurgy. some by clichée. { some by do. fusion. by fusion. do. Vegetable sub do. do. do. do. do. do. Gum do. Isinglass do. Siliceous bodies, by Electro- as Glass Metallurgy. by clichée. by fusion. by fusion. by fusion. do. Aluminous do do. do. do. do. do. do. Carbon, from its cheapness, from its indestructible nature, and from its being unaltered in all metallic solutions, is invaluable for electro-metallurgy. One variety of it, graphite, or plumbago, usually called black-lead, has a most extensive application, which we shall hereafter have occasion more especially to describe. Platinum, from its being unaltered by any solution, holds an important place for the reception of every metal its great price, however, must always be an impediment to its general use. Gold is equally valuable with platinum, but is still more expensive; yet when extended to that state in which it exists as gold-leaf, it may be applied over the surface of any soft substance, and thus a me- tallic surface is presented. This plan may be employed with other metals, such as silver or tin; but we have other methods which render all these modes unnecessary. Silver only reduces gold, platinum, palladium, and two or three more metals from these acid solu- tions, and therefore may be employed as a negative one for the reduction of metals. Silver-leaf of a thickness of about one square foot to the ounce, and made of pure metal, is much used by the forgers. The process they adopt is, to place the coin to be copied on a piece of wood, and upon the coin they place a piece of this thin silver. They beat it gently with a wooden mallet, till a perfect impression is taken on the metal, a result soon obtained. They then copy the opposite side of the coin in the same way. The two impressions are then soldered together, and the manufacturer sallies forth and risks his neck for the illicit shilling which has cost him this labor. The reader will doubtless have no inclination to practice this fraud, and, therefore, it is unnecessary to enter further into the process; but it should be borne in mind, that the same means may be employed with a better intention by the electro-metallur- gist, to obtain a mould. We have now to treat of the alloys of lead, tin, bismuth, antimony, and zinc, which demand especial attention, because there are means of casting these alloys, and of making reverses, moulds, and medals, by more ready methods than we possess for any other metals. It has been remarked that these alloys have melting properties, not only below the mean of the melting points of the respective metals which compose them, but even some of them considerably below the fusing point of the most fusible metal that enters into their composition. To some of these alloys we owe the manufacture of type, to others the process of stereotyping, to others that of polytyping or clichée. The composition of the type-metal is stated to be 1 part of lead to 16 of antimony, and sometimes a portion of copper is added this pro- Digitized by Google ELECTRO-METALLURGY 443 portion probably varies at each foundry as they generally consider that part of the business a secret Other compositions are given, as 6 to 2, 4 to 5, or 4 to 1 of antimony to lead. In the foundry there are a number of crucibles, each heated by a charcoal fire, one being allowed to each workman. To make a type, the operator takes a little of the melted alloy in a small ladle each time, and pours it into the mould which has the counterpart of the letter he wishes to make. The moment it is in the mould, he carries it suddenly upwards with a jerk, above his head, by which means the metal is forced into all the fine parts of the work, and a good impression is insured. Now we might expect that those who day by day work at this occupation, would attain to certainty in their proceedings; but this is by no means found to be the case, for they form a very large number of imperfect types which are obliged to be re- melted. I give this process to show that with those about to be detailed a strong analogy to coining is presented. In the first case, it is with a fluid, or semi-fluid, metal; in the last with a solid mass. The alloys which may be used for these purposes are very various, according to the object from which we desire to obtain a reverse, for as a great latitude is allowed in the fusing point, 80 at one time we prefer the more fusible, at another that which melts at a higher temperature. The following is a list of alloys which are employed by various authors, to which should be added all the compositions of type-metal last described, and as antimony possesses the property of expanding in the act of cooling, its alloys are well adapted for casting. Tin. Lead. Bismuth. Zinc. Tin. Lead. Bismuth. Zinc. 1 4 1 0 0 5 3 5 8 0 fuses about 212° Fah. 2 5 10 1 0 6 1 1 2 0 said to fuse at Fah. 200. 8 0 1 1 0 7 1 2 8 0 do. 200. 4 1 1 o 0 8 1 0 1 1 do. 200. All these compounds are used at a point between the fluid and the solid state, for at that heat they assume a pasty appearance, which is probably caused by the alloy consisting of two parts, one more fusible than the other. In fact, if we examine the mass very attentively, it appears to be composed of a quantity of perfectly solid metal in a fine state of division suspended in another portion of alloy per- fectly fluid. Having obtained our alloy in this state, it is ready for the process of making our reverse, and this process is termed the clichée. The alloy marked 1, 2, 3, 4, as well as the compositions for type-metal, will answer for iron, brass, copper, or other hard substances; perhaps No. 2 and No. 3 will be found, after type-metal, entitled to the preference. When we desire to clichée from wood, sulphur, or from another clichée, we must employ those alloys which fuse more readily, and Nos. 5, 6, 7, and 8 come into use. If hard metals are used from which to clichée, we should take care to clean them tho- roughly before using, and always employ them in a cool state. In using one clichée for making a second, we must take care to employ a less fusible alloy for the first than for the second; thus the type- metal and Nos. 1, 2, 3, 4, answer as a primary mould to make casts in 5, 6, 7, 8. To clichée from plas- ter of Paris, the material must be prepared either by linseed oil, gum, or gelatine, which processes will be described when treating of those substances, and sulphur moulds must be employed within a few hours of their manufacture. The simplest mode of making a clichée is to pour a little of the fused alloy on any flat surface, then to skim it clear with the edge of a card that the surface may be most per- 1283. fectly bright, after which we should wait till it is nearly at the point of cooling, when with a considerable jerk the ma- trix is to be brought down upon the alloy, by which opera- tion the fluid part will be forced out in all directions, and a reverse, equal in polish, sharpness, and beauty to the original, will be instantly obtained. If the alloy is used too hot, the surface is apt to present a crystalline appearance; it is there- fore very important that the object should be cool enough to make the alloy perfectly hard, as soon as the blow has driven the metal into all the finest lines. When taking a clichée from an intaglio the air has not always time to get away, in which case little holes or bubbles are very apt to be caused. The surplus metal round the edges of the mould so formed is then trimmed off in a lathe; but this operation is generally unnecessary for electro-inetallurgy. The Italians have a method of taking very perfect moulds with these alloys. They take a portion of the melted mass, and place it on a piece of paper; upon this they lay the medal, and under both a piece of carpet; upon the medal they place a log of wood, and then a sharp blow on the wood will ensure the sharpness of the cast. The worth of a cast thus made, is from sixpence to half-a-crown. I have before mentioned that clichée is nothing but a process of coining, and sometimes a sort of coining-press is used for these purposes; the medal or other object is fixed either by mastic or by screws on a piece of metal A, Fig. 1283, which descends with force on the semi-fluid alloy. Previously to the operation of striking, the object is suspended by a cord passing through a ring, and attached to the rod of iron connected with the piece of metal A. When every thing is ready, the doors are shut and the cord let loose, which allows the object to fall with great force on the metal. Digitized by Google 444 ELECTRO-METALLURGY. An impression may be given to a perfectly clean bright surface of sheet-lead, by placing upon it the object to be copied, and then with a steady hand dealing a heavy blow. By this mode even a sealing- wax impression may be copied, although this, at first sight, would appear hardly credible. By pres- sure alone, it would be difficult to obtain the result which can be given by the blow. Rolled lead, first scraped, in order to remove any oxide from the surface, and then flattened by running it through a press upon a polished iron plate, will readily take the impression of the most delicate work or engraving. The object to be copied is simply to be placed upon the lead, and then the two are to be sent once, and once only, through the printing-press, as in the ordinary operation for taking a print. The pressure in rolling is far greater than can be given by direct pressure, though there are instruments used by em- bossers capable of exerting great power. The disadvantage of forming moulds by rolling is a liability of distortion of the image from imperfect stretching of the metal. Non-conducting substances are of three kinds: substances having no affinity either for the metal or the solution; substances acted upon by the solution; and, lastly, substances capable of combining with the metal thrown down. Those of the first class are by far the most valuable, but are not very numer- ous. The best of these is sealing-wax-a composition of shell-lac, Venice turpentine, and coloring mat- ter. Dr. Ure gives, as the proportion in which these are used, four, one, and three. The manufacturers have several varieties, the most expensive of which is the best for making seals. Some of them are extremely hard, as for example, a black wax which is used for filling up the letters in the engraved plates of shop windows; but I do not know how a difference of composition can affect the properties of the wax in this important manner. The use of sealing-wax is attended with considerable expense, as good wax cannot be purchased under three and sixpence or four shillings a pound, but it takes impres- sions of objects of the greatest delicacy with the utmost accuracy. Every one uses this substance, and sealing is one of those operations in which every one thinks that he excels his neighbor in the manner in which he performs it; but, however well satisfied he may be with his skill in the small way, yet the management of large seals is attended with great difficulty and uncer- tainty. Proof-seals are made by engravers, by holding a piece of card over a flame, and rubbing, gradually, a stick of wax, previously softened by heat, upon the heated card, till a sufficiency is obtained, when the coin 1284. is to be pressed upon it. Very large seals are made by taking a good- sized stick of wax, and holding it in a flame, not only till the point, but even three or four inches of its length are lighted. It is then to be held over a piece of paper or card, when large drops of melted wax will keep falling, and in a short period a considerable quantity will be melted. The flame of the stick is to be blown out, and the fluid mass well stirred round and round, till all the air-bubbles are dispersed, and a clear sur- face of semi-fluid wax is exposed. It is now ready to receive the impres- sion of the object of which we are desirous of obtaining a copy. This is to be laid upon the wax, and pressed with considerable force, and lastly plunged into cold water, 80 as to cool it suddenly. Much less difficulty attends the use of a metallic die, for that abstracts the heat, and does not adhere. The accuracy with which sealing-wax takes impressions with care, is shown by its copying the lines on mother-of-pearl, and analogous substances which naturally possess the property of decomposing the rays of light; and the same colors which exist in the original are also to be observed in the copy. When we are desirous to obtain an impression in wax from wood or similar substances, they should be previously brushed over with a little salad oil. In these cases, by plunging the wax into cold wa- ter, its surface is apt to sink in places, and thus becomes uneven. Very large seals have been made of sealing-wax, by means of placing the mould on the semi-fluid composition, and subjecting it to hydro- static pressure. White wax may be used for taking casts, and can be procured with least expense by buying the waste ends of wax candles, which may be readily melted over a lamp. The object to be copied is to be very lightly oiled with a hog's-bristle brush previously dipped in that fluid. A moment's exposure of the medal to a current of steam, or even to the breath, will answer the same purpose, because a film of water, for which wax has no affinity, covers the medal, and therefore causes a separation between the wax and the metal. Electro-gilding, Plating, dc.-The infilming of one metal by another is a subject of much interest, and the process has received different names according to the metal employed for that purpose. Thus, when gold is used, it is termed gilding; when copper, coppering; silver, silvering, or plating, &c. In every one of these cases we have to be careful that the two metals adhere, and for this purpose we take means to prevent any film of air, oxide, or any non-conducting substance, from remaining on the first plate, as that would cause a separation between the metals. We apply heat, we scour the plate, or where it is possible, we slightly act upon the surface of the metal to receive the new deposite, taking care thoroughly to wash the metal after this operation. Electro-gilding is, in most cases, remarkably easy, for if care be taken to follow the laws which have been already detailed, it will be attended with very little trouble. The metal to receive the gold may be either platinum, palladium, silver, copper, carbon, gold itself, or indeed almost any other metal, when the auro-cyanide of gold is employed. The surface should be chemically clean, and freed from adherent air, either by plunging it into nitric acid or a solution of potash, or by heating it and then quenching it in acid. The smoother the surface the more favorably the deposite will take place upon it, for a very rough surface is not quite 80 well adapted for these operations, the hydrogen having a greater tendency to be evolved from it. When the metal to be gilt does not decompose the solution of gold, the solution may be stronger. When, on the contrary, the metal acts upon the solution, it must be weaker. The electrical current must be suited to these varying circumstances, and in general but a feeble current is required. Digitized by Google ELECTRO-METALLURGY. 445 For all cases of electro-gilding the auro-cyanide of potassium makes by far the best solution. It is scarcely decomposed by any metal. It may be prepared by digesting oxide of gold in a strong solution of cyanide of potassium. For our present purpose, a strong solution of the 1285. salt is to be preferred, and, from the corrosive nature of the cyanide of po- S 2 tassium, it should always be placed in a glass vessel. For gilding, the single- battery process will answer every purpose where time is not an object, and is indeed as a general rule to be much preferred; but if great speed is required the compound-battery, made of two, three, or four batteries, must be employed, or more cyanide of potassium must be added to the solution of gold. The size of the battery need never exceed the size of the object to be 9 gilded, though if it be larger it will not be of any material consequence, as a strong obstacle to the passage of the current is situated at the positive gold pole. The positive pole, as a general rule, should consist of a piece of pure gold flattened, and the part exposed to the solution should not exceed the size of the object to receive the deposite. Every portion of the object on which we are desirous to have no layer of gold, must be coated with tallow, wax, or any other non-conducting substance, the presence of which will prevent any deposite from taking place on those parts. In this way an object may be coated to any desired limit, or upon any circumscribed parts of its surface, as, for example, drawing or writing thereon. The rapidity of the process may be regulated to the greatest nicety by placing more or less of the positive plate of gold in the solution, by which means, as in other cases, the quantity of electricity passing may be regulated with the utmost precision. The time occupied for the process must vary according to the amount of electricity passing, and the quantity of gold required to be deposited; but the thickness of the deposite can at any time be learned, either by ascertaining the additional weight it has received, or by the reduction which the positive gold pole has suffered. To conduct this elegant process with the greatest economy of time, the quantity of electricity should be so regulated to the strength of the metallic solution, that the hydrogen is kept below its point of evolution from the negative plate; for we must always bear in mind that the evolution of hydrogen is attended with evil, as the precipitate will then be in one of the finely-divided states, or even as a black powder. During the process, particularly if the object have a rough surface, it is a good plan to remove it from the solution before the completion of the process, and rub it with a hard brush and a small quantity of whiting or rottenstone and well wash it; by these means any finely-divided metal will be removed, and the gold will be precipitated in a very even manner. This cleansing is not required when the deposition takes place very slowly from the auro-oyanide of potassium. The color of the gold, if the precipitated layer be very thin, will be a greenish yellow, but when thicker it will be the natural color of the pure metal The state of the surface of the reduced gold varies with the rapidity of the process, in relation to the strength of the metallic solution. If reduced very slowly, it will assume the beautiful frosted appear ance of dead gold. If deposited more rapidly, the surface will have a brighter appearance. If still more rapidly, the surface will again begin to be brown, and quicker than this the operator must not conduct his process; for then the spongy deposite begins, which the electro-gilder should shun as the very bane of his art. All objects of silver may be readily gilt in this way, and objects of copper with as great facility as those of silver. Some suppose, and, perhaps, with good truth, that copper articles require less gold than silver ones; the silver, when heated, having the property of taking into itself a certain portion of gold. However, copper is more difficult to bring into a thoroughly clean state than silver, especially in deep crevices. For those cases it is better to plunge the copper article into some acid solution of a metal which it can spontaneously reduce for instance, into dilute sulphuric acid, containing a trace of either nitrate of silver, chloride of platinum, palladium, or gold, the object of which immersion is not in any way to leave a deposite of the new metal upon it, but thoroughly to cleanse the surface. After this immersion the object may be washed, and as much of the reduced metal as possible rubbed off by means of a hard brush, when it will be found to possess a surface admirably adapted for the reception of the gold. If we have a number of small articles to gild, we may suspend them in the solution of gold opposite to the positive pole; and especial care must be taken that each part of the object is exposed for the same length of time opposite to, and at the same distance from, the positive pole; for any variation in this respect would cause a different thickness of gold to be deposited. The workman may be well assured, that if any article has an unequal coating of gold, it is owing either to some of the above causes, or that a different relative amount of the positive plate of gold radiated to the various parts of the object. An imperfect layer of gold betokens imperfection in the cleansing of the object before immersion. Electro-gilding is applicable from the finest platinum wire to any object however large, and no doubt the dome of the Capitol could be gilt as readily as a silver thimble if any person could place it in a proper apparatus. Whatever be the object to be gilt, it is highly important that every part should be entirely immersed in the liquid, or else that part at the junction of the air and water might be liable to be rapidly dissolved. The extent to which gold is applied to silver and copper articles is very great, and no variation is required in the process, except in those cases where the object itself may form a decomposition-trough- as silver vases, the bowls of large ladles or spoons, where it is only necessary to fill them with the solution of the auro-cyanide, which in this case should contain no free cyanide of potassium; connecting Digitized by Google 446 ELECTRO-METALLURGY. them by means of a wire with the zinc of a battery, and inserting a plate of gold in connection with the silver of the battery in the interior of the solution, taking care not to allow the gold and vessel to form a metallic contact; but even in these cases it is far better to immerse them entirely in the liquid, for reasons before stated. All these cases of gilding appear to be rather for appearance and beauty than utility; but sometimes metals are coated for the protection which the coat of gold affords: thus the hair-springs of chronometers have lately been gilt by this process, and patents have been taken out for its application-a circumstance to be more fully considered when treating of the history of electro- metallurgy. The gilding of iron and steel only differs from gilding silver and copper in the necessity to be careful to overcome the difficulty which occurs in most thoroughly cleansing the iron. It should be plunged into dilute sulphuric acid, and allowed to remain for a short time in that fluid before being immersed in the auro-cyanide; and if we wish most thoroughly to protect the metal from the action of extraneous causes, a tolerably thick layer of gold should be used. I am informed that the application of heat to the auro-cyanide favors the adhesion of the metals. Sometimes the operator is desirous of having his object bright, either entirely or partially, so 1286. that the bright and dead parts may form a contrast with each other. In this case the object is b dipped into a solution of soft-soap, to which a little prussic acid is added, thoroughly to cleanse it, when an instrument called a burnisher, b, Fig. 1286, which is nothing but a bright piece of steel, the shape of which is suitable to the object to be burnished, is rubbed over it two or three times; and finally the process is completed by a blood-stone 8 fixed upon a handle. The operation of burnishing is generally performed by women; and it is indeed remarkable that they should have learned the use of prussic acid for cleansing gold, which has been employed for many years, especially when we consider that the fact was not known to chemists at the time. It is worthy of remark, that the solution of soft-soap and prussic acid is admirably adapted for cleansing trinkets and all articles of gold when they have become dirty. The process of gilding by galvanic precipitation from a solution of gold, is very different in its effects from the method formerly patented by Elkington, termed water-gilding; by the latter process the metal which is to be gilt is dissolved in an equivalent proportion to the gold deposited, and therefore as soon as a mere surface of gold is obtained, it has been sup- posed that no further deposition can take place; but when the gilding is effected by the galvanic battery, any amount of gold may be applied upon the object; a consideration of no small importance, as upon the thickness of the coat must depend the durability of the gilding. It is not the solution of nitro-muriate of gold which is used for water-gilding, but a solution of the oxide of that metal in potash. The solution may be prepared by adding caustic, potash, or its car- bonate, to the ordinary solution of gold, in such proportion that the precipitate first formed is redissolved when it is fit for use. To gild any article, it is plunged, after being first thoroughly cleansed, into the hot solution, and allowed to remain in the solution till a thin coating is obtained, at the expense of a small quantity of silver. Platinating metals by the galvanic current is a new feature in science. The process is similar in all respects to gilding, but is more difficult. The best solution to be employed is the nitro-muriate of platinum, to which sufficient soda is added to render it neutral. The object to be coated should be smooth, and thoroughly cleansed by potash before the process is commenced. Having proceeded thus far, and the solution of platinum being ready, a fine platinum wire, in connection with the silver of a compound battery, must be placed so as to dip into the solution, but must not be immersed beyond a very short distance. The object to be platinated is now ready for connection with the zinc of the battery after this is effected it is to be dipped in the solution, Fig. 1287. Immediately oxygen gas will be given off from the platinum wire, in connection with the silver. From the copper or other metal to be platinated, no gas will be evolved, provided too much electricity be not generated. In a few minutes the object will be coated with platinum. This process must not be confounded with that by which negative metals are prepared for my battery for in this case the platinum is precipitated of the color and appearance of platinum, but in the latter case it is thrown down as a black powder. The first process I propose to name platinating, in contradistinction to platinizing. To platinize metals we use a strong current to throw down the metal in the black powder; to platinate we may employ solutions of any strength, but we must use more moderate currents, so that the electricity is insufficient for the production of hydrogen. There is no process at the present time more readily conducted than electro-plating. The best solution which can be used is without doubt the argento-cyanide of potassium. It is generally made by boiling the oxide of silver in a strong solution of cyanuret of potassium. The process which is most favorable is the single battery. The solution should be placed in a glass vessel, and used with a silver positive pole, about the same size as the object to be silvered. The same precautions should be taken and the same measures observed with regard to plating as gilding. The object should be clean, in order that a most perfect adhesion may be effected between the object to be silvered and the reduced metal The silver will be thrown 1287. down in somewhat different states, according to circumstances. If thrown down very slowly, it will assume a beautiful dead appearance; if still more rapidly, it will be brighter. It is, perhaps, as well to use the solution as strong as possible, and take care to stir the liquid occasionally, in order that a proper diffusion of the metallic salt may take place. As a precipitating-trough either the vertical or horizontal may be employed, according to circumstances; the latter is to be preferred for large surfaces, as waiters, and similar objects; in which case a corresponding large plate of silver should be used as the positive pole and placed over the object to be silvered. Sometimes a large circular silver posi- tive pole may be made to surround the object, as in the adjoining wood-cut. The Digitized by Google ELECTRO-METALLURGY. 447 silver pole is to be connected with the silver plate of a battery, exposing nearly as much surface as the object to be plated, while the object to be plated is to be connected with the zinc. A little free cyanuret of potassium, added to the argento-cyanide of potassium, hastens the process by increasing the solu- bility of the positive pole. The quantity of metal reduced can be readily ascertained, either by fiuding the additional weight of the object receiving the deposited silver, or by ascertaining the deficiency of the positive pole. Plated articles may be either partially or entirely burnished in the same way as gilt objects, according to the fancy of the operator; and the contrast of dead silver with the bright polished metal much increases the beauty of the object. Copper and its alloy are most readily silvered by this process. Non-conducting substances can be silvered by first black-leading them, then attaching a wire in such a way as to come in contact with the plumbago. In this case we should be careful to use rather a larger plate of silver than the object, as that favors the growth of the metal, but as a general rule it would be preferable to coat the object first with copper and then silver it. Electro-plating is of considerable advantage to the operator, for articles may be made entirely of copper, and even finished with laborious minuteness, and then silvered. The probability is, however, that electro-plated articles will not wear quite so well, in proportion to the thickness of the metal, as ordinary plating, for all metals reduced by electricity are found not to resist attrition so well as rolled metals. Electro-plating is a cheap process, independently of the intrinsic value of the silver used. A pretty application of the art of coppering is suitable to horticulturists, as by its means fruits, vege- tables, leaves, seeds, and various other specimens may be coated with copper, either for ornament or for the purpose of illustrating the size, form, and other peculiarities of the object. Apples and pears may be very readily coppered; they are to be brushed over with black-lead, and then 1288. a small pin is to be thrust in at the stalk; to this a wire should be attached, which s is connected with the zinc of the battery. It may then be placed in the solution, and the whole arrangement completed by the insertion of a piece of copper, which is to be connected with the silver of the battery. In a similar manner cucumbers, gourds, potatoes, carrots, and a hundred other vegetables, seeds, and roots can be covered. Fig. 1288 exhibits a bunch of grapes submitted to the action of the fluid to be electro-coppered. The form, after the process, is characteristic, and marks so strongly the individual character of each variety, that the horticulturist is at no loss to distinguish the specimens at once. A beautiful effect of metallic surfaces may be obtained by the deposition of crystallized metal on baskets. The wicker-work must be black-leaded, and con- nected by means of a wire to the zinc of a galvanic battery; when on being immersed in the metallic solution, and the circuit completed, it will be covered with the most beautiful crystals of copper, sparkling in the light from the facets of thousands of little crystals. It is well to pass a very fine copper wire round several parts of the basket, 80 that it may touch the black-lead in several places, for this will ensure the coating being more rapidly complete. In fact there is nothing organic or inorganic which will remain in a solution of salt of copper a few hours, that may not be coated with the metals. The foregoing electro-coppered objects are trifling compared to the purposes to which electro-cop- pering has been tried; for actually, experiments have been made to cover the bottoms of ships with that metal. To procure an electrotype copy from a page of type, we have to take an intaglio impression from the type, which is most conveniently effected by making a plaster cast, and afterwards rendering it non- absorbent, or we may take it in white wax; the intaglio impression must be black-leaded and placed in the solution to receive the deposite of copper. The horizontal apparatus is much to be preferred in this case, and great care must be taken to disperse air-bubbles. A moderately thin layer of copper would suffice, if it were backed with solder, type, or some such analogous alloy. This process is only likely to be useful for works that have a large circulation; and, probably, might be found to wear longer and print better than the usual stereotype metal; but at present we have no experience on that matter; though there is but little doubt that for these purposes electro-metallurgy will eventually be preferred. The application of the electrotype to the various departments of engraving, is of the greatest importance, and the new field opened in this branch alone, is very extensive. Engravings generally are made upon copper plates, which have undergone a tedious preparation. The copper which is to be employed for this purpose should be as pure as possible; it has first to be rolled to a certain thickness, after which it passes into the hands of the copper-plate maker. He carefully examines the plate, and picks out any little piece of foreign metal he may chance to perceive, and then fills up the gap by dex- terously hammering around it, 80 that he draws the neighboring copper over the hollow. The plate is then well hammered, and receives a rough polish by charcoal This copper-plate is by no means pure, as it generally contains tin and other metals, which render the engraving sometimes difficult, and the etching very uncertain. To obviate these faults we make an electrotype plate on one of the prepared copper-plates, and as the metal of this is absolutely pure, it is found to be far better adapted for the purposes of the engraver. This duplicate plate possesses a similar surface to the original, and may therefore be at once used; but it is found better to hammer the duplicate, and prepare it with charcoal, as that greatly improves it by making it more elastic; and it is the opinion of one of the first plate-makers in this city that the hammered plate will work as well as steel. On one of these electrotype plates, hammered and prepared as plates ordinarily are for engraving, a distinguished artist had various specimens of art executed. First, the plate-maker's opinion was taken of it, and he decided that it was vastly superior to the common copper. Here we may remark, that many persons have doubted whether the electrotype copper would bear hammering; now this plate was thus prepared. The plate was then sent to a letter-writer, to receive a specimen of this species of engraving, Digitized by Google 448 ELECTRO-METALLURGY. as well as to have his opinion of it; he stated that the quality of the copper was such that much less labor was required for the process which it had to undergo. It was then sent to an etcher, and he found it greatly superior to ordinary copper-plates; for the nitric acid bit with the utmost uniformity, on account of the purity of the copper. A specimen of machine-ruling, rose-engine turning, and medal- ruling was then executed, and the opinion of all the artists concerned in the work was similar; for the superiority of using pure copper over the ordinary copper, which is usually contaminated with other metals and charcoal, was apparent to all. The exact process by which these electrotype plates may be prepared, is very simple. The plain plate on which the deposite is to take place is to have a flat band soldered on its back, in order that efficient connection may be made with the zinc of the battery. The heat necessary to effect this drives off the air which infilms the metal, so that if it were placed at once in the solution of sulphate of copper the two plates would stand a very fair chance of adhering to each other. To prevent this serious evil, the plate which has been soldered ought to be placed in a cold place for twenty-four or more hours, which will enable it to regain a second time its film of air. Those who are not skilful in soldering metals may simply place a wire or piece of metal in contact with the back of the plate, as that connection will be amply sufficient. Every part of the plate which is not intended to receive the deposite, must be covered with tallow, wax, or any other non-conducting substance. Having thus prepared the plate, a platinized silver battery, which exposes about twice the surface of negative metal, is to be charged with dilute sulphuric acid, consisting of about one pint of strong sulphuric acid in two gallons of water. By using the acid thus diluted, the risk of much local action is materially lessened, and for the same reason the acid should never be poured into the battery till it is quite cold. Copying engraved copper-plates-Engraved copper-plates are not more difficult to copy than plain ones. A plate possessing the most elaborate design, the most brilliant conception, the finest execution, the most delicate workmanship, in fact every thing calculated to render a plate valuable, can be copied with the same readiness, the same fidelity, the same ease, as the plate without any workmanship at all; because the deposite of new metal takes place in such a way that an exact cast is made in both instances. The design of all engraved copper-plates is in intaglio, or depressed below the surface, and the problem is, to obtain a duplicate in a similar state. To effect this, a reverse of the plate must first be taken in relief. This may be done in various ways. In the first place a relievo may be obtained in copper, precisely in the same way as a duplicate plain plate. This is the most perfect process, and should always be adopted for very delicate designs. The multiplication of steel plates.-Steel plates can only be copied in a peculiar manner. They must not be placed either in the sulphate, nitrate, or muriate of copper, as certain destruction would ensue. I have heard of steel plates being thus destroyed, and therefore I particularly dwell on the fact to pre- vent its repetition. The crystallized acetate of copper is not decomposed by steel, though after the galvanic current has been passing for some time free acid is left, which is apt to attack the steel. A steel plate, however, undergoes no change in an alkaline ammoniuret of copper, ammonio-sulphate, or ammonio-nitrate of copper. From these salts, therefore, the copper may be thrown down upon the steel, but I am afraid that no advantage can be taken of the fact, as the reduction of copper by these means is attended with considerable difficulty. Under these circumstances we must have recourse to other methods of making a relievo duplicate from a primary plate of steel. This may be done in either lead, wax, plaster, or any other substance on which we can obtain a perfect cast, and from this a copper-plate can be again made in the same way. Besides these modes of making a relievo from a steel engraved plate, I have yet another plan to propose, which is even far superior to any yet detailed, and which, on that account, must supersede every other mode. This process of multiplication, which is so excellent, consists in first making a reverse in silver, and lastly, a second reverse in copper, which is used at once for printing. To effect this object the steel plate must be carefully cleaned from any adherent grease, and allowed to remain in a cold place twenty-four hours before using it. A strong solution of argento-cyanide of potassium must then be procured and placed in a stoneware or glass vessel. A piece of silver connected with the platinized silver of a battery should be next placed in the solution, and the size should be about the same as that of the steel plate. The last operation is to immerse the steel plate itself, which must not be effected before it is connected with the zinc of the battery. The process should be continued till the silver is sufficiently thick for removal, which operation must be performed in the usual manner. There are, perhaps, no processes in the whole range of electro-metallurgy more easy than this; for the silver may be obtained of excellent quality, and not the slightest adhesion will be found to exist between the original and duplicate; even the absolute polish of a highly-burnished surface will not suffer any injury from such a proceeding. It is hardly necessary to mention that this process is applicable to steel dies, punches, and every other kind of article, as no greater difficulty would ensue in conducting the operation. The only detriment to the formation of a silver relievo, is the expense of the metal, which in large plates would be considerable perhaps, in some cases, that might be diminished by giving a layer of copper; otherwise we must be careful, as soon as we have formed a second reverse of copper, to remelt our silver, and take especial care to suffer as little waste of metal as possible. The process, except in the great value of the silver, is profitable from the equivalent of silver being high. The multiplication of cood-cuts.-Civilized nations ought to regard the first application of wood-cuts with peculiar veneration, as they seem to have suggested the idea of printing. At the present time, however, wood-cuts demand especial notice, on account of the beauty of their execution; for they have now been brought to such perfection, that in minuteness and sharpness of drawing, I have seen speci- mens which fairly rival steel engravings. They might appear not often to require multiplication, because it is almost impossible to wear them out; 10,000, 20,000, 50,000, nay, even 100,000 impressions Digitized by Google ELECTRO-METALLURGY. 449 have been taken from one wood block. Still, however, a duplicate in copper is frequently required for various purposes. Wood-cuts are somewhat the reverse of copper-plates; for in the latter the print is obtained from the ink left in the hollows of the plate, but in the former the design is the most elevated part, and the impression is printed from the ridges. For the multiplication of wood-cuts and other analogous designs for printing surface-blocks, electro- metallurgy is useful in a variety of ways. Cuts that are used for a variety of purposes, where many persons design a separate block to print, the type-founder usually has the design cut in wood. This is coated at the back and edges with wax or grease, black-leaded, and immersed in the solution of copper in the usual way, so that an intaglio copper mould is produced. This mould may be used to make copper reverses, which are at once ready for the printer; or it may be used as a die to form clichée casts. In no application of electro-metallurgy is the value of the science more conspicuously shown than in a mode of producing surfaces for printing lately patented and called Glyphography. This branch of art forms an important feature in the general illustration of printed works, and on that account de- mands particular consideration. The term Glyphography has been given to this invention to signify that the original drawing itself is at once engraved, requiring no copying, and in fact scarcely any instruments, except those with which the artist makes his design. The mode in which so extraordinary an end is accomplished, appears very simple when it is detailed. The most essential part of the process is to make all the surfaces for printing as flat as possible, and for this purpose a plate of copper as used for engraving is first procured. This is blackened with the sulphuret of potassium, in order that the draftsman may be enabled to judge of the effect which his drawing would produce, as he proceeds with his work. This blackened plate is warmed, and then coated with a compound of burgundy-pitch, white wax, resin, spermaceti, and sulphate of lead, previously fused together. This composition, which is nearly white, must be uniformly spread over the plate, and the thickness should be about the one- thirtieth of an inch. The plate is now ready for the artist, who cuts through the white composition completely down to the blackened copper, and in fact with the exception of that precaution makes his drawing in the usual manner. In the selection of tools the artist should be guided by the manner in which they can completely and clearly cut out the composition; for it is important to make a clear indentation, and not to turn aside the coating and leave a burr. A simple hook fixed in a wooden handle, a hook filed away on one side, which most effectually cuts away the composition, or a piece of wood tapering to a fine point, are the forms particularly recommended. When the artist has finished his drawing, the parts of the composition which are removed leave black lines, which have precisely the same relation to the white ground as the black lines in the subsequent print have to the white paper. The plate upon which the design is drawn, in the manner already sufficiently detailed, is then sent back to the patentee to be treated differently, according as the artist desires an electro-glyphographic cast, or a stereo-glyphographic cast from which to print. If an electro-glyphographic cast is desired, and this is always to be preferred for very delicate and highly-finished drawings, the high lights are built up with any non-conducting substance, in order that they may not print. Where, however, the work is much thicker this process is not required, as the interval between the lines not being so great, the depression between the lines need not be so deep. The plate is then placed in the metallic solution, and an electro-cast is taken in the same way as in duplicate copper-plates, dc. As soon as this is finished, the back is soldered and mounted upon a block of wood or to a piece of metal. The block is at once ready for printing, and with the moderen improved system of overlaying now adopted by wood-cut printers, the print is an exact copy of the original drawing. All our previous operations have been conducted at the negative pole of the battery; but at the pos- itive pole certain effects take place which may be taken advantage of in the arts. Let us call to mind the fact, that gold, silver, and all metals with a greater affinity for oxygen, are dissolved when made the positive pole of a cell charged with a solution of the same metal. Now the relative distance which is maintained between the positive and negative poles affects the degree of solution which takes place. This property may be easily shown by attaching a wire by one of its ends to the silver of the battery, and placing the other in a solution of sulphate of copper, in the bottom of which a piece of cop- per connected with the zinc of the battery is immersed. After a short time, the wire will begin visibly to be dissolved, and the part nearest the negative metal will be affected; this will go on till the wire is dissolved, in such a manner that the part nearest the negative metal will diminish to the sharpest point. and the different amount of action will produce a perfect taper. Although this property is of no value in its application, yet I have introduced it to show the facility with which the copper in every place is dissolved exactly in proportion to the electricity passing and this is likely to be extremely valuable for engravers in their etchings. The term etching, is given to those engravings where the lines are not cut by any instrument, but are dissolved out by an acid. In order to make an etching, a copper-plate is first to be prepared by covering it with a substance which protects it from the action of the acid in which it has to be immersed. The substance used for this purpose is composed of asphalte and wax in equal proportions, combined with a fourth part of both black pitch and burgundy-pitch. This mixture is placed in a piece of silk, and rubbed over the copper- plate, which is kept at a moderate heat, by holding it over a lamp or chafing-dish. This operation is technically called laying a ground; this at first is colorless, but it is afterwards blackened by holding it over the flame of a candle, and depressing it till a copious supply of smoke covers the surface. The engraver, with an instrument like a needle, called an etching-point, executes his drawing, and in so doing removes the ground, and exposes a clean surface of metallic copper. The plate is then placed in a dish, and dilute nitric acid poured upon it, till the copper is dissolved out from the exposed lines to a sufficient depth. The plate is not allowed to remain in the acid a sufficient length of time to bite deeply, as this would cause the engraving to be of one degree of blackness; but after it has been in the acid a short time, those parts which are required to be of a light shade are stopped out, that is, they 57 Digitized by Google 450 ELECTRO-METALLURGY. are covered with brunswick-black, or a coat of varnish capable of resisting the action of the acid. The plate is then replaced in the dilute acid after a time it is again removed, and a further portion is stopped out and these operations are repeated as many times as there are differences of shade required in the engraving. The degree of perfection that the professed engraver obtains by practice is truly extraor- dinary, considering the uncertainty which must attend the operation; for the action of nitric acid is not subject to any regular laws, and moreover is never alike over all parts of the same plate. This is ow- ing to the copper-plate itself being never pure; but always containing tin, dispersed here and there throughout its texture, which resists the action of the acid. After a splendid plate is bitten in, some portions are sometimes left which cannot be acted upon by the nitric acid, but absolutely require the graver to bring up the fine lines. No engraver that I have conversed with, can explain the cause of these faults in their work, but to the chemist they are perfectly intelligible the nitric acid attacks the copper, forming a soluble nitrate of that metal which is dissolved in the fluid; but the action of nitric acid on tin is altogether different, for it converts the metal into a peroxide, which, being insoluble, protects the copper from the acid. The engravers have always noticed this white powder, (the peroxide of tin,) so fatal to the success of their operations. Etching by galvanism is a far more certain operation than the foregoing, because it can be reduced to known principles. In this case, the plate to be bitten in has the device first drawn upon the same ground that is used in the ordinary process; the back and edges of the plate are then coated with wax, and it is to be connected by means of a wire with the silver plate of one or two of my batteries. The piece of copper to form the negative pole should then be connected to the zinc, when both the copper-plate and the piece of copper are to be placed in a solution of sulphate of copper. Immediately copper will be reduced from the solution on the negative plate, and copper from the etching-plate will be dissolved to keep up the strength of the solution. Whatever is favorable to the increase of electricity, causes the copper to be more quickly acted upon, and whatever diminishes the galvanic current, retards the solution of the metal; the nearer the etching plate forming the positive pole, and the piece of copper forming the negative are approximated, the more rapid will be the action. In the same way, the intensity of the battery also affects the rate at which the plate is bitten in. The negative plate of copper, however, should not exceed in size the cop- per-plate on which the etching is executed, or else there is a risk of some of the lines being more deeply bitten in; and in like manner, if any considerable part of the plate has a great deficiency of lines com- pared with other parts, that part must be stopped out rather before the other, to ensure a uniformity of depth, or else the negative copper opposite this part must be bent in such a way as to increase the dis- tance. The advantages of galvanism for etching, are, the absence of poisonous nitrous fumes, which are evolved in the ordinary process; the greater uniformity of action which takes place than when acids -are used; and the rapidity of biting, which may be regulated to the greatest nicety. The lines may be made of any depth, and are sharper and cleaner than when acid is used; and lastly, no bubbles are evolved, which the engraver well knows are apt to tear up the ground, or to cause unequal action. The exact quantity of copper dissolved from the plate, can be ascertained by weighing the metal reduced on the sheet of copper which forms the negative pole, or by measuring the quantity of hydro- gen evolved from the silver plate of one of the platinized silver batteries for thirty-two grains of cop- per will be dissolved for every forty-eight cubic inches of gas evolved. Etching by getbvanism can be executed with any desired degree of rapidity, according to the series of batteries to which the plate is connected; but I believe that the practical man will find that the action should neither!b too slow nor too quick, and perhaps two or three batteries, arranged as a series, will be found best adapted, though a single cell would suffice. Galvanism-would be valuable to the engraver for executing gradations of shade, such as, for instance, the effect of a strong light illuminating a whole room. The most simple manner in which this can be shown, is to take a copper-plate and draw a number of lines on the ground with a ruling-machine. The plate, after having its back and edges coated with any non-conducting substance, should be then connected with the silver of the battery, and copper wire. These two should be then arranged in the solution of sulphate of copper, that at one end they nearly touch, while at the other they are widely apart. By this position, the greatest quantity of electricity would pass at that part of the plate where it is nearly in contact with the negative pole, whilst the least would pass at the opposite extremity. The action on the etched plate being exactly in proportion to the quantity of electricity passing, is un- equal over the whole length of the plate, being greater where the metals are nearest, and gradually diminishing to the other end. This is the most perfect mode by which it is possible to obtain a grada- tion of shade. Many variations in the arrangements might be made by using, as a negative plate, a wire or a rod of copper, placed over the centre of a prepared plate; for then a perfect gradation would be obtained, extending in all directions from the dark centre. In the same way, two or more radiating shades may be obtained, by using two or more negative wires. An insensible gradation might be made from the darkest shade at the external edge of the plate, to the lightest point at its centre, by cutting out a hole in the negative piece of copper, opposite to the part where the transition into light is re- quired. The professed engraver who once practically masters the galvanic method of etching by the theoreti- cal principles which I have here detailed, is sure to obtain great results. He could execute with ease the most extraordinary transition of light into darkness with fidelity, and with the utmost certainty. However, I trust that the value of electric etching will not be confined to the artist; for, by removing the disagrecable consequences attending the use of nitric acid in the present mode of etching, more per- sons may be induced to enter into it, and, by this means, numbers studying the sciences will be enabled to exccute an etching of those objects which are curious and rare, to send to their brethren who are stu lying the same subject. Those travelling in foreign countries, or in picturesque situations, might Digitized by Google ELECTRO-MOTIVE ENGINE. 451 transmit to their distant friends an idea of the sublimity and grandeur of the scenery which they are enjoying, or of the appearance of the towns and villages through which they are passing. In fact there is not a person who might not be benefited by receiving etchings from others, and who might not, in return, circulate engravings of those objects which he may see. Pictorial representations are avowedly better than any verbal descriptions, 80 that there is ample scope for any one to exercise his talents use- fully; and certainly many cannot be aware that etchings are not more difficult to execute than common pencil drawings. The process is as suitable for ladies to practise in their drawing-rooms, as are any of their usual amusements; the operation being attended with as little trouble. It is necessary at first to have the plate prepared, or have a ground laid, (which might be done by a workman,) and at the con- clusion of the drawing it has to be bitten in. The objection to this, hitherto, has been the disagreenble properties of the acid, as it is likely to spoil clothes or injure furniture; but now that these objections are removed, I trust that numbers will enter into this amusing and useful branch of art. Galvanic etching has lately extended to the etching of Daguerreotype plates. The silver plate is arranged as the positive pole in a trough, by connecting it to the negative plate of a battery. The sil- ver plate is about the same size as the Daguerreotype; but I believe that we should be able to bite much deeper by following the improvements in galvanic etching. It is stated that these etchings when printed showed extraordinary minuteness of detail. There are purposes besides electro-metallurgy for which the galvanic force is applicable to the wants of mankind, and of the most conspicuous of these is the mode of blasting in mines and under water now adopted. The barrel, Fig. 1289, in which the pow- 1989. der is placed has a hole bored in it, so that it may admit a copper tube t. This cop- per tube has a plate soldered to it at the upper part by which it may be fastened by copper nails to the cask a plug H is fixed in the tube, through which two cop- per wires are inserted, and round the end H of the wires is wound a fine piece of TT platinum wire p, so that but a single fila- ment extends from wire to wire; the rest of the tube is filled with fine powder, and a piece of cork c is placed on the other end. This copper tube is then carefully secured water-tight by smearing pitch round the copper. For securing the tube and wires in their place, the ends of the two copper wires are bent and nailed to the tub. The next thing is to fill the tub with blasting-powder by another hole, and then secure the aperture wa- ter-tight with a wooden plug, which is afterwards smeared over with pitch. The cask is then lowered to the bottom of the vessel, and placed in the situation where it is destined to act. A rope, previously made by procuring two wires first covered with cotton and varnished, and twisting them with the texture of which the rope is made, is then lowered to the bottom of the sea, and the ends of the two wires communicating with the tube are tightly lashed to the two wires in the rope. All these things being ready, the ends of two wires at the other extremity of the rope are connected with the two extremities of a small compound platinized silver battery, when, immediately on contact being made, the explosion takes place. ELECTRO-MOTIVE ENGINE Description of the Electro-Motive Engine-constructed on the supposed principle of muscular power. At a meeting of the Medico-Chirurgical Society of Aberdeen, July 6, 1848, W. Fraser, Esq., read a paper on the subject of the Electro-Motive power, of which we give the following extracts: " Having several years ago had an opportunity of seeing a number of electro-motive machines of various constructions, I was much struck by observing the extreme weakness of the power rendered available for practical purposes by the different mechanical arrangements employed, compared with the tremendous force actually exerted, under certain circumstances, by the moving power made use of. An electro-magnet, which would, within its proper sphere of power, attract to itself, and retain suspended, a weight of many tons, could not be made to perform the twentieth part of the labor of one horse. " I shall not occupy your time by describing those arrangements, but come at once to the description of one upon an entirely new principle, which 1 have carried into effect with the happiest result, and of which the idea was suggested by the mode in which the muscular force appears to be exerted in our own body. " It has for some time been a current belief in physiology, that the contraction of muscles is produced by the mutual attraction of minute cells, arranged in parallel lines, of which the ultimate fibrils of the muscular tissue consist. The stimulus that excites this attraction, is the vital electricity, transmitted by the nerves, and brought to bear upon the muscular globules by means of the ultimate nervous filaments, which interlace among them, and form a network, 80 as to complete the circle or current of nervous in- fluence of which the prime motor is the brain. The aggregate of these minute movements gives the extent of contraction of the entire muscle; the combined force of these molecular attractions, its full power or strength. The following extracts and figures, from Dr. Carpenter's Manual of Physiology,' will place the sub- ject more clearly before us:- When the fibrillæ are separately examined under a high magnifying power, they are seen to pre- sent a cylindrical or slightly beaded form, and to be made up of a linear aggregation of distinct cells. We observe the same alternation of light and dark spaces as when the fibrillæ are united into fibres or Digitized by Google 452 ELECTRO-MOTIVE ENGINE. into small bundles: but it may be distinctly seen, that each light space is divided by a transverse line, and that there is a pellucid border at the sides of the dark spaces, as well as between their contiguous extremities. This pellucid border seems to be the cell-wall; the dark space enclosed by it, (which is usually bright in the centre,) being the cavity of the cell, which is usually filled with a highly refracting sub- stance. When the fibril is in a state of relaxation as seen at a, Fig. 1297, the diameter of the cells is greatest in the longitudinal direction ; but when it is contracted, the fibril increases in diameter AS it diminishes in length, 80 that the transverse diameter of each cell becomes equal to the longitudinal diameter, as seen at b, Fig. 1297, or even exceeds it. 1292. 1291. 1290. 1293. The diameter of the ultimate fibrillæ will, of course, be subject to variations in accordance with the contracted or relaxed condition; but it seems to be otherwise tolerably uniform in different animals, being, for the most part, about 1-10000th of an inch. The average distance of the striæ, too, is nearly Digitized by Google ELECTRO-MOTIVE ENGINE. 453 uniform-about 1-10000th of an inch in different animals, though considerable variations present them- selves in every individual, and in different parts of the same muscle.' " On the subject of the arrangement of the nerves and tendons in connection with muscles, the same authority says, The muscles of animal life are, of all animal tissues except the skin, the most copiously supplied with nerves. These, like the blood-vessels, lie on the outside of the myolemma of each fibre, and their influence must, consequently, be exerted through it. The arrangement of these nerves is shown in Fig. 1296. Their ultimate fibres or tubes cannot be said to terminate anywhere in the muscular substance; for, 1296. after issuing from the trunks, they form a series of loops, which either return to the same trunk or join an adjacent one. The occasional appearance of the termination of a nervous fibril, is caused by its dipping down between the muscular fibres, to pass between another stratum. Every muscular fibre, of the striated kind at least, is at- tached at its extremities to fibrous tissue, through the medium of which it exerts its contractile power on the bone or other substance which it is destined to move. Thus the whole mus- cle is penetrated by minute fasciculi of tendinous fibres, and these collect at its extremities into a tendon.' " Of the anatomical arrangement now described, the electro- motive machine here presented is as close an imitation as possible: it consists of a number of electro-magnets opposed endwise to one another, arranged in parallel lines, and con- nected together by fastenings in such a way that, when made to act simultaneously, their united force can be brought to bear upon one point." The annexed figures will give an idea of the apparatus, both in a state of repose and of action. Fig. 1290 represents a series of eight rectangular prisms of soft iron, one and one-eighth of an inch long, by a quarter of an inch square, placed endwise, at the distance of one-twelfth of an inch from one another. Fig. 1291 shows the same in close contact. Figs. 1292 and 1293 represent the prisms in the same relative position, but armed with a continuous covered copper wire, and connected together in such a manner as to admit of free motion within a limited extent. Each prism has covered wire, about one-twentieth of an inch thick, wrapped around it closely and regularly, in three layers, and, before being carried to the next prism or magnet, the wire is extended out for about an inch and a half at right angles to the prism, and bent back again at an acute angle, by which means the resistance it offers to the motion of the magnets is almost entirely overcome. The prisms or magnets, with their opposite poles to each other, are connected together by ligaments of catgut, the length of which can be 80 graduated, by twisting them by means of a small pin, (which can be fixed by having its end inserted among the wire,) that any distance that may be necessary can be assigned as the limit of motion to the magnets. It is proper to mention that the prisms are all bound together by two bands of vulcanized india-rubber, in close contact with their opposite sides, and sufficiently on the stretch to overcome entirely the weight with which, when hanging perpendicularly, one part of the apparatus would bear upon the other. 1295. 1294. The advantage of the arrangement now described is, that as the same current of galvanısm is equally efficient in rendering many prisms magnetic as one, and the motions produced by the magnetic influence are, by the way in which the prisms in the apparatus are connected together, communicated from the one to the other, and all accumulated or brought to bear at the end of the series, the amount of power gained is just the attractive power of one prism multiplied by the number in the series, deducting, of course, the resistance to be overcome by removing the additional number of magnets.* * # The apparatus above described, which weighs five and a half ounces, with the aid of a moderate battery lifts a pound and a half a distance of nearly half an inch. Its action is almost instantaneous; and the shock with which it becomes rigid or relaxed, as the stimulus is applied or withdrawn, reminds one very forcibly of the spasmodic action of a muscle. Digitized by Google 454 ELECTRO-MAGNETIC ORE-SEPARATOR. Supposing one electro-magnet to be capable of raising three pounds one-twelfth of an inch by com- bining 96 of them into one chain or series, in the way shown in the model, there would be attained a power of raising three pounds a distance of 96-12 of an inch, or 8 inches; but allowing the additional magnets and their appendages to weigh one pound and to be provided with no counterbalancing arrange- ment, then it is evident that the actual power attained would be only that of raising two pounds a height of 8 inches. But by combining 100 such columns, each containing 96 magnets, there would be attained a power of raising 200 pounds 8 inches, or 100 pounds 16 inches, or 50 pounds 32 inches, &c., according to the manner in which the combination was made. Figs. 1294 and 1295 show how the chains of magnets might be combined into a compound machine; one end of them being attached to the fixed beam a, near which the battery is placed, their other extremities being fixed to the moveable beam b, from which any motion required could be easily taken. In Fig. 1294 the magnets are in a relaxed state, their connection with the battery being broken; while in Fig. 1295 they are in a state of contraction, the circuit of wire which connects them with the battery being complete. By combining a number of such frames together, all connected by the same wire, and by 1297 augmenting the strength of the battery, any degree of power might be obtained, and, as in a the steam-engine, the apparatus might be easily made self-governing in its action, by having a small cup of mercury with which one of the wires was connected, placed, say at c, Fig. 1294; the other end of the wire could be made alternately to dip into it and emerge from it by means of a pendulum, so as to break and restore the connection, and thus keep the machine going with any degree of frequency that might be required. Upon the whole, it is evident that the power of such an apparatus would depend upon the perfection of its mechanism. And as the force of the attraction of electro-magnets increases prodigiously as their distance diminishes, (see Robert Murphy's Elementary Principles of the Theory of Electricity,) it follows that the smaller and more numerous the component magnets of the machine could be made, the greater would be the power attained. But in this respect, it is not to be expected that human ingenuity could ever be able to reach, by many hundred, we might say thousand, degrees, the minuteness of the muscular tissue. Yet even if the motive power attained were only a five-hundredth part of that which muscle can be made to exert, in proportion to the weight of the apparatus, this would be a very great advance upon the results that have hitherto been arrived at in this department. Though, undoubtedly, it will be long before electricity be brought even to compete with steam as a source of mechanical power, yet such a result need not be looked upon as chimerical Another necessary step towards this consummation, besides the perfecting of the mechan- ical arrangement, would be the discovery of a cheap source of galvanism one whose price would not exceed that of the fuel employed in the production of steam. But that the very same source from which steam is obtained may be made available for the generation of elec- tricity, is proved by recent experiments; though whether in a form suitable as a source of electro-motive power, yet remains to be ascertained. ELECTRO-MAGNETIC ORE-SEPARATOR: Cook's. The machine represented in Figs. 1298, 1299, and 1300, was invented by Ransom Cook, Esq., of Clinton county, N. Y, and employed for the separation of the magnetic ore. The principle of this invention consists in charging successively, by a battery, different rows of magnets on a revolving cylinder, 80 that the magnets shall lift magnetic ore 1298. N from an endless web as it passes under the cylinder; and SO also that when the ore is lifted up a short distance the electric connection shall be broken with the magnets, and the ore then drop from them into the trough, and be discharged into a proper receptacle. Digitized by Google ELECTRO-MAGNETIC ORE-SEPARATOR. 455 Fig. 1299 is a side elevation of the machine ; Fig. 1298, a top plan; and Fig. 1300, a sectional view. A A is the frame. B is a pulley by which the cam-shaft C is revolved. This shaft, by the cam C, shakes the hopper F so as to spread the ore evenly across the endless web or carrying apron H. This is done by having a hook-rod K that catches the upper edge of C, and is made, from the shape of the cam, to traverse across the web, and spread the ore equally on the web. D is the revolving magnet cylinder, driven by band and pulleys ONP. L is the trough into which the ore is discharged from the cylinder. X X are mercury troughs, the one charged positively and the other negatively from the battery, by the wires MM. The magnets are fixed on the revolving cylinder, and wound round with copper wire, the one positive and the other negative. These wires are carried from one magnet to another across the row, and brought out at the axle of the cylinder, forming a circular fan E, 80 that as the cylinder revolves, and the wires dip into and rise from the charged mercury troughs, the rows of magnets are charged and broken alternately, to lift the ore from the dross and deposite it in the receiving troughs. D 1299. M L H B H The magnetic cylinder revolves to meet the ore as it comes forward on the web, and in the same direction. TT are the magnets. M represents the wires from the battery. The large cylinder is revolved by a band from the other side, passing over a pulley on the shaft of D, the magnetic cylinder. The cylinder is made of wood, a non-conductor; and to insulate the wires perfectly, the axle of the cylinder is boxed with wood, and wires turned up on the outside of it. 1200. E E D Ln TI T Fig. 1300 shows the manner in which the magnets are arranged on the cylinder. D is the cylinder; TT the magnets; E the current wires; and X the trough of quicksilver. The cylinder is about 30 inches in diameter, and the magnets are about I of an inch thick, with four polar points. There is a space of about 1 of an inch between each of the magnets, and a large cylinder has had thirty rows of ten magnets each. It will be observed that the wires are alternately wound in the direction of the polar currents. One wire is now represented as dipping in the mercury; but one-fourth of all the magnets are charged at the same time, as that number touch the mercury on the under side of the Digitized by Google 456 ELEVATORS. cylinder; but the magnets are charged and discharged successively in rows. The ore is carried forward on the endless apron; and the magnet cylinder, by revolving in the same direction as the apron, lifts the ore, while the dross is discharged from the apron while passing over the roller. This machine has been in operation at Plattsburgh for some time, where it is stated to have exceeded the most sanguine expectations. When ore is associated with hornblende no other process of separation can, it appears, compare with this. 1301. a 1302. R a O 1303. 1306. 0 SCALE.-8 feet=1 inch. & 1304. I & 1305. CL ELEVATORS. The general term Elevator includes gins, windlasses, cranes, &c.; but since these are described under their separate heads, in this article are comprehended only those smaller machines employed to raise materials in mines, furnaces, factories, and corn mills. Digitized by Google ELEVATORS. 457 Figs. 1301 to 1303, a vertical elevator, moved by hand. Figs. 1304 to 1306, a similar one, driven by steam or water-power. Figs. 1307 to 1316, a single elevator working on an incline with an endless chain. Figs. 1317 to 1321, a similar one, with a rope. Figs. 1322 to 1325, a similar one, but double. 01 a R 1307. B 1309. SCALE.-9 feet=1 inch. 1315. 1316. A A 1314. 1308. Hh DO 0 DO 9 0 00 1310. 1311. DO A 1312. 1313. Figs. 1326 to 1328, an elevator moved by condensed air or a pneumatic engine. Figs 1329 to 1333, elevators for corn-mills. Figs. 1334 to 1337, elevators for factories. Figs. 1338 and 1339, elevators for general purposes. 58 Digitized by Google 458 ELEVATORS. A vertical Elevator, moved by hand.-Fig. 1301 is a side elevation; Fig. 1302, a front elevation; Fig 1303 a section on the line a b. The weight to be raised is placed on the platform a of the frame a e. which, moving between the posts c 6, is retained in position by grooves in a and e, as shown clearly in the section, Fig. 1303. The platform is raised by the winding of the chains or ropes attached to the frame at f, on the barrel h, which, if the weight is trifling, is turned by a winch on its own shaft, but more commonly an extra shaft i, geer l, and pinion k, are employed with the winch m ; two ratchet- wheels q r and catches 8 and t hold the platform in any desired position. A counterpoise P is attached by the rope o, passing over the pulley n to the barrel h. A vertical Elevator, driven by steam or water power, used in the iron-works of Belgium.-Fig. 1304 is a front elevation; Fig. 1305, a side elevation; Fig. 1306, a plan of the lower part. The parts are as follows: The standards c and d support a lower shaft a and upper b, to each end of which are fixed the iron wheels e e, of about 71 feet diameter and 7 inches wide, cast with projections ff, adapted to the links of the endless chains gg; at distances of about 5 feet the two chains are connected by iron rods h h h, from which depend the platforms k, on which are placed the loads to be raised or lowered. These weights can be put on or taken off while the machine is in motion, and if from neglect the load is not removed, the only result is that it continues to ascend and descend with the revolutions of the wheels c e. Motion is communicated through the shaft p, the pinion m, and the geer z, fixed to the shaft a: q is a slide coupling; 00, standards of the shafts p and n: and и a pit or span necessary below a, for the passage of the platforms. An Elevator working on an incline, with an endless chain, used at some of the blast-furnaces of Belgium.-Fig. 1307 is the side elevation; Fig. 1308, the rear elevation; Fig. 1309, the plan. A A is the bottom, and BB the top platform; CC the railway, inclined at an angle of about 30°, and supported by the frame DD. The wagons are drawn up by the endless chain a a a, resting loosely in the wheels bbcc, to which last motion is communicated through the geers e and f, and the pulley h, over which passes a band i from the prime mover. Figs. 1310 and 1311, represent two views of a portion of the wheel cc; Figs. 1312 and 1313, of the wheel bb; Fig. 1314, of the chain. It will be seen that there is but one row of projections kk on the rim of the wheel c, fitting the openings m of the links of the chain, while on b the row is double, and is adapted to the spaces n n of the chain. The loaded wagon being brought to the bottom of the incline, the hind axle is caught by one of the hooks g, (which are about 9 feet apart,) and is drawn up. At the top the wagon is received on a small descending railway, inclined at an angle of about 5°, and whose summit is sufficiently above the plat- form BB, that gravity alone will carry the wagon to its place of unloading. The emptied wagons are placed on a side track $ s, and are lowered by means of a rope attached to the windlass tt, Figs 1308 and 1309. Along the railway 00, and at a distance of from 5 to 6 feet, are placed the moveable catches or bell- levers и, which, in case of the breakage of the chain, will catch the hind axle and stop the descent of the wagon. The wagons used in Belgium are composed of cast and wrought iron, and the materials for supplying the furnace are first put in plate-iron vessels, (holding from 30 to 40 pounds, and of the form repre- sented in Figs. 1315 and 1316,) and then placed in the wagons, which contain from 12 to 18 of them. An Elevator working on an incline with a pulley-rope.-In blast-furnaces, where only charcoal is used, the elevator, represented in Figs. 1317 to 1321, is frequently employed. Fig. 1317 is a side view Fig. 1318, a plan; Fig. 1319, a section on the line B; and Figs. 1320 and 1321 are details. The principal axis k1, Fig. 1320, is at k, where the drum I is cylindrical, and at k, squared. On this part is placed the moveable wheel m, with the knobs n n, which are inserted into corresponding holes of the drum 1, whenever this latter is to follow the movement of the axis k k1. In the periphery of the wheel is carved a groove, into which fits the quadrant o, Figs. 1317 and 1320, wound like the worm of a screw, and fixed to the shaft p. To this shaft is also fixed the disk q, Figs. 1317, 1320, and 1321, on whose periphery is placed the bar rr, which is joined to it by the counter-chains 8 and t, Fig. 1321, in such manner that the wheel, together with the shaft p and quadrant o, is alternately turned to the left and to the right, according as the bar is pushed backwards or forwards. By this the wheel m is either moved on or off the drum 1, and consequently the latter is brought in or out of connection with the axis k k₁. A double Elevator working on an incline with pulley-ropes.-At blast-furnaces, where the smelting of the ore is effected by means of coke, and large quantities of iron, stone, fuel, and other supplies are to be conveyed up to heights of 30 or 50 feet, several of these elevators are applied. On the inclined plane, forming an angle of 30 or 40°, are two railways, parallel to each other; the one serving for the ascent of the charged wagon, and the other for the descent of the empty one. An elevator of this kind is represented in Figs. 1322, 1323, 1324. and 1325. Fig. 1322 is a side elevation; Fig. 1323, a plan; Fig. 1324, a front elevation; and Fig. 1325 represents the principal axis with its two drums and levers for moving out and in the clutches. An Elevator moved by condensed air or pneumatic engine.-At the iron-works of Chatlinot, near Charleroi, in Belgium, an elevator of this description, and about 50 feet in height, was constructed in 1839, for three blast-furnaces, where the smelting of the ore is effected by means of coke. The con- densed air, required as motive power, was derived from the great wind-reservoir of the blast apparatus, the air here being condensed at the rate of 4 pounds pressure on the square inch. This elevator is represented on page 460, where Fig. 1326 is a side elevation; Fig. 1327, a front elevation; and Fig. 1328, a horizontal section of a part immediately above the cylinder. The frame a a, Figs. 1326 and 1327, is composed of upright standards and cross-bars, whose joints are, for the sake of durability, covered with iron bands. The nine vertical beams bbb form in the plan four equal squares, Fig. 1328. They rest on cast-iron pedestals cc, Fig. 1326 and 1327, and into whose holes they are firmly fixed by means of wooden wedges. In two of the squares, by the side of each other, the iron ore and other materials are drawn up in vessels or tubs A A, one of which is represented in Fig. 1328 The vessels are provided with two cast-iron crosses d and e, joined by the wrought iron bars Digitized by Google ELEVATORS. 459 ff. The cross-arms form diagonals of the squares, and are at their ends provided with rollers gggg, grooved at their periphery, to fit the rectangular rails hhhh, on which they run up and down from the bottom to the top of the elevator. The vessels containing the ore, etc., are placed on the iron plate ii a 8 1319. 1318. TN 8 0CK II n Or 1321. P B 1317. 1320. B - # b z 1325. F 1324. SCALE.-9 feet=1 inch. 1323. : 1322. 6 701 w IZ NSE resting on the lower cross. The equare marked kk, Fig. 1328, signifies the upper face of a pedestal. To each of the frames is fixed the chains il, II. The other ends of the chains pass round the cast-iron wheel m m and are fastened. The wheels are fixed on the shaft nn, to the middle of which a third wheel o is attached. of far smaller diameter than that of the other ones, and to whose periphery is fixed the Digitized by Google 460 ELEVATORS. chain pp, fastened at its lower end to the joint-head q of the piston-rod r. The piston P moves up and down in the air-cylinder 88, which is about 10 feet high, 2 feet in the diameter, and open below. The piston-rod is packed as in a steam-engine. At the side of the cylinder is the valve-box и, Fig. 1827, which receives the condensed air from the reservoir of the blast apparatus through the pipe vv, and from which again it can be let into the cylinder $8, by means of the valve w, Fig. 1327. The valve w m 1326. A 1327. & I my 1328. D m SCALE.-9 feet=1 inch. 0 @ 1332 OR I Y 1329. to 1331. D 1330. Y F a * B a 1333. & is hollow, to permit the escape of the condensed air (after it has pressed down the piston to the ex- tremity of the cylinder) through the aperture x. As soon as the valve w is moved out of its position, as shown in Fig. 1327. downwards, (which is effected by the combined contrivance of the bar a, the shaft B. end the lever y,) the condensed air acts on the piston t and presses it down. The effect of this Digitized by Google ELEVATORS. 461 is, that the vessels A A are drawn up simultaneously with a velocity surpassing the movement of the piston in proportion to the difference in diameter between the wheels m m and the wheel o. As soon as the vessels are lowered again, the slide w is drawn upward; and as the condensed air filling the cylinder, escapes through the aperture x, the vessels A A sink down by their own weight, which surpasses that of the counterbalance P. The piston t is at the same time drawn up to the upper part of the cylinder. Elevators in corn-mills, etc.-Elevators of this kind are very frequently used in corn-mills and grana- ries for the purpose of raising corn or flour from one loft to another. Elevators for corn are in general of larger size than those used for raising flour, although both are constructed and arranged on the same system. An elevator of this kind is represented on page 460, where Fig. 1329 is a side elevation, Fig. 1330 a front elevation, and Fig. 1331 a section of its lower part, (from the line A B, in Fig. 1329, downwards.) Around the wheels a a is strained the band bbbb, to which are fastened or riveted the vessels c c, of tinned sheet-iron. Motion-is generally communicated to the upper wheel by bands from some driving- shaft. Each of the two wheels is enclosed by a wooden case, the lower one by the case dd, and the upper disk by the case e. The interstices or channels ff and gg are so arranged, that in the former the band with its vessels has but little play, while in the latter more space is given to prevent any collision with the vessels cc, which otherwise might happen on account of the inclined position of the elevator. 1335. OC @ P a MN NM 1334. 9 N DD in k The corn or flour pours into the lower case by the channel h, and the influx can be regulated, or, if required, entirely stopped, by the shutter or slide i. In the rear of the same case is the shutter k, for the clearing of the case and removal of obstructions. At the bottom of the upper case is the aperture l, into which is thrown the grain or flour from the vessels cc, as they overturn on the upper wheel. From I the corn or flour is distributed by the trough m, turning on the bolt n, or is in some other way removed to its place of destination. See CORN ELEVATOR. Elevators in factories for removing manufuctured and other goods from one room to another.-An elevator of this kind is represented above, where Fig. 1334 is a plan, Fig. 1335 a side elevation of a section towards the middle, Fig. 1336 a transverse section, and Fig. 1337 a side elevation, showing the mechanism of the prime movers. In a square space passing through all the stories of the factory, the frame a a, Figs. 1334 and 1335, moves up and down, of about 5 feet square between two beams bb placed alongside of each other. It Digitized by Google 462 ELEVATORS. is driven by the same power that drives the factory. The frame is fastened to two ropes or bands c and c₁, passing over the cast-iron wheel dd. To the other end of the rope c₁ is fastened a counterpoise of the frame, or of the charge to be raised. On the shaft of the wheel d d is fastened the spur-wheel e e, into which the spring-wheel f plays, Fig. 1334, on the opposite end of whose shaft is the diagonal wheel g. Into this latter geer, simultaneously, the two smaller diagonal wheels h and i of the axis k k, to which the wheel h is firmly fixed, while the wheel i is moveable on it. On the latter wheel is screwed the cast-iron roller l, by the side of which are two other ones of the same size, m and n, the former being moveable and the latter fixed on the common shaft kk. The band 00, Fig. 1336, con- nected with the motive power, passes round one of these three .wheels. Suppose it be the wheel n, the shaft k k; together with the wheel h, is revolving in the same direction as the band moves round. Con- sequently the shaft of the wheels g and f, and at the same time the wheel dd rotating by the action of the wheel h, the frame a a is raised, while the wheel i is by the wheel g turned round, and rotates freely on the axis h k, in a direction the reverse of that of the band. If, on the other hand, the band 00 is removed from the disk n to l, by which the wheel i takes into the wheel g, while the wheel h is now kept out of action, the frame a a is moving downwards. Finally, if the band be placed round the moveable wheel m, the elevator is in the state of rest; this wheel then revolves on the axis kk, without exercising any action. 1336. 1337. 1. s a 1338. 1339. B b I e For the purpose of removing the band from one of the three wheels to another, and to regulate the different movements in the described manner, the following arrangement is made. The beam pp sup- ports the bearings of the shaft q, (parallel to that worked with gf,) on which is fixed the wheel r. An endless rope st, Fig. 1337, stretching from the top to the bottom of the building, passes round this wheel, and can everywhere easily be seized by the workmen. Now, according as the part 8 or the part t of the rope is pulled, the disk r and the axis q are turning either to the right or to the left, and by this and the handle v the sliding-bar и is pushed either onwards or backwards. This bar being fastened to the band 00, by means of a fork or handle, the band is removed to one of the three disks 1, m, and n. The distances between the two guides 20 w of the sliding-bar и, are exactly adjusted to these shiftings of the band 00. For stopping the movement of the frame a a whenever required, a contrivance is made, consisting of the wheel x, Figs. 1335 and 1337, on whose periphery is laid the band y of strong sheet-iron. This band is fixed at z, and with the other end fastened at a, to the lever ß, resting on the heart-shaped wheel γ, which is fastened on the axis q. Now, as soon as the band 00 is placed round the wheel l or n, the band y is lifted, and together with it the lever ß. But as soon as the band o o is removed to the wheel m, the lever lowers again, resting with its roller in the concavity of the disk γ, Fig. 1335. Elevators for general purposes.-In factories, for the purpose of winding or letting down heavy loads, an elevator is frequently made use of, as represented in Figs. 1338 and 1339. The frame a a is fixed to the timber-work of the mill, and supports a shaft with the drum bb, and the cast-iron geer cc, into which plays the endless screw d, whose shaft ff is at both ends provided with a winch e e. To the drum is fastened and coiled round the rope g, by means of which the load is raised Digitized by Google ELEVATOR. 463 up. As soon as the drum is put in motion by means of the winches, the load is either wound up or lowered. The ring h pressing against the socket i, serves to keep the screw or worm d in geer with the tooth-wheel c c. When the load has arrived at its place of destination, the shaft ff is pushed onwards until the ring k presses against the socket 1. The rope g can then easily be wound off from the drum. ELEVATOR, for raising bricks, mor- tar, and any other materials employed in building, and adapted to the unloading 1340. of ships and warehousing of goods. In- vented by M. Spurgiu. Fig. 1340. Description of machine.-The main B part of the machine A, consisting of the geering to set the machine in motion, rests upon the ground. The second part is a trestle, which may be placed upon the scaffolding of the bricklayers, as at F F; in the upper part of this trestle is an indented wheel B, which corresponds perpendicularly with a similar wheel, attached to the principal body of the machine, resting on the ground. Pass- ing round these two wheels is an end- less iron chain, which is put in motion by one or several men, who turn the G handle of the machine A, consisting of a pinion-wheel working into a large toothed wheel, on the axis of which is an in- dented wheel, round which an endless chain passes, and also round a corres- ponding wheel at the side of the one at M the foot of the vertical chain; the latter is set in motion when the wheel A re- volves, together with the endless chain just described, over the indented wheels at C and E, by which the chain oper- ates its rotation. On the side of the N chain ascending, the workmen attach their hods full of materials, by means of a hook fixed in the hod, as at B, and others detach them, as at F, to carry them to the bricklayers on the scaffold- I ing. The empty hods are attached to the chain on the opposite side, as at G, and descend to the ground, where they are detached, as at H. The chain may be lengthened and K shortened as necessary. When a story is added to the scaffolding, the trestle is placed upon the new story, and the chain lengthened as required. At the top is a screw for tightening or relaxing the chain, as occasion may require. L The figures I K L are accessories used for hoisting the materials, viz: I, for bro- H ken bricks; K, for water; and L, for pieces of stone for windows, chimneys, &c. M is an enlarged view of the in- dented wheel, and N the chain. C The advantages of this machine are, that it relieves the workman from the D most toilsome part of his labor, by doing away with the practice of ascending the E ladder; and it prevents, as far as possi- ble, the accidents arising from this prac- tice, to which he so often falls a victim. A It also enables building operations to be carried on with much greater expedition than heretofore; and at the same time it diminishes the cost of such works. DYNAMICAL TABLE of the strength of a man, showing the number of bricks that can be carried up a ladder by an ordinary laborer. Ft. in height. per min. per hour. in 10 hours. Ft. in height. per min. per hour. in 10 hours. 10 90 5400 54,000 40 22 1350 13,500 20 45 2700 27,000 50 18 1080 10,800 30 30 1800 18,000 60 15 900 9,000 Digitized by Google 464 ELLIPTOGRAPH. ELLIPTOGRAPH. Fig. 1341 is a side elevation of the machine, showing the pencil adjusted for describing an ellipse, and Fig. 1342 is a plan agreeing to the above. Fig. 1343 is a section of the slide of the ball o which forms a universal joint for E the pencil-holder. Fig. 1344 is the arm C drawn dou- ble size. Fig. 1345 is a section of the same arm, with its rocking slide-bar g. Fig. 1346 is the arm D, drawn double size, with its rocking slide-bar f. Fig. 1347 is an end view of the bar f. Fig. 1348 shows the bar f suspended from its top centre. Fig. 1349 represents the bar f generally used for ellipses of ordinary proportions. A is the top frame of the instrument which carries the revolving or generating circle B. C is the moveable centre arm which determines the major axis of the ellipse. D is the bottom moveable arm which determines the minor axis. E is the pencil-holder, being a light brass tube, turned exactly parallel; its use is to hold the describing pencil, which is fitted into its lower extremity, the point being in a direct line with the axis of the holder. F is the bottom plate, into which the upright pillar G is fixed, by means of the adjusting-screw H. The method of application of the instrument is as follows :-Take a straight-edge T or T square, having previously drawn two lines at right angles across each other, for the major and minor axes of the required figure; place the bottom frame, with the centre marks a a on the line for the major axis, and the marks b b on the line for the minor axis, which marks are inside of the frame F; then bring the straight-edge T against the side of the frame F and 1348. 1341. "A D 1347. 1343. f 1349. X G £ c D. D 1346. E F H D 1342. 1344. F 1345. 9 J C C B F T fix it. If the ellipsis required is the largest of the set, let the slide with the ball o be pushed out 80 far as to bring the point of the pencil to the length of the major axis II, the generating circle having been turned round until the sliding-groove, with the ball 0 is parallel with the major axis, that is, when the arm C is about half height, the position shown, (this should never be higher but in extreme cases, for the lower the cross-arms C and D are kept, the steadier will be the point of the pencil but if by sliding out the ball 0, it is not enough for the ellipsis required, the arm C must be raised until the point reaches the desired distance. When this is done, turn round the generating circle BB, until the sliding-groove of the ball o is parallel with the minor axis J J, which will be at right angles to its former position. Then slide the arm D up or down until the point of the pencil rests on the point of the minor axis. and if by turning round the generating circle B B, the pencil point touches all the four points [IJJ, the instrument is correct for that proportion of the ellipsis. With this single arrangement it will now draw any number of sizes, from a more point up to the full capacity of the instrument, by simply sliding the ball 0 out or in, until the point of the pencil reaches the point of either the major or minor axis required. the generating circles having been turned round to suit either of them, as before. It is Digitized by Google EMBOSSING MACHINE. 465 immaterial to which of the axes it is set, as the instrument will always produce the same proportions of ellipsis 80 long as the arms C and D are not altered. But if the major axis is required to be lengthened or shortened without changing the minor axis, the arm C must be drawn up or down 80 as to bring the pencil to the desired point; or if the minor axis is to be altered, the major axis remaining, the arm D must be moved up or down until the pencil again rests on the point required; the generating circle in either case having been turned round until the sliding-groove of the ball 0 is parallel with the axis of the ellipsis to be altered, or, which is the same, with the sliding-groove of the opposite arm. To pro- duce the figure, nothing more is necessary than to turn round the generating circle by the finger and thumb acting on the studs SS, when the pencil point will trace the figure on the paper below; the slide of the ball o should be so tight as not to alter with the action of the pencil. The particular use of the straight-edge T, is to enable the operator to change the plane of the ellipsis and return again to the same plane; all that is required being simply to bring the points a a to the line of the axis required, such as I to I, &c. The closer the arms C and D are brought, the nearer will the ellipsis be to the cir- cle, and if the rocking-bar f of the arm D, Figs. 1346, 1347, 1348, and 1349, is shifted to hang by the top centre, as in Fig. 1348, the two arms C and D can then be brought quite close, and the centres of suspension of both rocking-bars g and f in the arms C and D will be in the same plane, and yet both at perfect liberty to vibrate with the pencil-holder which passes through both these bars as well as through the ball O. In this case perfect circles will be produced, and if the arm D be lowered below that point in the slightest degree, the ellipsis will vary in that proportion, and so on until the arm D reaches the bottom. But if still further elongation is required, this arm D must be inverted, and the bar f again suspended as in Fig. 1348, when a straight line will be produced if required, by bringing the surface acted upon in the same plane with the centre of suspension of the bar f; and by raising the arm D in the slightest degree, an ellipsis of that proportion will be produced, and 80 on as the arm D is raised. EMBOSSING MACHINE, and Bookbinders' Arming or Stamping Press. With this machine the pressure is applied by means of a treadle, thereby allowing the operator the use of both hands to feed and fly with; also enabling him to apply an immense pressure with but little exertion. The form being stationary, it may be heated by steam if required. 1350. This machine is manufactured by R. Hoe & Co., New York. The embossing machines of Mr. D. Dick, and of Mr. Austin, are also favorite machines with bookbinders. EMBANKMENTS, Moveable Machine for executing. First employed on the St. Germain's Railway, by M. CLASSEYRON, Engineer-in-Chief. It consists of two trussed beams, which are laid with rails. It is placed at the head of the embank- ment during the course of execution, the earth wagons being run upon it after being tipped. Suppose 59 Digitized by Google 466 EMBANKMENTS. the formation of an embankment proceeding from one end of a cutting, the baleine is placed as shown in Figs. 1351 to 1356, with one end resting upon the embankment and the other laid in the same line of direction, and supported on a wheel-carriage. The carriage stands on a small auxiliary railway pro- ceeding from the lower level of the head of the embankment, the rails being taken up at one end as the other progresses. Upon a wagon being tipped, (at the battery head,) and the contents discharged between the rails, it is then pushed to the further end of the baleine. This course is followed with a second wagon, which is also discharged and run on the baleine, next the first, and it is continued until the baleine cannot accommodate any more, when the whole of the wagons are carried back together to the places of filling, by a horse or a locomotive engine. . a 1355. H O A B c 1351. 1352. a 1353. SCALE.-17 feet=1 inch. 1354. 1356. n The workmen move the baleines forward upon the wheels of the carriage supporting it, by crow-bars and other tools. They also raise it by ropes and pulleys to whatever height may be required at the head of the embankment. ENAMELLING. See GLASS and PORCELAIN. Digitized by Google ENGINES, DETAILS OF. 467 ENGINES, DETAILS OF. Pumping-Engine.-In a pamphlet printed by Messrs. Boulton and Watt, for the use of their workmen, some time between 1782 and 1785, we have some excellent practical directions respecting the construction and management of pumping engines, the greater part of which are applicable to the circumstances of the present time. Directions for putting the engine together.-' Having put the working-beam together, and fastened the gudgeon to it, rest it on the plummer-blocks; but do not fasten these blocks until the cylinder is fixed. Level the top of the stone platform, and lay the outer bottom of the cylinder down in its place, truly level, and corresponding to the holding-down screw-boxes. "Apply the inner bottom upon the outer one, and set its upper joint level, by wedging betwixt it and the outer bottom, if it requires it; then cut out segments of pasteboard, such as is used for the boards of books, (not such as is composed of paper pasted together let these segments be of such thicknesses as the different parts of the joint may require, (if it be more open in some places than in others.) Soak these pasteboard segments in warm water until they become quite soft, then lay them upon boards to dry, and when quite dry put them into a flat pan with a quantity of drying linseed-oil; warm the oil until the pasteboard ceases to emit bubbles of air, but take care not to heat the oil much hotter than boiling water, otherwise it will harden or burn the pasteboard. Anoint the segments on both sides with thin putty made with fine whiting and some of the linseed-oil; let the whiting be very dry, otherwise it will be difficult to mix with the oil-and N. B,, that white lead will not answer in place of it. " You must, as much as you can, avoid using more than one thickness of pasteboard, and the segments should be a little broader than the flanch, with all the holes cut out by a chisel, but not quite so large as the holes in the iron. The segments should also be thinned at the ends where they overlap each other, so that they may form a circle of pasteboard of a uniform thickness. To pack the piston, take sixty common-sized white or untarred ropeyarns, and with them plait a gasket or flat rope, as close and firm as possible, tapering for 18 inches at each end, and long enough to go round the piston and overlap for that length; coil this rope the thin way as hard as you can, lay it on an iron plate, and beat it with a sledge-hammer until its breadth answers its place; put it in and beat it down with a wooden driver and a hand-mallet; pour some melted tallow all round; then pack in a layer of white oakum half an inch thick, then another rope, then more oakum, so that the whole packing may have the depth of about four inches, or only three inches if the engine be a small one. Cast segments of a circle of lead, about 12 inches long, 3 inches deep, and 11 inch thick, fitted to the circle of the piston, and cut down square at both ends; lay them round upon the packing as close as they can lie to one another without jamming, and screw down the piston-springs upon them; the piston- springs should be bent downwards at the end next the piston-rod, and a little mortise should be cut in the cast-iron there, for the bent-down point of each of them to lodge in, which will prevent their coming forwards to touch the cylinder. Previous to the piston being put into the cylinder the hollows among the crosses should be quite filled up with solid pieces of deal wood, put in radius fashion. The packing of the piston should be beat solid, but not too hard, otherwise it will create so great a friction as to hinder the easy going of the engine. Abundance of tallow should be allowed it, especially at first; the quantity required will be less as the cylinder grows smooth. The joints being all made, the regulator valves in their places, and the covers screwed on, but no water in the condenser cistern, admit steam, and when the cylinder and steam-case are thoroughly warmed, screw up the nuts of all your screws, and caulk the pasteboard or oakum of such joints as may require it, with a caulking-chisel, until you find that every thing about the cylinder is perfectly stanch; then pour three or four feet deep of water into the hot-water pump; stake down the injection and blow- ing-valves, and also those on the air-pump lid; then let the steam into the condenser, which will show the defects or leaks, if there be any. 'Screw on the steam-gage to the steam-case near the nozzle, and behind the engine-man's place; pour as much mercury into it as will half fill the open leg; put a float on it, broad at bottom, but very slender in the stem; cut the float or index off close to the end of the open tube, and fix a scale to it, reckoning every half-inch the float rises equal to an augmentation of the elasticity of the steam, corres- ponding to the supporting of a column of mercury an inch high, because the surface has sunk as much in the one leg as it has risen in the other. Solder a small copper fosset-pipe, to fit the copper commu- nicating tube of the barometer, into the eduction-pipe, 12 inches under the fosset of the blowing-valve, and on the opposite side of the eduction-pipe; place the barometer in the door-way to the condenser on the further side from the plug-tree, 80 that the engine-man may see it when at his station; join the copper tube to it by pouring melted sealing-wax into the copper cup at top; fill the short leg of the barometer with mercury, within four or five inches of its top, and put a light float in it, long enough to reach to the top of its frame. do Fill the condenser cistern, shut the lower regulator, and there being no steam in the cylinder, or its communication with the boiler being cut off, take off the bonnet or cover of the exhaustion regulator, shut that regulator, and work the air-pump by means of the brake. If then you find that air enters by the regulator, pour some water on it, and continue pumping until you have raised the barometer, i. e. sunk its float, to 27 or 28 inches; leave off pumping, and observe if the vacuum continues good, or is a long time in being destroyed. If it loses fast, seek for the leaks, which must be somewhere in the eduction-pipe, and will make a noise if touched with a wet hand, (observe if the condenser moves by the pumping, and secure it.) And having cured these leaks, you may try the tightness of the cylinder by staking the working-beam, so that the piston cannot descend; then taking the cover off the cylinder, open the exhaustion regulator, and shut the steam regulator; on beginning to pump, you will perceive if the piston be tight; if it is not it may be beat a little, and some water being thrown upon it, and on the steam regulator, whatever air enters must be by leaks, which must be sought for and cured by screwing or caulking in oakum. N. B. A critical tightness in the piston cannot be obtained until the engine has gone a few days. Digitized by Google 468 ENGINES, DETAILS OF. without beating it too hard, to permit the engine to move easily. When you can detect no more leaks in this way, the steam must be admitted, and the same examination made as before. " After the engine has been set agoing, and has gone a few hours, the holding-down screws should be screwed tight, and so from time to time as they become slack; and in like manner all the other screws about the cylinder or nozzles should be screwed up as they slacken, and the joints caulked and puttied where they require it. " Directions for working the engine.-To set the engine agoing, raise the steam until the index of the steam-gage comes to three inches on the scale; when the outer cylinder is fully warmed, and steam issues freely on opening the small valve at the bottom of the siphon or waste-pipe, which discharges the condensed water from the outer bottom, open all the regulators; the steam will then forcibly blow out the air or water contained in the eduction-pipe, by the blowing-valve, but cannot immediately take place if the air is in the cylinder itself; to get quit of it, after you have blown the engine a few minutes, shut the steam regulator. The cold water of the condenser cistern will condense some of the steam contained in the eduction-pipe, and its place will be supplied by some of the air from the cylinder; open the steam regulator and blow out that air; and repeat the operation until you judge the cylinder to be cleared of air; when that is the case shut all the regulators, and observe if the barometer shows that there is any vacuum in the eduction-pipe. When the barometer gage has sunk three inches, open the injection a very little, and shut it again immediately; if this produces any considerable degree of vacuum, open the exhaustion regulator a very little way, and the injection at the same time. If the engine does not commence its motion it must be blown again, and the same operation repeated until it moves. If the engine be very lightly loaded, or if there is no water in the pumps, you must be very nimble and shut the exhaustion and top regulators so soon as it begins to move quickly, otherwise it will make its stroke with great violence, and perhaps do some mischief. To prevent which, open the top and exhaustion regulators only a little way and put pegs in the plug-tree, so that they may be sure to shut these regulators long before the piston comes to the bottom. If there is much unbalanced weight on the pump-end, you must also take care to put a peg in the ladder which guards the steam regulator lever, so as to allow that regulator to open only a little way, and so to lessen the passage for the steam when it enters to fill the cylinder, otherwise the rods, &c., at the pump-end may descend too fast and be prejudicial; if you find, after a few strokes, that the engine goes out too slow, the steam-regulator may be opened wider. In order to regulate the opening of the exhaustion regulator you should have pieces of board, of various thicknesses, to put under the weight which pulls it open, by means of which it may be made to open more or less at pleasure, and the top regulator may be managed in the same manner. 'Should the engine work with too great violence, on account of its being underloaded, you may correct it by giving the top regulator a lesser opening, and shutting it at such a part of the stroke as will just give the piston sufficient force to come to the bottom. Whenever the top regulator is used the exhaustion regulator should be thrown fully open every stroke, in order to give a free exit to the steam, on which a great part of the good effects of the top-regulator depends. The engine should always be made to work full stroke, that is, until the catch-pins come within half an inch of the springs on each end, which is easily managed by an attention to the pegs. Care must be taken that the piston rise high enough in the cylinder, when the engine is at rest, to spill over into the perpendicular steam-pipe any water which may be condensed above it; for if any water remain there, or in any other part of the cylinder while it is working, it will very much increase the consumption of steam. When the engine is to be stopped shut the injection and secure it; put a peg in the plug-tree to prevent the exhaustion regulator from opening, and take out the peg on the other side so as to allow the steam regulator to open and to remain open: otherwise you may have a partial vacuum in the cylinder, and it may be filled with water from the injection or leakages, which is a troublesome accident. The top regulator should also be open while the engine stands. " When an engine is in tolerably good order it will bear to stand ten minutes, and go to work again without blowing afresh; and though it has stood two or three hours, if there has been any steam issuing from the boiler, and no air has been admitted into the cylinder, it will generally go off with once blowing for about a minute. If you find, after following the above directions, that the engine does not go to work, shut the exhaustion regulator and give some injection; if it then makes no vacuum, it is likely there are air-leaks about the eduction-pipe; if it does make a vacuum which remains but a short time, it may be owing either to air or water leaks; these may be distinguished by blowing as before, and shutting the lower regulator for about a minute without giving any injection. If, upon opening it again, it throws out a good deal of water at the blowing-pipe before it blows steam, it is certain that it either has some leak in the condenser under water, or that the injection or blowing valve does not shut close; if they are found to shut close, every joint should be examined, and also the valve at the foot of the eduction-pipe. If, after blowing as before, you find that immediately on opening the exhaustion regulator a quantity of air is thrown out at the blowing-valve, the leak is in the eduction-pipe, somewhere between the surface of the water in the cistern and the nozzle. The particular place of these leaks may be found by emptying the cistern of water, putting three or four feet deep of water into the hot-water pump, and staking down the blowing and injection valves with those on the air-pump lid; then, if steam be admitted into the eduction-pipe it will come out at the leaks and point them out. If not found out in this way, apply the brake to the air-pump, taking care first to put some water on its bucket, and then by working that pump by hand, you will probably, on an attentive examination, observe where air goes in, which may be known more distinctly by wetting the place suspected. If upon shutting the lower regulator and making a vacuum in the exhaustion-pipe by pumping, or by injection, you find the vacuum continues good for a considerable time, then the fault does not lie in the eduction-pipe, but in the nozzle or joint of the cylinder bottom, where it must be sought for. In these examinations by pumping it is proper to take off the bonnet or cover of the exhaustion Digitized by Google ENGINES, DETAILS OF. 469 regulator, and to examine if air enters at that regulator; if it does, and only in small quantity, throw some water on the regulator while you are examining the eduction-pipe; and when the leak is suspected to be in the bottom joint of the cylinder, or in the lower nozzle, you must throw some water on the steam regulator and also on the piston, then, by pumping and strict examination, you will soon find where the air enters. When you are examining the tightness of the piston by pumping, you must stake the beam, 80 that the piston may not descend. 44 If in course of working you do not find the vacuum keep good, and the engine goes sluggishly, or stops and requires to be blown frequently, you must examine whether an uncommon quantity of air or water issues at the hot-water pump, or if any comes out at the valves on the air-pump lid; if the quantity of air is great, the engine has some air leak; and if the quantity of water be great, and is cooler than usual, it proceeds from a water leak in the condenser; if the quantity of water be great, and at the same time very hot, it proceeds from a bad piston, or from the steam regulator not shutting close. The engine will also go badly if the air-pump or water-pump buckets or clacks strip the water, that is, let it pass by them. You will know if this be the case with the water-pump bucket by observing whether the water follows down after it at the return of the stroke, and leaves a part of the pump empty; if it does not, either the bucket strips the water or the engine receives water in some way which it ought not. " ttention ought to be given to feeding the boiler in a regular manner, that it may not be spoiled, nor steam wanted. When there is too much water in the boiler the engine will not work regular, and if there is too little the sides of the boiler will be burnt by the flame in the flues. If by accident it should at any time run a little too low, the feed should be augmented 80 as to fill it gradually; for if you run in too much at once, you will check the steam, and stop the engine; but if it be run very low, stop the engine, open the puppet clack, and fill the boiler from the pool or reservoir, if you have one; otherwise fill it by working the air-pump, having first staked down the valves on its cover and opened the injection-valve. In working the engine the steam ought to be strong enough to make the index of the steam gage stand half an inch high at least, otherwise air will enter at the joints of the boiler, &c, and spoil the vacuum, 80 as to cause a good deal of trouble to get quit of it again. Therefore if you perceive the steam-gage to be lower, stop the engine until it rises again. By a little attention you will find the proper opening of the feeding-cock for any rate of working. Let all the coals employed to feed the fire be thoroughly watered just before they are thrown on, as that will prevent their being swept into the flues by the draught of the chimney. The fire should be kept of an equal thickness and free from open places or holes, which are extremely prejudicial, and should be filled up as soon as they appear; if the fire grows foul and wants air, by clinkers collecting on the bars, they must be got out with a poker, but the fire should be as little disturbed in that operation as possible, and the greatest care taken not to make any coals or coke fall through which are not thoroughly consumed; it is very common for a fourth of the whole coals to be wasted in this manner by mere carelessness. When the fire is newly made the damper should be raised a little, 80 as to let off the smoke freely, but should be let down to its proper place so soon as the smoke is gone off. The air door in the chimney should be always open more or less; it prevents the flame from being sucked up the chimney, and very considerably increases the effect of the coals. Once a month the boiler and flues ought to be cleaned, or oftener if the water be very subject to incrust the boiler. Every morning the ashes ought to be taken out, the engine-house swept clean, and a view taken of every part of the engine, to see that nothing be working out of its place or want oiling. Particular attention ought be paid to the bolts and cutters of the great chains and piston-rod, so that none of them get loose. 64 An engine, when in good order, ought to be capable of going so slow as one stroke in ten minutes, and so fast as ten strokes in one minute; and if it does not fulfil these conditions, somewhat is amiss that can be remedied. 'The hot water should issue of the heat of 96° of Fahrenheit's thermometer, that is, blood warm, when the engine is in excellent order, and should never exceed the heat of 110°, unless when the injection or cold water is hotter than 70°, and in that case the vacuum will not be good. To make putty for making or repairing the joints.-Take whiting, or chalk finely powdered, dry it on an iron plate or in a ladle until all the moisture be exhaled: then mix it with raw linseed-oil, and beat or grind it well, adding more oil or whiting until it be of the consistence of thick paint, and per- fectly free from lumps or inequalities. For some purposes, where the putty is wanted to dry and to be very sticky, use painters' drying oil, which is made by boiling the oil with a small quantity of litharge or red-lead. " Where the putty is wanted to continue always soft, mix about two ounces of butter or common salad-oil with each pound or pint of the linseed-oil This soft putty is principally useful in the caulked joints of the eduction-pipe above water. N. B. White-lead will not answer in place of the whiting. " No wet cloths should be suffered to be laid on the cylinder, boiler, or steam-pipes, and every part containing steam should be guarded as much as possible from the influence of cold air or water. The proper grease for the piston and cylinder stuffing-box is melted tallow, and for the chains, gudgeons, dc., common Spanish olive-oil, which, for some uses, may be thickened by dissolving some tallow or butter in it by means of heat. Linseed-oil should never be used as grease, as it dries and creates more friction than would have been without it. Hogs' lard, or train-oil, if applied anywhere about the cylinder, or where it is hot, will thicken like linseed-oil When the oil or grease about the great chains, or any of the working parts, grows clotted or very thick, it should be scraped off before new grease is added. An improvement has lately been made in the covering of boiler tops. The setting being built up to nine inches above the flues as usual, a course of horse or cow dung, three inches thick and well beat, is applied to the boiler top; on the outside of that is laid some good lime mortar, about an inch in thick- ness, to which is applied a course of bricks flatwise, with their ends upwards; on the outside of that Digitized by Google 470 ENGINES, DETAILS OF. another course of bricks (also laid in good mortar) in the same position, but 80 as to break joint with the first course; in which manner the covering is carried on until the whole top is covered, taking care to leave an opening for the man-hole; every flanch may be thus covered, and when well done it effectually makes the top steam-tight, and also defends it from cold and rain, 80 that a boiler-bouse is not necessary. The mortar employed must be such as stands water. " Additional observations.-Instead of using painters' drying-oil to make the joints with, take good raw or unboiled linseed-oil, put it in an iron pot, place it over a gentle fire, (out of doors, but protected from rain,) let it be watched as it heats, as it is very liable to boil over; when it boils make the fire more moderate, but continue to heat the oil, until upon dropping soine of it upon a cold stone or piece of iron, you find it is, when cold, of the thickness of thick tar or treacle. The pasteboards for the joints are to be soaked in this oil warm, or painted over with it, and laid in a hot place to suck it up; and it is also to be used to make the putty with. The oakum with which the joints are caulked should be well smeared with the strong or thick boiled oil mentioned in these additional directions. If the under side of the pipe of the inner bottom does not fit close to the lower edge of the opening made for it in the outer bottom, that is to say, if the space left there for pasteboard or caulking be wider than one quarter of an inch, a piece of hammered iron an inch and a half broad must be forged of such thickness as to fill up the space, 80 as to make it tight by the help of a thickness of pasteboard above it, and another below it. Lead ought not to be used in these cases, as its expansion and contraction by heat and cold are too great. Instead of putting a prop from the nozzle to the ground, it is found better to put a balance beam off sideways under the floor with a short upright having a flat end to take a broad bearing under the nozzle. The weight of the balance should not support more than two-thirds of the weight of the nozzle. Some people use a plaited rope to make the joint of the cylinder lid, which is a bad practice for though a plaited rope may make a joint apparently steam-tight, yet it has been found by experience, that such joints are not air-tight; but when, by the working of the top regulator, a partial vacuum is produced in the upper part of the cylinder, they permit some air to enter imperceptibly, and without noise, which, of course, passes to the condenser, and by persons that are not aware of this circumstance, may be thought to enter at some air leak in another place. We therefore recommend that this joint be always made with pasteboard and putty; and that a strict attention be paid to the tightness of the stuffing-box, wherever the top regulator is used." In the Cornish engines great diminution in the consumption of fuel has taken place, chiefly by the larger application of the principle of expansion. An 85-inch cylinder engine, erected at the United Mines in 1840, reached in 1842 an average duty of 107 millions of pounds raised 1 foot high with a bushel of coals. In this engine the pressure of the steam is 40 lbs, and it is cut off at one-tenth or one- twelfth of the stroke. To diminish the risk of fracture in engines using such high steam, the double cylinder engine is employed. The small cylinder here stands on top of the large one, and the same piston-rod passes through both. The same number of valves too that is used in common pumping- engines, suffices in this modification of the double cylinder plan. The Cornish engines are provided with a steam-jacket, but through this jacket the steam does not pass in its way to the cylinder. The steam jacket is kept filled with steam by a branch from the steam-pipe, which is about 4 inches in diameter in large engines. The clothing applied to the cylinder is very various a common plan is to enclose the cylinder in a brick wall, leaving a space between them; to plaster the wall, and coat it with timber. The cylinder cover and cylinder bottom are usually made hollow, and filled with steam they are then carefully coated with non-conducting materials. The main beam of the engine usually consists of two cast-iron plates, bolted together, and armed with projecting horns to catch the spring beams, should the piston be disposed to strike the bottom of the cylinder. From the beam hangs the plug-rod, by which the valves are moved by means of some such arrangement as that shown in Fig. 1358, which differs in some respects from the Cornish form. The valves of the Cornish engine erected 1357. by Mr. Hosking are shown on a large scale in Figs. 1357, 1359, and 1360. c These valves are of the equilibrium description. Figs. 1357 and 1359, the valve to the-left is the governor- valve, by the adjustment of which the flow of steam to the cylinder is regulated; the centre valve is the o o o steam-valve; and the valve to the right is the equilibrium-valve. Fig. c 1360 represents the eduction-valve, which, it will be remarked, is larger SCALE.-4 feet=3 in. than the others, so as to afford a free exit for the steam into the condenser. Three-quarters of a square inch per horse power is a common size for the steam-valve in rotative engines, furnished with spindle-valves; and a square inch and a quarter per horse power is a common size for the exhaustion-valve. The plunger-pump is the pump universally used in the Cornish mines, and it is much preferable to the lifting-pump, as it can be packed afresh, or the packing may be tightened, with much greater facility than can be done in the case of a lifting-pump, while the friction is at the same time less. The shaft is divided into a succession of lifts, in which the water of the lowest lift is delivered to the pump next above it, and 80 on in succession until the water reaches the surface. The plunger-pump is used in all these lifts except the lowest, where the lifting-pump is used, with the view of obviating inconvenience, should the water from derangement in the machinery, or otherwise, rise so high in the mine as would make the valves and barrel of a forcing-pump inaccessible, and also on account of the facilities afforded Digitized by Google C 1358. ENGINES, DETAILS OF. Digitized by Google 471 472 ENGINES, DETAILS OF. by the lifting-pump in the drainage of the water as the mine is sunk deeper. The plunger-pump ob- viates the necessity for as large a counterweight as would otherwise be necessary; for the force of the engine is expended in lifting the pump-rods, and the water is forced out by the weight of the pump-rods in their descent. The pump-rods of some of the engines, however, are too heavy for the engine to lift, and part of the weight has to be taken off by one lever or more, provided with counterbalance weights, placed either at the surface or in some convenient side excavation. The main pump-rod of Davy's engine at the Consolidated Mines, is one-third of a mile in length, and weighs 95 tons. The other rods weigh 40 tons, making a total weight of 135 tons, of which 39 only are wanted to balance the water in the 1359. 1360. SCALE.- inch=1 foot. pump, and the greater part of the remaining 96 is balanced by weighted levers. The main pump-rod is usually composed of balks of Memel timber, and at intervals down the sides of the shaft projecting pieces are bolted on, which catch upon suitable timbers let into the sides of the shaft, to prevent the rod from descending too far in the event of fracture above. The rod is guided at intervals by appropriate frames. There is something rather primitive in these expedients, and it is not improbable that the whole of this cumbrous apparatus will hereafter be superseded by machinery operating by atmospheric pressure, whereby the pump-rods will be rendered superfluous, or else by the centrifugal pump; and a small engine, working at a quick speed, will suffice for working such an apparatus. TABLE OF OBSERVATIONS UPON TEN CORNISH ENGINES. CONSOLIDATED MINES. UNITED MINES. Taylor's engine. Davy's engine. Job's engine. Woolf's engine. Bawden's engine. Pearce's engine. Cardozo's engine. Eldon's engine. Loam's engine. Hosking's engine. Diameter of cylinder-in inches 85 80 65 90 90 65 90 30 85 85 Dimensions of engine. Stroke of piston-in feet 10 111 9 10 10 9 9 9 10 10 Diameter of steam-valve-in inches 12 13 9 8 8 7 10 5 10 12 " equilibrium-valve-in in. 16 18 12 16 16 12 13 7 16 16 " exhaustion-valve-in in. 20 24 14 19 19 14 15 10 19 19 Number of boilers 4 3 2 4 3 3 3 1 3 3 Length of boilers-in feet 3-36 .... - 37 (31) 1·40 (32) 35 36 36 36 - 1-32 36 2-38 44 Dimensions of Diameter of boilers 6f 7 6f 61 64 61 61 6f 6f 6f boilers. 64 tubes - 3.34 14 41 34 31 32 3 34 4 4 4 Length of fire-bare 4 4 4 4 4 4 4 4 4 4 Total area of fire-bars 63 52 30 60 45 45 48 16 48 48 Heating surface exposed to flues 3781 3151 1598 3481 2694 2694 2694 941 2952 3451 Water space-in cubic feet 2467 2025 1033 2140 1650 1650 1650 579 1706 2085 Steam space- " 735 580 315 608 468 468 468 178 528 645 Open air-Fahrenheit 570 570 - 57° 57° 51° 55° 56° 51° 55° Engine-house-Fah. - - - - - 67° - 55° 63° 66° Temperatures Ashes over boller-Fah. 80° 80° 81° 98° 98° 97° 990 79° 82° observed. 88° Cylinder cover-Fah. 111° 90° 1020 126° 96° 109° 94° 98° 90° 84° Middle of cylinder clothing-Fah. W 77° W 76° 95° 102° B 140° I B790 W 600 W67° W 68° Clothing of steam-pipe-Fah. 79° - - 130° 95° - 140° 970 80° Rgo Condensing-water-Fah. 640 840 58° 115° 110° 57° 60° 61° 63° 60° Hot well-Fah. 980 100° 91° 140° 140° 970 1040 94° 102° 96° Height of condenser barometer-in in. 274 27f - 251 - - - - - 27f Number of plunger-pumps 9 12 2 7 8 9 8 1 5 5 bucket-pumps 2 2 - 1 2 2 2 - 4 3 Water load per sq. inch cf piston in lb. 11.46 13.12 8.78 11.56 83 16-8 11.5 17.96 11:95 13.58 Proport'n of stroke where steam cut off 1-5th 1-5th - $ 1 t t Strokes per minute 8f 7j 10 81 I 2-11ths - - on 8 7 Proportion of duration of in-door to out-door stroke } 4:7 5:8 4:7 5:7 5:7 5:6 4:0f 4:7 1:8 4:71 Grease used per day-in lbs. 12 12 10 12 12 10 12 6 12 12 Oil used per day-in pints 1 1 1 1 1 1 1 Men employed 4 4 3 was 1 1 4 4 3 4 3 4 4 Boys employed 3 3 3 4 4 3 3 - 3 3 Digitized by Google ENGINES, DETAILS. OF. 473 1363. 1302. + 10 , K c D Working-beam.-SCALE.-$ - inch=1 feot. 60 Digitized by Google 474 ENGINES, DETAILS OF. A bushel of Welsh coal now used in Cornwall weighs 94 pounds. Rotative engines.-A rotative engine of Messrs. Caird's, is represented in Fig. 1361, which is a general elevation. 1361. 1364. 1365. SCALE.- inch=1 foot. 1366. Figs. 1362 and 1363 are en- larged views of the working- beam, which is of cast-iron; and Figs. 1364 and 1365 are sections of the same. The sizes of this beam agree, with tolerable nearness, with those given in our tables of dimen- sions. The depth of beam at 1367. 1368. the centre is usually about equal to the diameter of the 1,3 cylinder, and the depth at the ends is generally made about one-third of the depth of the beam at the centre. The length of the beam is gener- ally about three times the length of the stroke, and the 1369. 1370. thickness 1-108th of the length. 2t By the thickness is meant the mean thickness: the edge-bead 1.4 is usually 11 time the thickness of the web. SCALE inch=1 foot. Digitized by Google ENGINES, DETAILS OF. 475 Fig. 1366 is the cast-iron main centre of the working-beam; Fig. 1367 is the cast-iron stud for the main links; Fig. 1368 is the connecting-rod stud, of cast-iron; Fig. 1369 is the wrought-iron stud for the air-pumps; Fig. 1370 is the wrought-iron stud for the hot and cold water pumps. The diameter of the end studs of the beam is generally made about 1-9th of the diameter of the cylinder when the studs are of cast-iron, and 1-10th of the diameter of the cylinder when they are of wrought- iron; but the larger proportion is preferable, as the wear of the brasses is then less rapid. It is a com- mon fault to make bearings too small, from their proportionment being viewed with reference only to strength, whereas it should also be viewed with reference to wear. Figs. 1371 and 1372 are views of the piston-rod clutch or cross-head. The piston-rod passes into the round hole in the centre of the clutch, and the main links encircle the projecting bearings, and join the clutch with the main beam. Fig. 1373 represents the cross-head gibs and cutter. 1371. 1374. 1375. 1372. 1376. SCALE.-11 inch=1 foot. 1373. SCALE.-11 inch=1 foot. 1377. 1378. 1379. SCALE.-11 inch=1 foot. SCALE.-11 inch=1 foot. Figs. 1374 and 1375 represent the main links: Fig. 1376, the pillar of the main link, which is interposed between the upper and under brasses; and Figa. 1377, 1378, and 1379 the upper brass and pillar-plate of the link. Fig. 1380 represents the gibs and cutter of the main links. The sectional area of the main links is usually made about 1-113th of the area of the piston, that of the piston-rod being 1-100th. To find the proper sectional area of the main links, a common rule is to divide the square of the diameter of the cylinder by 144. The length of the main links is usually about the same as the length of the crank, which is half the stroke. The main beam is always somewhat longer than the distance between the cylinder and crank centres, and at the cylinder end the perpen- 11 inch=1 foot. dicular centre line divides the versed sine equally. The angular motion of the beam is about 38° during the whole stroke. The length of stroke is the chord of the arc the centre of the end pin describes, and the versed sine represents the amount of deviation from the perpendicular, which is called the vibration of the beam. The beam being three times the length of the stroke, the dis Digitized by Google 476 ENGINES, DETAILS OF. tance from the main centre to the end stud is one and a half times the length of the stroke, and with these proportions the end stud will deviate from the perpendicular one inch for every foot of stroke. To find the amount of vibration of the end stud from the square of the radius in inches described by the stud, subtract the square of the length of the crank in inches; extract the square root of the remainder, which deduct from the radius in inches. To find the proper distance between the main centre and the centre of the cylinder: add the above-mentioned square root to the radius of the lever in inches; half their sum will be the horizontal distance in inches. The main centre of a land-engine beam is usually fixed in with 1380. keys; the other centres are sometimes fixed with keys, and at other times they are ground in, which appears to be the preferable practice. The beam is set upon its edge on two blocks of wood; a straight-edge is applied to ascertain if it is nearly straight, and if bent or twisted it is brought straight by being hammered with the face of the hammer, though this practice weakens the beam if carried far. A cross-piece of wood is put into each main-centre SCALE.-11 inch=1 foot. hole, upon which the central point is marked; the beam is plumbed, the end centres are put through, staked with wedges, and levelled by means of a short level with two legs passing down from the edge of the beam. The lengths from the main centre are next ascertained to be right, and the main centre is then put in, using the end centres as points to measure from. Finally, the keys are fitted. This is the mode of procedure when the holes for the centres are not bored out. It is expedient to put a centre line on the edge of the beam to fix the position of the studs laterally, and this is generally 1385. done. The force acting at each end of an engine-beam may be taken at 14 pounds per circular inch of the piston, or, if the beam be supposed to be sup- ported at both ends, it may be taken at 28 pounds per circular inch acting at the centre. The depth of the beam at the ends i.,10⁻s being one third of the depth SCALE.-11 inch=1 foot. at the middle, to find the di- mensions at the middle, divide 1386. the weight in pounds acting at the centre by 250, and multiply the quotient by the distance in feet between the supports. To find the depth, the breadth being given, divide this product by the breadth in inches, and extract the square root of the quotient, which is the depth. It is expedient, however, to make main beams stronger than is in- SCALE.-11 inch=1 foot. dicated by any of these rules, as a higher pressure of steam is now used almost universally than was employed by Mr. Watt. In our rules for the dimensions of beams at the centre, the resulting figures represent the web of the beam, or the dimensions within the beads, if the pressure of the steam be above that of the atmosphere. 1387. K 1388. SCALE.-11 inch=1 foot. The parallel motion.-Figs. 1381 and 1382 represent the radius bars, and Figs. 1383 and 1384 the parallel bars. The screws at the end of the parallel bars enter holes in the cross-bar shown in Figs. 1385 and 1386, and to the exterior bearings of the same cross-bar the radius-bars are attached, the other ends of those bars being attached to studs fixed to the spring beams in the line of the piston-rod. Digitized by Google 477 SCALE.-11 inch=1 foot. it 1f. f It [*[ X 1384 Digitized by Google < 86"s aw } 5-1 & 5" 3 1/8 It it 16 1 1 1383. ENGINES, DETAILS OF. t in ft O 11 I ! 1 # 1 1382. 4 02"s 11 ] I's 2n 12 Ll 11 ] 1381. 478 ENGINES, DETAILS OF. 1390. 1389. 1391. 1393. 1392. it SCALE.-11 inch=1 foot. Figs. 1387 and 1388 represent the 1395. back links, the upper brass of which en- circles the air-pump stud in the beam 1396. the middle brass receives the cross-head on the top of the air-pump rod, and the lowest brass connects with the cross-bar of back links, Fig. 1386, through the oval hole in which the air-pump rod passes. The sectional area of the back links is made the same as that of the air-pump rod, which is one tenth of the diameter of the air-pump, or one twentieth of the diameter of the cylinder. The sectional area therefore of the two back links taken together is equal to the area of a circle one-twentieth of the diameter of the cylinder; but in practice they are gen- erally made of somewhat stronger pro- portions. The best proportionment of the par- allel motions of land engines, and that now followed universally, consists in making the radius and parallel rods of exactly the same length, and this length equal to half the radius of the great beam. The stud from which the back links are hung is in this case situated midway between the main centre and the end stud of the beam, and the studs in the spring beams round which the radius bars move, are in the same verti- cal line as the centre of the cylinder. To find, therefore, the right position for those studs, measure down perpendicu- larly from the centre of the end stud, when the beam is level, to a distance equal to the length of the main or back links, and at this distance draw a horizontal line on the inner sides of the spring beams. Then set off from the main centre on this line the distance between the main centre and centre of the cylinder; the point of intersection is the right position of the studs in the spring beams to which the radius or bridle rods are attached. The back links and the main links are always of the 1397. same length, and ,,77 are now gener- ally made half the length of the stroke, or the length of the crank, as we have already stated. The air-pump cross-head is in- SCALE.-1t inch=1 foot. Digitized by Google 479 1.81 78 of 10 6Key seals it f broad. 10" 9't & 10+ Digitized by Google 10 1398. 1399. ENGINES, DETAILS OF. 0'8 #7 10 or $ SCALE.-1 inch=1 foot. $ ord 1401. 1400. "If 480 ENGINES, DETAILS OF. serted in the back links at the middle of their length. This point in the back links moves, it is obvious, in the vertical line, for as the top of the links follows the motion of the main beam, and the bottom that of the radius bars, which have the same radius and the same length of motion as the stud in the beam from which the links are suspended, the central point of the links will have motion in a curve equally removed from that of each end, which will be a straight line very nearly. The line traced 1402. 1404. 1408. 1409. 1 1403. 2 4 00 22 1 4 it 2 2" 00/00 1 cow on ] 6 1407. 1405. 1 1 by the parallel motion is not precisely a straight line, but a species of S 1406. curve; it approaches to a straight line, however, with sufficient nearness for every practical purpose. Notwithstanding the elegance of the parallel motion, Brass Stude. as an expedient for maintaining the perpendicular position of the piston-rod, it is questionable whether guides are not to be preferred. In this country they are very generally used, even with very long strokes and very short beams; and in some of the steam vessels in England they have been substi- X do 2 tuted with advantage. The adjustment of parallel motions is a difficult task and unless the parallel motion be very true it will be difficult to keep good packing in the stuffing-box, and the cylinder will speedily be worn oval. Figs. 1389 and 1390 represent the air-pump cross-head, which fits into the central brasses of the back links. Fig. 1391 is the pillar which fits between the brasses; and Figs. 1392, 1393, and 1394, are different views of the brasses, &c., of the air-pump cross-head. The parts appertaining to the air-pump are made of the size that would be requisite for a cylinder of the same diameter. Digitized by Google ENGINES, DETAILS OF. 481 Figs. 1395 and 1396 are views of the connecting-rod, which is of cast-iron. Malleable iron connecting- rods are now coming into use for land engines, and they are in every way preferable. When the con- necting-rod is of cast-iron, of the form represented in the figure, the breadth across the arms of the cross is made about 1-20th of the length of the rod; the sectional area at centre of rod 1-28th of the area of the cylinder, and the sectional area at ends of rod 1-35th of the area of the cylinder. Fig. 1397 shows the form of sectional area at centre. The length of the connecting-rod is generally made about three times the length of the stroke. The diameter of the crank-pin is about one-sixth of the diameter of the cylinder, and is generally made of cast-iron in land engines. The gudgeons of water-wheels are generally loaded with about 500 pounds for every circular inch of their transverse section, which is nearly the proportion which obtains in the end studs of engine-beams, but the main centre is usually loaded beyond this proportion. To find the proper size of a cast-iron gudgeon adapted to sustain a given weight, multiply the weight in pounds by the intended length of bearing expressed in terms of the diameter, divide the product by 500, and extract the square root of the quotient, which is the diameter in inches. For malleable iron the operation is the same, but the divisor may be made 1,000 instead of 500. These strengths are not intended to resist torsion, but are those proper for gudgeons. Experiments upon the force requisite to twist off cast-iron necks show, that if the cube of the diameter of the neck in inches be multiplied by 880, the product will be the force of torsion in pounds which will twist them off when acting at 6 inches radius. The strength for cast-iron crank-shafts may be determined by multiplying the square of the diameter of the cylinder in inches by the length of the stroke in feet, multiplying by the decimal -15, and extracting the cube root of the product, which is the proper diameter of the shaft-neck in inches. This rule has reference not merely to torsion, but also to the strength as a gudgeon necessary to sustain the fly-wheel. Messrs. Fenton and Murray use the following rule for determining the weight of the fly-wheel:- Multiply the number of horse power of the engine by 2,000, and divide the product by the square of the velocity of the circumference of the fly-wheel in feet per second; the quotient is the proper weight of the fly-wheel in hundred-weights. To find the weight of the rim of a fly-wheel in pounds, multiply the mean diameter of the rim in feet by the area of its transverse section in square inches, and multiply the product by 9817 pounds. This gives the weight of the rim in pounds when the sectional area is determined. Mr. Farey gives the following rule for determining the proper quantity of cast-iron in a fly-wheel in cubic feet :-Multiply the mean diameter of the rim by the number of its revolutions per minute, and square the product for a divisor; divide the number of horse power exerted by the engine by the number of strokes the piston makes per minute; multiply the quotient by the constant number 2,760,000, and divide the product by the divisor found as above. The quotient is the requisite quantity of cast-iron in cubic feet to form the fly-wheel rim. In large engines each arm is cast separate, and after having been fitted to the central boss, the rim of the wheel is fitted to the arms in segments. In small engines, an arm and a segment are generally cast together. In mill engines it appears expedient to work with a short stroke and rapid piston, whereby the fly-wheel is de more effectual, or a smaller one will suffice. We do not approve of the plan of putting cast-iron cranks on hot, as the cye is liable to be cracked in the process: it is preferable, we conceive, to grind them upon the shaft, and then to fix them by means of a strong square key, such as that shown in Fig. 1399. In cranks which are put on hot it is expedient to recess the crank-eye a little, 80 as to enable the collar upon the shaft to enter it, as the crank contracts sideways in the act of cooling; and unless the collar be recessed a space will be left between it and the crank-eye, which will be a disfigurement. The crank-pin is made slightly taper, and is fixed in by means of a key. Figs. 1400 and 1401 are representations of the eccentric-rod, and Figs. 1402 to 1409 are views of the several parts of the governor. We have given rules for determining the proportions of governors, and the arrangement of the parts here figured will be apprehended by a reference to Fig. 1402. The upright revolving spindle on which the collar shown in section, Figs. 1405 and 1406, slides, and the curved guide, Figs. 1408 and 1409, is fixed. From the top of the spindle, the arms, Fig. 1402, are suspended, with the balls at the end, the arms moving in the slit in the curved guides, Figs. 1408 and 1409. The divergence or collapse of the balls causes the collar to slide up or down on the spindle; and through a slit shown in the spindle, (which is hollow,) this movement is communicated to a rod sliding within it, which, by a suitable attachment, moves the throttle-valve. Horse power. Diameter of cylinder. Length of The speed given by Mr. Farey, in a table, from stroke in feet. Number of strokes per minute. Speed in feet per minute. Effective pres- sure per square inch in lbs. which the annexed is an extract. In this table the pressure is taken to vary slightly 4 12 3 29 174 6.8 with the size of the engine; but Messrs. Boulton and 8 16 4 24 192 6.84 Watt now adopt a uniform pressure of 7 pounds on 12 19 4 25 200 6.88 the square inch, as a preferable element of computa- 16 211 41 23 207 6.91 tion. The speed of the piston in feet per minute is 20 about 128 times the cube-root of the stroke; and the 234 5 211 215 6.92 30 281 6 19 228 6.92 nominal horse power of an engine may be found by 40 311 7 17} 245 6.92 multiplying the square of the diameter of the cylinder 50 35g 7 17} 245 6.94 in inches by the cube-root of the stroke in feet, and 60 381 7 17} 245 6.94 dividing by 47. To find how many millions of pounds 70 401 8 16 256 6.94 are raised 1 foot high by the consumption of a bushel 80 431 8 16 256 6.94 or 84 pounds of coal :-Divide 16632 by the number 90 46g 8 16 256 6.94 of pounds of coal consumed per hour by each horse 100 48% 8 16 256 6.94 power; the quotient is the number of millions of 61 Digitized by Google 482 ENGINES, DETAILS OF. pounds raised 1 foot high by the consumption of 84 pounds of coal A bushel of Newcastle coal will weigh about 84 pounds, but the Welsh coal is heavier. If a cubic inch of water be supposed to produce a cubic foot of steam, and the latent heat of steam at 212° be taken, with Mr. Watt, at 960°, or, in other words, the cubic foot of steam be supposed to contain as much heat in the latent form as would raise the temperature of the cubic inch of water, if it could be prevented from expanding, 960°, then the sum of the latent and sensible heats will be repre- sented by 1172°. The temperature of the water discharged by the air-pump is about 100°, which, taken from 1172°, leaves 1072°, which must be taken up by such a quantity of cold water that its temperature will not rise above 100°. If the temperature of the injection water be 50°, then the difference between that and 100°, viz. 50°, is available for the absorption of the heat; and 1072 divided by 50 = 21:44, which is the number of times the quantity of injection water must exceed the quantity of water in the steam. To condense a cubic inch of water, therefore, in the shape of steam, 21.44 cubic inches of injection water are necessary; but inasmuch as the water may not always be as cold as 50°, Mr. Watt's practice was to allow a wine pint, or 28.9 cubic inches of injection water for every cubic inch of water converted into steam. The capacity of the cold-water pump is usually made from one thirty-sixth to one forty-eighth of the capacity of the cylinder. The injection orifice should have an area of about one fifteenth of a square inch per horse power. The capacity of the hot-water pump should be about one 240th of that of the cylinder, supposing that the engine is double-acting, and the pump single-acting. The air-pump is usually made half the diameter of the cylinder, and half the stroke, or one eighth of the capacity. The power requisite to work the air-pump is from one thirtieth to one fortieth of the power of the engine. The openings through the foot and delivery valves are made of about one fourth of the area of the pump. The internal diameter of the steam-pipe may be found by dividing the horse power by 08, and extracting the square root of the quotient. We shall reserve what we have to say on the subject of bolts until we come to speak of the holding-down bolts of marine engines. 1410. There are many other kinds of parallel motion besides those which we have mentioned, but there are none of them of sufficient importance to justify a lengthened description. Fig. 1410 represents a spe- cies of parallel motion invented by Mr. James White, and published in his New Century of Inven- tions," in 1801. It depends on the principle that an encloidal curve, formed by one circle rolling within another, becomes a straight line when the diameter of the outer circle is just twice that of the inner one. A large wheel, with teeth on its inner circumference, is fixed on a frame concentric with the axis and circle of the crank. A wheel with external teeth is fixed freely on the crank-pin and the point of attachment of the piston-rod. By this arrangement the small wheel is compelled, by the pressure of the piston-rod upwards, to roll round the great circle, ascending on the one side, and descending on the other, so that the distance of the end of the piston-rod from the point of contact of the circles is always equal to the distance of the circle from the diameter. The fault of this species of parallel motion is, that the socket in the centre of the revolving wheel is exposed to a strain equal to twice that on the piston, and which it cannot conveniently be made long enough to resist, 80 that it is liable to break or speedily shake loose. In the plate of direct-action engines, various modifications of the parallel motion will be observed. In the Gorgon engine, by Messrs. Seaward, the parallel motion is formed by the application of a radius-bar to the air-pump lever, whereby one radius is made to counteract the other,-the centre of the lever resting upon a jointed pillar, in order to enable the cylinder end of the lever to move up and down in a vertical line. This species of parallel motion is sometimes made with a horizontal slide for the centre to move in, instead of a vibrating pillar or link; but a slide works slack sideways, and is not satisfactory in practice. The combination might be improved by causing the sliding ends of the rods, which in some cases are used instead of a lever, to work into stuffing-box tubes hung on a centre, so as to enable them to swivel. The rods, so soon as any wear took place, could be tightened afresh by screwing up the packing. Marine engines: Cylinder.-In the marine engine the cylinder-bottom is more frequently cast in, than in land engines, and a plug of metal is fitted into a hole in the centre of the bottom, which is left Digitized by Google ENGINES, DETAILS OF. 483 to allow the boring-bar to pass through. It is necessary that the cylinder should be bolted very firmly to the sole-plate, as in engines which exhaust at the under side of the valve-casing, an air-tight joint has to be made between the sole-plate and the part of the cylinder-bottom next to the valve. A cylinder of about 6 feet diameter is usually made about 11 inch thick, and the metal should be hard as well as solid. Messrs. Maudslay's practice in side-lever engines is to cast the cylinder-bottom in, up to 60 inches diameter, and above that size they prefer casting the cylinder open at the bottom, and making the bot- tom out of the sole-plate. A projection is cast on the sole- plate, to go a certain distance into the cylin- der, with a space hollowed out for the cylinder-port. The bottom joint should not be of rust, but metal to metal-the bottom flange of the cylinder and the place on which it stands on the sole-plate being both faced in the boring-mill. The cylinder cover should fit SO nicely as to be tight, by interposing a piece of lead or a ring of wire gauze, smeared with white or red lead. In oscillating engines the cylin- der bottom is generally cast in, whatever be the size of the cylinder. The valve-casing should be attached to the cylinder by means of a metallic joint, or, in other words, by fitting the surfaces SO accurately that a little red-lead interposed will make them tight. The valve- casing can thus be easily removed at any time to repair the valve faces; whereas, if the joint of the casing be of rust, the removal of the casing is an operation of much difficulty. The attachments of the cylinder to the diagonal stay are very generally made too small; that is, the surface is too small, and the flange too thick. A very thick flange cast on any particular part of a cylinder endangers the sound- ness of the cylinder by inducing an unequal contraction. It is much the best way to make the flange for the framing thin, and the surface large. The bolts, too, should be turned bolts, and nicely fitted. Some persons make them with a nut at both ends, the body of the bolt being made with a little taper; and the nut which answers to the head is screwed up after the conical part of the bolt has been drawn into the hole by the nut at the point. The object of this plan is to facilitate the fitting; but if the fitting be well done, it is unimportant whether it is done in this way or any other. Cylinders are not now usually made with steam-casings, yet experiment has satisfactorily proved that there is a loss of power consequent on their relinquishment. It is not very easy to discern the cause of this loss, as there is more radiating surface in the casing than in the cylinder; yet the existence of the loss is very certain. Mr. Watt, in some of his early trials, discontinued the steam-jacket; and he found the consumption of fuel to be materially increased. He therefore again resumed it, but it has been again discarded in most of the modern engines, except those of the Cornish construction. Escape- valves, for letting out any water that may enter with the steam, are now usually employed in marine engines: they may in most cases be applied conveniently to the ports of the cylinder, as shown in the details of engines of the West India packets, and may be kept shut by a spring, in the same manner as the safety-valve of a locomotive. Escape-valves should be placed on that side of the cylinder which is nearest the side of the ship; so that the attendants may not be scalded by the issuing water if the en- gine primes. The escape-valve is shown beneath the Plan of Cylinder" in the West India mail engine details; and to those details the remarks which follow are to be understood to refer, except where specified to the contrary. In boring cylinders of 74 inches diameter, the boring-bar must make one revolution in about 41 minutes, so that the cutters will move at the rate of about 5 feet per minute. In boring brass, the speed must be slower: the common rate at which the tool moves in boring brass air- pumps is about 3 feet per minute. If this speed be exceeded the tool will be spoiled, and the pump made taper. The speed proper for boring a cylinder will answer for boring the brass air-pump of the same engine. A brass air-pump of 36} inches diameter requires the bar to make one turn in about 8 minutes, which is also the speed proper for a cylinder 60 inches in diameter. To bore a brass air-pump 36} inches in diameter requires a week, an iron one requires 48 hours, and a copper one 24 hours. In turning a malleable iron shaft, 124 inches in diameter, the shaft should make about five turns per minute, which is equivalent to a speed in the tool of about 16 feet per minute. A boring-mill, of which the speed may be varied from one turn in six minutes to twenty-five turns in one minute, will be suitable for all ordinary wants that can occur in practice. Piston.-The proportion of taper given to the piston-rod where it fits into the piston, in the West India mail engines is a good one; if the taper be too small, the rod is drawn through the hole, and the piston is split. Small grooves are turned out of this piston-rod above and below the cutter-hole, and hemp is introduced, in order to make the piston-eye tight. Most piston-rods are fixed to the piston by means of a gib and cutter, as shown in the figures of details, but in some cases the upper portion of the rod within the eye is screwed, and it is fixed into the piston by means of an indented nut. This nut is in some cases hexagonal, and in other cases the exterior forms a portion of a cone, which completely fills a corresponding recess in the piston. But nuts made in this way become rusted into their seat after some time, and cannot be started without much difficulty. Messrs. Miller, Ravenhill and Co, fix in their piston-rods by means of an indented hexagonal nut, which may be started by means of an open box key. The thread of the screw is made flat upon the one side, and much slanted on the other, whereby a greater strength is secured, without any disposition to split the nut. When pistons are made of a single ring, or of a succession of single rings, the strength of each ring is tested previously to its introduction into the piston, by means of a lever loaded by a heavy weight. The old practice was to depend chiefly upon grinding, as the means of making the rings tight upon the piston or upon one another; but scraping is now chiefly relied on. A slight grinding, however, with powdered Turkey stone appears to be expedient, which may be most conveniently accomplished by setting the piston on a revclving table, and holding the ring stationary by a cross-piece of wood while the table turns round. -Pieces of wood may be interposed between the ring and the body of the piston, to keep the ring nearly in its right position; but these pieces of wood should be fitted 80 loosely as to give some side-play, else the ring will wear itself into a groove on the piston. Messrs. Penn grind their cylinders after they are bcred, by laying them on their side, and rubbing a heavy piece of lead, made to the curve of the cylin- der, and smeared with emery and oil, backwards and forwards by hand, the cylinder being gradually turned round, 90 as to subject every part successively to the operation. The pistons are also ground Digitized by Google 484 ENGINES, DETAILS OF. into the cylinders with great care, 80 that they are perfectly tight from the commencement. Messrs. Penn's piston for oscillating-engines has a single packing ring, with a tongue-piece, as in Messrs. Mauds- lay's and Messrs. Miller's arrangements. The ring is packed behind with hemp-packing, and the piece which covers the joint is made of sheet-copper, and is indented into the iron of the 1411. ring, so as to offer no obstruction to the application of the hemp. The ring is ground to the piston only on the under edge the top edge is rounded from the inside to a point, and the junk-ring does not bear upon it, but the junk-ring squeezes down the hemp-packing between the packing-ring and the body of the piston. The metallic packing of the piston consists of a double tier of rings, cut into numerous segments. We approve of the plan of adding a nut to the top of the piston-rod, in addition to the cutter, for securing the piston-rod to the cross- head, as shown in Fig. 1411, where the piston-rod is 7 inches in diameter, and the screw 5 inches: the part of the rod which fits into the cross-head eye, is 1 foot 51, inches long, and tapers from 61 to 6 13-16th inches diameter. The proportion of taper is a good one: if the taper be less, or if a portion of the piston-rod within the cross-head eye be left untapered, as is some- times the case, it is very difficult to detach the parts from one another. Cylinder cover.-The cylinder cover in plate of details is cast close, and a few holes are left for taking out the core by, which holes are afterwards plugged up. An annular recess is left in the under side of the cover, for the accommodation of the heads of the piston-bolts. The gland of the stuffing-box is shown on a larger scale on the same plate. Fig. 1412 repre- sents the stuffing-box of the Don Juan steamer, cylinder 68 inches diameter. This appears to us better than that of the West India packets: there is a great advantage in a deep 1412. stuffing-box, especially in the case of vessels intended to perform long voyages. Fig. 1413 represents the cylinder cover of a Cornish engine. The stuffing-box is provided with a lantern brass, into which steam is admitted by a small pipe. There is packing both above and below the lantern 84 brass, to prevent any leakage of air by the stuffing-box; for even if the packing be defective, it will be steam that 14/- leaks in, which is condensable; and such a leak, though it will increase the consumption of fuel, will not diminish the K 10+ power of the engine. It is the usual practice to interpose between the cylinder cover and the cylinder flange a gasket- 186 ring as a joint; but a joint of this kind leaks air impercep- tibly, and it is better to make the surfaces very true, and : to interpose either a ring of sheet-lead or a little red-lead putty. It appears expedient to us that all marine engines should be furnished with steam-jackets, and should also be furnished with spaces in the cover and cylinder-bottom for the admission of steam. Large engines, too, we conceive should be fitted with the lantern brass stuffing-boxes. Fig. 1414 represents the stuffing-box of the Trident, the engines of which are of the oscillating kind by Messrs. Boulton and Watt. The extra depth of this stuffing-box is necessary to counteract the ten- dency to wear oval. This tendency has not been found to occasion much inconvenience in oscillating engines. In engines with the ordinary parallel motion the stuffing-box has a tendency to wear oval, which may be perceived if attention be paid to the setting of the parallel motion. If the piston be moved through a stroke, the gland will be found to move easily upon the piston-rod at some points, and be jammed up tight in the stuffing-box at other points of the stroke; inequalities which clearly show 1414. 1413. SCALE t inch=1 foot. the existence of a very sensible deviation from a perfectly vertical motion. The brass dome attached to the gland and embracing the rod, is an excellent addition; it keeps the grease employed to lubricate the rod, from being split, and prevents grit and dust from getting into the gland, whereby in common engines the rod is frequently much scratched and injured. Metallic packing in the stuffing-box has been used in some engines, consisting in most instances of one or more rings, cut, sprung out, and slipped upon the piston-rod, before the cross-head is put on, and packed with hemp behind. This species of packing answers very well when the parallel motion is true, and the piston-rod free from scratches, and it ac- complishes a material saving of tallow. In some cases a piece of sheet-brass, packed behind with hemp, has been introduced with good effect, a flange, notched to permit the bending, being turned over on the under edge of the brass, to prevent it from slipping up or down with the motion of the rod. Digitized by Google ENGINES, DETAILS OF. 485 Slide-valve.-The slide-valve represented in the plate of details is that known as the long D. The valve-rod is attached to a cross-bridge in the plane of the under face, and the spring upon the rod is sufficient to allow the valve to be tightened up as the face wears. In short D valves, where the valve- rod is very short, the eye which attaches the valve to the rod has to be made oblong, Fig. 1415, or else the holes of the casing-cover have to be made oval, so as to enable the valve-cover to be advanced nearer to the cylinder, as the valve face wears. The valve-packings are introduced by doors at the back of the valve-casing. and are pressed by blocks, of which one is shown in the same plate as the valve. This block, it will be remarked, is in three pieces, which are tongued to one another; it is pressed forward by means of screws, which pass through a cross-bar extending across the packing-port, Fig. 1416, the ends of which rest in two angular lugs cast therein. The purpose of this bar is to pre- vent the strain requisite for tightening the packing from being thrown upon the packing-door, which would spring it out, and might cause the joint of the door to leak. In some cases the screws by which the packing is pressed, pass through the door, and are made tight by a jam-nut, with a recess. into which a turned part of the nut enters, as shown in Fig. 1417 a hemp washer being interposed at the point of contact. In the plate, however, a different plan is shown, which is again represented in Fig. 1417. The packing-screws do not pass through the doors, but are kept short; and opposite to each screw a plug is situated in the packing-door, which has to be withdrawn when the packing is to be tightened. In each of these plugs a small recess is turned out, for the reception of a ring of hemp. This recess is better half-round than square. 1416. 1415. 1417. Some packing-blocks are tightened sideways, by screws which are inserted in the sides of the pack- ing ports; but in the plate the block is tightened by its own wedge-shape point, which presses against another wedge-formed piece, cast on the valve-casing, as will be understood by a reference to Fig. 1418. In some cases the end of the packing abuts upon the cylinder face, but generally it overlaps two or three inches in large engines, and a piece, a, Fig. 1419, is cast on each side of the cylinder port, in con- tinuation of the circle of the valve, to furnish a surface upon which the packing may press. By this expedient the chance of leakage at the corner of the valve is diminished, and the length of the packing need not be adjusted with such critical exactitude as is necessary by the other arrangement. In some engines the packing of the valve is put in like that of a piston, and is pressed down by means of a junk- ring, but that plan is now little resorted to. Metallic packing has been tried in D valves, but only with very moderate success. The kind that has answered best is a piece of sheet-brass, thinned at the ends, bent to the shape of the valve, and packed behind with hemp. 1419. 1418. 1490. There is a good deal of trouble with every modification of valve faces; but cast-iron working upon cast-iron is perhaps the best combination yet introduced. The usual practice is to pin brass faces on the cylinder, allowing the valve to retain its cast-iron face. Some makers employ brass valves, and others pin brass on the valves, leaving the cylinder with a cast-iron face. Speculum metal and steel have been tried for the cylinder faces, but only with moderate success. In some cases the brass gets into ruts; but the most prevalent affection is a degradation of the iron, owing to the action of the steam, and the face assuming a granular appearance, something like loaf sugar. This action shows itself only at particular spots, and chiefly about the angles of the port, or valve face. At first the action is slow; but, once the steam has worked a passage for itself, the cutting away becomes very rapid, and in a short time it will be impossible to prevent the engine from heating when stopped, owing to the leakage of steam through the valve into the condenser. However truly the D valve may be formed at first, the face will become slightly hollow by the application of heat, as the circular will expand more than the straight part, and the packing resists the enlargement of the circle. The cross-section will therefore assume something of the form shown in Fig. 1420, where the dotted line represents the original position of the face; and on examining a valve newly put in action, it will generally be found that it presses hardest on the tails. The face therefore should be made slightly rounded in the manufacture; and if the engine is a large one, the cylinder must not be faced when lying on its back, unless it has been wedged up to the form it assumes when standing on end, else the partial collapse of the cylinder will Digitized by Google 486 ENGINES, DETAILS OF. cause the face to become untrue. Copper steam-pipes seem to have some galvanic action on valve faces, and malleable iron pipes have sometimes been substituted; but they are speedily worn out by oxydation, and the scales of rust which are carried on by the steam, scratch the valves and cylinders, 80 that the use of copper pipes is the least evil. The valve-rod in that part opposite to the steam-port is often much wasted by the steam; it therefore appears expedient to surround it by a copper pipe where an injurious action is to be apprehended. The valve-casing shown in the plates is made close at the bottom, the exhaustion being accomplished by the upper eduction-pipe. In cases in which exhaustion is performed from below, it is expedient to cast two projections on the sole-plate, to prevent the valve from falling down inconveniently far when the valve links are taken off. There is no expansion joint introduced in the valve-casing of these engines, which is a serious defect, as the steam gains admission to the valve-casing before it can enter the cylinder, and the joints are damaged, and in some cases the cylinder is cracked, by the inequality of expansion of the cylinder and valve-casing. In facing a valve recourse is had to the use of a face plate, to ensure the accuracy of the work. To ascertain whether the face plate bears equally, smear it over with a little red ochre and oil, and move the face plate slightly, which will fix the color upon the prominent points. This operation is to be re- peated frequently, and as the work advances, the quantity of coloring matter is to be diminished, until finally it is spread over the face plate in a thin film, which only dims the brightness of the plate. The surface at this stage must be rubbed firmly together to make the points of contact visible, and the higher points will become slightly clouded, while the other parts are left more or less in shade. If too small a quantity of coloring matter be used at first, it will be difficult to form a just conception of the general state of the surface, as the prominent points will alone be indicated, whereas the use of a large quantity of coloring matter in the latter stages would destroy the delicacy of the test the face plate affords. The scraping tool should be of the best steel, and should be carefully sharpened at short intervals on a Tur- key stone, so as to maintain a fine edge. A flat file bent, and sharpened at the end, makes an eligible scraper for the first stages; and a three-cornered file, sharpened at all the corners, is the best instru- ment for finishing the operation. The number of bearing points desirable on the surface of the work depends on the use to which it is to be applied, but in any case the bearing points should be distributed equally over the surface. Great care must be taken in fitting valve faces that the valve be not made conical: unless the back be exactly parallel with the face, it will be impossible to keep the packing from being rapidly cut away. When the valve is laid upon the face-plate, the back must be made quite fair along the whole length, by draw-filing, according to the indications of a straight edge; and the dis- tance from the face to the extreme height of the back must be made identical at each extremity. Should a hole occur either in the valve, in the cylinder, or any other part where the surface requires to be smooth, it may be plugged up with a piece of cast-iron as nearly as possible of the same texture. Bore out the faulty part, and afterwards widen the hole with an eccentric drill, 80 that it will be of the least diameter at the mouth. The hole may go more than half through the iron: fit then a plug of cast- iron roughly by filing, and hammer it into the hole, whereby the plug will become riveted in, and its surface may then be filed smooth. Square pieces may be let in after the same fashion, the hole being made dovetailed, and the pieces thus fitted will never come out. Brass faces are put upon valves or cylinders by means of small brass screws, tapped into the iron with conical necks for the retention of the brass: they are screwed in by means of a square head, which, when the screw is in its place, is cut off and filed smooth. In some cases the face is made of extra thickness, and a rim not 80 thick runs round it, forming a step or recess for the reception of brass rivets, the heads of which are clear of the face. Air-pump.-The air-pump is attached to the sole-plate by a rust faucet joint, which is preferable to a rust flange joint, as the salt water eats away the heads of the bolts, unless they are copper; and if they are copper, they waste the iron. The oil and grease which fall from the crank-pin upon the sole-plate, deoxidize the rust of a flange joint, whereas with a faucet joint, suitably made, they cannot remain in the same intimate contact. Short steel keys should be driven into the faucet in several places before the joint is made, but they should not rise to the top of the faucet 80 as to divide the joint into segments. The air-pump bucket is made with a junk-ring, whereby the packing of the bucket may be easily screwed down. The valve is of the spindle or pot-lid kind. The foot and delivery are of the flap or hanging kind. These valves all make a considerable noise in working, and are objectionable in many ways. Valves of the same construction as those known as Harvey and West's, which are similar to those shown in Fig. 1360, have been employed with advantage by Messrs. Rennie; and valves on Belidor's construction, which is in effect that of a throttle-valve hung off the centre, were some years ago proposed by us for the delivery and foot-valves. Some delivery-valve seats are bolted into the mouth of the air-pump, apparently in the conviction that the pump-bucket never requires to be looked at. If delivery-valves be put in the mouth of the air-pump at all, the best mode of fixing them appears to be that adopted by Messrs. Maudslay. The top of the pump-barrel is made quite fair across, and upon this flat surface a plate containing the delivery-valve is set, there being a small ledge all round to keep it steady. Between the bottom of the stuffing-box of the pump-cover and the eye of the valve- seat, a short pipe extends, encircling the pump-rod, its lower end checked into the eye of the valve-seat, and its upper end widening out to form the bottom of the stuffing-box of the pump-cover. Upon the top of this pipe some screws press, which are accessible from the top of the stuffing-box gland, and the packing also aids in keeping down the pipe, the function of which is to retain the valve-seat in its place. When the pump-bucket has to be examined, the valve-seat may be slung with the cover so as to come up with the same purchase. For the bucket-valves Messrs. Maudslay employ two or more concentric ring-valves, with a small lift. These valves have given a good deal of trouble, in consequence of the frequent fracture of the bolts which guide and confine the rings; but their principle appears superior to that of any of the other air-pump valves at present in common use, with the exception of the equili- brated-valve, in which it is preferable that the face should fall in a groove filled with end-wood. It would not be difficult to make this groove SO that the water would have to be forced out of it during Digitized by Google ENGINES, DETAILS OF. 487 the descent of the valve, whereby the shock would be still further diminished. It would be preferable, however, if all these valves could be discarded in favor of a slide-valve, which might be applied to the air-pump with much advantage. The air-pump bucket and valves are all of brass, and the chamber of the pump is lined with copper. It is now a common practice to make the chamber of the air-pump wholly of brass, whereby a single boring suffices. When a copper lining is used, the pump is first bored out, and a bent sheet of copper is introduced, which, is made accurately to fill the place, by hammering the copper on the inside. Muntz's metal is sometimes used instead of copper, and Muntz's metal air-pump rods are now as gen- erally used as copper rods or iron rods covered with brass. Iron rods covered with brass are not to be commended; they generally are wasted away where the bottom cone fits into the bucket-eye, and if the casing be at all porous, the water will sometimes insinuate itself between the casing and the rod, and eat away the iron. If iron rods covered with brass be used, the brass casing should come some distance into the bucket-eye; the cutter should be of brass, and a brass washer should cover the under side of the eye, so as to defend the end of the rod from the salt water. Rods of Muntz's metal are, probably. on the whole to be preferred; and it is a good practice to put a nut on the top of the rod to secure it more firmly in the cross-head eye. The part which fits into the cross-head eye should have more taper when made of copper or brass than when made of iron; as if the taper be small, the rod may get staved into the eye, whereby it will be 80 firmly fixed as to make its detachment a difficult operation. Me- tallic packing has in some instances been employed in air-pump buckets, but its success has not been such as to lead to its further adoption. Sole-plate and condenser.-Every marine engine, of the side-lever kind, should be constructed with a sole-plate; and we think it the best way that the condenser be cast upon the sole-plate. Engines un- furnished with sole-plates, and with joints between the valve-casing and condenser below the level of the keelsons, are extremely objectionable. Those joints, either from the working of the ship-the movement of the cylinder or condenser-the deoxidizing effect of the oil spilt about the machinery-or the combination of all these causes-will be sure, sooner or later, to become leaky; and it is almost im- possible to remake or effectually stanch them. Messrs. Maudslay and Co., in their West India mail packet engines, bolted the condenser to the under-side of the sole-plate; by which expedient the rust- joints are preserved, in a great measure, from the action of the grease, and from any strain or vibration consequent upon the yielding of the condenser or cylinder. Messrs. Miller and Co. adopted the same arrangement of condenser, but cast the condenser upon the sole-plate. There are very few of the engines made in Scotland in which the condenser is not cast upon the sole- plate; and in almost all of them the greater part of the condenser is situated above the sole-plate, and the main-centre passes through it. The height of the condenser, in this arrangement, has the advantage of enabling the air-pump to drain it of water very effectually but the same object is accomplishable by the use of a very large eduction-pipe immediately behind the valve-casing into which the injection wa- ter is admitted, and which thus becomes, in effect, a tall condenser. This latter is the arrangement of Messrs. Maudslay and Messrs. Miller. It has the advantage of leaving the space usually occupied above the sole-plate by the condenser, free and unperplexed by any species of machinery except the main- centre, which is supported by pillow-blocks resting or cast on the sole-plate. The practice of passing the main-centre through the condenser, either with or without a pipe, is ob- jectionable. A pipe is calculated to make the sides of the condenser crack by unequal contraction, and the absence of a pipe endangers a leakage of air round the main-centre joint. The keys employed to fix the main-centre will sometimes occasion trouble, from becoming loose; and, in some instances, we have known a main-centre boss to be split, from the keys being driven too hard. In all cases the thick- ness of metal requisite in the condenser sides for resisting the strain of the main-centre, will make the sides more liable to crack, in consequence of being suddenly cooled. Upon the whole, the practice of securing the main-centres by plummer-blocks appears greatly preferable: when the main-centre is made to pass through the condenser, the hole should be bored out, and the main-centre ground in with a little taper. It is the usual practice in engines which have the main-centre passing through the con- denser, to set the hot well on the top of the condenser, and this is the arrangement in the engines of which we have given the details. A part of the hot well is divided off, to serve as an eduction-passage for the conveyance of the steam from the superior part of the valve-casing. By this arrangement there is no danger of water running from the condenser back into the cylinder. Projections are cast in the foot-valve passage for the reception of the foot-valve seat, by means of which it is keyed into its place; and similar projections are cast in the mouth of the air-pump for the reception of the delivery-valve. There does not appear to be any man-hole door to the condenser in this engine, which is a defect. It would have been easy to make a man-hole in the curved nozzle leading from the air-pump to the hot well: a door in that situation would have been easy of access from the hot well man-hole, and it would have always been covered with water when the engine was at work, 80 that a leakage of air could not have taken place. The injection nose-pipe runs across the condenser, near the mouth of the eduction- pipe. A cock, by which water may be injected from the bilge, should the vessel spring a leak, is uni- versally employed in marine engines, and is shown in the sectional drawing of the engines, dotted in. This cock should never be furnished with a rose within the condenser, and should never be joined on to the injection-pipe proceeding from the sea. We have known various cases in which a vessel has been nearly lost from the internal roses of the bilge injection becoming choked up with refuse drawn out of the bilge, and which, but for those roses, would have passed into the condenser and been delivered by the air-pump without creating any obstruction. Framing.-Cast-iron framing is now given up in marine engines, and malleable iron framing alone is employed. It is a bad plan to attach the diagonal stay to the hot well, as is sometimes done, as the working of the stay breaks the hot-well joint. It is a bad plan, too, to attach the framing to the sides of the ship, as the working of the ship in a sea will strain and may break it. In iron steamers a plan now prevails of running the deep beams before and abaft the crank-hatch (which are also made of iron) Digitized by Google 488 ENGINES, DETAILS OF. through the ship's side, joining the extremities of those beams by curved cross-beams, on which the shaft plummer-blocks are made to rest. The paddle-wheel, by this plan, is overhung, and the whole of the arms radiate from a triple centre. A very substantial framing may be made by adopting this arrange- ment, and it is one which is applicable in the case of direct-action engines as well as in those on the side-lever plan. The brasses of the paddle-shaft plummer-blocks should not 1421. be made with fitting strips on the backs, but the whole of their exterior should be planed, and the interior of the plummer-blocks should also be planed for their reception. Brasses fitted with fitting strips soon wear slack sideways. Octagonal bottom brasses are not so good as those which are square, as they cannot be lined up so conveniently if the shaft gets out of truth. Square-bottom brasses, with flanges, as shown in Fig. 1421, we have found preferable to any other variety. Side-lever.-The drawing we have given of the side-lever will sufficiently explain its general form and dimensions. In some of the more recent side-lever engines, the side-levers are made of malleable iron, each lever being composed of two plates, set on edge, the length of the bearings apart from each other. The studs in the side-lever should be steeled, and should be of larger dimensions than is necessary for strength; as if they wear oval, they are likely to burst the side-rod or cross-tail straps, when the brasses are tightened up. Unless the main-centre journals be made spheroidal, there should always be large collars on the main-centre, against which the side-levers may press, so as to prevent lateral play; and the washers on the main-centre ends should be capable of being tightened up against the brasses of the side-lever eye. Without this precaution, the engines will jerk most disagreeably sideways in a sea-way when the brasses come to be at all worn. Cross-heads and tails, side and connecting-rods.-The parallel motion, it will be remarked in the drawings of details, is attached to the cross-head; but parallel motions are now falling into disfavor, and guides are taking their place. The side-rod eye is fitted with a conical bush, with a spiral cut in it, so that it may be tightened upon the cross-head journal by means of a washer drawn in by a screw. In some cases the side-rod eye is fitted with an octagonal brass, tightened by a cutter beneath the under portion; and in other cases the brass is round, and the upper portion is pressed down by means of a screw, which is made hollow, and serves also as an oil-cup. The upper piece is such as would require to be cut out of the brass, in order to permit the journal to come out without being shifted on end and the sliding joints of the bush are rebated, to prevent end-play. In the manufacture of brasses of this kind the pieces are first fitted and soldered together; they are then bored and turned; and finally the soldering is loosened by the application of heat. The cross-tail butts are generally ground on to their places, and the end of the cross-tail riveted over on them, a round steel pin being afterwards intro- duced, half into the cross-tail and half into the butt. In some cases, however, they are put on hot, as practised in the case of cranks; and in the specimen before us a washer is substituted for the riveting of the end. In all cases in which an eye is put on hot against a collar, the eye should be recessed for the reception of a small portion of the collar, as the eye in contracting sideways will leave a space between the collar and the eye, which, by this means, will not be discernible. The connecting-rod is made with a strap to embrace the crank-pin, as is the usual practice. Connecting-ro made in this way should always have a malleable iron cap above the upper brass, instead of having the cap and upper brass made in a piece. If the crank-pin heats, the brass cap will probably be cracked, and cases might be mentioned in which vessels have been nearly lost from such an occurrence. Cranks, eccentrics, shafts, and paddles.-The cranks and shafts of marine engines are now always made of wrought-iron. The crank is shrunk on the shaft hot, and a strong square key is then driven in at the part nearest the web, so as to obviate the weakening of the eye. The crank-pin is fixed in the intermediate crank, and is loose in the eye of the paddle-crank, which is fitted with a bush, upon which the rounded end of the crank-pin bears. The end of the crank-pin, fitting into the eye of the inter- mediate crank. is made conical, and is drawn into its place by a cutter passing through both pin and eye. The rounded end of the pin enables the paddle-shaft to fall at the outer end, as it always does, without breaking the pin. In some cases a drag-link is used instead of the rounded pin, but drag-links are not now much in fashion. A very good method of fixing the crank-pin into the eye consists in the application of a strong washer over the crank-eye, with a hole in the centre, through which a stout bolt passes tapped into the pin. The washer is indented a little into the crank-eye, 80 as to obviate any tendency to move laterally. This plan is unattended with any more trouble than if the pin were riveted in, and it admits of the pin being taken out by merely unscrewing the bolt of the washer. The end of the pin inserted in the loose eye is of course made spheroidal, 80 as to permit the outer end of the shaft to drop a little, without breaking the pin. The pin is steeled on both sides of this spheroidal part, and bears against two dovetailed steel plates. The plate situate on the backing side was, in the case of the Don Juan, tightened by means of a screw passing through the crank-eye. The web of the crank was made thicker and narrower than usual, the intention of the makers being that the web should be capable of resisting the twist occasioned by the overhang of the crank-pin more effectually than is done in the case of cranks whose shape is regulated by the supposition that the crank-pin does not overhang at all. There is more plausibility than soundness in this reasoning; the fact being, that the strength given for the single purpose of overcoming the leverage, is more than sufficient to withstand the twist. The crank-pin must be fitted very accurately into the crank-eye, else it will be very liable to be broken. The crank-pin should always be larger in diameter than is necessary for strength, for the purpose of keeping the journal from heating. The dimensions given in our tables will be found to answer very well, and they are slightly in excess of the common proportions. We may here set down a few remarks about paddle-wheels, which cannot well be severed from the subject of the engine. The best plan of making the centres is with square eyes, and each centre should be secured in its place by means of eight thick keys. The shaft should be burred up against the heads of these keys with a chisel, so as to prevent the keys from coming back of their own accord. If the keys are wanted to be driven back this burr must be cut off, and the keys, if made thick and of the right Digitized by Google ENGINES, DETAILS OF. 489 taper, may then be started without difficulty. The shaft must of course be forged with square pro- jections on it, 80 as to be suitable for the application of centres with square eyes. Messra. Maudslay & Co. bore out their paddle-centres and turn a seat for them on the shaft, afterwards fixing them on the shaft with a single key. The plan is objectionable for two reasons-it is insecure when new, and when old is irremoveable. One of the West India mail vessels, by Messrs. Maudslay, was almost disabled from this cause on the first voyage, the key on the shaft having slackened, and the centre having conse- quently turned round; and in some of the older vessels by the same makers, lately under repair at Woolwich, the centres had to be broken off, for they could not be got off in any other way. With this plan of centre we have often known the centres to shift: in one case the wheel on the weather side was forced against the side of the ship, and the floats, in their revolution, cut deeply into the outside plank- ing. The plan of making round bosses on the shaft, and fixing the centres with four keys, as shown in our plates of details, is also objectionable on the ground of insecurity. The general practice among the London engineers, is to fix the paddle-arms at the centre to a plate by means of bolts, Fig. 1422, a projection being placed upon the plates on each side of the arm, to pre- vent lateral motion. We have found this method to be inferior in durability to that adopted in the Clyde, Fig. 1423, in which each arm is fitted into a socket by means of a cutter, a small hole being left opposite to the end of each arm, whereby the arm may be forced back by a drift. A preferable way would be to form the paddle-centre out of the arms themselves, by widening them at the head until they touch one another, Fig. 1424, and then applying a boiler-plate upon one side, and riveting the arms firmly to it. If this plan be adopted, it will be expedient to swell the tops of the uncovered side at the part nearest the centre, 80 as to increase the length of bearing for the keys which secure the centre to the shaft. In the manufacture of this centre the heads of the arms would first be forged, then planed on the edges and fitted together on the plate. The holes would then be bored for the rivets, temporary bolts fitted into them, and the key-seats cut and the ends of the arms pared in the slotting- machine. Finally, the arms would be welded on to the heads, and the various parts of the wheel riveted together. 1424. 1423. 1422. Most of the London engineers join the paddle-arms to the outer ring, by means of bolts, but those bolts, after a time, generally become slack sideways, and a constant working of the parts of the wheel goes on in consequence. Some engineers form the part of the outer ring opposite the arm into a mortise, Fig. 1425, and they wedge the arms tight in the hole by wedges driven in on each side. But the plan is an expensive one, and not satisfactory, as the wedges work loose even though riveted over at the point. The best mode is the plan for the most part practised in the Clyde, Fig. 1426, of making the arm with a long T-head, and riveting the cross-piece to the outer ring with a number of rivets, not of the largest size, which would weaken the outer ring too much. The best way of securing the inner rings to arms is by means of lugs, Fig. 1427, welded on the arms, and to which the rings are riveted. 1425. 1420. 1427. Paddle-floats are usually made either of elm or of pine; if of the former, the common thickness for large sea-going vessels is about 21 inches; if of the latter, 3 inches. They should have plates on both sides, else the paddle-arms will be very liable to cut into the wood, and the iron of the arms will be rapidly wasted. When the floats have been fresh put on, they must be screwed up several times before they come to a bearing. If this be not done, the bolts will be sure to get slack at sea, and all the floats 62 Digitized by Google 490 ENGINES, DETAILS OF. on the weather side may be washed off, as once occurred to the British Queen, on the next voyage after the floats had been removed to allow the vessel to go into dock. It is a good plan to give the threads of the paddle-blocks a nick with a chisel after the nut has been screwed up, which will prevent the nut from turning back. The floats should not be notched out, to allow of their projection beyond the outer ring; as, if the sides of the notch be in contact with the outer ring, the ring is soon eaten away in that part, and the projecting part of the float, being unsupported, is liable to be broken off. It is usual to put a steel plate at each end of the paddle-shaft, tightened with a key, to prevent end-play when the vessel rolls, but the arrangement is precarious and insufficient. Messrs. Maudslay make their paddle- shaft bearings with very large fillets in the corner, with the view of diminishing the evil; and Mr. R. Napier causes the crank-eyes of both paddle and intermediate cranks to bear sideways against the brasses of the plummer-blocks. It would be preferable to make the bearings of the crank-shafts spheroidal, and, indeed, it would be an improvement if most of the bearings about the engine were to be made in the same fashion. The spheroidal form would not only prevent end-play, but would keep the oil from running out at the ends of the bearings. The loose end of the crank-pin should be made not spheroidal, but consisting of a portion of a sphere, and a brass bush might then be fitted into the crank-eye, that would completely encase the ball of the pin, and yet permit the outer end of the paddle-shaft to fall without straining the pin, the bush being at the same time susceptible of a slight end-motion. This arrangement is far preferable to that of making the pin bear upon a single point, as is the common practice. There is an inconvenient amount of wear on the pin, which involves a back- lash in the eye, and the point of contact sometimes heats and screeches, unless the eye be kept well supplied with tallow. Disengaging paddle-wheels.-Many plans have been contrived for disengaging the paddle-wheels of steamers, so as to enable one paddle to be worked without the other, or both paddles to be thrown out of geer, so as to revolve loosely when the vessel is under sail. The best of these expedients is that represented in Figs. 1428 and 1429, where A is the paddle-shaft; B, a cast-iron disk keyed thereon; C, 1428. 1429. c B B a wrought-iron strap surrounding the disk, lined with brass; D, a brass cushion with a tightening key for producing friction, by bringing the cushion in contact with the disk; F, the brass lining of the wrought-iron strap, excepting that portion occupied by the cushion; fff, screws by which the brass lining is held to the strap. A few blows of a hammer on the key D will connect or disconnect the paddle-shaft, even when the engines are at full speed. Messra. Maudslay's method of disconnecting is to shift the 1431. shaft on end by suitable geer, until the crank-pin leaves the crank-eye. Messrs. Miller's method is to put a clutch on the shaft, which catches into the paddle-centre-the whole of the a three centres being combined into one diverging one, which runs loose on the shaft. A method contrived by Mr. Grantham 1432. is represented in Figs. 1430, 1431, and 1432, where A is a moveable bush in the paddle-crank eye; B, the crank; C, a di screw for moving in or out the bush; D, crank-pin; E, slot in b b the crank-eye to permit the pin to pass in the revolution of the crank, except when the pin-bush is moved out to engage it B F, square head of screw C; G, H, the bush engaged with the B 1430. $ crank-pin. It is obvious that by screwing the bush out or in, 3 3 the crank-pin is either engaged with or disengaged from the paddle. In Messrs. Seaward's engines a method of disen- 1 gaging almost identical with this is sometimes employed. Eccentrics-The eccentrics of marine engines are always put on in two pieces; they are almost always loose on the : shaft, and are always capable of backing. The manner in which that shown in our plates of details is made, is a common one. The eccentric is loose upon the shaft, and is furnished with a back balance and catches, and the halves are put together with rebated joints, to keep them from separating laterally; and they are prevented from sliding out by round steel Digitized by Google ENGINES, DETAILS OF. 491 pins, each ground into both halves. Square keys would be preferable to round pins in this arrange- ment, as the pins tend to wedge the jaws of the eccentric asunder. In some cases the halves of the eccentric are bolted together by means of flanges. The eccentric-rod shown in the plates of details is not a particularly neat one. The eccentric-rod of the Don Juan is represented in Fig. 1433, and that 1433. form is now widely adopted It is expedient to cast an oil-cup on the eccentric-hoop, and where it is practicable, a pan should be placed beneath the eccentric, for the reception of the oil-droppings. The notch of the eccentric-rod, for the reception of the pin of the valve-shaft, is usually steeled, to prevent inconvenient wear; for when the sides of the notch wear, the valve movement is not only disturbed, but it is very difficult to throw the eccentric-rod out of geer. It is found to be preferable, however, to fit this notch with a brass bush, Fig. 1434, for the wear is then less rapid, and it is an easy thing to replace this bush with another when it becomes worn. The eccentric catches shown in the plates are the kind usually employed, but catches of this kind sometimes break off at the first bolt-hole, and it is preferable either to have a bolt in advance of the catch-face, as in Fig. 1435, or to have a hoop encircling the shaft, with the catches welded on it, the hoop itself being fixed by bolts or a key. This hoop may either be put on before the cranks in one piece, or afterwards in two pieces, as shown in Fig. 1436. The 1436. 1435. 1434. expansion-cam is figured in the plate; it is put on the shaft in two pieces, which are fastened to each other by means of four bolts passing through lugs, and is fixed to the shaft by keys. A roller at one end of a bell-crank, which is connected with the expansion-valve, presses against the cam, so that the motion of the lever will work the valve. The roller is kept against the cam by a weight on a lever attached to the same shaft. If the cam were concentric with the shaft, the lever which presses upon it would remain stationary, and also the expansion-valve; but by the projection upon the cam, the end of the lever receives a reciprocating motion, which is communicated to the valve. The position of this projection determines the point in relation to the stroke at which the valve is opened, and the extent of the projection determines the duration of opening. The time at which the valve should begin to open is the same under almost all circumstances; but the duration of its opening varies with the amount of expansion desired. In order to obtain this variable expansion, there are several projections made upon the cam, each of which gives a different degree or grade, as it is usually called, of expansion. These grades begin at the same point on the cam, but are of different lengths, so that they would begin to move the lever at the same time, but would differ in the time of returning it to its original position. The change of expansion is effected by moving the roller on to the desired grade. There are seven different grades in the West India steamers. The expansion-valve is of the kind used in the Cornish engines, and known as the equilibrium valve. Of the valve-shafts and links, parallel-motion rods, and other similar details, it is needless here to speak, as there is nothing of difficulty connected with those parts, and the plates make their arrangement sufficiently intelligible. Starting-geer.-The best starting geer is Stephenson's link motion, which will be described in our remarks respecting details of locomotives. This combination obviates the necessity of throwing the engines out of geer at all; and full speed ahead may be changed instantaneously into full speed astern, and without stopping the engines. Messrs. Rennie have introduced this species of starting-geer into the Samson and some other steam vessels with the most satisfactory results; and it appears likely to become general, at least in valves where there is little lap. In our plates of details the valve is moved by means of a lever, and the eccentric-rod is thrown out of geer by means of a pulley on the end of a lever, which, when raised, forces the pulley against the under side of the rod and lifts it out of the notch. The act of raising this pulley depresses another pulley on a lever fixed upon the same shaft, and enables another rod in connection with the starting-handle to fall into geer, the intention being, that when the eccentric-rod is in geer, the starting-handle shall be without motion, as its swinging would be Digitized by Google 492 ENGINES, DETAILS OF. inconvenient and dangerous if worked by the engine. This plan of preventing the starting-handle and the eccentric-rod from being in geer at the same time has now come into general use. The method adopted by Napier in the Precursor is a very elegant one: it consists in the use of an eccentric-stud for supporting the lever which carries the roller; and the act of moving this lever, 80 as to enable the eccentric-rod to fall into geer, draws back the pinion of the starting-shaft out of the sector, with which it is engaged. Instead of a lever, the starting-shaft in this case is moved by a wheel similar to a steering wheel of a ship. Brine-pumps.-Pumps for changing the water in marine engine boilers, so as to prevent the salt water from reaching an inconvenient degree of saturation, were first applied by Messrs. Boulton and Watt to the City of Edinburgh steamer, and their use is now very general. In the engines of the Centaur, represented in the plate of direct-action engines, the brine-pumps are set on each side of the feed-pump, and are wrought with it off the air-pump cross-head. In some cases the feed water is sent into a vessel called a refrigerator, through which the super-salted water proceeding from the boiler to the brine-pump is conducted in a multitude of small pipes,-the intention of the arrangement being to economize heat by communicating the heat of the super-salted water to the feed. But the amount of heat thus saved is exceedingly unimportant, and the refrigerators are not only expensive to construct, but are very liable to be choked up by deposite. They thus become a source of danger, as the engineer is led to confide in an expedient which may deceive him, while he believes it to be in effective operation. The valves of brine-pumps require to be loaded sufficiently to counteract the pressure of the steam, and of the head of water in the boiler. If brine-pumps be used, it appears preferable to use them without the refrigerator; they then become equivalent to a continuous blowing off, but the pipes are less liable to choke, and there is no blowing off while the engines are at rest. Sea-water contains about 1-33 its weight of salt, and its specific gravity is increased by boiling until it contains 12-33 of salt, which is the point of saturation, and the water will not then hold more salt in solution. As the water is more concentrated, it requires a higher temperature to make it boil. The boiling point of sea-water which has 1-33 of salt, is 2132°; with 2-33, 214'4°; with 3-33, 215-5; with 4-33, 216-7°; with 5-33, 217.9°; with 6-33, 219°; with 7-33, 220.2°; with 8-33, 221.4°; with 9-38, 222.5°; with 10-33, 223.7°; with 11-83, 224'9° and saturated water 226°. These are the boiling points in the open air in a steam boiler, where the pressure of steam is always above the pressure of the atmosphere, the boiling points will be correspondingly higher, but with any uniform pressure of steam in the boiler it is possible to make the thermometer an index of the saltness of the water. If the water be maintained at a concentration of 4-33, or if about one-fourth of the water be with- drawn from the boiler by the brine-pumps that is forced in by the feed-pumps, very little deposite will collect within the boiler. The quantity of fuel wasted by blowing off this quantity of water, cannot, it is clear, be considerable, and there should not be less blown off. Of every 4 cubic feet of water entering the boiler from the 1437. hot-well, 3 passes off in steam and 1 in brine. The temperature of the hot-well being 100°, the heat imparted to the water to raise it into steam, may be represented by 1112° X 3 = 3336, while the heat contained in the brine is 112°, or rather less, the specific heat of brine being less than that of fresh water, and 3336 ÷ 112 = so that about 1-29th of the heat passes out of the super-salted water when large blowing off is practised. A much larger quantity of heat than this goes to waste if there be any material accumulation of scale upon the flues, and engineers will therefore see that there is no economy in penurious blow- ing off. Pumps, cocks, and pipes.-In the plates of details the feed- pump plunger is shown with a screw at the bottom, for the extraction of the core, but it appears preferable to extract the O core out of a hole in the top, which may be adapted for the reception of the pump-rod. There should be a considerable clearance between the bottom of the plunger and the bottom of the pump-chamber, as otherwise the bottom of the chamber may be knocked out, should coal-dust or any other foreign substance gain admission, as it probably would do, if there were any in- jecting from the bilge. Messrs. Maudslay make the feed and bilge pump plungers serve as guides to the air-pump cross-head, the pump-rods being continued upwards and working through eyes in the framing. We do not see any objection to this arrangement, if the stuffing-boxes be made deep when separate guide-rods are used with eyes in the cross-head, those eyes should be fitted with stuffing-boxes, to diminish the wear, and the guides should be made very strong, for the same reason. The valves of the feed-pump are most conveniently arranged in a chest, which may be attached in any accessible position to the side of the hot-well. An arrangement of this kind is shown in Fig. 1437. Of the two side nozzles, the lower one leads to the pump and the upper one to the boiler. The pipe leading to the pump is a suction-pipe when the plunger ascends, and a forcing-pipe when the plunger descends. The plunger, in ascend- ing, draws the water out of the hot-well through the lowest of the valves, and in descending, forces it through the centre valve into the space above, which communicates with the feed-pipe. Should the Digitized by Google ENGINES, DETAILS OF. 493 feed-cock be shut, 80 as to prevent any feed-water from passing through it, the water will raise the top- most valve, which is loaded to pressure considerably above the pressure of the steam, and escape into the hot-well. This arrangement is neater and less expensive than that of having a separate loaded valve on the feed-pipe, with an overflow through the ship's side, as is the more usual practice. Figs. 1438 and 1439 1439. 1438. 8 E for L H 10 E 3.0 represent a double-acting deck feed-pump of a very complete and efficient construction. It is of the plunger kind, which is preferable to that which operates by a piston. The air-vessel is furnished with an escape-valve, to prevent the pump from being split should it be put in connection with the engine when the cocks in the pipe leading to the boiler are closed, an accident which not unfrequently happens. Fig. 1440 represents a four-way cock, the application of which enables the pump to draw from the sea, from the boiler, or from the bilge, and the pump can deliver 1440. either into the boiler or upon deck. This pump can be worked either by the engine , or by hand it is employed to feed the boilers when the engines are stationary, or to pump the boilers out, after they are blown off as far as can be accomplished by the steam. At other times it is useful for raising the water to wash the decks, to act as a fire-engine in case of fire, and to pump out the ship if she springs a leak. In most of the new vessels fitted with tubular boilers, small engines have been introduced, to pump water into the boiler when the vessel stops under steam. Most of these engines are furnished with a crank and fly-wheel, but that introduced by Messrs. Penn has no fly-wheel, and is a very compact and elegant arrangement. The pump-piston and the steam-piston are at different ends of the same rod, and, instead of the ordinary pump-valves, a slide-valve is introduced, which is situated at the opposite end of the steam slide-rod. The slide-valves are pipe-valves, and are moved by means of a tappet on the piston-rod. On another part of the same plate some views are given of a self-acting feed apparatus, which consists of a small chest, placed upon the front of the boiler at the level of the water-line, with ports, closed by a sliding-plate, communicating with the water in the boiler and the steam above it. When these ports are opened the water rises to the same height in the chest as in the boiler, and the ports are opened and shut by the small engine at every stroke of the pump. While the pump is making its stroke the ports leading from the chest to the boiler are closed, and if the chest be chiefly filled with steam, it will be compressed by the entering water, and the chest will receive a charge of water, which, on the ports being opened, will flow into the boiler. But if there be but little steam in the chest when the pump is making its stroke, or the chest be filled with water from the rise of the water-level, the water discharged by the pump cannot gain admission, and it must therefore escape overboard through the loaded valve. Thus, as the water-level rises, the chest takes less water from the pump, and it takes more when the level falls, the effect of which in practice is to maintain a uniform water-level in the boiler, however great the variations in the demand for steam. In some steam vessels floats have been introduced to regulate the feed, but their action cannot be depended on in agitated water, if applied after the common fashion. Floats would probably answer if placed in a cylinder which communicated with the water in the boiler by means of small holes; and a disk of metal might be attached to the end of a rod extending beneath the water-level, 80 as to resist irregular movements from the motion of the ship, which would otherwise prevent the satisfactory action of the apparatus. This disk would be placed within the cylinder, and a short distance above it a fixed diaphragm might extend across the cylinder, between which and the moveable disk or piston on the rod the water would be compressed, in the event of any sudden disposition of the float to rise, such as might be created by the sudden motions of the ship; whereas by the slow and gradual subsidence of the water-level from evaporation, the water in the cylinder would be able to subside by gradually passing through the small holes in the cylinder and disk. One objection to this plan is, that the small holes would be liable to be Digitized by Google 494 ENGINES, DETAILS OF. closed up by deposite; and the preferable arrangement, probably, would be to place the float within the boiler, guided, but without any cylinder, and to apply я small oil cylinder, such as is used for the cataract of some pumping engines, to the end of the float-rod where it protrudes through the top of the boiler. Such an arrangement would enable the float to resist suddenly acting forces, while any force that was gradual and steadily operative would still produce its due effect. The admission of the feed-water into the boiler is sometimes regulated by cocks, and sometimes by spindle-valves, raised and lowered by a screw. Cocks are less liable to accident or derangement than screw-valves, and in modern steam vessels are generally employed. The feed-water is usually con- ducted from the feed-cock to a point near the bottom of the boiler, by means of an internal pipe,-the object of the arrangement being to prevent the rising steam from being condensed by the entering water. By being introduced near the bottom of the boiler, it comes into contact in the first place with the bottoms of the furnaces and flues, and extracts heat from them, which could not be extracted by water of a higher temperature, whereby a saving of fuel is accomplished. In some cases the feed-water is introduced into a casing around the chimney, from whence it descends into the boiler. This plan appears to be an expedient one when the boiler is short of heating surface, and more than a usual quantity of heat ascends the chimney; but in well-proportioned boilers a water casing round the chimney is superfluous. When a water casing is used, the boiler is usually fed by a head of water, the feed-water being forced up into a small tank, from whence it descends into the boiler by the force of gravity, while the surplus runs to waste, as in the feeding apparatus of land engines, represented in Fig. 1439. Blow-off cocks are generally placed some distance from the boiler, but they should always be placed quite close to it, as there are no means of shutting off the water from the pipe between the blow-off cock and the boiler, should fracture or leakage there arise. Every boiler must be furnished with a blow-off cock of its own, independently of the main blow-off cock on the ship's sides, so that the boilers may be blown off separately, and may be shut off from one another. The preferable arrangement appears to be, to cast upon each blow-off cock a bend for attaching the cock to the bottom of the boiler, and the plug should stand about an inch in advance of the front of the boiler, 80 that it may be removed or reground with facility. The floor-plate covering the blow-off cock should have a cooming, a few inches high, cast round a hole of sufficient diameter to admit a box-key to turn the plug, and to each plug a box-key should be fitted with a collar, at the level of the top of the cooming, of sufficient diameter to cover the hole and thickness of metal around it, and with the top of the key-spindle supported by an eye attached to the boiler. These box-keys would not be shifted from one plug to another, as at present, but each would remain in its place, and the engineer would only have to turn them when he wanted to blow off the boilers. The present method of using the blow-off cocks is very inconvenient. A small plate has to be removed to enable the box-key to be applied; coal sometimes is lying upon the plate, which has to be removed, and coal-dust gets into the bilge in these continual removals, which chokes the roses of the bilge-pumps. In dark nights and rough weather, the engineer requires to feel the nick in the top of the plug, which is often filled with coal-dust and grease, before he can assure himself whether the cock is open or shut, and the operation of turning the cocks is more difficult when the spindle of the key is without support. These evils may be remedied by the arrange- ment suggested. The spindle will require to be made with a hole or eye to admit a handle wherewith to turn it round, and it would be an easy thing to make the stud supporting the top of the spindle of such a form that the handle for turning the spindle could not be withdrawn when the cock was open. The cock, therefore, could not be left open without the handle being left in its place, where it would stand out from the boiler, incommode the firemen, and duly notify the neglect. The general arrangement of the blow-off pipes is to put a main blow-off pipe beneath the floor-plates across the ship at the end of the engines, and into this pipe lead a separate pipe, furnished with a cock, from each boiler. The main blow-off cock, where it penetrates the ship's side, is furnished with a cock and in modern steam vessels Kingston's valves are also used, which consist of a spindle or plate-valve fitted to the exterior of the ship, 80 that if the internal pipe or cock breaks, the external valve will still be operative. Some expedient of this kind is almost necessary, as the blow-off cocks require occasional regrinding, and the sea cocks cannot be reground without putting the vessel into dock, except by the use of Mr. Kingston's valves or some equivalent expedient. When old vessels are getting new sea cocks applied, it may answer to make the old cocks serve the purpose of Kingston's valves, the new cocks being applied between the old cocks and the blow-off pipes. All the cocks about an engine should be provided with bottoms and stuffing-boxes, and reliance should never be placed upon a single bolt passing through a bottom washer for keeping the plug in, in the case of any cock communicating with the boiler, for a great pressure is thrown upon that bolt if the pressure of the steam be high and the plug be made with much taper; and should the bolt break or the threads strip, the plug will fly out, and persons standing near may be scalded to death,-an acci- dent which has sometimes happened. In large cocks it appears the preferable plan to cast the bottoms in; and the metal of which all the cocks about a marine engine are made should be of the same quality as that used in the composition of the brasses, and should be without lead or other deteriorating mate- rial. In some cases the bottoms of cocks are burnt in with hard solder, but this method cannot be de- pended upon, as the solder is softened and wasted away by the hot salt-water, and in time the bottom leaks or is forced out. The stuffing-boxes of cocks should be made of adequate depth, and the gland should be secured by means of four strong copper bolts. The taper of blow-off cocks is an important element in their construction; as if the taper be too great, the plugs will have a continual tendency to rise, which, if the packing be slack, will enable grit to get between the faces; while, if the taper be too little, the plug will be liable to jam, and a few times grinding will sink it so far through the shell, that the water-ways will no longer correspond. One-eighth of an inch deviation from the perpendicular for every inch in height is a common angle for the side of the cock, which corresponds with one quarter of an inch difference of diameter in an inch of height; but one-third of an inch difference of diameter for Digitized by Google ENGINES, DETAILS OF. 495 every inch of height, is a preferable proportion. The bottom of the plug must be always kept a small distance above the bottom of the shell, and an adequate surface must be left above and below the water-way, to prevent leakage. Cocks formed according to these directions will be found to operate satisfactorily in practice. Gage-cocks are rarely made with stuffing-boxes, and are for the most part adorned with stalactites of salt after a short period of service, in consequence of leakage. The water discharged from them, too, disfigures the front of the boiler, and adds to the corrosion in the ash-pits. It would be preferable to combine the gage cocks appertaining to each boiler into a single upright tube, connected suitably with the boiler, and the water flowing from them could be directed downwards into a funnel tube communi- cating with the bilge. The gage-cocks and also the glass tube-cocks should be furnished with stuffing- boxes, and with bottoms, unless the water enters through the bottom of the plug. The glass gage- tubes should always be fitted with a cock at each neck, communicating with the boiler, so that both the water and steam may be shut off if the tube breaks. The gage-cocks frequently have pipes running up within the boiler, to the end that a high-water level may be made consistent with an easily accessible position of the gage-cocks themselves. With the glass tubes, however, this species of arrangement is not possible, and the glass tubes must always be placed in the position of the water level, whether it be high or low. The sea injection-cocks are usually made in the same fashion as the sea blow-off cocks, and of about the same size. The injection water is generally admitted to the condenser by means of a slide-valve, but a cock is more easily opened, and has not any disposition to shut of its own accord. The sea injec- tion-pipes should be put through the ship's side in advance of the paddles, so that the water drawn in may not be injuriously charged with air. In some cases the suction-pipe of the deck-pump leads into the injection-pipe; but it is preferable to put a pipe through the ship's side for the exclusive use of the deck-pump, as is the general practice. The waste-water pipe, passing from the hot-well through the vessel's side, is provided with a stop-valve, called the discharge-valve, which is usually made of the spindle kind, so as to open when the water coming from the air-pump presses against it. In some cases this valve is a sluice-valve, but the hot-well is then almost sure to be split if the engine be set on with- out the valve having been opened. The opening of the waste-water pipe should always be above the load water line, as it will otherwise be difficult to prevent leakage through the engine into the ship, when the vessel is lying in harbor. Boilers are now generally supplied with stop-valves, whereby one boiler may be thrown out of use without impairing the efficacy of the remainder. These stop-valves are usually spindle valves of large size, and they are for the most part set in a pipe which runs across the steam-chests connecting the several boilers together. The spindles of these valves should project through stuffing-boxes in the covers of the valve-chests, and they should be balanced by a weighted lever and kept in continual ac- tion by the steam. If the valves be lifted up and be suffered to remain up, as is the usual practice, they will become fixed by corrosion in that position, and it will be impossible after some time to shut them on any emergency. These valves should always be easily accessible from the engine-room, and it ought not to be necessary for the coal boxes to be empty to gain access to them. The safety-valves should not be set on the common pipe connecting the boilers, but each boiler should have a safety-valve of its own set direct upon the steam-chest, for if the stop-valve should jam, and the safety-valve be exterior to it, the safety-valve cannot contribute any thing to save the boiler from explosion. Each boiler also should have a distinct steam-gage and a distinct atmospheric valve, if atmospheric valves be applied at all, but they scarcely appear to be necessary in the case of tubular boilers, which are capable of with- standing the atmospheric pressure with impunity. The pipes of marine engines should always be made of copper. Cast-iron blow-off pipes have in some cases been employed, but they are liable to fracture, and are dangerous. Every pipe passing through the ship's sides, and every pipe fixed at both ends and liable to be heated and cooled, should be furnished with a faucet or expansion joint, and in the case of cast-iron pipes, the part of the pipe fit- ting into the faucet should be turned. In the distribution of the faucets of the pipes exposed to pres- sure, care must be taken that they be so placed that the parts of the pipe cannot be forced asunder by the strain, as serious accidents have occurred from the neglect of this precaution. A faucet is usually placed where the main steam-pipe joins the branch steam-pipes proceeding to the cylinders, and if those branch steam-pipes are attached to the cylinders or valve-casings by means of faucets, the whole of the branch steam-pipes may swivel round on these faucets and leave the main steam-pipe, which will then discharge its full volume of steam into the engine room, an accident which could hardly fail to be at- tended with the most disastrous consequences. Where the pipes pierce the ship's side, they should be made tight, as follows:-The hole being cut, a short piece of lead pipe with a broad flange at one end should be fitted into it, the place having been previously smeared with white-lead, and the pipe should then be beaten on the inside until it comes into close contact all round with the wood. A loose flange should then be slipped over the projecting end of the lead pipe, to which it should be soldered, and the flanges should both be nailed to the timber with scupper nails, white-lead having been previously spread underneath. This method of procedure prevents the possibility of leakage down through the timbers, and all therefore that has to be guarded against after this precaution, is to prevent leakage into the ship. To accomplish this object, let the pipe which it is desired to attach be put through the leaden hawse, and let the space between the pipe and the lead be packed with gasket and white-lead. The pipe must have a flange upon it to close the hole in the ship's side; the packing must then be driven in from the outside and be kept down by means of a gland secured with bolts passing through the ship's side. If the pipe is below the water- line the gland must be of brass, but for the waste-water pipe a cast-iron gland will answer. In the case of iron vessels, it appears to be the best practice to attach a short iron nozzle, projecting inwards, to the skin, for the attachment of every pipe below the water-line, as the copper or brass would waste the iron of the skin if the attachment were made in the isual way. Digitized by Google 496 ENGINES, DETAILS OF. Parts of oscillating engines.-The most important parts of oscillating engines are the piston, the piston-rod stuffing-box, the trunnions, and the attachment for the valve. The two former parts we have already described; we shall here give the chief details of the two latter. Fig. 1441 represents the valve attachment to the steam vessel the Trident, constructed by Messrs. Boulton and Watt, cylinder 70% inches diameter, and 5 feet stroke, and reckoned at 350-horse power. The eccentric rod is attached to the stud a, which is fixed to the centre of a plate forming part of a frame which is guided vertically by means of the guide-rod b, and by the columns of the engine at c c. d is the end of the valve lever which is moved up and down by the frame, whatever position in the arc the end of the lever may occupy in consequence of the oscillation of the cylinder. e is a rack whereby the frame may be moved up or down by means of a shaft at A B, when the eccentric rod is not in geer, and at the end of the shaft a wheel is situated for starting the engine. The curved groove in which the end of the valve lever moves is part of a circle, but it is not swept from the centre of the trunnion when the valve is at half-stroke, but with a radius equal to the distance of the centre of the valve-shaft from the centre of the trunnion, when the cylinder is perpendicular. Messrs. Penn do not form the curve in this way, but sweep it from the centre of the trunnion when the valve is at half-stroke; and although the same motion of the valve is not thus obtained as when there is no oscillation, the difference is very slight, and is moreover considered to be a better motion than if no disturbance had taken place. It appears to us that the use of a curve might be dispensed with altogether by observing a suitable ad- justment of the eccentric; the effect would probably be to increase slightly the side pressure on the piston-rod, but the increase would be altogether inappreciable in the case of equilibrated valves which may be wrought with an inconsiderable exercise of force. b 1441. 1442. SCALE.-1 inch=1 foot. Fig. 1442 represents one of the trunnions of the Trident, which, instead of being cast upon the cylin- der, as is the usual practice, are bolted on with twelve 11-inch bolts, and are strengthened by twelve brackets, 1 inch thick, cast on the flanges of attachment. There is a projecting ring, it will be observed, left upon the part which is to be bolted on, which is accurately fitted into the hole in the belt in order to obviate slackness sideways. A rib 11 inch thick runs back from the hole on each side in the middle of the belt, to tie the belt more effectually to the cylinder, and above and below the belt a feather runs vertically 11 inch thick, and tapering in depth from the belt till it runs off to nothing on the cylinder side. The bearing part of the trunnion is 22 inches diameter, 7 inches long, and the metal is 21 inches thick; the steam-pipe entering the trunnion is 1 inch thick, and the packing space between the pipe and trunnion 11 inch wide. The gland for compressing the packing is usually put on in two pieces. The pipe requires to be so made that it can be pushed in against the cylinder in order to accommodate its outer attachment. It is not necessary to make provision at the outer end of the trunnion-pipe for the falling of the trunnion by wear, as the wear is so small as to be of no practical moment. The thickness of metal of the cylinder is 11 inch; the thickness of the top and bottom of the belt is 21 inches in the wake of the trunnion, and 2 inches in other places. The diameter of the hole in the belt is 18 inches; the internal diameter of the steam-pipe is 13 inches; and the diameter over the flange for the attach- ment of the trunnion is 301 inches. The interior of the beit in the wake of the trunnion measures 29 inches deep and 41 inches wide. The crank-shaft bearings are 12 inches in diameter and 13 inches long. The paddle-wheels are overhung, and the outer journal of the shaft is 14 inches diameter, and 14 inches long; the part on which the centre is fixed, from whence the arms diverge, being 16 inches diam- eter, and 24 inches long. When the paddle is overhung, the shaft increases in size at the outer end, in- Digitized by Google ENGINES, DETAILS OF. 497 stead of diminishing as in other cases. The diameter of the wheels is 22 feet; the floats are 2 feet broad and 9 feet long, and have a dip of 4 feet 7 inches from the load water-line, at which point the vessel draws 11 feet of water. The crank-pin is 9 inches in diameter, and has a length of bearing for the connecting rod of 14 inches. The diameter of the Trident's piston-rod is 71 inches; we think the introduction of larger piston-rods than have yet been introduced in oscillating engines would be an im- provement, and would add to the durability of the engines. Each cylinder measures 8 feet 1 inch across from centre to centre of trunnion, and 11 feet 6 inches from the level of the trunnion to the level of the shaft. The position of the trunnion should be a little above the centre of gravity of the cylinder, 80 that it will have no tendency to tilt over when the piston-rod is disengaged from the crank-pin, and very little tendency at the same time when pushed over to resume the perpendicular. The plan of attaching a weight to one side of the cylinder to balance the valve-casing is now discontinued in the best engines, and two valves are employed which balance one another. These valves are placed one on each side of the trunnion, so that they may both be wrought by the-same eccentric. If the curved eccentric frame were discarded, the eccentric rod might be attached immediately to a cross-head, from the ends of which the two valve-rods descended, and the intermediate geer at present used might thus be dispensed with. Engines applied direct to the screw.-It requires but little penetration to foresee that the present spe- cies of marine engine must be given up if the screw propeller gains a general introduction, for the engines will in that case be coupled immediately to the screw-shaft, which, as it requires to revolve much more quickly than a paddle-shaft, involves a greatly increased speed of piston. Small engines, with the pistons moving at a quick speed, will exert the same power as large engines moving with a slow speed; and small engines, by being applied to the screw-shaft direct, may be made to do the work of large ones. This is a manifest advantage to steam navigation, as a vessel may be constructed with very large power without being inconveniently burdened with the weight of the engines; and it is also an advantage to the makers of engines, who will thus be enabled to produce a given power at a less cost. The only impediment to the general introduction of this system lies in the difficulty of driving the air-pump at a high speed without causing the valves to strike 80 hard as to wear themselves out very quickly. The difficulty may be met by making the air-pump piston without valves, and opening and shutting the foot valve passage by means of a slide-valve, the motion for working which is derived from the eccentric-rod. The delivery valve must still be opened by the pressure of water in the pump; but it may be made to consist of a piston valve with skewed ports of the usual form, and it may be closed, or the piston be brought opposite to the ports by means of a pendulum weight at the end of a lever moving outside. Most of the engines at present in course of construction for direct application to the screw, are made with four cylinders lying horizontally with two cranks upon the screw shaft, to which the connecting rods are attached, the connecting rods being joined to the top of the pis- ton-rods, as in the Gorgon, or locomotive construction. Oscillating engines, laid at an angle of 45°, and joined to a single crank on the shaft, have in some cases been employed; and we think this arrange- ment is upon the whole the preferable one. The air-pump may be made double-acting, and may be worked from the same crank-pin to which the piston-rods are attached; the pin, however, being made eccentric in the part to which the air-pump rod is attached, in order to give the pump a shorter stroke than the piston. The crank and crank-pin will, if this arrangement be adopted, be stronger if made in the same piece, and the neck of the shaft from which the crank overhangs must be made stronger than usual. If the air-pump be made double-acting, as appears to be the preferable practice, its diameter may be very small, but the foot and delivery valve passages must be larger than usual in proportion to the size of the pump. If a piston valve be adopted for the delivery valve, it will be expedient to balance the valve by means of a counterweight, as is done in case of the steam-valve, adding then a pendulum, or a short crank pulled into the vertical position by a rod loaded with a weight, the end of the rod being suitably guided by a swivelling eye, in order to bring back the valve, or retain the piston opposite the ports until the pressure comes on. It is clear that, if this arrangement be adopted, the thrust of the shaft forwards, which in the case of the Rattler screw steamer is equivalent to a weight of four tons, cannot be sustained by the end of the shaft and the best arrangement appears to be, to re- ceive the thrust upon a collar on the shaft, which works within an oil cylinder,-oil being forced con- tinually by a small pump worked by the engine between the end of the oil cy 'inder and the collar, until the collar is forced back with a pressure equal to that of the forward thrust. It is not expedient, how- ever, to trust to the oil alone; and, therefore, between the collar and the bottom of the oil cylinder, and also between the collar and the top of the oil cylinder-so as to give security for backing-rollers car- ried by rings, as in the case of the rollers of a swivel bridge, or railway turn-table, should be interposed. These rollers should be as numerous as can be conveniently applied; they should each touch only in one point; should be made narrow, and several of these narrow rollers should be set upon the same spindle, so as to increase the quantity of the bearing surface. The collar and ends of the oil cylinder should consist of plates of hardened steel, and the rollers should also be of hardened steel, and be all made of exactly the same diameter. The oil cylinder would have to be supplied with a safety-valve on each side of the collar, so that any surplus oil sent in by the pump would be able to escape into a small tank, out of which the pump would draw. By these expedients, the thrust of the screw may be effectually and satisfactorily counteracted. It appears expedient to tooth out the eye of the collar, and to make it of sufficient length to serve as a coupling-box, the end of the shaft proceeding from the screw to the collar being similarly toothed, and fixed fast into the collar; while the end of the shaft proceeding from the collar to the engine is toothed in the same fashion, but so fitted as to slide endways in the collar. By this arrangement, should the oil cylinder yield slightly, or the rollers wear, the engine framing will still be preserved from the forward strain; the only effect of such accidents being to make the engine shaft slip somewhat further into the collar. The edge of the collar would be furnished with cupped leathers upon each side, of the same description as those used for the rams of hydraulic presses. Centres and lengths of rods.-In fixing the positions of the centres, it appears to be the most conve- 63 Digitized by Google 498 ENGINES, DETAILS OF. nient way to begin with the main centre. The height of the centre of the cross-head at half-stroke above the plane of the main centre, is fixed by the drawing of the engine, which gives the distance from the centre of cross-head centre at half-stroke, to the flange of the cylinder; and from thence it is easy to find the perpendicular distance from the cylinder-flange to the plane of the main centre, merely by putting a straight-edge along level, from the position of the main centre to the cylinder, and measuring from the cylinder-flange down to it, raising or lowering the straight-edge until it rests at the proper measure- ment. The main centre is in that plane, and the fore and aft position is to be found by plumbing up from the centre line on the sole-plate. To find the paddle-shaft centre, plumb up from the centre line marked on the edge of the sole-plate, and on this line lay off from the plane of the main centre the length of the connecting rod, if that length be already fixed; or otherwise the height fixed in the draw- ing of the paddle-shaft above the main centre. To fix the centre for the parallel-motion shaft, when the parallel bars are connected with the cross-head, lay off on the plane of main centre the length of the parallel bar from the centre of the cylinder, deduct the length of the radius crank, and plumb up for the central line of motion shaft; lay off on this line, measuring from the plane of main centre, the length of the side-rod; this gives the centre of parallel-motion shaft, when the radius-bars join the cross-head, as is the preferable practice where parallel-motions are used. The length of the connecting rod is the distance from the centre of the beam when level, or the plane of the main centre, to the centre of the paddle-shaft. The length of the side-rods is the distance from the centre line of the beam when level, to the centre of the cross-head when the piston is at half-stroke. The length of the radius-rods of the parallel motion is the distance from the point of attachment on the cross-head or side-rod, when the pis- ton is at half-stroke, to the extremity of the radius-crank, when the crank is horizontal; or, in engines with the parallel motion attached to the cross-head, it is the distance from the centre of the pin of the radius-crank, when horizontal to the centre of the cylinder. How to set the parallel motion.-In marine engines, having fixed the centre of the parallel-motion shaft in the manner just described, it only remains to put the parts together when the motion is attached to the cross-head; but when the motion is attached to the side-rod, the end of the parallel bar must not move in a perpendicular line, but in an arc, the versed sine of which bears the same ratio to that of the side-lever that the distance from the top of the side-rod to the point of attachment bears to the total length of the side-rod. The parallel motion when put in its place should be tested by raising and lowering the piston by means of the crane: first set the beams level, and shift in or out the motion-shaft, plummer-blocks, or bearings, until the piston-rod is upright. Then move the piston to the two extremes of its motion: if at both ends the cross-head is thrown too much out, the stud in the beam to which the motion side-rod is attached is too far out, and must be shifted nearer to the main centre: if at the extremities the cross- head is thrown too far in, the stud in the beam is not out far enough. If the cross-head be thrown in at the one end and out equally at the other, the fault is in the motion side-rod, which must be length- ened or shortened to remedy the defect. How to set the slide-valves.-The first thing is to ascertain whether the eccentric-rod is of the right length. To determine this, put the valve in the middle of its stroke, 80 that both ports are covered equally, and fix it in that position. Next, turn round the eccentric on the shaft until the eccentric-rod has reached the furthest point of its travel from the shaft, and square up from the side of the eccentric- pin a line upon the rod. Turn round the eccentric again until the eccentric-rod reaches the end of its travel towards the shaft, and square up another line on the rod from the other side of the pin. If the eccentric notch be equally distant from the lines thus marked upon the eccentric-rod, the rod is of the right length; but if the notch be too far down upon it, the rod requires to be shortened; and if too far up, to be lengthened-in each case to an extent equal to the deviation of the notch from the central line. Thus, if on trial, the notch be found to be half an inch nearer to the lower than to the upper line, the notch will require to be shifted up a quarter of an inch, to place it midway between the lines; and to do this, the rod must be shortened a quarter of an inch; whereas, if the notch be half an inch nearer the upper than the under line, the rod will require to be lengthened a quarter of an inch, and so on in all other proportions. The right length for the eccentric-rod having been thus obtained, and the rod having been adjusted thereto, the next step is to set the crank perpendicular. In a workshop this is easily done by a plumb- line, but in a steam-vessel recourse must be had to another method. Find on the sole-plate, or cylin- der-mouth if a direct action engine, the transverse centre line answering to the centre of the shaft. De- scribe on the large eye of the crank a circle of the size of the crank-pin, and lay off in a fore and aft direction from the transverse centre line on cylinder-mouth or sole-plate, a distance equal to the radius or half diameter of the crank-pin. Stretch a line from the point thus marked off to the edge of the circle described on the large eye of the crank, and turn round the paddle-wheels until the crank-pin just touches the stretched line-the crank will then be perpendicular, and may be set by this method either on top or bottom centre. The crank having been set in a perpendicular position while the valve is set and fixed with the amount of lead it is intended to give, the eccentric has only to be turned round upon the shaft until the notch comes opposite to the pin and the rod falls into geer, to determine the right position of the eccen- tric on the shaft. The situation of the eccentric may then be marked upon the shaft, and the catches fitted on in the usual way. The valve may first be set for going ahead, and may then be set for going astern,-shifting round the eccentric to the opposite side of the shaft until the rod again falls into geer. The position answerable to going ahead in some engines will be that answerable to going astern in others, depending on the way in which the engines are placed, the arrangement of the levers, and the kind of valve employed. It is necessary to recollect that it is the catches which drive the eccentric, and not the eccentric the catches, mistakes having sometimes arisen from forgetfulness of this condition. It is impossible to give any general rule for finding the length of the valve levers or the throw of the valve. In most engines, however, the travel of the valve is twice the depth of the port, and the throw Digitized by Google ENGINES, DETAILS OF. 499 of the eccentric is equal to the travel of the valve, so that motion is neither gained nor lost by the levers. In engines which do not operate expansively, the depth of the valve face is equal to the depth of the port; but all modern engines have a certain amount of lap or cover on the steam side; and some on the eduction side also. In the Thames and Medway steamers by Messrs. Maudslay, the travel of the valve is 16 inches, and the length of valve lever 81 inches; depth of port 6 inches; length of port 26 inches; distance from upper edge of upper port to under edge of under port, 8 feet 91 inches; and dis- tance between extreme edges of valve faces, 8 feet 91 inches; so that instead of there being cover upon the eduction side, the valve is one-eighth of an inch short at each end, and will not cover the ports in any position. In some engines the upper face is made narrower than the under face. In Messrs. Maudslay's 50-horse power engines, the breadth of the port is 3 inches, and its length 15 inches; the breadth of the lower valve face is 5 inches, and of the upper one, 43 inches. In the 48-inch cylinders of the same makers, the size of port is 34 inches by 18 inches; in the 54-inch cylinders the size of port is 20 inches by 4 inches; the valve faces, 8 inches, and 71 inches broad; and the length of the travel 11 inches. Other makers adopt different modes of setting the valves-we believe with little difference in the efficiency of the engine. We must refer the reader to the investigations and rules we have already given respecting alide-valves, as the best guide we can furnish for fixing the lap, lead, and other ele- ments, in the absence of a uniformity of practice. How to put the engines into a steamship.-First, measure across from the inside of paddle-bearers to the centre of the ship, to make sure that the central line, running in a fore and aft direction on the deck or beams, usually drawn by the carpenter, is really in the centre; and if it is not, make a fore and aft line or mark that is in the centre. Stretch a line across between the paddle-bearers in the direction of the shaft: to this line in the centre of the ship where the fore and aft mark has been made, apply a square with arms six or eight feet long, and bring a line, stretched perpendicularly from the deck to the keelson, accurately to the edge of the square; the lower point of the line where it touches the keelson will then be immediately beneath the mark made on the deck. If this point does not come in the centre of the keelson, it will be better to shift it a little, so as to bring it to the centre, altering the mark on the deck correspondingly, provided either paddle-shaft will admit of this being done-one of the paddle-brackets being packed behind with wood, to give it an additional projection from the side of the paddle-bearer. Continue the line fore and aft upon the keelson as nearly as can be judged in the centre of the ship; stretch another line fore and aft through the mark upon the deck, and look it out of winding with the line upon the keelson. Fix upon any two points equally distant from the centre, in the line stretched transversely in the direction of the shaft; and from those points as centres, and with any con- venient radius, sweep across the fore and aft line to see that the two are at right angles; and if not, shift the transverse line a little to make them 80. From the transverse line next let fall a line upon each outside keelson, bringing the edge of the square to the line, the other edge resting on the keelson. A point will thus be got on each outside keelson perpendicularly beneath the transverse line running in the direction of the shaft, and a line drawn between those two points will be directly below the shaft. To this line the line of the shaft marked on the sole-plate has to be brought, care being taken at the same time, that the right distance is preserved between the fore and aft line upon the sole-plate, and the fore and aft line on the central keelson. Before any part of the machinery is put in, the keelsons should be dubbed fair and straight, and be looked out of winding by means of two straight-edges. The art of placing engines in a ship is more a piece of plain common sense than any other feat in engineer- ing; and every man of intelligence may easily settle a method of procedure for himself. Plumb-lines and spirit-levels, it is obvious, cannot be employed on board a vessel; and the problem consists in so placing the sole-plates, without these aids, that the paddle-shaft will not stand awry across the vessel, nor be carried forward beyond its place by the framing shouldering up more than was expected. As a plumb-line cannot be used, recourse must be had to a square; and it will signify nothing at what angle with the deck the keelsons run, so long as the line of the shaft across the keelsons is squared down from the shaft centre. The sole-plates being fixed, there is no difficulty in setting the other parts of the engine in their proper places upon them. The paddle-wheels must be hung from the top of the paddle- box, to enable the shaft to be rove through them: and the cross-stays between the engines should be fixed in when the vessel is afloat. To try whether the shafts are in a line, turn the paddle-wheels, and try if the distance between the cranks is the same at the upper and under, and the two horizontal centres; if not, move the end of the paddle-shaft up or down, or backwards or forwards, until the distance between the cranks at all the four centres is the same. Miscellaneous remarks respecting marine-engines.-The cylinders should be felted, and then cased with wood that has been baked until it will shrink no longer. The steam-pipes should be cased in the same way, and the boilers should be felted, and then covered with sheet-lead, soldered at every joint. The whole of the screws about the engine should be made according to a uniform system of threads, and the nuts of the same sized bolts should also be of the same size, so that a single spanner will serve for those nuts. The spanners intended for polished nuts should be close and single-ended, and they should be themselves polished and case-hardened. and ranged in regular order on one of the engine-room bulk- heads. A pair of brase-sheaved blocks for raising the cylinder cover, and another smaller pair for raising the air-pump cover, should be provided; and a strong screw, with a large eye at the end, for raising the paddle-wheel. Strong spanners should also be provided for the holding-down bolts, with eyes at the end, to which a tackle may be applied; and a box-key for tightening down the bolts of the paddle-shaft plummer-blocks through the crank-hatch. Tallow kettles are little needed if the pistons and cylinder stuffing-boxes have metallic packings. Oil-cans and lamps should be ranged on a shelf in separate stands, so that they cannot fall off when the vessel rolls. For every article of engine-room furniture there should be a convenient and conspicuous place; and if there be any articles of spare geer, they should be all kept in sight. Unless this be done, they are almost sure to be eaten up with rust, as neglect generally follows their stowage in an unfrequented or inaccessible place. In most steam-vessels a good deal of trouble is caused by the holding-down bolts, which are generally Digitized by Google 500 ENGINES, DETAILS OF. made of iron. Sometimes they go through the bottom of the ship, and at other times they merely go through the keelson, a recess being made in the floor or timbers to admit of the introduction of a nut. The iron, however, wears rapidly away in both cases, even though the bolts are tinned; and it has been found the preferable method to make such of the bolts as pass through the bottom, or enter the bilge, of Muntz's metal, or of copper. In side-lever engines four Muntz's metal bolts may be put through the bottom at the crank end of the framing of each engine, four more at the main centre, and four more at the cylinder, making twelve through bolts to each engine; and it is more convenient to make these bolts with a nut at each end, as in that case the bolts may be dropped down from the inside; and the necessity is obviated of putting the vessel on very high blocks in the dock, in order to give room to put the bolts up from the bottom. The remainder of the holding-down bolts may be of iron; and may, by means of a square nut, be screwed into the timber of the keelsons as wood screws, the upper part being furnished with a nut, which may be screwed down upon the sole-plate, 80 soon as the wood screw portion is in its place. If the cylinder be a fixed one, it should be bolted down to the sole-plate by as many bolts as are employed to attach the cylinder-cover, and they should be of copper or brass, in any situation that is not easily accessible. In well-formed bolts the spiral groove penetrates about one- twelfth of the diameter of the cylinder, so that the diameter of the solid cylinder which remains is five- sixths of the diameter over the thread. The strain to which iron may be safely subjected in machinery, is one-fifteenth of its utmost strength, or 4000 pounds on the square inch, 80 that 2180 pounds may be sustained by a screw an inch in diameter at the outside of the threads. The strength of the holding- down bolts, therefore, may easily be computed, when the elevating force of the piston or main centre is known, but it is expedient very much to exceed this strength in practice, on account of the elasticity of the keelsons, the liability to corrosion, and other reasons. A very useful species of oil-cup is now employed in a number of steam-vessels; and which, it is said, accomplishes a considerable saving of oil, at the same time that it more effectually lubricates the bearings. A ratchet-wheel is fixed upon a little shaft which passes through the side of the oil-cup, and is put into slow revolution by a pendulum attached to it outside; and in revolving it lifts up little buckets of oil and empties them down a funnel upon the centre of the bearing. Instead of buckets, a few short pieces of wire are sometimes hung on the internal revolving wheel, the drops of oil which adhere to them on rising from the liquid being deposited upon a high side set upon the funnel, and which in their revolution the hanging wires touch. By this plan, however, the oil is not well supplied at slow speeds, as the drops fall before the wires are in the proper position for feeding the journal. Another lubricator consists of a cock or plug inserted in the neck of the oil-cup, and set in revolution by a pendulum and ratchet-wheel, or any other means. There is a small cavity in one side of the plug, which is filled with oil when that side is uppermost, and delivers the oil through the bottom-pipe when it comes opposite to it. In some cases bearings heat from making a cruciform groove in the top brass for the distribution of the oil, the effect of which is to leave the top of the bearings dry. In the case of revolving journals, the plan of cutting a cruciform channel for the distribution of the oil does not do much damage; but in other cases, as in beam-journals for instance, it is most injurious, and the brasses cannot wear well wherever the plan IS pursued. The right way is to make a horizontal groove along the brass where it meets the upper surface of the bearing, so that the oil may be all deposited on the highest point of the journal, leaving the force of gravity to send it downwards. This channel should of course stop short a small distance from each flange of the brass, otherwise the oil would run out at the ends. The paddle-shaft, where it passes through the vessel's side, is usually surrounded with a lead stuffing- box, which will yield if the end of the shaft falls. This stuffing-box prevents leakage into the ship from the paddle-wheels, but it is expedient as a further precaution to have a small tank on the ship's side immediately beneath the stuffing-box, with a pipe leading down to the bilge to catch and conduct away any water that may enter. The bearing at the outer end of the paddle-shaft is sometimes supplied with tallow forced into a hole in the plummer-block cover, as in the case of water-wheels; but for vessels intended to perform long voyages, it is preferable to have a pipe leading down to an oil-cup above the journal, from the top of the paddle-box, through which pipe oil may at any time be supplied. The eccentrics should be fitted with pans beneath them to catch the oil which falls. In vessels fitted with Hall's condensers, the pistons and stuffing-boxes must be supplied with oil instead of tallow, as the tallow congeals in the pipes of the condensers and chokes them up. The bolts for holding on the paddle-floats should be made extra strong on account of the corrosion to which they are subject, and the nuts should be made large and should be square, so that they may be effectually tightened up even though the corners are worn away by corrosion. Paddle-floats, when consisting of more than one board, should be bolted together edgewise by means of bolts running across their whole breadth; they should not overhang the ring much at the outside of the wheel, else they will be very liable to be broken off when the wheel strikes the water heavily. The aftermost paddle-beam should come as close as possible to the wheel to prevent the spray from being carried up. The angular pieces or wales running from the extremities of the paddle-beams to the back of the deck-houses, are best when fitted with iron gratings, as wooden gratings are liable from their greater opposing surface to be carried away. The brackets supporting the paddle-box steps should consist of circular pieces running round the paddle-box from step to step, as when put on with isolated brackets the steps are liable to be carried away by the sea. The funnel shrouds should consist of rope of the same dimensions as the shrouds of the mainmast, but a few feet at the top should consist of chain, as rope close to the funnel would be burned. It is very difficult to fix engines effectually which have once begun to work in the ship, for in time even the surface of the keelsons on which the engines bear becomes worn uneven, and the engines necessarily rock upon it. As a general rule, the bolts attaching the engine to the keelsons are too few and of too large a diameter; it would be greatly preferable to have smaller bolts and more of them. Twelve very strong brass or copper holding-down bolts going through the vessel's bottom are sufficient for a side-lever engine, and supposing the vessel to be a wooden one; but there should be a large Digitized by Google ENGINES, DETAILS OF. 501 number of wood screws securing the sole-plate to the keelson, and a large number of bolts securing the various parts of the engine to the sole-plate. In iron vessels, holding-down bolts passing through the bottom are not expedient, and then the engine has merely to be secured to the iron plate of the keel- sons, which are made hollow and admit of the most effectual attachment of the engine. Where the framing is of cast-iron, it is very expedient to have one piece running across the end of the engines clear of the connecting-rod, so as to bind the whole of the frames together, and a cross should extend horizon- tally between the intermediate frames immediately beneath the paddle-shaft, so as to counteract the disturbing action of the connecting-rods. At the cylinder jaw, if the frame works, the best expedient appears to be the introduction of a number of steel tapered bolts, the holes having been previously bored out; and if the flanges be thick enough, square keys may also be introduced, half into the one flange and half into the other, 80 as to receive the strain. If the jaw cracks or breaks away, a malleable iron hoop may be applied round the cylinder, and that will in all cases be the preferable expedient, where from peculiarities of structure it can be as easily done as introducing bolts and keys. If the engines rock very much in the vessel, and are defective in other respects, it will be the preferable plan to take them out and thoroughly repair them, preparatory to their re-introduction; and the keelsons will then have to be dubbed afresh, and the sole-plates fitted carefully to them. A common practice is to let the sole-plates rest on the bolt-heads, and then to fit in wedges all round until the vacuity is filled; but it is preferable to fit the plates down solid upon the wood, and such is the practice of the best engineers. Rust joints are not now much used in marine-engines, yet it is necessary that we should state how they are made. One ounce of sal-ammoniac in powder is added to 18 ounces or a pound of borings of cast-iron, and a sufficiency of water is added to wet the mixture thoroughly, which should be done some hours before it is wanted for use. Some persons add about half an ounce of flowers of brimstone to the above proportions, and a little sludge from the grindstone trough. This cement is caulked into the joints with a caulking-iron, about three-quarters of an inch wide, and one-quarter of an inch thick; and after the caulking is finished, the bolts of the joint may be tried to see if they cannot be further tightened. The skin of the iron must in all cases be broken where a rust joint is made, and if the place be greasy, the surface must be well rubbed over with nitric acid, and then washed with water until no grease remains. The oil about engines has a tendency to damage rust joints by recovering the oxide. Cop- persmiths stanch the edges of plates and the rivets by means of a cement formed of pounded quick- lime and serum of blood, or white of egg. and in copper boilers such a substance may be useful in stopping the impalpable leaks which sometimes occur, though Roman cement appears to be nearly as effectual. It would be worth trying, however, whether the mixture would not prevent the internal corrosion of boilers, if laid on as a paint. Wire gauze smeared with white or red lead and interposed between surfaces made quite true, appears to be the best description of joint yet introduced, and has now become identified with the practice of the best engineers. Metals used in the construction of engines.-The general ambition in making cylinders is to make them sound and hard; but it is expedient also to endeavor to make them tough, so as to approach as nearly as possible to malleable iron. This may best be done by mixing in the furnace as many different kinds of iron as possible; and it may be set down as a general rule in iron-founding, that the greater the number of the kinds of iron entering into the composition of any casting, the denser and tougher it will be. The constituent atoms of different kinds of iron appear to be of different sizes, and the mixture of different kinds maintains the toughness which adds to the density and cohesion. Hot-blast iron was at one time generally believed to be weaker than cold-blast, but it is now found to be the stronger of the two. The cohesive strength of unmixed iron is not in proportion to its specific gravity; and its elasticity and power to resist shocks appear to become greater as the specific gravity becomes less. We give here the average results of a number of experiments made in Scotland upon the strength of iron. The bars experimented on were one inch square and three feet long. Coltness iron (No. 1) bore a weight of 636 pounds, and the same iron (No. 3) bore 649 pounds; Gartsherrie (No. 1) bore 633 pounds; Shott's, (No. 1,) 594 pounds; Wilsontown, (No. 1,) 706 pounds, and (No. 2, 718 pounds; Pintwyn, (No. 1,) 681 pounds; Calder, (No. 3,) 765 pounds; Govan, (No. 3,) 645 pounds; Bumbow, (No. 2,) 734 pounds. Mixed irons are found to be stronger. Coltness and Gartsherrie (No. 1) bore 842 pounds; Coltness, Castlehill, Shott's, and Gartsherrie, (No. 1,) 639 pounds; Coltness, (No. 1,) and Bum- bow, (No. 2,) 677 pounds. A mixture consisting of 2 tons Pintwyn, (No. 1,) 4 tons Pintwyn, (No. 2,) 5 tons of Wilsontown, (No. 2,) 2 tons of Wilsontown, (No. 3,) 5 tons of Calder, (No. 2,) and 4 tons of Calder, (No. 3,) bore 1,008 pounds; and a miscellaneous lot of old cast-iron of the cold-blast manufacture, from Wilsontown, bore 1,500 pounds. Numbers 3 and 4 are the strongest irons in most cases: iron remelted in a cupola is not 80 strong as when remelted in an air-furnace; and when run into green sand it is not reckoned so strong as when run into dry sand or loam. The quality of the fuel, and even the state of the weather, exerts an influence upon the quality of the iron. Smelting furnaces on the cold- blast principle have long been known to yield better iron in winter than in summer, probably from the existence of less moisture in the air; and it would probably be found to be an improvement in iron- founding if the blast were to pass through a vessel containing muriate of lime, by which the moisture in the air would be extracted. The secret of making fine-skinned castings lies in using plenty of black- ening. In loam and dry sand castings the charcoal should be mixed with thick clay water, and applied until it is an eighth of an inch thick, or more; the surface should then be very carefully smoothed or sleeked, and if the metal has been judiciously mixed, and the mould thoroughly dried, the casting is sure to be a fine one. Dry sand and loam castings should be as much as possible made in boxes; the moulds may thereby be more rapidly and more effectually dried, and better castings will be got, with a less expense. In the malleable iron work of engines scrap-iron has long been used, and considered preferable to other kinds; but if the parts are to be case-hardened, as is now the usual practice, the use of scrap-iron is to be reprehended, as it is almost sure to make the parts twist in the case-hardening process. In Digitized by Google 502 ENGINES, DETAILS OF. case-hardening, iron absorbs carbon, which causes it to swell: some kinds of iron have a greater capacity for carbon than other kinds, and in case-hardening they will swell more; and any such unequal enlarge ment in the constituent portions of a piece of iron will cause it to change its figure. In some instances case-hardening has caused such a twisting of the parts of an engine, that they could not afterwards be fitted together. It is preferable, therefore, to make such parts as are to be case-hardened to any considerable depth of Lowmoor iron, which, being homogeneous, will absorb carbon equally, and will not twist. Piston-rods are now very generally made of steel, and are obtained of the requisite size and quality from the rolling-mill. Steel is made almost exclusively from Dannemora iron: the bars are arranged in a furnace about 14 feet long; a layer of charcoal is spread over the bottom, then a layer of bars, and S0 on until about 10 tons of iron have been introduced. The top is covered with charcoal, over which is a layer of sand, and above that a layer of slush from the grindstone trough, applied wet; the object of which is entirely to exclude the air. The fire is then lighted, and in about a week the iron will have increased in weight a one hundred and fiftieth part, and be found converted into blistered steel. These bars may then be fagoted and tilted, so as to form steel articles of any size. In the operation of case- hardening the same process is carried on as in converting iron into steel, but it is only continued for such a time as to enable the charcoal to penetrate to a moderate depth. In our judgment all the malleable iron parts of a marine steam-engine should be case-hardened, as they cannot then be 80 easily defaced, by hammer marks or otherwise, and will be much less liable to rust. The more unwieldy portions may be case-hardened by prussiate of potash, a salt made from animal substances, composed of two atoms of carbon and one of nitrogen, and which operates on the same principle as in the case of case-hardening by means of charcoal. The iron is heated in the fire to a dull-red heat, and the salt is either sprinkled upon it or rubbed on in the lump, or the iron is rolled in the salt in powder; the iron is then returned to the fire for a few minutes, and immersed in water. By some persons the salt is supposed to act unequally, as if there were greasy spots upon the iron which the salt refused to touch, and the effect under any circumstances is exceedingly superficial; nevertheless, upon all parts not exposed to wear, a sufficient coating of steel may be obtained by this process. The most common plan of case-hardening consists in inserting the articles among horn or leather cuttings, bone-dust, or animal charcoal, in an iron box provided with a tight lid, which is then put into a furnace, and kept hot for a period answerable to the depth of steel required. In some cases the plan pursued by the gunsmiths may be employed with convenience. The article is inserted in a sheet-iron case, amid bone-dust, often not burned; the lid of the box is tied on with wire, and the joint luted with clay, and the box is heated to redness as quickly as possible, and kept half an hour at a uniform heat. Its contents are then suddenly immersed in cold water. The carbonaceous lining in the inside of old retorts is sometimes used in case-hardening with good effect. Steel is hardened by heating and cooling it suddenly, and softened by heating and cooling it slowly. A thin blade of steel, if heated, and placed between the cold hammer and anvil, will become extremely hard; whereas a thick piece of steel would not be made hard by such a mode of treatment. Mercury has been proposed, instead of water, for hardening steel, but its use is not attended with sensible advantage. Salt and water is also used, but the articles immersed in it are liable to rust, unless after- wards steeped in lime-water. Water which has been long used for tempering is supposed to be preferable to fresh water, and if the steel is harsh the chill is taken off the water. In the case of thin edge-tools the water is sometimes covered with a film of oil, but it is a question whether plain water is not preferable. The file-makers medicate the water they use for tempering, and the method of doing so forms one of the secrets of the trade; but it appears probable that a little white arsenic is the chief addition they make. A common practice with some steel articles is to make them in the first instance as hard as possible, and then to soften them somewhat, or let them down, as it is called, by heating them to a certain temperature, which is indicated by the color they assume. A pale straw-color, which is indicative of a temperature of from 430° to 450°, is the color proper to tools for metal; a dark straw- color, 470° to 490°, is that suitable for tools for wood and for screw-taps; a brown-yellow, verging to a light purple, 500° to 530°, is the color suitable for hatchets and saws; and a dark blue, 550° to 600°, is the color for springs. Steel dies may be tempered by heating them to the color of sealing-wax, plunging them into naphtha heated to 200°, and so soon as ebullition ceases, plunging them into cold water. It appears to be the prevailing opinion among experienced machinists, that for the great majority of articles requiring to be tempered, plain cold water is the best agent, but that for small elastic works oil is preferable. For letting down large tools, a red-hot muffle is a convenient instrument, and is used in the Bank of England. Steel articles may be most effectually softened by exposing them to a high heat, imbedded in a mixture of charcoal and chalk. Steel that has been spoiled by over- heating may be recovered by heating and quenching in water four or five times, carrying each to a somewhat less degree than the first excess, and finally the steel must be well hammered at a red heat, continuing the hammering until the steel is nearly cold. Copper and zinc seem to mix in all proportions, and every addition of zinc increases the fusibility. The red color of copper slides into that of yellow brass at about 4 or 5 ounces to the pound, and remains little altered to about 8 or 10 ounces; after this it becomes whiter, and when 32 ounces of zinc are added to 16 of copper, the mixture has the brilliant silvery color of speculum metal, but with a bluish tint. The alloys with zinc retain their malleability and ductility well, to about 8 or 10 ounces to the pound; after this, the crystalline character begins to prevail. The alloy of 2 zinc and 1 copper may be crumbled in a mortar when cold. The ordinary range of good yellow brass, that files and turns well, is from about 41 to 9 ounces to the pound. Brazing solders may be stated in the order of their hard- ness-3 parts copper and 1 part zinc, (very hard;) 8 parts brass and 1 part zinc, (hard; 6 parts brass, 1 part tin, and 1 part zinc, (soft.) A very common solder for iron, copper, and brass consists of nearly equal parts of copper and zinc. Muntz's metal consists of 40 parts of zinc and 60 of copper. Any proportions between the extremes of 50 zinc and 50 copper, and 37 zinc and 63 copper, will roll and Digitized by Google ENGINES, DETAILS OF. 503 work at the red heat, but 40 zinc to 60 copper are the proportions preferred. Bell-metal for large bells consists of 41 ounces to 5 ounces of tin to the pound of copper. Tough brass for engine-work, 1} pound tin, 11 pound zinc, and 10 pounds copper. Brass for heavy bearings, 21 ounces tin, } ounce zinc, and 1 pound copper. There is a great difference in the length of time brasses wear, as made by different manufacturers, but the difference arises as much from a different quantity of surface as from a varying composition of the metal. Brasses should always be made strong and thick, as when thin they collapse upon the shaft, and increase the friction and the wear. A lining metal for bushes has latterly been introduced in the bushes of locomotive axles, and other machinery, composed of 1 pound of copper, 5 pounds regulus of antimony, and 50 pounds of tin, or other similar proportions, the presence of the tin being the only material condition. The copper is first melted, and the antimony is added, with a small portion of the tin, charcoal being strewed over the metal in the crucible, to prevent oxidation. The bush or article to be lined having been cast with a recess for the soft metal, is to be fitted to an iron, formed of the shape and size of the bearing or journal, allowing a little in size for the shrinkage; drill a hole for the reception of the soft metal, say from 1 to t of an inch diameter; wash the parts not to be tinned with a clay wash, to prevent the adhesion of the tin; wet the part to be turned with alcohol, and sprinkle fine sal ammoniac upon it; heat the article till a fume arises from the ammonia, and immerse it in a kettle of Banca tin, care being taken to prevent oxidation. When sufficiently tinned the bush should be soaked in water, to take off any particles of ammonia that may remain upon it, as the ammonia would cause the metal to blow. Wash with fine pipe-clay and dry, then heat the bush to the melting point of tin, wipe it clean, and pour in the metal, giving it sufficient head as it cools; the bush should then be scoured with fine sand, to take off any dirt that may remain upon it, and it is then fit for use. This metal wears for a longer time than ordinary gun-metal, and its use is attended with very little friction. If the bearing heats, however, from the stopping of the oil-hole, or otherwise, the metal will be melted out. Proportion of Boulton and Watt's Wagon Boilers of various powers. HORSES' POWER 2 3 4 6 8 10 12 14 16 18 20 30 45 ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. Length 4 6 5 3 6 0 7 0 8 0 90 10 0 10 0 11 9 12 8 13 6 16 0 19 0 Breadth at water-line 3 2 34 3 6 3 9 4 0 43 46 4 9 5 0 5 2 5 4 5 6 6 0 Height 4 1 44 4 71 5 If 56 5 9f 60 6 2f 6 6 6 8 6 10 Height of water 2 6 2 8 2 10 3 3 36 38 39 3 10 4 0 4 1 4 2 4 9 5 6 Radius of crown 1 7 18 19 1 10f 2 0 2 23 2 41 26 2 7 28 2 9 3 0 Heating surface 30 0 38 0 46 0 64 0 83 0 100 0 118 0 138 0 156 0 176 0 201 0 297 0 438 0 Height of flue round boiler 1 9 1 10 111 2 4 2 9 31 32 3 5 3 7 3 9 3 11 4 0 4 9 Width of flue round boiler 0 9 0 9 0 10 0 10 1 0 0 1 1 1 1 2 1 2 1 2 1 4 1 3 Heating surface per horse power 15 0 13 0 11 0 107 10-2 10 0 98 98 97 98 10 0 98 96 Capacity of steam room in cuble feet 174 too 231 341 50 64 72 80 97 106 114.7 190 268 Contents of water in cubic feet 37 40 56 76 103 134 102 205 238 270 299 282 342 The 30 and 45-horse power boilers contain internal flues. A pound of coal raises about 9 pounds of water into steam, in the majority of good land-boilers; but in some of the Cornish boilers, a pound of coal raises 12 pounds of water into steam, or a cwt. of coal evaporates about 20 cubic feet of water. The weight of fuel burned on each square foot of grate-bars varies very much in different boilers; in wagon boilers it is about 12 or 13 pounds, in Cornish boilers from 31 to 4 pounds, and in locomotive boilers about 80 pounds. The number of square feet of heating surface for each square foot of fire-grate, is in wagon boilers from 14 to 15 square feet; in Cornish boilers, about 40 square feet; and in locomotive boilers, upwards of 70 square feet. Reckoning an engine of 73 inches diameter of cylinder, and 7 feet length of stroke at 217-horse power, the area of fire- grate in the most judiciously constructed marine flue-boilers, such as that of the Great Western, is .46 of a square foot,-the engine working expansively from one-third to one-fourth of the stroke. The heating surface in this boiler is 88 square feet per horse power, if the horse power be reckoned by our rule, so that the heating surface is 19 times the area of the grate surface; and if the consumption of fuel be taken at 6 pounds per horse power per hour, as it was very nearly, there will be about 13 pounds of coal consumed per hour on each square foot of fire-grate. In the tubular boilers latterly introduced into steam vessels, the proportions are somewhat different. The boilers of the Braganza, reckoning the power of the engines at 289-horse power, have only 39 square feet of fire-grate per horse power, while the heating surface is 11-98 square feet per horse power; but the grate surface, in this case, admits of a ready increase by lengthening the bars. This is at the rate of 8071 square feet of heating surface for one square foot of fire-grate; and if the consumption be taken at 6 pounds per horse power per hour, there will be 15:38 pounds of coal consumed per hour on each square foot of fire-grate. The grate surface per horse power in the tubular boilers of the Tagus is .38 square feet, and the heating surface is 7.73 square feet, which is at the rate of 2039 square feet of heating surface per square foot of grate. In the tubular boilers of the Sydenbam, the proportion is 21.64 square feet of heating surface per foot of grate, but the proportion of grate per horse power is larger than in the Tagus. In the tubular boilers of the Ocean steamer (232-horse power) the grate surface per horse power is 59 square feet, the heating surface 13.48 square feet per horse power, which gives 22.84 square feet of heating surface per square foot of grate. The consumption of coal per horse power per hour is 8.08 pounds, which is at the rate of 14'71 pounds per square foot of fire-grate per hour; but if, for the sake of com- paring it with the previous examples, the consumption be taken at 6 pounds per horse power per hour, Digitized by Google 504 ENGINES, DETAILS OF. as would be the case if the engine were worked more expansively, then the consumption of coal per hour on each square foot of fire-grate would be 10-17 pounds. These particulars may be tabulated thus :- Heating surface Vessels. per nominal Grate surface per Heating surface horse power. per square foot horse power. of grate surface. Great Western Flue boilers 88 .46 19 Braganza Tubular 1198 39 3071 Tagus Tubular 7.73 38 2039 Ocean Tubular 13.48 59 22.84 Sydenham Tubular 2164 Phoenix Tubular 91 .44 20 The boilers of the Phoenix, by Messrs. Penn, are represented in one of our plates. The amount of steam room in boilers varies very much. Wagon boilers of 2-horse power, it will be observed, have about 8 cubic feet of steam room per horse power, and the proportion diminishes as the size of the boiler is increased, until at 45-horse power the steam room is about 5 cubic feet per horse power. In the tubular boilers of marine engines the proportion is less than this. The tubular boilers of the Braganza have about 3.44 cubic feet of steam room per horse power those of the Ocean, 2.58 cubic feet, while some have as little as 1.79 cubic feet; but these last are addicted to priming. The proportions of half a square foot of grate surface, 10} to 111 square feet of heating surface, and 3 cubic feet of steam room per horse power, seem to answer very well for tubular boilers when the engines work expansively through one-third or one-fourth of the stroke. In these estimations, the whole of the tube surface is reckoned as effective surface. The proper arrangement of heating surface in a boiler, 80 as to prevent the overheating of the plates, is very important. Surfaces exposed to a high temperature should always be so made that the steam may disengage itself easily from the metal; for if it be retained in contact with it for any considerable time, the access of the water will be prevented, and the plate will become overheated in consequence. The vertical sides of high furnaces are often greatly damaged from this cause the steam is retained among the landings of the plates and other irregularities of surface, and the sides of the surface become buckled and drawn, from the iron becoming overheated. It is very expedient, therefore, to make all furnaces of marine or locomotive boilers wider at the bottom than at the top. The landings of the plates should also be made so as to prevent the possibility of steam being retained in them. The after- most tube-plate should be set at a slight angle to facilitate the liberation of the steam; and as the tubes will thus be somewhat off the horizontal, any water which may escape by leakage will run into the furnace, instead of incommoding the firemen by running out of the smoke-box doors. Construction of boilers.-The whole of the shells of boilers intended to withstand any considerable pressure, should be double riveted, with rivets 21 inches from centre to centre, the weakening effect of double riveting being much less than that of single riveting. The furnaces above the line of the bars should be of the best Lowmoor or Staffordshire scrap plates, three-eighths thick, and each furnace above the bars should consist of three plates, one for the top and one for each side, the underseam of the side-plates being beneath the level of the furnace-bars. The tube-plates of tubular boilers should be of the best Lowmoor iron, seven-eighths to one inch thick; the shells should be of the best Thornycroft S crown iron, or of Staffordshire iron, of good quality, and seven-sixteenths thick at the least. Angle iron should not be used in any part of a boiler, as in the manufacture it becomes reedy, like wire, and is apt to split in the direction of its length. It is a much safer dependence to bend the plates, if it be carefully done, and without any more sharp turns than can be helped, but it is convenient to use a little angle iron about the furnace mouths, which should be of the very first quality. The whole of the plates of boilers should be punched with a double punch, one nipple of which enters the hole last punched, while the other punches the hole: and it is very convenient to have the punching-press provided with a travelling table, whereby the operation of punching and paring the edges of the plates is made a self- acting one. The use of drifts and screw-jacks in putting the parts of boilers together, should not be permitted. The rivets should be of the best Lowmoor iron, eleven-sixteenths in diameter. The whole of the work should be caulked both inside and cutside, so far as it is accessible; the parts may then be washed over with a solution of sal ammoniac, and the rivets and landings above water painted over with a mixture of whiting and linseed-oil. It is very desirable that the space between the furnaces and tubes of tubular boilers should be sufficiently large to enable a man or boy to get in. The bend joining the top of the furnace at the after end with the bottom of the tube-plate, is very liable to get burnt away and its repair will be most difficult, unless made accessible from the inside to hold on the rivets. It appears expedient to shield this and another such exposed part, where the heat acts injuriously upon the iron, by means of fire-blocks moulded to the place, and secured by nuts sunk into dovetailed recesses in the substance of the block, which recesses are finally filled up with fire-clay. In new boilers even, such an application is most expedient in situations in which injury to the iron, from the impact of flame, is experienced or apprehended. The plate on the furnace side of the water-space at the end of the boiler should be inclined considerably towards the tubes to facilitate the ascent of the steam and it appears to be the preferable way to round off the top of the chamber leading from the furnace to the tubes. It appears preferable, too, to zig-zag the tubes sideways, as a greater strength of iron is thus got between the holes in the end-plates, without diminishing the facility of scaling the tubes, or introducing any instrument down between them to keep the spaces clear. Tubing and staying of boilers.-The tubes of boilers are most generally secured at the ends by means of ferules driven tight into them, the holes in the end-plates being usually countersunk, and a corre- Digitized by Google ENGINES, DETAILS OF. 505 sponding projection being made on the ferules. The ferules next the furnace are best made of steel, while, for the other ends, malleable iron ferules answer as well. The tool in which the ferules are made consists of three pieces; one piece is set in the anvil, and consists of a flat plate with a nipple on it, rising to half the depth of the ferule, and rounded at the corners; the next piece consists of a ring furnished with a handle, and with its lower edge recessed slightly into the flat plate 80 as to steady it, and this ring is larger in its internal diameter than the nipple by twice the thickness of the ferule; the last piece consists of another nipple made like the first, but formed with a head like a punch. A small hoop is formed by welding a piece of steel or iron, and is dropped into the space between the interior of the ring and the lower nipple; the upper nipple is then forced down by striking the punch head with a forge hammer, whereby the ferule is moulded to the right form: the parts are finally taken asunder, whereby the ferule is liberated. In brass tubes the use of ferules appears to be indispensable, but in the case of stout iron tubes, such as Russell's patent boiler tube, they are unnecessary; and the best plan, when iron tubes are used, appears to be to widen one end of the tube slightly, and to drive the tube in from the front of the boiler into both tube-plates, the holes in the front plate being made one-sixteenth wider than those in the back plate, and the tube being widened correspondingly. Before the tubes are driven in, the holes in the tube-plates must be slightly countersunk, and the tubes must finally be carefully riveted in. It will be expedient to screw a few of the tubes into the tube-plates instead of riveting them, 80 as to serve as stays, and also as abutments to rivet the rest of the tubes against. The screwed tubes should be left a little longer than the others; and thin nuts made of boiler-plate should be screwed upon the projecting ends to prevent leakage, and add to the security of the staying. In fitting in the tubes in this way, great care is necessary to make them perfectly tight; and it will be expedient to turn the ends slightly in the lathe to give them a trifling taper, and make them all precisely of the same size. In driving them in, each tube should not be driven home at once, as that will spring out the iron between the holes, but they should be all fitted in first with the common chipping-hammer, and when thus all equally fitted, they should be driven home by a heavy hammer or ram. The countersink in the holes must be but slight, and must be filled rather by riveting up endways than by riveting over. In some cases boilers are made with collars riveted on the tubes immediately behind the tube-plates, but this plan is attended with the objection that a tube cannot be renewed without taking the boiler asunder and with the still greater defect, that the ends of the tubes will be liable to get burned away in consequence of the internal collar preventing the access of the water. Boilers formed on this plan, therefore, will be found to become leaky at the ends of the tubes; and unless stayed, independently of the tubes, the tube-plates will be forced asunder by the pressure of the steam. To illustrate our views upon the staying of boilers by taking a particular case: suppose that it was required to stay the boilers of the Phoenix in such a way as to be safe under a very high pressure. To do this, it would be necessary to stay the sides of the furnaces to one another by three stays in the direction of their height, and five or six stays in the direction of their length. The highest row of stays would run along where the crown of the furnace joins the side, and the lowest where the bottom of the furnace joins the side, the third being situated in an intermediate position, 80 as to be shielded as much as possible by the furnace bars from the action of the heat. The bottom of each furnace should be stayed to the bottom of the shell by two rows of stays, and the tops of the furnaces should be secured by means of arched malleable iron bars, to which the plate would be stayed as in locomotive boilers. These arches should touch the plates only at the points at which the stays go through, and their lower edges should be sharpened away in order to facilitate the disengagement of the steam; they may be joined together athwartships, or made in the same piece, and from the part opposite each water-space a row of stays should run to the top of the boiler. To enable these stays to pass, a perpendicular row of tubes must be left out opposite each water space, which will have the further advantage of enabling the water to circulate with greater facility. The steam-chest should be stayed both fore and aft and across, with stays pitched 18 inches or 2 feet apart; a row of athwartship stays should run horizontally across immediately under, and another immediately above the tubes, and from the ends of the stays of the superior, to the ends of those of the inferior row, vertical bars should ascend between the tubes and the shell, to which the shell may be stayed while the sides of the water-space between the end of the furnaces and the end of the boiler are stayed with stays of the same dimensions and pitch as those of the furnaces. These stays may consist of 14-inch bolts of the best scrap-iron tapped through both plates, and in the furnaces they should have thin nuts of boiler-plate on their ends; but where stay bolts penetrate the boiler shell, they may have heads on the outside of the boiler. The whole of the long stay bars should be fixed in their places, not with cutters, as is the common fashion, but with rivets; they should be as it were built into the boiler, so that the safety of the boiler cannot be endangered by the decay or accidental detachment of a cutter or pin. Where stays join on to the root of the funnel, they must be continued through it by placing short stays in the inside; and wherever a large perforation in the shell of a boiler occurs, from the application of a steam-chest or otherwise, a sufficient number of stays should be put across the opening to make the strength as great as if there were no perforation. Respecting the strength of boilers, it is expedient to keep within a load of 8000 pounds upon the square inch of iron in boilers in actual use. The breaking strain of good iron is about 60,000 pounds on the square inch, but the best malleable iron will not bear a greater load than about 18,000 pounds on the square inch, without permanent derangement of structure, or 17,800 pounds. Tredgold gives a rule for determining the strength of cylinders, cylindrical boilers, and other such vessels, which gives propor- tions not far from those which are advisable. It is this :-Multiply 2.54 times the internal diameter of the cylinder by the greatest force of steam on a circular inch; divide by the tensile force the metal will bear without permanent derangement of structure; the result is the thickness in inches. 'In practice, the iron of boilers has sometimes to sustain a greater strain than what is indicated in this rule. The utmost strain to which iron can be safely subjected in machinery, is 4000 pounds on the square inch, and 64 Digitized by Google 506 ENGINES, DETAILS OF. this strain is approached in locomotive engines. A cylinder 12 inches diameter, with a piston-rod 11 inch diameter, and with steam of 80 pounds on the square inch, bears a tensile strain of 3766 pounds on the square inch. Upon the iron of the boiler the strain is still greater, being about 5000 pounds on the square inch. If the plate be five-sixteenths thick, it will require 32 inches in length of the boiler to make a square inch of sectional area, and if the diameter be 39 inches, the separating force will be 39X32X 80=9984 pounds. But this strain is borne by a square inch of sectional area on each side of the boiler, wherefore the strain on a single square inch of sectional area is half of this, or about 5000 pounds. This takes no account of the support derived from the boiler ends, but in long boilers the support derived from the ends is but small, and is not equivalent to the weakness caused by the rivet holes. A strain at all approaching that upon locomotive boilers would be most unsafe in the case of marine boilers, on account of the corrosion to which they are subject. All boilers should be proved with water when new, to three or four times the pressure they are intended to carry, and they should be proved occasionally by the hand-pump, when in use, to detect any weaknesses that corrosion may have created. In con- nection with the strength of boilers, we may state that the Administration des Ponts et Chaussées," in France, has fixed the following formula for the dimensions of safety-valves for stationary engines. d= diameter in centimètres; c=the total heating surface in square mètres; n=the effective pressure in the boiler in atmospheres; d=2-6 n-0412 A mètre is 3.28 feet, and a centimètre is the hundredth part of a mètre, or 0328 of a foot. Every marine boiler should be provided with a safety-valve, the action of which is independent of that of the stop-valve, 80 that though the stop-valve becomes deranged, the safety-valve of that boiler will never- theless act. It is very desirable that a marine boiler should be fired from the one end only, a material saving of room being thereby effected in the ship. In that case, too, there is no inducement to use more than one funnel. Funnel plates are usually nine feet long and three-sixteenths thick, and if there be a platform for coal over the boilers, it will be the best economy to make it of the same thickness, but the other parts of the bunkers may be made of sheet-iron weighing 8 pounds to the square foot. The dampers should not be the funnel, but in the top of the uptake, 80 that they may be closed if the funnel is carried away. It is expedient to put two hoops upon the funnel for the attachment of the funnel shrouds, 80 that the funnel will not be carried overboard should the bolts joining the lugs of one hoop break, or should the funnel break across at the top hoop, as has sometimes happened from the corrosive action of the steam escaping from the waste steam-pipe. A high angle-iron cooming should surround the funnel, on the deck, outside of which should rise a sheet-iron casing, and this sheet-iron casing should be riveted to the cooming or made quite tight thereto, so as to prevent the possibility of water leaking down on top of the boiler. Over the casing, another short piece of casing riveted to the funnel should descend for about a foot, so as to prevent the spray from entering between the casing and the funnel, and thus getting down upon the boiler. The usual height of the funnel of sea-going steamers is from 40 to 50 feet. Miscellaneous remarks about boilers.-All the rough nuts about a steam-vessel which require to be screwed and unscrewed frequently, such as the bolts of the man-hole and mud-hole doors of the boiler, should have large square nuts, and the bolts should be strong and have coarse threads. Hexagonal nuts speedily become round in the hands of the firemen, by whom the mud-hole and man-hole doors are generally taken off, and fine threads soon get stripped and overrun. It is much the safest way to put on both mud-hole and man-hole doors from the inside, with cross-bars on the outside to keep them closed. The plan sometimes followed, of putting on mud-hole doors from the outside, and securing them by one or two bolts, is a practice we have already reprehended as full of danger, as, if the thread strips or the bolt breaks, the door will fly off, and the boiling water rush out, scalding every one in the vicinity. Mud-hole doors of this kind, even if they leak, cannot be screwed up to tighten them when the steam is up, as there is a perpetual risk, in tightening the doors, of stripping the thread or breaking the bolt. Upon the corrosion of boilers.-The tops and steam-chests of boilers, and the bottoms of the ash-pits, are the first parts to give way. The steam-chest wears chiefly from internal action; in some cases the iron exfoliates in the form of a black oxide, which separates in flakes like the leaves of a book; while in other cases the iron is, as it were, gouged away, and the heads of the rivets are worn off, as if by an acid. It is most important that a remedy should be found for this evil, and it appears probable that by painting the interior of the boiler with successive coats of Roman cement, or of some of the calcareous cements which resist the action of water, the internal corrosion of the boiler might be prevented. Can- vas soaked in liquid cement has been proposed, but it is questionable whether the canvas might not on some occasion come off, and if it got into the mouth of the safety-valve orifice, it might cause the boiler to burst. The ash-pits are worn away chiefly by the wetting of the ashes in the stoke-hole, and it is expedient to apply shield-plates to those places when the boilers are made, which plates only will be exposed to wear, and may be easily renewed, leaving the ash-pits untouched. The best method of setting boilers appears to be to set them on a platform, and care must be taken that no projecting copper bolts touch the boilers in any part, as they will be very likely to corrode the points of contact into holes. The platform may consist of 3-inch planking, laid across the keelsons, nailed with iron nails, and caulked and puttied like a deck. The surface may then be painted over with thin putty, and fore and aft boards of about half the thickness may then be laid down-the heads of the nails being well punched down. This platform must next be covered with mastic cement, and the cement must be caulked beneath the boiler by means of wooden caulking tools, so as completely to fill every vacuity. Coomings of wood must next be laid round the boiler, to confine the cement; and the space between the coomings and the boiler must be caulked full of cement, and be smoothed off with a slope on the top so Digitized by Google ENGINES, DETAILS OF. 507 as to throw off any water that may chance to fall upon it. Many cements suitable for the setting of boilers are sold ready made. The following is one of the compounds sometimes used :-To any given weight of sand, or pulverized earthenware, add two-thirds of such given weight of Portland, Bath, or any other similar stone, pulverized. To every five hundred and sixty pounds weight of these earths, 80 prepared, add forty pounds weight of litharge, and, with the last-mentioned given weights, com- bine two pounds weight of pulverized glass or flint-stone. Then join to this mixture one pound weight of minium and two pounds weight of gray oxide of lead. The composition being thus mixed, pass the same through a wire sieve, or dressing-machine, of such a fineness as may be requisite for the purpose intended, preferring a fine sieve, when the composition is to be used for works that require a fine, smooth, or even surface. It is now a fine and dry powder, and may be kept open in bulk or in casks for any length of time, without deterioration. When this composition is intended to be made into cement, it is spread upon a board or platform, or mixed in a trough; and to every six hundred and five pounds weight of the composition are added five gallons of vegetable oil, as linseed-oil, walnut-oil, or pink-oil. The composition is then mixed in a similar way to mortar; it is afterwards subjected to a gentle pressure by treading upon it, and this operation is continued until it acquires the appearance of moistened sand. The cement should be used the same day the oil is added, otherwise it will fix or set into a solid mass. The large rivets sometimes used as stays for the shells of boilers, are objectionable, as the heads very often come off; and if the fracture be between the boilers in a position not accessible from the outside, it will be necessary to empty the faulty boiler of its water, in order to repair the defect. The sides of furnaces should always be made to incline to each other in the manner already mentioned, 80 that the crown is not 80 wide as the fire-bars, and it is a good arrangement to place the bars adjoining the sides close against the sides throughout their length, so as to leave no air space in that situation. By this arrangement the intensity of the heat acting immediately against the plates of the sides is diminished. A crack in a plate is most conveniently closed, by boring several holes along its length and closing them with rivets having large heads which cover over the defect. If a patch be applied to the top of a furnace or flue, it is better to apply it from the inside of the boiler rather than from the flue, as in the latter case a recess is left into which deposite falls, and a hole is likely then to be burnt again in the same place. If the furnace mouth be contracted by bending in the sides of the furnaces, as is the general practice, it is necessary to be very careful that scale does not accumulate in these corners, else they will be very liable to be burnt into holes. The waste steam-pipe should be set into a faucet at the bottom, instead of being constructed with a flange, as the neck of a flange will be broken by the movement of the funnel when the vessel rolls. The waste steam-pipe should be as high as the funnel, as, if lower, the waste steam continually striking against the funnel wears it out in that part very rapidly. The pipe for conducting away the waste water from the top of the safety-valve, should lead overboard, and not into the bilge, as the steam which passes through it when the steam is blowing off is inconvenient if directed into the ship. Respecting fire bridges, the preferable practice, on the whole, appears to be to construct them of brick rather than to make them water bridges, as with water bridges there is often trouble from the cracking of the plates. If water bridges, however, be used, they should be made with a great inclination in the breadth of the furnace, to facilitate the escape of the steam. Flame bridges have been introduced into the furnace flues of steam-vessels on some occasions, consisting of a pile of fire-brick, between which and the sides of the flue only a space of about three inches is left for the flame and smoke to pass through, and the flame is spread in a sheet over the interior of the flue. Where the flue is very large, the use of a flame bridge appears to be expedient; and in land boilers with large internal tubes, its use has been attended with beneficial results, but in the majority of marine boilers we believe that it will prove of but little service. Hanging bridges, consisting either of brick or sheet-iron, descending from the top of the flue, are very beneficial in the majority of flue boilers, but are inapplicable in the case of tubular boilers. A Venetian damper, however, or a perforated plate applied at the end of the tubes, would probably produce the same effect, as it might be made to retain the heat in the upper portion of the tubes by only opening it partially. Locomotive engines.-General features of the boiler.-The boiler is the most important part of a loco- motive-engine, and the useful effect of the machine depends in a great degree on the boiler being capable of generating the requisite quantity of pure steam, without requiring the draught of air and flame through the fire and tubes to be accelerated or forced excessively. The fire-box is that part of the boiler in which the heat is generated and partially absorbed, the remaining absorption taking place in the flue tubes, which convey the products of combustion from the fire, through the water, to the smoke- box, whence they are dissipated in the atmosphere. Of course, the more nearly these products of com- bustion, at their entrance into the chimney, are found to have been cooled down to the temperature of the water in the boiler, the more economical in fuel the boiler will, cateris paribus, be. To obtain the utmost economy in this way, the superficial surface of the tubes has been increased to the utmost extent, by enlarging the diameter and increasing the number and size of the tubes. The boiler of Bury's 14-inch* engine contains 92 tubes of 21 inches external diameter, and 10 feet 6 inches long; the boiler of Stephenson's 15-inch engine contains 150 tubes of 11 inch external diameter, and 13 feet 6 inches long. It will therefore be seen that the superficial surface in Bury's tubes is, comparatively, rather small, but yet the production of steam is found to be sufficiently copious, with a blast-pipe of rather more than the average diameter on the other hand, notwithstanding its great surface, Stephenson's boiler is found to require a smaller blast-pipe than usual It seems highly probable that the extra intensity of blast requisite in the latter case consumes 80 much power to produce it, as completely to countervail the economy of fuel consequent on the very complete abstraction of the heat, by the great length of tubes in proportion to their diameter. In an experiment tried by Mr. Stephenson, the heating surface of the fire-box, where the heat is re- This dimension is the diameter of cylinder, by which dimension locomotivos are distinguished. Digitized by Google 508 ENGINES, DETAILS OF. ceived by radiation, was found to be more effectual than the tube surface, where the heat is received by conduction, in the ratio of 1 to 3, and hence the heating surface of a locomotive is sometimes esti- mated as the surface of the furnace plus one-third that of the tubes. The shell, which is cylindrical, is attached to the smoke-box and fire-box by angle-iron; the end of the shell next the smoke-box is closed entirely by the tube-plate, but at the smoke-box end the water has free access quite round the internal fire-box, one side of which forms the tube-plate. The shell, ex- ternal fire-box, and the smoke-box are always of iron, the thickness of plate being 5-16th in. in ordinary boilers of 3 feet to 3 feet 4 in. in diameter, though in some cases it is 1 in.; the pitch of rivets is 1f in., and the diameter of rivets 11-16th in. The shell is sometimes made with flush joints, a band of iron covering the joint attached by two rows of rivets. The boiler plates should have their fibres running round the boiler instead of in the direction of its length, as the plate is somewhat stronger in that direc- tion. The boiler is secured endwise by longitudinal stays, which are fastened by cutters to jaws at- tached to the end plates. The blast-pipe is the eduction-pipe diminished in area at the mouth to such a degree as to cause the steam to issue with a great velocity, whereby a powerful draught through the fire is maintained by the steam rushing up the chimney. The area of the mouth of the blast-pipe varies in different engines, but an area of 1-22d of the area of the cylinder is a common proportion. A variable blast-pipe, the orifice of which may be increased or diminished in area, is now much used. One arrangement for this purpose consists of the application of a regulator plate at the top of the blast-pipe, with a hole through the centre of the plate, through which the nozzle of the blast-pipe passes. When this regulator plate is closed, the whole of the steam has to ascend through the central nozzle; but when the regulator is open, or partly open, a part of the steam escapes through the holes in it. Another plan consists in the application of a moveable plug within the blast-pipe, which may narrow the escape orifice to an annular space of small area, the plug being raised or lowered by a lever and rod. Stephenson's method of contracting the blast consists in making the nozzle of the pipe conical, and forming it to slide within the upright pipe, whereby an annular space is left for the escape of the steam around the nozzle when the nozzle is lowered. The man-hole, or entrance into the boiler, consists of a circular or oval aperture of about 15 in. diam- eter, placed by Bury at the summit of his dome, and by Stephenson in the front part, a few inches above the cylindrical part of the boiler. The cover that closes this aperture in Bury's engine also con- tains the safety-valve seats, thus simplifying the construction by preventing the necessity of an inde- pendent aperture and cover for the safety-valves, as in Stephenson's engine, where the safety-valves'are placed independently on the top of the dome. The steam-tight joint of the man-hole cover is made in Bury's engine by a single thickness of canvas, smeared with red-lead; and the joint is not liable to be- come defective or leaky, because the surfaces are turned true and smooth, both on the cover and its seat. When these surfaces have not been made true in this manner, it becomes requisite to use a num- ber of thicknesses of canvas, or other material, to form the joint; and the action of the steam soon rotting away the soft substance, a leakage is caused through the joint, which makes repair indispensa- ble. The small domes are of the same form as those used on the Grand Junction Railway, which are cylindrical vessels of about 20 in. diameter, and 2 feet in height, with a semi-globular top, are gener- ally made of plate-iron, about 1 in. thick, welded at the seam, and with the flange at the bottom turned out of the same piece. In some cases, domes of this form have been constructed of cast-iron, about 1 in. thick, but they have been found objectionable from their top weight, and they cannot be considered as altogether safe from explosion. The steam-whistle is generally placed upon the fire-box dome within conve- 1443. nient reach of the engineer. It consists of a cock, Fig. 1443, opening by four side holes into an annular chamber, whence the steam escapes through an annular aperture about 1-64th in. in width, striking in its exit the edge of a bell, fixed by a stem to the cock, whereby the sound is produced. The edge of this bell should be about 1-32d of an inch thick, and should be exactly over the opening, so that the issuing steam may impinge directly upon it. The metal should be of similar composition to that of clock bells. The whistle is sometimes jointed by running melted lead between its flange and the dome-plate; but it is better to fit the sur- faces so truly together as to be steam-tight merely with the assistance of one thickness of fine canvas coated with red-lead or cement, for lead will always be found to decay by contact with high-pressure steam, making continual renova- tion necessary. This remark equally applies to the other joints connected to the shell of the boiler, such as the gage-tube, blow-off cocks, and feed-pipes. To save the steam which is formed when the engine is stationary, a pipe is fitted to the boiler which conveys the steam at such times to the tender, where it heats the water and is itself condensed. This method of disposing of the steam is bene- ficial in descending inclined planes, when more steam is formed than is required for the use of the engine. A cock for emptying the boiler is usually fixed to the bottom of the fire-box; this cock should not be placed at the front end of the fire- box, as the foul water blown out of the boiler is thrown over the geering, which is injured by the sand getting into the bearings. Fire-box.-Iron fire-boxes have been extensively tried by Bury and others, and in cases where the plate-iron of which they were formed has been of a peculiarly perfect texture, and not liable to laminate or crack under the action of the heat, they have been found to answer exceedingly well, and not only to be much cheaper than copper, but also to last at least twice as long before requiring renewal. If the materials be very carefully selected, the use of iron fire-boxes will be found productive of economy, if only used in situations where pure water is obtainable. The duration of ordinary copper fire-boxes de- pends in a great measure upon the original texture of the copper, which ought to be rather coarse-grained Digitized by Google ENGINES, DETAILS OF. 509 than rich and soft, and also particularly free from irregularity of structure and lamination. Considera- ble advantages have been found to arise from increasing the capacity of the fire-box, more especially its depth, which ought to be such as to allow of the requisite quantity of coke being placed within it with- out reaching above the mouths of the lower tubes, a fault which would cause the smaller pieces of coke to enter and block up the tubes, to the manifest deterioration of the draught, and diminution of the efficacy of the engine. The heating surface in the fire-box being of an extremely valuable and efficient nature, and the extensive area of fire-bar surface being very conducive to freedom of draught, we are induced to question whether the large square fire-box is not pro tanto preferable to the round one, which must necessarily be very small, except on the 7-feet gage, in which case the round fire-box offers de- cided advantages. The square fire-box is generally made of iron, i in. to I in. thick in every part ex- cept the tube-plate, which has been from t in. to t in.; but experience has shown considerable advan- tage in making the tube-plate i in. thick, as this great strength prevents the spaces between the tubes from being compressed, and the tube holes rendered oval, in the processes of drifting and feruling the tubes however, this evil will be found to exist, even with a i in. tube-plate, if the tube holes be placed in too close contiguity, as has been found the case in several of Stephenson's engines; and, from practi- cal observation, we find that t in. should be the minimum distance between any two tubes. The sides, back, and front below the tubes, of the square fire-box, are stayed at intervals of 41 in. to 5 in. with either copper or iron stays, screwed through the outer case into the fire-box, and securely riveted; but, as the riveting within the fire-box is found to decay rapidly, from the action of the heat, Mr. Dewrance, of the Liverpool and Manchester Railway, has adopted, with good results, stays formed with a large square head, and screwed from within the fire-box outwards, the square head projecting 2 in. into the flame. Iron stay-bolts for the fire-box are found to last nearly as long as copper, and, from their supe- rior tenacity, are often considered preferable. Until lately, it had been supposed that round fire-boxes possessed such advantages in point of strength over square ones, owing to their arched form, that they were capable of resisting the pressure of the steam without the use of stays; but experience has shown that, whatever be the shape, a fire-box must be stayed more or less to render it safe, for the shell of the fire-box is liable to be wasted so much by the heat, that it is not safe to depend altogether upon the strength its form confers, especially as the form will be changed if the boiler be suffered to become short of water. In round fire-boxes, the sides near the crown part generally suffer most from waste: these portions are now provided with stays by Messrs. Bury, Curtis, and Kennedy, who are the main sup- porters of round fire-boxes ; and with this provision the round fire-boxes are necessarily the stronger. The roofs of all fire-boxes require to be stayed by cross-bars; but the bars are required to be both stronger and more numerous for the square fire-boxes, and should always be carefully made of wrought- iron, and very carefully fitted before being bolted on. Stay-bars of cast-iron have been employed, on account of their cheapness; but, having led several times to accidents from explosion, they are now dis- carded. These bars are only in contact with the fire-box at the part around the rivets, and in all the other parts they permit the access of the water below them. It is advisable to bring these bars to an edge on the under side, 80 as to facilitate the escape of the steam. In Sharp and Robert's engines, the fire-box is made of three plates; the tube-plate and front plate have their edges bent over, and to these are attached a single plate which forms the crown, and two sides of the furnace. The interior fire-box is joined at foot to the exterior by a Z-shaped iron, which forms the bottom of the water-space, and is preferred, inasmuch as it leaves a wide water-space, and is easily cleaned. The outer and inner fire- boxes are joined round the furnace door, which is double, to prevent inconvenient radiation. The external fire-box has sometimes a semi-cylindrical top, joined by turning over the sides like an arch, and sometimes a dome-shaped top. The fire-bars have always been a source of much expense in the locomotive-engine, as they burn out very rapidly, and have to be often renewed; from the rapid combustion going on over their upper surfaces, they become heated intensely throughout, causing them to throw off scale, and to bend under the weight of the fuel. The best remedy has been found to consist in making the bars very thin and deep, so as to keep their lower edges exposed to a cooling draught of air, and to diminish the area of metal conducting heat downwards from their heated upper edges. Thin fire-bars admit of being placed nearer together than thick ones, thus offering no increased impediment to free draught, while preventing the loss of small pieces of unburnt coke, which might otherwise drop through into the ash-box, and be wasted. Fire-bars have given much satisfaction when made 4 inches deep, (parallel), and full I inch thick on the upper edge and I inch on the lower edge. The frame carrying the fire-bars has often been made capable of being dropped on the instant, with its fire-bars and fire, into the ash-box, or upon the road, by means of catches drawn back by levers; but though the fire-bar frame is thus left unsupported, very often it will not drop, and even cannot be forced down out of its place, owing to the clinkers and tarry products of combustion forming an adhesive binding between its edge and the fire-box; it has ac- cordingly been found best to support the fire-box frame permanently, and when any cause requires the sudden withdrawal of the fire, to lift the fire-bars singly out of place, by means of the ordinary dart. It is necessary to place the fire-bars with their upper surface about 3 inches higher than the bottom of the water-spaces, which, by this means, will be allowed to contain quiescent water, ready to retain with- out injury any deposite that subsides from the water, and the water-spaces should be periodically cleansed, by means of the mud-holes placed opposite the edge of each water-space in the lower part of the outer fire-box shell. These mud-holes are made water-tight by means of either a brass plug simply screwed in and with a slight taper, or by a door applied with a soft packing on its face, and screwed up with a bridge-piece and bolt, making the joint on the internal surface of the outer shell, the hole and door being made sufficiently oval to enable the door to be introduced into the water-space. The latter plan often gives rise to inconvenience, from the joint being found leaky when the steam is raised, ren- dering it necessary to drop the fire, and empty the boiler, before it can be renewed. In some very large square fire-boxes, such as those used on the Great Western Railway, a diaphragm, or divisional 4-inch water-space ,has been placed across the middle of the fire-box, with the view of obtaining increased Digitized by Google 510 ENGINES, DETAILS OF. heating surface. This diaphragm has its lower edge (in which deposite takes place) made straight, and about 2 inches below the general surface of the fire-bars, but its upper edge is of the form of an inverted arch, in order to promote the free delivery of the steam generated within it into the steam-dome. The sides of the fire-box, where the diaphragm is attached, are not cut away to form passages for the water and steam, but are pierced with a series of circular holes, 3 inches in diameter, to permit a due circula- tion without uselessly weakening the fire-box; but the uppermost hole of the series must be placed at the highest point of the diaphragm, otherwise an accumulation of steam, and consequent injury at that point, will ensue. The use of a diaphragm is found to be beneficial in the case of a very powerful en- gine, provided its upper edge be made sufficiently low to admit of the tubes being conveniently drifted over it, and to allow the dart to be used with facility, in dropping the front set of fire-bars. The ash-box consists of a plate-iron tray, placed below the fire-box, to receive the burning ashes that drop from betwixt the fire-bars. In the earlier locomotives, no ash-boxes being used, the red-hot ashes were dispersed to a considerable distance by coming in contact with the wheels, and conflagrations were often thereby originated. The ash-box should be as large as convenient, and not less than 10 inches deep, otherwise it will materially impede the draught but if of ample dimensions, and closed at the sides and back, it will increase the draught, particularly when running against a head wind, at which time a strong draught is required. A hanging shutter to open or close the front of the ash-box forms a good damper. The bottom of the ash-box is placed about 9 inches above the level of the rails, and should on no account be nearer than 6 inches, otherwise the engine cannot pass safely over stones or similar objects lying accidentally between the rails. Tubes.-The tubes are generally formed of brass; the ferules by which they are secured are for the most part made of steel at the furnace end, and of malleable iron at the smoke-box end, and the holes in the tube-plates are tapered, 80 that the tubes bind them together. Great care should be taken in securing the tubes, as any neglect will be productive of much inconvenience. The ferules are found to be very injurious to freedom of draught, particularly in very small tubes; and to overcome this objec- tion, the methods we have mentioned, and many others, have been tried for fastening the tubes in by riveting over or screwing into the tube-plates; but hitherto no method, except that of internal tube- rings, has been found to answer in the case of brass tubes; but we think it likely that, with wrought- iron tubes, internal tube-rings will be ultimately abandoned. Stephenson has frequently adopted iron tubes of late, in preference to brass, on the score of their greater cheapness and durability; and in some cases, where unusual attention has been paid to them, and pure water used, they have been found to answer very well. A common internal diameter of tubes is 18 in. If made very small, the tubes are liable to be choked by pieces of coke, and the sectional area will be inconveniently contracted, while, if made much larger, the heating surface will be unduly diminished. The number of tubes varies con- siderably in different boilers in one species of locomotive in extensive use the number is 134, and the pitch 21 in. Sufficient space is left below the tubes for deposite, that it may not be in contact with the tubes and cause them to be burned: the extreme tube of the widest row is about the diameter of a tube from the boiler shell. In the long-boiler engines of Stephenson, from the volume of water con- tained in them, considerable time is required to get up the steam, even 80 much as three and a half hours where the ordinary engines take two hours, and they require great care in firing and feeding to prevent the steam running low. Smoke-box and chimney.-The smoke-box door of many engines is hinged at the bottom, and is kept shut by means of handles and catches; but the position of the door when open is in that case inconve- nient, as it prevents ready access to the tubes. In some of Stephenson's engines, the smoke-box door is in two leaves, which open like the doors of a house, overlapping at the centre, where they are closed by a bar, and at top and bottom by handles and catches. This door admits of the easy examination of the cylinders and valves. A small door is usually left near the bottom of the smoke-box, by which the accumulated cinders may be removed. The bottom of the smoke-box should not be below the ash-pan, or be much nearer the level of the rails than 18 inches, else the waste-water cocks of the cylinder projecting through it, would be liable to injury from objects lying on the line. The smoke-box is lower in freight engines than in passenger engines, on account of the driving wheels being smaller and, being coupled with the other wheels, the cylinder has frequently to be inclined to let the moving parts work clear of the front axle. The chimney must not stand more than 14 feet high above the rails. The sectional area of the chim- ney is about 1-10th of the area of fire-grate. The chimney is usually provided with a damper, similar to the disk throttle-valve of an ordinary engine this is generally hung off the centre, and a hole is made in it for the top of the blast-pipe, which projects through it when it is closed. Another damper has been applied by Messrs. Rennie at the smoke-box end of the tubes, consisting of a sliding-plate perforated with holes, which when opposite the ends of the tubes will give a free current. and may be made to close them completely if required. Another kind of damper consists of an arrangement of thin bars similarly disposed to the laths of a Venetian blind; the plates being so hinged, that when placed with their edges to the tube-plate, they leave the flow of air through the tubes unimpeded, and when hanging down they close up the tubes, or they partially close the tubes in any intermediate position. By either of these arrangements, the hot air is retained for a longer period in contact with the tubes than if a simple damper were used, as each tube is virtually furnished with a hanging bridge which keeps in the hottest air and lets only the coldest flow out. An inconvenient degree of heat in the smoke-box is also pre- vented. The smoke-box is usually made of t plate; the chimney of fth plate; the blast-pipe of fth copper, and the steam-pipe of 3-16th copper. Framing.-In some engines the side-frames consist of oak, with iron plates riveted on each side. The guard-plates are in these cases of equal length, the frames being curved upwards to pass over the driving-axle. Hard cast-iron blocks are riveted between the guard-plates, to serve as guides for the axle- bushes. The side-frames are connected across at the ends, and cross-stays are introduced beneath the boiler to stiffen the frames sidewise, and prevent the ends of the connecting or eccentric rods from fall- Digitized by Google ENGINES, DETAILS OF. 511 ing down, if they should be broken. The springs are of the ordinary carriage kind with plates, con- nected at the centre, and allowed to slide on each other at their ends. The upper plate terminates in two eyes, through each of which passes a pin, which also passes through the jaws of a bridle, con- nected by a double-threaded screw to another bridle, which is jointed to the framing: the centre of the spring rests on the axle-box. Sometimes the springs are placed between the guard-plates and be- low the framing, which rests upon their extremities. One species of spring which has gained a con- siderable introduction consists of a number of flat steel plates, with a piece of metal or other substance interposed between them at the centre, leaving the ends standing apart. A common mode of connecting the engine and tender, is by means of a rigid bar with an eye at each end, through which pins are passed. Between the engine and tender, however, buffers should always be interposed, as their presence contributes greatly to prevent oscillation and other irregular motions of the engine. A bar is strongly attached to the front of the carriage on each side, and pro- jects perpendicularly downwards to within a short distance of the rail, to clear away stones or other obstructions that might occasion accidents if the engine ran over them. The axles bear only against the tops of the axle boxes, which are generally of brass; but a plate extends beneath the bearing to prevent sand from being thrown upon it. The upper part of the box in most engines has a reservoir of oil, which is supplied to the journal by two tubes and siphon wicks. Stephenson uses cast-iron axle boxes with brasses, and grease instead of oil, which is fed by the heat of the bearing melting the grease, and causing it to flow down through a hole in the brass. All the engines with outside bearings have inside bearings also; they are supported by longitudinal bars, which serve also in some cases to support the piston guides: these bearings are sometimes made so as not to touch the shaft, unless in the event of its breaking. Steam-dome pipes and regulator.-The steam-dome, or separator, from the upper part of which the supply of steam is obtained, is now generally placed over the fire-box; and in Bury's and Stephenson's engines it forms a part of the external shell of the fire-box; whilst in the engines used on the Grand Junction Railway, it consists of an independent cylindrical vessel, attached to the low roof of the fire- box. Either plan, this latter or Bury's, is perfectly safe and strong, without the addition of stay-rods; but Stephenson's dome presents a large extent of flat surface, from the roof of the internal fire-box up to the arched roof of the external fire-box; and this flat surface requires to be powerfully stayed by angle- irons and tension-rods. We remember an instance in which the accidental omission of one of the nu- merous tension-rods led to the forcing out and partial explosion of the side of the fire-box, showing how much depends on the circumstances of these rods, with their joints and pins, remaining sound and unin- jured from corrosion or other source of injury or decay. In this respect the round fire-box, with its dome, has the advantage of superior strength and safety. A large steam-dome is found to be the most efficacious mode yet tried for preventing the evil of priming or damp steam; but no height of dome will entirely prevent it if there be not space enough left above the tubes in the cylindrical part of the boiler to allow the free passage of the steam along to the fire-box and dome, while an excessive height of dome is also found to produce an unsteady motion of the engine, by causing the machine to be top-heavy. A height of about 2 feet 6 inches above the cylindrical part of the boiler is found to give satisfactory re- sults in practice, and to lead to the production of as pure steam as any greate. altitude could secure. In some engines the steam is withdrawn from a dome placed at the smoke-box end of the boiler, into which the steam-pipe rises. It is thought that the ebullition being less violent at this point, the steam will thus be more effectually dried. The steam-pipes are made either of iron or copper; and of these, iron best withstands the high temperature of the smoke-box and the impact of the cinders, but it is liable to internal corrosion. The steam-pipe, after entering the smoke-box, divides into two branches, one passing down each side of the smoke-box so as to leave a free space for cleaning the tubes, and also to avoid as much as possible the impact of the hot air and cinders; but in some engines the steam-pipe descends vertically, which is somewhat inconvenient in practice. The area of the steam-pipe is one- sixth to one-eighth of the area of cylinder, and the branch steam-pipes are each about one-teuth of the area of cylinder. The admission of the steam from the boiler to the cylinders is regulated by a valve or regulator, which is generally placed immediately above the internal fire-box, and is connected with two copper pipes, one conducting steam from the highest point of the dome down to it, and the other conducting the steam that has passed through it along the boiler to the upper part of the smoke-box. Regulators may be divided into two sorts, viz., those with sliding-valves and steam-ports, and those with conical valves and seats, of which the latter kind are the best. The former kind have for the most part hitherto consisted of a circular valve and face, with radial apertures, the valve resembling the outstretched wings of a butterfly, and being made to revolve on its central pivot, by connecting-links between its outer edges or by a central spindle. In some of Stephenson's engines with variable expansion geer, the regulator consists of a slide-valve covering a port on the top of the valve-chests. A rod passes from this valve through the smoke-box below the boiler, and by means of a lever parallel to the start- ing lever, is brought up to the engineer's reach. Cocks were at first used as regulators, but were given up, as they were found liable to stick fast. A gridiron slide-valve has been used by Stephenson, which consists of a perforated square plate moving upon a face with an equal number of holes. This plan of a valve with a small movement gives a large area of opening. In Bury's engines a sort of coni- cal plug is used, which is withdrawn by turning the handle in front of the fire-box; a spiral groove of very large pitch is made in the valve-spindle, in which fits a pin fixed to the boiler, and by turning the spindle an end motion is given to it which either shuts or opens the steam passage according to the direction in which it is turned. The best regulator would probably be a valve of the equilibrium description, such as is used in the Cornish engines. Safety-valves and fusible plugs.-The safety-valves are placed upon the dome, in Bury's and Stephen- son's engines; but it has been found much better to place them on the cylindrical part of the boiler, be- cause when an engine commences to prime, the water projected from the blast-pipe generally causes an Digitized by Google 512 ENGINES, DETAILS OF. unusual generation of steam, which escapes at the safety-valve, and in its passage of course accumulates and lifts the surface-water and foam at whatever point of the boiler the safety-valves are situated; thus the farther they are placed from the steam-dome the better, as they will then diminish the evil of prim- ing, which, if placed upon the steam-dome, they would only aggravate. Indeed, if the safety-valves are properly situated, an engineman has the great advantage of being able to check or stop the priming of the boiler on the instant, by causing his safety-valves to blow off strongly. It is requisite to place the safety-valves upon a tubular pillar, of such altitude as to prevent the escaping cloud of steam from obscuring the look-out of the engineman. Bury's 14-inch engine contains a pair of safety-valves of 21 inches diameter, exclusive of the mitre and Stephenson's 15-inch engine contains a pair of 4-inch diam- eter. The latter dimension is preferable, as large safety-valves are much less liable to adhere to their seats than small ones. Safety-valves require to be tested occasionally; and the best method consists in attaching the valve joint-pin to one end of an ordinary pair of scales, when the overbalancing weight at the reverse end will indicate the real pressure upon the valve, which exceeds the nominal pressure by the weight and friction of the lever, with its joints and spring balance, and the adhesion of the valve to its seat. To bring this adhesion to a minimum, it is a good plan to make the lip of the valve-seat somewhat flatter than a mitre, that is, at a less angle than 45° with the horizon: 30° answers very well. The safety-valve is pressed down by means of a lever, and a screw at its extremity is attached to a spiral spring balance. To find the pressure per square inch, multiply the weight indicated on the scale, by the ratio of the two arms of the lever, and divide the product by the number of square inches in the area of the valve; but to save the trouble of calculation, the 1444. ratio of the arms of the lever is made so as to be expressed by the number which represents the area of the valve, 80 that the weight marked on the balance is the pressure per square inch upon the valve. Some allowance must be made for the weight of the valve itself, and part of that of the lever. It is expedient to put a stop upon the screw by which the lever is screwed down or the tension of the spring increased, so as to prevent the pressure from exceeding a safe amount. Lock-up valves, which were intended as a precaution against the recklessness or neglect of the en- gineer, have fallen into disfavor, as from such valves being inaccessible and seldom being required to act, they became fixed in their seats; but it is an easy thing to make a valve which can be raised, but cannot be forced down by the en- gineer, and such valves are in general use in steam vessels. In the engines of Cave, Hick, and Jackson, one of the valves is permanently loaded a little above the usual pressure, and enclosed in a chest it is usually made with bent, flat, steel springs, pressing against one another, and guided by stand- ards screwed to the valve-seat. One of these valves is shown by Fig. 1444. A plug of lead is usually fixed in the furnace crown, which melts if the boiler becomes short of wa- ter, and gives notice of the danger. In some engines a cock is attached to the top of the steam-dome, against which a small disk of fusible metal is retained by a ring of brass bolted to the cock, and which is intended as an antidote to explosions. When the cock is opened, the steam has access to the under side of the fusible plate, which when melted is forced through the small hole in the retaining plate; and the engineer being thus warned of the undue pressure, can shut the cock and take measures to reduce the pressure. This, however, is altogether a futile expedient, for the steam would be too much cooled in passing through this cock and small pipe to melt the metal: and even if that defect were remedied, the objections still remain, as applying to all fusible plugs, and the danger is increased by leading the engineer to trust to a measure of safety that is inoperative in the hour of danger. Steam gages have not been applied hitherto to locomotives, on account of the inconvenient height of the column of mer- cury requisite to balance the steam. But it would be an easy thing to make a steam gage of moderate dimensions, by making the tube, whether straight or siphon, of glass, closed at the top, so that the mercury in its ascent would have to compress the air above it; and the graduations would be equal, or nearly so, if the tube were made taper. Cylinders and valves.-The cylinders are made of cast-iron, about three-quarters of an inch thick, and should be of hard metal, 80 as to have but little tendency to wear oval from the weight and friction of the piston. The ends of the cylinder are made about one inch thick, and both ends are very generally made removable. At each end of the cylinder there is generally about half an inch of clearance. The valve is invariably of the three-ported description it is made of brass, and is not pressed upon by the valve-casing, as it is necessary in the absence of cylinder escape-valves that the steam-valve should be capable of leaving the face to enable the steam or air shut within the cylinder to escape when the train is carried on by its momentum, and also to afford an escape for the water carried over by the steam when priming takes place. The operation of priming upon the cylinders and valves is very in- jurious, as the grit and sediment then carried over with the steam wears the pistons, cylinders, and valve faces very rapidly; so that if the water be sandy and the engine addicted to priming, the pistons and valves may be worn out and the cylinders require re-boring in the course of a few months. The valve-casing is sometimes cast on the cylinder: the face of the cylinder on which the valve works is raised a little, so that any foreign matters deposited upon it may be pushed off to the less elevated parts by the valve. The area of the steam-ports is in some cases one-ninth, and in others one-twelfth Digitized by Google ENGINES, DETAILS OF. 513 or one-thirteenth of the area of the cylinder; and the eduction one-sixth to one-eighth of the area of the oylinder,-proportions which allow at mean speeds of twenty-five to thirty miles per hour, a pressure little different from that of the steam in the steam pipes: for higher speeds the ports should be larger in proportion. The valve casing is covered with a door, which can be removed to inspect the valves or the cylinder face. Some valve casings have covers upon their front end as well as their top, which ad- mits of the valve and valve bridle being more readily removed. A cock is placed at each end of the cylinder to allow the water to be discharged which accumulates there from priming and condensation. The four cocks of the two cylinders are connected, so that by working a handle the whole are opened or shut at the same time. In Stephenson's engines with varia- ble expansion, there is but one cock, which is on the bottom of the valve chest. The valve lever is usually longer than the eccentric lever, to increase the travel of the valve. The pins of the eccentric lever wear quickly. Stephenson puts a ferule of brass on these pins, which being loose and acting as a roller, facilitates the throwing in and out of geer, and when worn can easily be replaced; so that there need be no material derangement of the motion of the valve from play in this situation. The starting lever travels between two iron segments, and can be fixed at the dead point or for the forward or backward motions. This is done by a small catch or bell crank jointed to the bottom of the handle at the end of the lever, and coming up by the side of the handle, but pressed out from it by a spring. The smaller arm of this bell crank is jointed to a bolt which shoots into notches made in one of the segments between which the lever moves. By pressing the bell crank against the handle of the lever, the bolt is withdrawn, and the lever may be shifted to any other point; when the spring be- ing released, the bolt flies into the nearest notch. The pistons which consist of a single ring and tongue piece, or of two single rings set one above the other so as to break joint, are preferable to those which consist of many pieces. In Stephenson's pistons the screws are liable to work slack and the springs to break. The piston-rods are made of steel, the diameter being from one-seventh to one-eighth of the diameter of the cylinder. They are tapered into the piston, and secured there with a cutter. The top of the piston-rod is secured by a cutter into a socket with jaws, through the holes of which a cross-head passes, which is embraced between the jaws by the small end of the connecting rod, while the ends of the cross-head move in guides. Between the piston-rod clutch and the guide blocks, the feed-pump rod joins the cross-head in some engines. The guides are formed of steel plates attached to the framing, between which work the guide blocks, fixed on the ends of the cross-head, and which have flanges bearing against the inner edges of the guides. Steel or brass guides are better than iron ones. Stephenson and Hawthorn attach their guides at one end to a cross-stay,-at the other to lugs upon the cylinder cover; and they are made stronger in the middle than at the ends. Stout guide-rods of steel encircled by stuffing-boxes on the ends of the cross- head would probably be found superior to any other arrangement. The stuffing-boxes might contain conical bushes cut spirally, in addition to the packing; and a ring cut spirally might be sprung upon the rod and fixed in advance of the stuffing-box with lateral play, to wipe the rod before entering the stuffing-box, and prevent it from being scratched by the adhesion of dust. Feed apparatus-The feed-pumps are made of brass, but the plungers are sometimes made of iron, and are generally attached to the piston-rod cross-head, though in Stephenson's engines they are worked by rods attached to eyes on the eccentric hoops. There is a ball valve be- tween the pump and the tender, and two usually in the pipe leading from the 1445. pump to the boiler, besides a cock close to the boiler, by which the pump may be shut off from the boiler in the case of accident to the valves. The ball valves are guided by four branches which rise vertically and join at top in a hemispher- ical form, as shown in Fig. 1445. The shocks of the ball against this have in some cases broken it after a week's work, from the top of the cage having been made flat, and the branches not having had their junction at top properly filleted. These valve guards are attached in different ways to the pipes; when one occurs at the junction of two pieces of pipe it has a flange, which, along with the flanges of the pipes and that of the valve seat, are held together by a union joint. It is sometimes formed with a thread at the under end, and screwed into the pipe. The balls are cast hollow, to lessen the shock as well as to save metal: in some cases, where the feed-pump plunger has been attached to the crose-head, the piston-rod has been bent by the strain; and that must in all cases occur if the communication between the pump and boiler be closed when the engine is started, and there be no escape valve for the water. Spindle valves have in some cases been used instead of ball valves, but they are more subject to derangement. Slide valves might easily be applied, and would probably be found preferable to either of the other expedients. The pipes connecting the ten- der with the pumps should allow access to the valves and free motion to the engine and tender. The feed-pipe of many engines enters the boiler near the bottom, and about the middle of its length. In Stephenson's the water is let in at the smoke-box end of the boiler, a little below the water level. By this means the heat is more effectually extracted from the escaping smoke but the arrangement is of questionable applicability to engines of which the steam-dome and steam-pipe are at the smoke-box end, as in that case the entering cold water would condense the steam. To ascertain the height of water in the boiler, gage-cocks and glass tubes are provided, as in the case of marine boilers. One of these glass gages is represented in Fig. 1446. The upward turn of pipe pro- ceeding from the top of the tube in the interior of the boiler, is calculated to prevent the water from boiling down through the tube, as it sometimes will do if the boiler be too full. The downward turn of the tube at the lower end does not appear calculated to be of service. A small screw plug is placed on each socket opposite the cock to enable a wire to be introduced, to clear the cock, should it become choked. There are generally three gage-cocks attached to the boiler,-besides the glass tube,-the 65 Digitized by Google 514 ENGINES, DETAILS OF. lowest of which should always run water, and the highest should always blow steam. If the water 08. cillates inconveniently in the glass tube, the evil may be checked by partially closing the cocks. Wheels.-The driving wheels are made large to increase the speed; the bearing wheels also are easier on the road when large. In freight 1446. engines the driving wheels are smaller than in passenger engines, and are generally coupled together. Wheels are made in various ways; they are frequently made with cast-iron naves, and with the spokes and rim of wrought-iron. The spokes are forged out of flat bars with T formed heads; these are arranged radially in the founder's mould, whilst the cast-iron centre is poured around them; the ends of the T heads are then welded together to constitute the periphery of the wheel or inner tire, and little wedge-form pieces are inserted where there is any deficiency of iron. In some cases the arms are hollow though of wrought-iron, the tire of wrought-iron, and the nave of cast- iron; and the spokes are turned where they are fitted into the nave, and are secured in their sockets by means of cutters. Hawthorn makes his wheels with cast-iron naves, and wrought-iron rims and arms, but instead of welding the arms together, he makes palms on their outer end, which are attached by rivets to the rim. These rivets, however, unless very carefully formed, are apt to work loose; and we think it would be an improvement if the palms were to be slightly indented into the rim, in cases in which the palms do not meet one another at the ends. When the rim is turned, it is ready for the tire, which is now often made of steel. The materials for wheel tires are first swaged separately, and then welded together under the heavy hammer at the steel works, after which they are bent to the circle, welded, and turned to certain gages. The tire is now heated to red- ness in a circular furnace; during the time it is getting hot, the iron wheel, previously turned to the right diameter, is bolted down upon a face-plate or surface; the tire expands with the heat, and when at a cherry-red, it is dropped over the wheel, for which it was previously too small, and it is also hastily bolted down to the surface plate; the whole load is quickly immersed by a swing crane into a tank of water about five feet deep, and hauled up and down until nearly cold; the tires are not afterwards tempered. It is not indispensable that the whole tire should be of steel, but a dovetail groove turned out of the tire at the place where it bears most on the rail, and fitted with a band of steel, which may be put in in pieces, is sometimes adopted, though at the risk of being thrown off in working. The steel, after being introduced, is well hammered, which expands it sideways, until it fills the dovetail groove, but it has sometimes come out. The tire is attached to the rim by rivets with countersunk heads, and the wheel is then fixed on its axle. The tire is turned somewhat conical, to facilitate the passage of the engine round curves-the diameter of the outer wheel being virtually-increased by the centrifugal force, and that of the inner wheel corre- spondingly diminished, whereby the curve is passed without the resistance which would otherwise arise from the inequality of the spaces passed over by wheels of the same diameter fixed upon the same axle The rails, moreover, are not set quite upright, but are slightly inclined inwards, in consequence of which the wheels must either be conical or slightly dished, to bear fairly upon them. One benefit of inclining the rails in this way and coning the tires is, that the flange of the wheel is less liable to bear against the side of the rail, and with the same view the flanges of all the wheels are made with large fillets in the corners. Wheels have been tried loose upon the axle, but they have less stability, and are not now much used. In all locomotives, there is a very material loss of power from the contraction of blast-pipe necessary to maintain the blast; at high speeds one half of the power of the engine is lost by the inadequate area of the steam passages, of which the greatest loss is that arising from the contraction of the blast-pipe. Tenders are now made larger to obviate the necessity of so many fuel and water stations. Tenders can be put on any number of wheels, so that inconvenience is not likely to arise from their size and weight. Cranked axle.-The cranked axle is made of wrought-iron, with two cranks forged upon it, towards the middle of its length, at a distance from each other answerable to the distance between the cylinders; bosses are made on the axle for the wheels to be keyed upon, and there are bearings for the support of the framing. The axle is usually forged in two pieces, which are then welded together. Sometimes the pieces for the cranks are put on separately, but those 80 made are liable to give way. In engines with outside cylinders the axles are straight, the crank-pins being inserted in the naves of the wheels. The bearings to which the connecting-rods are attached are made with very large fillets in the corners, so as to strengthen the axle in that part, and to obviate side play in the connecting-rod. In engines which have been in use for some time, however, there is generally a good deal of end play in the bear- ings of the axles themselves, and this slackness contributes to make the oscillation of the engine more violent. Connectiny-rods.-It is very desirable that the length of the connecting-rod should remain invariable, in spite of the wear of the brasses, for there is a danger of the piston striking against the cover of the cylinder, if it be shortened, as the clearance is left as small as possible, in order to economize steam. In Digitized by Google ENGINES, DETAILS OF. 515 some engines the strap encircling the crank-pin is fixed immovably to the connecting-rod by dovetailed keys, as shown in Fig. 1448, and a bolt passes through the keys, rod, and strap, to prevent the dovetail keys from working out. The brass is tightened by a gib and cutter, which is kept from working loose by three pinching screws, and a cross-pin or cutter through the 1448. 1447. point. The effect of this arrangement is to lengthen the rod, but at the cross-head end of the rod the elongation is neutralized, by making the strap loose, 80 that in tightening the brass the rod is shortened by an amount equal to its elongation at the crank-pin end. The tightening here is also effected by a gib and cutter, which is kept from working loose by two pinching screws press- ing on the side of the cutter. Both journals of the connecting-rod g are furnished with oil-cups, having a small tube in the centre, with siphon wicks. The connecting-rod, represented in Figs. 1448, 1447, is a thick flat bar, with its edges rounded. Stephen- son's connecting-rod is made at the crank end; a strap of round iron passes over both brasses, and is attached to the T end of the connecting-rod by means of nuts upon the ends of the bent iron, which is made thickest in the middle, to resist the strain. This plan has the defect of shortening the connecting-rod when the brasses are screwed up, and the brasses require to be very strong and heavy. Hawthorn's connecting-rod has a strap at each end, tightened by a gib and cutter; but, to obviate the tendency to shorten the rod, the piston-rod end is furnished with a cutter for tightening the brass outwards. The point of the cutter is screwed, and goes through a lug attached to the gib, and is tightened by a nut. It would be preferable to attach the lug to the cutter and the screw to the gib, as the projection of the screw, when the cut- ter is far in, would not then be so great. In the engines on the Rouen Railway the piston-rod end of the connecting-rod has nei- ther strap nor brass, but simply embraces the cross-head, while the crank end is hollowed out to admit brasses, which are tight- ened by a gib and cutter. The length of the connecting-rod va- ries from four times the length of the crank to seven times. The long connecting-rod has the advantage of diminishing the friction upon the slides. Eccentrics and eccentric-rod.-The eccentrics are made of cast-iron; and when set on the axle between the cranks, they are put on in two pieces held together by bolts, as shown in Figs. 1449, 1450: but in straight-axle engines they are cast in a piece, and are secured on the shaft by means of a key. The eccentric, when in two pieces, is retained at its proper angle on the shaft by a pinching screw, which is provided with a jam-nut to prevent it from working loose. A piece is left out of the eccentric in cast- ing it, to allow of the screw being inserted, and the void is afterwards filled by inserting a dovetailed piece of metal. Stephenson and Hawthorn leave holes in their eccentrics on each side of the central arm, and they apply pinching screws in each of these holes. The screws sometimes slacken and allow the eccentric to shift, unless they are provided with jam-nuts. In the Rouen engines with straight axles, the four eccentrics are cast in one piece. Eccentric straps are best made of wrought-iron, as inconveni- 1450. 1449. ence arises from the frequent breakage of brass ones. When made of malleable iron, one-half of the strap is forged with the rod, the other half being secured to it by bolts, nuts, and jain- nuts. Pieces of brass are in some cases pinned within the mal- leable iron hoop, but it appears to be preferable to put brasses within the strap to encircle the eccentric, as in the case of any other bearing. When brass straps are used, the lugs have gen- erally nuts on both sides, so that the length of the eccentric-rod may be adjusted; but it is better for the lugs of the hoops to abut against the necks of the screws, and if any adjustment is neces- sary from the wear of the straps, washers can be interposed. In some engines the adjustment is effected by screwing the valve- rod, and the cross-head through which it passes has a nut on either side of it by which its position upon the valve-rod is determined. The forks of the eccentric-rod are steel. The length of the eccentric-rod is the distance between the centre of the crank axle and the centre of the valve-shaft. Valve motions.-In locomotives the eccentrics are now always fixed upon the axle, and two are used, one for the forward, the other for the backward motion: the loose pulleys have been given up on ac- count of their liability to get out of order from the shocks to which they were subjected by sudden change of direction when worked at a quick speed. The arrangement whereby the motion of the ec- centric is transmitted to the valve, is either direct or indirect. In cases of indirect attachment the motion is given through the intervention of levers, and there is some variety in the arrangements by which the reversing is accomplished. Alcard and Buddicome use a pair of eccentrics at the end of the axle, which is straight; the reversing shaft is placed below the level of the piston-rod, and to a lever keyed upon it are attached links of unequal length, connected at their upper extremities with the ends of the eccentric-rods, one of which is above and one below the studs on the lever of the valve-shaft, 80 that the upper eccentric-rod, being in geer, gives the forward motion, and the lower gives the backward motion. In other engines, forks are situated above and below the stud of the eccentric levers; the for- ward eccentric-rod is lifted up out of geer by a link depending from the lever on the reversing shaft, Digitized by Google 516 ENGINES, DETAILS OF. and by the same movement the backing eccentric is lifted into geer by a longer link connecting it to a lever, not upon the reversing shaft, but upon a shaft below it. Stephenson and Hawthorn have both used a similar arrangement, but admitting of the eccentric-rods being both under the studs of the lever on the valve-shaft, so that there is no danger, in the event of a disengaged rod falling down, or of any part of the geering being bent or twisted by both rods being in geer at the same time. The motion of the eccentrics is now frequently transmitted directly to the valves. In Pauwel's arrangement of valve geering, the valve works on the side of the cylinder, and the valve-rod is prolonged in the form of a deep flat blade of a lozenge section, on each side of which a stud is fixed,-one being intended for the notch of the forward eccentric-rod, and the other for that of the reversing eccentric. Above them is fixed the reversing shaft, from a lever on which depend two links of unequal length, which are jointed to the ends of the eccentric-roda. By working this lever up or down, the eccentric-rods will be alter- nately engaged and disengaged, and will communicate their respective motions to the valve; or if the lever be kept in its mid position, both eccentrics will be out of geer, and the valve of course will remain stationary. Pauwel's engines are difficult to work, and are subject to shocks from going suddenly into geer: this arises from the whole weight of levers and rods being on the front of the reversing shaft, but the evil might be remedied by attaching a counterbalance to the shaft. Valves situated upon the sides of the cylinders are in many cases more easily connected with the eccentric, but they require springs to keep them up to the face, so that it appears preferable to make the faces of the two cylinders inclined to one another rather than upright, if valves on the sides of the cylinders are preferred. Stephenson's link motion is the most elegant, and one of the most eligible modes of connecting the valve with the eccentric yet introduced. The nature of this arrangement will be made plain by a reference to Fig. 1451, where c is the valve-rod which is attached by a pin to an open curved link connected at the one 1451. end with the driving eccentric-rod d, and at the other with the backing eccentric-rod d'. The link with the eccentric rods is capable of being moved up or down by the rod f and bell crank f", situated on the shaft g, while the valve-rod remains in the same horizontal plane. It is very clear that each end of the link must acquire the motion of the eccentric-rod in connection with it, whatever course the central part of the link may pursue, and the valve-rod will partake most of the motion of the eccentric-rod that is nearest to it. When the link is lowered down, the valve-rod will acquire the motion of the upper eccentric-rod, which is that proper for going ahead; when raised up, the valve-rod will acquire the motion of the reversing eccentric, while in the central position the valve-rod will have no motion, or almost none. The link motion therefore obviates the necessity of throwing the eccentric-rod out of geer; it also enables the engine to be worked to a certain extent expansively, though as a contrivance for working expansively, we cannot hold it as deserving of much commendation. The dead point of the link motion is where the line of the valve-rod bisects the angle formed by the eccentric rods. The maximum forward motion is when the rods are as figured, and the maximum backward motion when the rods d and d' are in the position h" and h'. The best forms of the link motions have side studs, to which the ecrentric-rods are connected, and these are placed so that at the greatest throw, whether 1452. backward or forward, the valve-rod and eccentric-rod are in the same straight line, and the valve re- ceives the full throw of the occentric. A counter-weight is also attached to the shaft to balance the weight of the link and rods. The second eccentric and eccentric-rod of the link motion might, it appears to us, be beneficially dispensed with by placing the shaft g in the plane of the valve-rod, and attaching a pin to the centre of the link, which would work in the eye of the horizontal arm of the lever f. This lever would in such case require to be made much stronger than at present, as it would have to with- stand the thrust of the eccentric, and the link would then virtually be a double-ended lever with a movable centre. Where more convenient, the pin in the centre of the link might be moved in vertical or curved guides, instead of being attached to the lever f. The act of raising the link, and with it the Digitized by Google ENGINES, DETAILS OF. 517 eccentric-rod, would in effect alter the position of the eccentric on the shaft, and if the eccentric-rod were properly proportioned in length, would make the lead right on the reversing side. The movement for working the valves is in some cases derived from the connecting-rod, as iL the arrangement known as Melling's motion, represented in Fig. 1452, where the valve-rod is attached by suitable connections to a pin in the connecting-rod. A somewhat similar mode of working the valve has been employed by Hawthorn, of Newcastle, which admits of expansive action, and which is represented in Fig. 1452a. The pin in the connecting-rod works in a link, to which arms are attached at right angles. The extremity of the lower of these arms is connected by a link and lever to a shaft, which is worked by the reversing handle, while the upper arm is attached to a lever upon the valve-shaft. Upon this shaft there is a double-ended lever, with either end of which a rod, in communication with the valve, geers, according as a forward or reverse motion is wanted. This valve-link is connected by a link with the starting-shaft. The central slot in he link permits the free end movement of the pin on the connecting-rod, while the lateral movement is communicated to the link, and made available for working the valve ievers. To reverse the engine, the inclination of the link must be altered, and the fork in geer must be changed to the other end of the lever, which is done by the same handle: the lead is regulated by the degree of inclination of the par- allelogram, which might be changed by lengthening the lever on the reversing-shaft connected with the lower arm of the link, or by shifting it round on the shaft 80 as to throw the lower arm towards the cylinder. There is much complication in this arrangement; the parts, too, require to be large, and the plan has not been received with much favor, although good results have been obtained. 1452a. If PT Variable expansive action has recently been extensively introduced in locomotives, and the whole of the various expedients for its accomplishment operate either by altering the travel of the valve, or by the introduction of superposed valves. The first mode is that adopted by Stephenson and Cabrey, and the second is principally used by Mayer and Gonzenbach. In the first the effect is to uncover the steam ports less, and re-shut them sooner; to hurry the eduction, and to compress the steam shut within the cylinder: from the early closing of the eduction, the advantages due to expansion are partly sacrificed, for the steam escapes before it has done all its work, and power is lost in the compression of vapor. The second class of expansion contrivances is not chargeable with these defects. It admits of the steam being cut off at any part of the stroke, without any derangement of the valve motion, but there is greater complication in the apparatus. In the class with variable throw, the cutting off is the result of a vir- tual contraction of the ports, which wire-draws the steam, increasing the speed of the entering steam, and making the pressure in the cylinder less than in the passages. In Cabrey's expansion geer, the fault is, that for certain degrees of travel, and when there is much cover on the valve, it may happen that instead of opening the port before the end of the stroke, the valve may not have uncovered the steam port when the piston is about to begin the return stroke. This evil results from the invariable position of the eccentrics on the shaft, and the immobility of the centre of the valve lever. Stephenson gets rid of the defects of Cabrey's system in regard to changing the lead of the eccentric, by rendering movable the centre of oscillation of the valve lever, as the link may be considered, whereby he vir- tually turns round the eccentric on the axle. Mayer's geer has given very good results, and is free from the defects of Cabrey's and Stephenson's. Whatever be the degree of expansion, it presents the same area of steam port; the eduction is not unduly hurried, the linear lead is unvarying, and the compres- sion of the steam before the piston is but small, and is not liable to increase. The wheel and chain geering, however, used in working it, are very troublesome, and liable to get out of order, and the valves have a great deal of friction. Gonzenbach's has less friction than Mayer's, and gives equally good results. How to set the valves of locomotives.-When the cylinder is horizontal the crank is horizontal at the ends of the stroke; but it is not vertical when the piston is at the middle of its stroke, owing to the deviation from parallelism introduced from the connecting-rod being compelled to move at one of its extremities in a straight line. When the piston is at the end of the bottom stroke, and is gradually advanced towards the middle of the stroke, the end of the connecting-rod is carried round by the crank in a curve opposed to that which it would naturally describe round the cross-head as centre; but when the piston has approached the end of the top stroke, the curvature of the path in which the end of the connecting-rod is moved by the crank is in the same direction as that of the circle which it would de- scribe round the cross-head, and these curves would coincide if the connecting-rod were equal in length to the crank: it will be easily seen, therefore, that at the top stroke the piston-rod requires but a small movement to enable the end of the connecting-rod to traverse a large portion of the circle of the crank, while at the bottom stroke the piston has to travel farther to allow of an equal are being described by the crank. From these considerations it follows, that the motion of the crank being nearly uniform, there must be considerable inequalities in the speed of the piston; and more than a half circle will be described by the crank during the top half of the stroke, and less than a half circle in the bottom half of the stroke. The length of the connecting-rod is the distance from the cross-head at half stroke to the Digitized by Google 518 ENGINES, DETAILS OF. centre of the shaft; and it is clear, therefore, that at mid-stroke the crank cannot be vertical. The mo- tion of the valve partakes of the same species of irregularity; but as the eccentric-rod is much longer in proportion to the radius of the eccentric than the connecting-rod, that inequality only may be noted which arises from the relation between the circumference of a circle and its diameter. The irregularity arising from the angle of the connecting-rod also affects the valve, but not to an injurious extent in ordi- nary cases. In Fig. 1453 we have shown the direct connection, as used in some of Stephenson's loco- motives, A EBF representing the crank circle, and the inner circle that of the eccentric. Supposing. now, that the total length of the valve face were equal to the distance between the extreme edges of the steam ports, the valve would be without lap and leaving the question of lead out of consideration for the present, that is, supposing that the steam were admitted exactly at the ends of the stroke, the eccentric would be fastened upon the shaft at right angles to the crank; in other words, the small crank which constitutes the eccentric would be at right angles to the large crank, which is attached to the piston-rod. In this way the valve would be in the middle of its stroke when the piston was at either end of its stroke, so as to close both the steam and eduction passages, and to be ready with the slightest possible advance, to open both for the return stroke of the piston. It has been found advantageous, however, to make the valve face longer than the distance between the extreme edges of the steam ports, so that when it is in the middle of its stroke, it projects or overlaps the ports at both ends; and hence it requires to move through a space equal to the overlap before it is in a condition to open the steam port for the return stroke of the piston. To effect this, it is only necessary to move the eccentric for- ward in its path, until, at the end of the stroke of the piston, the valve is on the edge of the steam port, ready, as before, upon the slightest farther advance, to admit the steam to the cylinder. Now, as the valve is thus required to move through a part of its travel or throw equal to the overlap at each end, and as the throw is equal to the diameter of the circle which the eccentric describes, it follows that, to give the requisite advance, that distance must be measured upon the diameter of the circle, and the cor- responding position of the centre of the eccentric is that of which we are in search. E 1453. M A H K B N F On the remote side of the centre of the crank-shaft, and on the line of centres, mark off DC, the amount of overlap at each end of the valve, and draw a line parallel to EF, the vertical centre line of the crank-shaft; the arc of the eccentric circle intercepted between these parallel lines is that through which the eccentric must move, in order to draw the valve through a portion of its stroke equal to the overlap DC; and the point in which the line intersects the circle of the eccentric is, therefore, the posi- tion which the centre of the eccentric should occupy when the piston is at the end of its down-stroke, and on the very point of beginning its up-stroke. In practice, however, the valve is not so set as to open simultaneously with the commencement of the stroke of the piston, but is set so that the steam commences to flow into the cylinder a very little before the beginning of the stroke; and hence, when the piston actually commences its stroke, the valve has already partially opened the port. To make this adjustment, an additional advance must be given to the valve, and of course in the same direction; and the amount of lead, or opening, which the port has at the commencement of the stroke of the piston, must be added to the lap, their sum from C to D being treated the same in every respect as if the whole were lap and so, for the sake of brevity, we may treat it. Let us suppose now that it was required to find the length that the eccentric-rod should be:-Place the crank horizontal, so that it may have the piston at the bottom of its stroke; bring round the eccen- tric to the corresponding position which we find it should occupy, and measure the distance from that point to the centre of the joint by which the eccentric-rod is to be attached to the valve-rod; this will be the length of the eccentric-rod. When the length of the eccentric-rod is known, either the valve or eccentric may be put in its proper place, if one of them be already set: thus, if the valve be set, as in the drawing, and the eccentric-rod connected also with the eccentric, it will bring the latter into its place, where it may be fixed; but if the valve could not be conveniently set, it would then be necessary to take the following method, which requires the knowledge of the amount of lap, and the length of the eccentric-rod. Find, as before, the position of the eccentric, attach the rod, and the valve must come into connection in the proper position. In practice, the most convenient method of finding the position of the eccentric with a given lap is to draw a circle, such as HK, representing the crank-shaft, upon a board or a piece of sheet-iron, and another equal to the circle of the eccentric, and draw two diameters perpendicular to each other mark off from the centre of the crank-shaft, and upon one diameter, the amount of lap CD; through this point draw a line parallel to EF, the other diameter; the points in which this line cuts the circle of the eccentric are the positions of the forward and backward eccentrics. Through these points, and from the centre of the crank-shaft, draw lines CM, CN, which will intersect the circumference of the crank-shaft; upon this circumference measure with a pair of compasses the chord of the arc intercepted between either point of intersection and that of the vertical diameter EF; Digitized by Google ENGINES, DETAILS OF. 519 and the lines of diameters being first drawn upon the shaft itself, then, by transferring with the com- passes the distance found upon the diagram, the proper position of the eccentric at the end of the stroke of the piston is at once determined; and this being marked upon the shaft, the eccentric can at any time be set, by bringing it round to that mark. Before leaving this figure we may remark, that as the valve in Stephenson's locomotives of this kind is on the side of the cylinder, the cylinder face should be towards us in the drawing. As this arrangement, however, would have afforded a less easy explana- tion, we have adopted the present one. It will also be observed that the crank-shaft and cylinder are too close, and are not in a line with each other; but this, while it could not be easily avoided, is at the same time of no importance in considering the respective motions of the piston and valve, crank and eccentric, which are shown in their true relative positions. The crank is upon the centre, and the piston. consequently, at the end of the bottom stroke; the eccentric and valve being put in advance of the piston by the lap, have shut off the steam before the end of the stroke, and have also opened the educ- tion in readiness for the up-stroke; whereas, without lap, the valve would shut off the steam at one end. and open the eduction at the other, simultaneously with the termination of the stroke of the piston. 1454. In Fig. 1454 we have a different kind of valve geering, there being levers, which reverse the direction of the motion; that is, while the eccentric-rod and lever are moving in one direction, the valve-rod and lever, being on the opposite side of the weigh-bar shaft, are moving in the opposite direction. In the former case there were no levers, and therefore no reversal of the motion. Hence, in order to give the valve the same motion as before, in relation to the crank, it is necessary to throw the eccentric to the opposite side of the crank-shaft, so that its motion may be in the reverse direction, to compensate for the reversing action of the levers. For whereas, when upon one side of the shaft they caused the valve to move in the same direction as themselves by means of the eccentric-rods, now that the levers are introduced, the eccentrics must themselves move in an opposite direction, to give the valves the same motion as heretofore. And this can only be done by putting the eccentrics on the opposite side of the crank centre, round which they move, and, of course, in an opposite direction. 1455. Fig. 1455 is intended to illustrate the valve connection of the common locomotive, in which the mo- tion of the eccentric is communicated through levers to the valve, and generally with an increase of throw. In this figure we have the cylinder face, with the valve upon it, at one end of its travel. Measure off the length of the valve throw, from the end of the valve face, in the direction of its travel. The throw of the valve may best be found by adding the lap to the breadth of the steam-port, and dou- bling their sum. If there were no levers intervening between the valve and eccentric, the line thus measured, which is the throw of the valve, would be the diameter also of the circle described by the centre of the eccentric pulley; but the use of levers interferes with this proportion unless the levers be Digitized by Google 520 ENGINES, DETAILS OF. made of equal length. The effect of levers of unequal length, in making a proportional inequality be- tween the throw of the valve and of the eccentric, will be readily seen by reference to a diagram. From the centre A of the diameter, representing the throw of the valve, draw a line perpendicular to the valve face; and from the same point measure off, upon that line, the length of the lever A B, which is to be attached to the valve-rod, and which, for distinction, we shall call the valve lever. From the point B thus found as a centre with the radius B A, describe a portion of a circle intersecting perpendic- ulars drawn from C and D, the extremities of the line which represents the throw of the valve; from those points in the circumference of the circle produce lines through the centre B. On either side of the centre line A E, and at a distance from it equal to the radius of the eccentric, draw a parallel line. From B as a centre, with the distance from the centre B to the points HK,-in which the parallels in- tersect the produced lines of the lever, as radius,-describe an arc of a circle; the radius of this circle is the length which the eccentric lever must be, in order to give the requisite throw to the valve. It will be evident from the inspection of this diagram, that if it be desired to give a smaller throw to the valve than that of the eccentric, it is necessary to make the valve lever shorter than the eccentric lever; and if it were desired to make the valve throw greater than the eccentric throw, it is indispensable that the valve lever should be made proportionally longer than the eccentric lever. If, for example, the throw of the valve is to be made twice the throw of the eccentric, then this can only be accomplished by mak- ing the valve lever twice the length of the eccentric lever. Hence the relations between these quan- tities are expressed by simple proportion; and any three being given, we can readily find the remain- ing one. For the sake of clearness, we shall state the various forms which the proportion will assume. First-Given the throw of the valve, the throw of the eccentric, and the length of the lever attached to the valve-rod, to find the length of the eccentric lever; we have then the proportion:- Rule-As the throw of the valve is to the throw of the eccentric, 80 is the length of the valve lever to the length of the eccentric lever. If we represent the throw of the valve by T, that of the eccentric by t, the valve lever by L, and the eccentric lever by l, we will have the proportion in a condensed algebraic form, thus,-T t: l; or taking the actual dimensions in inches of the engine before us, 45:3::9:6. Secondly.-Given the throw of the valve, the throw of the eccentric, and the length of the eccentric lever, to find the length of the valve lever. Then, Rule.-As the throw of the eccentric is to the throw of the valve, so is the length of the eccentric lever to the length of the valve lever; Or, algebraically, t:T::1: L; or, as before, in actual dimensions, 8:45::6:9. Thirdly.-Given the throw of the valve and the lengths of the levers, to find the throw of the ec- centric. Rule.-As the valve lever is to the eccentric lever, so is the valve throw to the eccentric throw; Or thus, L l T or, 9: 3. Fourthly.-Given the eccentric lever, the valve lever, and the eccentric throw, to find the valve throw. Rule-As the eccentric lever is to the valve lever, so is the eccentric throw to the valve throw; Or, 1: L T; or,6:9::3:45. We formerly explained how the reversing action of the levers rendered it necessary to set the eccentric on that side of the crank-shaft centre nearest to the cylinder; whereas, in the case of the direct valve connection, it was set on the side remote from the cylinder. Having now found the means of ascertain- ing the lengths of the levers to be employed with a given throw of valve and eccentric, the next step necessary is to determine the true position of the eccentric upon the shaft, in reference to the crank. Place the crank-pin in the dead point nearest the cylinder; that is, place the centres of the crank- shaft and crank-pin in a line with the centre line of the piston-rod. Upon this line of centres A G, raise a perpendicular M, through the point F. From F draw a circle, the diameter of which is equal to the throw of the eccentric, and another equal to the cranked axle. If the levers are equal, mark off from F, upon the line of centres and on the cylinder side, the amount of lap, and draw a line parallel to L M, cutting the eccentric circle in the points NO. From F draw lines through N and o to the circumference of the cranked axle. The points N and o are the positions of the centres of the eccentric pulleys for the forward and backward geer, only one of which is necessary for going one way. In practice it is convenient to make marks at PR, as the points N and o are inaccessible. If there were no lap upon the valve, there would be nothing to set off from the centre line LM, and therefore that line would give the positions of the eccentrics. The intersections of the perpendicular A G would give the positions of the eccentrics on the shaft if the connecting-rod were infinitely long; but inasmuch as the shortness of the connecting-rod introduces irregularity, the true position of the crank at the middle of the stroke of the piston must be taken. If the lengths of the levers be unequal, the throws of the eccentric and valve will also be unequal; and if the valve lever be the longer, as in the case we have taken, the eccentric throw is less than the valve throw in the same proportion as the eccentric lever is less than the valve lever; and therefore, since the eccentric throw is thus less than the valve throw, by reason of the levers, it follows that the lap, which we set off from F, and which is part of the valve throw, must also be diminished in the same proportion as the whole throw, in order to set off the proper quantity from F. The simplest way of accomplishing this is, by marking off the lap from the line of centres, Fig. 1455, at the point A, at the same end as we formerly marked off half the valve throw. This distance will be from A to the edge of the port, that being the overlap; then from the edge of the port draw a parallel to A G; and from the point in which this parallel cuts the are of the longer lever, draw a line through the centre B, and Digitized by Google ENGINES, DETAILS OF. 521 produce it till it cuts the arc K H; the perpendicular from this point to the line E A is the reduced amount of lap, which is to be set off from the point F. Another useful problem is the method of finding the length of the eccentric-rod, the positions of the crank-shaft, and the weigh-bar shaft, and the length of the eccentric lever being given. From the centre of the weigh-bar shaft, with the length of the eccentric lever as radius, describe an arc; draw a tangent from this to the centre of the crank-shaft; from the centre of the weigh-bar shaft drop a perpendicular to the tangential line; the distance from the point of intersection to the centre of the crank-shaft is the length of the eccentric-rod, and the perpendicular is the line of the eccentric lever, when the valve lever is perpendicular to the line of the valve-rod: this gives, therefore, the positions in which these levers must be keyed upon the weigh-bar shaft. In Fig. 1455 the mid-line of the eccentric-rod was the same as the line of the piston-rod; but in Fig. 1454 it is thrown down below that of the piston-rod, forming an angle with it, the vertex of which is the centre of the crank-shaft. In this case the centres of the eccentric pulleys must, consequently, be moved downwards as many degrees as the central line. In order to facilitate this adjustment, we may briefly explain, that every circle is supposed to have its circumference divided into 360 equal parts, called degrees; and if two diameters be drawn in it at right angles to each other, they will divide the circum- ference into four equal parts, each of which contains 90 degrees. This, therefore, is the means by which the angle is measured; nor will it matter, although the circle be of any size whatever, for it is still equally divided by the two diameters. Hence, if the number of degrees contained in the angle which the mid-line of the eccentric-rod makes with the line of the piston-rod, be measured upon any circle described from the centre of the crank-shaft, and the angle be laid down upon a board, and if from the vertex of the angle a circle be described equal to the diameter of the crank-shaft, the chord of the are of this circle intercepted between the lines containing the angle, is the distance to be transferred upon the crank-shaft, and through which the eccentric pulley must be moved round, in order to compensate for the obliquity of the eccentric-rod. In the example, Fig. 1454, the mid-line of the eccentric-rod, when in geer, lies at an angle of five degrees with the line of the piston-rod; and in all such cases this line is to be taken when reference is made to the valve motion; and the piston-rod line is to be taken when reference is made to the motion of the piston. In the case of Fig. 1455, these lines were made to coin- cide, for the sake of simplicity. Miscellaneous remarks respecting locomotives.-The tractive force requisite for drawing carriages over well-formed and level common roads is about 1-36 of the load, at low speeds. On railways, the tractive force has generally been rated at about 1-300 of the load, or 73 pounds per ton, at low speeds; but in well-formed railways the tractive force is probably less than this, to keep the train moving slowly. The resistance of railway trains, however, increases rapidly with the speed, on account of the resistance of the atmosphere; and the resistance occasioned by the atmosphere may be taken at 15 pounds per ton, with an ordinary passenger train moving at the rate of 30 miles an hour. The friction of the engine and the resistance of the rails vary simply as the velocity, if the power of the engine remains the same; but the resistance of the atmosphere varies as the square of the velocity, and the power requisite for overcoming that resistance as the cube of the velocity: so that by doubling the speed of a train, by dimin- ishing the load without increasing the power, the friction is doubled, the atmospheric resistance is made four times greater than before, and the power requisite to overcome that resistance eight times greater. This shows the extravagance of high speeds, even if the power were as economically produced at high speeds, which is by no means the case. In moderately light trains upwards of 50 per cent. of the power is expended in overcoming atmospheric resistance, in speeds of about 35 miles per hour; and the loss will be greater if the trains be very light, and present a large frontage. We have already stated that in low-pressure condensing engines the evaporation of one cubic foot of water from the boiler may be taken to represent a horse power. In high pressure engines, working without expansion, the mechanical efficacy of a cubic foot of water raised into steam will be somewhat less, on account of the resistance to the motion of the piston, occasioned by the pressure of the atmos- phere; but in locomotive-engines, where the working pressure is very high, the resistance due to the pressure of the atmosphere becomes relatively nearly as small as the resistance due to the rare vapor within the condenser of a condensing-engine; and it will not, therefore, be a material deviation from the truth if, in locomotive-engines, working without priming, we reckon a cubic foot of water evaporated per hour as equivalent to a horse power. An engine evaporating 200 cubic feet of water per hour, and therefore exerting about 200-horse power, draws about 110 tons at thirty miles an hour; but if there were no loss from the resistance of the atmosphere, or of the blast-pipe, and no increased friction upon the engine from the increased power requisite for high speeds, the tractive force, if taken at 8 pounds per ton, would only require to. be 70:4-horse power for 110 X 8 X 2640, the number of feet travelled per minute at 30 miles an hour, ÷ 33000 = 704-horse power. The friction of the train, however, at 80 miles an hour, including that of an engine of 200-horse power, cannot be taken at much less than 10 pounds per ton; for the friction of an engine increases with the power exerted, which determines the pressure upon its moving parts; and the friction of the carriages is also increased at high speeds, in consequence of the draw-bars being attached below the centre of effort of the frontage exposed to the wind, whereby the carriages are pressed down more firmly on the rails. If the traction be taken at 10 pounds per ton, then the power requisite for propulsion of a train, setting aside the resistance of the atmosphere, will be about 90-horse power, and the remaining 110-horse power is absorbed in overcoming the resistance of the atmosphere and of the blast-pipe. If the speed be increased from 30 to 60 miles an hour, about 200-horse power will be required for overcoming the friction of the train, and 880-horse power will be required to overcome the atmospheric resistance; making 1,080-horse power, which will be necessary to propel a train of 110 tons at 60 miles an hour. The evaporation of a locomotive boiler is greatest when the speed is at its maximum, as the blast-pipe then produces its greatest effect; and the power of the engine varies nearly as the rate of evaporation, provided the blast-pipe be not unduly contracted. At ordinary railway speeds the power of the boiler is seven or eight times greater than it 66 Digitized by Google 522 ENGINES, DETAILS OF. would be without the blast, though, indeed, such a comparison hardly holds, as without the blast the fire of a locomotive boiler would not draw at all. At a speed of 20 miles an hour, a locomotive boiler boils off from 10 pounds to 14 pounds of water per square foot of beating-surface, and the rate of evap- oration varies nearly as the of the speed. The adhesion of the wheels upon the rails is about one-fifth of the weight when the rails are clean, and either perfectly wet or perfectly dry; but when the rails are half wet or greasy, the adhesion is not more than one-tenth or one-twelfth of the weight. The weight of locomotive engines varies from 15 to 20 tens. A powerful locomotive engine and tender, such as is suitable for high speeds, will weigh about 25 tons. The consumption of power by the locomotive itself is very great at high speeds, chiefly in consequence of the resistance occasioned by the blast-pipe to the free escape of the steam. Mr. Ste- phenson considers that, at ordinary railway speeds, a locomotive engine will absorb as much power as 15 loaded carriages, weighing 60 tons; so that in a train of 15 carriages, half the power is consumed by the engine. These determinations, however, are all very indefinite, and experiments are yet wanting to show the power produced and consumed by locomotives under different circumstances. Locomotive engines in England cost from $9,000 to $11,000 each. They run, on an average, about 130 miles a day, at a cost for repairs of about 5 cents per mile; and the cost of locomotive power, including repairs, wages, oil, and tallow, and coke, may be taken at 12 cents per mile, on economically managed railways. This does not include a sinking fund for the renewal of engines which may be worn out, and which may be taken at 10 per cent. on the original cost of the locomotives. On second class railways the expense of locomotives, and workshops, and tools for repairing them, may be set down at $10,000 per mile. Economy of fuel in locomotives is materially promoted by working expansively; but all attempts at economizing fuel in locomotives should begin with an increase in the area of the fire-grate, 80 that the power of the engine may not suffer so large a diminution by the creation of the necessary draft. Every locomotive engine should be furnished with efficient expansion apparatus, of some kind or other as, setting aside the economy of fuel accomplishable by expansion, it is clear that expansion acts beneficially by diminishing the weight of the boiler, which may be made smaller at every increase of the efficiency of the steam. When the draft is strong, a great loss of effect is caused by opening the furnace door, from the refrigeration due to the large volume of air admitted; and it would be a material improvement if the furnace could be fed by some such mechanism as the revolving grate. The use of sediment-collectors in locomotive boilers also appears expedient, as, if judiciously applied, they will effectually prevent the formation of scale upon the tubes, and will also operate as an antidote to priming in many cases. The form of collector best adapted for a locomotive boiler, will depend in a great measure upon the peculiar structure of the boiler; but generally any form will answer which communicates with the water level, and contains water within it in a tranquil state. The V-shaped cuts for establishing the communication between the exterior and interior of the vessel, have been found preferable to holes of any other form; for a subsiding particle, so soon as it falls in a slight degree, gets behind the case of the collecting vessel, and cannot afterwards escape. Details of the engines of steam-frigate Dragon.-Fig. 1456 represents the paddle and intermediate shafts from the centre line of the vessel to the outer bearing. In this figure are introduced a section of one of the cranks and of the cam for working the expansion valve. Fig. 1457 is a sectional view (taken through the centre of the valve face) of the cylinder and piston, with the piston-rod and cross-head. Fig. 1458 shows a plan and sections of the elastic packing-ring at the middle and ends. Fig. 1459 is a sectional view of the steam-pipe, showing the expansion and throttle valves. Fig. 1460 represents a vertical section of the expansion-valve detached. Fig. 1461 is a transverse section of the air-pump and feed-pump with their appendages. In this figure are also introduced external views of the air-pump rod and cross-head, and of the plunger-rod of the feed-pump. Figs. 1462 and 1463 show the air-pump link. Figs. 1464 and 1465 the connecting-rod. Figs. 1466 and 1467 the long parallel-motion beams which work the air-pump. Fig. 1468 the radius-rod for the parallel motion. Literal references.-A, the sole-plate, of cast-iron, 2 inches thick, laid on a solid bed of African oak 16 inches thick, and cast 80 as to form the bottom of the cylinder. It is made of larger dimensions than are absolutely required for the attachment of the fixed parts of the engines, being extended to some distance on each side, in order to cover a larger space and to increase the strength of the keelsons and lower timbers of the ship. The sole-plate does not, however, on that account, occupy additional room, being 80 constructed as to form the flooring on every side, and at the same time to distribute the weight and action of the engines over a more extended surface of the flooring. E, the steam-cylinder, 14 inch thick, cast open at each end, the sole-plate forming the cylinder bottom. Its internal diameter is 88 inches, and the stroke 5 feet 9 inches. Besides being strengthened by the flanges at the top and bottom, it is encircled by three belts, each 3 inches deep, in order to give rigidity to the cylinder when laid horizontal during the process of boring. It is now usual to bore cylinders of large diameter in a vertical position, to avoid all chance of ellipticity arising from this cause. The cylinder is fitted with escape-valves for priming or condensed water both above and below the piston, the valve being loaded to somewhat above the highest tension of the steam in the cylinder. dd, the steam-ports, 3 feet 8 inches long, by 77 inches wide. e, a separate casting for the cylinder face, planed and scraped to a true surface. i, the throttle-valve, of gun-metal, worked by one of the three handles at v' through a series of rods and levers. H, the steam-piston, 81 inches deep at the circumference, and 114 inches at the centre, formed of cast- iron 1} inch thick, stiffened by radiating feathers. Digitized by Google ENGINES, DETAILS OF. 526 j, the external packing-rings, of cast-iron, 21 inches deep, on Goodfellow's patent construction. These rings are turned concentric, and each, being cut across diagonally, to prevent grooving the cylinder, is free to accommodate itself to the interior of the cylinder as it wears by the friction of the piston, but possesses no elasticity in itself. 1459. A 1460. i i M G 1456. 1458. M 1457. I I d " H K R k and 1 represent the thick and thin ends of the inner eccentric V-shaped ring, of cast-iron, which, by its elasticity, presses the two external rings against the cylinder, thus forming a steam-tight joint. The requisite elasticity is given to this ring by forming in it a series of cuts or grooves increasing regularly in depth from k, where the ring is entire, to l, where the grooves are deepest; and also by causing the projections at the back of the rings shown at k to vanish at 1. The ring is 44 inches deep, its thickness Digitized by Google 524 ENGINES, DETAILS OF. being 5g inches at the thickest part, and 1 inch at the thinnest. The grooves (86 in number) are, at the point l, 21 inches deep, and 7-16 inches wide, and they are pitched at 21 inches centre to centre. m, the junk-ring, of cast-iron, 11 inch thick. n, a brass nut for fixing the piston-rod. I, the steam-cylinder cover, cast hollow, with radiating feathers, and with a thin polished plate of cast- iron for the upper part. o, the stuffing-box gland, made 80 as to allow the strap of the connecting-rod to clear it on each side. It is formed of cast-iron, with a brass lining, and packed with hemp. J, the piston-rod. It is fastened into the piston by a cone and screw n, and further secured by a cotter. p, the piston cross-head, of forged iron, secured to the rod by a long cone and cotter. The bearings for the connecting-rod and the first parallel-motion beams are forged in one piece with it. M, the connecting-rod, formed with a fork at the lower extremity, which is attached by straps, gibs, and cotters to the great bearings on each side of the piston cross-head p. N, the crank, of wrought-iron. 1462. 1463. 1461. 0 r q Y V v w, the crank-pin. That portion of it which passes through the crank on the intermediate shaft P is firmly fixed to it by being driven into a slightly tapered eye, and is further secured by a cotter but at the opposite extremity it passes loosely through the crank on the paddle-shaft, to allow for the deviation from the true vertical and horizontal lines of the shafts, occasioned by the unavoidable tendency of the outer bearing of the paddle-shaft to droop and to wear forwards. o, the paddle-shaft, of wrought-iron. x x x, bosses on the paddle-shaft for fixing the paddle-centres. P, the intermediate shaft, which connects the two engines. The diameter at the centre is 181 inches, and the bearings are 17 inches diameter, by 18 inches long. y, the position of the eccentric. In this, as in most other marine engines, the eccentric is not fixed firmly to the shaft, but revolves between the bearings shown at y, to admit of its turning the valves 80 as to give the engine motion either backwards or forwards. By placing the eccentric loose upon the shaft, only with a projecting catch on one side which is carried round by a corresponding projection on the shaft, it is left free, except when this check comes into contact with the other, at either end of the stroke. To effect this it is necessary to open the valves by hand during at least one-half stroke. The eccentric, of cast-iron, revolves within a ring of gun-metal The throw of the eccentric is 20 inches; the diameter of the bearing surface is 3 feet 5/8 inches; the thickness of the gun-metal ring is 11 inch, and the breadth 4 inches. o, the air-pump links. Thickness of strap, 11 inch the columr 21 inches, tapered to 1f inch diameter. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 525 p, the air-pump cross-head. The diameter over the boes is 11} inches; diameter of hollow cone, 5 7-16 inches, tapered to 5f inches; thickness of blade, 3 inchea. q, the air-pump rod, formed of wrought-iron, cased with gun-metal, 1 inch thick when finished, cast round the rod and the cone, to prevent galvanic action. r, the air-pump bucket, of gun-metal, packed with hemp. 38, the bucket-valves, of gun-metal, of the descrip- tion commonly called butterfly-valves. They work on M a curved hinge encircling the pump-rod. tt, discharge valves, also of gun-metal, and of the same construction as the bucket-valves. U, the condenser, of cast-iron, 11 inch thick. It is M cast in one piece for both engines, with a partition through the middle to keep the condenser of each dis- tinct from the other. There is a passage-way through the lower part of the condenser to the valve-jackets, 1464. 1465. in order to gain access to the valve-ports for packing them. V, the air-pump, of solid gun-metal, t inch thick when finished, 48 inches diameter, and 34} inches stroke. W, the feed-pump, with brass plunger, 91 inches external diameter, and 841 inches stroke. Y, the discharge-pipe, of cast-iron, forming the top of the air-pump. From the air-pump to the sluice- valve through the ship's side, it becomes a circular copper pipe, 21} inches bore. M Z, the supplementary engine for feeding the boilers previous to starting the large engines. vvv, a combination of levers and rods for working. so, the injection-valve. M x, the blow-through or snifting-valve, and i, the throttle-valve. The connections for each valve are distinctly shown in the elevation. y, a graduated cam on the intermediate shaft for working the expansion geer. 222, a brass roller, levers, and rods for conveying the motion from the cam to the expansion-valve. The roller is adjusted to each cam by a screw, according to the amount of expansion required. 1468. 1466. L % 1467. L to ENGINES, for further details of, See MARINE, LOCOMOTIVE, STATIONABY, PUMPING, HIGH-PRESSURE, NON-CONDENSING, &c., dc. ENGINES, rules for calculating the parts of. Rules and tables for facilitating the construction of boilers, &c., by determining the lengths of plate or angle-iron requisite for the formation of hoops of different diameters. For plate or flat bar :- Rule.-Add the thickness of the bar to the required diameter, and the corresponding circumference in the table of circumferences of circles is the length of the bar. If the iron be bent edgewise the breadth of the bar must be added to the diameter; for it is the thickness of the bar measured radially that is to be taken into consideration. In such pieces of work as the tires of railway wheels, which have a flange on one edge, it is necessary to add, not only the thickness of the tire, but also two-thirds of the thickness of the flange. Generally, however, the tire bars are sent from the iron works 80 curved that the plain edge of the tire is concave, and the flange edge convex; while the side which is afterwards to be bent into contact with the cylin- Digitized by Google 526 ENGINES, RULES FOR CALCULATING THE PARTS OF. drical surface of the wheel is a plane. By this means the addition to the diameter of two-thirds the thickness of the flange is unnecessary; for the curving of the flange edge has the effect of increasing the real length when only the chord of the arc is measured for the circumference. The radius of the curve in which the tires are first bent may be safely taken as four times the circumference of the hoop or wheel. In the form of rules, these results will be, first: when the tire is straight- Rule.-Add the thickness of the hoop, and two-thirds the thickness of the flange to the diameter, and find the corresponding circumference. And when the tire is curved it will be:- Add the thickness of the hoop to the diameter, and find the circumference. TABLE OF DIMENSIONS OF THE PARTS OF LOCOMOTIVE ENGINES. RAILWAYS. Northern Bordeaux and North Mid- Great Belgium. and East- La Teste. land Cos. Western. Hartlepool. ern Cos. ft. in. ft. in. ft. in. ft. in. ? in. ft. in. Width of railway between rails 4 81 4 81 4 81 5 0 7 0 4 81 Diameter of boller (inside) 3 41 3 If 3 7t 3 7t 3 111 3 51 Length of ditto 8 2 8 9 8 6 8 0 8 6 8 6 Thickness of plates 0 of 0 0.5 0 of 0 of 0 8 of 0 of Length of outside fire-box 3 84 3 41 4 0 4 04 4 6 3 7 Breadth of ditto 4 0 3 91 4 0 4 of 4 8 4 1 Depth below boiler 2 0 1 8 2 2 2 2 2 3 2 of Height above ditto 0 41 not ascertained 2 7 2 7 2 1 0 41 Thickness of plates 0 of 0 of 0 01 0 04 0 of 0 04 Length of inside fire-box 3 of 2 8 3 31 3 34 3 8+ 2 104 Breadth of ditto 3 4f 3 2 3 44 3 41 3 10+ 3 5± Thickness of copper plates 0 of 0 of 0 01 0 of 0 of 0 01 Extra thickness of ditto for insertion of tubes 0 of 0 of 0 of 0 of 0 of 0 01 From bottom of fire-box to top of fire-bare 0 8 0 9 0 9 0 8 From top of fire-bars to crown of fire-box 3 41 3 71 3 5 Area of fire-grate in superficial feet 10 21 11 2 11 3 12 10 9 104 Length of smoke-box (inside) 1 111 1 111 2 1 2 1 2 21 2 1 Breadth of ditto (outside) 3 111 4 1 4 2 4 21 5 21 4 2 Thickness of tube-plate 0 of 0 of 0 01 0 of 0 of 0 01 Thickness of side-plates 0 04 0 of 0 04 0 01 0 of 0 01 Diameter of chimney (inside) 1 04 1 0 1 2 1 2 1 4 1 2 Height of top of ditto from rails 13 0 14 0 13 6 14 10 13 6 Number of brass tubes 86 94 123 121 131 105 - 115 at 2 Exterior of diameter of ditto 0 21 0 % 0 8 at 14 2 - 127 at 2 0 2 & at Thickness of tubes.-Wire gage No. 14 No. 14 No. 14 No. 14 No. 12 No. 14 Distance from centre to centre of tubes 0 3 0 24 0 21 0 24 0 21 0 of Diameter of steam-dome (inside) 1 5 1 7 Height of ditto 2 71 2 74 Diameter of safety-valves 2j&3 34 & 34 4&4 4&4 31&34 4&3 Diameter of inside copper steam-pipe 0 5 0 5 0 61 0 61 0 61 0 61 Thickness of ditto.-Wire gage No. 10 No. 10 No. 10 No. 10 Diameter of branch steam-pipe (inside) 0 3f 0 31 0 4} 0 4f 0 41 0 41 Diameter of top of blast-pipe (inside) 0 21 0 21 0 3 0 3 0 3f 0 3 Diameter of cylinders 1 of 1 0 1 2 1 2 1 3 1 2 Length of stroke 1 6 1 6 1 6 1 6 1 6 1 6 Distance of centres of cylinders 2 5 2 5 2 5 2 5 3 0 2 5 Size of steam-ports 11 x 1 of x 1 11 11 If 11 11 11 11 Size of eduction-ports 11 x 2 91 X 8 11 21 11 st 11 11 Breadth of bridge between ports 0 01 0 04 0 01 0 of 0 of 0 of Lead of slide-valves 0 0,10 0 of 0 0.3 0 03 0 0,3 16 Cover of ditto 0 0,2 0 of 0 of 0 of 0 01 0 0,8 16 Distance from centre of cylinder to centre of steam-chest 0 11 1 of 1 04 1 2 1 04 Thickness of piston 3f 3f 4 4. 4 # Diameter of piston-rod 2 2 2 2 21 2 Diameter of valve-spindle of 1 1 1 If 1 Diameter of pump-ram 1f 2 2 2 2t 2 Length of pump-lever 61 None 64 67 None 6 Diameter of bali-valves 2 2 27 277 2f 2 10 Diameter of union and section pipes (inside) 11 11 11 14 21 11 Diameter of driving-wheels 5 6 6 0 5 0 6 0 7 0 4 6 Tyres of ditto in centre of tread 6 x 11 7x11 7X11 51X2 51x11 Diameter of leading-wheels 3 9 4 0 5 0 4 of 4 0 4 6 Tires of ditto 5f x 11 6x11 6X0 51X2 5+X11 Diameter of trailing-wheels 3 9 4 0 3 6 4 0 4 0 None Tires of ditto 5f x 11 6x11 6x11 54X2 Diameter of plain part of cranked axle 41 5 5f 51 6f 5' Diameter of inside bearings 5 5 52 51 of 5f Length of ditto 3j&3 3 31&3 3j&3 4 3 Radius of ditto 9 3 &2f 21 51 Diameter of crank-pins 5 5 54 51 61 5 Length of ditto 3 3 3 3 4 3 Radius of ditto 21 21 29 2 51 6 Diameter of outside bearings 34 34 34 34 4 31 Length of ditto 51 5f 51 5¥ 64 51 Diameter of bosses on axles for eccentrics 6J&4 5 & 5 7&51 7X51 7}&6f 7X51 Diameter of bosses for driving-wheels 64 64 64 61 71 64 Length of bosses for ditto 7. 7j 8f 77 71 Diameter of axle for leading-wheels 34 4 5 4f 6j&44 41 Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 527' TABLE OF DIMENSIONS OF THE PARTS OF LOCOMOTIVE ENGINES-(Continued.) RAILWAYS. Bordeaux and North Mid- Northern Great Belgium. La Teste. land Cos. and East- Western. Hartlepool. ern Cos. ft. in. ? in. ? in. ft. in. ft. in. ft. in. Dismeter of bearings for leading-wheels 3t 31 34 34 31 31 Length of bearings for ditto 51 5 51 51 61 5f Diameter of boes for wheels 41 5 6f 5) 52 5f Length of boss for ditto 64 7 81 71 8 Diameter of axle for trailing-wheels 34 4 44 41 61X41 Diameter of bearings 3+ 34 34 31 3f Length of bearings 5f 51 5f 51 64 Diameter of boss for wheels 41 5 5 51 54 Length of boes 64 7 8 71 8 Diameter of boes on axle for outside cranks None None 41 None 41 Length of ditto 31 34 Length of outside cranks from centre to centre None None 1 11 None 1 It Diameter of plain pin on ditto 14 14 Length of plain pin 2 None 2 Diameter of ball pin 211 21 Outside frame (extreme breadth) 6 4 6 4 6 5 6 81 8 91 6 31 Length of ditto 18 3 18 21 18 3 18 21 20 4 18 3 Depth of frame sides 7 7 7t 7t 8 7t Thickness of ditto 4 4 4 4 41 4 Thickness of side-plates of of of of 01 01 Thickness of horn-plates of of of of of of Length of driving-wheel springs 2 8 2 9 2 9 2 6 Breadth of ditto 3f 3f 31 31 Number of plates - 2at0f 1 at 1 at of 2at of 12at 04 12 at 14 at 10 at 0-3 Length of leading-wheel springs Ellip.22 2 9 Ellip20 2 3 Breadth of ditto 3 4 3 34 { 281015 1 at of 1 at of 2 at of Number of plates 11at04 at 015 11 &t 0 5 10 at 0.5g Length of trailing-wheel springs Ellip.22 Ellip20 Ellip20 2 3 Breadth of ditto 3 3 3 34 - 2at015 1 at of 1 at 2 at of Number of plates 8at04 6at015 6at5-50 8 at 0,5 Diameter of eccentrics 10f & 12f 10f 1 1 1 1 1 11 124X111 Throw of ditto 11 If 113 113 11 19 Breadth of ditto (brass hoops) 14 11 21 21 Iron 11 14 Diameter of valve-geer shafts 21 21 21 2t 21 21 Diameter of journals to ditto 11 11 11 14 2 11 Length of journal 21 2f If 21 21 21 Length of side-levers 5 5 6 6 6f 6 Length of fork-end levers 6f 5 & 4116 6 6 54 6 Diameter of ferules If If 1f If 11 2 Length of lifting levers 10 1 0 1 0 1 0 1 3 1 0 Length of reversing levers 12 & 10 1 0 12&10 12&10 1 3 1 0 Distance between motion bars 81 77 7 74 1 of Diameter of ball on cross-head spindle 3 3 34 3t 3f 34 Diameter of connecting-rods in middle 21 24 at 21 21 Inside horn-bars 4 x 1 34 x If 3fX14 31X11 4jX1j 31X11 Distance from centre of crank-axle to fire-box 1 6 1 6 1 6 1 6 1 5f 1 3 Distance from centre of crank-axle to centre of leading-axle 5 6 6 % 5 6 5 7 6 7 5 10f Distance from centre of crank-axle to centre of trailing-axle 5 6 5 34 5 9 5 91 6 7 None In the construction of the boilers for these engines, the cylindrical parts of each are fixed to the smoke and fire-boxes, by 21 inch angle-irons round the upper, and 8 inch angle-irons round the lower half of the boiler, firmly riveted with t of an inch rivets. The tops of the outside fire-boxes of the en- gines for the North Midland, Northern and Eastern Counties, and the Great Western Railways, are worked into a dome-shaped figure, by which means the advantage is obtained of placing the regulator, with its appendages, immediately over the inside fire-box. The man-hole, being also placed in this dome, admits of a free access to the interior of the boiler. The outside fire-boxes for the engines of the Belgium railways, having low semicircular tops, the steam domes are fixed on the cylindrical part of the boiler, and the regulators fixed to the tube-plate of the smoke-box. The inside fire-boxes are formed of copper plates of the dimension shown; that por- tion of the tube-plate, necessary for the insertion of the tubes, being increased in thickness in order to increase its stability, as well as to assist in the more perfect securing of the tubes. The opening, in the front plate for the smoke-box doors, is, in all respects, sufficiently large to admit of free working-room, for the removal and reinstatement of the copper tubes of the boiler, as occasion may require. In the inside fire-boxes of the engines for the Great Western Railway, there are low hollow parti- tions, forming a clear water-space of four inches across the box; in the sides of this box, to which the partition is riveted, apertures, eight by four inches, are cut 80 as to allow of the free escape of steam from this division. The cylinders in the whole of the engines here enumerated are fixed in the lower part of the cavity of the smoke-box, and firmly bolted to the front and back plates, these plates being cut to receive the same. The pipes from the eduction ports (excepting in the engines for the Great Digitized by Google 528 ENGINES, RULES FOR CALCULATING THE PARTS OF. Western Railway) are cast on the body of the cylinders, and extending across towards the middle, and uniting with its corresponding pipe, is strongly bolted thereto; on the upper surfaces of these pipes, flanches are cast with a horizontal plane, upon which the blast-pipes are fixed. The blast-pipe of cop- per, of a conical or pyramidal shape, formed with flanches at the bottom, is placed immediately over the junction of the pipes from the eduction ports, and firmly bolted thereto. The pumps are fixed either directly or indirectly to the outer bars of the inside framework, as the shape and position of the parts may require; the rams of the engines for the Great Western Railway are worked immediately from the spindle of the cross-head; those of the North Midland and the Bel- gium engines, by an arm or lever attached to the piston-rod. The whole of the valve-geer, as well as the carriages for the cross-head guide-bars are supported in their position by strong iron framework, technically called horn-bars. These bars extend from: the back plate of the smoke-box to the front plate of the outside fire-box, and are bolted to lugs fixed thereon to receive the ends of the bars. These bars also serve the purpose of staying the crank axle by means of horns, which are worked on the bars, and in which the bearings are fixed. The inner horn-bars of the engines for the North Midland, the Belgium, and the North Eastern Railways, extend in a parallel direction, from the smoke-box to the extreme length of the guide-bars; and from thence obliquely in a Y-shaped form, uniting with each other, and forming, with the two outside horn-bars, a third stay to the crank axle. The construction of the valve-geer of the engine for the Bordeaux and La Teste Railway, differs widely in its details from the rest of the engines here noted. The eccentric bosses are placed close to each other, in the middle of the driving-wheel axle, the end of each eccentric-rod being furnished with a pin on which the ferules are placed, instead of forked ends, as have been hitherto generally adopted. On the shaft which gives motion to the valve lever is fixed a double lever, with forked ends; in the hollow of each fork a socket is formed for the reception of the pin and ferule on the end of the eccentric-rod; and of such depth as to allow the lever to have a throw, variable from 4110 to 5 inches. Each of these fork-ended levers are placed in a vertical position with each other, but acting in opposite directions upon the inner end of the valve-shaft. The eccentric-rod ends are connected with a lever on the reversing shaft, by lifting and lowering links, which not only admit of the eccentrics being thrown in or out of geer, but also allow of a greater or less degree of travel to the side valve, by increasing or diminishing the throw of the fork-ended lever. The peculiar advantage of the plan thus adopted is obvious from the economy in the saving of steam, the travel of the slide being regulated 80 as to admit of no more steam into the cylinder than what is necessary to propel the engine at the velocity required. The link motion has, to a great extent, superseded the fork-ended levers, and it is a greatly preferable arrange- ment. RULES FOR THE CALCULATION OF THE PARTS OF MARINE ENGINES. Rule 1.-To find the breadth of crank at paddle centre.-Multiply the square of the length of the crank in inches by 1.561, and then multiply the square of the diameter of cylinder in inches by -1235 multiply the square root of the sum of these products by the square of the diameter of the cylinder in inches; divide the product by 45; finally, extract the cube root of the quotient. The result is the breadth of the web of crank at paddle centre. EXAMPLE. 48 = length of crank in inches. 48 2304 1.561 = constant multiplier. 3596.5 5058 4102'3 64 = diameter of cylinder. 64 4096 1235 = constant multiplier. 5058 and 4102·3 = 64.05 nearly. 4096 = square of the diameter of the cylinder. 45) 2623485 5829.97 and 5829.97 = 18 nearly. Rule 2.-To find the thickness of large eye of crank.-Multiply the square of the length of the crank in inches by 1.561, and then multiply the square of the diameter of the cylinder in inches by 1235; multiply the sum of these products by the square of the diameter of the cylinder in inches; afterwards, divide the product by 182828; divide this quotient by the length of the crank in inches; finally, extract the cube mot of the ouotient. The result is the proper thickness of the large eye of crank in inches. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 529 EXAMPLE. 48 = length of crank in inches. 48 2304 1.561 = constant multiplier. 85965 5058 41023 64 = diameter of cylinder in inches. 64 4096 1235 = constant multiplier. 5058 4102'3 4096 = square of diameter. 48) 16803020-8 182828) 350062.94 19147 and 2/191.47 = 577 nearly. Rule 3.-To find the thickness of the web of crank at paddle-shaft contre.-Multiply the square of the length of crank in inches by 1.561, and then multiply the square of the diameter in inches by 1235 multiply the square root of the sum of these products by the square of the diameter of the cylinder in inches; divide this quotient by 360; finally, extract the cube root of the quotient. The result is the thickness of the web of crank at paddle-shaft centre in inches. Thus to apply the rule to the particular example which we have selected, we have 48 = length of crank in inches. 48 2304 1561 = constant multiplier. 3596.5 5058 4102'3 64 = diameter of cylinder. 64 4096 -1235 = constant multiplier. 5058 And V4102 8 = 6405 nearly 4096 = square of diameter. 360)2628485 72875 And 472875 = 9 nearly. Rule 4.-To find the diameter of the paddle-shaft journal.-Multiply the square of the diameter of cylinder in inches by the length of the crank in inches; extract the cube root of the product; finally, multiply the result by -242. The final product is the diameter of the paddle-shaft journal in inches. Rule 5.-To find the length of the paddle-shaft journal.-Multiply the square of the diameter of the cylinder in inches by the length of the crank in inches; extract the cube root of the quotient; multiply the result by 303. The product is the length of the paddle-shaft journal in inches. (The length of the paddle-shaft journal is 11 times the diameter.) Rule 6.-To find the diameter of crank-pin journal.-Multiply the diameter of the cylinder in inches by 142. The result is the diameter of crank-pin journal in inches. Rule 7.-To find the length of crank-pin journal.-Multiply the diameter of the cylinder in inches by -16. The product is the length of the crank-pin journal in inches. Rule 8.-7b find the breadth of the eye of cross-head-Multiply the diameter of the cylinder in inches by 041. The product is the breadth of the eye in inches. Rule 9.-To find the depth of the eye of cross-head-Multiply the diameter of the cylinder in inches by 286. The product is the depth of the eye of cross-head in inches. Rule 10.-To find the diameter of the journal of cross-head-Multiply the diameter of the cylinder in inches by 086. The product is the diameter of the journal in inches. Rule 11.-To find the length of the journal of cross-head-Multiply the diameter of the cylinder in inches by 097. The product is the length of the journal in inches. 67 Digitized by Google 530 ENGINES, RULES FOR CALCULATING THE PARTS OF. Rule 12.-To find the thickness of the web of cross-head at middle.-Multiply the diameter of the cylinder in inches by .072. The product is the thickness of the web of cross-head at middle in inches. Rule 13.-To find the breadth of web of cross-head at middle.-Multiply the diameter of the cylinder in inches by 268. The product is the breadth of the web of cross-head at middle in inches. Rule 14.-7o find the thickness of the web of cross-head at journal.-Multiply the diameter of the cylinder in inches by 061. The product is the thickness of the web of cross-head at journal in inches. Rule 15.-7o find the breadth of web of cross-head at journal.-Multiply the diameter of the cylinder in inches by 101. The product is the breadth of the web of cross-head at journal in inches. Rule 16.-7b find the diameter of the piston-rod-Divide the diameter of the cylinder in inches by 10. The quotient is the diameter of the piston-rod in inches. Rule 17.-To find the length of the part of the piston-rod in the piston-Divide the diameter of the cylinder in inches by 5. The quotient is the length of the part of the piston-rod in the piston in inches. Rale 18.-To find the major diameter of the part of piston-rod in cross-head-Multiply the diameter of the cylinder in inches by 095. The product is the major diameter of the part of piston-rod in cross- head in inches. 'Rule 19.-To find the minor diameter of the part of piston-rod in cross-head-Multiply the diameter of the cylinder in inches by 09. The product is the minor diameter of the part of piston-rod in cross- head in inches. Rule 20.-To find the major diameter of the part of piston-rod in piston-Multiply the diameter of the cylinder in inches by 14. The product is the major diameter of the part of the piston-rod in piston in inches. Rule 21.-To find the minor diameter of the part of piston-rod in piston.-Multiply the diameter of the cylinder in inches by 115. The product is the minor diameter of the part of piston-rod in piston. Rule 22.-To find the depth of gibs and cutter through cross-head-Multiply the diameter of the cylinder in inches by 105. The product is the depth of the gibs and cutter through cross-head. Rule 23.-Tb find the thickness of the gibs and cutter through cross-head-Multiply the diameter of the cylinder in inches by 021. The product is the thickness of the gibs and cutter through cross-head. Rule 24.-To find the depth of cutter through piston.-Multiply the diameter of the cylinder in inches by 085. The product is the depth of the cutter through piston in inches. Rule 25.-To find the thickness of cutter through piston.-Multiply the diameter of the cylinder in inches by 035. The product is the thickness of cutter through piston in inches. Rule 26.-To find the diameter of connecting-rod at ends.-Multiply the diameter of the cylinder in inches by 095. The product is the diameter of the connecting-rod at ends in inches, Rule 27.-To find the major diameter of the part of connecting-rod in cross-tail.-Multiply the diam- eter of the cylinder in inches by 098. The product is the major diameter of the part of connecting-rod in cross-tail. Rule 28.-To find the minor diameter of the part of connecting-rod in cross-tail.-Multiply the diam- eter of the cylinder in inches by 09. The product is the minor diameter of the part of connecting-rod in cress-tail in inches. Rule 29.-Tp find the breadth of the butt.-Multiply the diameter of the cylinder in inches by .156 The product is the breadth of the butt in inches. Rule 30.-To find the thickness of the butt.-Divide the diameter of the cylinder in inches by 8. The quotient is the thickness of the butt in inches. Rule 31.-To find the mean thickness of the strap at cutter.Multiply the diameter of the cylinder in inches by 043. The product is the mean thickness of the strap at cutter. Rule 32.-To find the mean thickness of the strap above cutter.-Multiply the diameter of the cylin- der in inches by 032. The product is the mean thickness of the strap above cutter. Rule 33.-To find the distance of cutter from end of strap.-Multiply the diameter of the cylinder in inches by 048. The product is the distance of cutter from end of strap in inches. Rule 34.-Tb find the breadth of the gibs and cutter through cross-tail.-Multiply the diameter of the cylinder in inches by 105. The product is the breadth of the gibe and cutter through cross-tail. Rule 35.-To find the breadth of the gibs and cutter through butt-Multiply the diameter of the cyl- inder in inches by 11. The product is the breadth of the gibs and cutter through butt in inches. Rule 36.-To find the thickness of the gibs and cutter through butt-Multiply the diameter of the cylinder in inches by 029. The product is the thickness of the gibs and cutter through butt in inches. Rule 37.-To find the breadth of the small eye of crank.-Multiply the diameter of the cylinder in inches by 063. .The product is the proper breadth of the small eye of crank in inches. Rade 38.-Tb find the length of the small eye of crank.-Multiply the diameter of the cylinder in inches by 187. The product is the proper length of the small eye of crank.in inches. Rule 39.-To find the thickness of the web of crank at pin centre.-Multiply the diameter of the cyl- inder in inches. by 11. The product is the proper thickness of the web of crank at pin centre in inches. Rule 40.-To find the breadth of the web of crank at pin centra-Multiply the diameter of the cylin- der in inches by 16. The product is the proper breadth of crank at pin centre in inches. Rule 41.-To find the diaméter of cylinder side-rods at ends.-Multiply the diameter of the cylinder in inches by 065. The product is the diameter of the cylinder side-rods at ends in inches. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 531 Rule 42.-To find the breadth of butt in inchea-Multiply the diameter of the cylinder in inches by 077. The product is the breadth of the butt in inches. Rule 43.-7b find the thickness of the butt-Multiply the diameter of the cylinder in inches by .061. The product is the thickness of the butt in inches. Rule 44.-To find the mean thickness of strap at cutter. Multiply the diameter of the cylinder in inches by 032. The product is the mean thickness of the strap at cutter. Rule 45.-To find the mean thickness of strap below cutter.-Multiply the diameter of the cylinder in inches by 023. The product is the mean thickness of strap below cutter in inches. Rule 46.-To find the depth of gibs and cutter.-Multiply the diameter of the cylinder in inches by 08. The product is the depth of gibe and cutter in inches. Rule 47.-7b find the thickness of gibs and cutter. Multiply the diameter of the cylinder in inches by 016. The product is the thickness of the gibe and cutter in inches. Rule 48.-To find the diameter of the main centre journal.-Multiply the diameter of the cylinder in inches by 188. The product is the diameter of the main centre journal in inches. Rule 49.-To find the length of the main centre journal.-Multiply the diameter of the cylinder in inches by 275. The product is the diameter of the cylinder in inches. Rule 50.-To find the depth of eye round end studs of lever.-Multiply the diameter of the cylinder in inches by 074. The product is the depth of the eye round end studs of lever in inches. Rule 51.-7b find the thickness of eye round end studs of lever-Multiply the diameter of the cylin- der in inches by 052. The product is the thickness of eye round end studs of lever in inches. Rule 52-To find the diamster of the end studs of laver.-Multiply the diameter of the cylinder in inches by 07. The product is the diameter of the end studs of lever in inches. Rule 58.-To find the length of the end studs of lever.-Multiply the diameter of the cylinder in inches by 076. The product is the length of the end stude of lever in inches. Rule 54.-To find the diameter of the air-pump studs.-Multiply the diameter of the cylinder in inches by 045. The product is the diameter of the air-pump studs in inches. Rule 55.-To find the length of the air-pump studs.-Multiply the diameter of the cylinder in inches by 049. The product is the length of the air-pump studs in inches. Rule 56.-To find the depth across the centre of the side lever.-Multiply the length of the side lever in feet by 7423; extract the cube root of the product, and reserve the result for a multiplier. Then square the diameter of the cylinder in inches; extract the cube root of the result. The product of the final result and the reserved multiplier is the depth of the side lever in inches across the centre. Rule 57.-To find the diameter of the air-pump.-Multiply the diameter of the cylinder in inches by 6. The product is the diameter of the air-pump in inches. Rule 58.-7b find the thickness of the eye of air-pump cross-head-Multiply the diameter of the cyl- inder in inches by 025. The product is the thickness of the eye of air-pump cross-head in inches. Rule 59.-7b find the depth of eye of air-pump cross-head-Multiply the diameter of the cylinder in inches by 171. The product is the depth of the eye of air-pump cross-head in inches. Rule 60.-To find the diameter of the journals of air-pump cross-head-Multiply the diameter of the cylinder in inches by 051. The product is the diameter of the end journals. Rule 61.-To find the length of the end journals for air-pump cross-head-Multiply the diameter of the cylinder in inches by 058. The product is the length of the air-pump cross-head journals in inches. Rule 62.-To find the thickness of the web of air-pump cross-head at middle.-Multiply the diameter of the cylinder in inches by 048. The product is the thickness at middle of the web of air-pump cross- head in inches. Rule 63.-To find the depth at middle of the web of air-pump cross-head-Multiply the diameter of the cylinder in inches by 161. The product is the depth at middle of air-pump cross-head in inches. Rule 64.-7b find the thickness of the web of air-pump cross-head at journala.-Multiply the diame- ter of the cylinder in inches by 087. The product is the thickness of the web of air-pump cross-head at journals in inches. Rule 65.-To find the depth of the air-pump cross-head web at journals.-Multiply the diameter of the cylinder in inches by 061. The product is the depth at journals of the web of air-pump cross-head. Rule 66.-To find the diameter of the air-pump piston-rod when of copper.-Multiply the diameter of the cylinder in inches by 067. The product is the diameter of the air-pump piston-rod, when of cop- per, in inchea. Rule 67.-7b find the depth of gibs and cutter through air-pump cross-head-Multiply the diameter of the cylinder in inches by 063. The product is the depth of the gibe and cutter through air-pump cross-head in inches. Rule 68.-7b find the thickness of the gibs and cutter through air-pump crose-head-Multiply the diameter of the cylinder in inches by 013. The product is the thickness of the gibs and cutter in inches. Rule 69.-7o find the depth of cutter through piston.-Multiply the diameter of the cylinder in inches by 051. The product is the depth of the cutter through piston in inches. Rule 70.-To find the thickness of cutter through air-pump piston-Multiply the diameter of the cylinder in inches by 021. The product is the thickness of the cutter through air-pump piston. Rule 71.-To find the diameter of air-pump side-rod at ends-Multiply the diameter of the cylinder in inches by 039. The product is the diameter of the air-pump side-rod at ends in inches. Digitized by Google 532 ENGINES, RULES FOR CALCULATING THE PARTS OF. Rule 72.-To find the breadth of butt for air-pump.-Multiply the diameter of the cylinder in inches by 046. The product is the breadth of butt in inches. Rule 73.-To find the thickness of butt for air-pump.-Multiply the diameter of the cylinder in inches by 037. The product is the thickness of butt for air-pump in inches. Rule 74.-To find the mean thickness of strap at cutter.-Multiply the diameter of the cylinder in inches by -019. The product is the mean thickness of strap at cutter for air-pump in inches. Rule 75.-To find the mean thickness of strap below cutter.-Multiply the diameter of the cylinder in inches by 014. The product is the mean thickness of strap below cutter in inches. Rule 76.-To find the depth of gibs and cutter for air-pump.-Multiply the diameter of the cylinder in inches by 048. The product is the depth of gibe and cutter for air-pump in inches. Rule 77.-To find the thickness of gibs and cutter for air-pump.-Divide the diameter of the cylin- der in inches by 100. The quotient is the proper thickness of the gibs and cutter for air-pump in inches. With regard to the following rule we may remark, that the area of the steam port ought to depend principally upon the cubical content of the cylinder, which again depends entirely upon the product of the square of the diameter of the cylinder and the length of the stroke of the engine. It is well known, however, that the quantity of steam admitted by a small hole does not bear 80 great a proportion to the quantity admitted by a larger one, as the area of the one does to the area of the other; and a cer- tain allowance ought to be made for this. In the absence of correct theoretical information on this point, we have attempted to make a proper allowance by supplying a constant; but of course this plan ought only to be regarded as an approximation. Rule 78.-To find the area of each steam port.-Multiply the square of the diameter of the cylinder in inches by the length of the stroke in feet; multiply this product by 11 divide the last product by 1800; and, finally, to the quotient add 8. The result is the area of each steam port in square inches. To show the use of this rule, we shall apply it to a particular example. We shall apply it to an engine whose stroke is 6 feet, and diameter of cylinder 30 inches. Then, according to the rule, we have 30 = diameter of the cylinder in inches. 80 900 = square of diameter 6 = length of stroke in feet. 5400 11 59400 ÷ 1800 = 33 8 = constant to be added. 41 = area of steain port in square inches. Rule 79.-To find the diameter of branch steam-pipe.-Multiply together the square of the diameter of the cylinder in inches, the length of the stroke in feet, and 00498; to the product add 10-2, and ex- tract the square root of the sum. The result is the diameter of the steam-pipe in inches. Rule 80.-To find the diameter of waste-water pipe.-Multiply the square root of the nominal horse power of the engine by 1.2. The product is the diameter of the waste-water pipe in inches. Rule 81.-To find the area of foot-valve passage.-Multiply the nominal horse power of the engine by 9; divide the product by 5; add 8 to the quotient. The sum is the area of foot-valve passage in square inches. Rule 82.-To find the area of injection-pipe.-Multiply the nominal horse power of the engine by 069 to the product add 2.81. The sum is the area of the injection-pipe in square inches. Rule 83.-To find the diameter of feed-pipe.-Multiply the nominal horse power of the engine by 04; to the product add 3; extract the square root of the sum. The result is the diameter of the feed-pipe in inches. Rule 84.-To find the diameter of waste-steam pipe.-Multiply the collective nominal horse power of the engines by 375; to the product add 16875; extract the square root of the sum. The final result is the diameter of the waste-steam pipe in inches. Rule 85.-To find the diameter of the safety-valve when only one is used-To one-half the collective nominal horse power of the engines add 225; extract the square root of the sum. The result is the diameter of the safety-valve when only one is used. Rule 86.-7b find the diameter of the safety-valve when two are used-Multiply the collective nominal horse power of the engines by 25; to the product add 11-25; extract the square root of the sum. The result is the diameter of the safety-valve when two are used. Rule 87.-To find the diameter of the safety-valve when three are used-To one-sixth of the collective nominal horse power of the engines add 7.5; extract the square root of the sum. The result is the diameter of the safety-valve where three are used. Rule 88.-To find the diameter of the safety-valve when four are used-Multiply the collective nomi- nal horse power of the engines by 125; to the product add 5-625; extract the square root of the sum. The result is the diameter of the safety-valve when four are used. Another rule for safety-valves, and a preferable one for low pressures, is to allow 8 of a circular inch of area per nominal horse power. Rule 89.-To find the depth of the web at the centre of the main beam of a land engine.-Multiply together the square of the diameter of the cylinder in inches, half the length of the main beam in feet, Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 533 and the number 8; extract the cube root of the product. The result is the proper depth of the web of the main beam across the centre in inches, when the main beam is constructed of cast-iron. Rule 90.-7b find the depth of main beam at ends-Multiply together the square of the diameter of the cylinder in inches, half the length of the main beam in feet, and the number 192; extract the cube root of the product. The result is the depth in inches of the main beam at ends, when of cast-iron. Rule 91.-To find the content of the feed-pump.-Multiply the square of the diameter of the cylinder in inches by the length of the stroke in feet; divide the product by 30. The quotient is the content of the feed-pump in cubic inches. Rule 92.-To find the content of the cold-water pump.-Multiply the square of the diameter of the cylinder in inches by the length of the stroke in feet; divide the product by 4400. The quotient is the content of the cold-water pump in cubic feet. Rule 93.-To find the thickness of the large eye of crank for fly-wheel shaft when of cast-iron.- Multiply the square of the length of the crank in inches by 1.561, and then multiply the square of the diameter of the cylinder in inches by 1235; multiply the sum of these products by the square of the diameter of cylinder in inches; divide this product by 666-283; divide this quotient by the length of the crank in inches; finally, extract the cube root of the quotient. The result is the proper thickness of the large eye of crank for fly-wheel shaft in inches, when of cast-iron. Rule 94.-To find the breadth of the web of crank at Ay-wheel shaft, when of cast-iron.-Multiply the square of the length of the crank in inches by 1.561, and then multiply the square of the diameter of the cylinder in inches by 1235; multiply the square root of the sum of these products by the square of the diameter of the cylinder in inches; divide the product by 2304, and finally extract the cube root of the quotient. The final result is the breadth of the crank at the centre of the fly-wheel shaft, when the crank is of cast-iron. As this rule is rather complicated, we shall illustrate it by showing its application to the particular example of an engine whose stroke is 8 feet, and diameter of cylinder 64 inches. For this engine, fol- lowing the directions of the rule, we have in succession, 64 = diameter of cylinder in inches. 64 4096 = square of the diameter of cylinder. 1235 = constant multiplier. 5058 48 = length of crank in inches 48 2304 = square of the length of crank. 1.561 = constant multiplier. 3596.5 5058 41028 = sum of products. 41028 = 64-05 nearly. 4096 = square of the diameter of cylinder. constant divisor = 28-04)262348 11386.66 nearly. and ¥11386.66 = 22:49. Rule 95.-To find the thickness of the web of crank at centre of fly-wheel shaft, when of cast-iron.- Multiply the square of the length of the crank in inches by 1.561, and then multiply the square of the diameter of the cylinder in inches by 1235; multiply the square root of the sum of these products by the square of the diameter of the cylinder in inches; divide this product by 184-32; finally, extract the cube root of the quotient. The result is the thickness of the web of crank at the centre of the fly-wheel shaft when of cast-iron, in inches. As this rule is rather complicated, we shall illustrate it by applying it to the particular engine which we have already selected. For this engine we have in succession, 48 = length of crank in inches. 48 2304 = square of the length of crank. 1561 = constant multiplier. 35965 64 = diameter of cylinder in inches. 64 4096 = square of the diameter of cylinder. -1235 = constant multiplier. 5058 3596.5 4102'3 = sum of products. Digitized by Google 534 ENGINES, RULES FOR CALCULATING THE PARTS OF. and 41023 = 64.05 nearly 4096 = square of diameter. Constant divisor = 184-32)262348-5 1423'33 and V142833 = 11'25. Rule 96.-To find the diameter of the fly-wheel shaft at smallest part, when it is of cast-iron-Multi- ply the square of the diameter of the cylinder in inches by the length of the crank in inches; extract the cube root of the product; finally multiply the result by 3025. The result is the diameter of the fly-wheel shaft at smallest part in inches. Rule 97.-7b find the sectional area of the rim of the fly-wheel, when of cast-iron.-Multiply together the square of the diameter of the cylinder in inches, the square of the length of the stroke in feet, the cube root of the length of the stroke in feet, and 6-125; divide the final product by the cube of the diameter of the fly-wheel in feet. The quotient is the sectional area of the rim of fly-wheel in square inches, provided it is of cast-iron. As this rule is rather complicated, we shall endeavor to illustrate it by showing its application to a particular engine. We shall apply the rule to determine the sectional area of the rim of fly-wheel for an engine whose stroke is 8 feet, diameter of cylinder 50 inches; the diameter of the fly-wheel being 20 feet. For this engine we have as follows: 2500 = square of the diameter of cylinder. 64 = square of the length of stroke. 160000 2 = cube root of the length of stroke. 320000 6.125 = constant multiplier. 1960000 therefore sectional area in square inches = 1960000 ÷ 20' = 1960000 ÷ 8000 = 1960 ÷ 8 = 245. In the following formula we denote the diameter of the cylinder in inches by D, the length of the crank in inches by R, the length of the stroke in feet, and the nominal horse power of the engine by H.P. Marine engines-Dimensions of several of the parts of the side-lever. Depth of eye round end studs of lever = 074 X D. Thickness of eye round end studs of lever = 052 X D. Diameter of end studs, in inches = 07 X D. Length of end studs, in inches = 076 X D. Diameter of air-pump studs, in inches = 045 X D. Length of air-pump studs, in inches = 049 X D. Depth of cast-iron side-lever across centre, in inches = Di X (7423 X length of lever in feet)³. Marine engine.-Dimensions of several parts of air-pump cross-head. Diameter of air-pump, in inches = 6 X D. Thickness of eye for air-pump rod, in inches = 025 X D. Depth of eye for air-pump rod, in inches = 171 X D. Diameter of end journals, in inches = 051 X D. Length of end journals, in inches = 058 X D. Thickness of web at middle, in inches = 043 X D Depth of web at middle, in inches = 161 X D. Thickness of web at journal = 037 X D. Depth of web at journal = 061 X D. Marine engine-Dimensions of the parts of air-pump piston-rod. Diameter of air-pump piston-rod when of copper, in inches = 067 X D. Depth of gibs and cutter through cross-head, in inches = 063 X D. Thickness of gibs and cutter through cross-head, in inches = 013 X D. Depth of cutter through piston, in inches = 051 X D. Thickness of cutter through piston, in inches = 021 X D. Marine engine.-Dimensions of the remaining parts of the air-pump machinery. Diameter of air-pump side-rods at ends, in inches = 039 X D. Breadth of butt, in inches = 046 X D. Thickness of butt, in inches = 037 X D. Mean thickness of strap at cutter, in inches = 019 X D. Mean thickness of strap below cutter, in inches = 014 X D. Depth of gibe and cutter, in inches = 048 X D. Thickness of gibe and cutter, in inches = D ÷ 100. Marine and land engines.-Area of steam ports. Area of each steam port, in square inches = 11 X 1 X D' ÷ 1800 + 8. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 535 Marine and land engines-Dimensions of branch steam-pipes, Diameter of each branch steam-pipe = 00498 X I X Dª + 10.2. Marine engine.-Dimensions of several of the pipes connected with the engine. Diameter of waste water-pipe, in inches = 1-2 X VH.P. Area of foot-valve passage, in square inches = 1.8 X H.P.+ 8. Area of injection-pipe, in square inches = 069 X H.P. + 281. Diameter of feed-pipe, in inches Diameter of waste steam-pipe, in inches = 375 X H. P. + Marine and land enginea-Dimensions of safety-yalves. Diameter of safety-valve, when one only is used = V5XH.P.225. Diameter of safety-valve, when two are used = 25 X H. P. + 11-25. Diameter of safety-valve, when three are used = X H. P. + 75. Diameter of safety-valve, when four are used = X H. P. + 5-625. Land engine.-Dimensions of main beam. Depth of web of main beam across centre = V3 X D' X half length of main beam, in feet. Depth of main beam at ends = 192 X Dª X half length of main beam, in feet. Land and Marine-engines-Content of feed-pump. Content of feed-pump, in cubic inches = Dª X l Land engines.-Content of cold-water pump. Content of cold-water pump, in cubic feet = Land engines-Dimensions of crank. Thickness of large eye of crank, in inches = VD' X (1-561 X R* 1235 D') ÷ (R 666-283.) Breadth of web of crank at fly-wheel shaft centre, in inches = X 1235 X D')÷ Thickness of web of crank at fly-wheel shaft centre, in inches = (1.561 X R² 1235 D') Land engines-Dimensions of fly-wheel shaft. Diameter of fly-wheel shaft, when of cast-iron, = 3025 X VR X Dª. DIMENSIONS OF PA : # OF LOCOMOTIVES. Diameter of cylinder.-In locomotive engines the diameter of the cylinder varies less than in either the land or the marine engine. In few of the locomotive engines at present in use is the diameter of the cylinder greater than 18 inches, or less than 12 inches. The length of the stroke of nearly all the locomotive engines at present in use is 18 inches, and there are always two cylinders, which are-gener- ally connected to cranks upon the axle, standing at right angles with one another. Outside, cylinders, operating upon pins in the driving-wheels, have latterly been largely introduced. Area of induction ports. Rule-To find the size of the steam ports for the locomotive engine.-Multiply the square of the diameter of the cylinder by 068. The product is the proper size of the steam ports in square inches. Example.-Required the proper size of the steam ports of a locomotive engine whose diameter is 15 inches. Here, according to the rule, size of steam ports = 068 X 15 X 15 = 068 X 225 = 153 square inches, or between 151 and 15} square inches. After having determined the area of the ports, we may easily find the depth when the length is given, or, conversely, the length when the depth is given. Thus, suppose we know the length was 8 inches, then we find that the depth should be 158÷819125 inches, or nearly 2 inches; or suppose we knew the depth was 2 inches, then we would find that the length was 153 ÷ 2 = 785 inches, or nearly 74 inches. Area of eduction ports.-The proper area for the eduction ports may be found from the following rule. Rule.-To find the area of the eduction ports-Multiply the square of the diameter of the cylinder in inches by -128. The product is the area of the eduction ports in square inches. Example.-Required the area of the eduction ports of a locomotive engine, when the diameter of the cylinders is 18 inches. In this example we have, according to the rule, area of eduction part = 128 X 13" = 128 X 169 = 21632 inches, or between 211 and 211 square inches. Breadth of bridge between ports.-The breadth of the bridges between the eduction port and the in- duction ports is usually between t inch and 1 inch. Digitized by Google 536 ENGINES, RULES FOR CALCULATING THE PARTS OF. Diameter of boiler. Rule.-To find the inside diameter of the boiler-Multiply the diameter of the cylinder in inches by 8·11. The product is the inside diameter of the boiler in inches. Example.-Required the inside diameter of the boiler for a locomotive engine, the diameter of the cylinders being 15 inches. In this example we have, according to the rule, inside diameter of boiler = 15 X 8'11 = 46-65 inches, or about 3 feet 10g inches. Length of boiler.-In the Northern and Eastern Counties Railway the length of the boiler is 8 feet; while in the North Midland Counties Railway, in the Great Western Railway, and in the Hartlepool Railway, the length of the boiler is 81 feet. In the Belgian railways the length of the boiler is 8 feet 2 inches. And in the Bordeaux and La Teste railway the length of the boiler is 8 feet 9 inches. In Stephenson's locomotive engines, the length of the boiler is between 11 and 12 feet. In this country the length is from 10 to 14 feet. Diameter of steam dome inside.-It is obvious that the diameter of the steam dome may be varied considerably, according to circumstances; but the first indication is to make it large enough. It is usual, however, in practice, to proportion the diameter of the steam dome to the diameter of the cylin- der; and there appears to be no great objection to this. The following rule will be found to give the diameter of the dome usually adopted in practice. Rule-To find the diameter of the steam dome-Multiply the diameter of the cylinder in inches by 148. The product is the diameter of the dome in inches. Height of steam dome-The height of the steam dome may vary. Judging from practice, it appears that a uniform height of 21 feet would answer very well Diameter of safety-valve.-In practice the diameter of the safety-valve varies considerably. The fol- lowing rule gives the diameter of the safety-valve usually adopted in practice. Rule-To find the diameter of the safety-valve.-Divide the diameter of the cylinder in inches by 4. The quotient is the diameter of the safety-valve in inches. Example.-Required the diameter of the safety-valves for the boiler of a locomotive engine, the diameter of the cylinder being 18 inches. Here, according to the rule, diameter of safety-valve = 13 ÷ 4 = 34 inches. A larger size, however, is preferable, as being less likely to stick. Diameter of valve spindle.-The following rule will be found to give the correct diameter of the valve spindle. It is entirely founded on practice. Rule-To find the diameter of the valve spindle.-Multiply the diameter of the cylinder in inches by 076. The product is the proper diameter of the valve spindle. Example-Required the diameter of the valve spindle for a locomotive engine whose cylinders' diameters are 18 inches. In this example we have, according to the rule, diameter of valve spindle = 13 X 076 = 988 inches, or very nearly 1 inch. Diameter of chimney.-It is usual in practice to make the diameter of the chimney equal to the diameter of the cylinder. Thus, a locomotive engine whose cylinders' diameters are 15 inches would have the inside diameter of the chimney also 15 inches, or thereabouts. This rule has, at least, the merit of simplicity. Area of fire-grate.-The following rule determines the area of the fire-grate usually given in practice. We may remark, that the area of the fire-grate in practice follows a more certain rule than any other part of the engine appears to do; but it is in all cases much too small, and occasions a great loss of power by the urging of the blast it renders necessary, and a rapid deterioration of the furnace plates from ex- cessive heat. There is no good reason why the furnace should not be nearly as long as the boiler it would then resemble the furnace of a marine boiler, and be as manageable. Rule.-To find the area of fire-grate.-Multiply the diameter of the cylinder in inches by 77. The product is the area of the fire-grate in superficial feet. Example-Required the area of the fire-grate of a locomotive engine, the diameters of the cylinders being 15 inches. In this example we have, according to the rule, area of fire-grate = 77 X 15 = 11.55 square feet, or about 11} square feet. Though this rule, however, represents the usual practice, the area of fire- grate should not be contingent upon the size of the cylinder, but upon the quantity of steam to be generated. Area of heating surface.-In the construction of a locomotive engine, one great object is to obtain a boiler which will produce a sufficient quantity of steam with as little bulk and weight as possible. This object is admirably accomplished in the construction of the boiler of the locomotive engine. This little barrel of tubes generates more steam in an hour than was formerly raised from a boiler and fire occu- pying a considerable house. This favorable result is obtained simply by exposing the water to a greater amount of heating surface. In the usual construction of the locomotive boiler, it is obvious that we can only consider four of the six faces of the inside fire-box as effective heating surface; viz., the crown of the box, and the three per- pendicular sides. The circumferences of the tubes are also effective heating surface; 80 that the whole effective heating surface of a locomotive boiler may be considered to be the four faces of the inside fire- box, plus the sum of the surfaces of the tubes. Understanding this to be the effective heating surface, the following rule determines the average amount of heating surface usually given in practice. Rule-To find the effective heating surface.-Multiply the square of the diameter of the cylinder in inches by 5; divide the product by 2. The quotient is the area of the effective heating surface in square ft. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 537 Example.-Required the effective heating surface of the boiler of a locomotive engine, the diameters of the cylinders being 15 inches. In this example we have, according to the rule, effective heating surface = 15' X 5 ÷ 2 = 225 X 5 ÷ 2 = 1125 ÷ 2 = 5621 square feet. According to the rule which we have given for the fire-grate, the area of the fire-grate for this boiler would be about 11} square feet. We may suppose, therefore, the area of the crown of the box to be 12 square feet. The area of the three perpendicular sides of the inside fire-box is usually three times the area of the crown; 80 that the effective heating surface of the fire-box is 48 square feet. Hence the heating surface of the tubes = 526.5 48 = 4785 square feet. The inside diameters of the tubes are generally about 11 inches; and therefore the circumference of a section of these tubes is 5.4978 inches. Hence, supposing the tube to be 81 feet long, the surface of one = 5.4978 X 81 ÷ 12 = -45815 X 81 = 3.8943 square feet. And, therefore, the number of tubes = 4785 ÷ 3.8943 = 123 nearly. Area of water-level.-This of course varies with the different circumstances of the boiler. The aver- age area may be found from the following rule. Rule-To find the area of the water-level.-Multiply the diameter of the cylinder in inches by 208. The product is the area of the water-level in square feet. Example-Required the area of the water-level for a locomotive engine, whose cylinders' diameters are 14 inches. In this case we have, according to the rule, area of water-level = 14 X 2-08 = 29-12 square feet. Cubical content of water in boiler.-This of course varies not only in different boilers, but also in the same boiler at different times. The following rule is supposed to give the average quantity of water in the boiler. Rule.-To find the cubical content of the water in the boiler.-Multiply the square of the diameter of the cylinder in inches by 9; divide the product by 40. The quotient is the cubical content of the water in the boiler in cubic feet. Example.-Required the average cubical content of the water in the boiler of a locomotive engine, the diameters of the cylinders being 14 inches. In this example we have, according to the rule, cubical content of water = 9 X 14" ÷ 40 = 44.1 cubic feet. Content of feed-pump.-In the locomotive engine, the feed-pump is generally attached to the cross- head, and consequently it has the same stroke as the piston. As we have mentioned before, the stroke of the locomotive engine is generally in practice 18 inches. Hence, assuming the stroke of the feed- pump to be constantly 18 inches, it only remains for us to determine the diameter of the ram. It may be found from the following rule. Rule.-To find the diameter of the feed-pump ram-Multiply the square of the diameter of the cylin- der in inches by -011. The product is the diameter of the ram in inches. Example-Required the diameter of the ram for the feed-pump for a locomotive engine whose diam- eter of cylinder is 14 inches. In this example we have, according to the rule, diameter of ram = -011 X 14" = -011 X 196 = 2-156 inches, or between 2 and 21 inches. Cubical content of steam room-The quantity of steam in the boiler varies not only for different boilers, but even for the same boiler in different circumstances. But when the locomotive is in motion, there is usually a certain proportion of the boiler filled with the steam. Including the dome and the steam-pipe, the content of the steam room will be found usually to be somewhat less than the cubical content of the water. But as it is desirable that it should be increased, we give the following rule. Rule-To find the cubical content of the steam room.-Multiply the square of the diameter of the cylinder in inches by 9; divide the product by 40. The quotient is the cubical content of the steam room in cubic feet. Example.-Required the cubical content of the steam room in a locomotive boiler, the diameters of the cylinders being 12 inches. In this example we have, according to the rule, cubical content of steam room = 9 X 12* ÷ 40 = 9 X 144 ÷ 40 = 32.4 cubic feet. Cubical content of inside fire-box above fire-bars.-The following rule determines the cubical content of fire-box usually given in practice. Rule-To find the cubical content of inside fire-box above fire-bare-Divide the square of the diam- eter of the cylinder in inches by 4. The quotient is the content of the inside fire-box above fire-bars in cubic feet. Example.-Required the content of inside fire-box above fire-bars in a locomotive engine, when the diameters of the cylinders are each 15 inches. In this example we have, according to the rule, content of inside fire-box above fire-bars = 15" ÷ 4 = 225 ÷ 4 = 561 cubic feet. Thickness of the plates of boiler.-In general the thickness of the plates of the locomotive boiler is 9-32 inch, or No. 3 wire gage. Inside diameter of steam-pipe.-The diameter usually given to the steam-pipe of the locomotive en- gine may be found from the following rule. Rule-To find the diameter of the steam-pipe of the locomotive engine.-Multiply the square of the diameter of the cylinder in inches by 03. The product is the diameter of the steam-pipe in inches. Example-Required the diameter of the steam-pipe of a locomotive engine, the diameter of the 68 Digitized by Google 538 ENGINES, RULES FOR CALCULATING THE PARTS OF. cylinder being 13 inches. Here, according to the rule, diameter of steam-pipe = 03 X 18" 03 X 169 =5.07 inches; or a very little more than 5 inches. The steam-pipe is usually made too small in en- gines intended for high speeds. Diameter of branch steam-pipes.-The following rule gives the usual diameter of the branch steam- pipe for locomotive engines. Rule-To find the diameter of the branch steam-pipe for the locomotive engine.-Multiply the square of the diameter of the cylinder in inches by 021. The product is the diameter of the branch steam- pipe for the locomotive engine in inches. Example.-Required the diameter of the branch steam-pipes for a locomotive engine, when the cylin- ders' diameter is 15 inches. Here, according to the rule, diameter of branch pipe = 021 X 152 = 021 X 225 = 4725 inches, or about 41 inches. Diameter of top of blast-pipe-The diameter of the top of the blast-pipe may be found from the fol- lowing rule. Rule.-To find the diameter of the top of the blast-pipe.-Multiply the square of the diameter of the cylinder in inches by 017. The product is the diameter of the top of the blast-pipe in inches. Example.-The diameter of a locomotive engine is 13 inches; required the diameter of the blast-pipe at top. Here, according to the rule, diameter of blast-pipe at top= .017 X 13 = 017 X 169 = 2.878 inches, or between 21 and 3 inches; but the variable exhaust is now generally used. Diameter of feed-pipes-There appear to be no theoretical considerations which would lead us to de- termine exactly the proper size of the feed-pipes. Judging from practice, however, the following rule will be found to give the proper dimensions. Rule-To find the diameter of the foed-pipes-Multiply the diameter of the cylinder in inches by -141. The product is the proper diameter of the feed-pipes. Example-Required the diameter of the feed-pipes for a locomotive engine, the diameter of the cylinder being 15 inches. In this example we have, according to the rule, diameter of feed-pipe = 15 X 141 = 2-115 inches, or between 2 and 21 inches. Diameter of piston-rod-The diameter of the piston-rod for the locomotive engine is usually about one-seventh the diameter of the cylinder. Therefore, Rule-To find the diameter of the piston-rod for the locomotive engine.-Divide the diameter of the cylinder in inches by 7. The quotient is the diameter of the piston-rod in inches. Example.-The diameter of the cylinder of a locomotive engine is 15 inches, required the diameter of the piston-rod. Here, according to the rule, diameter of piston-rod = 15 ÷ 7 = 21 inches. Thickness of piston-The thickness of the piston in locomotive engines is usually about two-sevenths of the diameter of the cylinder. Therefore, Rule-To find the thickness of the piston in the locomotive engine.-Multiply the diameter of the cylinder in inches by 2; divide the product by 7. The quotient is the thickness of the piston in inches. Example.-The diameter of the cylinder of a locomotive engine is 14 inches, required the thickness of the piston. Here, according to the rule, thickness of piston = 2 X 14 ÷ 7 =4 inches. Diameter of connecting-rods at middle.-The following rule gives the diameter of the connecting-rod at middle. The rule is entirely founded on practice. Rule.-To find the diameter of the connecting-rod at middle of the locomotive engine.-Multiply the diameter of the cylinder in inches by -21. The product is the diameter of the connecting-rod at middle in inches. Example.-Required the diameter of the connecting-rods at middle for a locomotive engine, the diameter of the cylinders being 12 inches. For this example we have, according to the rule, diameter of connecting-rods at middle = 12 X -21 = 2.52 inches, or 21 inches. Diameter of ball on cross-head spindle.-The diameter of the ball on the cross-head spindle may be found from the following rule. Rule-To find the diameter of the ball on cross-head spindle of a locomotive engine.-Multiply the diameter of the cylinder in inches by 23. The product is the diameter of the ball on the cross-head spindle. Example.-Required the diameter of the ball on the cross-head spindle of a locomotive engine, when the diameter of the cylinder is 15 inches. Here, according to the rule, diameter of ball = .23 X 15 = 3.45 inches, or nearly sh inches. Diameter of the inside bearings of the crank-axle.-It is obvious that the inside bearings of the crank- axle of the locomotive engine correspond to the paddle-shaft journal of the marine engine, and to the fly-wheel shaft journal of the land engine. We may conclude, therefore, that the proper diameter of these bearings ought to depend jointly upon the length of the stroke and the diameter of the cylinder. In the locomotive engine the stroke is usually 18 inches, 80 that we may consider that the diameter of the bearing depends solely upon the diameter of the cylinder. The following rule will give the diam- eter of the inside bearing. Rule-To find the diameter of the inside bearing for the locomotive engine.-Extract the cube root of the square of the diameter of the cylinder in inches; multiply the result by 96. The product is the proper diameter of the inside bearing of the crank-axle for the locomotive engine. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 539 Diameter of plain part of crank-axle.-It is usual to make the plain part of crank-axle of the same sectional area as the inside bearings. Rule-To determine the diameter of the plain part of crank-axle for the locomotive engine.-Extract the cube root of the square of the diameter of the cylinder in inches multiply the result by 96. The product is the proper diameter of the plain part of the crank-axle of the locomotive engine in inches. Diameter of the outside bearings of the crank-axle.-The crank-axle, in addition to resting upon the inside bearings, is sometimes also made to rest partly upon outside bearings. These outside bearings are added only for the sake of steadiness, and they do not need to be so strong as the inside bearings. The proper size of the diameter of these bearings may be found from the following rule. Rule-To find the diameter of outside bearings for the locomotive engina-Multiply the square of the diameter of the cylinders in inches by 396; extract the cube root of the product. The result is the diameter of the outside bearings in inchea. Diameter of crank-pin-The following rule gives the proper diameter of the crank-pin. It is obvious that the crank-pin of the locomotive engine is not altogether analogous to the crank-pin of the marine or land engine, and, like them, ought to depend upon the diameter of the cylinder, as it is usually formed out of the solid axle. Rule-To find the diameter of the crank-pin for the locomotive engine-Multiply the diameter of the cylinder in inches by 404. The product is the diameter of the crank-pin in inches. Example.-Required the diameter of the crank-pin of a locomotive engine whose cylinders' diameters are 15 inches. In this example we have, according to the rule, diameter of crank-pin = 15 X 404 = inches, or about 6 inches. Length of crank-pin-The length of the crank-pin usually given in practice may be found from the following rule. Rule.-To find the length of the crank-pin.-Multiply the diameter of the cylinder in inches by 283. The product is the length of the crank-pins in inches. The part of the crank-axle answering to the crank-pin is usually rounded very much at the corners, both to give additional strength, and to prevent side play. These, then, are the chief dimensions of locomotive engines, according to the practice most generally followed. The establishment of express trains and the general exigencies of steam locomotion are daily introducing innovations, the effect of which is to make the engines of greater size and power; but it cannot be said that a plan of locomotive engine has yet been contrived that is free from grave objec- tions. The most material of these defects is the necessity that yet exists of expending a large propor- tion of the power in the production of a draft; and this evil is traceable to the inadequate area of the fire-grate, which makes an enormous rush of air through the fire necessary to accomplish the combustion of the fuel requisite for the production of the steam. To gain a sufficient area of fire-grate an entirely new arrangement of engine must be adopted; the furnace must be greatly lengthened, and perhaps it may be found that short upright tubes may be introduced with advantage. Upright tubes have been found to be more effectual in raising steam than horizontal tubes; but the tube-plate in the case of upright tubes would be more liable to burn. We here give the preceding rules in formulæ, in the belief that those well acquainted with algebraic symbols prefer to have a rule expressed as a formula, as they can thus see at once the different operations to be performed. In the following formulas we denote the diameter of the cylinder in inches by D. Locomotive engine.-Parts of the cylinder. Area of induction-porta, in square inches = 068 X D'. Area of eduction-ports, in square inches 128 X D'. Breadth of bridge between ports between t inch and 1 inch. Locomotive engine.-Parts of boiler Diameter of boiler, in inches 3'11 X D. Length of boiler between 8 feet and 12 feet. Diameter of steam dome inside, in inches = 143 X D. Height of steam dome feet. Diameter of safety-valve, in inches = D÷4. Diameter of valve-spindle, in inches X D. Diameter of chimney, in inches D. Area of fire-grate, in square X D. Area of heating-surface, in square feet = 5 X D' ÷ Area of water-level, in square feet 2.08 X D. Cubical content of water in boiler, in cubic feet = X ÷ Diameter of feed-pump ram in inches 011 X D'. Cubical content of steam room, in cubic feet X D'÷40. Cubical content of inside fire-box above fire-bars, in cubic feet = D' ÷ Thickness of the plates of boiler = i inch. Locomotive engine.-Dimensions of several pipes. Inside diameter of steam-pipe, in inches = 03 X Dª. Inside diameter of branch steam-pipe, in inches = 021 X Dª. Inside diameter of the top of blast-pipe 017 X D'. Inside diameter of the feed-pipes= X D. Digitized by Google 540 ENGINES, RULES FOR CALCULATING THE PARTS OF. Locomotive engines-Dimensions of several moving parts. Diameter of piston-rod, in inches = D ÷ 7. Thickness of piston, in inches = D ÷ 7. Diameter of connecting-rods at middle, in inches = 21 X D. Diameter of the ball on cross-head spindle, in inches = 23 X D. Diameter of the inside bearings of the crank-axle, in inches = 96 X D'. Diameter of the plain part of crank-axle, in inches = 96 X Dª. Diameter of the outside bearings of the crank-axle, in inches = V.396 X Dª. Diameter of crank-pin, in inches = 404 D. Length of crank-pin, in inches 233 X D. Expedients for regulating the velocity, and ascertaining the state and effective power of the engine.- In most engines yet invented for developing mechanical effect from steam, there are great irregularities in the velocity of the engine unless some contrivance be added to equalize the action of the steam. In the land engine, and in the marine engine, the inequalities of velocity may be considered to proceed from two sources; one, the unequal action of the mechanism of the engine itself, and the other the unequal resistances which the engine has to overcome. The piston does not move with a uniform velocity up and down the cylinder. The velocity is greatest at half stroke, and gradually decreases towards the end of the stroke till it stops altogether, and finally returns in the opposite direction. When it is said that the velocity of the piston is so many feet per minute, it is at once inferred that this can only be the mean velocity, and that at the middle of the stroke the piston moves faster, and at the termination slower, than the specified velocity. But even if the piston were to move uniformly, the intervention of the crank would introduce irregularities into the velocity of the engine. The crank is certainly the best constructive expedient yet devised for deriving a rotary motion from the reciprocating motion of the piston; but, with all its advantages, it has the defect of not transmitting uniformly the pressure and velocity of the engine. Let it not be inferred from this statement that we intend to show the least favor to the exploded notion of the crank absorbing some of the power or mechanical effect of the steam. The crank, like every other piece of machinery, transmits at every instant all the mechanical effect com- municated to it; so that the only way in which we can suppose it to have an appetite for devouring power is by taking into consideration the friction of the parts connected with it. But this is not incon- sistent with our statement that the crank does not transmit the pressure and velocity of the piston uniformly. The mechanical effect transmitted by the crank at any instant is measured by the product of the effective pressure on the crank into its velocity at that instant; and this is exactly equal to the mechanical effect generated at the piston at the same instant, as measured by the product of the pressure on the piston into its velocity. But then the velocity of the crank does not always bear the same proportion to the velocity of the piston, nor does the effective pressure on the crank always bear the same proportion to the pressure on the piston. The products are constantly equal, but the pro- portions of the elements constantly change; and the effect of the intervention of the crank, if unre- dressed, would be to cause the velocity of the machinery driven by the engine to undergo inconvenient fluctuations. These irregularities proceeding from the internal mechanism of the engine itself would leave the mean velocity unaffected. Supposing the amount of steam supplied, and the amount of resistance to be over- come, to remain constant, then, although the velocity would be different for different positions of the crank, still the average velocity throughout a whole revolution would remain constant. If, however, the amount of resistance to be overcome be changed, the average velocity will also change, unless the supply of steam be modified 80 as to suit the exigency. We may see the great variation of resistance which a marine engine has to sustain in a storm. Sometimes the paddle-board is deeply immersed in the wave-at other times it is almost completely out of the water; and in these circumstances it is obvious that the average velocity of the paddle-shaft will vary. Analogous variations are experienced in most of the applications of the land engine. If a land engine be employed to drive the machinery of a cotton-mill, it will have to impart motion to all the spinning-frames in that mill. The operation of one or more of these may from time to time be suspended, and consequently the moving power will be relieved from a corresponding amount of resistance, and again the spinning-frames offer different resistances at different times. These circumstances, it is obvious, must effect the mean velocity of the engine, unless some contrivance be added to modify the supply of steam 80 as to correspond to the amount of resistance to be overcome. If, under such circumstances, the energy of the moving power remains the same, the velocity with which the machinery will be driven must be subject to variation, being increased whenever the operation of any portion of the machines usually driven by it is suspended and, on the other hand, diminished when any increased number of machines are brought into operation. In fine, the speed will vary nearly in the inverse proportion of the load driven, increasing as the load is diminished, and vice versa. Now in most of the applications of the steam-engine, irregularity of velocity is considered to be a great evil, and every exertion is made to lessen it as much as possible. Indeed, in all applications of machinery it is desirable, all other things being equal, to have the motion uniform. On this Tredgold remarks, very justly, An equable motion is desirable in almost every kind of machine, it being strained much more by an irregular desultory one, as well as the fabric that supports it, than when the motion is equable. The strength of the machine must be adapted to the greatest strains that occur; but the quantity of work done is equivalent to the mean action only, and more is not performed by a desultory motion than by one at a mean rate, and uniform." But uniformity of velocity is more sought after in some of the applications of the steam-engine than in others. In the marine engine and the locomotive engine all the requisite uniformity is obtained by attaching two engines to the main shaft, and so adjusting them that the irregularities of the one engine partly counteract the irregularities of the other. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 541 The plan does not ensure perfect uniformity, but it approaches to it as far as particular circumstances seem to require. In these engines no provision is made that the supply of steam should adapt itself to the amount of resistance to be overcome. Again, in the common pumping-engine, there is not 80 much urgent necessity for uniformity of motion as in most other applications of the land engine. Indeed, judging from practice, we may infer that the advantage to be gained by a greater uniformity in the velocity of the pumping-engine is not sufficiently great to compensate for the increased expense incurred in providing and repairing a mechanism for redressing its inequalities. However, in many of the other applications of the land engine, uniformity of velocity is the great object aimed at, and provision is made for approximating to it as closely as possible. We have pointed out two sources of irregularity of velocity; one the peculiar internal mechanism of the engine itself, and the other the unequal resistances which it has to overcome. We proceed now to mention in detail the several remedies that have been proposed for redressing these inequalities; and first we proceed to mention those remedies which have been proposed for redressing the inequalities arising from the peculiar mechanism of the engine itself. Remedies for redressing the inequalities arising from the mechanism of the engine itself.-We have already mentioned, that in the marine engine and locomotive engine an approximation to uni- formity of velocity and uniformity of pressure is obtained by putting two engines upon the same shaft, and 80 adjusting them that when the piston of the one engine is at its maximum velocity, the piston of the other is at its minimum, and vice versa. This is effected by placing the cranks at right angles to one another. The velocity obtained in this way is more nearly uniform than when only one engine is used, but, unless assisted by a fly-wheel, the irregularities would be too great for many of the nice applications of the modern steam-engine. Another objection to this plan is, that it requires two engines, and thus takes up more room, and offers more constructive difficulties, than if the requisite power were obtained from one engine only. These objections are to a certain extent obviated by an ingenious plan first proposed by Mr. Mark Isambard Brunel, and for which he obtained a patent in 1828. In his plan, instead of using two cranks, two cylinders are employed to give motion to the same crank. This is effected by inclining the two cylinders to one another at an angle of about 90°, and causing them to act upon the same axle by means of their connecting-rods. The frame of the engine is of the form of an isosceles triangle. The working cylinders rest upon the inclined sides, and the main shaft upon the apex of the triangle. The piston-rod is preserved in its rectilineal course by metal rollers running upon guide-plates, which act a similar part to the vertical guides in the common direct-action engine. Mr. Brunel states that the axis of the cylinders should be inclined to one another at an angle of 102°; having, as he says, found that angle to be preferable to all others for transmitting a rotary motion to the axle from the reciprocating motion of the pistons: but there seems to be no theoretical considerations which would lead us to prefer an angle of 102° to an angle of 90°, except that the weight of the pistons and their connections presses only in a downward direction. Underneath each of the working cylinders is placed a small cylinder containing the valve. The valves are wrought by eccen- trics from the main shaft, and the steam is alternately admitted into one end of the working cylinder, and a passage opened for its escape at the other, as is the usual arrangement. From this form of con- struction it follows, that when the piston of one of the cylinders is at half-stroke, the piston of the other is at the termination of its stroke, or nearly 80; and thus the irregularities of the one cylinder partly counteract the irregularities of the other. It is obvious, however, that this engine, whatever may be its peculiar advantages in other respects, will fail in obtaining any greater regularity of velocity than is obtained in the more usual construction, by placing two marine engines or two locomotive engines upon the same shaft-a motion which of itself is too irregular for many of the modern applications of the steam-engine. When the expansive principle is employed in an engine, it involves the condition of a variation in the intensity of the moving power. If the steam acts with a uniform energy on the piston as long as the supply from the boiler continues, 80 soon as that supply is stopped by closing the steam-valve, the steam contained in the cylinder will fill a gradually increasing volume by the motion of the piston, and con- sequently will act above the piston with a gradually decreasing energy. Now, if the resistance to the moving power be not subject to a variation corresponding exactly to this variation in the moving power, the result will be that the motion will cease to be uniform. For if the momentum of the moving power at any part of the stroke be greater than the resistance, the motion of the machinery will be accelerated; and if it be less, the motion of the machinery will be retarded. Hence the application of the expansive principle will introduce irregularities peculiar to itself. In the patent which Watt took out for the ap- plication of the expansive principle, he specified several expedients for approximating to a uniform effect upon a uniform resistance, notwithstanding the variation of the energy of the power which neces- sarily attended the expansion of the steam. One method consisted in causing the moving force, when acting with the greatest energy, to impart momentum to a mass of inert matter, which should be made to restore the same force when the moving power was more enfeebled. Another expedient consisted in causing the moving power, when acting with greatest energy, to lift a weight hung considerably above the centre of the beam which should resist the ascent of the piston at the beginning of the stroke, but aid its motion as soon as the beam passed the horizontal line, when the weight, like a tumbler, would pass its centre of gravity. He also proposed to make the piston act on a lever, which should have an arm of variable length, and so regulated, that when the momentum of the moving force in- creased or diminished, the length of the arm diminished or increased in the same proportion. This last expedient had been already applied in mechanics for the purpose of equalizing a varying power, and a familiar example of its action occurs in the internal mechanism of a watch. When a watch is newly wound up, the force of the spring is much greater than when the watch is nearly run down; so that if the force of the spring always acted at the same leverage, a very unequal velocity would be produced. The irregularity, however, is counteracted by the varying diameters of the grooves of the fusee, on which the force of the spring, through the intervention of the chain, acts. As the watch goes down, the Digitized by Google 542 ENGINES, RULES FOR CALCULATING THE PARTS OF. main-spring relaxes, and its force diminishes; but then the chain acts upon a wheel or circle having a diameter increased in the same proportion as the strength of the spring is diminished. This expedient, however, has never been successfully employed to regulate the action of the moving power of the steam- engine; and it does not appear to be as practicable a scheme as that of hanging a weight above the centre of the beam. The following ingenious expedient for equalizing the action of the steam in the engine, was first, sug- gested by Mr. Buckle, of Soho, and constructed by him for Mr. Lucy, of Birmingham. It acts upon the principle of causing the engine to drag up a piston against the pressure of the atmosphere when the en- ergy of the moving power is above the average; the power thus consumed being returned to the engine by the atmosphere forcing down the piston when the energy of the moving power is below the average, Fig. 1469. The manner in which this is accomplished may be easily understood from the accompanying figure. P represents the piston in the cylinder, LL the great beam, LR the connecting-rod, RO the crank, and R WWW a toothed wheel carried round by the crank. These are all the same as in the common steam-engine. There is added r w to w, a smaller wheel, whose diameter is only one-half that of the larger, and consequently it has only one-half the number of teeth. The small wheel will obvi- ously perform a half revolution whilst the large wheel performs a quarter revolution. 11 is a second 1469. L L W R W lever, driven by the crank of the small wheel, to which it is attached by means of its connecting-rod. The piston-rod l H is attached to the small lever 11, carrying with it a piston from top to bottom of an open cylinder H. At the points marked 1, 2, 3, 4, the circumference of the great wheel is supposed to be divided into four equal quadrants. Suppose now that the figure represents the state of the engine when the piston is ascending. Whilst the crank moves from its present position to the position corre- sponding to 2, the small wheel will have performed a semi-revolution, and the piston H will have ascended to the top of the open cylinder, leaving a vacuum behind it. The piston H has been dragged up against the pressure of the atmosphere, and this has consumed so much of the power of the engine. This power, however, is not lost-it is only lent; for while the crank moves from the position 2 to the position 3, the pressure of the air forces down the piston, and then the mechanical power is given back to the large wheel. Again, whilst the crank moves from the position 3 to the position 4, the piston H has to be dragged up to the top of the cylinder. Finally, whilst the crank moves from the position 4 to the position 1, the pressure of the air forces down the piston of the open cylinder. Thus all the power consumed in dragging up the piston against the pressure of the atmosphere, whilst the crank moves from 1 to 2 and from 8 to 4, is faithfully given out to the wheel whilst the crank moves from 2 to 8 and from 4 to 1. By this arrangement the engine is made to lay up, as it were, a store of power when the moving force is acting with greatest energy, and this store is employed to assist it when the moving force is acting with least energy. The pressure of the atmosphere is very adroitly converted into a sort of reservoir, in which is deposited the surplus power generated while the crank moves from 1 to 2, and from 3 to 4, to be withdrawn in order to supply the deficiency whilst the crank moves from 2 to 8 and from 4 to 1. Let A denote the number of square inches in the piston H, and h the number of feet in the diameter of the small wheel; then the power necessary to drag the small piston from the bottom of the cylinder to the top, exclusive of the friction, is represented by a mechanical effect of 15 X A X h lb. raised one foot high. Hence, the total effect of this pneumatic pump is equivalent to causing the engine to raise 15 X A X h lb. one foot high whilst the crank is passing the quadrantal points, and allowing that weight to fall whilst the crank is passing the line of the centres. At the first considera- tion we may perhaps infer that there would be a sudden change of velocity and pressure when the small piston had arrived at the top or the bottom of its stroke; but a little more attention will convince us that the change is gradually introduced by the peculiar relation of the wheels to one another. In the position represented in the figure, the crank moves a certain distance past position 1 without raising the piston to any great extent. As the crank descends to the quadrantal point, in which position most power is generated, the crank of the small wheel descends to its quadrantal point, in which position the pressure of the atmosphere on the piston H, offers the greatest resistance to the motion of the wheel. After the large crank has passed its quadrantal point, the energy of the moving power begins to lessen, and at the same time, the small crank having passed its quadrantal point, the motion of the small wheel is less retarded by the pressure of the atmosphere on the piston H. When the large crank ap- proaches to the position 2, the small crank approaches to the lowest part of its revolution, where the pressure of the atmosphere on the piston H, offers little opposition to the motion of the small wheel. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 543 It is unnecessary to examine the action of the pump throughout the whole revolution of the wheel, as it would be only a repetition of the process for a quadrant. But we see that, by the peculiar connection of the wheel, the pressure of the atmosphere acts at one time as an accelerating force, at another as a retarding force; that the change is not abrupt, but gradual; that it acts most efficiently as a retarding force at the very moment that the energy of the moving force is greatest, viz., when the large crank is passing the quadrantal points; and finally, it acts most efficiently as an accelerating force at the very moment that the energy of the moving force is least, viz, when the crank is passing the line of the centres. In fact, this pneumatic equalizer approaches more closely to theoretical perfection, than any expedient ever proposed for equalizing the action of the engine. It may easily be shown that the equalization of the effective pressure on the shafts is more efficient than that obtained by using a pair of engines, and certainly it is much less complicated and expensive. The superiority is still more mani- fest. when we consider the regularity of velocity which it in practice has been known to introduce. The principal objection against the expedient is, that the toothed wheels are very bad constructive ex- pedients, as they cause considerable friction, and the teeth are apt to break and to throw the whole into disarrangement. Several ingenious expedients have been proposed for enabling one shaft performing a certain number of revolutions per minute to drive another shaft 80 as to make more revolutions per minute without con- necting them together by tooth geering; but it would take up too much of our space to describe them here. We may only refer to one which is applied in Smith's direct-action engine. This expedient enables the main shaft to drive a second shaft with a double velocity the very thing which is required for Buckle's pneumatic equalizer. We may remark that expedients for multiplying velocity are in- vested with additional interest at present, from the introduction of the screw propeller. Before a suffi- ciency of resistance can be obtained from the screw propeller, it must be made to perform more revo- lutions per minute than the paddle-shaft, in the more common construction. To demonstrate the practical efficiency of Buckle's equalizer, we may instance the great success which has attended its application at a Birmingham flour-mill. So perfect was the action of this me- chanism that the fly-wheel had been wholly removed, and the engine and the whole mill-work were moving in the most smooth and effective manner. It was found that the change enabled them to give all the grinding stones a greater velocity than formerly, so that the quantity ground was greater, in the proportion of 56 to 52. and the quantity of the finest or first flour, from the same wheat, was likewise much increased; 80 that, both by quantity and quality, the owner of the mill was now able to command the market. The same motion has subsequently been applied to cotton-mills with perfect success, the quality and the quantity of yarn produced being much improved. The last expedient for equalizing the action of the steam which we shall notice, is that known as the fly- wheel. The fly-wheel derives all its efficacy as an equalizer of the action of the steam from the principle, that a large mass of matter offers great resistance to a change of motion. In a common double-action engine, the steam loses all energy as a moving power for driving the machinery when the crank is pass- ing the line of the centres, and a person not familiar with the laws of matter might conclude that the engine would come to a stand-still, unless some moving foree was applied at these critical positions. It is well known, however, that the momentum of the moving parts of the machinery will supply a force sufficient to force the crank over the centre, although with a diminished velocity. The momentum of the moving parts acts therefore to a certain extent as a regulator of the action of the steam, and the addition of the fly-wheel only promotes regularity of velocity in so far as it increases this momentum. The moving force of a body in motion is estimated by the product of its mass into its velocity. If, therefore, we wish to regulate the velocity of an engine, by increasing the momentum of its moving parts, we have only to connect with it some large mass that it moves with great velocity. Such a mass is the fly-wheel: it is made of large diameter, 80 that its rim revolves with great rapidity; and the rim is made of great weight, it being generally constructed of cast-iron. It is obvious that the same amount of momentum may be obtained by other forms of construction; but the wheel possesses three advan- tages peculiar to itself, which entitle it to the preference: it consumes no power by friction; it suffers but little resistance to its motion from the air; and, finally, it can be so exactly poised on its axis as to cause little strain on the machinery. When the piston is at half-stroke, the energy of the moving force is at its maximum, 80 that at this time more mechanical effect is generated than the usual resistance can appropriate. The surplus me- chanical effect is expended in quickening the velocity of all the moving parts of the machinery. But the greater the mass of a moving body, the more opposition does it offer to a change of motion; so that the large mass of the fly-wheel absorbs the surplus mechanical effect without any great change of velo- city. As the crank approaches the dead points, the effect of the moving power upon the axle and the wheel is gradually enfeebled. The defect can only be supplied by abstracting some of the momentum of the moving parts, and in these circumstances the large mass of the fly-wheel can give out the suffi- cient quantity of momentum without any considerable change of velocity. The mass of the fly-wheel is thus converted into a reservoir for receiving the surplus power at one time, and giving it out at another. It is obvious, however, that the equalization of the motion produced by the fly-wheel is par- tial, and can never be theoretically perfect. The fly-wheel acts as a receptacle of momentum, and as matter can only receive momentum or give out momentum by a change of velocity, its agency as an equalizer presupposes a slight change in the velocity of all the machinery. The motion of revolution received by the main shaft is always subject to a variation corresponding to the amount of change of momentum in the great mass of the fly-wheel sufficient to extricate the crank twice in every revolution from its critical position while passing the line of centres; but this change can be rendered smaller and smaller by increasing the weight and magnitude of the fly-wheel. Buckle's Pneumatic Equalizer acts upon the principle of increasing or diminishing the resistance according as the energy of the moving force increases or diminishes; the fly-wheel, on the other hand, acts upon the principle of increasing the momentum of the moving parts of the machinery, so that when the energy of the moving force is greater Digitized by Google 544 ENGINES, RULES FOR CALCULATING THE PARTS OF. or less than the resistance, the surplus may be absorbed or the defect supplied without any sensible change in the motion of the whole. The former is capable of theoretical perfection; the latter must necessarily fall short of that perfection, though it may be made sufficiently near it for practicable purposes. Fly-wheels are sometimes employed for other purposes than merely regulating the velocity of the steam-engine. Whenever the employment of an engine is such that an enormous force is required to act only for short times, such as when it is employed for rolling iron, or for stamping coins, then an enormous fly-wheel is attached to the engine, which absorbs the power generated when the resistance is removed, and gives it all the force at once at the proper moment. In these cases, the mass of the fly- wheel rim is generally much greater than when the fly-wheel is only employed to regulate the velocity in order that the momenta may be accumulated without inconveniently increasing the velocity. In some cases the energy of the fly-wheel would be thirteen times greater than what the proportions given by our rule would make it. Fly-wheels moving at a great velocity should always have malleable iron arms, and the ring should be cast in a piece, and may be hooped with malleable iron with advantage. Expedients for redressing the inequalities of velocity arising from the variation of resistance which the engine has to overcome.-By the expedients which we have mentioned for equalizing the velocity of the engine, the motion imparted to the main shaft will approximate to uniformity, provided that the moving power of the engine be always proportionate to the load which the engine has to drive. But it is obvious that in the general application of the steam-engine to the purposes of manufacture, provision must be made for a considerable variation of the amount of resistance. If, while the amount of resistance was changed, the energy of the moving power remained the same, then the velocity would also change, increasing as the resistance diminished, and diminishing as the resistance increased. It is obvious that an expedient for redressing the inequalities arising from this source may act upon the principle of regu- dating the supply of steam from the boiler. The elastic force of the steam is the moving agent of the whole machine; 80 that if we wish to keep the mean velocity constant, we must regulate the supply of steam to the amount of resistance to be overcome. The simplest contrivance for this purpose is the throttle-valve; so called from its agency in cutting off the supply of steam by throttling it in the steam- pipe. It consists of an axis placed across the steam-pipe 80 as to form the diameter of a section of the pipe, and on this axis is fixed a thin circular disk of nearly the same diameter as the inside diameter of the steam-pipe; 80 that when the axis is turned to a certain position, the supply of steam is cut off alto- gether. On one end of the axis is placed a short lever or handle, by which it can be turned in either direction. When the handle is turned 80 that the plane of the disk is nearly at right angles to the direc- tion of the steam-pipe, the passage within the pipe is closed altogether, and no steam can find admission to the cylinder. On the other hand, when the handle is turned about a fourth of a complete revolution from this position, the plane of the circular disk will then be in the direction of the length of the pipe, 80 as to offer little or no opposition to the passage of the steam. By turning the handle to any other angle, the disk may be made to offer any required degree of opposition to the passage of the steam. The form of the valve is obviously such, that, if constructed accurately, the pressure of the steam in passing from the boiler will have no tendency to change any given position of the valve. If constructed accurately, the quantity of surface on both sides of the axis is equal, and therefore the pressure of the steam balances itself on the axis, 80 that it can have no tendency either to change the valve from its existing position, or to oppose the effect of a pressure upon the handle. Any slight inaccuracy in the construction of the valve, which would give the steam a capability of changing its position, would be counteracted by the friction of the valve on its axis. By this expedient the variations of the velocity of the engine, consequent upon the inequalities of resistance which the engine has to overcome, may be remedied. If the load on the engine be lightened, then, the supply of the steam continuing the same, the motion will be immediately accelerated; but the tendency will be counteracted if the attendant workman turn round the handle, so as partially to close the valve. If, on the other hand, the load on the engine be increased, then, the supply of the steam con- tinuing the same, the motion will be immediately retarded. To counteract this, the attendant workman must turn round the valve, 80 as to admit a greater supply of steam. By the adoption of these means the mean velocity of the engine would be rendered uniform, provided the vigilance of the attendant work- man were sufficient for the due management of the valve, and provided that the evaporating power of the boiler continued in sufficient activity to supply the greatest amount of steam which would ever be necessary for the maintenance of the mean velocity when the valve was fully open. For some purposes engines are thus regulated by hand at the pleasure of the attendant workman. In general, however, the proper manipulation of the handle is impracticable with any degree of vigilance and skill which could be obtained from the person employed to attend the engine. Before the steam- engine could be employed in those cases where great uniformity of velocity is required. it was necessary that means should be found for enabling the engine itself properly to manipulate the valve without any care or attention on the part of the attendant workman. The governor.-In the mechanism of the governor as represented in Fig. 1470, EE represent two heavy balls of iron, which are suspended from the point e by suitable arms. These bars cross one another at e, forming a joint there, and are continued to f. At f these bars are joined by pivots to other bars fh, which last fit into a ring or collar of metal at F, placed on the upright spindle, 80 as to be capable of a motion upwards and downwards. The lever FG H rests upon a bar at G as fulcrum, and is connected to the ring of metal at F by means of a forked end interposed between two collars on the sliding piece. In this species of connection it is obvious that the ring of metal may revolve with the spindle without moving the lever, but that it cannot move upwards or downwards on the spindle with- out at the same time depressing or raising the remote extremity, H, of the lever. The bars E f pass through slits in a metallic arch, which is firmly fixed to the upright spindle, 80 that the balls, the arms, and the spindle must all revolve at the same time. If, now, the spindle be made in any manner what- ever to revolve with a certain velocity, say thirty revolutions per minute, the balls EE will diverge from Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 545 the spindle till their centrifugal force balances their weight. Let this be the position represented in the figure. If the spindle be made to make more revolutions than 30, then the balls will diverge more than what is represented in the figure. The points ff will diverge, and by means of the bars fh pull down the one end F of the lever F H, and raise the other end H. This, by the mechanism represented in the figure, would obviously tend to shut the valve, and to cut off the supply of steam. If, on the other hand, the spindle be made to perform fewer revolutions per minute than 30, the balls will collapse more than what is represented in the figure. The points ff will approach to one another, and by means of the arms f h force up one end F of the lever, and depress the other end H. This will obviously tend to open the valve, and to increase the supply of steam. After this action is understood, suppose that by some mechanism the upright spindle is 80 connected with some moving part of the machinery, that when the velocity of the engine is unduly accelerated, the spindle performs more than 80 revolutions, and 1470. 5 H E B D that when the velocity of the engine is unduly retarded, the spindle performs less than 80 revolutions per minute, then this expedient becomes a regulator of all the inequalities of velocity arising from the variations in the amount of resistance to be overcome. The upright spindle may be connected with the fly-wheel shaft by means of an endless cord passing over a small grooved wheel d on the axis of the spindle, and working into a similar groove on the fly-wheel shaft, or by geering, which is a preferable mode in large engines. By properly proportioning the diameters of these wheels, the spindle may be made to perform any number of revolutions per minute. It is obvious, that by these means the speed of the grooved wheel d may be considered as representing the speed of the fly-wheel, and of the machinery which the fly-wheel drives. After these observations, and the remarks upon the subject we have already made, the principle which renders the governor so admirable a regulator of the velocity of the machine will be easily apprehended. Let t denote the time in seconds of a periodic revolution of the balls, and h the height in inches of e above the horizontal plane passing through the centre of the balls; then, according to the well-known formula- Let n denote the number of revolutions per minute, then we have the proportion- < 60 31986 60 = 31986 h or n = 18758 ÷ √h, which also may be written h = 35186 We have supposed Fig. 1470 to represent the divergence of the balls when the spindle was making 30 revolutions per minute. In that case n = 30, and h = 35186 ÷ 30' = 35186 ÷ 900 = 39.09 inches, or about 3910 inches. Now suppose that the velocity of the engine was accelerated so much that the spindle performed 31 revolutions per minute; then, taking n = 31, we obtain h = 35186 ÷ 31" = 35186 ÷ 961 = 36.61 inches, or somewhat more than 361 inches. Thus, before the spindle can perform one more revolution per minute, the plane of revolution of the balls rises 39 10 = 215 = inches, which obviously would cause a very great change in the angle of divergence of the arms E ef. Suppose, on the other hand, that the velocity of the engine were retarded 80 much that the spindle performed only 29 revolutions per minute. Then, by taking n = 29, we find h = 35186 ÷ 20" = 35186 ÷ 841 = 41.84 inches, or between 411 and 42 inches. Thus, before the spindle can perform one less revolution per minute, the plane of revolution of the balls must fall 41.84 391 = 2.74 = inches nearly, which would obviously cause the angle of divergence of the arms E e to diminish very considerably. The efficiency of the governor in regulating the supply of steam depends very much upon the mechanism employed to communicate its agency to the throttle-valve. We may suppose the relations of the different bars E ef,fh, FGH, and 20, to be such, that when the horizontal plane passing through the centre of the two balls EE is only 3661 inches below the point of suspension e, the throttle-valve would entirely close up the steam-pipe, and that when the horizontal plane passing through the centres of the two balls E E is 41.84 inches below the point of suspension e, the throttle-valve would be fully open. On this supposition the effect of the governor would be, that the engine could never be 80 much retarded as that the upright spindle per- formed less than 29 revolutions per minute, or so much accelerated that the upright spindle performed more than 31 revolutions per minute. This would ensure that the greatest change of velocity of any 69 Digitized by Google 546 ENGINES, RULES FOR CALCULATING THE PARTS OF. part of the machinery could never exceed of its mean velocity,-a variation which in practice is scarcely perceptible; 80 that such a governor might be considered as practically perfect. In the best modern engines the amount of variation is seldom less than one-tenth of the mean velocity. But we may easily suppose the governor to be so connected with the engine as to act with even greater efficiency than the one which we have described. The governor can be 80 proportioned, and 80 con- nected with the engine, as to make 60 revolutions per minute; and the mechanism connecting it with the throttle-valve may be 80 contrived, that when it makes 59 revolutions per minute the valve may be fully open, and that when it makes 61 revolutions per minute the valve may be entirely closed. In this case the greatest variation of the velocity of any part could never exceed one-thirtieth of the mean velocity of that part. Indeed, in theory there is no limitation to the degree of regularity which may be produced by the application of the governor. Practical considerations, however, limit the application of the principle in several ways. It has been found inconvenient, for example, to allow minute altera- tions of the governor to affect sensibly the position of the valve, and in order to prevent the incon- venience arising from a continual changing in its position it is found expedient to construct the governor such that even a considerable change in the divergence of the balls shall not produce too much alteration in the opening of the valve. This consideration, and several others, limit the application of the governing principle, and prevent engineers from approximating so closely to theoretical perfection, as the principle permits. In the construction of a governor to regulate a particular engine, it is necessary to consider the position of the balls corresponding to the mean velocity of the engine, the range of motion which must be given to the arms 80 as to enable them to confine the variations of velocity within certain limits, and the weight of each of the balls. We proceed to consider each of these points separately. Position of balls when moving with mean velocity.-To determine this position, we have only to con- sider the vertical height of the point of suspension above the horizontal plane passing through the centre of the balls when the spindle is making the average number of revolutions per minute. This is found from the formula, 35186 From which we have the following rule:- Rule-To determine the height of the point of suspension above the plane of the balls, when moving with mean velocity.-Divide the number 35186 by the square of the mean number of revolutions per minute. The quotient is the height of the point of suspension above the plane of the balls when moving with mean velocity. Example 1.-In a particular engine the governor is so connected with the fly-wheel shaft, that when the engine is moving with average velocity the upright spindle makes 40 revolutions per minute. Required the proper height of the point of suspension above the plane of the balls In this example, 35186 35186 1600 35186 21.99 inches; so that the proper height is about 22 inches, Example 2.-The governor spindle is driven by the fly-wheel shaft by means of an endless cord passing over a groove on the spindle, and another groove on the fly-wheel shaft. The diameter of the groove on the governor spindle is 9 inches, and the diameter of the groove on the fly-wheel shaft is 12 inches. The engine has a stroke of 8 feet, and the mean velocity of the piston is 256 feet per minute. Required the proper height of the point of suspension above the plane of the balls. In this example, since the mean velocity of the piston is 256 feet per minute, and the length of the stroke 8 feet, it follows that the engine makes 256 8 = 32 single strokes, or 16 double strokes per minute. The fly-wheel makes one revolution for each double stroke of the piston, and therefore the fly- wheel also makes 16 revolutions per minute. The number of revolutions of the fly-wheel shaft is to the number of the revolutions of the governor spindle inversely as the diameters of the grooves; 80 that we have the proportion 9: = 9 Hence, according to the rule, 35186 (21f)2 35186 77.31 inches. This proportion is one never em- ployed in practice on account of the inconvenience of the dimensions; but it is that proper to the data assumed. The range of motion of the arms.-This depends entirely upon the amount of variation of velocity which may be permitted without detriment to the work upon which the engine is applied. We have already shown, that when the governor performed on an average 30 revolutions per minute, a variation of velocity equal to one-fifteenth of the mean velocity required only a range corresponding to a vertical height of 523 (=41:84-86:61) inches. But we shall now conduct the inquiry in general terms. Let v = mean velocity of any moving part of the machinery. n = number of revolutions of the governor spindle corresponding to v. h = height of point of suspension above the plane of balls corresponding to v. v + f v v = maximum velocity of any moving part of the machinery h' = value of h corresponding to I v = minimum velocity of any moving part of the machinery. h₁ = value of h corresponding to velocity (1-fm) v. Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 547 Then we wish to find the value of h₁ It is obvious that the value of n corresponding to the maximum velocity will be and the value of n corresponding to the minimum velocity will be Hence, according to the rule, 35186 35186 and therefore, This formula is too complicated to be easily expressed in the form of a rule; but its applications may easily be apprehended from the following example: Example.-The governor of a steam-engine performs 80 revolutions per minute when the engine is moving at the average speed. Required the range as expressed in vertical height of the arms of the governor, such that the difference between the maximum and minimum velocity of any moving part should never exceed one-fifteenth of the average velocity of that part. In this example 1 and as we have shown previously, h X 3909 inches. We may conclude these investigations respecting the governor with a summary of the most important points in the rationale of its operation. The governor may either be considered as a conical pendulum compounded of the movements of two pendulums vibrating at right angles with one another, or it may be viewed simply as a system of revolving balls, of which gravity is the centripetal force. In the former case the governor will make half the number of revolutions that a pendulum of the same vertical height makes of vibrations; and if the speed of the governor be urged beyond this point, the arms will fly out and diminish the vertical height, until it just becomes equal to the length of a pendu- lum that makes twice the number of vibrations in the minute that the governor makes of revolutions. Every one knows that if the length of a pendulum be diminished, it will make a greater number of vibrations in a given time than before; the cause of which simply is, that the steepness of the are in which the ball of the pendulum descends is then increased, and it consequently descends with a greater velocity. The length of the seconds' pendulum at the level of the sea in London is 39-1398 inches, and the number of vibrations made in a given time by pendulums of different lengths varies inversely as the square roots of their lengths. The proper speed for a governor, therefore, with a vertical height of about 39 inches, is 30 revolutions per minute, which accords with the preceding determinations; and similarly if the vertical height of governor proper to any other number of revolutions be required, it is only necessary to find the length of a pendulum, which will give twice the number of vibrations. If the number of revolutions and the length of the arm be fixed, and it is wanted to know what is the diameter of the circle described by the centre of the ball, it is necessary to find the vertical height by the fore- going rule; or the following may be adopted. Divide the constant number 187.68 by the number of revolutions per minute, and the square of the quotient will be the vertical height in inches of the centre of suspension above the plane of the ball's revolution. Deduct the square of the vertical height in inches from the square of the length of the arm in inches, and twice the square root of the remainder is the diameter of the circle in which the centres of the balls revolve. The vertical height of the governor is in every case taken as the distance between this circle and the point of suspension. In considering the governor as a system of bodies acted upon by centrifugal and centripetal forces, the same results are obtained as where it is regarded as a conical pendulum. The horizontal distance of the ball from the spindle, divided by the vertical height, will give the amount of centripetal force; and the velocity of revolution requisite to produce an equivalent centrifugal force may be found by multi- plying the centripetal force of the ball in terms of its own weight by 70-440, and dividing the product by twice the distance of the centre ball from the centre of the spindle in inches. The square root of the quotient is the right number of revolutions of the spindle per minute. Considering the question in this way, we first fix the length of the arms and the diameter of the base of the cone, or what is the same thing, the angle at which it is desired the arms may revolve; and then, by the rule given above, we make the speed of revolution such that the centrifugal force will koep the balls in the desired position. Many persons find some difficulty in considering the governor as a pendulum, inasmuch as it may be driven at any speed; but each particular speed has a vertical height of the centre of suspension above the plane of revolution proper to itself, and one condition cannot be altered without affecting the other. The method of considering the governor, however, as a revolving system of balls, does not involve this difficulty, and to many engineers it will therefore be the most satisfactory. Weight of balls-The proper weight of balls depends principally upon the nature of the mechanism employed to transmit the agency of the governor to the throttle-valve. In practice they are generally somewhere between 30 and 80 pounds each. It may be remarked in general, that of two governors performing the same number of revolutions per minute, the one which is farthest removed from its throttle-valve, and which is consequently connected with it by the most complicated mechanism, ought to have the heaviest balls. No general rule founded upon theory can be given for determining the proper weight of these balls in any particular case. In fnct, according to theory, the agency of the governor is altogether independent of the weight of the balls; for the balls perform the same number of revolutions per minute, and revolve at the same distance from the spindle, whatever is their weight. The truth of this remark will appear clear enough if each ball be supposed to be compounded of a number of smaller balls, each of which would certainly keep the same position as the larger ball; and every particle may therefore be supposed to act for itself. Though the centripetal force of the balls be increased, therefore, by adding to their weight, yet, inasmuch as their centrifugal force when in motion is increased in the same proportion, their position, when the governor is set into revolution, cannot be Digitized by Google 548 ENGINES, RULES FOR CALCULATING THE PARTS OF. affected thereby. An increase in the weight of the balls gives the governor more power to open or close the throttle-valve, but does not in any other way affect its operation. Large engines, where the valves are large and stiff, require to have the balls of the governor of corresponding size, especially if the connections between the governor and throttle-valve are stiff and complicated; but in no other respect is the size of the balls of importance. The principle on which the governor acts, necessarily supposes temporary variations of the speed. The governor, theoretically speaking, does not maintain a uniform velocity, but restores it after it has been disturbed. Suppose that, either by reason of the diminished load upon the engine, or an increased evaporative power in the boiler, the speed of the engine is accelerated, the governor, being immediately affected, will cause a corresponding alteration in the throttle-valve; but in general, this alteration being too much, the velocity of the engine will be too much retarded. This second error will again affect the governor in the contrary way, and the speed will now be increased beyond the proper limit. Thus a succession of alternations of effect will ensue, until the governor settles down into the position correspond- ing to the proper speed. The agency of the governor is never brought into use before a change of ve- locity has taken place. The very supposition that a governor acts, presupposes that a change of the speed has ensued and which, though it corrects, it cannot prevent from arising. Varieties of governors.-The conical pendulum is the governor employed almost universally for the regulation of the speed of rotative steam-engines. Yet other kinds have been introduced, and in some instances with a good effect. One very sensitive governor consists of a cylindrical double bellows, worked by the engine, and furnished with a small cock at the orifice at which the air escapes, 80 that it may be contracted at pleasure. When the engine runs beyond the right speed, an additional quan- tity of air is taken in by the bellows, which, as it cannot obtain a free exit by the orifice contracted by the cock, raises up the superior or floating part of the bellows, to which a rod is attached that closes the throttle-valve. When the speed slackens, the floating part of the bellows subsides, and opens the throttle-valve, until, after a few fluctuations, a mean point is reached-determined by the size of the orifice left for the issuing air-at which the floating part of the bellows will remain nearly stationary. A bellows on this plan has been for some years attached to the engine that gives motion to the ma- chinery in Truman and Hanbury's brewery, and its operation is spoken of in the highest terms. Another plan of governor was some years ago contrived by Mr. Hick, of Bolton. Upon an upright spindle he wound a spiral feather, and then fitted upon the spindle a single ball, 80 that the ball might be moved up or down on the spindle, but would turn on its axis in the operation. To the ball were fixed two vanes, which, impinging upon the air when the ball was put into revolution with a high velo- city, caused the ball to mount up on the spiral feather or thread. So long as the speed of the shaft upon which the ball was placed remained moderate, the ball continued at the foot of the spiral; but when the speed was increased, the impact of the vanes upon the air 80 far resisted the rotation, that the ball rose on the spiral feather in opposition to the force of gravity; and in its ascent it closed the valve. A governor upon this plan seems to be well adapted for steam vessels, if a spring be substituted for the ball. The ordinary governor, however, may be rendered applicable to the marine engine if the balls be made to move out horizontally instead of in an arc of a circle. It is clear that a common governor would not act at sea without this modification, as the balls would diverge or collapse at every heave of the ship. In Siemen's chronometric governor a clock movement furnished with a weight and pendulum is employed. The clock movement carries round a bevel-wheel at a uniform speed; and another bevel- wheel of the same size, and situated upon the same axis, is carried round by the engine in an oppo- site direction. A bevel-pinion at the end of a crank-arm geers with both wheels in the manner of a differential motion, and to this crank is attached a rod communicating with the throttle-valve. When both wheels are moving at the same speed the pinion remains stationary, but if one wheel travels faster than the other, the crank will be carried round upon its axis, and will thereby affect the throttle-valve. There appears to be too much complication in this contrivance to enable it to gain an introduction into practice, unless a clock movement be required for other uses than that of the engine. The governor, as at present applied to regulate the steam-engine, acts only on the throttle-valve, to restrain the flow of steam into the cylinder; but in our humble judgment it ought also to act upon the injection-valve, to restrain the flow of water into the condenser. In all cases of large fluctuations of velocity, inconvenience and danger is the inevitable effect of the injection water being left without due regulation, and in steam vessels in particular, accidents are frequently traceable to this cause. If the injection-cock be adjusted to give admission to the right quantity of water when the engine is working with a mean velocity, it will clearly admit too much when the velocity is arrested 80 as to be brought to one-half or one-fourth of the common speed; and as the air-pump cannot, when it is working 80 slow, deliver the water which rushes into the condenser in undiminished quantity, the engine becomes choked with water, and the water sometimes runs back into the cylinder, and occasions fracture by resisting the descent of the piston. The most common cause of breakages in steam machinery is the entrance of water into the cylinder. Sometimes it passes over with the steam, when priming in the boiler takes place; and at other times it finds its way from the condenser, and this will more frequently happen if the cylinder exhausts from below than if it exhausts from the top or superior portion of the valve casing. The right remedy for this danger is to apportion the quantity of water admitted to an engine to the quantity of steam; and this may be accomplished by placing a throttle-valve in the injection-pipe, which will also be operated on by the governor; but little condensing water will then be admitted when there is but little steam to be condensed, and the engine will neither be burdened by needless water nor starved into inefficiency by an inadequate supply. The cataract.-The governors we have already mentioned are chiefly applicable to the rotative en- gine. The accredited governor of the single-acting or pumping engine, is the cataract, of which instru- ment there are many varieties. The cataract consists of a small pump plunger, and barrel, set in a cistern of water, the barrel being furnished on the one side with a valve, opening inwards, through which the water obtains admission to the pump chamber from the cistern; and on the other by a cock, Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 549 through which, if the plunger be forced down, the water may be sent out again, with a rapidity propor- tionate to the size of the orifice left by the cock. The engine, in its upward stroke, which is accom- plished by the preponderance of weight at the pump end of the beam, raises up the plunger of the cataract by means of a small rod, represented in the drawing of valve geering already referred to- the water entering the pump chamber through the spindle valve, which is also represented, and filling the pump chamber completely. By the time the engine reaches the top of the stroke, it liberates the rod by which the plunger has been drawn up, and the plunger then descends by gravity, forcing out the water in the barrel, and at the same time opening the injection valve. If the cock of the cataract be shut, it is clear that the plunger cannot descend at all; and as, in that case, the injection valve cannot be opened, the engine stands still: but if the cock be slightly opened, the plunger will descend slowly, the injection valve will slowly open, and the engine will make a gradual stroke as it gains the water necessary for condensation. The degree to which the cock is opened, therefore, determines the speed at which the engine moves; 80 that by the use of the cataract, the speed of the engine may easily be ad- justed to the quantity of water in the mine. There are other varieties of cataract employed besides that here described, but they all depend upon the same general principle. In some cases air is used instead of water, and in others a cylinder of oil is employed, fitted with a piston with a valve after the manner of a pump bucket, and a small side pipe, fitted with a cock, which communicates between the spaces on each side of the piston. When the piston of this cataract is forced down, the oil easily ascends through the valve into the superior part of the cylinder; but when it is drawn up, the oil can only escape by the curved pipe, from the space above the piston to the space beneath it, by passing through the con- tracted orifice of the cock; and, though a considerable counterbalance be applied, the piston, if the cock be partially closed, can ascend but slowly. The effect is the same as in the arrangement first described. Expedients for ascertaining the state and power of an engine.-Water gages.-There are three kinds of water gages: the first the ordinary gage cock, the second the glass gage, and the third the float. The gage cock, on being turned, shows whether it is water or steam that exists at the level at which it is inserted. There are usually three gage cocks inserted in each boiler, at different levels; and the rule is, to 80 feed the boiler that there will be steam in the top gage-cock, and water in the other two. The glass gage consists of a glass tube set in front of the boiler, communicating in its superior portion with the steam space, and in its inferior portion with the water within the boiler, the position of the tube being so adjusted that the water level stands at about the middle of its length. The tube is connected at the top and bottom to the boiler by means of sockets furnished with cocks, 80 that the tube may be blown through by the steam to clear it, and the water and steam may be shut off if the glass breaks. It is unsafe to trust to the glass gages altogether as a means of ascertaining the water level, as some- times they become choked, and the water continues to stand high in the tube though it may have sunk low in the boiler. If the boiler be short of steam, however, and a partial vacuum be produced, the glass gages become of essential service, as the gage cocks will not operate in such a case, for though opened neither steam nor water will come out, but air will rush in. This sometimes occurs in practice, and glass gages are then found to be of especial value. We may mention, however, that a vacuum in the boiler should never be suffered to occur, as if the boiler is short of steam the throttle-valve should be closed to a corresponding degree, or a higher degree of expansion should be employed, 80 that the due pressure of the steam may be maintained. A better economy is to be realized by this plan of proce- dure than by suffering the engine to draw from the boiler the attenuated steam. In steam vessels the operation of blowing off cannot be performed, unless the pressure of the steam be considerably above that of the atmosphere, and the neglect of this operation entails evils which are of serious moment, and which are very expensive to cure. The float gage consists of a float resting on the surface of the water, and communicating with an in- dex, 80 that the fluctuations in the water level are, by reference to this index, made apparent. The float is usually of stone or cast-iron, but is 80 balanced by a counter weight as to make its operation the same as if it were a buoy of timber. In land boilers a float is generally employed to regulate the ad- mission of the feed-water, and the same float may also indicate the height of the water within the boiler. The feed-water is admitted from a small open cistern at the top of the stand-pipe, as shown in Fig. 1471. At the bottom of the cistern is a valve, which the float opens or closes, and into the cistern the water is poured by the feed-pump. When the valve is open the water 1471. runs down into the boiler, but when closed it runs away by an overflow shoot. The foot of the stand-pipe penetrates to near the bottom of the boiler, 80 that steam cannot escape by it, but the water rises in the stand-pipe to a height proportionate to the pressure of the steam, and a most effectual safety-valve is thus provided, which will come into operation in the event of a dangerous pressure being attained. In the stand-pipe a float is placed, which rises and falls as the pressure of the steam varies, and opens or closes the damper leading from the boiler flue to the chimney. Some stand-pipes are contracted in their diameter below the level at which the damper float usually operates, and danger has arisen from this cause; for the float has de- scended into this narrow neck when there was no longer a pressure of steam in the boiler, and by stopping up the passage it has prevented the access of the feed-water. The length of the damper chain should be 80 regulated as to obviate accidents of this description, which are not unlikely to burst the boiler, by causing the boiler bottom or flues to become red-hot. Salt gages.-In steam vessels it is a commendable practice to apply salt gages to the boiler, 80 that the water may never be suffered to reach an injurious degree of saturation. These gages usually consist of glass balls, which operate on the principle of the hydrometer, rising to the surface when the water becomes highly concentrated, and therefore heavier. In some instances bulbs of this description, enclosed in a large glass tube, are fitted to the front of each boiler; but the general plan is to draw off some of the water into a separate Digitized by Google 550 ENGINES, RULES FOR CALCULATING THE PARTS OF. vessel, and then to test its saltness by an instrument provided for the purpose. The Don Juan steamer was fitted with large copper balls, to determine the saltness of the water in the boiler: they were of course totally immersed in the water, and as the water increased in density they rose and opened the blow-off valve, which was made of such a construction as to be capable of being easily opened. There is too much refinement probably in this expedient, and the ball requires to be large to realize a sufficient motive force to make the action of the instrument certain, yet the operation of the plan is very complete, especially if conjoined with a self-acting feed, as was the case in the instance referred to. A good salt gage is still a desideratum, for the plan of drawing off water from the boiler, and testing it by an hydro- meter, is very inconvenient in practice. A salt gage, to be a convenient instrument, should indicate, by a hand or other simple appendage, the density at the time of observation of the water in the boiler, and such an instrument becomes of especial importance if the amount of water blown off be regulated by the position of the feed-cocks, as is done in the case of Mr. Lamb's blow-off apparatus for steam vessels, which is now gaining an extensive introduction. In this apparatus the mouth of the blow-off pipe within the boiler is situated near the water level, whereby it catches and removes from the boiler the particles of impalpable matter which, by their subsidence on the flues, occasion scale. Mr. Lamb attaches a valve to the mouth of the blow-off pipe regulated by a float, with the view of preventing the steam from blowing off when the water has subsided below the said mouth, which is situated about 12 inches beneath the average water line. The float is made of copper, of the form of an oblate spheroid, with a tube passing through it for the reception of a spindle, the position of which in reference to the float is regulated by nuts above and below the float, which connect with screw threads cut upon the spindle. The valve resembles a flute key. The lower end of the spindle is attached to the valve arin, 80 as to enable the float to exert a greater power, and the upper end of the spindle moves in a guide attached to any convenient part of the boiler. By this apparatus the operation of blowing off is continuously performed; but when the salt gage shows that the quantity of water blown off is either needlessly great or insufficient, the position of the feed-cock is altered 80 as to give a diminished or increased supply. When more feed-water is admitted, the float upon the surface of the water opens the blow-off valve more widely, and permits a larger quantity of water to be blown out; and when less feed-water is admitted, the contrary effect is produced. The operation of the float, therefore, is to main- tain the water at a uniform level, and also to preserve the water within the boiler at a uniform density 80 soon as the right position of the feed-cock is ascertained. In boilers which are thus worked, or to which brine pumps, or any continuous blow-off contrivances are applied, an efficient salt gage is indis- pensable, as there can otherwise be no intimation of the accidental interruption of the operation, and much mischief may be the result. In the ordinary way of blowing off, where the engineer keeps the blow-off cocks open until the water level has descended any given number of inches, it is certain that, if the water level descends, a certain volume of super-salted water has been ejected; unless, indeed, as has sometimes happened where there is a difference of pressure in the different boilers, one boiler has discharged its contents into the other when all the blow-off cocks are opened at once. But in the ordi- nary operation of blowing off one boiler at a time, a determinable quantity of water is expelled by blow- ing out at determinate intervals with a certainty which leaves nothing to the chances of accidental de- rangement, and which the use of the salt gage in the case of boilers fitted with any description of con- tinuous blow-off is indispensable to insure. Steam gage.-The steam gage consists generally of a simple tube, sometimes of glass and sometimes of iron, bent 60 as to form the letter U. One of the ends is placed in communication with the boiler, and the other end is open to the atmosphere. Into the bent part of the tube mercury is poured, which, it not acted on by the steam, will stand at equal heights in both legs of the tube. If, however, the steam be admitted to act upon the mercury at one of the extremities of the tube, it will force it up in the other leg, and may be made to indicate the amount of pressure on a divided scale. The scale is com- monly divided into inches and parts of an inch, each inch corresponding to a pressure of very nearly one pound on the square inch. Some people prefer estimating the elasticity of the steam by pounds per circular inch. For this purpose each of the divisions of the scale ought to be 1,³ₓ inches, and these divided again into 10 equal parts, when the pressure in lbs. and tenths of a lb. will be shown by the scale. When the tube is constructed of iron, it is necessary that a float of wood resting on the top of the mercury should ascend above the tube, and indicate on a proper scale the place of the mercury. It is clear that every inch the mercury rises in the open end of the tube occasions a difference of level of two inches, for the level in the leg pressed on by the steam falls an inch at the same time that the level in the open end rises an inch. Some steam gages consist of a straight glass tube, with one end termi- nating in a small cistern of mercury, while the other end is open, and the mercury is forced up into the tube by the pressure of the steam. In this case the graduation has to be such that a pound pressure will be represented by two inches in height upon the scale, for the level of mercury in the cistern does not subside appreciably by the rise of mercury in the tube. The siphon gage is the one generally employed, and it appears to be entitled to the preference it enjoys. Every boiler ought to be provided with a steam gage as a precaution of safety, as well as a means of seeing that the steam is kept steadily up. If the pressure rises to any dangerous pitch, the mercury will be blown out of the gage, and the escape of steam will notify the existence of danger. In such case, if the safety-valve cannot be raised, from derangement or otherwise, the best plan is to open the blow-through valve of the engine. To start the engine might cause a flow of water from the feed-pump over hot plates within the boiler, if the water be at the same time low within it, and an explosion might be the consequence of such an indiscretion. Vacuum gage.-The vacuum gage is a barometer for determining the relative elasticities of the air and of the attenuated vapor in the condenser. It consists of a glass tube, of which the inferior orifice is inserted in a small cistern of mercury, while the superior orifice is fitted with a small pipe, which communicates with the interior of the condenser. The air presses on the surface of the mercury in the cistern, while the pressure of the condenser vapor only exists within the tube, and the mercury rises in the tube to a height corresponding to the difference of these pressures-usually to a height of about 27 Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 551 inches. There is a good deal of oscillation in the mercury of a vacuum gage if the cock in the pipe leading from the top of the tube to the condenser be opened fully, and it should therefore be nearly closed before the observation of the quality of the vacuum is made, else it will be very difficult to tell at what point the mercury stands on the average, in consequence of its rapid rising and subsidence. In the graduation of vacuum gages reference enough is not generally had to the size of the mercury cis- tern, which is usually made small; and as the subsidence of the level of the mercury in the cistern falls considerably when the tube becomes full, the graduation, if made in inches, is correspondingly inaccu- rate, as the divisions should be less than an inch apart to represent inches, if the surface of the inercury in the cistern falls. Some vacuum gages are made on the principle of indicating the difference between the vacuum in the condenser and a perfect vacuum, instead of the difference between the vacuum in the condenser and the pressure of the atmosphere. This species of vacuum gage is much used in sugar re- fining, and is convenient there from its portable nature; but it has not met with any extended adoption for the uses of the steam-engine. A siphon vacuum gage, like the steam gage in form, is also some- times used; but the straight glass tube, arranged in the manner we have described, is generally pre- ferred to any other arrangement. The indicator.-The indicator is an instrument for determining the amount of power actually exerted by an engine. In computing the power of engines, one important element is the unbalanced pressure of the steam on the piston; and any inaccuracy in the statement of this particular must vitiate the cal- culation, and give an erroneous result. In all ordinary cases, even when no expansion geer is used, it is wrong to reckon the pressure of the steam in the cylinder as uniform, or the condensed vapor as of a constant elasticity; and to assume that the pressure in the cylinder is the same as that indicated by the steam gage, is to introduce a fallacy into the computation of power. The use of the indicator is to measure and register the variations of pressure during a complete stroke of the engine, and thus to ob- tain accurate data whereby the effective power of the engine may be computed. The indicator consists of a small cylinder c, Fig. 1472, placed in connection with the cylinder of the engine either above or below the piston, and fitted with a piston P, which is connected with the spiral spring 8. By opening the cock of the indicator the steam is admitted below the piston P, on which it presses during the whole stroke. If the pressure were uniform, the piston would remain stationary but if the pressure vary, the piston will have corresponding movements either up or down. If a pencil p, be attached to the piston-rod, it will register the variations of pressure upon a piece of paper held against it; but, unless some provision were made to give a clear space upon the paper at each instant of time, one mark of the pencil would be upon the other, and the registration could not be deciphered but, if the paper receives a continuous lateral motion in one direction during the down stroke of the 1472. piston, and a reversed motion during the return stroke, while the pencil moves vertically, a continuous line will be traced upon the paper, which will inclose a space, and the vertical ordinates of the figure will represent the effective pressure during a complete stroke. Instead. however, of using a plain sur- face, as was done in Boulton and Watt's establishment for some time after its formation, it is now the universal practice to wind the paper round a cylinder, or roller, which is made to turn upon its axis with a reciprocating motion, and the apparatus is thus rendered more compact. If the pressure of the steam were uniform, the line described upon the paper would be in a plane perpendicular to the axis of the roller, so that, if the paper were unrolled, the line would be straight. The paper is fastened to the roller by means of a catch h, the edge of which is graduated. Before the instrument is connected with the steam cylinder, the roller is set in motion, and the pencil then describes a neutral line, which repre- Digitized by Google 552 ENGINES, RULES FOR CALCULATING THE PARTS OF. sents the pressure of the atmosphere-any vertical ordinate above this being the steam pressure above that point, and any vertical ordinate below, the pressure below it. If the connection between the indi- cator and the cylinder be now formed, while steam is entering the cylinder, the piston of the indicator will rise; and, if steam is escaping from the cylinder, it will fall; the extent of rise and fall being reg- ulated by the spiral spring, which yields more as the pressure becomes greater. The vertical motion of the pencil, combined with the circular motion of the roller, will form a curve more or less regular, the vertical ordinates of which represent the values of the steam pressure and vacuum during a com- plete stroke, measured by the scale which is marked upon the roller clasp. The graduation of this scale depends upon the strength of the spring s, which forces the piston down when the steam ceases to force it up; because, the stronger the spring is made, the smaller is the distance through which steam of a given force will compress it by raising the piston. The alternate motion of the roller is given by connecting it with any reciprocating part of the engine, such as the parallel motion, by means of a cord attached to the pulley a, which is fixed upon the same axis as the paper roller d. This cord gives mo- tion in one direction, and the return motion is received from a spring m, which is coiled up like a watch- spring; l is a guide pulley for changing the direction of the cord when it passes from the pulley a; it is not shown in its place except in the bottom plan, where part of it is dotted in. Let us now suppose the engine to be in motion, and the stop-cock of the indicator closed. If the cord be drawn out by hand, or connected with the engine, the pencil pressing against the paper will describe the horizontal line representing the atmospheric pressure; and if, when the piston is at the top of its stroke, the indicator stop-cock be opened, it will commence its registration. When the steam be- gins to rush into the cylinder, it will, of course, also press upon the piston of the indicator, which it will raise, and with it the pencil; and the roller, with the paper upon it, being moved by its connection with the engine, a line will be traced upon the paper, which rises higher up on the cylinder as the pres- sure of the steam increases, and comes lower upon it as the steam pressure subsides. The area of the curve traced out by the pencil, therefore, represents the pressure on the piston through all its variations, and, when multiplied by the number of strokes, represents the power exerted by the engine. This power has no connection with the nominal horse power, which is determined by the dimensions of the engine, and which does not vary with variations in the pressure of the steam; but it is the effective power, or the power actually exerted. The indicator, however, not merely tells the amount of power exerted by every stroke of an engine, but the nature of the faults by which the power is impaired. A particular form of the indicator dia- gram shows that the ports of the cylinder are too small; and the indication in such a case obviously is to enlarge them. If the valve be wrongly set, the indicator will explain the nature of the imperfection, and its adjustment then becomes easy. By the indicator too the amount of power consumed by each of the several mechanisms of a factory may be determined, and the relative values of different oils fixed that may be employed for the lubrication of the shafts. If, for example, it is wanted to know the amount of power consumed by a fan or a saw-mill that may be driven by the engine, the machine in question has only to be put in connection with the engine, while all the rest of the machinery of the factory is cast off; and if the indicator be applied to the engine, the amount of power consumed in dri- ving the one machine will be determined; and then it will be found, by taking another diagram, with all the machinery on, what proportion this part bears to the total power. In testing the quality of oils, if it be found that the engine requires more power to drive the shafting with one kind of oil than with another, that which involves the largest expenditure of power is, of course, the worse. To read off the indications of the indicator is a thing every one may do after the foregoing explanation. The pencil describes a curved line inclosing a space. Across that space any number of lines may be drawn at right angles to the atmospheric line. The lengths of the lines are then measured on a scale, and their mean taken, which mean represents the power exerted. The indicator is an invention of Watt's, but it does not very clearly appear who it was that first applied the pencil to trace a curve. The applica- tion was, however, first made at Soho, probably by Mr. Southern or Mr. Creighton. Continuous indicator.-A continuous indicator is an instrument that will not merely ascertain, but also register the work done by an engine during any given period, whereby the performance of one engine may be compared with the performance of another, to the end of ascertaining which is the most economical in fuel. In Cornwall this object is accomplished by means of a counter, which merely reg- isters the number of strokes made by the engine; but this expedient will only answer where the load upon the engine is constant and easily measurable, and becomes of but little avail in a steam vessel, where the load is continually varying. The invention of an instrument of a simple kind, that will re- cord the varying power of the engine under all circumstances of speed and variation of expansion, be- comes an object of no trivial importance, when it is recollected that such an instrument is indispensable to the success of any effectual scheme of registration. This chasm has now been filled up by W. H. Linslay. By registration we mean the determination by an authorized person of the power exerted by steam vessels, or, in other words, the work done in relation to the fuel consumed, and the publication of these results obtained from a large number of steam vessels at regular intervals; 80 that it may appear on the face of a table suitably drawn up what steam vessels are the most effectual. These published tables would, therefore, be identical in all their main features with the tables published in Cornwall by the Messrs. Lean; and indeed the measure we propose consists in the extension to steam vessels of the system of registering the duty of engines pursued in Cornwall, and which has produced such beneficial effects in that district. The best proof of the saving in fuel derivable from the plan of registering the duty of steam-engines consists in an enumeration of the wonders it has already done; and we find that the amount of work performed in Cornwall by a bushel of coal, represented by 20,000,000 in 1815, had arisen to 60,000,000 in 1843. Nor is this a solitary case, but, on the contrary, it is the average duty of all the engines regis- tered at the two periods, 80 that the expense of fuel to do the same amount of work is at present only one-third of what it was in 1815, and we think we may add only one-third of what it would have been Digitized by Google ENGINES, RULES FOR CALCULATING THE PARTS OF. 553 now, had the plan of registration not been adopted. The Messrs. Lean have drawn up a table which makes the value of this system very conspicuous, and from which it appears that the Cornish mine owners are now saving about £85,000 per annum in their limited operations, by the simple expedient of registering and publishing the duty of their engines. Such a practice puts all the engineers upon their mettle, and induces an emulation out of which improvement cannot but spring; and at the same time it stimulates all engine attendants to a more sedulous attention, as any negligence on their part will be sure to tell to their disadvantage. If such a saving can be realized out of the contracted sphere of Cornish engineering, what a magnificent result might not be realized by the application of the plan to the innumerable steam vessels of this country ! Yet the saving in the cost of the coal in the case of steam navigation, important as it would be, is not the greatest benefit of such an economy the powers of steam navigation would be prodigiously increased, and its profits correspondingly augmented, by any improvement by which the quantity of coal carried was materially lessened for steam vessels could then go farther without a relay of coal, or could carry more cargo, and the growth of our steam marine would just be in proportion to the extension of the limits which now hinder its development. It is needless, however, to dwell much on the advantages of the system of registration, as they must be conspicuous enough to every one who gives attention to the subject. Professor Moseley professes to have invented an indicator of the continuous kind, but it is far too complicated for ordinary practice; and as some of the parts drive the other parts by friction surfaces, which are apt to slip should a little oil chance to fall upon them, its indications are correspondingly uncertain. A suitable indicator being obtained, every steamer of any pretensions should be provided with one, and an inspector should then be appointed, in whose skill and honesty all parties have confidence, and whose business it should be to examine the indications of the several instruments, and make up from thence tables of the perform- ance of each vessel, which should periodically be published. The quantity of coal consumed could of course only be got at by a reference to the coal accounts of the several vessels; and it would be a good thing if those coal accounts were all kept upon a uniform plan to facilitate the discovery of this ele- ment. A continuous indicator of a very complete description was some years ago brought under the notice of the British Association by Dr. Lardner, though its expense and complication were too great to war- rant its introduction in practice. A web of paper was wound upon a small brass drum, and a larger drum, which was put into revolution by means of clock-work, wound the web of paper off the small drum on to itself. At suitable distances round the larger drum pencils of different colors were placed, which were acted upon by floats placed in siphon tubes of mercury, to which the steam-pipe, condenser, dec., were respectively connected. When the pressure of steam in the boiler varied, the pencil attached to the float in the siphon gage communicating with the boiler was elevated or depressed correspondingly, and traced a line upon the drum above or below the right position. At the termination of the voyage the paper was taken off and translated into words, and the difference in the colors of the different pen- cils prevented the lines made by each from being confounded with any other. There was more trouble connected with the use of this instrument than engineers would willingly take, and more expense than the proprietors of steam vessels would willingly incur, added to which it took no satisfactory cognizance of any variation in the degrees of expansion, though that is the most important of the elements demand- ing registration. Counter.-The counter is an instrument with wheelwork 80 contrived, that, by every stroke of the engine, an index hand is moved a certain distance forward, so that it registers or counts the number of strokes made by the engine during any given period. The construction of the counter varies very much: in most cases, however, the wheels are moved round by a pendulum attached to some vibrating part of the engine, the wheel being carried on one tooth by every vibration. Some of the French counters are extremely neat and portable, being much like a pedometer watch in size and appearance. A very ele- gant counter for locomotive engines has been contrived by Mr. Adie: an endless screw works into the rim of two small wheels, situated on the same axis, but one wheel having a tooth more than the other. A differential motion is thus obtained, of great slowness, for the wheel with the additional tooth will only move slightly more slowly than the other wheel, and the result is indicated by the difference of the two speeds. The end of the screw is attached to a revolving part of the engine, by means of an appropriate fastening, and the wheels hang down like a pendulum from it, and do not turn with the revolving part in question, 80 that the wheels are turned on their axis by the screw, without any thing of the nature of reciprocation. The counter was first introduced by Mr. Watt, and was attached by him to the Cornish engines for the purpose of showing the proportion of savings in fuel due to him from the application of his improved engine; and in the case of those engines which were uniformly loaded, the counter afforded a correct indication of the power exerted. The number of strokes of the engine multiplied by the capacity of the pump, and the height through which the water is raised, will give a quantity representative of the engine power; and in the case of pumping engines, the indications of the counter will enable us to determine the duty, the registration of which has in Cornwall been productive of such beneficial effects. Dynamometer.-In screw vessels the forward thrust of the screw has been measured by a dynamo- meter, an instrument constructed on the principle of a weighing-machine, in which a small weight or spring pressure at the index will sustain a much greater weight or pressure at the other end. In the Rattler screw steamer the forward thrust of the screw, as determined by the dynamometer, was found to be about four tons, and it was also found that when a piece of paper was drawn slowly along be- neath the index, a pencil attached to the index described upon the paper a serrated line showing great fluctuations of pressure in the different positions of the screw. The greatest thrust is when the screw blade is in a line with the stern post. A dynamometer has also been employed in Woolwich dockyard to test the tractive force of paddle-wheel steamers. Morin's dynamometer is usually employed for as- certaining the resistance of railway trains. It consists substantially of two blades of steel, the flexure of which indicates the resistance. 70 Digitized by Google 554 ENGINE, VARIETIES OF THE STEAM. ENGINE, VARIETIES OF THE STEAM-Condensing and high-pressure enginea-Steam-engines of every kind are divisible into two great classes-high-pressure engines and condensing engines. Con densing engines are sometimes also worked with a high pressure of steam, and the distinctive appellation of high-pressure engines is applied to engines of which the steam is not condensed. All locomotive engines are of the high-pressure variety; and generally all engines are made on the high-pressure plan, where the carriage of condensing water would be inconvenient, or the first cost of the machine becomes a point of more importance than an increased consumption of fuel High-pressure engines are neces- sarily more expensive in fuel than low-pressure engines, as they occasion the loss of the power derivable from a vacuum; and as the quantity of heat in the same weight of steam is nearly the same at all pressures, there is no countervailing source of economy to compensate for this deduction. Where high- pressure steam is employed, it is expedient to make the pressure considerable. as the deduction to be made for the pressure of the atmosphere is less in proportion, with a high, than with a moderate pressure. Some locomotive engines are worked as high as 90 pounds on the square inch. The pumping engine.-The pumping engine, as arranged by Watt at an early period of his career, and the modern pumping engine, differ from this primitive type only in a few details of secondary impor- tance; excepting, however, the use of steam of a higher pressure, and the larger employment of the principle of expansion, by which a greatly increased economy of fuel has been realized. All the Cornish engines are furnished with a steam-jacket to the cylinder, and, in some cases, a flue winds spirally round the jacket, carrying hot air from a small fire in the engine-house, to maintain the temperature of the steam unimpaired. Where this is not done, the cylinder is encased in a large jacket, filled with some non-conducting substance, or is covered with wood. In most pumping engines one end of the beam is made longer than the other, the intention being to enable the cylinder to have a long stroke, without communicating such a velocity to the pump buckets as will make them strike hard, and wear themselves quickly out. One advantage of a long stroke is, that high-pressure steam may be used without being obliged to make the parts inconveniently strong for the principal parts of the engine have to be made of the same strength whatever be the length of the stroke, and to increase the diameter of the cylinder, to compensate for shortness of the stroke, involves the necessity of a strong and expensive engine. Woolf's plan of employing two cylinders is sometimes used as an alternative remedy, and in some recent engines the plan has been much simpli- fied, by placing the small cylinder on the top of the large one, and working both with the same piston-rod; although there is less irregularity in the impelling force, there is greater complexity in the machine, 80 that a long stroke with an unequal beam appears to be a preferable expedient. The pump valves of engines working high lifts are a continual source of trouble and expense, and many expedients have been contrived to abate the shock and tremor caused by their rapid closing. Of these, the best is probably the valve known as Harvey and West's, which is, in all its material features, identical with the balance valve. This valve presses down with very little force, and an annular recess is frequently made in the pump bucket, which is filled with end-wood, on which the valve falls. In some engines canvas valves are used even for the air-pump of engines which are intended to work at a high speed-in some cases with good effect; though in others, probably from the employment of an inferior quality of canvas, the valves have worn out very quickly. The bucket consists of a metal disk, perforated with a large number of small holes, and these holes are all closed by a canvas disk, which rises and falls like a common pot-lid valve; with the exception that it is bound down at the eye, and the edges only left. India-rubber has been tried as well as canvas, but it sinks too much into the holes, and has not answered 80 well. If there be any case in which the use of an engine beam can be excused, it is in the case of a pumping engine; direct action is so inconvenient and precarious over the mouth of a mine. The main beam rests on a wall of masonry near the mouth of the mine, as may be seen by a reference to the plate of a " Cornish pumping engine." At the one end of the beam is the cylinder, and at the other end the pump- rod, which penetrates into the mine. From the pump-rod end of the beam the rods for working the air- pump and feed-pump are suspended. The air-pump is shown in dotted lines, and beyond it appears the condenser, situated in the cold-water cistern, with a valve attached to the end of a curved pipe, for admitting the injection water-the valve being wrought by the cataract which stands beneath the valve geering. A rod passes through the end wall of the house, for adjusting the position of the centre of the radius-bar of the parallel motion. The cylinder end of the beam is armed with catch-pins, which strike on the spring beams stretching from the lever wall to the end of the house, if the piston proceeds down 80 far as to endanger the cylinder bottom. The feed-pump stands on the top of the eduction pipe: the valve geering we have already explained. It is usual in the Cornish practice to make the lowest pump of the series of lifts a lifting pump, and all the others forcing pumps. The plungers of the forcing pumps are more easily packed than the buckets of the lifting pumps, and there is not the same risk of drawing air; but the lowest pump is made a lifting one, to facilitate extensions to a lower level, and also to prevent the pump valves from becoming inaccessible if the water accumulates in the mine. Rotative engine.-We shall not here dwell upon any description of the ordinary rotative or mill- engine, as we look upon it now as a mere piece of antiquity. Marine engine.-The marine engine has now become the most important variety of the steam-engine, not merely on account of the great extension of steam navigation, but because it is fast superseding the ordinary steam-engine, even for land purposes. We shall therefore enter into the consideration of the structure and operation of this engine with considerable fulness of detail, and much of what we say will also be found to illustrate the merits of the other varieties of engine. Paddle-wheels.-If a body moves through a quiescent fluid with a given velocity, or if a fluid moving with a given velocity impinge against a body at rest, the resistance will in either case be as the square of the velocity, while the power requisite to overcome that resistance will be as the cube of the velocity; 80 that if the velocity of a steamer be doubled, the resistance experienced in passing through the water becomes four times greater than before, and the power required to achieve that doubled speed eight Digitized by Google ENGINE, VARIETIES OF THE STEAM. 555 times greater than before. This is explained by the circumstance that the resistance of a body moving in a fluid is proportionate to the number of particles struck and the velocity with which they are struck as twice the number of particles are struck, and each particle with twice the force, there is four times the resistance; and as the strain occasioned by this resistance is four times greater upon the engine, and the engine has at the same time to work at twice the speed, there must be four times the expenditure of power. The absolute resistance which a quiescent fluid opposes to a plane surface moving through it with a given velocity, is equal to the weight of a column of the fluid whose base is the plane, and altitude the same as that which is due to the velocity of motion; that is, the height through which a heavy body must fall to acquire that velocity by the action of gravity. Reduced to a simple Rule, Resistance area X velocity squared X 0.9715. When a fluid impinges upon a plane surface in an oblique direction, it will impel the plane in a direction at right angles to its surface with a force which is proportional to the square of the velocity of motion, the density of the fluid, the area of the plane, and the square of the sine of the angle of inci- dence. The equation for the resistance then becomes- Resistance = area X velocity squared X sine squared of angle of incidence X 0.9715. When a paddle-wheel is first put in motion, every point upon it describes a circle round the centre; but as the vessel begins to move, the forward motion of the vessel being compounded with the rotative motion of the wheel, each point describes in the air or water a curtate cycloid differing from a circle in the proportion of its propinquity to the centre. The speed of the vessel is usually about a third less than the speed of the extremities of the paddle-arms, and a circle, therefore, described on the wheel with a radius of two-thirds the length of the paddle-arm, will travel with the same speed as the vessel passes through the water. This circle, which is usually called the rolling circle, is such, that if the vessel were travelling upon land upon wheels of that size, and with the same speed of engine, her velocity would remain unaffected. As every point in the radius of the wheel moves with a greater velocity as it is further from the centre, it is clear that the portion of the paddle-board furthest removed from the centre must experience a different degree of resistance from the portion nearer to it; and the mean centre of pressure therefore cannot be at the centre of the float, but at a point nearer the outer edge, and varies also with the angle of the paddle and the depth of the immersion. For light immersions it may be reckoned that the resistance on any point of the paddle-board varies as the 3d power of its distance from the rolling circle; and assuming this, we arrive at the following rule: From the radius of the wheel subtract the radius of the rolling circle; to the remainder add the depth of the paddle-board, and divide the fourth power of the sum by four times the depth; then from the cube root of the quotient subtract the difference between the radii of the wheel and circle of rotation, and the remainder will be the distance of the centre of pressure from the upper edge of the paddle. Instead of the common radial paddle-wheel, a description of wheels with moveable floats, known as Morgan's wheels, are now much employed, though they were for many years regarded with disfavor. In this wheel each paddle. which is of iron, is hung upon a centre in the manner of a throttle-valve, and is connected by a rod to a fixed eccentric, either on the side of the ship, or upon the spring beams which sustain the end of the paddle-shaft. When the wheel revolves, the operation of the eccentric maintains every float in the vertical position, or nearly so, whereby a more perfect action of the wheel is realized than if the floats were fixed, as in the case of the common radial paddle with wooden floats. In considering attentively the action of the paddle-wheel, it will be remarked, that although the cir- cular velocity of the wheel is uniform, very unequal portions of the cycloidal path are described in equal times; for the space described during the first quadrant is more than double that described during the second, and that described during the third quadrant is less than half that described during the fourth. The result of this action is, that the verticle paddle-board, instead of being the most effectual in the propul- sion of the vessel, as might appear on a cursory survey, is the least effectual of the floats immerged for the horizontal velocity of a float, when in the vertical position, is at its minimum point, and consequently in the common radial paddle-wheel both the entering and emerging floats are the more effectual. In the feathering paddle this action is materially modified, and the feathering paddles do not involve the same loss of power. By rendering a smaller diameter of wheel applicable, too, they enable the engines to move at a higher speed, whereby their efficacy is increased a vessel that will go 13 miles an hour with the common wheels, will make a mile an hour more with the feathering wheels, the power of the engines being the same in both cases. The screw propeller.-There is too little yet known respecting the performance and manner of opera- tion of the screw propeller to justify the formation of rules pretending to regulate the details of practice; but the conviction of the most experienced engineers appears, at the present time, to be, that while for river steamers the feathering paddle is the best propeller, the screw has, at least, established a claim to equality in the case of ocean steamers; while as a propeller for vessels fitted with auxiliary power it has an undisputed superiority. For vessels of war the screw has the manifest recommendation, that it is less exposed to shot, and the whole of the machinery for driving the screw may be placed under the water-line, which is not possible in the case of paddle-wheel steamers. The form in which the screw propeller was first applied to the Archimedes steamer consisted of a broad helical feather attached to a cylindrical axis, driven by the engine, and which, working in the water in nearly the same manner as a carpenter's screw works in a piece of wood, carried the vessel forward in the direction of its length. The helical feather made & single convolution round the axis, the length of the convolution being regulated by the pitch of the screw but this arrangement was relinquished, as it gave a vibratory motion to the boat, interfered with the action of the rudder, and threw the strain too much on one side of the axis; and two half convolutions of a double-threaded screw were adopted, instead of the whole convolution of a single-threaded screw. In later applications the screw has been Digitized by Google 556 ENGINE, VARIETIES OF THE STEAM. made much shorter than what answers to half a convolution; about one-sixth of a convolution is now a common proportion. In the Great Northern, the area of midship section at 16 feet draft of water is 540 square feet, while the screw contains about 90 square feet, deducting the area of the boss. The speed of the vessel is nine statute miles an hour, and the slip of the screw is one-tenth. If, when the vessel is at rest, the engine causes the screw to revolve on its axis without advancing forward in the water, every point of its surface will describe a circle, the magnitude of which is propor- tional to the distance of the describing point from the centre of motion. It is clear the surface of the screw will strike the water with a force that is due to the velocity of motion, and the water will be impelled in a direction at right angles to the surface, with a velocity corresponding to that of the revolving feather, but varying in proportion to the distance of any particular point from the axis. This is the force that is effective in propelling the vessel, and it will be seen that it is greater, at a greater distance from the centre, decreasing gradually as we approach the axis where the velocity of the revolving surface is small. On the other hand, if the vessel moves forward in the direction of its length while the screw is prevented from revolving on its axis, every point on the surface of the projecting feather will trace a straight line, equal in length to the distance passed over by the vessel or, in other words, the screw, in being pulled forward, will displace a cylinder of water of its own diameter and of the length of the vessel's motion, occasioning, of course, a waste of power in the operation. When the screw is put into action by the engine, both of these resistances are encountered. If the action of the propeller were perfect, the screw would operate as if working in a nut; and as there would be then no loss by slip, we could ascertain the speed of the vessel by multiplying the number of revolutions by the pitch of the screw, and dividing by 88, which would give the speed per hour in statute miles; but in practice the speed is generally from one-tenth to one-twentieth less than the speed thus ascertained. There is not an invariable loss by slip, however, or at least not an apparent loss, for in some cases, the vessel is propelled at a faster rate than if the screw worked in a solid. One cause of this anomaly probably is, that the water, in closing in upon the wake of the vessel, having a motion given to it, the screw impinges, not upon still, but upon moving water, whereby an increased reaction is obtained; but something depends too upon the size of the screw, and in general it has been found that when the superficial area of the screw, taken as a disk, is about one-fourth of the area of the immersed section of the vessel, the speed will be as great or greater than if the screw was working in a solid. The water partakes very little of the rotatory motion of the screw, but is drawn in on all sides from the circum- ference towards the centre, and is then projected aft in a column slightly conical, as it recedes from the screw. The pitch of the screw, or the angle at which the blades are set, differs necessarily with the form of the vessel and the power of the engine; or, in other words, with the speed expected to be at- tained a common enough angle is from 66 to 68 degrees with the axis. In settling the dimensions and pitch of screw proper for any particular vessel, the first indication is to make the diameter of the screw as large as it can be got; and then the probable speed of the vessel, judging from the power and form, is to be estimated, which, after fixing the number of revolutions and making an allowance of say one-tenth or one-twelfth for slip, will give the pitch of the screw. Most of the screws now used are made with two threads, or have two blades. Screws with three blades act more equably, as the whole of the blades are never in the line of the stern-post at once, at which point the forward thrust is greatest; but double-threaded screws seem upon the whole to be the most effective, and they may, if necessary, project beneath the keel, as they can be turned into the horizontal direction when the vessel is in harbor, to prevent them from touching the ground. To ascertain the amount of helical surface of a screw making one convolution, multiply the sum of the radii of the screw and of the central boss by their difference, and the product will be the difference of their squares: mul- tiply this number by 31416, and the product by the secant of the angle of the screw, and the result will be the area of the helical surface sought. Bourne's double-power engine.-The screw propeller has created a new exigency in steam me- chanism. The propeller generally requires to make a greater number of revolutions than the engines can conveniently perform; and cog-wheels have in many cases been introduced to bring up the speed, thus introducing into steam vessels the jar, tremor, and liability to fracture incidental to the use of such devices. To remove this source of objection it is necessary that the engines should be coupled direct to the propeller shaft; but as the valves of the air-pumps would strike 80 hard as to knock themselves to pieces if the engines were worked at any very high speed, and as the various contrivances of canvas and India-rubber valves are of doubtful efficacy in such an emergency, Mr. Bourne has contrived a species of engine in which the whole of the air-pump valves are replaced by a particular arrangement of slide- valve, whereby the engine may be worked at any degree of speed without inconvenience. One effect of this innovation is to make engines work more noiselessly than before, as there is no longer any shock, such as that which attaches to the action of the foot and delivery valves and the valves of the air-pump bucket in common engines. But the most important feature of the arrangement is, that by enabling the engines to work at twice the ordinary speed, it enables them to exert twice the ordinary power. It is not for screw vessels alone, therefore, that such engines are appropriate, but they may be applied with advantage to most of the purposes for which steam power is required. In the case of mill engines they possess the recommendation of imparting a more equable motion to the machinery, and in other cases they may be 80 arranged as to save fuel by permitting a larger expansion than could be allowed with a lower speed. The boiler of the double-power engine is for the most part constructed with upright tubes, and the engine set upon the boiler in all powers under 40 horses. The following are the chief dimensions of a one-horse power engine and boiler :-Diameter of boiler, 16 inches; height of boiler, 40 inches; diameter of furnace at crown-plate, 12 inches; diameter of furnace at bars, 13 inches; height of crown-plate above bars, 12 inches; depth of fire-bars, 2 inches; depth of ash-pit, 4 inches; depth of smoke-box, 4 inches; diameter of chimney, 3 inches. There are 36 tubes in the boiler, 1 inch in diameter, and 16 inches long. but 12 inches in the length of tube only passes through the water, and is alone counted as Digitized by Google ENGINE, VARIETIES OF THE STEAM. 557 effective: the thickness of the shell of the boiler is three-sixteenths; and the pressure the boiler is cal- culated to bear is 80 pounds, though 70 pounds is the working pressure. The diameter of the cylinder is 2 inches; length of stroke, 3 inches; number of revolutions per minute, 872; number of feet travelled by the piston per minute, 436; and though these dimensions are small, that they will give fully a horse power is made manifest by a simple calculation. The area of a cylinder 2 inches in diameter is 3.1416; and if the effective pressure be taken at 60 pounds per square inch, instead of 70 pounds, (as a com- pensation for friction and loss of effect from radiation and expansion,) we have a force of 1881 pounds urging the piston at a speed of 436 feet per minute, which is equivalent to 82,184 pounds raised one foot high in the minute; and dividing by 33,000, this gives us about 21 horse power. On calculating the amount of tube surface, it will be found to amount to 12 square feet, and the furnace surface will amount to about sh square feet more, making a total of 151 square feet of heating surface per horse power, which is a large allowance. The weight of the boiler is about 24 cwt., and the total weight of engine and boiler, with water in the boiler, is about 41 cwt. Of the 40-horse power engine and boiler on the double-power plan, the following are the principal dimensions :-Diameter of boiler, 4 feet 8 in. height of boiler, 8 feet; diameter of furnace at crown-plate, 4 feet; diameter of furnace at bars, 4 feet 1 inch; height of crown-plate above bars, 20 inches; depth of fire-bars, 4 inches; depth of ash-pit, 8 inches; depth of smoke-box, 12 inches; diameter of chimney, 12 inches. There are 547 tubes 1 inch diameter, and 52 inches long, of which a length of 34 inches only passes through the water, and is alone reckoned as effective. The thickness of the shell of the boiler is half an inch, and the plates are all double riveted; the pressure which the boiler is calculated to with- stand is 80 pounds. The diameter of the cylinder is 12 inches; length of stroke, 18 inches; number of revolutions per minute, 195; number of feet travelled by the piston per minute, 586. The area of a cylinder 12 inches in diameter is 113.097 square inches; and if we take the effective pressure as before, at 60 pounds, we have a force of 67858 urging the piston at a speed of 586 feet per minute, which is equivalent to 3,976,490 pounds raised one foot high per minute, which, being divided by 33,000, gives 120 horses' power, which is just three times the nominal power. The weight of the boilers is about 611 cwt.; and the total weight of engine and boiler, with water in the boiler, is 90 cwt., or 21 cwt. per horse power. The engine is of the oscillating kind, and the shaft, crank, and framing for supporting the crank, are all of polished malleable iron; the fly-wheel is very small, and is made with a polished rim, which also answers for the drum upon which the belt runs that carries away the power. The governor is made in the usual manner. The waste steam passes into the chimney, as in locomotive engines, whereby the draught is 80 quickened that a small area of grate-bar suffices; but the end of the eduction pipe entering the chimney is never contracted, as in locomotives. In the larger class of engines a platform is attached to the boiler, to make the engine accessible to the engine-man, thus obviating the necessity of any peculiar structure in the engine-house. Galloway's direct-action engine.-This engine consists of two steam cylinders, the piston and rods of which are attached by suitable links to a main cross-head or beam, connecting both engines; forming a part of this cross-head are two triangular frames of wrought-iron, which, serving the double purpose of side-rods and connecting-rods, descend one on each side of the cylinders, and they are connected imme- diately with the cranks on the main shaft, lying between the cylinders in a line with the keel of the vessel. The air-pumps are worked by the same arrangement of levers which forms the parallel motion for the piston-rods; the hot water and bilge pumps are wrought by the air-pump cross-heads in the usual way. The main shaft gives motion to the screw shaft through the medium of a new multiplying geer. The engines are of 300-horse power, and every part of them is below the water line of the vessel. There is extraordinary ingenuity in the whole of these arrangements; nevertheless this engine has not come into use. The mode of operation of the multiplying geer is not easily comprehended, but the principle of the arrangement may be explained to consist in such an arrangement of two cranks, of which the one is twice the length of the other, that the movement of the crank-pin of the longer crank through a semicircle will cause the crank-pin of the smaller crank to move through a whole circle. The prin- ciple, however, will be made more clear by an extract from Mr. Galloway's specification, which we therefore introduce. 1473. 1474. 1475. 1476. CO If the wheels shown in Fig. 1474 revolved upon axes in the usual way, a would make an entire revolution, whilst b made only some portion of a revolution; but if b, instead of revolving upon an axis, be suspended upon three cranks ccc, of equal length, and the radii of which are respectively equal to one-half the difference between the diameters of the wheels, (calculating such diameters from the pitch- lines and if the whole apparatus be at first in the position indicated by the drawing, thereby causing a to revolve, it will be found that the cranks c, and consequently their axes, will make three revolutions during the time that the inner wheel a makes one revolution. So if the proportionate diameters differ, say as 2 to 8, or 4 to 5, or any other integral proportions, and the lengths of the cranks c be deter- mined, then the cranks will always make as many more revolutions than the axis of a, as the diameter of the driving-wheel a is to the difference between the diameter of the two wheels. Digitized by Google 558 ENGINE, VARIETIES OF THE STEAM. But I propose, in most cases, as I have stated, instead of using toothed wheels, to adopt the arrange- ment shown in Figs. 1474, 1475, and 1476, which I shall now explain :-Let it be supposed that three equidistant points, ddd, Fig. 1473, could trace their path upon a plate or disk, attached to b, and moving therewith, such path would be four epicycloids dotted thereon; and if to the points ddd, three rollers, of equal diameter, were affixed, then a figure, eece, Fig. 1474, would be the tangent of the said rollers in every part of their path; or, in other words, the rollers would trace out the figure eeee, Fig. 1474; such being the case, it will be manifest that if, instead of toothed wheels, we adopt the arrangement shown in Fig. 1474, where ddd are the three rollers, affixed to arms, and revolving in bearings, and the figure eee, whose interior curved aperture is generated upon the principle I have explained-then, on motion being given to the main axis, the cranks, dotted at cc, will make three revolutions for one of the main axis; and if the figure be accurately constructed, and the cranks truly proportioned, the action of the machine will be comparatively smooth and noiseless. In like manner, if the circles or wheels a and b be in their diameters as 2 to 8, the figure fff, Fig. 1475, would be generated, and by attaching the two rollers to the axis, as there shown, the velocity of the main axis would be to the crank axis as 2 to 1; or, if the diameter of a and b be as 4 to 5, the figure Fig. 1476, would be generated, and by constructing the apparatus, as shown at Fig. 1476, the relative velocities of the main axis and crank axis will be as 4 to 1. I would further observe, that in whatever proportion the multiplication be effected, it is necessary that the number of the rollers and of epicycloids should be respectively equal to the number of times the generating circles can be divided by the difference between the two diameters. It will also be manifest, that the multiplication effected by this method does not admit of fractional quantities, but must always be in integral proportions. I must further explain, that if one propeller only is intended to be used, one only of the three crank axes must be pro- longed for that purpose; but if two propellers are intended to be applied, then two of the crank axes should be similarly prolonged. It is further necessary to explain, that the arrangement of this con- trivance may be changed by attaching the driving axis to the epicycloidal figure, and the cranks to the part to which the rollers are attached; in which case the proportion of the multiplication will also be changed, so that the cranks of Fig. 1474 would make three revolutions instead of two; those of Fig. 1475 would make four revolutions instead of three; and those of Fig. 1476 would make five revolutions instead of four." This method of multiplying the speed of the screw-shaft, though most ingenious, is likely to be rendered needless by the acceleration of the speed of the engine itself which is now taking place. Direct-action enginea-Direct-action engines have of late years come into extended use in steam vessels, and their employment appears likely to become universal. They are less bulky and less weighty than side-lever engines, and although most engineers resisted their introduction, these engines have now, even in the engineering world, risen to considerable favor. Most of the early devices were crude and unsatisfactory, but the excellent performance of the oscillating and double-cross-head engines have redeemed the class from the disgrace that might otherwise have been expected to overtake it. The existing crop of direct-action engines is divisible into five varieties the Gorgon, Siamese, Steeple, Double-cross-head, and Oscillating. Many nautical men, and some engineers, have objected to oscillating engines on account of the move- ment of the cylinder, which they imagined would become a formidable evil in the case of a vessel roll- ing heavily at sea. These objectors do not seem to have remarked that the rolling of the cylinder is neither dependent upon, nor proportionate to, the rolling of the ship, but is regulated exclusively by the movement of the piston; and it is difficult to see why a mass of matter, in the form of a cylinder, should be more formidable or intractable in its movements than a similar quantity of matter in the form of a side-lever, or in any other shape whatever. It has also been objected against the oscillating engine, that the eduction passages are more tortuous than in common engines, so that the steam gets out of the cylinder less freely. We do not believe such to be the fact, if the comparison be made with the com- mon run of marine engines; and in practice, no diminution of efficacy from this cause is appreciable. The fact is, all the objections that have been raised to the oscillating engine are merely hypothetical; they are anticipations of defects to be found out in large engines on the oscillating plan, and would prob- ably be plausible enough to carry some weight, were it not the fact, that they have been completely controverted by experience. The remark, indeed, is heard sometimes even yet, that the oscillating method may do very well for small engines, but is of doubtful efficacy for large ones. But the defini- tion of large engines has been continually changed. to escape the contradiction experience afforded, and that size is, in every case, decided to be large, which just exceeds the size of the oscillating engine last constructed. The grounds of this skepticism, however, are now being fast contracted and, indeed, ex- perience has now demolished every objection that theory had raised. Some persons have apprehended that it would be difficult in large oscillating engines to obtain sufficient surface of trunnion to prevent the trunnions from heating; yet we have never been able to learn that any heating of those bearings has been found to occur in practice, and it appears probable that any such disposition would be resisted by the cooling effect of the steam passing through them, which, though hot, is of greatly inferior tem- perature to that of a hot bearing. It does not appear to us, however, that the trunnions may not be made with any amount of surface that is thought desirable. Rotary engines.-Rotary engines are engines for obtaining a motion round an axis by the direct action of the steam, without involving the necessity of reciprocation. Some of them operate on the principle of reaction, others operate on the principle of impulse; a third kind trusts to the intervention of some liquid to produce the desired effect. It cannot be said that any one of the multitude of rotatory engines yet tried has been completely successful. It is, of course, impossible that we can give any enumeration, even, of the numberless schemes for rotatory engines that have at various times been pro- jected, but we shall briefly describe a few of those which have attracted the most attention. A rotary engine, designed by Hornblower, is represented in Figs. 1477, 1478, and 1479, and con- sists of a steam vessel made of cast-iron, of the form of a globe, flattened at the poles. Fig. 1479 is a Digitized by Google ENGINE, VARIETIES OF THE STEAM. 559 representation of the parts of the machine which move round within the steam vessel, and Fig. 1478 represents the interior of Fig. 1477, with its lid removed. The pipe A, Fig. 1477, receives the steam from the boiler, to which is connected a valve-box, of any usual construction, by which to regulate the admission of steam. At B the eduction pipe is connected, leading from the upper apartment to the condensing apparatus, and turning in such a direction as may be most convenient for the discharging pump to be wrought by the axle of the engine. DD is a middle part of the steam vessel, furnished with flanges for the purpose of screwing it to EE, and also for receiving the lid; by which means the partition within is secured to its place in the middle of the machine; and the lid may easily be removed for the purpose of rectifying and repairing the internal structure. G is the square part of one end of the axis of the machine, over which is placed a gland H, divided into parts, in order that it may be put on over the square, and properly embrace the round part of the axis. Within this gland is a stuffing- box, for the purpose of keeping the axle both air and steam tight. In one side of the lower apartment of the steam vessel is a small opening, secured by a lid, for the purpose of cleaning that part of the machine. Fig. 1478 represents the partition within the steam 1477. vessel, which may be made either of brass or iron, or of both those metals combined. BB is the lower flange, the upper part being taken away. CC are the two openings or passages for the vanes: these the E. inventor calls vane-ports; and to reach a right concep- tion of their figure, it may be explained, that the largest vane-port is formed by the exterior portions of D B two cones, and by a portion of the concave part of a sphere. The extent of this passage throughout must at least be equal to ninety degrees of a circle, and the vanes must be of a sufficient width for two of them always to make their entrance into the vane-ports before the other two make their exit. The edge may, therefore, be supposed to descend into the lower apart- ment one-half of its depth, and to rise the other half to meet the eye. The part E is formed spherically, and is G 1478. provided with a packing groove, which meets the edge of metal in the middle of the vanes. FF is the main axle of the machine, as well as the descending vane, by which means both the nave and the vanes move steam- @ tight in their revolutions. VVVV is that part of the V partition which forms a plane at the axis of the globe, and is secured in its place by being seated in a rabbet with the usual jointing materials on the interior margin o C of the steam vessel. Two brasses, G G, are let down B into the partition, and they are raised or depressed by screws, as occasion may require. The open vane ex- hibits a frame of metal, which receives a plate on each K side: these plates, with the edge of metal K, cast with the frame, form grooves and vacuities to receive the 0 packing. Mr. Samuel Clegg's patent for a rotary engine is re- 1479. presented in Figs. 1480, 1481, and 1482. Fig. 1480 is the under side of a circular piece of S cast-iron, and of a diameter and thickness propor- F tioned to the size of the engine. I is the common centre of the different circles shown on this piece. With any convenient radius less than that of A A, describe the circle CC, and within the latter the cir- cles DD and EE, the radius of the latter being the least of those now named. From the uses of these parts, which will be immediately described, an idea of their relative dimensions will readily be inferred. Let that part of the surface AB, AB which is con- tained between the circles A and C, be plain. Be- tween the circles C and D sink a circular groove CD of any given depth: and between the circles D and E let another circular groove be cut, of the breadth DE, and of any given depth less than that of the groove CD. Let the remaining part of the surface A B, namely, that included between E and B, be cut down to any depth less than the depth of the groove DE Into the groove CD let such a num- ber of segments of a circle be fitted as shall form a complete circle, excepting the space at L, which is occupied by adjusting screws or springs, to keep the segments close together. The segments are the breadth (or nearly) of the groove CD, and of a depth less than that of the groove CD. Those sides of them which apply to each other are to be ground together plain, and air-tight if possible. Their under- surfaces, which are shown in Fig. 1480, are to be flat, 80 that the whole may form one complete plain surface, excepting the space before mentioned, which is taken up by adjusting screws or springs L, which screws or springs are placed so far below the surface as to let & roller pass by them, which will be mentioned hereafter. Fig. 1481 represents a vertical section of the plate and grooves of Fig. 1480, resting upon a circular Digitized by Google 560 ENGINE, VARIETIES OF THE STEAM. chamber or hollow space Y Y, to which chamber the said plate forms a light covering, excepting that space occupied by springs or screws LL, as before mentioned. I, the centre of all the grooves and circles before described, is also the centre of the shaft. On the shaft I is fastened a plate or coupling Z, in which is inserted a bar F. This bar may be of any given breadth, but in depth must be less than that to which the circle EB was cut below the surface AB. To this bar is attached a wheel or roller G, shown in Fig. 1482. The manner in which it is attached to the bar F is also there seen, and it is so attached to it that the top of the wheel or roller G shall always be higher than the top of the bar F. The wheel G being attached to the bar F, will, when the bar is made to revolve, describe a circular path H HH, along the plain surface of the segments before described. c is the condenser, a the air- pump, b the air-pump bucket, d the hot well, e the foot-valve, ff the cam which works the air-pump, and r a roller resting thereupon. Let that portion of the plain surface of each segment, which answers to the path of the roller G, be rounded off in such a manner as to make that portion of the surface an are of a circle, the convex circumference of which is presented to the roller G. In Fig. 1482, at H, is shown a perpendicular view of one of the segments, rounded off in the manner described, and present- ing its convex circumference to the roller G. There may, likewise, be another roller attached to the bar behind it, to lower down the segments in the same manner in which they are raised by the first roller. Now it is obvious, all the said segments being in their places in the groove D, Fig. 1480, that the roller G, in performing a revolution round the centre I, must travel along a series of convex arcs of circles equal in number to the number of segments in the groove The groove D E is, in fact, a recess in the deeper groove CD, and may, if necessary, be filled with hemp or tallow, or any other ma- terial, which may answer the purpose intended. It must be remembered that Fig. 1480 is a 1480. view of the under side of the machinery. Fig. 1481 is a section of it, supposed to be in its proper R position, resting as a cover to the circular cham- ber Y Y, and the segments resting upon a flat facing 0 0. Each segment projects over the facing 00 on both sides; their projection on one side completes the cover over the hollow chamber, and the other is the rounded surface for the roller to lift them. The facing 00 is exactly, or as nearly as can be, level with the under side of the A plate A B A B, when the plate is on its place, as represented in Fig. 1481 80 that, when the seg- ID ments are all in their places, they complete the semicircular chamber, and fit 80 close on their seats and in the groove, that were the chamber to be filled with any elastic fluid, they would pre- vent its escape, or nearly, excepting where the space is left for the springs or adjusting screws. The use of these segments, which are what the patentee claims as his invention, is as follows :- Conceive a door or valve to be fitted in the hollow chamber at Q, and a piston R, likewise fitted in the chamber 80 as to move round in it, and the bar F made fast to the piston, on the side and in the man- ner represented in Fig. 1480; then, if an elastic fluid of sufficient strength enters the chamber at N, it will press equally against the door-valve and the piston; but the door or valve being immovable, and the piston movable, the piston will be propelled forward in the circular chamber by the elastic fluid. The bar F being fastened to the piston, and the roller G to the bar F, in the manner represented in Fig. 1482; and the roller being in motion with the bar and piston, the roller will lift the segments in suc- cession as it comes in contact with them. The segments before the bar, being by this means lifted, allow the bar to pass; and the operation being the same in all, the bar and piston make a complete revolu- tion. Each segment, as soon as the bar leaves it, falls down by its own gravity, or by springs, or any other contrivance, so that the opening which is made for the bar to pass is closed before the elastic fluid reaches it; the elastic fluid being kept from the opening by the inner breadth of the piston exceeding the outer diameter of each segment. The door or valve is lifted out of the way of the piston, when the piston comes in contact with it, into the opening in the plate at N, a recess being made in that segment which is opposite the door for that purpose; during which time the elastic fluid is shut out, but it enters again when the door returns to its seat, and thus the operation continues. There is much ingenuity in this contrivance: the principle on which the bar is enabled to pass the segments is nearly identical with that introduced by Mr. Clegg into the atmospheric railway, for enabling the piston within the pipe to be joined on to the carriages outside. Our next example is Mr. Turner's rotary engine, patented in 1816. Fig. 1483 is a plan of the en- gine, represented 80 as to show the internal structure. Fig. 1484 is another plan. Figs. 1485 and 1486 are sections, taken through the axis of the engine in different directions. A A, BB, CC, is the cylinder, or external case of the engine, made in two or more parts, which are fastened together with screws, so as to form a circular or annular passage, the transverse section of which is likewise circular, as shown at EE, Figs. 1485 and 1486. The piston F, Fig. 1483, is accurately fitted into this circular passage, and is caused to revolve therein by the pressure of the steam, which is applied behind it, or on the side F, whilst a vacuum is made before it, or on the side G. The piston being connected with a central plate G, which is fixed fast upon the axis or shaft H, the said shaft is put in motion; and by wheel- work I, or any machinery which is best accupted, the power of the engine is communicated to any use- ful purposes to which it is intended to be applied. The means by which the force of steam is made to Digitized by Google ENGINE, VARIETIES OF THE STEAM. 561 produce the rotary motion is as follows:-Two valves or sliders, K and L, are applied at the opposite sides of the annular passage or cylinder EE in the manner represented in Figs. 1483 and 1485. The edge of the central plate G, which has the projecting arm to communicate with the piston, must be made 80 that they can be made to shut up the passage of the cylinder EE, as represented at L, and prevent the passage of the steam through the same, or the slider may be opened, as shown by the detted lines, to allow the piston F to pass freely through the cylinder. This is done by moving it 1481. sideways on its centre 3 out of the eyl- inder, into the box or case M, which IS provided for its reception. The sliders a are put in motion by a communication M from the outside of the engine, 80 that each one shall begin to open as soon as S the piston F approaches it, and shall be Y Y completely opened whilst the piston passes by, and that it shall then descend again upon its seat. NO, Figs. 1483 and 1486, are two passages, through each of which the steam is alternately introduced and withdrawn from the cylinder. The two passages are placed on opposite sides of the centre of the engine, and are provided with valves or cocks, which are adapted to be opened and shut by the action of the machinery in such succes- sion, that when steam is entering from the boiler into the cylinder at one pas- sage, it shall be going out into the open air, or to the condenser, at the opposite passage. The mechanism which actuates the slides K L, and the mechanism which opens the valves for the admission and exhaustion of the steam through the passages N and O, act in concert with each other, and in unison with the mo- tion of the piston F; 80 that, as soon as possible after the piston has passed by T the seat of a slider, the slider shall be f lowered down into its place ready to close the passage of the cylinder behind the piston. The instant the piston has passed by the next opening, the steam 1482. is admitted to flow through it, and act between the slider and the piston, to force the piston forwards in the cylinder by its expansive force. To explain the action of the engine F more clearly, suppose the parts in the G position in Fig. 1483; the slider L is shut, and the steam is flowing, through the passage O, into the space between the slider L and the piston F; at the same 1483. time the passage N is open to the condenser, to exhaust the steam from the remaining part of the cylinder, and to remove the pressure from the front side G of the piston. In consequence, the pressure of the steam acting behind the piston F, puts it in motion in the direction of the arrow, and drives the arm of the central plate before it. The slider K is now in the act of opening, and by the time M M the projecting part of the plate G arrives at its seat, it will be quite open into the box M, where it will remain 8 until the piston F has passed by its seat; it then begins to G descend, and by the time the piston arrives at the opening of the passage N, the slider K will be completely shut and stop the cylinder. The instant the piston has passed over the opening of the passage N, the steam valves are changed by the machinery, so as to admit the steam into the passage N, and also to allow the steam to pass away, through the other passage 0, to the condenser; in consequence, the steam enters the space between N and K, and thus, being behind the piston, drives it still forwards towards the slider L, which immediately begins to rise by the action of the machinery, and as soon as the projecting part G of the central plate approaches it, it will have retreated into the box M, leaving the cylinder free for the 71 Digitized by Google 562 ENGINE, VARIETIES OF THE STEAM. passage of the piston. Immediately after the piston has passed, the slider L descends again, and gets settled to its place by the time the piston arrives at the opening 0; and the instant the piston has passed over this opening, the steam valves are changed again; 80 that the steam will be admitted at 0, behind the piston, and act between the slider L and the back of the piston, to force it forwards, which is the same position represented in the figure. By this means the pressure of the steam is always made to act behind the piston, and the vacuum is maintained before it. The sliders K and L are put in mo- tion by levers 9 and 10, which are fitted on the outside of the boxes M, but move upon the same centre pins 3, as the sliders move upon withinside the boxes, the levers being forked, as shown in the figure, to reach on each side of the boxes; and the centre pins 3 pass through the sides of the boxes, and also through both forks of the levers 9, 10, but do not turn round in the holes. To communicate motion from the levers at the outsides of the boxes to the valves withinside, curved rods 11, 11, are carried from the levers through the sides of the boxes M, and jointed to the arm of the sliders; stuffing-boxes are formed round the rods to make tight fittings where they pass through the sides of the boxes M. The ends of the levers 9, 10, are made to be included in an eccentric groove or rein ZY, fixed to the central axis H. The form of this is shown in Fig. 1484, and is such as to hold the sliders shut, except during the time that it is necessary to lift up the same to allow the piston to pass by. To make the sliders fit steam-tight when they are shut, they are made rather larger than the diameter of the cylin- der, and are received in grooves and made round in the inside, and the valves are ground against one of the faces of each of these grooves, so that they will fit tight without any packing. The piston is made of several segments put together, with springs behind them, to throw them out against the inside surface of the cylinder, and it is thus made tight without any packing of hemp. 1484. 1486. 0 I 0 6 c I : II B c C B R 1485. 5 10 9 M 11 M Q Q C L A GL K O We now come to the patent of Joseph Eve, taken out in 1825. Fig. 1487 presents an end section; Fig. 1488 a longitudinal section of this engine. a a are the cylinder and cone, revolving in contact in opposite directions, the cone having one groove, and being one-third of the diameter of the cylinder, which latter has three wings or pistons ccc, the ends of which, as they revolve, touch the outer case e, and do not admit any steam to pass. The steam is admitted through the pipe f, and acting on the wing c, causes the cylinder to revolve until the said wing passes the pipe g, when the volute of steain lodged betweeen each two wings, is allowed to escape. The wing, which has thus passed, falls into the groove d of the cone, the bottom of which groove it touches in passing, thus allowing no steam to escape between. The said wing c then passes again by the steam pipe f, and is acted upon as before de- scribed, and 80 on in rotation. The cylinder a, which is firmly fixed to its axis b, rests on one side on the outer case e, through which the axis projects; but as there is some friction produced by the revolu- tion of the cylinder at its two ends touching the outer case, a false end hh is placed under the opposite end of the cylinder, which false end slides on the axis b freely, and has a thread cut at the end, by means of which, and the adjusting nut i, the cylinder, if worn at the two ends, can be easily tightened and adjusted. The adjusting nut is confined by the collar k, which collar is screwed to the outer case. The conical shape of the small runner, which can likewise be moved upwards or dow nwards in the outer case, serves to keep the two convex surfaces of the cylinder and cone in contact. The groove d, in the conical runner, is cut into a separate piece of metal, which slides by an adjusting SCI ew o, up and down: Digitized by Google ENGINE, VARIETIES OF THE STEAM. 563 90 that when the engine is adjusted, the groove d, on the piece of metal, into which the said groove is cut, can be moved up and down, 80 as to fit the wings of the cylinder. Letters nn, in Fig. 1488, re- present two cog-wheels running into each other, attached on the outside of the engine to the axis of the cylinder and cone, placed there for the purpose of producing a corresponding revolution of the said cylinder and cone, thus causing the groove of the cone to present itself regularly to the wings of the cylinder; o is a pinion fixed to the other end of the axis, by means of which any machinery can be put in motion. 1491. 1487. b Oa c a a b e m 1492. 1488. n n e c a a 1 € b K b / i i 0 1495. 1489. N % r e e 1490. h 1 P M g b Another variety of steam-engine on this principle is shown by an end section view in Fig. 1491, and an external view in Fig. 1492. This engine has a cylinder with two small conical runners on each side, the said conical runners being of the same construction as before described, with one groove cut into each, and being one third of the diameter of the cylinder. There are two induction and two eduction steam pipes; and although the engine may be, with the exception of the addition of one of the conical runners, exactly of the same size as the one first described, a double quantity of steam is requisite, and twice the power of the former engine is gained: the steam enters through the pipe fa, and acts on the wing c, which, after having passed the pipe go, where the steam escapes, falls into the groove d, of the lower cone, and appearing at the induction steam pipe fb, is loaded again with steam pressure, which it discharges at the second eduction pipe go, and then enters the groove of the upper cone, which having passed, it is loaded again at the first-mentioned induction pipe. Letters mm are bridges by which the spindles or axes 666 are supported. This engine has three cog-wheels, nnn, attached to the three spindles, 80 as to cause the cylinder and cones to revolve in unison, and, like the first-described engine, has a pinion o on the opposite end of the axis of the cylinder. Fig. 1493 shows'an end section, Digitized by Google 564 ENGINE, VARIETIES OF THE STEAM. Fig. 1494, a longitudinal section, and Fig. 1495, the exterior of another form of this engine, in which there are two rollers. The conical runners, in this case, are of an equal length and diameter; each has two wings or pistons attached, and two grooves cut into it, and in revolving in opposite directions, the wing of one runner falls alternately into the groove of the other. The steam enters by pipe f, and as the cylinders are running in contact, it cannot escape between them, but acts upon the two wings in oppo- 1493. site directions, and escapes at the eduction pipe g, after the said wings have passed the same. By reference to Fig. 1494, which represents a longitudinal section, it will be seen that the two cones have each two false ends hh, sliding freely on their spindles; the two outer cases ee, fit over the runners and their wings exactly; each of the four a false ends has an adjusting nut, by which the engine is tightened if steam should escape, or slackened if it should d d run too tight. Each pair of the false ends, where they join, have a plate that connects them and breaks their joints, 60 as to prevent an escape of steam; this plate h alides into the groove r, cut out of the false ends, as exhibited by Fig. 1489 and Fig. 1490, the former showing an end view of the false ends with the connecting plate in the middle. On these false ends packing rings, g gg, which are confined to the sliding plate, as exhibited in the latter figure, are placed. These rings press against the hollow outer cases, 1494. and prevent any steam escaping by them. These packing rings are shown in section, in Fig. 1494. It will be evident that the false ends need not be made true, if the connecting plates and packing rings, as above described, be adopted, and that the engine, if provided with movable false ends, conical runners, and the afore-described connecting plates, and packing rings attached, as shown in Fig. 1494, can always be kept steam-tight, and by use the various parts, on which there is any friction, will fit better." Fig. 1496 (A) is Beale's rotary engine, in which the steam is admitted on the one side of an eccentric frame, armed with rollers, which serve the place of pistons; and the cen- trifugal force is reckoned capable of keeping the rollers against the interior of the cylinder. An engine upon this plan has been put into a steam vessel, but its success has not been such as to induce its more extended adoption. 1. Fig. 1496 (B) is the engine specified in the last patent of the Earl of Dundonald, and which has been introduced in the steam frigate Janus." It is not very cor- rectly represented in the accompanying sketch, which is copied from the rough drawing given in his specification. This plan very much resembles that contrived by Watt, except that an eccentric is sub- stituted for a leaf, and a ball and socket joint is introduced in order to enable the steam and exhaustion 1496. A B doors to make a steam-tight junction with the eccentric. This contrivance has not as yet realized any great success, and the prevailing opinion among engineers.appears to be, that it will not supersede ordinary engines. Similar engines have been tried on many former occasions, but they have been always found to involve either a ruinous amount of leakage, or such a degree of friction as to make the plan Digitized by Google ENGINE, VARIETIES OF THE STEAM. 565 impossible in practice. These difficulties will probably be abated as the resources of workmanship increase; but they exist at the present time, and have proved fatal to nearly the whole tribe of rotary engines. 1497. Threttle ? adid SCALE.-1 inch=1 foot. Fig. 1498 is a rotary engine invented by Mr. Yule, and he has had it in operation, working smoothly for some years. It consists of a cylinder C, in which, upon the axis A, revolves another eccentric cylinder B, fitting tightly by means of packing at the line of contact. D is a diaphragm. which slides vertically in strong guides and rests upon the upper side of the revolving piston B. The steam is admitted by either of the pipes S'S', according to the direction the engine is intended to revolve in, the slide valves at the lower end of the steam pipes being regulated accordingly. E is the eduction pipe. In the figure the steam is represented as entering by the steam pipe S', the valve of which covers the eduction port, and admits the steam to press upon the diaphragm D, and the piston B. The steam from the pipe S2 is at the same time shut off, and the eduction on that side of the piston Digitized by Google 566 ENGINE, VARIETIES OF THE STEAM. opened, and there being nothing to counterbalance the pressure of the steam on the other side of the piston, and the diaphragm being incapable of any internal movement, the piston B is made to revolve in the direction of the eduction port. If motion in the contrary direction be desired, it is only uncessary to reverse the valves. American engines.-The performance of the American steam vessels is such as to make them more than a match in point of speed to the best steam vessels of English construction. Their efficient performance is partly perhaps due to the high pressure of steam employed, and partly to the pecu- liarities of American river navigation, which are such as to enable a large sized vessel to subsist with a very moderate draft of water. On the Mississippi and its tributaries most of the engines employed are of the high- 1498. pressure kind a hundred pounds upon the square inch is esteemed a moderate pressure, and sometimes the pressure is raised as high as 200 pounds on the inch. The engines employed in the vessels on the Hudson and other Eastern rivers are for the most part condensing engines. Some of them have horizontal or inclined cylinders; in other cases the cylinder is placed above the shaft, with side-rods extending from the ends of a cylinder cross- head to cranks on the shaft beneath; while in most a beam is employed as in the ordinary land rotative engine. Two engines S2 is are generally employed; but sometimes only one, the crank being carried over the centre by the momentum of the vessel. In the preceding page, Fig. 1497, will be seen a view of the ma- chinery of THE NORTH AMERICA;" and we may here set down a few of the chief dimensions :-Diameter of cylinder, 43 inches length of stroke, 11 feet; length of keel, 200 feet; breadth of beam, 25 feet; diameter of paddle-wheel, 27 feet; length of float, 10 feet dip of float, 27 inches; pressure of steam. 50 pounds. The framing of this engine is of timber; the working beam 0 consists of a cast-iron skeleton frame, trussed with wrought-iron; and the crank and connecting-rod are both trussed with malleable iron rods. The beam is very short in proportion to the length of C the stroke, and the place of the parallel motion is supplied by guides, the piston-rod being coupled to the beam by a long link, C to enable the guides to operate efficiently. The several pieces B composing the wooden framework which supports the crank- shaft are keyed together with wooden keys, and bound with iron knees and plates of iron, to make the whole stiff and firm. The E valves are double spindle-valves, 80 that they are kept in equi- librium. The cut-off or expansion-valve consists of a disk turning on a centre, like the throttle-valve, and set in the steam pipe, which it exactly fills when closed in the rest of the engine there is little that is peculiar. The trussed beam is adopted with advantage in all large beam engines, as it is not merely lighter than the entire cast-iron beams, but stronger and more safe. The saloons of most American steamers are magnificently fitted up: many of them are upwards of 150 feet long, 20 feet wide, and 12 feet high; and the accommodations are in every respect most complete and commodious. The paddle-wheels are generally entirely constructed of wood, with the ex- ception of the centres, to which the arms are bolted, and which are of cast-iron. The usual number of strokes per minute, with an 11 feet stroke, is from 25 to 27, so that the piston travels at a great velo- city. In the vessels on the Mississippi the paddles are made with a clutch or friction-strap, 80 that they may be thrown out of geer, and the engines may be turned so as to feed the boilers when the vessel is alongside a wharf, without moving the paddle-wheels. The engine of the steamboat New World, constructed to run on the Hudson river from New York to Albany.-The steamboats which navigate the lakes and rivers of this country are perhaps among the most striking of the many evidences of American ingenuity and enterprise that present themselves to the notice of the European traveller. Their dimensions far exceed those of the steamboats constructed in Europe, and the extent of their internal accommodations corresponds to that of their external propor- tions, whilst the very high speed which they attain is almost, if not altogether, unrivalled elsewhere. The magnificent first-class steamboats at present in operation on the Hudson river and Long Island sound are of comparatively modern construction, dating back but seven or eight years; but during each successive year new vessels have been built, which have surpassed their predecessors in size, power, and in the splendor of their decorations, while they possess every improvement that the skill, taste, and experience of their constructors could devise. There exists, nevertheless, in the general external ap- pearance of the boats, a great similarity, and this similarity extends both to the details of their construc- tion and of that of their machinery, and also in some degree to their form or model. The general fea- tures of this latter are, great proportion of length to beam, a shallow hold, and a long flat floor, which extends almost to the extremities of the boat. Great buoyancy, and consequently a very light draught of water, are by these means secured. Experience has demonstrated the advantages of attempting to go over rather than through the water when very high speed is desired to be attained. The absolutely best form of model. and that which under all circumstances is subject to the least average resistance, is still a matter of speculation and experiment, and every builder has opinions and theories of his own, differing more or less from those entertained by his brethren of the craft. The rivalry which exists has, however, been productive of extraordinary results, 80 that a sustained speed of 20 miles per hour is not now uncommon; and these astonishing performances are to be attributed Digitized by Google ENGINE, VARIETIES OF THE STEAM. 567 partly to the improved form and fineness of the water lines, and partly to the great size and power of the engines constructed within the last few years. To avoid overloading the boat, it is absolutely essential that the motive power be obtained with com- paratively little weight of material, and this requirement is admirably fulfilled by the " American Boat Engine." Its characteristic peculiarities are, the long stroke and prodigious velocity of the steam piston, the use of steam of 8 high pressure, together with expansion and condensation. A large effective power is thus developed by a machine, the aggregate weight of whose parts is comparatively small. Moreover, from the great tenacity and strength of the American iron, the constructor is enabled to give to his engine proportions considerably lighter than would be deemed safe in Europe. The im- mense diameter of the paddle-wheels is worthy of note as an element of no small importance in the economical expenditure of the power developed by the engine, and consequently in its effect on the speed of the boat. Nearly all the largest class engines are on the beam plan, like that of the New World. Many of the second class and smaller boats have cross-headed, or, as they are termed, square engines. In this ar- rangement the cylinder is situated directly over the paddle-shaft and cranks, to which motion is com- municated by side-rods from the cross-head. The air and feed pumps are worked by a separate beam, which is connected with the cross-head by means of appropriate links. There are several examples of inclined and horizontal engines; of the latter kind, two or three of tolerably large size. The John Ste- vens, now on the Delaware river, and the John Potter, of New York, have steeple engines. With very few exceptions the engines are all single, and are situated in the middle of the boat. In the existing instances of double engines, there are no connecting shafts, but each cylinder works separately one paddle- wheel. In the construction of all these engines, or at least of their framing, wood is largely employed, its cheapness, as well as the facility with which it is worked, being strong recommendations to its use. The gigantic engine, which is very fully elucidated in detail in the accompanying engravings, was completed and put into operation in the early part of the summer of 1849. It is larger and more pow- erful than any hitherto constructed, and from the late date of its completion, it may be regarded as an example of the American River Boat Engine in its most perfected form. It was built by the well- known firm of T. F. Secor and Co. With the following description of the engine in detail will be cou- pled remarks explanatory of any important differences of arrangement or construction existing in other engines. The Bed-plate is a single casting, and forms the foundation of the heavier portions of the engine. It is carefully fitted upon the keelsons of the boat, and is firmly secured by numerous holding-down bolts of large dimensions. That part of the plate which lies between the keelsons forms the channel-way or passage from the condenser to the air-pump. In the centre of this passage are the foot-valves. The Foot-valves are of the ordinary description. They are four in number, and, with their seats, are made of cast brass. They are fitted down, metal to metal, to their seats in the bed-plate, and are se- cured by brass keys. A removable bonnet over them admits of a ready access, for the purpose of adjustment or repairs. The Condenser is of a cylindrical form, flanged at both ends, of the same diameter as the steam cylin- der, by 6 feet 6 inches in height; its content is therefore about 13-30th of that of the space through which the piston passes during one stroke. The upper extremity is cast close, the lower end is open, and is fitted down to the chipping-fillets on the bed-plate, to which it is firmly bolted and secured by a rust joint. Near the top of the condenser, and in the front of it, is the exhaust steam branch, a long ob- long opening, corresponding to that on the lower steam-chest, to which it is attached. A small branch admits the injection water, which flows upwards through a curved elbow pipe within the condenser. Encircling this pipe, is a circular perforated plate, upon which the water falls in its descent, and becomes dispersed throughout the condenser. On the sides of the condenser, and running in an inclined direc- tion, strongly bracketed webs or flanges are cast, to which the wooden framing that supports the main beam is fastened by bolts and keys. The Injection-valves are of the ordinary conical form, and are worked by screws, which are connected by light spur-geering to hand-wheels, conveniently placed within reach of the engineer. The injection supply-pipes are of copper, and lead directly to the valves from the bottom of the boat. The Cylinder-bottom is a circular flanged cast- ing, containing the lower steam-port. It forms 1498(s). the connection between the cylinder and the con- denser, to both of which it is fitted and bolted. The Steam-cylinder is secured to its bottom by a rust joint. It stands vertically over the condenser, and has its upper end steadied by horizontal stays to the framing. Its bored di- ameter is 76 inches. Fig. 1498 (a) is a section of guide for cross-head, showing the foot which is bolted on the cylinder flange. The Piston is a hollow casting of iron, strengthened by radiating arms, and also by two wrought-iron bands, which are bored and shrunk upon it. The application of these bands is a recent improvement, by which great additional strength and security are given to the piston. The steam packing is of cast- iron, and consists of three rings, two external, and one internal, whose depth equals that of the other two combined. These rings are all ground to the piston, and to each other. The packing is pressed out by a great number of short elliptical steel springs, which are placed close together round the entire circumference of the body of the piston. The Cylinder-cover is a hollow casting, ribbed similarly to the piston. Its upper surface is turned and polished bright. Circular holes are formed between the ribs, for the support and subsequent ex- traction of the core, and these holes are afterwards closed with turned stoppers of cast-iron. Digitized by Google 568 ENGINE, VARIETIES OF THE STEAM. The Steam-chests are large and capacious castings of iron, containing the valves and seats, and the in- let and outlet steam passages. On the upper chest is cast the throttle-valve pipe, to which is attached the supply steam-pipe, leading from the boilers. On the bottom chest the exhaust branch is cast, through which the waste steam passes to the condenser. The valve-bonnets and glands are turned and polished bright. The chests are rust jointed to the upper and lower steam-ports of the eylinder. The Side-pipes, which connect the steam-chests, are of cast-iron, ornamented with numerous bands and mouldings, and turned and polished bright throughout their entire length. At the upper end of each pipe is an expansion-ring of thin copper, which, by its yielding, compensates for any slight elongation or contraction of the side-pipes, occasioned by heating and cooling. The Valves which govern the entrance and exit of the steam are of a circular form, connected together in pairs, and of the kind called double balance-valves, from the fact that the downward pressure on one valve is balanced, or nearly so, by the upward pressure on the other valve of the same pair. The upper valve of each pair on the steam side, and the lower one of each pair of the exhaust, are a little larger than the others, and, consequently, there exists a small amount of unbalanced pressure, which effectually retains the valves in their seats, and insures their tightness. The valve-seats are formed by boring out the metal of the steam-chests, and the valves are fitted into their places by turning and subsequent grinding with emery and glass-powder. This is an operation requiring great care and skill, as it is ab- solutely necessary that the valves bear uniformly on both beats, 80 that there may be no leakage of steam. The taper or cone of the valves and seats is a matter of considerable importance; from I inch to I inch in the diameter, for every inch in depth, is a good proportion The valves themselves are of brass. The connecting piece of each pair is made of cast-iron, in order to insure, by its expanding uni- formly with the steam-chest, the accurate fit of both valves when hot. Engines working in perfectly fresh water have their valves altogether of cast-iron, and in these cases both valves and connecting pieces are cast together; excepting, however, the lower exhaust-valves of each pair, which are kept separately, because, from their larger diameter, they cannot pass through the upper seat, and conse- quently they have to be introduced either through the steam-port, or through an opening formed in the back of the chest, and then connected with their upper valves. Where salt water is largely or exclusively used in the boilers, not only the valves but their beats also are made of brass. These are fitted into the chests by turning and boring, and they are then firmly se- cured by turning over and riveting the under edges, which have been previously rendered this and sharp, to facilitate this operation. The combined area of the two valves in each pair is about equal to the area of the side-pipe, which is between fth and 1-9th of that of the steam-cylinder. Engines whose pistons move more slowly have proportionately smaller openings for the admission and exit of the steam. The valve-spindles are made either of cast-steel or of the very best wrought-iron. The spindle passes completely through both valves and their connecting piece, and the lower extremity works in a guide, which is a separate casting, bolted to the steam-chest, or when brass beats are used, it is cast with the lower one. The valve-spindles pass upwards through stuffing-boxes in the steam-chest covers to the lifters by which they are worked. The Valve-geering consists of the lifter-rods with their lifters, and the rock-shafts with their levers. There are four lifter-rods, which are turned bars of wrought-iron, placed in front of the steam-chesta. They are made to move vertically up and down through guides which are cast or bolted to the chests and side-pipes. On the lifter-rods are keyed eight projecting arms, called lifters. Four of these em- brace the extremities of the valve-spindles, which are screwed, and provided with double jam-nute. The spindles pass quite loosely through the ends of the lifters, and the jam-nuts are adjusted so as not to bind them there is thus an allowance made for any slight lateral motion which inaccuracy of adjust- ment or wear of guides may render requisite. The four remaining lifters are likewise keyed upon the roda, and they are placed directly over the levers on the rock-shafts, from which they receive their mo- tion. There are two rock-shafts, one for the steam and one for the exhaust-valves, and they are worked by separate eccentrics. On the shafts there are four levers, by which the lifters and rods are raised, and they are curved on their working faces, 80 that their action is rendered perfectly smooth and noise- less. By the reciprocating or rocking motion of the shafts, the lifter-rods, and with them the valves, are alternately raised and lowered. The exhaust-valve levers are of a length just sufficient to give the requisite amount of lift and lead, and they are so adjusted on their rock-shaft, that the moment one rod is fairly down, the raising of the other commences. The steam levers are considerably longer, and are placed upon their rock-shaft in a position inclined to one another, 80 that an interval, longer or shorter, occurs between the falling of one rod and the rising of the other. During this interval both valves are down, and the steam is of course shut off from the piston. This apparatus then constitutes the expan- sive or cut-off geering, and it may be varied at pleasure, by simultaneously adjusting the respective po- sitions of the eccentric on the paddle-shaft, of the two levers on the rock-shaft, and of the pin in the eccentric lever. This latter has a slot in it, in which the pin travels, 80 that it can be moved to or from the shaft, and fixed as required. By advancing the eccentric, and lowering the extremities of the levers, the steam will be earlier cut off, and vice versa. The amount of lift may be regulated by moving the eccentric pin. The movement of the rock-shaft in the interval during which the valves are down is very considerable, especially in a high expansion, and this, added to the additional amount of movement by which the valves are lifted the requisite height, makes the total angular motion of the rock-shaft very great, and therefore an eccentric of corresponding throw is required. The steam eccentric has conse- quently a throw of 91 inches each way, giving a travel of 19 inches to the rod. The exhaust eocentric throws 51 inches, giving 11 inches travel. The expansive geer above described is called "Stevens's cut-off," and it is the one employed in the engine of the New World. Another variety of geer in fre- quent use has but one rock-shaft and eccentric, with but two lifter-rods. The exhaust lifters and their action are precisely the same as in the geer already described. The steam lifters, which are, like the others, keyed to the rod. have spring catches fitted at their extremities, which lock into the valve-spin- dles when down, and which are released at the proper time, by coming in contact either with an adjust- Digitized by Google ENGINE, VARIETIES OF THE STEAM. 569 1499. B G C E F 1500. 1504. C 1502. 56 is 15 = 42% 38 76 26% 12/1 1503. B R 1501. B A 76ins 19 OF C E 3% ZZZ 72 Digitized by Google 570 ENGINE, VARIETIES OF THE STEAM. able stop, or with a reciprocating arm, moved by the engine. The valves then fall by their own weight. To prevent damage arising from the concussion, a contrivance called the dash-pot is made use of this consists of a small cylinder containing water, and a piston which fits it loosely, and is attached to the valve-stem. The height of the water is 80 adjusted that the piston touches or dashes upon it before the valve reaches its seat: the momentum is thus effectually overcome, and injury to the surfaces of contact completely prevented. The expansion-valve of many of the older engines is simply a throttle-valve. worked by cams on the paddle-shaft. The rock-shaft, lifters, and levers are of cast-iron, turned and finished bright. The outer supports of the rock-shafts are bolted to the side-pipes, and the middle sup- port, which is common to both shafts, is fastened to brackets cast on the cylinder. The Hand rock-shaft, or trip-shaft, is a small shaft of wrought-iron working in bearings cast on the lower steam-chest. It has projections welded upon it, corresponding to similar ones on the lifter-rods, and its reciprocating motion raises and lowers the valves precisely in the same manner as in the large rock-shafts. Sockets are formed in the trip-shaft, into which the starting-handle is inserted. The lever- age of this is considerable, whilst the resistance amounts to but little more than the weight of the lifter-rods, valves, and their appendages; consequently the handling of the engine is performed with great facility. The whole front of the engine, consisting of the chests, side-pipes, geers, and the various handles. is highly finished and ornamented, and the profusion of bright work gives it a very showy appearance. Between the side-pipes are placed the clock, counter, steam and vacuum gages, which are very hand- somely mounted, and supported by an ornamental framework of cast-iron. The Eccentrics are of cast-iron, turned, bored, and fixed in their places on the paddle-shaft by means of keys and set-screws. The Eccentric-bands and rods are of wrought-iron. The latter are in two lengths, supported at the junction by a pendulum link, which vibrates on a stud fixed to the framing of the engine. The chief portion of the weight of the rod is thus supported, so that the eccentric-hook is very easily disengaged from the pin in the rock-shaft lever. The unhooking geer is a simple arrangement of rods and levers, by means of which the engineer throws out the eccentric-rod hooks. The Piston-rod, cross-head, and cap are of wrought-iron. The guide-blocks, which are of brass, lined with Babbit's metal, are retained by jaws bolted to the extremities of the cross-head. The upper ends of the guide-blocks, projecting above the jaws, are cast hollow, and form very convenient oil-cups. The Guides are of cast-iron, bolted at the bottom to the cylinder-flange, and at the top to a light casting which connects them laterally. Braces of wrought-iron, running horizontally from the framing to the guides, retain them in their truly vertical position. The Air-pump is fitted and bolted to the bed-plate directly behind the condenser; it is of cast-iron, and is lined with brass. The lining is cast in narrow pieces, the edges of which are planed; they are then placed, like the staves of a cask, all round the interior of the pump, which is previously bored out. The last piece is driven in very tightly, and the entire lining then undergoes a severe and continued hammering, by which the metal is condensed, the joints closed, and the brass and cast-iron forced into intimate contact. A second boring completes the pump. The upper flange of the air-pump is made of large diameter, in order to receive the reservoir which stands directly upon it, and is secured to it by a faucet-joint. The Air-bucket and valves are of cast brass. The valves are of the kind called butterfly-valves, and have hinges somewhat longer than the valves which work in corresponding grooves cast in the face of the bucket. The guard which limits the lift of the valves is of brass; it is bored out and slipped over the rod, and bolted down to the bucket. The bucket is provided with a loose junk-ring, fastened with copper bolts. The Air-pump rod is of wrought-iron, sheathed with brass, which is cast around it. Its lower end is turned of a conical form to suit the eye of the bucket, to which it is fastened by a brass key. The Discharge or delivery valve is a dome-shaped casting of iron, having in its centre a deep stuffing- box, through which the rod works. A groove is turned out in the lower edge of the valve, and this groove is filled up with wood. This wood forms the beat of the valve, and it works upon a faced ring, cast on the upper end of the air-pump. The Reservoir or hot-well is a large cylindrical casting, standing upon the upper flange of the air- pump. It has a cover on the top, with a stuffing-box, through which the rod works. The Air-pump cap, cross-head, and guides are of the same form and construction as those of the steam- cylinder. The Feed-pumps are two in number, and stand on each side of the air-pump, under its broad upper flange; they consist of the barrels, valve-chambers, and buckets, with their rods. The valve-chambers are square castings of iron, which are bolted to projecting brackets cast on the air-pump; they contain the brass flap-valves, to which there are appropriate bonnets. The barrels are plain cylinders of brass, bored out truly cylindrical; they are cemented at the lower end into faucets cast on the valve-cham- bera, and at the upper end to faucets in the flange of the air-pump. The buckets or plungers are of brass, and are keyed fast to wrought-iron rods which pass through stuffing-boxes in the cover of the reservoir to the air-pump cross-head, to which they are attached. The Front links which connect the cross-head with the working-beam are of wrought-iron, and with their straps, cotters, and brasses, are finished bright. The Air-pump links are similarly fitted up and finished. The Working beam is composed of a skeleton frame of cast-iron, round which a wrought-iron strap of great strength is fixed. This strap is forged in one piece, and its extreme ends are formed into large eyes, which are bored out to receive the end journals. The skeleton frame is a single casting in the form of a cross, and it contains the eyes for the main centre and air-pump journal. The centre eye is strengthened by wrought-iron hoops which are shrunk upon it. At the points of contact of the strap and skeleton, key-beds are prepared, into which the keys are carefully fitted and tightly driven. The Digitized by Google ENGINE, VARIETIES OF THE STEAM. 571 keys are afterwards riveted over at both ends. By this they are retained in their places, as well as the strap on the skeleton frame. The strap is likewise secured to the frame by small straps and keys. The skeleton frame is still further braced by straps with cotters and gibs, which tie the middle of the long arms of the cross to the extremities of the shorter arms. The Beam-journals are all of wrought-iron, secured in the working-beam by keys. The Connecting-rod is of wrought-iron. It is forked at its upper extremity and single at the crank- pin end. It is stiffened by a double truss-brace of round iron, which is secured by bolts to the rod near each end, and passes over a strut at the centre. This strut is screwed and furnished with nuts, by which the brace is tightened. The rod and its appurtenances are finished bright, in the same style as the front links. 1505. 56 28 3% 23% 19½ 1507. 1506. A 42a B 3% 1% 4% is 27 1% 25 21½ The E 20% 20% G C 21% 10% "14 D H 28 The Cranks are of wrought-iron, bored out and shrunk upon the shafts. Cast-iron cranks, strapped with wrought-iron, are very commonly employed on account of their less first cost. The Crank-pin of wrought-iron is keyed fast into a conical hole in the eye of one crank. The other end of the pin is planed square, and passes into a parallel hole in the other crank. In the four seg- mental spaces thus left between the pin and crank-eye, wedges are fitted, and these are retained in their places by a washer bolted to the end of the pin. This arrangement permits the pin to accommo- date itself to any relative motion of the two cranks which the falling of the shaft sooner or later produces: it also facilitates the adjustment of the pin, which is effected by slipping sheet-iron packing under the wedges. The Paddle-shafts are of wrought-iron. The Shaft-bearings or pillow-blocks are bracketed castings, formed to suit the angles of the wooden framing on which they lie. They are fitted with the usual brasses, which are lined with Babbit's metal. The holding-down bolts, by which the pillow-blocks are secured, are arranged in a radiating direction from the centre, so that they embrace a considerable exteut of the floors and keelsons. The Outer-bearings are simple plummer-blocks, fitte with brasses, and resting on frames which are raised upon the guard-beama Digitized by Google 572 ENGINE, VARIETIES OF THE STEAM. The Spring-bearing is a mere cushion of brass, which is placed to support the shaft just within the wheel, in order to prevent vibration. It is occasionally supported on springs. The Pillow-blocks of the main centre of the working-beam are similarly made with those of the shaft, and are fastened by strap-bolts attached to the wooden framing, and also by bolts extending right down to the floor timbers of the boat. The Water-wheels are made up of the centres, arms, and buckets. The centres are circular bracketed castings of iron, to which the arms are fitted and bolted; they are bored out to fit the shaft, and secured by eight keys in each. The arms and rims are of wrought-iron, fastened to each other and to the centres by riveting they are braced laterally by round iron stays, fastened in the form of a cross between the outer arms of each set. There are nineteen sets of three arms in each wheel. The Floats or buckets are of wood, and there are thirty-eight in each wheel, attached to the arms by hook-bolts. Various forms of wheel are in use: some have the single bucket, as the New World; in others the float-board is divided, sometimes in the direction of its length, and in other cases in that of its width. Iron arms, though much lighter, are more expensive than wooden ones, and are but seldom employed. Wooden arms, moreover, are more readily repaired when fractured by ice, floating timber, or other causes, and such fractures are of frequent occurrence at certain seasons of the year. The divided buckets tend greatly to the smooth and equable motion of the engine, especially in rough water, although the full board will give a somewhat higher speed in water perfectly smooth. The wheels of the New World are the largest ever made, being upwards of 45 feet in diameter. The Framework of the engine is composed of four pieces of pine-wood, which are formed into two triangles, inclined laterally to each other. Their lower ends rest upon the keelsons, and upon their upper extremities are placed the pillow-blocks of the working-beam. They are very solidly fastened together and to the boat by numerous horizontal and diagonal timbers, which are secured by wooden knees and keys, and are heavily bolted The two front legs of the framing are bolted and keyed to the diagonal flanges cast on the sides of the condenser. At the other end, the framing is attached to the large mass of timbers which support the shaft pillow-blocks. The framing is further steadied by two additional timbers running from the beam pillow-blocks outside the shaft to the keelsons of the boat. The entire fastening of the engine and of its framing is 80 disposed as to reduce all the strains to direct ones of extension or compression on the fibres of the iron and wood employed in the construction. The Boilers are on what is termed the single return plan, that is, the flame and heated gases make but one change of direction in their progress from the furnace to the smoke-pipe. The latter is directly over the furnace, at which the flues commence and lead directly to the space or connection at the back of the boiler; from thence another set of flues over the first runs straight to the smoke-pipe. The shell, the upper part of the front, and the flues are all circular, and therefore require no staying. On all flat surfaces, screw, socket, or crow-feet stays, are placed every eight or nine inches apart. The smoke up- take is likewise stayed to the steam-drum by socket-bolts. In the construction of these boilers no angle iron is used, but the plates are everywhere bent to form the junctions at the angles, and the flue-heads are worked out into collars, into which the flues are inserted and riveted. The excellent qualities of the Pennsylvania iron enable this bending to be performed with safety and ease. Except at the junction of the shell and front part, there is no double riveting. With unimportant differences of detail, the great majority of the boilers made and used in and about New York are of the same general form and con- struction. Tubular boilers on various plans have been and still are occasionally employed, but they have bitherto met with no very extensive adoption. The New World has two boilers, and they are placed on the guards of the boat, abaft of the wheel-houses. The front part of the boilers rests on a bed of putty laid directly on the deck, and the shells are supported by appropriate saddles of cast-iron. The space between the front of the boilers and the wheels is used for the firing-rooms, the coal, and the blowers with their driving engines. The fuel used is the anthracite coal, and the consumption in both boilers is about 6000 pounds per hour. The durability of the boilers depends very much on the care which is taken of them. The Fire-bars are 11 inch wide on the top, with a space of 7 of an inch between them; they are cast in pairs, and have a circular groove along their upper surfaces, which, becoming filled with ashes, &c., protects the bar from the extreme heat 1508. 1509. of the fire. Fig. 1508 is a section of fire-bars of the Georgia and Ohio, burning anthracite coal. Total grate surface, 416 square feet; steam, 15 pounds per square inch; consumption, 5000 pounds weight per hour in the four boilers. Fig. 1509 is a section of fire-bars of the New World, burning anthracite coal. Total grate surface, 221 square feet; steam, 20 to 35 pounds; consumption of coal per hour, average 6000 pounds. The Blowers are of the direct-action kind, that is, are worked directly on the shafts of their engines, and they are consequently of much larger diameter than those whose speed is got up by pulleys and belts. They are made precisely in the same manner as a paddle-wheel, having cast-iron centres, wrought- iron arms, and wooden buckets, all of course of very slender proportions, answerable to the nature of the work they perform. The casing of the blowers is made of wood, and the air passes through wooden conduits under the fire-room floors, to the ash-pits, which are furnished with suitable doors of wrought-iron. The Blower engines, of which there is one to each boiler, have 14-inch cylinders, by 14 inches length of stroke; they are very simple and compact direct-action engines, and are bolted to perpendicular posts which are fixed to the deck; they receive their steam from the boilers, and exhaust into the con- denser, by which the benefit of the vacuum is obtained. The handles of the steam regulators are Digitized by Google ENGINE, VARIETIES OF THE STEAM. 573 placed within convenient reach of the firemen, who can thus start or stop the blower engines, increase or diminish their speed at pleasure, and to suit the varying requirements of the fires. The Safety-valves are of the usual description, with levers and weights; they are eight inches in diameter, and there is one to each boiler. The Pipes round the engine, both steam and feed, are of wrought copper, with cast flanges. The dimensions of the New World are, Ft. In Ft. In. Length 375 0 Breadth 36 0 Breadth over guards 69 0 Depth of hold 10 6 She is constructed of wood. There are some good examples of iron boats, two or three of them of considerable size. The external planking is 8 inches in thickness, and the ribe are sheathed internally, for a considerable distance amidships, by double-crossed diagonal planking. Further forward and aft, the sheathing is single, and towards the ends of the boat the ribs are not sheathed. The floor timbers are strengthened by several longitudinal timbers or keelsons of considerable size. To compensate for the want of depth in the sides of the boat, the 'hog-back" or bow" frame, is applied to strengthen it. This consists of timbers joined together in the shape of a bow, springing from the side at some little distance from each end of the boat, and rising to a height of 20 or 25 feet at the centre. It is braced to the side in several places by vertical and diagonal timbers and bolts. The whole forms a powerful trussed framework, which is placed directly over the side of the boat, and is to be regarded as being virtually an addition to the depth of the side. The floor of the boat is strengthened by a system of bracing, consisting of masts 40 or 50 feet in length, which are slipped on the keelson, and are furnished at their top with caps, to which are fastened iron rods: these rods radiate to the sides of the boat, like the shrouds in a ship, and they thus transfer the upward pressure on the centre of the floor directly to the side. The deck beams project over the sides of the boat to the extreme width of the wheel-houses, forming what are called the guards." These guards are sup- 1510. ported by diagonal struts underneath them, and they overhang at the centre 16 feet 6 inches; they meet in a point at the bow, and at the stern project about 2 feet 6 inches, forming a gang- way round the ladies' saloon. The New World being a day boat, has of course no sleeping berths. The entire space below deck, with the exception of that occupied by the engine, is de- voted to two immense dining-saloons. On the after-part of the main deck is the ladies' saloon, nearly one-fourth of the length of the boat. Over this is the hurricane deck, which extends nearly to the bow, and forms a magnificent promenade. The space underneath this deck, forward of the ladies' saloon, is appropriated to the baggage, &c., and on each side of it are rooms for the accommodation of the officers and crew of the boat. The fittings and decorations of the saloons are most costly and magnificent. The night boats have three tiers of berths running completely round the saloon under the main deck, and there is another saloon upon the hurricane deck, ex- tending entirely over it. Opening into this saloon, and on each side of it, are state-rooms containing berths. These night boats thus possess sleeping accommodation for many hundred pas- sengers. The passage from New York to Albany occupies on the average about 9 hours: the total distance is 146 miles. The boats usually make 13 landings, which involve a loss of time of at least 5 minutes each, leaving 7 hours 55 minutes as the average running time, giving a speed of about 181 miles per hour: this is, however, by no means the top speed, since the passage through is frequently made in much less time. Upwards of 20 miles per hour is commonly effected, and when racing, the swifter boats have occasionally moved at the tremendous rate of at least 22 miles per hour through the water. Details of the engine of the Osceola.-As another example of American steamboat engines, we have selected the engine of the steamboat Osceola, made by Adam Hall, of New York, and represented in Figs. 1511 to 1534. The frame is made of yellow pine, well jointed and bolted together, the mortises and tenons being well inlaid with white-lead. The timbers which sustain the crank-shaft bearings are firmly dowelled and bolted to the fore-leg of the main frame, and are further supported with large knees of oak, firmly secured to the keelson. The prevailing and American characteristic in the construe- tion of the engine consists in the free use of tension-rods and straps of wrought-iron, arranged diago- nally so as to receive and sustain the alternate strains to which the moving parts are subjected. The advantage of this principle of construction is very obvious, as it renders the parts extremely strong and rigid, at comparatively a small expense of material. This will appear from the description which fol- lows. The arrangement of the working parts is simple and efficient: the handles for starting, stopping, and the injection, being brought to one spot behind the cylinder, thus enabling the engineer to attend instantly when required. The arrangement by which the eccentric-rod is supported on a vibrating rod, renders the working of the engine much less laborious than without it and by using the balance-valves in- stead of the ordinary poppet-valves, a very moderate degree of manual force is requisite to work the engine. Fig. 1511 is a side elevation of the engine. Fig. 1512 is an end elevation, exhibiting the steam-chests, the cylinder, and the parallel motion. Fig. 1518 is a vertical section of the steam cylinder, the condenser, the bed-plate, and the air-pumps. Fig. 1515 is a plan of the bed-plate, showing the passage connecting Digitized by Google 574 ENGINE, VARIETIES OF THE STEAM. the condenser with the air-pump, and the opening by which the foot-valve is introduced to its place. Fig- 1516 is a transverse section of the steam-chests, showing the arrangement of the balance-valves. Fig. 1517 is a plan of the steam-chest, and of the cylinder with the lid removed. Figs. 1518 and 1519 are views of the traverse shaft for working the valve-lifters. Figs. 1520 and 1521 are face and edge views of the crank, showing the method of binding it by a wrought-iron strap. Figs. 1522 and 1523 are front and side views of the connecting-rod, with the method of bracing it by wrought-iron rods. Figs. 1524, 1525, 1526, and 1527, are elevations and plans of the crank-shaft and main centre pedestals, showing the attachments for securing the blocks to the framing. Figs. 1528 and 1529 are an elevation and a plan of one of the paddle-wheels of the steamboat North America. We give this wheel as an example of American paddle-wheels, and of the modes of framing timber for the support of the journals of the paddle-shafts. Fig. 1530 is a front view of one of the floats; Fig. 1531 is an edge view and Fig. 1532 is a plan. Figs. 1533 and 1534 are a face and edge view of one of the centres of the wheel 1511. F K x y E 0 G 2 E b h A D A C 1 b X d a 'II 9 C r D a M M L o c K c LE B SCALE.-1 inch=1 foot. The following are the literal references :- A. is the principal frame, which supports the main centres of the beam, and also the bearings of the crank-shaft. B, are the keelsons. a a, the fore and aft legs of the frame. b, the upright post under the main centre. c, oak knees, by which the legs are secured to the keelsons. d, timbers which support the crank-shaft bearings; the fore and aft timbers are placed obliquely to strengthen the support. e, the back-stay for further securing the main centre. C is the steam cylinder, and C' is the cylinder bottom. f. the piston; the under side of it, 1, is a solid web, rounded and in one piece with the centre, 2, by which it is keyed to the rod, and with the circular flange, 3, at the circumference, upon which the pack- ing is laid. These three parts are connected together by stiffening flanges, 4; and the whole is covered in by a flat plate, 5, which holds down the packing, and is bolted to the body of the piston. Digitized by Google ENGINE, VARIETIES OF THE STEAM. 575 g, the piston-rod. hh, the steam ports; the under port is formed in the cylinder bottom. This, it will be observed, is hollowed out to the form of the under side of the piston. i, the clutch and cross-head, keyed to the upper end of the piston-rod. k, the links connecting the cross-head to the working-beam. D, are the steam chambers, in which are placed the valves for regulating the motion of the steam into and out of the cylinder. 11, the chambers whence the steam is admitted to the cylinder. m m, the chambers into which the steam is discharged from the cylinder. I nn, pipes connecting the upper and under chambers; bolted fast to upper chambers, but connected to the under chambers by expansion joints. v h o, the steam-valves, and p, the exhaust-valves, fixed in pairs on the spindles, and denominated equilibrium or balance valves. 5 qr, the valve-spindles, having their under ends guided in inverted caps, introduced through the under sides of the steam-chests; their upper ends pass through stuffing-boxes, and are connected on the out- f side to the brackets on the lifting-roda. 1514. 1512. q P i r h, t L II K 1513. n ml D N me 1515. N K k A K N B B m SCALE.-11 inch=1 foot. s, the steam-pipe from the boiler. It is furnished with two valves; one of them c", is the throttle valve; the other d", is the cut-off valve; the latter is worked by a cam fixed on the crank-shaft, which works the lever e", the fulcrum of which is fixed on the timbers of the crank-shaft bearings; this lever working the lever on the valve-spindle by means of the rod f", the traverse-shaft and levers g", and the rod h". t, the exhaust-passage, connected to the passage i', in the condenser. Digitized by Google 576 ENGINE, VARIETIES OF THE STEAM. 1516. 8 - r q P 0 P u и b 0 m 6 b 1523. 1522. G n n r q THE P 0 m l P u 0 b t 8 1517. C 1521. 1590 h D H H WALKOU S [2] 1518. a d 2 1519. 3 '26 , 12 Digitized by Google ENGINE, VARIETIES OF THE STEAM. 577 uu, the steam passages to the cylinder. v, the lifting-rods, with brackets, 1, 1, 2, 2, fixed on them, and connected at the extremities to the valve-spindles, on which they are adjusted by nuts; 3 3, the lifting faces. w, the traverse-shaft; 1, the lifting-frame 2, the lifters 3, the eccentric-rod lever. (See Figs. 1518 and 1519.) We may take this opportunity of describing the operation of the balance-valves, and of pointing out the peculiar advantages of them. Referring to Fig. 1516, it will be observed that the valves are ar- ranged in pairs, keyed on distinct spindles, and that each pair, therefore, is moved as one valve; fur- ther, the valves in each pair are of unequal diameters, the upper valves o, on the steam-side, being larger than the under valves, and, on the contrary, the under-valves p, on the exhanst-side, larger than the upper ones. And here the peculiar and elegant adjustment is shown. The common poppet-valve sustains the full pressure of the steam on its exterior surface, which must, therefore, be overcome before the valve can be opened; but, in the balance-valve the steam pressure is made to balance itself, (hence the name,) as it enters the steam port from both above and below. The upper valve in each pair on the steam side is larger than the under by as much as will afford, by the difference of pressures upon them, sufficient force, in conjunction with the weight of the valves, to shut them steam-tight in their seats. Vice versa, the under valve in each pair on the exhaust side is the larger of the two; that by the resulting tendency of the pressure of the steam from within, when entering the cylinder through the steam-valve, the exhaust-valve may be kept shut when required. Thus, it is clear that by regulating the relative diameters of the 1524. valves in each pair, the absolute difference of the areas of surface of each, exposed to the steam pressure, may also be regulated; and, consequently, also the amount of pressure effective in shutting them. In the present instance, the valves are 10 inches and 9 g inches respectively in diameter; therefore, the steam pressure effectively exerted in shutting them is that due to a surface equal to the difference of these areas, or to 15-2 square inches. Let the steam pressure be 50 lbs. on the inch, then the acting pressure will 1525. 3 amount to 15.2 X 50 = 760 lbe, or, the weight of the valves being added, say 840 lbs. This will, indeed, appear little when it is considered what a common poppet-valve would require. If the poppet-valve were 11 inches in diameter, it would be subject to a 1596. pressure of 4750 lbs. The slides, also, such as are used in British engines, weigh 3920 lbs, without the friction of the faces being taken into account. But, in fact, as the starting lever has a power of 6 to 1, the resistance to be overcome by the engineer in starting is only 140 lbs. 1527. E are the parallel guides for the cross-head of the piston-rod. These, the cross-head, and the links k, constitute the parallel motion of the engine. The guides E are bolted to the projections on the cylinder flange, seen in Fig. 1517, and are stayed to the frame A, by wrought-iron ties, and a small cast-iron cornice near the top. See Fig. 1511. F is the main lever of the engine. x, a cast-iron centre, strung with tension-rods. y, tension-rods of wrought-iron, which are strapped to the centre piece at the middle, the extremities, and the intermediate points. 2, additional tension-rods, strengthening the intermediate points where the air-pump and force-pump rods are connected. The main centre pedestals are represented in elevation and plan in Figs. 1526 and 1527. 1, the sole; 222, flanges for securing the bearings more steadily to the frame. G, the connecting-rod constructed of wrought-iron. a', the rod, fitted with straps at the ends for embracing the bushes. b'b', tension-rods for stiffening the main rod, and preventing the effects of vibration. These rods are jointed at the upper ends to the main rod; held in tension at the middle by the strut c', which is screwed and nutted at the extremities to regulate the tension of the rod; and keyed up at the under ends. H is the crank, composed of a cast-iron body, and a wrought-iron binding strap. d', the cast-iron centre, in which the holes are formed for receiving the ends of the crank-shaft and the crank-pin. Its form in section is that of a web terminated on both sides by flanges. e', a wrought-iron tension-rod in one piece, passing entirely round the crank. f', horns cast upon the crank for the purpose of stretching the strap e', the strength being thereby rendered available. The fellow of this crank, which is seen in the general elevation, Fig. 1511, is differently formed, being made solid at the end, and provided with bolt holes, through which a strap embracing the crank-pin is introduced and screwed upon the other side. By this arrangement, the crank-pin may at any time be readily disengaged from the crank, and the parts are more easily put together. I is the crank-shaft. g', the plummer-block. 1, the sole of the block resting on the timbers: 22, flanges for securing the block to the framing by bolts and nuts; 33, snugs cast on the sides of the sole, through which holding- down bolts are passed, which are secured to the keelsons. a", the eccentric for working the balance-valves. 6", the eccentric-rod, having its length divided, at a point near the handle, into two parts jointed together, the longer and heavier part next the eccentric being supported on a vibrating joint. By this 73 Digitized by Google 578 ENGINE, VARIETIES OF THE STEAM. means it becomes an easy matter to disengage the rod from the lever of the traverse-shaft; which is done by means of a small rope attached to the extremity of the rod. K is the condenser. i', the exhaust-steam passage. k', the injection passages. l', the injection cocks. m' m', the flanges by which the condenser is bolted to the principal frame. L is the air-pump. re', the bucket, the construction of which is obvious from the section, Fig. 1518. o', the bucket-rod. 1528. I K K M E M C A A B B p', the delivery valve, which is cast hollow, and has its lower edges, where it rests on the air-pump, filed true, so as to fit and form a good joint. This serves a two-fold purpose, namely, as the air-pump lid and the delivery valve. Its action is simple and ingenious; for when the bucket arrives at a certain height, the lid is raised and the water flows out all round, thus discharging more effectually and rapidly than by the common valve, and requiring little or no power to discharge, having only the lids to raise. q', the hot-well, made of copper, and riveted to the air-pump by means of a vertical flange. r', the waste-pipe. 1529. s', the feed-pipe. t', the pipe for drawing off the water from the hot-well. u', the rod from the beam, which drives the air-pump rod. Q v, the guide for the cross-head of the air- pump rod, staid to the principal frame by means of the bracket w'. M is the force-pump. x', the pump-rod, moving in the guides y' y', driven from the beam by the rod x'. M' is the bilge-pump. N is the bed-plate. i", the foot-valve. The principal dimensions of the Osceola are these:- Diameter of cylinder 31 inches. Length of stroke 11 feet Length of beam 17 44 9 " Length of connecting-rod 21 44 1 66 Lengths of links 7 " 6 " Height of beam, from keelson 31 " 0 " Width between guides of piston-rod 3 " вь " Diameter of paddle-wheel 28 " 0 $6 Number of strokes per minute 24 Velocity of piston in feet per minute 528 The paddle-wheel, of which we have represented the construction in Figs. 1528-1529, is the wheel, 30 feet in diameter, of the steamboat North America. Digitized by Google ENGINE, VARIETIES OF THE STEAM. 579 Fig. 1528 shows the outside framing of the paddle-box, or, as it is frequently termed, the wheel- house; also an elevation of the paddle-wheel, showing the arrangement of the buckets, arms, centre- plate, dtc. ; A A is the main waling which rests upon the transverse timbers B B, which project from the side of the vessel. C, the main upright on which the outer bearing of the paddle-shaft E rests; DD, diagonal framing for rendering the upright C steady, and also for completing the truss formed by the four pieces. G G, two lighter diagonals quartered into FF, which are mortised into A A, and firmly bolted together with I; the foot of I is mortised into H, which acts as a tie to confine the pieces F F to their places, thus forming a stiff framework for the planking of the wheel-house, and supporting the outer end of the shaft. K K K are the arms; LL, battens by which the floats are attached to the arms; MM, the float boards; N an inner ring of segments of wood for the purpose of staying the arms; 0, an outer ring of iron for further security; P, the centre-plate. Fig. 1529 is a plan of the paddle-wheel, showing the arrangement of the floats, which gives this kind of wheel the name of split bucket," and also showing the diagonal bracing QQ, for the purpose of pre- venting vibration in the wheel. 1531. 1534. U o 1530. L L M 1533. L M TT A N 1532. D Fig. 1530 is an enlarged view of one of the floats, showing the method of fastening the same to the arm. K K are the arms, three inches by six deep, of red pine; LL, two battens of hard wood placed on the face of the float to retain it more firmly against the arm when the motion is reversed, above 57 inches wide at one end, and 4 inches at the other, and one inch thick; the float-board M, is 5 feet 8 inches long, 2 feet 4 inches wide, and 11 inch thick; it is fixed to the arms K K, by means of straps passing round the arm, through the batten L and washer R. and held to its place by A screws and nuts, as shown in Figs. 1513 and 1515; it is also held by two inch bolts and nuts at TT. Fig. 1531, a side view of the method of attaching the same. Fig. 1532 shows the method of connecting the outer ring to the arms; aaa is a strap of iron, half an inch thick and three inches wide, which goes round the arm K, and by being riveted tight to the rings 00, keeps the arm steady in its place. Fig. 1533 is an elevation of part of the centre-plate, showing the arrangement for fixing the arms. A aa is a plate with webs cast upon it, 16 in number, and at B they diverge to the periphery of the plate, thus forming 16 spaces 6 inches wide, and 16 smaller ones. In the wider spaces, holes are drilled or cast for receiving the t bolts, which are used in fixing the arms to the plate. D is the hole in the centre, 14 inches diameter, by which the wheel is fixed to the shaft; C is the ring which is made 2 inches thick and 71 wide, for the key-seats. The plate A is one inch thick, as are also the webs BB. Fig. 1534 shows the thickness of the plate and the width of the boss or ring C. Pistons.-By presenting a somewhat heterogeneous and unselected enumeration of the principal varieties, just as they have occurred to us in practice, and noting their respective characteristics, whether merits or defects, we may, perhaps, make our account more instructive than if we were to give either a more methodical description or more restricted catalogue. A consideration of the annexed sketches leads us to rank metallic packed pistons under two divisions, (which, if not perfectly distinct, are sufficiently so for the purpose of classification,) to one or other of which each may be referred those in which the expansive force of the rings alone is used, and those in which it is either assisted or entirely superseded by springs. Of the former kind, we may reckon three varieties; first, those in which hemp packing requires to be compressed into the space between the rings and the piston, to aid the elasticity of the former; this is commonly the case in pumping engines, where hitherto the more complicated and expensive descriptions of packing have not been generally adopted. Fig. 1585 represents a piston of this variety; the oblique cut in the ring being designed to prevent the sharp edges of the break from grooving the cylinder. In this description of piston, two rings are generally employed, one above the other, with the breaks about 90° apart, to prevent the steam escaping at the joint. This is the simplest kind of metallic packing, but when properly fitted up, it possesses nearly all the advantages of the more complicated descriptions; the only disadvantage being the necessity of occasional adjustment, when the internal hemp gasket loses its elasticity, the frequency of which depends upon the accuracy with which the end joinings of the external rings are contrived to prevent the inlet of steam into the hemp, and also in some degree upon the temperature and pressure Digitized by Google 580 ENGINE, VARIETIES OF THE STEAM. of the steam itself. Another form consists of a single ring with a tongue joint, as shown in the figure. Closely allied to the above is what we may term the second variety of this species, an external packing ring like the former, but deriving its tightness from its own elasticity, and, of course, not dependent on the hempen packing behind. The simplest and perhaps the most common method of giving the requisite spring is to turn the packing rings a little larger 1535. than the diameter of the cylinder, and when sawn through to cut a tenon and mortise, or a half check in the abutting ends, and then to compress the ring by an iron hoop with screws, and to fix it tempo- rarily with a pin put through the overlapping or mortised ends; in this state the rings are ground on the surface joints, and the piston made ready for its place; when, the hoop being unscrewed and the temporary pin withdrawn, the rings are suffered to expand in the cylinder by their own elasticity, which will generally continue to act till the rings and the cylinder are 80 much worn as to permit the rings to expand to their natural extent. Sometimes the abutting ends are left plain, in which case a piece is merely cut off one end, to allow the ring to be compressed to a lesser diameter. Great diversity of opinion exists as to the merit of this species of packing: that it is a decided improvement upon the former is unquestionable, but it is alleged, that in accuracy of form, and facility of application to the cylinder, it is greatly inferior to the ordinary more complex varieties, with a number of segments and artificial springs to each. It is said, in the first place, that it tends to wear the cylinder off the truth. Appeal to experience might seem the shortest way of settling the question, as many pistons both of the simple and the amended construction are in use, but in this, as in many other cases, recorded experience only serves to prevent any conclusion whatever, or rather tends equally to two contradictory results. Let us then investigate the action of the simplest form. The ring, SCALE.-1 inch=1 foot. when first compressed, does not naturally assume the circular form, as by the two ends being brought together the tendency to expand to its original dimensions is mainly checked in only one direction. When confined in the cylinder, however, it will be seen at once that it is compressed equally in all directions, and must therefore exert a corresponding force equally in every direction, to recover its original dimensions. This appears 80 plain, as scarcely to be susceptible of illustration. The variety, ingenuity, and complexity of the various contrivances adopted, to correct this supposed defect in this description of packing, and the alleged success by which they have been attended, must be our apology for dwelling on the subject. But although the apprehended evil did exist in its full amount, and the rings really had a greater tendency to expand in the direction perpendicular to the diameter passing through the break, we do not see what bad effect would ensue; the cylinder would be worn almost imperceptibly oval, till at length the inequality of pressure in the ring would be exactly counterbalanced by corresponding ellipticity in the cylinder; and not only so, but the next rings that happened to be put in would fit with as great truth as the most hair-breadth system of compensation could possibly effect, since the alleged unequal expansion of the ring would then correspond exactly with the shape to which the cylinder has by that time worn. It is abundantly obvious, however, that the effect upon the cylinder of the unequal expansion might be altogether neutralized, (were it ascertained to have any proper existence,) by using two rings instead of one, the position of the joints being 90° apart. It is not uncommon to have the rings placed with the joints on opposite sides of the cylinder, or 180° apart: an arrangement only useful to prevent the passage of the steam through the single break, (an object which might be easier attained in another way,) and incapable of exerting a correcting influence on the above-named inequality. Under the third modification of this description of packing, we class pistons in which each ring is still in one piece, but in which some of the above modes of compensation are had recourse to. The common method is, simply to turn the ring about one-third thinner towards the part where the joining is made; two rings are commonly used, the position of the joints being as above described, and instead of the rings being turned of greater than the required diameter, and then sprung in, the requisite elasticity is given by hammering the thicker semicircumference on the hollow side. Of course, the same method may be taken with rings of uniform thickness, and to derive the full effect of the hammering, it might be well to retain the original skin of the casting on the inside of the ring. The advantage of giving the requisite elasticity by hammering rather than by compressing the ring, lies in the more perfect circu- larity ensured by the former; but were the precaution taken to turn up the compressed rings in the lathe, this difference would no longer have place; and this is now generally done in addition to the hammering. This arrangement has been generally found to work very well; but perhaps not better than the pre- ceding more simple variety, when the workmanship of both is equally correct. Numberless methods have been taken to prevent the escape of the steam by the open end joints which this species of ring exposes; frequently hemp packing is put behind the rings; sometimes they are merely cut without any further provision; but by far the best plan, is to rivet a piece of brass or iron, previously fitted to the proper curvature, to the inside of the ring on one side of the break, 80 that it shall apply correctly to the other side, and alide along steam-tight as the ring expands by wearing. Inattention to this simple pre- caution has been the occasion of great inconvenience, and has even led to the substitution of a much more expensive, though not in reality much more efficient system. Digitized by Google ENGINE, VARIETIES OF THE STEAM. 581 The second principal division of our subject comprises many subvarieties: we mean that class of pistons where artificial springs are used, acting in most cases by the intervention of blocks or wedges. The most common construction is as follows :-Two strong cast-iron rings of such dimensions as to have no perceptible elasticity themselves, (say from 14 inch to 21 inches square in the cross-section,) are cut, each into from three to six or eight segments, according to the size of cylinder, or other regulating cir- cumstance, placed the one above the other, 80 as to break bond at each joint, and at each break part of the ring is cut away to admit the introduction of a wedge usually of the angle of 90°, the point of which may be 1 inch from the surface of cylinder a common elliptical spring is then introduced between the body of the piston and the back of the wedge. Sometimes, instead of a wedge, a simple block is used, or the spring presses immediately upon the back of the ring. In the original form of this piston the points of the wedge came in contact with the cylinder, being situated in the periphery of the piston, and. in order to prevent their injurious action in grooving the cylinder, it was proposed to make them of softer metal. In this description of piston, the mode of action of the wedges is what seems principally to require investigation. When the points of the wedges are not in contact with the cylinder, the mode of action is sufficiently obvious; the intervention of the wedge serving simply to multiply the energy of the springs on the principle of the wedge, as a simple mechanical power. Of course, the more acute the angle of the wedge, the greater force is imparted to the springs, on the principle of virtual velocities; and were the segments only required to expand indefinitely, instead of expanding and contracting by turns, to suit the inequalities in the cylinder, then a very acute wedge might be used; but as the wedge must be ready to spring back, to allow the packing to yield when it comes to a tight part of the cylinder, as at the top and bottom of the stroke, it is plain that the incli- nation must be considerably greater than the angle of repose; it is seldom, however, made less than 80° or 90°, but we believe a considerably sharper angle would be found to answer. Considering now, for a moment, the case in which the points of the wedges come in contact with the cylinder, it might seem, at first sight, that they would exert no pressure at all upon the adjacent segments; and such would be the case, were it possible for them to wear no faster than the rings themselves; a little consideration, how- ever, will show that this can never be the case, as the wear upon the wedge must be to that of the ring, in the proportion of the side to half the base of the wedge; that is, in the case of a right-angled wedge, as the diagonal to one of the sides of a square: were the wedge and cylinder then to be made of the same material, the wear of the cylinder opposite the wedge would exceed that of the rest of its surface, in the above proportion, or probably in a somewhat higher ratio, arising from the different grain of the metal composing the wedge. The wedges, however, are almost always made of gun-metal, which serves in a great measure to neutralize what would be otherwise the injurious tendency of this arrangement. Fig. 1536 represents two views of the locomotive piston. The peculiarity of construction and mode of action is apparent from inspecting the drawing. By fitting a tongue-piece, or tenon, into a corre- sponding mortise, in both wedge and ring, it is intended to prevent the passage of steam at the breaks of the segment, instead of the common method of using two rings, each of half the thickness, with the joinings of the one ring placed midway between those of the other. We believe this construction has been found to answer perfectly; but this is not paying it a distinguishing compliment, as we shall soon see that the same may be said of certain other descriptions, about which there is not above one-fourth of the workmanship here displayed. 1536. 1538. 1539. 1537. o ECALE.-1 inch=1 foot. Fig. 1537 represents plan and section of a piston, differing from the above in having only one wedge and break in the ring instead of four. The set screw, on the side farthest from the wedge, might be omitted; the two side-screws serve in some measure to compensate for the sluggish action of the right- angled wedge. which seems rather to press the ring against the cylinder at the point immediately adja- cent than to force it open, and thus make it bear equally all round. A more acute wedge would propagate the pressure of the spring more readily throughout the entire circumference. A circular spring, like that used here, while it possesses several conveniences, is yet less delicate and perfect in its action than the common elliptical kind; and perhaps, too, less easily reset or retempered. Very similar to the first variety is that shown in Fig. 1538. We doubt whether the slight superiority in point of simplicity gained by doing away with the adjusting screws, and substituting a single spring hoop, be not more than counterbalanced by less perfect action. A method intermediate between the Digitized by Google 582 ENGINE, VARIETIES OF THE STEAM. two last is sometimes adopted; the packing-ring is cut, and a sliding piece and wedge employed in two opposite places, and a circular spring, with set screws, acts upon each. Fig. 1539 represents a plan of the piston. The distinctive feature in it is, that each spring acts upon one wedge in the upper ring, and another in the lower, the centre of the spring, contrary to common usage, being made the " point d'appui," from the body of the piston. Fig. 1540 represents a piston that has been much used. It consists of three concentric rings, the two outer being rebated and mortised upon their edges, and together filling up the space between the flanges of the piston. The inner ring is equal in depth to the two outside rings. When the rings are turned to fit the cylinder and each other, they are hammered on the inside, to give them a tendency to spring outwards, and are then cut through, to allow them to expand. The divisions of the rings are placed 80 as to break joint. To provide for the wear of the outside rings, springs are placed at the back, which can be tightened up by means of screws bearing upon the centre part of the springs. 1542. 1540. 1541. SCALE.-1 inch=1 foot. Fig. 1541 represents a kind of piston very similar to Fig. 1537. The pistons are sometimes made of brass. This is an advantage in horizontal or inclined cylinders, as the softness of the material, and the greater lightness of the piston, considerably reduce the wear of the cylinder. Brass pistons have been, on this account, much used for locomotive engines ; one drawback, however, to their employment, is, the inferior elasticity of the metal, which renders the employment of artificial springs necessary. Fig. 1542 represent+ the packing-rings. The peculiarity of this piston consists in the two rings being grooved and tongued into each other in a manner similar to common flooring-deals. Fig. 1543 represents the plan of a piston which is superior in simplicity, and at least equal in effi- ciency, to several of those we have figured. Fig. 1544 represents the piston which is free from all or most of the defects we have pointed out, and has given much satisfaction in practice. The position of the rings, in being placed with the breaks, 90° apart instead of 180°, is one of those trivial but judicious arrangements which often determines the character of a mechanical contrivance. 1545. 1543. 1544. BCALK.-1 meh=1 look. SCALE inch=1 foot. Fig. 1545 is a plan and section of piston much used. It has two packing-rings, 1 inch X 11 inches, each in three segments, pressed out by three elliptical springs with set screws, through the medium of an inner ring equal in depth to the two, and cut in three places. These then are the principal specimens of locomotive pistons: we shall next describe some of the most approved pistons for marine engines, all of which are also applicable to land engines. Fig. 1546 represents a variety of packing adapted for marine engines. Fig. 1547 represents Jessop's spiral metallic packing. On considering the action of the spiral coils, when the ring is compressed into a lesser diameter, it will be found that the tension of the springs is a Digitized by Google ENGINE, VARIETIES OF THE STEAM. 583 minimum at the centre of the coil; while it increases towards each extremity in the ratio of half the number of coils to unity. Fig. 1548 represents an arrangement that was formerly extensively adopted. The packing consists of four rings, from t to 11 square, according to the size of the cylinder, which may vary from 6 to 50 inches in diameter. In pistons of the latter dimensions the rings are turned fully two inches more in diameter, and afterwards cut in one place, and bent to the proper circle in a mould prepared for the purpose- the ends being half checked in such a way as to be steam-tight without the necessity of using packing behind, which, however, is frequently added. In order to bring the cylindrical surface of the rings sooner to an exact bearing, a groove is turned out of the outer circumference of each: this may help, besides, to keep the piston tight, by affording a lodgment for oil and tallow, and may in certain circum- stances be of considerable use. In one instance within our knowledge this kind of piston has been at work, with occasional interruption, but little or no repair, for a period of ten years. 1548. 1546. 1547. SCALE-1 Inch=1 foot. Fig. 1549 represents plan and section of piston both for marine and land. This may be regarded as a favorable, and at the same time, characteristic specimen of the most generally approved and widely adopted variety of packing in which separate springs are employed. The ease with which the springs may be bent and reset to the proper compass prevents set screws from being required the only seri- ously objectionable point seems to be the expense of fitting and grinding steam-tight the ten wedges required. The use of wrought-iron nuts, fitted into the body of the piston to receive the junk ring screws, instead of tapping them into the cast-iron, is a very obvious improvement. 1549. 1550. SCALE.-1 inch=1 foot. SOALE.-1 inch=1 foot. Fig. 1550 represents a form of marine piston. To enter into a detailed analysis of it would be super- fluous, after having considered 80 much at length the general principles by which our judgment has been regulated. Fig. 1551 is another form of piston. The peculiar shape of the blocks against which the springs press, instead of the usual V wedge, is one point of identity. Digitized by Google 584 ENGINE, VARIETIES OF THE STEAM. Fig. 1552 represents the form of piston much used. 1551. Two rings, about 24 inches square, (cylinder being 65 inches diameter,) divided into two segments, the lengths of which may be in the proportion of 1 to 5, each ring being pressed out with a number of springs, generally made very stiff, and of little compass: the rings, in con- sequence, wear 80 rapidly, that we have known them to require to be eked with a considerable thickness of copper at the ends. The distinguishing feature of this piston lies in the cut on the outer circumference of the rings being made at a considerable angle with the per- pendicular, while that on the inner side is vertical; an arrangement that we do not recollect to have met with before. Fig. 1558 represents a species of packing-ring also much employed. Only one packing-ring is used, about 34 inch X 14 inch; sprung in from a larger diameter, or hammered internally so as to have considerable elas- ticity. This ring is cut in only one place, and a piece, 110 8 or 9 inches in length, half the thickness, and about one-third the depth of the ring, is checked in on the upper side, in order to break bond; and at the back of the joint a block is placed, screwed to the one end of the ring and loose at the other, so as to prevent the steam from passing through the cut. In addition to the elasticity of the ring, it is pressed out by six elliptical SCALE.4- inch=1 foot. springs. This is, on the whole, one of the best marine pistons. The ring, however, in wearing, deranges the joint between the ring and the small segment- piece. The joint opens at each end, 80 that the only contact comes to be at the central point, which is a defect. Fig. 1554 shows plan and section of the piston of a cylinder 68 inches diameter. There are two rings cut into two segments, the lesser being one-third the circumference, with V blocks at the joinings, and stiff elliptical springs. 1552. SCALE.-1 inch=1 foot. Fig. 1555 shows a species of piston. The ring is turned the full size, measuring to the point of the tongue-piece, and squares are then cut out to allow the ends to come together, 80 that the tongue-piece is in one piece with the ring. The malleable iron bridle is for the purpose of expanding or contracting the ring, which is effected by driving in a cutter at the one end of the bridle or the other, whereby the ring is contracted or expanded. One end of the bridle is attached to the ring by a bolt, which slides in an oblong hole in the bridle; and if a cutter be driven between the bridle and one end of the piece Digitized by Google ENGINE, VARIETIES OF THE STEAM. 585 ground on the back of the joint, the ring will be expanded; whereas, if driven at the opposite side, the ring will be drawn together. Fig. 1556 represents a marine engine piston. The tongue-piece is not cast in one with the ring, but is put in with pins; and the slot is on the incline, to prevent a rut in the cylinder. The tongue-pieces, of this and the preceding variety, are of course ground in, a piece being ground on the back to prevent the steam from passing. This species of piston ring is probably among the best yet introduced in prac- tice. It is a very common fault of metallic pistons that the springs are made too weak. We have often known them to be too weak, but never in any one instance knew them to be too strong. 1553. 1 SCALE.-1 inch=1 foot. Fig. 1557 represents the piston often used for cylindrical slide-valves. By raising or lowering the screw, it will be evident that the rings are compressed or expanded. A flat place is of course cast in the body of the piston to leave room for the bridle. 1554. SCALE.-1 inch=1 foot. In the pistons of oscillating engines, it is necessary to take precautions against any compression of the packing-ring by the weight of the piston during the inclination of the cylinder. The method pursued by Messrs. Penn is to pack the space between the metallic ring and the piston with hemp. It might be a good way to force out the ring by means of a V block placed on one side of the piston, in the line of the 74 Digitized by Google 586 ENGINE, VARIETIES OF THE STEAM. trunnion, a steady pin being inserted in the piston on the opposite side, with a corresponding oblong hole in the packing-ring, 80 as to prevent the packing-ring from turning round at the same time that it was permitted to expand. Messrs. Penn make use of a single ring and tongue-piece with the block be- hind recessed, 80 as not to interfere with the hemp packing. The upper side of the ring, too, is sharp- ened off to an edge. 1556. SCALE.-1 inch=1 foot. 1557. 1555. o SCALE.-1 inch=1 foot. SCALE.-1 inch=1 foot. Valves-The function of a valve is to open or close a passage, and all the varieties are divisible into the genera of lifting and sliding valves. Sliding-valves are generally employed to admit the steam alternately above and below the pistons of engines, except in the case of pumping engines, and there 1558. 1550. lifting or spindle valves are usually employed. Safety-valves are always spindle-valves, though a slide-valve, opened by the rise of a column of water or mercury, has been proposed as a safety-valve. The valves of pumps are generally spindle, flap, or ball valves, but are slide-valves sometimes. A cock is to be regarded as a circular aliding-valve. The diameter of the spindle of spindle-valves is usually made about one-eighth of the diameter of the valves; in small valves the proportion is greater. Safety-valves.-A common proportion is a circular inch of orifice per 14-horse power, or 8 of a circular inch per horse power. In ma- rine engines safety-valves are usually lifted by a lever, which presses up the spindle from underneath, and the weights are either wholly or partially hung from the spindle. The spindles are sometimes guided by means of an iron bar, which passes across the steam-chest; but this is not a commendable practice, as explosions have occurred from the jamming of the spindles in the guide, in consequence of an altera- tion of shape in the steam-chest when the pressure came on. Fig. 1558 represents the safety-valve of a locomotive engine, which is of the steelyard kind, and the end of the lever is kept down by a spring. Boiler explosions sometimes arise from the adhesion of the safety-valve to its seat, and numerous plans have been devised, and some of them of considerable ingenuity, for obviating this source of danger. Digitized by Google ENGINE, VARIETIES OF THE STEAM. 587 The ordinary method of feeding land boilers by a head of water may rank among these contrivances it is shown in Fig. 1559. A float, which is usually made of stone or iron, is so balanced, by means of a counterweight, that it rises or falls with the fluctuations of the water level, and in so doing opens or closes a valve in a small cistern, at the top of a stand-pipe set on top of the boiler, thereby maintaining the water at the right level. The stand-pipe is of sufficient diameter to receive a float connected with a chain proceeding to the damper; and as the water is forced up in the stand-pipe to a height corre- sponding to the elasticity of the steam, the float in the stand-pipe will rise and fall with the varying pressure, thereby adjusting the vehemence of the draught to the wants of the engine. If the pressure becomes very high, the water will be forced out of the boiler through 1560. the feeding-valve. This valve, however, is usually made too small to be capable of answering as a safety-valve, but it gives intimation of danger. In steam vessels an upright pipe has been recommended to be applied to the top of the boiler, of sufficient capacity to give free exit to the steam, and descending beneath the water level, 80 as to be under ordinary circumstances filled with water. When the steam becomes too high, the water is forced up this pipe, and proceeds into the chimney by a branch-pipe provided for the purpose. If the pressure be not speedily relieved, the whole of the water above the mouth of the pipe will leave the boiler, and then the steam will rush out. Another plan consists in the application of a vessel at the end of a lever, to receive the water which flows over from the upright pipe, and this vessel of water is 80 arranged that its weight opens the safety-valve. In some combinations a column of quicksilver is employed, instead of a column of water; but it has been found that the quicksilver is gradually dissipated by the action of the steam. A large steam-gage is recommended by some persons as an effectual safeguard against explosion, in the event of an adhesion of the safety-valve; but for all ordinary pressures we think the column of water will be found to be a preferable expedient. Slide-valves-There are three principal varieties of slide-valves-the long D, the short D, and the three ported. This last valve, Fig. 1560, consists of a box set over a central port, and moved alternately over ports set on each side of the central port, 80 as to establish a communication between the central and side ports alternately. The central port is the escape port: the steam passes in the direction of the arrows, and when exhaustion is being performed by one port, steam is being admitted by the other. This species of valve is used very extensively in 156L high-pressure engines, and almost universally in locomotives. It is very simple; and by leaving the face of the cylinder when the press- ure within the cylinder exceeds the pressure in the valve-casing, it enables the water to escape when the engine primes: but it occasions a con- siderable waste of steam if the ports and pas- sages are large; and if they are not large, a considerable loss of power arises from the extra- resistance experienced by the piston. A The long D valve has always been in much favor with engineers, though, as we think, with- out sufficient reason. The short D valve is, in our judgment, preferable, and we give in Fig. 1561, an excellent specimen of this species of valve. Some short D valves have only one rod to connect the ends, and others have two; but three are preferable, as they give greater stiff- ness than is otherwise attainable. It is expe- dient to zinc the connecting-rods, as in the wake of the ports they frequently get wasted rapidly away by the steam. The piston-valve with skewed ports is repre- sented in Fig. 1562. This species of valve is, in our judgment, preferable to the D in many respects. It is more easily worked, admits of metallic packing, and is not liable to have its form altered by twisting. V In working large engines considerable diffi- culty is experienced in handling the valves, from the weight and the pressure of the steam forcing the valve against the face of the cylin- der. Various schemes have been adopted to obviate this disadvantage. In some cases a small engine has been used to work the valves at starting, and another plan has been to balance the valves by the opposing pressure of the steam. One of these balance valves is rep- resented in Figs. 1563, 1564, and 1565. It is a slide-valve, and has no hemp packing as is usual, but is kept tight by means of a metallic packing-ring, divided into segments which are pressed against the inner side of the valve-chest back by spiral springs Digitized by Google 588 ENGINE, VARIETIES OF THE STEAM. and steam pressure. Some inconvenience might be anticipated from the circumstance of the rubbing surface of the packing-ring at the sides of the valve being greater than at the ends. aaa is a brass ring divided into segments, as shown in the plan, the object being to allow the ring to accommodate itself to any slight curve that may be caused by the pressure of steam on the valve-box back or cover. 6666 is a space containing about three layers of well-plaited square gasket. ccccisa brass ring in one piece fitted loosely into the groove, having on one side of it a number of small steel pegs, dddd, on which is placed spiral springs. These 1562. n springs force the ring, and by it the hemp packing is pressed hard against the brass segments, causing them to slide steam-tight against the valve-box cover, the pressure being further regulated by a communication made between the space in which the spiral springs work, and the steam in the valve-box. A communication is made between the condenser and the space within the brass ring a a a in the valve-box cover, and the condenser regulated by a cock, 80 that when the engineer is handling the engine he can cause a vacuum at the back of the slides. EEE is a wrought-iron hoop bound to fit the turned part of the valve, which slides freely in it, uninfluenced by the valve-rod FF. The valve employed by Messra. Penn in the most recent of their oscillating- engines, is substantially the same with that just represented. The ring, however, is in a single piece, and is tightened against the back plate by means of another ring, armed with four lugs, lying beneath the packing-ring. Between this ring and the packing-ring hemp packing is interposed, and the lower ring is raised up by unscrewing, out of bosses on the valve, four bolts passing through the lugs. These bolts may be unscrewed, and the pack- ing tightened, by removing four plugs in the back of the valve-casing. By this method of arrangement 1563. E Back View. it is not necessary to make the back of the casing removable, but merely to plane and fit the back to the rings before the parts are put together. The back plate which forms the cover of the casing is scraped as carefully as the valve and cylinder faces, but only as much of the back plate is thus fitted as the ring comes into contact with during the travel of the slide, and the fitted portion is cast a little higher than the other portions. Digitized by Google ENGINE, VARIETIES OF THE STEAM. 589 Expansion-valves.-Slide-valves are the most satisfactory species of expansion-valve; but spindle- valves are the simplest, and they are the most frequently employed. Most of the spindle expansion- valves are of the double beat or equilibrium kind, such as are used in the Cornish engines. The form of the cam is a sort of twisted elliptical cylinder, 80 to speak, against the exterior surface of which a pulley fixed, on the end of a lever, presses, and by the motion thus derived opens the valve. Fig. 1566 represents the variable expansion-geer of Gonzenbach. It consists of an ordinary short slide-valve and casing, with ports in the back, upon which another slide-valve and casing are im- posed. The ordinary valve is worked in the usual manner; but 1565. 1567. F 1564. a a E 6 6 W E Transverse section. Perpendicular section. the travel of the supplementary valve may be lengthened or shortened, so as to cut off the steam at any part of the stroke. A is the common valve, and F the valve-chest; B is the supple- mentary valve, which is a solid block with two perforations, which, 1566. H 1K B F 9 D 2 when opposite the ports in the cover F, admit steam from the supplementary valve-chest K. The starting-handle is connected with the shaft g, upon which a lever is fixed, and 80 connected by links with the extremities of the eccentric-rods D and d, that when one eccentric-gab is in geer with the pin e', upon the valve-lever, the other shall be disengaged. In the figure the engine is in geer for going ahead, and the reversing eccentric-rod D is disengaged from the ordinary valve, and in geer with the supple- mentary valve, by means of a second gab f. which receives a pin upon the expansion-valve lever G. in this lever there is a long slot, in which a pin G, fixed on the valve link H, may be moved to a grenter Digitized by Google 590 ENGINE, VARIETIES OF THE STEAM. 1569. : E C H G Et 1 I K S' 0 B O F H G E Q L I K S 0 P c U A Digitized by Google ENGINE, VARIETIES OF THE STEAM. 591 or less distance from the centre of the expansion-valve shaft, by means of the handle T; and the effective length of the valve-lever being thus varied, the travel of the valve receives a corresponding variation. The expansion-valve thus receives the reversing motion while the slide-valve is receiving the forward motion. Fig. 1567 represents the variable expansion geer of Mayer. It consists of an ordinary valve, with the addition of perforations through the top and bottom faces, each of which is covered by a supple- mentary valve upon the back of the first, consisting of two solid blocks, into which a valve-rod is screwed, having a right-handed screw where it penetrates the one block, and a left-handed screw where it penetrates the other; 80 that the blocks will be set closer or further apart, according to the direction in which the rod is turned. The ordinary valve receives its motion in the usual way, and the expan- sion-valve is moved by means of a pin attached to the piston-rod, which works in a slotted lever, to which the expansion valve-rod is attached. The motion of the two valves is, therefore, at right angles, and the expansion-valve is about one-fourth of a revolution in advance of the steam-valve. In Fig. 1567, A is the steam-valve, BB the expansion-valve, TT the valve-rod, with right and left handed screw; G a wheel attached to the valve-rod, over which a pitch chain passes, by means of which the valve-rod is turned, and the blocks are altered 80 as to give the requisite amount of expansion; D is the valve- shaft, and CE the valve-lever; F is the pin attached to the piston-rod. In all cases in which the mo- tion of the expansion-valve is the same as that of the piston, the slide-valve must be provided with lap. Sliding cut-off valve.-This is the invention of Mr. Simon P. Winne, of Albany, N. Y. Fig. 1568 is a vertical longitudinal section of the steam chest and passages of a cylinder, with the valves in their place and ready to act. ABCD represent a steam cylinder, having on its top A C, the usual hollow steam channel E E, divided by partitions to separate the entering from the issuing steam in the usual way with the exit passage G, and openings into the cylinder at HH. JJJJ is a steam chest made 1568. a little longer than the ordinary kind, but of the same form. The steam entering in by the pas- sage X, fills the chest, from which, as will be no- ticed, there are four openings into the channels c E, and one into the exit passage G. They are J J all properly faced with slides, and arranged in M E E reference to the valves to move over them, as seen in the engraving. cd are the three slide- valves. c and e have solid bottom surfaces, and d, the central valve, has the usual chambered D passage to effect a communication together be- tween two of the three central passages from the chest into the steam channel. The valve- rod K passes through a stuffing-box at the one end, and has the other end passed through a stuffing-box or into a chamber L. bored out to receive support and steady its movements. The rod passes through the upper parts of the valves c c, which are pierced to receive it; but it is not attached, but moves freely through them. The rod K, moved by the eccentric, communicates motion to the valves by means of two stop-nuts, which screw upon a thread in the rod for adjusting the cut-off. These nuts will readily be noticed at the ends of the catches. Upon the two valves c and e are mounted catches h and i, moving on pivots, and have handles k k. The catch drops down upon the valve-rod and is held in this position by its own weight or a spring, as may be found most suitable. m is a metallic plate placed over the centre of the valve range. It has its lower edge curved or made flat, as may be desired. Its chord is parallel with the rod K. This plate is attached to a spindle at right angles to it, which passes through a stuffing-box, where it is at- tached to the handle 0, for raising and depressing it, thus attaching and detaching the catches h and i from the nuts on the rod K. The valve d lies upon its bed unattached to the rod, and is only moved by the impulse of c and e alternately. Between these two valves and d there is a space to be determined by the portion of the stroke of the piston at which the steam is to be cut off. Operation.-The valves are to be attached to the rod by the catches when the cut-off is to be used. The engine in the engraving is represented as having just begun the stroke of its piston from left to right, and the valve-rod from right to left. Before the piston has passed over one-third of its stroke, e will have covered the first opening, cutting off all passage of steam from the chest to the opening H of the cylinder, and will keep it covered during the remainder of the stroke, during which, valve d is kept stationary, passing steam from the right passage of the cylinder H, through the two passages indicated by the middle arrow, and out of G, until the valve e impels it to the left, and the valve c is carried over the other opening, and opening the other exit passage. This completes the stroke, and the same opera- tions are repeated continuously from left to right and right to left. When it is desired to give the en- gine full steam, the lever o is depressed, by which the catches are raised to allow the three valves to act in concert, operating as a single slide driven by a cam. The stroke can be cut off and regulated by the handle O. It is only necessary to depress the bar-plate m, to permit the proper catch to drop over the stop nuts. and the required cut-off will be effected. The valves when used for upright engines may be kept in their places by springs during the absence of steam pressure. Expansion-Allen's cut-off-The combination whereby an adjustable cut-off is obtained for engines using poppet-valves, is represented by the drawings hereto attached, Figa. 1569, 1570. A is the rock-shaft, B the lifting ro.ls, and c the exhaust-valve lifter, as usually arranged and worked. D is the steam-valve. E the valve stems. F is a piece attached to the valve stem by means of which it rests on the toe G. This toe G is attached to the shaft H. On the same shaft H is the toe T, On the lifting rod B is fastened the stud I, having a centre on which it is supported, and turns one end of the lever K; the other end L is connected with the arm N, by the rod S. This arm N is at- Digitized by Google 592 ENGINE, VARIETIES OF THE STEAM. 1570. C G H KI 0 N P B B P H G I K I 0 A P o o Digitized by Google ENGINES, SUMMARY OF. 593. tached to the shaft O. On the same shaft 0 is attached the arm P, to which arm is given a recipro- cating motion coincident with that of the piston, and taken from the beam or any part having the same motion (suitably reduced) as that of the piston.-On the lever K is placed the movable piece Q, the roller R is attached to the piece Q, and on the roller R rests the toe T. It will be seen that by the upward motion of the lifting rod, the end I of the lever K is raised, while by the downward motion of the arm N the other end of the lever K is lowered. But it will also be per- ceived that the upward motion of the end I is at its greatest velocity at the beginning of the stroke, while the arm N, which lowers the end L, has no motion at the immediate beginning of the stroke; by reason of these relative motions, the lifting end will have the advantage, and the valve will therefore be raised at the early part of the stroke, but the motion of the lifting end is rapidly diminishing, while that of the lowering end is increasing; it therefore will soon happen that the lowering end will lower the valve more rapidly than it is raised at the other end, and thus the valve will be restored to its seat. The point of stroke at which the valve will be restored to its seat, will depend on the proportion of parts, and with suitable proportion parts, on the position of the movable piece Q. If, in the position repre- sented in the drawings, the valve is restored at half stroke, then by moving the piece Q towards the lifting end the valve will be restored at à later point, and by moving it towards the lower end the valve will be closed at an earlier point.-Further descriptions of American engines will be found under the heads, LOCOMOTIVE, MARINE, STATIONARY, and SCREW PROPELLER. ENGINES, Summary of.-The greater part of this summary is taken from the Engineers' and Mechanics' Pocket-Book, by C. H. Haswell, engineer in chief of the U.S. Navy. Nominal Horse-Power of Engine. Names of Parts. 10 15 20 25 30 40 50 60 70 80 90 100 110 120 Diameter of in. in in. in. in. in. in. in. in. in. in. in. in. in. Cylinder 20 24 27 291 82 36, 40 43 46 48 50 521 551 57 Piston-rod 2 21 24 3 34 31 4 41 41 44 41 5 51 51 Air-pump 12 15 17 17} 18} 21 23 24 26 271 28 30 311 34 Air-pump rod 11 11 2 21 21 21 24 21 3 81 31 34 4 41 Injection-cock 11 11 11 1] 2 21 21 21 3 3b 34 31 31 81 Hot-water pump 21 21 8 31 81 4 41 41 5 51 6 61 7 71 Feed-pipe 11 11 2 21 21 21 21 21 3 3t 31 81 31 4 Steam-pipe 4 5 54 6 61 7 74 81 91 10 101 11 111 12 Waste water-pipe 5 6 7 71 8 9 91 10 10} 111 121 13 131 14 Beam gudgeon 81 44 5 54 of 6 6} 7 71 8 81 9 91 94 Pins in beam ends 2 21 21 8 3₺ 31 4 41 41 41 5 51 51 51 Air-pump pins in beam 11 18 11 1] 2 24 21 21 21 2] 3 3f 31 84 Crank pin 21 8 31 31 4 41 5 51 6 6} 7 71 74 8 Main shaft 41 51 64 62 7 73 81 91 10 104 101 111 12 121 Paddle wheels, in feet 9 11 11 12 13 13 15 17 17 19 19 21 21 23 Weigh-shaft bearings 2 21 21 21 25 24 24 21 3 31 34 31 31 34 Stroke of piston 24 30 30 33 36 36 42 48 52 56 60 63 66 72 $4 air-pump bucket 12 15 15 16} 18 18 21 24 26 28 30 311 33 36 44 feed-pump plunger 6 73 71 8 9 9 101 12 13 14 15 16 16} 18 Cylinder cross-head, Depth of boes 6 73 8 9 91 10, 12 18 14 141 15 16 17 17+ Diameter of boss 4 41 5 51 6 64 73 8 84 9 91 10 11 12 Depth of middle 5 51 64 7 71 81 91 101 111 111 121 13 131 14 Thickness 1f 18 11 2 21 21 21 3 31 31 31 31 4 4d Air-pump cross-head, Depth of boss 41 5 51 6,1 64 8 9 10 101 10} 11 111 12 121 Diameter of boss 21 3} 81 4 4g 41 5f 51 54 6 61 64 7+ 7+ Depth of middle 31 4 41 5 51 61 7 78 8 81 81 9 94 91 Thickness 1 1f 11 1} 11 11 2 21 21 21 21 21 21 21 Columns, Diameter at top 4 41 5f 51 6 7 8 81 91 91 91 10 101 101 Diameter at bottom 41 51 61 6} 6} 71 9 97 101 101 11 111 111 12 Centre to centre of Air-pump, side rods trans- versely 291 341 371 391 421 471 53 55} 601 63 67 681 70 72 Beams, do. 33 39 421 45 48 54 60 63 69 69 72 78 80 83 Frames, do. 21 23 25, 26 27 30 34 34 40 40 42 44 45 46 Engines, do 66 72 76 80 84 88 96 100 108 108 112 126 128 130 Length of steam port 71 84 10 11 111 13 15 181 181 19 19 20 20 21 Breadth of steam port 11 11 2 21 21, 21 8 3 4 4 41 41 41 41 Fort valve passage, depth 2 2 21 21 34 34 4 41 5 51 51 6 6} 7 64 44 width 13 14 151 17 18 20 24 26 28 28 29 31 31 32 Beam, Breadth at middle 14 18 19 21 23 25 28 29 33 34 35 36 38 39 Breadth at ends 5 6 61 73 8 81 10 10} 12 121 124 14 15 151 Thickness 1 11 11 11 11 11 11 2 21 21 21 21 21 21 75 Digitized by Google 594 ENGINES, SUMMARY OF. TABLES OF DIMENSIONS, &c., of 63 STEAM VESSELS, and of their ENGINES and PROPÈLLERS; selected from a more extended list, with the view of presenting only those of which the complete particulars are recorded. Nore.-The tonnage is according to the old builders' measurement. In the column showing the material of each vessel, the letter W. signifies Wood, and I. Iron. Length. Number. Name of Vessels. Date of launch. Material. Tonnage. Between Over Of all. keel. perpendi- Depth. Mean draught. Extreme breadth. culars. ft. in. ft. in. ft. in. ft. in. ft. in. ft. in. 1 Actseon, &c. 1837 W. 552 171 o 17 8 10 o 25 10 2 Agir 1841 I. 254} 150 0 145 0 10 1 5 8 19 o 3 Alice 1839 I. 170 95 0 9 0 4 6 20 0 4 Arcadia, &c. 1840 W. 1200 228 0 206 0 22 6 16 6 34 6 5 Archimedes 1836 W. 237 125 0 107 0 13 0 9 4 22 6 6 Avon and Severn 1841 W. 1354 238 0 213 0 30 6 17 6 36 6 7 Berenice 1836 W. 646 148 5 164 10 20 0 13 0 28 8 8 Black Eagle W. 496 136 9 155 0 14 10 10 6 26 1 9 Blackwall 1842 I. 2581 145 0 9 10 5 0 19 1 10 British Queen 1838 W. 1862 275 0 27 6 17 0 40 0 11 Clyde, &c 1841 W. 1354 238 0 213 0 23 6 17 6 36 6 12 Colchis, &c. 1837 W. 4331 156 0 13 6 9 6 24 0 13 Cormorant 1843 W. 1110 210 0 180 0 21 0 36 0 14 Courier 1841 I. 310 158 water line 9 o 1 4 20 0 15 Cyclops 1839 W. 1195 216 6 23 0 15 6 35 6 16 Dart. I. 48 81 0 7 0 2 3 11 0 17 Dee, &c 1841 W. 1354 213 0 30 6 17 6 36 6 18 Devastation 1841 W. 1100 210 0 180 0 21 0 36 0 19 Dolphin 1839 I. 107 110 0 7 6 2 3 14 0 20 Dundalk 1834 I. 560 170 fore rake 16 0 10 6 26 0 21 Dundee, &c 1834 W. 650 170 0 17 6 11 6 28 0 22 Eclip&e 1840 I. 2771 156 0 11 0 5 6 19 o 23 Enterprise 1839 I. 92 76 6 8 0 3 9 16 0 24 Era I. 60 85 0 5 11 2 5 12 0 25 Fairy 1845 I. 260 145 0 10 6 5 0 21 0 26 Father Thanes 1840 I. 247 140 0 10 0 4 0 19 0 27 Fulton W. 181 6 deck 10 0 34 6 28 Grappler 1845 I. 557 165 0 17 0 10 0 26 6 29 Great Britain 1844 I. 3443 320 0 289 0 32 6 16 0 51 0 30 Great Liverpool 1837 W. 1140} 209 5 19 8 16 0 30 10 31 Great Northern 1842 W. 1430 247 0 221 0 26 0 18 0 37 0 32 Great Western 1838 W. 1321 236 0 23 3 16 0 35 4 33 Hamlet 1842 I. 130 96 0 9 6 5 6 17 o 34 Herne 1844 I. 355 155 6 10 0 6 2 21 6 35 Hibernia 1842 W. 1350 218 fore rake 24 0 17 6 36 o 36 India W. 1000 189 0 28 0 32 0 87 Invincible 1844 I. 125 0 8 0 5 6 17 8 38 Isis and Trent. 1841 W. 1298} 215 0 23 0 17 3 36 0 39 Lady Burgoyne 1843 I. 126 0 9 6 4 9 17 6 40 Locomotive 1841 I. 70 105 0 6 6 2 6 11 6 41 Medea 1843 W. 807 179 4 20 0 14 0 31 11 42 Nimrod 1843 I. 591 175 0 180 0 16 0 11 0 26 0 43 Nile W. 911 180 0 deck 20 " 13 6 33 0 44 Northern Light Yacht 1845 I. 3031 146 3 deck 142 0 12 9 6 0 21 o 45 Peloro 1843 W. 252 130 0 11 2 20 21 46 Penelope 1842 W. 1630 215 main deck 25 0 40 0 47 Precursor 1841 W. 1476 244 0 225 0 25 0 17 0 37 0 48 President 1840 W. 1840 265 0 30 0 17 0 41 0 49 Prince Albert I. 300 155 0 9 6 .4 6 19 6 50 Prince of Wales 1842 I. 585 160 0 15 6 7.9 26 6 51 Princess Royal 1841 I. 800 185 0 17 0 10 0 28 0 52 Princess Alice 1843 I. 260 145 0 10 6 6 6 20 0 53 Railway 1842 I. 2581 145 0 9 10 5 3 19 1 54 Rainbow 1837 I. 581 190 0 12 0 6 0 25 0 55 Retribution 1844 W. 1710 192 10 220 0 26 4 18 0 40 6 56 Rocket 1842 I. 70} 90 0 7 4 12 8 57 Rose, &c 1840 I. 306 148 0 11 6 6 6 20 6 58 Ruby 1836 W. 2721 141 91 155 0 10 2 4 6 19 0 59 Styx, &c. 1839 W. 1057 180 0 duk 21 0 14 9 36 2 60 Thunderbolt 1842 W. 174 0 deck 21 0 14 6 36 0 61 Vernon 1841 W. 1000 170 0 22 0 15 6 36 0 62 Water Witch I. . 123 0 5 6 2 9 16 4 6:) William Wi'berforce 1810 W. 650 200 0 17 0 10 0 27 0 Digitized by Google ENGINES, SUMMARY OF. 595 PROPELLING MACHINERY. NOTE.-In the last column, showing the description of engines, the abbreviations S. L. signify Side Lever; D. A. Dirret Action; O. Oscillating; St. Steeple; D. C. Doub.e Cylinder; H. P. High Pressure. Stroke. Number of Horse power Number. Diameter of Paddle wheel's Kind of of Diameter. engines. each engine. cyllnders. No. per boards. engines. Length. minute. in. ft. in. ft. in. ft. in. ft. in. 1 2 146 62 5 9 20 24 6 8 10 X 2 3 2 2 41 361 3 0 30 16 0 7 6 X 1 4 S.L. 3 2 30 31 3 3 14 0 D.A. 4 2 210 72 6 10 16 28 0 9 0 X 3 0 S.L. 5 2 42 37 3 0 26 screw 6 2 230 7 0 16 30 0 S.L. 7 2 118 56 5 6 21 23 0 8 6 X 2 1 S.L. 8 2 135 62 4 6 23 0 5 6 X 4 0 O. 9 1 92 55 3 0 31 15 6 9 10 X 1 2 St. 10 2 2441 771 7 0 16 30 0 9 6 X 2 81 S.L. 11 2 230 744 7 6 15 30 0 S.L. 12 2 62 42 4 6 23 17 0 8 0 X 1 9 S.L. 13 2 158 651 5 3 22 26 8 8 3 X 2 0 D.A. 14 2 35 34 3 0 28 15 0 8 0 X 1 11 O. 15 2 154 64 5 6 21 26 0 8 0 X 1 10 D.A. 16 2 101 20 2 0 35 11 0 4 6 X 0 11 17 2 217 73 7 0 16 28 6 9 6 X 2 6 S.L. 18 4 112 54 1-16th 6 0 18 26 0 9 0 X 2 1 D.C. 19 2 21 28 2 0 85 10 4 4 8 X 1 6 S.L. 20 2 140 61 5 6 21 24 9 8 8 X 2 1 S.L. 21 2 126 58 5 6 21 24 0 8 0 X 2 2 S.L. 22 1 100 54} 4 0 28 16 6 9 0 X 1 3 St. 23 2 21 271 2 6 34 12 6 5 4 X 1 2 S.L. 24 2 12 17] and 29 1 8 34 10 4 5 o X 1 0 D.C. 25 2 54 42 8 0 50 screw O. 26 2 371 35 3 of 30 18 6 8 6 X 1 3 O. 27 2 250 50 9 0 25 22 5 11 6 X 3 0 28 4 110 40 4 6 25 21 0 8 0 X 1 6 D.C. 29 4 300 88 6 0 18} screw 30 2 229 75 7 0 16 28 5 S.L. 31 2 162 68 4 6 22 screw 32 2 220 731 7 0 16 28 9 10 0 X 2 6 S.L. 33 2 21 271 2 8 88 11 0 5 6 X 1 8 S.L. 34 2 60 431 3 6 29 18 6 11 0 X 1 6 S.L. 35 2 250 77f 7 6 15 30 4 10 0 X 3 0 S.L. 36 2 151 63 5 9 20 26 6 8 0 X 2 3 S.L. 37 1 83 49 4 2 314 16 0 5 8 X 1 2 St. 38 2 225 74¥ 7 0 15 29 0 10 0 X 3 0 S.L. 89 2 46 39 3 0 32 16 0 8 0 X 1 4 O. 40 2 51 4 0 27 H.P. 41 2 112 557 5 0 22 24 0 5 8 X 4 6 S.L. 42 2 160 66 5 3 22 24 6 8 6 X 2 7 D.A. 43 2 132 60 5 2 22 22 0 9 7 X 2 9 S.L. 44 2 76 47 4 3 25 19 0 7 6 X 1 10 O. 45 2 50 391 3 6 29 15 6 8 0 X 1 4 S.L. 46 2 320 91 6 0 18 30 0 10 0 D.A. 47 2 260 80 7 0 16 28 0 S.L. 48 2 266 80 7 6 15 31 0 S.L. 49 2 50 40 3 4 32 17 6 9 0 X 1 4 D.A. 50 2 135 61 5 0 22 25 0 6 9 X 2 0 St. 51 2 208 78 6 3 17 29 0 7 9 X 2 4 St. 52 2 60 48 8 6 30 18 5 7 0 X 2 3 D.A. 53 2 46 39 8 0 33 15 6 9 8 X 1 2 O. 54 2 88 50 4 6 25 21 0 9 10 X 1 8 St. 55 4 400 72 6 0 34 0 13 0 X 2 6 D.C. 56 2 10 19 2 0 40 9 8 3 8 X 0 10 O. 57 2 53 40.1 3 6 29 17 0 8 0 X 1 6 S.L. 58 2 511 40 3 6 30 17 6 9 2 X 1 3 S.L. 59 2 142 62 5 3 20 26 0 8 3 X 1 10 D.A. 60 2 163 67 5 0 20 26 0 7 10 D.A. 61 1 28 30 8 0 32 14 0 S.L. 62 2 16} 22 4 0 45 10 0 D.A. 63 2 140 60 6 0 20 24 0 8 6 X 2 0 S.L. Digitized by Google 596 ENGINES, SUMMARY OF. The following are considered in England the most approved proportions for steam vessels:- Length of keel 1. Breadth of beam fth. Depth of vessel 10ᵗʰ. Centre of paddle boxes fths from the stern end of the keel, and fths from the stern post. LOCOMOTIVE ENGINES.-TABLE containing the velocity of the pistons, that of the circumference of the driving wheels being taken as 1. Stroke of the Pistons. Diameters of Driving Wheels. in. 4ft. Oin. 4ft. 6in. 5ft. Oin. 5ft. 6in. 6ft. Oin. 6ft. 6in. 7ft. 0in. 7ft. 6in. 8ft. Oin. 20 0.2652 0.2393 0.2122 0.1929 0.1768 0.1632 0.1516 0.1414 0.1326 19 0.2519 0.2273 0.2016 0.1832 0.1679 0.1550 0.1440 0.1343 0.1259 18 0.2386 0.2153 0.1910 0.1736 0.1591 0.1468 0.1364 9.1272 0.1194 17 0.2254 0.2034 0.1803 0.1640 0.1503 0.1387 0.1288 0.1202 0.1127 16 0.2121 0.1914 0.1697 0.1543 0.1415 0.1305 0.1213 0.1131 0.1061 15 0.1989 0.1795 0.1591 0.1447 0.1826 0.1224 0.1137 0.1060 0.0994 14 0.1856 0.1675 0.1485 0.1350 0.1237 0.1141 0.1061 0.0990 0.0928 13 0.1724 0.1555 0.1379 0.1254 0.1149 0.1061 0.0985 0.0919 0.0862 12 0.1591 0.1436 0.1273 0.1157 0.1061 0.0979 0.0909 0.0848 0.0796 Application of this table for finding the tractive power of locomotive engines.-Multiply the sum of the areas of the two pistons by the effective pressure of the steam in pounds, and further, that product by the coefficient in the table (belonging to its driving wheels and stroke of the pistons), and this new product will be the traction of the engine in pounds. Ex. A locomotive engine to have 5 feet 6 inch driving wheels, cylinders of 13 inches diameter by 18 inches stroke, and the effective pressure of the steam to be 40 lbs. on the square inch what is its traction 1 (2 X 132.66) 40 X 0.1736 1842.39 lbs. of traction. If it be required to know the number of tons the engine is able to draw on a level, divide its traction by the friction in pounds. If the engine is to go up inclines, then add to that friction the gravity in pounds due to a ton on that incline, and use this sum as a divisor for the traction: the quotient will be the number of tons the engine is capable to rise up that incline with. In both cases is the weight of the engine and its tender in the quotient included. Explanations.-By effective pressure is understood the pressure of the steam above the pressure of the atmosphere, less the number of pounds necessary to keep the engine by itself just in motion. Friction, the power necessary to move a mass along, which is generally taken to be, on railways, equal to 10 lbs. for every ton. Gravity, the power to overcome the tendency of a mass or load to descend an incline, being always equal to the quotient of the product of the load, and height of the incline, divided by the length of the incline. Therefore the above engine would draw 1842.39 = 184 tons on a level; 10 and, on an incline, say as 1 in 300, Friction = 10 lbs. Gravity = 1 X 2240 = 7.466 lbs. 300 17.466 lbs. Consequently, 1842.39 = 105.5 tons up an incline of 1 in 300. 17.466 If the weight of the engine, with its tender, be taken at 18 tons, it will draw a net gross load of 166 tons on a level, and 87.5 tons up an incline of 1 in 300. Digitized by Google ENGINES, SUMMARY OF. 597 TABLE showing the Speed of an Engine, when the time of performing a 1, 1, or 1 Mile, is given. Time of Time of Time of Time of Time of Time of Speed per hour. performing performing performing Speed per hour. performing performing performing t mile. t mile. 1 mile. t mile. t mile. 1 mile. Miles. min. sec. min. sec. min. sec. Miles. min. sec. miu. sec. min. sec. 5 3 0 6 0 12 0 53 0 17. 0 34. 1 7.9 6 2 30. 5 0 10 0 54 0 16.7 0 33.3 1 6.6 7 2 8.6 4 17.2 8 34.3 55 0 16.4 0 32.7 1 5.4 8 1 52.5 8 45. 7 80. 56 0 16.1 0 32.1 1 4.3 9 1 40. 8 20. 6 40. 57 0 15.8 0 31.6 1 3.1 10 1 30. 3 0 6 0 58 0 15.5 0 31. 1 2. 11 1 21.8 2 43.6 5 27.3 59 0 15.2 0 30.5 1 1. 12 1 15. 2 30. 5 0 60 0 13. 0 30. 1 0 13 1 9.2 2 18.4 4 37. 61 0 14.7 0 29.5 0 59. 14 1 4.3 2 8.6 4 17.1 62 0 14.5 0 29. 0 58. 15 1 0 2 0 4 0 63 0 14.3 0 28.5 0 57. 16 0 56.2 1 52.4 8 45. 64 0 14.1 0 28.1 0 56.2 17 0 52.9 1 46. 3 81.8 65 0 -18.8 0 27.7 0 55.4 18 0 50. 1 40. 3 20. 66 0 13.6 0 27.2 0 54.5 19 0 47.4 1 34.8 3 9.5 67 0 13.4 0 26.9 0 53.7 20 0 45. 1 30. 3 0 68 0 13.2 0 26.5 0 52.9 21 0 42.8 1 25.6 2 51.4 69 0 13. 0 26.1 0 52.2 22 0 40.9 1 21.8 2 43.6 70 0 12.8 0 25.7 0 51.4 28 0 89.1 1 18.2 2 86.5 71 0 12.7 0 25.3 0 50.7 24 0 37.5 1 15. 2 80. 72 0 12.5 o 25. 0 50. 25 0 36. 1 12. 2 24. 73 0 12.3 0 24.6 0 49.3 26 0 34.6 1 9.2 2 18.4 74 0 12.1 0 24.3 0 48.6 27 0 33.3 1 6.6 2 13.3 75 0 12. 0 24. 0 48. 28 o 32.1 1 4.3 2 8.6 76 0 11.8 0 23.7 0 47.3 29 0 31.1 1 2.1 2 4.1 77 0 11.7 0 23.4 0 46.7 30 0 30. 1 0 2 0 78 0 11.5 0 23.1 0 46.1 31 0 29. 0 58. 1 56.1 79 0 11.4 0 22.8 0 45.6 32 0 28.1 0 56.2 1 52.5 80 0 11.2 0 22.5 0 45. 33 0 27.3 0 54.6 1 49.1 81 0 11.1 0 22.2 0 44.4 34 0 26.5 0 53. 1 46. 82 0 10.8 0 21.9 0 43.9 35 o 25.7 0 51.4 1 43. 83 0 10.8 o 21.7 o 43.4 36 0 25. 0 50. 1 40. 84 0 10.7 0 21.5 0 43. 37 0 24.3 0 48.6 1 37.3 85 0 10.6 0 21.2 0 42.3 38 0 23.7 0 47.4 1 34.3 86 0 10.5 0 20.9 0 41.9 89 0 23. 0 46.1 1 32.3 87 0 10.3 0 20.7 0 41.4 40 0 22.5 0 45.0 1 30. 88 0 10.2 0 20.4 0 40.9 41 0 21.9 0 43.9 1 27.8 89 0 10.1 0 20.2 0 40.4 42 0 21.4 0 42.8 1 25.7 90 0 10. 0 20. 0 40. 43 0 20.9 0 41.9 1 23.7 91 0 9.9 0 19.7 o 89.5 44 0 20.4 0 40.9 1 21.8 92 0 9.8 0 19.5 o 39.1 45 0 20.0 0 40. 1 20. 93 0 9.7 0 19.3 0 38.7 46 0 19.5 0 39.1 1 16.6 94 0 9.6 0 19.1 0 38.3 47 0 19.1 0 38.3 1 16.6 95 0 9.5 0 18.9 0 37.9 48 0 18.7 0 37.5 1 15. 96 0 9.4 0 18.7 o 37.5 49 0 18.3 0 86.7 1 18.4 97 0 9.3 0 18.5 0 37.1 50 0 18. 0 36. 1 12. 98 0 9.2 0 18.4 0 36.7 51 0 17.6 0 35.3 1 10.6 99 0 9.1 0 18.2 0 36.4 52 0 17.3 0 34.6 1 9.2 100 0 9. 0 18. 0 36. NOTE.-If the distance of a journey, and the time it was performed in, be given, and the speed per hour be required, divide the time elapeed by the distance, and look in the table for the nearest speed belonging to that quotient. Example. A distance of 31 miles was performed in 57 minutes; it is required to know the average speed per hour. 57 = 1 minute 50.3 seconds. 31 The nearest speed in the table to that time is 33 miles. TABLE showing the Circumferences of different Driving Whoels. Diam. of Wheel. Length of Circumference. Diameter of Wheel. Length of Circumference. ft. in. feet. n. in. feet. 4 0 12566 6 6 20-419 4 6 13927 7 0 21990 5 0 15707 7 6 23561 5 6 17278 8 0 25-132 6 0 18849 Digitized by Google 598 ENGINES, SUMMARY OF. TABLE showing the Number of Revolutions of the Driving Wheels, or strokes of the Piston, per minute, while the Engine is performing a known number of miles per hour. Diam. of Wheel 4 ft. Diam. of Wheel É e Diam. of Wheel e Diam. of Wheel 5 ft. 6 in. Diam. of Wheel : d Diam. of Wheel lb. 9 è Diam. of Wheel 7 ft. Diam. of Wheel 7 6 in. Diam. of Wheel 2. No. of No. of No. of No. of No. of No. of No. of No. of No. of revolutions revolutions revolutions revolutions revolutions revolutions revolutions revolutions revolutions Number of miles performed per Hour. or strokes or strokes or strokes or strokes or strokes or strokes or strokes or strokes or strokes per min. per min. per min. per min. per min. per min. per min. per min. per min. 35.03 31.59 28.03 25.47 23.34 21.55 20 18.67 17.5 5 70-06 63.17 56.06 50.95 46.68 4310 40 37.34 35.0 10 105.09 9476 84-09 76.42 70.02 64.65 60 56.01 52.5 15 140-12 12636 112-12 101-70 93.36 86.20 80 74.68 750 20 175.15 15795 140:20 12737 11670 107.75 100 93.35 875 25 210-18 189.54 168-18 152.85 140-04 12930 120 112.02 105.0 30 24521 22113 19621 17729 163:38 150.85 140 130-69 122.5 35 28024 252-72 22424 203-76 18672 172.40 160 14936 140·0 40 31527 284'80 25227 22923 210-06 19395 180 16803 1575 45 35030 31590 28030 25475 23340 21550 200 18670 175.0 50 88533 34749 308:33 280.17 25674 23705 220 20537 192.5 55 42036 37908 33686 305-64 280.08 258 60 240 22404 210-0 60 45539 416.67 36439 33111 803.42 280-15 260 242'71 2275 65 490-42 442.19 89242 856.58 32676 301.70 280 261.38 2450 70 525.45 473.85 420-50 372-05 350.10 323.25 300 280.05 262.5 75 560.48 505.50 448-48 40760 373.44 34480 320 298.73 280-0 80 595.51 53689 477-01 43299 39678 366.35 340 31789 2975 85 63054 568.60 50451 458.55 42012 387.90 360 336-06 315-0 90 66557 600-19 53257 48393 443'46 409.45 380 35473 3325 95 700-60 63178 560-63 50950 46680 431-00 400 37340 350 0 100 NOTE-To find the velocity the piston is travelling at in feet, per minute, multiply the number of revolutions of its driving wheels, in the table, by twice the length of its stroke in feet. Ex. What is the speed of the piston of an engine with 6-feet driving wheels and 15-inch stroke, when going at the rate of 50 miles an hour 1 By means of the table: 233.4 revolutions X (2+⁵) = 5835 feet per minute. The number of revolutions of driving wheels is inversely as their diameters, and in direct proportion to the number of miles performed. Ex. How many revolutions have the driving wheels of an engine to make when it is going at 95 miles an hour, their diameter being 9 feet 6 inches According to the table, a 4-feet wheel would have to make 66557 revolutions; therefore 95 : 4 : : 66557 : 4 X 66557 = 280 revolutions. 95 The driving wheels of an engine make 35.03 revolutions when going at the rate of 5 miles an hour how many will they make when going at 9 miles 1 5 : 9 :: 35-03 : 9 X 35.03 = 63-05 revolutions. 5 TABLE of the Areas of Cylinders, from 9 to 15 inches diameter. Diameter of Cylinder. Area of Cylinder. Diameter of Cylinder. Area of Cylinder. Inches. Square Inches. Inches. Square Inches. 9 68.58 121 122.65 10 78.5 13 132.66 101 86.56 131 143-02 11 95.01 14 153.96 111 10384 14} 165-04 12 118.07 15 17662 Digitized by Google ENGINES, SUMMARY OF. 599 TABLE containing the Speed of a Locomotive Engine, in feet per minute, when the rate it is going at in miles per hour is given. Miles Velocity Miles Velocity Miles Velocity Miles Velocity performed in feet performed in fret performed in feet performed in feet per hour. per minute. per hour. per minute. per hour. per minute. per hour. per minute. 2 176 28 2364 54 4752 80 7040 4 352 30 2640 56 4928 82 7216 6 528 32 2816 58 5104 84 7392 8 704 34 2992 60 5280 86 7568 10 880 36 3168 62 5456 88 7744 12 1056 38 3344 64 5632 90 7920 14 1232 40 3520 66 5808 92 8096 16 1408 42 3696 68 5984 94 8272 18 1584 44 3872 70 6160 96 8448 20 1760 46 4048 72 6336 98 8624 22 1936 48 4224 74 6512 100 8800 24 2112 50 4400 76 6688 26 2288 52 4576 78 6864 Application of this table for finding the useful effect of an engine. RULE -Multiply the resistance of the weight or friction of the train in pounds, by the speed of the engine in feet per minute, and divide the product by 33000. Ex. An engine to which are attached 6 carriages, weighing altogether 24 tons, going at the rate of 50 miles an hour, what is its useful effect! (10 X 24) X 4400 33000 = 32 horses' power. MARINE ENGINES.-WITH SIDE WHEELS. CONDENSING.-For 550 square feet of immersed section, with a displacement of 2800 tons. Cylinders. Two, each of 215 cubic feet in capacity. Condensers. 75 cubic feet in each. Air pumps. 50 cubic feet in each. Force Pumps. 71 inches diameter by 46 inches stroke. Water Wheels. 28 feet in diameter by 11 feet in width, 21 arms in each; buckets, (divided both in depth and length,) 14 and 16 inches. Shafts, (wrought-iron.) Diameters of journals, 17 184, and 12 15 inches. Boilers. 6000 square feet of fire and flue surface; flues 40 feet in length, including steam chimney. Grates. 260 square feet. Steam Room. 1770 cubic feet. Pressure. Average, 10 lbs. per square inch, cut off at t of the stroke of the piston: attainable, 20 lbs. Revolutions. From 12 to 184 per minute. Dip of Wheel. 5 feet at load-line. Consumption of Fuel. 35 to 40 tons of bituminous coal per day. Weights. Engines, boilers, water wheels, water in boilers, coal bunkers, engineers' stores, tools, &e., &c., 490 tons of 2240 lbs., viz.:- Engines 211 tons. Water wheels 47 tons. Boilers and smoke pipe 120 " Engineer's stores, tools, dic. 7 " Water in boilers 82 " Coal bunkers 23 " Hull. Launching weight, 1280 tons. CONDENSING.-For 200 square feet of immersed section, with a displacement of 650 tons. Length, 162.5 feet between perpendiculars 27 feet beam; and 12 feet depth of hold. Load-line, 8.25 feet. Cylinders. Two, each of 56.5 cubic feet in capacity. Pressure. 16 lbs. per square inch, cut off at I the stroke. Revolutions. 22 per minute. Water Wheels. 21 feet in diameter by 7.5 feet face, with 16 arms. Dip. 2.5 feet. Buckets. 16 and 10 inches in depth. Boilers. 1900 square feet of fire and flue surface. Grates. 84 square feet. Steam Room. 480 cubic feet. Fuel, (natural draught.) At 19 revolutions, 1750 lbs. of anthracite coal per hour. Weights. Engines and frames 196,000 lbs. Water in boilers 50,000 lbs. Boilers and Chimney. 68,000 " Tools and stores, dc. 4,500 " Coal bunkers 16,000 " 834,500 lbs. Weights of metals in engines, (unfinished.) Cast-iron 100,500 lbs. Composition 11,300 lbs. Wrought-iron 82,000 " Copper 6,700 " Hull. Wrought-irou, weighing 507,387 lbs. Digitized by Google 600 ENGINES, SUMMARY OF. GREAT WESTERN." CONDENSING.-For 2372 tons displacement, (load-line,) with an area of immersed section of 480 square feet. Length between perpendiculars, 212 feet; beam, 35 feet 4 inches : depth of hold, 23 feet 2 inches; draught of water, 17 feet. Cylinders. 781 inches in diameter by 7 feet stroke of piston. Pressure. 81 lbs. per square inch. Revolutions. 121 per minute. Water Wheels. 28 feet in diameter by 10 feet face. Buckets. 20 and 10 inches in depth. Tonnage. Vessel, 1340 tons. Engine room, 641.5, or one-half of the whole. Weights. Engines, 300 tons. Boilers, 100. Water in boilers, 80. Total, 480. Centre to centre of engines, 13 feet. H. M. RETRIBUTION." CONDENSING.-For 1641 tons burden, with 600 square feet of immersed section. Length between perpendiculars, 220 feet; beam 40 feet 6 inches; depth of hold, 26 feet 4 inches. Cylinders. Four, of 72 inches in diameter by 8 feet stroke of piston, (direct action.) Water Wheels. 33 feet in diameter by 13 feet in width. Revolutions. 15 per minute. Dip of buckets, 7 feet; depth, 30 inches. Boilers. Four, containing 3418 square feet of fire and flue surface, 2272 cubic feet of steam room, and 704 cubic feet in furnaces, over the grate-bara. Length of engine-room, 75 feet. SCREW PROPELLER, (ERICSSON.) CONDENSING.-For 338 square feet of immersed section, with a displacement of 1046 tons. Length, 156.5 feet between perpendiculars; beam, 30.5 feet; hold, 21.5 feet; tonnage, 673.53. Cylinders. Two, each of 54 cubic feet in capacity. Pressure. 25 lbs. per square inch, cut off at t of the stroke. Propeller. 120 square feet of surface. Pitch. 35 feet. Diameter. 14 feet. Revolutions. 36 per minute. Shafts, (wrought-iron.) Diameter of journals, 12 X 16 inches. Boilers. 2500 square feet of fire and flue surface. Flues, 50 feet in length. Grates. 134 square feet. Steam Room. 1150 cubic feet. Fuel. 1 ton of anthracite coal per hour, (blast.) Weights. Engines 92 tons. Water in boilers 34 tons. Boilers 17 " Coal bunkers 6 " Hull. Launching weight, 418 tons. Sails. Area in square feet, 11,762. Surface of sails in propor- tion to immersed section, 3492 square feet to 1. RIVER ENGINES.-WITH SIDE WHEELS. NIAGARA." CONDENSING.-For 123 square feet of immersed section. Length of vessel, 265 feet; beam. 28 feet 6 inches; depth of hold, 9 feet 8 inches; draught, (loaded,) 4 feet 9 inches. Cylinder. 216 cubic feet in capacity. Condenser. 88 cubic feet. Air-pump. 33.5 cubic feet. Force-pumps. 51 inches diameter by 41 feet stroke. Pressure. 40 to 45 lbs. per square inch, cut off at half the stroke of the piston. Revolutions. 24 per minute. Water Wheels. 30 feet in diameter by 11 feet face. Arms. 24 in each flange. Buckets. Two, of 15 inches deep. Dip, (at load-line.) 30 inches. Shafts, (wrought-iron.) Journal, 14 inches. Boilers. Two, of 27 feet in length by 10 feet front. Shell. 8 feet 6 inches in diameter. Fire and Flue Surface. 3000 square feet. Grates. 108 square feet. Steam Room. 1200 cubic feet. Fuel. 3200 lbs. of anthracite coal per hour, (maximum.) Blowers. Two, of 9 feet in diameter. Fans. Ten, of 24 inches by 3 feet face. Blowing-engines. Two, of 10 inches diameter of cylinder by 12 inches stroke. Revolutions. 150 per minute. Weights. Engines 186,000 lbs. Boilers 65,000 64 Wood, in engines and wheels 29,000 " Water in boilers 76,000 " Total 356,000 lbs. "SOUTH AMERICA." CONDENSING.-For 132 square feet of immersed section. Length of vessel, 250 feet; beam, 27 feet; depth of hold, 9 feet; draught, (loaded,) 5 feet. Cylinder. 175 cubic feet in capacity. Air-pump. 38.5 cubic feet. Condenser. 72 cubic feet. Force-pumps. 5 inches diameter by 4 feet stroke. Pressure. 35 to 40 lbs. per square inch, cut off at half the stroke of the piston. Revolutions. 23.5 to 23 per minute. Water Wheels. 29 feet in diameter by 11 feet face. Arms. 24 in number. Buckets. Two divisions, and 30 inches deep. Dip, (at load-line.) 30 inches. Shafts, (wrought-iron.) Diameter of journal, 13 inches. Boilers. Two, 27 feet in length by 9.5 in width. Fire and Flue Surface. 8000 square feet. Shell. 8 feet in diameter. Grates. 100 square feet. Steam Room. 1000 cubic feet. Digitized by Google ENGINES, SUMMARY OF. 601 Consumption of fuel. 3000 lbs. of anthracite coal per hour, (maximum.) Blowers. Four, 4 feet diameter by 26 inches face. 4 arms. Fans. 13 inches deep. Revolutions. 75 per minute. Blowing-engines. Cylinder, 8 inches in diameter by 12 inches stroke. Weight of boilers. 62,000 lbs. The above engines and boilers were designed and constructed at the Phoenix Foundry, New York. CONDENSING.-For 160 square feet of immersed section. Length of vessel, 335 feet; beam, 35 feet; depth of hold, 11 feet 6 inches. Cylinder. 313 cubic feet in capacity. Air-pump. 54 cubic feet. Pressure. 38 lbs. per square inch. Revolutions 22 per minute. Water Wheels. 34 feet in diameter by 10 feet 8 inches face. Buckets. 30 inches deep. Boilers. Shell. 91 feet in diameter. Surface. 3660 square feet. Steam Room. 1570 cubic feet. Grates. 145 square feet. Blowing-engines. Two cylinders, of 14 inches diameter by 14 inches stroke. Two blowers. 10 feet in diameter by 2 feet in width. Ten fans in each, of 26 inches in depth. Revolutions. 100 per minute. Fuel. 3000 lbs. of anthracite coal per hour. NON-CONDENSING. For 300 square feet of immersed section. Vessel 260 feet in length, 38 feet beam, and 8 feet draught when loaded. Cylinders. Two, each 30 inches in diameter by 10 feet stroke of piston, (983 cubic feet.) Force pumps. 64 inches in diameter by 25 inches stroke. Water wheels. 33 feet in diameter by 15 feet in width, 19 arms in each. Buckets. 36 inches deep. Shafts, (cast-iron.) Diameter of journals, 16 and 14 inches. Connecting-rod. 35 feet in length. Piston-rod. Diameter, 6 inches. Steam valves. 50 square inches each. Exhaust valves. 63 square inches. Boilers. Five, of 42 inches in diameter by 34 feet in length, with two return flues in each, 16 inches in diameter, having 2278 square feet of heating surface. Grates. 84 square feet. Boiler plates. Shells. t of an inch in thickness. Flues. Full t of an inch. Pressure. 75 to 100 lbs. per square inch, cut off at 1 the stroke of the piston. Revolutions. 16 to 21 per minute. Dip of wheel. 5 feet when loaded. Consumption of fuel. 2.3 cords yellow pine per hour. Weights. Engines, 160 tons; boilers, 9000 lbs. NON-CONDENSING.-Pressure of steam, 100 lbs. per square inch, cut off at t stroke. Revolutions, 22 per minute. Cylinders. 421 cubic feet. Boilers. 1393 square feet of fire and flue surface. Water wheels. 221 feet in diameter by 10 feet 4 inches face, with 13 inches depth of bucket. Smoke pipe. 42 inches in diameter X 45 feet high. Area of flues. 1600 square inches. Fuel. 36 cords western wood in 12 hours. Furnace. 17 feet in width by 42 in length, and 17 inches in height. Grates. 68 square feet. NOTE-3275 square feet of fire and flue surface is the proportion for each cubic foot in the cylinders at the above given revolutions. STEAM VESSELS.-MARINE. " GREAT BRITAIN."-Displacement at 16 feet draught, 8000 tons. Length of keel, 289 feet; beam, 51 feet; depth of hold, 32 feet 6 inches. Plates. t. H, #, and i thick. Frames. 18 and 24 in. apart. 1 thick, by 35 X 6 inches; by 2.5 X 6 inches, and by 3 X 4 inches, L. Weight of Hull, (in iron.) 1040 tons. MICHIGAN."-Displacement at 8 feet 8 inches draught, 658 tons. Length between perpendiculars, 162 feet 6 inches; beam, 27 feet; depth of hold, 13 feet. Plates. 1. 1, i, 15, 4, and 1' thick. Frames. 2 feet apart. t and I thick, by 4 X 4.5 inches, 1; and t and i, by 4 X 2.25 inches, L. Deck beams. i, by 4.5 X 7 inches, L. Weight of Hull, including bulwarks and berth deck, 507,387 lbs. SPENOER."-Displacement at 9 feet 3 inches, 440 tons. Length between perpendiculars, 143 feet; beam, (average,) 20 feet 3 inches; depth of hold, 11 feet 6 inches. Plates. 1. is. and t of an inch. Frames. 20 inches apart. 1 thick, by 2.5 X 45 inches, L. Deck beams. t, by 2.87 X 5.5 inches, L. Weights. Platin 125,922 lbs. Knees 13,845 lbs. Bulk-heads 11,663 " Rivets 18,005 " Keelson 3,093 64 Stanchions 2,997 " Deck beams 34,463 " Sundries 20,918 " Frames 44,661 " Total 275,567 lbs. CANAL Волт, (very full built.) Length between perpendiculars, 80 feet; beam, 14 feet; depth of hold, 7 feet. 76 Digitized by Google 602 ENGINES, SUMMARY OF. Plates. Nos. 3 and 4, wire gage. Frames. 18 inches apart, and È thick by 3 inches wide, 1. Deck and beams of wood. Weight of Hull, 42,300 lbs. SUGAR MILL. For expressing 20,000 lbs. of cane juice per day.-Nox-Condensing ENGINE Cylinder. 15 inches in diameter by 4 feet stroke. Pressure. 50 lbs. per square inch, cut off at I the stroke of the piston. Revolutions. 36 per minute. Boiler. One of 62 inches in diameter by 30 feet in length, with two 18 inch return flues. Grates. 36 square feet. Rolls. Two sets of three each, of 24 inches in diameter by 5 feet in length; geered 21 to 36 of engine, giving a speed of periphery of 15} feet per minute. Fly-wheel. 18 feet in diameter; weight, 5 tons. This arrangement of a second set of rolls is a late improvement; its object, that of expressing the cane a second time. An increase of 30 per cent. is effected by it. For a crop of 3000 boxes of sugar of 500 lbs. each. A non-condensing engine, with a cylinder of 11 inches in diameter by 4 feet stroke, making 48 revo- lutions, with a pressure of steam 60 lbs. per square inch, driving one set of rolls, 24 inches by 4 feet, at a speed of periphery of 36 feet per minute. Boiler. 52 inches by 24 feet, with two 16 inch return flues. Grate surface. 25 square feet. Fly-wheel. 16 feet diameter; weight, 4 tons. SAW-MILL-NON-CONDENSING ENGINE. Two vertical saws of 34 inches stroke. Lathes, &c. Cylinder. 10 inches in diameter by 4 feet stroke. Pressure. 90 to 100 lbs. per square inch, full stroke. Revolutions. 35 per minute. Boilers. Three, plain cylindrical, 30 inches in diameter by 20 feet in length. NOTE-This engine has cut, of yellow pine, 30 feet by 18 inches in one minute. COTTON FACTORY. CONDENSING ENGINE-Driving 13,000 spindles, (mules and throstles,) with 256 looms for t cloth No. 30. Cylinders. Two, 22 inches in diameter by 8 feet stroke of piston. Pressure. 15 to 45 lbs. per square inch, cut off at $ of the stroke. Revolutions. 50 per minute. CONDENSING ENGINE, (British.) Driving 22,060 hand-mule spindles, with preparation, 260 looms, and common sizing. Engine.-Cylinder, 371 inches diameter by 7 feet stroke; indicated pressure (average) 16.73 lbs. per square inch; revolutions, 17 per minute. Friction of engine and shafting, indicated 4.75 lbs. per square inch of piston. Total power = 1. Available, deducting friction = 717. Estimated power of engine, 134 horses. Nores-Each indicated horse power will drive 305 hand-mule spindles, with preparation, or 230 self-acting or 104 throstle " " or 101 looms with common sizing. Including preparation: 1 throstle spindle = 3 hand-mule, or 21 self-acting spindles. 1 self-acting spindle = 1} hand-mule spindles. Exclusive of preparation, taking only the spindle: 1 throstle spindle = 31 hand-mule, or 25 self-acting spindles. 1 self-acting spindle = 11 hand-mule spindles. The throsties are the common, spinning 34 twist for power-loom weaving: the spindles revolve 4000 per minute. The self-acting mules are, one half spinning 36's weft, spindles revolving 4800; the other half spinning 36's twist, spindles revolving 5200. The hand-mules spinning about equal quantities of 36's weft and twist. Weft spindles 4700, and twist spindles 5000 revolutions per minute. Average breadth of looms 37 inches, (weaving 37 inch cloth,) making 123 picks per minute. All common calicoes about 60 reed, Stockport count, and 68 picks to the inch. No power consumed by the sizing. When the yarn is dressed instead of sized, one-horse power cast not drive 80 many looms, as the dressing machine will absorb from 1-6th to 1-7th of the power. COTTON PRESS. Non-Condensing ENGINE.-For 1000 bales in 12 hours Cylinder. 14 inches in diameter by 4 feet stroke. Pressure. 40 lbs. per square inch, at full stroke. Revolutions. 60 per minute. Boilers. Three, plain cylindrical without flues, 30 inches in diameter by 26 feet in length. Grates, 82 square feet. Presses. Four, geered 6 to 1, with two screws each of 71 inches in diameter by 18 inch pitch. Shaft, (wrought-iron.) Journal, 81 inches. Fly-wheel. 16 feet in diameter; weight, 4 tons. BLOWING OR BLAST ENGINE-Dimensions of a furnace, engines, &c. At Lonakoning, (Md) Furnace. Diameter at the boshes 14 feet, which fall in 633 inches in every foot rise. Digitized by Google ENGRAVING. 603 Engine, (Non-condensing) Diameter of cylinder 18 inches, length of stroke 8 feet. Revolutions. 12 per minute, with a pressure of 50 lbs. per square inch. Boilers. Five, each 24 feet in length, and 36 inches in diameter. Blast cylinders. 5 feet diameter and 8 feet stroke. At a pressure of from 2 to 21 lbs. per square inch, the quantity of blast is 3770 cubic feet per minute, requiring a power of about 50 horses to supply it. For blowing four furnaces, 14 feet in diameter, each making 100 tons of pig iron per week. At Mount Savage, (Md.) Engine, (Condensing.) Diameter of cylinder 56 inches, length of stroke 10 feet. Revolutions. 15 per minute. Pressure. 60 lbs. per square inch, cut off at t of the stroke. Boilers. Six of 60 inches in diameter, and 24 feet in length, with one 22 inch flue in each, double re- turned. Grates. 198 square feet. Blast cylinder. 126 inches in diameter by 10 feet stroke. Revolutions. 15 per minute. Pressure of blast. 4 to 5 lbs. per square inch. Area of pipes. 2300 square inches, or 1-5th that of the cylinder. For blowing two furnaces and two fineries, making 240 tons of forge pig per week. Engine, (Non-condensing.) Diameter of cylinder 20 inches, length of stroke 8 feet. Revolutions. 28 per minute. Pressure. 50 to 60 lbs. per square inch, (full stroke.) Boilers. Six of 36 inches in diameter and 28* feet in length, (without flues.) Grates. 100 square feet. Blast-cylinders. Two of 62 inches in diameter by 8 feet stroke. Revolutions. 22 per minute. Pres- sure of blast. 21 lbs. per square inch. Area of pipes. 3 feet, or 1-6th that of the cylinders. One blast furnace has two 3 inch and one 31 inch tuyeres, the other has three of 3 inches. One finery has six tuyeres of 11 inch, and the other, four of 11 inch. The ore yields from 40 to 45 per cent. of iron. The temperature of the blast is 600°. PILE-DRIVING. NON-CONDENSING ENGINE-Driving two piles. Cylinders. Two of 6 inches in diameter by 18 inches stroke. Pressure. 60 lbs. per square inch, full stroke. Revolutions. From 60 to 80 per minute. Boiler. Tubular. Shell. 31 feet in diameter by 6 feet in length. Furnace end, 3 feet 9 inches in width, 31 feet in length, and 6 feet in height. Rams. 1000 lbs. each, lifted five times in a minute. Frame. 81 feet in width by 26 feet in length. Leaders. 3 feet in width by 24 feet in height STEAM-DREDGING MACHINE. NON-CONDENSING ENGINE-For dredging 30 feet from water-line. Six full buckets per minute. Cylinder. 12 inches in diameter by 5 feet stroke of piston. Pressure. 60 to 70 lbs. per square inch, full stroke. Revolutions. 20 per minute, geered 30 of engine to 1 of buckets. Boilers. Two of 20 feet in length by 36 inches in diameter, with one 15 inch return flue in each. Ways. 55 ft. in length by 6 in width. Buckets. Ten of 28 inch. in width by 58 in length, and 14 in depth. At a depth of 18 ft., ten buckets full of mud are discharged per minute, the engine making 30 revolutions. NOTE-This engine is geered too slow, being but 21 to 1. Hulls. Two of 50 feet in length, 12 feet in width, and 9 in depth each; connected on deck, space be- tween for the ways, 7f feet. ENGRAVING.-Engraving on Copper is performed by cutting lines representing the subject ona copper-plate by means of a steel instrument ending in an unequal-sided pyramidal point, such instru- ment being called a graver or burin, without the use of aquafortis. Besides the graver there are other instruments used in the process; viz-a scraper, a burnisher, an oil-stone, and a cushion for supporting the plate. In cutting the lines on the copper the graver is pushed foward in the direction required, being held in the hand at a small inclination to the plane of the copper. The use of the burnisher is to soften down lines that are cut too deep, and for burnishing out scratches in the copper it is about three inches long. The scraper, like the last, is of steel, with three sharp edges to it, and about six inches long, tapering towards the end. Its use is to scrape off the burr, raised by the action of the graver. To show the appearance of the work during its progress, and to polish off the burr, engra- vers use a roll of woollen or felt called a rubber, which is put in action with a little olive-oil. The cushion, which is a leather bag about nine inches diameter filled with sand for laying the plate on, is now rarely used except by writing-engravers. For architectural subjects. or in skies, where a series of parallel lines are wanted. a ruling-machine is used the accuracy of its operation is exceedingly perfect. This is made to act on an etching ground by a point or knife connected with the apparatus, and bit in with aquafortis in the ordinary way. The plate of copper must be perfectly polished, very level, and free from every imperfection: to this must be transferred an exact copy of the outlines of the drawing. To do this the plate is heated in an oven or otherwise, very uniformly, till it is sufficiently hot to melt white wax, a piece of which is then rubbed over it and allowed to spread 80 as to form a thin coat over the whole surface, after which it is left in a horizontal position till the wax and plate are cold. A tracing being taken of the original design with a black-lead pencil on a piece of thin tracing-paper, this is spread over the face of the pre- pared plate with the lead lines downwards, and, being secured from slipping, a strong pressure is made use of by a press or otherwise, by which operation the lead lines are nearly obliterated on the paper, being transferred to the white wax on the plate. These pencil marks on the wax are now traced with 40 feet would have afforded much economy of fuel. Digitized by Google 604 ENGRAVING. a fine steel point, 80 as just to touch the copper the wax being then melted off, a perfect outline will be found on the copper; and on this the engraver proceeds to execute and finish his work. With respect to the process itself it would be useless to speak it depends on manual dexterity and genius, which it is impossible to teach by description. Engraving on Steel-The method of engraving is the same as copperplate-engraving, except in cer- tain modifications in the use of the acids, and therefore, 80 far as the process is concerned no particular description is necessary; but it will be proper to explain the means employed for decarbonizing the steel plate 80 as to reduce it to a proper state for being acted upon by the graving tool. Mr. Perkins, an eminent artist and engineer, (a native of Massachusetta,) has the merit of having established engra- ving on steel. About the year 1823 he was induced to visit London, where he obtained a patent for the invention; this was intended principally to prevent the forgery of bank notes, which at that time, or rather previously to that time, had been carried on to a very fearful extent The method employed for decarbonizing and recarbonizing the plate may be applicable to many other useful purposes, and we shall therefore give it in the words of the patentee. In order to decarbonate the surfaces of cast- steel plates, cylinders, or dies, by which they are rendered much softer and fitter for receiving either transferred or engraved designs, I use pure iron filings divested of all foreign or extraneous matters. The stratum of decarbonated steel should not be too thick for transferring fine and delicate engravings; for instance, not more than three times the depth of the engraving; but for other purposes the surface of the steel may be decarbonated to any required thickness. To decarbonate it to a proper thickness for a fine engraving, it is to be exposed for four hours in a white heat, enclosed in a cast-iron box with a well-closed lid. The sides of the box are made at least three-quarters of an inch in thickness, and at least a thickness of half an inch of pure iron filings should cover or surround the cast-steel surface to be decarbonated. The box is allowed to cool very slowly, which may be effected by shutting off all access of air to the furnace, and covering it with a layer of six or seven inches in thickness of fine cinders. Each side of the steel plate, cylinder, or die, must be equally decarbonated, to prevent it from springing or warping in hardening. It is also found that the safest way to heat the plates, cylin- ders, or dies, is by placing them in a vertical position. The best steel is preferred to any other sort of steel for the purpose of making plates, &c., and more especially when such plates, &c., are intended to be decarbonated. The steel is decarbonated solely for the purpose of rendering it sufficiently soft for receiving any impression intended to be made thereon; it is therefore necessary that after any piece of steel has been 80 decarbonated, whether it be in the shape of a plate, or a cylinder, or a die, it should, previously to being printed from, be again carbonated or reconverted into steel capable of being hardened. In order, therefore, to effect this decarbonization or reconversion into steel, the fol- lowing process is employed a suitable quantity of leather is to be converted into charcoal by the well- known method of exposing it to a red heat in an iron retort for a sufficient length of time, or until most of the evaporable matter is driven off the leather. Having thus prepared the charcoal, it is reduced to a very fine powder; then take a box made of cast-iron, of sufficient dimensions to receive the plate, cylinder, or die, which is to be reconverted into steel, so as that the intermediate space between the sides of the said box and the plate or die may be about an inch. This box is to be filled with the powdered charcoal, and. having covered it with a well-fitted lid, let it be placed in a furnace similar to those used for melting brass, when the heat must be gradually increased until the box is somewhat above a red heat; it must be allowed to remain in that state till all the evaporable matter is driven off from the charcoal; then remove the lid from the box, and immerse the plate, cylinder, or die, into the powdered charcoal, taking care to place it as nearly in the middle as possible, so that it may be surrounded on all sides by a stratum of the powder of nearly a uniform thickness. The lid being re- placed, the box, with the plate, cylinder, or die, must remain in the degree of heat before described for from three to four hours, according to the thickness of the body 80 exposed; three hours are sufficient for a plate of half an inch in thickness, and five hours when the steel is one inch and a half in thick- ness. After the plate or other piece of steel has been thus exposed to the fire for a sufficient length of time, take it from the box and immediately plunge it into cold water. Here it is important to observe, that it is found by experience that the plates or other pieces of steel when plunged into cold water, are least liable to be warped or bent when they are held in a vertical position, or made to enter the water in the direction of their length. If a piece of steel, heated to a proper degree for hardening, be plunged into water, and suffered to remain there until it becomes cold, it is found by experience to be very liable to crack or break, and in many cases it would be found too hard for the operations it was intended to perform. If the steel cracks or breaks, it is spoiled. In order, therefore, to fit it for use, should it happen not to be broken in hardening. it is the common practice to heat the steel again, in order to reduce or lower its temper, as it is technically called. The degree of heat to which it is now exposed determines the future degree of hardness, or the temper, and this is indicated by a change of color upon the surface of the steel. During this heating a succession of shades is produced, from a very pale straw-color to a very deep blue. It is found, however, by long experience, that on plunging the steel into cold water, and allowing it to remain there no longer than is sufficient for lowering the temperature of the steel to the same degree as that to which a hard piece of steel must have been raised to temper it in the common way, it not only produces the same degree of hardness in the steel, but, what is of much more importance, almost entirely does away the risk or liability of its cracking or breaking. It is impossi- ble to communicate by words, or to describe the criterion by which we can determine when the steel has arrived at the proper degree of temperature after being plunged into cold water it can only be learned by actual observation, as the workman must be guided entirely by the kind of hissing or singing noise which the heated steel produces in the water while cooling. From the moment of its first being plunged into the water the varying sound will be observed; and it is at a certain tone, before the noise ceases, that the effect to be produced is known. The only directions which can be given whereby the experimentalist can be benefited, are as fol- Digitized by Google ENGRAVING. 605 lows namely-to take a piece of steel which has already been hardened by remaining in the water till cold, and by the common method of again heating it to let it be brought to the pale yellow or straw color, which indicates the desired temper of the steel plate to be hardened. By the above process, as soon as he discovers this color to be produced, to dip the steel into water and attend carefully to the hissing, or as some call it a singing, which it occasions, he will then be better able, and with fewer ex- periments, to judge of the precise time at which the steel should be taken out. It is not meant to be understood that the temper indicated by a straw-color is that to which the steel plate, cylinder, or die, should be ultimately reduced, because it would then be found too hard, but merely that the tempera- ture which would produce that color is that by which the peculiar sound would be occasioned, when the steel should be withdrawn from the water for the first time. Immediately on withdrawing it from the water, the steel plate, cylinder, or die, must be laid upon, or held over a fire, and beated uniformly until its temperature is raised to that degree at which tallow would be decomposed or, in other words, until a smoke is perceived to arise from the surface of the steel plate, after having been rubbed with tallow now the steel plate must then be again plunged into water, and kept there until the sound becomes somewhat weaker than before. It is then to be taken out and heated a second time, to the same degree, by the same rule of smoking tallow as before, and the third time plunged into water, till the sound becomes again weaker than the last; exposed the third time to the fire as before; and for the last time returned into the water and cooled. After it is cooled, clean the surface of the steel plate, cylinder, or die, by heating it over the fire. The temper must be finally reduced by bringing on a brown or such other lighter or darker shade of color as may best suit the quality of the steel for the purpose to which it is to be applied." The following is another improvement of Mr. Jacob Perkins' :-A cylinder of very soft or decarbon- ized steel is made to roll, under a great pressure, backward and forward on the hardened engraved plate, till the entire impression from the engraving is seen on the cylinder in alto-relievo. The cylinder is then hardened and made to roll again backward and forward on a copper or soft steel plate, whereby a perfect facsimile of the original is produced of equal sharpness. The improved press, now generally used by steel and copper-plate printers, is also due to Mr. Perkins. In short, he bears the same relation to steel engraving that Senefelder does to the lithographic process. Engraving on Stone, or Lithography-A modern invention, by means whereof impressions may be taken from drawings made on stone. The merit of this discovery belongs to ALOYS SENEFELDER, a musical performer of the theatre at Munich about the year 1800. The following are the principles on which the art of lithography depends:-First, the facility with which calcareous stones imbibe water second, the great disposition they have to adhere to resinous and oily substances; third, the affinity between each other of oily and resinous substances, and the power they possess of repelling water or a body moistened with water. Hence, when drawings are made on a polished surface of calcareous stone with a resinous or oily medium, they are so adhesive that nothing short of mechanical means can effect their separation from it, and whilst the other parts of the stone take up the water poured upon them, the resinous or oily parts repel it. Lastly, when over a stone prepared in this manner a colored oily or resinous substance is passed, it will adhere to the drawings made as above, and not to the watery parts of the stone. The ink and chalk used in lithography are of a saponaceous quality the former is prepared in Germany from a compound of tallow soap, pure white wax, a small quantity of tallow, and a portion of lampblack, all boiled together, and when cool dissolved in distilled water. The chalk for the crayons used in drawing on the stone is a composition consisting of the ingredients above mentioned, but to it is added when boiling a small quantity of potash. After the drawing on the stone has been executed and is perfectly dry, a very weak solution of vitriolic acid is poured upon the stone, which not only takes up the alkali from the chalk or ink, as the case may be, leaving an inso- luble substance behind it, but it lowers in a very small degree that part of the surface of the stone not drawn upon, and prepares it for absorbing water with greater freedom. Weak gum water is then ap- plied to the stone, to close its pores and keep it moist. The stone is now washed with water, and the daubing ink applied with balls as in printing; after which it is passed in the usual way through the press, the process of watering and daubing being applied for every impression. There is a mode of transferring drawings made with the chemical ink on paper prepared with a solution of size or gum tragacanth, which being laid on the stone and passed through the press leaves the drawing on the stone, and the process above described for preparing the stone and taking the im- pressions is carried into effect. In Germany many engravings are made on stone with the burin, in the same way as on copper; but the very great inferiority of these to copper engravings makes it improbable that this method will ever come into general use. Copper or steel plates may be transferred to stone and worked by power-presses; and from the les- sened expense, it is now generally resorted to by publishers of maps where large quantities are re- quired. Perhaps one of the greatest advantages of the art of lithography is the extraordinary number of copies that may be taken from a block. As many as 70,000 copies or prints have been taken from one block, and the last of them nearly as good ns the first. Expedition is also gained, inasmuch as a fifth more copies can be taken in the same time than from a copper-plate: and as regards economy, the ad- vantage over every other species of engraving is very great. Engracing on Silver and Gold-M. Poitevin, a Frenchman, has succeeded in producing plates, engraved either in relief or in sunk lines, from which proofs may be taken. For the carrying out of this pro- cess from two to three hours only are required. The engraving is first exposed to the vapor of iodine, which becomes deposited upon the black parts only. The iodized engraving is then applied, with slight pressure, to a plate of silver, or silvered copper, polished in the same manner as daguerreotype plates. The black parts of the engraving, Digitized by Google 606 ENGRAVING ON WOOD. which have taken up the iodine, part with it to the silver, which is converted into an iodide at those parts opposite to the black parts of the design. The plate is then put in communication with the negative pole of a small battery, and immersed in a saturated solution of sulphate of copper, con- nected with the positive pole by means of a rod of platinum. The copper will only be deposited on the non-iodized parts, corresponding to the white parts of the engraving, of which a perfect representa- tion will thus be obtained;-the copper representing the white parts, and the iodized silver the black parts. The plate must be allowed to remain in the bath for a very short time only; for, if left too long, the whole plate would become covered with copper. The plate, after having received the deposit of copper, must be carefully washed, and afterwards immersed in a solution of hyposulphite of soda, to dissolve the iodide of silver, which represents the black parts; it is then well washed in distilled water, and dried. The next operation is to heat a plate to a temperature sufficient to oxidize the surface 01 the copper, which successively assumes different tints, the heating being stopped when a dark brown color is obtained. It is then allowed to cool, and the exposed silver is amalgamated,- the plate being slightly heated, to facilitate the operation. As the mercury will not combine with the oxide of copper, a design is produced, of which the amalgamated parts represent the black, and the parts of the plate covered with oxide of copper represent the white parts. The amalgamation being complete, the plate is to be covered with three or our:thicknesses of gold leaf; and the mercury is evaporated by heat, the gold only adhering to the black parta. The superfluous gold must then be cleaned off with the scratch-brush; after which the oxide of copper is dissolved by a solution of nitrate of silver, and the silver and copper underneath are attacked with dilute nitric acid. Those parts of the design which are protected by the gold, not being attacked, correspond to the black parts of the plate; the other parts corresponding to the white parts of the engraving, may be sunk to any required depth. When this operation is completed the plate is finished, and may be printed from in the ordi- nary method of printing from wood-cuta. To obtain from the saine prints plates with sunk lines similar to the ordinary engraved copper-plates, a plate of copper covered with gold is operated upon. On immersion in the sulphate of copper solu- tion the parts corresponding to the white parts will become covered with copper. The iodine. or com- pound of iodine, formed, is then to be removed by the hyposulphite, the layer of deposited copper is oxidized, and the gold amalgamated, which may be removed by means of nitric acid,-the oxide of copper being dissolved at the same time. In this instance the original surface of the plate corresponds to the white parts of the print, and the sunk or engraved parts to the black parts, as in the ordinary copper-plate engravings. ENGRAVING ON WOOD. There are various modes for protecting the eyes when working by lamp-light, but we are aware of only one which both protects the eyes from the light and the face from the heat of the lamp. This consists in filling a large transparent glass globe with clear wa- ter, and placing it in such a manner 1571. between the lamp and the workmen that the light, after passing through the globe, may fall directly on the block. in the manner represented in B the Fig. 1571. The height of the lamp can be regulated according to the engraver's convenience, in conse- quence of its being movable on the upright piece of iron or other metal which forms its support. The dotted line shows the direction of the light when the lamp is elevated to the height here seen; by lowering the lamp a lit- tle more, the dotted line would incline more to a horizontal direction, and ena- ble the engraver to sit at a greater dis- tance. By the use of these globes one lamp will suffice for three or four per- sons, and each person have a clearer and cooler light than if he had a lamp without a globe solely to himself. There are only four kinds of cutting tools* necessary in wood engraving, namely gravers, tint-tools, gouges or scoopers, and flat tools or chisels. Of each of these four kinds there are various sizes. Fig. 1572 shows the form of a graver that is principally used for outlining or separating one figure from another. A is the back of the tool; B the face; C the point; and D what is technically called the belly. The horizontal dotted line C, 2, shows the 1572. surface of the block. and the manner in which part of A B 2 the handle is cut off after the blade is inserted.t This c tool is very fine at the point, as the line which it cuts D A sharp-edged scraper, in shape something like 8 copper-plate engraver's burnisher, is used in the process of lowering + The handle, when received from the turner's, is perfectly circular at the rounded end; but after the blade is inscrted, a segment is cut off at the lower part, as seen in Fig. 1572. Digitized by Google ENGRAVING ON WOOD. 607 ought to be 80 fine as not to be distinctly perceptible when the cut is printed, as the intention is merely to form a termination or boundary to a series of lines running in another direction. Though it is necessary that the point should be very fine, yet the blade ought not to be too thin, for then, instead of cutting out a piece of the wood, the tool will merely make a delicate opening, which would be likely to close as soon as the block should be exposed to the action of the press. When the outline tool becomes too thin at the point the lower part should be rubbed on a hone, in order to reduce the extreme fineness. About eight or nine gravers of different sizes, beginning from the outline tool, are generally sufficient. The blades differ little in shape, when first made, from those used by copper-plate engravers; but in order to render them fit for the purpose of wood engraving, it is necessary to give the points their pecu- liar form by rubbing them on a Turkey stone. In 1573. Fig. 1573 are shown the faces and part of the A backs of nine gravers of different sizes; the lower dotted line AC shows the extent to which the points of such tools are sometimes ground down by the engraver in order to render them broader. When thus ground down the points are slightly rounded, and do not remain straight as if cut off by the dotted line A C. These tools are used for nearly all kinds of work, except for series of parallel lines, technically called "tints." The width of the line cut out, according to the thickness of the graver towards the point, is regulated by the pressure of the engraver's hand. Tint tools are chiefly used to cut parallel lines forming an even and uniform tint, such as is usually seen in the representation of a clear sky in wood-cuts. They are thinner at the back, but deeper at the side than gravers, and the angle of the face, at the point, is much more acute. About seven or eight, of different degrees of fineness, are generally sufficient. Fig. 1574 will afford an idea of the shape of the blades towards the point. The 1574. handle of the tint tool is of the same form as that of a graver. The figure marked A presents a side view of the blade; the others marked B show the faces. Some engravers never use a tint tool, but cut all their lines with a graver. There is, however, great uncertainty in cutting a series of parallel lines in this manner, as the least inclination of the hand to B A one side will cause the graver to increase the width of the white line cut out, and undercut the raised one left, more than if in the same circumstances a tint tool were used. This will be rendered more evident by a comparison of the points and faces of the two different tools, Fig. 1575. The tint tool, being very little thicker at B than at the point A, will cause a very trifling difference in the width of a line in the event of a A 1575. wrong inclination, when compared with the inequality occasioned by B the unsteady direction of a graver, whose angle at the point is much greater than that of a proper tint tool. Tint tools ought to be suffi- ciently strong at the back to prevent their bending in the middle of the blade when used, for with a weak tool of this kind the engraver can- not properly guide the point, and hence freedom of execution is lost. Tint tools that are rather thick in the back are to be preferred to such as are thin, not only from their allowing of great steadiness in cutting, but from their leaving the raised lines thicker at the bottom, and consequently more capable of sustaining the action of the press. A tint tool that is of the same thickness both at the back and the lower part, cuts out the lines in such a manner that a 1576. section of them appears as in Fig. 1576: the black raised lines from which the impression is obtained being no thicker at their base than at the surface; while a section of the lines cut by a tool that is thicker at the back than at the lower part appears as in Fig. 1577. 1577. It is evident that lines of this kind having a better support at the base, are much less liable than the former to be broken in printing. Gouges of different sizes, Fig. 1578, from A the smallest to B the largest, as here represented, are used for scooping out the wood towards the centre of A the block; while flat tools or chisels, of various sizes, are chiefly employed in cutting away the wood towards the edges. Flat tools of the shape seen in figure C are sometimes offered for sale by tool-makers, but they ought never to be used for the projecting corners are very apt to cut under a line, and thus re- 1578. move it entirely, causing great trouble to replace it by inserting new pieces of wood. A The face of both gravers and tint tools ought to be kept rather long than B short; though if the point be ground too fine, it will be very liable to break. When, 1'579. as in Fig. 1579, the face is long-or,strictly speaking, when the angle, formed by the plane of the face and the lower line of C the blade, is comparatively acute-a line is cut with much greater clearness than when the face is comparatively obtuse, and the small shaving cut out turns gently over towards the hand. When, however, the face of the tool approaches to the shape seen in Fig. 1580, the reverse happens; the small shaving is rather Digitized by Google 608 ENGRAVING ON WOOD. ploughed out than cleanly cut out; and the force necessary to push the 1580. tool forward frequently causes small pieces to fly out at each side of the hollowed line, more especially if the wood be dry. The shaving also, in- stead of turning aside over the face of the tool, turns over before the point, as in Fig. 1580, and hinders the engraver from seeing that part of the pencilled line which is directly under it. A short-faced tool of itself prevents the engraver from distinctly seeing the point. When the face of a tool has become obtuse, it ought to be ground to a proper form; for instance, from the shape of the figure A to that of B, Fig. 1581. 1581. A. B Gravers and tint tools when first received from the maker are generally too hard,-a defect which IS soon discovered by the point breaking off short as soon as it enters the wood. To remedy this, the blade of the tool ought to be placed with its flat side above a piece of iron-a poker will do very well- nearly red-hot. Directly it changes to a straw-color it is to be taken off the iron, and either dipped in sweet oil or allowed to cool gradually. If removed from the iron while it is still of a straw-color, it will have been softened no more than sufficient; but should it have acquired a purple tinge, it will have been softened too much and instead of breaking at the point, as before, it will bend. A small grind- stone is of great service in grinding down the faces of tools that have become obtuse. A Turkey stone, though the operation requires more time, is however a very good substitute, as, besides reducing the face, the tool receives a point at the same time. Though some engravers use only a Turkey stone for sharpening their tools, yet a hone in addition is of great advantage. A graver that has received a final polish on a hone cuts a clearer line than one which has only been sharpened on a Turkey stone: it also cuts more pleasantly, gliding smoothly through the wood, if it be of good quality, without stirring a particle on each side of the line. The gravers and tint tools used for engraving on a plane surface are straight at the point, as are here represented, Figs. 1582 and 1583; but for engraving on a block rendered concave in certain points by lowering, it is necessary that the point should have a slight inclination upwards, as in Fig. 1582. The 1583. 1582. dotted lines show the direction of the point used for plane-surface engraving. There is no difficulty in getting a tool to descend on one side of a part hollowed out or lowered; but unless the point be slightly inclined upwards, as is here shown, it is extremely difficult to make it ascend on the side opposite, with- out getting too much hold, and thus producing a wider white line than was intended. As the proper manner of holding the graver is one of the first things that a young wood-engraver is taught, it is necessary to say a few words on the subject. Engravers on copper and steel, who have much harder substances than wood to cut, hold the graver with the fore-finger extended on the blade beyond the 1584. thumb, Fig. 1584, 80 that by its pressure the point may be pressed into the plate. As box-wood, however, is much softer than copper or steel, and as it is seldom of per- fectly equal hardness throughout, it is necessary to hold the graver in a different manner, and employ the thumb at once as a stay or rest for the blade, and as a check upon the force exerted by the palm of the hand, the motion being chiefly directed by the fore-finger, as is shown in Fig. 1585. 1585. The thumb, with the end resting against the side of the block, in the manner above represented, allows the blade to move back and forward with a slight degree of pressure against it, and in case of a slip it is ever ready to check the graver's progress. This mode of resting the thumb against the edge Digitized by Google ENVELOP MACHINERY. 609 1586. of the block is, however, only applicable when the cuts are so small as to allow of the graver, when thus guided and controlled, to reach every part of the subject. When the cut is too large to admit of this, the thumb then rests upon the surface of the block, as seen in Fig. 1586; still forming a stay to the blade of the graver, and a check to its slip, as before. ENVELOP MACHINERY, by M. Rémond. In earliest stages of the invention, the paper blanks were cut out, and the subsequent folding performed entirely by hand; but the necessity of a prodigious increase in the power of production, speedily led to the employment of mechanical means for the entire manufacture. One of the first of these improvements was an improved paper-cutting machine, a plan for cutting out the blanks. Many envelop-makers use this machine now; but others employ a hollow cutting die, cutting through about 250 sheets of paper at once; but the cutter being made very thin. to give an easy cut, generally springs under pressure, and the blanks thus become unequal in size, easily detected when the folding operation comes into action. As an example of the class of cutting-die employed, we have en 1587. graved two views of it. Fig. 1587 is a sectional elevation of the die. and Fig. 1588 a plan. It is simply a knife, shaped to the contour of the envelop blank, A being the sharp edge. This is forced through a thick pile of sheets by 14 convenient press, 80 as to produce blanks agreeing in shape to the interior of the two lines in Fig. 1588. This shape, it will be observed, is not one now in common use, but it serves as an example of some of the attempts which have been made 1588. to give additional security, and probably a greater appearance of style. The cut pieces are gummed on one side, at the ends of each flap; and when folded, as indicated by the dotted lines in the plan of the cutter, the long narrow part adheres to one end of its counter- part, forming the back, and the remaining pair of flaps fold down upon it. This shape of envelop has, for many reasons, never come into ordinary use. In 1845 a folding machine for completing the envelops from the blanks was invented by Mr. Edwin Hill, and Mr. Warren De la Rue, jointly. and is now worked in the extensive establishment of Messrs. De la Rue, London. Its rate of production is stated to be 42 folded envelops per minute; or, for a day's work of 10 hours, 25,200. The blanks are laid by hand upon a table carrying a metal frame, the interior of which exactly corre- sponds to the size and shape of the finished envelop; and immediately over this is a box or plunger, which, fitting to the interior of the frame, is caused to descend upon the paper blank when laid over it, thus creasing it on all the four sides, as will be understood on examining a partially-opened envelop; the box then opens to admit of a partial folding. In this condition the blank has simply been creased, and the four flaps stand up at right angles to the plane of the sheet. Before the creasing box is entirely raised, two of a set of folders, placed one on each of the four sides of the frame, come forward and press down the two flaps corresponding to their situation; and the remaining pair of folders come into action to press their two flaps after the other portion of the plunger is raised. These movements complete the envelop, by turning down the right angle flaps to the plane of the sheet, and the next step is to remove them from the folding frame. For this purpose two finger-shaped projections of caoutchouc are made use of; and, owing to the strong adhesion existing between this substance and paper, the folded envelops are quickly removed as fast as they are produced. The twenty-two movements required in folding each envelop are performed rapidly and noiselessly, principally by various adaptations of cams. Prior to Messrs. Hill and De la Rue's invention, the only facilitation of manual labor in folding was obtained by the use of a species of tool, which partially creased the blanks, leaving them to be turned up and finished by band. Compared with "the results of machinery," the hand labor, although in itself an astonishing instance of practical dexterity, is inordinately slow. Girls are always employed in this work; and a first-rate hand can fold and gum for use from 3,000 to 3,500 per day, or from 5 to 6 per minute, the average performance being from 2,500 to 3,000. To arrive at this perfection, at least six or eight months' practice are required. By another comparative statement now before us, we find that, in unstamped envelops, hand labor, 6 per minute, 10 hours per day = 3,600; the work of one girl. Stamped envelops, hand labor, 4 1-6 - per minute, 10 hours per day = 2,500, a day's work; the time being divided into 7 hours for folding and gumming, and 3 for stamping. 77 Digitized by Google 610 ENVELOP MACHINERY. Fige. 1589 to 1597 exhibit, in very full detail, an improved folding machine, patented during the present year, by M. Rémond. In this machine some ingenious appliances are introduced, whereby atmospheric pressure is employed to facilitate the feeding in of the blanks to the folding apparatus and the secondary folding action of the flaps in connection with the creasing plunger. Fig. 1589 is a side elevation of the machine, partially in section. Fig. 1590 is a corresponding view at right angles to Fig. 1589. Fig. 1591 is a vertical section of a portion of the machinery, taken at the dotted line A B in Fig. 1589. Fig. 1592 is a horizontal view or plan of the folding table, with the details of the apparatus for receiving the blanks preparatory to folding. Fig. 1593 is a transverse section, taken at the dotted line CD in Fig. 1589. Fig. 1594 is a plan of the feeding-slide NN in Figs. 1589 and 1590. Figs. 1595, 1596, and 1597 are details of the guide apparatus for the several move- ments on the main shaft A of the machine. 1595. I 1596. o N W 1589. y A H 1597. The arrangement of the mechanism is such, that a quantity of blanks of the required size being placed on the feeding table, each will be taken up singly from the pile, and fed into the folding apparatus by means of an instrument, in which, at proper intervals, a partial vacuum is formed, whereby each sheet is sucked up against the surface of the fingers for conveyance to the folder. The first step of the process of folding is accomplished similarly to the mode hitherto adopted, and generally explained, in reference to Messrs. De la Rue's machine, that is, the flaps of the blanks are bent to a right angle by the same means; but a novel arrangement is introduced for the performance of the secondary fold. The bottom of the creasing frame or box is perforated, so that the passing back of the plunger leaves the blank within the recess, with its four flaps standing upright: and here the second application of the atmospheric action comes into play, for the purpose of giving the flaps a pre- Digitized by Google ENVELOP MACHINERY. 611 liminary inclination inwards, in order to fit them for receiving the flat folding pressure of the return stroke of the plunger. To this end the sides of the folding box are perforated, SO as to allow streams of atmospheric air to be forced against the outsides of the flaps; so that, on the descent of the plunger. they will all be folded down at once, the interior and under surface of the plunger being suitably formed to cause the flaps to succeed each other in their proper order. In addition to this, certain contrivances are adapted for stamping the outer flaps with an embossed or perforated device, and also for gumming the lowest flap as a fastening for the completed envelop. A is the main driving shaft, which gives motion to the machine. It carries at one end a fast-and-loose driving pulley, and at the other a fly-wheel, to assist in regulating the movement; and its intermediate portion is fitted with seven cams, for communicating motion to the different working parts. B is the folding box, or recess, in which the folding process is performed. It consists of four side pieces, at the angles of which are projections C C, between which the blanks are successively fed, so that they may be correctly placed, and held during the action of the plunger. D is the door or movable bottom of the box, hinged at one end, so that when an envelop has been folded in the box, it may be discharged below; it is perforated with numerous holes for the escape of the air, as the blank is forced down, and is kept closed by means of a lever E, which is actuated at the proper intervals of time by means of the cam F on the main shaft, giving motion to a slide G, of which there are seven, all alike in construction, in connection with the same number of cams. The slide works between two fixed guiding surfaces H H. as detailed in Figs. 1595 and 1596, and has at its upper end a small anti-friction roller, kept up in con- tact with its actuating cam by the elastic tension of a band of vulcanized India-rubber. The lower end of the slide presses on the tail of the 1590. cranked lever E, the other end of which rests against the under surface of the movable door D, so that the latter is kept closed during the proper portion of the revolution of the main shaft. The feeding action is accomplished by the exterior cam K on the shaft, giving motion-as before explained with regard to the cam F-to its slide L, which is attached to the shorter L " arm of the cranked lever M, the opposite arm of which is jointed by connecting rods to the feeder N. This instrument is car- ried upon a slide, having dovetailed edges, moving between fixed guiding dovetails at O O. It consists of two hollow fingers PP, each having an opening on the under side; the interior of the fingers opening into the hollow portion of the slide, shown by dotted lines, allowing of a partial g vacuum being obtained within the fingers when the exhaust movement comes into use. A flexible tube Q, of vulcanized India-rubber, is attached to the under side of the slide, the opposite end being con- nected with the bellows R, which receive motion at the required intervals from the a cam S acting on the slide T in connection with the bent lever U, carried by a pillar at the back of the machine. The longer end of this lever is jointed by a connect- ing rod V to the front plate W of the horizontal bellows running on guide spin- dles X X. In this way, when the under side of the fingers comes upon the top of the pile of blanks at Y, the exhausting action is brought into play, and the top sheet is carried over to the top of the box B for deposit, with its angles fitting the corner guide pieces, as in plan at Fig. 1592. At the termination of the outward stroke of the bellows, the sheet is separated from them by the action of a valve in the bellows, opening outward at the commencement of the return stroke. The platform Y carrying the pile of blanks, is made to rise and fall to suit the feeding action, by a mechanical arrangement worked from the cam Z. This cam actuates a slide a, from which an arm b descends for connection with the long lever c at the bottom of the framing, the opposite end of which is jointed to a projection on the vertical spindle d of the platform. To compensate for the continual decrease in the height of the pile of blanks, so that the upper one may always come in contact with the lifting fingers when the platform rises, an India-rubber spring e is added, its action being to keep up the platform in contact with the fingers, when permitted to do 80 by the actuating cam. AN every thing depends upon accuracy of set. it becomes of the first importance to place the blanks in the exact position intended; and to facilitate this, four projecting arms, or guides ff, are formed on the top of the platform, agreeing, as in the angle pieces of the folding box, with the angles of the flat blanks. As the blanks are fed into proper position, the folding plunger g comes into action. This is a hollow rectangular metal frame, carried by a slide h. receiving motion from the cam k. It has in its interior a set of three projections, which, in the secondary movement, act on the separate flaps, folding them all Digitized by Google 612 ENVELOP MACHINERY. down at once, when they are held in the required inclined position by the atmospheric side currents, as previously detailed. The inclined projections are essentially necessary, in order that the flaps may be folded down in their proper relative positions; the projection 1 pressing on one of the side flaps, causes it to be folded first; afterwards the projection m acts upon one of the ends, whilst the third, n, carries down the opposite one, the final folding being completed by the under edges of the plunger, which gives a sharp pressure to the initiatory fold of the whole series. By suitably setting these projections, any 1598. order may be given to the flaps-thus, if the two end ones do not overlap each other, they may be folded down to- gether by equal projections. The detailed figures, 1598 and 1599, exhibit two intermediate stages of the plunger's folding action. Fig. 1598 is a longitudinal elevation of the plunger and the top of the folding box in the position taken up after the first action of the former, the side air passages for inclining the flaps being at 000. Fig. 1599 is a longi- tudinal section of the same parts, taken just as the plunger is about to descend in its secondary movement to give the completing fold. The necessary atmospheric side pressure on the flaps is obtained from the inclined air-pump p, the piston of which 1599. is driven by a crank pin on the fly-wheel; and a tube q conveys the forced air from the bottom of the pump to a hollow channel passing all round the edges of the folding box, as dotted in the plan, Fig. 1592, whence the orifices already pointed out, open inwards to the box. For the application of gum, or other cementing fluid, to the lowest flap, to secure the three stationary ones, a fountain is placed at r, from the bottom of which two tubes 8 8 branch out to the two flat tubular receptacles tt inclosed in a vessel u, the supply being regulated by a stop-cock before the junc- tion of the two supply branches. The gumming action is performed by pieces of sponge placed in the upper ends of the flat tubes t, which, standing slightly above their upper edges, the presser v descending just before the plunger, presses the edges of the lowest flap upon the sponge, as clearly illustrated in the plan view. This presser receives its motion from the cam 10 acting on the slide x, to which the presser is attached. If it is intended to stamp or emboss the outer flap with an embossed of perforated device, dies are applied as at yz. The die y being attached to a slide 1, acted on by the external cam 2, the stamping action takes place just before the descent of the plunger. 1502. 1591. и m / 72 B D This machine produces easily 60 envelops per minute, or 36,000 per day, completed, gummed, and stamped, and might probably be worked faster. As at present practised in other modes of production, the folding. gumming, and stamping are all separate processes; and as, at each of these operations, every single envelop must be separately handled, we may form a tolerable conception of the economy gained by the use of M. Rémond's machine, as the most improved contrivance of earlier date saves no more than one-third of the manual labor. The isolation of the different stages of manufacture, conse- quent upon the employment of manual labor, adds immensely to the cost of production, the loss mainly arising from the mere removals from one process to another. In hand-stamping, a child will perhaps get through 8,000 or 9,000 per day and then there must be an assistant to turn the tops where the stamp has been placed, and count them into parcels. Since the first anticipations of the value of the envelop for general consumption, many modifications have been introduced. In 1844, Mr. Wilson, the inventor of the cutting machine, hit upon the ingeniously simple mode of economizing the paper in cutting out the blanks, by cutting the original web of paper diagonally across its width. Formerly, when the web was divided longitudinally, and then by trans- verse cuts at right angles, the rectangular sheet thus formed, when cut up into diamond pieces for Digitized by Google ETCHING. 613 envelops, suffered considerable loss in the reduction. By Mr. Wilson's plan this was avoided, as the transverse cuts being all made diagonally, each blank fitted exactly to its neighbor, and this source of loss was removed. In 1846, again, Mr. Charles Chinnock obtained a patent for some contrivances for the obtainment of greater security of enclosure, by applying the ordinary postage stamp, or other adhesive labels, so as to become a fastener for the edges of the paper forming the envelop. In one of his arrangements, a small hole, somewhat less than the area of a postage stamp, is punched at the right- hand corner of the address side, so that, when the stamp is put on, it adheres not only to the edges of the hole, but also to the turned-in edge produced in the end fold of the envelop, as well as partially to the enclosed note. Thus the enclosure cannot be removed without leaving detective marks. According to another mode, the patentee punches holes of various sizes through the parts of the envelop where the seal is placed-in some cases placing a bit of blotting-paper beneath, this being for the purpose of securing the whole by the seal. In another arrangement, the envelop is the same shape as that now generally used, having four triangular flaps, meeting in the centre for the seal. In the ends of three of these flaps are small holes, each one a little different in size, so that when folded the smallest hole is the lowest, and the largest the third in the layers, whilst the fourth is blank, the wax below which not only secures all the flaps, but adheres also to the enclosure. When a piece of blotting-paper is placed below the holes, as in another modification, any attempt to open the letter would involve a tear. 1593. 1594. DC N The ordinary four-cornered envelop, fitted to form what M. Rémond calls the " Detector," appears to answer all the requisites of security and elegance. The sealing-flap is embossed with some device, the centre of which is perforated in any ornamental way, and a colored wafer is placed beneath it, showing through the perforations like a colored device. When this is fastened in the usual way, a very slight examination serves to show whether or not it has been tampered with. If the wafer is used, and hot water or steam has been employed to soften it, its brilliancy will have entirely disappeared and if attempted to be cut through, its substance is 80 thin, that, either wet or dry, the chances are, that the minute integuments of the star, or other device, will be broken or disarranged. This species of seal is besides ornamental, and for general purposes may supersede the now common plan of color- stamping. The only American machine in practical use is one secretly used by Bell & Gould, Nassau-street, N. Y. We are unable to give any details respecting it. ETCHING. The entire apparatus is contained in a box not larger than a music-book. They consist of copper-plates, &c., etching-needles, hand-rest, etching-ground, dabber, oil-rubber, rottenstone, smo- king-taper, engraver's-shade, bordering-wax, stopping-out varnish, tracing-paper, aquafortis, &c. Ground-The ground is composed of asphaltum, Burgundy-pitch, and beeswax. Take equal por- tions of the above-named materials, place them in an earthen pipkin in an oven, and melt them. The mass must be kept stirred until well incorporated any small piece of wood will answer this purpose. When well mixed, it must be poured into a basin of cold water, and when nearly cold should be pressed and rolled with the hand, that all the water may be discharged, then made into a ball. Procure a piece of worn silk, but be careful it is without holes, double it, place the ball therein, and tie up the ends with packthread, taking care that the double silk reaches well over the ball. When tied tight, cut off the overplus silk, and let the knot remain for a hand-hold. Be sure that the silk is tight over the ball. Dabber.-Take another piece of silk, twice the size of the last, double it, place in it a ball of coarse wool well picked out, about the size of a small apple, tie it up in the same way as the ball for the ground, and it is ready for use. Oil-rubber.-The next thing necessary is an oil-rubber, which is simply a strip of woollen cloth, about two inches wide, rolled up tight, and bound over with packthread or thin tape. With a sharp knife cut off one end, avoiding the string so that the surface may be quite flat. This is used for taking out stains or polishing the plate. Rot'enstone.-Procure a piece of fine flannel, rather less than the silk which covers the etching ground ball, double it, place on it a small quantity of rottenstone in powder, which tie up in a bag. A small portion of fine whitening in the lump should be kept at hand for the sake of cleanliness any small box will answer this purpose. Smoking-taper.-Procure a wax taper, uncoil it by degrees before the fire until it is all equally pliant: double it up in about six lengths, give it one twist while warm, and turn it a few times before Digitized by Google 614 ETCHING. the fire, that the pieces of taper may adhere to each other melt the wax at one end, so that the wick is exposed; see that all the cotton ends will light freely: care should be taken to extinguish the cotton, or it will revive with the least draught, and may become dangerous. Bordering-waz.-This may be obtained ready made, but engravers make it to their own liking. The component parts are three ounces of resin, two ounces of beeswax, and such a quantity of sweet-oil as will soften the mixture to your fancy. Procure an earthen pipkin, place in the bottom a small quantity of sweet oil, (half an ounce or more,) add your resin and beeswax, broken in small pieces; when melted. work the ingredients well together with a stick until thoroughly incorporated, then pour into a basin of cold water; as it gets cold, work it well with the hands by pulling out into lengths and doubling it to- gether again the more it is worked the better it will be for use. Should it turn out brittle, return it broken to the pipkin, and add more oil; work it well together as before; pour it into water, and work it again with your hands. Engraver's-shade.-The next thing required is a shade, which can be made of wire. Bend it to a half-circle, bind it together with waxed string, lay it on tissue paper, cut away all but half an inch round the wire, cover that half inch with paste, and turn it over the wire; when dry, the shade is complete. Fasten a light string to the centre of the half-circle, and suspend it from the window- latch when in use. This shade must be placed in a forward position, sloping before your plate, and the white light it produces will enable you to see the lines made by your etching-needle. It is now the real amusement begins. You can work any time you please at the plate, and lay aside without injury to it. Hand-rest.-Any flat and thin piece of wood will answer this purpose, which is merely to keep the hand clear of the plate whilst at work. Stopping-out Varnish.-Turpentine varnish is superior, for several reasons, to Brunswick black. Turpentine Varnish.-Break small bits of resin into a vial, cover it over with spirits of turpentine to about twice the height of the resin. Place the bottle in a small saucepan of water on the hob, near enough to the fire to make and keep the water hot; a cork may be lightly placed in the mouth of the bottle, as the mixture will require to be shaken occasionally. A small portion of this mixture should be poured into a small pot, with a little lampblack added, to give it color, and well incorporated. This last is necessary to prevent lumps; it may be done by work- ing the mixture well together with the camel-hair pencil. You have now a good stopping-out varnish. With this varnish go over the border or margin of your plate: do this when about to put it away, and the varnish will become hard by being left a night to set. When inclined to put your plate through the process of biting-in, again go over the margin, using the same brush and mixture. You can always work it up by adding a little turpentine. When it is set 80 hard that you can place the finger on it without adherence, it is time to make up your wall or border of wax to hold the aquafortis. Aquafortis.Provide yourself with three half-pint bottles having glass stoppers, and two pint earthen jugs with spouts. Then obtain at the chemist's half a pound of nitric acid in a bottle No. 1. Pour into bottle No. 2 rather less than the fourth of. the nitre pour the bottle three parts full of water with a slow action pass it into one of your pint jugs, and back again to the bottle, to unite it well. In bottle No. 3 put one half of the remaining nitre; water it as before; see that the nitric acid in bottle No. 1 is well stoppered, and cover it with a piece of old glove. Tracing, and Tracing-paper.-Tracing-paper of various qualities may be purchased at any depôt of arts. But, in case of necessity, very good tracing-paper may be made by saturating with a camel-hair pencil the finest tissue paper with the following mixture :-Half an ounce of the balsam of Canada to one ounce of the spirits of turpentine, shaken well together in a two-ounce bottle: it requires no heat. When covered with the mixture, hang the paper on a line to dry then wash in like manner the other side. Place your drawing on the tracing-board, (a piece of soft planed deal,) over it lay the tracing-paper, fasten down with the brass-headed points, not through the drawing, but close to it, so that the pressure of the brass head secures both the drawing and tracing-paper from moving. Go carefully over all the lines of your drawing with an H-pencil, occasionally placing a piece of white paper between the drawing and the tracing-paper, to ascertain that you have not neglected any part of the lines on the drawing. Transferring-paper.-This is very easily made, as follows:-Take half a sheet of very fine bank post paper, lay it on a clean place and rub it well with the scrapings of red chalk a small bit of sponge is good for this purpose. Apply the chalk until the paper is all of one color, then, with a piece of clean old muslin, rub the greater part of the color from the surface. The color may be renewed occasionally as the marking becomes faint. Testing the Ground-Heat one corner of your plate, and rub over it the ground, in a thin and even surface. Next apply your dabber, to make a yet more equal distribution of the ground. When cold, mark over it with rather a blunt needle, (No. 3.) Should the ground be brittle, and crack with the passage of the needle, add to it more beeswax; should it drag with the needle. more asphaltum: the ground will easily melt again. When a ball is made to your satisfaction it will last a long time. The weather has considerable effect on the mixture, but the quality of the ingredients more, so that it is advisable to get the ground as perfect as you can while you have the melting-pot in use. Heating the plate for ground-You must have a small hand-vice with a haft of wood to resist the passage of heat to the hand. If your plate is stained or discolored, the mark must be removed with the oil-rubber, with a little rottenstone and oil, polished off with a bit of old muslin powdered with whitening. Be careful that no dust remains on the plate. Screw the vice on the long side of your copper-plate with a slight hold, covering the part grasped by the jaws of the vice with a small piece of paper, to prevent injury to the surface. Heating may be performed by burning paper under the back of the plate; but a stove or clear fire Digitized by Google ETCHING. 615 is much the preferable mode. Be careful not to overheat your plate. If the surface becomes dis- colored the plate is over hot as a test, turn it over and spit on the back; if the moisture jumps off, the plate is sufficiently hot should it hiss and remain on the plate, more heat must be obtained. A piece of sailcloth, rather larger than the plate, should be warmed by laying it before the fire during the heating process ; place it on the table, and lay upon it the plate, retaining the vice. Now pass your ball of ground over it backwards and forwards until the plate is covered, spreading the ground as evenly and thinly as possible. Then use your dabber with a quick action, pressing it down and plucking it up. If the ground does not distribute itself easily burn paper under it, as before, until it shines all over, being cautious that the ashes of the paper do not settle on the surface; dab on again, decreasing the pressure but not the speed of action, until the surface is all over alike. Smoking the plate-Have your taper ready, and a single taper or candle to take the light from the surface of your plate being perfectly covered, it may be as well to renew the heat in your plate by a paper burnt under the back until the surface shines, taking the same precautions as before. Hold the plate up in your left hand, with the face downward; light your smoking-taper, at the same time, having all the wicks burning, pass it rather quickly round the margin, and by degrees towards the centre, using a fluttering action with the hand ; smoke on until the whole surface is of a dark color, keeping the taper at such a distance from the plate that the burning cotton may have no chance of touching it, although the flame spreads over it when the surface is all black alike, and no sooty marks are to be seen on the working part of the plate, the ground is fit for use. Take the plate, face down- ward, to some convenient place, and pour cold water over the back, holding the plate in a sloping position, the vice up, Fig. 1600. This last process produces a stronger and harder surface than could be obtained if the plate were left gradually to cool. Now place the plate face downwards, supported on one side by the screw of the vice, Fig. 1601. Clean the smoke from the back, and let it remain until quite cold. 1606. 1602, 1605. 1601. 1603. 1600. 1604. As Figs. 1600 to 1611 consist of examples of the etching, biting-in with the acid, &c., I shall take advan- tage of it to exemplify the manual craft of laying the ground, smoking, &c. Some difficulty may be found in laying the first ground with success; but having managed one well, you may be sure for the future. Transferring.-If you have not an etching-board place your copper-plate on a thick piece of brown paper, larger than the plate make two ribe of the same paper, doubled four or more times, and about an inch wide place them at each end of your plate on the brown paper, and fasten them with sealing- wax: these ribe serve as shoulders for the rest to lay on, which will prevent your hand from touching the work. You may now cut your tracing-paper to the size of your plate, having ruled your margin line, if one is required. Place your tracing reversed, that is, the pencil side to the plate. Fix it with bits of soft wax round the border, leaving open the bottom to admit the transferring-paper, which introduces the chalk side next to the plate: the upper side of the paper must be kept clean, that you may see the pencil lines on your tracing-paper. Next with an H H pencil, sharp and short in the cut, go over all the lines of your tracing with rather an upright hand, that you may be able to make strong pressure the upper side of your tracing-paper, not being marked with pencil, will show whether you have gone over the whole of the lines with the pencil on the upper side; look sideways at your work, and the black-lead mark will be perceptible. Before you advance far in your transfer, lift up the bottom of your tracing to ascertain if the lines are of sufficient strength if not, apply more red chalk to your transfer-paper. When you think the transfer is completed, do not take off the whole of your paper, Digitized by Google 616 ETCHING. but allow the part affixed by the top spots of wax to remain. You can then lift up the whole of the work, and if any part of it has been neglected the tracing can again be laid down, and the omis- sion rectified. Etching.-You must begin with needle No. 1 (the fine point) and go carefully over the outline, not making much impression on the copper, but sufficient to remove the ground with the same point go over all the lighter parts, increasing the pressure, so that a slight indentation may be made on the plate. No. 2 point may now be used to go over the lighter shade with increased weight of hand. No. 2 point will answer for the darker shades by making the lines nearer together and increasing the pres- sure. Interline parts that require extra color with No. 1 point: the etching may be worked at for a considerable time by interlining and dotting. Should you by accident or mistake make any marks you wish to expunge, dip a pointed camel-hair pencil into the turpentine bottle, and with its point work up some of the ground on the margin of the plate, and therewith stop out the objectionable marks. When set it will resist the aquafortia. Bordering the plate.-In cold weather the wax will be too hard to be rolled out with the hand, it must then be placed in moderately warm water until it becomes pliable; then pull and roll it out to about the thickness of a small walking-stick slightly grease the point of the thumb and two fore- fingers with deer or mutton fat, press the roll of wax flat as you place it on the border of your plate, with the edge to the varnish, taking great care that the bordering-wax does not go off the varnish. At what you intend to be the darkest corner of your plate pinch out the wax broader, that the height of the wall may increase to that corner where the spout is to be formed with the wax, to prevent spill- ing the aquafortis in pouring it off. Biting-in.-Lay your plate flat on a piece of sailcloth larger than the plate, as a protection from any splashings that may be made. Place the spout of your plate in front for the convenience of pouring off. One of your jugs being filled with water, pour it over the plate to prove if there is any leakage in your border; should you find any, pour off the water let the plate dry, particularly in the defective part; then press down the outer edge of the wax with a piece of stick. Lay by the side of your plate two or three wedges, (small pieces of firewood,) to be,used for tilting the plate should the acid not lay even. It would be worse than useless to prescribe rules for the proportions of water to be used to the nitric acid, as that will entirely depend on the strength of the acid. Having proved that your border is sound, pour off the water then cover the surface of the plate with the aquafortis from No. 2 bottle. If in the course of half a minute the etching on your plate should assume a light-gray coating the mixture will do; but if it should throw up bubbles it is over strong, and more water must be added, but not on the plate. The mixture must be placed in the jug, then in the bottle, and afterwards returned to the plate. Should the lines on the plate remain as bright copper after the acid has been on half a minute, it is not strong enough, and some aquafortis out of bottle No. 3 must be added. Having mixed your aquafortis 80 that the lines do not produce foam, but continue a gray frosty ap- pearance, the process is going on well. The power of biting-in correctly must depend on the experience you have of your acid. With a soft camel-hair pencil lightly remove the frosty appearance, taking care that the quill does not touch the ground. Should any part of the ground be breaking up, that is, the lines becoming united, pour off your acid carefully into the jug. Lay the plate again on the flat, and cover it with water from the other jug, moving it gently with the camel-hair pencil, which should be placed in the water-jug when taken from the acid, or it will soon become useless. The wash-water from the plate must be thrown away. The first biting now is supposed to be com- pleted, therefore set the plate up endways to dry. Second biting.-When the plate is perfectly dry, take off with your scraper a spot of ground in the lighter part, to ascertain if the acid has made sufficient indentation. If it has, work up your stopping- out varnish with a camel hair pencil, and with it cover all the parts you intend to remain light you must elevate your rest so that you do not press the border-wax. When the stopping-out varnish is dry, which may be ascertained by placing your finger on it and finding that it does not stick, put on the same aquafortis (bottle No. 2) and let it remain until you ob- serve the ground giving way then pour off the acid, and wash well as before. Put the plate to drain. Should it be required, more biting may be performed, and the process is the same. Cleaning off.-Now comes the least agreeable part of the process. Great care must be taken that the plate is perfectly dry if it be not it may be placed before the fire, but not close enough to melt the wax. Having carefully wiped the sailcloth, lay the plate a little more than half way upon it, but 80 that the balance remains to the table. Apply a lighted taper or a folded paper match progressively under the wax; pull up the wax as the warmth proceeds; you will find that the slightest warmth answers the purpose. By removing the wax with a knife you are liable to injure the margin, an evil which gives much trouble to remedy. This being the most unpleasant process of engraving, it may be as well to use old gloves if any of the wax should adhere to the plate, to remove it use a bit of deal firewood cut in the shape of a chisel. Now fix your vice on the same end, and place as you did when laying on the ground. Rub the plate over with a bit of rush candle, using the side, (taking care to cover every part have some old soft rags ready; hold the plate up by the vice heat the back with burning paper as before, until the ground varnish and tallow are melted. Rub off with a soft rag. Should any smut remain, apply a little turpentine; withdraw the vice and wash the spot with turpentine. Rub the plate front, back, and sides, with the rag. Dab the plate with your bag of rottenstone; pour on it a little sweet-oil and with your oil-rubber polish the plate with up and down strokes, using considerable pressure wipe the plate quite clean, and polish off with fine whiting. Digitized by Google ETCHING. 617 Should you have succeeded in biting-in well, the plate is fit for the printer. Dry point-Should your work have 80 far succeeded as to require but little improvement, the dry point may next be used. For this purpose the needle No. 3, well pointed, (as indenture must be made by pressure of the hand,) may be employed. For interlining the parts which are too weak, and uni- ting lines neglected in the etching, the dry point will be sufficient; but as the pressure will leave a projection or burr on the plate, it must be carefully removed by the sharp scraper should your plate require more than the dry point can accomplish, recourse must be had to re-biting. Re-biting.-Heat your plate as before, but make one corner (the one with the least work in it) hotter than the other part. Rub your ground on the hot corner, and with the dabber take the ground therefrom, and dab quickly over the other part until the whole surface is covered. Prior to laying the ground the plate should be polished with whiting, using a piece of old muslin folded in the shape of a dabber, which will fill the etched lines, and prevent the new-laid ground from entering. All the parts but those wanting more color must be stopped out as before; again the border-wax must be used. Next follow with acid the same process. Re-etching.-This is the most certain method of finishing the plate. The ground must be laid as in the first instance, but using a greater body, and with the dabber rubbing it well into the lines, taking care that no whiting remains in the etching marks; for this process the plate should be merely washed with turpentine; a slight extra warmth and good dabbing will render the ground acid proof. The smoking is here dispensed with Set up your shade, and work at the plate as in the first instance. Now use No. 3 point, (sharp,) and interline the parts you wish darker and where you want greater strength, crossing the lines, not in direct angles, but lozenge ways. The plate, cleaned off as before directed, receiving a light oil rubbing with a little rottenstone, and washed off with turpentine, may now be sent to the printer's and a proof obtained. By repeating the re-etching your plate may be worked up to the color of a line engraving. In some of the darker parts a graver or lozenge tool may be used; but as it is rather dangerous in the hands of the uninitiated, perhaps it may be best to do without it, as it is apt to slip and make deep lines where none are wanted. Re-biting will produce any extra color that may be wanted with little more trouble, and certainly with less danger. General instructions-The following directions may be rather prolix, but will relieve beginners from much trouble, and enable them to avoid many accidents to which engravers are liable. 1st. When using the acid, slightly grease that part of the hand likely to come in contact with it, as a preventive to its making stains, which are not easily eradicated. 2d. When your border-wax has done its duty have it well washed in cold water; then warmed be- fore the fire; pulled out and pressed together again, as the more frequently that is done the more flexible the wax will be for future use. 3d. As your aquafortis will become reduced in strength by exposure to the air, it becomes necessary to add a portion of No. 3 bottle to that of No. 2; and a small quantity of No. 1 bottle to No. 3: No. 1 bottle being the undilute acid. 4th. When making a point to your etching-needle work the point round, as, should there be any flat side to the point, it will bite the copper and prevent the freedom of hand required to give spirit to the etching. 5th. With your burnisher you may soften down any part of your etching that appears harsh or crude, by gently passing it over the parts to be reduced in color. 6th. Having your shade before you, which must be between you and the light, you will be enabled to see the marks of the burnisher fine charcoal and oil will remove them, and the oil-rubber will clear away the charcoal marks. The charcoal can be obtained at any coppersmiths or plate-printers. 7th. If your burnisher is good at first it never requires alteration. The scraper must be occasionally sharpened. Soft ground-Take half a ball of hard ground, (mixed as described under the head Etching-ground to that add a piece of mutton-suet. Melt them well together, observing that the mixture must be thoroughly incorporated; then pour into cold water, and use it as before directed. Laying the ground-The process is exactly the same as in laying the etching-ground, with this differ- ence, that the plate does not require 80 great a heat. Smoke the plate the same as in laying etching-ground. The ground must be spread as thinly as it possibly can, to cover the plate and bear smoking. The surface of the plate must be alike all over, and quite bright or shining. If any part but the edges appear sooty, it must be cleared off, and the plate polished, as described for etching, and laid again. You may by chance make a good ground at the first melting, but that can scarcely be expected. It may be as well to test the quality of your mixture before you lay a whole ground. To this end, heat a small portion of your plate; lay some of the ground; smoke it; and let it get quite cold. Obtain some of the finest tissue-paper,-not fine from thinness, but from its even texture. Place a piece of the paper on the patch of ground laid, and with a fine-pointed H pencil make a slight sketch:-a bit of foliage for instance; the paper should slightly stick to the plate: when carefully raised by the two bottom corners, the back of it should clearly show every line made on its surface, only darker. Should the sketch on the copper have a grainy appearance,-that is, look as if it was dotted all over, the mixture of ground will do. Should the ground adhere to the paper, like marks with pen and ink, the ground must be melted with an addition of hard ground; and if even the most tender marks of the pencil do not pull the ground from the plate, the ground must be remelted, and 80 with one or the other, as the ground may require, until it is fit for work. As the season has great effect on this ground, the one that will answer for summer will not do for winter, so it may be as well to make or procure two or three sorts of mixtures, and number them according to their several degrees of hardness. 78 Digitized by Google 618 ETCHING. Having succeeded in mixing your ground, take a piece of tissue-paper twice the size of your plate. Place the plate in the centre, and with a black-lead pencil draw a line all round it. Make the same mark on the other side; then lay the ground as before described. When cold, wipe the back and edges before you take off the hand-vice. This ground being very tender, care must be taken not to touch the face of the plate. Upon the square marked on the paper your drawing is to be made. If you intend to copy the sub- ject, you must go through the same process as in transferring for the hard-ground etching; only, instead of transferring the red lines on the plate, they must be made within the square marked on the paper. Take care that your tracing is reversed. If you intend making your drawing on the plate without copy, you must lightly make your design on the square marked with fine-pointed red chalk. Should the subject be figures, every thing must be drawn, as it were, left-handed or reversed. Fold a clean silk handkerchief in four, lay it flat and smooth on the table, place on it the paper with the chalk sketch downwards. Now, with great tenderness, lay the plate face down, exactly on the square mark of the paper; fold over the back the overplus paper, and fix the sides with four thin spots of sealing-wax near the corners: be sure you do not move the plate on the silk. Take your plate care- fully up, and place it for work. Use a rest as in etching, and a hard pencil, H H, on the places you wish to be dark. There is one drawback to the pleasure of soft-ground engraving you must finish what you begin the same day the mechanical part of the work may be delayed. Your drawing finished, pull up your paper by the two bottom corners. Varnish the border down the same as in etching. The acid used must be much stronger; the border- wax higher and broader in the spout, as you may perhaps have to pour off suddenly. Biting-in.In biting-in the signal to pour off your acid is, when you perceive the ground breaking up,-that is, coming up in patches. During the biting-in the soft camel-hair pencil may be used, but very tenderly. Wash well off with cold water, and place it to dry. For cleaning, see Etching, (supra.) Should the plate require more finishing, have recourse to the hard ground without smoking. 1608. 1609. 1607. Aqua-tinta engraving.-In this we have another variety of entertaining engraving; one, moreover, which, unlike the last, is still much practised by professional engravers. It forms the ground-work of many of the best modern prints, and is generally resorted to where the object is to produce a plate, the impressions from which are to be colored. It will at once be recognized by its similarity to an Indian Ink or Sepia Drawing; for in working the plate at press, black and brown inks are used indifferently, as the artist or publisher may direct. Resin forms the ground in this method of engraving. Without further remark, we proceed to a description of the materials and the mode of employing them. Aqua-tint ground-Break some of the best white resin into pieces, sufficiently small to go into the mouth of the bottle used. Fill the bottle up, or nearly so, with spirits of wine. This must be occa- sionally shaken, until the resin is dissolved. The bottles must have corks, not glass stoppers. Have two other bottles ready; mark the bottles 1, 2, 3. No. 1 is the bottle in which the resin is placed. Pour from the mixture No. 1 into No. 2 one-third; fill this bottle nearly with spirits of wine. Pour into No. 3 bottle rather less of the mixture from No. 1, and nearly fill it with spirits of wine. These bottles must be occasionally shaken, and their contents allowed to settle well before use. The contents of the three bottles must be so mixed that they are one under the other in strength, as the size of the grain to be laid on the plate depends on the quantity of resin each mixture contains. The more of resin the larger the grain. The spirit must be entirely free from water. To test the spirit.-Place a small quantity of gunpowder in a silver spoon; pour over it some of the spirit; light the spirit, and let it burn down to the powder. If the powder takes fire and explodes, the spirit is good, and fit for use. If it should remain in the bottom of the spoon black and wet, the spirit has been adulterated with water, and is not fit for the purpose. Trial of aqua-tinta ground-Have a tin trough about two inches wide and rather longer than your plate, with a convenient spout at one end; the trough is to act as a receiver of the spirit when poured over the plate; the spout to return it to the bottle. Laying the ground-Polish the plate well, as before directed. Place it on a slight slope, the tin trough under the lower edge to receive the spare mixture. As a trial of your ground, pour the liquid from each bottle, and make a small patch in different places at the bottom of your plate. When the liquid has run off to your tin trough lay the plate flat, and with a piece of rag wipe the lower edge. Take a magnifying-glass and look at the grains deposited on the copper. Having poured the spirit from the trough to bottle No. 1, make choice of the grain most likely to suit Digitized by Google ETCHING. 619 your work, if indeed either of the three should; if not, you must mix the large grain and the small together until it does, letting the mixture settle well before it is used. When you have made one bottle of ground to suit your purpose, make a memorandum of the circumstance upon the bottle. Having removed your trial spots, polish the plate well, and place it as directed for trial, with the side you intend for the foreground next to the tin trough. Pour the mixture along the top of the plate, from one end to the other, until the whole of the surface is covered. As soon as the spirit has run into the tin, lay the plate flat: the sooner it is laid flat the rounder will be the setting of the grain: the longer the plate remains on the slope, the more elongated the deposit of resin will become, which, for some sort of work, will answer better than round-such as broken rock, water-falls, &c In most cases it is advisable to make a very fine etching of the subject intended to be placed on the plate prior to laying the aqua-tinta ground; in the end it will save time. The etching must be very light, otherwise the aqua-tinta ground will hang round the lines and form a ray of light. Should the etching be strong, it will require being filled up with wax, and polished off before laying the ground. Engravers send the plate to the printer's, and have it filled up with ink, which is much the best method, where it can be resorted to. If obliged to use wax, the plate must be heated rather above what is required for the etching-ground, the surface wiped off, and polished with the soft part of the hand slightly rubbed with whiting. Having laid the ground to your satisfaction, the next pro- 1610. ceeding is stopping out the lights. Stopping out the lights.-Place on the left side a small looking-glass in a stooping forward position lay before it the drawing intended to be worked from, with the base or foreground towards the bottom of the glass; you will then see the subject reversed in the glass, which will enable you to copy with greater freedom. Go over the margin as directed under the head Etching. For this a camel-hair pencil, and the same pot of varnish, with a little more lamp-black added, and well worked to- gether, should be used. Stop out all the white lights you observe in the drawing. By the time you have done this the varnish on the margm will be dry or set; if not, the plate must remain until it is. Then go over the margin again with the same varnish, and let that set hard. Now place up your border-wax as before directed, making the spout rather larger, that you may be enabled to pour off the acid quickly, if necessary. Use the same aquafortis as for etching, but the strength somewhat increased, as it will have to remain on the plate a much shorter time. Lay your plate an inch or so over the front of the table, with the piece of sailcloth underneath, having small wedges of wood ready to be used should the acid not float evenly. 1611. Put on the acid rather quickly; running it from the bottle to the jug, then on the plate; the other jug, having been filled with cold water, should be kept ready for washing off. When the acid has entirely covered the plate, the sur- face should immediately assume a frosty appearance, but not come up in bladders. Little more than a minute may be enough for the acid to remain on the plate; pour it into the jug as quickly as you can without spilling it; immediately wash off with cold water; have a receiver for the wash- water, as it must be thrown away. Wait until the surface of the plate is dry. If in a hurry, blow it dry with bellows. When you adjust your plate for work, should any spots of moisture remain on the surface, carefully take them up with blotting-paper. Now, with the same varnish, stop out all the second lights. To prevent injury to your border, place two blocks or old books under the ends of your rest. When the second stopping out is set, put the plate through the same process with the same acid. Again dry the plate, and stop out the third light parts; when set, apply the acid, but let it remain on rather longer; wash, &c., as before directed. You will now have all the flat tints, and only require the very dark ones. With your magnifying- glass ascertain if the spots of resin remain on the plate; if so, it will bear biting again. Should the ground remain sound enough to stand another application of the nitre, you must prepare a mixture called touching stuff Touching stuff.-Burn a good-sized cork to ashes, and take a piece of whiting about the size of a filbert; mix them together with treacle; then add as much ivory-black as will make the mixture a dark color, by the addition of a small quantity of sheep's or ox gall; it works almost as free as the varnish. Make the composition to a lump. A small quantity to be used with water when required. Again lay the plate for work. Paint over all the parts that are required to be very dark, such as projecting foliage, and all sharp shadows, with the touching stuff. I say paint, for you must load all the touches with as much of the mixture as can be placed on them. Digitized by Google 620 ETCHING. When the touching stuff is dry, mix some thin turpentine varnish, slightly colored with lamp-black, and with a larger brush go over the whole of the plate. When this last varnish is set, pour on some very weak acid and water-the former washings of the plate will do. With the soft camel-hair pencil used for the acid, work up the touching stuff until the whole comes off; then wash the plate clean with cold water, and again apply the acid. For this last biting the acid may remain on the plate as long as the ground will stand. This may be ascertained by clearing your plate with the camel-hair pencil, and using the magnifying-glass. The plate must now be cleaned. Release your border-wax as before described. On this tint the oil-rubber should be very carefully used. The plate being quite clean, place it under the shade. You will find your tints or bitings rather sharper against each other than you wish. The burnisher is to do away with this by rubbing with pressure the parts to be reduced in color. The parts to be burnished should be slightly touched with the oil-rubber. Aqua-tint engraving requires some skill in the use of the burnisher, which can only be acquired by practice. The scraper will be found very useful for bringing out sharp lights and modulating the darker parts. Should you have failed in making the first ground tell to your satisfaction, the plate must be polished, and another ground laid. The second ground must be larger than the first, that is, contain more resin. The bordering, biting, and stopping out are as before. The plate should be sent for proof before the second ground is laid. When you have the proof you will be able to ascertain where you require increase and where reduction of color. The burnisher must reduce, the increase can only be had by laying another ground. Ground to etch on.-Mix a small quantity of turpentine varnish with turpentine very slightly colored with black, but only sufficiently 80 to render the lines made by the needle perceptible. With this thin varnish and a good-sized camel-hair brush, go over the plate longways; when that is set, repeat the coating crossways; let it set, and lay it by for a night, if convenient. The etching finished, border and bite as before directed, but with stronger acid. Incidental instructions.-A few hints or cautions, apparently on trifles, may be found useful, and enable the beginner to avoid many troublesome obstacles which, neglected, prevent engraving becoming an entertaining amusement. Great care must be taken, while laying the ground, that there is not much dust floating in the air; for should the slightest particle of fluck lodge on the plate whilst wet, it will cause, what the engravers call, an accident." Wherever the speck falls, the resin will corrode around it, and consequently form a white spot on the ground where the acid has been applied. These accidents" are of little conse- quence, unless they should happen on the sky. To do away with such light places, the chalk tool or dotter must be used, which is simply a bent graver. From pouring your ground mixture backwards and forwards, it is likely to become foul; it should then be passed through a double piece of clean muslin, and put away in a bottle to settle. The burnisher acts as principal in forming a good sky and background. As the action of the acid will leave all the tints with a sharp edge, they must be softened down with the burnisher. Every fresh aqua-tinta ground laid should be increased in the size of the grain, or the ground will become murky. To enrich and darken the foreground or foliage, etching over the parts with the etching-ground above described, is much the easiest method. Resin-ground engraving.-This style of engraving is well adapted to ornamental work, as great depth of color can be obtained. The process is extremely simple. The best white resin should be reduced to powder by pestle and mortar, then placed in a fine doubled flannel, and tied up in a bag. The plate must be heated as in laying etching-ground, and the bag of resin then powdered on the surface. The best plan is to lay the plate on a table, 80 that you may use both hands. With the bag of resin pendent in the right hand, strike it against the left, (the bag must be held some distance from the plate,) which will force the powdered resin to escape from the flannel bag, and falling on the hot plate, will there fix itself in small spots, something similar to the aqua-tint deposit, but much more enduring. The stopping out process is exactly the same as in the aqua-tint. By repeating the process with the flannel bag a positive black ground may be procured, as dark and more enduring than a mezzotinto ground, which may be scraped on much in the same way. Figs. 1608 to 1611, represent the apparatus, and the hand-craft to bring it into action ;-such as heating the plate, laying the ground, smoking the ground, bordering the margin, biting-in the etching, taking off the border, and polishing the plate. Etching on glass.-The glass is covered with a thin ground of beeswax, and the design being drawn with the etching-needle, it is subjected to the action of sulphuric acid sprinkled over with pounded flour or Derbyshire spar. After four or five hours this is removed, and the glass cleaned off with oil of turpentine, leaving the parts covered with the beeswax untouched. This operation may be inverted by drawing the design on the glass with a solution of beeswax and turpentine, and subjecting the ground to the action of the acid. Stippling is also executed on the etching-ground by dots instead of lines made with the etching- needle, which, according to the intensity of the shadow to be represented, are made thicker and closer. The work is then bit in. Etching on steel is executed much in the same way as in the process on copper. The plate is bedded on common glazier's putty, and a ground of Brunswick black is laid in the usual way, through which the needle scratches. It is then bit in, in the way above described. Digitized by Google FAN. 621 FAN. A wheel with vanes revolving in a case or box, used for the production of a current of air or gas. The principle of its operation depends on the law of centrifugal forces; the air is drawn in at the centre and discharged at the periphery of the wheel it may therefore be applied either to draw air from any place, or to force it into any place, as may be best suited to the purpose intended. The fan is employed for draft or suction-in cotton pickers, for the extraction of dirt and for the formation of a lap. It is used generally for blast to furnaces (see Blowing Machines) and for agricultural purposes, as in the winnowing of grain; for ventilation it is used indiscriminately for draft or blast. When used to promote the rapid combustion of fuel, it is evident, that whether the fan be placed in the smoke flue, and the air be drawn into the fire, or whether it be placed in front of the fire, and the air forced in, the result will be in most cases nearly the same. It is applied in both ways, but there are some mechani- cal difficulties that interfere with the economical use of it in the former method, and it is therefore almost universally applied to fires as a blowing machine. Of the practical working of the fan. The power required to drive it, the proper velocity to be given to it, and the density of air required, we know no more satisfactory experiments than those made by W. Buckle, Esq., and published in the Practical Mechanic's and Civil Engineer and Architect Journals, from which we extract his observations and the results of his experiments. The experiments were made with a fan 8 feet 1013 inches diameter, the width of the vanes being 10} and the lengths 14 inches; the eccentricity of the fan 110 inches, with reference to the fan case, the number of vanes being 5, and placed at an angle of 6° to the plane of the diameter; the inlet open- ings on the sides of the fan chest 171 inches diameter, the outlet opening 12 inches square; the space between the tips of the blades and the chest increasing from 1 inch on the exit pipe to 31 at the bot- tom, in a line perpendicular with the centre. To the blast pipe leading to the tuyeres a slide valve was attached, by means of which the area of the discharge was accurately adjusted to suit the required density." Velocity of the Height of mer- Height of col- Area of dis- Theoretical ve- No. of tips of vanes in Density of air cury in inches umn of air charge pipe Indicated locity of air in Experi- feet per sec- in ounces per equivalent to equivalent to in square horse pow- feet per sec- ments. ond. square inch. the density. the density of inches. er. ond. air in feet. 1 2368 9.4 1.175 1093-10 closed. 960 264'4 2 2208 7.9 987 918.20 " 7.54 242-4 3 204'16 6-9 862 80191 " 6-68 2265 4 18528 5.6 r 651'21 " 586 204'1 5 171.5 45 562 5228 " 3.82 1829 6 144.10 3.5 437 406.5 " 2.214 161-2 7 2218 7 875 814-01 87.5 13:31 228-24 8 21709 7 875 " 38-125 11-02 22824 9 2218 6 750 69772 48.75 1381 211.8 10 2133 6 750 " 53125 12.54 2113 11 192.2 6 750 " 24875 6.48 2113 12 2218 5 625 581-48 60 1426 1929 13 211.48 5 625 " 65. 18-05 1929 14 1939 5 625 " 525 8-75 1929 15 174.5 5 625 " 225 453 1929 16 2218 4 5 465.1 69. 14.19 172.5 17 211-48 4 5 " 75. 13:33 172.5 18 196.68 4 5 " 65.62 9-58 172.5 19 177.62 4 5 " 78125 1132 1725 20 155.11 4 5 " 83125 33 1725 21 200-7 8 .875 34886 82.68 10-15 150- 22 174.5 3 375 " 10272 10-61 150- 23 1578 3 375 " 8963 7.56 150- 24 134.5 3 875 " 56.25 298 150- 25 160.5 2 250 232.5 151.6 91 122- 26 138.15 2 -250 " 124-125 589 122. 27 155.1 1 125 116.28 2649 938 86.26 28 138.15 1 125 " 264-9 7.27 86.26 By this table it will be seen that there are certain velocities with which the tips of the fans should move according to the required density of air, and that there are certain laws which govern these ve- locities. The centrifugal force or density of the air coincides with the results obtained by the law of falling bodies; that is, when the velocity is the same as the velocity which a body will acquire in falling the height of a homogeneous column of air equivalent to a given density. Having given the velocity of the air, and the diameter of the fan, to ascertain the centrifugal force- Rule-Divide the velocity by 401, and again divide the square of the quotient by the diameter of the fan. This last quotient multiplied by the weight of a cubic foot of air, at 60° Fahrenheit, is equal to the force in ounces per square foot, which, divided by 144, is equal to the density of air per square inch. Or, substituting the following formula, we have D = N X 000034. Where D is the density of the Digitized by Google 622 FAN. air in ounces per square inch, and N the number of revolutions of fan per minute, and V the velocity of the tips of the fan in feet per second. Having given the density in inches of mercury, (1 inch of which is equal to 8 OZ. pressure.) To find the velocity which a body would acquire in falling the height of a column of air equivalent to that density Rule.-Multiply the density in inches of mercury by 9303, and this product by 64. The square root of the last product will be the velocity in feet per second, or more simply- Multiply the square root of the density in inches of mercury by 244, and the product will be the velocity. It will be seen by the table that the velocity of the tips of the fan is practically somewhat less than this theoretical velocity, and from the experiments we fix the laws which govern the velocity of the tips of the fan 9-10th of the velocity a body would acquire in falling the height of a homogeneous column of air equivalent to the density. Experiments were made as to the proper size of the inlet openings, and on the proper proportions to be given to the vane. The inlet openings in the sides of the fan chest were contracted from 17t, the original diameter, to 12 and 6 inches diameter, when the following results were obtained: First, that the power expended with the opening contracted to 12 inches diameter, was as 21 to 1 compared with the opening of 171 inches diameter; the velocity of the fan being nearly the same, as also the quantity and density of air delivered. Second, that the power expended with the opening contracted to 6 inches diameter, was as 21 to 1 compared with the opening of 171 inches diameter; the velocity of the fan being nearly the same, and also the area of the efflux pipe, but the density of the air decreased one-fourth. These experiments show that the inlet openings must be made of sufficient size, that the air may have a free and uninterrupted action in its passage to the blades of the fan, for if we impede this action we do 80 at the expense of power. With a vane 14 inches long, the tips of which revolve at the rate of 2368 feet per second, air is con- densed to 9.4 ounces per square inch above the pressure of the atmosphere, with a power of 96 horses; but a vane 8 inches long, the diameter at the tips being the same, and having, therefore, the same velo- city, condenses air to 6 ounces per square inch only, and takes 12-horse power. Thus, the density of the latter is little better than 6-10th of the former, while the power absorbed is nearly 1.25 to 1. Although the velocity of the tips of the vanes is the same in each case, the velocities of the heels of the respective blades are very different; for, whilst the tips of the blades in each case move at the rate of 236.8 feet per second, the heels of the 14-inch blades move at the rate of 90.8 feet per second; and the heels of the 8-inch move at the rate of 15175 feet per second or, the velocity of the heel of the 14 inch moves in the ratio of 1 to 1.67, compared with the heel of the 8-inch blade. The longer blade approaching nearer the centre, strikes the air with less velocity, and allows it to enter on the blade with greater freedom, and with considerable less force than the shorter one. The infer- ence is, that the short blade must take more power at the same time that it accumulates a less quan- tity of air. These experiments lead me to conclude, that the length of the vane demands as great a consideration as the proper diameter of the inlet opening. If there were no other object in view, it would be useless to make the vanes of the fan of a greater width than the inlet opening can freely supply. On the pro- portion of the length and width of the vane, and the diameter of the inlet opening, rest the three most important points, viz., quantity, and density of air, and expenditure of power. In the 14-inch blade, the tip has a velocity 2.6 times greater than the heel; or, by the laws of cen- trifugal force, the air will have a density 26 times greater at the tip of the blade than that at the heel. The air cannot enter on the heel with a density higher than that of the atmosphere, but in its passage along the vanes, it becomes compressed in proportion to its centrifugal force. The greater the length of vane, the greater will be the difference of the centrifugal force between the heel and the tip of the blade; consequently, the greater the density of the air. Reasoning, then, from these experiments, I recommend, for easy reference, the following proportions for the construction of the fan :- Let the width of the vanes be one-fourth of the diameter. Let the diameter of the inlet openings in the sides of the fan chest be one-half the diameter of the fan. And, let the length of the vanes be one-fourth of the diameter of the fan. In adopting this mode of construction, the area of the inlet openings in the sides of the fan chest will be the same as the circumference of the heel of the blade, multiplied by its width; or the same area as the space described by the heel of the blade. The following table gives the sizes of fans varying from 3 to 6 feet diameter: TABLE OF BEST PROPORTIONS OF FANS. Diameter of Fan. Width of Vane. Length of Vane. Diameter of inlet opening. P. in. IL in. ft. in. ft. in. 8 0 0 9 0 9 1 6 8 6 0 10} 0 101 1 9 4 0 1 0 1 0 2 0 4 6 1 If 1 11 2 3 5 0 1 8 1 8 2 6 6 0 1 6 1 6 3 0 I recommend the proportions in the above table for density ranging from 8 to 6 ounces per square inch, and for higher densities, vis. from 6 to 9, or more ounces, the sizes given in the following table: Digitized by Google FALLING STOCKS. 623 Diameter of Fan. Width of Vane. Length of Vane. Dismeter of inlet opening. ft. in. ft. in. P. in. ft. in. 8 0 0 7 1 0 1 0 8 6 0 81 1 If 1 3 4 0 0 91 1 81 1 6 4 6 0 101 1 41 1 9 5 0 1 0 1 B 2 0 6 0 1 2 1 10 2 4 The dimensions of the above tables are not laid down as prescribed limits, but as approximations obtained from the best results in practice. Experiments were also made with reference to the admission of air into the transit or outlet pipe. By a slide the width of the opening into this pipe was varied from 12 to 4 inches. The object of this was to proportion the opening to the quantity of air required, and thereby to lessen the power necessary to drive the fan. It was found that the less this opening is made, provided we produce sufficient blast, the less noise will proceed from the fan; and by making the tops of this opening level with the tips of the vane, the column of air has little or no reaction on the vanes. As to the pressure of the blast commonly required in smithies, the range is from 4 to 5 ounces per square inch. And an ordinary eccentrically placed fan, 4 feet diameter-the blades 10 inches wide and 14 inches long, and making 870 revolutions per minute-will supply air at a density of 4 ounces per square inch to 40 tuyeres, each being 18 inch diameter, without any falling off in density. The above embody the results and deductions from Mr. Buckle's experiments on the common form of eccentrically placed fan; but, besides this form, there is a great variety of others, on which, it is true, no scientific experiments have been made of their working, but which, in practice, have given very sat- isfactory results. We give drawings and slight descriptions of two in common use. Figs. 1612, 1613, and 1614, represent the fan of F. P. Dimpfel, of Philadelphia 1614. 1613. 1612. Fig. 1612 is a side view. Fig. 1613 an end view, looking into the outlet pipe. Fig. 1614 a section. It will be seen that the vanes of the fan are in the form of a trapezium, and that the air-chamber not only extends all round the periphery of the fan, but also at the sides. This fan is in use at the Novelty Works, New York; where it is also made, and is highly recom- mended by the proprietors of various foundries and forges where it is in operation. 1615. 1616. Figs. 1615 and 1616 represent sections of a fan made by Wm. Mason. Taunton, Mass. The vanes are three in number, of a triangular form: the air-chamber is circular, and extends entirely round the fan the arms of the fan are curved, and in movement present the convex side to the impelled air. The construction of this fan is extremely simple: the fan is cast entire in one piece; the case enclosing the fan and forming the air-chamber, is cast in halves and bolted together. This fan is extensively used, and gives general satisfaction. Both Dimpfel and Mason's fans are made of various sizes to suit the purposes for which they are designed. FALLING STOCKS. Each mill consists of a pair of heavy oak hammers, weighing about 75 pounds each, and lifted alternately by the cams a a', on opposite sides of the tappet-wheel A, as in the drawing. The hammers should be about 91 inches wide each, and 16 to 17 inches deep. The cloth to Digitized by Google 624 FELLOE MACHINE. be milled is placed in the cup of the mill B, with a small quantity of soap. The hammers are then put in operation and run from 12 to 48 hours, according to the weight of the fabric, Fig. 1617. See FULLING. 1617. 65 A B a a FEED APPARATUS. See DETAILS OF ENGINES, page 513. FELLOE MACHINE This is a machine for cutting felloes of wheels out of plank, on which valua- ble improvements have been made by Joshua and Levi Adams, and T.H. Mores, of Ainherst, Mass. K 1618. A C + : D E 9 h A G Digitized by Google FILES. 625 Fig. 1618 is an elevated section of the machine at the line X X of Fig. 1619, which is a horizontal view with the friction wheels removed. The same letters refer to like parts OD both the figures. A is a frame, B is an upright shaft resting in a movable step at its lower end, and having a cireular plate a, secured to its upper end, above the hub b. C is a horizontal beam secured between projections on the upper surface of the circular plate. D are angular metallic boxes with flanges on their sides attached to the beam by the straps d. E are the cutters of the desired form passing through openings in the boxes and adjusted by screws. F is an upright shaft resting in a step in the frame and turning in a box screwed to a vibrating timber at its upper end, and with a friction wheel and pulley f at the top, and a gang of pulleys g below, around which is seen the band h extending around a pulley i on B. G is a lever arranged below the frame and secured at one end to the front of the same by a pin upon which it moves, and at its opposite end upon a similar lever j, which is connected to a cross-head, moving between upright wave. H is a vertical screw shaft passing through a screw in the cross-head, and having a button or shoulder at its lower end, which shoulder turns in a permanent block in the frame. Q is a lever moving on a fulcrum, and connected at the end by a rod, which is connected to a lever below the frame, having a weight hung on its upper end to counterbalance the weight of the ver- tical shaft of cutters and levers to relieve the screws of part of the pressure and prevent it from wear- ing. K, Fig. 1619, is a horizontal beam containing the boxes in which the upper end of the upright boxes turn, and it is provided with tennons at the ends which fit into mortises in the vertical parts of the frame and has cords attached to its ends, one of which, with a weight, pa-ses over a pulloy in the outside, and the other cord passes over another pulley and is attached to a lever Z W, moving on a ful- crum, for lowering the cross-head by lowering the said lever. 0.00 E Z D 1619. P K H When it is desired to cut a felloe, the plank from which it is to be cut is placed upon the tables and firmly secured by the dogs and clamps 1. The upright shaft is then set in motion by the friction wheels being brought in contact by the lever, and therefore the cutter shaft by the band h is set in motion. The cutters EE. are set in the cutter heads by the straps dd, 80 that one cutter shall move in a circle cutting the outside of the felloe and the other cuts the inside circle, while the cutter shaft can be raised or lowered by the lever G, to cut the required depth. The dogs and clamps can be shifted on the table for larger or smaller feiloes, and the cutters can be shifted on CCC. to correspond with the same. FELTING. The process of blending or matting different kinds of fur or wool into a compact texture. A heavy kind of fell is used as a lining to the magazines of men-of-war, between two thicknesses of wood also to cover over the steam boilers of steam-ships. An Indian-rubber felt, composed of caoutchouc and cork, is now made, but is as yet not much in use. See HAT MANUFACTURE FILES. The file is a strip or bar of steel, the surface of which is cut into fine points or teeth, that act by a species of cutting, closely allied to abrasion. Files are almost endle-s in variety; and there is some four, five, or six features in every file, to adapt the instrument to the several kinds of work for which the file is used. Most of the names of files express these different features; for instance the three following files are in common use :- 6 inch, blunt, single-cut, saw file. 9 inch, taper. smooth, half round file. 12 inch, parallel. rough, cotter file. The watchmaker frequently uses files not exceeding three-quarters of an inch in length; mathemati- 79 Digitized by Google 626 FILES. cal instrument makers and gunmakers employ files from about 4 to 14 inches long; and machinists and engineers commonly require files from about 8 to 20 inches long, and sometimes use those of two and three feet and upwards in length. Almost all files are required to be as straight as possible in their central line, and are distinguished as taper, blunt, and parallel files; a very insignificant number of files are made curvilinear in their central line, as in the rifflers used by sculptors and carvers, and some other files. Many files that are in all other respects alike, differ in the forms and sizes of their teeth. Three forms of teeth are made, those of double-cut files, those of Roats, or single-cut files, and those of rasps. The floats and rasps are scarcely used but for the woods and soft materials; the double-cut files are used for the metals and general purposes. In a double-cut file, the thousands of points or teeth occur from two series of straight chisel-cuts crossing each other in a single-cut file or float, the ridges occur from the one series of chisel-cuts, which are generally square across the float; and in a rasp the detached teeth are made by solitary indenta- tions of a pointed chisel or punch. Double-cut files are made of several gradations of coarseness, and which are thus respectively named :- 1. Rough. 1. Rough. 2. Middle-cut. 2. Bastard. 3. Bastard. 8. Second-cut. 4. Second-cut. 4. Smooth. 5. Smooth. 5. Dead-smooth. 6. Superfine. Some files have one or more edges that are left uncut, and these are known as safe-edges, because such edges are not liable to act upon those parts of the work against which they are allowed to rub, for the purpose of guiding the instrument. Occasionally the edges alone of files are cut, and the sides are left safe or smooth, as in some warding files, which nearly resemble saws. The names of files are often derived from their purposes, as in saw-files, slitting, warding, and cotter files; the names of others from their sections, as square, round, and half-round files. Fig. 1620. Sections derived from the Square. A B C D E F G II Flg. 1621. Sections derived from the Circle. I K L M N o P Q Fig. 1622. Sections derived from the Triangle. R S T V W X Y Z Files of all the sections represented in the groups, Figs. 1620 to 1622, are more or less employed, although many of them are almost restricted to particular purposes. Taper files, or taper flat files, are made of various lengths from about 4 to 24 inches, and are rectan- gular in section as in B, Fig. 1620; they are considerably rounded on their edges, and a little also in their thickness; their greatest section being towards the middle of their length or a little nearer to the handle, whence these files are technically known to be " bellied;" they are cut both on their faces and edges with teeth of four varieties; namely, rough, bastard, second-cut, and smooth-cut teeth. Taper flat files are in extremely general use amongst smiths and mechanics, for a great variety of or- dinary works. Hand files or flat files resemble the above in length, section, and teeth, but the hand files are nearly parallel in width, and somewhat less taper in thickness than the foregoing. Engineers, machinists, mathematical instrument makers, and others, give the preference to the hand file for flat surfaces and most other works. Cotter files are always narrower than hand files of the same length and thickness; they are nearly flat on the sides and edges, 80 as to present almost the same section at every part of their length, in which respect they vary from 6 to 22 inches. Cotter files are mostly used in filing grooves for the cotters, keys, or wedges used in fixing wheels on their shafts, whence their name. Pillar files also somewhat resemble the hand files, but they are much narrower, somewhat thinner, as in C, and are used for more slender purposes, or for completing works that have been commenced with the hand files. Pillar files have commonly one safe edge, and vary from 3 to 10 inches in length. Half-round files are nearly of the section L, notwithstanding that the name implies the semicircular section; in general the curvature only equals the fourth to the twelfth part of the circle. Digitized by Google FILES. 627 Triangular files are of the section R, and from 2 to 16 inches long; they are used for internal angles more acute than the rectangle, and also for clearing out square corners. Cross files, or crossing files, are of the section M, or circular on both faces, but of two different curvatures. Round files, of the section I, range from the length of 2 to 18 inches; they are in general taper, and much used for enlarging round holes. Square files measure in general from 2 to 18 inches in length, and are mostly taper. Equalling files are files of the section D. In width they are more frequently parallel than taper; in thickness they are always parallel. They are in general cut on all faces, and range from 2 to 10 inches long. Knife files are of the section T, and in general very acute on the edge, they are made from 2 to 7 inches long, and are as frequently parallel as taper. Slitting files, called also feather-edged files, resemble the last in construction and purpose, except in having, as in section V, two thin edges instead of one; they are almost always parallel. Rubbers are strong heavy files, generally made of an inferior kind of steel; they measure from 12 to 18 inches long, from 1 to 2 inches on every side, and are made very convex: they are frequently designated by their weight alone, which varies from about 4 to 15 lbs. Rubbers are nearly restricted to the square and triangular sections A and R. Some few rubbers are made nearly square in section, but with one side rounded, as if the sections K and B were united: these are called half-thick. Many artisans, and more particularly. the watchmakers, require other files than those described, and it is therefore proposed to add the names of some of the files to which the sections refer, premising that such names as are printed in Italics designate small files especially used in watchmaking. Names of some of the Files corresponding with the Sections A to Z, (represented by Figs. 1620 to 1622.) A.-Square files, both parallel and taper, some with one safe side; also square rubbers. B.-When large, cotter files; when small, verge and pivot files. C.-Hand files, parallel and flat files; when small, pottance files; when narrow, pillar files; to these nearly parallel files are to be added the taper flat files. D.-When parallel, equalling clock-pinion and endiess-screw files; when taper, slitting, entering, ward- ing, and barrel-hole files. E-French pivot and shouldering files, which are small, stout, and have safe-edges; when made of large size, and right and left, they are sometimes called parallel V files, from their suitability to the hollow V V's of machinery. F.-Name and purpose similar to the last. G.-Flat file with hollow edges, principally used as a nail file for the dressing-case. H.-Pointing mill-saw file, round-edge equalling file, and round-edge joint file; all are made both parallel and taper. I-Round file, gulleting saw file, made both parallel and taper. K-Frame saw file for gullet teeth. L-Half-round file. Nicking and piercing files, also cabinet floats and rasps; all these are usually taper. Files of this section which are small, parallel, and have the convex side uncut, and have also a pivot at the end opposite the tang, are called round-off files. M.-Cross, or crossing files, also called double half-rounds. N.-Oval files; oval gulleting files for large saws, called by the French limes à double dos. Oval-dial file when small. O.-Balance-wheel or swing-wheel files, the convex side cut, the angular sides safe. P.-Swaged files, for finishing brass mouldings; sometimes the hollow and fillets are all cut. Q-The curvilinear file. R.-Triangular, three-square, and saw files, also triangular rubbers, which are out on all sides. S.-Cant file, probably named from its suitability to filing the insides of spanners, for hexagonal and octagonal nuts, or as these are generally called, six or eight canted bolts and nuts; the cant files are cut on all sides. T.-When parallel, Aat-dovetail, banking, and watch-pinion files; when taper, knife-edge files. With the wide edge round and safe, files of the section T are known as moulding files and clock- pinion files. V.-Screw-head files, feather-edged files, clock and watch-slitting files. W.-Is sometimes used by engineers in finishing small grooves and key ways, and is called a valve file, from one of its applications. X.-A file compounded of the triangular and half-round file, and stronger than the latter; similar files with three rounded faces have also been made for engineers. Y.-Double or checkering files, used by cutlers, gunmakers, and others. The files are made separately and riveted together, with the edge of the one before that of the other, in order to give the equality of distance and parallelism of checkered works, just as in the double saws for cutting the teeth of racks and combs. Z-Double file, made of two flat files fixed together in a wood or metal stock; this was invented for filing lead pencils to a fine conical point. The manufacture of files.-The pieces of steel, or the blanks intended for files, are forged out of bars of steel that have been either tilted or rolled as nearly as possible to the sections required, 80 as to leave but little to be done at the forge; the blanks are afterwards annealed with great caution, so that in neither of the processes the temperature known as the blood-red heat may be exceeded. The surfaces of the blanks are now rendered accurate in form and quite clean in surface either by filing Digitized by Google 628 FILES. or grinding. For the smaller files the blanks are mostly filed into shape as the more exact method for the larger, the blanks are more commonly ground on large grindstones as the more expeditious method; in some few cases the blanks are planed in the planing machine, for those called dead-parallel files. The blank before being cut is slightly greased, that the chisel may slip freely over it. The file-cutter is seated before a square stake or anvil, and places the blank straight before him, with the tang towards his person; the ends of the blank are fixed down by two leather straps or loops, one of which is held fast by each foot. The largest and smallest chisels commonly used in cutting files are represented in two views; and half size in Figs. 1623 and 1624. The first is a chisel for large rough files; the length is about 3 inches, the width 21 inches, and the angle of the edge about 50 degrees; the edge is perfectly straight, but the one bevel is a little more inclined than the other. and the keenness of the edge is rounded off, the object being to indent, rather than cut the steel this chisel requires a hammer of about 7 or 8 lbs. weight. Fig. 1624 is the chisel used for small superfine files its length is 2 inches. the width 1 inch; 1623. 1624. 1395. " a b 1626. it is very thin, and sharpened at about the angle of 35 degrees; the edge is also rounded, but in a smaller degree it is used with a hammer weighing only one to two ounces, as it will be seen the weight of the blow mainly determines the distance between the teeth. Other chisels are made of intermediate proportions, but the width of the edge always exceeds that of the file to be cut. The first cut is made at the point of the file; the chisel is held in the left hand, at a horizontal angle of about 55 degrees, with the central line of the file, as at aa, Fig. 1625, and with a vertical inclina- tion of about 12 to 4 degrees from the perpendicular, as represented in the figures 1623 and 1624, supposing the tang of the file to be on the left-hand side. The following are nearly the usual angles for the vertical inclination of the chisels; namely, for rough rasps, 15 degrees beyond the perpendicular; rough files, 12 degrees; bastard files, 10 degree second-cut files, 7 degrees; smooth-cut files, 5 de- grees: and dead-smooth-cut files, 4 degrees. The blow of the hammer upon the chisel causes the latter to indent and slightly to drive forward the steel, thereby throwing up a trifling ridge or burr; the chisel is immediately replaced on the blank, and slid from the operator until it encounters the ridge previously thrown up, which arrests the chisel or prevents it from slipping further back, and thereby determines the succeeding position of the chisel. The chisel having been placed in its second position is again struck with the hammer, which is made to give the blows as nearly as possible of uniform strength; and the process is repeated with considerable rapidity and regularity, 60 to 80 cuts being made in one minute, until the entire length of the file has been cut with inclined, parallel, and equidistant ridges, which are collectively denominated the first course. So far as this one face is concerned, the file, if intended to be single-cut, would be then ready for hardening; and when greatly enlarged, its section would be somewh.it as in Fig. 1626. The teeth of some single cut files are much less inclined than 55 degrees; those of floats are in general square across the instrument. Most files, however, are double cut, or have two series or courses of chisel cuta, and for these the surface of the file is now smoothed by passing a smooth file once or twice along the face of the teeth. to remove only 80 much of the roughness as would obstruct the chisel from aliding along the face in receiving its successive positions, and the file is again greased. The second course of teeth is now cut, the chisel being inclined vertically as before, or at about 12 degrees, but horizontally, about 5 to 10 degrees from the rectangle, as at bb, Fig. 1625; the blows are now given a little less strongly. 80 as barely to penetrate to the bottom of the first cuts, and consequently the second course of cuts is somewhat finer than the first. The two series of courses fill the surface of the file with teeth which are inclined towards the point of the file. and that when highly magnified much resemble in character the points of cutting tools generally, as seen in Fig. 1626. If the file is flat and to be cut on two faces, it is now turned over; but to protect the teeth from the hard face of the anvil, a thin plate of pewter is interposed. Triangular and other file< require blocks of lead having grooves of the appropriate sections to support the blanks, 80 that the surface to be cut may be placed horizontally. Taper files require the teeth to be somewhat finer towards the point, to avoid the ri k of the blank being weakened or broken in the act of its being cut, which might occur if as much force were used in cutting the teeth at the point of the file, as in those at its central and stronger pa:t Eight courses of cuts are required to complete a double cut rectangular file that is cut on all faces, but eight, ten, or even more courses are required in cutting only the une rounded face of a half-round Digitized by Google FILES. 629 file. There are various objections to employing chisels with concave edges, and therefore in cutting round and half-round files the ordinary straight chisel is used and applied as a tangent to the curve. It will be found that in a smooth half-round file one inch in width, that about twenty courses are required for the convex side, and two courses alone serve for the flat side. In some of the double-cut gullet- tooth saw files, of the section K, as many as twenty-three courses are sometimes used for the convex face, and but two for the flat. The same difficulty occurs in a round file, and the surfaces of curvilinear files do not therefore present, under ordinary circumstances, the same uniformity as those of flat files. Hollowed files are rarely used in the arts, and when required it usually becomes imperative to employ a round-edged chisel, and to cut the file with a single course of teeth. The teeth of rasps are cut with a punch, which is represented in two views, Fig. 1627. The punch for a fine cabinet rasp is about 31 inches long, 1627. and 1 square at its widest part. Viewed in front, the two sides of the point meet at an angle of about 60 degrees viewed edgeways, or in profile, the edge forms an angle of about 50 degrees, the one-face being only a little inclined to the body of the tool. In cutting rasps, the punch is sloped rather more from the operator than the chisel in cutting files, but the distance between the teeth of the rasp cannot be determined as in the file, by placing the punch in contact with the burr of the tooth previously made. By dint of habit, the workman moves or, technically, hops the punch the required distance; to facilitate this movement, he places a piece of woollen cloth under his left hand, which pre- vents his hand coming immediately in contact with, and adhering to the anvil. The teeth of rasps are cut in rather an arbitrary manner, and to suit the whims rather than the necessities of the workmen who use them. Thus the lines of teeth in cabinet rasps, wood rasps, and farriers' rasps, are cut in lines sloping from the left down to the right hand side; the teeth of rasps for boot and shoe last makers and some others, are sloped the reverse way; and rasps for gun-stockers and saddle-tree makers are cut in circular lines or crescent form. These directions are quite immaterial; but it is important that every succeeding tooth should cross its predecessor, or be intermediate to the two before it; as if the teeth followed one another in right lines, they would produce furrows in the work, and not comparatively smooth surfaces. In cutting files and rasps they almost always become more or less bent, and there would be danger of breaking them if they were set straight whilst cold; they are consequently straightened whilst they are at the red heat, immediately prior to their being hardened and tempered. Previously to their being hardened, the files are drawn through beer grounds, yeast, or other sticky matter, and then through common salt, mixed with cow's hoof previously roasted and pounded, and which serve as a defence to protect the delicate teeth of the file from the direct action of the fire. The compound likewise serves as an index of the temperature, as on the fusion of the salt, the hardening heat is attained the defence also lessens the disposition of the files to crack: or clink on being immersed in the water. The file, after having been smeared over as above, is gradually heated to a dull red, and is then mostly straightened with a leaden hammer on two small blocks also of lead; the temperature of the file is afterwards increased until the salt on its surface just fuses, when the file is immediately dipped in water. The file is immersed, quickly or slowly, vertically or obliquely, according to its form; that mode being adopted for each variety of file which is considered best calculated to keep it straight. It is well-known that from the unsymmetrical section of the half-round file, it is disposed, on being immersed, to become hollow or bowed on the convex side, and this tendency is compensated for by curving the file whilst soft in a nearly equal degree in the reverse direction. It nevertheless commonly happens, that with every precaution the file becomes more or less bent in hardening. and if so, it is straightened by pressure, either before it is quite cold, or else after it has been partially reheated. The pressure is variously applied, sometimes by passing one end of the file under a hook, supporting the centre on a prop of lead, and bearing down the opposite end of the file; at other times by using a support at each end, and applying pressure in the middle, by means of a lever, the end of which is hooked to the bench. Large files are always straightened before they are quite cooled after the hardening, and whilst the central part retains a considerable degree of heat. When straightened, the file is cooled in oil, which saves the teeth from becoming rusty. The tangs are now softened to prevent their fracture; this is done either by grasping the tang in a pair of heated tongs, or by means of a bath of lead contained in an iron vessel with a perforated cover, through the holes in which the tangs are immereed in the melted lead that is heated to the proper degree. The tang is afterwards cooled in oil, and when the file has been wiped and the teeth brushed clean, it is considered fit for use. The superiority of the file will be found to depend on four points,-the primary excellence of the steel-the proper forging and annealing without excess of heat-the correct formation of the teeth-and the success of the hardening. Means of grasping the file.-In general. the end of the file is forged simply into a taper tang or spike, for the purpose of fixing it in its wooden handle, but wide files require that the tang should be reduced in width, either as in Fig. 1628 or 1629. The former mode, especially in large files, is apt to cripple the steel and dispose the tang to break off, after which the file is nearly useless. The curvilinear tang, Fig. 1629, is far less open to this objection. Some workmen make the tangs of large files red-hot, that they may burn their own recesses in the handles, but this is objectionable, as the charred wood is apt to crumble away and release the file. It is more proper to form the cavity in the handle with coarse floats made for the purpose. Digitized by Google 630 FILES. In driving large files into their handles it is usual to place the point of the file in the hollow behind the chaps of the tail vice, and to drive on the handle with a mallet or hammer. Smaller files are fixed obliquely in the jaws of the vice, between clamps of sheet brass, to prevent the teeth either of the vice or file from being injured, and the handle is then driven on. In the double-ended rifflers, or bent files, Fig. 1630, and in some other files, there is a plain part in the middle, fulfilling the office of a handle; and in several of the files and rasps made for dentists, farriers, and shoemakers, the tool is also double, but without any intermediate plain part, so that the one end serves as the handle for the other. 1631. 1628. 1632. 1629. 1633 1630. 1634. In general, the length of the file exceeds that of the object filed, but in filing-large surfaces it becomes ecasionally necessary to attach cranked handles to the large files or rubbers, as in Fig. 1631, in order to raise the hand above the plane of the work. Sometimes the end of the file is simply inclined, as in Fig. 1632, or bent at right angles, as in Fig. 1633, for the attachment of the wooden handles represented; but the last two modes prevent the second side of the file from being used, until the tang is bent the reverse way. The necessity for bending the file is avoided by employing as a handle a piece of round iron, I or } inch in diameter, bent into the semicircular form as an arch, the one extremity (or abutment) of which is filed with a taper groove to fit the tang of the file, whilst the opposite end is flat, and rests upon the teeth; in this manner both sides of the file may be used without any preparation. Fig. 1684 represents, in profile, a broad and short rasp with fine teeth, used by iron-founders in smoothing off loam moulds for iron castings; this is mostly used on large surfaces, to which the ordinary handle would be inapplicable, and the same kind of tool when made with coarser teeth, will be recog- mised as the baker's rasp. Cabinet-makers sometimes fix the file to a block of wood to serve for the grasp, and use it as a plane. Thns mounted. the file may also be very conveniently used on a shooting-board, in filing the edges of plates to be inlaid. 1635. 0 b a 0 c, © o 0 d c Fig. 1635 represents a very good arrangement of this kind. a a is the plan, and b the section of the file stock, cc is the plan of the shooting-board, and d its section. Two files (that are represented black) are screwed against the sides of a straight bar of wood, which has also a wooden sole or bottom plate, that projects beyond the files, so that the smooth edge of the sole may touch the shooting-board instead of the file teeth. The shooting-board is made in three pieces, so as to form a groove to receive the file dust, which would otherwise get under the stock of the file. The shooting-board has also a wooden stop 8, faced with steel, that is wedged and screwed into a groove made across the top piece, and the stop being exactly at right angles, serves also to assist in squaring the edges of plates or the ends of long bars, with accuracy and expedition. Short pieces of files (or tools as nearly allied to sawa) are occasionally fixed in the ends of wooden Digitized by Google FILES. 631 stocks, in all other respects like the routing gages of carpenters, as seen in two views in Fig. 1636. The coopers' croze is a tool of this description. Files intended for finishing the grooves in the edges of slides, are sometimes made of short pieces of steel of the proper section, (see Fig. 1637,) cut on the surfaces with file teeth, and attached in various ways to slender rods or wires, serving as the handles, and extending beyond the ends of the slides: or the handle is at right angles to the file, and formed at the end, as a staple, to clip the ends of the short file, as in reaching the bottom of a cavity. Files intended to reach to the bottom of shallow cavities are also constructed as in Figs. 1638 and 1639, or sometimes an inch or more of the end of an ordinary file is bent some 20 or 80 degrees, that the remainder may clear the margin of the recess. 1638. 1639. 1636. 1640. 1641 W 1642. 1637. To stiffen slender files, they are occasionally made with tin or brass backs, as in Figs. 1640 and 1641 such are called dovetail files; and thin equalling files are sometimes grasped in a brass frame, Fig. 1642, exactly like that used for a metal frame-saw. Notwithstanding the great diversity in the files already alluded to, it is to be remarked that all those hitherto noticed are made entirely of steel, and their teeth are all produced in the ordinary manner by means of the chisel and hand hammer. It now remains to notice a few of the less usual kinds of rasps, floats, and files, the teeth of which are, for the most part, produced by means differing from those already described. The rifflers, Fig. 1630, used by sculptors, are required to be of numerous curvatures, to adapt them to the varying contour of works in marble. In general the rifflers are made of steel in the ordinary mode, but they have also been made of wrought-iron, and slightly case-hardened, in which case the points of the teeth become converted into steel, but the general bulk of the instrument remains in its original state as soft iron consequently such case-hardened rifflers admit of being bent upon a block of lead with a leaden mallet, so that the artist-is enabled to modify their curvatures as circumstances may require. Several kinds of floats are made with coarse, shallow, and sharp teeth; these teeth could not be cut with the chisel and hammer in the ordinary manner, but are made with a triangular file. Figs. a to 1, 1648, represent the sections of several of these floats, which have teeth at the parts indicated by the double lines; for instance, a is the float, b the graille, c the found, d the carlet, e the topper, used by the born and tortoiseshell comb-makers. The floats f to i are used by ivory carvers for the handles of knives, and in the preparation of works, the carving of which is to be completed by scorpers and gravers; k and l are used in inlaying tools in their handles; k is made of various widths, and is generally thin, long, and taper; 1 is more like a key-hole saw. 1643. 1644. a b c e 6 1645. 0 0 Q © 1646. f i l The larger of the floats, such as those a to e, used by the comb-makers, are kept in order principally by the aid of a burnisher, represented in two views in Fig. 1644; the blade is about 2 inches long, 1 inch wide, and 1-16th thick; the end is mostly used, and which is forcibly rubbed, first on the front edge of every tooth, as at a, Fig. 1645, and then on the back, as at b, by which means a slight burr is thrown up on every tooth, somewhat like that on the joiner's scraper; but in this art the burnisher is commonly named a turn file. Digitized by Google 632 FILE AND RASP MACHINE. The quannet is a float resembling Fig. 1634, but having coarse filed teeth, of the kind just described; it may be considered as the ordinary flat file of the horn and tortoiseshell comb-makers, and in using the quannet, the work is mostly laid upon the knee as a support. An ingenious artisan in this branch, Mr. Michael Kelly, invented the quannet represented in Figs. 1645 and 1646. The stock consists of a piece of beach-wood, in which, at intervals of about one-quarter of an inch, cuts inclined nearly 30 degrees with the face, are made with a thin saw; every cut is filed with a piece of saw-plate. The edges of the plates and wood are originally filed into the regular float-like form, and the burnisher is subsequently resorted to as usual. The main advantage results from the small quantity of steel it is necessary to operate upon, when the instrument requires to be restored with the file. From this cir- cumstance, and also from its less weight, the wooden quannet, Fig. 1645, is made of nearly twice the width of the steel instrument, Fig. 1634, and the face is slightly rounded, the teeth being sometimes inserted square across, as in a float, at other times inclined some 30 degrees, as in R single-cut file. The cutting of files by machinery.-The practical introduction of machinery for cutting files appears to be due to a Frenchman of the name of Raoul, at about the close of the last century, but the descrip- tion of the machine has not been published, and the manufacture is now carried on by his son. His files are beautiful specimens of workmanship, being more strictly regular, and also less liable to clog or pin when in use, than files cut by hand, as usual. His manufacture is principally limited to watch files with flat sides, and measuring from I of an inch to 5 or 6 inches long. Machines have been recently constructed in England for cutting both large and small files, and half a dozen or more at a time. The details of the machines display great ingenuity and skill, but there are various drawbacks that prevent, under ordinary circumstances, any great commercial advantage in the machine over the hand process, from which considerations the patent file-cutting machines are not at present used. We give drawings and a description of a recently invented file machine, patented in 1847 by George Winslow, of Boston. We know not how far it has been successful, but it is well worthy of notice as an example of ingenious combinations, and to illustrate what has been done in this department of mechanism. FILE AND RASP MACHINE Fig. 1647 represents a plan view of this apparatus or machinery, as laid down by the patentee, in the drawing attached to the specification; and Fig. 1648 is a side ele- vation of the same. It consists of a rectangular framework a a, which may be of wood or other suita- ble material; stretched across this framework is a plate b, on which are two levers a' a', disposed on either side of the machine and moving on fulcra a" a""; the long ends of these levers are connected to a sort of toggle d', by means of the straps c', and the short ends are connected by links to the blocks or chisel-holders dd; the chisel-holders move on the plate b, and are guided by the brackets eeee, and though constrained to move in a particular direction, are free to turn round, 80 that the chisels ff may be adjusted to any angle at which it may be required to form the indentations or teeth on the blank g. This is supported between two poppets hh, the one receiving the shank or tang in a socket, in which it is secured by binding screws, and the other is supported by a centre, received by an indentation made in the end of the blank. It will be observed that a tooth on each side of the blank is produced at the same time, the pressure of one chisel sustaining the opposing force of the other, the poppets h h being 80 fitted to their support j as to admit of a movement in a transverse direction, to allow for any inequality in the surface of the blank i is a slide, which is fitted between dovetailed grooves, so as to admit of sliding in a longitudinal direction. This slide forms the immediate support for the blank, and is strength- ened by an arch-piece p', as seen at Fig. 1648. This slide is caused to travel by means of a screw i, which passes through a nut attached to the bottom of the slide. A plate b' is fitted on two longitudi- nal slides 'n'. This plate receives a reciprocating motion from the main driving-shaft, through the intervention of the connecting-rod a", and upright lever p. The driving-shaft is furnished with a disk or plate x, having a radial slot cut therein, in which the crank pin can be adjusted, 80 as to vary the throw, and consequently the motion of the connecting-rod a". This rod is also adjustable in the verti- cal lever p, so as to bring the connection nearer to, or further from, the fulcrum on which it moves. Each movement of this sliding plate b' produces a closing of the cutters ff, by reason of the movement of the toggles d' d', which are mounted on the plate b', and thus raise a tooth by forming an indenta- tion in the blank. Now in cutting files by this machine, it is necessary to begin the cut at the point or thinnest part of the file, when the greatest range of movement is given to the plate b'; and as the cutting proceeds to- wards the thick part of the blank, the movement of the plate b' must decrease, imparting less move- ment to the levers a' a'; and consequently the cutters will not be brought 80 close together; but in re- ducing this movement of the plate, the angle formed by the levers c' c' will be less, and consequently their power will decrease also, but which is compensated for by an apparatus hereafter explained. As the cutters always close at the same point, it is necessary that the blank should move a sufficient dis- tance at each closing thereof to allow for the formation of another tooth; this is effected by partially turning the screw i which moves the carriage or slide j, which is performed as follows: A spur-wheel k is mounted on the end of the screw i which projects through the bearing; this is not fixed to the screw, but is allowed to revolve freely thereon, and is furnished with a click pivoted to the side thereof; this takes into a ratchet affixed to the screw, and therefore as the wheel is turned in one direction it will carry the screw round with it, but on a reverse motion taking place the click will slip the teeth of the ratchet; the screw i at the same time remaining stationary. The wheel k has this mo- tion communicated to it by means of a vertical rack-bar l', being connected by a rod c" to a bell-crank b", the pendent arm of which is moved by contact of a pin placed in the connecting-rod a", the reaction heing produced by the weight of the rack-bar. the rise and fall of which may be varied by moving the position of the pin in the rod a"; thus may the number of indentations produced to a given length of the blank be regulated according to the requisite degree of fineness of the file. Digitized by Google FILE AND RASP MACHINE. 633 The upper end of the rack-bar is connected by a rod m' to the hand lever h', which oscillates on a fixed fulcrum at k'; this arrangement being for the withdrawal of the teeth of the rack-bar, and thereby stop the movement of the screw i; but the movement of the hand lever h' at the same time withdraws the clutch q' from the fly-wheel, and therefore stopping simultaneously the entire action of the ma- chine. The hand lever h' is connected by the rod 8' to the clutch lever r'; this lever is also connected by a rod l' to a spring inside the framework, which maintains a permanent pull to withdraw the clutch, but which is counteracted by a catch on the end of a lever g'; this retains the lever h' in a position for work, which may be released by hand at pleasure, or the lever g' is tripped up by a projection x' on the under side of the slide j; at the completion of the teeth, this throws the restraint from the lever h', and the machine stops. A spur-wheel 1 is mounted on the screw i, which geers into another wheel m, placed on a longitudinal shaft n; this is turned by a hand-wheel o, and is for the purpose of working the slide j back, or otherwise adjusting its position before commencing the cut. 1647. d d D of 0 P F 9 T g o m all $ $ s <<<<<<<04 00 2 It will be seen by the general arrangement of the geer for moving the slide b', that if the fulcrum on which the vertical lever p moves were stationary, the space traversed by b' would be the same, but to allow it to recede as the thickness of the file increases, the lower end of the lever p is jointed to a bent lever p", attached to a horizontal bar q"; this is fitted in bearings, so as to be capable of movement in a longitudinal direction, but restrained by the cord 26" with a certain amount of force, which when over- come by the force required for the cutters ff, the har q" recedes and is retained by a catch f" falling into the teeth on the end of the said bar; by a complication of levers not seen in the cuts, this catch is raised at each revolution of the disk x, a pin fixed thereto actuating the levers before mentioned. The cord u" is wound on a drum placed on the same shaft as the plate t", and cam v"; this cam has a groove on its periphery, over which a cord c" passes while the cutting is in progress; the cord being attached at one end to the smallest part of the cam v", is carried thence, and wound on a drum 8", from 80 Digitized by Google 634 FILE AND RASP MACHINE. the opposite side, while another cord r" supports the lever u, on which hangs the weight v. The force of this weight is therefore brought to bear on the cam x", with the requisite degree of force to give the necessary tension to the cord w'; the cord c", as it is gradually wound on the cam, gives, by reason of the leverage thereof, a greater amount of tension to the cord u", in order to compensate for the loss of power of the progressive levers c' c', as their range of movement is removed nearer the end of the machine. As a further compensation for this loss of power, the weight v, which is hung on the lever и, is grad- ually moved further from the fulcrum on which one end of this lever is supported, thus increasing the weight on the cord r" which supports the other end thereof; this is arranged as follows a bar t placed side by side of the lever u is fitted in slots, cut in the framing 80 as to move in a longitudinal direction, and is furnished with a sliding piece so, which can be in any position; this piece w has a projection which takes the suspending rod of the weight v, 80 that any movement imparted to the bar t is trans- mitted to the weight. A vertical lever h" is pivoted to a fulcrum fixed to the framing; the lower end of this lever is again connected to a horizontal lever (not seen in the cuts) in such manner as to multi- ply the movement which is communicated to the bar t. The upper or driving end of the lever h" is 1648. a = :~ b a r is a. F 8 8 X' furnished with a pawl g". pivoted about the middle of its length; one end of the lever falls into the teeth of a rack v', affixed to the sliding carriage j, and the other has a stud pin which traverses an irregular slot or guide l", k", i''; the motion imparted to the slide j is thus communicated by the pawl g" to the lever h", thence to the weight v, altering the position thereof gradually as the cutting progresses. This motion will continue so long as the stud pin of the pawl g" continues to traverse the horizontal portion of the guide from i" to k", which will occupy the time necessary for cutting the tapered part of the file, at the completion of which the stud pin will pass down the incline from k" to l", canting the other end of the pawl g", consequently withdrawing it from the rack, and preventing any further movement of the weight on the lever 24, the cutters ff advancing within a uniform distance of each other after Digitized by Google FILING. 635 that point. Two bearings are raised from the plate be which support a shaft f'; this is furnished with two screws, one being what is termed a right and the other a left hand thread, corresponding with screws in the toggles d' d' these are adjusted by the hand-wheel on the end of the shaft 80 as to suit the thickness of the first cut, commencing at the thinnest part of the blank g. This screw shaft is con- tinued beyond the bearing at the opposite end from the hand-wheel, and furnished with a ratchet-wheel q; this is brought into action as the plate t" and cam are gradually turned round, it being connected thereto by a spring s which depresses one end of a lever r, supported by the framing, the other end car- rying a pawl, which, when sufficiently elevated by the action of the machine, will be brought into con- tact with the ratchet q, as it traverses backwards and forwards with the plate b', at each movement causing the ratchet to turn one tooth, thereby actuating the toggles d' d' in the requisite manner to form an additional compensation for the loss of power before mentioned in maintaining the requisite amount of advance of the cutters. The patentee claims, first, the general arrangement of machinery or apparatus whereby the teeth of a file or rasp may be cut with great regularity, and on both sides of the said blank at one and the same time. Secondly, the combination of the cam with this machine, together with the increasing power of the weight for the purpose of keeping up a compensatory power for the loss occasioned by the decreas- ing obtuse angle formed by the progressive levers c' c', as the range of their advancing movement is restricted. FILING. The use of the file is more difficult than that of the generality of mechanical tools, from the circumstance of the file possessing, in a very inferior degree, the guide principle, the influence of which principle, affects all tools, from the most simple cutting tool used by hand, to the most complex outting machine or engine. Commencing with the position of the work, it is in all cases desirable that the surface to be filed should be placed horizontally, and the general rule for the height of the work above the ground is, that the surface to be filed should be nearly level with the elbow joint of the workman. Some latitude is, however, required in respect to the magnitude of the works, as when they are massive, and much is to be filed off from them, it IS desirable that the work should be a trifle lower than the elbow when the work is minute and delicate, it should be somewhat higher, so that the eye may be the better able to add its scrutiny to that of the sense of feeling of the hand, upon which, principally, the successful prac- tice depends. It is apparent that the most direct way of producing a flat surface with the file, would be to select a file the face of which was absolutely flat, and that should be moved in lines absolutely straight; but there are certain interferences that prevent these conditions being carried out. First, although it is de- sirable to employ files that are as nearly straight as possible, and that are also fixed straightly in their handles, yet very few files possess this exactitude of form, and although in the attempt to obtain this perfection, some files are planed before being cut with teeth, still the cutting and the hardening 80 far invalidate this practice, that few even of these planed files can retain their perfect straightness. There- fore, as it may be almost taken for granted that no files truly possess the intended form, it is better purposely to adopt that kind of irregularity, which the least interferes with the general use of the in- strument. z 1649. 1651. 1652. 1650. 1653. The file, if concave or hollow in respect to its length, in the manner coarsely exaggerated in Fig. 1649, might be used for works of corresponding convexity; but it would be impossible to file a flat surface therewith, as the concave file would only touch the surface at its edges, but the convex side of the same file might, as in Fig. 1650, be made to touch any and every part of the surface if moved in a right line. On this account most files are made thicker and wider in the middle, or with both faces convex, and the error of hardening will then rarely make either side concave, but will leave both faces convex, although differently so; and consequently, both sides, notwithstanding some irregularity, are usable upon flat works, provided the operator can move them in a right line across the work. It might be urged that the file, from being itself in the form of the are of a large circle, would reduce the work to the counterpart form; it is true this is the tendency, and may by dexterity become the result, even on narrow pieces; but the contrary error is more common, 80 that the surface of the work becomes rounded instead of concave or plane. The file held in the two hands upon the narrow work, may be viewed as a double-ended lever, or as a scale-beam supported on a prop; and the variation in distance of the hands from the work or prop gives a disposition to rotate the file upon the work, and which is only counteracted by habit or ex- perience. Assuming, for the moment, that in the three diagrams the vertical pressure of the right hand at r, and the left at 1, to be in all cases alike, in Fig. 1651, or the beginning of the stroke, the right hand would, from acting at the longer end of the lever, become depressed; in Fig. 1652, or the central posi- tion, the hands would be in equilibrium and the file horizontal and in Fig. 1653, or the end of the stroke, Digitized by Google 636 FILING. the left hand would preponderate; the three positions would inevitably make the work round, in place of leaving it plane or flat. It in true the diagrams are extravagant, but this rolling action of the file upon the work is in most cases to be observed in the beginner; and those practised in the use of the file have, perhaps uncon- sciously, acquired the habit of pressing down only with the left hand at the commencement, and only with the right hand at the conclusion of every stroke; or negatively, that they have learned to avoid swaying down the file at either extreme, and which bad practice will necessarily result, if the operator have not at first a constant watch upon himself, to feel that the file and work are always in true con- tact, throughout the variable action of the hands upon the instrument. The work, when small, is almost invariably held on the filing-block with the left hand, occasionally through the intervention of a hand-vice, Fig. 1657. In this case the two hands act in concert, the right in moving the file, the left in adjusting the position of the work, until the individual is conscious of the agreement in position of the two parts. 1654. 1655. 1656. TO Sometimes indeed the partial rotation of the work, in order to adapt the work to the file, is especially provided for, so as to compensate for the accidental swaying of the file; such is the case in the various kinds of swing tools, used by watchmakers in filing and polishing small flat works. A similar end is more rarely obtained, on a larger scale, when the file is required to be held in both hands. For example, filing-boards resembling Fig. 1654, and upon which the work is placed, have been made to move on two pivots, somewhat as a gun moves on its trunnions; consequently the works, when laid upon the swinging board, assume the same angle as that at which the file may at the moment be held. A more common case is to be seen in filing a rectangular mortise, through a cylindrical spindle, as in Fig. 1655; the hole is commenced by drilling three or four holes, which are thrown into one by a cross- cut chisel, or small round file; and the work, when nearly completed, is suspended between the centres of the lathe, 80 that it may freely assume the inclination of the file. At other times, the cylinder is laid in the interval between the edges of the jaws of the vice, that are opened as much as two-thirds the dinmeter of the object, which then similarly rotates on the supporting edges; this mode is shown in Fig. 1656. These three applications are objectionable in some instances, as the file is left too much at liberty, and the works are liable to be filed hollow instead of flat. especially if the file be rounding, because the unstable position of the work prevents the file from being constrained to act on any particular spot that may require to be reduced. After a file has been used for wrought-iron or steel, it is less adapted to filing cast-iron or brass, which require keen files; therefore to economize the wear of the instrument. it is used for a time on brass or cast-iron, and when partially worn, it is still available for filing wrought-iron or steel; whereas, had the file been first used on these harder materials, it would have been found comparatively ineffective for brass and cast-iron. As a further measure of economy, the pressure on the file should be always relieved in the back stroke, which otherwise only tends to wear down or break off the tops of the teeth. as their formation shows that they can only cut in the ordinary or advancing stroke; the file should, in consequence, be nearly lifted from the work in drawing it back, but it is not usual actually to raise the file off the work, as it then becomes needful to wait an instant before the next stroke, to ensure the true position of the file upon the work being resumed; whereas, if it is brought back with inconsiderable pressure, the file is not injured, and the hand still retains the consciousness of the true contact of the file and work, with- out which the instrument is used with far less decision and correctness than it otherwise would be. Some workmen smooth the work by the method called draw-filing, or by drawing the file sideways along the work. using it in fact as a spoke-shave instead of a file. Another mode sometimes employed is to curl the work with the file, by describing small circles with the instrument as in grinding or pol- ishing, but neither of these practices employs the file teeth in the mode in which they are legitimately adapted to cut, and no great reliance should be placed upon them. When smooth surfaces are required, it is better, as the work advances towards completion, to select files that are gradually finer, but always to use them from point to heel. When it is desired to make the smooth files cut wrought-iron, steel, and other fibrous metals very smoothly, the file is used with a little oil to lubricate the surface, 80 that it may not penetrate to the same degree as it would if used dry. The particles removed from the materials operated upon, are always more or less liable to clog the file, but which, particularly when the instrument is dry. are partially removed by giving the edge of the file a moderately smart blow on the chaps of the vice or the edge of the bench; but particles of wrought- iron, steel, and other fibrous metals, are apt to pin the file, or to stick in so hard as to require to be picked out with a pointed steel wire, which is run through the furrow in which the pin is situated. Files are sometimes cleaned with a scratch-brush. which is a cylindrical bundle of fine steel or brass wire, bound tightly in its central part, but allowing the ends of the wire to protrude at both extremities as a stiff brush. Occasionally also, a scraper is used, or a long strip of sheet brass, about an inch wide, a small portion of the end of which is turned down at right angles, and thinned with a hammer; the thin edge is then drawn forcibly through the oblique furrows of the file, and serves as a rake to remove any particles of metal that lodge therein. Digitized by Google FILING. 637 But the best and most rapid mode of cleaning the file, is to nail to a piece of wood about two inches wide, a strip of the so-called cotton card, which constitutes a most effective brush, and answers the pur- pose exceedingly well. Some workmen, to lessen the disposition of the file to hold the file dust, or become pinny, rub it over with chalk; this absorbs any oil or grease that may be on the file, and in a considerable degree fulfils the end desired. To remove wood-dust from files, floats, and rasps, some persons dip them for a few moments into hot water, and then brush them with a stiff brush. This plan, although effective, is neither general nor important. The principal methods of fixing works. in order to subject them to the action of the file, will be no- ticed under the heads, Vice, Tail-vice, and Vice-bench. However, many of the massive parts of machi- nery are 80 heavy, that gravity alone is sufficient to keep them steady under the action of the file, and for such as these, it is therefore only needed to prop them up in any convenient manner. A great number of small works are more conveniently filed, whilst they are held with the left hand, the tile being then managed exclusively with the right; this enables the artisan more easily to judge of the position of the tile. In such cases, a piece of wood f, Fig. 1657, called a filing-block, is fixed in the table or tail-vice. Pieces that are sufficiently long and bulky, are held upon the filing-block by the hand unassistedly: but small and short works are more usually fixed in some description of hand-vice, and applied in the position shown in Fig. 1657, and the vice being larger than the work, serves as a handle, and affords a better grasp. For works of larger size the hand-vices are progressively larger, as in Fige. 1658 and 1659; some of them have wooden handles. Almost all the hand-vices have fly nuts to be twisted with the fingers, but the most powerful, which sometimes weigh as much as about three pounds, have square nuts that are fastened by a key or spanner 8. Hand-vices are not, however, in all cases employed; but small wires and other pieces are also held in a species of pliers, Fig. 1660. called pin-tongs, or sliding-tongs, which are closed by a ferule that is drawn down the stem. Fig. 1661 shows another variety of this kind, that has no joint, but springs open by elasticity alone when the ring r is drawn back. 1657. 1658. 1659. 1660. 1661. r The small pin-vice, Fig. 1657, is used by watchmakers in filinz up small pinz and other cylin !rical objects; the jaws are not united by a joint, but are formed in one piece with the stem of the vice, the end that constitutes the jaw being divided or forked; the screw an I stem are e ich perforated thro ugh- out. that the en Is of long wires may be file 1: all I the stem is octang dar that the pin-vice may be readily twis'ed to and fro. This is more usuil in the D BITTOW vices, Fig. 1658, known as dog-nose or pig- more hand-vices, then in those with wi le or cross chaps. Figs. 1637 and 1659. Many circular works that were formerly thus filed, are now, from motives of expedition and accu- racv. more commonly execute I in the turning-lathe, since the great extension in the use of this mit- chine. which has become nearly as general a: the vice or the file itself; but frequent occasions still remain in which the hand vice an 1 file are thus employed. In the pin-tong³. Fig 1681, besi les the facility of turning the instrument round with the fingers, from the rever-e end having a cen're and pullev, the same spring tongs serve conveniently no forceps for holding small drills to be worke.l with the drill-bow and also for other purpo e' in watch work. Numerous flat works are ton large, thin. and irregular in their superᶜcie+ to admit of being fixed in the various kinds of bench-vice: as there would be risk of bending such thin pieces by the pressure of the vice applied against the edges of the work. The largest flat works are simply laid on the naked surface of the work-bench, and temporarily Digitized by Google 638 FILING. held by half a dozen or more pins or nails driven into the bench. The pins should be as close to the margin as possible, and yet below the surface of the work. For thin flat works of smaller size, the filing-board, Fig. 1662, is a convenient appendage; it measures six or eight inches square, and has a stout rib on the under side, by which it is fixed in the vice. In filing thin flat works, such as the thin handles or scales of penknives and razors, and the this steel plates used in pocket-knives, cutlers generally resort to the contrivance represented in Fig. 1663, and known as a patting-vice. 1662. 1063. One face of the small filing-block f, Fig. 1657, is also used for very small thin works, and which are prevented slipping from the file by the wooden ledge, or by pins driven in. In many instances, also, thin works are held upon a piece of cork, beneath which is glued a square piece of wood, that the cork may be held in the vice without being compressed. The elasticity of the cork allows the work to become somewhat imbedded by the pressure of the file, between which and the surface-friction it is sufficiently secured for the purpose without pins. Before any effective progress can be made in filing flat works, the operator must be provided with the means of testing the progressive advance of the work; he should therefore possess a true straight- edge and a true surface-plate. The straight-edges used by smiths are generally of steel, and although they have sometimes a nearly acute edge, it is much more usual to give them moderate width thus, in steel straight-edges from one to four feet in length, the width of the edge is from one-sixteenth to one- fourth of an inch, and in cast-iron straight-edges from six to nine feet in length, the width is usually two to three inches. The straight-edge is used for trying the surface that is under correction, along its four margins, across its two diagonals, and at various intermediate parts, which respective lines, if all exact, denote the surface to be correct; but the straight-edge alone is a tedious and scarcely sufficient test, and when great accuracy is desired, it is almost imperative to have at least one very exact plane metallic surface or surface plate, by which the general condition of the surface under formation may be more quickly and accurately tested at one operation; and to avoid confusion of terms, it is proposed in all cases, when speaking of the instrument, to employ the appellation planometer, which is exact and distinctive. The flat piece of cast-iron intended to be operated upon, having been chipped all over, a coarse hand- file, of as large dimensions as the operator can safely manage, is selected, and in the commencement the rough edges or ridges left by the chipping chisel are levelled, those parts however being principally filed, that appear from the straight-edge to be too high. The strokes of the file are directed sometimes square across as on a fixed line, or obliquely in both directions alternately; at other times the file is traversed a little to the right or left during the stroke, no as to make it apply to a portion of the work exceeding the width of the file. These changes in the applications of the file are almost constantly given, in order that the various positions may cross each other in all possible directions, and prevent the formation of partial hollows. The work is tried at short intervals with the straight-edge; and the eye directed on a level with the work to be tested, readily perceives the points that are most prominent. After the rough errors have been partially removed, the work is taken from the vice and struck edgeways upon the bench to shake off any loose filings, and it is then inverted on the planometer, which should be fully as large or larger than the work. As, how- ever, it cannot be told by the eye which points of the work touch the planometer, this instrument is coated all over with some coloring matter, such as pulverized red chalk mixed with a little oil, and then the touching places become colored. The work is slightly rubbed on the surface plate, and then picks up at its highest points some of the red matter; it is refixed in the vice, and the file is principally used in the vicinity of the colored parts, with the occasional test of the straight-edge, and after a short period the work is again tried on the planometer. This process is continually repeated, and if watchfully performed it will be found that the points of contact will become gradually increased. The grooved or roughing-out cutter is employed in the commencement, because it more rapidly pene- trates the work, and a few strokes are given to crop off the highest points of the surface; the furrows made by the serrated cutter are then nearly removed with the file, which acts more expeditiously although less exactly than the plane, and in this manner the grooved plane iron and the coarse file are alternately used. In the absence of the planometer, the metal plane assumes a greatly increased degree of importance. As the work becomes gradually nearer to truth, the grooved cutter is exchanged for that with a con- tinuous or smooth edge a second-cut, or bastard file, hand is also selected, and the same alternation of planing and filing is persevered in, the plane serving as it were to direct the file, until it is found that the plane iron acts too vigorously, as it is scarcely satisfied with merely scraping over the surface of the cast-iron'; but when it acts it removes a shaving having a nearly measurable thickness, and therefore, Digitized by Google FILING. 639 although the hand-plane may not injure the general truth of the surface, it will prevent the work from being so delicately acted upon, as the continuance of the process now demands; a smoother hand file is consequently alone employed in furthering the work. If the piece of cast-iron should have been turned in the lathe, or planed in the planing machine, instead of having been wrought entirely with the chipping chisel, plane, and file, the former instructions would be uncalled for, as the remaining steps alone would remain to be followed. It is now often usual to discontinue the use of the file, and to prosecute the work with a scraper, which having a sharp edge, instead of a broad and abrading surface, may be made to act with far more decision, on any, even the most minute spot or point. A worn-out triangular file, ground at the end on all the faces, so as to make thin keen edges, is generally used as the scraper; this should be keenly sharpened on an oil-stone, so as to act without requiring much pressure, which would only fill the work with strise or utters. In producing metallic surfaces the constant effort should be to reduce all the high places with as much expedition as circumstances will admit, but avoiding, on the other hand, that energetic use of the tool, which may too hastily alter the condition of the surface, and in expunging the known errors, induce others equal in degree but differently situated. Throughout the work, attempt should be made to keep the points of bearing, whether few or many, as nearly equidistant as may be, instead of allowing them to become grouped together in large patches. The periods of alternation between the hand-plane and the file, and also the times when these are successively rejected, in favor of the scraper as the finishing tool, must be in great measure left to the judgment of the operator. There should be a frequent examination of the work by means of the straight-edge and planometer, which latter should at all times be evenly tinted with the color. It is not to be supposed that it is in every case needful to proceed in the careful and progressive mode just described, as the parts of different works require widely different degrees of perfection as to flatness. For instance, in many it is only necessary they should be clean and bright, and have the semblance of flatness; with such, even the straight-edge is little if at all used as a test. Those surfaces by which the stationary parts of framings are attached, require a moderate degree of accuracy, such as may be comparable with the perfection in the hewn stones of a bridge, which require to be flat, in order that they may bear fairly against each other, as without a certain degree of truth, the stone might break from the unequal strain to which it would be exposed. The flat parts of metallic works, if similarly imperfect, would bend, and perhaps distort the remainder but although it is of great importance that bearing surfaces should be out of winding, or not twisted, it is by no means important that such bearing surfaces should be continuous, as a few equally scattered bearing points frequently suffice. Thus it was the common practice before the general introduction of the planing machine, to make fillets around the margin of the bearing surfaces of castings, which fillets alone were corrected with the chisel and coarse file, for the juxtaposition of the larger pieces or frame- work of machines, the intermediate spaces being left depressed and out of contact. This mode sufficed, provided the pressure of the screw-bolts could not, by collapsing the hollow places, distort the castings, with which view chipping places were also generally left around the bolt-holes of the work: this method greatly reduced the labor of getting up such works by hand; but fillets and chipping places are now in a great measure abandoned. Smaller and more delicate works, requiring somewhat greater accuracy than those just described, are left from smoother files, but in most cases without the necessity of scraping; but the rectilinear slides and moving parts of accurate machinery, and the trial or surface- plates of the mechanician, require beyond all other works the most dexterous use of the file. Until very recently, when the points of bearing had been so multiplied by the file and scraper, as not to exceed about half an inch in average distance, and that a still higher degree of accuracy was desired; it was the ordinary practice to attempt the obliteration of these minute errors by the method of grinding. That two surfaces which are very nearly accurate, if ground together for a very short time, do in some degree correct each other, is true, but it has been long and well known, that a continuance of the grinding is very dangerous, and apt to lead the one surface to become convex, and the other concave in a nearly equal degree, and on this account three pieces were usually operated upon that the third might act as an umpire, as although two pieces possessing exactly opposite errors may appear quite to agree, the third cannot agree with each of these two until they have all been made alike, and quite plane surfaces. But the entire process of grinding, although apparently good, is 80 fraught with uncertainty, that accurate mechanicians have long agreed that the less grinding that is employed on rectilinear works the better. A further and equally important advantage results from the discontinuance of grinding, as regards the slides and moving parts of machinery. Some of the grinding powder is always absorbed in the pores of the metal, by which the metallic surfaces are converted into species of laps, 80 that the slides and works carry with them the sources of their depreciation and even destruction. The former instructions have been restricted to the supposition that only one of the superficies of the work was required to be made plane or flat; but it frequently happens in rectangular works, such as the piece A BC, Fig. 1664, that all six surfaces, namely, the top and bottom A a, the two sides Bb, and the two ends C c, all require to be corrected and made in rectangular arrangement, (the surfaces a b c being necessarily concealed from view,) and therefore some particulars of the ordinary method of pro- ducing these six surfaces will be added. The general rule is first to file up the two largest and principal faces A and a, and afterwards the smaller faces or edges Bb, and Cc. The principal faces A a, especially when the pieces are thin, must be proceeded with for a period simultaneously, because of the liability of all materials to spring and alter in their form with the progressive removal of their substance, and on this account the work, Digitized by Google 640 FILING. whether thick or thin, is frequently prepared to a certain stage at every part, before the final correction is attempted of any one part. The straight-edge and surface-plate are required to prove that each of the faces A and a is a plane surface, and the callipers or a similar gage is also needful. to prove them to be in parallelism. Calli- pers, unless provided with set screws, are very liable to be accidentally shifted, and it is needful to use them with caution, otherwise their elasticity, arising from the length of their legs, is apt to deceive. There are gages, such as Fig. 1665, with short parallel jaws that open as on a slide, and are fixed by a side screw; and a still more simple and very safe plan is to file two rectangular notches, in a piece of sheet-iron or steel, as in Fig. 1666, the one notch exactly of the finished thickness the work is required to possess, the other a little larger to serve as the coarse or preliminary gage. 1654. 1665. 1666. K c B Sometimes the one face of the work, or A, having been filed moderately flat, a line is scored around the four sides of the work with a metal marking-gage, the same in principle as the marking-gage of the joiner. At other times the corrected face A is laid on a planometer larger than the work, and the marginal line is scribed on the four edges by a scribing point p, Fig. 1664, projecting from the sides of a little metal pedestal that bears truly on the surface-plate. Chamfers or bevelled edges are then filed around the four edges of the face a, exactly to terminate on the scribed lines: the central part of a can be reduced with but little watchfulness, until the marginal chamfers are nearly obliterated. This saves much of the time that would be otherwise required for investigating the progress made; but towards the last, the callipers and planometer must be carefully and continually used, to assist in rendering A and a at the same time parallel and plane surfaces. The two principal edges Bb are then filed under the guidance of a square; the one arm of the square is applied on A or a at pleasure, as in joinery work; or if the square have a thick back it may be placed on the planometer, as at 8, Fig. 1664; if preferred, the work may be supported on its edge B upon the planometer, and the back square also applied, as at 8, in which case the entire length of the blade of the square comes into operation, and the irregularities of the plane B are at the same time rendered obvious by the planometer. Another very convenient test has been recommended for this part of the work, namely. a stout bar, such as r, Fig. 1664, the two neighboring sides of which have been made quite flat and also square with each other. When the work and trial-bar are both laid down, the one side of the bar presents a truly perpendicular face, which may, by the intervention of coloring matter. be made to record on the work itself, the points in which B differs from a rectangular and vertical plane. When the edge B has been rendered plane and square, the opposite edge b may in its turn be marked either with the gage or scribing-point at pleasure; the four edges of b may be then chamfered, and the entire surface of b is afterwards corrected, (as in producing the second face a,) under the guidance of the square, callipers, rectangular bar, and surface-plate, or some of these tests. The ends Cc now claim attention, and the marginal line is scribed around these by the aid of the back square alone; but the general method 60 closely resembles that just described as not to call for additional particulars. Should one edge of the work be inclined, or bevelled, as in the three following figures, in which the works are shaded, to distinguish them from the tools, the rectangular parts are always first wrought, 1669. 1670. 1667. 1668. 1672. 1674. 1671. 1673 and then the bevelled edges, the angles being denoted by a bevel instead of a square; either with a bevel having A movable blade, Fig. 1667, or by a bevelled templet made of sheet metal. as in Figs 1668 or 1669, which latter cannot get misadjusted. The bevelled edge of the work is also applied if possible on the planometer; in fact, the planometer and bevel are conjointly used as the testa Bevelled works Digitized by Google FILING. 641 are either held in the vice by aid of the chamfer-clamps, or they are laid in wooden troughs, with grooves so inclined, that the edge to be filed is placed horizontally. Triangular bars of equilateral sec- tion are thus filed in troughs, the sides of which meet at an angle of 60 degrees, as in Fig. 1670. The succeeding examples of works with many plane surfaces are objects with rebates and grooves, as represented in Figa. 1671 to 1674. Pieces of the sections. Figs. 1671 and 1672, supposing them to be short, would in general be formed in the solid, either from forgings or castings, as the case might be; the four exterior and more accessible faces would be filed up square and true, and afterwards the interior faces, with a due regard to their parallelism with the neighboring parts, just after the mode already set forth. The safe-edge of the file is now indispensable: as in filing the face b the safe-edge of the file is allowed to rub against the face a of the work. and which therefore serves for its guilance; and in filing the face a the side b becomes the guide for the file. The groove in Fig. 1672 requires a onfe-edge square file. When, however, pieces of these sections, but of greater lengths, have to be produced by means of the file alone, it is more usual to make them in two or three pieces respectively, as shown detached in Figs. 1673 and 1674 and which pieces are first rendered parallel on their several edges, and are then united by screws and steady pins. In works of these kinds, which have rebates, grooves, internal angles, or cavities, the square, with a sliding blade, shown in Fig. 1672, is very useful, as the blade serves as a gage for depth, besides acting as a square, the one arm of which may be made of the precise measure of the edge to be tried. This instrument is often called a turning square, as it is particularly useful for measuring the depth of boxes and other hollowed works turned in the lathe. In making straight mortises, as at 88, Fig. 1675, unless the groove is roughly formed, at the forge, or in the foundry, it is usual to drill holes nearly as large as the width of the mortise, and in a straight line; the holes are then thrown into one another by a round file, or a cross-cutting chisel, and the sides of the mortise are afterwards filed square and true. $ 1676. 1675. : For R circular mortise cc the mode is just the same, with the exception that the holes are made on a circular line; and that, instead of a flat file being used throughout, a half round or a crossing file is used for the concave side of the mortise. Short rectangular mortises, or those which may be rather considered to be square holes, as in Fig. 1676, would, if large, be prepared by forging or casting the material into the form; and then the SIX exterior fuces having been corrected, the aperture would be filed on all sides under guidance of some of the various tests before referred to. And in such a case it is convenient to employ a small square 8, in the form of a triangle, to which is attached a wire that may serve as a handle, whereby the square may be applied at any part within the mortise without the sight of the workinan being intercepted by his own fingers. Sometimes also a cubical block filed truly on four of its faces to the exact dimensions of the aperture, is used as a measure of the parallelism and flatness of the four interior faces. The method first to be described is one that is considerably used in thick pieces of metal, for making holes differing from the circular form, such as square, hexagonal, triangular, elliptical, and other holes, by first drilling a round hole, and then enlarging and changing the section of the circular hole by a taper punch. better known as a drift, which tool is made of steel, and exactly of the same section as that required in the hole; the drift is hardened and tempered before use. The drift for a taper square hole is made as in Fig. 1677, or simply as a square pyramid, considerably longer than the hole required; a round hole is first drilled in the work, just large enough to admit the small end of the drift, which is then driven in; its angles indent and force out the metal, making it first like the magnified line m, and ultimately exactly square, unless by mistake the hole were drilled too large, when the circular parts would not be quite obliterated. If admissible, the endlong blows on the drift are mingled with a few blows on the sides of the work, as at bb, or parallel with the sides of the drift, which cause the metal to adapt itself more readily to the tool. The drift must not, however, be used too violently, for as it acts as a wedge, it may burst open the work. and which latter is therefore mostly left strong and rough before being drifted; and generally, when the angles have been somewhat indented. they are partly filed out, and completed by the alternate employment of the file and drift, the marks made by the latter serving continually to in licate the parts to be removed with the file. Taper square holes, such as those in the chucks for drills, are made with some facility. The chuck is first drilled on its own mandrel, and the drift is put in the four different ways in succession, that the errors incidental to its form may be scattered and lost; the chuck is also placed on the mandrel at intervals. with the drift in its place, that the drift may show, as it revolves, whether or not the hole is concentric. When it is required that the drifted hole should be parallel instead of taper, the drift is 81 Digitized by Google 642 FILING. made as in Fig. 1678; that is, parallel for a short portion in the middle of its length, and the extremities alone are tapered 80 as to make the tool smaller at each end; the work is therefore first gradually enlarged to admit the largest part of the drift, and the parallel part is then driven through the work, and renders the inner surface of the same a true counterpart of the drift, if proper care have been taken. In some few cases the sides of the drifts are notched with a file, 80 as to act as teeth; but this is not general. When drifts are used, the interior surfaces are often completed before the exterior. The holes are first drifted whilst the work is larger than its intended size, and afterwards the exterior part is filed or turned, as the case may be, from the hole, that is, the hole is made the basis of the measurement of the exterior portions of the work. In making by hand the key-ways in the round holes of the wheels, it is to be observed, that it is common to turn a cylindrical plug exactly to fill the hole, and to make a notch in the plug as wide as the intended key-way and parallel with the axis; the plug is shown at g, Fig. 1679. A piece of steel f is then filed parallel, and exactly to fit the 1678. notch, and its edge is cut as a file, and used as such within the guide-block, the latter being at the time inserted in the hole of the wheel. In this case the block becomes the director of the 1679. file, and the notches in any number of wheels are made both parallel and axial, and the only precaution that remains to be observed is in the g depth of the notches, and this is not always im- 1677. portant; the depth may however be readily de- termined by making the grooves at first a little shallower than their intended depth, and then, 4 m the plug having been removed from the hole, a s f stop is attached to the side of the file, parallel with its edge, as at 8, to prevent its penetrating beyond the assigned depth. In filing works that are convex, flat files are always used, and the file is necessarily applied as a tangent to the curve; and in filing concave works round and half-round files are used, and in some -cases they are selected, nearly or exactly as counterparts of the hollows to be wrought. The manipulation of the file upon curvilinear works is entirely different from that required to produce a plane surface, in which latter case the work is held at rest and the hands are moved as steadily as possible in right lines; but in filing curved works an incessant change of direction is important, and 80 far as practicable, either the file, or the work, is made to rotate about the axis of the curve to be produced. A semicircular groove of half an inch radius, as in Fig. 1680, would be most easily filed with a round file of nearly the same curvature, and the correspondence between the file and work, and consequently of their axes likewise, would render the matter very easy; but the file, from the irregularity of its teeth, would leave ridges in the work, unless in every stroke it were also twisted to and fro axially by the motion of the wrist, and occasionally in the reverse direction, 80 that the furrows made by the teeth might cross each other. If the groove to be filed had a diameter of three or four inches, although the file might be selected to correspond in curvature with the groove, as it would not embrace the entire hollow, the twisting and traversing of the file would be imperative in order to arrive at all parts of the work. 1680. 1681. 1682. b Under ordinary circumstances it is certainly best that the curvature of the file and work should agree as nearly as possible: but it is obvious that the file, if more convex than the work, can only touch the latter at one part, as at a, Fig. 1681; whereas, if the file is less convex, or flatter, than the work, it will act at two places, as at bb, Fig. 1682. Cutlers, in filing out the bows of scissors, always avail them- selves of this circumstance, and until nearly the conclusion, use files flatter or less convex than the work. In filing concave works, there is but little choice of position, as the file is always parallel with the axis of the curve, as in the dotted line in Fig. 1683; but in convex works, such as Fig. 1684, the file may be applied either parallel with the axis as at pp, or transversely thereto as at tt. In general, how- ever, the work would be fixed obliquely as in Fig. 1685. and the file would be first used transversely for some one or two strokes, at an inclination of about 30 degrees with the horizontal line, as at a. 80 as nearly to agree with the straight side of the object: the file would be successively raised to the horizon- tal, and depressed in the same degree on the other side; in fact. proceeding through the positions a be, Fig. 1685, at some eight or ten intervals. and which would tend to make as many insignificant ridges upon the work. The ridges would be then melted together by swinging the hands from the position a to c in every stroke, to be repeated a few times; but as the entire semicircle could not be embraced at one stroke, the work would be re-fixed in two or more positions, $0 as to divide the operation into about three stages. A more exact although less energetic method would be to place the file parallel with the axis, as on pp, Fig. 1684, and to sweep round the curve principally by the twisting motion of the wrist. A third Digitized by Google FILING. 643 mode, frequently adopted in such small pieces as can be held upon the filing-block with the hand-vice, is to swing the work upon its axis, and to use the file with the right hand, as if on a flat surface. Some works are curvilinear in both directions, such as curved arms and levers with rounded edges; many of these kinds are completed by draw-filing them, or rubbing the file sideways or laterally around the curve, instead of longitudinally as usual. The great majority of curved works are moulded and formed prior to the application of the file, which is then principally used to smooth and brighten them- other works are shaped almost entirely with the file, assisted by outlines drawn on the pieces them- selves-and again other works are shaped with the file, under the guidance of templets or pattern-plates of hardened steel. Some observations will be offered on all three of these modes. t 1684. 1685. 1633. b P Firstly, in respect to filing up metal works that have been accurately shaped by founding or forging, little or nothing remains to be added, as the only object is to act on every part of curvilinear surfaces in the most expeditious and commodious manner, with the general aim of reducing any trifling errors of form that may already exist in them, and avoiding the introduction of new ones; which circumstances call for the frequent scrutiny of the eye, and an incessant yet judicious variation in the position of the hands. Secondly, curved works that are moulded or formed almost entirely with the file. These are blocked out square, and the outlines of the curves are drawn on the ends and sides of the pieces, to guide the file in a manner analogous to the routine pursued by carpenters, masons, and other artisans. For in- stance, to form a bend, as in Fig. 1686, the work is prepared of a nearly rectangular form, and the half circle having been drawn at each end, the angles of the works are coarsely removed about 45 de- grees, making the end a semi-octagon; sometimes the four angles are farther reduced, giving to the work eight facets, prior to their being thrown together in making the general curve. If these sides are made with only a very moderate degree of exactness, they will greatly tend to preserve the uniformity of section throughout. 1686. 1688. " 1687. u c b b a Many workmen, when they have removed the two principal angles at 45 degrees, make a chamfer entirely around the semicircle at each end, to guide the file in hastily reducing the principal bulk of the material. It is also desirable that the straight-edge should be frequently applied along the axis of the curve, at various parts, during the progress of the work. Should the entire piece, Fig. 1687, have to be made from a solid block, two cuts a and b, made with the saw, would remove the corner. The round part of the bead would be made as before, and previous to filing the hollow, it would be chamfered on the line c; a half-round file, of less curvature than the hollow itself, would be first sunk in the middle of the chamfer, and the hollow would be deepened and extended sideways, always maintaining an easy curve, until it reached the marginal lines where the hollow meets the plane surfaces. Where hollows run on to right lines as at a, Fig. 1688, there is some risk of making a break in the junction, either from the curve sinking below the right line, as at b, or from the straight line, as at c, advancing too far and breaking in upon the curve. On this account a break or fillet is usually made at the part as at d. or el«e it is usual primarily to give that form. by filing the flat first, and then sinking down the hollow just to meet it, an.l at the conclusion letting the half-round file run a little way on to the right line. Some, bowever, prefer the opposite course. or that of sinking the hollow to its full depth, and then filing down the remainder with the flat file, but which mode is certainly attended with more risk. Thirdly, curved works that are shaped with the file under the guidance of templets or pattern-plates of hardened steel This mode is much followed in works of two principal kinds, namely, thin works re- quired in great numbers and precisely of one form, and in a variety of works that require to be exactly circular, although they may not admit of being 80 fashioned in the lathe. Many thin works of the first kind are stamped or punched out of the sheet metals, as for instance, the washers for machinery, the links of jointed chains, steel pena, parts of locks for joinery. and numer- ous other thin work<; but many objects of larger kinds, and that are not wanted in such large numbers, are not stamped, but are either cn-t. or cut out with the shears, and afterwards filed between templets. The snail-wheel of a striking clock, Fig. 1689, is frequently thus formed, by means of a templet: it Digitized by Google 044 FILING. has an edge formed in twelve steps. arranged spirally, the positions of which determine the number of strokes of the hammer on the bell. In this case, which will serve as a general example, a piece of sheet-steel is cut out, flattened, and smoothed on one side, to receive the drawing of the snail-wheel, and a second piece is also prepared. The two are first drilled together with a central hole, and another hole as distant from the centre as admissible. The two plates are then united by two pins, and the outline of the work having been drawn on one of them, they are next filed in steps carefully to the lines, and square across the edges, and they are afterwards hardened and slightly tempered to lessen their liability to fracture on being pinched in the vice. The dozen or more snail-wheels having been cast, or cut out of sheet-brass, and flatened with the hammer, two or three at a time are pinched along- side one of the templets, whilst the two pin-holes are made with the breast-drill or in the lathe, with a drill that exactly fits the holes in the templets. It only remains to place the dozen plates between the templets, keeping them in position by two pins extending through the whole number, and then all the notches are filed in the brass plates, until the file very nearly touches the steel patterns, as absolute abrasion on the steel itself would greatly injure the files. In this mode the several brass plates become very exact copies of the pattern. Templets are as much used for setting out and producing series of holes in any special arrangement, as in filing works to any particular form a complex example of templets being used in this manner, is in drilling the side plates of harps intended for the arbors and link-works, used in temporarily shorten- ing the strings. The respective positions of the holes in these side plates require a most exact arrange- ment. any departure from which, would prevent that precise shortening of the string required to pro- duce the semitones with critical accuracy, and would also cause an unbearable jar, unless the cranks of the harp were severally in true position, or on the lines of centres, 80 as firmly to support the tension of the strings under all circumstances. A different application of templets is sometimes met with in filing up numerous similar parts in the same object, as the arms or crosses for the wheels of clocks and other machines. The exact pattern of one spoke is filed up as a templet, which is shaded in Fig. 1690, and serves for the similar configuration of every spoke; the position of the templet being given by a central pin, aided by any little contrivance which catches into the 3, 4, 5, or 6, equidistant teeth corresponding with the number of arms. It frequently happens that certain forged, cast, and other works have parts, known as bosses, swells, collars, and knuckles, that are pierced with holes, which require their flat surfaces and also their mar- gins to be made partially or entirely concentric with the holes. When such parts occur as bosses, they often project from a flat surface, and after the central hole is drilled, some of the pin-drills, or analogous tools used in drilling machines, are employed in finishing the margins. 1689. 1690. a 1691. When the circular margins are discontinuous, files and templets are more or less require 1: thus the extremity of a forged arm, such as Fig. 1691, is drilled. and in the configuration of the remaining parts, if but one or two such pieces are to be m lile, a bois or plug of wood is turned like a, that shall fit the hole; the shoulder of the wood is then rubbed with red chalk to mark that part of the surface which is not at right angles to the hole, and the circular edge of the boss serves for the guidance of the file in finishing the exterior margin: visually rather than obstructively, as the wooden hoss would be reduced instead of the file being checked. If therefore many such objects had to be filed, two bosses or tem- plets would be made of hardened steel, and used one at each extremity of the hole, and they would be held in position by grasping the three pieces collectively in the tail-vice. The same general method is very largely and more rigorously followed in making joints or hinges. The brass and steel plates, Fig. 1692. used for the joints of carpenters' rules are filed up to templets in all respects after the manner described in reference to the snail-wheel, Fig. 1689, and the joint-plates are inlaid by means of the file, saw, chisel, and plane. The joints of dr.wing-compasses are made somewhat differently, and mostly as follows: The solid knuckle, a, Fig. 1693. is first drilled and made circular by aid of a templet c. and the hollow side b is filed to correspond exactly with a; the two are then pinched together in the vice on the line dd, and the parallel notches for the steel joint-plates are made in each with the saw, as deep as the line c. The parts a and b are then separated. the notches in b are completed with the frame-saw, and the bot- tom of the notches in a are rendered circular with the joint-saw. The middle plates, when filed a little larger than the templets c. are inserted in b, and soldered in their places; the two parts are smoothed on their various internal surfaces, and united by a temporary joint-pin. and any little irregularities in the external or circular curves, (which are left purposely a trifle too large,) are mutually detected by their want of agreement when the joint is opened to different distances any parts in excess are very carefully reduced with a small smooth file, principally by draw-filing, after which the screw-pin with its brass cheeks or bosses is added. The pin-drill is commonly used for cutting out the concave parts that extend to the side of small Digitized by Google FILING. 645 compass-jointa, such as are represented in Fig. 1694, and also for inlaying the heads of small counter- sunk screws. Larger joints with wider knuckles, such as Fig. 1695, are in many instances cast from patterns closely resembling the finished works. In such cases the first process is generally to remove any little exter- nal errors with the file, and to clear the angles with a small chipping chisel; the faces of the knuckles are then smoothed and inserted within one another very tightly. The joint-hole is afterwards drilled throughout all the knuckles, and which are filed up externally, sometimes under the guidance of tem- plets put at the ends, but principally by the reduction of those high parts which get scratched or rubbed by the opposite parts, and thereby show their excess of height. a 1692. 1693. z 1694. b b But if such joints are required to be made more accurately, the holes are first drilled in each piece separately, and rather too close in the corners; the holes are broached with a parallel broach, 80 as ex- actly to admit a steel cylinder, Fig. 1696, which has a square end for the brace; this rod is intended to receive the cutters, shown on a larger scale in Fig. 1697, which are cylindrical pieces of steel bored to fit the rod, and cut with teeth on the outer cylindrical part and on one flat surface; R pin is inserted through both the cutter and bar, 80 that the two may be united after they have been placed within the joint to be worked; sometimes the back face of the cutter has only a diametrical notch to receive the driving-pin, which pushes the cutter before it as it revolves. A recess must first be cleared for the cut- ter with a chisel and hammer, or by a wide-joint saw or cutter; and the hollowed parts at aa, Fig. 1695, are then cut throughout their length with the cutter, that afterwards serves to flatten the faces of the knuckles in exact parallelism throughout, and at right angles to the central hole. a 1697. 1695. 1696. The two halves of the joint, having been separately hollowed, and faced until the knuckles will pene- trate some distance into one another, the external parts of the joint are next separately filed under the guidance of hard steel rings, or templets, of the same diameter as the cutter, and placed on the cylin- drical rod; after which. the two parts of the joint are put together when yet slightly too large, and the central pin is inserted, in order that the rubbing of the knuckles against the corresponding hollows may denote the parts that are still too high or full; and by cautiously removing all the parts that are abraded, the joints may be made to fit very closely and accurately, and yet to move with great smooth- ness. Many joints that are at the same time wide and small, as in hinged snuff-boxes, could not be drilled, as above described, with safety, and are therefore made quite differently, by means of small tube, called joint-wire. For instance, in making a snuff-box, the rims for the top and bottom are fitted and jointed together before the top and bottom plates are soldered in, and the joint is thus constructed. Supposing that five knuckles are required for the bottom, and four for the top, the nine pieces of joint-wire are cut off, and filed square at the ends; the rims for the top and bottom having been fitted 80 as to form the rebate, are placed together, and carefully filed out with a semicircular recess, or groove, by means of a parallel round file, or a joint-file, exactly of the diameter of the joint-wire, which therefore leaves a hollow equal to the fourth part of the circle in each rim. Five of the joint-pieces are then strung on a wire, inserted in the hollow of the rim for the bottom of the box, and tied therein with fine binding wire; the intervals between these five knuckles are regu- lated by inserting the other four between them for the moment, while the binding wire is being fast ened; after " hich this first serios of knu kles is solder d in with mod erately hard ilver solder, which Digitized by Google 646 FILTRATION. is usually fused with the blow-pipe. The lid is then treated in the same manner, and the bottom part of the box now serves as the gage for regulating the distance between the knuckles in the top rim. The same plan is also used by mathematical instrument makers and others, who however more gene- rally turn the joint-pieces in the lathe, as the draw-bench forms no part of their ordinary supply of tools; and the wide joint-pieces or knuckles in mathematical works are usually larger than could be produced in that manner. FILTRATION. The process of separating liquids from the substances mechanically suspended in them, by passing them through some porous material, sufficiently compact to retain the insoluble matters. The materials employed as filters are numerous; as, porous stone, broken stone, glass or earthen- ware, gravel, sand, sawdust, pulverized charcoal, chaff, straw, sponge, paper, cotton and linen, and woollen cloth. These and many other things are made use of in the arts, but some of them have a particular application as being better suited to the character of the liquid to be strained, and the perfec- tion required in the process. Thus, unsised or filtering paper is generally used for chemical purposes; charcoal for oi!s and sirups. Care should be taken in the selection of the material that no injurious chemical action ensue, 80 that the liquid, in passing through, may not lose any essential quality nor acquire any deleterious one. Under the heads, sugar, oil, &c., will be found a description of the filters used in their manufac- ture; we shall confine ourselves now to the filters used for the puritication of water for the supply of cities and towns, and for domestic purposes. In all filters the rapidity with which the liquid passes through the filtering materials, or the quantity of strained liquid discharged in a given time, depends on the porosity of the filtering materials, the extent of their surface, the fluidity of the liquid itself, and the pressure under which it is forced through. Among the first plans adopted for filtering on a large scale was by drawing the water into trenches, excavated below the level, beside, and a few feet distant from the stream which was to afford the supply; the intervening earth forming a natural filter. This arrangement has been found to answer well in some cases where the trenches excavated were extensive in comparison with the supply but where from the demand, the level of the water in the trench is drawn unsiderably below that of the stream, so that the water passes through under pressure of some amount, the rapidity of the percolation of the water is found to diminish rapidly, from the drawing off of the finer earths into the body of the filter, filling up the interstices. New trenches have now to be excavated, in addition, and this is but a temporary relief, and, to prevent the filling up of the trenches, they have to be walled up and covered; on the whole, this plan of filtering was found to be expensive, especially when a large supply was needed. At the Chelsea Water Works, London, two subsiding reservoirs are used, 80 that the water in one of them can always be in repose, 80 as to deposit the heavier matters in suspension; a precaution al- ways, if possible, to be adopted After the deposition, the water passes through a filter of gravel and sand in a third reservoir. From time to time the top layer of sand is stirred up and renewed. and in course of time the whole material of the filter. This is of course expensive, and some readier and cheaper way of cleansing the filtering material has been sought. This has been effected by changing the direction of the current of water; that is, if the water has been passing down through the filter, to make it pass up, or vice versa: by this means the material is cleansed and continues to serve the pur- pose of filtering without replacing or change, and on this principle most filters are at present constructed. No large filtering apparatus is attached to the Croton Water Works, but for domestic purposes the diaphragm filter of W. M. Gibson, of New York, has been found to answer an excellent purpose, and is in extensive use throughout the United States. It consists of a metal box, Fig. 1698, shaped like a dish or flattened spheroid, about five inches in diameter, and not larger than a pint 1098. measure, with a screw-fitted orifice in the centre, on both sides, either oritice of which is screwed to the hydrant pipe faucet,and is adapted to any vessel, 1699. pipe, or reservoir; the filter suffers the water to pass through, but retains the impurities. The quartz a, Fig. 1699, is enclosed between two diaphragms of fine silver wire gauze and Britannia metal plates, and the water passes through both the gauze and the crushed quartz. To clean the filter, unscrew and re- verse it once a day, and the water will instantly wash away the sediment, slime, animalculæ, and all other impurities, and then run pure, clear, and pellucid as before. They can be attached to any hydrant, and under a pressure of eight feet head, will deliver a gallon a minute. Large filters, on the same principle, are made for manufacturing purposes, which can render 200 to 400 barrels of turbid water clear in an hour. The following is the construction of a filter on a more extensive scale: The stone pipe A brings the water from the regulating basin to the filters, and iron pipes communicate between the stone pipe or aqueduct and the top and bottom of the filters. A valve near the top of the iron pipe S P, at S, Fig. 1700, forces the water to enter on the top or at the bottom of the filter at pleasure. The filter is 100 feet in length, and 60 feet in breadth. divided into three compartments, which may either act together or separately, 80 that when one compartment is being cleansed, the other two continue in operation. The site of the filters is a piece of level ground. exca- vated to the depth of 6 or 8 feet, with retaining walls all round, joined with cement, and puddled be- hind, 80 as to become water-tight. The bottom is laid about a foot deep with strong stiff puddle, over which is a pavement 80 cemented as to be impervious to water. The whole of this bottom is then di- vided into drains or spaces, 1 foot wide, and 5 inches deep, by means of fire-brick laid on edge, and covered with flat tiles, of the same material, perforated with small holes, like those used in a kiln for drying oats. These holes are placed very near each other, and are rather more than 1-10th of an inch in diameter; there is also a space of f of an inch left open between the ends of the bricks, which sup- port the perforated tiles, and their upper edges are little more than an inch broad, in order that there Digitized by Google FILTRATION. 647 may be no space without holes, and nothing to prevent the water spreading equally over every part of the bottom of these drains. This is particularly necessary when the filters are being cleaned by the upward motion of the water. The perforated tiles or plates are covered to the depth of 1 inch with clean gravel, about 3-10th of an inch in diameter: this is followed by five other layers of gravel, each of the same depth, and each succeeding layer a little finer than the previous one, the last being coarse sand over this is placed 2 feet depth of clean, sharp. fine sand, similar to that used in hour-glasses, but a very little coarser; about 6 or 8 inches deep of the fine sand nearest the top is mixed with ani- 1700. s " mal charcoal, ground to the size of coarse meal, each particle about 1-16th of an inch in diameter. A longitudinal drain or pipe N runs between the filter and the pure-water basin. communicating with both; on each of the openings between the pipe and the filter is a stop-cock to close the communication when necessary; there are also two drains, to carry off the foul water when the filters are being cleaned, and another to prevent the water from rising too high: when the filter is complete, its action is as fol- lows: The aluice R and the valve S are opened, and the water permitted to flow through the filter into the drain N below, until it becomes quite clear. This will take two or three days when first set to 1701. L work, unless very great pains are taken to wash the gravel and sand before they are put into the filter, which will now flow copiously for some weeks, and when the quantity passing begins to decrease, the stop-cocks are shut, and the valve SS raised. The water then enters below, filling all the drains, and having a head pressure of several feet it will force its way up through the sand to the top. and in its passage raise the scales or particles of mud which have been deposited in the downward passage, and carry them into the foul-water drain below. If the sand of the surface be stirred by a fine-toothed rake, 1702. $ $ 9 after the water has been raised above it, and a little additional water admitted on the top, through the conduit, it will facilitate the operation of cleaning, as the mud is always deposited on the very surface of the sand. By this means the sediment will be carried off, and the water pass through quite clear again in a few hours: the valves S should then be lowered, the stop-cocks opened, and the operation of filtering will again proceed as above described. The cost of this filter would be about $3000, and the quantity of pure water produced regularly every 24 hours on an average about 106,632 cubic feet. Digitized by Google 648 FIRE ANNIHILATOR. M. Fonvielle, of Paris, has invented a filter in which two currents of water instead of one are em- ployed to cleanse the materials used for filtering. This arrangement can be readily understood from the section, Fig. 1703, in which S is the pipe sup- 1703. plying water to the filter D, the discharge pipe; a a, a stop-cocks by which the current may be made to pass in any direction through the filtering material F, which is supported between two perforated dia- phragm plates. When in operation one cock only in each pipe is opened, diagonally opposite, as S D shown in the section. But to cleanse the filtering materials, both supply-cocks are opened and one discharge-cock, alternately the lower and upper; by this means the filtering materials are effectually cleansed. Filters on this principle, with numerous compartments and of various cupacities, are used for the filtration of the waters of the Seine, and give complete satisfaction. A floating filtering pump has been patented in England. A flont supports the filter submerged a few inches, and it is connected by a pipe with a joint or piece of hose to the pump. By these means the water is drawn always from near the surface of the water, where the least matter is suspended. Without the filter a floating supply-pipe, whose aperture is always a few inches only below the surface of the water, would be a useful appendage to many pumps, since water drawn from near the bottom of a reservoir is very apt to be turbid. FIRE ANNIHILATOR. A portable machine for domestic use, which is stated to possess the power of almost instantaneously extinguishing fire. Fig. 1704 exhibits a section of the annihilator, which is composed of a set of light iron cases, thus arranged A and B the two outer cases, forming a close water-chamber; C and D two inner cases, per- forated in such a manner as to allow the free passage of vapor; E the inner lid; F the outer lid, or cover; G a water-pipe, forming the handle; H the charge; I the igniter; K the igniting-pin. The work of charging the machine is performed in a minute. The two lids F and E being taken off, the charge (which is already provided with the 1704. igniter bottle) is introduced, and the two lids are H H replaced, the outer one being secured by a thumb- screw. The igniter pin is placed in the neck, and covered with the wooden stopper, and this may be sealed down at pleasure. Water is then poured G into the handle, and confined by a small screw- plug. The charge K is a compound of charcoal, nitre, and gypsum, moulded into the form of a brick. The igniter I is a glass tube enclosing two bottles -one containing a few drops of sulphuric acid, placed over another containing a mixture of chlo- rate of potassa and sugar. The mode of using the annibilator is to carry the machine to the place on fire, take out the wooden stopper, with the knob of the stopper strike down the plug or pin in the neck of the machine, and hold the machine by the handle in the best posi- D D tion for the vapor, which will come out of the hole on the top to reach the flame, which is almost mo- C mentarily extinguished. The action of the ma- chine is as follows: The pin being forced down, B B breaks the igniter bottle, when the sulphuric acid falling on the mixture of chlorate of potassa and sugar, ignition takes place; the flame spreads over the upper surface of the charge, which instantane- ously ignites, and evolves heated gases; these, in their passage through the perforated cylinders, impinge against the water-chamber, expand the contained air, and produce steam, by which the water is forced through the tubular passage. The steam of the water mixing in the annular chamber with the hot gases, they escape together from the discharge tube in a dense expansive cloud, and are continuously delivered until the charge and water are expended. Mr. Phillips, the inventor, states the portable machine to be applicable to the protection of dwelling- houses, detached buildings, and ships; but it is requisite that public stores, warehouses, manufactories, and large pile of building, be protected by stationary engines of immense power, the construction of which varies materially from that of the portable machine, although based on the same principle of action; namely, that of extinguishing fire by gases and vapor resulting from combustion. FIRE-ARMS. See GUNS. FIRE BOX. See DETAILS OF ENGINES, page 508. Digitized by Google FIRE ENGINE. 649 FIRE-BRICKS. Used for furnaces and the lining of stoves where great heat is generated, are moulded in various parts of the United States. At Newark, Amboy, and other places in New Jersey, where the loam contains a considerable amount of sand, they are made in large quantities. Rondout (on the river Hudson) and Long Island bricks are a similar quality, and will stand the action of great heat. Retorts for a variety of purposes are made with a mixture of clay and iron, particularly for the manu- facture of gas; the iron retort receiving a casing of prepared clay, which permits the fire to act first on the clay. and thus prevents the rapid destruction of the metal. Retorts or bricks made of one part pure clay and three parts of coarse and pure sand, slowly dried and annealed, will resist a very high temperature, and are not readily fused; but if in contact with any metals in a fusible state, which are suffered to oxidize, they will then act upon the earthy matter, and cause it rapidly to fuse. A long-continued white heat will soften the compound made of any of the silicious and aluminous earths; therefore clay and sand are not so well adapted to bear a great heat as an entire clay coarsely powdered and burnt clay being substituted for sand, the vessels which contain glass in the furnace, and which are subjected to intense heats, are thus made, and resist for a length of time the action of the saline fluxes they contain. Windsor loam, or a mixture of clay and sand, made by beating a thin paste, is employed as a lute to unite the joints of fire-bricks, or to set them in instead of common mortar; and if it is required that vitrefaction should take place with the clay 80 used, borax or red lead, mixed in small portions, will produce the effect; such a compound will destroy the porosity of earthenware, when exposed to high temperatures. See FLOATING BRICKS. FIRE ENGINE. This most useful machine is constructed in a variety of forms, which all, however, agree in one principle. It generally consists of a double forcing pump communicating with the same air vessel; and instead of a force-pipe, a flexible leathern hose is used, through which the water is driven by the pressure of the condensed air in the air vessel The annexed diagram represents a section of the apparatus. The pipe T descends into a receiver or vessel containing a supply of water. This pipe communicates with two suction valves V, which open into the 1705. pump barrels of two forcing pumps A B, in which solid pistons P are placed. The piston-rods of these are connected with a working beam F, elongated, so that a num- ber of persons may work at both ends of it at once. Force-pipes tt proceed from the sides of the pump barrel above the valves V, and they communicate with an air vessel M. by means of forcing valves V, which also open upwards. The pipe descends into the air vessel near the bottom. This pipe is connected with the flexible leathern hose L, the length of which is adapted to the purposes to which the machine is to be applied. The extremity of the hose may be carried in any direction, and B may be introduced through the doors and windows of buildings. By the alternate action of the pistons, water is drawn through the suction valve, and propelled through the forcing valves until the air in the top of the vessel M is highly compressed. The pressure acts on the surface of the water in the vessel, and forces it through the leathern hose in a con- tinued stream, so as to spout from its extremity with a force depending partly on the degree of conden- sation, and partly on the elevation of the extremity of the hose above the level of the engine. It is to be considered that the pressure of the condensed air has, in the first instance, to support a column of water, the height of which is equal to the level of the end of the tube above the level of the water in the air vessel; and until the pressure exceeds what is necessary for this purpose, no water can spout from the end of the hose; and, consequently, the force with which it will so spout will be proportional , the excess of the pressure of the condensed air above the weight of the column of water, the weight of which is equal to the elevation of the end of the hose above the level of the water in the air vessel. The fire engine has received various improvements from 1518 to the present time. The above description applies to our ordinary engines, Fig. 1706. Braithwaite's steam fire-engine is an application of the power of steam to the working of the fire engine. The mechanical arrangement consists of two cylinders of about six inches in diameter, one of them being the steam cylinder, and the other the water pump; and they are placed horizontally, 80 that a parallel motion is easily produced. This engine will deliver 9000 gallous of water an hour at the height of 90 feet. The time of getting the machine into action, from the time of igniting the fuel, (the water being cold.) is only 18 minutes. Some of the fire insurance companies in London have floating engines on the Thames, which are extremely serviceable in cases of fire among the shipping or buildings near the river. Of all the engines hitherto constructed and worked by manual labor, the floating fire engine is the most powerful. Engines of this kind generally consist of three cylinders, working into an air vessel of large dimensions, and are built in appropriate barges. They are put in motion by the power of from forty to fifty men, applied to four long revolving cranks, which, by suitable machinery, work the three pistons. These engines will throw a column of water, one inch in diameter, upwards of a hundred feet high. They are advantageously employed on the river and in docks, where an abundant supply of water can always be depended upon. These engines, however, have been greatly surpassed by the fire engine recently constructed, worked by steam power. The engine of this kind, built for the Prussian government in 1832, had two working cylinders ten inches and a half in diameter, with a fourteen-inch stroke, the steam cylinders being twelve inches in diameter. When working with a steam pressure of seventy pounds upon the square inch, and making eighteen strokes per minute, this engine threw a jet of water, an inch and a quarter in diameter, nearly one hundred and twenty feet high. The same power gave two jets of seven-eighths of an ir ch, and a terwards four or five-ei ghth of an irch, an elevation of about eighty feet The ccp- 82 Digitized by Google 650 FLASH BOARDS. sumption of coke was three bush- els per hour, and the average working of the engine was calcu- Inted to be equal to the discharge of between 80 and 90 tons per hour. Steam fire engines have been tried in this country, but have not been found to be sufficiently eco- nomical to warrant their use. A common and convenient form of fire engine is shown, Fig. 1706, taken from one of the smaller New York engines. The cylinder shown on top of the carriage con- tains a reel, on which is wound a supply of hose. It is usually pro- tected by a cover of patent-leather, tastily ornamented. A suction- hose is swung on the side of the engine. Generally the hose is carried on a separate carriage, and when the supply of water is to be taken from an aqueduct the suc- tion-hose is unnecessary. In this engine it will be perceived that the power is applied by brakes, 1706. and that the movement is up and down. To increase the power of such engines, in some places, a rope is att ched to each of the brakes, which passing over blocks or sheaves fastened to the bottom of the carriage, are grasped by rows of men at right angles to the body of the engine, who, by recip- rocating pulls, assist very much the men at the brakes. Besides the up and down brakes there are engines in much use in Cincinnati and at the West, in which the movement is horizontal; the men sit at their work, and the action is similar to that of rowing. Various engines on the rotary principle have been constructed. The power was generally applied by means of a crank. but they were found very laborious in their operation, and liable to disarrange- ment. They are now seldom used as fire engines in the common ac- ceptation of the term; but as sta- tionary force-pumps, driven by steam or water, there are some which are extremely valuable and useful. See PUMP. FLASH BOARDS. Movable boards placed on the top of a dam or weir, to retain the water of the b b b 1707, 1708. e c d CL a e stream when the flow is small which, in case of floods, are removed to give free vent to the surplus. In case of low water, therefore, they maintain the head, and in case of freshets, there is less obstruction Digitized by Google FLAX, MACHINERY FOR PREPARING AND SPINNING. 651 and less danger from flowage than if the structure was permanent to the level of the top of the flash boards. On the dams of the rivers which, when swollen, bring down ice or flood-wood, flash boards are used, of rough boards supported by iron rods inserted in the top of the dam, the joints being stopped with saw-dust, shavings, or gravel; and as the water rises the irons are bent down, and the boards are swept off by the flood. Where there is no danger from ice or floating lumber, or very sudden rising of the water, flash boards a are constructed 80 as to be removed by hand, Figs. 1708 and 1707, about 4 feet long, and from 6 inches to 12 inches wide, with long handles b at each end, at right angles to the board, by which a person standing on the platform c can raise the boards. They rest in the rabbits of posts or stanchions d, and are placed one above another to the required height. Flash boards of this form being easily managed, are almost invariably used on the waste-weirs of canals, to regulate the height or level of the water. FLASHING. The accumulating of a flow of water, by movable constructions, for the purposes of manufacturing, navigation, or scouring. See SLUICES and SEWERS. FLASK. The iron or wooden frame or box which serve- in foundries to support and contain the sand used in moulding. See CASTING, Figs. 807 to 836. FLAX, Machinery for preparing and spinning. Flax, compared with the other materials used in the textile manufactures, such as wool and cotton, possesses several characteristic properties. While the latter are presented by nature in the form of insulated fibres, which simply require to be freed from their impurities previously to being spun, the former must have its filaments separated from each other by tedious and careful treatment. This circumstance has opposed 80 serious an obstacle to the success- ful introduction of machinery, as materially to have retarded the progress of the linen manufacture; and it is only within the last thirty years that the distaff and the hand-wheel have been entirely laid aside. Such rapid progress has, however, been made during that period in the improvement of flax machinery, that it has now attained to a state of perfection little short of that by which the cotton manufacture has been 80 long distinguished. The double breaking machine.-The flax, when delivered at the mill, (having previously undergone such preparation as entirely to free it from its boon or woody particles, and to dissever its grosser filaments,) consists of long parallel fibres of different degrees of fineness, and varying from 26 to 36 inches in length. After having been duly assorted, it is divided into stricks, or small bundles, which are brought to this machine for the purpose of being cut or broken into two, three, or more lengths, according to the nature of the flax, the length of the staple, and the different sorts of yarn into which it is destined to be spun. It is most generally divided into three lengths, in which case the finest and best qualities of yarn are spun from the middle portion, on account of the superior strength as well as delicacy of the fibres at that part. Fig. 1709 is a front elevation, and Fig. 1710 an end view of the breaking machine. LL, the iron framework of the machine. MM. the fast and loose pulleys. NN, the cutter or breaker, fast upon the driving shaft. It is constructed of three wrought-iron rings, firmly bolted together between two cast-iron flanges these rings have projecting points formed at regular intervals on their peripheries, and 80 disposed, when in combination, as to present numerous diagonal groups of cutters all round the circumference of the breaker. The cutters are of an elliptical form, and project about a quarter of an inch. 00, a pair of grooved wheels fixed upon a horizontal shaft at a short distance on each side of the breaker, which revolves between them. P P, a similar pair of wheels with projections on their circumferences, fitting into the grooves in the wheels 00, and revolving in the contrary direction. QQ, a set of compound levers, rods, and weights, for keeping the upper grooved wheels PP in con- tact with the lower 00. The purpose of these wheels is to bring the strick of flax under the action of the breaker, while the levers and weights QQ maintain the requisite pressure upon it; the shaft car- rying the upper grooved wheels being capable of moving vertically in the framing LL The opposite end of the machine is provided with a set of grooved wheels, weights, and levers, in all respects the saine as those shown in Fig. 1709. R R, a pair of spur-wheels fast upon the shafts of the upper grooved wheels and working into SS, a similar pair of spur-wheels fixed to the shafts of the lower grooved wheels 00, which is driven by a train of wheels at the opposite side of the machine. The wheels R RSS are made with teeth of a somewhat greater length than usual, to allow the flax to pass between the grooved wheels without disengaging the connection. TTT, a train of spur-wheels and pinions by which the motion of the driving shaft is communicated, with a greatly reduced velocity, to the grooved wheels Action of the machine.-The strick or small bundle of flax is held in both hands, and laid trans- versely against the grooved wheels OOPP, which rotate slowly in the direction of the breaker. The latter, which makes about 300 revolutions per minute, tears or breaks it across by separating but not cutting the fibres. Two hands may be employed at the same time at this machine, one at each side. The coarser having been thus divided from the finer portions of the flax, each sort is collected into a separate heap, and it is then ready to undergo the next process; namely, the hackling. Hackling, and hackling machinery.-This is an operation of the utmost importance in the prepara- tion of flax, as its successful accomplishment affects not only the quality but the quantity or yield of & the yarn into which it is ultimately converted. The object proposed by it is threefold First, the part- ing of the filaments into their finest fibrils; secondly, the separation and removal, with the least possi- ble injury to the real fibres, of the tow, or short fibres which adhere to the former and bind them together ; and thirdly, the equable and parallel arrangement of the long filaments. To accomplish these objects, the flax is drawn successively over two or more surfaces, thickly studded with sharp steel Digitized by Google 652 FLAX, MACHINERY FOR PREPARING AND SPINNING. A 1711. K A 1716. 1714. 1715. 4 и - A w - is V SCALE.-3 Inches=5 feet. n 3 3 1712. m E D 1713. C D A D A 1 Digitized by Google FLAX, MACHINERY FOR PREPARING AND SPINNING. 653 pins, or hackle teeth ; the thickness of these, and their degree of approximation varying with the pro- gressive stages of the operation. In hackling by the hand, the operative wraps one end of the strick of flax firmly over his right hand, throws it upon the points of the coarse hackle, and draws it towards him, while he holds the left hand upon the other side of the hackle, in order to spread the flax, and to prevent it from sinking too deeply among the teeth. The other end of the strick is treated in the same manner; and the opera- tion is repeated, first upon the coarse and then upon the fine hackles, until the fibres have been reduced to a sufficient degree of fineness, and, by careful handling, little more tow can be formed. To facilitate subsequent operations, the ends of the strick of flax should assume, at this stage of the pro- ceis, an elliptical form when laid on a flat board. For this purpose the hackler wraps the end of the dressed strick round a pin shaped like a knife, and breaks or pulls away such of the fibres as by their length would tend to give it a pointed instead of an elliptical shape. The hackling machine consists of two horizontal cylinders about 3 feet in diameter, on the peripheries of which are fixed hackles; the strength and number of these being varied according to the different stages of the operation. These cylinders are fixed upon shafts which are made to revolve with a con- aiderable velocity in directions contrary to each other, both cylinders moving towards the centre of the machine. At each end of these cylinders is placed a large spur-wheel, geering with a central one, called the transfer wheel, situated between the two hackle-cylinders. All these wheels are fitted with a number of segments fixed to their inner surfaces and forming a species of drums, of a diameter considerably greater than that of the hackle-cylinders. Each of these drums contains a series of re- cesses, into which are fitted the clamps or strick-holders by which the flax is secured. The drums and hackle-cylinders are set with a considerable degree of eccentricity in relation to each other, 80 that the rim of the external drum may be further from the hackles at the back part of the machine, where the operation commences, than at the part where the strick is delivered to the transferring mechanism; this arrangement is requisite for the purpose of subjecting the end of the strick to the action of the hackles for a longer period than the middle, where the fibres are naturally much stronger, finer, and do not contain so much tow. The operation of this machine is as follows: the stricks having been firmly secured to their holders, the latter are inserted into the recesses of the first external drums; these rotate with a slow motion towards the centre of the machine, and the hackle-cylinders, revolving within them in the same direction but with a much greater velocity, dress the under sides of the stricks. On reaching the transfer wheels the strick holders are, by an ingenious combination of slides and weighted levers, disengaged from the back cylinder, and pushed into the recesses on the transfer wheels; by these they are inverted and conveyed to the front cylinder and drums, which complete the process by hackling the upper side of the flax. On being delivered at the front of the machine, which we have supposed to be the first, or roughing hackle, the stricks are conveyed by the attendant to the finishing machine, which is in all respects identical with that described, but is furnished with finer hackles. After passing through this the strick holders are unscrewed, and the undressed ends drawn through them; they are again secured and returned to the roughing machine, where, by a repetition of the process already described, the opposite ends are finished. For further particulars of the hatchel, see rope manufacture. The tow is cleared from the hackle-cylinders by means of revolving brush-cylinders situated at each end of the machine and underneath the centres of the former. From the brush-cylinders it is again transferred by doffing cylinders covered with card filleting; these latter are cleared by means of doffing knives, worked by eccentrics on the end of the brush-cylinders, the tow being delivered in broad sheets on the floor of the factory or into proper receptacles. The carding and spinning of the tow is per- formed by machinery similar to that employed in the cotton manufacture, though of considerably greater strength. The spreading machine.-The next process undergone by the flax is its conversion into an endless band of parallel and rectilinear filaments, called a sliver, being the foundation of the future yarn. This is accomplished by the machine now under notice, which is fully delineated in Figs. 1711 to 1716. Fig. 1711 is a front elevation of the spreading machine; Fig. 1712 a side elevation; Fig. 1718 a general plan; and Figs. 1714 to 1716 detached views, on an enlarged scale, of the spirals and fallers. AA A, the cast-iron framework of the machine. B B, the driving shaft, fitted with a fast and loose pulley. CC, the feeding or spreading table; it is divided into two compartments, the one being considerably longer than the other, for the convenience of the attendants who spread the flax. DDD. rollers situated at each end of the feeding-table over these pass four endless leather straps, upon which the stricks of flax are spread. E E, a polished iron plate, upon which are fixed the guides which serve to conduct the flax to the back or detaining rollers. F, a cylindrical tin can, placed in front of the machine to receive the sliver. aaa, the front or lower drawing ruller. bbb, the top drawing or pressing rollers, made either of wood or iron, and covered with leather. ecc, the back or detaining rollers. G G. two weighted levers for imparting the requisite pressure to the top drawing rollers. HH. two weighted levers bearing in a similar manner upon the top detaining roller. dd, the fallers or gill bars, forming a sheet of advancing hackles between the detaining an I drawing rollers; these are for the purpose of producing great regularity in the draught, and a perfectly parallel distribution of the fibres. ece, the rubbers for clearing the top drawing rollers from adhering fibres. fff. brans guides for conducting the sliver to the drawing rollers. gg, the sliver-plate, formed with bevelled openings for the aliver to pass through towards Digitized by Google Digitized by Google B 00 D Y K 1717. 1718. SCALE.-3 inches=5 feet. 8 D ДИР N MIIII 1709. 1719. R K 0 THE JJ 3 M 1710. 1721. D. 7799 I. C R new SECURITY 1720. $ FLAX. MACHINERY FOR PREPARING AND SPINNING. 154 FLAX, MACHINERY FOR PREPARING AND SPINNING. 655 hh, the calender rollers, by which the four slivers compressed into one, and delivered in the form of a riband into the can F. K, the calender rolling shaft. ii, cast-iron hangers for transmitting the pressure of the weighted lever G to the top drawing rollers. k k, are similar hangers attached to the lever H. 11, the spirals or screws; into the spaces between the threads of which the ends of the fallers are inserted. m, two pairs of small bevel-wheels by which the lower spirals are driven from the back shaft. two small spur-wheels communicating motion from the lower to the upper spirals. 00, the tappets or cams by which the fallers are elevated in succession from the lower to the upper spirals, and vice versa. P p, small weighted levers for guiding the fallers between the threads of the spirals. q. a small endless screw cut upon the extremity of the axis of the lawer drawing rollers aa; it works into r, a worm-wheel on the axis of which is another endless screw, driving a similar wheel, called the bell-wheel; at every revolution of this last wheel, a pin fixed into its rim acts upon a spring L, to the end of which a bell is attached. Thus the ringing of this bell serves to register the length of the aliver delivered into the can. The following is the detail of the wheel work in this machine:-On the driving shaft B is fixed the spur pinion s, working into the wheel t on the lower drawing roller shaft; to this latter axis is affixed the wheel u, whose motion is communicated by the movable intermediates v and w to the change pinion x on the back shaft the relative diameters of these wheels regulating the amount of draught or the degree of extension which the flax sustains in passing between the detaining and drawing rollers. The opposite end of the back shaft carries the pinion y working into the stud-wheel y'. having on its boss the pinion 2, which, by means of a movable intermediate z', drives the wheel 1 on the axis of the detaining roller. This train of wheel work is calculated to produce a nearly uniform surface speed of the rollers and the sheet of hackles. A slow motion is communicated to the sheet roller D, over which the feeding bands pass, by means of the spur-wheel 3 working through an intermediate 2 into the pinion 2. A uniform velocity is imparted to the lower drawing and calender rolling shafts a and K, by a pinion 4 on the extremity of the former, working through an intermediate wheel 5 into a similar pinion 6 on the end of the latter. And lastly, a revolving brush situated under the lower range of fallers, for the purpose of clearing away the dust, is driven by the stud-wheel 7, geering with the pinion 4, and having on its boss a small pinion working into the wheel 8 on the end of the brush-shaft. Action of the machine.-The flax is placed in the sheet-iron guides behind the detaining rollers and along the endless bands or feed sheets, by laying down one handful after another, 80 that the points of the second strick reach to about the middle of the first, and thus preserve a uniformity of thickness in the feeding. By the motion of the machine it is introduced between the back rollers cc, and carried forward by the sheet of hackles dd. towards the front or drawing rollers a a b b, which, revolving at a velocity considerably greater than the former, lengthen or draw it out to a proportional extent; the hackles at the same time combing, separating. and straightening the fibres. The slivers from the four drawing rollers are then passed through the bevel slits in the sliver-plate g g, and united into one by the calender rollers h, where they are subjected to a gentle pressure and delivered into the can F. This union of the slivers is necessary in order that the varying thicknesses of each may be compensated and perfect uniformity attained. When the can has received its destined supply, the ringing of the bell warns the attendant to break the flax, remove the can, and substitute another. The drawing frame.-The next process in the preparation of flax consists in causing it to pass twice in succession through the drawing machine, for the purpose of still further increasing the fineness and uniformity of the sliver. These machines, which are represented in Figs. 1717, 1718, and 1719, are in principle identical with, and in the details of their construction, very similar to, the spreading machine already described. They contain, as will be seen by the drawings, two sets of fallers and rollers, and the place of the feeding table and guiles is supplied by a bent plate of polished sheet-iron C, extending across the entire breadth of the machine, over which the slivers glide in passing from the cans to the detaining rollers. These latter differ slightly from those used for the same purpose in the spreading machine; here they are three in number, and coupled together by small pinions, 1, 2, and 3, and disposed in a triangular form, the sliver being made to pass under the first, over the second, and under the third. With these exceptions there is no essential difference between the present machine and that last described, and as we have been careful to designate the same or analogous parts in both by the same letters, it will be unnecessary to repeat the description. Spiral or screw gill.-Figs. 1720. 1721, and 1722 give a representation of a very interesting and im- portant piece of mechanism which enters largely into the construction of modern flax machinery. This ingenious contrivance has, in a great measure, superseded all former modes of effecting the same object, which is the combing and separating the fibres of the flax, in order to facilitate the drawing and to give uniformity to the sliver. The fallers or hackle bars dd, Fig. 1721, are supported at both extremities by the horizontal steel guide rails k k, screwed to the insides of the sockets in which the spirals or screws work these sockets being bored in projecting parts cast upon the stands DD. The lower screw is driven from the back shaft by a bevel-wheel and pinion m m', and a small spur-wheel n, on the back of the bevel pinion, works into a corresponding wheel on the top screw, driving both screws at equal velocities but in contrary directions. In the sides of the sockets in which the screws revolve, openings are formed, Digitized by Google 656 FLAX, MACHINERY FOR PREPARING AND SPINNING. parallel with their axis and coinciding with the surfaces of the guide rails k k; through these openings the ends of the gill-bars, (which are steeled and bevelled to compensate for the angle of the threads,) are inserted into the helical grooves of the screws. Thus the rotary motions given to the spirals cause the fallers to be driven along the guide rails in a vertical position, and with a uniform simultaneous movement; the top sheet in the direction of the drawing rollers, and the lower towards the detaining rollers. On reaching the front part of the machine, close behind the drawing rollers, the fallers are depressed and put out of operation by means of the rotary cams 00, fixed to the ends of the top screws; being guided vertically downwards between the ends of the upper guide rails and the weighted levers P. They are thus engaged in the threads of the lower screws, which carry them to the opposite end, where similar cams 00, and weighted levers pp, raise them successively into their original position on the upper guide rail, where they are traversed forward as at first. It is usual to make the lower spiral with the threads considerably wider than those of the upper, which arrangement diminishes the total number of fallers requi-ite for the due performance of the work. Self-regulating spiral roving machine.-Fig. 1723 presents a general elevation of the entire machine as seen in front; one of the plates which protect the spiral pinions being removed in order to show the mode of giving motion to the spindles, flyers, and bobbins. Fig. 1724. A corresponding general elevation of the back part of the roving frame exhibiting the cone and differential movements, and by the removal of one of the covering plates, exposing a part of the back shaft and geering for working the fallers. Fig. 1725 is an end elevation, showing the principal geering employed in this machine. Fig. 1727 is an elevation, partially sectioned, of portion of the spindle rail or beam, and Fig. 1728 is a plan corresponding. Fig. 1729 is an elevation, also partially sectioned, of part of the bobbin lifter with its attached geering, and Fig. 1730 is a plan of the same. Fig. 1726 is a transverse section of the machine, exhibiting some of its internal arrangements, and showing the course of the sliver from the cans to the bobbins. Fig. 1731 is an elevation of part of one of the stands, showing the slides, springs, and weighted levers used for defining the course of the fallers. Fig. 1732. An elevation and plan of the contrivance for transmitting motion to the axis of the spirals on the bobbin rail. Fig. 1733. A cross section of a part of the machine, showing the apparatus for maintaining constant tension upon the strap driving the cone pulley of the traverse and equational bobbin motions. A A, the driving shaft, situated towards the back of the machine and extending throughout its entire length. BB, a shaft parallel and near to the driving shaft, extending from the centre to one end of the machine. It carries a spur-wheel at each extremity, one of which is commanded by the equational bobbin motion, while the other, by means of A peculiar arrangement of geering, to be hereafter described, transmits the motion to the spiral shaft on the bobbin rail. C C, the mangle pinion shaft worked by a train of bevel-wheels from the cone shaft, and, through the mangle wheel, situated at one end of the machine, close to the driving pulleys, working. D, the mangle wheel shaft extending the whole length of the machine, and carrying pinions working into racks 8, 8, 8, attached to vertical slides; these slides are furnished with projecting arms fixed to the bobbin rail. which is traversed up and down by the mangle wheel; causing the flyers to wind the roving between the flanges of the bobbins, with all the regularity of a screw. Counter-balance weights 1, 1, 1. attached to the bobbin lifter by means of chains passing over pulleys, serve to relieve the racks from all unnecessary strain. E, a short shaft situated at the back of the machine, and driven by a train of spur-wheels from the driving shaft at the same velocity as the latter. Upon this shaft is suspended a species of frame, fitted to slide longitudinally upon it, and carrying two pulleys and a weight at the extremity the first pulley being adapted to rotate with the shaft E, by means of a long slot and sunk feather, and the other being merely a conical friction roller, for the purpose of maintaining a constant tension upon the strap driving the cone F, Fig. 1733. The frame, with its appendages, is traversed along the shaft by means of a weight 2, situated at the opposite end of the machine, and attached by a chain and adjustable rod to the frame and to a rack working in a slide fixed to the back of the roller beam, Fig. 1726. This rack is serrated on both edges, the teeth of the upper alternating with those on the lower edge, and the pawls are alternately disengaged at every revolution of the mangle wheel in such a manner as to allow the drag weight to advance the rack and pulley frame by half the distance between two contiguous teeth. The mechanism by which the pawls are disengaged is as follows :-At the back of the rack slide a short rectangular bar is fitted to slide vertically, having two projecting pins acting upon the points of the clicks, Fig. 1726. This bar is worked by the end of a lever inserted through its lower extremity, and having its fulcrum under the roller beam: to the other end is attached the vertical rod 5, carrying two adjusta ble catches 4, 4, which, at every alternate movement of the mangle wheel, are struck by an arm 6 extending from the rack 7. Thus one of the pawls is constantly in geer to prevent the rack and attached pulley frame from being drawn beyond the prescribed limits for each stroke. The lower pawl is kept pressed against the rack by a counter-weight 3, while the upper one merely rests on it by its own gravity. The pitch of the teeth on the rack must be varied according to the degree of fineness of the roving. F, the cone driven by a strap belt from the pulley on the shaft E, and communicating a gradually retarded motion, at once to the bobbins themselves and to the traverse of the bobbia rail; the velocity of the spindles and flyers remaining constant. This is necessary in order to compensate for the con- tinually increasing diameter of the bobbins as the roving is wound upon them. The come is set at a Digitized by Google FLAX, MACHINERY FOR PREPARING AND SPINNING. 657 1723. 2 S X N 8 DE x S 10 1(ALK.- 3 incluse=4 leet. o D M 10 X S h H m k B 88 Digitized by Google 658 FLAX, MACHINERY FOR PREPARING AND SPINNING. slight inclination, in order to allow the belt to act upon a greater part of its periphery towards the apex than towards the base where, on account of the increased diameter, this precaution is less necessary to ensure the rotation of its shaft. A lever handle (seen in the end elevation, Fig. 1725,) is attached to the carriage of the cone shaft, for the purpose of raising its outer extremity previously to winding back the pulley frame. G H, two short shafts situated towards the centre of the machine, and carrying geering to be here- after specified, for transmitting the motion of the cone shaft F to the traverse and equational bobbin motions respectively. I, a hollow boss fitted to rotate 1733. upon the driving shaft A, with a mo- 1732. tion independent of that of the latter, and carrying at one end a spur pin- ion working into a wheel on the shaft N B, and at the other a bevel-wheel, being part of the equational bobbin motion. 1731. K is a similar bevel-wheel fast upon the driving shaft A. LL, the back shaft traversing the entire length of the machine, and F N carrying the bevel-wheels for work- B ing the mechanism of the fallers. M M, a longitudinal shaft working in bearings on the spindle rail, and X 8 carrying the spiral pinions for con- E veying motion to the spindles and flyers, Figs. 1726, 1727, and 1728. The spindles are disposed in two rows, so that each spindle in the back range stands opposite to the interval between two in the front % D 1727. range. The object of this distribu- tion is economy of space, as the ma- chines would require to be greatly M longer if the spindles stood all in one line. The shaft M is situated be- tween the two rows, and drives both rows in the same direction. NN, a longitudinal shaft working in bearings on the bobbin rail, and carrying the spiral pinions for work- ing the bobbins, Figs. 1726, 1729, and 1730. The spindles pass through 1728. brass sockets fixed to the bobbin rail to hold them steady as the latter 0 traverses up and down. These sock- M M ets serve also as pivots for the spiral pinions to revolve upon it being understood that the motion of the U bobbin spirals is totally independent of that of the spindles. A small flange on the top of each spiral car- 1729. ries two projecting pins fitting into corresponding holes in the bottom of N the bobbins, and causing both to re- volve together. OP, the back detaining rollers having the iron pressing rollers be- tween them, which are cut into short lengths, and are carried round by the h 1730. friction caused by their own gravity. QQ, the axes of the pressing or top drawing rollers marked 10, which are usually made of wood, and are N pressed against the lower drawing rollers 12, 12, by hangers 11, 11, rest- ing in necks cut in the axes and at- tached to weighted levers 9, 9, pass- ing under the roller-beam. RR, a slender rod extending the entire length of the machine, for conducting the slivers to the detaining rollers. They pass under this rod. and slide over a polished sheet-iron plate covering the back shaft and bevel geering for driving the gill screws. SS, a rod by which the attendant is enabled at any part of the machine to stop or set it motion Digitized by Google 1724. S S S z e s P F a W d U F 1 7 1 2 6 D FLAX, MACHINERY FOR PREPARING AND SPINNING. 9 Digitized by Google X 9 SCALE.-3 inches=4 feet. 699 660 FLAX, MACHINERY FOR PREPARING AND SPINNING. TT, are a set of friction pulleys placed upon a rod surmounting the machine, for the purpose of guid- ing the slivers as they are drawn out of the cans by the action of the machine. UV, the fast and loose pulleys on the end of the driving shaft for starting and stopping the machine. W W W, is a train of spur-wheels conveying the motion of the driving shaft A to X, a spur-pinion on the end of the shaft M, which drives the spindles and flyers with a uniform motion. YZ, the draught geering between the drawing and detaining rollers, the particulars of which will be given below. abcc and d, are spur and bevel wheels and pinions, the combination of which forms the differential motion for driving the bobbins. Supposing that the large spur-wheel a, which, through the pinion b, receives its motion from the cone, were driven at the same velocity as the driving shaft A, then it is obvious that no motion what- ever would be imparted to the bobbins. On the other hand, if the wheel a were held absolutely im- movable, the bevel K, which is fixed upon the driving shaft, would convey, through the pinions c, a motion equal to its own, though in the contrary direction, to the boss I and attached geering; conse- quently, in the case we have last supposed, the motion communicated to the bobbins would be uniform. Hence, by combining the two extreme cases, and supposing the wheel a to be driven in the direction of the driving shaft, but with a slower velocity, it will be understood that the boss I will be made to re- volve at a speed which, if added to that of the wheel on will be exactly equal to that of the driving shaft A. Thus, when the driving strap is at the apex or starting point of the cone F, the wheel a is at its maxi- mum velocity, and the boss I with the train of wheels to the bobbins at their minimum, causing the flyers, which revolve at a considerably greater uniform speed, to coil the given quantity of rove upon the bobbins; then as the strap advances towards the base of the cone, (every point in this advance being simultaneous with the commencement of a fresh layer of roving,) the speed of the wheel a is diminished, causing that of the boss I to increase in the same ratio, and thus approximating the speed of the bob- bins to that of the flyers, at every alternate motion of the traverse. In this way the irregularity due to the varying diameters of the bobbins is compensated, and a uniform very slight tension maintained upon the slivers between the flyers and the drawing rollers. eee, a train of bevel-wheels and pinions for conveying the motion of the short shaft G to the mangle pinion shaft C. f g g, a train of spur-wheels and pinions (including change pinions) for conveying the motion of the cone F, at once to the traverse and equational motions. It is obvious that to preserve the regularity of the winding, the speed of the traverse or copping motion, as well as that of the bobbins themselves, must be progressively retarded. h hh, a train of spur-wheels for conveying the differential motion to the bobbin shaft N. The pinion d on the boss I works into a wheel fixed to the end of the shaft B; this shaft has another spur-wheel h, Figs. 1725 and 1732, upon its opposite extremity, which geers with h an intermediate wheel suspended in a joint formed by the meeting of two pairs of arms; one of which have their centre of motion on the shaft B, and the other upon the shaft N. Thus, when the latter ascends and descends in obedience to the traverse motion, the arms move in a radial direction round their respective centres, and consequently the suspended wheel h is kept constantly in geer both with the wheel on the end of the shaft B and with the pinion on the shaft N. This will be clearly understood by observing the dotted lines in Fig. 1732, which denote the different positions of the bobbin lifter, and the corresponding positions of the arms and intermediate wheel. k m., a train of spur-wheels for conveying the motion of the driving shaft to the shaft E working the cone motion, Fig. 1725. n, is a spur-wheel on the end of the drawing roller, also working into the movable intermediate k, which thus commands the drawing, the bobbin, and traverse motions. The train i k n, is called the twist geering, and its object is to vary the speed of the front roller while the speed of the spindles remains the same, and thus to put more or less twist into the rove as may be required. oop, a train of wheels between the drawing rollers and the back shaft-p being a change pinion; these, together with the train Y Z, at the opposite end of the machine, constitute the draught geering. vr, small pinions connecting the detaining rollers together. tu, a handle and small bevel-wheels working a barrel round which is coiled a chain attached to the pulley frame for winding the rack, &c., towards the apex of the cone F. vvwwyy, the fallers and geering for working them, as minutely detailed in a preceding description. the flyers fixed upon the top of the spindles for twisting, guiding, and winding the rove upon the bobbins. The wet spinning frame.-With the exception of the hot-water trough and its adjuncts, this machine bears a close resemblance to the throstle frame of the cotton manufacture, and like it, is employed for the completion of the yarn, after being subjected to the processes of drawing and roving. Although the principle of its operation be. for the most part, the same as that of the roving machine, it is much less complicated than the latter, inasmuch as it dispenses with the gill apparatus, (which is, of course, only applicable to parallel slivers,) and with the equational bobbin motion, which, in the pre- sent instance, is rendered unnecessary by the circumstance of the yarn itself having attained a sufficient degree of cohesive force to enable it, with the aid of a simple contrivance, to regulate the drag upon the bobbins. A very important improvement in the spinning of flax is the use of the hot-water trough, through which the rovings are caused to pass in the act of spinning. By this means, the glutinous matter ad- hering to the fibres is thoroughly dissolved, and a much finer, smoother, and more uniform thread than could otherwise have been possible. is produced. There is an improvement in the method of driving the spindles, by which one tape is made to communicate motion to four spindles, and another in the method of working the traverse motion, as seen in the figures. Digitized by Google FLAX, MACHINERY FOR PREPARING AND SPINNING. 661 5 1726. 3 $ P N Et D FOIRS & = 1725. J E 10) OF Digitized by Google 662 FLAX, MACHINERY FOR PREPARING AND SPINNING. Fig. 1734 is a front elevation, broken in the middle, for the purpose of exposing part of the geering for working the traverse motion. Fig. 1785 is an elevation of the geering end of the machine; and Fig. 1736 is a transverse section of the entire machine. Literal References.-A A, the frame ends or standards of cast-iron. B B, the middle support. C C, longitudinal beams of cast-iron, on which are supported a a, the stands or framing of the rollers. The bottom or drawing roller journals are fixed, while the top or detaining roller N j purnals slide on the upper part of the stands, and are regulated by screws, (see dotted lines in Fig. 1736.) 80 as to adapt the reach or distance between the draw- ing and detaining rollers to the various lengths of fibres. This distance should always be a little more than the average length of the filaments. bb, the bottom or drawing rollers, usu- Y ally called the front rollers. cc, the top or detaining rollers, usually called the back rollers. Both front and back rollers are made of brass cast upon a wrought-iron shaft or axle, and fluted. dd, the saddles for retaining the press- ing rollers in their proper places. The bushes or bearings of the top pressing rollers are made to slide upon projecting arms, in order to suit the various lengths of reach. The top pressing rollers are generally made of brass and the bottom G of box-wood, and both are fluted. A ee, are bolts fitted with adjusting thumb-screws for attaching the saddles 1734. dd, to ff9 g, levers with weights for giving SPALE-3 inches=5 feet. the requisite pressure to the pressing rollers. H hh, cranked axles extending the entire length of the machine for relieving the pressing rollers from the strain of the weighted levers when the machine is at rest. ii, ratchet-wheels fixed upon the end of the cranked axles for maintaining them in the position in which they may be placed. DD, the wooden troughs surmounting the machine, and through which the ro- vings pass before reaching the detaining rollers. These troughs are supplied with hot water, and kept at a high temperature by steam from a boiler. E, the creel in which the roving bobbins are placed vertically, in alternating rows. F, a wooden rail surmounting the creel, to which are attached E jj, the slender sheet-iron supports for the top of the roving bobbin spindles, the lower ends revolving in footsteps on the top of the trough, Fig. 1736. kk, the bobbins, as filled with loose yarn by the roving machine. illi, longitudinal brass rods for conducting the rovings into and through the troughs DD. m m, is a flat brass rod, placed immediately above the detaining rollers, and extending the entire length of the machine; opposite to each boss of the detaining rollers an indentation is cut in the rod m, for the purpose of guiding the rovings. A small endless screw is cut on the end of the detaining roller shaft, and geers with a worm-wheel p. Fig. 1734, which works on a stud fixed to the beam C, and has R small heart-wheel formed upon its upper surface. A small steel pin n is fixed to the end of the rod m, and is pressed against the heart by a drag-weight o, attached to it by a chain passing over a small pul- ley. As the roller revolves, it produces a slow motion of the heart causing the rod m m, to traverso Digitized by Google FLAX, MACHINERY FOR PREPARING AND SPINNING. 663 nearly the whole length of the boss, and thereby preventing the roving from wearing the surface of the rollers unequally. qq, the thread-plates or guides, having small notches opposite to each bobbin through which the threads pass on their way from the drawing rollers to the eyes of the flyers. These plates are made in separate lengths as may be convenient, and are hinged in order to enable the bobbins to be inserted into or withdrawn from the spindles. 1735. K K E D D R q P S KAMAN ? N A A M J G G, are sheet-iron linings extending from the beam C to H H, spouts formed under and within the rows of bobbins. These linings and spouts serve to collect and withdraw the water which is thrown off by the centrifugal force of the bobbins. 1736. K K E D D 70 10 10 a B B G C V T и H H A X t OL W K Consents r B A A rr, the flyers for guiding and winding the yarn on 88, the bobbins, formed with a species of pulley on their lower flanges. In this machine the bobbins are not driven independently of the spindles, for a reason which we have specified in our introductory remarks. The natural tendency of the bobbins to wind on the yarn regularly is assisted by the follow- ing contrivance: tt, are drag weights, attached by pieces of string to loops on the back of the bobbin lifter; these cords pass across to a plate with a serrated edge fixed to the front of the bobbin lifter, and press against Digitized by Google 664 FLOATING SECTIONAL DOCKS. the grooves formed in the lower flanges of the bobbins. The friction thereby occasioned, which may be varied by changing the length of leverage at which the weights act, gives the bobbin the requisite re- tardation for winding on the yarn. uu, the bobbin beams or lifters supported by the traverse rods x x, which are attached to bosses upon the traverse shaft xx, by chains furnished with adjusting thumb-screws for adapting the bobbine to the height of the flyers. vv, are the spindle rails or beams, in which are inserted the steps and collars for the spindles to run in. w, the spindles themselves, with their driving wharves or pulleys fixed to them. I, is a bracket upon which works the strap-guide for starting and stopping the machine. J. the fast and loose pulley fitted to the end of KK, a long cylinder constructed of tin plates and extending the entire length of the machine, form- ing a continuous drum for driving the spindles. L, a balance pulley round which the tape passes for driving the spindles, and which keeps it at the proper tension. The tape passes over the cylinder K, then over the balance pulley L, and round two spindles on each side of the frame, thus causing one belt or tape to drive four spindles. Previously to the introduction of this method, each spindle was impelled by a separate tape. MNOPQRS, a train of spur geering, (0 being a change pinion,) constituting the twist geering and conveying motion from the driving shaft to the front rollers on both sides of the frame. TUV, a train of spur-wheels situated at the middle of the frame, and constituting part of the trav- erse geering. T is a pinion fast upon the end of the shaft which carries the intermediate twist wheel P, and which has a bearing in the middle support B. This wheel works through the intermediate U, into V upon the mangle pinion shaft. W is the mangle wheel situated at the opposite end of the frame to the twist geering, and actuated alternately in both directions by the mangle pinion. X. a small spur-pinion fixed to the axis of the mangle wheel, and working into a rack formed on the top edge of Y, a cast-iron horizontal bar working transversely in slides bolted to the inside of the end framing A A. Each extremity of this bar is formed into a radial rack; these work into the eccentric spur-wheel yy, fixed upon the traverse shafts z 2, imparting to the latter a graduated motion of rotation, which is com- municated to the bobbin lifter by the mechanism previously described; causing the flyer to wind the yarn upon the hobbin in a slightly spherical form. a' d', a combination of wheels forming the draught geering, precisely similar to the draught geer- ing in the other machines which have come under our notice. FLOATING BRICKS, in imitation of those made by the ancients, were formed by M. Fabbroni, out of a material which consisted of 55 parts of siliceous earth, 15 of magnesia, 14 of water, 12 of alumina, 3 of lime, and 1 of iron: this kind of brick does not become altered by fire, being infusible, and although it loses 1 part of its weight, it is not in any way diminished in size: as these bricks are found to float on water, they have been very much used where lightness of construction was desirable. See FIRE- BRICKS. FLOATING SECTIONAL DOCKS, Messrs. Burgess and Dodge, New York, patentees. These docks are very powerful, being capable of lifting vessels of upwards of 2,000 tons burden, and are executed at a comparatively small cost, being chiefly of timber. These docks, instead of being fixed, and in one position, like the marine railway and screw docks, may be towed to any vessel within a convenient distance. Suppose that a ship is sunk, say in 5 fathoms water, it may be raised to the surface by hogsheads, or slung by any of the usual modes; and, once got up to the surface, the sectional floating dock can be readily introduced beneath it, and the whole towed together to the landing or shipwright's wharf. The sectional floating dock derives its name from its consisting of distinct sections of timber framing in the form of a floating dock, into which ships can enter. In the sections on each side are balance tanks raised and lowered by means of a rack and pinion, and also tanks, which, by being filled with water, cause the dock to sink, and by the water being pumped out enable it to be raised to any required height out of the water, the ship resting on the platform within. On the top of the sections is machinery for working the racks and pinions and pump-work. Such is the general principle of the contrivance. Now to detail the construction. According to the size of the vessel to be raised, any number of sections, more or less, may be used, as convenience suggests. Each section is 92 feet broad externally, and 64 feet internally, and 23 feet long. The section is 38 feet high externally, exclusive of engine house, and 28 feet high internally to the top of the standards. The dock, it will be seen, is neither more nor less than a large floating timber vessel, and is constructed of beams strongly bolted together. Each section may be considered as consisting of three parts, two lateral scaffoldings or framings of standards within which the balance tanks run, and a central platform connecting them. The object of the lateral framing is to enable the balance tanks B to be run up and down, and to prevent the machines from coming in contact with the water. Each lateral portion, Fig. 1737, consists of two external standards G, 36 feet high and 12 inches square, and of four internal standards ff, 371 feet high and 12 inches square. These standards are at the bottom secured to the outside truss girders F, and on their tops carry a platform on which the engine apparatus is placed. The standards are bound together by proper tie-pieces, and are further secured to the outside truss girders F by a 12-inch beam 44 feet long, F*. At the bottom of each lateral framing is a flooring on which rests a balance tank B, 191 feet long, 10 feet broad, and 8 feet deep, being of a capacity of about 1500 cubic feet. The total capacities of the fourteen tanks would therefore be 21,000 cubic feet. Besides these are water tanks within the platform in which the pump rods t' work. The platform is about 10 feet deep, and on the upper surface consists of two outside truss girders FF, being about 70 feet long and 17 inches across, composed of two beams scarped together. Between these Digitized by Google FLOATING SECTIONAL DOCKS. 665 G A F B M M M M & & 1737. K F A at K M L B n 84 Digitized by Google 666 FLOATING SECTIONAL DOCKS. are a cross beam, 7 inches square, in the centre, secured to the keel beam P, and a cross beam on each side D D, 9 inches square, for carrying the chock blocks E, and secured to the keel beams P. These cross beams rest on joists or tie-pieces, 10 inches square. In the centre across are the two keel beams PP, 241 feet long and 12 inches square, and which carry five keel blocks C. This upper plat- form rests on the foundation truss girders F, by means of posts and timbers scarfed in, and is further secured by four stout iron ties. The bottom truss girder F2 is 93 feet long, and formed in three por- tions, well scarped, tied, and bolted together. These bottom truss girders extend under the lateral framings, knitting together the whole structure. 1738. o n 1741. A DC G OC R The sections are connected together, in case of need, by double tie beams, which can be readily slipped out, by withdrawing the nuts and screws by which they are secured. On the cross beams DD, Fig. 1737, on each side is a rack and pawl, enabling the chock blocks E to be readily moved, and secured by means of tackle. The chock blocks are 4 feet high and 3 feet 9 inches wide. These receive the bottom of the ship; but in order to steady the sides there are side supports on each side LL, worked by block and pawl M, 80 as to make the ship firm to the inner standards ff. The object of the balance tanks B is to keep the dock steady and in an upright position. They con- tain no water, and it is only necessary to keep them depressed to the level of the water, either in sinking or raising the dock, and their resistance keeps the whole dock, with the ship, perfectly steady. The lateral framings are furnished with two stationary spuds II, 34 feet high and 7 inches square, provided, on one side, for 27f feet, with a rack plate. This spud is secured into the framing at top and bottom, and is for the purpose of working the tank up and down by machinery, subsequently to be ex- plained, and part of which is seated on the top of the tank B. Each lateral framing is also provided with a ladder N, and an upper stage for the workmen. On each side of the centre section is an engine house, which contains the machinery for working the thrusting and pumping apparatus, and from which shafts run along the sections on each side. It should be observed that the machinery on all the sections is covered in, although it is not 60 repre- sented. The engine house contains a tubular boiler, a, Figs. 1739 and 1740, like a locomotive boiler, with steam pipe b, and exhaust pipe c, cylinder d, and valve box C. From the piston a cross-head carries a connecting rod g, working on the crank h, which drives the main shaft i, on which is the balance wheel j From Digitized by Google FLOATING SECTIONAL DOCKS. 667 the main shaft a pinion and bevel wheel k and k' carry the motion to the shaft 1, which is the longitu- dinal driving shaft, continued, as hereafter explained, along the sections for a length of 140 feet. From this longitudinal driving shaft l, a wheel o, working by a belt on the wheel p, communicates the power to the pumping geer on the shaft r, crank t, and pump-rod t', running down to the water tanks. This geering can be thrown in and out by means of the movable pulley q, which by being raised or let fall tightens or loosens the belt on o and p. The longitudinal shaft l also works the shaft w, by which the thrusting geer is moved, and which by means of the wheels and pinions u, v, x, and y, put on or off by the clutch z, works the tank and pinion J either upwards or downwards as may be required. The shaft l is connected at each end by means of the universal joint m, and by the small circular shaft n, with the longitudinal shafting on the end sections. By this means the different sections may be placed at such distance from each other as the length of any ship may render necessary. It is to be observed, that a necessity constantly occurs for sinking one or more sections lower than the others. This is also provided for by the slip and universal joints. 1745. n m m n The thrusting geer, Figs. 1742 and 1744, for raising and lowering the tank B, takes its motion, as men- tioned, from the shaft by means of the bevel wheel, which moves the pinion at the head of the square vertical shaft. On this shaft is a movable socket, with a square hole in it, and four friction rollers, 80 that the vertical shaft may easily pass through it. Beneath the friction rollers is a pinion, working into the bevel wheel. This bevel wheel is on the horizontal shaft, secured into a framing on the top of the platform of the tank B. The horizontal shaft carries a worm, working into a worm wheel, the shaft of which carries a pinion J at each end, working into the spud J, which is kept in geer by a friction roller. The number of spuds is twenty-eight, four on each section, or two for each tank. On the end sections the machinery consists merely of a longitudinal shaft, the thrusting and pumping geer. The process of taking a ship into the sectional floating dock is as follows The dock is sunk to any required depth by opening the gates or valves with which each water tank is furnished, and the dock necessarily sinks. The dock still being at the required depth, the ship is then introduced between the vertical side framing, rests on the keel blocks C, and when supported on the sides by the chock blocks E and side supports L, is ready for lifting.-Fig. 1737. The valves which have previously admitted the water into the water tanks are now closed, the water Digitized by Google 668 FLOATING SECTIONAL DOCKS. is pumped out, and the air again fills the tanks, and they rise, bringing with them the vessel to the height necessary for repairs. The vessel is taken out of dock by a repetition of the process of admitting water into the tanks. The patent is for the general arrangement in the construction of the side balance tanks B. 1739. Fig. 1787.-Elevation of a section. BB, the balance tanks. C, the keel block. DD, cross beams supporting the chock blocks E. EE, the chock blocks. FF, the outside truss girders. ff, the inside standards of the main framing to guide the balance tanks B. *F Beam securing the standards. G G, the outside standards of ditto. 1740. P m W t II, the stationary spuds for working the tanks. JJ, pinions working in the racks on the spuds. K K K, outline of a vessel in the dock, supported by the side supports LL, the chock blocks EE, the keel block C, and the balance tanks BB. LL, the side supports run up and down by the blocks and tackle MM. 00, engine houses on centre section. cc, vertical shaft from the main shaft in the engine houses. g, the worm working the wheel h. h, the worm wheel working the pinion J and the spud I. Digitized by Google FLOATING SECTIONAL DOCKS. 669 Fig. 1738.-Inner side elevation of a section. Fig. 1745.-Plan of the engine and machinery at 0 on the centre section A 4 of the sectional floating dock. a, the tubular boiler. b, the steam pipe. c, the exhaust pipe. d, the cylinder. e, the valve-box. g, the connecting rod working on h. H, the cross-head. h, the crank on the main driving shaft i. i, the main driving shaft. j, balance wheel. k k', the main bevel wheel geering, transmitting the power from the main driving shaft i to the longitudinal driving shaft 1. i, longitudinal driving shaft working the thrusting geer, and communicating along the sections by m and n. m m, universal joints connecting the shafts 11. n n, small circular shafts working into the shaft I with a aleeve or socket and feather. 1744. 1743. I 1742. B B B 74 B B B a, pulley or wheel on shaft I for setting in action the pumping apparatus, and connected by a belt with p. p, pulley or wheel driving the pump shaft r. q, a movable pulley for tightening or loosening the belt connecting o and p. v, a crank shaft working the pump rods t'. 8, a balance wheel on the pump shaft r. t, crank on the pump shaft r. t', connecting rod from the crank t to the pumps in the balance tanks B B. UVXY, wheels and pinions for changing the motion, making it slower or faster, and reversing the action of the spuds I. uv, wheel and pinion on the longitudinal shaft 1. xy, wheel and pinion on the thrusting shaft 10. to, shaft carrying the change motion wheela, and working the thrusting geer. , clutch for changing the motion on the shaft w. Digitized by Google 670 FLOOR CLOTH. a' b' part of the thrusting geer taken from the shaft w. a', bevel-wheel on the shaft w. b', pinion working on a' and moving c'. c', square vertical shaft of the thrusting geer. Fig. 1741.-Plan of the machinery on the side sections A 1, 2, 3, 5, 6, 7 of the sectional floating dock. Fig. 1739.-End elevation of the engine and machinery at o on the centre section A 4 of the sectional floating dock. Fig. 1740.-Side elevation of the engine and machinery at 0 on the centre section A 4 of the sectional floating dock. Fig. 1742.-Plan of balance tank B with machinery. B, the balance tank. ff, the inside standards of the main framing to guide the balance tank B. c, the square vertical shaft from the shaft 20. d, small pinion working on the vertical shaft c, and on the bevel-wheel e. e, bevel-wheel working on the worm shaft n. f', movable socket of the shaft c, having a square hole in it, and four friction rollers on it. n', worm shaft. g, worm working on the shaft n from the bevel e. h, worm wheel worked by the worm g, and turning the shaft o. o, shaft worked by h, and working the pinions JJ. JJ, pinions working on the teeth of the spuds IL II, upright stationary spuds for raising and lowering the balance tank B. k, small friction roller for keeping the spud I in geer. Fig. 1743.-Side elevation of machinery on the balance tank B. Fig. 1744.-Enlarged front elevation of the pinion d, bevel-wheel e, and friction rollers f. FLOOR CLOTH. This useful and ornamental manufacture was originally made of narrow canvas sewn together like sail-cloth, to which successive coats of paint were applied; but the seams proving inconvenient, a canvas was wove for the purpose, about four yards wide; it was then extended to seven yards in width, and afterwards to nine, which is the widest at present made; but the common dimen- sions of the oil cloths produced being 20 yards by 8, and 30 yards by 7. giving therefore entire pieces of 160 and 210 square yards without seams. These canvases are stretched upon frames, and accessi- ble over their whole surface by stages erected for the purpose these are the circumstances which render the large dimensions of the manufactory requisite. The canvas being duly strained, is rubbed over with pumice stone, which renders its surface smooth and even, and then brushed over with a weak solu- tion size; when this is dry, the first coat of oil color is laid on, not with brushes, but with trowels, some- thing in the manner of plastering; when this is dry a second coat follows it; and in this way seven coats of paint are usually applied in succession, three on the back and four on the front. When the cloth in this state, and of one color, is sufficiently dry, it is removed from its frame upon a large roller, and carried to the upper part of the building to be printed; that is, to receive its pattern. This was originally effected by a process of pencilling; but in the year 1780, there was introduced the great im- provement of block-printing; by which the colors are more correctly laid on, and in greater body and variety. The printing table, which is about 30 feet long, 4 wide, and 2 feet 6 inches high, is very firmly constructed of deal timbers laid edgeways and clamped together, the surface being truly planed; the roll of painted cloth is placed underneath it, and as it is unrolled it gradually passes over the table, where it is printed, and is then drawn forward so as to hang perfectly free while drying. the height of the building being such as conveniently to admit of this, without rolling, doubling, or folding the mate- rial, which in these stages would of course injure it. The colors, which are the usual oil colors very carefully prepared, are put on in succession with wooden blocks, which are made of pear-tree, box, or holly-wood, and upon which the patterns are cut in relief; they are about eighteen inches square, and are applied in succession over the whole of the surface of the cloth lying upon the printing table. Every color is put on by a separate block, and much dexterity is required in so placing them that the patterns may correctly interlace and join each other, without in any case overlapping or interfering to effect this, the workman is aided by guide pins, or pitches, as they are termed, which direct him in placing the block. The colors are first brushed or tiered upon hard cushions, from which they are transferred to the block, and thence to the cloth; and, though many are often required, it is astonishing how much effect is sometimes obtained by the judicious arrangement or mixture of two only, upon a third, which forms the ground. It will be obvious, from what has been stated, that the weight of the finished oil cloth, as compared with the naked canvas, is no unimportant criterion of its goodness; each square yard when finished weighing from three pounds and a half to four or four and a half: this distinguishes a good oil cloth from those which are vamped up and stiffened with size and other perishable materials. Independent of the common application of oil cloths, it is not unfrequently advantageously employed as a roofing material, especially for covering verandas and other light structures. When used for this purpose, the canvas should be made of picked long flax, and thoroughly saturated with good oil paint. FLOUR MILL See CORN MILL. FLY FRAME. See SPEEDER. FLY-WHEEL A large heavy wheel, used as a regulator or equalizer of motion, wherever either the power communicated or the resistance to be overcome is variable. In the one case the fly-wheel may be said to be a distributor of power. The communicated impulses act on the mass in motion, and go to preserve the momenta, without disturbing very sensibly the regularity of movement. The effect of one impulse is so absorbed or distributed in the momentum of the wheel, that its effect may be said to have hardly been diminished before the next impulse is received. In the other case, or where the fly-wheel is used to overcome a variable resistance, it may be considered a collector of power; the power having been employed to get up the speed in the fly-wheel only, is retained in the mass in move- ment; and the whole of the power expended, with the exception of that which has been lost through friction and resistance of the air, can be brought to bear at any instant upon the resistance to be over- come. The applications of fly-wheels are very general;-there are few stationary engines without them. Digitized by Google FLY-WHEEL. 671 But it is usual in this country to communicate the power directly from the periphery of the fly-wheel, either by making it a geered wheel or using it as a pulley or drum, and transmitting the power through a belt or band. We know of no rules more accurate by which to calculate the dimensions of fly-wheels for steam engines, than those given by Mr. Hann. They are as follows:- RULES FOR THE FLY-WHEEL. For the double-acting engine, the number of revolutions, or the number of double strokes per minute, the mean radius and the horse-power being given. To find the weight of the wheel.Rule 1. Multiply the number of horse-power by 2275, and that product by n. Multiply the square of the mean radius by the cube of the number of revolutions per minute. Divide the former product by the latter, and the quotient will be the weight in tons. The value of n given by M. Morin varies with the purposes to which the engine is applied. Thus, when great regularity of movement is not required, as in saw-mills, grist-mills, the working of pumps, &c., n = 20 to 25. For cotton-mills spinning not less than 60, n = 30 to 50; for those spinning higher numbers, n 50 to 60. For rolling-mills for making bar iron, with 6 to 8 sets of rollers, requiring an engine of 80 to 100 horse-power, n = 20; for smaller mills, of 4 to 6 sets of rollers, and engines of 60 horse-power, n = for mills of 1 set of rollers for large bars, or 2 for small rods, and engines of 30 to 40 horse-power, n = 80. To find the mean radius of the wheel.Rule 2. Multiply the number of horse-power by n, divide the product by the area of the section of the rim, and extract the cube root of the quotient. Divide 12.17 by the number of revolutions per minute, and multiply the quotient by the cube root before obtained. The product will be the mean radius required. To find the area of the section of the rim-Rule 3. Multiply 1802'9 by the number of horse-power, and that product by n. Multiply the cube of the mean radius by the cube of the number of revolu- tions per minute. Divide the former product by the latter, and the quotient will be the area of the section. For the double-acting engine, the number of single strokes per minute, the mean radius, and the horse-power being given. 7σ find the weight of the wheel.Rule 4. Multiply the number of horse-power by 18200, and that product by n. Multiply the square of the mean radius by the cube of the number of revolutions per minute. Divide the former product by the latter, and the quotient will be the weight in tons. To find the mean radius of the wheel.-Rule 5. Multiply the number of horse-power by n, divide the product by the area of the section of the rim, and extract the cube root of the quotient. Divide 24.34 by the number of revolutions per minute, and multiply the quotient by the tube root before obtained. The product will be the mean radius required. To find the area of the section of the rim-Rule 6. Multiply 14423 by the number of horse-power, and that product by n. Multiply the cube of the mean radius by the cube of the number of revolutions per minute. Divide the former product by the latter, and the quotient will be the area of the section. For the single-acting engine, the number of revolutions, or the number of double strokes per minute, the mean radius, and the horse-power being given. To find the weight of the wheel-Rule 7. Multiply the number of horse-power by 11860, and that product by n. Multiply the square of the mean radius by the cube of the number of revolutions per minute. Divide the former product by the latter, and the quotient will be the weight in tons. 7'o find the mean radius of the wheel.-Rule 8. Multiply the number of horse-power by n, divide the product by the area of the section of rim, and extract the cube root of the quotient. Divide 211 by the number of revolutions per minute, and multiply this quotient by the cube root before obtained. The product will be the mean radius required. To find the area of the section of the rim.-Rule 9. Multiply 93958 by the number of horse-power, and that product by n. Multiply the cube of the mean radius by the cube of the number of revolu- tions per minute. Divide the former product by the latter, and the quotient will be the area of the section. For the single-acting engine, the number of single strokes per minute, the mean radius, and the horse-power being given. To find the weight of the wheel.Rule 10. Multiply the number of horse-power by 94880, and that product by n. Multiply the square of the mean radius by the cube of the number of revolutions per minute. Divide the former product by the latter, and the quotient will be the weight in tons. To find the mean radius of the wheel.-Rule 11. Multiply the number of horse-power by 92, divide the product by the area of the section of the rim, and extract the cube root of the quotient. Divide 42.2 by the number of revolutions per minute, and multiply the quotient by the cube root before obtained. The product will be the mean radius required. To find the area of the section of the rim.-Rule 12. Multiply 75166 by the number of horse-power, and that product by n. Multiply the cube of the mean radius by the cube of the number of revolu- tions per minute. Divide the former product by the latter, and the quotient will be the area of the section. Digitized by Google 672 FOLDING AND MEASURING MACHINE. Ex. 1.-A double-acting engine makes 20 single strokes per minute, the radius of the fly-wheel is 15 feet, the horse-power is 60; what must be the weight of the fly-wheel, supposing the variation to be s'o from the mean velocity 1 By rule (4,) 18200 X 60 X 40 18200 X 60 X 40 = 15' X 20" ; 225 X 8000 18200 X 60 40 364 = = 2426. 225 X 8000 15 Ex. 2.-Wishing to diminish the number of strokes to 17 per minute, by how much must I increase the weight of the fly-wheel to preserve the same regularity of motion By rule (4,) 18200 X 50 X 20 18200 X 50 X 20 = = 3706 tons, the weight of the wheel 100 X 17' 100 X 4913 Hence, 3706 2426 = 12.8 tons, the weight by which the fly-wheel must be increased. Ex. 3.-A double-acting engine makes 20 single strokes per minute, the horse-power is 60, the area of the section of the rim is 15 feet; what must be the mean radius, supposing the variation to be 1'o from the mean velocity ? By rule (5) the mean radius is 24.34 60 X 20 24:34 9-2 X = 11.2 feet nearly. 20 15 20 Ex. 4.-A double-acting engine makes 20 single strokes per minute, the horse-power is 60, the mean radius of the fly-wheel is 11.2 feet; what must be the area of the section By rule (6) the area of the section is 14423 X 60 X 20 = 15. (11.2)' X (20) In the application of the fly-wheel to the steam engine, the varying effect of the power of the steain communicated through the crank has been particularly regarded. The next consideration is to over- come variable resistances, in cases where the moving power is not steam. Here it may be remarked, estimating the force of any prime mover in horse-power, and taking the number of revolutions of the fly-wheel, that the rules already given for finding the dimensions of fly-wheels may be applied to mills where the resistances to be overcome are variable, as in the case of rolling-mills; in fact, the values given to n in these particular cases were intended for a mill to be driven by water, and there- fore may be somewhat too small when applied to the steam engine. For the smaller variations in resistances, always experienced in the movements of machinery, no fly-wheels are necessary, when the power is. constant, as in the case of water-wheels-the wheels themselves are sufficient regulators; and whenever fly-wheels are necessary, the size, weight, and velocity of the water-wheel should be taken into consideration, as it will be found to have considerable effect on the equalization of the movement. As to the position of the fly-wheel, it should be as near as possible to the prime mover if the power is variable, and near to the resistance if this is inconstant, as the strain on the intermediate shafts would frequently be very considerable. With regard to the diameter of the wheel, it will depend consider- ably on position; but in some cases too small a diameter is to be guarded against. Tbus the tly-wheel of an engine for a corn or flour mill. ought to be of such a diameter that the velocity of the circum- ference of the wheel may exceed the velocity of the circumference of the stones, to prevent, as much as possible, any tendency to back lash. In conclusion, we give from M. Morin the rules for finding the weight of the rim of the fly-wheel when employed to overcome the resistance of forge hammers. To find the weight in tons of the rim of the fly-wheel on the cam shaft of a forge hammer. For the largest forge hammers, striking 70 to 80 blows per minute- Hammers weighing 3 to 4 tons, divide 240 by the square of the mean radius. " " 4 to 5 " " 360 " " 64 " For trip hammers striking 150 to 200 blows per minute- Hammers weighing 1000 to 1200 pounds, divide 108 by the square of the mean radius. " 64 700 to 800 " " 72 " " " " The quotient will be the weight of the rim of the fly-wheel in tons. FOCUS in Geometry is that point in the transverse axis of a conic section at which the double ordi- nate is equal to the parameter, or to a third proportional to the transverse and conjugate axis. In optics. it is the space into which the rays of light are collected by a burning glass or mirror. FOLDING AND MEASURING MACHINE Formerly, for the folding and measuring of cotton cloth at the manufactories, hooks were universally used. These consist of two hooks or long needle-like points, slightly curved upwards, inserted in a wooden bar, at a distance of a yard from each other; this bar is supported on a stand at a beight convenient for the operative, and at least the width of the cloth to be measured, from the floor, 80 that the folds may hang straight; the bar. for convenience, is often permitted to have a movement horizontally. Attaching the cloth at one corner to one of the hooks, one edge is drawn straight and hooked alternately on one and the other of the points, and in this manner the whole piece is laid in folds of one yard each. But latterly, in the larger manufactories and bleacheries, when the quantity of cloth prepared for the market is large, the improved cloth measuring and folding machine" has been exten-ively adopted; this machine was patented by S.C. Durgin in 1844, and is manufactured by Gay, Silver and Co., North Digitized by Google FOLDING AND MEASURING MACHINE. 673 Chelmsford, Mass. Introduced first at Lowell, it is now employed in all the cotton factories in that city. Since its first introduction, it has been improved in workmanship and detail; and, as an evidence of its present capability, we give the statement of W. A. Kimball, overseer of the cloth room at the Atlantic Mills, Lawrence, Mass. One machine will fold nearly 25000 yards of cloth per day, and more cor- rectly than upon hooks, and ours has run 8 months without repairs." From the specifications at the Patent Office we take the drawings and a description, which will give an idea of the construction and working of the machine. Fig. 1746 represents a plan or top view of the folding machine. Fig. 1747 is a side elevation. Fig. 1748 is a vertical and central section. The principal operative parts of the machine are similar to those of that patented by J. Spalding, of Morristown, Vermont, in 1841. Durgin's inventions are certain improvements which render the opera- tion of Spalding's machine more certain and expeditious. A, Figs. 1746, 1747, and 1748, represent the main framework, which consists of two cast-iron sides or frames, rising above and secured to the ends of a horizontal platform or table B. The main driving or crank shaft C, supported in suitable bearings arranged near the upper part of one side of the machine, is revolved by means of a spur geer D fixed upon one end of the shaft, and actuated by a toothed pinion, impelled by the driving power. E E are connecting-rods proceeding from bell cranks FF, (upon the shaft C,) and jointed to two of the four upright sweeps QQQQ, which carry the folders. These upright sweeps are suspended in a propersmanner at their tops, 80 as to be easily and alternately vibrated backwards and forwards. The two sweeps at each end of the machine are connected together at or near the middle of each by a bar G, while the movements of the sweeps that are connected to the crank shaft cause corresponding mo- tions of the other sweeps. The folders H H consist of two metallic plates or bars, having arms II ex- tending backwards and at right angles from them, which (arms) are so jointed to the lower ends of the sweeps as to permit the folders to have a vertical movement with respect to the sweeps. 1746. D 1749. F a a T 1750. z K H H of k s B 0 Z l T m K The latch or retaining bars which confine the folds of the cloth down upon the platform B are seen at KK. The first improvements consist in the mechanism by which the folders are alternately lifted from and depressed upon the cloth in order to lay it in successive folds upon the platform. At or near the centre of the inner side of each bar G a pulley L is arranged upon a pin M, projecting from the bar, the said pulley turning upon the said pin. Upon each of these pulleys a chain or band N passes, hav- ing its ends attached to collars 00, of two bent rods PP, each of which is jointed at one end to one of the sweeps QQ, (or moves upon a pin inserted horizontally therein,) in the position, as seen in Fig. 1748, and passes and moves freely at its other end through a vertical stud R, rising upwards from the arm of the folder. Each of the collars 00 should be movable upon its rod, and so arranged as to be con- fixed upon any desirable part of the rod by a set screw, so by moving the collars into suitable positions on their respective rods the folders may be balanced when in the centre of the machine. Each pulley has one end of a cam lever S attached to its side, and near its periphery, by means of a pin or stud a, upon which the lever works. The cam lever has a semicircular slot b and a straight slot c formed on its opposite end, as seen in Fig. 1748, and is connected to one of the sweeps Q by pins de, projecting from the inner side of the sweep, and passing through the grooves bc. The two cam levers extend from their respective pulleys in opposite directions to each other, being connected to the sweeps as in Fig. 1746. Now when the sweeps are moved to and fro by means of the crank shaft, the slots b and c in each of the levers will permit the levers to accommodate themselves to the motion of the sweeps. and to turn their pulleys L L around a short distance upon their axis, and thus gradually elevate one of the folders 85 Digitized by Google 674 FOLDING AND MEASURING MACHINE. above the platform, and the latch or retaining bar towards which the sweeps are moved, and at the same time depress the other folder towards the platform. During the elevation of either of the folders above the platform, the rods PP of the folder pass or move longitudinally through the studs R R, and 80 as to cause the collars 00 of the rods to approach towards the studs. So when either of the folders is depressed towards the platform, the rods PP of it move in the opposite direction through the studs RR of it, and carry the collars away from the studs. By this peculiar operation the balance of the folders is overcome, and that folder which is in immediate action upon the cloth, or which is pressing the same towards one of the retaining bars or latches, is depressed upon the cloth, and bears thereon with a slight force, and at the same time raises the other folder above the cloth and the retaining bar, towards which the depressed folder is proceeding. The next improvement consists in the mechanism by which the cloth is introduced into the machine, and the overlap of the first fold produced. It is customary, in folding piece goods by hand, to turn the end of the piece between the folds b and c, as seen at a, in Fig. 1749. By the ordinary folding machine, the same has been arranged in the order as seen in Fig. 1750. The placing the ends between the folds b and c, as in Fig. 1749, is what is termed the overlap of the first folds." A small horizontal shaft f, supported 80 as to revolve in suitable bearings, extends across the machine from one end of the frame to the other, in the position seen in Figs. 1746 and 1748. This shaft is put in revolution by a pulley 2, arranged upon one end, which (pulley) is driven by a band proceeding from the driving power, and the power which operates the shaft f should be 80 applied that it can be put in action and thrown out thereof at pleasure. There are two pulleys placed on the shaft f near its ends and at equal distances on each side of the centre of the shaft, one of these pulleys being represented in Fig. 1748, at h. 1747. r a Q Q n D 1 e 2 M 1 N A N P K R 02 P 1 di H B 0 M A series iklmnopq of pulleys, arranged in the positions with respect to each other, and the pulley i, as seen in Fig. 1748, and in the same vertical plane with one of the pulleys h, is disposed at each end of the machine, they being supported by suitable shafts extending across or projecting from the frame- work. Over each series of pulleys a band r passes, as seen in Figs. 1746 and 1748, and between the bands rr a metallic or wooden bar 8 extends, having its two ends attached to the band, as represented in Fig. 1746. Small hooks or pins tt and c are inserted in the upper edge of the bar, upon which (hooks) the end of the piece of cloth to be folded is hooked, 80 as to confine the said end to the bar. This being accom- plished, the shaft f is to be put in revolution so as to cause the bands r r and bar 8 to move in the direction denoted by the arrows in Fig. 1748, and the cloth into the machine until the bar 8 arrives at or near the point t, when the revolution of the shaft f is to be stopped. The cloth thus drawn in will pass over the horizontal shafts и v, and under the horizontal shaft w x. In its passage from the shaft w to the shaft x it passes beneath a horizontal rod or bar y, which is supported at its ends by bent arms zz, extending from the horizontal shaft x. Therefore, on turning the shaft x in its bearings, it causes the bar y to descend in a curved direction towards one of the retaining bars k, and to press or carry the cloth down with it, and to deposit it in a lap underneath the retaining bar. On unhooking the end of the piece of cloth from the points of the bar 8 and putting the folders in operation, the end of the cloth will be smoothed down upon the platform and then the overlap of the first fold will be produced. In its passage into the machine the piece of cloth passes over 2 feeding roller a', which is arranged in Digitized by Google FORCE. 675 the position denoted in the drawings, and moved by a belt or band b' passing around a small pulley c', (fixed on the axis or shaft of the feeding roller,) and a large pulley d' fixed upon one end of a horizon- tal shaft e', Figs. 1746, 1747, and 1748, which extends centrally under the platform from one end of the machine to the other, and has a bevelled pinion f fixed upon its opposite end, which (pinion) works into another bevelled geer wheel g' fitted upon the lower end of an inclined shaft h'. A bevelled geer i, fixed on the end of the crank shaft, imparts motion to the inclined shaft, by engaging with another bevelled geer H, fixed on the upper end of the shaft h. The central shaft e has two other shafts l' and m' ar- ranged horizontally on opposite sides of it, as seen in Fig. 1748, and extending from one end of the frame- work to the other. Each of the shafts Im has an arm n, (projecting from the centre in a direction to- wards the shaft e,) and two arms projecting in opposite directions from its end respectively, one of the latter arms being seen at O, Fig. 1748. Each of the retaining bars rests upon two of the arms O', by means of suitable guides of the retaining bar projecting vertically through the platform and resting upon the arms 00. The central arms n of the shafts I'm' are alternately depressed by cams or wipers p, fixed upon the central shaft; the depression of the said arms elevating the retaining bars. The surface of the roller a should move a very little faster than the cloth does, as it (the cloth) is drawn by the folders over the guide shafts w v in order that the portion of the cloth which is between the feeding roller a and the shaft u may hang loosely between the two rollers, and the feeding roller do all the work of drawing the cloth towards itself, and thus freeing the folders from the strain in consequence thereof; thereby enabling them to perform their operations with certainty and ease. 1748 m Q Q Lo T c F G o W N A A N R P o P R K H I H K B m c Having thus described the machine, Durgin claims the mechanism by which the folders are elevated and depressed, the same consisting of the pulley L, cam lever S, bent rods PP, chain or band N, and parts as before described, as combined with each other and applied to the folders and sweeps. Also the mechanism by which the cloth is introduced into the machine, and the 'overlap of the first fold" produced, the same consisting of the endless band rr, (with the pulleys and shafts arranged substan- tially as described,) and cross bar S, or machinery of similar character in combination with the depress- ing bar y. Also the peculiar method of feeding the cloth into the machine so as to present it to the action of the folders as required by them, and with little or no strain upon them, viz. by supporting the cloth on one or more horizontal rods or shafts u v, (placed above the folders,) in combination with giving to the sur- face of the feed rollers a motion sufficiently increased beyond that of the folders, to cause that part of the cloth which is between the supporting rod or rods and the feed roller to be loose or hang down in proper quantity, to readily yield to the irregular motion of the folders over the platform, caused by the cranks of the shaft which operates the sweeps of the said folders. FORCE. Force is the cause of motion or change of motion in material bodies. Every change of motion, viz. every change in the velocity of a body must be regarded as the effect of a force. On the other hand, rest, or the invariability of the state of motion of a body, must not be attributed to the ab- sence of forces, for opposite forces destroy each other and produce no effect. The gravity with which a body falls to the ground still acts, though the body rests; but this action is counteracted by the solidity of the material upon which it reposes. Forces that are balanced, 80 as to produce rest, are called statical forces or pressures, to distinguish them from moving, deflecting, accelerating, or retarding forces; i. C. such as are producing motion, or a Digitized by Google 676 FORCE. change in the direction or velocity of motion. This distinction is wholly artificial, for the same force may act in any of these modes; it may sometimes be a statical, and sometimes an accelerating force ; but it is convenient to confine our attention in the first instance to forces in a statical point of view. Statical forces can, of course, be compared only with each other, but the ratio between any two quan- tities may be represented by the ratio between two other quantities, however different in kind from the first two: thus, two pressures may have the same ratio as two lines, or two surfaces, or two bulks. or two times, or two numbers. Now, when we represent magnitudes of any kind by numbers, we in fact compare them with some fixed or standard magnitude of the same kind, which we represent by the number 1: thus, the units commonly used for comparing lengths, are inches, feet, miles, &c.; and so also the units of pressure are ounces, pounds, tons, &c. In strictness, however, these terms do not properly express units of pressure, but of mass, (or quantity of matter;) and they are used as standards of pressure simply because the earth's attraction on a given quantity of matter is always the same at the same place, and differs but slightly in different places. But the same mass, in a different situation, (as regards latitude, or level,) would gravitate with a rather greater or less pressure. Mass must not be confounded with weight, because the same names are applied to the units of both for, in fact, the units of pressure are quite distinct from, though founded on, those of mass; just as the latter are derived from those of length, and all from that of time; the connection being as follows:- 1. A pound pressure means, that amount of pressure which is exerted towards the earth, in the lati- tude of London and at the level of the sea, by the quantity of matter called a pound. 2. A pound of matter means a quantity equal to that quantity of pure water which, at the tempera- ture of 62° Fahrenheit, would occupy 27727 cubic inches. 3. A cubic inch is that cube whose side taken 39-1393 times would measure the effective length of a London seconds pendulum. 4. A seconds pendulum is that which, by the unassisted and unopposed effect of its own gravity, would make 86,400 vibrations in an artificial solar day, or 86163.09 in a natural sidereal day. Forces may also (like any other magnitudes) be represented by lines of definite lengths. A unit of length being taken to represent the unit of pressure, the length of the line represents the magnitude of the force but the line has this great advantage over a number,-its direction represents the direc- tion of the force; and its commencement or extremity, the point at which the force acts, or its point of application: thus, by a line, the force is completely defined in all its three elements; while a number can only represent one of them, viz. its magnitude. In this way forces can be brought under the domain of mathematical science, geometry serving to investigate their various relations by means of lines, arithmetic by means of numbers, and algebra and trigonometry by the properties common to directions and magnitudes of all kinds. If two forces be in equilibrium at a point; they must be equal in magnitude, and opposite in direc- tion. But whatever number of forces may act upon a point, and whatever their directions, they can only impart one single motion in one certain direction. We may, therefore, incorporate all these single forces into one force, or resultant, capable of producing the same mechanical effect as the forces them- selves, which are called the components. When any number of forces act at a point in the same straight line, and in the same direction, the resultant is equal to their sum; if the forces act in opposite directions, the resultant is equal to their difference. When two forces act upon a point in different directions, the resul- A tant is found more easily by the geometrical method. It is obvious, 1751. in the first place, that the line representing the resultant must lie in the same plane which contains the directions of the two forces for if a not, on which side of the plane should it lie 1 There is evidently nothing to determine it to one side more than the other. For the same reason, when the forces are equal, the resultant must bisect the angle between their directions, for it cannot be nearer one than the other. Moreover, in all cases, whether equal or not, the nearer they coincide in direction, the greater will be the resultant, and vice versa ; P C since their exact coincidence makes it equal their sum, while their ex- act opposition makes it equal their difference. But it is doubtful whether elementary mathematics will carry us further than this with- out the aid of experiment, which teaches us the following beautiful law. Let the point P, Fig. 1751, be acted on by two forces, pressing in the directions PA and PB. From the point P, upon the line P A, measure off any length Pa; and from the point P, upon the line P B, b take a length Pb bearing the same ratio to P a that the force B bears to the force A. The easiest way to do this is to make the lines Pa, Pb, contain respectively as many units of length (inches or feet, for B example) as the forces A B contain units of force, (ounces or pounds, for example.) Through a draw a line parallel to PB, and through b draw a line parallel to PA, these lines will meet at some point c. We thus get a parallelogram P and the line Pc, called its diagonal, will represent a single force acting in the direction PC, and consisting of as many units of force as the line Pc contains units of length; and this force will produce upon the point P the same effect as the two forces PA and PB produce acting together. This method of finding an equivalent, or the resultant of two forces, is called the parallelogram of forces, and is thus concisely expressed :- If two forces be represented, in magnitude and direction, by the sides of a parallelogram, an equivalent force will be represented, in magnitude and direction, by its diagonal." The two forces are called, the components of the resultant. Digitized by Google FORCE. 677 Any number of forces, acting at one point, can be compounded by the same rule. For instance, let the body x, Fig. 1752, be pressed at once by the three forces whose directions are expressed by the arrows A BC, and their magnitudes by the lengths x a, x b, xc. We may first compound any two of them, (such as A and B,) by completing the parallelogram x a db, by which we find that the direction of their resultant is x d, and that its magnitude is to their magni- 1752. tudes as the length x d is to the lengths xa, x b. We may then compound this resultant with the remaining force xc, by complet- a ing the parallelogram x dce, the diagonal of which, viz. xe, will represent both the magnitude and direction of the general result- ant of all three forces; so that a force of the magnitude expressed by this length xe, and acting in the direction e x, would balance those three forces. Of course the resultant of any greater number of pressures might have been found in the same way, by combin- ing two at a time. C In this problem it matters not whether the directions of the forces lie all in the same plane or in different planes. In the latter case, the three lines x a. x b, xc would form the three edges that meet at one solid angle of a parallelopiped; and by completing this solid figure, as shown by the outer dotted lines of Fig. 1752, its diagonal x e will represent the result- ant. Hence, whether we regard the lines of this figure as they really lie flat on the paper, or as the projection or picture of a solid parallelopiped, the law is equally true. The same process is of course capable of being extended to any number of forces in different planes. It would scarcely be possible to arrive at some of the simplest results of its application to every branch of physics, if recourse were not constantly had to the inverse problem of the resolution of forces. It is constantly necessary to consider a force as capable of being resolved into two or three distinct forces, having different directions; for it is evident that we may substitute for any given force, any num- ber of other forces, having any given directions, (not opposite to each other ;) for we may make the line L e the diagonal of any number of parallelograms, or parallelopipeds, having their sides running in any proposed directions. When their directions are decided on, their lengths will be discoverable : and thus we shall know both the directions and magnitudes of the forces into which, for convenience sake, the whole, or resultant force, has been resolved. Examples of the composition of forces are of constant occurrence, as in the exertions of our limbs, the action of the various tools and implements which we employ, and the external actions in which we par- ticipate. It is frequently of importance to consider whether the component forces are employed so as to produce the best resultant; that is, one acting in a direction most available for the object intended to be accomplished, and with as small an expenditure of force as possible. As a familiar illustration of the composition of forces, take the flying of a boy's kite. To counteract (permanently) the force of gravity which would bring it to the ground, two other forces at least are required-viz. the wind, and the resistance of the string or of the point where it is fixed or held. The wind alone would keep it suspended, but only for a time-viz. until the kite had either turned its edge to the wind, (so as to be pressed no more on the under than on the upper side,) or else had become vertical, so as to be pressed only horizontally and not upwards. If the kite had no tail, the former effect would rapidly ensue, and with a tail the latter would be equally certain. It is necessary, there- fore, that the kite be inclined, and this is effected by the string being attached at such a point as to leave more surface (and therefore, a greater pressure of wind) below the point of attachment than above it. This excess of pressure on the lower half drives it to leeward, but only to a certain extent, where it is counterbalanced by the weight of the tail. The horizontal force of the wind W, Fig. 1753, the inten- 1753. w s S sity of which is represented by the line 0 w, must be resolved into two portions, one parallel, and the other perpendicular to the surface. The former portion o a has no effect; the kite is pressed only by the other portion, in the direction o b, in which direction it would move, if it maintained its inclined po- sition, and were subject to no other force than the wind. But there are two other forces, the string and gravity. Supposing the string to pull in the direction S, we shall find the intensity of this force by resolving the whole effect of the wind on the kite represented by b, into two portions, o d perpen- dicular to the string, (and therefore not resisted by it,) and oc, which must be balanced by an equal and opposite force in the string, which will accordingly be represented by 0 & The action of the string and Digitized by Google 678 FORCE. wind alone would therefore be to urge the kite in the diagonal o d of the parallelogram o b but with this we must further compound the force of gravity, which (the kite being very light) we will re- present by the short line o g, and this, compounded with o d, gives the resultant o F, in which direction the kite will rise when subject to all three forces, in the degrees here supposed. If the wind suddenly cease, the resultant of the string and gravity is found by compounding o $ with og, which gives o e as the direction in which the kite would then be pulled; and this compounded with the effective portion of the wind's force, viz o b, will give 0 F as before. In this direction, then, the kite will, under these cir- cumstances, rise till it has attained a position where the three forces b, o 8, and og, are in equilibrium, i. 6. where each is equal and opposite to the resultant of the other two, in which case we should on our construction find o F= 0, or the point F would coincide with o. In order to raise the kite to its greatest altitude, the most advantageous angle for the kite to form with the horizon is 54° 44'; which is the same as the rudder of a ship should make with the keel, in order that the vessel may be turned with the greatest facility, supposing the current to have a direction parallel with the keel; and the same that the sails of a windmill, and the vanes of a smoke-jack or of a screw-propeller, should make with the plane of their rotation. Forces in a plane.-In order to find the mean force P for a system of forces P₁ P, P₃, &c. by the re- peated application of the parallelogram of forces, we may resolve them two and two and so on, till but a single force remains. The forces P₁ and P2, for example, give from the parallelogram M P₁ Q P2, the mean force MQ=Q; if this be joined to P2, we have from the parallelogram M Q R P2, M = R; and this last again forms a parallelogram with P. and gives the force M P = P the last, and the resultant of the four forces P₁ P, P, P4. It is not necessary, in this way of composing forces, to complete the parallelogram, and draw its diagonal. We may form a polygon M P₁ QRP, whose sides MP₁, P₁ Q, Q R, RP, are parallel and equal to the given components P, P, P, P4 the last side MP completing the polygon will be the mean force sought, or rather its measure. This simple and elegant theorem is called the Polygon of Forces. By this, any number of statical forces are represented in direction and magnitude by the sides of a polygon, taken in order; and they will, when applied to one point, produce equilibrium. 1755. 1754. R M d c b P. OLE H P N Q 0 R To make this theorem clearer, attach a number of pulleys to a vertical plane, such as an upright board, and carrying over them the lines which represent the forces, and attach weights to their ex- tremities, as in Fig. 1755. Then take any part A a on the string A m, and from a on the board, draw a line parallel to the string A n, and take a part a b upon that parallel, such that A a is to a b, as M is to N. Again, through b draw a parallel to the string A o, and on that parallel take a part b c such that ab is to b as N is to O. In like manner, draw c d parallel to A p, and such that bc : d : o : P; and draw d parallel with A q, and bearing the same relation to the other lines that Q bears to the other weights. Finally, join the points e and A by a right line. A single force R, acting in the direction of the line e A. and having the same ratio to each of the other forces as the line e A has to the side of the polygon, which is parallel to that other force, will produce a pressure on the fixed point A equivalent and opposite to the combined actions of the forces MNOPQ This may be proved by attaching any weights at random to the various strings, and (when they have settled in equilibrium) making the con- struction above described, beginning with any side of the polygon, and making all its sides, except one, parallel with their respective strings, and with lengths proportional to their respective weights. The remaining side will then be found to lie always in a straight line with the remaining string, and to have the exact length proportioned to the remaining weight. Parallel forces.-It is evident that forces may be made to act side by side with quite as much effect as in the same straight line. Two horses drawing a cart may of course be placed side by side, or one before the other, and the effect will be the same. Hence, the resultant of two parallel forces, acting in the same direction, is equal to their sum; it has the same direction with them, and when they are equal, is applied at a point midway between their points of application. But when they act in contrary di- rections, they have no simple resultant, for they tend to produce rotation, and this tendency cannot be counterbalanced by any single force. When two parallel but unequal forces are supported or balanced by a third, it must be equal to their Digitized by Google FORCE. 679 sum, it must act in the contrary direction, and must be applied at a point nearer the greater force than the less, its distances from them being inversely as their intensities. Thus, in Fig. 1756, when the three forces at B A and a are in equilibrium, B A the distance A a: the distance B a. 1756. When one point of a rigid body is supposed to be immov- ably fixed, the effect of any forces applied to that body can B n only be to turn it round the fixed point, as a centre of mo- tion; and when two points are fixed, the motion can only be round the line joining them, which thus becomes an axis. Now, as has been said above, two forces which tend to turn the body in contrary directions will be in equilibrium if their intensities are inversely as their distances from the centre or axis. But in every inverse proportion, the product of the first and second terms is equal to the product of the third and fourth; or the product of the first and third = that of the second and fourth. Thus, instead of saying that the forces A and B are inversely as the distances a A and a B, we may express the same thing by saying that the product of the force A X the distance a A = the product of the force B X the distance a B. Thus, if a straight bar be balanced, as in Fig. 1756, and, at the distance of one foot from its fulcrum, or point of support, a weight of 12 pounds be suspended, it will be found that this weight will be balanced by a weight of 6 pounds, distant 2 feet on the other side of the fulcrum; or by a weight of 4 pounds at the distance of 3 feet; or by a weight of 3 pounds at the distance of 4 feet. Now by multiplying these weights by the number of units (feet) representing the distances from the centre, we get in each case 12; thus 6 pounds at 2 feet = 12 pounds placed at 1 foot, or 6 X 2 = 12 X 1. In like manner, 4 pounds at 8 feet, or 4 X 3 = 12; and 3 pounds at 4 feet, or 3 X 4 = 12. These products are called the moments of the force. It is evident, also, that by increasing the number of forces on each side of the axis, the body will be in equilibrium, provided the sum of the moments of those forces which tend to turn it round in one direc- tion, be equal to the sum of the moments of the forces which tend to turn it round in the other direction. As this principle may be considered as the basis of mechanical science, it is desirable to illustrate it by another method. If two weights in equilibrium, as in Fig. 1756, at the extremities A and B of a bar supported on an axis a, passing through its centre of gravity, be made to oscillate gently through a small space, it is evident that the spaces moved through by the two ends of the bar will be directly as their distances from the axis; for, the angles A a m and B a n being equal, the arcs A m and B n, are as their radii a A and a B. For instance, if the weight B be 12 pounds, suspended at 3 inches from a, its moment may be expressed by the number 36; and it will be balanced by a weight of 6 pounds, 6 inches from a, because its moment is also 36. Now if these two weights be made to oscillate through a small space, such as B m for the weight which descends, and A n for the weight which ascends, the latter space will be only half the former, because it bears the same ratio to a B (or 8 inches) that A m bears to a A, (or 6 inches.) Hence, if B n be one ineh, A m will be two inches, and the products of these two quantities with their respective weights will be equal to each other; that is, the effect of 12 pounds moving through 1 inch, or of 6 pounds moving through 2 inches of space, is the same. And though we are not now concerned with motions, but with pressures, the same principle applies to them. Any two pressures, however un- equal, (a pressure of 1 pound and one of 1000 pounds, for instance,) will balance each other, if they are so applied that the motion of the first through 1000 inches would be necessarily accompanied by a mo- tion of the second through one inch, and vice versa. This principle is known under the name of the principle of virtual velocities, and is that which regu- lates the action and constitutes the efficacy of every machine in which power is employed to overcome weight or resistance. In the composition of machines it is usual to speak of six mechanical powers; namely, the lever, the wheel and axle, the pulley, the inclined plane, the wedge, and the screw; although in reality these contrivances are but applications of the principle of virtual velocities, whereby a small force acting through a large space, is converted into a great force acting through a small space. But in this there is no gain of power, neither is there any loss; the advantage is in its application. Every pressure acting with a certain velocity, or through a certain space, is convertible into greater pressure, acting with a less velocity, or through a smaller space; but the quantity of mechanical force is not altered by the transformation, and all that the mechanical powers can accomplish is to effect this trans- formation. Thus far we have regarded force simply as that which is necessary to oppose or balance force. We are now to consider it as the cause of change of motion. Force, in the sense in which we have already used it, is not required for the maintenance of motion, but only for its change-i. e. for effecting, 1st, a change of state from rest to motion, or from motion to rest; 2d, a change in the velocity of motion, either by accelerating or retarding it; or 3d, a change in its direction, by deflecting it upwards, downwards, to the right, or to the left. The inertia of matter is only another mode of impressing this idea. And since matter is inert, that is, has no tendency either to rest or motion, a body impressed with a motion must persist in that motion, in a straight line and with uniform velocity, for ever, unless some new force act upon it, either to change its state, its direction, or its velocity; for it cannot of itself change either its state of rest or its state of motion, its velocity, or its direction. This is inferred from experiments and observations on all the motions presented to our notice either in the heavens or on the earth, and is known to be true, because any other law which can be substituted for it will be incompatible with some or all of those motions. We are therefore to regard as being in equilibrium, not only such bodies as are at rest, but also such as are performing uniform rectilinear motion; for it is only while their velocity or direction is changing that the forces acting on them can produce a resultant pressure; and as long as this pressure remains Digitized by Google 680 FORCE. unbalanced, the motion will continue changing in velocity, or direction, or both; whenever it becomes straight and uniform, the resultant of all the forces acting on the body = 0. Thus, when a train or a steamboat has started, its velocity continues for a certain time to increase, because the forces that urge it forward exceed the friction in one case, or the resistance of the water against the bows of the boat in the other; but these opposing forces are dependent on the velocity and increase, because it increases so that they presently become equal to the forward force imparted by the engines, and then the motion becomes uniform, and the body, though moving at its full speed, is as completely in equilibrium as when it was at rest. Thus the motive power is required, not to maintain the motion, but to maintain equi- librium with the opposing friction or resistance. The motion is maintained because the body has been set in motion, and, being inert, has no tendency of itself to alter that state; and also because any alter- ation of velocity would, by increasing or diminishing the resistance, while the steam power remains unaltered, leave a portion of the former or of the latter unbalanced, and this unbalanced force, acting against or with the direction of the motion, would retard or accelerate it till the former velocity was re- established. Thus the equilibrium is stable, or tends, when disturbed, to restore itself. The dynamical effect of force being a change in motion, a continued force or pressure must produce a continuous change, whether in velocity or direction The simpler effect of a sudden change of velocity, or an angular deflection, can only be produced by an impact, or instantaneous exertion of force. The greater part of the forces which impart motion to a body act directly upon only a few of its molecules: thus, when a billiard ball is struck with the cue, we touch only a small portion of its surface. As all the parts of a body are set in motion by an impulse communicated to a few only of its mole- cules, it is clear that there must be a diffusion of motion from the parts acted on over all the other parts of the body before it can begin to move. When this is not the case, the part struck is compressed, or it is chipped off, and performs its journey alone, leaving the mass behind; but when the force has time to be propagated through all the particles, the body is then impressed with a motion common to all its particles. When a force has acted upon a body, and the motion has diffused itself over all the molecules, 80 as to impress them with a common velocity, the force has done its work; it has produced its effect, and may be said to have passed from the moving power, or source of motion, into the thing moved. Thus a stone projected by the hand, describes a certain path in space in obedience to the force which has acted upon it once for all, and then ceased, leaving the force thus impressed to do its work. Now, if the stone in its progress met with no other form of matter at rest or in motion-if, in short, no other force acted upon it, it would continue to move with the same velocity and in the same direction for- ever. But the same force does not produce the same effects on different bodies. The charge of powder capable of projecting a small shot, for example, may scarcely produce the slightest motion in a cannon ball. And it is an established principle in mechanics, that when the same force acts upon different bodies free to move, their velocities are in the inverse ratio of their masses, or of the quantity of matter of which they are composed. Thus the same charge of gunpowder which would project leaden balls whose volumes or masses were as 1, 2, 3, 4, &c, would impart velocities to them as the numbers 1, 1, 1. 1, &c.; hence it will be seen that the mass multiplied into the velocity gives in each case the same number: in the first case, 1 X 1=1; in the second, 2 X = 1, and 80 on. When there is no friction, the smallest impact is sufficient to impart motion to the largest mass; but only, of course, a very slow motion. This product of the mass of a moving body by its velocity, is called the momentum, or moving force, or quantity of motion. The same impact always gives the same quantity of motion, whatever may be the body which it impels; so that the true measure and characteristic of an instantaneous force or impact is the quantity of motion it is capable of imparting. Thus we may describe an impact by saying that it is equal to 50 pounds moved 1 foot per second, or 1 pound moved 50 feet per second, or 2 pounds moved 25 feet per second, &c., &c, all meaning the same thing. In ordinary language, the force of any moving body means its momentum, or the impact required to stop it, or to impart the same quantity of motion to a body previously at rest. But the useful effect is in most cases proportional, not to the momentum, but to the vis viva. Hence-1. When equal masses are in motion, their forces are proportional to their velocities. 2. When the velocities are equal, their forces are proportional to their masses, or quantities of matter. 3. When neither the masses nor velocities are equal, the forces are in the proportion of both taken jointly, that is, the proportion of their products. Thus the force of a moving body, or the work which it will perform in a given time, (that is, its mo- mentum,) varies as its velocity multiplied by its weight; but its whole accumulated force, or the total amount of work which it will perform, no matter in what time, in being brought to a state of rest, (that is, half its vis viva,) varies as the square of its velocity multiplied by its weight. In order to illustrate this, let us suppose a railway train of a certain weight in motion upon a perfectly level and straight railway, and let us assume that the resistances opposed to its motion are the same, whatever may be its velocity, the practical incorrectness of this assumption not affecting our present object. Imagine the velocity of the train to be fifteen miles per hour, and let it be desired to bring it to a state of rest at a station which it is approaching suppose that the engine driver, judging from experience, shuts off the steam at a distance of a mile from the station, and that the resistance experienced by the train in moving over this mile is just sufficient to bring it to rest at the station, the time occupied in passing over the mile being six minutes. Now if we again suppose the same train to be moving with a velocity of thirty miles per hour, and it be desired to stop at the station, then, the resistance being the same as before, it will in this case be necessary to shut off the steam at a distance of four miles from the station, in order that it may be brought to a state of rest there, and the time which the train will occupy in passing over these four miles will be twelve minutes. Again, let two bodies, both of the same weight, be projected upwards, one with double the velocity of the other, and suppose the resistance of the air removed, and only the force of gravitation, perfectly uniform in its action, to be opposed to the motion Digitized by Google FORCE. 681 of the bodies then will the body projected with twice the velocity rise to four times the height, against the same resistance, before being brought to a state of rest, but it will occupy, in doing so, twice the time similarly occupied by the slower body. When two masses moving in the same direction impinge one upon the other, and after impact move together, their common velocity may be determined by multiplying the numbers expressing the masses by the numbers which express the velocities; the sum of the two products thus obtained, divided by the sum of the numbers expressing the masses, will give a quotient expressing the required velocity. For example, if a musket-ball weigh one-twentieth of a pound, and its velocity on being fired be 1300 feet per second, if it strike a cannon-ball of 48 pounds, suspended by a string, it will set it in motion; and the common velocity of the two is to that of the bullet as 20 is to 48 + or as 1 is to 961; the 1300 common velocity of the two is, therefore, 961 or about 1} feet per second. When a musket-ball strikes against a large stone, or is fired at a mountain, it communicates both to the stone and the mountain a certain velocity, small indeed, and not measurable unless we knew the mass of the mountain in addition to other particulars. In fact, motion can only be destroyed by motion; resistances and friction disperse it, but do not destroy it. The resistance which a moving body meets with in the air, or in the water, is only an effect of the transference of motion. A body moving in water must constantly displace a portion of the fluid equal to its own bulk, and the amount of motion thus communicated to the water is 80 much lost by the moving body. It is generally admitted in such cases that the resistance is in proportion to the square of the velocity of the moving body. When the velocity is doubled, the loss of motion by resistance is quadrupled, because not only is there twice as much fluid to be moved in an equal time, but it has to be moved with twice the velocity. So also when the velocity is trebled. the moving body meets three times the number of particles, to which it communicates three times the velocity, thereby occasioning nine times the loss. The resistance to a body moving in water is, therefore, about 800 times greater than if it were moving with the same velocity in air, for it has to move 800 times as much matter in the same time. But if the motion in air were 28 times faster than in water, the resistance would be about the same, for 28 times the velocity generates 28 times 28 times times) the resistance. Action and reaction.-Action and reaction are equal and opposed to each other. This law not only prevails in reference to forces produced by contact, but also in the so-called forces of attraction and repulsion; amongst which the magnetic force and gravity itself may be ranked. The force with which the moon is attracted towards the earth (gravitation) is equal to that with which the moon reacts upon the earth. The force with which a workman draws or pushes at a machine, &c., reacts upon the workman and strives to move him in the opposite direction. When a body impinges against another, the pressures are reciprocally equal on each of the bodies. Effects of continued forces-uniformly accelerated motion.-One cannot fail to be struck with the different degrees of rapidity with which bodies fall through the air. A piece of gold falls rapidly. and a dry leaf very slowly; and the popular reason for this difference is, that the gold is heavy and the leaf light: this, however, is not the true reason, for if the gold be beaten out into a thin leaf, neither its absolute nor its specific weight is diminished, but the time of its descent through the air is greatly pro- longed. The fact is, that every body falling through a fluid is continually subject to two opposite forces; 1st, its weight, which is constantly uniform, and acting alone would constantly accelerate the fall, and 2d, the fluid resistance. Now the gold presenting a larger surface when beaten out than in the lump, far more resistance is opposed to the leaf than to a thick piece of equal weight, moving with equal velocity. The fall of a heavy body from a height is a uniformly accelerated motion, because the attraction of the earth, which is the cause of its fall, never ceasing to act, the body gains at each instant of its fall a new impulse, whereby it receives additional velocity, so that its final velocity is the aggregate of all the infinitely small but equal increments of velocity thus communicated. Hence, the velocity of a falling body at the end of two seconds is twice that which it had at the end of one; at the end of three seconds three times that which it had at the end of one, and so on. Now, it has been ascertained that a body falling freely through space by the force of gravity acquires at the end of the first second a velocity such as would carry it, without any assistance from gravity, through about 32 feet during the second second. This is the final velocity of the body after one second. But during this second, the body passes gradually from a state of rest through various increasing degrees of speed, until it acquires a velocity equal to 32 feet per second. Its average speed, therefore, during the whole first second will be the arithmetical mean between its starting velocity, which is 0, and its final velocity, which is 32 feet per second. This mean is 16 feet per second; consequently, the space actually fallen through during this one second must be 16 feet. During the second second, the body starting with the velocity of 32 feet acquired during the first second, falls through 32 feet, and also through another 16 feet due to the action of its weight during this one second only. At the end of the second second the final velocity is twice that at the end of the first second; 80 that during the third second the body would move through 64 feet, if subject to no force, i e., if its weight had ceased to act; but as this force continues to act, and would, during a second, move it through 16 feet, (if it had no velocity at starting,) the whole space described during this second will be 80 feet, viz., 64 feet by its previously acquired velocity, and 16 by that gradually added during this third second. Hence, it appears that the time occupied in falling, and the final velocity, are proportional to each other; and that an increase in one is necessarily attended by a proportional increase in the other. Now, we have seen that the average velocity, during any fall, is exactly half the final velocity, for it is the mean between the velocity at starting, viz. 0, and that final velocity hence, any increase in the time of falling, is attended by a proportional increase in the average speed during the whole fall. But the space fallen through is jointly proportional to the time occupied and the average velocity; consequently, 86 Digitized by Google 682 FORCE. when the time is increased in any proportion, (say doubled,) the body falls, not only twice as long, but also twice as fast, and must therefore fall through four times the distance. So, also, if one body falls three times as long as another, it also falls with three times the average speed, and consequently falls altogether nine times the distance. The distance fallen must always be proportional to the square of the time occupied. We thus get an easy rule for determining the space through which a body has fallen, simply by knowing the time occupied by the fall, and multiplying the square of this by the number of feet through which a body falls in one second. The same rule will apply to any number of seconds, whole or fractional. To show more clearly how this law is derived from the uniformity of the accelerating force, take the length of any figure to represent the time of the whole fall, which divide into any convenient number of parts; and make the breadth of the figure, at each of those divisions, represent the velocity at the cor- responding instant of the fall. Then the area of the figure, or of any portion thereof, will represent the distance fallen through during the corresponding part of the time for this distance is jointly propor- tional to the time and the average velocity, just as the area of a figure is jointly proportional to its length and its average breadth. Let us draw such a figure, then, in which the breadth at the commencement is 0, and increases uniformly, i. e. by equal additions, for equal additions to the length. By observing the relations between its breadths at different points, and also between the areas of the whole and different portions of it, and the areas they would have if their breadth continued equal throughout their length, we may learn all that has been stated above, by simply substituting time for length, velocity for breadth, and distance fallen for area. The following is an example:- A body falling freely during 5 seconds: Starting with a velocity 0 Ft. Tot. Fall. Falls during the 1st second 16 = 16 16 Acquiring a velocity of 32 feet per second. Falls during the 2d second 32+ 16 48 64 Acquiring a velocity of twice 32, or 64 feet per second. Falls during the 3d second 32+ 32+ 16 = 80 144 Acquiring a velocity of 3 X 32 = 96 feet per second. Falls during the 4th second 32+ 32+ 32+ 16 112 256 Acquiring a velocity of 4 X 32 = 128 feet per second. Falls during the 5th second 32+ 32+ 32+ 32+ 16 = 144 400 Acquiring a velocity of 5 X 32 = 160 feet per second. These laws are not confined to the motion of falling, but apply equally to every uniformly acceler- ated motion, i. e. every motion produced by an uniform force or pressure. In every such motion, the velocities, at any different instants, are proportional to the times elapsed since the beginning of the mo- tion; the average velocity is half the final velocity; the space described during successive equal inter- vals are as the series of odd numbers, 1, 3, 5, 7, &c.; and the whole spaces described from the begin- ning of the motion are as the squares of the times taken to describe them. But the numerical data will be different in each case of such motion; that is to say, the velocity acquired in a given time, or the time occupied in acquiring a given velocity, will vary in each case from the effects of fluid resist- ance and friction. To submit all the laws which have thus been expounded to the test of direct experiment, is the object of Atwood's machine, which see, Fig. 3. Uniformly retarded motion.-Whatever has been stated respecting uniformly accelerated motion, will be found equally applicable to the converse case of uniformly retarded motion. As in the former case the velocity increased by equal additions in equal times, so in this case it is reduced by equal losses in equal times; and if the force be the same, the velocity lost in any unit of time (such as a second) will be equal to that gained in a similar unit in the former case. Thus, when a body is pro- jected or thrown directly upwards, and then left to the action of gravity, it rises during any second 32 feet less than during the previous second, until its velocity is reduced to 0, and then to a motion in the contrary direction, when the same law continues unaltered, for the body gains (like any other falling body) 32 feet of downward motion per second. The composition of motions.-It is a physical law of great importance and simplicity, that the dyna- mical effects of forces are proportional to their statical effects. The same force which balances another force of twice the amount, will also, when unbalanced, produce twice as much motion; that is to say. it will either (I.) impart to twice as much matter the same velocity in the same time; or (II.) it will im- part to the same matter twice the velocity in the same time; or (III.) it will impart to the name matter the same velocity in half the time. It must be distinctly understood that this is a physical fact, or law of nature,-not a fact to be learnt by deduction, but by induction from experiments. The doctrine of the parallelogram of forces is applicable to the composition of motion. Thus, sup- pose the body x, as in Fig. 1752, to be acted on at once by three forces in the directions of the arrows ABC; that A acting alone would in one unit of time (such as a second, or an hour) drive the body to Digitized by Google FORCE. 683 a; that B acting alone (and being weaker than A) would in the same length of time drive the body no further than b; and that C, in like manner, acting alone, would cause it in the same length of time to reach c. Now, to find the effect of A and B united, complete the parallelogram x a db, and its further angle d is the point to which the body will be sent by the joint action of both A and B, in the same length of time that it would have occupied in reaching a by the action of A only, or in reaching b by the action of B only. This will be true, whether the two forces act both in the same manner or in different manners, however varied but in the latter case, although the body arrives at the point d just as soon, yet it will travel thither by a different route. In order that it may move along the straight line x d, it is necessary that the two forces act in the same manner; such, for example, as by an instan- taneous impulse, which will cause a uniform motion; or both may act continuously and uniformly, so as to produce a uniformly accelerated motion, (like that of falling bodies;) or both forces may act with a continually varying intensity, both increasing or diminishing at the same rate, and the motion will still be rectilinear. But if one force be instantaneous and the other continuous, or one uniformly con- tinued and the other varying in intensity, or both varying by different laws, 80 as not to preserve con- stantly the same ratio to each other, then the path of the body will be a curve, still, however, conducting it eventually to the point d, in the same time that the force A would have taken to send it to a, or B to b. But suppose the third force C to act on the body x, and to be capable of carrying it to c in the same time that A and B jointly would carry it to d. We have only to complete the parallelogram x d e c, to find that by the combined action of all three forces the body will be sent in the same unit of time to e. It is another remarkable consequence of this law, that whether we regard the directions of the three forces as being all in one plane, or in different planes, the law is equally true. This most important law as regards motions, may therefore be simply expressed in the following terms :-that by any number of forces acting together for a given length of time, a body is brought to the same place as if each of the forces, or one equal and parallel to it, had acted on the body separately and successively for an equal length of time. 1757. b k l a Let us now consider the effect of the composition of a uniform with a uniformly accelerated mo- tion, the two being in different but not opposite directions, as in the case of projectiles, i. e. bodies thrown horizontally, or obliquely. To simplify the questions, let us suppose them subject to no other force than gravity, which continually deflects them out of the straight line which they would otherwise describe, and which is called the line of projection. Now it matters not whether this line be horizontal, inclining upwards, or inclining downwards, it will constantly be found that the vertical depth of the pro- jectile below this line at any moment, is equal to the depth which it would have fallen during the time which has elapsed since its projection. Thus, if a cannon-ball be shot from A in the direction A b, Fig. 1757, and its original velocity be such as would carry it through the space A a during one second, then, if not subject to gravity, it would proceed in a straight line and arrive at a in one second, at b in two seconds, and 80 on. But gravity alone would cause it during the first second to fall 16 feet, (say from A to G.) By completing the parallelogram A a Gg, then. we see that after one second the body will have arrived at g, exactly as if it had first been carried by the projectile force during one second to a, and then fallen during one second to g. In the same way, during the next second, the ball moves in the direction of projection through the space a b, or g h, and in the direction of gravity through h 2 = 3 times 16 feet. In the third second it advances as much as before, viz. 2 i, and falls 5 times 16 feet, bringing it to the point 3. In the fourth and fifth seconds it advances in the direction 3 k, or 4 l, as much as in the first second, but falls 7 times and 9 times as much, thus arriving at the points 4 and 5. Now it results from this, that the points A, g, 2, 3, 4, 5, are necessarily situated on a curved line of that kind called a para- bola, and if the place of the ball at any other moments (however numerous) be found, all these points will likewise fall on the same curve. The distance from A, at which the ball again crosses the horizontal line A 5, is called the horizontal range. This will be the greatest possible, with a given velocity of projection, when the body is pro- jected at an angle of 45° with the horizon. In this case the greatest height attained is just one-fourth of the range. So that. as the time of flight is twice the time of falling that height, (or the exact time of falling four times that height,) the ball arrives at its destination in the same time as if it had fallen a like distance vertically by the action of gravity. Hence the range (in feet) is 16 times the square of the number of seconds in the flight. It is also remarkable that the range will be diminished equally by equal deviations from this angle, whether above or below it. Thus a mortar will (with the same charge) carry to the same distance, on a level plain, when it is inclined 40° as when inclined 50°; or the same at 10° as at 80°. We have hitherto regarded gravity as a parallel force. But if the range of a projectile amounted to some miles, 80 as to bear a measurable ratio to the earth's radius, it would be necessary, in finding its Digitized by Google 684 FORGE. path very exactly, to regard it as a central force, by making the lines A G, a g, b2, i 3, k 4, 1 5, no longer parallel, but such would, if continued, meet at the earth's centre. The effect of this change is to convert the parabola into one extremity of a very long and narrow ellipse, whose other extremity passes round the earth's centre, and has its focus at that centre. Such, indeed, is the curve described by every projectile. It is in this manner, then, that the moon revolves in an ellipse of small eccentricity, of which one focus is occupied by the earth's centre. Her deflection from the straight line is due to a force exactly with that which deflects a projectile; which force varies in intensity inversely as the square of her distance from the earth's centre varies. Now, if we calculate in this manner her deflection or fall, supposing her situated at our own distance from the earth's centre, we shall find it would be exactly 16 feet in a second, 64 feet in two seconds, &c., &c., like that of our projectiles or falling bodies. The observance of exactly the same laws in the motions of the satellites of the great planets, shows that a force of the same kind is exerted towards their centres. Moreover, it has been established by the joint labors of the two Herschels, that the same force regulates the motions of the immeasurably distant double stars. It appears, then, that attraction or gravity is a universal property common to all matter, every par- ticle in the universe attracting every other particle; and there is no irregularity in the motions of the bodies of the solar system, no deviations appreciable by the most delicate astronomical observations, which has not been explained, and its period and amount accurately calculated on the principles of uni- versal gravitation, according to the laws discovered by Kepler. Central force.-The tendency which bodies in motion have to recede from its centre is called the centrifugal force: the tendency to approach the centre of motion, is called the centripetal. The central force of a body describing a circle with a uniform velocity is directly proportional to the square of the velocity, and inversely as the radius of the circle. The doctrine of central forces has its practical application in astronomy; the force by which the planets describe their orbits is a central force, directed to the sun as a centre; and the forces by which the planetary motions are sustained, vary inversely as the squares of the distances of the planet from that body. In the case of fly-wheels, the succeeding rules will be found sufficient: (A.) velocity X weight = centrifugal force. radius X 32 (B.) Divide the velocity by 401, square the quotient, and divide by the diameter: this last quotient multiplied by the weight, will give the centrifugal force. (C.) Number of revolutions per minute X diameter X weight = the 5870 centrifugal force. (D.) velocity 2 X radius. centrifugal force X (E.) radius X centrifugal velocity force X 32 = weight. (F.) radius X centrifugal force X 32 = the velocity. weight The following examples will illustrate the application of these rules. What is the centrifugal force of the rim of a fly-wheel moving with a velocity of 321 feet in a second, and whose diameter is 20 feet. (By B.) 4:01 321 = 8.02 then 20 = 3-216, which multiplied by the weight of the rim, will give the 8-02" centrifugal force. A grindstone makes 120 revolutions in the minute, the radius of the circle of its motion being 2 feet, and its weight 6 pounds. (By C.) 120² X 4 57600 5870 X 6 = 5870 X 6 = 981 X 6 = 58.86 = the centrifugal force. A fly-wheel makes 65 revolutions per minute, its diameter being 12 feet, and the weight of the rim one-ton, the weight of the entire fly being 11 tons, the circle of gyration is 5.5 feet from the axis, the wheel consisting of two halves joined by bolts capable of resisting a pressure of 4 tons, wherefore, 12 X 3.1416 X 65 = 40.84 = velocity in feet per second. 60 And (by A.) 40.84' X X 6 = 8688 tons, the centrifugal force. 1 32 And (by F.) 32 X 4 X 5.5 X 1408 = 30-638, and since 2 X 55 X 3.1416 = 345576 = 1.5 1.5 the circle of gyration, therefore, 345576 638 X 60 = 59.197, the number of revolutions per minute, which would cause the fly to burst asunder. FORGE. The workshop in which iron is hammered and shaped by the aid of heat. The term is generally applied to the places in which these operations are carried on upon the comparatively small scale; the great workshops in which iron is made malleable for general purposes being called a Digitized by Google FORGING. 685 shingling mill. A common forge consists of the hearth or fireplace, which is merely a cavity in masonry or brickwork well lined with fine clay or brick, upon which the ignited fuel is placed, and upon the back or side of which a powerful blast of air is driven in through the nozzle of a double-blasted bellows, which, in a common forge, is generally worked by a hand lever. Forges are sometimes con- structed 80 as to be portable, when the bellows is most conveniently placed under the hearth; these are used in ships, and for various jobs on railways, &c. FORGING-Iron and steel. The heaviest works are generally heated in air furnaces of various descriptions, some of which resemble, but greatly exceed in size, those employed in the works where iron is manufactured, and in which the process of forging may be truly considered to commence with the first blow given upon the ball, as it leaves the puddling furnace for being converted into a bloom. The paddle-shafts of the largest steamships are wrought by successive additions at the one end, as follows: A slab of iron, technically called a use," is welded on one side close to the end, and when drawn down to the common thickness, the additional matter becomes thrown into the length; the next use is then placed on the adjoining side of the as yet square shaft, and also drawn into the length, and so on until the full measure is attained. First, the heat" has a long iron rod attached to it in continuation of its axis, to serve as a porter" or guide rod the mass is suspended under a traversing crane at that point where it is nearly equipoised; the crane not only serves to swing it round from the fire to the hammer, but the traverse motion also moves the work endways upon the anvil, and small changes of elevation are sometimes effected by a screw adjustment in the suspending chain. The circular form is obtained by shifting the work round upon its axis by means of a cross level fixed upon the porter, and moved by one or two men, so as to expose each part of the circumference to the action of the helve; this is readily done as the crane ter- minates in a pulley, around which an endless band of chain is placed, and the work lies within the chain, which shifts round when the work is turned upon the anvil. A similar mode of work is adopted on a smaller scale for many of the spindles, shafts, and other parts of ordinary mechanism, which are forged under the great hammer, often of several bars piled together and fagoted; a suitable term, as they are frequently made of a round bar in the centre, and a group of bars of angular section, called mitre iron, around the saine, which are temporarily wedged within a hoop, somewhat after the manner of a fagot of wood. Such works are also made of scrap-iron. A number of these fragments are enveloped in an old piece of sheet-iron, and held together by a hoop; the mass is raised to the welding heat in a blast or air furnace, and the whole is consolidated and drawn down under the tilt-hammer; one long bar that serves as the porter being welded on by the first blow. The mingling of the fibres in the scrap-iron is considered highly favorable to the strength of the bar produced. The scrap-iron is sometimes twisted during the process of manufacture, to lay all the filaments like a rope, and prevent the formation of spills, or the longitudinal dirty seams found on the surface of inferior iron. The long furnaces are particularly well suited to straight works and bars, but when the objects get shorter and of more complex figures, the open fire or ordinary smith's hearth is employed. This, when of the largest kind, is a trough or pit of brickwork about six feet square, elevated only about six inches from the ground; the one side of the hearth is extended into a vertical wall leading to the chimney, the lower end of which terminates in a hood usually of stout plate iron, which serves to collect the smoke from the fire. The black wall of the forge is fitted with a large cast-iron plate, or a back, in the centre of which is a very thick projecting nozzle also of iron, perforated for admitting the wind used to urge the fire; the aperture is called the tuyere. The blast is sometimes supplied from ordinary bellows of various forms; at other times by enormous air-pumps, which lead into a cylinder or regulator, the piston of which is loaded with weights, so as to force the air through pipes all over the smithy, and every fire has a valve to regulate its individual blast; but the more modern and general plan is the revolving fan, also worked by the engine, the blast from which is similarly distributed. In some cases the cast-iron forge back is made hollow, that a stream of water may circulate through it from a small cistern; the water-back is thereby prevented from becoming 80 hot as the others, and its durability is much increased. In other cases the air, in its passage from the blowing apparatus, flows through chambers in the back plate 80 as to become heated in its progress, and thus to urge the fire with hot blast, which is by many considered to effect a very great economy in the fuel. Some heavy works of rather complex form, such as anchors, are most conveniently managed by hand forging; many of these require two gangs of men with heavy sledge hammers, each consisting of six to twelve men, who relieve each other at short intervals, as the work is exceedingly laborious. The square shanks of anchors are partly forged under a vertical hammer of very simple construction, called a 'monkey." It consists of a long iron bar running very loosely through an eye or aperture several feet above the anvil, and terminating at foot in a mass of iron, or the ram. The hammer is ele- vated by means of a chain, attached to the rod and also to a drum overhead, which is put into geer with the engine, and suddenly released by a simple contrivance, when the hammer has reached the height of from two to five feet, according to circumstances. The ram is made to fall upon any precise spot within a horizontal range of some twenty inches from the central position by two slight gye-rods, hooked to the ram and placed at right angles. This contrivance is far more effective than the blows of the sledge hammers, and although now but little used is perhaps more suitable to such purposes than the helve or lift hammer, which always ascends to one height, and falls upon one fixed spot. Nasmyth's steam hammer is now almost entirely used in forging anchors: it has very much shortened the process, and makes more perfect work. The square shank of the anchor, and works of the same section, are readily shifted the exact quarter circle, as the sling-chain is made with flat links, each a trifle longer than the side of the square of the work, which therefore bears quite flat upon one link, and when twisted it shifts the chain the space of a link, and rests as before. Digitized by Google 686 FORGING. Many implements and tools, such as shovels, spades, mattocks, and cleavers, are partly forged under the tilt-hammer the preparatory processes, called moulding, which include the insertion of the steel, are done by ordinary hand forging. The objects are then spread out under the broad face of the tilt- hammer, the workman in such cases being sometimes seated on a chair suspended from the ceiling. and by paddling about with his feet, he places himself with great dexterity in front or on either side of the anvil with the progressive changes of the work; the concluding processes are mostly done by hand with the usual tools. A similar arrangement is also adopted in tilting small sized steel With the reduction of size in the objects to be forged, the number of hands is also lessened, and the crane required for heavy work is abandoned for a chain or sling from the ceiling; but for the majority of purposes two men only are required, when the work is said to be two-handed. As the works to be forged become smaller, the hearth is gradually lessened in size, and more elevated, so as to stand about two and a half feet from the ground it is now built hollow, with an arch beneath serving as the ash-pit. . The single hearths are made about a yard square, and those forges which have two fires under the same hood, measure about two yards by one; a double trough to contain water in the one compartment and coals in the other, is usually added, and the ordinary double bellows are used. Figs. 1765 and 1758 are called flat-bit tongs these are either made to fit very close as in Fig. 1758, for thin works, or to stand more open as in Fig. 1765, for thicker bars, but always parallel: and a ring or coupler, is put upon the handles or reins, to maintain the grip upon the work. Others of the same general form are made with hollow half-round bits; but it is much better they should be angular, like the ends of Fig. 1759, as then they serve equally well for round bars, or for square bars held upon their opposite angles. Tongs that are made long, and swelled open behind, as in Fig. 1759, are very excellent for general purposes, and also serve for bolts and similar objects, with the heads placed inward. The pincer tongs, Fig. 1760, are also applied to similar uses, and serve for shorter bolts. 1759. 1762. 1760. 1764. 1763. 1758. 1761. 1765. Flg. 1761 represents tongs much used amongst the cutlers; they are called crook-bit tongs; their jaws overhang the side, so as to allow the bar of iron or steel to pass down beside the rivet, and the nib at the end prevents the rod from being displaced by the jar of hammering. Fig. 1762. or the ham- mer tongs, are used for managing works punched with holes, such as hammers and hatchets; as the pins enter the holes and maintain the grasp. Fig. 1763, or hoop tongs, are very much used by ship-smiths, for grasping hoops and rings, which may be then worked either on the edge, when laid flat on the anvil, or on the side, when upon the beak-iron; and lastly, Fig. 1764 represents the smith's pliers, or light tongs, used for picking up little pieces of iron, or small tools and punches. In addition to the hearth, anvil, and tongs, the smithy contains a number of chisels, punches, and swages or striking tools, called also top and bottom tools, of a variety of suitable forms and generally in pairs; these may be considered as reduced copies of the grooves turned in the rollers, and occasion- ally made on the faces of the tilt-hammers of the iron-works for the production of square, flat, round, T-fonn iron, angle iron, and railway bars, as referred to. In fitting the hazel-rods to the top tools, the rods are alternately wetted in the middle of their length, and warmed over the fire to soften them; that portion is then twisted like a rope, and the rod is wound once round the head of the tool, and retained by an iron ferrule or couples; a rigid iron handle would jar the hand. When these tools are used for large works, a square plate of sheet-iron, with a hole punched in the middle of it, is put on the rod towards the tool, to shield the hand of the workman from the heat; and it not unfrequently happens with such large works that the rod catches fire, and the tool is then dipped at short intervals in the slake trough to extinguish it. The smith who works without any helpmate is much more circumscribed as to tools, and he is from necessity compelled to abandon all those used in pairs, unless the upper tools have some mechanical guide to support and direct them. In addition to the anvil he only uses the fixed cutter and heading tools; he may occasionally support the end of the tongs in a hook attached to his apron-string, or sus- pended from his neck, whilst he applies a hand-chisel, a punch, or a name-mark in the left hand, and strikes with the hammer held in the right. Attempts to work small tilt-hammers with the foot have been found generally ineffective, as the attention of the individual is too much subdivided in managing the whole, neither is his strength sufficient for a continued exertion at such work; but the " Oliver" is one of the best tools of this class. Digitized by Google FORGING. 687 A portable forge of suitable dimensions for single hand-forging, and made entirely of iron, is repre- sented in Fig. 1766. The bellows are placed beneath the hearth and worked by a treadle. This forge is also occasionally fitted with a furnace for melting small quantities of metal, and with various apparatus for other applications of heat, such as soldering, either with a small charcoal fire, or a lamp and blow-pipe, which are likewise urged with the bellows. These applications, and also that of hardening and tempering tools, are much facilitated by the bellows being worked with the foot, as it leaves both hands at liberty for the management either of the work or fire. The forge represented is sufficiently powerful for a moderate share of those works which require the use of the sledge- 1766. hammer. The ordinary fuel for the smith's forge is coal, and the kinds to be preferred are such as are dense and free from metallic matters, as these are generally accom- panied with sulphur, which is highly detrimental. In forging, the iron or steel is in almost every case beated to a greater or less degree, to make it softer and more malleable by lessening its cohe- sion; the softening goes on increasing with the accession of temperature, until it arrives at a point beyond that which can be usefully employed, or at which the material, whether iron or steel, falls in pieces under the blows of the ham- mer, but which degree is very different with various materials, and even with varieties bearing the same name. Pure iron will bear almost unlimited degree of heat the hot-short iron bears much less, and is in fact very brittle when heated other kinds are interme- diate. Of steel, the shear-steel will gen- erally bear the highest temperature, the blistered-steel the next, and the cast- steel the least of all but all these kinds, especially cast-steel, differ very much according to the processes of man- ufacture, as some cast-steel may be readily welded, but it is then somewhat less certain to barden perfectly. The smith commonly speaks of five degrees of temperature, namely: The black-red heat, just visible by daylight; The low-red heat; The bright-red heat, when the black scales may be seen; The white heat, when the scales are scarcely visible; The welding heat, when the iron begins to burn with vivid sparks. Steel requires on the whole very much more precaution as to the degree of heat than iron; the temperature of cast-steel should not generally exceed a bright-red heat, that of blistered and shear-steel that of a moderate white heat. Although steel cannot in consequence be 80 far softened in the fire as iron, and is therefore always more dense and harder to forge, still from its superior cohesion it bears a much greater amount of hard work under the hammer, when it is not over-heated or burned but the smallest available temperature should be always employed with this material, as in fact with all others. The cracks and defects in iron are generally very plainly shown by a difference in color at the parts when they are heated to a dull red this method of trial is often had recourse to in examining the soundness both of new and old forgings. When a piece of forged work is required to be particularly sound, it is a common practice to subject every part of the material in succession to a welding heat, and to work it well under the hammer, as a repetition of the process of manufacture to ensure the perfection of the iron: this is technically called, taking a heat over it; in fact, a heat is generally understood to imply the welding heat. For a two- inch shaft of the soundest quality, two and a half inch iron would be selected, to allow for the reduc- tion in the fire and the lathe; some also twist the iron before the hammering to prevent it from be- coming " spilly." The use of sand sprinkled upon the iron is to preserve it from absolute contact with the air, which would cause it to waste away from the oxidation of its surface. and fall off in scales around the anvil. If the sand is thrown on when the metal is only at the full red heat, it falls off without adhering but when the white heat is approached, the sand begins to adhere to the iron; it next melts on its surface, over which it then runs like fluid glass, and defends it from the air when this point has been rather exceeded, so that the metal nevertheless begins to burn with vivid sparks and a hissing noise like fireworks, the welding temperature is arrived at, and which should not be exceeded. The sparks are, Digitized by Google 688 FORGING. however, considered a sign of a dirty fire or bad iron, as the purer the iron the less it is subject to waste or oxidation in the course of work. In welding two pieces of iron together, care must be taken that both arrive at the welding heat at the same moment; it may be necessary to keep one of the pieces a little on one side of the most intense part of the fire, (which is just opposite the blast,) should the one be in advance of the other. In all cases a certain amount of time is essential; otherwise, if the fire be unnecessarily urged, the outer case of the iron may be at the point of ignition before the centre has exceeded the red heat. In welding iron to steel, the latter must be heated in a considerably less degree than the iron, the welding heat of steel being lower from its greater fusibility but the process of welding will be sepa- rately considered under a few of its most general applications, when the ordinary practice of forging has been discussed, and to which we will now proceed. The general practice of forging works from the bar of iron or steel, are for the most part included in the three following modes; the first two occur in almost every case, and frequently all three to- gether; namely, By drawing-down, or reduction: By jumping or upsetting, otherwise thickening and shortening: By building-up, or welding. To meet the variety of cases which occur, the smith has hammers in which the panes are made in different ways, either at right angles to the handle, parallel with the same, or oblique. In order to obtain the same results with more precision and effect, tools of the same characters, but which are struck with the sledge-hammer, are also commonly used: those with flat faces are made like hammers, and usually with similar handles, except that for the convenience of reversing them they are not wedged in these are called set-hammers others which have very broad faces, are called flat- ters; and the top tools with narrow round edges like the pane of the hammer, are called top-fullers; they all have the ordinary hazel-rods. When the sides of the object are required to be parallel, and it is to be reduced both in width and thickness, the flat face of the hammer is made to fall parallel with the anvil, as represented in Fig. 1767; or oblique for producing taper pieces, as in Fig. 1768; and action and reaction being equal, the lower face of the work receives the same absolute blow from the anvil as that applied above by the hammer itself; it is not requisite, therefore, (for works of moderate dimensions,) to present every one of the four sides to the hammer, but any two, at right angles to each other. The smith must acquire the habit of feeling when the bar lies perfectly flat upon the anvil, by hold- ing it slenderly, leaving it almost to rotate in his grasp, or in fact to place itself. Next he must cause the hammer to fall flat upon the work. It would be desirable practice to hammer a bar of cold iron, or still better, one of steel, as there would be more leisure for observations; the indentations of the hammer could be easily noticed; and if the work, especially steel, were held too tightly, or without resting fairly on the anvil, it would indicate the error by additional noise and by jarring the wrist; whereas, when hot, the false blows or positions would cause the work to get out of shape, without such monitorial indications. 1769 1767. 1768. As to the best form of the hammer, there is much of habit and something of fancy. The ordinary hand-hammer is represented in Figs. 1767 and 1768; but cutlers, and most tool makers, prefer the hammer without a pane, or narrow edge, and with the handle quite at the top, the two forming almost a right angle, or from that to about eighty degrees; and sometimes the head is bent like a portion of a circle. Similar but much heavier hand-hammers, occasionally of the weight of 12 or 14 pounds, are used by the spade-makers for planishing; but the work being thin and cold, the hammer rises almost exclusively by the reaction, and requires little more than guidance. Again, the farriers prefer for some parts of their work, a hammer the head of which is almost a sphere; it has two flat faces, one rounded face for the inside of the shoe, and one very stunted pane at right angles to the handle, used for drawing down the clip in front of the horse-shoe; in fact, nearly a small volume might be written upon all the varieties of hammers. Suppose it required to draw down six inches of the end of a square or rectangular bar of iron or steel; the smith will place the bar across the anvil with perhaps four inches overhanging, and not resting quite flat, but tilted up about a quarter or half an inch at the near side of the nnvil, as in Fig. 1768, but less in degree, and the hammer will be made to fall as there shown, except that it will be at a very small angle with the anvil. In smoothing off the work, the position of Fig. 1767 is assumed; the work is laid flat upon the anvil, and the hammer is made to fall as nearly as possible horizontally; a series of blows are given all along the work between every quarter turn, the hammer being directed upon one spot, and the work drawn gradually beneath it. In drawing down the tang or taper-point of a tool, the extreme end of the iron or steel is placed a little beyond the edge of the anvil, as in Fig. 1768, by which means the risk of indenting the anvil is entirely removed, and the small irregular piece in excess beyond the taper is not cut off until the Digitized by Google FORGING. 689 tang is completed. Fig. 1769 shows the position of the chisel in cutting off the finished object from the bar of which it formed a part; that is, the work is placed between the edge of the anvil and that of the chisel immediately above the same; the two resemble in effect a pair of shears. When it is required to make a set-off, it is done by placing the intended shoulder at the edge of the anvil: the blows of the hammer will be effective only where opposed to the anvil, but the remainder of the bar will retain its full size and sink down, as represented in Fig. 1770. Should it be necessary 1772. 1770. 1771. 0 to make a shoulder on both sides, a flat-ended set-hammer, struck by the sledge, is used for setting down the upper shoulder, as in Fig. 1771, as the direct blows of the hammer could not be given with so much precision. In each of these cases some precaution must be observed, as otherwise the tools, although 80 much more blunt than the chisel, Fig. 1769, will resemble it in effect, and cripple or weaken the work in the corner on this account the smith's tools are rarely quite sharp at the angles: this mischief is almost removed when the round fullers, Fig. 1772, are used for reducing the principal bulk, and the sharper tools are only employed for trimming the angles with moderate blows. When the iron is to be set down, and also spread laterally, as in Fig. 1773, it is first nicked a with a round fuller as upon the dotted line at a, 1773. and the piece at the end is spread by the same tool, upon the short lines of the object, or paral- lel with the length of the bar: the first notch greatly assists in keeping a good shoulder at the bottom of the part set down, and the lines are supposed to represent the rough indentations of the round fuller before the work is trimmed up. There is often considerable choice of method in forging, and the skilful workman selects that method of proceeding which will produce the result with the least portion of manual labor. Figs. 1775, 1776, and 1777, explain these processes of making an ordinary screw-bolt; the latter is a single tool, but the heading-tool, Fig. 1778, with several holes, is also used. In upsetting the end of the work, if more convenient, it may be held horizontally across the anvil, and struck on the heated extremity with the hand-hammer; or it can be jumped forcibly upon the anvil, when its own weight will supply the required momentum. If too considerable a portion of the work is heated, it will either bend, or it will swell generally; and therefore to limit the enlargement to the required spot, should the heat be too long, 1774. 1777. 1781. the neighboring part is partially cooled by immer- 1778. sing it in the water-trough, as near to the heat as admissible. 1776. A bolt may be made by building up or weld- 1775. ing :-An eye is first made at the end of a small rod of square or flat iron by bending it round the beak-iron, as in Fig. 1779, it is placed around the 1780. rod of round iron, and the curled end is cut off with the chisel, as in Fig. 1780, enough iron being left in the ring, which is afterwards welded to the rod to form the head of the bolt, by a few quick light blows given at the proper heat; the bolt is then 1779. completed by any of the tools already described that may be preferred. A swage at the angle of sixty degrees, Fig. 1781, will be found very couve- nient in forming hexagonal heads, as the horizontal blow of the hammer completes the equilateral tri- angle, and two positions operate on every side of the hexagon; Fig. 1781 is essential likewise in forging triangular files and rods. For the parts of mechanism in which a considerable length of two different sections or magnitudes of iron are required, the method by drawing down from the large size would be too expensive; the method by upsetting would be impracticable; and therefore a more judicious use is made of the iron store, and the object is made in two parts, of bars of the exact sections respectively. The larger bar is reduced to the size of the smaller, generally upon the beak-iron with top fullers, and with a gradual transition or taper extending some few inches, as represented in Fig. 1782; the two pieces are scarfed or prepared for welding. Fig. 1782 is also intended to explain two other proceedings very commonly required in forging. Bars are bent down at right angles as for the short end or corking of the piece, Fig. 1782, by laying the work on the anvil, and holding it down with the sledge-hammer, as in Fig. 1783; the end is then bent with the hand-hammer, and trimmed square over the edge of the anvil; or when more precision 87 Digitized by Google 690 FORGING. is wanted, the work is screwed fast in the tail-vice, which is one of the tools of every smith's shop, and it is bent over the jaws of the vice. When the external angle, as well as the internal, is required to be sharp and square, the work is reduced with the fuller from a larger bar to the form of Fig. 1784, to compensate for the great extension in length that occurs at the outer part, or heel of the bend, of which the inner angle forms as it were the centre. The holes in Fig. 1782 for the cross-bolts are made with a rod-punch, which is driven a little more than half way through from the one side whilst the work lies upon the anvil, 80 that when turned over, the cooling effect of the punch may serve to show the place where the tool must be again ap- plied for the completion of the hole; the little bit or burr is then driven out, either through the square hole in the anvil that is intended for the bottom tools, or else upon the holster, Fig. 1785, a tool faced with steel, and having an aperture of the same form and dimensions as the face of the punch. 1783. 1782. MM The 1785. 1786. 1787. 1788. 1784. 1789. Fig. 1788 shows the ordinary mode of making the square nuts for bolts. A flat bar is first nicked on the sides with the chisel, then punched, and the rough nuts, if small, are separated and strung upon the end of the poker, (a slight round rod bent up at the end,) for the convenience of managing them in the fire, from which they are removed one at a time when hot, and finished on the triblet, Fig. 1789, which serves both as a handle, and also as the means of perfecting the holes. For making hexagon nuts, the flat bar is nicked on both edges with a narrow round fuller; this gives A nearer approach to the hexagon: the nuts are then flattened on the face, punched, and dressed on the triblet within the angular swage, Fig. 1781, before adverted to. Thick circular collars are made precisely in the same way, with the exception that they are finished externally with the hammer, or between top and bottom rounding tools of corresponding diameter. It is usual in punching holes through thick pieces, to throw a little coal-dust into the hole when it is partly made, to prevent the punch sticking in so fast as it otherwise would the punch generally gets red-hot in the process, and requires to be immediately cooled on removal from the hole. In making a socket, or a very deep hole in the one end of a bar, some difficulty is experienced in getting the hole in the axis of the bar, and in avoiding to burst open the iron; such holes are produced differently, by sinking the hole as a groove in the centre of a flat bar by means of a fuller; the piece is cut nearly through from the opposite side, folded together lengthways, and welded. The hole thus formed will only require to be perfected by the introduction of an appropriate punch, and to be worked on the outside, with those tools required for dressing off its exterior surface, whilst the punch remains in the hole to prevent its sides from being squeezed in this method is very good. For punching square holes, square punches and bolsters are used, and Fig. 1786, the split bolster, is employed for cutting out long rectangular holes or mortises, which are often done at two or more cuts with an oblong punch. When a thick lump is wanted at the end of a bar, it is often made by cutting the iron nearly through and doubling it backwards and forwards, as in Fig. 1787; the whole is then welded into a solid mass as the preparatory step. 1790. 1791. A piece with three tails, such as Fig. 1790, is made from a large square bar an elliptical hole is first punched through the bar, and the remainder is split with a chisel, as in Fig. 1791, the work at the time being laid upon a soft iron cutting plate in order to shield the chisel from being driven against the hardened steel face of the anvil; the end is afterwards opened into a fork, and moulded into shape over the beak-iron, as indicated by the dotted lines. Such a piece as Fig. 1790, if of large dimensions, would be made in two separate parts, and welded through the central line or axis. Should it happen the two arms are not quite parallel, an error that could scarcely be corrected by the hammer alone, the work would be fixed in the vice with the two tails upwards, and the one or Digitized by Google FORGING. 691 other of these would be twisted to its true position by a hook wrench or set, made like the three sides of a square, but the one very long to serve as a lever; it is applied exactly in the manner of a key, spanner, or screw-wrench, in turning round a bolt or screw. Some bent objects, such as cranks and straps, are made from bar-iron, bent over specific moulds, which are sometimes made in pairs like dies, and pressed together by screw contrivances. When the moulds are single, the work is often retained in contact with the same, at some appropriate part, by means of straps and wedges; whilst the work is bent to the form of the mould by top tools of suitable kinds. Objects of more nearly rectilinear form are cut out of large plates and bars of iron with chisels; for example, the cranks of locomotive engines are faggoted up of several bars or uses laid together, and pared to the shape they are sometimes forged in two separate parts, and welded between the cranks; at other times they are forged out of one parallel mass, and afterwards twisted with a hook-wrench, in the neck between the cranks, to place the latter at right angles. The notches are sometimes cut out on the anvil whilst the work is red-hot; or otherwise by machinery when in the cold state. A very different method of making rectangular cranks and similar works is also recommended, by bending one or more straight bars of iron to the form; the angles, which are at first rounded, are per- fected by welding on outer caps. In this case the fibre runs round the figure, whereas when the gap is cut out, a large proportion of the fibres are cut into short lengths, and therefore a greater bulk must be allowed for equal strength: this method is however seldom used. All kinds of levers, arms, brackets, and frames, are made after these several methods, partly by bending and welding, and partly by cutting and punching out; and few branches of industry present a greater variety in the choice of methods, and which call the judgment of the smith continually into re- quisition. There are several ways of accomplishing the operation of welding, and which bear some little analogy to the joints employed in carpentry; more particularly that called scarfing, used in the construction of long beams and girders by joining two shorter pieces together endways, with sloping joints, which in carpentry are interlaced or mortised together in various ways, and then secured by iron strape or bolts. In smith's work likewise, the joinings are called scarfs, but from the adhesive nature of the iron when at a suitable temperature, the accessories called for in carpentry, such as glue, bolts, straps, and pins, are no longer wanted. The scarfs required for the shut, are made by first upsetting or thickening the iron by blows upon its extremity, to prepare it for the loss it will sustain from scaling off, both in the fire and upon the anvil, and also in the subsequent working upon the joint. It is next rudely tapered off to the form of a flight of steps, as shown in Figs. 1792 and 1793, and the sides are slightly bevelled or pointed, as in Fig. 1793, the proportion being somewhat exceeded to render the forms more apparent. 1792. 1796. 1793. b a c 1794. 1795. The two extremities are next heated to the point of ignition; and when this is approached, a little sand is strewed upon each part, which fuses and spreads something like a varnish, and partially defends them from the air the heat is proper when, notwithstanding the sand, the iron begins to burn away with vivid sparks. The two men then take each one piece, strike them forcibly across the anvil to remove any loose cinders, place them in their true positions, exactly as in Fig. 1792, and two or three blows of the small hammer of the principal or fireman stick them together; the assistant then quickly joins in with the aledge-hammer, and the smoothing off and completion of the work are soon accom- plished. It is of course necessary to perform the work with rapidity, and literally to strike whilst the iron is hot the smith afterwards jumps the end of the rod upon the anvil, or strikes it endways with the hammer this proves the soundness of the joint, but it is mostly done to enlarge the part, should it during the process have become accidentally reduced below the general size. The sand appears to be quite essential to the process of welding, as although the heat might be arrived at without its agency, the surfaces of the metal would become foul and covered with oxide when unprotected from the air; at all events common experience shows that it is always required. The scarf joint, shown in Figs. 1792 and 1793, is commonly used for all straight bars, whether flat, square, or round, when of medium size. In very heavy works the welding is principally accomplished within the fire: the two parts are pre- viously prepared either to the form of the tongue or split joint, Fig. 1794, or to that of the butt joint, Fig. 1795, and placed in their relative positions in a large hollow fire. When the two parts are at the proper heat, they are jumped together endways, which is greatly facilitated by their suspension from the crane, and they are afterwards struck on the ends with sledge-hammers, a heavy mass being in some cases held against the opposite extremity to sustain the blows; the heat is kept up, and the work is ultimately withdrawn from the fire, and finished upon the anvil Digitized by Google 692 FORGING. The butt joint, Fig. 1794, is materially strengthened, when, as it is usually the case for the paddle shafts of steam-vessels and similar works, the joint whilst still large is notched in on three or four sides, and pieces called stick-in pieces, dowels, or charlins, one of which is represented by the dotted lines, are prepared at another fire, and laid in the notches; the whole, when raised to the welding heat, is well worked together and reduced to the intended size; this mingles all the parts in a very substantial man- ner. For the majority of works, however, the scarf joint, Fig. 1792, is used, but the stick-in pieces are also occasionally employed, especially when any accidental deficiency of iron is to be feared. When two bars are required to form a T joint, the transverse piece is thinned down as at a, in Fig. 1796; for an angle or corner the form of b may be adopted; but c, in which each part is cut off ob- liquely, is to be preferred. The pieces a, b, c, are represented upside down, in order that the ridges set down on their lower surfaces may be seen. In most cases when two separate bars are to be joined, whatever the nature of the joint, the metal should be first upset, and then set down in ridges on the edge of the anvil, or with a set-hammer, as the plain chamfered or sloping surfaces are apt to slide asunder when struck with the hammer, and prevent the union. When a T joint is made of square or thick iron, the one piece is upset, and moulded with the fuller much in the form of the letter; it is then welded against the flat side of the bar such works are sometimes welded with dowel or tenon joints, but all the varieties of method cannot be noticed. Fig. 1787 may be taken as an example, in which the parts have no disposition to separate; in this and similar cases the smith often leaves the parts slightly open, in order that the very last process before welding may be the striking the whole edgeways upon the anvil, to drive out any loose scales, cinders, or sand, situated between the joints. In works that have accidentally broken in the welded part, the fracture will be frequently seen to have arisen from some dirty matter having been allowed to remain between them, on which account, shuts or welded joints extending over a large surface are often less secure than those of smaller area, from the greater risk of their becoming foul In fact, throwing a little small coal between the contiguous surfaces of work not intended to be united, is a common and sometimes a highly essential precaution to prevent them from becoming welded. The conical sockets of socket chisels, garden spuds, and a variety of agricultural implements, are formed out of a bar of flat iron, which is spread out sideways or to an angle, with the pane of the hammer, and then bent within a semicircular bottom tool also, by the pane of the hammer, to the form of Fig. 1797 after which the sockets are still more curled up by blows on the edges and are per- fected upon a taper-pointed mandrel, so that the two edges slightly overlap at the mouth of the socket, and meet pretty uniformly elsewhere, as in Fig. 1798; and lastly, about an inch or more at the end is welded. Sometimes the welding is continued throughout the length, but more commonly only a small portion of the extremity is thus joined, and the remainder of the edges are drawn together with the pane of the hammer. 1797. 1798. In making wrought-iron hinges, two short slits are cut lengthways and nearly through the bar, to- wards its extremity; the iron is then folded round a mandrel, set down close in the corner, and the two ends are welded together. To complete the hinge, it only remains to cut away transversely, either the central piece or the two external pieces to form the knuckles, and the addition of the pin or pivot fin- ishes the work. Musket-barrels, when made entirely by hand, were forged in the form of long strips about a yard long and_ four inches wide, but taper both in length and width, which were bent round a cylindrical mandrel until their edges slightly overlapped; they were then welded at three or four heats, by intro- ducing the mandrel within them instantly on their removal from the fire at the proper heat, in order to prevent the sides of the tube from being pressed together by the blows of the hammer. They have been subsequently, and are now almost universally welded by machinery at one heat, and whilst of the length of only one foot, as on removal from the fire the mandrel is quickly introduced, and the two are passed through a pair of grooved rollers: they are afterwards extended to the full length by similar means, but at a lower temperature, 80 that the iron is not 80 much injured as when thrice heated to the welding point. The twisted barrels are made out of long ribands of iron wound spirally around a mandrel, and welded on their edges by jumping them upon the ground, or rather on an anvil embedded therein. The plain stub barrels are made in this manner, from iron manufactured from a bundle of stub-nails, welded together and drawn out into ribands to ensure the possession of a material most thoroughly and intimately worked. The Damascus barrels are made from a mixture of stub-nails and clippings of steel in given proportions, puddled together, made into a bloom, and subsequently passed through all the stages of the manufacture of iron already explained, to obtain an iron that shall be of unequal quality and hardness, and therefore display different colors and markings when oxidized or browned. Other twisted barrels are made in the like manner, except that the bars to form the ribands are twisted whilst red-hot like ropes, some to the right, others to the left, and which are sometimes again laminated together for greater diversity they are subsequently again drawn into the ribands and wound upon the mandrel, and frequently two or three differently prepared pieces are placed side by side to form the complex and ornamental figures for the barrels of fowling-pieces, described as stub-twist, wire- troist, Damascus twist," &c., which processes are minutely explained and figured by Greener, on Gunnery." All these matters are also explained in Wilkinson's Engines of War," which likewise treats of one Digitized by Google FORGING. 693 method amongst others of the formation of the Damascus gun-barrels, by arranging twenty-five thin bars of iron and mild steel in alternate layers, welding the whole together, drawing it down small, twisting it like a rope, and again welding three such ropes, for the formation of the riband, which is then spirally twisted to form a barrel, that exhibits, when finished and acted upon by acids, a diversified laminated structure, resembling when properly managed an ostrich feather. To turn from these engines of destruction to a modification of one of them to a happier purpose. When the illumination by gas was first introduced in the large way, by Aaron Manby, Esq., then of the Horsley Iron Works, the old musket-barrels, laid by in quiet retirement from the fatigues of the last war, were employed for the conveyance of gas; and by a curious coincidence, various iron foundries desisted in a great measure from the manufacture of iron ordnance, and took up the peaceful employ- ment of casting pipes for gas and water. The breech ends of the musket-barrels were broached and tapped, and the muzzles were screwed externally, to connect the two without detached sockets. From the rapid increase of gas illumination, the old gun-barrels soon became scarce, and new tubes with detached sockets, made by the old barrel- forgers, were first resorted to. This led to a series of valuable contrivances for the manufacture of the wrought-iron tubes, commencing with Russel's patent, in 1824, under which the tubes were first bent up by hand-hammers and swages, to bring the edges near together; and they were welded between semicircular swages, fixed respectively in the anvil, and the face of a small tilt-hammer worked by machinery, by a series of blows along the tube, either with or without a mandrel. The tube was com- pleted on being passed between rollers with half-round grooves, which forced it over a conical or egg- shaped piece at the end of a long bar, to perfect the interior surface. Various steps of improvement have been since made; for instance, the skelps were bent at two squeezes, first to the semi-cylindrical, and then to the tubular form, (preparatory to welding,) between a swage-tool five feet long, worked by machinery. The whole process was afterwards carried on by rollers, but abandoned on account of the unequal velocity at which the greatest and least diameters of the rollers travelled. In the present method of manufacturing the patent welded tube, the end of the skelp is bent to the circular form, its entire length is raised to the welding heat in an appropriate furnace, and as it leaves the furnace almost at the point of fusion, it is dragged by the chain of a draw-bench, after the manner of wire, through a pair of tongs with two bell-mouthed jaws; these are opened at the moment of intro- ducing the end of the skelp, which is welded without the agency of a mandrel. By this ingenious arrangement, wrought-iron tubes may be made from the diameter of six inches internally and about one-eighth to three-eighths of an inch thick, to as small as one-quarter inch diameter and one-tenth bore; and 80 admirably is the joining effected in those of the best description, that they will withstand the greatest pressures of gas, steam, or water, to which they have been sub- jected, and they admit of being bent both in the heated and cold state almost with impunity. Some- times the tubes are made one upon the other when greater thickness is required; but these stout pipes, and those larger than three inches, are comparatively but little used.* Various articles with large apertures are made, not by punching or cutting out the holes, but by folding the metal around the beak-iron, and finishing them upon a triblet of the appropriate figure; thus the complete smithy is generally furnished with a series of cones turned in the lathe, for making rings, the ends of which are folded together and welded, such as Fig. 1799. The same rings, when made of such cast-steel as does not admit of being welded, are first punched with a small hole, and gradually thinned out by blows around the margin, until they reach the diameter sought; but this, like numerous other works, requires considerable forethought to proportion the quantity of the material to its ultimate form and bulk, 80 that the work may not in the end become either too slight or too heavy. Chains may be taken as another familiar example of welding; in these the iron is cut off with a plain chamfer, as from the annular form of the links their extremities cannot slide asunder when struck; every succeeding link is bent, introduced, and finally welded. In some of these welded chains the links are no more than half an inch long, and the iron wire one-eighth of an inch diameter several inches of such chain are required to weigh one pound; these are made with great dexterity by a man and a boy at a small fire. The curbed chains are welded in the ordinary form and twisted alterwards, a few links being made red-hot at a time for the purpose. The massive cable-chains are made much in the same manner, although partly by aid of machinery. The bar of iron, now one, one and a half, or even two inches diameter, is heated, and the scarf is made as a plain chamfer by a cutting machine; the link is then formed by inserting the end of the heated bar within a loop in the edge of an oval disk, which may be compared to a chuck fixed on the end of a lathe mandrel. The disk is put in geer with the steam-engine; it makes exactly one revolution, and throws itself out of motion; this bends the heated extremity of the iron into an oval figure: afterwards it is detached from the rod with a chamfered cut by the cutting machine, which at one stroke makes the second scarf of the detached link, and the first of that next to be curled up. The link is now threaded to the extremity of the chain, closed together, and transferred to the fire, the loose end being carried by a traverse crane; when the link is at the proper heat, it is returned to the anvil, welded, and dressed off between top and bottom tools, after which the cast-iron transverse stay is inserted, and the link having been closed upon the stay, the routine is recommenced. The work A piece of tube of the smallest dimensions, and fourteen feet long, which has been bent cold almost into the form of the Gordian knot, may be seen at the Institution of Civil Engineers. The wrought-iron tubes of hydrostatic presses, which measure about half an inch internally, and one-fourth to three-eighths of an inch thick in the metal, are frequently subjected to a pressure equal to four tons on each square inch. Pipes proved to the same degree are also used in Mr. Perkins' patent apparatus for warming buildings, and in his recently patented steam-boiler. The safety of each of these is entirely secured by a fusible plug. which melts and allows the water to escape into the fire when its temperature exceeds any predeter- mined degree, namely, from about 300° to 600° F,, generally the former. Digitized by Google 694 FORGING. commonly requires three men, and the scarf is placed at the side of the oval link, and flatway through the same. In similar chains made by hand it is, perhaps, more customary to weld the link at the crown, or small end. The succeeding illustration of the practice of forging will be that of the formation of a hatchet, Figs. 1800 and 1801, which, like many similar tools, is made by doubling the iron around a mandrel, to form the eye of the tool; it will also permit the description of some other general proceedings, and likewise the introduction of the steel for the cutting edge. 1800. E 1801. 1802. 1803. 1799. B F C G I J D H In making the hatchet, a piece of flat iron is selected, of the width of A E, and twice the length of A D; it is thinned and extended sideways before it is folded together, to form the projections near B and F, by blows with the pane of the hammer or a round-edged fuller, on the lines A B to EF, but the metal must be preserved of the full thickness at the part A E, to form the poll of the hatchet, although a piece of steel is frequently welded on at that part as a previous step. The work is then bent round a mandrel, Figs. 1802 and 1803, exactly of the section of the eye as seen in Fig. 1801, and the work is welded across the line BF; the mandrel is again introduced, and the eye is perfected. A slip of shear-steel, equal in length to DH, is next inserted between the two tails of the iron, as yet of their original size, up to the former weld, and all three are welded together between D H: the combined iron and steel are now drawn out sideways, by blows of the pane of the hammer on and between CD and G H, to extend them together to IJ. The tool is then flattened and smoothed with the face of the hammer, and the edges are pared with straight or circular chisels to the particular pattern, and trimmed with a round-faced hammer, or a top fuller. In smoothing off the work, the smith pursues his common method of first removing with a file the hard black scales that appear like spots when the work is removed from the fire; he then dips the hammer in the slake trough, and lets fall upon the anvil a few drops of the water it picks up, the ex- plosion of which, when the red-hot metal is struck upon it, makes a smart report and detaches the scales that would be otherwise indented in the work. It should be observed that the mandrel, Fig. 1802, is purposely made very taper, and is introduced into the hole from both sides, so that the eve may be smaller in the middle; when, therefore, the handle of the tool is carefully fitted and wedged in, the handle is, as it were, dovetailed, and the tool can neither fly off nor slip down the handle; the same mode is also adopted for the heads of hammers. In spades, and many similar implements, the steel is introduced between the two pieces of iron of which the tools are made; in others, as plane irons and socket chisels, it is laid on the outside, and the two are afterwards extended in length or width to the required size. The ordinary chisel for the smith's shop is made by inserting the steel in a cleft, as in Fig. 1794, and 80 is also the pane of a hammer; but the flat face of the hammer is sometimes stuck on whilst it continues at the extremity of a flat bar of steel; it is then cut off, and the welding is afterwards completed. At other times the face of the hammer is prepared like a nail, with a small spike and a very large head, 80 as to be driven into the iron to retain its position, until finally secured by the operation of welding. In putting a piece of steel into the end of an iron rod to serve for я centre, the bar is heated, fixed horizontally in the vice, and punched lengthways with a sharp square punch, for the reception of the steel, which is drawn down like a taper tang or thick nail, and driven in; the whole is then returned to the fire, and when at the proper heat united by welding, the blows being first directed as for forming a very obtuse cone, to prevent the piece of steel from dropping out. For some few purposes the blistered steel is used for welding, either to itself or to iron. It is true the first working under the hammer in a measure changes it to the condition of shear-steel, but less efficiently so than when the ordinary course of manufacture is pursued, as the hammering is found to improve steel in a remarkable and increasing degree. The tires of wrought-iron wheels for locomotive engines and carriages, are in general bent to the circle by somewhat analogous means to those employed in chain-making, as are likewise the skelps for the twisted barrels of guns: the latter only require a mandrel or spindle with a winch handle at the one extremity, and a loop for the end of the skelp, which is wound in contact with the mandrel by means of a fixed bar placed near the same; such barrels are colled up in three lengths, which are joined together after the spirals are welded. Wheels for railways display many curious examples of smithing: thus some, except the nave, are made entirely by welding; others are partly combined with rivets; in all, the nave or boes is a mass of cast-iron usually poured around the ends of the spokes, with the exception of Bourne and Bartley's patent wheel, in which the nave, spokes, and periphery, are made entirely of wrought-iron and welded together. The common practice of welding the tires of railway wheels is now as follows: the tires are cut off with ridges in the centre, so as in meeting to form two angular notches, into which two thin iron wedges are subsequently welded radially; the four parts thus united together in the form of a cross, make a very secure joint without the necessity for upsetting the iron, which would distort the form of the tire. Digitized by Google FORGING. 695 For the majority of works in which it is necessary to weld steel to iron, or steel to steel, the shear, or double shear, is exceedingly suitable; it is used for welding upon various cutting tools, as the majority of the cast-steel will not endure the heat without crumbling under the hammer. Shear-steel is also used for various kinds of springs, and for some cutting tools requiring much elasticity. It is more usual to reserve the cast-steel for those works which the process of welding is not required, although of late years mild cast-steel, or welding cast-steel, containing a smaller proportion of carbon has been rather extensively used; but in general the harder the steel the less easily will it admit of welding, and not unfrequently it is altogether inadmissible. The hard or harsh varieties of cast-steel are somewhat more manageable when fused borax is used as a defence instead of sand, either sprinkled on in powder or rubbed on in a lump; and cast-steel, other- wise intractable, may be sometimes welded to iron by first heating the iron pretty smartly, then placing the cold steel beside it in the fire, and welding them the moment the steel has acquired its maximum temperature, by which time the iron will be fully up to the welding heat. When both are put into the fire cold alike, the steel is often spoiled before the iron is nearly hot enough, and therefore it is generally usual to heat the iron and steel separately, and only to place them in contact towards the conclusion of the period of getting up the heat. In forging works either of iron or steel, the uni- formity of the hammering tends greatly to increase and equalize the strength of each material and in steel, judicious and equal forging greatly lessens also the after-risk in hardening.* Concluding remarks on forging; and the applications of heading tools, swage tools, punches, &c.- With the utmost care and unlimited space, it would have been quite impossible to have conveyed the instructions called for, in forging the thousand varieties of tools and parts of mechanism the smith is con- tinually called upon to produce; and all that could be reasonably attempted in this place, was to convey a few of the general features and practices of this most useful and interesting branch of industry. It is hoped that such combinations of these methods may be readily arrived at as will serve for the majority of ordinary wants. The smith in all cases selects or prepares that particular form and magnitude of iron, and also adopts that order of proceeding which experience points out as being the most exact, sound, and economical. In this he is assisted by a large assortment of various tools and moulds for such parts of the work as are often repeated, or that are of a character sufficiently general to warrant the outlay, and to some of which I will advert. The heading tools, Figs. 1777 and 1778, are made of all sizes and varieties of forms; some with a square recess to 1804. produce a square beneath the head, to prevent the bolt from being turned round in the act of tightening its nut; others for countersunk and round-headed bolts, with and without square shoulders: many similar heading tools are used for all those parts of work which at all resemble bolts, in having any 0000 sudden enlargement from the stem or shaft. The holes in the swage-block, Fig. 1790, are used after the manner of heading tools for large objects; the grooves and recesses around its margin, also serve in a variety of works as bottom swages beyond the size of those fitted to the anvil. At the opposite extreme of the heading tools, as to size, may be noticed those constantly employed in producing the smallest kinds of nails, brads, and rivets, of various denominations; some of which heading tools divide in two parts like a pair of spring for- ceps, to release the nails after they have been forged. These kinds are called wrought-nails and brads, in contradistinction to similar nails cut out of sheet-iron by various processes of shearing and punching, which latter kinds are known as cut- brads and nails. The top and bottom rounding tools, Fig. 1774, are made of all diameters for plain cylindrical works and when they are used for objects the different parts of which are of various diameters, it requires much care to apply them equally on all parts of the work, that the several circles may be concentric and true one with the other, or possess one axis in common. To ensure this condition some of these rounding tools are made of various and specific forms, for the heads of screws, for collars, flanges, or enlargements, which are of continual occurrence in machinery; for the ornamental swells or flanges about the iron work of carriages, and other works. Such tools, like the pair represented in Figs. 1805 and 1806, are called swage or collar tools; they save labor in a most important degree, and are thus made. A solid mould, core, or striker, exactly a copy of the work to be produced, is made of steel by hand-forging, and then turned in the lathe to the required form, as shown in Fig. 1807. When cast-steel has been spolled by overheating, it may be partially recovered by four or five reheatings and quench- ings in water, each carried to an extent a little less and less than the first excess; and lastly. the steel must have a good hammering at the ordinary red heat. Some go so far as to prefer for cutting tools the steel thus recovered, but this seems a most questionable policy, although the change wrought by this treatment is really remarkable; as the fragment broken off from the bar in the spoiled state, and another from the same bar after part restoration and hardening, will exhibit the extreme characters of coarse and fine. The hammering we suspect to be the principal requisite, and in superior tools it should be continued until the work IS nearly cold, to produce the maximum amount of condensation before hardening; but no hammering will restore the loss of tenacity consequent upon the overheating. or even the too frequent heating, of steel, without excess. + The forge used by the nail-makers is built as a circular pedestal, with the fire in the centre and the chimney directly over it; the rock-staff of the bellows extends entirely around the forge, 80 that one of the four or five persons who work at the same fire is continually blowing it, whence the fire is always at the heat proper for welding, and which keeps the nails sound and good. Digitized by Google 696 FORTIFICATION. The top tool is first moulded to the general form in an appropriate aperture in the swage-block, Fig. 1804; it is faced with steel like a hammer, and the core, Fig. 1807, is indented into it; the blows of the sledge-hammer not being given directly upon the core, but upon some hollow tool previously made; otherwise the core must be filed partly flat to present a plane surface to the hammer. The bottom tool, which is fitted to the anvil, is made in a similar manner, and sometimes the two are finished at the same time whilst hot, with the cold striker between them; their edges are carefully rounded with a file so as not to cut the work, and lastly they are hardened under a stream of water. In preparing the work for the collar tools, when the projection is inconsiderable, the work is always drawn down rudely to the form between the top and bottom fullers, as in Fig. 1772; but for greater economy, large works in iron are sometimes made by folding a ring around them, as in Fig. 1780. The metal for a large ring is occasionally moulded in a bottom tool, like Fig. 1808, and coiled up to the shape of Fig. 1809, after which it is closed upon the central rod between the swages, and then welded within them. The tools are slightly greased, to prevent the work from hanging to them, and from the same motive their surfaces are not made quite flat or perpendicular, but slightly conical, and all the angles are obliterated and rounded. 1809. 1805. 1812. 1808 1811. 1810. 1807. 1806 The spring swage tool, represented in Fig. 1810, is used for some small manufacturing purposes; it differs in no respect from the former, except in the steel spring which connects the two parts; it is employed for light single hand-forgings. Other workmen use swage tools, such as Fig. 1811, in which there is a square recess in the bottom tool to fit the margin of the top tool so as to guide it exactly to its true position; * this kind also may be used for single hand works, and is particularly suited to those which are of rectangular section, as the shoulders of table-knives: these do not admit of being twisted round, which movement furnishes the guide for the position of the top tool in forging circular works. The smith has likewise a variety of punches of all shapes and sizes, for making holes of corresponding forms; and also drifts or mandrels, used alone for finishing them, many of which, like the turned cones, are made from a small to a large size to serve for objects of various sizes. Two examples of the very dexterous use of punches are in the hands of almost every person, namely, ordinary scissors and pliers. The first are made from a small bar of flat steel the end is flattened and punched with a small round hole, which is gradually opened upon a beak-iron, Fig. 1812, attached to the square hole of the anvil; the beak-iron has a shallow groove (accidentally omitted) for rounding the inside of the bows. The remaining parts of the scissors are moulded jointly by the hammer and bottom swage tools; but the bows are mostly finished by the eye alone. In the Lancashire pliers, the central half of the joint is first made; the aperture in the other part is then punched through sideways, and sufficiently bulged out to allow the middle joint to be passed through, after which the outsides are closed upon the centre. This proceeding exhibits, in the smallest kinds especially, a surprising degree of dexterity and dispatch, only to be arrived at by very great practice; and which in this and numerous other instances of manufacture could be scarcely attained but for the enormous demand, which enables a great subdivision of labor to be successfully applied to their production. FORTIFICATION is the art of constructing such works of defence as may enable a comparatively small number of men to maintain possession of a city or place against the assaults of a superior force. Modern fortifications, though differing in some subordinate details, which differences are dignified by the name of systems, closely resemble one another in all their essential parts. In order to explain their structure, it will be convenient to consider them first without reference to their form, or the position of the ground lines in respect of each other, but merely as defences against an army with artillery ad- vancing directly in front. The annexed figure repre- sents a vertical section of a regular fortification on the G D 1813. ground line X Y, the place to be defended being sup- B H C posed between X and A. The mass of earth ABCD R M P EFGH forms the rampart with its parapet. A B is L the interior slope of the rampart; BC is the terre-plein of the rampart, having a breadth of about 40 feet, on which the troops and cannon are placed DE is called the banquette, or step, on which the soldiers mount to fire over the parapet; EFG is the . In practice the recess in the bottom tool would be deeper, and taper or larger above to guide the tool more easily to its place; but if so drawn the figure would have been less distinct. + The remarks on steel also refer to the necessity of good primary forging and hammering to produce homogenelty; and also to many of the other points generally admitted by practical men as being conducive to the success of hardening. Digitized by Google FORTIFICATION. 697 parapet, of a height (about 7 feet) sufficient to protect the men and guns on the terre-plein, and sloped in the direction F G towards M, the opposite edge of the ditch, so that a man approaching there may be seen and fired at; G H is the exterior slope of the parapet; HI is the revetment, or wall of masonry supporting the rampart, and strengthened by buttresses placed at small intervals behind it. This must be of sufficient height to prevent its being easily scaled; but yet must not rise higher than the edge of the exterior work at Qn in order that it may not be seen and breached by distant batteries. The exterior front of the rampart, covered with the revetment HK, is called the escarp; M is the ditch, the dimensions of which will be determined by the nature of the ground, but must be such, in general, that its excavation or deblai must produce sufficient earth or remblai to form the rampart the opposite side of the ditch LM is the counterscarp, also supported by a revetment of masonry MN is the covered way, a space about 10 yards in breadth, having a banquette NOP, and protected by a parapet PQ, the superior slope of which, QR, is called the glacis. The use of the covered way is to allow troops to be drawn up, unseen by the besiegers, for the purpose of making sorties; it also enables the garrison to keep up a closer fire on the approaches of the enemy, and its parapet forms a strong protection to the revetment of the rampart. It is easy to see that the strength of a place will be increased by a succession of such works, so that when the besieged are driven from one they may retire to the next behind it. Sometimes there are three ditches with intermediate works, or rather works raised within the ditch itself, similar to the rampart, though of a less height, in order that the guns on the rampart may range above them. A work of this sort, between the inner and the main ditch, is called a tenaille; that between the main ditch and the outer ditch is called a ravelin. All works outside the ditch are called outworks. Before proceeding to construct a fortification, it is necessary to lay down a plan. This will differ in some respects according to the system adopted; but the following description, which properly belongs to Vauban's First System, will explain the general method When the work is regular, the sides are all equal, and therefore the general form will be that of a polygon inscribed in a circle. The first thing to be done is to determine on the number of sides. We shall suppose them to be six, and the radius of the circumscribing circle to be 360 yards, when the construction will be as follows: Let A B, be two 1814. sides of a hexagon inscribed in a circle; each of B these lines will be equal to the radius, or 360 yards. Bisect A B in D; draw the perpendicular DE, on I which set off DE, equal to one sixth of A B or 60 yards; draw the lines EF and BEG, in which F take A H and BI, each equal to 100 yards, or five H ninths of D; make H F and IG each equal to the distance HI; then the line A HGFIB is the prin- cipal outline of the front; and by making the same construction on each of the sides of the hexagon, we obtain the principal outline of the whole forti- fication, or that by which the first figure of the work is defined. The part F IBK L is called the bastion, BI and BK are the faces of the bastion; IF and KL are its flanks; F L is the gorge; GF is the curtain; A F and BG are the lines of defence; B is the flanked angle; I and K are the angles of the shoulder; GFL and M the angles of the flank. From the points A and B as centres, and a radius of 40 yards, describe circular arcs; if lines be drawn from the oppo- site angles of the shoulder HI to touch those arcs, the parts of those lines a c, b c, together with the arcs, will represent the counterscarp of the ditch. The curtain is defended by a ravelin, which is constructed thus: From c, the re-entering angle of the counterscarp, set off, on the perpendicular DE, a line c d, equal to 110 yards, and from d draw de, df, in the directions of H and I, to meet the counterscarp; then de and df are the faces of the ravelia, and oe and cf its semi-gorges. The counterscarp ghi of the ditch of the ravelin is parallel to its faces, and rounded off at h. Stairs, called pas-de-souris, are con- structed to facilitate the descent from the ravelin to the ditch. Besides the ravelin, there is usually another appendage to the bastion and curtain. This is the tenaille, represented in the figure by the parts Pq made in the direction of the lines of defence; but it has sometimes other forms. The tenaille is made in the ditch before the curtain, with passages between the ends and the flanks of the bastion. It is a low work, having its parapet only about three feet higher than the level ground of the ravelin, and its use is to defend the bottom of the ditch by a grazing fire. Such are the works which form the envelop of the place fortified; but various other constructions are in most cases added, according to the nature of the ground and other circumstances, for the purpose of protecting or strengthening such parts as are most exposed, or of interrupting the works of the be- siegers. These additional constructions are either internal or external. Among the former are retrench- ments of various kinds, either constructed at the same time with the principal works or thrown up during the siege. They are made behind the ramparts, or the bastions most exposed to attack, their use being to enable the garrison to continue the defence from behind a fresh obstacle when a rampart or bastion has been breached. When a hill or rising ground overlooks any of the works, a cavalier is raised, about ten or twelve feet higher than the rest of the works. This is commonly placed within the bastion when it has the same form, but sometimes on the middle of the curtain when its form is semicircular. Of the exterior works one of the most important is the counter- 1815. guard, constructed to cover some of the principal parts, as the bastion or the cavalier, in such a manner that without obstructing their fire it prevents them from being breached till itself is taken. The counterguard is constructed paral- lel with the faces of the work it is destined to cover; and it must be lower than the principal work, though of a sufficient height to screen its revetment. A horn- work, represented in the annexed figure, is composed of two branches, and a front composed of two half bastions and a curtain, resembling a front of the body of 88 Digitized by Google 698 FORTIFICATION. the place. It is here represented as made before the curtain, but it may be also constructed before a bastion. A crown-work is of the same nature as a horn-work, but larger, and having two fronts, which give it somewhat the appearance of a crown. Horn-works and crown-works are constructed where a large spot of ground lies beyond the fortification which might be advantageous to an enemy, or to cover a gate or entrance into a town. Lunettes, a a, are placed on both sides of the ravelin, and are con- structed on lines bisecting the faces of the ravelin at right angles. A bonnet, b, is a 1816. work covering the salient angle of the ravelin. Tenaillons are similar in construc- tion to lunettes, but having one of their faces formed on lines which are the produc- tion of the faces of the ravelin, instead of bisecting those faces. The application of all these and other works of a similar description depends on the nature of the lo- calities; and it must be left to the judgment of the engineer to determine in each particular case which is best adapted to the ground. We have already alluded to the use and importance of the covered way. In order to increase its strength traverses, or portions of parapet, are thrown across it, which screen it from an enfilading fire, and enable the defenders to dispute its possession foot by foot. Places of arms, or places for assem- bling troops, and protected by traverses and redoubts, are also formed on it at the re-entering and salient angles of the counterscarp. The redoubts serve not only as a place of retreat, but facilitate the making of sorties upon the enemy's lodgments. The descriptions given above belong more especially to that method of fortification which, in the mili- tary schools, is denominated Vauban's first system. In his second system, represented in the annexed figure, he separated the bastions from the body 1817. of the place by a ditch about 40 feet wide, in order that the besieger, after the breach and capture of the bastions, might be compelled to renew his operations against his enceinte or body of the place. The angles of the polygon are crowned by pentagonal towers of masonry, called tower bastions, to which, in fact, the regular bastions only form countergards. Vauban's third system does not differ in any material respect from the second. He 1818. increased the size of the ravelin, and gave it a redoubt. The tower bastions were likewise made larger, and the curtain which united them was broken inwards, so as to form two small flanks underneath; while casements for cannon were constructed, to co-operate with those of the tower bastions in the defence of the ditch. Coehorn's system.-Contemporary with Vauban was the Baron de Coehorn, director-general of the fortifications of the United Provinces of Holland. This celebrated engineer is also the author of three different systems, though the third has never been constructed. His methods are only applicable in low swampy countries, like Holland and the object which he kept principally in view was to throw such obstacles in the way of a besieging force that the place could only be approached with great difficulty and hazard. This he sought to accomplish 1819. by covering and flanking his works more effectually than had previously been done, and by depriving the assailant of the room necessary for erect- ing his batteries. An idea of his methods may be formed from the annex- ed figure, which represents his first system. It is constructed on a hexa- gon the second was on a heptagon, and the third on an octagon. And it may be remarked of his systems in general, that they differ from Vauban's principally in the greater width of the ditch and the narrow space between the flanks. Cormontaigne's system.-The methods of Vauban were improved in many essential respects by Cor- montaigne. In his system, which is here represented, the faces of the bastion are 1820. made longer than in Vauban's methods, and the flanks are placed at right angles with the faces of the opposite bastions. The enlargement of the bastion renders it capable of containing interior retrenchments; and the flanks, though shortened. are better covered. His ravelins are also constructed on a larger base, and contain a larger redoubt, from which the besiegers can keep up a reverse fire on breaches made in the collateral bastions; 80 that the assault upon the latter becomes impracticable until the ravelin and its redoubt are both captured. The combination round the extremities of the traverses of the covered way are arranged in a zigzag line ; so that the passage round the extremity of one traverse is defended by the fire of another in its rear, and the advance of the assailants along the covered way thereby checked. In general, Cormontaigne's system possesses greater defensive properties, and IS more economical of materials. Modern System.-Fig. 1821 represents what is called the modern system it varies but little from that of Cormontaigne. The ravelin is made to cover the shoulder of the bastion more effectually by a greater projection, and its faces are retrenched by coupures or cuts through the rampart, perpendicular to the faces of the bastion, which prevent the enemy 1821. from taking the redoubt in the re-entering place of arms without first possessing himself of the redoubt in the ravelin. All the systems above enumerated agree in their principal features, and may be included under the name of the bastion system. Some engineers, however, have pointed out defects which appear to be inherent in the system, and proposed to give the polygon a different form. By suppressing the curtain and the tenaille, and producing the faces of the bastions inward, a line of rampart would be formed presenting simply a succession of salient and re-entering angles. But as the Digitized by Google FORTIFICATION. 699 plan has never been practically carried into effect, it is unnecessary to enter into particulars. In the present state of the military art, such is the superiority of the means of attack over those of defence, that however strong the works may be, and however skilfully disposed, their reduction, when assailed by adequate means, is, generally speaking, a matter of absolute certainty. The besieging army, shel- tered by its trenches from the missiles of the garrison, advances in zigzag lines parallel to the faces of the ramparts, till it passes over or circumvents all the exterior defences of the place, and arrives at the main wall, where a breach has been made by batteries erected for the purpose. To this covered mode of attack, supported by the ricochet batteries, by which the defenders are driven from the ramparts and the guns dismounted, it is perhaps impossible to offer any effectual resistance. Indeed, such is the per- fection to which the art of attack has been reduced, that even the length of time which any fortress will be able to hold out against an enemy provided with the proper train of sappers and miners, and the implements necessary for carrying on their operations, may be computed with the greatest precision. Field fortification.-Field fortification is the art of constructing all kinds of temporary works for assisting the operations of an army in the field, and enabling it to maintain a position against a superior force. On account of the endless varieties and accidents of the ground, the observance of fixed rules is, indeed, impracticable: nevertheless there are certain general maxims which apply to the construction of fortifications of all kinds, whether temporary or permanent. For example, works constructed to flank others, must not be at so great a distance as to be beyond the effective range of musketry the angles of defence should be nearly right angles, and the salient angles as obtuse as possible. The general na- ture of defensive works is also the same in all cases, namely, a ditch and a parapet; though, as the pickaxe and the spade are the only implements which an army in the field can carry about with it, the depth and width of the ditch and the height of the parapet are in field-works necessarily limited to what can be effected by these simple means. Field-works are usually divided into three classes 1, works open at the gorge; 2, works inclosed all round; and 3, lines either continued or with intervals. To the first class belong redans, single and dou- ble, tenailled heads, and bastioned heads; to the second, redoubts, star forts, and 1822. bastioned forts; and to the third, lines of various kinds for defending a position. The redan is the simplest of all works, consisting merely of two lines, A B and A C, forming an angle with each other. It is only employed for such purposes as defend- ing the avenues of a village, bridge, or defile. The length given it is usually about B C 50 yards. When the redan is thrown out in front of other works it is called a fleche, D or arrow. Lunettes are also applied for similar purposes, and are formed by adding two parallel faces, BD and C E, to the redan, at the extremities of its open flanks. 1823. The double redan, or bonnet de prêtre, consists of two faces, A B and CD; and two A c flanks A E and CE, usually shorter than the faces, and affording a reciprocal defence E to each other. The re-entering angle at E should be a right angle; if it is less, the two flanks are in danger of being struck by each other's fire; and if it is much greater B than a right angle, the defence will be weakened; for it is found by experience that soldiers placed be- hind a screen invariably fire straight before them, or at right angles to the screen. When a greater extent of front is to be fortified, the lines are disposed in the form of bastions or tenailles, and thence called bastioned heads, and tenailled heads. Redoubts are works closed on all sides, of a polygonal or quadrilateral figure, and usually square. An opening is left in one of the sides, for communication with the exterior, and a traverse is thrown up within for protection. As the work is without flanks, the ditches are left without defence. The angles are sometimes rounded, or cut off, in order that a fire may be maintained on an as- 1824. sailant advancing in the direction of the diagonal. Star forts are inclosed works constructed upon an equilateral triangle or a square. In the former case they have six points, in the latter eight. When constructed on a square, each of the sides (which may be about 90 vards long) is divided into three equal parts, and on the middle part an equilateral triangle is constructed, which gives the trace of the figure. The object of this work is to remedy the defects of the redoubt by flanking the angles of the square; but as a-considerable space is consumed by the re-entering angles, it scarcely admits of sufficient troops and artillery being placed in it for its defence. Bastioned forts are constructed in the field on the same principles as in permanent works; but are only constructed on the square or pentagon. The distance A B, or exterior side of the polygon, should not exceed the range of musketry, or about 200 yards. They are employed only 1825. in fortifying important position: and require, accordingly, to be constructed in a more solid manner than other works of a temporary nature. The last class of field-works comprehends lines of various descriptions. Con- tinued lines are constructed to inclose a front, or connect principal works with one another by a continued parapet. They are constructed, according to circumstances, with redans, tenailles, or bastions, placed at certain intervals, seldom exceeding 180 yards. From the descriptions given above, the different forms of the redan line, tenaille line, and bastion line, will be readily conceived. Sometimes they are formed of a succession of faces and flanks at right angles. In this case they are called lines-encremail- lières. The flanks are about a fourth of the length of the faces, and afford a defence to the ditches. Lines with intervals consist of isolated works, as redans or redoubts, 1826. placed at distances which should not exceed 200 yards, and so as to afford one another a mutual defence. Besides the works now enumerated, various expedients are resorted to in order to prevent, or at least to render more difficult, the approaches of an enemy. Among these are palisades, abatis, trous-de-coup, chevaux-de-frize, crows' feet, &c. The principal authors on fortification are Errard, Stevinus, Antoine de Ville, Compte de Pagan, Coe- Digitized by Google 700 FOUNDATIONS. horn, Vauban, Mallet, Belidor, Blondel, Montalembert, Bisset, Bousmard, Carnot, Mouzé, &c. For a practical treatise the reader may be referred to the article " Fortification" in the Encyc. Metropolitana. Also the works of D. H. Mahan, Professor of Military and Civil Engineering in the United States' Mili- tary Academy; and of H. W. Halleck, of the U.S. Army. FOUNDATIONS. In preparing the foundation for any building, there are two sources of failure which must be carefully guarded against: viz. inequality of settlement, and lateral escape of the sup- porting material; and, if these radical defects can be guarded against, there is scarcely any situation in which a good foundation may not be obtained. It is therefore important that previous to the com- mencement of the work, soundings should be taken to ascertain the nature of the soil and the ray of the strata, to determine the kind of foundation; and the more important and weighty the superstructure, the more careful and deeper the examination. Natural foundations.-The best foundation is a natural one, such as a stratum of rock, or compact gravel. If circumstances prevent the work being commenced from the same level throughout, the ground must be carefully benched out, i. e. cut into horizontal steps, so that the courses may all be per- fectly level. It must also be borne in mind that all work will settle, more or less, according to the perfection of the joints, and therefore in these cases it is best to bring up the foundations to a uniform level, with large blocks of stone, or with concrete, before commencing the superstructure, which would otherwise settle most over the deepest parts, on account of the greater number of mortar joints, and thus cause unsightly fractures. Many soils form excellent foundations when kept from the weather, which are worthless when this cannot be effected. In dealing with soils of this kind nothing is required but to keep them from the action of the atmosphere. This is best done by covering them with a layer of concrete, (see mortar.) For want of this precaution many buildings have been fractured from top to bottom by the expansion and contraction of their clay foundations during the alternations of drought and moisture, of frost and heat, to which they have been exposed in successive seasons. Artificial foundations-Where the ground in its natural state is too soft to bear the weight of the proposed structure, recourse must be had to artificial means of support, and, in doing this, whatever mode of construction be adopted, the principle must always be that of extending the bearing surface as much as possible; just in the same way, that, by placing a plank over a dangerous piece of ice, a couple of men can pass over a spot which would not bear the weight of a child. There are many ways of doing this-as by a thick layer of concrete, or by layers of planking, or by a net-work of timber, or these different methods may be combined. The weight may also be distributed over the entire area of the foundation by inverted arches. The use of timber is objectionable where it cannot be kept constantly wet, as alternations of dryness and moisture soon cause it to rot, and for this reason concrete is very extensively used in situations where timber would be liable to decay. In the case of a foundation partly natural and partly artificial, the utmost care and circumspection are required to avoid fractures in the superstructure; and it cannot be too strongly impressed that it is not an unyielding, but a uniform yielding foundation that is required, and that it is not the amount, so much as the inequality, of settlement that does the mischief. The second great principle laid down at the commencement of this article was-To prevent the lateral escape of the supporting material. This is especially necessary when building in running sand, or soft clay, which would ooze out from below the work. and allow the superstructure to sink. In soils of this kind, in addition to protecting the surface with planking, concrete, or timber, it is often necessary to inclose the whole area of the foundation with piles driven close together; this is called sheet-piling. Where there is a hard stratum below the soft ground, but at too great a depth to allow of the solid work being brought up from it without greater expense than the circumstances of the case will allow, it is usual to drive down wooden piles, often shod with iron, until their bottoms are firmly fixed in the hard ground. The upper ends of the piles are then cut off level, and covered with a platform of tim- ber on which the work is built in the usual way. The piles are generally of about 1 foot diameter, and are driven at distances of from 2 to 3 feet from centre to centre. Where a firm foundation is required to be formed in a situation where no firm bottom can be found within an available depth, piles are driven, to consolidate the mass, a few feet apart over the whole area of the foundation, which is surrounded by a row of sheet-piling to prevent the escape of the soil the space between the pile heads is then filled to the depth of several feet with stones or concrete, and the whole is covered with a timber platform, on which to commence the solid work. Foundations in water.Hitherto we have been describing ordinary foundations; we now come to those cases in which water interferes with the operations of the builder, oftentimes causing no little trouble, anxiety, and expense. Foundations in water may be divided under three heads: 1st, Foundations formed wholly with piles. 2d, Solid foundations laid on the surface of the ground, either in its natural state, or roughly levelled by dredging. 3dly, Solid foundations laid below the surface, the ground being laid dry by cofferdams. Foundations formed wholly of piles.-The simplest foundations of this kind are those formed by rows of wooden piles braced together 80 as to form a skeleton pier for the support of horizontal beams; and this plan is often adopted in building jetties, piers of wooden bridges, and similar erections where the expense precludes the adoption of a more permanent mode of construction; an example of this kind is shown in Fig. 1827. There is, however, an objection to the use of piles partly above and partly under water, that, from the alternations of dryness and moisture, they decay at the water-line; and in tidal waters, they are often rapidly destroyed by the worm. To obviate the inconveniences attending the use of timber, cast iron is sometimes used as a material for piles; but this again is objectionable in salt water, as the action of the sea-water upon the iron con- verts it into a soft substance which can be cut with a knife, resembling the lead used for pencils, Digitized by Google FOUNDATIONS. 701 In situations where a firm hold cannot be obtained for a pile of the ordinary shape, such as shifting sand, Mitchell's patent screw piles may be used with great advantage. These piles terminate at the bottom in a large iron screw 4 feet in diameter, which, being screwed into the ground, gives a firm foot- hold to the pile. This is a very simple and efficient mode of obtaining a foundation where all other means would fail, and has been used in erecting light-houses on sand-banks with great success. An ingenious system of cast-iron piling was adopted by Mr. Clark in the erection of the Town Pier at Gravesend, in forming a foundation for the cast-iron columns, supporting the superstructure of the T head of the pier. Under the site of each column were driven three cast-iron piles, on which an adjust ing plate was firmly keyed, forming a broad base for the support of the column, which was adjusted to its correct position, and bolted down to the adjusting plate. 1827. SCALE.-20 feet=1 inch. A kind of foundation on the same principle as piling has been lately much used in situations where ordinary piling cannot be resorted to with advantage. The method referred to consists in sinking hollow cast-iron cylinders until a hard bottom is reached. The interior of the cylinder is then pumped dry, and filled up with concrete or some equally solid material, thus making it a solid pier on which to erect the superstructure. The cylinders are made in lengths, which are successively bolted together as each previous length is lowered, the excavation going on at the bottom, which is kept dry by pumping. It often happens, however, in sinking through sand, that the pressure of the water is 80 great as to blow up the sand at the bottom of the cylinder; and, when this is the case, the operation is carried on by means of a large auger, called a miser, which excavates and brings up the materials without the necessity of pumping out the water. The lower edge of the bottom length of each cylinder is made with я sharp edge, to enable it to penetrate the soil with greater ease, and to enter the hard bottom stratum on which the work is to rest. This method was adopted by Mr. Redman in the erection of the Terrace pier at Gravesend. Before closing our remarks on pile foundations, we must mention a very curious system of carrying up a foundation through loose wet sand, which is practised in India and China, and is strictly analogous to the sinking of cast-iron cylinders just described. It consists in sinking a series of wells close together, which are afterwards arched over separately, and covered with a system of vaulting, on which the superstructure is raised. The method of sinking these wells is to dig down, as far as practicable, without a lining of masonry, or until water is reached; a wooden curb is then placed at the bottom of the excavation, and a brick cylinder raised upon it to the height of 3 or 4 feet above the ground. As soon as the work is sufficiently set, the curb and the super- incumbent brick-work are lowered by excavating the ground under the sides of the curb, the peculiarity of the process being that the well-sinker works under water, frequently remaining submerged more than a minute at a time. These cylinders have been occasionally sunk to a depth of 40 feet. Solid foundations simply laid on the surface of the ground.-Where the site of the intended struc- ture is perfectly firm, and there is no danger of the work being undermined by any scour, it will be sufficient to place the materials on the natural bottom, the inequalities of surface being first removed by dredging or blasting. Pierre perdue.-The simplest mode of proceeding is to throw down masses of stone at random over the site of the work until the mass reaches the surface of the water, above which the work can be car- ried on in the usual manner. This is called a foundation of pierre perdue," or random work, and is used for breakwaters, foundations of sea-walls, and similar works. Plymouth breakwater is an example on a large scale. Coursed masonry.-Another way, much used in harbor work, is to build up the work from the bot- tom (which must be first roughly levelled) with large stones, carefully lowered into their places; and this is a very successful method where the stones are of sufficient size and weight to enable the work Digitized by Google 702 FOUNDATIONS. to withstand the run of the sea. The diving-bell affords a ready means of verifying the position of each stone as it is lowered. Béton.-On the continent, foundations under water are frequently executed with blocks of béton or hydraulic concrete, which has the property of setting under water. The site of the work is first inclosed with a row of sheet piling, which protects the béton from disturbance until it has set. This system is of very ancient date, being described by Vitruvius, and was practised by the Romans, who have left us many examples of it on the const of Italy. The French engineers have used béton in the works at Algiers, in large blocks of 324 cubic feet, which were floated out and allowed to drop into their places from slings. This method, which proved perfectly successful, was adopted in consequence of the smaller blocks first used being displaced and destroyed by the force of the sea. Caissons.-A caisson is a chest of timber, which is floated over the site of the work, and, being kept in its place by guide piles, is loaded with stone until it rests firmly on the ground. In some cases the stone is merely thrown in, the regular masonry commencing with the top of the caisson; which is sunk a little below the level of low water, so that the whole wood-work may be always covered, and the caisson remains as part of the structure. In others, the masonry is built on the bottom of the caisson, and when the work reaches the level of the water the sides of the caisson are removed. Westminster Bridge, London, is a noted instance of the failure of this method of building. The bot- tom of the river has been scoured out to a depth of several feet since the erection of the bridge; and the foundations of the piers remained in a dangerous state until they were secured by driving sheet piling all around them, and underpinning the portions which had been undermined. An improvement on the above method consists in dredging out the ground to a considerable depth, and putting in a thick layer of béton on which to rest the bottom of the caisson. There is a third method of applying caissons which is practised in Europe, and which is free from the objections which commonly attend the use of caissons. A firm foundation is first formed by driving piles a few feet apart over the whole site of the foundation. The tops of the piles are then sawn off under water just enough above the ground to allow of their being all cut to the same level. The cais- son is then floated over the piles, and, when in its proper position, is sunk upon them, being kept in its place by a few piles left standing above the others, the water being kept out of the caisson by a kind of well constructed round each of these internal guide piles, which are built up into the masonry. This method of building in caissons on pile foundations is shown in Figs. 1828 and 1829. The piers of the Pont du Val Benoit at Liége, which carries the railway across the Meuse, have been built on pile foun- dations in the manner here described. 1829. WATER SUMMER 1828. BOTTOM OF CAISSON WELL A similar plan of foundation was adopted in the construction of three of the piers of the railroad bridge across the Connecticut, at Springfied, Mass. but to give the greatest stability to the work, the bottom was previously dredged, the piles were then driven, and cut off level considerably below the bed of the river. The spaces between the piles, and a few feet outside of them, was filled with béton, and raked off even with the top of the piles; the caisson was then floated into its position. The foun- dations of the other piers and abutments were of piles, but cofferdams were used, and the bottom laid dry and excavated. 1830. FLOOD WATER PUDDLE PIER SUMMER WATER LOUSE GRAVEL SCALE.-20 feet=1 inch. Solid foundations laid in cofferdams.-There are many circumstances under which it becomes neces- sary to lay the bottom dry before commencing operations. This is done by inclosing the site of the Digitized by Google FOUNDRY CRANE. 703 foundation with a water-tight wall of timber, from within which the water can be pumped out by steam power or otherwise. Sometimes, in shallow water, an earth embankment or a single row of sheet piles only is sufficient; but in deep water two or even four rows of piles will be required, the space between them being filled in with puddle, 80 as to form a solid water-tight mass, Fig. 1830. The great difficul- ties in the construction of a cofferdam are-1st, to keep it water-tight; and, 2d, to support the sides 1831. against the pressure of the water outside, which in tidal waters is sometimes 80 great as to render it necessary to allow a dam to fill to prevent its being crushed. Of the difficulties experienced in the con- struction of a cofferdam in deep water, and of the excavation for foundations, an interesting and in- structive example may be found in the able report of Captain Turnbull, on the construction of the Poto- BETON mac Aqueduct, published in the Civil Engineers' and Architects' Journal. In order to save timber, and to avoid the difficulty of keeping out the bottom springs, it has been pro- posed by a French engineer, after driving the outer row, to dredge out the area thus inclosed, and fill it up to a certain height with béton. The cofferdam is then to be completed by driving an inner row of piles resting on the béton, and puddling between the two rows in the usual manner; and the masonry is carried up on the béton foundation thus pre- pared. This construction is shown in Fig. 1831. See Day Dock. FOUNDRY See CASTING. FOUNDRY CRANE Fig. 1832.-Side elevation of the crane, and section of the masonry which sup- ports it. Fig. 1833.-Elevation of the geer side taken at right angles to Fig. 1832. Fig. 1884.-Horizontal section on the line 1-2, Fig. 1832. Fig. 1835.-Section on the line 3-4. S s 1834. t E 0 M 1833. R 850 1835. S 1832. A 1000 G 400 g R I I E E h 9 h 0 0 1843. A 4 P 2 1 B 325 A A 1844. 6 ? a K [ F 5 ! K G aug 1836. C 0 0 510 S60 720 D D 09114 D 006 n A J 280 D SCALE.-17 feet=4 inches. Fig. 1836.-Elevation of geers and pinions. Fig. 1887.-Shows the arrangement of the break; Fig. 1838.-A section of the same. Figa 1839 and 1840.-Horizontal section on the line 5-6; Fig. 1839 being the section of the frame which supports the geering; Fig. 1840, the section of the body or shaft of the crane. Digitized by Google 704 FREEZING APPARATUS. Fig. 1841.-Plan of the cast-iron plate and friction wheels against which the shaft of the crane bears, and which facilitate its rotation. Fig. 1842.-Section of this plate on the broken line 7-8-9. Figs. 1843 and 1844.Show a different arrangement of steps from that already given, Figs. 1832 and 1833. Explanatory Letters. A, vertical shaft or body of the crane cast in one piece; a, a steel point (easily replaced when worn) at the lower end of the shaft, Fig. 1843. This step is cast with the base, and in Fig. 1844 it is steel, and fitted in the base plate. B, cast-iron base or step-plate; a, steel step; b, ribe to strengthen the shaft; c, cylindrical-turned collar, against which the six strong cast-iron friction wheels d bear, maintaining the shaft perpendicular, and allowing it to turn freely. C, large plate cast in one piece, containing the wheels d; e, small corner pieces to strengthen the cast- ing; f, man-hole to get at the step. D, the masonry, in which is formed a circular well for the admission of the shaft A. E, the oaken arm of the crane, supported by a strong brace F; g', shoes or sockets cast with the shaft, which receive the feet of the arm and brace. Fig. 1835 shows the same in section. h, an iron strap inclosing the top of the shaft and bolted securely to the arm E. 1841. 1838. 1837. 1840. C 1839. a J °d 300 50+ 9 600 8 1842. c 2 les 260 c E O C P P 1.270 G, two cast-iron frames for the support of the geering, attached by bolts to the body of the crane through the ears i; jj, projections which support the boxes of the intermediate geer shaft k, the cranks of wrought-iron. H, shaft which can be moved endwise, on which are the two pinions II'; l, a clutch which holds the shaft H in either of three positions m, a rod connecting the two frames or sides G. Operation.-When small weights are to be raised, the pinion I' is thrown into geer with L; on the extremity of its shaft M the pinion N works in the geer o, on the same shaft P with the barrel Q. on which is wound the chain r, which, passing over the rollers R and the pulley S, is attached at its other extremity to the weight to be raised. Figs. 1832 and 1836. But if the weight is considerable, the pinion I is thrown into gear with J, on whose shaft K is a pinion q, geering into L. The break consists of two curved strips of wrought-iron 00, connected by a hinge encircling the pulley n, (on the shaft K,) and brought into more or less contact with it by the lever p, to the arms of which the other extremities of the metallic strips o o are attached. FREEZING APPARATUS. An experiment of freezing water in vacuo, by its own evaporation, Fig. 1845, is shown by a shallow glass vessel, as a watch-glass, for containing the water to be frozen, which is supported over a wide glass basin. containing strong sulphuric acid, the whole covered by a low receiver. When the air is exhausted from the receiver, the acid will absorb the vapor from the water as rapidly as it is found, thereby abstracting the sensible heat from the water, till congelation ensues. 1845. This is a mere matter of experiment, but within the last year an invention has been patented by which ice can be manufactured mechanically in large quanti- ties, and it is supposed economically in low northern and southern latitudes. But it has not yet been sufficiently tested. It consists essentially of a force-pump, in which air is divested of its latent heat by mechanical compression, and an engine in which the same air is made to act expansively, and in the process to absorb from the water to be frozen the heat due to its increase of volume. But there are several auxiliary agents for giving this simple contrivance its greatest effective utility. Thus by an obvious arrange- ment of attaching the pump and engine to the opposite ends of a common beam, the power consumed in condensing air in the pump is, to a considerable degree, recovered in its expansion in the engine. At the same time the heat evolved by the compression of the air is extinguished by a jet of water thrown into the body of the force-pump by means of a smaller pump; while the heat necessary to impart to the expanding air the elasticity and mechanical force due to its volume is furnished through a similar pump, which takes from the cistern a portion of the liquid, and after injecting it into the expanding air in the engine, returns it to the same cistern. The cistern thus operates as a reservoir of cold, and as the sufficient means of abstracting heat from water which is to be converted into ice. It is proposed to use the same air over and over again and thus the inventor attains the object of employing air which previous condensation has deprived of heat, and subsequent expansion has left at a lower temperature than the atmosphere. Digitized by Google FRICTION. 705 FRICTION.-Friction is the resistance occasioned to the motion of a body, when pressed upon the surface of another body, which does not partake of its motion. Under these circumstances, the surfaces in contact have a certain tendency to adhere. Not being perfectly smooth, the imperceptible asperities which may be supposed to exist on all surfaces, however highly polished, become to some extent inter- locked, and in consequence a certain amount of force is requisite to overcome the mutual resistance to motion of the two surfaces, and to maintain the sliding motion, even when it has been produced. By increasing the pressure, the resistance to motion is increased also; and on the other hand, by rendering the surfaces more smooth, and by lubrication, its amount is greatly diminished, but can never be en- tirely nulled. Friction ought not strictly to be called a force, unless that term be in this case taken in a negative sense. The tendency of force, in the rigid meaning of the word, is to produce motion, whereas the tendency of friction is to destroy motion. An active force may indeed oppose motion in one direction, but only in virtue of a tendency to produce motion in the opposite direction; the peculiar characteristic of friction, on the other hand, is that it tends to destroy motion in every direction. It is essentially a passive resistance, a negative force, produced by pressure, to which it bears such relation that its amount may be measured by the same unit and enunciated in the same terms. Nor is the measure of the friction between two surfaces in contact, properly the amount of force necessary to produce motion; but the amount of pressure necessary to balance the friction, and bring the body to a state of indifference to rest or motion. To understand this, let us suppose that a heavy hemispherical body rests with its flat surface upon a horizontal plane, and that the plane and the body are perfectly smooth: on this supposition there would be no friction, and the smallest possible force would put the body in motion. This condition being remarked, let us suppose that the surfaces in con- tact are of the ordinary kind, and that a weight of 10 lbs. attached to the movable body and made to act in the direction of the plane, is found to induce the same state of indifference to rest and motion as in the assumed case of no friction; we then conclude that 10 lbs. is the measure of the friction. As it is not always easy to determine when this condition is induced, it is better to regard the weight as an active force, which may, by addition, be made more and more intense, till motion of the body is actually induced. For the sake of convenience we may also speak of friction as a force and oppose it to other force : this can induce no erroneous conclusion. Friction being then considered a passive force, its effect is the result of having other force to resist. If the measure of the friction of a body upon a plane be 10 lbs., and if an increasing force of 1, 2, 3 lbs, and 80 on, be applied, the friction increases with the force till the limit is reached; motion then ensues by the addition of any fraction of weight to the 10 lbs. The force of friction, although tending to pre- vent or destroy motion, may also be conceived to act like other force, in a direction opposite to that in which the balancing force acts: that A B is, in the language of mechanics, if the force P, applied to balance the friction F, act in the direction A B, the friction F acts in the direction B A. If then the body placed upon the horizontal plane, as supposed, be capable of motion in the two directions A B and BA, the body will remain at rest when acted upon by any force up to 10 lbs. in either of the directions. If therefore we distinguish the forces acting in opposite directions by the positive and negative symbols + and -, then the limits of equilibrium will be expressed by P = ± 10 lbs., according to the usual mode of representing an equilibrium of forces. What is here stated in reference to a heavy body placed upon a horizontal plane, is equally true of the rubbing parts of every machine; the pressure upon the journals, by instituting resistance to motion, that is, friction, the equilibrium will subsist between certain limits, and it is only by transgre-sion of those limits on one side, that the equilibrium is destroyed and motion established. To determine accu- rately those limits in machines, is one of the most important problems in mechanics; and it has only been by the elaborate and admirably conducted experiments of the French Academy, that a sufficiently extensive code of data has been attained possessing the requisite evidence of accuracy, to warrant im- plicit confidence in the truth of the following important laws, which include the whole doctrine of fric- tion as a retarding force in the dynamical operation of machines. LAW L- The friction bears to the pressure upon the surfaces in contact, a ratio which is constant for the same materials with the same condition of surfaces. To express this somewhat more familiarly: If the surface of one body be pressed upon that of another, with a certain force, and if that force be doubled, the friction will be doubled; and if the force pressing them together be tripled, the friction will be tripled; and so on. Thus if a piece of cast-iron weighing 100 lbs. be laid with its plane surface upon a larger surface of brass, level, and it be found that a certain weight made to act in the direction of the supporting plane, is just sufficient to induce in the mass of iron a state of indifference to rest or motion, that weight is the measure of the friction be- tween the two surfaces; and if these be well polished and clean, and without lubricant of any kind, the weight which it will be necessary to apply will be 14.7 lbs. If now we place a weight of 100 lbs. upon the mass of cast-iron, making the gross pressure upon the surfaces in contact 200 lbs,, the weight neces- sary to balance the friction will be increased in the same ratio, that is F = 14-7 lbs. X 2 = 29 lbs. Another weight of 100 lbs.. placed on the first, making the pressure 300 lbs., will increase the measure of friction to 14-7 lbs. X 3 = 44.1 lbs. And 80 on for every increment of pressure as expressed by the law. If now we divide the weight which balances the friction, by the weight which measures the pressure upon the surfaces, we obtain a ratio which is manifestly constant, since the pressures upon the surfaces and the weights balancing the friction, corresponding to those pressures, are respectively multiples throughout, of the first units 100 lbs. and 14-7 lbs. Thus we have 14.7 lbs. 294 lbs. 44.1 lbs. 100 lbs. 200 lbs. 300 lbs. From this then it appears, that knowing the measure of the friction for a given unit of pressure upon 89 Digitized by Google 706 FRICTION. the surfaces in contact, these remaining constant in kind and condition, the measure of the friction an- swering to any other pressure may be deduced. In the case assumed we have a common ratio of .147 between the pressures of contact, and the measures of the friction; this ratio therefore being known, together with the pressure in the particular case, the measure of the friction for that case will also be known. Putting P = the pressure upon the rubbing surfaces; F = the measure of the friction; and f=ₚ; then we have F=fxP. In this formula the ratio f of the friction to the pressure is termed the coefficient of friction. Its value, as already announced, is constant for the same materials and condition of the surfaces in con- tact; but varies as these vary. Thus in the particular case taken, the value is .147; but if the rubbing surfaces be unctuous, it is reduced to 132; that is, by repetition of the experiments described above, with this new condition of surfaces, we should find 132 X 100 lbs. = 132 lbs. = = -132 X 200 lbs. = 26'4 lbs. } measures of the friction. = = 132 X 300 lbs. = 396 lbs. If a cast-iron plate be substituted for the brass plate used as the supporting surface, and the surfaces be first well polished, clean, and dry, next wetted with water, and lastly, be freely lubricated with hogs' lard, we have the three values = 314, answering to these conditions; hence taking P as before, we have by substitution in the formula F=fxP, the following results: Surfaces wet. Surfaces dry. Surfaces lubricated. For 100 lbs. F = 15.2 lbs. F 31·4 lbs. lbs. 200 lbs. F = 304 lbs. 628 lbs. = 14 lbs. 300 lbs. F = 45-6 lbs. F 932 lbs. F 21 lbs. The determination of f, that is, of the coefficient of friction, for different kinds of materials, and also for different states of their surfaces in contact, is manifestly the business of experiment. There is no a priori rule by which it can be arrived at in the present state of our knowledge of the physical prop- erties of bodies. 1846. There is another mode of considering the subject here discussed, which has its expression likewise in the subjoined table, and which it becomes us therefore to explain.-Let us suppose the arrange- P ment as in the experiments described, and that AB, Fig. 1846, is the supporting surface, and C the mass of cast-iron resting upon it. Again, let the pressure of the mass acting perpendicularly to the surfaces in contact, be denoted by P, and let the force Q, parallel to the surfaces, be applied to slide the c body towards A. Then since the forces P and Q a F act in directions perpendicular to one another, B A they manifestly cannot counteract one another; consequently, were there no third force F opposed to Q. the system would be unbalanced, and there would obviously be motion of the mass C in the direction of the second force. The third force F is the friction, and so long as the force Q does not exceed its limit, the system must remain stable. This being understood, let us suppose that the force P, Figs. 1847 and 1848, instead of having its direction perpendicular to the surfaces in contact, is impressed obliquely; if then the parallelogram of forces P' Q be completed, the force P, represented by the line M, is equivalent to two others represented by P'M, by which the surfaces are pressed together, and Q M which tends to give motion to A the body in a direction parallel to the sur- B 1847. B 1848. faces. Now the actual friction F of the "P surfaces must be a certain fraction of P P P PM; let it be MQ'=MF and complete P P the parallelogram P'Q', and draw its diagonal P"M. Since then repre- sents the friction of the body upon the plane, that is, the resistance called into action by the force PM, and since Q M represents the whole tendency of PM to produce motion of the body, it follows that the body will move or not according as QM is greater or less than Q'M, that is, as PP' is greater or less than P"P', or as the angle PMA is greater or less than the angle BMA. These conditions Q d) M are shown in the diagrams: in the first F É a M F there would be motion induced by the preponderance of force QQ'; in the second, the friction F = MQ' being greater than QM, the system would remain at rest. The angle BMA is termed the limiting angle of resistance, or more shortly the angle of friction. Its tangent is the fraction which is the coefficient of friction. The angle is manifestly Digitized by Google FRICTION. 707 the same for surfaces of the same nature, whatever be the actual amount of the impressed force P; but is different for different surfaces. From this then it appears that the force impressed upon the surface of a solid body, at rest, by the intervention of another solid body, will be destroyed, whatever be its direction, provided only the angle, which the direction makes with the perpendicular to the surface, do not exceed the angle of friction of that surface; and that this is true, however great the force may be. Also that if the direction of the force lie without this angle, it cannot be sustained by the resistance of the surfaces in contact; and that this is true, however small the force may be. This beautiful principle of the angle of friction was first examined by the celebrated mathematician Euler. His mode of demonstration was different, and in some respects, more obvious; it consisted in showing at what angle of inclination a body would begin to slide down an inclined plane. By similar reasoning to that employed above, it is readily determined that the body will just be sustained on the inclined plane, without slipping, when the inclination of the plane is equal to the limiting angle of re- sistance; and the tangent to the angle of inclination is the ratio of the friction to the pressure. Know- ing therefore this angle the coefficient of friction is known, and conversely, the coefficient being known the inclination is likewise known. LAW II-The measure of friction is independent of the extent of surface, the pressure and the condi- tion and character of the surfaces remaining the same. This important property of friction was also first announced by Amontons; and finally established by M. Morin, who found it to hold good, even at pressures so great that the surfaces were considerably abraded. It might, in fact, be inferred from the law previously explained, to which it is nothing more than a corollary; for by increasing the surface which supports the pressure, the amount of pressure upon every point of the surface is diminished and although there are more rubbing points, their aggre- gate amount of friction must of necessity be the same as before. It can readily, however, be conceived that there will be a limitation to the proposition, when the rubbing surface is 80 small in proportion to the pressure, that abrasion of the surfaces ensues to an immoderate extent, (as in the operations of cut- ting and hewing, which are not contemplated in the enunciation;) but if the surface is sufficient to ren- der the cutting and wearing, and also the heating, imperceptible, then the friction is as the pressure, and independent of the extent of the surfaces. LAW III-The friction is entirely independent of the velocity of continuous motion. This fact results from the experiments of M. Morin; but it must not be supposed that it implies that the same amount of mechanical power is expended in overcoming friction at all velocities of motion. On the contrary, the law implies that the amount of mechanical power expended in overcoming the friction, is proportionate to the velocity of the motion, since a constant force must be exerted with a varying velocity. For instance, whatever amount of mechanical power may be lost by the friction of the parts of any machine, while moving with a given velocity, (supposing the pressure on the rubbing parts to remain constant,) a double power will be lost by friction when the machine moves with a dou- ble velocity and 80 on in proportion. It also follows that the amount of mechanical power lost by friction will, in all cases, be proportionate to the space passed over by the surfaces in contact without regard to time; for instance, the amount of mechanical power, which must be expended to move a car- riage for a given distance along a level railway, will be the same whether it travels quickly or slowly over that distance. The friction is, in short, a uniformly retarding force, and is always the same fraction of the pressure, however great, (within certain limits,) and however small that pressure may be. From the preceding discussion, it then appears that the whole doctrine of friction may be reduced to the single proposition that the friction is proportionate to the pressure upon the surfaces in contact, and independent of the extent of these surfaces, and of the velocity of their motion. There is still, however, to be noted the extreme case of no velocity after the two surfaces have remained for a considerable time in contact. If a body be laid upon an inclined plane, and the angle of this be very slowly increased, the body will not begin to slide down when the inclination is exactly equal to the angle of friction. This condition of quiescent friction was also investigated by M. Morin, and a summary of the results which he obtained will be found in the subjoined table. It must, however, be observed that this species of friction does not only differ in its amount from the friction of surfaces in continuous motion, but like- wise in its nature, especially in this, that the friction of quiescence is subject to causes of variation and uncertainty from which the friction of motion is exempt. Nor does the variation appear to depend upon the extent of the surfaces of contact; for with different pressures, the ratio of the friction to the pres- sure, that is, the coefficient of friction, varied greatly, although the surfaces in contact remained the same. This uncertainty appears at first to complicate the whole question; but fortunately the difficulty is removed by a second very important fact developed accidentally in the course of the experiments; namely, that by the slightest jar or shock, even the most imperceptible movement of the surfaces of con- tact, the friction is made to pass from a state accompanying quiescence to that entirely different state of friction which accompanies motion, and as every machine, of whatever kind, may be considered subject to such shocks, it is evident that the state of friction to be made the basis on which all questions of statics are to be determined, should be that which accompanies continuous motion, the laws of which are uniform and precise. The actual measure of the friction of two rubbing surfaces for a given pressure, must obviously de- pend upon the hardness and smoothness of the surfaces, as upon these depend the extent of the mutual penetration and interlocking of the insensible asperities. It was also supposed to be established by the experiments of Coulomb, that the friction between similar substances is greater than between substances which are dissimilar; but this conclusion, although it has been long received as a general law of fric- tion, is not sanctioned by the investigations of M. Morin, which are in every respect more worthy of confidence than those upon which the assumption is based. When lubrication is employed to lessen the friction, a distinction is to be made between the case in Digitized by Google 708 FRICTION. which the surfaces are simply unctuous and in intimate contact, and the case in which the surfaces are wholly separated from one another by an interposed stratum of the unguent. If the pressure upon the surfaces of contact of given dimensious be increased beyond a certain limit, the latter of these cases passes into the first; the stratum of unguent being pressed out, and the unctuous surfaces which it separated from one another being brought into intimate contact. As long as either of these two states romains, the laws of its friction are not affected by the pressure of the unguent; but in the transition from the one state to the other, an exception is made to the independence of the friction upon the extent of the surfaces of contact for supposing the extent of two surfaces of contact between which a stratum of unguent is interposed, and which sustains a given pressure, to be continually diminished, it is evident that the portions of this pressure which take effect upon each element of the surfaces of contact will be continually increased, and that they may thus be so increased, as to press out the interposed stratum of unguent, and cause the state of the surfaces to pass into that designated as unctuous, thereby chang- ing the coefficient of friction. The second law of friction then, which is known as the law of the in- dependence of the surface," is to be received in the case where a stratum of unguent is interposed, within certain limits. The observation made by M. Morin, that whenever two perfectly clean surfaces were made to move upon one another, both were worn into alternate ridges and channels, accompanied by the formation of a powder, is not without its practical value. During the experiments this effect was invariably pro- duced whenever the pressures were very great, and was commonly attended in the experiments upon the friction of woods. with the odor of burning wood. The effect was also found to be very considera- ble in the case of fibrous metals, such as wrought-iron, sliding upon each other; less in the case of granular metals, such as cast-iron, sliding upon the fibrous; and least of all when the granular metals were slid upon one another. This was found not to be the case when the surfaces of contact were unctuous, and the circumstance suggested to M. Morin what appears to be a true explanation of the remarkable difference between his results and those of Coulomb. He conceives that in the experiments of that celebrated engineer, the requisite precautions had not been taken to avoid unctuosity-such as might present itself accidentally in polishing the surfaces. In that case abrasion would be prevented, and instead of a new surface being continually presented by wear, the same surface would remain, and receive by the motion continually a more perfect polish. Rolling friction.-The theory of rolling friction is by no means firmly grounded. We know that it increases with the pressure. and that it is greater for a smaller than for a larger diameter of the rolling body; but in what algebraical dependence this friction stands to the pressure and diameter of the rolling body, cannot as yet be considered as determined. Coulomb made only a few experiments with rollers, from two to twelve inches thick, of lignum-vite and elm, which were rolled along a surface of oak, by means of a thin thread passing over a roller whose extremities were stretched by unequal weights. From the results of these experiments, rolling friction appears to increase directly with the pressure and inversely with the diameter of the roller, 80 that the force necessary to overcome this friction may be expressed by F=/R, if R be the pressure, r the radius of the roller, and f the coefficient of f.iction derived from experiment. If r be given in inches, then from these experiments, for rolling upon compressed wood, if the wood be These formulas suppose that the force F acts at the circumference of the roller, but if the force be applied to the axis of the rolling bodies, by which, as in every description of carriage, axle friction ensues, the required force is F, because here the arm is only half that of the diameter with respect to the point of application. Explanation of the tables.-The first and most extensive of the following tables, contains a very complete summary of M. Morin's experiments of the friction of plane surfaces sliding upon another. It embraces the three conditions of clean and unctuous surfaces, and surfaces between which a stratum of the lubricant is interposed. The coefficient of friction is given for each of those conditions for both the friction of motion and the friction of quiescence, and also the limiting angle of resistance answering to the coefficients of friction in the cases of clean and unctuous surfaces. The sliding surfaces were varied from 03336 to 2.7987 square feet, and the pressures from 88 lbs. to 2205 lbs. The surfaces of the woods were planed, and those of metal filed and polished with the utmost care; and when the friction of the clean surfaces was to be determined, any unctuosity was especially guarded against. In the experiments upon unctuous surfaces, the unguent was carefully wiped off, 80 that no interposing layer of it should prevent their intimate contact. In the experiments to determine the friction with unguents interposed, the extent of the surfaces bore such a relation to the pressure, that a stratum of the lubri- cant was retained between them. The relations kept in view were such as are commonly found in the larger class of machines in which the adhesion of the lubricant to the surfaces of contact may, as re- spects opposition to motion caused by its viscidity, be overlooked as altogether insignificant compared with the friction. As respects the nature of the substance used in lubrication, it will be observed by comparison of the coefficient of the friction of motion, that with hog's lard and olive oil, surfaces of wood on metal, wood on wood, metal on wood, and metal on metal, have all very nearly the same fric- tion, the value of the coefficient being in all those cases included between 0.07 and 0-08. With tallow the coefficient is the same except in the case of metals upon metals; this lubricant seems therefore less suited for metallic surfaces than the others named. The second table contains the results of experiments upon the friction of axles of different materials upon their bearings. It requires no further explanation, but attention may be directed to the advan- tage to be derived from attention to the mode in which the lubricating substance is applied. Digitized by Google FRICTION. 709 SUMMARY OF M. MORIN'S EXPERIMENTS OF THE FRICTION OF PLANE SURFACES. Friction of Friction of motion. quiescence. SLIDING SURFACE Limit- Limit- STATE OF THE SURFACES. SURFACE. Co-effi ing an. an- Co-effi. AT REST. ing an- cient of gie of cient of gle of friction. resist. friction. resist- nuce. ance. Without lubrication 0.478 25.33' 0-625 39. 1 Oak Oak Direction of fibres parallel to tallow 0.975 0-160 the motion Lubricated with lard 0.067 Without lubrication 0.324 17 58 0.540 28 23 Uncinous 0.143 8 9 0-314 17 96 do do Fibres of the moving surface tallow 0.083 0-254 perpendicular to the motion. Lubricated with lard 0.072 water 0.250 Fibres of both surfaces perpen- do do dicular to the direction of the Without lubrication 0.336 18 35 motion Fibres of the moving surface do perpendicular to the surface of do contact, and those of the qui- Without lubrication 0.192 10 52 0.271 15 10 eacent surface parallel to the motion do do Fibres of both surfaces perpen- dicular to the surface of con- Without lubrication 0.43 23 17 tact, or the pieces end to end Without lubrication 0.246 13 50 0.376 20 37 Unctuous 0.136 7 45 Oak Elm Fibres parallel to the motion dry soap 0.136 Lubricated with tallow 0-073 0.178 lard 0.066 Without lubrication 0.432 23 92 0.694 34 46 Unctuous 0-119 6 48 0.420 22 47 Fibres parallel to the motion dry soap 0.137 0.411 Elm Oak Lubricated with tallow 0.070 0.142 lard 0.060 Fibres of the moving surface Without lubrication 0.450 24 16 0.570 29 41 perpendicular to the motion Without lubrication 0.360 19 48 0-530 27 56 Beech Oak Fibres of both surfaces parallel Unctuous 0.330 18 16 to the motion Lubricated with tallow 0.550 Ash and Sor- Without lubrication 0.400 21 49 0.570 29 41 rel wood do do 0.355 19 33 0.590 27 29 Fir Oak Fibres of both surfaces parallel do do 0.370 20 19 0.440 23 45 Pear-tree to the motion. do do 0.619 31 47 0.619 31 47 Wrought-iron Cast-iron Lubricated with dry soap 0.214 tallow 0.085 0.108 Tallow 0.098 Greased and saturated with water 0.256 0.649 Oak Wrought-iron Without lubrication 0.252 14 9 Elm Elm do do Unctuous 0.138 7 52 Wrought-Iron do tallow 0.078 Lubricated with lard 0.076 olive oil 0.055 Without lubrication 0.490 26 7 Unctuous 0.107 6 7 0.100 5 43 dry soap 0.189 tallow 0.078 0.100 Cast-iron Oak do do. Lubricated with lard or olive oil 0.075 0.100 Greased and saturated with water 0.218 0-646 Fibres of the wood parallel to Lubricated with tallow 0.80 Oak Cast-iron the motion do do. perpedicular Without lubrication 0.372 20 25 to the motion do do. 0-195 11 3 tal- Surface unctuous with low 0.125 7 8 Cast-iron Elro do do. parallel to lard 0.137 7 49 the motion. tallow 0.077 Lubricated with lard 0.091 olive oil. 0.061 Surfaces unctuous 0.135 7 42 0.098 5 36 do. lubricated with tallow 0.066 Elm Cast-iron Without lubrication 0.394 21 31 Hornbeam do. Pear-tree do. do do do do. 0.436 23 34 do do. 0.617 31 41 0.617 31 41 Copper Oak Surfaces unctuous 0.100 5 43 Lubricated with tallow 0.069 0.100 Without lubrication 0.138 7 52 0.137 7 40 Surfaces unctuous 0.177 10 3 Wrought-iron Wrought-irom Fibres of both surfaces par- tallow 0.082 allel to the motion Lubricated with lard 0.081 olive oil 0.070 0.115 Without lubrication 0.194 10 59 0.194 10 50 Surfaces unetuous 0.118 6 44 Wrought-iron Cast-iron do do tallow 0.103 Lubricated with lard 0.076 olive oil 0.066 0-100 5 43 Digitized by Google 710 FRICTION. SUMMARY OF M. MORIN'S EXPERIMENTS OF THE FRICTION OF PLANE SURFACES.-(Continued.) Friction of Friction of motion. quieecence. SLIDING SURFACE Limit- Limit. STATE OF THE SURFACES. Co-effi. ing an- Co-effi- ing an- SURFACE. AT REST. cient of gle of cient of gie of friction. restal. friction. resist. ance. ance. Surfaces unctuous 0.143 8' 9' Cast-iron Wrought-iron Fibres of both surfaces par- Lubricated with tallow 0.100 5.43' allel to the motion Without lubrication 0.152 8 39 0.162 9 13 Surfaces unctuous 0.144 8 12 water 0-314 soap 0.197 tallow 0.100 5 43 0.100 5 43 Cast-iron Cast-iron do do Lubricated with lard 0.070 0.100 olive oil. 0.064 lard and pl'bago. 0.055 Without lubrication 0.172 9 46 Surfaces unctuous 0.160 9 6 Wrought-iron Bronze Fibres parallel to motion tallow 0.103 Lubricated with lard 0.075 olive all. 0-078 Without lubrication 0.161 9 9 Surfaces unctuous 0.166 9 26 tallow 0.081 Bronze Wrought-iron do do Lubricated with lard and pl'bago. 0.089 olive oil. 0.072 Without lubrication 0.147 8 22 Surfaces unctuous 0.132 7 98 Cast-iron Bronze do do tallow 0.103 Lubricated with lard 0.075 olive oil. 0.078 Without lubrication 0-217 12 15 Surfaces uncluous 0.107 6 7 Bronze Cast-iron do do. tallow 0.086 0-106 Lubricated with olive oil 0.077 Without lubrication 0.201 11 22 Bronze Bronze do do. Surfaces unctuous 0.134 7 38 0.164 9 19 Lubricated with olive oil 0.058 Without lubrication 0.189 10 49 Surfaces unctuous 0-115 6 34 Brass Cast-iron do do. tallow 0.072 0.103 Lubricated with lard 0.068 olive oil 0.066 Without lubrication 0.202 11 26 Steel tallow 0.105 0-108 Cast-iron do do Lubricated with lard 0.081 olive oil 0.079 Lubricated with tallow 0.093 lard 0.076 Steel Wrought-iron Fibres of iron parallel to the Without lubrication 0.152 8 39 Steel tallow 0.056 Bronze motion olive oil 0.053 Lubricated with lard and pl'bago. 0.067 Fibres of the oak parallel Black leather Without lubrication 0.265 14 51 0.74 3631 leather laid flat (as used for Oak do. polished and light straps) hardened by do do 0.296 16 30 hammering Ox hide (such 0.52 27 29 0.605 31 11 as used for Without lubrication do rough 0.335 18 31 0.43 23 17 strong belts Fibresof woodparallel smooth Leather saturated with &c.) water 0.29 0.79 Surface unctuous 0.229 12 54 0.267 14 57 Greased and saturated with do Cast-iron do do water 0.365 Lubricated with tallow 0.159 olive oil. 0.133 0.122 Surfaces unctuous 0.244 13 43 do Brass do do tallow 0.241 Lubricated with olive oil. 0.191 Fibres of hemp not twisted and placed in a direction perpen- Hemp Oak dicular to those of the motion Greased and saturated with fibres of the oak parallel to the water 0.338 0.889 motion Hemp Cast-iron Fibres of hemp, as above Hemp-twist Cast-iron do tallow do. 0.194 Lubricated with olive oil. 0.153 Fibres of the wood and direction Hemp-band Oak of the cord parallel to the mo- Without lubrication 0.52 27 29 0.64 22 38 tion Hemp plait band ofsmall do do do do do 0.28 17 45 0.50 26 34 cords Old cordage If in. diam do do do do do 0.58 27 29 0.79 38 19 Digitized by Google FRICTION ROLLERS. 711 RATIOS OF FRICTION TO PRESSURE FOR AXLES IN MOTION IN THEIR BEARINGS. I.-ACCORDING TO MORIN'S EXPERIMENT. State of Surfaces and nature of Lubrication. Designation of surfaces Oil, tallow, or hogs' lard. Dry Greasy, Lubricated, Purified Hogs' lard Greasy, in contact. or slightly and wet with and wet with Supplied in The grease very soft with very soft to greasy. water. water. the ordinary continually grease. plumbago. the touch. manner renewed. Bronze on bronze 0.079 do. on cast-iron 0.049 Iron on bronze 0.251 0.189 -075 0.054 0.000 0·111 do. on cast-iron .075 0.054 Oast-iron on cast-iron 0.137 0.079 .075 0.054 do. on bronze 0.194 0·161 0.075 0.054 0.065 0.137 Iron on lignum-vite 0.188 0.125 0.166 Cast-iron on do 0-185 0.100 0.92 0.109 0.140 Lignum-vite on cast-iron 0-116 0-153 do. on lignum-vitse. 0.170 IL-ACCORDING TO COULOMB'S EXPERIMENT. Dry. Olive-oil. Hogs' lard. Tallow. Greasy. Old lubrication. Observations. Iron on copper 0-155 0·130 0.120 0.085 0.127 0-133 The number relative to Iron on wood 0.050 the friction of iron on Green-oak on lignum-vite 0.060 wood is deduced from a 0.038 0-070 pulley. the lubrication of do. on elm 0.030 0-050 which, or the nature of the Box on lignum-vitse 0.043 0.070 axis and bearings, are not Box on elm 0.035 0.050 mentioned by Coulomb. FRICTION ROLLERS. The obstruction which a cylinder meets in rolling along a smooth plane is quite distinct in its character, and far inferior in its amount to that which is produced by the friction of the same cylinder drawn lengthwise along a plane. For example, in the case of wood rolling on wood, the resistance is to the pressure, if the cylinder be small, as 16 or 18 to 1000; and if the cylinder be large, this may be reduced to 6 to 1000. The friction from sliding, in the same cases, would be to the pressure as 2 to 10, or 3 to 10, according to the nature of the wood. Hence, by causing one body to roll on another, the resistance is diminished from 12 to 20 times. It is therefore a principle in the composition of machines that attrition should be avoided as much as possible, and rolling motions sub- stituted whenever circumstances admit. On this principle depends the advantages resulting from the application 1819. of friction wheels and friction rollers. The extremity of an axle C, instead of resting in a cylindrical socket, is made to rest on the circumferences of two wheels, A and B, to the axles of which, a and b, the friction is transferred, and consequently diminished in the ratio of the radius of the wheel A to the B radius of the axle a. This ingenious contrivance appears to have first been applied by M. Sulley, in the year 1716.-Descr. Abrigée d'une Horoge, &o., Bordeaux, 1716. The following are deductions from Coulomb's experiments relative to the friction of rolling bodies: 1. Like the friction of sliding bodies, it is a con- stant force. 2. It is affected by the nature of the surface 80 far as polish is concerned; but is not lessened by the interposition of unctuous substances. 8. It is less between heterogeneous than between homogeneous substances. 4. It is directly propor- tional to the pressure. 5. It has no relation to the magnitude of the surface. 6. It is much less than in the case of sliding surfaces, and varies in the inverse ratio of the diameter of the rolling body. The friction of the axle of a wheel or pulley (whether the axle itself turns, or the wheel turns on the axle) is of a different kind from that of a cylinder rolling on a plane. It is less than that of sliding but greater than that of rolling bodies, and follows in all respects the laws of the friction of sliding bodies. A great advantage is here obtained by greasing the surfaces. By the application of fresh tallow the friction is reduced to one half. Friction is one of the most effectual means of arresting motion. In some 1850. machines, especially wind-mills, cranes, &c., it is very important to have the power of suddenly stopping the machine, or at least of controlling its motion. This is effected by means of a strong bridle of wood or iron, a b c, fixed at one end, and at the other furnished with a lever, by pressing on which, the bridle is brought into close contact with the broad rim of a wheel which participates in the general motion of the machine. The bridle may be made to bear on the whole circum- ference of the wheel; and a moderate pressure on the lever will produce a resist- ance sufficient to destroy the motion almost instantaneously. Coulomb's experiments were also directed to ascertain the resistance arising from the rigidity of ropes when bent round rollers or cylinders. The results are as follows 1. The resistance of ropes are directly proportional to the tensions to which they are subjected. 2. The resistance increases with some determinate power of the diameter, and is greatest in ropes that have been strongly twisted. or are coated with tar. 3. The resistances are inversely as the diameters of the cylinders about which the ropes are bent. Digitized by Google 712 FRINGE MACHINE, SHAWL. When a rope is wound more than once round a cylinder, the resistance increases in a geometrical progression. This principle is frequently applied in practice: thus, in arresting the progress of a vessel, a rope is wound round a post, and a very few turns is sufficient to overcome any force which the rope is capable of withstanding. FRINGE MACHINE, SHAWL, invented by Milton D. Whipple, and used at the Bay State Mills, Lawrence, Mass., to twist the fringe of shawls, is a very successful, and as far as our knowledge extends, the only machine which has ever been applied for this purpose. We extract from the patentee's spe- cifications the following description of it and its operations:- The machine is so constructed as to imitate and perform the ordinary manual operations of dividing the yarns into proper quantities to form the two single strands, and then twisting the said strands separately in one direction, and afterwards bringing together and twisting them in opposite directions to form the fringe. A'A'A'A' is the framework of the machine. a a, a' a' is a stretching frame, 1851. having a strip of card teeth bb, Fig. 1852, on the stationary side of the frame, and a set of vertical points on the sliding bar a' a'. The yarn from which the fringe is 0 à formed, having woven fabric on each side as usual, is stretched from said card teeth to said points, and the bar a' a' is arranged и 0 so as to slide in and out to accommodate t different lengths of fringes. This stretch- 0 ing frame is moved, or fed along by means of rack teeth formed on the under side of the bar a a, as shown at c, Fig. 1851, which engage with the teeth of a pinion d, on the shaft e said pinion being q shown by dotted lines in Fig. 1852. This shaft has one of its bearings on the top of one side of the framework A'A'A'A', as shown at Fig. 1852; its other bearing being in a diagonal mortise g in the ad- justable aliding bar hh, fitted in the op- posite side of the framework, as shown by dotted lines in Fig. 1852, and in detail q in Fig. 1854; 80 that by moving the said sliding bar in one or the other direction, the pinion may be thrown into or out of geer with the rack, and permit the stretch- ing frame to be moved backwards, after twisting the fringe of one side of a shawl, for a new operation. During the oper- ation of twisting, this frame is fed along accurately by means of a ratchet wheel i, q on the shaft 11, the teeth of which are operated upon by the long pawl k, work- ing on an eccentric l, fitted on the driving shaft m m, as shown in Fig. 1852, and by dotted lines in Fig. 1853. The feed motion is regulated by means of the adjustable forked supporter n, in which the pawl k rests, as shown in the drawings. By raising or lowering which supporter, the fall of the pawl k, when it is drawn backwards on the ratchet wheel i, by the action of the eccentric l, will be diminished or increased, as the case may be. The machinery for dividing the yarns into proper quantities, to form the two single strands, as here- inbefore suggested, is as follows :-0 are two metallic triangular dividing plates, set at a proper interval apart on opposite sides of the elliptical ring pp, which ring is firmly fitted on the top of the vertical sliding beam gg, Figs. 1852 and 1853, arranged so as to slide up and down in proper guides r, as shown in the drawings. The plates 00 are curved transversely and vertically, 80 as to effectually separate the yarns, and have a rectangular slot or opening formed through each, as shown at Fig. 1851, for the passage of twisting fingers or rubbers, hereinafter described. The yarns embraced between these plates 00 are subdivided or halved, for the purpose of forming two strands by means of the separator tu, having the same triangular contour as the plates 00, so as to enter, as they do, between the yarns at a mere point at first, and not get entangled with them. This separator is constructed in two parts, with sufficient space cut out to allow the passage of the rubbers or twisting fingers before referred to; both of said parts being connected to the top of the sliding beam VV, arranged side by side with that before referred to, and denoted by q q. and moving up and down in the same guides. One of said parts t of the separator is required to be fixed to said beam VV, and the other U is hinged, as shown by dotted lines in Fig. 1851, so as to turn from it, when in descending, it comes against the top of the upper twisting fingers;-the operation being similar to that of a pair of callipers or bent compasses used for measuring the diameter of cylinders, &c. After the yarns have been divided, as above described, into two parcels for the formation of two strands, they are twisted by the curved twisting fingers or rubbers W X, which slide over each other, Digitized by Google 713 Digitized by Google a B n FRINGE MACHINE, SHAWL. H m E m 1852. y á a a' a & 06 E d c a I f I I l 714 FRINGE MACHINE, SHAWL. y :- V 1853. I g A. a Digitized by Google FULLING. 715 one above and the other below the yarns, as they pass through the openings in the dividing plates o o and separator t u. These twisting fingers or rubbers should be clothed with leather, or some other suitable substance, sufficiently rough to turn and twist the yarns. They are connected to the ends to two arms a b¹, pro- jecting out when the machine is stationary, about at right angles to each other, from the vertical shafts c', d d', and arranged with set-screws so as to be adjustable thereon. The vertical shafts have proper bearings in the framework, and are connected in their movements, so as to turn together by the pinions e' f' arranged on them as shown in the drawings. Said shafts are turned inwards, 80 as to bring the twisting fingers towards and over each other by the projecting stud g, inserted in the shaft c' c', as shown in Fig. 1858, and abutting against the cam formed on the pulley h', on the driving shaft, as shown in Fig. 1852. The outward or back turning of said shafts c' c', d'd' is effected by the heavy counteracting weight i', connected to the shaft d' d, as shown in Fig. 1853. When the rubber or twisting fingers are passing over each other, twisting the yarns into two strands, the yarns are supported and lifted up in grooves in the upper side of flange pieces set on each side of the two parts 1 u of the separator, as shown at k' k' k', &c., Fig. 1853, by dotted lines; and after the two strands are sufficiently twisted, the separator tu is drawn downwards, opening over the rubbers or twisting fingers in its descent; which descent is effected by the cam l' on the driving shaft m m, said cam operating on the treadle m' m', the moving end of which is connected to the vertical sliding beam V v, on which the separator is fastened as above suggested. 1854. When the separator IS withdrawn after the two strands are twisted, as above explained, the rubbers or twisting fingers are moved outwards by the action of the weight as above described,-twisting the two strands together firmly, and forming the fringe as perfectly as it can be done by the most skilful operative. The two dividing plates o o are then withdrawn by a cam n' on the driving shaft, said cam operating on the treadle o' o', and vertical sliding beam qq, on which said plates are fixed, in the same manner as explained above, for the beam V V and cam and treadle by which it is operated. The stretching frame is now fed along, and the cams ceasing to act upon the treadles, the retroacting springs p', p', connected to the beams V V and qq, bring them, and with them the plates 0 and separator 26, between the yarns for another operation. While the yarns are being divided by the plates 00 and separator, it is absolutely essential that they should be stretched transversely a little and held tight, in order to be easily divided, and that during the operation of twisting, this stretching and holding should be gradually relaxed. This result is attained by the long metallic hooked depresser and holder q' r', which moves up and down in proper guides or mortises in the framework. The end r' of this depresser and holder falls on the yarn just behind the plates o o and separator 26, and immediately after said yarns have been divided, and presses them into a groove or bent plate formed at 8', Figs. 1852 and 1851, to receive them. This bent depresser is operated by an arm t', which extends at right angles from one side of it, and rests on the face of a proper cam, formed to regulate its motion on the pulley h', as shown by dotted lines in Fig. 1853. The patentee claims-First. Dividing the yarns into proper quantities for the formation of the two strands, by means of the dividing plates and separator. Second. Twisting the two strands separately first, and then together, by means of the twisting fingers or rubbers, constructed and arranged 80 as to turn inwards and outwards over each other, one above and the other below the yarns. Third. The peculiar construction and arrangement of the separator, 80 that it may open over the rubbers, and drop down just before the two strands are to be twisted together. Fourth. A machine for twisting the fringes of shawls, &c., having a stretching frame, dividing plates, and separator, twisting fingers or rubbers combined, and operated successively, as hereinbefore specified and described. 1855. FROG. The cast-iron crossing plate at the in- tersection of two lines of rails on a railroad. The intermediate point, being subject to great wear from its small surface and exposed position, is usually made of steel. This improvement was made the o subject of a patent in 1837. FULCRUM, in mechanics, the prop, support, or fixed point upon which a lever is sustained; and about which the lever is supposed to turn freely. FULLING. A process by which woollen cloths are divested of the oil imbibed for the operation of carding, and the texture is at the same time rendered much closer, firmer, and stronger. This process, also called milling, was formerly entirely performed by the machine described under the head of Fall- ing Stocks, also called fulling stocks, and fulling-mill. The stocks, although still in extensive use, are fast being superseded by a superior class of machines, in which the cloth passes between squeezers, and is not subjected to heavy b'ows. By these machines the pressure can be regulated according to the quality and requirements .f the fabric. the milling is more perfect, the power expended is less, and, not least, the disagreeable noise consequent on the use of stocks is avoided. Figs. 1856, 1857, and 1858, represent different views of one of this class of machines. Fig. 1856 is a side elevation, Fig. 1857 a cross section, and Fig. 1858 a front end elevation of the machine. It will be Digitized by Google 716 FULLING. perceived that the machine is composed of four cylinders n n' ff' running horizontally, arranged in pairs one above the other, and two vertical cylinders gg'. Both horizontal and vertical cylinders are sub- jected to pressure: to the former it is applied by means of the weight movable on the arm of the m 1856. C I a a' 9 9 d A A 0 6 a A 1858. 1857. t a 5 o D a (1) 8 e n D 0 n 0 0 D 0 o A a a lever C, which forces down the yoke k on the boxes of the cylinder. The pressure is applied to the vertical cylinders by the variable weight 8, through the levers w. In both cases the pressure to be ex erted can be varied at pleasure. Digitized by Google FULLING. 717 The operation is as follows one end of the cloth having been passed between the sets of horizontal and vertical cylinders, the two ends of the cloth are then attached together, 80 as to make an endless band. The machine is now set in motion by the pulley e on the shaft b, and the cloth continues to make the round between the cylinders or squeezers, falling in folds at the front of the machine, and drawn up again at the back till the washing and fulling is finished. A rotary fulling-mill, still better than the 1859. preceding, is given in Figs. 1859 and 1860. Fig. 1859 is the side elevation, and Fig. 1860 the longitudinal section, showing the interior arrangement. P A A is the main cylinder, (driven by a geer;) on either side are cheeks between which the small cylinders or rolls B' B' B' re- Bo volve, and between these rolls and the cyl- inder the cloth passes. C is the lower side or bottom of a trough which receives the K cloth after it has passed the roll B', and down which it slides into the tub d' d' d', L curved, as shown in the drawings. D is the top of the trough, and is supported by the cross piece d; its upper extremity touches, but without friction, the surface of the roll B'. EE are the grooved sides of the trough; their upper extremities are held by small iron straps attached to the frame by screws, and to EE by pins; the centre of the sides are fastened to small iron plates F F, which are supported on the standards G G, on which they turn freely; the standards themselves, attached to the plates HH, can turn on the pivots IL L is a cord attached to the ends of the levers KK, by which, through the aid of a pulley, the weight M tends to draw them together. NN, a cross piece attached to the frame and supporting the pivots I, and guide plates C'. The journals 2, 3, 4, of the rolls B' Bª, run in bearings, inserted in the bars PPP, whose lower ex- tremities are maintained in a position by the guide rings 8, attached to the frame, which admits of a motion in the direction of their length; while at their upper extremities are racks into which play the toothed segments ppp, fixed in pairs on the shafts n n n. P' 'P'P', weights movable on the arms of the levers L' L', whose fulcra are at nn n. and attached to the toothed segments P by these weights the force with which the rolls B' B' B' press on the cylinder A is regulated. QQQ, guide rolls which keep the racks in geer with the segments. R', a plate perforated with an oval hole, through which the cloth is first passed, the effect of which is to straighten the folds; thence the cloth passes over a conducting roll S, through the short tube R, to the main cylinder; the tube R is supported by a cross plate attached to the frame. The draft or drawing in of the cloth is oc- 1860. P casioned by the pressure of the roll B' on the P main cylinder, which cylinders are geered together by the pinion X' and the geer X, on their respective shafts. Operation of the machine.-The cloth is first passed through the aperture R', over the B roll S, through the tube R, to the groove or space between the cheeks of the main cylin- der A, thence beneath the rolls B' B' B', and is delivered through the trough CD E at the N back of the machine. The ends of the cloth are now fastened together, the mill is set in motion, and the operation is performed as in the preceding machine. The cloth is pre- sented successively in a continuous round to the action of the squeezers till the fulling is finished. It will be easily perceived that the effect of the passage of the cloth beneath the rolls B' B² B' is a stretching of the cloth in the direction of its length, which causes a thick- ening or fulling of the cloth in the width. The cloth should also undergo a compression or fulling lengthwise. This is effected by the sides E E of the trough CED; these sides hold by iron straps at their upper extremities, at a constant distance, equal to that between the cheeks of the main cylinder, while their lower extremities, by means of the pivots G G and II, admit of a lateral motion at these extremities. The weight M is made to act through the levers K K, which brings them together, and prevents the discharge of the cloth; the result Digitized by Google 718 FULLING-MILL FOR CLOTH. is that the cloth being still delivered by the roll B¹ is forced into the guide box till the pressure is suffi cient to overcome that with which the two sides of the box are brought together by the weight M. The sides of the box then take a nearly parallel position. The cloth escapes gently and falls into the cir- cular box or tub, which composes the lower part of the machine. As by the weights P'P' P' the pressure on the cylinders B' B²B' can be regulated, and consequently the fulling breadthways of the cloth, so by varying the weight M more or less resistance can be opposed to the discharge of the cloth, and by this means the fulling of the cloth lengthways can be increased or diminished. A system of percussion has also been added to this machine. Small revolving or reciprocating beaters, making their blows on a fulling table, strike the cloth as it leaves the expanding trough. These machines have long been used in England and on the continent. They are now manufactured in this country, and where they have been adopted have given satisfaction. FULLING-MILL FOR CLOTH. Fig. 1861 is a side elevation of the mill. Fig. 1862 is an end elevation of the same. The same parts are designated by the same letters of reference in both drawings 1861. g h g a k E E k S m e a A R b m P A j j B C C w I C C kk, the side framing of the machine, made of strong rectangular pieces of wood, connected together at the top by the cross beams dd, the cross rails gg, upon which the four pieces hhhh rest in positions parallel to dd, and at right angles to the rails g g. The use of the beams hhhh is, besides affording additional stiffness to the framing, to carry the four pedestals ffff. in which are the working centres of the feet, or beaters A A. These are suspended by the legs, or pieces EE From the under side of Digitized by Google FULLING-MILL FOR CLOTH. 719 the feet, the lifters, or wipers BB project; and by means of these the feet are continually thrown back by the two pairs of wipers CCCC, upon the common driving shaft I The upright framing is secured at bottom by cross beams, into which the uprights k k are mortised; and these are bolted down usually to a solid foundation of stone. R is the rowhead of the receptacle or trough into which the cloth to be washed is put, and in which the beaters A A are suspended. The end R of this receptacle is formed of two or more blocks of wood, commonly oak, firmly jointed together, and is shaped internally into a parabolic curve, against which the cloth is pressed, by the beaters A A, alternately, during the opera- tion of washing. By this means the cloth is continually, but slowly, being turned round by the action of the beaters upon it. Water is meantime supplied from the cistern a, which extends across the back of the framing, through a series of small holes pierced in the back of the trough R, and is let off through holes pierced in the bottom of the same. The centre a is filled from a well or other reservoir, by the pipe P. 1862. h h h h g d d 0 O lc E E D E k 1863. S S A 0 0 S X e 0 b B m b i B W C C Y I C C The feet A A, as above described, are worked by the double wipers CCCC on the wiper shaft I; these wipers being set pair and pair at right angles to each other, work the feet alternately; 80 that when one foot is being caught by its wiper, the other is at that moment being released. The feet thus rise and fall alternately, and make each two strokes during one revolution of the shaft I. Into the heel of each foot is screwed a staple of iron m, which receives a hook-catch 8, jointed upon a lever, having its centre of motion at the stud o. The use of this arrangement is to keep up the feet when the cloth is being taken out of the trough. This lever and catch are represented separately by Fig. 1863. The wiper shaft is usually connected to one of the main shafts of the works by a friction coupling of Digitized by Google 720 FURNACE. some kind, for the purpose of starting the machine with as little shock as possible. An efficient and simple coupling of this sort is, however, still a desideratum in practical mechanics. In the machine from which these drawings were made, the wipers are of b 1864. cast-iron This, however, is not to be recommended, as the wipers are liable to break by concussion with the lifters if a B B; and, being cast pair and pair, in one piece, they are difficult and costly a to replace. The most approved, and now the most common mode, is to cast strong centres which fit upon the shaft I, and to attach to these malleable iron 1865. wipers, which are not only less lia- ble to fracture, but are also replaced with more facility in cases of failure from accident or decay. This arrange- ment is represented by the annexed wood-cuts, of which Fig. 1864 is an C elevation, and Fig. 1865 a plan of a b B pair of the wipers. c, is the wiper shaft, upon which the cast-iron centre is keyer This centre is cast with two flange pieces projecting in the plane of I the axis, and strengthened by feathers on one side. These pieces are of the same breadth as the malleable iron arms ab, a b, which are to be bolted to them at aa FURNACE An enclosed fireplace for generating great quantities of heat. Furnaces are of various forms, according to the purposes to which they are applied. In some cases it is intensity of heat that is required, as in the furnaces for smelting, casting, and forging metals, for descriptions of which see iron, metallurgy, &c. In other cases, a steady temperature is to be maintained, as in furnaces for the generation of steam. The first object in the erection of a furnace is to procure a sufficient supply of air for the support of the combustion of the fuel. In most of the former class of cases air is supplied by blowers, fans, dic.; in the latter, more commonly, but not entirely, the draft is created by high stacks of chimneys. Flues-To determine the area of the flue and chimney, it must be considered that 15035 cubic feet of air are required for the combustion of 1 lb. of coal. Of this air 44.64 feet combine with the gases evolved from the coal, and 105-71 feet with the solid portion of the coal. The combination of the air and gases increases their volume 1-10th. The 44.64 feet thus become 49104 feet. The sum of 105.35 with the carbon remains the same. The total product of the combustion (without considering the in- crease of volume resulting from raising the temperature) of 1 lb. of coal. is therefore 105.71 + 49-104 = 154814 cubic feet. Assuming the temperature of the furnace at 1000° Fahr., at which aēriform bodies are expanded to about three times their original bulk, the product will be 154814 X 3 = 464'442 feet. Adopting the result of Dr. Ure's experiments, viz. that the products of combustion pass off at a velocity of 36 feet per second, the area to allow this quantity to pass off in an hour will be 516 square inch. In a furnace in which 18 lbs. are burnt per hour on each square foot of grate, which is, according to Mr. Parkes, the average consumption throughout England, the minimum area over the bridge, or of the flue immediately behind the furnace, would be 516 X 13 = 6-709 square inches. In practice, how- ever, as a large surplus of air is always admitted, and the exactness supposed in this calculation cannot be secured, it is found advantageous to make the area 2 square inches instead of 516. This gives 26 square inches of area over the bridge to every foot of grate where 13 lbs. of coal are consumed per hour to every foot of grate. As the temperature and bulk become gradually reduced in proportion to the distance from the fire, the area of the flue towards the chimney may be narrowed; but this should be done without awkward bends or sharp angles. Proportions of heating, or flue surface to size of grate.-In boilers burning 13 lbs. per foot per hour, 18 superficial feet of heating surface to each foot of grate is a good proportion. This proportion omits the bottom surface of flat flue-, and from 1 to t the surface in circular flues, as being inoperative. Chimneys.-The area of the chimney should be 4 that of the opening over the bridge, viz. 11 inch per lb. of coal consumed, or 191 inches for each foot of fire surface burning 13 lbs. per hour. But the whole diminution of flue should be made gradually, and not by any sudden contraction. A common rule is, that the minimum area of chimneys 24 to 30 yards high, is 400 square inches for each 20-horse power. Chimney at St. Rollox's Chemical Works, Glasgow. Total height from foundation 447 feet 6 inches. Depth of foundation 15 = 0 as Total height above surface 432 " 6 $ Diameter at base 45 " 0 " " surface 40 " 0 " " top 13 « B " Thickness-bottom 31 bricks. at top 11. Internal flue 260 feet high, and perfectly vertical. Digitized by Google FURNACE. 721 Circular chimney at Friar's Grove Chemical Works, near Newcastle. Extreme height 254 feet 9 inches. Outside diameter at bottom of foundation 27 " 6 " Inside diameter at bottom of foundation 14 " 3 " Thickness 24 feet 8 inches 31 bricks. Thickness 107 " 3 " Thickness 53 " 21 " Thickness 46 u 6 " 2 " Stone top 6 " Uniform taper of 11 inch per yard. Foundation, clay. The temperature of the furnace and the surrounding flues.-It is a difficulty of no ordinary descrip- tion to ascertain with sufficient accuracy the temperature of a furnace. In fact every fire and every furnace is continually changing its temperature, as well as the nature of the volatile products as they pass off during the process of combustion. When a furnace is charged with a fresh supply of fuel, its temperature is lowered, and that from two causes first, by the absorption of heat which the cold fuel takes up when thrown upon the fire; and, secondly, by a rush of cold air through the open door of the furnace. Attempts have been made to remedy these evils by the aid of machinery and continuous firing, but taking the whole of the existing schemes into account, and bestowing upon them the most favorable consideration, it is questionable whether they are at all equal (either as regards efficiency or economy) to the usual way of working the fires by hand. Provided a class of careful men were trained to certain fixed and determined regulations, and paid in proportion to the saving effected. The results of experiments obtained by Mr. Houldsworth's Pyrometer, indicating the mean tempera- ture of the flues in a steam engine boiler, and the effects produced by the admission of air through regulated and permanent apparatus behind the bridge, show that in taking the quantity of water evap- orated by 1 lb. of coal as the measure of economic value, the mean of nearly the whole experiments is as 100 to 112-65, or about 121 per cent. in favor of a regulated and continuous supply of air. Taking, however, the mean of some of the experiments, and comparing it with some of the others, it will be observed that a much higher duty is obtained; and having accomplished a maximum, there appears no reason for doubting why it should not be continued, and still further advantages secured by a judicious arrangement of the furnace for the admission of oxygen to the uninflamed gases, which under other cir- cumstances would make their escape into the atmosphere unconsumed. In furnishing this supply it is not absolutely necessary to administer it immediately behind the bridge, as the same quantity of air taken through the grate bars, or in at the furnace doors, would nearly effect the same purpose, not only as regards the quantity of heat evolved, but also as respects the transparency of the gases and the consequent disappearance of smoke. Mr. Houldsworth estimates the advantages gained by the admission of air (when properly regulated) at 35 per cent., and when passed through a fixed aperture of 43 square inches, at 34 per cent. This is a near approximation to the mean of five experiments, which gives 831 per cent, which probably ap- proaches as near the maximum as can be expected under all the changes and vicissitudes which take place in general practice. In order to ensure economy and effect in the combustion of fuel, a large and copious supply of air must be admitted to the furnace, and that in the ratio of 10 volumes of air to 1 of coal gas; when that quantity is at its maximum or in excess, there is no smoke; when it is different, smoke is invariably present. Now perfect combustion is the prevention of smoke. It therefore follows, that in order to render the residue of the products of combustion transparent, or 'smokeless," a supply of air amounting to ten times that of the gases evolved must be admitted. Should it exceed that quantity the effect will not be smoke, but an additional expenditure of fuel to supply the loss of heat which this excess of air would require for absorption, rarefaction, &c. Hence the necessity which exists for power to regulate the admission, if not the exact, at least an approximate quantity of air. On the other hand, should the supply be deficient in quantity, (which is often the case,) a dense volume of smoke is then visible, ac- companied with all the defects and annoyances of imperfect combustion. It is difficult to determine the exact quantities of gas evolved from every description of fuel, and probably equally so to supply its equivalent of air; but in order to attain certainty in this respect, let the openings be made sufficiently large, and by a little attention to the quality of the fuel and quantity of air required for its combustion, the apertures may be contracted till such time as a mean average and a close approximation to the maximum effect are obtained. The concentration of heat is a consideration of much importance in the economy of the steam engine and the industrial arts; and much depends upon its preservation. For this purpose we should recommend the flues and furnaces of boilers, and other fires, to be closely encased with good building material adapted for the retention of heat, and all steam boilers to be well covered and clothed, 80 as to prevent (as much as possible) the escape of heat in that direction; and for steam engines, that all the steam pipes, cylinders, &c., should be closely enveloped in a thick coat- ing of felt, canvas, or wood, and afterwards well painted. These precautions being taken, the effects will soon become visible in a saving of 15 to 20 per cent. of fuel. The above extracts are from Reports on English practice, and have their application more particularly to furnaces using bituminous coal. On the principle above enunciated, that in the combustion of fuel a certain quantity of air is requisite, and that either an excess or deficiency is prejudicial to proper and economic combustion, Messrs. Bar- ron and Brothers, of New York, have constructed their portable blast furnace. The furnace is 80 arranged that all metals are melted by it at a less expense of time and fuel than by any other furnace. 91 Digitized by Google 722 FURNACE. Gold, silver, and copper, can be melted by it in less than ten minutes. No. 1 size will melt from 4 to 12 ounces of gold with less than one quart of coal No. 2 will melt from 50 to 100 ounces with two quarts of coal; Nos. 3 and 4 from 100 to 500 ounces. Fig. 1866 represents not only the furnace, but also an operating table, to which is attached blow- pipes, bellows, &c.; it forms a convenient stand for the furnace, but is not necessarily connected with it. Fig. 1867 represents a contrivance for supplying it with air by a small pair of bellows resting on a table. P is the bellows, R a block for the support of the nose of the bellows, to keep it at a convenient height and distance with respect to the air-pipe O. It will be seen that as the air comes out of the bellows in a condensed form, by the time it reaches o it begins to expand, and the heat it abstracts by that action is drawn from the tube O, and not from the fire in the furnace, at the same time the warm and expanded state in which it reaches the fire, causes it to be equally diffused through the burning material, and produces throughout an effective intensity of heat. 1866. L 1868. H H. G $ H F 1867. E D c R Fig. 1868 exhibits a section of the furnace. K is an inverted crucible on which another crucible L is placed, surrounded by fuel. o is the tube through which the air is supplied. The operating table, Fig. 1866, is not necessarily connected with the furnace-nevertheless its con- veniences deserve the consideration of the artisan. It is a table covered with a sheet-iron top, having holes through which are brought three blow-pipes H H H, supplied with air by the bellows C under- neath, which is furnished with a wind chest whereby a steady stream of air is sustained. Before the blow-pipes you can place either furnaces F or G, or spirit lamp J, as may be required. The table and furnace and spirit lamp supply all that is needful to render the melting and soldering of metals safe as well as easy. FURNACE, Reverberatory. Figs. 1869 to 1872. These Figs. represent the form and dimensions of a most important adjunct to Nasmyth's steam hammer, which, with slight modifications, will be found applicable in many stages of the iron manufacture. A A, the hearth and building upon which the fur- nace is erected. It is lined throughout with fire- bricks, and the hearth is formed at a slight inclination, so that the flame and heat may more effectually react 1869. from the arched roof upon the work placed on it. BB, the roof and sides of the furnace, also formed of fire-bricks. The roof is arched throughout its en- tire length, in order that the heat may be reflected B and concentrated upon the work placed on the hearth. CC, the sheet-iron sides of the furnace, by which the brick-work is secured and retained in its proper form. DD, the end plates for binding the side plates to- gether. Instead of being riveted to the side plates, they are secured by bolts and nuts, so that the whole C structure may be easily taken asunder when it is @ necessary to rebuild the furnace. E, the ash-pit. F F, cross bearers of wrought-iron for supporting the furnace bars a a a. The ends of the bearers rest in small cast-iron brackets bb, secured to the sides of the ash-pit. G, the passage to the chimney, formed in continuation of the arch of the roof. H H, the chimney, constructed internally and throughout its entire height, of fire-bricks. II, corner pieces of ordinary bricks built upon the angles of the interior chimney for the purpose of giving stability to the whole structure, which is further bound together by bolts ddd passing through the small cast-iron pieces ccc. JJ, cast-iron sole plate for supporting the brick-work of the chimney, and which is itself supported by Digitized by Google FURNACE. 723 1872. 1871. Y H 22 c C o 0 = = c o , , o o o c o o O , o o o O o o 0 A o , 9 ; O o o o O c C c o 0 C Q c O c o 2 o e c 0 . 0 o c N e C c C 1870. o o o o o . o o o 0 o o o c M N G Digitized by Google 724 FURNACE. K K, four strong cast-iron columns resting on a solid foundation of mason-work. L, the stoke-hole, through which the fuel is introduced into the furnace. The mouth of this stoke- hole is so constructed as to admit of its being stopped with a piece of coal when the furnace is in full operation. M, a small square aperture in the side of the furnace by which the attendant is enabled to inspect the state of the furnace without interrupting the progress of the work. It may be stopped with a single brick. NN, the main openings into the furnace, through which the shaft or other work to be heated is passed. O, the sliding door by which the aperture N is guarded. It consists of a square cast-iron frame, lined internally with fire-bricks, and fitted to slide vertically between guides of angle iron. PP, levers working upon the cast-iron brackets QQ, surmounting the furnace. They are loaded at the outer ends with counter-weights, and attached by short connecting rods to the doors 00, so as to enable the stoker to raise or lower the latter with the utmost facility. R, a register or damper surmounting the chimney, for the purpose of regulating the draught of the furnace. It is brought within the command of the attendant workman by means of a long chain or wire ee, depending from the lever upon which it is hung. FURNACES, Hot-air. See WARMING. FURNACE. Ovens, and machinery used for making bread. Fig. 1873 represents a front view of a bread machine recently erected in Glasgow, under Messrs. 1873. Robinson and Lee's patent. One ton and a half of loaf bread, or a ton of biscuit, is produced by this invention hourly, without the intervention of human labor in any stage, although the machine itself Digitized by Google FUTTOCK. 725 occupies less than a square yard of space. It is well known that the process of setting the sponge, in the common mode of bread-making, consumes a considerable period of time, and occasions great waste of the nutritive qualities of the flour. The patentees of this machine state that they prevent both these losses by the use of carbonated water, which can be very cheaply prepared; but the machine is equally adopted for those who prefer yeast in the manufacture of bread. By a very simple but ingenious pro- 1874. 1875. 1876. 100 10 42 cess, the liquid and flour are made to fall together in due proportions upon a cone A, which partially mixes and conveys them into the kneading trough B, whence the dough is forced out at an aperture C, and cut off by an eccentric knife D in the precise quantities wished. Falling upon a roller E, these pieces are carried by the same machinery through a moulding tube F, and thence into the oven, Figs. 1874 and 1875; where the steam by which the whole concern has been kept moving is, after passing through a red-hot coiled pipe in the furnace, Fig. 1876, applied in direct contact with the batch, and produces a very pure crust. The heat, too, is both indicated and regulated by a self acting pyrometer, whereby the baker can assure his batch against being either burned or slack baked. FUSE, for blasting. In this country the safety fuse" is most generally employed. It consists of a cotton tube filled with powder, wound with tarred thread or twine, and a coat of tar is then applied on the outside. The whole forms a cord of about 3-16th of an inch in diameter, 80 hard and firm in its texture as to resist the action of tamping. It is impervious to water, and burns regularly at a rate of about 21 feet per minute. An improvement on the safety fuse has been patented, namely, the introduc- tion of a thread in the centre of powder to ensure its continuity, and prevent any chance of a miss-fire. Powder hose is sometimes used in England, made of strips of linen or cotton cloth sown together, and filled with powder; these, when full, vary from half inch to an inch in diameter. The hose is inclosed between two hollowed strips of wood, where it would not be damaged by the tamping, and a piece of port fire is attached to the match end, to afford time to the blaster to escape before the charge is ex- ploded. FUSEE, in clock-work, is a mechanical contrivance for equalizing the power of the main-spring of a watch; for as the action of a spring varies with its distance from the quiescent position, the power derived from the force of a spring requires to be modified according to the circumstances, before it can become a proper substitute for a uniform weight, which is what it is intended to supply. In order, therefore, to correct this irregular action of the spring, the fusee F, Fig. 1877, on which the chain or catgut acts, is made somewhat conical, 80 1877. that its radius at every point may correspond with the strength of the spring, being greater and greater as the action of the spring becomes more and more weakened by unbending. If the action of the spring di- minished equally, the fusee would then require a perfect conical figure; F but the decrease of the power of the spring does not follow that uniform law, and, in consequence, the figure of the fusee deviates from the form which it would otherwise take, and becomes a solid, generated by the revolution of an equilateral hyperbola about its asymptote. See WATCHES. FUSIBLE METAL, consisting of 8 parts of bismuth, 5 of lead, and 3 of tin; it melts at the heat of boiling water, or 212° Fahr. By the addition of a very little mercury it becomes still more fusible, and is used for certain anatomical injections, and for the filling of carious teeth. FUTTOCK, or ship timber converting machine. We are glad to have it in our power to lay before our readers a set of engravings of the machinery of Mr. J. Webster Cochran, of New York, for sawing Futtocks and other timber used in ship building. We exhibit this machine not merely as described in his English specifications, but as it has been since improved in many important particulars. We shall take the specification for the groundwork of our description, and deviate from it only when this may be rendered necessary by the modifications introduced by the inventor. Fig 1878 is a front or end elevation of the machine. Fig. 1879 is a side elevation. Fig. 1880 a plan. Fig. 1881 is a transverse section through the chuck-plate wheel; and Fig. 1882 is a detached view of part of the steam machinery. A A A are the stationary framing or sills upon which the sliding carriago of the mill is mounted. They are firmly fixed, in the usual way, upon the ground, or upon masonry in the building in which the mill is intended to be placed. Two longitudinal rail plates a a, of the usual description, having V edges Digitized by Google 726 FUTTOCK. on their upper sides, are securely fixed upon the horizontal longitudinal sills or beams of the framing, and upon the V edges of these rail plates the sliding carriage moves in the usual way, for the purpose of advancing any piece of wood which it may carry up to the saw or saws, in order that it may be cut into the required shape or shapes. The sliding carriage in or upon which is to be placed any log or piece of wood intended to be cut, consists of two longitudinal bars BB, (which form the base of the carriage,) placed parallel to each other, and braced together into the form of a rectangular frame by the transverse rod b, and the head block or plate C C. 1881. 1880. 1879. 1882. 1878. The under sides of the longitudinal bars BB have each a longitudinal groove extending the whole length of the carriage, and fitted to the V edges of the rail plates aa, 80 that the carriage may slide easily and securely along the ordinary way. There are also on the under sides of the longitudinal bars BB two toothed racks, extending along the whole length of the carriage. These racks are placed parallel with the grooves before mentioned, and so that a pair of pinions hh' may, when a piece of timber is to be cut, move the carriage along upon the rail plates a a, by means of trains of wheels connected with the pinions. And when the piece of Digitized by Google FUTTOCK. 727 timber has been cut, the machinery may be thrown out of geer, and the sliding carriage moved back by any of several well known means. The sliding carriage is kept down in its proper position by two friction rollers h²h, one on each side, which have their edges fitted to the V rails which run along the upper sides of the sliding carriage, as after mentioned. Each of these rollers is attached to the inside of one of the standards or fender posts JJ, (within which the sawgate works immediately above" the sliding carriage.) Upon the head block CC is mounted the poppet head cc, which is made capable of being moved laterally in a dovetailed groove, for the purposes of adjustment. In this poppet head is an axle, which carries the chuck plate D, and this chuck plate is made capable of turning freely upon its axis. This chuck plate has a dovetailed groove extending across the face of it, and having fitted into it the foot of the jaws or clips dd, the lower of which is made fixed and the other movable. The movable jaw is kept in its place by two bolts, and by a nut; upon one of these bolts it may be screwed towards the other jaw, for the purpose of holding one end of a log of wood or piece of timber firmly in the carriage. And the lower or fixed jaw, or clip, must be mounted in such a way that the inner surface will at all times coincide with an imaginary line drawn across the face of the chuck plate D, and through the centre of the axis thereof. These jaws or clips may, by means of the screw shaft g, be moved across the face of the chuck plate in either direction, as may be required for the purpose of balan- cing a log or piece of wood, which is to be held between the chuck plates whilst it is being cut. The head block EE is mounted upon the side bars BB of the sliding carriage. Along the tops of the side bars BB are V edges, and under and across the ends of the head block E E, are grooves to receive the last mentioned V edges, 80 that the head block EE, when placed across the sliding carriage, with its grooves upon the same V edges, may slide easily along. above, or upon the tops of the sliding car- riage, in the direction which may be required for the purpose of adjustment, according to the length of the log or piece of timber to be cut. The head block E E has motion given to it (along the carriage) by means of a pair of pinions, which are fixed upon a transverse shaft under the head block, and which serve the purpose of keeping the head block down in its proper position on the carriage. This transverse shaft forms the axis of each of the last mentioned pinions, and the bearings of the shaft (in which it is made to turn by means of a hand wheel, handle, or other convenient means) are fastened to the under side of the head block E E. The last mentioned pinions are placed in such a position that the teeth of these pinions take into the teeth of the toothed rack, which is placed upon the under sides of the longitudinal bars BB, as before mentioned; and as the pinions are turned round in the one direction or the other, the head block EE will be moved towards the one end of the sliding frame or the other. Upon the head block E E is mounted a puppet head ec, which is made capable of being moved lat- erally in a dovetailed groove, for the purpose of adjustment, in like manner as the poppet head c c, on the head block C C. In this poppet head e is an axle, which carries a toothed wheel K, to which is attached the chuck plate F, and this wheel with the chuck plate is made capable of turning upon its axis. This chuck plate has a dovetailed groove extending across the face of it, and having fitted into it the foot of the adjustable jaws or clips ff, which are intended to hold the other end of the log of wood or piece of timber placed in the sliding carriage to be cut. These jaws or clips are constructed and mounted in or upon the chuck plate F, in like manner as the jaws or clips dd, which are mounted in or upon the chuck plate DD. The fixed and movable jaws of the clips may be made also with quadrant slots. in order that the movable jaw or clip may be capable of being turned to one side or the other, 80 as the better to grasp and hold the end of any irregularly formed end of a piece of timber. In each of these figures there is represented a log or piece of timber m, held in the sliding carriage by means of the jaws or clips, showing its appearance after it has been submitted to the action of the saws, and had two of its sides cut so as to make it externally of the required shape. To place a log or piece of timber in the sliding carriage in a proper position for being cut, one end of it must be placed between the jaws or clips of the chuck plate D, which is mounted on the fixed head block cc, and the movable head block E E being then moved to a proper position for enabling the jaws or clips of the chuck plate F to receive the other end of the log or piece of timber, that end of the log or piece must then be placed between those joints or clips. The nut of the screw bolt of each pair of jaws or clips is then to be turned 80 as to bring the movable jaw or clip down upon the log and hold it securely. In the place of the roller, which is ordinarily used in sawing mills or machines, for the purposes of supporting a log or piece of wood, at an intermediate point between the ends, and near to the saws of the mill, an oscillating cylindrical roller is used, or a roller having its axis capable of being deflected from a horizontal position. This roller support is placed at a position as near as conveniently may be to the saws of the mill, and in front thereof, and must be independent of, and separate from, but within the frame of the sliding carriage. This roller, and the machinery connected therewith, may be supported by any framing, or other convenient means, upon the ground, or in connection with the stationary framing of the mill. G, Fig. 1878, represents a cylindrical iron roller mounted upon an axle in an oscillating segment piece H. This segment piece is supported by an axle, stud, or trunnion, at each side thereof, which is mounted in the frame H; these axle studs being placed at right angles with the axle of the roller. The segment piece H has the semicircular edge thereof toothed, 80 as to take into the threads of the endless screw L, and the segment piece is held down by a quadrant slot in the segment piece, and working on a pin or pins in the frame I, so as to allow of the oscillation of the segment piece for the purpose of varying the deflection of the axis of the roller G, in any manner which may be required. The quadrant slot is to be made of a sufficient length to allow of the deflection of the roller support to any extent which may be requisite. Each side of the frame II is fitted within two upright supporters inn in*, the sides of the frames Digitized by Google 728 FUTTOCK. having longitudinal grooves or slots to receive the ends of pins to be driven through the uprights into the grooves, so as to keep the frame II securely within its two uprights, and yet allow it to be varied or depressed as may be required. The frame II is supported by two jack screws 4, 4, which are threaded into the lower part of the frame II, and the shoulders of these screws work against a stationary rail or bar I*, which is firmly fixed to the stationary framing, or foundation of the mill. The lower ends of the jack screws are furnished with bevel wheels 3, 3, which respectively take into two bevel wheels 2, 2; and the bevel wheels 2, 2, are fixed upon a transverse shaft 1, which may be turned by a handle or other convenient means. By turning the shaft 1, the bevel wheels will be put in motion and the jack screws turned, and as these screws are turned the one way or the other, the frame II may be raised or lowered as may be desired. By these means the frame II, and the roller G, may be lowered 80 as to remove the roller G out of the way when desirable so to do; and by rais- ing the frame II and the roller G, the roller may be elevated in such a way as to form an intermediate support to a log or piece of wood whilst the saws are cutting it. If the pieces of wood intended to be cut in a mill, should happen to be of such a description that they will not be held sufficiently steady during the operation of sawing by one intermediate roller support, such as before described, the same mill may be constructed with an additional oscillating roller support, (similar to that before described,) and capable of being raised and lowered as before mentioned, and such additional oscillating roller support may be placed behind the vertical saws, or in any other posi- tion which may be found desirable, for the farther or better supporting the pieces of wood to be cut in the mill. Pieces of wood for shipbuilding, and for various other purposes, frequently require to be cut into irre- gular shapes, and for the purpose of preparing such pieces of wood of the desired shapes, it is often ne- cessary that one or more of the surfaces thereof should be cut with a varying bevel or surface, or with a surface cut in a twisting or winding manner, the bevel or direction of a cut, or cuts, constantly vary- ing, either regularly or irregularly, in one or more than one direction as the cutting proceeds. The saws of a vertical saw-mill cannot, as such mills are usually constructed, be moved out of their perpendicular position, to either the one side or the other for the purpose of varying the bevel or surface of a log, or piece of timber, which they are cutting. This object may, however, be attained by gradually turning a log, or piece of timber, which has been placed in a mill to be cut in the requisite direction, or directions, as the operation of sawing proceeds. For the purpose of being enabled to turn a log, or piece of wood, during the cutting thereof, this in- proved sawing machine is constructed with revolving chuck plates and oscillating segment pieces, with roller support, or supports, as before described. These chucks and the intermediate roller support, or supports, may be turned in the manner required by the hand, or by any convenient machinery effecting that object, such as that now about to be described. The teeth of the wheel K, behind the chuck plate F, take into an endless screw L, as shown in Fig. 1881, which is fixed upon a transverse shaft K¹, and in like manner the teeth of the oscillating segment piece H take into the endless screw L'. The chuck plate D may, if it should be thought desirable, be furnished with a rim of teeth taking into an endless screw in like manner; but a machine will work sufficiently well for all ordinary purposes without this addition to the machine as represented in the figures. When a log or piece of wood has been placed with its ends in the jaws or clips of the turning chuck plates, the roller support G must be raised until the upper surface thereof comes in contact with the log; and the mill or machinery must be put into geer in such a way that the direction and degree of the inclination (if any) of the axis of the roller support G to the horizon must at all times be the same as that (if any) of the face of the fixed jaw or clip of the chuck plate F. The chuck plate F, and the segment piece H, must at all times be turned together in the same direction, and in the same degree, or with the same speed; and the chuck plate D being left free to turn upon its axis, will be turned as the log or piece of wood may be turned. Upon the end of the driving shaft K¹, of the endless screw taking into the teeth of the chuck wheel K, is fixed a bevel wheel K³, taking into another bevel wheel K' upon the driving shaft y, which last men- tioned wheel is prevented from turning upon the shaft by means of a feather or key in the boss of the wheel, which takes into a groove along one side of the shaft y. For the purpose of preventing the shaft y from springing, and also for keeping the bevel wheel K' in geer with the other bevel wheel Kᵃ, a collar K° is fitted upon the boss of the bevel wheel K⁴, (within which collar the boss of the wheel turns freely ;) and the collar is attached by its arm to the under side of the head block E. The boss of the wheel K' is kept in its place within the collar K' by a narrow collar fastened upon the outer end of the boss by a set screw. And as the head block E on the sliding carriage, with the same head block, is moved along in either direction, the bevel wheel K4 which the shaft y turns will be moved along at the same time, and kept in geer with the other bevel wheel K', with which it is intended to work. The driving shaft K" has its bearings in the movable frame II, with which it must rise and fall. One end of this driving shaft passes through its bearings in one side of the frame II, and through the next adjoining upright inn, in which a slot is cut, 80 that the shaft K' may pass up and down within the slot, as the frame I I rises and falls. The shaft K' has its outer end fitted into a hole or bush in the collar upon the boes of the wheel, 80 that the collar must be raised or lowered in like manner as the end of the axle which works within the same bush or hole. Upon or near to the end of the shaft K³, which is next to the collar, is fixed a bevel wheel, which takes into another similar bevel wheel. The bevel wheel, with its long boss below it, is placed upon an upright driving shaft, which has a groove or key-way cut along one side of it, to receive a feather placed in the inside of the boss of the bevel wheel, which is made to move freely up and down within the groove. Digitized by Google FUTTOCK. 729 The bevel wheel and its boss move freely up and down upon the shaft, and the boes of the bevel wheel, which turns freely within the collar, is kept securely within that collar by means of a narrow collar fastened upon the end of the boss by a set screw, in the usual manner. The bevel wheels are thus at all times kept in geer with each other. The shaft has its bearings at the foot in a socket or step, and at the top in a bracket, as shown. Upon the top of the shaft is fixed a bevel wheel, which takes into another bevel wheel fixed upon the shaft y. The boss of the bevel wheel nb is made to move in a bearing or bush at one end of a bracket or arm, within which the boss turns freely, and the bracket or arm is fixed to the frame I*, and by these means the shaft y is kept steady, and in its proper position whilst in motion. When the driving shaft y is left at rest, the movable chuck plate F, and the segment piece H, with the roller G, will also be left in a state of rest; that is, they will not be turned either to one side or the other of the machine. And when it is unnecessary that a log or piece of timber should be turned in either direction during the process of cutting, for the purpose of producing a piece of wood of the in- tended shape, then the chuck plates and roller support are to be left in a state of rest; and if the chuck plates and roller support are turned by machinery, as shown in the figures, then also the driving shaft y, and all the machinery connected therewith and before described, are to be left in a state of rest. But when it is necessary that a log or piece of timber should be turned during the process of cutting, then that may be done by hand, as before mentioned; or if the machine be such as before described, then motion is to be given to the shaft y, and such motion regulated and (when necessary) accelerated or retarded by the machinery next to be described. And whenever motion is given by means of the driving shaft y to the transverse driving shaft K¹, and the movable chuck plate F, a similar motion will, by means of the train of wheels before described, be also communicated to the transverse driving shaft K², and the segment piece H, carrying the roller support G. To show more clearly the mode in which the saws are mounted and worked, we have given in Fig. 18824 a front elevation of the machine, with all the parts removed that have no relation to this branch of the invention, and also in Figs. 1883, 1884, 1885, 1886, 1887, and 1888, 1889, some of the more im- portant of the minor details. Although any required number can be used at the same time, the saw- gate is represented as fitted with two saw blades with their respective shackles and sliding frames; but as both saws are actuated by precisely similar means, we shall, for the sake of greater distinctness, confine ourselves to describing the parts belonging to one saw blade only. The sawgate M M consists of two top and bottom rails C O, which are connected together by the upright rods N N, to the lower end of which are jointed the rods by which motion is communicated to the gate from the cranks of the main driving shaft. The saw blade i is attached at the top and bottom to two cylindrical axes G G, which are separately represented along with the parts peculiar thereto in Figs. 1883, 1884, 1885, 1886; Figs. 1883, 1884, 1885, being side elevations, and Fig. 1884 a cross section on the line E F of Fig. 1886. The axes G G are hollowed out in the centre from a to b, as represented in the cross section, Fig. 1884, and fit by means of the parts 80 hollowed out upon the projecting pieces H H, which form the extreme ends of the top plates of the shackles IL The form of these projections H H is shown separately in Fig. 1887, which is a plan of the top plate of the shackles. When the axes G G are fitted upon H H, and the saw connected to them by the pins cc, the saw blade is brought to the proper degree of tension by means of the top screws X'X'. The points of these screws, which are conical and made of hardened steel, take into hollows formed in the pieces H H, so that the saw blade has thus, in so far as respects the screws by which it is stretched, perfect liberty to turn round in any direction, the friction of the bearing parts presenting a very trifling obstacle to its rotation. The saw is, however, limited at the same time in respect of angular motion by the sides of the recesses formed in the axes G G, and the neck which connects the bearing points H H of the shackles II; the range allowed to the saw by the parts just described being still sufficiently extensive for all practical pur- poses. (It may be turned till it stands at an angle of 45 degrees, or even a greater angle, with the central line of the sliding carriage upon which the wood to be cut is placed.) It is to be observed, that when the saw is stretched, the points of resistance to its tension are not the rails of the sawgate; for the strain falls entirely upon the shackles or buckles II, which, together with the rods L and M, form a frame complete in itself, which fits accurately into and slides upon the sawgate. By this improved method of mounting the saw, great facilities are obtained for connecting and disconnecting it from the frames, while the friction of the bearing points being reduced to a very small amount, the workman is enabled to direct the course of the saw in any intended line with great precision and ease. On the rod or strut L there is closely fitted a hollow shaft or tube 0°, two ends of which bear against the top and bottom shackles II. So that by this means it is prevented from moving in a longitudinal direction upon the rod L, but is still left free to be turned round upon it, as on an axis. To the upper and lower ends of the shaft or tube, there are securely fixed cross arms 0ª O', corresponding with similar cross arms P' P', which are keyed upon the axes G G of the saw. These two sets of cross arms are again connected with each other by rods qq, (a plan of which is given in Fig. 1888,) 80 that, if the hollow shaft O° be made to turn by any means either to the right or left, an equivalent movement of the saw upon its axes G G takes place at the same time. PP are two round rods, which are secured to the upright standards of the framework of the machine, and occupy positions parallel to each other, and also parallel with the sawgate. T is a bridge, or sliding bearing, which is free to slide to and fro upon the rods PP, that is, from one side of the sawgate to the other, being attached to the rods by the bosses dddd U and p' are two bosses inserted into the upper plate of the bridge T, in such a way that they are at liberty to revolve in the holes into which they are inserted while they are prevented from getting out of their places by collars ff formed on, or affixed to, their upper and lower ends. One of these bosses, U, embraces the upright hollow shaft 0°, and allows of its moving freely up and down within it. On the side of the hollow shaft 0 there is a feather 6 which takes into a corresponding groove formed in the boss U, 80 that if the boss is made to revolve, the hollow shaft must go round along with 92 Digitized by Google 730 FUTTOCK. it. W is a worm-wheel which is attached to, or formed in one piece with the brass U, and geers into an endless screw X, upon the end of which there is a hand-wheel X', 80 that the attendant may be enabled, through the intervention of the endless screw X, the worm-wheel W, the hollow shaft 0, the cross-arms 0ª P', and the rods qq, to cause the teeth of the saw to be directed at pleasure, more or less towards the right or left, according to the form desired to be given to the piece of wood. 1882f. L x & c M D. d d X" o 0 X I N 601 o M c 1887. 1888. - 1883. N°1 c 1889. 1885. 1886. : 1884. 1 6 When the saw has been inclined towards either side of the sawgate (by means of the apparatus before described) during the operation of cutting a log or block of wood, the regular feeding in of the wood takes place by the advance of the travelling bed under the sawgate. The saw would, therefore, very soon be broken unless the shackles were made by a free lateral motion, or some other means, to advance towards that side of the sawgate to which the teeth of the saw are directed. To effect this object, the arrangement next to be described is adopted: V' is a hand-wheel fixed upon, or made in one piece, with the brass Pᵃ, which is connected with a hollow shaft 0* upon the rod M; being in this Digitized by Google GAS. 731 respect exactly similar to the hollow shaft, 0° and brass U, before described. The hollow shaft 0* has pinions Y Y affixed to each end, which geer into racks Y' Y', which last are fixed to the upper and lower rails of the sawgate. In general the draft of the saw itself is sufficient to cause the shackles to move along the sawgate; but whenever any obstruction to the lateral movement is experienced, all that the attendant has to do is to turn the hand-wheel Vs in the required direction, which causes the pinions Y Y, by geering into the fixed racks, to draw the shackles and saw along with them. The arrangements which have just been described for regulating the lateral and simultaneous move- ment of the shackles, both at top and bottom of the sawgate, serve the further purpose of keeping the saw at all times vertical in the sawgate, it being impossible, on account of the racks and pinions, for one of the shackles to be moved without a corresponding movement being produced in the other. Not only may the machine be worked with either one or more saws at a time, but one saw may be used to cut in a curvilineal direction, while the other cuts in a straight line. Thus if both or either of the sides of a log should be intended to be cut in a curved or irregular line, that object may be attained by turning, from time to time, the saw in the required direction; and when simultaneously making two cut, in a log by my said machine, it is not at all necessary that the cuts should be made parallel with each other, for the lateral movements of the saw within the sawgate being perfectly independent of each other, each saw may be turned in the required direction for the purpose of making the intended cut in the line described, however much the two lines to be cut by the two saws may vary from each other. " Neither is it necessary that two saws should be actually used for the purpose of cutting timber in one of my said machines, although two saws may be mounted in the sawgate; for the peculiar con- struction of my said sawing machine may be made available for the purpose of making single as well as double cuts. And if it should happen that the shape into which a piece of timber is intended to be cut requires the adoption of such a mode of proceeding, I can enter one of the saws and commence cutting a piece of timber with it, and after the cutting with one saw has proceeded the requisite dis- tance, I can then enter the other saw also, so that both saws may then proceed with the cutting of the log; or the cutting with either or both of the saws alternately or simultaneously may be varied from time to time, as may be required for the purpose of cutting the pieces of timber into the desired shape." This invention has recently been introduced into England from this country, and has been in active operation for two years in the government dock-yard at Woolwich, where the estimation in which it is held is fully testified by certificates of the highest officers of the admiralty, and other persons of dis- tinction, in Europe, competent to judge of its merits. It has also been adopted by the government of Sweden; has met the approval of the officers of the Russian government and of several other conti- nental naval boards. We are confident that the machines erected at Woolwich in 1847 were the first and only ones that ever had converted compass timber for a ship's frame for actual use. Mr. Cochran is now under contract for the construction, in England, of machines for the dock-yards of that country. Machines are now in the course of erection in this city, and are considered by the most competent judges to be one of the greatest improvements of the present day. Cochran's Patent Machine for Sawing Ship Timber" is capable of cutting both straight and crooked work at the same time. One futtock can be sided at the same time the curvilinear and bevelled sides of another are being sawed, or a straight timber can be cut at the same time that a crooked one is sawed into planking, with the grain of the wood. FUTTOCK PLATES. Flat iron bars or plates, receiving at one end the lower dead-eye of the top- mast rigging, and at the other the futtock shroud. FUTTOCKS. In nautical language, the timbers between the floor timbers and the top timbers. GALVANISM. This term is generally used as synonymous with that of voltaic electricity, or the phenomena resulting from the evolution of electricity by the contact of different metals, or by chemical action, as manifested by the galvanic or voltaic battery. For descriptions of some of the more useful of these batteries and their practical application, see ELECTRICITY, ELECTRO-METALLURGY, TELEGRAPH. GALVANIZED IRON. Iron covered with a coating of zinc and tin. This process is as follows: Clean the surface of the iron perfectly by the action of dilute acid and by rubbing; then plunge it first into a bath of zinc, stirring it about till it is alloyed superficially with this metal; then immerse it in a bath of tin, such as is used for making tin plate. The tin forms the exterior coat. Iron thus pre- pared is found to withstand the action of rust much longer than tin plate, and is now used extensively for gutters and leaders, and in other exposed situations. GALVANOMETER An instrument for ascertaining the presence of a current of electricity, espe- cially galvanic or voltaic electricity, by the deviation which it occasions in the magnetic needle. The simplest form of galvanometer is a magnetic needle poised upon a point, and surrounded by one or more coils of copper wire covered with silk, the ends being either left free or terminating in two small copper cups containing mercury, for the convenience of communication with the source of electricity. When this needle is placed parallel to the coil, and in the magnetic meridian, it immediately deviates when the electric current passes through the coil; and the deviation is either to the east or the west, according to the direction of the current. See ELECTRO-MAGNETISM. GAS, and the machinery employed in the manufacture of. All substances, whether animal, vegetable, or mineral, consisting of carbon, hydrogen, and oxygen, when exposed to a red heat, produce various inflammable elastic fluids, capable of furnishing artificial light. We perceive the evolution of this elastic fluid during the combustion of coal in a common fire. Bituminous coal, when heated to a certain degree, swells and kindles, and frequently emits remarkably bright streams of flame, and after a certain period these appearances cease, and the coal glows with a red light. The flame produced from coal, oil, wax, tallow, or other bodies which are composed of carbon and Digitized by Google 732 GAS. hydrogen, proceeds from the production of carburetted hydrogen gas, evolved from the combustible body when in an ignited state. If coal, instead of being burnt in the way now stated, is submitted to a temperature of ignition in close vessels, all its immediate constituent parts may be collected. The bituminous part is distilled over, in the form of coal-tar, &c., and a large quantity of an aqueous fluid is disengaged at the same time, mixed with a portion of essential oil and various ammoniacal salts. A large quantity of carbu- retted hydrogen, carbonic oxide, carbonic acid, and sulphuretted hydrogen, also make their appearance, together with small quantities of cyanogen, nitrogen, and free hydrogen, and the fixed base of the coal alone remains behind in the distillatory apparatus, in the form of a carbonaceous substance called coke. An analysis of the coal is thus effected by the process of destructive distillation: the products which the coal furnishes may be defined as follows:- Oxygen, which was discovered by Priestley in 1774. This gas has resisted all attempts to convert it into a liquid; it is colorless and inodorous, and heavier than atmospheric air, 100 cubic inches weighing 34193 grains, while 100 cubic inches of the latter only weigh 31.0117. As atmospheric air is considered as unity when comparing the density of gases, the specific gravity of oxygen is 1.1026. It eminently supports combustion, all combustible bodies when introduced into it burning much more vividly than in common air; indeed it is to the presence of this gas that the property of supporting combustion, which common air possesses, is owing. Hydrogen was discovered in the year 1766 by Cavendish. It is gaseous, and the lightest body known, its specific gravity being only 0-06896. This gas is colorless, and, when perfectly pure, inodorous. It is not perceptibly dissolved by water: it has a powerful affinity for oxygen, and is there- fore eminently combustible. Intense heat is developed by the combustion of hydrogen in oxygen gas, but little light: the compound thus produced is water. Carbon is well known under the form of coke, charcoal, lampblack, &c. It is one of the principal constituents of all varieties of coal, and is the basis of the illuminating gases. It is a colorless and inodorous gas, rather lighter than common air, having a specific gravity of 0-9727; is sparingly absorbed by water, and does not precipitate lime-water. It is inflammable, burning with a beautiful blue flame; the product of its combustion is carbonic acid. Carbon unites with hydrogen in many proportions, and many of these compounds are produced during the distillation of coal, but the only two of importance are carburetted hydrogen and olefiant gas. Carburetted Hydrogen is abundantly formed in nature in stagnant pools, ditchés, &c, wherever vege- tables are undergoing the process of putrefaction: it also forms the greater part of the gas obtained from coal. Carburetted hydrogen consists of 100 volumes of vapor of carbon and 200 of hydrogen. It is colorless, and almost inodorous; is not dissolved to any extent by water and is much lighter than atmospheric air, its density being 0.5594. It is very inflammable, burning with a strong yellow flame the products of its combustion are carbonic acid and water. The carburetted hydrogen, or coal-gas, when freed from the obnoxious foreign gases, may be propelled in streams out of small apertures, which, when lighted, form jets of flame, which are called gas-lights. Olefiant Gas is thus named from having the property of uniting and forming an oily substance with chlorine. It is a product of the distillation of oil, resin, and also of coal, when the process is well con- ducted. It is colorless, tasteless, and without smell when pure. Water dissolves about one-eighth of its bulk of this gas. It is formed of two volumes of hydrogen, and two of the vapor of carbon, con- densed into one volume. It burns with an intense white light, and requires a large portion of oxygen for its combustion; one volume of the gas requiring not less than three volumes of pure oxygen, or fifteen volumes of atmospheric air, for decomposition. The products of the combustion are water and carbonic acid. Sulphur exists in coal as an impurity, under the form of the sulphuret of iron. During the distilla- tion it is decomposed, the sulphur combining with a portion of hydrogen, and escaping under the form of sulphuretted hydrogen gas, part of which unites with the ammonia, and is condensed in the aqueous fluid which floats on the surface of the tar; while another portion escapes uncombined, and would mix with and deteriorate the gas, were it not intercepted by the lime purifiers. Sulphuretted Hydrogen is a colorless gas, with an offensive taste and odor, resembling that of putre- fied eggs. It dissolves in its own bulk of water, to which it communicates its taste, odor, and character- istic properties. It is combustible, burning with a blue flame, and emitting a suffocating smell similar to that of a burning match. During the combustion its hydrogen unites with oxygen to form water, while its sulphur unites with another portion of oxygen to form sulphurous acid. It is to the presence of the vapor of this substance that the disagreeable property of tarnishing metals which characterizes the combustion of impure gas is owing. Its specific gravity is generally estimated at 1.178. Nitrogen is one of the constituents of coal. It has the property of extinguishing burning bodies, and is not absorbed by water; its specific gravity is 0.9760, being lighter than common air, of which it forms a constituent part. Ammonia is formed during the distillation of coal, and of all organic substances containing nitrogen. In such distillation the nitrogen unites with hydrogen in the proportion of one to three, and ammonia is the result. It is a colorless gas, very pungent, acting strongly on the eyes and nose when respired. It dissolves in a very small portion of water, one volume taking up about 750 of the gas, forming a liquid possessed of similar properties, and sold in the shops under the name of Spirits of Hartshorn. The presence of Cyanogen is frequently detected in coal-gas before purification; it contains its own bulk of nitrogen, and twice its volume of the vapor of carbon. Chlorine is one of the elementary substances, supporters of combustion. It is possessed of striking properties, but that which alone is of interest at present is its action on olefiant gas. On mixing chlorine with a gas in which olefiant is contained, a diminution of volume is observed, and drops of oil are seen to fall on the surface of the water over which the operation is conducted. This fact enables us to estimate correctly the bulk of olefiant in any given portion of mixed gases. Digitized by Google GAS. 733 With a view to the generation of gas on a large scale, the coal is put into vessels called retorts, and furnished with pipes connected with reservoirs, to receive the distillatory products. The retorts are fixed into a furnace, and heated to redness: the heat develops the gaseous and liquid products of the coal the latter are deposited in receivers or tanks, and the former conducted through lime-water, or thin strata of the hydrate of lime, and purified. The sulphuretted hydrogen and carbonic acid, which are mixed with these, become absorbed by the lime and moisture, and the pure carburetted hydrogen is stored up in a vessel called a gasometer, and is then ready for use. From the reservoir in which the gas has been collected proceed pipes, which branch out into small ramifications, until they terminate at the place where the lights are wanted and the extremities of the branch pipes are furnished with stop- cocks, to regulate the flow of the gas into the burners or lamps. The production of gas-lights is therefore analogous to that of flame produced from tallow, wax, or oil. All these substances possess, in common with coal, the elements of certain matters, which are capable of being converted into inflammable elastic fluids by the application of heat. The capillary tubes, formed by the wick of a candle or lamp, serve the office of the retorts, placed in the heated furnace in the gas-light process, and in which the inflammable gaseous fluid is developed. The wax, tallow, or oil, is drawn up into these ignited tubes, and is decomposed into carburetted hydro- gen gas, and from the combustion of this substance the illumination proceeds. In the lamp, as well as in the candle, the oil or tallow must therefore be decomposed before they can produce a light; but for this purpose the decomposition of a minute quantity of the materials successively is sufficient to give a good light: thus originates the flame of a candle or lamp. Nothing more therefore is required in the gas-light process which coal affords, when submitted to a temperature of ignition in a close vessel, than to collect these products in separate reservoirs, and to convey one of the products, the inflammable gas, by means of pipes and branching tubes, to any required distance, in order to exhibit it there at the orifice of the conducting tube, so that it may be used as a candle or lamp. The whole difference between the greater process of the gas-light operation and the miniature operation of a candle or lamp, consists in having the distillatory apparatus at the gas-light manufactory at a distance, instead of being in the wick of the candle or lamp-in having the crude inflammable matter decomposed, previous to the elastic fluid being wanted, and stored up for use, instead of being prepared and consumed as fast as it proceeds from the decomposed oil, wax, or tallow; and lastly, in transmitting the gas to any required distance, and igniting it at the burner or lamp of the conducting tube, instead of burning it at the apex of the wick. Retorts.-The proper mode of constructing retorts in which coal 1890. is distilled, and the art of applying them, form objects of primary importance in every gas-light establishment. The forms of the retorts used at the present time are various. The annexed Figs. 1890, represent sections of a retort, of cast-iron, com- monly known by the name of a D. The charge is 3 bushels, or 21 cwt., which may be drawn at the end of six hours. The dimensions can- not be increased with economy beyond those marked on the draw- ings. Retorts of smaller dimensions are more usually adopted. Mode of setting a bench of five D retorts.-These Figs. represent a front elevation, two sections and plan of a bench" of five common retorts, such as are in general use. Fig. 1892 is a front elevation. Fig. 1893, a transverse section, through a b in Fig. 1894. Fig. 1894, a longitudinal section, through c d in Fig. 1893. Fig. 1895 is a plan showing the furnace and side openings below the fire-tiles, on which the lower retorts rest, and the bedding of the lower retorts. Fig. 1896 is a plan over the three lower retorts, the two upper retorts being removed. Fig. 1897 is a plan over the oven-arch, showing the flues, &c. The same letters refer to corresponding parts in the several views. A. Retorts of the kind called D's. Some engineers prefer those of a cylindrical form, but D's allow of the coal being laid in thinner strata, consequently it is more evenly acted upon by the heat, an advantage under every circumstance. Set in the manner shown in the Figs. the bottoms of those retorts placed immediately over the furnace are well protected. The dimensions are-length 7 feet, diameter 1 foot 2 inches, thickness of metal 11 inch. Their weight is about 15 cwt. of cast-iron. The most economical charge is two bushela, or 11 cwt. of coal to each retort, drawn at the end of six hours. This charge will fill the retort to the depth of about five inches; if the coal be moderately small, the layer will be rather less in thickness. At a heat of 27° of Wedgewood's pyrometer, or that of melting copper, each charge ought to produce about 650 cubic feet of gas, of the specific gravity 400, (the specific gravity varies between 390 and 420, according to the heat at which the retorts are worked, and the quality of the coal carbonized,) from Newcastle coal, making the products of the entire bench equal to 3250 cubic feet in six hours. To introduce the coal into the retorts, a "scoop" ought to be employed, 1891. in preference to the primitive mode, with a shovel. The scoop is a semi- cylinder made of thin plate-iron, six feet six inches long, and twelve inches in diameter, with a cross-handle at one end, represented in Fig. 1891. The charge for the retort is placed in this; one man takes the cross- handle, and two others at the opposite end lift it with its contents up to the retort; it is then pushed forward, quite to the bottom, turned round, and withdrawn immediately, and the coal left in the retort raked into an even stratum. The lid, previously luted, is now quickly jointed on to the retort-mouth. It must be obvious that the loss of gas by this simple method is very trifling, the whole operation not occupying more than forty seconds; whereas, when the shovel is used, the coal is thrown in 80 much by degrees, that more gas is Digitized by Google 734 GAS. lost, owing to the greater length of the operation, and the heat producing some effect on each separate shovelfull: in either case the loss is inconsiderable. Previous to drawing the charge, loosen the lids of the retorts, and apply a light to the issuing gas, beginning at the upper retorts. This precaution is necessary to prevent explosion. S is the mouth-piece, ten inches long, with a socket cast on the top to receive the stand-pipe. There ought to be a neck to this socket, as shown in Figs. 1892 to 1894; because the joint, when close upon the top, from its greater thickness, retains much heat, and decomposes the tar which will accumulate at this place and eventually choke the pipe with hard carbon. The length of the neck may be from four to five inches. D D C c C G E Q B S D H B A A A A P S W Y M Y L V 0000000 X d 1892. 1893. The mouth-piece is three-quarters of an inch in thickness, secured to the retort by bolts, and a cement joint made between their flanches. Iron cement is the most valuable for this purpose, and is used in all places where heat is present. It may be compounded as follows: To one ounce of sal- ammoniac, add one ounce of flowers of sulphur, and thirty-two ounces of clean cast-iron borings; mix all well together, and keep the composition dry. When the cement is wanted for use, wet the mixture with water, and when brought to a convenient consistence, let it stand for a few hours; then apply it to the joints, and screw them together. The flanches ought to be kept about three-eighths of an inch apart, by wrought-iron wedges, and the cement well filled in between them with a square blunt-pointed chisel, called a caulking-chisel; the cement is stopped from being driven through by a hoop of thin iron placed inside the pipe or retort to be thus operated upon, which is afterwards removed. A consider- able degree of action and reaction takes place among the ingredients, and between them and the iron surfaces, which causes the whole to unite as one mass; the surfaces of the flanches become joined by Digitized by Google GAS. 735 D C' 1894. a 2 0 0 B M M N N L V X b 1895. 1896. P N T A P N T Digitized by Google 736 GAS. a species of pyrites, all the parts of which adhere strongly together. Mr. Watt found that the cement is improved by adding some fine sand from the grindstone trough. A very economical joint for the retort mouth-piece is made of five parts of fine clay, and one part of the mixture just described. The face of the retort mouth-piece is bevelled inwards, and is chipped and filed, if necessary, to re- move any lump that would prevent the lid from fitting close; a clean and true casting, however, seldom requires this to be done. 1897. R o o The lid is jointed on to the face of the mouth-piece, with "luting" made of the spent lime from the dry purifiers, mixed with a little fire-clay, and tightened into its place by a strong, square-threaded screw, and cross-bar of wrought-iron, the ends of the cross-bar being passed through projecting ears, against which it bears when the screw is turned. B is the "stand-pipe," through which the gas, as it is generated, passes from the retort; it is three or four inches in diameter at the top, increasing to five inches at the bottom, to prevent the tar which adheres to the lower parts from obstructing the flow of the gas. The lowest joint is made with a socket, instead of a flanch, to allow for some expansion without injury. B' is the "bridge-piece," connecting the stand and dip-pipes. C is the "dip-pipe," passing through the upper metal of the hydraulic main, upon which it is jointed, and having its lower extremity, which is three inches in diameter, immersed four or five inches into the tar contained therein. The holes in the hydraulic main, through which the dip-pipes pass, are generally drilled and chipped out while the apparatus is in process of erection; because they are at unequal distances from one another. The height of the dip-pipes from the surface of the tar, measured from the lower bend of the bridge-piece, ought to be sufficient to contain the perpendicular head of tar forced up into them by the pressure of the gas from the working retorts. This would probably in no case exceed three feet. DD are the bonnets, to be removed when the pipes require clearing, jointed by putty and paste- board. E is the "hydraulic main," running the entire length of the retort-house, over the benches, in a per- fectly horizontal direction, and sufficiently high up to allow of head-room; and to be removed from the flame issuing from the retorts while charging. They are sometimes turned the reverse way to that shown in the Figs, and made to rest upon the brickwork of the benches; but this is inconvenient when the brickwork has to be taken down or repaired. This main is three-quarters of an inch in thickness, and cast in convenient lengths, contrived to reach over two benches; in this case they would be equal to 13 feet 6 inches. The joints are made with iron cement. Its use is to cut off the communication between the retorts, when one or more benches are charging or open. Being half full of tar, the gas evolved from the retorts in action remains in the upper part, and the ends of the dip-pipes immersed under the surface are effectually sealed. The diameter of the hydraulic main must be sufficient to form a reservoir capable of supplying the quantity of tar contained in the open dip-pipes without suffering it to fall below their immersed ends, and thus open a communication between the open and working retorts. In the general arrangement of the hydraulic main two things must be observed. First the diameter must be sufficient to supply at least 20 inches perpendicular head of tar to each dip-pipe, without causing the general level to fall below their immersed ends; and secondly, the lower part of the cir Digitized by Google GAS. 737 cumference of the pipe, which conveys the gas to the condensers, must be 80 placed that the tar may always be kept from rising too high, and either choking the free exit of the gas or increasing the working pressure of the retorts unnecessarily. The diameter of the main in the engraving is 18 inches-amply sufficient for fifteen benches of retorts. F is a light, hollow, cast-iron pillar, supporting the hydraulic main in the centre of each length; it is based upon the cast-iron girder which supports the firing-floor. G is the pipe through which the gas makes its exit from the hydraulic main to the condensers, furnished with a slide-valve to disconnect the mains at each side of the house, when at any time it may be found requisite to repair or clear them. H is a small pipe for conveying the surplus tar formed in the hydraulic main to the tar-well situated beneath the firing-floor; its lowest extremity is sealed, by being immersed in the tar contained in the well, or in a small vessel by the side and connected with it; the latter is the most convenient. This surplus pipe is not absolutely necessary, because the siphon at the bottom bend of the first stand-pipe would perform its duty, but it is advisable to draw off the tar as soon as possible. In the construction of retort-houses the firing-floor is raised upon flat 9-inch brick arches over the coke vault, high enough to give head-room, a space about 24 inches wide being left in front of the benches for the coke to fall through when drawn from the retorts: it should be of such a material as will not be injured by frequent blows; some prefer cast-iron. The flat arches supporting the floor spring from cast-iron girders fixed at one end in the brickwork of the benches, at the other in the wall of the retort-house. The distance between the centre and centre of these girders is six feet nine inches. L is the furnace for heating the retorts; its breadth is 14 inches, the length of the fire-bars 24 inches. The bars are placed loosely upon the bearers, and must occasionally be clinkered," or lifted from their seat in the front and cleared from the slag which adheres to them. M M are side openings, three inches square, left in the brickwork, through which the heat of the furnace passes. N N are 4}-inch walls, built of fire-bricks, one between each of the openings M; they serve to support the fire-tiles T, on which the outside lower retorts rest. The direction of the flues is shown by arrows. P P are fire-bricks, placed on end, and a fire-lump, upon which the two upper retorts rest. The heat acting on these being somewhat moderated, no guards of fire-tiles are necessary. o o are openings, 3 inches by 41, in the crown of the main arch communicating with the branch flue. Q is the branch flue, one being built over the centre of each bench of retorts. R is the main flue, running the entire length of the benches, and connected with the chimney into which all the branches lead. Between this main flue and each branch is a damper Z, to regulate the draught through the furnaces. S'S' are cast-iron plugs, covering sight-holes, through which the heat of the retorts is seen and judged of. V is the furnace-door, protected by a fire-lump inside. W is a cast-iron plate, 11 inch thick, on which the fire-door is hinged, serving also to protect the face of the brickwork which it covers. In the centre, and about six inches above the fire-door, a square opening is cast for the admission of an iron spout, when it is required to burn tar. X is a pan at the bottom of the ash-pit, for evaporating ammoniacal liquor, and the offensive unsale- able liquid products which cannot be disposed of otherwise. Y Y are openings left in the walls N, by which the carbon deposited from the furnace is cleared away. It must be obvious that the durability of the distillatory apparatus greatly depends on the manner in which the heat is applied to effect the decomposition of the coal contained within the retort. If the heat be very intense, the whole vessels are rapidly destroyed; if it be too languid, the distillation is protracted, the gas is of inferior quality, much fuel, time, and labor are wasted to no purpose, and the retorts are speedily deteriorated, as the heat acts upon one part more than upon another. The experi- ments by which the present plan of heating retorts was arrived at, were many and expensive. Origi- nally they were built in brickwork singly, and heated by flues passing beneath and over them, without any guard, except in some instances that of an iron saddle. They were afterwards placed in pairs, then in a great number; but nevertheless, until the guard of fire-tile was used, the wear and tear was enormous. The great obstacle to working more than two retorts to one furnace evidently arose from the diffi- culty of conducting the heat by means of flues around the series of retorts in such a manner that it should act with equal force on all. Different workmen constructed these flues in different ways: in short, the forms varied in every possible manner, and still with the same result. The fuel required for heating the retorts, when set without guards, was less by nearly ten per cent. than that required for the same purpose on the oven plan; but the greater duration of the retorts much more than compen- sated for the additional fuel. The oven represented in Figs. 1893 and 1894 is one of the latest arrangements. The heat from the furnace passes through the square openings M at each side, and is thus equally divided along the whole length of the retorts; from between the walls N it rises between the fire-tiles at the outer sides of the lower retorts. The flame is not suffered to impinge upon any part, but is equally distributed throughout the oven, and consequently the retorts work and burn out" evenly. The lower retorts, which would otherwise be exposed to a more direct heat, are carefully guarded by fire-tiles, which at the same time prevent the bottoms from bulging. The openings 0 at the top of the main arch act more in the manner of safety-valves than flues, serving to regulate the final exit of the heated air, and, being distributed along the outer length, they do not draw the flame to one part. The whole interior of the oven, as well as those parts in contact with the flame, must be constructed of fire-bricks. The main arch, six feet in span and half a brick in thickness, is formed of bricks moulded on purpose to suit the curve, the joint being kept as close as possible. As this arch is permanent, much care should be taken in its formation. 93 Digitized by Google 738 GAS. A bench of retorts on this plan, if well and regularly used, ought to last from 12 to 14 or even 15 months, and ought never to be suffered to become cold. The first portion of oxide which forms upon the surface, when allowed to cool, cracks and falls off, leaving a new surface to be acted upon the next time it is heated. When it becomes necessary to reduce the number of working retorts on the approach of summer, those that are nearly burned out should be selected; or, if there are none in this condition, let them down" very gradually, by keeping the damper closed after the fire is raked out it will be a week before they become quite cold. The same precaution should be taken in getting up" the heat-opening the damper gradually. When a bench of retorts is newly set, the green work must be suffered to get quite dry before any fire is lighted. The results of a chaldron, or 36 bushels of Newcastle coal, weighing 27 cwt., distilled in retorts set in the manner just described, and the quantity of fuel used for the distillation, will be as follows :- Gas of specific gravity -400 8650 cubic feet. Gas of specific gravity 400. 8600 cubic fect. Coke of good quality 14 cwt. Coke 13 cwt. 3qr. Ammoniacal liquor 121 gallons. Ammoniacal liquor 121 gallons. Thick tar 12 do. Thick tar 111 do. Tar used as fuel 19 do. Coke used as fuel 6 cwt. Lime for purifying 86 lbs. Lime for purifying 84 lbs. In country towns, where the quantity of gas made during the winter seasons does not exceed 10,000 cubic feet in twenty-four hours, the retorts must be set singly, as represented in Fig. 1898, the flue passing beneath and over the retort, which rests upon a half-brick arch, cut flat at the top to receive it; the end is guarded by a thick fire-tile. 1898. 1899. TopFlue Furnaces When the quantity of gas made in twenty-four hours does not exceed 30,000 cubic feet, or when the quantity made is decreased 1200 cubic feet at a time, on the approach of summer, the ovens may contain two retorts, as shown in Fig. 1900. The flues are arranged in a similar manner to those in a large oven. 1901. 1900. :- The Fuel used for heating the retorts may be either coal or coke, according to the relative value of each in the district. If coal is used, a well-regulated bench will require about 18 to 20 per cent. of the coal distilled ; that is to say, to heat the retorts for the production of 12,000 cubic feet of gas, from 5 to 51 cwt. of coal will be necessary. The use of coke as fuel is general in those places where coal is valuable, and where coke is less in requisition as fuel for manufacturers. The quantity of coke for heating the retorts will vary from 40 to 45 per cent. of the quantity produced; that is to say, from 16 to 18 bushels of coke are requisite to distil one chaldron of coal, or 5 cwt. will distil one ton. Mr. Croll has introduced a system of using the coke as fuel while red-hot. The charge from the re- torts is drawn into a wrought-iron carriage, and immediately taken to those furnaces which require feeding. The saving effected by this simple process is equal to 10 or 12 per cent. The reason is evident; because when a quantity of black coke is thrown on the previously-heated mass of fuel, the flues will to a certain extent become cool, since the heated air is absorbed. When hot coke is thrown on, no absorption takes place, and the flues are kept up at a uniform temperature. Digitized by Google GAS. 739 The use of tar as fuel has of late become frequent, and is the most economical, as far as it is availa- ble. In almost every instance it is worth more to burn than to sell. The quantity required for car- bonizing a chaldron of coal varies from 24 to 27 gallons. The furnace used for burning tar is the same as that used for other fuel, and is fed by a small continuous stream, conducted by a wrought-iron service-pipe, from a tank placed on the top of the 1902. retort-benches, on to a sheet-iron spout projecting a few inches outside the furnace-plate, and into the furnace itself, as shown in Fig. 1902, were it spreads over a "breeze-bottom," previously brought to a red heat. When retorts have been at work for some months, their interior surfaces become incrusted with a hard carbonaceous deposit, approaching, in some of its properties, to plumbago; in process of time carburet of iron and the more infusible parts of the coke form a thicker crust, which it becomes necessary to re- move, both to prevent the destruction of the retort, and to allow the fuel to have full effect upon the coal contained within. This was formerly effected with great difficulty by crowbars, the force required often increasing the evil it was intended to remedy. It was afterwards found. that leaving the retort open, and allowing cold air to come in contact with the heated interior, the deposit contracted, and could be broken away in about twelve hours without danger to the retort. In order to take off this crust without endangering the retorts, an air-blast is used, as follows :-A cast-iron pipe, about three inches in diameter, is carried along the front of the benches, at a little distance above the upper retorts; at points in this pipe, directly over every retort, a screw and plug is attached, into which screw, when the plug is removed, a wrought-iron service, about an inch in 1903. 1904. 1906. 1905. diameter, can be fixed, and led into any open retort The main pipe is connected with a blowing cylinder, worked by the steam-engine, 80 that a strong blast can be made to impinge upon any part of the hard incrustation, which gradually yields to it, and may then be removed without difficulty. Ear-shaped retort.-Fig. 1903 is a front elevation of a bench containing three retorts Digitized by Google 740 GAS. Fig. 1904 is a section taken transversely. Fig. 1905 is a longitudinal section through the centre of the arch. Fig. 1906 is a plan of Fig. 1904. Figs. 1907, 1908, and 1909 are views of a mouth-piece on a scale of t an inch to a foot, which will show the method usually adopted for securing the lid in all ordinary retorts. 1909. 1907. 1908. 1.0 The great objection to the ear-shaped retort is, that the bottom bends are liable to become filled up with hard carbon, and when that is the case they are sure to crack. The principle on which they are constructed is good; and if they could be charged properly, viz. with a stratum of coal from 3 to 31 inches thick, evenly spread over the bottom, they would be found to make more and better gas than D's and circular retorts, (where the stratum of coal is thicker,) simply because it would be more evenly acted upon. In all cases, with the same degree of heat, the thinner the stratum of coal the better the gas. The mode of setting these retorts may be precisely similar to that explained in Figs. 1902 and 1903. Brunton's patent.-Fig. 1910 represents a front view of a bench of four retorts, upon Mr. Brunton's principle. 1911. 1910. B B D D F E LAAI A A are the retort-mouths, the lids of which are fitted with stuffing-boxes, for the reason to be pre- sently described, and permanently jointed in their places with iron cement. B B are hoppers, capable of holding from 20 to 28 pounds of coal, which, when an air-tight slide- valve C is drawn back, falls into the retort through the neck D: the valve is closed immediately. 1912. B D K G F H R E is the furnace, projecting beyond the face of the brickwork in which the retorts are set. F F are handles for working a piston contained in the mouth-piece A. Fig. 1911 is a transverse section of one half of a bench. The retorts G, shown as circular, may be varied in form if thought necessary. We believe the patentee gives thepreference to those of a D shape. Digitized by Google GAS. 741 E is the furnace; the direction of the flues is shown by arrows. Fig. 1912 is a longitudinal section through the centre of the furnace. H is a short pipe, open to the interior of the retort, sealed at the lower end by dipping into water, through which, after a charge is thrown into the retort from the hopper B, a portion of coke is expelled, by advancing the piston contained in the mouth-piece. 1914. I 1913. 6 и H E I is the pipe by which the gas, as it is formed, passes to the hydraulic main. K is a bonnet, to be taken off at any time when required to examine the interior of the retort. Fig. 1913 is a back view of Fig. 1910. Fig. 1914 is a plan below the retorts. (The same letters refer to corresponding parts in all the figures.) 1915. The annexed diagram, Fig. 1915, will explain the construction of the piston before alluded to. a is the piston, drawn back in the proper po- sition to receive a charge, which, when the slide- valve is opened, will fall into the space b, and be propelled forwards into the heated part of the re- tort by turning the screw c, which works in a nut d on the back of the piston. e is a collar upon the shaft of the screw, work- b ing between the bottom of the stuffing-box and a washer held in its place by four pins. The stuf- fing-box is made tight in the usual way, by screw- ing the gland f against a gasket. g is a shield loosely attached to the front of the piston, to prevent the accumulation of small coal- dust in the mouth of the retort. When the charge is thrust forward, the piston is turned back directly into the mouth, to preserve it from the action of the heat. That part of the retort adjacent to the flues only is heated, consequently the only part liable to much wear and tear. The only part requiring renewal is that of the retort situated between the outer walls of the bench, and weighing about 9 or 10 cwt. The fuel required to carbonize the coal is about 25 per cent. in coal on the quantity distilled. Reciprocating retort, the invention of Mr. George Lowe. It has been stated that the first portion of vapor produced by coal when undergoing destructive dis- tillation in ordinary retorts will, when converted into gas, form that of the most brilliant quality, and it is to effect this that the following arrangements have been patented. Fig. 1916 is a back elevation of two pairs of retorts. A1, A3, Aᵃ, A' are the retorts; BB the stand- pipes; CCC, slide-valves for opening and shutting off the communication between the retorts and hydraulic main; D is the hydraulic main. The front elevation differs but little from it. Fig. 1917 is a plan of the lower pair of retorts; the operation is as follows:-Supposing the entire bench to be at the requisite heat for decomposing the coal, and that they are working six-hours' charges, the lids of the retorts A' and A' are removed, and by means of scoops (each half the length of the retort) the coal is introduced at both ends, and the lids immediately secured in their places: the slides F' and F' are opened, and C' and Ca closed. The bituminous vapors that rise first will pass through the pipes EE, and thence through the entire length of the hot retorts A2 and A', and be converted into gas, which will pass to the hydraulic main by the stand-pipes on which the slide-valves Cs and Cª are fixed, and which remain open. When the distillation has gone on for half the duration of the charge- viz. three hours-the valves C' and C' are opened, F' F' shut, and the gas evolved from the retorts A' and A' passes through the stand-pipes attached to them. The retorts A2 and A' are now charged, the mouths closed, the valves F' and F' again opened, and Cs and C4 shut. The operation is now reversed, the first vapors passing through the two first-charged retorts until their charge is expended, when C2 and C' are opened, F' and F' closed, and the charge drawn. They are then immediately recharged, and the operation of opening and closing the valves repeated. Retorts on this construction have been worked, and are found to act well, producing gas of average quality and in greater abundance than by the ordinary method. The reason of the gas being only of Digitized by Google 742 GAS. an average quality is, that the carburetted hydrogen made after the production of bituminous vapor has ceased, still passes over the red-hot surface of another retort and deposits some portion of its carbon, the rich gas formed by the conversion of the bituminous vapor only serving to make up the deficiency. 1917. c⁴ C°C¹ 8 D 1916. B B E A4 As At A2 E E As A4 E E F2 If, instead of having only two retorts in a set, the number could be increased to six, and after the first hour the gas be allowed to pass away on the ordinary plan, both the quantity would be augmented and the quality improved. Revolving web retort.-This retort is arranged 80 that the coal is acted upon in a thin stratum and converted into gas at once: the chemical advantages of this method are many ;-all the elements of the coal are liberated at nearly the same time, and unite with one another in such proportions as to form gas of the best illuminating quality, and in greater abundance than when the coal is carbonized in mass. The condensed bituminous vapor which forms tar in the ordinary process is by this nearly all converted into olefiant gns. 1918. a C G Brich Rnbble D M Fig. 1918 is a longitudinal section through A B in Fig. 1920. Fig. 1921 is a transverse section through CD in Fig. 1918. Fig. 1919, plans of the retort in section, over the top of the retort, the web, and furnace, respectively. Digitized by Google GAS. 743 The same letters refer to corresponding parts in all the figures. E is a hopper containing the coal; F is the discharging-disk; G is the retort; H is a web on to which the coal is discharged by the disk F; II are revolving drums carrying the web H; K is the furnace; LL the flues passing under and over the retorts, and finally into the main flue; M the shoot into which the coke falls; the end of which may either dip into water or be furnished with a tight door. The retort itself, and the cham- ber in which the drums work, are made of wrought-iron boiler- plates, riveted together 80 as to be 1919. quite gas-tight. The only parts subject to wear and tear are the retort adjoining the flues and the web, both of which are heated; G F the latter however never becomes so hot that the shape alters. The action of this arrangement is as follows :- All the coal must be either ground, or beaten small and H screened, so that no lumps re- main larger than coffee-berries, and a twenty-four hours' charge must be thrown into the hopper and secured by a luted cover. The discharging-disk, which is nine inches in diameter, with six arms, is made to revolve uni- formly with the drum below it, at the rate of four revolutions an hour for this purpose two shafts run the entire length of the retort-beds, on one of which the drums are fixed; on the other are the dis- charging-disks, connected at one end by a strap. The diameter of the hexagonal drums is so regulated, that the coal which falls on the web from the discharging-lip will at one revolution have passed the entire length of the retort. Fifteen minutes is quite time enough to convert the coal so distributed into gas. Each link of the web is 14 inches long and 24 inches broad, having a surface of 336 square inches, upon which the contents of one partition of the disk will be discharged, viz. a little more than 124 cubic inches of coal in a stratum less than three-eighths of an inch thick. Each successive link receives the same quantity, so that, in one entire revolution of the disk and drum, 745 cubic inches of coal (equal to 21 pounds) are distributed over a heated surface of 2016 square inches, and converted into gas. Eighty-four pounds of coal will by this process make 450 cubic feet of gas of the specific gravity 490. It therefore follows, that in 24 hours 18 cwt. of coal will be discharged by each retort, making 10,800 cubic feet of gas, equal to to 12,000 cubic feet per ton. 1920. 1921. d G I Is K B M These retorts are considerably more expensive in the first instance than those in general use, but in the end they would be found cheaper. Indeed, the entire arrangement is one of great economy, and by far the most scientific process yet adopted for making coal-gas; it requires no attendance, except that of keeping up the furnace and charging the hopper once in twenty-four hours. No gas is lost, and no tar made. The coke produced is increased in quantity by about 75 per cent., but its quality is not 80 well fitted for general purposes (although superior for culinary uses) as that produced by the common process. The power employed for turning the shafts may be A water-wheel which would be preferable to a steam-engine, unless in large works, where the latter could be employed for other purposes. An overshot wheel, six feet in diameter and nine inches in breadth of float, would drive twelve retorts at the speed required; the water for turning such a wheel for twelve hours may be pumped up by two men in about an hour and a half. This form of retort is in first cost more expensive than others, but it is believed to be in the end more economical. Digitized by Google 744 GAS. The quantity of gas produced by five D retorts, such as are shown in Fig. 1892, will be about 14,000 cubic feet in twenty-four hours, of specific gravity 390 or 400, and the quantity produced by four of the proposed retorts will be 43,200 cubic feet in twenty-four hours, of the specific gravity .470 or 490. All the machinery, except the retorts and webs, will last for years without any repair, except what may arise from contingencies, to which all machinery is subject. Earthen retorts.-In speaking of clay or earthen retorts, it is necessary to limit our remarks upon them to the results of practice; for in many instances, owing to actions not entirely and clearly ac- counted for, the results given by these vessels differ from those which theory in its strict sense would admit as being correct. One practical point must be observed, that clay retorts of small dimensions are less economical than those of larger size, owing to the great per centage of fuel required to keep them at a proper tempera- ture for decomposing the coal. The advantage of using the latter description of distilling vessel is sim- ply a question of profit and loss, or whether it is cheaper to burn iron or coal. The material of which they are formed is a non-conductor of heat, consequently the absorption of caloric is less rapid; and although they retain their heat when a fresh charge is introduced better than iron retorts, yet not sufficiently to bring down the quantity of fuel as low as that required for metal. Notwithstanding this, even small clay retorts are preferred in many places, particularly in Scotland. Mr. James Reid, of the Montrose Gas-works, has favored us with the following description of his earthen retorts: 1922. D D D e so " We have had clay retorts in operation for the last three years, and from the great difference in price, compared with that of iron retorts of the same size, and from the immense superiority over metal in working them, we have entirely given up the use of the latter. I tried the clay retorts in the shape of an ellipsis, in the D and circular form. The size I find best adapted to all purposes is eight feet long, fourteen inches diameter, and four inches thick: such a retort costs £2 6s. ; the pillars or columns for supporting them are 6s. each, and each retort finished costs £3 48. The mouth-pieces are cast metal, and fastened to the end of the retorts by bolts and flanches, as in the ordinary description, and jointed with fire-clay and iron cement. The retorts are made in two lengths, and are jointed by a body of fire- clay well diluted with water. The most economical plan for erecting them is to set them, three under one arch, heated by one fire. Their only drawback is, that when the heat is let down they contract unevenly on cooling, and are liable to leak when again required for distillation; they generally last two years." Clay retorts have been used for some years at Wolverhampton with success. The retorts are circu- lar and made in joints of 32 inches long. In several places these retorts are made at the works. The reader will fully understand their plan of construction from the elevation and sections. Trans- Digitized by Google GAS. 745 verse section and elevation, Fig. 1922, and Fig. 1923, longitudinal section, which require no description, ex- cept that the bottom is exposed directly to the heat of the fire, and is slightly cambered," or curved up- wards, to enable it with more certainty to retain its form. The cement with which the parts of the oven are jointed is a composition the ingredients of which are not known, but seems to be an excel- lent substance, and when the interior is coated with it, becomes vitrified and quite gas-tight under con- siderable pressure. In England and Scotland the fire-clay retort has superseded the use of metal in no less than forty towns; in some instances it has lasted for the extraordinary period of twelve years. The oven or D-shaped retorts are found to be the most advantageous, being made with a capacity to carbonize one cwt. of coal every hour. They can be constructed either to be heated by coke ovens, or coke furnaces, or by the burning. of tar: with coke ovens they are more durable. It appears that clay retorts, when constructed upon such a scale as that given in Fig. 1922, have great power to retain their heat when brought to the proper temperature for decomposing the coal, viz. 27° of Wedgewood, and the intro- duction of a fresh charge is not nearly so much felt by them as by metal This power of retaining heat is proved by constant practice to produce 1000 cubic feet of gas per ton from the same coal more than the average of the London produce, and the consumption of fuel is not more than 22 or 23 lbs. of coke to carbonize 100 lbs. of Newcastle coal, taking the average of six months' working. 1923. A) B When properly constructed, these retorts are not in any degree liable to fracture or to the escape of gas, but are of such strength as to resist the greatest pressure which is likely to be put upon them. The coke also made by them is invariably of better quality, and produces less breeze or waste. Oil gas.-It appears, at first sight, both inexpedient and superfluous to distil oil for the production of gas, when we consider that oil can be burnt in lamps without any further preparation, whilst it loses carbon by deposition in the retorts. Purified lamp-oil is consequently never used but gas can be prepared from impure oils, train-oil, or refuse fat, with as much ease as from the purer kinds. The manufacture of gas is, therefore, under certain circumstances, an admirable means of using up such materials for the production of light, as could not otherwise be employed, or only applied to the lowest uses. The experiments of Henry, which extend also to this part of the subject, show at once the plan that must be adopted upon a large scale. His results are given in the table in the following page; from which it appears that oil gas is superior to that obtained from coal, as is also shown by its density, and that the produce, dependent chiefly upon the temperature, is of the best quality when obtained at a low red heat. This temperature suffices to convert the oil into gas, but is not sufficiently high to decarbonize the gas to any great extent. The apparatus for obtaining gas by the distillation of oil is represented in the following drawing, Fig. 1924. To accelerate the evolution of gas, and shorten the time which the gas already produced has to remain in the red-hot vessel, the retort a is filled with bricks, or 94 Digitized by Google 746 GAS. lumps of coke, which extend the red-hot surface very materially. The second cylinder b, serves both as reservoir and hydraulic main at the same time, and, with this object in view, a and b are connected in two places d and g. Oil flows from a large cistern above the apparatus in a constant stream through the tube c to b, which b is thus kept filled up to a certain level. From b the oil descends through e to a, is converted into gas and tar, returning through d to b. The tube d makes a short bend, and just enters below the fluid level in b, so that the vapors of the decomposed oil must constantly pass through the reservoir of oil, and deposit their tar. The retort a is, therefore, constantly supplied, not only with oil, but with a mixture of oil and tar, in such a manner, that all the condensed products return to the 1924. b retort together with a fresh quantity of oil, until they are completely converted into gas. If the ex- periment is made in a long tube, inclined at the hinder part, whilst the front is kept cool, hardly any tar will be produced. The gas which collects above the oil in b, passes on through the tube g. As the objections raised in the case of coal gas do not here occur, cast-iron retorts are solely used in oil gas works, with the same firing in other respects, r being the grate. According to trustworthy statements, 1 cubic foot (= about 4 gallons) of oil produce 600 to 700 cubic feet of gas, which is equivalent to from 90 to 96 per cent. by weight; the remainder is carbon, which is deposited between the coke or bricks, and some unavoidable loss. The production of oil gas is a continuous process, and thus differs from the distillation of coal. The retorts only require opening now and then, for the removal of the deposit of graphite. Vapors of the same composition and properties are found in oil gas, as in coal gas. Thus, according to Hesz, all the volatile empyreumatic oils, which occur mixed with each other in tar from oil, have the same composition per cent. as olefiant gas. Faraday had previously observed in England, where oil gas was compressed for technical purposes with a pressure of 30 atmospheres, that these vapors were condensed to a fluid, of which 1 part occupied the space of 7500 parts of gas. Substances Temperature of the Specific gravity of the gas. Absorbed by chlorine. Light carburetted hydrogen. Carbonic oxide. Hydrogen. Nitrogen. distilled. Distillation. In 100 parts of illuminating gas. Bright red heat 0.464 6 28.2 14.1 45'1 6·6 Oil Ditto 0.590 19 32.4 12.2 324 4 Lowest possible temperature 0.758 22.5 50.3 15.5 7.7 4 Train-oil Low red heat 0-906 38 46.5 95 3 8 Resin gas.-If resin (colophony) were usually fluid, instead of being solid, there would be no differ ence in the mode of obtaining gas from it to that practised in the oil-gas manufacture; as this, however, is not the case, it becomes necessary to render the resin fluid by some suitable means, that it may be easily supplied to the retort. The volatile oil from tar is frequently used for this purpose. Digitized by Google GAS. 747 The flame from the retort fire, before escaping by the chimney, is caused to heat up a vessel con- taining resin. As this melts, it trickles through a sieve, into the second division of the vessel, leaving the impurities and the solid portion behind, where it is mixed with an equal part of the oil of resin (tar). Thus a solution which will no longer solidify is obtained, and with it the retort is supplied, as with oil in the former case. When the gas has parted with its condensible vapors in the coolers, it is in a fit state for consumption, no further purification being required, as is likewise the case with oil gas. One of the best arrangements for resin gas, and which has stood the test of practice, is that which has been extensively carried out by Chaussenot, and is shown in Fig. 1925; the resin is here melted by itself, and the oil of tar collected and disposed of as a secondary product. The draught to the fire- place P is regulated through the ash-pit by means of the plate Q, which can be moved horizontally backwards and forwards in the groove h. The air passing from below through the grate r r, and the fuel, creates a powerful flame, which passing, in the first instance, through the apertures in the roof, plays round the retort A, in the space M, and then, before reaching the chimney, heats the vessel I, containing the resin, by means of the flue NN. If this vessel requires filling, the fire is shut off from N, by the damper b, and is allowed free egress at the aperture 0, by drawing back the damper c. Both the dampers are worked by iron rings and rods from without. In Chaussenot's apparatus, it is not necessary to dissolve the resin in tar-oil, because the vessel I, in which the resin is melted, and the conducting tube H, being constantly surrounded with hot air, no solidification of the melting resin at the bottom f need be apprehended. Combustible gases are generated by merely melting the resin, which may possibly endanger the whole apparatus. To avoid such contingencies, the edge of I is fur- nished with a groove filled with water и и. into which the lid K dips at v v, and is consequently secured by a water-valve. By means of the appendage y, the vapors can be conducted into the chimney, or under the grate. The melted resin flows consecutively through H G and x, into the retort A. Between 1925. Ga G and H is a plate o, with a funnel-shaped aperture in the middle, in which the conical end of the rod d is movable. If this is raised through the stuffing-box e, the retort A receives a larger flow of melted resin ; if it is pushed down the stream diminishes, or the flow ceases entirely. The resin flowing from x is carried to that part of the retort containing the coke, by means of the inclined plate g. The coke is prevented falling into the neck of the retort by the grating 1; here, too, the gas escapes through a tube downwards to the tar cistern C, and from thence through E to the cooling pipe D, which is im- mersed in " ater in a long trough P. C is constantly nearly filled with tar, that the mouth of to may always rem n immersed; this, therefore, dips into C, whilst the gas-pipe E, behind the sectional level in the draw H. only just passes through the material of the main C. The neck F. situated above x, has a small appendage a'; this, as well as a" and a", is constantly immersed, and all three are used only for introducing iron rods in cleansing the approaches to the retort; a is a similarly constructed appen- dage for screwing up the lid of the retort; a a' a" and a"" are all furnished with iron semicircles and Digitized by Google 748 GAS. screws, for forcing iron plates flat against the apertures. In such a furnace, therefore, distillation goes on continuously, until the deposition of carbon renders a renewal of the coke necessary. Resin gas is not 80 highly illuminating as oil gas, and is of about the same quality as coal gas; it is used in many towns, as in Frankfort-on-the-Maine, Antwerp, &c. 14 to 23 cubic feet of gas are obtained from 1 lb. of resin. Gas from soap-roater.-Few cases are adapted to give 80 favorable an idea of the practical value of gas illumination, as the process carried out at the works of Houzeau Muiron, at Rheims, where very good gas is obtained from refuse which previously cost something to throw away, and which now is a source of profit to the manufacturer. This refuse is the soap-water, in which woollen stuffs have been freed from fat. Besides the unchanged fat with which those goods are charged as they come from the loom, the soap-water contains a solution of oleate and stearate of soda, and compounds of the same acids with lime in suspended flakes, and lastly, animal matters extracted from the wool. From all parts of the town the soap-water is collected, and brought to the reservoirs of the works, where 300 cwts. at a time are treated with 2 per cent. of sulphuric acid, (or twice as much hydrochloric,) mixed with equal parts of water. After the lapse of 12 to 18 hours, complete coagulation is effected. The water contains Glauber's salt (sulphate of soda) in solution; a little gypsum is formed at the same time, and an impure gray fatty matter rises to the surface. This consists of the fatty acids, oil, and animal matter with much water the greater part of the latter has already been mechanically separated, and the remainder is removed by melting in copper vessels; the contents are then drawn off into a second boiler containing some sulphuric acid to effect a clarification. The filtration which follows affords a clear oil, and this gives with crude soda (containing sulphuret of sodium) a very tolerable soap, whilst sulphuret of iron separates, together with a black solid residue, containing much fat for distillation in the gas retorts. The process of distillation is like that practised with resin: the tar produced the first day is used on the morrow to dissolve and render fluid the solid residue, and 80 on. The ohm (= about 30 gall.) of soap- water costs 28 kreuzèrs, about 18 cents.) Gas from animal matter.-In the distillation of animal matters, bones, flesh, &c., as it has long been practised for the production of bone-charcoal and bone-black, tar (stinking oil, Dippel's animal oil) and gases are generated. The illuminating power of the latter has latterly attracted the attention of man- ufacturers. Seguin, in particular, has carried on the process on a large scale, making use of the gases. The material, for instance, the flesh of dead animals, contains 60 per cent. of water, which must be re- moved by drying before being placed in the retorts, and the latter should be kept at a cherry-red heat. The sulphur (a constituent of albumen, fibrine, &c.) is chiefly found in the gas as sulphuret of carbon, the nitrogen of the flesh as carbonate of ammonia. After being properly cooled, the gas is first passed through a solution of chloride of calcium, where carbonate of lime and sal-ammoniac are formed, and from thence through tubes containing lumps of sulphur, which condense the sulphuret of carbon to the fluid state, and dissolve in it. The latter would be converted in the flame into sulphurous acid and carbonic oxide. Retort-house.-The adjoining cut, Fig. 1926, represents a retort-house built of brick, for coal gas, upon the most simple construction, and well adapted for a town requiring 70,000 cubic feet of gas for the supply of each night in the winter season. Being without coke-cellar, the charges must be drawn into wrought-iron barrows, the contents wheeled into the open air and spread abroad to cool 1926. arche open arches a a reforts ground line The outside walls are calculated to give the greatest security with the least possible material. The piers a a are 18 inches thick at the base, projecting 41 inches (on the outside) from the brickwork filling the space between them. Half way up the walls there is a 41-inch offset, which leaves the thickness of the panels 14 inches below, and 9 inches above the offset. The roof is of wrought-iron; the ventilator is of wood. The retorts were set five in one oven, making forty retorts, which will allow two extra benches for repairs. In twenty-four hours, thirty working retorts will carbonize 240 bushels, or 180 cwt. of coal, and pro- duce 78,000 cubic feet of gas. In some places, where little gas is required in the summer season, one- half or even the entire number of retorts may be set three to one oven with economy. In the example, Fig. 1927, advantage was taken of sloping ground to form a coke-shed, which saved a considerable quantity of brickwork. The charge, as it was drawn, fell through the space in front of the retorts, and was carried by an inclined plane into the shed behind. This house is considerably larger than that described in the last example, and is furnished with a coal-store. It may perhaps be as well to state here, that coal from which gas has to be distilled should if possible be always kept under cover, because, when moisture is present, the hydrogen arising from Digitized by Google GAS. 749 the decomposition of water will deteriorate the quality of the gas. It is, therefore, a matter of econ- omy to construct a sufficient shed to preserve the coal in a dry state. The house contained 55 retorts, allowing two benches of five retorts each for repairs. The coal car- bonized by the remaining 45 retorts was 360 bushels, or 270 cwt. in twenty-four hours, producing 117,000 cubic feet of gas. The cost of these buildings will depend upon the price of brick, lime, labor, &c., and will vary in different localities. Chinineys.-The draught absolutely required for the proper combustion of the fuel beneath the retorts is little; indeed, that usually given to a common coke-oven would be sufficient. It is necessary to build a high chimney, however, to carry off the smoke, which, if not allowed to spread, would become a nuisance to the neighborhood. The height of a chimney does not decrease the quantity of smoke, but distributes it over a larger surface and causes less inconvenience. To obviate the excess of draught, it is advisable to 1927. make an opening into the shaft communicating with the ventilator external air. The dampers of the retort-flues might be used to adjust the draught, but this would be relying too much upon the workmen. It often happens, if there is no check, that during the night the heat of the ovens will be neglected, and suffered to fall below the proper tem- open arches perature; and then, to make up, the dampers are opened and the furnaces forced, to the deterioration of the retorts, the waste of fuel, and the production of inferior gas. When there is an air-opening into the shaft this cannot be done, and there will therefore be less danger from such carelessness. coal store With this precaution, the chimney may with advantage be built seventy feet high, even for a small number of retorts; but the height of the shaft must always be regu- lated by the description of property surrounding or in the vicinity of the works. Purifiers.-The gas, when it leaves the reforts, retains its impurities, and in this state is quite unfit for illumination. The impurities are bituminous vapor, ammoniacal gas, essential oil, and sulphuretted hydrogen; the processes adopted for removing these are partly mechanical and partly chemical. The first operation is the condensation of the volatile portions, which is effected at different places in differ- ent ways. The condensers generally adopted either consist of a series of pipes arranged in the manner of a distiller's worm, or of a number of chambers contained in a tank, and surrounded by cold water; at the lowest points of these vessels siphons are attached, sealed by dipping them into tar to a sufficient depth to prevent the gas from escaping, and through them the condensed bituminous and ammoniacal vapors pass away to the cistern constructed to receive them in the forms of tar and ammoniacal liquor. The same tank serves to contain both, the difference of their specific gravities keeping them separate; the ammoniacal liquor, being the 1928. lightest, swims on the surface of the tar. The tank is generally sunk below the surface of the ground; the respective heights of the two fluids are registered by floats and gages, and, when found necessary, are pumped out. If there be no sale for the tar, it is burned beneath the retorts, and the ammoniacal liquor is either evaporated in the cast-iron pans placed under the furnaces for that purpose, manufac- tured into the carbonate and muriate of ammonia, or used as manure. The simplest and best condenser is formed of a few upright pipes. Their number and length being regulated by the quantity of gas required to pass through them, ten feet run of pipe for every 10,000 feet of gas is ample; in height they may be equal to that of the wall of the retort-house, for the convenience of placing a tank on the roof to supply them with water. At the bottom of each bend is a siphon, similar to that represented in the annexed woodcut, by which the condensed vapors before mentioned are conveyed to separate vessels, the fluids passing away being of different values, (that from the last siphon is the most valuable.) These pipes must be kept wet in warm and dry weather by small streams of water running on to them from a tank placed at the top of the retort-house. The quick evaporation of this moisture will keep the pipes much colder than if they were completely immersed in water. If after condensation 'dry lime" (the term dry lime" is used in contradistinction to lime-water, the tirst being simply a hydrate, the latter holding lime in suspension with a large quantity of fluid) is used for purifying, the gas must pass through a wash-vessel, that a portion of sulphuretted hydrogen may be absorbed before the gas comes in contact with the lime in the purifiers; and to effect a final separation of the ossential oil, ammoniacal and carbonic acid gases, the essential oil is 80 intimately mixed that it may be detected in gas after it has passed through a pipe a mile long. (Its presence may be proved by shaking the gas with a little alcohol contained in a bottle; the oil will unite with the latter, forming a soapy liniment.) A wash-vessel is shown in Figs. 1929, 1930, and 1931 : A is the inlet pipe for the gas, which displaces a column of water about three inches high, and passes first through the openings 666 and at the sides of the wrought-iron box B, then through the continuous opening or slit C C, (which must be equal in area Digitized by Google 750 GAS. to that of the inlet and outlet pipes, viz. in this example, 50-265 square inches, the diameter of the pipes being eight inches,) and finally through the water. The use of the opening CC is to divide the gas into small portions and distribute it over a large surface. The more minutely it is divided, the better will the wash-vessel effect its object. D is the outlet-pipe. E is a siphon, for maintaining the water at a certain level; the part which enters the tank is con- ducted to the bottom, in order that the sediment may run off. The upper end of this dip-pipe is open, or it would otherwise form an actual siphon and drain the tank. F is a portion of a condenser, called by workmen a gridiron condenser," which, when separators are used, may be dispensed with. 1929. B B 1930. B B After this last process, the gas is in a state to come in contact with the dry or hydrate of lime to be purified, which is much the best for that purpose, as it is attended with less nuisance, less pressure, (which is also of importance,) and the sulphur which has united with the lime may be sublimed from it by putting the spent lime from the machine into burnt-out retorts kept at a heat just red by daylight, with the refuse coke-dust and cinders, for which there is no sale. The sulphur thus produced is a mar- ketable commodity. The larger the surface of dry lime to which the gas is exposed the better for if it be allowed to pass through the stratum with much velocity and in an undivided stream, it will work a passage in such a way that a great bulk will not be purified 1931. at all, for of course it will pass through that part where it meets with the least resistance from this not having been understood or attended to, many superintendents have aban- doned the use of dry-lime purifiers. The quantity of lime required for purifying coal-gas by the above process will depend upon the quality of both the lime and gas. One bushel of quick-lime will suffice in some places to purify 10,000 cubic feet of gas, while in others twice that quantity will hardly serve. By being slacked and reduced to a proper consistency for use, its bulk will be more than doubled ; two bushels of this hydrate will spread over a surface of 25 square feet, 21 inches deep, which is about the thickness found in practice to be the best. In Figs. 1932 and 1933 are represented an elevation and plan in section of one of a series of three " dry-lime" purifiers, through which the gas passes successively; in other words, they are " worked to- gether," and, though separate, may be considered as one machine. A is the inlet pipe from the wash-vessel, entering at the bottom of the first purifier. B is a plate of sheet-iron, about two feet square, placed over the mouth of the inlet-pipe, to separate the stream of gas in some degree, as well as to prevent any lime from falling into the pipe. CCC are the layers of hydrate of lime, spread upon screens formed of an outside frame, and a num- ber of round rods or wires about 5-16ths of an inch in diameter, stretched across them in one direction, to afford greater facility for clearing, with a small interstice between each. These screens are placed Digitized by Google GAS. 751 one over another, in three tiers, from six to eight inches asunder; each tier may consist of four screens, for the convenience of lifting them out and replacing them. D is the outlet-pipe leading to the second purifier. This arch-pipe is made of thin plate-iron, sealed at each end by a water-joint; because, when the lid has to be lifted, this arch-pipe must be removed, and any other kind of joint would be troublesome. E is the lid of the purifier, also sealed by a water-joint: e e are round 5-8ths rods, keyed at one end into the keep-ring k, and riveted to each corner of the lid at the other; a chain is hooked on to the ring k, and passed over a pulley to a balance-weight, by which, and the rods just mentioned, the lid is lifted. F F are blank flanches or bonnets, through which, when removed, the pipes are cleared from any de- posited impurity. 1932. F D G G are clamps, to keep the lid of the purifier in its place. A is the pipe leading from the wash-vessel into one partition of the hydraulic valve, which shall be described immediately. B is the pipe leading to the three purifiers CD E in action, and rising into the same partition of the valve as B. F is the pipe leading the purified gas back to another partition of the valve. 1933. E A D G G is the pipe conveying this gas to the meter and gasometers; the connection between the two last- named pipes is formed in the same way as that between the pipes A and B. It will be evident that the lime contained in the first purifier will be spent or saturated before the other two, and that con- tained in the third will be comparatively untouched. At the expiration of twenty-four hours CD and E must be shut off, by changing the divisions of the hydraulic valve to the situation shown by the dotted lines in the figure representing that valve, and turning the gas through HIK, having previously been put in readiness; at the instant of turning the valve the gas will pass through both sets of purifiers, all the communications being open. When the covers of CD and E are taken off, remove the screens from C, and place those from E in their stead. The lime from C is quite expended, and must be either heated to sublime the sulphur, or laid aside until it can meet with a sale as manure, or be otherwise disposed of. That from D may be spread for a time in the open air, (if there be room in the works,) and in a week or two it will be fit to use in the first purifier. After renewing the lime in the second and third purifiers, replace the covers, and they are again ready for action. The same operation is repeated when H I and K are spent. Fig. 1934 represents the hydraulic valve just mentioned. A is a cast or sheet iron tank, three feet diameter and two feet six inches deep, generally filled with tar to within six inches of the top. B is a light sheet-iron or tin gasometer-shaped vessel of less diameter, divided into three partitions by the plates CD and E, of less depth than the rim. F is the pipe from the wash-vessel or condenser. G is the pipe leading to the first set of purifiers. Digitized by Google 752 GAS. H is the outlet or return pipe from them. I is the pipe leading to the meter and gasometers. These pipes, in the present position of the valve, are all in action. F and G, being in the same partition, communicate with each other, as do H and I, for the same reason. When the purifiers have to be changed, the vessel B is lifted up, until the bottom of the par- tition, at C in the elevation, Fig. 1933, clears the pipes, the outside rim remaining immersed in the tar, (the stops S on the guide-rods prevent it from being lifted too high,) and turned partly round until it occupies the position shown by the dotted lines in the plan, Fig. 1934}. The length of each dot N through which the guide-rods M pass, mark this position and effectually prevent mistakes, for the vessel cannot be turned the wrong way. 1934. K and L are the pipes connected with the second set of purifiers thrown into action and into communication with F and I, when the vessel B is shifted to the position shown by the dotted lines in the plan. P is a wooden frame supporting the pulleys and bal- S S ance-weight Q to assist in lifting the vessel B, which, while Q in action, is kept from rising with the pressure of the gas by a bolt. P In preparing the lime for the purifiers, it ought to be beaten, well sifted, and water added, until, by compression B in the hand, the lime will just adhere; if any lumps re- main, their outside only will be acted upon; when broken, they will be found untouched in the inside; and although such lumps may be used again, it is always better to sys- temize the process in the first instance, and prevent even the smallest waste. Lime-water purifier.Fig. 1935 is an elevational section of a lime-machine, and Fig. 1936 a plan through a b in Fig. 1935. A is the inlet-pipe through which the gas passes into the chamber B, which is four feet diameter, jointed to the lid K G of the purifier, and supported upon two cast-iron beams C. On to the bottom flanch of this chamber a circular ring of thin wrought-iron plate is riveted, of such diameter that its outside rim will be within five inches of the tank of the purifier. D is a hoop supported from the tank by bolts dd, etc., having its upper edge level with the before- named plate, and its lower edge four or five inches below it. The space left between this hoop and the ring is three-eighths of an inch, through which the gas (after having overcome the pressure of the column of water contained in the tank, plus the pressure in the gasometers) will pass, and bubble up through the lime-water. E is an arm made to revolve on the spindle S: the parts e e of this arm continue through the aper- ture and over the ring, serving to keep the lime from settling or obstructing the passage of the gas. F is the outlet for the purified gas. G is a stuffing-box, through which the spindle S passes. H is a miter-wheel, connected to a water wheel or steam-engine for turning the spindle. 1935. 19341. F G K B Lime H E L b a N I I is a pipe, through which the lime-water is drawn off when it has become saturated with the im- purities of the gas. It will be observed, that by this contrivance the water can be completely drained off, by opening a slide-valve bolted to the flanch of the pipe K, without suffering the gas to escape along with it, because a column of water will remain in the tube I equal to the height of the bottom of the tank, measured from the inner radius of the curve of the tube, viz. twelve inches, which is always Digitized by Google GAS. 753 more than sufficient to overcome the pressure of the gas in the purifier when the valve on the inlet- pipe A is closed, which should be done before that at K is opened. L is a cylindrical vessel, open at the top, for filling the purifier; it also serves to show the quantity of water required; when the machine is at work the column contained in the vessel will be as much higher than that in the tank, by the pressure of gas in the gasometers, usually about three inches. The lime-water may be mixed in a cistern, and drawn off by a hose into any of the machines, care being taken to keep the mixture well agitated while passing. The proportions are one measure of paste-lime to three of water; that is, to every five bushels of paste-lime about 120 gallons of water must be added. The size of the lime-machines ought to be 80 regulated that they will contain suffi- cient lime-water to purify the quantity of gas made in twenty-four hours, without having occasion to fill them higher than the water-line shown in the engraving. Four lime-machines are necessary, two being in action and two out, alternately. When that ma- chine is spent through which the gas first passes, shut it off, and open a third, leaving the second to perform the duties of the first, and 80 on. The quantity of lime required for the complete purification of coal gas varies very much with the quality of the lime and the gas; that coal which produces the greatest volume of sulphuretted hydro- gen from the presence of iron pyrites will require the most lime. As the best means for arriving at a proper practical conclusion, we annex the quantities used at different gas-works in various places. 1936. R At the Imperial Gas-Works, London, one bushel of quicklime purifies on an average 10,000 cubic feet of gas, the price of lime being 7d per bushel. The lime is used both as a hydrate and in the fluid state, in the following proportions:-For the purification of 1,000,000 cubic feet, the produce in the winter season of twenty-four hours, eighty bushels mixed as dry lime," and twenty bushels mixed into a fluid this quantity performs its part thoroughly. At Cheltenham 11 bushel of quick-lime, reduced to the state of a hydrate, will purify 10,000 cubic feet of gas perfectly cost per bushel from 5d. to 6d. At Birmingham the purification of 1000 feet costs, in lime and labor, from 11d to 1td, but in reality not nearly so much, as the refuse is sold for two-thirds the original cost of the lime. Lias lime is used, and dry purifiers." With the dry-lime purifiers at Chester, 1 cwt. 2 qrs. is required to purify 10,000 cubic feet of gas. The Welsh lime is used, its price being 13s. 4d. per ton; therefore the purification of 10,000 feet will cost 12d without labor, which is about the average cost. In making the dry-lime purifiers, that they may present a sufficient surface to the gas which passes through them, an excess, rather than a smaller area, should be given. A bushel of lime, when reduced to the state of a hydrate, contains very nearly 4500 cubic inches: allowing that this quantity will purify 5000 cubic feet, it follows that 12.5 square feet of screen surface is required, the depth of the lime being 25 inches. For retorts calculated to produce 300,000 cubic feet of gas in twenty-four hours, the purifiers should present a surface of at least 750 square feet. If three machines are worked together, each containing five screens, their dimensions may be 8 feet 6 by 6 feet, and 3 feet deep, four bushels of hydrate of lime being spread on each screen. The surface presented by three machines like Fig. 1932, is 324 square feet they were erected for an establishment producing 130,000 cubic feet of gas in twenty-four hours. The work performed by a lime-water purifier is generally computed by its contents in gallons, and the head of water or pressure opposed to the passage of the gas through it. Taking the latter at a constant quantity of eight inches, the computation is easy. 4500 cubic inches of hydrate of lime, (which has been before stated is the quantity produced by reducing one bushel or 2150 cubic inches of quick- lime,) mixed with forty-eight gallons of water, will purify 10,000 cubic feet of gas, if properly applied. In the example at Fig. 1935, the lime machine contains 316 gallons, which will hold in solution thirteen 95 Digitized by Google 754 GAS. bushels of hydrate of lime, and purify 65,000 cubic feet of gas. Two of these machines will therefore do the same work as the three dry-lime purifiers before mentioned, viz. 130,000 cubic feet. Notwithstanding, however, that the quantity of lime required may be well known, it is necessary to test the gas in its progress through the various purifiers. A saturated solution of the acetate of lead in distilled water is an excellent test, detecting the presence of the minutest quantity of sulphuretted hydrogen, and more convenient than the carbonate, from its complete solubility. Test-papers may be printed in the following form :- Station and Date. Crude Gas. 1st Purifier. 2d Purifier. 3d Purifier. Lime machine having been charged - hours with - bushels of lime. Fill a bladder, furnished with a stop-cock, full of gas from the main, before it enters the purifiers, and also one from each separate purifier, and let the bladders be labelled; with a camel-hair pencil paint the square marked crude gas with the test solution, and force the gas from the proper bladder upon it while wet; the paper will immediately be turned black then paint the square marked 1st purifier, and force the gas into it, and proceed in like manner with the two others: the paper in the fourth square ought not to be discolored. The squares must not be moistened at once, because the first impure gas would in that case blacken them all. Lime for the purpose of purifying coal-gas should be free from foreign matter. That which slackens the quickest, and produces the greatest heat during the operation, is the best. When dissolved in diluted muriatic acid it should not effervesce, and should, when perfectly pure, leave no insoluble residue. Gas-meter.-Before passing the purified gas to the gasometers, it is necessary that it should be meas- ured and its quantity registered, which operations are effected by the meter. Of this machine there are two kinds,-the station-meter, for measuring the total products of the coal at the works before it is sup- plied to the mains; and the consumer's meter, for measuring small quantities as supplied to individuals. Station-meter.-Fig. 1937 is a front elevation in section. Fig. 1938 is a side elevation, also in sec- tion, of a station-meter of the capacity of 200 cubic feet, by which 300,000 cubic feet of gas may be measured and registered in twenty-four hours. 1937. 1938. F A n Water Line K G E D K H The principal part of the machine consists of a hollow drum of thin sheet-iron A A, revolving upon an axis a, and divided into compartments, 80 arranged, that, as the gas enters, it shall in revolving suc- cessively fill all the chambers, pass through them, and be discharged measured. The part of the drum which contains the gas is in the form of a concentric ring, one foot six inches broad, and six feet deep, and seven feet six inches in extreme diameter, which will be understood by reference to the engraving. The plates which form the sides are of the same outer diameter as the drum, viz. seven feet six inches, but are two feet nine inches broad they will therefore project within the smaller diameter, leaving the centre circle (through which the inlet-pipe K passes) two feet in diameter. The surface of the water contained in the drum and outside tank of the meter, is four inches above the upper circumference of this centre circle, when the drum is in its place; 80 that the cominu- nication between the outside and inside of the drum is cut off by a head of water of that height, and continues to be so in every part of the revolution. It is evident, therefore, that the gas must enter any chamber having its inner hood above the surface of the water. BCD E represent the inner hoods, and the direction of the gas from the inlet-pipe is shown by the Digitized by Google GAS. 755 small arrow at B. As the chamber fills with gas, it displaces the water, and causes the drum to re- volve. Before B dips into the water, the hood C rises above the surface, and opens a communication for the gas into its chamber; and 80 on with E, when it will have completed one revolution and measured 200 cubic feet. The same action that allows the free passage of the gas into the chambers causes it to be expelled from them through the outer hoods FGHL in the direction of the arrow at F: each of these outer hoods is sealed alternately in the same manner as the inner hoods, and opened for the passage of the gas from them, by one constantly being above the water-line. The direction in which the drum revolves is marked by the arrow over the top of the case. The bevels of the division-plates dd are arranged so that they will enter the water without effort. The axis a a on which the drum revolves is supported on friction rollers; on the front end of this axis a spur-wheel S is fixed, working into another wheel T, having half the number of teeth; at every half revolution of the drum it will therefore make an entire revolution its spindle passes through a stuffing- box, and is furnished at the opposite end with another wheel V, which marks 100 feet on the index. From a pinion on the spindle of this last wheel another wheel is worked, having ten times the number of teeth on the pinion, which will therefore mark thousands. This last wheel is again furnished with a pinion and works into a third wheel, which will mark tens of thousands, and so on; the quantities marked on the dials increasing in a tenfold ratio up to hundreds of millions, or higher if thought necessary. The entire train of wheel-work is shown in Fig. 1939, where a is the first spur-wheel, working upon the main axis; b the second wheel, 1939. both being inside the meter-case c is the wheel on the opposite end of the shaft of b, which projects through a stuffing-box on the case, in order to communicate motion to the train of wheel-work, which must of course be on the outside of the meter-case d is the b wheel driving the hand which marks hundreds on the index, and having 100 teeth, (c has likewise the same number of teeth ;) e is the d pinion on the wheel d, having ten teeth; f is the wheel driving the h hand which marks thousands on the index, having 100 teeth, and e driven by the pinion e; g is the pinion of the wheel f driving h, which marks tens of thousands on the index: and in like manner any quan- tity may be registered. If it be required to register units, (and in smaller meters it is useful,) the first wheel d is made to drive a pinion p. having ten teeth, to the spindle of which the hand marking units is attached. The consumer's meter is constructed upon precisely the same principle as that shown in Fig. 1937 but the partitions of the drum are differently arranged, and placed in such a manner, that, as they reach the water, the surface presented shall be as small as possible. or the resistance offered shall be so gradual that the stream of gas flowing through the machine is uniform and constant. This is necessary in a meter from which any number of lamps are immediately supplied because the most minute diminution or increase of the volume of gas flowing to them would cause a variation in the light, and produce an oscillation. In a station-meter the intervention of the gasometer will remedy this defect. A variation in the arrangement of the drum, therefore, is a matter of necessity. 1940. As in the former case, the outer circumference or rim of the drum is divided into four partitions, separated from each other by partition-plates, not running across directly at right angles with the face, but bevelling from the plane of the water, meeting the wrap of the opposite hood. The sides of these partitions are also bevelled; the space left between each plate forming, on one side of the drum, the Digitized by Google 756 GAS. inlet, and on the other side the outlet for the gas: the area of the latter being greater than the inlet, to insure perfect freedom of action. The dotted lines show the wrap of the hoods. Fig. 1940 represents a view of the front or inlet side of the drum, with the convex cover removed. The outlets will present the same appearance, but of course reversed. By referring to Figs. 1941 and 1942, the remaining parts will be 1941. 1942. 62 P a water line 2 UNITED 10 side view inlet. c d 6 200 understood. The direction of the gas is marked by arrows. The box a, in which the inlet-valve is con- tained, is soldered tight, having no communication with the rest of the case, except through the valve, the position of which is shown by the arrows; b is the inlet-pipe projecting above the water-line, con- veying the gas into the meter by the bent arm c, rising above the water between the convex cover and the inlet-hoods; d is a float attached to the inlet-valve, adjusted so that when the water falls below the centre opening, the valve will close, and the gas cease to enter the meter. Motion is communicated to the train of wheel-work behind the index from a spiral worm w, fixed on to the axis of the drum, working into a wheel, the spindle of which passes through the tube t, sealed by dipping under the water contained in the case. The following are the principal dimensions of consumer's meters:- Number of lights 5 10 20 30 50 80 100 150 200 400 800 Diameter of drums (inches) 121 141 171 191 211 25 271 33 33 44 60 Depth of drums " 5 6} 91 10] 11} 121 13} 201 241 301 401 Diameter of water circle " 34 31 41 5 5 61 71 9 10 15 21 Centre opening " 11 2 21 3 31 4 5 6 7 10 15 Hollow cover projects " t 1 1 g 11 1] 11 11 21 31 31 41 Depth of inner hoods " t I I § - 1 1 11 2 8 5 Depth of outlet " t 1 11 1 g 11 11 11 2 21 4 51 Capacity in cubic feet " 25 50 100 1:50 200 3:00 400 800 10-00 20-00 50.00 Gasometers.-The simplest and most general kind, consist of an iron vessel, open at the bottom, and inverted into a tank of water below the surface of the ground, having perfect freedom to rise and fall, and guided by upright rods fixed at several points in the circumference. The diameters and numbers of the vessels will vary according to the magnitude of the works to which they are attached, and the space to be occupied by them. If the works are situated in a town, where ground is too valuable to allow an increased extent, Telescope Gasometers" are used, which consist of three iron tanks, the one within the other, and working like the slides of a telescope. These require counterpoises, which the simpler form do not, and are more expensive; they work with equal precision, but are not used save in cases of necessity. Fig. 1943 represents the half section of a simple gasometer, capable of containing 150,000 cubic feet, Digitized by Google GAS. 757 the diameter being eighty-seven feet six inches, and height twenty-five feet. The sides A A are made of No. 16 iron-plate, (Birmingham wire-gage,) weighing 21 pounds to the square foot, riveted together; the top B of plate weighing about three pounds to the square foot, or No. 14 gage. CC, etc., are rings of three-inch T iron, placed five feet asunder, and riveted strongly to the sides; the rivets ought not to be more than three inches apart. The top and sides are secured together by three-inch angle-iron, rolled to fit the curve. Values Inlet Esit $ 1943. stayer dd are rings of bar-iron, about half an inch thick and three inches deep, fastened to the top by clips, which are riveted; these rings are placed about six feet apart, and strengthened further by diagonal bars, from one to another, breaking-joint. E are stays formed of wrought-iron pipe, about 11 inch diameter, fixed in the situations represented, their ends being bolted to the T iron at the sides, and the rings on the top. G are vertical rods, fixed at their upper and lower ends to the brickwork of the tank, and being passed through eyes fast to the bottom of the side of the gasometer, serve to guide the vessel in its rise: their positions are between the standards S, on which are also guide-rods acting in like manner. The eyes serve as stops to prevent the vessel rising out of the water. The standards S, eight in number, are each formed of three cast-iron frames, six feet broad at their bases, of the same height as the gasometer, and jointed together in the form of a T on the plan; they are secured to the stone plinth by dovetailed lock-nuts, keyed and leaded. H is the wooden curb, which ought always to be attached to a gasometer; its use is to regulate the Digitized by Google 758 GAS. flow of gas from one gasometer to another. While immersed in the water of the tank it acts as a float, and, to some extent, buoys up the vessel; when the gasometer has risen to its full height, it acts as a weight, being partly out of the water, thus causing the gas to flow into another gasometer not yet full, and which, having its curb completely immersed, is under less pressure. I is the inlet-pipe, of the same diameter as that leading from the retorts, viz. eight inches. Its mouth above the water-line should be rather bigher than the edge of the tank. K is the outlet-pipe, twelve inches diameter, entering the gasometer, under the same circumstances as the inlet-pipe. L are receivers in which the tar or water collects from the mains, being pumped out by a small hand- pump, of which a and b represent the suction pipes. P, masonry or brickwork. A gasometer 100 feet diameter and 39 feet high at the sides, containing 300,000 cubic feet, weighs as follows:- Tons. Cwt. Lbs. 30 Pieces of bottom curb 6 16 30 8 Bags of rivets 0 9 94 60 Plates and rivets for bottom curb 0 1 32 24 Bottom eyes 0 8 24 100 Small sheets, 2 plates each, for side plates 2 8 17 300 Large ditto, 6 plates each, ditto 19 6 7 30 Short pieces of angle-iron bottom curb 0 3 o 24 Vertical stays 10 16 56 60 Pieces of angle-iron top curb 2 13 54 350 Short bracket irons, for crown framing 1 9 45 4 Bags of rivets 0 5 o 1 Centre crown plate 0 9 101 1 Cast-iron cup and ring 0 18 62 1 Centre pipe 0 10 28 6 Bags of rivets 0 9 86 1 Ditto 1-bolts 0 3 90 150 1-inch bolts for top curb 0 5 1 50 Upright rods 2 11 103 50 Ditto, ditto, 6 feet long 1 2 56 50 Ditto, ditto, 3 feet 6 inches long 0 9 7 150 Long braces 3 4 37 196 Crown plates 17 5 71 8 Diagonal stays, at centre pipe 0 2 64 48 Small plates, at bottom and top curb o 4 4 1 Man-hole, cover, ring, and bolts 0 0 52 130 Small plates for joints and bolts 0 3 15 100 1-inch bolts, and 100 t ditto 0 8 64 100 f-bolts 0 0 60 50 Principal bars for roof 11 17 51 50 Secondary bars 3 16 58 50 Tie-rods for principal 4 17 86 1 Bag of bolts 0 1 17 200 Diagonal stays for roof 1 11 110 72 Cast-iron brackets for vertical stays 0 15 72 24 Timbers for middle, curb, and king-post 1 0 64 48 Tie-rods and bolts for ditto 0 12 24 12 Cast-iron carriages, rollers, and bolts, complete 2 6 56 4 Pigs of lead for ditto 0 3 0 2 Extra man-holes, plates and rings, over 18-inch pipes 0 0 100 Tons 100 6 101 24 Brackets for guide-rods 2 2 16 24 Lock-nuts for bottom of guide-rods 0 5 16 24 Guide-rods, each 6, 3, 20 9 3 8 12 Sets of tripods, each 8, 18, 3, 1 104 5 12 528 1-inch bolts for ditto 0 18 96 Tons 116 14 36 A gasometer 36 feet diameter and 12 feet deep contains 12,200 cubic feet, and weighs as follows:- Tons. Cwt. Lbs. Ironwork of gasometer, sides of No. 18 and top of No. 17 wire-gage 2 17 57 Wood-curb and diagonals 1 0 97 Stays and bolts 2 5 7 Sundry bolts, man-hole, etc. 0 2 28 Tons B 5 67 8 Sets of tripods 4 19 28 3 Guide-rods 0 3 21 Tons 5 2 49 Digitized by Google GAS. 759 It is hardly necessary to observe, that the cost of brick tanks will never be twice alike. If the ground in which the tank of the gasometer represented in the engraving was built, had been less favor- able, the thickness of the retaining wall must have been greatly increased, and other expenses incurred, perhaps amounting to one-half more than the cost. The " working pressure" of a gasometer will depend upon the area of water surface, and the weight of the vessel itself. For 1944. example, in the gasometer quoted as 100 feet diameter, the area of water surface is 7854 feet, a stratum of which 5 150 the deep will be equal in weight to the gasometer, viz. 100 tons 5 cwts. Its working pressure will therefore be equal to a column of water 5 the of an inch high. The governor.-The governor is a machine for regulating and equalizing the flow of gas from the gasometers to the street-mains, and is much more perfect in its action than any slide-valve applied for that purpose requiring attendance. Fig. 1944 is an elevation, in section, and a plan of a governor capable of equalizing the flow of 300,000 cubic feet of gas in twenty-four hours. A A is a cast-iron tank containing water, five feet four inches diameter, and four feet six inches deep, in which the regulating vessel B B floats. C is a cone of cast-iron, turned true in the lathe, and suspended by an eye-bolt to the top of the floating vessel. D is the inlet-pipe, having a plate d on the top, furnished with an aperture, bored out to fit the diameter of the cone at the base, and which, if raised to that height, will completely shut off the gas from entering the vessel. E is the outlet-pipe, its diameter being regulated by the dis- tance to which it has to convey the gas to the equilibrium-cylinder D E of the street-mains. The floating vessel B, when immersed in water, of course loses a portion of its weight, equal to that of the water which it dis- places; and the density of gas contained in it will vary as the immersion. By making the chain F of a proper weight, it may be made to answer the purpose of a regulator of the pressure. Let it be supposed, for example, that the vessel weighs 1000 lbs., and loses 100 lbs. of that weight when immersed in the water, and that a portion of the chain, equal in length to the height which the vessel risea, shall weigh 50 lbs., and the counterbalance weigh 950 lbs. lbs. Then, when the vessel is immersed, its effective weight is 900 To which must be added the portion of chain now acting, as increasing the weight of the vessel 50 The sum corresponds with the actual weight of the counterbalance 950 lbs. Again, let the vessel be elevated out of the water, its actual and effective weight then is 1000 To balance which is opposed the counterpoise 950 And the portion of the chain now removed to the other side of the pulley to counter- poise, and acting with it 50 The sum corresponds with the actual weight of the vessel 1000 The effects of the vessel and counterpoise being thus opposed to each other, the pressure of the gas contained therein is equalized. By adding or removing the weight of the counterbalance, an increase or decrease of pressure may be effected. The action of the governor is as follows:-The outlet-pipe is connected with the mains, and the inlet-pipe with the gasometer supplying gas into the machine: it will be evident, that if the density of the gas in the inlet-pipe becomes by any means increased, a greater quantity of gas must pass between the sides of the adjusting cone and the aperture in the plate d, the consequence of which will be that the floating vessel will rise, and therefore contract the area of the opening in d; and if, on the contrary, the gas in the inlet-pipe decreases in density, the vessel will descend; 80 that whatever density the gas may at any time assume in the gasometers or mains, its pressure in the floating vessel will remain uni- form, and consequently the velocity of the gas passing into the mains will be regular; for when the aperture of the plate d would admit more gas than necessary for the supply to the mains, the floating vessel rises and diminishes the area of the inlet-pipe; and when, on the contrary, the inlet does not allow a sufficient quantity of gas to come from the gasometers, the gas passes out of the governor into Digitized by Google 760 GAS. the mains, and in 80 doing the vessel déscends, and increases the area of the inlet-pipe, to admit the requisite gas into the mains. This action is not influenced by any circumstances connected with pressure or velocity, but is constant and uniform, insuring at all times a proper and sufficient discharge. Pressure indicator.-If a governor be not used, it is advisable to have a Pressure Indicator attached to the main or mains that leave the works, to serve as a check upon the conduct of the workmen, whose duty it is to regulate the pressure of gas in them according to the demand at certain hours of the night. It is thus constructed:-A small gasometer about twelve inches diameter is made to move in a tank of water in such a manner that it shall rise or fall according to the pressure in the mains, with which it is connected by a small pipe; a guide-rod, furnished on the top with a pencil, marks the exact amount of pressure upon a sheet of paper coiled round a cylinder. This cylinder is moved round once in twelve hours by a time-piece. It is evident, therefore, that if the paper be divided by horizontal lines corresponding to the rise or fall of the gasometer by every tenth 1945. of an inch increase or decrease of pressure; and if it be divided by vertical lines corresponding to the revolutions of the time-piece in twelve hours, it will effect the object required. The gasometer must be formed with an air-vessel inside, so that when it is totally immersed it shall be in exact equilibrium with the ex- ternal atmosphere; and when risen to its full height it shall have a pressure equal to that required to force the gas through the mains; say the height to which the gasometer rises is equal to ten inches, and the pressure required is three inches; then if the paper be divided into thirty parts by horizontal lines, each division will indicate one-tenth of an inch. Pressure-gages, as the name implies, are instruments by which the velocity with which the gas flows into the mains is ascertained. They are made of glass tubes partially filled with colored water, and furnished with graduated scales divided into inches and tenths from a point in the centre of the scale marked zero. When no gas is passing into the main to which one of these instruments is attached, the columns of water contained in the tubes are in equilibrium with B the external air, and stand at 0. When the gas is admitted, the equilibrium is destroyed; the gas depresses one column and raises the other, the total varia- tion being the amount of pressure. Fig. 1945 shows a section of a water-valve: it is formed of an air-tight cyl- inder A A, containing a portion of tar or water. B is the inlet-pipe, which com- municates with the gasometer; C is the outlet-pipe, which conveys the gas to the mains; DD is an inverted cup, ten inches deep, furnished with a rod passing through a stuffing-box, by which it is raised or lowered. When the cup is in the situation shown in the figure, it is evident that the communication between the outlet and inlet pipes is shut off by the pressure of a column of water ten inches high. When the cup is raised above the mouth of the outlet-pipe by the rack and pinion, a free passage is left for the gas. This description of valve may be fixed with advantage between the gas-holders and the mains, or between any system of lime-water purifiers. Mains.-The term main is applied to all cast-iron conduit-pipes that serve to convey gas from the works to the place or district to be lighted, and especially applied to those pipes from which smaller ramifications branch. The diameters of the mains vary from 11 to 15 or 18 inches, according to the quantity of gas required to be supplied, and the distance it has to flow. The 11-inch mains are cast four feet six inches long, the two and three-inch mains about six feet long, and all the other sizes nine feet, with a socket at one end, and a plain bead at the other. 1946. 1947. 1948. Sockets.-Figs. 1946, 1947, and 1948, represent the sections of sockets of different sized pipes to a scale of 1} inch to one foot. Fig. 1948 is that of mains from nine to fifteen and eighteen inches diameter. The usual thick- ness of metal is shown by the hatched lines, and is proved to be sufficient. The depth of these sockets is 4} inches. Fig. 1947 is a section of the sockets of mains from four to eight inches diameter ; their depth four inches. Fig. 1946 is the thickness of those of a smaller diameter, three inches deep. The thickness of the main pipes ought to be as follows :- 11 inch diameter t inch thick. 9 inches diameter inch thick. 2 do. do. " " 10 do. do. " full. 3 do. do. " full. 12 do. do. " " 4 do. do. " " 13 do. do. " " 5 do. do. " " 14 do. do. " " 6 do. do. " full. 15 do. do. " " 8 do. do. " " 18 do. do. " " The annular space left between the bead end of one, and socket of the next pipe, should be about half an inch in the large mains, and not less than three-eighths in the small. Joints.-To make the joints, spun yarn is driven between the pipes to within 21 inches of the lip of the socket, and a good fitting of the two pipes being effected, melted lead is poured into the remaining cavity, which, when set, is caulked or hammered in with a blunt square-pointed chisel. Digitized by Google GAS. 761 In order to guard against the danger of water remaining that enters from the external surface into the pipes, and the deposition of other condensed matter, a reservoir should always be placed at the lowest point, where two or more descending mains meet and form an angle, to receive the water, etc., that may happen to collect at this angular point, an accumulation of which would obstruct the passage of the gas through the mains. These receivers ought to be at least twice the diameter of the mains between which they are interposed, and four times that diameter in depth. These receivers afford the best indication of the sound or leaky state of the system of mains. In all instances where the pipes are perfectly sound, observation has shown that half a mile of gas-mains, three inches in diameter, does not deposit more than a quart of condensed vapor or water in the year; on the other hand, when the mains are leaky, the water of the reservoir requires to be pumped out, particularly in wet weather, as frequently as once a fortnight. The loss of gas by such leakage is much greater than is generally imagined. In order to keep the common air out of the faulty mains, a constant influx of gas is often necessary this is of course so much gas lost to the economy of the establishment. Distribution of gas through mains.-The velocities of different gases under the same pressure will be to one another, inversely, as the square roots of their specific gravities; therefore a heavy gas will be discharged through the same opening with a less velocity than, that due to a lighter gas. For ex- ample, if coal gas of the specific gravity 420, and with a pressure of five-tenths of an inch, flows through a circular orifice one-fourth of an inch in diameter, at the rate of eighty cubic feet per hour, gas having the specific gravity 400 will flow through the same opening at the rate of 819 per hour, pressure ro- maining the same. For by inverse proportion, As 400 = 20-000 Is to 80, the quantity discharged of the heavy gas, So is 420 = 20-493 To 819, the quantity of lighter gas discharged. The discharges of the same gas through different open- ings and under the same pressure, are proportional to the areas of the orifices in circular inches, or to the Diameter Quantities of gas discharged in cuble squares of their diameters. Allowing an excess in the of orifice in feet per hour. Pressure = 5-10ths. inches and larger openings for the difference of the friction, the parts. By experiment. By calculation. results of the annexed experiments will agree very nearly with this law. 25 80 To obtain the velocities of the same gas from any 50 321 320 other opening, say, 75 723 720 As the square of given opening, 1:00 1287 1280 Is to the given quantity discharged, 1.125 1625 1620 So is the required opening 1.25 2010 2000 To the required quantity discharged. 150 2885 2880 The quantities of the same gas discharged in equal 600 46150 46080 times by a horizontal pipe under the same pressure and for different lengths, are to one another in the inverse ratio of the square roots of the lengths. Hence, when we know the quantity of gas discharged from a given length of pipe, we may find the quantity discharged by any other length with any pressure, and of gas of any specific gravity. Example of the foregoing rule.-It is required to find the number of cubic feet that will be discharged from a horizontal pipe six inches diameter and 1760 yards long, the specific gravity of the gas being -420, and the pressure, equal to five-tenths of an inch perpendicular head of water. We know by experiment that 44,280 cubic feet will be discharged by a six-inch pipe 3.46 yards long; therefore, by inverse proportion, say, As 1760 = 41-952, the required length, Is to 44,280, the known quantity discharged, So is 3:46 = 1·860, the known length, To 1963-2, the required quantity discharged. We therefore find that the loss by friction in a pipe a mile long is 44,116'8, the initial velocity being equal to 46,080 by calculation. A horizontal main, 16 inches diameter and 1760 yards long, is laid from the works to the equilibrium cylinder: it is required to know how many cubic feet of gas of the specific gravity 390 will be dis- charged with a pressure equal to a head of water of 6-10ths of an inch. We have found by the last example that a six-inch pipe, one mile long, with a pressure of 5-10ths of an inch, will deliver 1963 cubic feet of gas having the specific gravity 420, in one hour. Then say, as 36, the square of the diameter of the six-inch pipe, is to 1963, the quantity of gas delivered, 80 is 256, the square of the diameter of the sixteen-inch pipe, to 13,959, the required quantity delivered by a sixteen-inch, one mile long. For the difference of specific gravity, say, As 390 = 197, the specific gravity of the lighter gas, is to 13,959, the quantity delivered of the specific gravity 420, 80 is 420 = 204, the specific gravity of the heavy gas, to 14,455 = the quantity delivered of the specific gravity 390. And for the difference of pressure, say, As .50 = 707, the first pressure, is to 14,455, the quantity discharged through a sixteen-inch pipe by that pressure, so is ·Bo = 774, the required pressure, to 15,824, the required quantity, of specific gravity 390 discharged from a sixteen-inch pipe, with a pressure equal to 6-10ths of an inch head of water. The actual quantity discharged is about 16,500 cubic feet. 96 Digitized by Google 762 GAS. An accurate experiment was made by Mr. Clegg, at the Pancras Station, on the quantity of gas dis- charged through a four-inch main, six miles in length, with a pressure of three inches perpendicular head of water. The specific gravity of the gas was not taken until some hours after the experiment, when it was found to be 398. A new four-inch main had to be laid for the purpose of supplying parts of the parish of St. Maryle- bone with gas; after completing a circle of nearly six miles in circumference, it terminated within the distance of a short street from the point at which it left the works. By completing this distance, the two ends of the pipe were brought together on exactly the same level. There were no short bends, and all the services and branches were closed. The pipe measured exactly six miles in length. The leakage was ascertained in the first place by shutting the valve adapted to the returned end, and ob- serving the gasometer; it was found to be thirty-three cubic feet at the end of one hour, and was allowed for. At the commencement of another hour the valve was opened and free passage given to the gas, which was allowed to escape: by observing the gasometer at the end of this hour, it was found that 885 cubic feet had been expended; deducting thirty-three cubic feet from this for the leakage, 852 will remain for the actual quantity discharged at the end of six miles. This experiment is valua- ble to the practical man, both for the unquestionable data it supplies, and for its close approximation to the rules here laid down. The quantity discharged by calculation is 873 cubic feet By experiment 852 " Difference 21 TABLES of the different quantities of coal gas of the specific gravity 420, delivered in one hour, from horizontal pipes of different diameters and lengths, and under different pressures. QUANTITIES DELIVERED BY A TWO-INCH MAIN IN CUBIC FEET. Length of Pressure in inches and parts. Perpendicular head of water. pipe in yards. 0.50 0.75 100 1.50 2-00 300 10 2896 3558 4185 4923 5792 6950 15 2364 2904 3331 4089 4728 5768 20 2047 2507 2886 3541 4094 4994 25 1830 2241 2580 3165 3660 4465 30 1673 2049 2368 2894 3346 4082 40 1445 1770 2037 2490 2890 3525 50 1294 1585 1824 2238 2588 3157 100 915 1121 1290 1582 1830 2232 150 748 916 1054 1304 1496 1825 200 647 792 912 1119 1294 1578 250 579 709 816 1010 1158 1412 800 522 639 736 903 1044 1273 400 457 559 644 790 914 1115 500 409 500 576 707 818 997 QUANTITIES DELIVERED BY A SIX-INCH MAIN IN CUBIC FEET. Pressure in inches and parts. Perpendicular head of water. Length of pipe in yards. 0.50 0.75 1-00 150 200 3-00 100 8242 10095 11657 14276 16484 20190 150 6730 8242 9517 11657 13460 16484 200 5828 7138 8242 10095 11657 14276 300 4759 5828 6730 8242 9517 11657 440 3929 4813 5557 6806 7858 9626 500 3686 4515 5213 6384 7372 9030 600 3365 4121 4759 5828 6730 8242 700 3115 3816 4406 5396 6230 7632 880 2778 3403 3929 4813 5557 6807 900 2747 3365 3886 4759 5494 6730 1000 2606 3192 3686 4515 5213 6384 1760 1965 2406 2778 3403 3929 4813 2640 1604 1965 2269 2778 3208 3929 3520 1389 1702 1965 2406 2778 3403 5280 1134 1389 1604 1965 2269 2778 7040 982 1149 1389 1702 1965 2298 8800 879 1076 1287 1521 1758 2152 10000 824 1010 1166 1428 1648 2019 Digitized by Google GAS. 763 QUANTITIES DELIVERED BY A TWELVE-INCH MAIN IN CUBIC FEET. Pressure in inches and parts. Perpendicular head of water. Length of pipe in yards. 0.50 0.75 100 1.50 200 3.00 100 32968 40380 46628 57104 65936 80760 150 26920 32968 38068 46628 53840 65936 200 23312 28552 32968 40380 46628 57104 300 19036 23312 26920 32968 38068 46628 440 15716 19252 22228 27224 31432 38504 500 14744 18060 20848 25536 29488 36120 600 18460 16484 19036 23312 26920 32968 700 12460 15264 17624 21584 24920 30528 880 11112 13612 15716 19252 22228 27224 900 10908 13460 15544 19036 21816 26920 1000 10424 12768 14744 18060 20848 25536 1760 7860 9624 11112 13612 15716 19252 2640 6416 7860 9076 11112 12832 15716 3520 5556 6808 7860 9624 11112 13612 5280 4536 5556 6416 7860 9076 11112 7040 3928 4596 5556 6808 7860 9624 8800 3516 4304 5148 6084 7032 8608 10000 3297 4038 4663 5710 6594 8076 In the foregoing Tables we have considered the mains as horizontal. In mains rising above the horizontal line the quantity of gas delivered by them will be greater, and in mains falling below that line it will be less. In the first instance, the resistance offered to the flow of gas by the atmospheric pressure will be lessened, and in the latter it will be increased, and will cause a difference in the necessary pressure for the discharge of the gas of one-tenth of an inch head of water for every ten feet rise or fall. The effect of bends and angles in the main, upon the quantity of gas delivered, is essentially a matter of experiment: they may be considered as 80 many mechanical obstructions. The results of the fol- lowing experiments will show, in some measure, what allowance to make for quadrant, semicircular, and right-angle bends. A two-inch pipe thirty feet long, perfectly horizontal and free from obstruc- tions, delivered 2898 cubic feet of gas in one hour, with a pressure of five-tenths of an inch head of water. The same pipe, disconnected in the middle of its length, and returned by a semicircular bend to the point at which it left the gasometer, delivered 2754 cubic feet in the same time, being a differ- ence of nearly one-twentieth in the whole quantity. The semicircular bend was removed and a quad- rant bend substituted, making the two fifteen-foot lengths of pipe form a right angle with one another; the quantity delivered was 2834 cubic feet in the hour, a difference of about 1-45th of the first dis- charge. Again, the pipes were disconnected, and a right-angle bend substituted for the quadrant; the quantity delivered in the hour was 2824, a difference of 1-39th of the first discharge. Services are wrought-iron or pewter tubes, for the purpose of supplying the interior of houses with gas from the mains; every small tube on to which a burner is fixed, whether for public or private use, is called a service. The arrangement of these tubes, and their adaptation to the interior of private dwellings, shops, &c., is a separate branch of business, and fitters" are almost universally employed, who work independently of the gas companies. In order that the pipes for conveying the gas from the mains and distributing it through the houses or other buildings to be lighted, may in the first place be neither unnecessarily large or too small, the following rule is given: One gas-lamp consuming four cubic feet in an hour, if situated forty feet from the main, requires a service not less than a quarter of an inch in the bore. 2 lamps, 40 feet from the main, require a three-eighth service. 8 " 30 44 " a three-eighth tube. 4 " 40 " " a half-inch service. 6 " 50 " = a five-eighth service. 10 " 100 " a a three-quarter service. 15 " 130 " " an inch service. 20 " 150 " " a service 11 in diameter. 25 " 180 " " a 11 service. 30 " 200 " " a service 11 in diameter. It is desirable that all bends should be circular. No branch ought to proceed from a service of a quarter of an inch in the bore, and no more than two from a three-eighth service. All pipes, before they are fixed, must be proved by condensing air into them by means of a hand-syringe while under water; the leak will be easily detected by the air-bubbles which rise through the water. For con- ducting the gas from the street-mains into the interior of a house, or any building to be lighted, a wrought-iron pipe of sufficient diameter is tapped into the main, and carried in a straight line to the nearest wall of that building, through which it must pass; and on the inside be furnished with a good stop-cock. If all the fittings rise from the main no siphon is necessary, but if any part of them fall Digitized by Google 764 GAS. below the main a small receiver must be attached to the lowest point, fitted with a screw-plug at the bottom, 80 that any moisture may be drawn off. The pipes which convey the gas to the burners must be in as direct a line as possible, to avoid unnecessary expense and obstructions. The union joints used to connect two services together must be of the same diameter as the pipes, and soldered firmly on to them. The excessive cost and defective construction of fittings have in numerous instances tended more than any thing besides to engender prejudices against gas, and more particularly in private houses. Gas-fittings ought to be made of the best materials; they should be judiciously arranged, and fixed by skilful workmen. The choice of a situation for the main cock is of importance; it should be placed as near as possible to the inside of the wall through which the gas is admitted from the street-main, and where it will at all times be accessible to the inmates of the house. The key or spanner by which it is turned should always be attached, and the nick which indicates whether it is open or shut should be distinctly marked. The cock should be literally a stop-cock. Throughout their various ramifications the pipes should have a slight inclination towards the point where the main cock is fixed, and thence to the street-main; this is to allow the water, which is occa- sionally deposited in them, to drain off without interrupting the passage of the gas. In fittings which are not thus arranged the water accumulates in some curvature of the pipes, and occasions an oscilla- tion, or, as it is very commonly called, jumping of the lights. The intensity of light is ascertained by an instrument called the Photometer, invented by Count Rumford; it is constructed on the principle that the power of a burning body to illuminate any defined space is directly as the intensity of the light, and inversely as the square of the distance. If two un- equal lights shine on the same surface at equal obliquities, and an opake body be interposed between each of them and the illuminated surface, the two shadows must differ in intensity and blackness, for the shadows formed by intercepting the greater light will be illuminated by the lesser light only and inversely, the other shadow will be illuminated by the greater light-that is, the stronger light will be attended with the deeper shadow but it is easy, by removing the stronger light to a greater distance, to render the shadow which it produces not deeper than that of the smaller, or of precisely the same intensity; this equalization being effected, the quantity of light emitted by each lamp or candle will be as the square of the distance of the burning body from the illuminated surface. By reference to the diagram, Fig. 1949, the instrument will be rendered perfectly intelligible. A is a wooden box, painted black inside, except at the back D B, which is painted white, (or a sheet of fine white paper © fastened to it may be preferable;) C is the substance inter- cepting the light of the gas-lamp D, and throwing a shadow on the paper. C is formed of a strip of thin brass, about a quarter of an inch broad, movable round its axis on a pin at the top and bottom, so that its shadow may be adjusted to correspond in breadth to that cast by the lamp; for the candle being nearer, 1949. if its intercepting wire were of the same diameter as that of the lamp, the shadow would of course be much broader, and tend to deceive the operator. D is the lamp placed 5 feet from the wire C;. E is the candle-socket sliding upon a rod, which is marked according to the number of candles the gas-lamp is equal to. If, when the candle is placed at 1, the two shadows are equal, the lamp only gives a light equal to one candle; if at 2, the lamp is equal to 4 candles; and if at 4, the lamp is equal to 16 candles. A simple rule-of-three statement will give the comparative quantities of light, the candle being at any distance. The burner remaining 5 feet from the interposed wire, supposing the candle to be 1 5-10ths of a foot from its wire, The square of 1.5 = 2-25. The square of 5·0 = 2500. Then as 2.25, the square of the candle's distance, is to 10, 80 is 25'00, the square of the lamp's distance, to 11·11, the number of candles the gas-lamp is equal to. Gas-exhauster.-Much attention has been directed to discover an effectual method of relieving the retorts from the pressure occasioned by the necessary obstructions with which the gas has to contend in the purifying process, and in its subsequent passage to the gas-holder. The pressure required to surmount these resistances, varies in different establishments according to the method of purification employed, in some cases being equal to a column of water of 36 inches. The annexed engraving represents a gas-exhauster designed by Mr. Methven for the Commercial Gas Company's Works, Stepney. This machine consists of three vertical wrought-iron cylinders, which are made to rise and fall in a tank containing water, by the revolution of a treble crank-shaft with connecting rods and guides. Each of these cylinders is inverted over a chamber of cast-iron, the interior of which communicates with the hydraulic main. The top of each chamber is provided with a flap-valve, which allows the gas to escape into the movable cylinders, during the ascent of the latter by the action of the crank. The cylinders have valves on the top, similar to those in the cast-iron chambers, which during the descending stroke allow of the discharge of the gas into the upper part of the external cistern. From the cistern a main leads through the purifiers to the gas-holder, and the gas is thus pumped out of the retorts and discharged into the gas-holder, independent of any amount of pressure required to be overcome in its passage. Digitized by Google GAS. 765 The velocity of this machine is regulated by the use of conical strap riggers to suit as nearly as possible the amount of gas being generated, but in order to avoid the possibility of the pressure upon the hydraulic main becoming less than that of the surrounding atmosphere, and the gas thereby becoming impoverished by the admixture of atmospheric air, a regulating machine is attached to the exhauster, which, by self-action, maintains that pressure perfectly uniform. The regulator consists of a chamber which communicates alike with the inlet and outlet passages of the exhauster, and which is divided by a valve or conical plug acted upon by a float sustained in water, under the immediate influence of the exhausting power of the machine. The action of the float is communicated to the valve with the smallest amount of friction by a lever and connecting rod with the usual adaptation of a water joint, and the effect is, that when the machine from any cause is reducing the pressure of gas upon the hydraulic main below that of the atmosphere, and thereby causing a partial vacuum in the retorts, the float of the regulator is by the same means depressed, and the communication between the inlet and outlet of the exhauster, thereby opened to a sufficient extent to restore the equilibrium. 1950. The most perfect equilibrium is maintained between the interior of the hydraulic main and the atmosphere, during the various velocities. The pressure has been even increased to 48 inches of water without any sensible variations in the effect upon the gage indicating the pressure upon the hydraulic main. The highest speed of this machine is calculated to discharge 60,000 cubic feet of gas per hour, at a pressure of 30 inches, and will not then require a driving power greater than that of three horses. Dry gas-meters.-The ordinary wet gas-meter described, is unexceptionable where fraudulent means are not employed for under-estimating the amount of gas consumed, but its construction admits of great deception being practised by dishonest consumers. If, for instance, the water level in the meter be lowered, more gas will pass through than is registered by the instrument; if the case of the meter be tilted forward to an angle of from 5° to 13°, according to its construction, and a proportion of the water drawn off, so as to expose the outlet of the measuring chamber, the gas will pass through it without affecting the index, and without being registered at all. This is constantly done, and the large amount of gas which is unaccounted for in the calculations kept at the gas-works, and which is frequently at- tributed to leakage, is no doubt traceable to this nefarious practice. In cold weather the water in the meter is liable to freeze, and the passage of the gas is then completely stopped. The use of a solution of caustic potash or soda has been proposed, which is not so easily affected by frost, to replace the water in the meter, which will also tend to render the gas more pure, should either carbonic acid or sulphuretted hydrogen have escaped the general purifiers. The objections to the use of the wet meter stated above, have given rise to great ingenuity in the construction of a variety of measuring instru- ments, in which the use of water or any liquid is dispensed with, and in which the gas is measured by the number of times that a certain bulk will fill a chamber capable of undergoing contraction and ex- pansion by the passage of the gas. These alternate contractions and expansions of the chamber set certain valves and simply constructed arms in motion, which, by the aid of a few wheels, can be made to turn the hand of a dial, as in the ordinary wet meter. We will restrict our remarks upon dry meters to one of the most recent inventions, which appear well calculated for affording accurate meas- urements. Messrs. Croll and Richards' meter consists of a cylinder or case A A, Fig. 1951, divided by a plate B in the centre into two separate cylindrical compartments, which are closed at the opposite ends by metal disks C C. These metal disks serve the purpose of pistons, and are kept in their places by a kind of universal joint attached to each; the space through which the disks move by the action of the gas, which affords the means of measurement in this meter. is governed by metal arms and rods, shown in the side cut, Fig. 1952, which space, when once adjusted, cannot vary. To avoid the friction attend- Digitized by Google 766 GAS. ing a piston working in a cylinder, a band of leather DD is attached, which acts as a hinge, and folds with the motion of the disk; this band is not instrumental in measuring the gas, 80 that its contraction or expansion would only decrease or increase the capacity of the hinge, the disk being still at liberty to move through the required space only. The leather is also attached in such a manner that it can only bend in one direction, and this renders it much more durable. 1951. 1952 D D B C C D D The machine is comparable to a steam-engine measuring its steam, which it does in all cases by the strokes of the piston. The gas enters the cylinder at the top, from the space occupied by the arms, valves, &c., Fig. 1953, and forces the disks bodily forward through a certain space the motion commu- nicated by the disks to the arms and rods causes the supply of gas to be cut off, and admits of its escape by another valve; at the same moment the gas is admitted to the other side of the disk, and this is forced to return to its original position, traversing, of course, the same space as before. Each backward and forward motion consequently indicates the passage of a constant quantity of gas, and the same apparatus which admits and shuts off the supply by means of valves is connected with clock- work, and thus the motion of the disk, or the quantity of gas which has passed through the meter can be indicated upon a dial-plate, as in the ordinary wet meter. Gas-burners-From the leaden pipes-in the circuit of which the meter is placed, if used at all- the gas enters brass tubes, which project from the wall, and passes to the burners, each of which must be furnished with a separate brass stop-cock. Good tight stop-cocks are much more difficult to make for so light a gas, than for liquids. Instead of fixing the carefully ground conical plug into its place by a screw, which occasions either too much friction or an imperfect joint, it is better to use a watch- spring, which, in spite of the wear, keeps the plug always tight. The gas-burners are quite similar to lamp-burners; by the former we are to understand the different mouth-pieces attached to the ends of the tubes for burning the gas. As neither the wick nor the level of the oil has here to be considered, the management of these burners is comparatively simple; but as the amount of fat in candles and lamps required regulation, 80 here the amount of gas consumed in a given time must bear a proper relation to the current of air from without, i. e. the flame must neither smoke, nor must it be too short and blue. Such regulation is partly effected by the cock attached to the burner, and all excess of gas is avoided from the beginning by allowing the gas to issue only from very small apertures. In passing through such apertures, the original velocity of the current of gas is much increased, and the flame thus acquires the proper size and height. A great variety of gas-burners have been successively brought into public notice, all of which lay claim to the production of an increased intensity of light with a smaller consumption of gas. It is im- possible, however, from a mere inspection of the flame produced by these burners, without accurately measuring the amount of gas consumed by each, to arrive at any conclusion as to which form is the most economical or generally desirable. Until impartial comparative experiments have been instituted with all, decided preference cannot be ascribed to any one in particular. Fig. 1954 is a representation of Whinfield's lucent burner, in which the Liverpool button is applied to an Argand gas-burner, and the peculiar form of chimney causes an external current of air to impinge at a certain angle upon the flame, producing the same effect as the metallic cone in the solar lamp. A basket of wire-gauze is fitted into the crutch of the burner, which moderates the supply of air from below, and prevents the flickering caused by sudden draughts, by fixing the chimney to a circular ring, which screws up or down upon the triangular support. Lowe, in his improvement upon this form of burner, alters the direction of the external current caused by the contraction of the chimney, and by converting the button into a screw, its height can also be altered and the internal current regulated. Fig. 1955 shows a form of burner patented by Mr. Leslie, in which the gas is caused to flow through a number of small copper tubes, instead of from the apertures of an Argand burner. The object of this is to effect a more complete combustion of the gas by surrounding each single jet with abundance of air, as it issues from the orifice; and the low form of chimney or combustion chamber diminishes the Digitized by Google GAS. 767 velocity of the draught, and adds, consequently, to the illuminating power of the flame. The orifices of the copper tubes become stopped up, either with sulphuret of copper or the ammoniacal oxide, and require to be cleansed with a stiff brush. The only effectual remedy for this objection to the burner, is the use of purer gas. 1953. 1954. Ventilation of gas-burners.-Serious objections still stand in the way of the introduction of gas-light into private dwellings, unless some means can be adopted for removing the products of combustion. For every cubical foot of gas burnt, rather more than a cubic foot of carbonic acid is produced. A pound of coal gas contains, on an average, 03 of hydrogen, and 07 of carbon; it produces, when burnt, 2.7 of water, and 2.56 of carbonic acid gas; consumes 4'26 cubic feet of oxygen, which is the quantity con- tained in 193 cubic feet of air. It is thus obvious that the air of a close chamber must soon be vitiated by the combustion of gas, and that the consequences of breathing an atmosphere impregnated with a large proportion of carbonic acid must consequently soon be felt by the inhabitanta. The water evolved at the same time, in the state of steam, is found to be seldom free from sulphurous and sulphuric acids, derived from impurities in the gas: and this, condensing upon the furniture, books, goods in shops, dec. very soon damages them in a very perceptible manner. The large quantity of water evolved from the Bude burner in lighthouses, condensing on the glass windows and materially impeding the passage of the light, attracted the attention of Mr. Faraday to the invention of some means for effectually removing the noxious products of combustion. After several more or less successful trials, the method illustrated by Fig. 1956 has been adopted, and exhibits a beautiful adaption of the principle of a descending draught to a lamp-burner: a is an ordinary Argand burner, with a common straight chimney ee; the glass- holder c is, however, 80 constructed as to sustain not merely the chimney, but an outer cylinder of glass also ff. larger and taller than the inner one ee; the glass-holder has an aperture d. connected by a mouth-piece with a metal tube i, which serves as a ventilating flue, and which, after passing horizontally to the centre of the chandelier, ascends to produce draught, and carry off the products of combustion into the chimney or the open air; d is the pipe connected with the burner for supplying gas. The outer cylinder f is closed at the top by a plate of mica g; or still better, by two plates of mica, one resting on the top of the glass, and the other h dropping a short way into it. They are connected together by a metal screw and nut, which also keeps them a little apart from each other. The chimney and burner may then be surrounded by a ground-glass globe, which has no opening except at the bottom for the Digitized by Google 768 GATES, WROUGHT-IRON. admission of air to the burner. The course of the current of air, carrying with it the products of com- bustion, is indicated by the direction of the arrows. It is stated that the intense heat produced by the hot current of air traversing the space between the two glass cylinders, causes the glass to become more or less opaque, and thus obstructs the passage of the light. To avoid this objection, the same principle has been applied in a still more elegant and perfect manner to a ventilating gas-burner, a section of which is represented in Fig. 1957 b is the 1955. d 0 1956. C 1957. f i b K a a c d b burner, with an ordinary chimney, discharging the products of combustion into the metal tube F; K is a large glass tube, open at the top, in the vicinity of the metal flue F, from which it is suspended. The air for feeding the flame descends in the direction of the arrows, enters the burner at b, and is carried off through the flue F C, after having supplied oxygen to the flame and become vitiated. Ventilating burners of this kind not only prevent the diffusion of the products of combustion through the apartments in which they are erected, but with the hot current of gas ascending through the metal tube a large quantity of air from the room is also carried away, and thus a proper circulation established. GATES, wrought-iron, for the United States Dry Dock at Brooklyn, New York. The danger of accident by fire and decay, and the increasing difficulty of procuring timber, especially of large dimensions or peculiar shapes, has directed the attention of engineers to the substitution of iron for wood in structures designed for permanence. European engineers have been long forced to make this substitution, by the increasing cost of timber. The ingenuity and skill of artisans have led to some very beautiful designs and applications of iron, producing great strength with small weight and dimensions. The substitution of iron for wood has been heretofore chiefly confined to the construction of vessels and bridges. Sufficient experience has demon- strated the great superiority of iron over wooden vessels, and as soon as the prejudices of the old constructors are overcome it will doubtless be used exclusively. In America timber can be obtained at a moderate cost, unless it be of unusual dimensions or shapes, and a general substitution of iron will be more distant. The difficulty of procuring the immense tim- bers required for the construction of the folding gates of the graving dock at New York, led to an examination of the question of substituting iron for wood. There have been no works of this kind constructed in America; and even in England and France most of the recently built docks have been provided with gates of wood. A few iron gates of large size have been constructed; among them are those for the new graving and wet docks at Woolwich, Sheer- ness, Shinburness, Bristol, Dundee, and Montrose, and for the locks on the Caledonian and Elsmere canals at an earlier date. and also for the docks at Sevastapol on the Black Sea. The mode of constructing these gates has not been published, except in the case of the docks at Montrose, and the gates of the locks of the Caledonian canal. The general plan which has been adopted has been to construct a frame of cast-iron, and cover it with a sheathing of wooden planks; some of those recently constructed are covered with a sheathing of boiler-plate. The low temperature of the atmosphere in this climate renders the use of cast-iron dangerous where Digitized by Google GATES, WROUGHT-IRON. 769 it is subject to violent concussions; and to avoid this difficulty Mr. McAlpine (the engineer who designed these gates) proposed the adoption of wrought instead of cast iron for the frames of the gates. The successful introduction of these plates of wrought-iron in the construction of the tubular bridges over the Menai Straits, has given a direction to the use of this kind of iron which will produce important changes in the designs of such structures. A beautiful application of the same description of iron has been made in the design for the gates of the graving dock at New York. It is believed that no experiments have hitherto been made, at least none have been published, on the strength of iron thus applied. Some of the best practical engineers in the United States have ex- pressed doubts as to the strength of the horizontal ribs of the gates as arranged on the annexed plan. To satisfy these doubts, a trial-bar was modelled after the form proposed, and full size, and subjected to pressure. The result of this experiment has proved that the strength of a bar thus formed has been under instead of over rated. The following tables of the deflection of the bar under various weights possess great interest. The bar was set up, supported at its extremities, and loaded by weight suspended from the centre; provision was made against the lateral extension of the bar by placing it between solid abutments of masonry, which happened to be convenient for the purpose; care was also taken to preserve it in a truly vertical position. The whole arrangement is shown in the annexed sketch. $16 1960. 1959. 1958. 1961. Fig. 1958, elevation of the apparatus used in testing the strength of the wrought-iron bar intended for the folding gates of the United States Dry Dock, Brooklyn Navy Yard Fig. 1959, plan of the same. Fig. 1960, cross section of the frames for preserving the bar upright Fig. 1961, scale. Levels taken at each loading on different parts of the bar, as well as the weights applied at each loading, are given in the tables. The weights are given in pounds, and the deflections in decimals of a foot. 97 Digitized by Google 770 GATES, WROUGHT-IRON. The bar was thirty-seven feet long, twenty-two inches wide, and three-fourths of an inch thick, and made of three plates, for the length, secured by splicing plates riveted. The point marked No. 5 in the table was in the centre of the bar, and the other points equally dis- tant from each other. TABLE No. 1. TRIALS. No. 1. No. 2. No. 3. No. 4. No. 5. No. 6. 9,798 lbs. 16,821 lbs. 24,697 lbs. 32,883 lbs. 39,710 lbs. 55,132 lbs. No. of mark on boards. Total Total Total Total Total Total Deflec- Deflec- Defiec- Deflec- Deflec- Deflec- Deflec- Deflec- Deflec- Deflec- Defiec- Deflec- tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. 0 000 000 005 -005 009 004 005 001 008 .009 012 003 1 -000 000 003 003 005 002 004 002 003 .001 001 000 2 -002 002 005 007 002 005 '010 .015 004 -011 -011 022 3 001 001 004 005 007 012 005 017 007 024 007 031 4 003 003 009 012 008 020 004 024 010 034 014 048 5 025 025 007 032 008 040 006 046 022 068 005 073 6 001 001 010 009 008 017 003 020 010 030 010 040 7 .004 004 008 012 004 016 008 024 '001 025 016 *041 8 -002 002 .005 003 005 008 002 010 -001 009 002 -011 9 .001 '001 003 002 001 003 000 003 000 003 -002 005 10 *000 000 003 003 003 006 008 002 008 -006 003 003 The bar was then left, loaded with 55,132 pounds, for 201 hours, at which time the loading was resumed. TRIALS. No. of mark on bar. No. 7. No. 8. No. 9. No. 10. No. 11. No. 12. 55,132 lbs. 61,786 lbs. 67,788 lbs. 76,143 lbs. 84,620 lbs. 92,609 lbs. 0 .006 003 000 003 000 003 002 .005 002 003 000 003 1 000 001 .002 003 001 004 002 002 002 .004 000 004 2 .005 007 .004 025 005 026 003 029 003 032 019 051 3 001 030 005 035 .005 .040 012 .042 -011 053 044 097 4 001 049 011 060 012 072 007 079 010 089 080 -169 5 .003 070 008 178 *011 089 007 076 012 -108 057 -165 6 000 040 005 045 005 050 005 055 013 068 051 -119 7 .008 033 008 041 004 045 008 053 008 -061 039 ·100 8 -002 013 001 014 002 016 001 015 004 -019 019 039 9 004 .001 -001 000 003 003 -001 004 000 .004 004 008 10 001 004 002 '002 .001 003 001 004 001 003 000 003 Table showing the amount of elongation in the bar during the first experiments. Weight No. of Different points on the bar. on the bar in Experi- Observations. pounds. ments. a. 1 2 3 4 5 6 7 8 C. in. in. in. in. in. in. in. in. in. in. a and C were 0 0 0 0 0 0 O. O. 0. 0 0 9,798 1 points immedi- 32,883 4 005 005 ately over the 39,710 5 005 003 001 001 .003 005 plumb face of 55,132 6 010 .008 005 .003 .005 007 .005 010 altar No. 9 ;- more reliance 61,786 8 .010 008 005 003 005 007 008 010 69,788 9 .015 010 may be placed on their accura- 76,143 10 016 -010 84,620 11 .016 .013 cy than on that of the others. 92,609 12 NOTE.-In consequence of an imperfection in the arrangement which was made for securing the beam in a vertical position, at the twelfth loading, it lurched to one side, and prevented a continuance of the experiment. Digitized by Google GATES, WROUGHT-IRON. 771 The bar was repaired, and the following experiments were made without abutments, which allowed the ends to move horizontally ; it was loaded as stated in the first set of experiments. TABLE No. 2. No. 5. No. 1. No. 2. No. 3. No. 4. 33,673 lbs. No. 6. Between 4 and 5 11,771 lbs. 20,354 lbs. 31,495 lbs. 33,673 lbs. an interval of 15 No. of mark 35,961 lbs. on bar. hours. Total Total Total Total Total Total Deflec- Deflec- Deflec- Deflec- Deflec- Deflec- Deflec- Deflec- Defiec- Defiec- Deflec- Deflec- tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. . 0 001 001 .001 002 001 .003 1 -002 -002 001 .003 001 004 2 013 013 .014 027 018 045 8 026 026 021 047 030 077 4 035 -035 028 063 038 ·101 5 035 .035 035 070 046 -116 -010 -126 .005 181 007 138 6 031 031 031 062 045 .107 7 029 -029 023 052 032 084 8 .016 016 -012 028 .020 048 9 .005 -005 008 013 003 016 10 000 000 000 000 001 .001 No. 7. No. 8. No. 9. No. 10. No. 11. No. 12. 38,033 lbs. 40,131 lbs. 41,973 lbs. 44,456 lbs. 46,074 lbs. 48,179 lbs. No. of mark on bar. Total Total Total Total Total Total Defiec- Deflec- Defiec- Deflec- Deflec- Deflec- Deflec- Deflec- Defiec- Deflec- Deflec- Defieo- tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. 0 .005 006 1 -010 010 2 .074 085 3 .130 -154 4 175 .203 5 014 -152 .008 ·160 .017 .177 .023 .200 008 208 020 228 6 183 209 7 .143 ·166 8 085 098 9 028 033 10 004 000 004 000 004 The bar was then left, loaded with 48,179 lbs., for 20 hours, at which time the loading was resumed. No. 15. No. 16. No. 18. No. 13. No. 14. 56,694 lbs. 56,694 lbs. No. 17. 58,894 lbs. Between 15 and Between 15 and Between 17 and 48,179 lbs. 52,209 lbs. 16 an interval of 16 an interval of 58,894 lbs. 18 an interval of No. of mark bar. go 20 minutes. 20 minutes. 20 minutes. Total Total Total Total Total Total Deflec- Deflec- Deflec- Defiec- Deflec- Defiec- Deflec- Deflec- Defiec- Deflec- Deflec- Defico- tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. 0 002 008 001 -009 001 010 000 010 000 -010 000 010 1 003 013 000 013 000 013 000 .013 000 013 000 018 2 008 093 002 095 -016 '111 010 -121 007 128 006 134 8 -013 167 004 .171 036 207 -018 .225 016 .241 -012 253 4 015 -218 .008 .226 043 269 026 295 019 314 -015 329 5 018 246 -015 261 047 308 026 334 025 359 -015 379 6 017 226 004 230 050 -280 027 307 020 327 020 .341 7 013 179 004 183 036 219 -020 239 016 .255 -014 267 8 008 -106 .003 .109 029 .129 014 .143 .009 152 .009 -161 9 003 036 -002 038 009 047 000 047 004 051 .001 052 10 000 004 000 004 000 004 -001 .005 000 .005 000 005 Digitized by Google 772 GATES, WROUGHT-IRON. 1966. 1964. 1963}. SC 1962. 2'2' 1963. 1965. 1967. Digitized by Google GATES, FLOATING. 773 No. 23. No. 24. No. 19. No. 20. No. 21. No. 22. 65,284 lbs. 65,284 lbs. Between 22 and Between 23 and 60,904 lbs. No. of mark 63,104 lbs. 65,284 lbs. 65,284 lbs. 23 an interval of 24 an interval of on bar. 2 hours 50 min. 17 hours. Total Total Total Total Total Total Deflec- Deflec- Deflec- Deflec- Deflec- Deflec- Defiec- Deflec- Deflec- Deflec- Deflec- Deflec- tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. tion. 0 *000 010» 000 010 000 010 001 -011 000 012 *001 015 1 000 -013 000 -013 000 -013 -001 014 000 014 003 017 2 008 -142 023 .165 015 -180 011 191 .004 -195 005 200 8 .014 267 048 315 013 328 038 366 .007 373 006 379 4 022 351 064 415 022 437 049 486 007 493 010 503 5 026 405 076 481 034 -515 054 569 012 581 010 591 6 022 363 077 440 028 468 039 507 013 520 007 527 7 016 283 059 342 028 370 024 394 007 .401 008 409 8 -010 .171 029 200 019 219 012 231 005 -236 005 241 9 -003 055 -013 068 008 .071 003 074 001 -075 006 081 10 000 -005 000 005 000 005 000 005 000 -005 000 005 These experiments having demonstrated that the bars as arranged were of sufficient strength, the construction of the gates was No. 25. No. 26. No. 27 commenced. Fig. 1962 shows an elevation of the back 67,314 lbs. side of the gate. No. of mark 71,804 lbs. 75,299 lbs. Figa. 1963 and 19631 are vertical and hori- on bar. Total Total Total zontal sections of the mitre post. Deflec- deflec- defiec- Deflec- tion. Figs. 1964 and 1965 are the same sections of tion. tion. tion. the quoin post. Fig. 1966 is a plan of the horizontal rib, and 0 002 015 010 a horizontal section of the gates. 1 002 019 Fig. 1967 is an elevation of the front of the 2 -005 205 423 gate. 3 007 386 844 In the article " Dry Dock," at page 401, a ft. in. full description and specifications of these 4 007 512 820 1.152 gates are given, to which the reader is re- 5 004 595 1.450 ferred. 6 -003 530 860 1272 There being nothing peculiar in the cap- 7 001 410 953 stans and sluice-gates and other fixtures, 8 008 249 514 they have been omitted in the drawings. 9 003 084 -169 GATES, CANAL See Locks OF CANALS. 10 000 005 *000 GATES, FLOATING. Specifications for constructing the wrought-iron floating gate, or The levels of experiment No. 57 were taken after the caisson, for the United States Dry Dock, at the bar broke. Brooklyn Navy Yard, represented in plan, sec- tion, and elevation in Figa. 1968, 1969, 1970.* Dimensions.-The vessel is to be 50 feet long on the keel and 69 feet on the deck. The width in the centre is to be 4 feet on the bottom, and curved to 16 feet at 6 feet above the bottom, and to continue this width to the top. The width at the end is to be two feet. The whole height is to be 31 feet. The sides are to be curved on a radius of 88 feet 7 inches at the top, and diminished 80 as to pre- serve the width at the stems (2 feet) and in the centre (16 feet) for the upper section of 24 feet. The ends or stems are to be built to conform to the shape of the masonry of the dock. The bottom or keel is to be 50 feet long, straight; the stem is to be curved on a radius of 3 feet 10 inches for 21 feet in height, and then on a curve of 56} feet radius for 19] feet in height, and then carried up on a bevel to the top, 9 feet in height, making the whole height (including the keel) 31 feet. Ribs.-There are to be 26 ribs on each side of the gate. The 14 centre ribs are to be 24 inches apart, 4 to be 25, 4 to be 26, and 4 to be 27 inches apart; each set of ribs are to be formed of 4 plates exclusive of the bulwarks. The two bottom plates from the opposite side are to lap past each other 8 feet over the keel, the lips being turned opposite ways to allow them to be riveted together where they lap. The two bottom plates are to be each 20 feet long, and are to be formed of angle iron, 5 inches on each angle and I inches thick, with rivets # inches diameter, and 4 inches apart, or rectangular plates of iron 6 by 1 inches, secured by angle iron. The two side plates are to be each 20 feet long, and to lap past the bottom plates 9 feet, and to be riveted to them; the rivets are to be 1 inch diameter, and 6 inches apart. They are to be formed of angle iron, 4 inches on each angle and 1 inch thick. A general description of the caisson or floating gate is given in the article " Dry Dock," p. 402. Digitized by Google 774 GATES, FLOATING. "A 1969. B N° HC 1968. Plan. DD 00 1970. + a + Digitized by Google GATES, GUARD. 775 The bulwarks are to be formed of plates 7 feet long, and to lap on and be riveted to the side plates; they are to be formed of angle iron 21 by 3 inches, and i inch thick. Sheathing.-The bottom plates are to be bent to form the sides of the keel they are to be 6 feet long, 2 feet wide, and I inch thick. The vertical joints are to be butted; the plates are to be riveted to the angle iron running lengthwise of the keel, with 1 inch rivets 21 inches apart; they are also to be riveted to the angle iron of the ribs in the same manner. The horizontal joints are to be butted on a line, and the plates to be riveted to a piece of iron on the inside, between the ribs, 4 by 5 inches; the rivets to be as before described. The rivets on the bottom and sides of the keel and stem, and the bottom of the vessel, are to be countersunk. The sheathing plates, to a vertical height of 6 feet 10 inches, will be made of the same sized plates, and secured and riveted in the same manner. The next two courses above are to be made of t inch plates; the next four courses above of 1 inch plates; the next three courses of t inch, and the bulwarks of 3-16th inch plates, all secured and riveted in the manner above described. The rivets through the & and t inch plates will be 1 inches diameter, and 21 inches apart through the 1 and t inch plates they will be 9-16th inches diameter, and 21 inches apart; through the 3-16th inch plates they will be i inches diameter. The lapping plates on the inside of the horizontal joints will be made of the same thickness as the sheathing plates. The bulwarks will be braced with light wrought-iron knees, and sealed up on the inside with light sheet-iron. The keel and stems.-The keel and stems are to be formed of a single plate of iron for the keel, and each stem forged and welded together. The plates are to be 2 feet wide, and I inch thick. The sides of the keel are to be made by bending the bottom sheathing plates, and of the stems, by bending the side sheathing. The bottom plates and the sheathing are to be connected by angle iron, 4 inches on each flange, and 1 inch thick, to which both plates are to be riveted. The rivets are to be 1 inch diameter, 21 inches apart. The stiffening plates in the keel will be 3 feet long on the top, 15 inches deep, and 1 inch thick; plates of cast-iron, transversely and longitudinally, are also put in. The part which projects into the keel will be cut to the interior shape, cutting out the bottom corners for the angle iron, and the shoulders to fit against the bottom sheathing plates. The stitfening plates will be placed between the plates of each rib, and will be riveted or bolted through both plates, where they lap past each other. The nine courses of horizontal stiffening plates in the stems are made of cast-iron, conforming to the curve of the sides of the vessel on the outside edge, and fitted to the shape of the interior of the stem. They are to be placed at each horizontal joint of the sheathing, and take the place of the butting strips. Plates of angle iron 3 inches wide on each flange, and 1 inch thick, will be riveted to the sheathing plates, and bolted to the stiffening plates. Deck.-The angle iron is to be 4 by 2 inches, 1 an inch thick. The covering is to be formed of sheets about 6 feet long, 2 feet wide, 3-16th inch thick, made of scratched iron. Rivets to be 1 inch diameter, and 2 inches apart. The combing of the hatches will be made of cast-iron, bolted to the angle iron. Suituble ring-bolts will be put in the deck, and on each quarter outside of the vessel. Tube braces will all be 14 inches diameter, and made of & inch wrought, or 1 inch cast iron; the flanges of the tubes are to be 21 inches wide on each end, and bolted to the sheathing. The cast-iron chambers will be cast in halves, and planed and fitted together, and riveted through the chamber and flanges of the tube, and secured with tap bolts on the top. The valves will be of cast-iron, planed and fitted; the seats will also be planed and fitted closely. There will be four branch pipes discharging into the interior of the vessel, by means of similar valves. The valves will be raised by a stem of 1f inch round iron, guided by a frame, and operated by a hand-wheel and screw on the level of the deck. There will be a steam-engine with a cylinder of 6 inches diameter and 18 inches stroke, and a suit- able locomotive boiler set under the deck, and two double acting force-pumps 15 inches diameter, (the pumps are also to be arranged to be worked by hand.) The whole is to be made portable. A flight of iron steps is to be put in at the stem at each end, and extend from the deck to the bottom of the vessel. The keel will be suspended from and braced to the sides of the vessel, to meet the different strains to which it will be subjected when floating, and when aground in peace. This bracing is made by a trussing of hollow cast-iron pipes, 5 inches diameter, through which are passed suspension rods of wrought-iron, 21 inches diameter. General remarks.-All of the joints exposed to the water shall be chipped, and calked so as to be water-tight. All of the iron and other materials used shall be of the best quality, and shall be bent and forged to the required shape, to conform to the plans, and shall be neatly and accurately fitted. The riveting shall be done when hot, and the rivets made to fill the hole completely. The whole surface, both outside and inside, shall be painted with two coats of red lead and oil, and a third coat of such other color as may be directed. GATES, GUARD. One of the most complete examples to be found is at Lowell, Massachusetts, at the head of the Northern Canal, the principal feeding canal to the large manufacturing establishments of that city. It was constructed by James B. Francis, Esq., Agent of the Locks and Canals Company. The average width of the canal is 100 feet, the depth of the water 15 feet; the sides being nearly perpen- dicular. The guard gates are placed at its entrance from the Merrimack river, for the purpose of regu- lating the quantity of water to be admitted, and for protecting the canal and a considerable part of the Digitized by Google 776 GATES, GUARD. city from freshets, which sometimes raise the level of the water in the river 10 to 13 feet above its ordinary height. The entrance to the canal being nearly in the direct line of the stream, it was necessary that the guard gates and masonry should be of great solidity, to withstand the violent action of the ice in the spring freshets; as the river sometimes breaks up suddenly when the ice is from eighteen inches to two feet thick, and not sensibly weakened by previous warm weather. Figs. 1971 and 1972. The water is admitted to the canal through ten openings, each eight feet wide and fifteen feet deep in the clear. These openings are separated by piers of hammered granite A A, two feet thick, fifteen feet high, and a little over fifty feet long. These piers rest on a granite paving BBB, laid on the rock CC of hard mica slate. The openings are covered with granite lintels D DD, about two feet thick, resting on the piers; wells E E being left for the gates F. Above the lintels the masonry is carried up under the gate-house to the height of twelve feet, and below the gate-house, six feet higher, for the passage of the road G leading to the Pawtucket bridge across the river. 1971. 1972. M T S S P o G H W. E D H E a L. W. A A The gates F are made of white-oak timber, one foot thick, laid one above the other, and connected together with four bolts, two inches in diameter, passing through the feet of the castings H, to which the screws I are attached, and passing down through the middle of the gate to a cast-iron plate K, forming the bottom of the gate. The ends of the gate project into grooves at each end, and are faced with plates of cast-iron 7 inches wide and 11 inch thick. These plates slide on the castings L built into the masonry; the sliding surfaces being planed so that they make a joint nearly water-tight. The gates are raised and lowered by means of two screws II, about 17 feet long and 5 inches diameter, with threads of one inch pitch. These screws pass through the hubs of the pair of geers M M, which are cut into female screws. The pair of geers are driven by one pinion N placed at the bottom of the upright shaft 0, on the top of which is a bevel geer P, driven by another pinion Q placed on a hori- zontal shaft driven by pulleys R and leather bands or belts SS, three inches wide. There are two sets of pulleys and belts to each gate, one to raise the gate, the other to lower it. The proportions of the geering are such that the belt travels 1800 times faster than the gate. The belts are all driven Digitized by Google GEER-CUTTING MACHINE, BEVEL. 777 by the shaft T carrying the pulleys U. This shaft is driven by a water-wheel of fifty-horse power, by which means the whole of the gates can be lifted at one time, under almost any circumstances, in fifteen minutes. 1973. GEER-CUTTING MACHINE, BEVEL. For the cut- ting of bevel geer an admirable machine has been recently invented and patented by George H. Corliss, of Provi- dence, R. I., in whose shop (Corliss, Nightingale & Co.) it is in successful operation. From the specifications of the patentee we extract the following full and clear descrip- tion of the machine, its distinguishing characteristic, con- struction, and operation. Fig. 1973, plan of the machine. Fig. 1974, a side elevation. Figs. 1975 and 1976, enlarged cross sections, taken at the line A a of Fig. 1973; the former with certain parts removed. Fig. 1977, another cross section at the line Bb of Fig. 1974. Fig. 1978, a vertical cross section at the line C c of Fig. 1976. Figs. 1979 and 1980, enlarged end and side views of the cutter and carriage. Fig. 1981, an enlarged separate view of the hinge which 0 0 E forms the axis of the guide-bar on which the cutter carriage x 1 slides. Fig. 1982, an enlarged separate view of the end of the guide-bar, with a stem connected therewith. 0 0 The same letters indicate like parts in all the figures. In the machines heretofore employed for cutting cogs of toothed wheels, a rotating burr cutter has been used; and although this is, to a certain extent, effective for cut- ting spin geer, yet in cutting the cogs of bevel geer it is, h. from the very nature of the case, defective. The cogs, when cut with a rotating cutter, must be defective for the following reasons: if the sides of the cutter-wheel be parallel, the space cut out between the cogs will also be parallel, whilst in bevel-wheels they should be in the lines of the radii, that is, farther apart at the outer than at the inner periphery; and if to avoid this the sides of the cut- 0 ] ter-wheel are bevelled, to make the spaces wider by cut- 0 0 ting deeper towards the outer periphery, then the spaces will be wedge-formed in their section, which is at variance with the proper formation of cogs, for the spaces below 0 0 the pitch-line should be vertical, or curved inwards, and from the pitch-line upwards curved outwards; and these 0 0 curves should be sections of cones, which cannot be formed u by a rotating cutter, which, from the very nature of its operation, 0 0 will make the same curve from 0 0 end to end of the cog. The object of this invention is to avoid this objection; and for this purpose the first part of the inven- tion consists in the use of a recip- 72 rocating cutter, governed by a guide-bar on which the cutter carriage slides, and which has its axes of vibration to adapt the cut- ter to the required depth of cogs at the apex of a cone correspond- a ing with the bevel of the wheel to be cut, whether such axes be fixed or adjustable to wheels of different sizes, that all the cuts may be in the direction of the radii. The second part of the invention consists in combining the guide-bar, on which the cutter carriage runs, with a secondary frame hinged to the main frame outside of the circle of the largest wheel intended to 98 Digitized by Google 778 GEER-CUTTING MACHINE, BEVEL. be cut in the machine, that the axis of vibration of the guide-bar may be elevated or depressed to adapt the machine to different bevels; and that the main driving shaft, which communicates motion to the operative parts of the machinery placed at the hinged end of the said frame, may be in the line of the axis of vibration of the said frame, that the vibration thereof may not change the relative position of the driving shaft and the parts receiving motion therefrom. The third part of the invention consists in combining with the guide-bar a guide-plate, against which it bears by means of a weight, spring, or the equivalent thereof, 80 that as the guide-bar descends to give the proper depth to the cogs, the said guide-bar shall follow the curve of the guide, and thus de- termine the form of the face of the cogs. And the last part of the invention consists in making that part of the rear end of the guide-bar which rests against the guide, movable, 80 as to have an endwise motion, in or on the said bar, in the direction of its length; the said movable part or stem being bevelled back of where it rests against the guide, and so connected, either with the guide-bar or some other part of the machinery, that at the time of the cutting motion it will move forward. that its bevelled surface may be brought in contact with the guide and give a lateral motion to the guide-bar, to relieve the cutter from the surface of the cog that is being cut, to admit of its moving back clear of the cog; and then, at the end of the return motion, a reversed motion to bring the cutter in the proper line for cutting. 1983. q 1974. a In the accompanying figures, a represents the main frame of the machine, to the inside of which is adapted a frame b that carries the spindle c of an index-plate, made in the usual manner. This frame b is secured to the main frame by the bolts dd that pass through elongated holes ee in the side pieces of the main frame; and as there are several of these holes along the frame, the index-plate can be moved to any place required on the main frame, to adapt the machine to wheels of various sizes. The upper end of the spindle c is adapted, like other cutting engines, to receive the wheel f to be cut. A secondary inclined frame h is provided near one end with a shaft i, the journals of which run in boxes jj at the end of the main frame, so that the secondary frame can be inclined to any desired extent with the axis of the index-wheel to determine the bevel of the cogs to be cut. And the extreme rear end of the secondary frame is provided with a bolt and temper-screw that pass through a segment mortice in the main frame, by means of which the secondary frame may be secured and held in place at any inclination required. The shaft i of the secondary frame extends out sufficiently on one side to receive one loose pulley k, and two fast pulleys 1m, one on each side of the loose pulley. The loose pulley k turns freely between and on the barrel of the other two in я manner well known to machinista. And the inner end of the fast pulleys Im is provided with a pinion n, which engages and carries a cog-wheel o that turns on a stud-pin p, and the arbor of the wheel carries a pinion (see dotted line in Fig 1974) that engages and carries a sector-rack q on the end of a rock-shaft r, provided with a pendulous arm s, to the lower end of which is joined a connecting rod t that takes hold of the rear end of a carriage &, (as seen in Fig. 1980,) to which is secured the cutter v, in any appropriate manner. The carriage alides Digitized by Google GEER-CUTTING MACHINE, BEVEL. 779 on a guide-bar w properly formed for this purpose, as shown in the figures, and in turn this guide-bar alides inways x, connected by a socket y with a stud 2 that projects from an arbor a' which turns on pivot screws b' b', that pass through the two cars c' c' of a plate d', secured by bolts or screws to the side pieces of the secondary frame, 80 that by shifting these screws the plate can be moved along the sec- ondary frame, as the index-plate and its spindle can be moved along the main frame to adapt the machine to the cutting of wheels of various diameters. The guide-bar is thus connected with the sec- ondary frame by a universal joint, and the connection of the universal joint with the secondary frame can be shifted to adapt the machine to the cutting of wheels of different sizes, and as the axis of the vertical vibration of the guide-bar must always be in the line of the axis of the index-plate. the mode of shifting either the one or the other must be such as will admit of accurate adjustment. For this purpose the holes in the main frame, through which the securing bolts pass, are elongated. The machine is driven by two belts e'f', one being crossed, and the two governed by a double belt-shipper g', 80 formed that when the direct belt e' runs on the pulley m, to give the cutting motion to the cutter carriage by the connection of parts from the pinion 71, the crossed belt f' runs on the loose pulley k, and when the belts are shifted at the end of the cutting motion, to reverse the motion, the crossed belt runs on and 1976. 1977. h B x h 1979. 1975. h u V b carries the pulley 1, and with it the cutter carriage by the same connections, and the direct belt e' then runs on the loose pulley; or, if desired, this arrangement of belt may be reversed. In this way the desired motions are given, and the shifting of the belts is effected in the following manner: The belt- shipper is attached to the outer end of two rods i'i' that slide in a plate h' attached to the frame, and these way-rods i'i' are connected by a cross-bar is with one arm of a right-angle lever j', the other arm of which passes to the inside of the main frame, and is there jointed to a rod k' which passes through a thimble i, jointed to the pendulous arm 8 that communicates motion to the carriage. The rod k' is pro- vided with two adjustable stops m'm', on each side of the thimble, and at such distance apart that when the pendulous arm 8 moves forward to effect the cutting motion, towards the end of this motion the thimble strikes one of the stops m', and shifts the belts to give the return motion, towards the end of which the other stop m' is struck to re-shift the belts. In this way, by simply varying the distance between the two stops m', any desired range of motion can be given to the cutter carriage, to adapt it to the length of the cogs to be cut. As before described, by reason of the universal joint connection, the guide-bar is free to move either vertically or horizontally, and with it the cutter carriage which slides on it. Its rear end is suspended to a cord o' which passes over a pulley p' with a counter weight q' attached to it, by which it is held up against the end of a set screw r', the turning of which will therefore determine the depth of cut to be made by the cutter. This guide-bar is also borne laterally by means of a bent lever s', (see also Fig. 1977,) one arm of which acts against it, and the other attached to a cord t' that passes over a pulley u', and is provided with a weight v'. This weight always tends to bear the guide-bar in one direction, horizontally, and against a guide-plate w', one edge of which is formed 80 as to determine the form to be Digitized by Google 780 GEER-CUTTING MACHINE, BEVEL. given to the face of the cog, and as this plate can be removed, others may be substituted to suit the various and desired forms of cogs. The rear end of the guide-bar, however, does not bear against this guide-plate, but, instead of this, there is a stem x' with a socket in its forward end that slides accu- rately, but freely, on a projection y', Fig. 1982, from the rear end of the guide-bar, 80 that one can slide on the other longitudinally; and this stem it is that bears against the guide-plate. The rear end of the stem is looped to receive the arm z' of a slide a². It will be observed that whilst the stem is in the position represented in the drawings, as the rear end of the guide-bar is moved up and down to cut the depth of the cog, the stem x' follows the curvature of the guide w', and therefore communicates a cor- responding motion to the point of the cutter in a direction converging to the centre of the universal joint, on which the guide-bar w vibrates, and that, therefore, any curve to be given to the cross section of the cog will be gradually reduced as it approaches the axis of the wheel. But when the cutter is to be moved back, it is necessary that it should run clear of the metal, and for this purpose the stem x', back of the part which is represented as bearing against the guide-plate, is curved inwards, or bevelled as at b², so that when this part is brought in contact with the guide-plate a slight lateral motion is given to the guide-bar sufficient to relieve the cutter. The required endwise motion for this purpose is given to the stem by the operation of shifting the belts to reverse the motion of the cutter. The inner arm of the lever j', of the belt, carries a box c3, that slides freely on the slide a³, and towards the end of the forward motion of the cutter carriage; this box strikes against a stop dᵃ, from which the arm z', con- nected with the stem x', projects and forces forward the stem to the distance required to bring the bevel ba against the guide-plate w' to relieve the cutter. The cutter carriage then runs back and towards the end of this back motion; the box on the lever of the belt-shipper strikes another stop e3, on the slide a², and moves back the stem to bring the cutter in the proper line for making its cut. In this way at each operation the cutter is relieved and returned to its proper position for cutting. The cutter is fitted in any desired manner in a socket in the carriage, and when it is desired to cut cogs of the form represented in the enlarged Fig. 1983, the cutting edge of the cutter must be bent forward, as shown in that figure. 1982. w 1980. o 0 0 и 1978. on 1981. x y b O 0 c' h In a machine constructed and operating on the principle of this invention, every cut converges to the apex of a cone that represents the bevel of the wheel, and therefore the cogs, and the spaces between them, will gradually and in the true proportion diminish from the outer to the inner periphery. Thus far as to the mode of operation of the machine for cutting the faces of the cogs on one side but as each cog has two faces on opposite sides, 80 soon as one face of all the cogs have been cut, the machine must be reversed to cut the other side, and for this purpose it is simply required to reverse the cutter V, the guide-plate 20', and the lever 8. The reversed position of these parts is shown in dotted lines in Figs. 1977 and 1979. By the shifting of these parts, it will be observed that the machine will cut the re- versed side of the cogs. The lower end of the cutter should be properly formed to give the required shape to the bottom of the cogs. The patentee claims, first, The method of cutting the cogs of bevelled wheels by means of a recipro- cating cutter that moves in or on a slide, or slides, that vibrates on an axis that coincides, or nearly so, with the apex of a cone representing the bevel of the whecl to be cut, substantially as herein described, Digitized by Google GEER-CUTTING ENGINE. 781 by which vibration the depth of the cut is determined, and irrespective of the adjustment of the axes of vibration as described. Secondly, The guide-bar, (or its equivalent,) on which the cutter carriage runs, and having its axis of vibration for the depth of cut, as above described, when combined with a secondary frame jointed to the main frame at some point outside of the circumference of the wheel to be cut, that the machinery may be adapted to the cutting of cogs on various bevels. Thirdly, In combination with the guide-bar, having a universal joint, or the equivalent thereof, and operated substantially as described in combination with the guide-plate, to guide the cutter and deter- mine the form of the face of the cogs, as described. And lastly, Making that part of the guide-bar which rests against the guide-plate to determine the form of the face of the cogs separate from, and movable on, the guide-bar, and properly bevelled to relieve and clear the cutter for its back movement, substantially as described. GEER-CUTTING ENGINE. Figs. 1984 and 1985 are front and side elevations of a geer-cutting engine, as built by the Lowell Machine Shop, sufficiently large to cut a geer 7 feet in diameter and 8 a m F 0 N c X E If 1985. a A inches face. This is a heavy and strong-built machine, adapted to cutting spiral spur and bevel geers, without any additional fixtures. M is the spindle to which the geers are fastened when being cut, and to which is attached the dial- Digitized by Google 782 GEER-CUTTING ENGINE. plate B, on the upper surface of which are drilled circular rows of holes very accurately spaced off ; by means of this, and the spring and point N, Fig. 1984, the geer is divided into the required number of teeth. A, hand-wheel for raising and lowering spindle M when cutting small geers. For cutting large spur or bevel geers, the geer remains stationary, and the head to which the cutter is attached is traversed up and down by means of the crank D, which moves the pinion d, geering into a larger geer H, on chain pinion-shaft. An endless chain running up over a pulley K is attached to the plate, to which the cutter shaft stand is attached. This stand can be turned around at any angle for spiral or worm geers. 1984. o K G e H 0 D E M R B 6 Z R, guide for spindle when cutting worm, or slightly spiralled geers. When spiral geers of greater angle are to be cut, there is a circular inclined plane of plate steel screwed to the cylindrical part of the yoke, (under the dial,) which bears on a friction roll attached to the main frame. It is kept against this roll by means of the weight G, at the end of the string passing over the grooved pulley F. P, weight to balance spindle M and the geer, being cut. This weight has a pinion playing into the rack on the top of the long arm of the lever o, by means of which it can be moved forth and back to balance geers of different weight. G', crank and pinion geering into segment, for setting the head at an angle for cutting bevel geers. C, driving pulley coupled to cutter shaft. L, geer on nut for rai-ing the cutting head. It is worked by a pinion L' on the end of the upright shaft, to which a hand-wheel is attached. E, crank and bevel geers which communicate with the screw inside of frame, by means of the geers E'. Turning this crank moves the head stock to different positions, for different sized geers. bb, arms to which the cord and weight are attached when cutting spiral geers. This machine is a very convenient one to work at, as the operator can stand in one position and com- mand overy part of it. Digitized by Google GEER-CUTTING ENGINE. 783 Figs. 1986, 1987, another form of geer-cutting engine for cutting bevel, spiral, and spur geers, also made by the Lowell Machine Shop. Fig. 1986, side elevation. Fig. 1987, front or end elevation. EE are the end standards which form part of the frame. D, swing slide, in which the cutter head slides when cutting bevel geers. B, hand-wheel on pinion shaft passing through the axis of the swing slide D, which has a pinion geering into a rack on the back side of the cutter head, for traversing the cutter. E X o 4 R A 1986. L I R C, handle nuts for fastening the swing slide in the circular slot at any angle required. A, driving pulley on the shaft that drives the cutter shaft. This pulley and shaft are fixed. The cutter shaft can be taken out without throwing off the belt, as the two shafts are connected together with a clutch coupling. N, hand-yheel on screw for traversing cutter head to suit geers of different diameters, or in cutting worm geers, &c.; to the left of N are seen the screw and lever for fastening the head. Digitized by Google 784 GEERING. G, dial or index, having rows of holes of different numbers drilled on its face, which can be divided by means of the point and spring I, 80 as to cut any number of teeth wanted. K is a hand lever for raising spindle F and dial with the geer while cutting. This lever is on one end of a short shaft passing through a stand, and on the other end there is a quadrant, to which a chain is attached, that connects with the long lever L, on which the spindle stands. 1987. A B D c C E H K G P L" is a balance lever weight to counterbalance the spindle and dial, and the weight of the geer which is being cut. The weight has a movable cover for the purpose of putting in more or less weight, as the heft of the geer being cut may require. To the extreme left of the upper part of the frame, Fig. 1986, is a thumb-nut for tightening up the spindle in case it should wear and become loose. H, pulley over which the cord passes to support the weight P, used in cutting spiral geers. GEERING is the general term employed to denote a combination of mechanical organs, interposed between the prime mover and the working parts of machinery. Frequently, however, the signification is restricted to the series of toothed wheels by which the motion is conducted from one revolving axis to another, independently of the shafts and bearings by which they are supported. Two toothed wheels are also said to geer when they have their teeth engaged together, and to be out of geer when separate and consequently out of action. In the transfer of motion from one axis to another in a system of mechanism, wheels are the most important organs. Of these there are two principal varieties with several modifications, distinguished by peculiarities of form, construction, and adaptation. When motion is to be transferred from one axis to another which is parallel to it, the peripheries of the wheels act upon each other tangentially, and the teeth are disposed round their cylindrical surfaces in the direction of radii from their centres. Wheels of this sort take the general name of spur geer. In Digitized by Google GEERING. 785 the ordinary cast-iron wheels, the teeth are made in one piece, with the rim, and commonly the wheel consists of one entire piece, though sometimes the wheel is cast in segments when of very large size, and especially if intended for shipment, for convenience of packing and transport. Cast-iron wheels of all sizes above, and frequently below 18 inches diameter, are made with arms; but in very small-sized wheels the arms are commonly omitted, and the rim and teeth are 1988. united to the central boss by a thin continuous plate, as represented in elevation and section, by the annexed cuts. Wheels of this sort are usually denominated plate- wheels, to distinguish them from those of similar size having arms, and which are therefore described, especially by clock-makers, as being crossed out. In very small machinery the wheels are sometimes formed out of plain disks by cutting out a series of equidistant notches round the circumference. In wooden wheels, which were in general use for all species of millwork till towards the end of the last century, and of which we have still some examples, the teeth are formed of separate pieces, and fixed into equidistant mortises pierced through the rim of the wheel. The rim is formed of segments of hard wood firmly bound together by iron straps and bolts, and is connected to the shaft by a wooden framing, consisting of bars set at right angles. The square opening, thus left at the centre to receive the shaft, also of wood, and square at that part, is purposely made larger than the section of the shaft, to admit of adjustment and fixing by wedges. The arms are, however, very frequently mortised into the shaft: but such a mode of fixing weakens the shaft, and at the same time renders it difficult to get the wheel off, should this be required in consequence of the failure of the shaft. Wheels of this kind are technically known as cog-wheels, and the teeth take the name of cogs. These are made of some well-seasoned hard wood, as mountain-beech, plane-tree, hornbeam, hickory, and the like, with the grain disposed in the direction of their length, which being the radical direction, is the most favorable to transverse strength. A modification of this construction of toothed wheels is still very commonly employed in millwork under the name of mortise-wheels. In these, the body of the wheel is of cast-iron, and the teeth of wood, fixed into mortises made in the rim, as in the old cog-wheel. The individual teeth, or cogs, are often formed so that the part which projects without the rim is the tooth; and the shank, tail, or tenon, is made to fit its mortise in the rim of the wheel very tightly, and is left sufficiently long to project on the inside, so that being driven into the mortise up to the shoulders, it is secured in its place by an iron pin inserted into a hole bored through the tenon, closely under the rim of the wheel. There is, however, another mode of fixing the cogs, which is more commonly practised than that described. This mode will be understood by reference to Fig. 1990, from which it will be observed that the cogs, instead of being made fast in their places by pins, are retained in the mortises of the rim by dovetail keys v v, driven between every contiguous pair inside of the rim. The tenons. when the cogs are intended to be fitted in this manner, are made with an expanding dovetail at their extremities, to receive one side of the key, which being driven tightly into the V-shaped space, thus formed between the ends of each pair inside of the rim of the wheel, retains the cogs in their places. The keys, which are made of well-seasoned hard wood, usually.of the same kind as that used for the cogs, are made long enough to project some way beyond the side of the rim, to 1991. allow of their being driven in more tightly, should the cogs in the course of working become loose. The ends of the tenons are b 1, c S 8 c also very commonly made flush with the surface of the keys, but b b the mode of finishing shown in Fig. 1991 has some advantage in point of strength. Spur mortise-roheel.-Fige. 1989 and 1990 give two views in elevation, and Fig. 1991 a section of a mortise spur-wheel of 841 1989. inches diameter, and containing 48 coge; pitch 21 inches. Fig. 1991 is a section of the wheel where a a represents the cogs; r r the ring; c c the face arms; bb the feathers of the arms, and SS the socket or eye of the wheel Fig. 1989 is a view parallel to the axis of the wheel, and Fig. 1990 is a plan of the same wheel in the line of its centre. These figures are intended to illustrate the mode of drawing the wheel. The pitch and number of cogs being given, the first part of this operation is to determine the diameter of the pitch circle. This may be done by multiplying the pitch of the teeth 1990. by their number, and dividing the product by 3.1416; or it may be directly found from the rule and table given in page 795; or the compasses may be at once set to draw the pitch circle from scale of Fig. 2022, (see pages 799 and 800.) The pitch being 21 inches, the radius of the pitch circle will be found in the line which runs parallel with A D, and which is marked 24; and the distance C to 48 in that line being the radius for a 21 inch pitch with 48 teeth, one point of the compasses placed in the intersec- tion of the line 21 by C B, and the other in the intersection of the line terminating in 48, will be that radius. The other required dimensions will also be found in the line 21; the distance A C = the pitch; a c = the length; b = the :hickness; a c = the length from the pitch line to the point, and twice this is the working depth; the width of space is A b, and their lateral clearance is A b C b, and the bottom clearance a C 2 c. The same scale may be used in finding the proportions of parts in making out reduced drawings of wheels to different scales. If the compasses be set to the required pitch, and moved up the line C B, keeping one point in CB until the other point meets the line A B, the points running parallel to A C, 99 Digitized by Google 786 GEERING. then in a line drawn parallel to A D, and passing through the points in which the compasses meet the converging lines, will be found all the other required dimensions in accordance with that scale. Fig. 1989 shows the method of finding the shape and position of the teeth, by the application of the T square to Fig. 1990, as indicated by the dotted lines eeee at 2, 2, 2. The lines forming the outline of the shaft are found in a similar manner from Fig. 1990. The mode of drawing the curves of the top and bottom of the teeth is shown by the dotted circles, marked ffff, and which are drawn from the centres of the teeth a a. This curve is, however, very variable, and depends much upon the size of the pinion intended to work in the wheel. The mortise-wheel is preferred, where a high velocity with smoothness of motion is required. It is usually made to work into a wheel with cast-iron teeth, a pair of this sort being found to work together with less vibration, less noise, and less wear, than when both wheels of the pair have iron teeth. For these reasons it is very common, in good millwork, to make one wheel of every large-sized pair with wooden cogs, especially when the speed is high, and subject to variations of velocity. But it may be here remarked, that in cases where a very large wheel is required to geer with a smaller one, the former is commonly made the mortise-wheel. It may be here well to observe, that when two wheels geer together, the one which communicates the motion to the other is called the driver or leader; and the wheel impelled is the follower. If the two wheels be of very different sizes, the smaller one very commonly takes the name of pinion, which may be regarded as the diminutive of toothed-wheel. For the sake of further distinction the teeth of pinions are often termed leaves. In geering of the ordinary kinds, the pinions are commonly of the same form of construction as the wheels with which they act; but in the old wooden machinery the pinion is commonly formed by inserting the extremities of a number of wooden cylinders into equidistant holes, in two parallel disks, (technically called heads and cheeks,) upon a square shaft. A pinion of this description is denominated a trundle, lantern, or wallower, and its cylindrical teeth are termed staves, sometimes rounds and roundles, very commonly pronounced rungs. In early machinery the toothed wheels were often cut out of thin metal plates, which rendered it im- possible to make a pair thus formed to work together, for the slightest deviation of one of the wheels from the plane of rotation of the pair, would allow the teeth to lose hold of each other sidewise. To obviate this, one of the wheels of a pair was always made either in the lantern form, as just described, or more commonly with pins inserted at one end only, into a disk. A modification of this method also in use, was to form the teeth on the edge of a hoop; by these arrangements, the thin wheel was enabled to retain its hold of the teeth of the wheel with which it geered, notwithstanding a little deviation from the plane of rotation. This form of wheel is still in common use in watch and clock work, under the names of crown and contrate wheel. Fig. 1992 represents the case of a wheel working into a rack, commonly called 1992. a rack and pinion. If the rack be curved upon the pinion it becomes an internal or annular wheel, that is, a wheel having the teeth inside of the rim, as represented by Fig. 1993. In this the axes of the wheel and pinion are parallel, and moreover, revolve in the same direction. The arms of the internal wheel are necessarily situated behind the rim to prevent their interference with the pinion, and the latter must overhang its bearing, that is, be fixed on the extremity of its shaft, to avoid interference with the arms of the 1993. 1994. wheel When the pinion is made half the diameter, that is, equal in diameter to the radius of the annular wheel, the arrangement admits, in small steam-engines, of an application, known as White's parallel motion. In this the annular wheel is fixed, and the pinion is attached upon a crank-arm. The rod being at- A. tached at the circumference of revolution of the pinion, it is thereby made to describe a right line, coinciding with a diameter of the annular wheel, which is therefore equal to the length of the stroke of the engine. Similar combinations to that of the crown-wheel and pinion were early introduced into mechanism. In examples of this con- struction, which are still to be found along with cog-wheels and trundles, the cogs are simply disposed on the rim of the wheel, from which they project in lines parallel to the axis, 80 as to geer with those of an ordinary cog-wheel, having the cogs disposed round the circumference, or with a trundle when 1995. 1996. one of the axes revolves much quicker than the other. This is exemplified in the hand-mill still to be found in some parts of Germany and the north of Europe, as depicted in Fig. 1995, in which we have the face-wheel upon the crank-axle, geering with the trundle upon the millstone axle, which forms an angle of 90° with the former. Digitized by Google GEERING. 787 In several parts of Scotland, the combination shown in Fig. 1996, as a first pair in the geering of a thrashing-mill, is still common. In spur-geer, the principle depends upon two cylindrical surfaces being made to act on each other tangentially; in bevel-geer the cylinders are replaced by thin frusta of cones, which have their smooth surfaces exchanged for a regular series of equidistant teeth directed to the apex of the cone; so that a right line passing through the apex, if brought into contact with any part of the side, or top of a tooth, shall touch it throughout its whole breadth; consequently in any pair adapted to work together, the apices of their cones must meet in the same point, and thus the contact of one tooth with another will take place along their sides. This is illustrated in Figs. 1997, 1998, and 1999. Arm Tooth and Space 1997 1998. 1999. nnn Detailed drawings of a mitre-wheel. Fig. 1997 is a section, Fig. 1998 a side view, and Fig. 1999 a face view of a mitre-wheel. This is a kind of bevel-wheel that is used when it is required to change the direction of motion 90° without altering its angular velocity-a case which occurs very frequently in practice. It is obvious that only one pattern is required for the pair of wheels of this kind, and the method of drawing any one of them will apply to both. The following is the process: Draw a line A B equal to the diameter of the wheel, (diameter of pitch circle;) bisect A B, and pro- duce a line at right angles to it, which will represent the centre line of the shaft. The points C and D in this line, Figs. 1997 and 1998, where the produced centre lines of the two shafts intersect each other, is the point to which all the lines running in the direction of the breadth of the teeth are drawn. The distance of the point D or o from the line A B is equal to half the diameter of the pitch circle. This will be evident if BC be drawn from the point B at right angles to A B: the line BC being equal to A B, will represent the proper position of the other wheel, and if bisected in E, the line ED produced perpendicular to it will be the centre line of the shaft. The point D is therefore the position of the common apex of the two cones. Join A D and BD, and A o and BO, and at right angles to these lines draw e m and ri, Fig. 1997, passing through the points A and B. Make A k, Bn equal to the breadth of the teeth, and draw kg and n h parallel to A m, BL Set off upon A m, BI the length of the teeth, as f, r 8; also the thick- ness of rim, as fm, 8 I; and from these points let lines be drawn to the apex of the cones, as shown. Join g h, and make q v equal to the size of the eye; Pq and V w are each to be equal to the intended thickness of the eye, and Pt equal to the depth. Draw pt, qu, vx, wy, at right angles to gh and join t m and y I, and thus a section of the wheel is determined, from which all the lines and points re- quisite for drawing the plan can be found. Fig. 1998 is a face view, the mode of proceeding with which is to transfer the points 1, 2, 3, 4, 5, from Fig. 1997 to it, by means of the T square, which determines the extremities of the teeth and rim circles are then described passing through these points, and that passing through the point 4 is divided into the number of teeth intended to be in the wheel: the thickness of the teeth is then set off, and drawn in a similar manner to that described in Fig. 1990. The lines forming the edges of the top and bottom of the teeth are radial lines, and of course are drawn in the direction of the centre of the wheel. Fig. 1999 the side view. The elementary lines for this drawing, viz. 6, 7, 8, 9, 10, correspond to the lines in the section having the same figures, and the points forming the teeth are derived from Fig. 1998, by the application of the square. For example, the two points a b, forming the top of the out- side of the tooth F, are transferred to the line marked 8, on Fig. 1999, and the points c d to the line marked 7; these points being connected by the lines ac and bd, form the end of the tooth straight lines are then drawn from a b in the direction of the point D, until they meet the line marked 10, and n line in the same direction from c meeting the line marked 9. The terminations of these lines mark out the extremities of the inside of the tooth, which being joined, complete the tooth F. The shape and direction of the other teeth in the wheel are found by a similar operation to that used for finding F, keeping in view that the slope of all the teeth tends to the point D. The eye of this wheel is intended for a round boss, on which it may be keyed in the usual manner The thickness of the web is equal to that of a tooth of the wheel; the arms have a thickness somewhat less, and the thickness of the metal of the eye is equal to the pitch of the teeth. The radius representing the circle of action of wheels of the kind described, is found by producing the line BI till it meets the centre line of the shaft. Digitized by Google 788 GEERING. Bevel-wheel and pinion.-This pair of wheels, shown in Fig. 2000, differs from that in the preceding, in being of unequal size; and hence come under the denomination of bevel-wheels. Both wheels of this pair are supposed to be placed on horizontal shafts, in which they differ from the pair of bevels in Fig. 2001, of which the pinion is placed on an upright or vertical shaft, having its bottom bearing in a foot- step, while the wheel with which it is in geer is placed on a horizontal shaft. The mode of drawing a pair of wheels of this kind will be understood from what follows. Fig. 2000 is a side view of the wheel and pinion. 2000. 2001. When only the side view of a bevel-wheel and pinion is required, it is not necessary that the whole section, as in Fig. 1997, should be drawn, farther than to determine the position of lines a bcde and f, and the position of the apex of the two cones, as at 0, Fig. 1997. It should also be observed, in the example given in Fig. 1997, that the view in Fig. 1998 was requisite for drawing the side view, only 80 far as finding the position of the four points of the teeth abc d was concerned; but for common purposes, these points can be found with sutti- 2004. cient exactness by merely drawing circles of the same diameter as the wheel and pinion, and dividing them into the given number of teeth, and marking off their thickness. This will be readily understood, by examining Fig. 2000, in which circles, so divided, are laid down equal in diameter to the wheel and pinion; and 6. 7, 8, &c., show the thickness of the teeth. Now by applying the T square, as at 6 and 7,* and 5538 marking these points upon the pitch line c, the 2003. lines forming the sides of the teeth at 3, 4, are found by drawing them parallel to the centre line, which is drawn to the point where the lines 1 and 2, forming the bevel of the ends of the teeth, meet. This point is not shown in the drawing, being at too great a distance for the size of the plate. The lines forming the face of the teeth are all drawn to the point 0 where the cones meet, as shown by the lines gg; and exactly the same mode is adopted in determin- ing the shape and position of the teeth of the 2002. pinion C. When the wheels are drawn to a small scale, as in Fig. 2001, the two lines forming the sides of the teeth may both be drawn to the same point, as shown at a, as in such cases they will not differ sensibly from the parallel. A bevelled mortise-wheel.-Figs. 2002, 2003, and 2004, are plan, section, and side view of a bevel-wheel, having wooden teeth, commonly termed cogs. The ratio which the wheel and pinion bear to each other is four to one, as will be observed from the section, Fig. 2003, in which A B The scale is too small in the cut to show these figures, but the process will readily be followed by a glance at the method pursued in Fig. 1997. Digitized by Google GEERING. 789 represent the diameter of the wheel, and BC that of the pinion. By following the instructions given in Figs. 1997, 1998, and 1999, the point D will be found to be the junction of the two cones, and conse- quently that point to which all the lines of the teeth are drawn. The manner of finding the points for drawing the plan, Fig. 2002, is by applying the square to Fig. 2003, as shown by the dotted lines 1, 2, 3, 4, 5, 6, 7, &c., and the shape of tooth in Fig. 2004, is pre- cisely the same as described in Fig. 1999. In these examples, motion is led off at an angle of 90°; but bevel-geer may be employed to change the direction of the motion to any angle required. This will readily appear from the following dia- grams. in which, for the sake of simplicity, we suppose the cones continued till their apices meet. In Fig. 2005 we have an illustration of the principle of those cases already described. Here a is the point at which the apices meet, and supposing the motion to be conveyed in the axis Aa, it is trans- ferred to the axis a B in a right angle to its first direction. In Fig. 2006 the change of direction is no longer a right angle; for the angle included between the axes is obviously less than 90°, and might evidently be made still less by diminishing the angles which the slanting sides of the cones make with their respective axes. Wheels of this kind-rather wheels of which the angle included by the axes is less or greater than a right angle-are usually distinguished by the name of conical-wheels. 2008. 2005. 2007. 2006. In Fig. 2007 the apices of the two cones meet in a point, so that one of them becomes a plane sur- face; its teeth therefore become radial as referred to its apex; in other words, they diverge in the manner of radii, drawn from the centre a. The change in the direction of the motion is in this case greater than 90°, and might be further increased, if consistent with the relative velocity of the pair, by increasing the angle of the cone. In Fig. 2008 we have an expression of a mode of changing the angle of direction differing from those shown in the preceding figures, inasmuch as one of the cones has become hollow, and the teeth are dis- posed upon its interior surface, thereby forming an internal bevel-wheel analogous to the internal spur- geer previously noticed; wheels are, however, very rarely made in this manner. 2009. When the direction approaches a right line, the cones may be made to roll upon each other, as in Fig. 2009. In cases where the axes do not meet in a point as hitherto considered, the geer- ing becomes somewhat more complicated. The direct mode of arrangement in this case is to employ an intermediate dou- ble bevel-wheel. To avoid the multiplication of parts, the object is more commonly attained by a modification in the direction of the teeth, by which they are made to come into contact in an oblique position, answering to the obliquity of the position of the cones upon which they are formed. This artifice is often practised when it is ne- cessary to cross the two axes,-which it must be observed are not theoretical lines but actual shafts of diameters proportionate to the power they are required to transmit. This arrangement is represented by Fig. 2010, and illustrates that variety of toothed-geer, known as skew-wheels. Wheels of this char- acter are commonly avoided in practice; as, on account of the oblique form of the teeth, they are not only of more difficult construction, and therefore rarely possess the same degree of accuracy which we find in bevels of the ordinary sort, but the strain upon the shafts is likewise oblique, and therefore more severe upon the bearings. Another form of toothed-wheel, known as " Hooke's Geering," from the name of the inventor, Dr. Hooke, consists in disposing the teeth upon the peripheries of the wheels in equidistant steps, or in such a manner as to form a continuous slope. This remarkable contrivance, which has several times since been re-invented and patented, was intended, to use the words of the learned inventor, First, to make a piece of wheel-work 80 that both the wheel and pinion, though of never 80 small a size, shall have as great a number of teeth as shall be desired, and yet neither weaken the work nor make the teeth 80 small as not to be practicable by any ordinary workman Next, that the motion shall be 80 equally communicated from the wheel to the pinion, that the work being well made, there can be no inequality of force or motion communicated. Thirdly, that the point of touching and bearing shall be always in the line that joins the two centres together. Fourthly, that it shall have no manner of rub- bing, nor be more difficult to be made than the common way of wheel-work, save only that workmen have not been accustomed to make it." The mode of construction contemplated by Dr. Hooke was to make the wheel and pinion of several plates, laid one beside the other, and to bolt them together. These plates are individually cut into wheels, which are fitted together in the manner described, but in such order that the teeth of the suc- cessive plates follow each other in regular gradation, 80 that the last tooth of each group may, within one step, answer to the first tooth of the next group. The pinion being constructed in the same manner, and of the same number and thickness of plates, it is obvious that the inequalities in the touching sur- faces are reduced in proportion to the number of thicknesses; and the amount of rubbing friction is reduced to what it would be between the two next teeth of one of the sets. This is still further reduced by reducing the steps formed by the ends of the teeth to a straight, or rather a spiral edge. A wheel and pinion of this kind, observes Dr. Hooke, are equivalent to the same having an infinite number of teeth, and are best made each of a single plate of convenient thickness, Digitized by Google 790 GEERING. " which thickness must be more or less, according to the bigness of the sloped tooth And this is always to be observed in the cutting of the teeth, that the end of one sloped tooth on the one side be full as forward as the beginning of the next tooth on the other side;" in other words, that the end b of one tooth on the right side be full as low as c, the beginning of the next tooth on the left side. 9010. In a pair of wheels of this construction it is easy to perceive that the contact of the teeth will bear every instant at a single point, which, as the wheels revolve, will travel from one side to the other, a fresh contact always beginning on the first side immediately before the last contact has ceased on the 2011. 2012. A B B opposite side. The contact, moreover, being always in the plane of the centres of the pair, the action is reduced to that of rolling; and as there is no sliding motion, there is consequently no rubbing friction between the teeth. Digitized by Google GEERING. 791 The motion of wheel work of this description is remarkably smooth and free of vibration, but is liable to the objection of introducing endlong pressure upon the axes, in consequence of the obliquity of the sur- faces of contact to the planes of rotation. To obviate this objection, the wheels have been made with dou- ble sloped teeth, in the form represented in Fig. 2011. This wheel may be conceived to be composed of two thicknesses of metal, each having teeth formed upon its periphery in the same manner as the wheel of Dr. Hooke just described, and that these plates are fitted together with the direction of the teeth reverse to each other. More strictly, the wheel may be supposed to consist of two equal and concentric plates, which being, in the first place, made as separate wheels, have their teeth of equal size, and cut at equal but contrary angles with the axis of rotation, are fitted together so that the teeth of the one plate meet those of the other plate in the plane of contact. The slopes of the teeth on the two sides being thus reverse, and projected at equal but contrary angles with the axis of the wheel, and the pinion being formed in the same manner, the action of the respective sides of the V-shaped teeth on each other will be as before described; but the endlong pressure arising from the obliquity of contact on one side, will be exactly equal and opposite to that resulting from the obliquity of action on the contrary side; these pressures must, therefore, neutralize each other, and relieve the journals of an amount of friction which is necessarily involved in the mode of action contemplated in the original invention. A further modification of Dr. Hooke's geering has of late been somewhat extensively adopted, espe- cially in the newer cotton-spinning machines. This consists, when the direction of the motion is simply to be changed to an angle of 90°, in forming the teeth upon the periphery of the pair at an angle of 45° to the respective axes of the wheels it will then be perceived that if the sloped teeth be presented to each other, in such a way as to have exactly the same horizontal angle, the wheels will geer together, and motion being communicated to one axis, the same will be transmitted to the other at a right angle to it, as in a common bevel pair. Thus, if the wheel A, Fig. 2012, upon a horizontal shaft have the teeth formed upon its circumference with an angle of 45° to the plane of the axis, it can geer with a similar wheel B upon a vertical axis. Let it be upon the driving-shaft; then the motion transmitted will be changed in its direction, as if A and B were a pair of bevels of the ordinary kind, and as with bevels generally, the direction of motion will be changed through an angle equal to the sum of the angles which the teeth of the wheels of the pair form with their respective axes. 2013. The contrivance, as stated, is directly a modification of Dr. Hooke's geering; but, in effect, it may be described as a modification of the tangent screw and screw-wheel. In this last arrangement, repre- sented by Fig. 2013, in its common form, it will be observed that the plane of the thread coinciding 80 nearly with that of the axis of the wheel, renders it necessary that the screw be uniformly the driver; and as the screw, by one revolution, passes only a single tooth of the wheel, the motion is necessarily slow. Both of these circumstances are manifest advantages in a large class of instances; but for very many purposes it is desirable to retain the principle of the screw, with an increase of velocity and a diminution of its rubbing friction. This is accomplished by diminishing the inclination of the thread of the screw to the axis-more correctly by increasing the number of separate spiral threads upon the surface of its cylinder; for, as every one of those spirals will pass its own wheel-tooth across the line of centres in a revolution of the screw, it follows that as many teeth of the wheel will pass that line dur- ing one revolution of the screw as this last has threads. If. therefore, we suppose the number of threads to be increased until they equal in number the teeth of the wheel, then the screw and wheel may be made exactly alike. This is precisely the case exemplified by Fig. 2012. in which we suppose A and B to be the same size, and to have the same number of spiral teeth-which might manifestly be con- tinued round the axes of the wheels without affecting in the least their mode of action. 88 Digitized by Google 792 GEERING. Relative direction and velocity of rotation.-A wheel describes a circle because its axis is fixed; but the direction and the velocity of its rotation depend upon its connection with the next wheel of the train, which lies between it and the moving power and it is evident that the relative velocities of any given pair, must depend upon the relative magnitudes of the circles which they respectively describe. Thus, supposing the circumference of the wheel be double that of its pinion, and, therefore, to have double the number of teeth upon it, every revolution of the wheel must of necessity effect two revolu- tions of the pinion about its axis. And similarly knowing the respective circumferences of any pair acting together, it is easy to assign the ratio of their velocities. This form of the question, however, more rarely comes into use than that requiring the determination of those quantities from the diameters, which is slightly more involved. and renders it necessary, before entering further upon the consideration of the subject, to examine the conditions a little more closely. Supposing that A and B, Fig. 2014, are two axes 2014. of motion referred to the same perpendicular plane, Pi and that A B is a right line connecting them. Further, let it be supposed that the moving force is transmit- ted through A, and that it is required to connect it with B in such a way-that is, by a pair of spur- OB wheels of such sizes-that while A makes two revo- lutions B shall make three revolutions, the distance between A and B being six feet. It is manifest that the circumferences of the wheels, the axes being fixed and the circumferences in geer, must of necessity have the same velocity. Thus, supposing for an instant that the question is already resolved, and that the circles described about A and B, having their point of contact at c, then if a con- stant force, P1, act tangentially to the circle described about A with the radius A c, it is evident that the rotation of this circle being transmitted to that de- scribed about B with the radius Bc, will cause it to describe an equal length of arc to that through which itself passes, in any unit of time. But although the arcs be of the same absolute length, it is easy to per- ceive that they form very different portions of their respective circles. In fact the arcs described by the B two points of a and b, taken as portions of the circle to which they belong, are in the inverse ratio of the radii A c and Bc by which the circles are described. Now, if this be true for a part of a revolution, it is equally true for a whole revolution of either of the wheels, and consequently for any number of revolutions. Hence, to obtain the radii of the wheels, it only remains to divide the distance between the centres-that is, the line A B into parts inversely proportional to the number of revolutions which the wheels respectively make in the same unit of time. These rules are expressed as follows:- I. To find the radius of the wheel, the relative number of revolutions and the distance between the centres of the pairs being given, multiply the distance between the centres by the numbers expressing the velocity of the pinion, and divide the product by the sum of the numbers expressing the relative velocities of the pair-understanding by velocities the number of revolutions which the wheels make in the same time. IL To find the radius of the pinion or other wheel, multiply the distance between the centres by the number expressing the velocity of the wheel, and divide the result by the sum of the velocities; or sub- tract the radius of the wheel from the distance between the centres: the remainder is manifestly the radius of the pinion. Now in the arithmetical question proposed, the distance d between the centres is six feet, the velocity of the wheel two, and that of the pinion three; hence, 6 feet 2+3 X 3 = 18 5 feet = 3 feet 7½ inches. 6 feet X 2 = 12 5 feet = 2 feet 43 inches. 2+3 Sum of radii d = R + = feet. Having the radii or diameters of the wheels given, it is not necessary to find their circumferences in order to determine the ratio of the velocities of their axes. The relative number of revolutions which they will make in a given unit of time is ascertained by dividing the measure of the one by that of the other, the quotient being the number of revolutions, or parts of a revolution, the axis of that wheel will make which is made the divisor, while the axis of the wheel whose diameter or radius is divided makes one revolution. Questions of this kind may be solved very readily by means of the compasses and a scale of equal parts. Thus let A and B, Fig. 2014, be the given centres, the ratio of their velocities being respectively two and three, if the line joining the centres A and B be divided into 2+3=5 equal parts, that is, into as many equal parts as there are units in the terms of the given ratio, the radius of the wheel upon A will contain three of these parts, and the radius of the pinion on B will contain the remaining two parts, Digitized by Google GEERING. 793 and the point of contact of the wheels will be at c. This method is very convenient in practice when the terms of the ratios are small. In the preceding examples, only a single pair has been taken; but it frequently occurs in practice that motion is to be transferred through a system of shafts, with varying degrees of intensity, according to the purposes to be attained. It likewise not unfrequently happens that a pair of shafts are to be connected at such distances as to require the interposition of carrier wheels, that is, wheels intended simply to connect the two, without being subservient to any other purpose. Let there be two motion-axes, A and B, of which the angular velocities are as 27 to 343, and let it be required to connect them by four wheels on two intermediate shafts, the wheels to have a common velocity ratio throughout. Let A be the driver; then the intensity of the motion is required to increase from 27 towards B, in which it is expressed by 343. Now, it has been shown that if a pair of wheels be in geer, their radii are to each other as the angubar velocities, that is, the relative number of revolutions which they make upon their axes. In order, there- fore, that the geering pairs in the question proposed may have a common velocity ratio, it is obvious that the same must apply to the axes upon which they are fixed. These velocities ought, therefore, to form a geometrical progression, of which the first and last terms, (A = and B = 343,) and also the number of terms, namely, the four axes, are given. Now, the formula for all such questions, m being the number of geometrical means to be inserted, P the ratio, is for an increasing series. P m+1 which becomes Hence the angular velocity Also, A will be connected with C, and 0 with D, and D with B by wheels of radii 7 and 3 respectively. These examples illustrate the whole process of calculation of the transfer of angular velocity from one axis to another, and include every case of the kind to be met with in practice. In the case taken, we have supposed the motions of the pair to be in the same plane, and the axes of rotation of the circles parallel. But it is often found necessary to change the direction of motion through all conceivable angles, as in case the axes of rotation meet in a point by common bevels and face wheels, and when the axes are neither parallel nor do they meet in direction by screw-wheels. These cases require to be separately noticed. Let us, in the first place, suppose that the two axes of rotation B A and CA intersect in A, and in- clude the angle BAC. If we suppose a cone to be generated by the revolution of the line A E about A B, and another by the revolution of the line A E about A C, then these cones 2015. being made to revolve in contact about their respective axes A B and A C, their surfaces will roll upon one another along their whole length of contact A E. For, as already shown, if n times the circumference of a circle D e be equal to m times that of a circle F e, and these circles be conceived to revolve in contact about their centres b and c, and to carry the cones with them, then it is evident that whilst the cone EAG makes n revolutions the cone E A H will make m revolutions. But n times the circumference of any other circle EG of the one cone, is equal to m times the circumference of the corresponding circle EH of F the other cone; for the diameters of these circles, and, therefore, their circum- D ferences are to one another in the same proportion as the diameters and circum- M ferences of the circles e D and e F. It is therefore obvious, that whilst the cones G make n and m revolutions respectively, the circles EG and EH are carried B through n and m revolutions respectively, and that n times the circumference E of EG being equal to m times the circumference of EH, it follows that these circles roll in contact through the whole of their path. And the same is equally true of any other corresponding circles in the cones, and therefore of their whole surfaces, 80 that the rotation of one axis being communicated to the other, by the rolling together of the two cones, the sur- face of the one cone will carry with it the surface of the other along the whole line of contact A E with equal perimetral velocities, and with angular velocities inversely proportional to the circumferences, diameters, or radii, of the corresponding circles. In practice, thin frusta only of the cones, with teeth upon their perimeters, are employed; but in this there is no new consideration involved, as respects the angular velocities of the axes upon which the wheels are carried. In determining the size of a pair of bevels, we are not, however, limited to any particular diameters as when the axes are parallel; the wheels may be made of any convenient sizes, and the teeth consequently of any breadth, according to the stress they are intended to bear. The question, however, which presents itself here, is the mode of determining the relative sizes of the conical frusta of a pair; and this resolves itself into a division of the angle included between the two axes inversely as the ratio of their angular velocities. Let B and C be the position of the two given axes, and let them be prolonged till they meet in a point A. Further, let it be required that C make seven revolutions while B makes four. From any points D and E in the lines A B, A C, and perpendicular to them, draw Dd and E e of lengths (from a scale of equal parts) inversely as the number of revolu- tions which the axes are severally required to make in the same unit of time. Thus, the angular velocity of axis B being 4, Fig. 2016, and that of the axis C being 7, the line Dd must be drawn = 7, and the line Ec=4 Then through d and B parallel with the axes A B and A C draw d and till they meet in 100 Digitized by Google 794 GEERING. c. A straight line drawn from A through c will then make the required division of the angle B A 0, and define the line of contact of the two cones, by means of which the two rolling frusta may be pro- jected at any convenient distance from A. Otherwise, having determined the relative perimeters, 2016. diameters, or radii, of the pair, then the lines D d and E are to each other directly as these quantities. The point c may also be found more directly thus: From A towards C in the axis A C, set off from a scale as many equal parts (Af) as there are units in the number (7) ex- pressing the velocity of that axis; from the point f draw fc parallel to A B, and set off from the same scale as many parts (fc) as there are units in the number (4) ex- pressing the velocity of the axis A B; then a line drawn from A through c, as before, will divide the angle, as required. By one or other of these methods the division of the angle of inclination of the axes may always be determined, the ratio of the angular velocities of the pair being known. The case in which the axes are neither parallel nor inter- secting, admits of solution by means of a pair of bevels upon an intermediate axis, 80 situated as to meet the others in any convenient points. Thus, if DF and EG, Fig. 2017, be the two given axes, they may be connected by a third axis FG intersecting them in the points F and G; and if a shaft be mounted in the posi- tion of this third axis with a pair of bevels upon it, geering with the bevels on the main axes, and having their apices in the points F and G of these axes, the motion of the driving- shaft will be communicated, as if the two bevel-wheels C and M were in immediate contact; the ratio of their velocities remaining the same, provided the bevels H and K be of the same size. If it be re- quired to bring up the speed or reduce it, between the two shafts, in a higher ratio than is convenient by that arrangement, the interposed bevels will afford additional facility of accomplishing the purpose. When the contiguity of the shafts is such as to per- 2017. mit of their being connected by a single pair, skewed- bevels are frequently employed as shown in Fig. 2010; and as respects the relative velocities of a pair of this kind, it is evident that the same law obtains as in the F preceding cases. When the axes are at right angles to each other, and H do not intersect, the wheel and screw may be em- ployed to connect them. The velocity of angular c motion is in this arrangement immediately deduced from that of the screw, its number of threads, and the number of teeth in its geering wheel. Thus, if it be required to transmit the motion of one shaft to another contiguous, and at right angles to it-the angular mo- tions being as 20 to 1; then, if the screw be a single- threaded one, the wheel must have 20 teeth; but if double-threaded the number of teeth will be increased M to 40, for 2 teeth will be passed at every revolution. If the velocities be as 2 to 1, the condition is, that the screw have half as many threads upon its barrel, as D there are teeth on the wheel; and if 1 to 1, the wheel and screw lose their distinctive characters: both be- come many-threaded screws under the form of wheels, E as represented by Fig. 2011. Wheels of this sort may often be applied with peculiar advantage, especially in light geering; and when 80 applied it is not essentially necessary that the axes be at right angles to each other any more than it is in bevel-geer. If the screw have few threads compared with the number of teeth of the wheel, it must always assume the position of driver on account of the obliquity of the thread to the axis; and in this respect its action is analogous to that of a travelling rack, moving endwise one tooth, whilst the screw makes one revolution on its axis. On the pitch of wheels.-The primary object aimed at in the construction of toothed-geer is the uni- form transmission of the power, supposing that to be constant and equal This implies that the one wheel ought to conduct the other, as if they simply touched in the plane, passing through both their centres. This plane is denoted by the line A B, in Fig. 2018. When this line-which is usually denominated the line of centres-is divided into two parts. A c and Bc, proportional to the number of teeth formed upon the perimeters of the pinion and wheel, these two parts are proportional or primitive radii of the pair; and a circle CC being described from each centre passing through the common point c, limite what is called the pitch line or circle; that is, a circle de- scribed from the centre A, and another from the centre B, through the same point, are called, the first, the pitch circle or pitch line of the pinion, and the other of the wheel. They are also sometimes called the primitive and proportional circles. If the pitch circle be divided into as many equal parts as there are teeth to be given to the wheel the length of one of these parts is termed the pitch of the teeth. Digitized by Google GEERING. 795 One of these arcs, as that intercepted by pp in Fig. 2018, comprehends a complete tooth and space, meaning by space the hollow opening between two contiguous teeth. B C R R 2018. By the pitch lines of a geering pair is, therefore, to be D P X N N X understood the proportional circles in which they would * revolve upon each other if they were simply cylinders Pitch in inches RULE.-To And the RULE. -To find the without teeth; and the pitch of the teeth is the length and parts of an diameter in inches, number of teeth, mul- inch. multiply the number tiply the given diam- of are of the pitch circles, measured from the centre of of teeth by the tabu- eter in inches by the one tooth to the centre of the contiguous one. Any right lar number answer- tabular number an- ing to the given pitch. swering to the given lines, P and P, drawn from the centre of the wheels till pitch. they meet the pitch circles or lines, are termed propor- tional radii, because they determine the relations of their P * Values of P Values of Values of angular velocities; and any similar radial lines, P' and * P P', continued to the extremities of the teeth, are called the true radii of the wheel and pinion-for no very ob- 6 19095 5236 vious reason. In bevel and conical wheels the pitch cir- 5 15915 6283 cle is the base of the frustum, as AB of Fig. 1997. 41 14270 6981 Rules.-L To find the pitch of the teeth of a wheel, 4 1.2732 -7854 the diameter and number of teeth being given, divide 31 1.1141 8976 the diameter D, (in inches,) by the number of teeth N, 8 9547 10472 and multiply the quotient by 3.1416: the product is the pitch in inches or parts of an inch. 21 8754 1-1333 II. To find the diameter of a wheel, the number of 21 7958 1.2566 teeth and pitch being given, divide the pitch by 3-1416, 21 7135 1'3963 and multiply the quotient by the number of teeth. 2 6366 15708 III. To find the number of teeth, the diameter and pitch being given, divide 3.1416 by the pitch, and multi- 1½ 5937 1.6755 ply the result by the diameter in inches. 11 .5570 1.7952 In ordinary geering the pitches most commonly in use 13 5141 1.9264 range from 1 inch to 4 inches, increasing up to 2 inches 1f .4774 2.0944 by eighths, and beyond by fourths of an inch. Below 1] 4377 2.2848 inch, the pitches decrease by eighths down to t inch. 11 3979 2.5132 The pitches being few and definite, the rules given 1f 3568 2.7926 above may be greatly simplified by the use of the an- 1 3183 3.1416 nexed table, which will be found very convenient when the diameter D is to be determined, the pitch P and number -2785 3.5904 of teeth N being given; and conversely, when the diame- 4 2387 4'1888 ter and pitch are given to find the number of teeth. a 1989 50266 The use of this table may be rendered obvious by the 1592 6.2832 following examples :- 1 -1194 8.3776 1. Given a wheel of 88 teeth, 21-inch pitch, to find the 0796 125664 diameter of the pitch circle. Here the tabular number in Digitized by Google 796 GEERING. the second column answering to the given pitch is 7958, which, multiplied by 88, gives 70.03 for the diameter required. 2. Given a wheel 33 inches diameter, 14-inch pitch, to find the number of teeth. The corresponding factor is 1.7952. which multiplied by 33 gives 59-242 for the number of teeth, that is, 591 teeth nearly. Now, 59 would here be the nearest whole number; but as a wheel of 60 teeth may be preferred for convenience of calculation of speeds, we may adopt that number and find the diameter corresponding. The factor in the second column answering to 11 pitch is .557, and this multiplied by 60 gives 33.4 inches as the diameter which the wheel ought to have. A mode of sizing wheels in relation to their pitches, diameters, and numbers of teeth, is adopted in some engineering factories as a simplification of that explained above. Suppose the diameter of the pitch circle to be divided into as many equal parts as there are teeth to be given to the wheel; let one of these parts be called the diametral pitch, to distinguish it from the circular pitch hitherto employed, and let a few definite values (in terms of the inch) be assigned to it; then it is clear, that calling M the diametral pitch, we have the relation N=M And as M is always a simple fraction of an inch, let M=1/, then we have the general expressions, N N=mXD D=N To illustrate this by an arithmetical example, let it be assumed that a wheel of 20 inches diameter is required to have 40 teeth; then the diametral pitch, that is, the diameter being divided into equal parts corresponding in number to the number of teeth in the circumference of the wheel, the length of each of these parts is 1 an inch, consequently m = 2; and according to the phraseology of the workshop, the wheel is said to be one of two pitch The circular pitch corresponding to this diametral pitch is by the properties of the circle 3 X 3.1416 = 1.5708 inch. In this mode of sizing wheels a few determined values are given to m, as 20, 16, 14, 12, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, which includes a variety of pitches from 16 inch up to 3 inches, according to the following table, which shows the value of the circular pitches corresponding to the assigned values of m. Values of m. 1 2 3 4 5 6 7 8 9 10 12 14 16 20 Corresponding circular pitch in decimals of an in. } 3.142 1.571 1047 -785 628 524 449 393 .349 314 .262 .224 -196 .157 From this table, having the value of m given, the corresponding circular pitch is found; and from the rules given above, if the number of teeth and value of m be known the diameter of the wheel is also known, for D=N÷m. Thus if the number of teeth be 80 and m = 10, then the diameter D=8 inches, and the circular pitch is 314 inch, that is, 5-16th inch very nearly. Generally, the diameter and value of m being given, the number of teeth is found from the rule N =m X D. Thus the value of m being 10, and the diameter 20 inches, the number of teeth is 200. From these remarks, it is easy to perceive that this mode of sizing wheels differs from that before explained simply in this, that it expresses in small whole numbers the quantity * | P instead of the quan- tity P, and therefore affords a ready way of calculating the diameter and number of teeth of any re- quired wheel. This method, however, has not hitherto been introduced into millwright work; but has been confined to the sizing of small wheels of spinning and like machinery. It has long been regarded as a rule among millwrights that the number of teeth in a wheel should be prime to the number of teeth in its pinion; in other words, that the number of teeth of the wheel should not be divisible by the number of teeth in the pinion without a remainder; and that the best possible relation of the numbers is such, that in effecting the division the remainder be 1. This one is termed a hunting tooth, and effects the purpose of preventing the same pair of teeth of the wheel and pinion from coming together until the former has made as many revolutions as it has teeth. By such an arrangement it is supposed the wear would be less uniform; and it may be observed, that if the teeth be at first incorrectly made, there is some advantage to be gained by taking prime numbers. But in the practice of the present day, when millwrights are fully alive to the method and advantages of giving to the teeth, in the construction of their wheel-patterns, the proper geometrical form. and do not trust to the wheels wearing themselves into shape, the precaution of making the numbers of the wheel and pinion prime to each other, is less required, and may, in fact, be disregarded in proportion as accuracy of construction is attained. In respect of the relative sizes of the pairs which geer together, the main purpose to be accomplished is the modification of the contemporary velocities of the parts to such extent that their respective speeds shall be adapted to the work to be performed at the several points. To exhibit the method of applying the principles of angular velocity to the computation of the num- bers of a system of toothed geering, we shall consider, in the first place, the action of a single pair. The fundamental proposition may be stated thus :-If there be an equal pair in geer, then whether the pinion drive the wheel or be driven by it, the number of turns of the wheel multiplied by the number of its teeth, is equal to the number of turns which the pinion makes in the same time, multiplied by Digitized by Google GEERING. 797 the number of its teeth, so that the number of the contemporary turns of the wheel and pinion are re- ciprocally proportional to the numbers of their teeth. Applying this principle to a system of geering, we deduce the following rules: To find the number of revolutions of the last pinion of the system, multiply the number of revolutions of the first wheel by the quotient which is found by dividing the continued product of the numbers of teeth of all the wheels, by the continued product of the numbers of teeth of all the pinions. It thence also follows that the number of revolutions of the last pinion, for one revolution of the first wheel, is equal to the product of all the wheels divided by the product of all the pinions. And conversely for one revolution of the last pinion, the first wheel will make that portion of a revo- lution expressed by a fraction, having for its numerator the product formed by multiplying together the numbers of the teeth of all the pinions, and for its denominator the product formed by multiplying to- gether the numbers of teeth of all the wheels. From these rules it immediately follows, that whether a system of geering contains one wheel and pinion, or any greater number of wheels and a like number of pinions, if we designate the product of all the wheels by W, and the product of all the pinions by P, and if p represent the number of revolutions made by the last pinion during one revolution of the first wheel, we shall have W In reference to the strength of the teeth of wheels, the first subject of inquiry is the stress they are severally required to sustain when in action. The fundamental principle involved in the consideration of this subject, is expressed by the condition that the pitch being the same, the stress is inversely as the velocity; and this is obviously true, since the teeth which act with superior force must be proportionally stronger; and the momentum of the power remaining constant, the higher the velocity becomes, the more is the weight of the power diminished, 80 that in any combination of wheels, the stress upon the teeth is reciprocally proportional to the ve- locity at a given point of the train. Thus, the strength which is sufficient to transmit a given amount of horse power, when the velocity is one foot per second, will be equal to the transmission of double that amount when the velocity is two feet a second, three times the amount when the velocity is tripled. Knowing therefore the strength of teeth necessary to transmit a given amount of horse power, the same strength of wheel will be sufficient under any other circumstances of increase, or diminution of velocity, when the horse power of the first mover in both cases, divided by the velocity in feet per second, pro- duces the same quotient. Thus assuming as the standard the received mechanical unit of a horse power, namely, 33,000 pounds raised one foot high in a minute, or 550 pounds raised one foot in a second, then if H be the number of horses' power of any first mover, and v the velocity of the pitch circle (in feet per second) of any wheel in the system of geering moved by it, then the stress will be expressed in pounds by 550 X H v For example, if the pitch line of a wheel move with a velocity of 11 feet per second, and the power of the prime mover be twenty-horse power, the stress will be 550 11 X 20 = 1000 pounds. Otherwise, if P be the power of the prime mover in pounds, and V be the velocity of that power it feet per second, the stress on the teeth of a wheel through which the power is transmitted, and of which P X V the velocity of the pitch circle is v, will be expressed in pounds as before, by v It is necessary, however, to be observed, that the absolute power of the prime mover must only be considered at those points of the geering through which it is wholly transmitted; for if the power be taken off at different points, it is obvious that the stress will be successively diminished as these points are passed. For instance, the power of a steam-engine being employed to drive a cotton factory if the first geering be 80 arranged that the whole power of the engine is transmitted from the fly-wheel shaft to a vertical shaft, which ascends from the bottom to the top-flat of the building, by a bevel pair, and if the geering of the several flats be successively connected with this upright shaft, it is clear that, in esti- mating the stress at the several points, with a view to ascertaining the requisite strength of the several pairs, the whole power of the engine ought to be taken only at the first point; that is, at the point where it is connected with the vertical shaft. In estimating the strength of the bevel pair there placed, H, in our formula, will be equivalent to the whole power given off by the engine; but at the successive points, where the power is taken off to drive the machinery of the several flats, H will represent only the amount of power requisite to do the work at these points. A difference is besides very properly made in practice, in the strength of those wheels of a system of geering which are placed near the first mover, to compensate for irregularities in the motion; for were the strength exactly limited to the resistance to be overcome under constant action, a sudden accelera- tion of the speed would tend to stripe the wheels, in other words, to break the teeth. Also in operations of an irregular kind, the strength ought to be greatly more than is requisite in such geering as that of a cotton factory. Thus the geering in iron-works, and the like, is greatly beyond the strength which a calculation of the power of the prime mover would indicate, and this is required to counteract the sud- den shocks which result from the chocking of rolls and the like. It may also be necessary to remark, that, in estimating the strain upon a system of geering, it is the actual power required to do the work which is to be taken as an element of the data-that is, the horse power at which the resistance is valued. Digitized by Google 798 GEERING. In the teeth of wheels, it is of importance that the whole be made of such strength as to sustain un- injured the greatest stress that is likely to come upon it in the course of working in the worst possible position; that is to say, in the direction in which the 3 structure is capable of offering the least effective resist- D ance to fracture. Now supposing the strain to act with its whole energy upon the extreme corner of a tooth, it is easy to perceive that it will there more readily pro- 2019. duce fracture than if it acted along the whole line of the breadth; for supposing it to act along the whole line of B breadth, if fracture of the tooth should take place, it must traverse the whole line A B, or some line parallel to it; but acting at D, should the force be sufficiently great to break the tooth, the fracture will take place, not along the root of the tooth A B, but in the line B b, or in some line parallel to it-these being the lines of least resistance. Rather, under the circumstances of the force being applied at D, the strain will be greatest along the line Bb, which is defined from BD=Db. To show that this is strictly true, let it be borne in mind that the strength of beams of equal thickness is directly as their breadths, and inversely as their lengths; consequently, if the proportion of the length to the breadth be preserved, the strength will remain unaltered whatever difference is made in the actual dimensions. But this being true, it necessarily follows that the line of fracture, under the cir- cumstances presumed, will be along the line which, as a base, bears the least proportion to the perpen- dicular height from that base to the point where the pressure is applied. This least proportion is when B D = D b, for the base Bb is then only double the effective length of the beam, that is, double the perpendicular e D. If a line be drawn from B to d, it will manifestly be more than double the altitude of the triangle B d D, of which it is the base ; and, similarly, the line B c is more than double the alti- tude of its triangle B c D. This might be directly proved by application of the rules of maxima and minima rather, it might be shown that the strain is greatest under a force acting at D, in a line determined by DB=Db, which makes B b = 2 e D. In effect, therefore, the line Bb (including all lines parallel to it) is the line of least resistance of the tooth, and consequently the line in which fracture would be produced by a force sufficiently great ap- plied at D. Presuming, then, that wheels, in consequence of inaccuracy of workmanship, unequal wearing of brasses, vibration of shafts, and other circumstances incidental to the action of a system of geering, are liable to stress acting upon them in the least efficient position of the teeth, it would appear that the effective proportion of the breadth of the tooth, assuming the thickness to be uniform, does not exceed twice the length. Whatever may be the force, the principle informs us that there is a limit be- yond which no strength is practically gained, and this limit will be found in general not to differ materially from double the length of the tooth. It must not, however, be inferred from this that it is useless to make the breadth of any proportion greater than that stated for although no additional practical strength be gained by increase of breadth, it is still highly advisable that the dimensions named should bear a much higher ratio, than is given by the consideration of the merely mathematical principle. This is accordingly followed in practice, and the advantage is, that the wearing action, by being distributed over a larger surface, does not so soon reduce the thickness, and thereby render the wheel too weak for the work it has to perform. Moreover, there is the additional advantage in giving more breadth than is indicated above, that the surfaces OI contact being longer, vibration is to some extent diminished; the centres are accordingly better pre- served, and the wearing of the tooth becomes greatly more uniform. An error of workmanship, and of unequal contraction of the casting, becomes likewise more apparent, and may possibly admit of correction. 2020. Ox3 P P As it is convenient to express all the dimensions in terms of the same unit, and the pitch being an appropriate quantity, is nearly universally adopted as the term of comparison. These proportions differ, though slightly, in different works and in different localities; but they are the most commonly employed, and are besides the most consistent with good and accurate workman- ship. For the sake of more easy reference, we collect them into a table, which the annexed Fig. 2020 will serve fully to explain. They stand thus: Digitized by Google GEERING. 799 = Pitch of teeth, = 1 pitch. " ac = Depth to pitch line, PP, = a X a = Working depth of tooth, = 6 " " C - A a = Bottom clearance, = 10 " Ca= Whole depth to root, = 10 " Cb = Thickness of tooth, = " b = Width of space, IT These proportions, as remarked, are found to work very advantageously, and are those adopted in several workshops; but the following are preferred by some engineers of experience. Thus supposing the pitch divided into 15 equal parts: then the Depth from point to pitch line, = 53 parts. Depth from pitch line to root of tooth, = 61 of Whole length of tooth, = 12 " Working depth, = 11 as Thickness of tooth, (also of arms and rim,) = 7 " Width of space, = 8 " . In practice, these proportions are usually laid off in lines for the convenience of the workmen in the pattern shop, so that for any given pitch the other dimensions may at once be determined by means of the compasses, and without having recourse to calculation. In Figs. 2021 and 2022 two diagrams of that sort are given. Fig. 2021 contains the proportions last enumerated, in which the pitch is supposed to be divided into 15 equal parts; and Fig. 2022 is constructed nearly according to the proportions first given, but embraces the recognized principle that the relative amount of clearance ought to vary inversely as the pitch, wheels of small pitch requiring more clearance relatively than those in which the pitch is greater. Accordingly, in this scale, the clearance in a wheel of 4-inch pitch is 1-10th the pitch, whereas were the scale sufficiently extended, it would show a clearance of only 1-18th for a pitch of six inches. The construction of these scales is very simple. Thus in Fig. 2021, and to six inches pitch, let A B be divided into 15 equal parts, and draw BC perpendicular to it; and again divide BC into a determinate number of parts from B, actual measures of the pitches for which the scale is intended to be used that is, B a = t inch; Bb = 1 inch; B = 2 inches, and so on, and join a and A, b and A, e and A, and so on. To complete the scale, draw 15 parallels to BC from the points numbered in the line A B, numbering their intersections (if thought proper) with the line A C in the same order; and also the two parallels T and U, (which are full lines in the diagram,) equidistant from the parallels on each side of them. The scale is thus ready for use, and its principle is evident. To get from it the several propor- tions for a given pitch, say of 8 inches = Bd, let the compasses be extended from the intersection of the parallel marked T, with the line A B, to the point where it intersects the line A d; this will be the part of the tooth from the pitch line to the point, and equivalent to 57 parts of the pitch, (viz. of B d;) sim- ilarly the compasses being extended from the intersection of the parallel U, with the line A B, to its point of intersection of the line A d, will give the part of the length of the tooth from the pitch line to the root, and equivalent to 61 parts of the pitch. For the whole length of the tooth (if wanted in one measurement) set the compasses to the point where the parallel marked 12 meets the line A B, and extend to its point of intersection of the line A d at 8, the length is 12 parts of the pitch Bd; the work- ing depth is in like manner found from the parallel marked 11; the thickness from that marked 7; and the width of space from that marked 8. The proportions for any other given pitch comprised in the scale are found in precisely the same way, and if the scale be well constructed they may be measured off with the utmost accuracy and readiness. To save confusion it is, however, better in practice to insert in the diagram only those parallels, namely, T, U, 12, 11, 8, 7, which are required the others are not requisite, and by inattention may lead to error. Both this scale and that marked 2 are commonly drawn on hard-wood boards; but sometimes, for the sake of greater accuracy, on plates of polished brass. The description of the scale as here given supposes that the lateral clearance is constantly 1-15th of the pitch; but as it is commonly desired and desirable that this should vary slightly with the pitch, relatively increasing as the pitch decreases, two other lines, m n and pq, have been introduced into the scale, to enable such modification to be adopted, should it be required. These lines are drawn at such angles as to give a clearance at 6 inches pitch of 1-18th, which is increased at 4-inch pitch to 1-10th. From these lines the thickness and space are to be taken, instead of using the lines marked 7 and 8, setting the compasses in the points of intersection with the pitch lines, and extending perpendicularly to the line A B; in other words, the shortest distance from the point of intersection with the pitch line to the line A B, is the required measure of the space when the line pq is taken, and of the thickness of tooth when the line m n is taken. Fig. 2022 is more complete than the one described, and when well constructed insures, with moderate care, a degree of accuracy and uniformity, in the construction of the various sizes of wheels for which it is employed, that can hardly be otherwise attained. The principle of its construction is in effect the same as that described, but its use is more extended; the diameter of the wheel being found from it simultaneously with the length and thickness of tooth, width of space, and clearances. The scale is adapted to wheels of all the pitches enumerated in the table, p. 795, from 1 inch up to 3 inches. The mode of construction is this: having drawn the line AD of any convenient length, raise the perpendic- ular CB to it, also of any convenient length. On the line A D lay off the greatest pitch of the scale from C to A; then from C towards D lay off seven times the pitch once or twice, according to the sizes of wheels to which the scale is intended to be applied. In the scale given, double of seven times the Digitized by Google 800 GEERING. pitch is laid off, namely, 42 inches; then each of these great divisions being subdivided into 11 equal parts, one of these parts will be equal to four teeth upon the radius of the wheel, so that the whole line CD will be divided into 88 radial pitches. Next on the line CB set off the pitches which may be re- quired in the scale, and through these points draw the 24 parallels to A D, terminating in the lines A B and DB. Then each parallel measured from the line BC to its point of termination in BD, is the radius of a wheel of 88 teeth of the particular pitch marked against it on the line AB. They also express the radii of wheels having less than 88 teeth when measured only to the corresponding point in the line joining B, and the divisional on CD, against which the number of teeth is marked. Thus the radius of a wheel of 52 teeth and 1 f-inch pitch, is T8= 15 7-16th inches very nearly. (The true answer by the table, p. 795, is 308724 ÷ 2 = 154362 inches.) PROPORTION SCALES FOR GEERING. a b c d 2021. B 1/1% 1 1½ 2 2½ 3 3½ 15 4 4½ 5 5½ C B 2022. ½ 14 1/4 13 % 12 1/2 % 11 % 10 ½ 9 1 P 1½ 8 1 1% n 7 m 1% 0% U/ 0 1½ 6% 1% 5 1% 4 1% 3 2 2½ 2 2% , 2% 2½ A 2% 2% 2% D A 88 84 8:0 7.6 72 68 61 GO 5.6 52 48 44 40 36 3 : 2:8 24 20 1,5 12 8 4321 all 22 21 20 19 18 17 16 15 11 13 12 11 10 9 8 7 6 5 4 3 12 1 14 13 12 11. 10 9 S 7 6 5 4 3 2 1 The scale may also be used when the number of teeth exceeds 88; for example, to find the radius of a wheel having 100 teeth. Thus having found the radius answering to 88 teeth, upon the same parallel take off the measure answering to the difference 100 - 88 = 12 teeth; and the two measures together will be the radius required. To adapt the scale to odd numbers of teeth, the first division on the right of C is divided into single radial pitches, 80 that the radius of any wheel may be measured off without baving recourse to calcu- lation of any kind. Thus, for example, if the wheel is intended to contain 50 teeth, the compasses being Digitized by Google GEERING. 801 extended from 52 to the intersection of the parallel answering to the particular pitch to where it meets the line joining Q and B, will give the radius required, that is, a radius answering to 52 - 2 = teeth; and any other number of teeth when not marked against the base may be found in the same way, ob serving that it is more convenient to subtract than to add in this use of the scale. For the proportions of the teeth, set off a = 7-tenths of the pitch, then will A a = 3-tenths of the pitch, which corresponds to the depth from the point of the tooth to the pitch line. Again, set off = 7-fifteenths of the 3-inch pitch, and 5-elevenths on the parallel against the 1-inch pitch; this will be the thickness of the tooth, allowing from a fifteenth for clearance on the largest pitch, to a tenth on those from f-inch and under; and A b will be the width of space, including the clearance. Lines being drawn from those points to B complete the diagram, which will be found to contain all the proportions enumerated in the preceding table. To use the scale, lay off the addendum of the tooth; that is, the length beyond the pitch line, equal to A a = in pitch, and the same length marked off within the pitch line will give the whole working depth of the tooth, namely, 6-10ths pitch. Then with the measure C a = T⁷₀ pitch in the compasses, mark off the whole length of the tooth, and this will allow 1-10th at bottom for clearance. Again, set off the thickness of tooth = C b, and the space = b which will contain the clearance for the particular pitch, varying from 1-15th to fully 1-10th on the small pitches. It is hardly necessary to observe that these measurements must be taken upon the parallel corresponding to the particular pitch under con- sideration at the time. The amount of bottom clearance is here presumed to be uniformly 1-10th of the pitch; but if it be thought advisable to make this vary as in the case of the lateral clearance, it will then be necessary to insert a third line c B in the scale, and 80 related to a B that the space a c shall be throughout equal to the depth of tooth from the pitch circle to the root, and giving any bottom clearance that may be desired. In relation to the strength of wheels, M. Morin, in his Aide Mémoire de Mécanique Pratique, gives it as a rule that when the velocity of the pitch circle does not exceed five feet per second, the breadth of the tooth measured parallel to the axis ought to be equal to four times the thickness; but when the velo- city is higher the breadth ought to be equal to five thicknesses, the teeth being constantly greased. If the teeth be constantly wet, he recommends the breadth to be made equal to six thicknesses at all velocities. With respect to the thickness of the tooth, it is plain that it must be dependent on the pressure which the tooth is required to sustain. This relation may be conveniently expressed for all cases by the formula, = o W. where t is the thickness of the tooth, W the pressure upon it in pounds, and c a constant multiplier depending upon the nature of the material of which the tooth is formed. Therefore for cast-iron c = 025; and reasoning in the same way for brass, we find it = 035 for hard wood, = 038; so that for the thickness of teeth of these materials, we have, For cast-iron, t=025 √W For brass, t=035 √W which give t in inches or parts of an inch, For hard wood, = 038 W W being taken in pounds. As an example of the application of these formulæ, let it be required to find the thickness of a tooth (cast-iron) which is to sustain a pressure of 4000 pounds at the pitch circle, the breadth being double the length. Here W = 4000; therefore W = 63.25. Hence t = 025 W = 025 X 63.25 = 1.58 inch. The same calculation applied with the formula for brass, would give t = 2.21 inches; and for wood it gives t = 2.4 inches. The thickness of tooth given by our rules is intended to make allowance for wear at a velocity of three feet per second, and has been found to be sufficient in practice. It is, however, less by a small fraction than would be found by application of Mr. Tredgold's rule; that is, divide the stress at the pitch circle in pounds by 1500, and the square root of the result is the thickness of the tooth in inches. To compare this rule with that given above we subjoin the following table, which will likewise be found useful in calculating the strength of wheels. Thickness of teeth. Stress in lbs. at Actual pitches to Corresponding thickness, al- the pitch circle. By Author's which the wheels By Tredgold's would be made. lowing 1-10th for clearance. rule. Rule. lbs. Inches. Inches. Inches. Inches. 400 0.50 0.52 1g to 11 0536 to 0.593 800 0-71 0-75 11 - 11 0.714 0774 1200 087 0.90 11 - 2 0.893 0.952 1600 100 103 2 - 21 0.952 1012 2000 1.12 1.15 24 - 21 1031 1.132 2400 1.22 1.26 21 - 21 1.190 1.250 2800 1'32 1'86 21 - 21 1.250 1.309 3200 141 1'43 21 - 8 1'369 1429 3600 150 1.56 31 - st 1-488 1548 4000 1.58 163 31 - 81 1548 1607 4400 1·66 170 31 - 31 1607 1.667 4800 178 178 31 - 84 1667 1.726 5200 180 186 31 - 34 1726 1.786 5600 187 193 34 - 4 1-786 1.904 6000 194 200 4 - 41 1904 2024 101 Digitized by Google 802 GEERING. The last column of this table is calculated from the expression pitch t. = (2 + to) = 2.1t. the clear- ance being a tenth. The thickness, allowing 1-15th for clearance, may in like manner be calculated from the expression pitch = t. (2 + 1'3) = 2067 The formula reduced to expressions giving the pitch p in the same manner as the thicknesses are given above, will stand thus :- Clearance a tenth. Clearance a fifteenth. For cast-iron teeth P 0525 W and p = 0517 W. For brass teeth 0735 W and p = 0723 W. For wooden teeth p = 0798 W and p = 0785 W. By means of these rules the pitch may be directly calculated. Thus, for a pressure of 15,000 pounds we have, W = 15,000 = 122.5. Consequently, the pitch of a cast-iron wheel capable of sustaining that pressure at the pitch circle, allowing 1-15th for clearance, will be 0517 W = 0517 X 122.5 = 6'333 inches. The wheel from which this example is taken has been several years in action, and has an actual pitch of six inches, and the mean pressure at the pitch circle is 14786 pounds. It may be here observed that it is common, in calculations relative to the strength of the teeth of wheels, to make additional allowance for wear of the pinion; for if the pinion make double the number of revolutions made by the wheel with which it is engaged, its teeth will manifestly be subject to double the amount of wear by friction; consequently, to proportion the teeth of the pair 80 that they shall wear equally long, it is necessary to give an allowance of thickness on those of the pinion equivalent to the increase of abrasion to which they are subject. If we assume one-third the thickness as the proper allowance, this will give for the thickness of the pinion the expression 3 , in which n is the number of revolutions which the pinion makes for one revolution of the wheel, and t the thickness of the teeth of the wheel. Thus, for example, if the pinion make 21 times as many revolutions as the wheel, of which the thickness of the teeth is 1-12 inch, then the thickness of those of the pinion will be 3 3 = 168 inch. This amount of difference, is not, however, commendable in practice. at least in spur-geer, and it is therefore rarely adopted, as wheels would in that case require to be constantly made in pairs, which would lead to an endless accumulation of wheel patterns. Instead of making the allowance spoken of, the common practice is to adopt a larger pitch-rather, indeed, to use wheels somewhat beyond the strength which is requisite for the work. It has already been shown that by a horse power is meant a pressure of 33,000 pounds moved with a velocity of one foot in a minute. But this is the mean of the force exerted, and as most prime movers are more or less variable in their motion, any wheel required to transmit that motion should be strong enough to bear the maximum force with safety. For ordinary and general purposes we may assume, as a very safe approximation, that it exceeds the mean of the whole force exerted by the fraction 3-11ths. Making that allowance, we shall have, as the practical strain of a horse power, 550 lbs. X 1 = 700 lbs. raised one foot per second. By substitution of this value of the horse power, in the rule formerly given, it will become '700 X H = the stress on the teeth of the wheel in pounds. v As an example, let a steam-engine of 12-horse power be applied to drive the machinery of a factory. and let it be required to find the strength of the teeth of a first wheel on the main shaft, which will have a velocity of four feet a second, at the pitch circle. Here H = 12 and v=4; therefore 700 X H = 700 4 X 12 = 2100 lbs., the pressure at the pitch cir- cle = W in the rule for the thickness of teeth. Now the square root of 2100 is 45826, and supposing the wheel to be of cast-iron, then we have = 025 W = 025 X 45826 = 1.1456 inch, the thickness of the teeth of the wheel; consequently, if 1-10th be allowed for clearance, the pitch wil be 1.1456 X 2.1 = 252 inches. The actual pitch would therefore be made from 21 to 21 inches. If the wheel have wooden teeth, then the rule t = 038 W must be used, which gives 1.74 inch as the thickness of tooth, and 3.66 inches as the pitch; the pitch to be adopted would therefore be 31 inches. When cast-iron and wooden teeth work together, their action upon each other tends, in consequence of the elasticity of the wood, to maintain a more uniform distribution of the strain, and being at first commonly more accurately dressed, to prevent abrasion of the wood by the iron, they work with much less friction, are less liable to shocks, and nearly exempt from accident by hard particles coming be- tween the teeth. The best practice, when a mortise and iron wheel are to work together, is to make both of the same pitch, and in the first instance, of the same thickness of tooth-the pitch being of course calculated for the wooden wheel by the rule p = 0785 W, which allows 1-15th for clearance, (and with good work- manship this is amply sufficient in cases of the kind proposed afterwards to dress down the teeth of the iron wheel, by the chipping tool, or the wheel-cutting machine, and file, to the exact form and thick- ness, as given by the formula l = 025 W; that is, to a thickness in relation to the thickness of the wooden teeth, which shall have the ratio of 25 to 38. Both of the wheels will then be of the same Digitized by Google GEERING. 803 strength, and from their superior finish, will work with much less friction, and, consequently, less wear than if both wheels were of iron. If m be the number of revolutions to be made by the wheel in a minute, and n the number of teeth to be cut on it, and W the pressure upon each tooth in lbs., we shall have the following values of the pitch p in inches and parts of an inch, agreeable to the method adopted in the preceding rules, namely, H For 12 3 1728 cast-iron p = mn m H 2197 H For Brass P = 13 > or = p mn m n H 2744 H For hard wood = 14 or = p mn m Conversely, the power which the teeth of a wheel of given pitch are capable of transmitting may be readily calculated from the following rules, which are immediately deduced from the above: For cast-iron H = or 12' 1728 m For brass H p³ = or 13' 2197 For hard wood H = or 14ª 2744 Thus supposing the pitch p = 3 inches, the number of teeth n = 60, and the number of revolutions n which the wheel is designed to make per minute = 50; then the wheel being cast-iron, the power H which it is capable of transmitting will be H = 60 1728 50 = 47 horses' power nearly. This wheel is employed to transmit 45 horses' power at the given velocity, and has been at work for several years. Every writer on the teeth of wheels has thought it necessary to adduce rules for finding the proper breadth of the teeth. As respects strength, such a calculation has been shown to be in a manner un- necessary beyond merely doubling the length, which is immediately deducible from the pitch; and as respects durability there seems to be no theoretical limit to the breadth, for the more the pressure and rubbing action is diffused, the less rapidly will the teeth be worn. The breadth to be assigned in prac- tice must, therefore, be always a quantity to be determined by circumstances, and modified by the par- ticular opinions of those concerned; if the motion be particularly uniform and free of vibration, the breadth may be extended even to four times the pitch with advantage; but if the contrary circum- stances obtain, this great breadth will in like manner have a contrary effect, the teeth becoming fre- quently locked together, will more speedily wear out of shape if they be made too strong to twist and break one another out at the ends. When the shafting is light, this is a frequent occurrence, although the reason does not seem to be always understood; and accordingly, the remark is not uncommon, that the wheel ought on account of its great breadth to have been more than sufficient for the work. How- ever contradictory it may appear, strength in this sense is not an unfrequent cause of weakness and failure. Assuming that the teeth of wheels follow the same law of strength by increase of breadth as in thick- ness, and referring back to the general formula for the strength of a beam of given dimensions, we arrive at the conclusion that the breadth b and the length 1 are in the relation of b = & and suppos- ing with some engineers of experience that a breadth of 6 inches is sufficient for a power equivalent to 9 horses, when the pitch line moves with a velocity of 8 feet per second, then we have the following rule: Double the number of horses' power of the prime mover, and divide the result by the velocity of the pitch circle in feet per second the result is the breadth of the teeth in inches. Thus the power transmitted by a wheel moving at 51 feet velocity per second, transmits 16 horses' power; the breadth of the wheel will therefore be 2 51 16 5.5 5.82 inches nearly. Again, on the same principle, having the breadth and velocity of teeth given, multiply the velocity of the pitch circle in feet per second by the breadth of the teeth in inches, and half the product will be the number of horses' power which the wheel is capable of transmitting. Thus, let the breadth be 12 inches, and the velocity 21 feet per second; then 12 X 21 = 252, half of which is 126, the number of horses' power required. It is easy to see, however, that unless the breadth be a function of the pitch, any calculation of this kind cannot be satisfactory and from the remarks already made, there cannot exist such difficulty in fixing upon the proper breadth the wheel ought to have for the particular purpose intended. The following table may be useful in determining the relation of the dimensions of the teeth of wheels of the given pitches, and the power which they are capable of transmitting safely at the various speeds named. The table was originally constructed from the formula 2p"Xv 5 = H, and has since been extensively used. Digitized by Google 804 GEERING. Velocity of the wheel at the pitch circle. Thickness Length of Least Pitch. of teeth. teeth. breadth of teeth. 3 feet per 4 feet per 5 feet per 7 feet per 11 feet per second. second. second. second. second. Inches. Inches. Inches. Inches. H. P. H. P. H. P. H. P. H. P. 6 2.9 42 8·4 43 x 57 72 1001 158} 51 26 3.85 7.7 48 601 84to 133110 4 19 28 5.6 19 25 32 45 70 3½ 16 2.45 49 143 19 24 34f 54 3 1·4 2.1 42 11 14 18 25 39 21 12 1.75 3.5 71 10 12, 171 27 2 0.95 14 2.8 4 6} 8 11 17 13 0.83 1.225 2.45 3 5 61 81/ 13 1 0.71 1.05 2.1 2 31 4 6 10 1 0.59 0.875 1.75 2 2 3 4 64 1 0.53 0.7875 1.575 11 2 2 3 5 1 0.48 0.7 1.4 1 1 2 24 4 0.41 06125 1.225 1 1 13 2 34 0·36 0.525 105 7 1 1 2 0.33 0.4375 0.875 1 1 0'24 0.35 0.7 3 7 1 0.18 0.2625 0.525 3 0.12 0.175 0.35 3 To To find the power which a wheel is capable of transmitting for other velocities than those in the table :-For 6 feet per second, double the result given for 8 feet; for 8 feet double the result at 4 feet, and so on; and for lower velocities than those given, divide the tabular number by the ratio which they bear to those enumerated. Thus, for 21 feet velocity, take half the result at 5 feet, and so of other velocities. When a wheel and pinion, which differ very much in size, work together, the teeth of the latter, on account of their unequal thickness, are capable of sustaining much less pressure than the teeth of the wheel they are in effect, if not in fact, much reduced in thickness; and, in applying rules to the cal- culation of the strength of wheels, the difference of size of the pair ought not to be overlooked, unless, as is indeed very common in practice, the deficiency of strength be made up to the pinion by a flange cast on one or both sides of the rim, of the same depth as the teeth, and binding these together like the staves of a trundle. In this case the pinion is commonly the stronger wheel of the pair. In the construction of wheels, the problem which presents itself relative to the shape of the teeth is this, that the surfaces of mutual contact shall be so formed that the wheels shall be made to turn by the intervention of the teeth, precisely as they would by the friction of their circumferences. 2023. 2024. B c b c n T m Thus, if we take Fig. 2023 to represent two teeth of a pair of wheels of which that marked A is the driver; then it is plain that the faces of the teeth may be of such curvature in relation to each other, that as the circle A revolves and carries with it the circle B by their mutual contact at C, the teeth may continually touch one another throughout their lines of curvature, continually altering their rela- tive positions and their point of contact t, as the primitive circles change their point of contact; and this being true, it evidently follows that the two circles would be made to revolve by the contact of teeth, whose surfaces are thus formed, precisely as they would by the friction of their circumferences Digitized by Google GEERING. 805 at the point c. For observing the action of the circles upon each other, in the former case we find a series of points of contact passing through c, and bringing about a corresponding rotation of points of contact of the teeth at t; and in the latter case, the action being transferred to the teeth, the same transposition of the points of contact at t is followed by the same transposition of points, as formely, through c. To form teeth whose surfaces of contact shall possess the property here assigned to the curves of the teeth m m and nn, is the problem to be solved; and the solution is dependent on the following Fundamental principle.-In order that two circles A and B may be made to revolve by the contact of the surfaces of the curves m m and n n of their teeth precisely as they would by the friction of their circumferences, it is necessary and sufficient that a line drawn from the point of contact t of the teeth to the point of contact c of the circumferences, (pitch circles,) should in every position of the point t be perpendicular to the surfaces of contact at that point; that is, in the language of mathematicians, that the straight line be a normal to both the curves m m and n n. In proceeding to establish this principle, we must in the first place recur to a proposition, which in effect is that employed by the mechanic in the use of his templets for drawing in the curves of the teeth. Thus if we have two circles, as in Fig. 2024, described about A and B as fixed axes, and these circles be free to revolve by their mutual contact at T; then supposing A B the line of centres divided as usual in T, in the inverse ratio of the angular velocities of the circles; if the circle B be provided with a fine tracing point fixed into its circumference, and it be made to roll upon A, the point will describe the curve b. Again, if the curve a b continued to c be cut out of thin plate and caused to turn round the centre A, and the pin at b be carried by an arm round the centre B, the motion commu- nicated by the pin to the curve will fulfil the required conditions. For at the beginning of the motion let Te be the position of the curve, then the pin will coincide with T; and if the curve move into any other position a driving the pin to b, the arc Ta will be equal to Tb, and the path described by the pin in its motion will be that indicated by a b. But the ares T a and Tb are also those described by the two pitch circles respectively in moving from T to the second position, and since these equal arcs are described in the same unit of time, the angular velocity is not charged, but remains constant as if the motion had been produced by the rolling contact of the two pitch circles. 2025. 2026. B b DB e b d 1 a M A M A A further illustration of the same principle is afforded by Fig. 2025, in which A and B are centres of motion, as before, and T the point of contact of the pitch circles of the wheels. In this case, let the curve a c be described by a point b fixed in the circumference of a circle TbB, having for its diameter the radius BT of the pitch circle of the wheel B. From the centre B, let a radial line Bb be drawn, touching b and meeting the pitch circle in d. Further, let motion be communicated by contact from the edge a b c of the curve which revolves about the centre A to the radial line Bbd, which revolves about B, and let the beginning of the motion be reckoned from the position in which a coincides with T, and therefore d with a; then in moving to any other position of contact, the ares simultaneously described by the two pitch circles will be T a and Td. Now TB b is an angle at B, the circumference of the rolling circle, and TBd an angle at the same point, which is the centre of the pitch circle; there- fore Tb measures an angle double of Td. Also the radius Tb is half that of Td, consequently the are Tb=Td=Ta; that is, the arcs of the pitch circles measured from the beginning of motion are equal, and therefore the angular velocity ratio, as before, is constant and the same as would be obtained by the rolling contact of the pitch circles. To exhibit this principle in another point of view, let there be two circles having their axes in A and B, and their point of contact c as shown in Fig. 2026 then supposing that the circle B is made to roll Digitized by Google 806 GEERING. upon the circumference of A, a point in the circumference of the former will describe a curve a b; that they are applied by their axes to a third plane MM, into which their axes are fixed, and which has also an axis of motion coinciding with A; then it is evident if the plane M M be made to move while the circle on A is kept at rest, the circle upon B will be made to revolve upon the circumference of this last, and a point b fixed into its circumference will trace out a curve a b upon the plane M M, precisely the same as would have been described by that point, if the latter plane bad remained at rest, and the centre of the circle B had been set free from its axis, and been made to roll by its circumference on the circumference of A. This is obvious, and it is also obvious that, both circles being fixed by their axes to the plane M M, and the circle on A being made to revolve with an equal, but opposite angular velocity to M M, and which communicates its angular velocity to the circles A and B, these revolving meantime in respect to one another, and by the mutual contact of their circumferences precisely as they would if the plane M M were at rest, then the circle A being carried round by its own proper motion in one direction, and by the motion common to it, and the plane M M with the same angular velocity in the opposite direction, will in point of fact rest in space; and at the same time the circle B having no motion proper to itself, will revolve with the angular velocity of the plane M M, and all the points of that circle will have angular velocities compounded of their proper velocities, and the veloci- ties they receive in common with the plane M M; but these velocities being equal and opposite at the point c, will there neutralize one another. Now this point c is the point of contact of the two circles; so that while B revolves about A, the point c at which it is in contact with the latter is at rest; yet this quiescent point of the circle B is continually varying its position on the circumferences of the two circles, so that the circle B is thus made to roll on the circle A, which, in consequence of its own proper motion in one direction being neutralized by the equal and opposite motion it receives from the plane M M, is in reality at rest. It therefore appears that by communicating a certain common angular velocity to both the circles A and B about the centre A, the former is made to roll upon the latter at rest, and moreover that this common angular velocity does not alter the form of the curve b, which a point b in the circumference of B describes upon the plane M, that is, in effect upon the plane of the circle A; in other words, that the curve traced under these circumstances is the same whether the circles revolve about fixed centres by their mutual contact, or whether the centre of one circle be released and it be made to roll upon the circumference of the other at rest. And this shown to be true, the principle announced becomes evident; for if B roll on the circumference of A, it is evident that a point b will at any instant be de- scribing a circle about their point of contact c, and this being true, it likewise follows that the point b is at every instant of the revolution describing during that instant an exceedingly small circular are about c, and therefore is bc always perpendicular to the curve a b at the point b; in other words, it is always a normal to it. Now returning to Fig. 2023, let P be a point exceedingly near to t in the curve n n, which is fixed upon the circle B; it is evident from what has been shown, that as that point passes through the point of contact t of the two curves, it will be made to describe on the plane of the circle A an exceedingly small portion of the curve m m. But the curve which under these circumstances it describes, has been shown to be always perpendicular to the line tc, now the curve m m being perpendicular to that line at t, the point of contact with n n, that curve must likewise be perpendicular to it at the same instant, and consequently we have tc; a normal to both curves at the point t. This is the characteristic prop- crty of the two curves m m and n n by which they satisfy the condition of a continual contact with each other at the same time that the circles revolve by the contact of their circumferences at c; and con- versely, supposing the motion to be induced by the mutual contact of the curves, they will communi- cate the same motion to the circles, as these would receive by the mutual contact of their circum- ferences. The principle here announced, exhibits a special application of one particular property of that curve known to mathematicians as the epicycloid. The mode of generating it is that described, and that upon which a mathematical definition of it is founded. Thus generally when two circles are in contact at their circumferences, and the one is made to roll upon the other, any point beyond the centre in the moving circle describes during its revolution the particular curve named. This curve, as already stated, may be traced upon an immovable plane, against which a point in the moving circle is made to bear. For the sake of distinctness this is termed the generating circle, and the circle upon which it rolls is called the fundamental circle, and the portion of it on which the epicycloid rests is called the base. The definition of the epicycloid is rendered obvious by reference to Fig. 2026, in which B is the gen- erating circle, and A the fundamental circle of the epicycloidal curve a b. If the generating circle, in- stead of rolling on the outside, roll within the base circle, the curve is usually called an interior epicy- cloid; that generated when the circle rolls on the convex circumference, being termed for distinction an exterior epicycloid. An essential condition of the epicycloid is that the generating circle, in revolving from its first posi- tion to different other situations, as shown in Fig. 2026, applies successively all the parts of its circum- ference to those of the base; it is therefore evident that the base of the complete epicycloid is equal to the circumference of the generating circle, and each portion of its base as a is equal to the corres- ponding part c b of the generating circle by the rolling of which it is traced. Hence we have a method of drawing the epicycloid by describing a series of circles which have all the same, diameters as the generating circle B, and which all touch the base A then making the lengths of the arcs b taken from the points of contact with the base equal to the ares a of the base, we can readily determine the points of the curve, and consequently the curve itself. The epicycloid may be described by the compasses in the following manner. Let us in the first place take the exterior curve. Having divided the circumference A B D, Fig. 2027, into a series of equal parts 1, 2, 3, begin- ning from the point A; set off in the same manner, upon the circle A x A y, the divisions 1', 2', 3', Digitized by Google GEERING. 807 equal to the divisions of the circumference ABD. Then, as the circle ABD rolls upon the circle A x A y, the points 1, 2, 3, will coincide successively with the points 1', 2', 3'; and, drawing radii from the point 0 through the points 1', 2', 3', and also describing arcs of circles from the centre o, through the points 1, 2, 3, they will intersect each other successively 2027. at the points de, Take now the distance 1 to c, and set it off on the same arc from the point of intersection of the radius A C to t; in like manner, set off the distance 2 to d, B from b to и, and the distance 3 to e from a to v, and 80 on. Then the points A tuv, will be so many points in the epicycloid; and their frequency may be increased at pleas- 11 ure by shortening the divisions of the circular arcs. Thus the A form of the curve may be determined to any amount of accu- racy, and completed by tracing a line through the points found. As the distances 1 to c, which are near the commence- ment of the curve, must be very short, it may, in some in- stances, be more convenient to set off the whole distance t to 1 from c to t', and in the same way the distance b to 2 from x d to u³, and 80 on. In this manner the form of the curve is 0 the more likely to be accurately defined. A second method of finding the points in the curve is, in D the first place, to find the positions n, of the centre of the rolling circle corresponding to the points of contact 1', 2', 3', &c., which may be readily done by producing the radii from the centre O, to cut the circle EF. From these centres de- V scribe arcs of a circle with the radius of C A, cutting the cor- If responding arcs described from the centre o, and passing 1. A through the points t и v, as before. Two distinct portions of the curves are represented in combination 80 as to form the faces of a tooth of a wheel of which the primitive circumference is A x A y. When the moving circle A BD is made to roll on the interior of the circumference A x A y, as shown in the under part of Fig. 2027, the curve described by the point A is called an interior epicycloid. It may be constructed in the same way as in the preceding case. The first operation is to divide the two circles into equal parts, at the points 1, 2, 3, and 1', 2', 3', &c. Draw radii from the points 1', 2', 3', &c., to the centre O, and also ares of circles through the points 1, 2, 3, &c., from the same centre o, meeting the corresponding radii at the points de. Then by transferring the distances c to 2, d to 3, to the axis A D, as in the other case, we find a series of points t u v, which may be increased in number to any extent, and are points in the curve, through which, if a line be traced, the epicycloid will be formed. 2028. To determine the relation of the epicycloid and hypocycloid in D connection with the form of the teeth of wheels, let m p and p n, Fig. 2028, be respectively portions of these curves, having the same gener- ating circle c Pp and having for their bases the pitch circles c D c B and c E c of two wheels. If the faces of the teeth upon the cir- cumferences of these wheels coincide with these curves, it may be m shown that they will work truly together; for let them be in con- c 76 tact at p, and let their common generating circle be in contact with both pitch circles at c, then will its circumference manifestly P pass through the point of contact of the two teeth and if it were made to roll through an exceedingly small angle upon the point c, P rolling there upon the circumferences of both circles, its generating point would traverse exceedingly small portions of both curves. But since a given point in the circumference of the generating cir- cle is thus at the same instant in the perimeters of both the curves, that point must of necessity be the point p of the curves and since moreover the generating circle rolls upon the point of con- tact c, its generating point traverses a small portion of the perim- eter of each of the curves at p, it follows that the line cp is a normal to both curves at that point; for whilst the generating circle c P p is rolling through an exceedingly small angle upon c E the point p, it is describing a circle whose radius is cp. If the teeth of a pair of wheels have their edges formed to these curves, they will therefore satisfy the condi- tion that the line cp, drawn from the point of contact of the two pitch circles to any point of contact of the teeth, is a normal to the surfaces of both at that point, and this condition has been shown to be necessary and sufficient to the correct working of the teeth. From this then it appears that if an epicycloid be described on the plane of one of the wheels with any generating circle, and with the pitch circle of that wheel for its base; and if a hypocycloid be de- scribed on the plane cf the other wheel with the pitch circle of that wheel as its base, and if the acting surfaces of the teeth on the two wheels be cut 80 as to coincide with these curves, they will be driven by the intervention of these teeth in the same manner as they would by simple contact of their pitch circles. It might be shown in exactly the same manner that the curves m p and n p may be generated by the rolling of any other curve than a circle upon the pitch circles of the wheels; they would still possess Digitized by Google 808 GEERING. this property, that a line drawn from any point of their contact to the point of contact of the pitch circles is a normal to both, which, as already shown, is the one necessary and sufficient condition. Further, it can be shown that a tooth of any form whatever being cut upon a wheel, it is possible to find a curve which, rolling upon the pitch circle of that wheel, shall, by a certain generating point, traverse the edge of the given tooth; and the curve thus found being made to roll on the circumference of a second wheel, will trace out the form of tooth which will work truly with the first. Let a Mb, Fig. 2029, be any curve whatever intended to 2029. form the condition of the acting surfaces of teeth of the wheel, and let c M be the pitch of the wheel; take c m = c M, it is required to find the curve which passes through the point m, and which being continually in contact with the curve a M b will be impelled by the latter according to the B required condition. Now, as the common normal must al- ways pass through the point c, if we draw the perpendic- ular c t to the curve a Mb, which may be done by describ- ing an arc of a circle from the point c as a centre, with a a radius such that that arc will cut the curve a M b in two points infinitely near and joining the point c to the middle & c M of the distance of these two points, the point t will be the point of contact of the two curves. Supposing now that we divide the pitch c M and m into the same number of equal parts at the points 1, 2 and 1'2', when these points arrive successively in contact in the course of the revolution 6 of the two circles, they will coincide with the point c; and the normal to the curve a Mb, passing through the point 1, will also be the normal to the curve sought, and will pass through its point of contact with a Mb. If, then, from the point l' as a centre, with a radius equal to a normal to the curve a M b, we describe an arc of a circle, it will be a tan- gent to the curve sought. And doing the same with the other points of division, we find a number of points through which, if a curve be traced tangential to the small arcs described, it will fulfil the conditions of the problem, with more or less accuracy, according as the points taken have been more or less numerous. From this it therefore appears that, having the curve given of the teeth of one wheel, the curve to which the teeth of the second wheel ought to be formed may be readily found; which is the problem in its most general form, and may be stated summarily thus Given the form of the teeth of one wheel, to find out the form of those of another that may work with it correctly. Solution Describe the pitch circles of the required wheels, and find the curve which, revolving upon the one, will describe the given tooth; make the same curve revolve within the other, and with the same describing point it will gen- erate the tooth required. 2031. 2030. 0 B B o D D C e o a o A R It is however to be observed, that these curves, to be applicable in practice, imply the condition that the curvature of the concavity of one tooth should be greater than the convexity of the other, or else that both should be convex. The practical solution may be conducted in the following simple manner: Let A and B, Fig. 2030, be two boards, whose edges are formed into arcs of the given pitch circles. Attach to one of them the shape of the proposed tooth C, and to the other a piece of strong paper D, the tooth being slightly raised to allow the paper to pass under it. Keep the circular edges of the board in contact, and make them roll together. Draw upon D a number of successive positions of the outline of the edge of C, which, touching one another in a corresponding number of points, a curve f e, passing through these points, will be the corresponding tooth required for B. For it is obvious, from the method it is obtained, that if the tooth be cut out, and be made to work upon C. it will touch that tooth in every position; and therefore the contact of these curves will exactly fulfil the required condition, by replacing the rolling action of the two pitch circles. To illustrate the preceding process more particularly; by means of Fig. 2031, let o be the centre of the piece B, supposed to be fixed and suppose the piece A rolling upon it over the arc c' of sufficient extent to include the extreme positions of the acting surfaces. Then c and c', being the extreme points Digitized by Google GEERING. 809 of contact of the pieces, draw the radii oc, oc', and from the centre o, with a convenient radius, draw an arc de, meeting o c and c', produced at d and e; divide this arc into a number of equal parts, cor- responding to the number of positions of the tooth C intended to be taken; the radii drawn to the points of division will give corresponding points of contact at the circumference of the piece B, from which the relative positions of the tooth C may be severally described. In Fig. 2039, the extreme positions of the piece A and the tooth C are indicated by dot lines, though, with the exception of two other positions of the tooth, the rest is omitted to prevent confusion. A curve nn, being traced 80 as to touch, in succes- sion, the different positions of the tooth C, will indicate the form of tooth required for the piece B, 80 as to geer with the piece A. It is, however, true, that many forms of C may be tried which will prove impracticable; for some of the successive portions of its edge may come up and interfere with parts of a b, previously drawn thereby showing, that although it may be geometrically possible to assign a form of a b, which shall work with any given form of C, it by no means follows that this is practically true; and, indeed, it does not appear that any new forms of curves deduced from this general principle are likely to adapt them- selves in practice 80 well as those commonly adopted. There is also one curve highly applicable in practice, the importance of which requires that it be noticed as a separate principle, which may be thus stated The teeth of two wheels will also work truly together, if their acting surfaces coincide with curves traced out by the extremity of a flexible line, unwinding from the circumference of a circle, and called the involute of that circle, provided- the circles, of which the bounding curves of the teeth are respect- ively portions, be concentric with the pitch circles of the wheels, and have their radii in the same ratio as the pitch circles. Thus, let there be two centres of rotation, A and B, Fig. 2040, of which AT and BT are the primitive radii; through the point T draw any straight line D E; through B the points A and B draw the perpendiculars A D and BE, and describe circles from the points A and B as centres, with these lines as radii. Again, let T H be the invo- E F lute of a portion of the circle A D, traced by the (flexible) line DT, and this line is manifestly a normal to that curve K at T; this point will also be that at which the second 2040. curve, traced by ET, the line touches the first. But sup- G pose the circle A D to turn on its centre, and taking with it the curve K T H, the line D E will be a constant normal to that curve, in all its positions; and consequently also to the conducting curve in all its positions, and at the same point. Now this property of a curve, of having its H normal tangential to a circle, belongs only to the involute D of that circle; the conducted curve must therefore be the involute of the circle BE. As an illustration of this principle, let DE be conceived to represent a band passing round the two circles drawn with the radii D E and A D; the wheels will evidently be driven by this band precisely as they would by the con- tact of their pitch circles, since the radii of the involute circles have the same ratio as the radii of the pitch circles. Let it also be supposed, that the projected circles carry round with them their planes as they revolve, and that a tracing point is fixed at any point T of the band; it will trace at the same instant the two curves, and upon both planes, as they revolve beneath it; it is then obvious that these curves, being traced by the same point, must be in contact in all positions of the circles when driven by the band, and therefore when driven by their mutual contact. The wheels would therefore be driven by the contact of teeth of the forms of the curves thus traced by the point T of the band, precisely as they would by the contact of their pitch circles; and it is easy to see that the curves H TK and FTG, so described, are involutes of the circles drawn with the radii A D and B E, from the given centres. A particular property of teeth formed according to the principle here pointed out, is that they trans- mit the pressure without altering its intensity-this being the same when we suppose the force con- stantly applied at the pitch circles, but not at the points of contact of the teeth. In epicycloidal teeth the normal to the curves is variable, as may be seen from Fig. 2029. Thus the pressure at the pitch circles being constant, may be expressed by A c, while that upon the points of contact of the teeth will be expressed by A t, which manifestly varies with the direction of the normal ct, and consequently with the position of the points of contact of the teeth. Such variation does not occur when the teeth are of the involute form; for then the relation of AD to BE, Fig. 2040, is invariable, since the constant line D E is always normal to the curves in contact and hence it is obvious that the pressure transmit- ted from the one circle to the other at D and E has always the same value. An advantage of this form of teeth is, that if the distance of the centres A and B be altered, but so that the involutes still remain in contact, the velocity of the pitch circles of the wheels will not be affected, and therefore the angular motion of the curves in contact will remain unaltered. This is a property which distinguishes the involute from the other curves that have been given, and is of some practical importance; for, in a pair of wheels of which the teeth are of that form, it is not only unne- cessary to fix the centres at a precise distance, but a derangement of the centres, from wearing of the journals and brasses, or settlement of the framework, does not impair the action of the teeth. 102 Digitized by Google 810 GEERING. It may also be observed, that for every pair of pitch circles an infinite number of pairs of involutes may be assigned that will answer the required conditions; for the inclination of ETD to the line of centres is manifestly arbitrary, and every change of inclination mani- 2041. festly produces a new pair of base-circles, and of involutes to these circles. Of epicycloidal teeth.-The simplest illustration of the action of epi- cycloidal teeth, is when they are employed to drive a trundle, as rep- resented in Fig. 2041. In the first place, let it be assumed, that the staves of the trundle have no sensible thickness; that the distance of B their centres apart, that is, their pitch, and also their distance from the centre of the trundle, that is, their pitch circle, are known. The pitch l circles of the trundle and wheel being then drawn from their respec- K tive centres B and A, set off the pitches upon these circumferences, corresponding to the number of teeth in the wheel and number of staves in the trundle; let five pins, a b c, &c., be fixed into the pitch circle of the trundle to represent the staves, and let a series of epicy- cloidal arcs be traced with a describing circle, equal in diameter to the radius of the pitch circle of the trundle, and meeting in the points k 1 m n. &c., alternately from right and left. If new motion be given to the wheel in the direction of the arrow, then the curved face m T will press against the pin b, and move it in the same direction; but as the motion continues, the pin will slide upwards till it reaches m, when the tooth and pin will quite contact. Before this happens, the next pin a will have come into contact with the face a 1 of the next tooth, which repeating the same action will bring the succeeding pair into contact; and 80 on continually. We have here assumed the pins to represent the staves of the trundle and to be without sensible thickness, which is not true in practice. To allow, therefore, of the required thickness of staves, it is manifestly necessary and sufficient to diminish the size of the teeth of the wheel, by a quantity equal to the radius of the staves, sometimes increased by a certain fraction of the pitch for clearance, in this case termed backlash. This may readily be done by drawing within the primary epicycloids at the required distance, another series of curves parallel to these. For example, let it be required to draw the proper tooth to impel a stave of the radius bt; with that radius plus the requisite amount of clear- ance in the compasses, draw a series of smail ares from and within the original curve, then a curve touching all the arcs 80 drawn will be the epicycloid required; this curve acting upon the stave will fulfil the condition stated, for being symmetrical with the first, which passes through the axis of the stave, it will act similarly at its circumference. In practice, a portion must be cut from the points of the teeth, and also a space must be cut out within the pitch circle of the driver, to allow the staves to pass; but as the sides of these parts never come into contact with the staves, no particular form is requisite; the condition to be attended to is simply to allow of sufficient space for the staves to pass without contact. We have here supposed the wheel to be the driver, and this being the case it is evident that the staves being indefinitely small, the contact of the tooth will begin at the instant its base reaches the line of centres at a; and during the action of the tooth the point of contact will gradually slide upwards, remaining always in the pitch circle of the trundle, at the same time it recedes from the line of centres, until the contact is finally terminated at the point of the tooth. If the trundle be made the driver, the pitch lines of the pair will still move with the same uniform angular velocity; but the reverse of the preceding action will take place, for in that case the contact would commence at the top of the teeth and cease at their base; it would moreover commence before the line of centres, and terminate when it had reached the point of intersection of that line. Now the friction which takes place between teeth whose point of contact is approaching the line of centres, is of a much more injurious character than that which happens while the points of contact are receding from it. Not only does it cause much more friction and vibration, in consequence of the inequalities of the surfaces in contact-and the surfaces even of the most highly-polished bodies have some inequalities, which, when pressed together, interlace -but the teeth at the same time tend to force the axes of the wheels outwards, and very speedily induces injurious effects upon the journals, and also upon the planes of the teeth. When the action is receding from the line of centres the friction is less intense, and its effects less injurious; it tends to draw the axes together, and induces much less vibratory action of the geering. For these reasons it is studied in practice to avoid as much as possible the kind of contact which takes place before the line of centres, by making the wheel the driver and the trundle the follower. The diameter of the staves is also commonly made equal to that of the teeth, with an allowance of a teeth of the pitch for clearance; the radius is therefore rather less than a quarter of the pitch, conse- quently the contact will begin, the wheel being the driver, when the centre of the stave reaches the line of centres, and therefore at a distance before that line equal to the radius of the stave, or rather less than a quarter of the pitch. It is also evident that since one tooth must not quit contact before the succeeding tooth is engaged, that when the point a has reached the line of centres the tooth T must not have quitted contact with the stave b, and the point at which contact ceases must therefore be at an angular distance from the line of centres equal at least to half the distance ar, that is, to half the pitch. In a pair of this kind, the action which takes place before the line of centres is less than a half of that which takes place after passing it. The action of a wheel and trundle being understood, it is easy to comprehend that of the teeth of a pair of wheels of the ordinary construction. Let A and B of Fig. 2042 be respectively the centres of a Digitized by Google GEERING. 811 wheel and pinion of which the teeth are intended to be of the epicycloidal form, and A c and Bc their primitive radii. To lay off the teeth of this pair, having determined the pitch and number of teeth in the wheel and pinion, let the pitch lines be divided 2042. into as many equal parts, setting out from the point of contact c, as there are teeth in them respectively. Let the thickness of the teeth be next set off, taking ca for the thickness of a tooth of the wheel, and c b for that of a tooth of the pinion. Upon the radii A c and B c as diameters, describe two circles, having also their point of contact at c and their centres X and Y. Now let the circle Y be made to roll upon the pitch line of the wheel, and a point io its circumference at c will describe the epicycloidal arc c m, and this curve X determines the form of the point of the tooth of the wheel. In the same way describe the epicycloidal are by making the circle X to roll upon the pitch circle of the pinion, and this curve will determine the form of the part of the tooth of the pinion beyond the pitch line. Again, the teeth must have the same form on both sides; in other words, they must be symmetrical in reference to the radius which passes through the mid- dle of their thickness, in order that the wheel and pinion may be turned in either direction. If, then, through a point equidistant from c and a and from the centre A of the wheel, a right line be drawn as the axis of the tooth, it limits at m the outline of the tooth to complete the form of the addendum, it therefore only remains to describe the opposite epicycloidal are a m equal to m. A similar process completes the form of the addendum of the pinion. The curve c m of the tooth of the wheel is constant- B ly in contact with the radius Bc, and its point. of contact is at the same time situated in the circumference of the circle X; the contact will therefore cease when the extremity m of the tooth becomes the point of contact and this occurs when the point m has arrived at the circumference of Y. If. then, an arc of a circle be described from the centre A with the radius A m, its point f of intersection with the circumference of Y is that at which the tooth ought to cease to act, to secure uniformity of motion, and at the same instant that another new tooth advances into geer. The determination of the point f limits also the useful length of the flank; for if from B as a centre, with radius Bf an arc be described, the part c 8 of the radius c B is that which is in contact with the tooth till it arrives at the position Bf; and consequently this is the useful length of the flank of the pinion. Reasoning in the same manner with respect to the teeth of the wheel, it may be determined, that the useful length of the flank of the tooth c a is the portion c g. We have yet to find the form of the portions of the teeth within their respective pitch circles, or more properly of the spaces between them. The first condition which presents itself is manifestly that the spaces ought to be sufficiently large to allow the projecting portions of the teeth of the opposite wheel to enter freely between them. To resolve this problem in its most general form, it is necessary to find the curve described by the point m upon the movable plane of the circle of B, the pinion being driven by the wheel A. For practical purposes this is not reckoned a matter of much importance; it is usually considered enough that sufficient space for play be allowed whilst the tooth remains strong enough for its work. As every tooth moves between two flanks, and touches only one of them, the space may be bounded literally by radial lines prolonged towards the centre of the wheel. The bottom of the space being sufficiently removed from the pitch circumference to allow the tops of the teeth of the pinion to pass round without touching them, may be described by arcs of a circle drawn from the centre. By this arrangement, then, the flanks of the teeth of both wheels of the pair, that is, the portions of the teeth which lie within the respective pitch circles, are radial lines drawn from the centres to the pitch circles, and the faces of the teeth, or those portions which lie without the pitch circles, are arcs of epicycloids traced in each wheel with a describing circle equal in diameter to the pitch radius of the other wheel. Accordingly each flank and face will act in contact to produce a constant angular velocity ratio of the pitch circles of the pair, and the action of each pair of teeth will be confined to its own side of the line of centres. In practice, and especially when the teeth of the wheels are small, it is not usually considered necessary to apply strictly the form of the epicycloid to find curves of the teeth; but to define them approximately by some such mode as the following. Referring to Fig. 2043, after having divided the pitch circles into the proper number of parts cor- responding to the number of teeth, and set off upon the pitch lines the thicknesses of the teeth, through the extremity b of the pitch a b of the pinion, draw a radius B b cutting the circumference of the epicy- cloidal circle Y in d. Joining the point d with the first division b' of the wheel, draw a perpendicular upon the middle of the line db' meeting the circumference of A at the point h; an arc described from this point as a centre, and with hb as a radius, will define the curve of the teeth of the wheel with sufficient exactness. Digitized by Google 812 GEERING. The length of the teeth is limited at d where the curve of the tooth meets the circumference of the epicycloidal circle Y; for when the tooth has arrived at that point, another pair ought to come into geer at the line of centres. The flank of the tooth being radial, may be defined by a right line from the termination 2043. A of the curve of the face of the tooth in the pitch circle drawn towards the centre A. As the tooth is symmetrical about the axis A k, its op- posite face may be described by taking off the form of the side found upon a mould; and the two sides being thus found, a pattern tooth may be formed and used in draw- ing in the other teeth of the wheel. A similar process gives the form of the teeth of the pin- ion. Having taken an arc a e equal to the pitch, draw A e till it meets the circumference of X in g; with this join the division é of the pinion, and through the middle of the line draw a perpendicular, meeting the circumference of Y in h'; from this point as a centre, and with radius h'e', de- scribe the curve ge', which defines the face of the tooth. A radial line meeting the curve at e' and drawn towards B as a centre, will in like manner define the flank of the tooth. To determine the bottom of the space between two teeth, it is to be remarked that in the pinion this must be at a distance from the centre A. at least equal to A if, therefore, from the point B as a centre, with radius Bm, a circle be described, it will define the bottoms of the teeth of the pinion; and in like manner, if with radius A n a circle be described from the centre of the wheel, it will define the bottoms of its teeth. The angles at bottom are commonly rounded, which, at the same time that it im- B proves the appearance, strengthens the teeth. The forms of the teeth are also occasionally described by arcs, of which the radii are equal to the pitch, and with the centres taken upon the pitch lines. In this case the centres of these arcs must fall upon the sides of the teeth, which being already marked off, it becomes a simple process to describe the upper portions. This method, which differs little from the preceding, may be conveniently substituted for it, when the diameters of the wheels are not very unequal, and the teeth not thick. But for small pinions, with larger teeth, the first method must be adopted. In many cases the curves of the teeth are described by arcs drawn from the centres of the adjacent teeth upon the pitch line. This gives a radius equal to the pitch, plus half the thickness of a tooth. In like manner, the sides of the teeth also are sometimes described by ares from the centres of the ad- jacent teeth giving a radius equal to the pitch, minus half the thickness of a tooth. This form of the tooth may be defective, in the case of a very small pinion having to transmit great pressure, as the extremities of the teeth may be too much reduced. In this case, the curves or faces of the teeth may be described with radii equal to three-fourths of the pitch; and if this be not sufficient curvature, radii equal to some smaller fraction of the pitch may be used. When, on the contrary, the pitch is large, and the pressure comparatively small, the teeth may be too short; this will be remedied by employing arcs of which the radius is one and a half or twice the pitch. A general method of determining these radii will presently be given. Another condition which it is necessary to advert to, is the point in the circumference at which con- tact of the teeth commences. This point is necessarily that in which the two pitch circles cut the line of centres, as may be rendered obvious by reference to Fig. 2042. Here it is plain that the face c m of the tooth of the wheel ought to act upon the side of the tooth of the pinion, until the extremity m of the tooth arrives at the extremity of that side, as shown by the position of the tooth f. But were this to take place before the acting surface of the succeeding tooth of the pinion had arrived at the line of centres, the succeeding tooth of the wheel would of necessity act, during the first part of its contact, upon the face of that of the pinion, and continue so to do until it had arrived at the line of centres. On the other hand, should the extremity of the tooth on arriving at f not immediately cease contact, but only be disengaged when the acting surface of the next tooth of the pinion had arrived at or passed the line of centres, the face of that tooth would not be at all acted upon by the tooth of the wheel, and the contact with the flank would be entirely beyond the line of centres. In this case, were the wheel constantly to drive the pinion, the curved faces of the teeth of the latter might be altogether dispensed with, without in any way injuring the equality of action. But the condition assumed does not occur in practice; for, on account of the inequalities which take place in the motion of the wheels, whether arising from inequality in the resistance or of speed in the moving power, the wheel and pinion act upon each other alternately, even when the general movement is continuously in the same direction, a cir- cumstance which cannot be safely neglected in the construction of any system of geering. When the teeth fall into action before the line of centres, they must obviously slide upon each other as they approach that line, and their friction, as in the case of the wheel and trundle, is then much greater than it is after they have passed it, on account of their sliding inwards upon each other instead of outwards, and against a pressure which is augmented in proportion to the curvature of the acting surfaces. And, moreover, in the contact after the line of centres, although there exist inequalities on the acting surfaces, they offer comparatively little obstruction to the sliding of the teeth upon each Digitized by Google GEERING. 813 other; whereas, when the contact is in advance, every inequality becomes an abutting obstacle to the closing in of the teeth, and which it is necessary to surmount by a species of backward motion at great expense of motive power, and greatly to the detriment of smoothness of motion among the parts of the geering. But although it is thus clear that an advantage is gained by making the teeth engage after the line of centres, yet this is as clearly desirable only within certain limits. For, as already observed, it is necessary that the tooth of the pinion continue to geer with the wheel until the succeeding tooth has arrived at the line of centres-a condition in which is involved the problem of the minimum number of teeth that can be given to a pinion to work with a wheel of given size, and which may be determined when the pitch and radii are given. From these data, the angle of the sides of the teeth is immediately deduced. The length and thickness of teeth and width of space must be modified to answer the con- dition imposed, and the smaller the number of teeth in the pair, the more difficulty there is in accom- plishing the solution. To resolve the conditions of the question into the simplest form which they admit, let us take the imaginary case of a pinion of seven teeth, without visible thickness, to geer with a wheel of fifty epicycloidal teeth, as represented in Fig. 2044. In this the line A B is the line of centres; cm b one of the teeth of the wheel, and B m a one of the radial teeth of the pinion, with which the tooth m b has been in contact during its motion from c to b. Now since the pinion has seven radial teeth, the value of the angle c B a is 3800 = 51° 25' 43"; and making the radius Bc=1, the right-angled triangle Bm c, completed by drawing the right line c m, gives, m = cos a B = cos 51° 25' 43" = 0-62349. If radius Bc=1, then A c = 50 and A B = 597. Thus we have given in the triangle A m B the two sides A B and Bm and the angle a Bc; and therefore we have also the angle B A m = 3° 35' 50". Now if the wheel have 50 teeth, we have the angle c Ab, containing a tooth and a space, = 3600 35 = 70 12'; and subtracting from this the angle c A m, there remains the angle b A m = 8° 36' 10"; but the angles b A m and m A c are equal, and by consequence the angle b A is double the former of those, that is, 70 12' 20", the tooth being symmetrical in reference to Am. Now we found the angular value of the pitch c = 70 12', which ought to contain the tooth and the space. It therefore follows that even when the tooth of the pinion has no thickness, it is impossible to place the tooth of the wheel in the pitch interval- for this is shown to be less than the tooth of the wheel would occupy; and it is easy to understand that a wheel of less than 50 teeth could still less be made to drive a pinion of seven teeth. And although in a wheel which has more than 50 teeth the pitch angle would be found greater than the thickness of a tooth, still it would be less than that which should contain the thickness and the space together; hence the angle which would be found due to the space would be 80 small as to be insufficient to receive the tooth of the pinion, allowing for lateral clearance, and in consequence the pair would necessarily geer before the line of centres. 2045. B m r 2044. B D m a S.C b This problem is often more conveniently solved organically, when the teeth of the wheel and pinion are formed in the usual manner. Thus in Fig. 2045, let c B m be the angle through which it is desired that the contact of the tooth a m should continue after passing the line of centres; then as the contact ends at m, the point of contact will be at the extremity m of the tooth Join c m by a right line which will be a perpendicular to the radius Br; also join A m. Then, since a was in contact with r at the line of Digitized by Google 814 GEERING. centres, the are ca=cr is given, and is that portion of the pitch through which the contact of the tooth is required to continue. Then a b is half the thickness of the tooth, minus half the base of the portion cut off; and ea is equal to the pitch, and must contain one tooth and the space between. Sup- posing these qualities to be equal, then since a b contains less than half a tooth, and cannot contain more, e b must contain half a tooth and space at least, and in this case as much more as a b is less than half a tooth. Therefore for every given value of c Bm, a value of A may be assigned which shall make e b exactly equal to a space and half a tooth, when the tooth is pointed, and with a corre- sponding and known increment when the tooth is blunted If a greater radius c A' be taken, the point b will manifestly fall still nearer a and the tooth may be still more blunted but if a less radius c A" be assumed, then the point b will fall nearer to c, and eb will become too small to contain the space and remaining half tooth; and in this case, if the wheel were set out, it would be found that the epicycloidal ares on the two sides of the tooth would intersect between m and b, and therefore the tooth would be too short to continue in action through the required arc a. This mode of illustration is due to Professor Willis, to whom we are also indebted for the following tables derived organically in the manner described, for spur and annular wheels:- TABLE I.-For spur wheels, showing the least num- TABLE 11.-For annular wheels, showing the great- bers of teeth that will work with given pinions-Tooth est numbers of teeth that will work with given pinions - space. -Tooth space. Least number of teeth in Greatest number of teeth in No. of teeth in the wheel. No. of teeth in annular wheel. given pinion. pinion. Wheel driving. Pinion driving. Wheel driving. Pinion driving. 5 impossible. impossible. 2 impossible. 5 6 - 176 8 - 12 7 - 52 4 - 26 Arc of action c r = pitch. 8 - 35 5 - 85 9 - 27 7 14 any number 10 rack. 23 8 25 - 11 54 21 Are of action cr = pitch. 9 60 - 12 30 19 13 20 18 14 24 17 15 17 16 16 15 - 3 impossible. impossible. 2 impossible. 10 4 - 35 3 - 77 pitch. II 5 - 19 14 pitch. - II 4 5 any number 6 - 5 12 - 7 31 12 6 77 - 8 16 10 9 12 10 10 10 10 2 impossible. impossible 2 impossible. 14 8 I 36 4 8 pitch. can II 1 . 4 - pitch can II any number 15 5 64 - 5 - 13 6 20 10 7 11 9 8 8 8 These tables contain all the limiting cases under the three suppositions of the arc of action being equal to the pitch, to three-fourths of the pitch, and to two-thirds of the same. When the are of action and pitch are the same, the teeth of the follower may be reduced in length to the pitch circle, and the contact of the teeth confined to their recess from the line of centres; when the are of action is reduced, as in the other two cases given, the reduction will of course indicate the portion of contact which must take place in advance of the line of centres. Thus when = 1 and 1 of the pitch, then it is obvious that the contact of the teeth must begin at least t and I of the pitch respectively before they reach the line of centres. It also appears from the table, that a smaller pinion may be employed to drive than to follow. Thus when the action begins at the line of centres, the least wheel that can drive я pinion of eleven teeth is fifty-four ; but the same pinion can drive a wheel of twenty-one and upwards. Again, nothing less than a rack can drive a pinion of ten, but this pinion can drive a wheel of twenty-three and up- wards. No pinion of less than ten leaves can be driven, but pinions as low as six may be employed to drive any number above those in the table. And lastly, the least pair of equal pinions that will work together is 16. These limits being geometrically exact, and making no allowance for wear, it is better, indeed necessary, in practice, to allow more teeth than the table assigns. Digitized by Google GEERING. 815 It often occurs in practice that a wheel is required to drive more than one pinion, and vice versa, and those of different diameters. In this case the usual mode of obtaining the epicycloidal form of the face of the driving teeth is inapplicable, as that curve is made to depend upon the diameters of the pair when uniformity of motion is studied. But before adverting to the methods by which this condition may be fulfilled, it will relieve us of some of the difficulties of the question to examine the ordinary mode in which epicycloidal teeth are set out. As the workman cannot be expected to be in possession of that accurate mathematical knowledge which would enable him to determine the neces- sary forms by purely theoretical means, he has recourse to the mechanical method of forming the pattern teeth by templets. We give the process in detail. 2046. B A C Having determined the pitch of the teeth and the radius of the pitch circle by the methods de- scribed, a thin slip of wood-say 100 thick-is provided, and on this an arc of the pitch circle is struck. The shp is then cut to the circumference of the circular are described upon it. Another similar slip is now provided, and on this an arc of a circle equal to the diameter of the wheel to the points of the teeth is in like manner struck, and the edge worked off to the circumference of the circular are as be- fore. These two pieces so prepared are laid together as in the Fig. 2046; the piece A, whose 2047. D g s s C edge S f is an arc of the pitch circle, is fixing upon B, whose edge is an are of the extreme circumfer- ence of the wheel, the space 8 8 between those edges being in breadth equal to the length of the teeth from the pitch circle to the points. The slips are held firmly in their relative position by two screws c c. This done, a like templet is prepared for the pinion, Fig. 2047; the piece C, whose edge sg is an arc of the pitch circle, is similarly fixed on the piece D, whose edge is an are of a circle the diameter of which is the true diameter of the pinion, the breadth of space 88 being, as before, equal to the length of addenda of the teeth. 2048. 2049. m m c m D C O m O 7 to B U 7 D 2 A B The pair of templets being thus prepared, two tracing points m m are inserted obliquely, and from behind into the piece D of the pinion templet. One of these points passes out at the edge of the piece C, and the other at the edge of the piece D, and the templets are then placed upon each other, as shown in Figs. 2048 and 2049 annexed, so that the circumference of the piece C, that is, the pitch Digitized by Google 816 GEERING. circumference of the pinion, shall meet the circumference of the piece A, that is, the pitch circumference of the wheel. If in this position the templets be made to roll upon each other through a certain are, pressing them at the same time slightly together, the tracing points will mark two epicycloidal curves upon the pieces A and B, as v and r; of these two curves, that marked v, which is traced on the face of the piece A, will be the curve of the lower portion or flank, and that marked r will be the curve of the upper portion, or face of a tooth of the wheel. If now the thickness of the tooth be marked off on the edge of the piece C, that is, on the pitch circle, and the corresponding tracing point be made to coincide with that point, the curves of the opposite side of the tooth will be formed by making the templets roll together in the contrary direction. A complete outline of a tooth of the wheel is thus described, to which à pattern tooth may be cut and used to shape the teeth by in making the wheel pattern. Let now the tracing points be taken out of the pinion templet, and inserted in exactly the same way into the templet of the wheel, and the templets applied to each other as above shown, the operation described will give the outline of a tooth of the pinion upon the parts C and D of the pinion templet. Having thus found the curves of the teeth of the pair, pat- 2050. tern teeth may be made and used in setting them out; but this mode is not uniformly adopted. Instead of forming pattern teeth, many prefer to lay off the teeth by circular B c D ares coinciding approximately with the epicycloidal arcs found by the templets. This is readily done by taking any three points in the curve, and finding the radius with which a circle may be drawn whose circumference will pass through F G H the points 80 taken, and which will thus of necessity coincide approximately with the normal curve. Radii being found for the curves of the top and bottom of the teeth of the wheel and pinion, their centres are transferred to the circumference of the pitch circles, and circles drawn within these last. Figs. 2050 and 2051 illustrate the process. The ares B and D, drawn with the radii A B and CD, are those of the face and flank of the wheel tooth; and the arcs F and H, drawn with the radii EF and G H, those of the corresponding off teeth, are drawn from the pitch circles cc, Fig. 2051, and parts of the tooth. The pinion curves of the faces in setting those of the flank are drawn from the circles nn within the others. 2051. n The preceding is a very common mode of obtaining the curves of the teeth of a pair of wheels which are to geer together; but it is faulty, in as far as it gives a form of teeth smaller at the root than at the pitch circles, and also in the circumstance that a pair of wheels set off with templets formed in the manner described, will only work correctly with each other, and not with wheels of any other numbers, although of the same pitch. Thus, a wheel of 30, set off as described, to work with another of 50, will not work correctly with a wheel of 40 or of 60, although the pitch be the same. To effect this it is necessary to employ the proposition already announced and illustrated, and which shows that if there be two pitch circles touching each other, then an epicycloidal tooth formed by causing a given describing circle to roll on the exterior circumference of the one, will work correctly with an interior epicycloid formed by causing the same generating circle to roll on the interior circumference of the other. This proposition having been already established, it is unnecessary to dwell upon it further than to observe, that although it has been admitted into the workshop as a fundamental truth, the practice founded upon it does not afford the full advantage which it is adapted to afford, and which might be derived from it by a slight modification of the ordinary practice. To describe the practical application of the principle, let a thin slip of wood be provided, and let an arc of the pitch circle be struck upon it; divide the slip into two portions through the line of this are with a fine saw one part, A, will have a concave, and the other, B, a corresponding convex circular edge. (Or the same slip may be made with a convex and concave edge of the same radius.) Describe an arc dd of the pitch circle upon a second board CD, upon which the pattern tooth is to be drawn. Fix the piece B upon the board, so that its circular edge may accurately coincide with the circumference of the are dd. A portion of a circular plate D is next provided, of the same radius which it is proposed to give to the generating circle: this plate has a fine tracing point at P inserted into it, and projecting slightly Digitized by Google GEERING. 817 from its under surface, and accurately coinciding with its circumference. Having set off the thickness of the tooth a c upon the pitch circle dd, so that twice this width increased by the clearance which it is desired the teeth should have, may be equal to the pitch, the generating circle D is made to roll upon the convex edge of B; meantime the point at p will trace upon the board the curve of the fa- ces of the tooth, having caused the point to coin- cide successively with the two points a and c, and the circle to roll from right to left, and vice versa. Let the piece B be now removed, and the 2052. piece A applied and fixed, so that its concave edge may accurately coincide with the circular arc dd; then, with the same circular plate D pressed against the concave edge of A, and D made to roll upon it, the point at p, which is made as before to coincide successively with the c D points a and c, will trace upon the surface of the board CD the two hypocycloidal arcs a b, b, e which form the flanks of the tooth. The com- a plete tooth, thus formed, has this advantage over the form of tooth found by the former b B mode, that it will work correctly with the teeth similarly described upon any other wheel, pro- vided the pitch of the teeth be the same, and provided the same generating circle D be used to strike the curves upon the two wheels. In this manner the general forms of the teeth of the pair are determined. And it only remains to cut them off at such lengths that they shall come into contact in the act of passing through the line of centres. Thus, in Fig. 2042, let Y be the centre of the generating circle of the teeth, then the points ab, where the circle intersects the edges of the driving teeth, are the points of contact of the teeth Now as the teeth ought to come into action only at the line of centres, it is clear that the tooth f must have been driven by the tooth of the wheel from the time their contact was at c, to which another tooth of the wheel is shown to have advanced, the former being about to quit contact; and since the tooth now advanced to c is about to take up the task of impelling the driven wheel, and the other to yield it, it is clear that all the part of the tooth falling within the circumference of the generating circle might be removed; this done, it is evident that all the driving strain would immediately be transferred to the succeeding pair of teeth as required. In order, therefore, to obtain a form of tooth which shall satisfy this condition, by the mode of setting out which has just been described, it is only necessary to take ac, in Fig. 2052, equal to the pitch of the tooth, and to bring the circumference of the generating circle D to touch the convex circumference of the are dd in that point: the point of intersection o of this circle, with the face ta, will be the last acting part of the tooth; and if a circle passing through that point be struck from the centre of the pitch circle, all that portion of the faces of the teeth which lie beyond it may be cut off. The length of the tooth of the wheel intended to act with this may be determined in exactly the same manner. It may, however, happen that the point o will fall beyond the point t of the tooth; when this occurs, it is then impossible to cut the teeth of such length as to satisfy the condition that they shall drive only after the line of centres. This may be proved organi- cally with a pair of 15 to 15, and other numbers which the preceding table of cases will suggest. We have here supposed the same generating circle to be used in striking the entire surfaces of the teeth of both wheels. This is convenient, but not essentially necessary; for if the same generating circle be used in striking those parts of the teeth which act together, the required condition will be satisfied. Thus the flank of the driving tooth and the face of the driven tooth come into actual contact; it is therefore requisite that these curves be respectively an epicycloid and hypocycloid, struck with the same generating circle. And, again, the face of the driving tooth and the flank of the driven tooth being in contact, these curves must in like manner be struck with the same generating circle. But it is evi; dently unnecessary that the same generating circle be used in the first and second cases any generating circle will satisfy the proposed conditions in either case, provided it be the same for the epicycloid and the hypocycloid, which are to act together; observing, however, that as the diameter of the generating circle is increased, the thickness of the root of the teeth will be diminished and conversely, when made less than the radius of the pitch circle, the root of the teeth will spread out, and the curvature of the epicycloidal faces will be proportionally increased, and the teeth shortened. From these observa- tions it is also clear that the forms of the teeth of a pair of wheels which are required to drive continuously in 2053. one direction may be 80 modified as to give additional strength to the teeth without impairing their delicacy of ac- tion. Thus, if the wheels represented here, Fig. 2053, the lower A B being the driver, move always in the direction of the arrows, then, instead of the teeth being formed symmet- rically, the back of each tooth may be filled up, either by striking the curves by a very small generating circle, or bet- ter by involutes, which being proportional to the pitch circles B will be sure to clear during the working of the wheels. By this means the strength of the teeth is greatly augmented, as must be obvious, and their action is in no way impaired, since the acting surfaces are not altered 103 Digitized by Google 818 GEERING. Returning now to the condition often required, though seldom fulfilled in practice, of making wheels of different numbers, when of the same pitch, to work correctly together, it is clear from what has been advanced in connection with the preceding mode of setting out, that it is not absolutely necessary to assume the generating circle of any precise radius; it may be taken greater or less within certain limits without affecting the correctness of the working surfaces of the teeth. Proposition.-" If for a set of wheels of the same pitch, a constant describing circle be taken and employed to trace those portions of the teeth which project beyond each pitch line by rolling on the exterior circumference, and those which lie within by rolling on the interior circumference; then any two wheels of this set will work correctly together." In illustration of this principle, first announced by Professor Willis, he adduces the established and well-known condition, that the portion of each tooth within the pitch line of a driving-wheel works only with the portion which lies beyond the pitch line of the follower, as above shown, and that its action is confined to the approach of the point of contact to the line of centres. After the point of contact of the teeth has passed that line, then the case is reversed, and the portion of the driving tooth which lies beyond the pitch line is in contact only with some part of the follower's tooth, which lies within its pitch line. Consequently, if a constant describing circle be used for the whole set, it is clear that the propo- sition will apply to any pair of the wheels, both before and after the teeth have passed the line of centres; for in each case we have an exterior epicycloid working with an interior epicycloid, and both have been drawn by the same describing circle; that is, by the constant circle of the set. To carry this scheme into practice, it only remains to settle the proper diameter to be given to the describ- ing circle. Let the external circle B C, Fig. 2054, be a pitch circle whose centre is 0; then upon this system the flank of the tooth-that is, the portion of it which 2054. lies within the circle-will be an arc of an interior epicycloid (or hypocycloid) mn or m' n. Now, if the describing circle be half the diameter of the pitch cir- cle, the flank will become a straight line, coinciding with the radius o n, as shown in Figs. 2042 and 2043. But if the describing circle be of less than half the diameter of the pitch circle, the flank m n will be con- cave, and the base of the tooth will spread on the contrary, if the describing circle be more than half the C o B diameter, the flank m' n will be convex, and the base of the tooth will be contracted inwards-a form man- ifestly unpractical and useless. It is therefore clear, that the describing circle must not be greater than half the diameter of the pitch line; nor must it be too small, for then the base of the teeth would spread inconveniently, and the curvature of the exterior epi- cycloids would be injuriously increased, and the teeth m $ become too short. The circle selected should there- fore be as large as it can, consistently with the limita- 76 tion just stated, 80 that we finally arrive at the prac- tical rule: Make it equal in diameter to the radius of the least pitch circle of the set. And, as pinions should never have less than 12, and if possible not less than 14 teeth, it would be well to establish one of these numbers for that least pitch circle. Thus, then, by the use of the same generating circle for all the wheels of the same pitch, they will all work correctly together. It has already been observed, that, having found the epicycloidal curves of the teeth, by means of the templets, a common method of proceeding is to find, by trial, a centre and small radius, by which the arc of a circle can be described that will coincide nearly with the templet-traced curve. Having found these, as in Fig. 2052, and having struck upon the ends of the rough cogs of his pattern, a circle, con- centric with the pitch circle, and whose distance from it is equal to that of the centre of this arc, the workman adjusts his compasses to the small radius, and always keeping one point in the circle just described, he steps with the other to each cog in succession, the cogs having been previously divided into two parts corresponding to the pitch and thickness of the teeth. Upon each cog he describes two arcs, one to the right and the other to the left, which serve him as guides in shaping and finishing the acting surfaces of the teeth. The practical convenience of this method is evinced by the extent of its adoption, and requires only to be aided by a more commodious and certain method of determining the centre and radius of the approximate arc, which has been supplied by Prof. Willis. But before entering upon the geometrical consideration of the conditions involved, it may simplify the investigation to explain, in the first place, the practical application which Mr. Willis has made of it in the construction of his Odontagraph, an instrument which deserves to be extensively known and un- derstood. The fundamental principle which it involves may be thus exhibited:- Let A, Fig. 2055, be the centre and AT the radius of the pitch circle of a proposed wheel draw T 3, making an angle A T3 = 75° 30', with the radius, and drop a perpendicular A 3 upon T3.' Or draw AT, and upon it describe a semicircle, and cut off T3 = & of AT, that is, equal to a quarter of the radius, then will 3 be the centre from which, if an arc p be described through T, that arc will be the side of the tooth required. This principle being established, it may be adapted conveniently to practice by constructing a bevel of brass, of the requisite form, the angle at T being 751 degrees the side T3 may for convenience be graduated into a scale of quarters of inches as in the Figure; and these divisions may be further sub- divided if thought proper. If the bevel so formed be laid upon the radius A T of the proposed wheel and its point T to the pitch circle, the centre point 3 will be found at once by reading off the length of Digitized by Google GEERING. 819 the radius of the wheel in inches upon the reduced scale. Thus in the figure the radius A T is three inches long, and the point 3 is found at 8 of the scale. To draw the curves of the other teeth, describe from centre A with radius A 3 the circle pq, dotted in Fig. 2055, and falling within the pitch circle; this will be the locus of the centres of the teeth. Thus having divided the pitch circle into arcs corresponding to the pitch of the teeth, take the constant radius 3T in the compasses, and keeping one point in the dotted circle as at q, step from tooth to tooth, de- scribing successively the arcs of the faces first to the right and then to the left. For example, m n is described from centre q, and P 0 from P. 9055. 6 $ B 1 0 P T m 11/16 C The sides of teeth thus formed, consisting each of a single arc, bear considerable analogy to involute teeth, and like these have the fault of acting together with rather too much obliquity; but the mode of describing them is exceedingly simple, and they have this advantage, that they will work correctly with wheels of any number of teeth, with any amount of clearance, and without any great nicety of adjust- ment of the pitch circles. For wheels of a small pitch-as 1 inch and under-this mode of setting out may be adopted without risk; but when the sides of the teeth consist of single arcs, there can only be one position of action in which the angular velocity will be strictly constant-and that is when the point of contact is on the line of centres. This objection is obviated by making the side of each tooth to consist of two arcs, joined at the pitch line, and so struck that the point of action of the one shall be a little before the line of centres-say at the distance of half the pitch; and the exact point of the other at the same distance beyond that line. The mode of drawing these arcs is very fully described by Professor Willis, but it is much too com- plex to be rendered available in the workshop; besides, it has been rendered superfluous for practical purposes by his Odontagraph, in which it is embodied. This instrument, which is fast coming into use, is usually formed of card-paper, sheet-brass, or plane-tree. Fig. 2056, as constructed by Messrs. Holt- zapffel and Co., of London, contains within it the requisite tables of numbers. One side is graduated into a scale of half inches, each half inch being again subdivided into ten equal parts. The line tD, which corresponds to the radius of the wheel, makes an angle of 75° with the side. The mode of using the instrument is thus explained in its application to the setting out of a wheel of 29 teeth of 3-inch pitch. Describe an arc of the required pitch circle, and upon it set off the pitch Tt, Fig. 2057; bisect this in e, and draw radial lines BT and Bt. For the arc within the pitch circle apply the slant edge of the scale to the radial line Bt, placing its extremity t on the pitch circle as in the Fig. In the table headed Centres for the Flanks of the Teeth, look down the column of 3-inch pitch, and opposite to 80 teeth-which is the nearest number to that required-will be found the number 49. The point T indi- cated on the drawing board by the position of this number on the scale of parts marked Scale of centres of Teeth within the Pitch Circle," is the centre required, from which the arc of must be drawn with a radius re. The centre for the are de, which lies outside the pitch, is found in a manner precisely similar, by applying the slant edge of the scale to the radial line BT. The number 21 obtained from the table of Centres for the Faces of the Teeth, will indicate the position of this centre upon the scale of Centres for Teeth outside the Pitch Circle, namely, at R. Digitized by Google 820 GEERING. 2056. THE ODONTAGRAPH. 210 900 TABLE SHOWING THE PLACE OF THE CENTRES 190 UPON THE SCALE. 180 CENTRES FOR THE FLANKS OF THE TEETH. 170 160 PITCH IN INCEES AND PARTS. 150 Num- ber of t 1 1 coton t 1 11 If 14 2 21 8 Scale of centres for the fianks of the teeth. 21 st 140 teeth. 130 13 32 48 64 80 96 129 160 193 225 257 289 321 386 450 14 17 26 35 43 52 69 87 104 121 139 156 173 208 242 120 15 12 18 25 31 37 49 62 74 86 99 111.123 148 173 16 10 15 20 25 30 40 50 59 69 79 89 99 191 138 110 17 8 13 17 21 25 34 42 50 59 67 75 84 101 117 100 18 7 11 15 19 22 30 37 45 52 59 67 74 89 104 19 10 13 17 20 27 35 40 47 54 60 67 80 94 90 20 6 9 12 16 19 25 31 37 43 49 56 62 74 86 22 5 8 11 14 16 22 27 33 39 43 49 54 65 76 80 94 7 10 12 15 20 25 30 35 40 45 49 59 69 70 26 9 11 14 18 23 97 32 37 41 46 55 64 28 4 6 13 22 26 30 35 40 43 52 60 60 30 8 10 12 17 21 25 29 33 37 41 49 58 35 : 9 11 16 19 23 26 30 34 38 45 53 50 40 5 7 : :. 15 18 21 25 28 32 35 42 49 40 60 3 6 8 9 13 15 19 22 25 28 31 37 43 30 80 4 7 12 17 20 23 26 29 35 41 100 .. 8 11 14 : : 22 25 28 34 39 90 150 5 :. 13 16 19 21 24 27 32 38 Rack. 2 : :. 6 7 10 18 15 17 20 22 25 30 34 10 t Θ Scale of centres for the 10 faces of the teeth. 20 30 40 D TABLE SHOWING THE PLACE OF THE CENTRES UPON THE SCALE. CENTRES FOR THE FACES OF THE TEETH. PITCH IN INCHES AND PARTS. Number t 1 t 1 t 1 11 11 11 2 21 21 8 st of teeth. 12 1 2 2 3 4 5 6 7 9 10 11 12 15 17 15 8 7 8 10 11 12 14 17 19 20 2 4 5 6 8 9 11 12 14 15 18 21 30 3 4 7 9 10 12 14 16 18 21 25 40 6 8 ... 11 13 15 17 19 23 26 60 5 10 12 14 16 18 20 25 29 80 9 11 13 15 17 19 21 26 80 100 7 18 20 22 31 150 5 6 ... ... 14 16 19 21 23 27 32 Rack. 4 10 12 15 17 20 22 25 30 34 Digitized by Google GEERING. 821 The double curve df is also true for an annular wheel of the same number of teeth, f becoming of course the point of the tooth and d its root. For a rack the pitch line Tt will be a straight line, and Bt, BT, drawn perpendicular to it at a distance from each other, equal to the pitch 2057. E 200 150 100 50 r D B T R a The numbers for pitches not stated in the table, may be obtained from the column of some other pitch by direct proportion. Thus for 4-inch pitch, by doubling the number of the column of the 2-inch pitch; for 41 by doubling 21, and 80 on; or if the difference be small, the column belonging to the 2058. nearest pitch may be employed without a serious error; or more accurately, a number may be taken half-way between those given in the two nearest columns. Also no tabular numbers are given for 12 teeth in the upper table, because within the pitch circle their teeth are radial lines. Digitized by Google 822 GEERING. In reference to the numbers given in the tables, the inventor observes that it is unnecessary to extend these to every wheel, as the error produced by taking those belonging to the nearest, as above directed, is so small as to be unappreciable in practice. The difference in form between the tooth of one wheel and of another is due to two causes; the first is the difference of curvature, which is provided for in the Odontagraph, by placing the compasses at the different points of the scale of equal parts; and secondly, the form depends on the variation of the angle T Bt, Fig. 2057, which is met by placing the instrument upon the two radii in succession. The first is the only cause with which these calculations are concerned. Now in three-inch pitch, the greatest difference of form produced by mere curvature in the portion of tooth which lies beyond the pitch circle, is only 1-25th of an inch between the extreme cases of a pinion of 12 teeth and of a rack; and in the acting part of the arc within the pitch circle it is 1-10th of an inch; so that as all the other forms lie between those two, it is clear that if we select only four or five examples for the outer side of the tooth, and ten or twelve for the inner side, we can never incur a greater error than the 200 part of an inch, in a three-inch pitch, by always taking the nearest number in the manner directed, and a pro- portionally smaller error in smaller pitches. But to insure this, the numbers ought to be 80 taken, that the corresponding form shall lie equally between the extremes. This is more necessary with wheels of small numbers of teeth, since the variation of form is much greater among the teeth of low than among those of larger number. Fig. 2058 shows the relation of the curves of the teeth of a rack and pinion of 12 teeth, both adapted to work into the same wheel. They are drawn with accuracy, and on a large scale, 80 as to afford a graphical comparison of the two extreme cases. The Odontagraph is likewise applied to determine the correct form for cutters used in the wheel- cutting machine, for shaping the teeth of metal and cog wheels. The form of the cutter is manifestly that of the space between two contiguous teeth; and may therefore be determined by drawing a pair of teeth in any particular case. But in making a set of cutters especially for small pitches, it is not by any means necessary to make one for every number. The forms for numbers of teeth that lie closely together are, as already remarked, very nearly alike-so nearly alike indeed, that the errors of work- manship would entirely destroy the difference, particularly when the numbers are high. When the num- bers are very low, there is less room for deviation from the strict rule-not more, for example, between the form of a cutter for 16 and 17, than there is for a cutter for a wheel of 150 teeth and another for one of 300. This being the case, it appeared to Mr. Willis to be worth while to investigate some rule by which the necessary cutters could be determined for a set of wheels, 80 as to incur the least chance of error; and to this effect he has calculated, by a method sufficiently accurate for the purpose, the following series of what may be termed equidistant values of cutters; that is, a table of cutters 80 arranged that the same difference of form exists between any two consecutive numbers. TABLE OF EQUIDISTANT VALUES FOR CUTTERS. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 No. of Rack. 300 150 100 76 60 50 43 38 34 30 27 25 23 21 20 19 17 16 x 15 14 13 x 12 teeth. This table affords the requisite information in the selection of the wheel to which each cutter shall be accurately adapted, after it has been determined how many are necessary in a set. For example, if a single cutter were thought sufficient for a set of very small wheels, it had better be accurately adapted to teeth of 25, for that value is intermediate between the two extremes. If three cutters are to suffice for the whole set, then 76, 25, and 15 ought to be selected-of which the cutter 76 may be used for all teeth from a rack to 38; the cutter 25 from 38 to 19, and the cutter 15 from 19 to 12; and so on. In cutters, the greatest difference of form is at the apex of the tooth, that is, at the base of the cutter, and this amounts to t of an inch in 2-inch pitch, when the teeth have the usual addendum. From this the difference for any smaller pitch may be ascertained, and as many cutters interposed as the workman's notion of his own powers of accuracy may induce him to think necessary. Thus, if the hundredth of an inch be his limit of accuracy in forming his cutters, and he proposes to make a set for half-inch pitch, where the difference of form is & X t = 18, that is, Too nearly, then half a dozen cutters will be sufficient, and these must be made as nearly as possible to suit the wheels 150, 50, 30, 21, 16, 13. The following table contains a selection of numbers for different cases which may save trouble :- TABLE OF CUTTERS. No. of cutters in the set. Numbers of Teeth to be selected. 2 50 16 3 75 25 15 4 100 34 20 14 6 150 50 30 21 16 13 8 200 67 40 29 22 18 15 13 10 200 77 50 35 27 22 19 16 14 13 12 300 100 60 43 34 27 23 20 17 15 14 13 18 300 150 100 70 50 40 30 26 24 22 20 18 16 15 14 13 12 24 rack 300 150 100 76 60 50 43 38 34 30 27 25 23 21 20 19 18 17 16 15 14 13 12 Digitized by Google GEERING. 823 When the numbers have been selected, the Odontagraph may be employed to draw the figure of the cutter corresponding to each wheel, either on the same scale, or better, on a larger scale, which may be afterwards reduced proportionally to the size required. To explain the principle of the Odontagraph, let us, in the first place, observe the action of the two pieces in the annexed diagram, Fig. 2059, of which P and Q are the centres of curvature at the points 9059. 0 B P M M 8 n P of contact, and which are capable of revolving round A and B. It is plain that the line PQ is, in every position of contact of these curves, equal to the sum of their radii, and must therefore be constant during such motion; and hence, if for the circular arcs, a pair of rods AP, BQ, connected by a link PQ, be substituted, their angular velocity will be to each other as the segmental arcs which they respectively represent, and PQ will be a constant and common normal to their arcs of motion. It is also clear that a change in the actual lengths of the radii will not affect the motion, the distances of the centres being constant. Now let the rod A P be moved into a new position Ap, as shown in Fig. 2060; its extremity 2060. R If L T B Q I will manifestly carry with it the end of the link PQ, and communicate through it a motion to the arm BQ, causing it to assume likewise a new position Bq. It is necessary to know the relative value of this motion to that of AP which produced it, which, though constantly changing, may be thus deter- mined at any instant. When the rod PQ changes its position, it may be considered during its motion to turn about some centre in space, although the relative position of that centre be perpetually shifting. This centre must of necessity be the point in which the arms A P, BQ would intersect if produced: Thus the momen- tary centre, when the motion begins, is K. For as the extremity P moves round the centre A, the direction of its motion at starting must be perpendicular to AP, and therefore the momentary centre must be somewhere in the line AP produced. In like manner the initial motion of the extremity Q must be perpendicular to BQ, and the momentary centre must lie somewhere in the direction BQ Q: but these directions intersect in K, which is therefore the centre in space about which the rod PQ on starting into motion may be conceived to turn. And since the rod PQ turns about K, the direction of motion of P and Q are to each other at any given instant as their radial distances from K; that is, as PK and QK, which is true whether we consider them as the extremities of the rod PQ or of the radii A P, B Q; also the angular motions of the latter will be found by dividing those direct motions by their radii; that is, Angular motion of PK QK P round A: angular motion of Q round B : AP : BQ Digitized by Google 824 GEERING. If now we draw BS, then we have KL: AR by similar triangles KPL; APR BQ: QK KL BQS KLQ ...... ART BTS And compounding these three proportions we obtain PK QK BQ that is to say, the angular motion of the arms are to each at any moment inversely as the segments into which the link divides the line AB, joining the centres of motion or line of centres. If now the link move into a new position pq near the first, and it happen that this second position intersects the first in a point L above or below the line of centres, as shown in the Figure, then the ratio AT: BT will be changed into At: Bt, and consequently the angular motion will be an increasing or decreasing ratio. But if the point L coincide with the line of centres, this ratio for the moment will remain constant. Now, a little consideration will show that the point of intersection between two successive positions PQ, pq of the link must be at the place where the perpendicular from K falls upon it. For as K is the momentary centre of motion, the extremity L of the perpendicular will begin to move in line at right angles with it, and consequently will remain in the direction of the first position when the link has passed into the second position; in other words, it will be in the point of intersection of the two posi- tions. When, therefore, the rods are in such a position that the perpendicular from K meets the link PQ in the line of centres, the ratio of the angular motions of A P and BQ is constant; and if in this state the points P and Q be employed as centres whence short arcs are drawn through any common point M', as in Fig. 2059, and applied as teeth, these arcs will manifestly drive each other correctly when in the exact relative position described, and very nearly so when removed to a short distance on either side of it, which is the thing required. 2061. Now these relative positions of P and Q may be determined by a simple construction founded upon the necessary coincidence of L and T. Thus let A and B, Fig. 2061, be the centres of a pair of wheels, and A B the line of centres divided at T, the point of contact of the B pitch circles. Draw PTQ, making any angle with the line of centres, and upon it assume P as a centre from whence the circular side is to S be described of a tooth of the wheel whose centre of motion is A. To find the corresponding centre for a tooth of the wheel which turns upon B, draw TK perpendicular to PQ, produce AP to meet it in K; join KB and produce it to meet in Q, then will Q be the required centre-as will appear by comparing Fig. 2061 with Fig. 2060. If then a small arc m n struck from P be taken as the face of a tooth of the wheel on A, it will work cor- rectly with an arc m p struck from Q through m, and employed as a tooth of the wheel on B. Were BQ 80 taken as to make the angle K BT acute-for example at B', then would Q fall at Q' on the same side of T as P, but beyond it, and the effect would be that the tooth m p would be concave instead of convex. And if the angle = then will K B become parallel to PT, and the point Q being thus removed to an infinite distance, the arc m P of the tooth of the wheel on B will be a right line perpendicular to PT. The angle ATP is arbitrary, and its value may, therefore, be determined from other conditions than those stated. It may be remarked, however, that if made a right angle, the points P and Q will vanish by coinciding with T; and if it be made a little less than a right angle, the points P and Q will be thrown 80 near to T, that the radii by which the arcs are struck become too short, and the points of the teeth too much rounded off. On the other hand, if the angle A TP be made too acute, the action of the teeth upon each other at the moment of passing the line of centres and elsewhere becomes very oblique, and an injurious pressure is thereby thrown upon the axis of the wheels. By various trials Mr. Willis has adopted 75° as the value of the angle which appears to avoid these extremes, and he has accord- ingly employed it in the construction of his Odontagraph. Again, the position of the point m, through which the arcs are to be struck, is also arbitrary, and must be determined by considering which point of the action we wish to make the correct point. If the teeth consist of a single arc each, the correct point may be fixed at the moment of passing the line of centres, and therefore the arcs must be struck through the point T; but if the side of the tooth be formed of two arcs joined, one lying within and the other beyond the pitch line, then the action of one of them will be confined to the approach of the point of contact of the teeth and the line of centres, and the action of the other to its recess from that line, and m must be assumed upon such a principle that the correct point of each arc shall fall nearly in the middle of its action. The distance between the centres may also be found by calculation, thus: AR being perpendicular to PT, we have by the similar triangles ARP; PTK PTXAR PR TR-PT sin ATP AT.co& ATP-PT therefore sin Digitized by Google GEERING. 825 which is the centre for the arc m n. And similarly drawing BS perpendicular to TQ we have for the corresponding arc m p. Now the point P being obtained from the point K on the opposite point of T to A, these formulae be- long to that part of the tooth of the lower wheel beyond the pitch line and the flank of the tooth of the upper wheel The corresponding face of the upper and flank of the lower wheel may be determined in a similar manner, by joining Bk and following the course of reasoning stated for the point K. In these formulse, the values of PT and QT may be determined for any forms of teeth, and also for a set of wheels which shall work correctly together. But the greatest value which in this last case can be correctly assigned to KT must be one which, if r be the smallest radius, shall make KT=reinATP Consequently, putting R for the radius of the wheel, and angle ATP = 0 the values of D and d, that is, the distances of the centre points of the ares measured from T, will become d-R.r.come By assuming constant values of r and Θ in a set of wheels, the values of D and d which correspond to different numbers and pitches may be calculated and arranged in tables for use. In this way the tables which accompany the diagram of the Odontagraph were obtained by taking the least number of teeth to be given to a wheel = 12 and = 75°, the numbers being expressed in twentieths of an inch. In this way these tables may be extended at pleasure, and for any values of r and Θ; and perhaps it would be preferable in the construction of such tables to express the numbers in inches and 32ds of an inch, which would better adapt them to the common foot-rule. Involute teeth.-Involute teeth have the disadvantage, already stated, of being, when in contact, too much inclined to the radius, by which an undue pressure is transferred to their axes. Their mutual friction is thereby little affected, but that of the axes is increased, and their journals are more speedily worn. But they have at the same time the advantage of working with more accuracy under derange- ment and incorrectness of fitting, and any pairs of them will work truly to- gether in sets within certain limits, however different in diameters, the pitch 2062. being the same. Until Professor Willis had developed the mode of adapting the epicycloid to the condition in question, the involute was the only form known in practice by which the conditions of perfect figure for wheels of any sizes to work smoothly in wheels of any other sizes, could be satisfied. B To describe this curve for the teeth of a pair, of which the radii of the pitch circles, and pitch of the teeth are determined, we may employ the mode illustrated by Fig. 2062. Let A and B be the centres of the pair, and eb be their pitch lines; join A and B by a right line passing through c; from this last point draw cd, c d perpendicular to the radials Bd, Ad, and cutting them in d and d; this line dd is then a common normal to the teeth in contact, and the perpendiculars A d, B d, are the radii of the involute circles which form the acting faces of the teeth. The involute curve may be described mechanically in several ways. Thus let A, Fig. 2063, be the centre of a wheel, for which the form of involute teeth is A to be found. Let m.n a be a thread lapped round its circumference, having a loop-hole at its extremity a; in this fix a pin, with which describe the curve or involute a b h, by unwinding the thread gradually from the circumference, and this curve will be the proper form for the teeth of a wheel of the given diameter. 9064. B b o 9063. 2065. TM d B The involute a b---h may also be produced by an epicycloidal motion; for since the circumference of a generating circle, whose centre is infinitely distant, must be & straight line, we may form the invo- 104 Digitized by Google 826 GEERING. lute by making a straight ruler roll upon the circumference of the circle to be evolved. Thus let R, in Fig. 2063, be a straight ruler, at whose extremity a pin P is fixed with the point resting upon the point q of the circle; then by rolling the straight ruler upon the circumference, so that the point at which it touches the circle may move gradually from q towards r, the curve q p will be generated exactly simi- lar to the involute a b h, and the method is perhaps easier and more accurate than by unlapping a thread from the circumference of the evolute, as above described. Mr. Hawkins, in his Appendix to Camus' Treatise on the Teeth of Wheels, recommends a very simple instrument for striking involute teeth. Two views of this instrument are given in Figs. 2064 and 2065. In these a b is a piece of watch-spring, with two teeth cc, formed upon its edges; at a is a small screw by which the spring is attached to a templet formed of thin board, and equal to a sector of the circle upon which the involute is intended to be generated. At b a small bit of wire is inserted into the spring, to form two knees as a handle by which the spring can be kept stretched. The templet is equal in the thickness to the width of the spring. In using the instrument, the templet is to be fixed upon the drawing board or surface upon which the involute is to be traced; the centre f coinciding with the axis of the wheel, or its representative on the drawing board; then by holding the knobs b as a handle, and keeping the spring thereby tightly stretched, so that it remains a correct tangent to the circle, and lapping the spring upon the are of the templet, one of the points c will trace upon the surface over which it passes a curve which, when the point has arrived at the circumference of the pitch circle represented by the templet, will be a true involute of that circle. If the tracing instrument be now turned over, the opposite tooth c on the side of the spring now un- dermost, will, by repeating the same operation, trace the counter involute for the other side of the tooth of the wheel. Mr. Hawkins' mode of proceeding to draw the outlines of a pair of involute wheels with his tracer is simple, and may be explained by reference to Fig. 2062. Having drawn the line of centres A B, and divided it at c into parts A c, Bc, proportionate to the intended velocities of the two wheels, next draw the right line dd cutting the line of centres at c, and making with it an angle deviating not more than 20 degrees from a right angle. From centre A describe a circle touching the line d d at d within the pitch circle of that wheel, and which will thus have dd as a tangent at d. In like manner from B as a centre describe a circle touching the same straight line at d within the pitch circle of that wheel, and also having that straight line as a tangent. Then the distance between the two circles is the proper length of the teeth, from which, however, the necessary clearance ought to be deducted. The two cir- cles last drawn are likewise the bases upon which the involutes for forming the boundaries of the teeth are to be generated. Next, having provided two involute traces made in the way above described, each with a templet corresponding to a sector of the base circle of its wheel, the centre f of the templet is to be applied to the centres A or B of the wheel of the pair to which it belongs, and meeting the points d; then sup- posing the templet for A to be first used, let it be adjusted until the tracing point c of the spring coin- cides with some point as d of the base circle of the wheel B, by moving it until it meets the circum- ference of its own base circle at b, the side db of the tooth dc b will be formed, and of the proper length, by moving the templet spring over the space included between the exterior of one base circle to the other. By turning over the templet, and adjusting it for the required thickness, the outline of the opposite side of the tooth may be traced in the same manner. Repetition of the operation with the templet of B will give the form of the teeth of that wheel. If thought desirable all the teeth of the pair may be drawn in the way indicated, or a single tooth of each wheel may be accurately drawn, and two pattern teeth cut to the forms thus found. Mr. Hawkins states that teeth formed according to this method will communicate equable motion from either wheel to the other, without possessing any tendency to press the shafts outwards-which tendency would exist if the angle of the common tangent (dd) of the two base circles deviated much more than twenty degrees from a right angle with the line of centres. If the teeth of both wheels are to be of equal thickness at the base, which they ought to be when of the same material for the sake of equal strength, the part df of the common tangent ought to be bi- sected in the middle c of its length, and the involutes drawn in the way described will give the roots of the teeth so nearly equal, that a very slight correction only will be required-the amount depending on the relative diameters of the wheels. But when the teeth of one wheel are required to be thicker than those of the other, the part df of the common normal d d must be unequally bisected in propor- tion to the required difference. It is finally to be observed that the teeth may have their bases in any other circles than those given, since the radii of the generating circles are entirely arbitrary; but the proportion taken is found to satisfy the conditions required with very little outward action. In respect to the character of the in- volute curve as compared with the epicycloid, it is obvious that the former possesses the advantage that a greater number of teeth of equal strength may be given to a wheel by this than the epicycloidal form; for with the latter the space must be at least equal to the tooth, while not much more than half the space is required to be marked off on the base circle for an involute tooth of the same length. There are also more teeth engaged at the same time, and thus the strain is divided. Teeth of a rack and pinion.-A rack, as before observed, may be regarded as a wheel of infinite diameter. The teeth may, therefore, be defined by the epicycloidal method explained for spur-wheels, by making their planks straight, and the teeth of the pinion involutes. Now, the properties which have been shown to belong to involute teeth manifestly obtain, however great may be the dimensions of the pitch circle of their wheels, or whatever disproportion may exist between them. Thus of the two wheels A and B with involute teeth, which work together, let the radius of the pitch circle A c, Fig. 2066, of one become infinite; its circumference will then become a straight line represented by the face of a rack. But whilst the radius A c becomes infinite, the radius A D of the circle from which its involute teeth are Digitized by Google GEERING. 827 struck, and which bears a constant ratio to the first, will also become infinite, and therefore the invo- lute m a will become a straight line, perpendicular to the pitch line at a. For it is evident that the extremity of a line of infinite length, unwinding itself from the circumference of a circle of infinite diameter, will describe through a finite space a straight line perpendicular to the circumference of the circle. The involute teeth of the rack will, therefore, have their faces perpendicular to 2066. the pitch line; and this line will be deter- B mined by drawing a tangent to the circle on B through the point of contact from which the involute teeth of the pinion are to be struck. If the radius B m, with which the involute circle m of the pinion is described, be equal to the radius of its pitch circle, the line D m will become parallel to the face of the rack, and the sides of the teeth of the rack perpendicu- lar to it. But in this, while the teeth of one wheel, B, have remained unaltered, and the accuracy of their action uninfluenced by the change in the dimensions of the pitch circle of the other, which has converted it into a D rack, and its curved into straight teeth; it therefore follows that straight teeth upon a rack work truly with involute teeth upon a pinion. But as straight teeth are not the form of greatest strength which may be attained, and as strength is of importance as well as uni- formity of action, the conditions of the problem may be examined with a view to the best modi- fication which the form admits with respect to this test. If with the pitch radius B c of the pinion, Fig. 2067, we describe the pitch circle, and draw MN a tangent to it at c, we next make this right line the pitch line of the rack; and, further, describe the circle whose radius is Bh, making this last the base of an involute h then if the tooth of the rack be bounded by a right line h D E, making an angle BDM with the pitch line equal to Bch, and the involute h b be moved into the position h'b', it will drive the sloped tooth to the position P m, always touching it in the line h c H; and the velocity of the circumference of the pitch circle will always be equal to that of the pitch line. A wheel with involute teeth will work truly with a rack whose teeth are straight-sided, and 2007. inclined to the pitch line at an angle 0, pro- vided only radius of base Bh sin Θ. radius of pitch circle Bc In a rack of this kind, the locus of contact of the teeth being the tangent line h H, the sloping teeth will be pressed downwards by a B certain portion of the working pressure, which in some cases may be an advantage in itself by neutralizing vibration, and the advantage of a greatly increased form of teeth is at the same time secured. b The teeth of the pinion being of the regular epicycloidal form, the faces of the teeth of the P P rack will have a cycloidal form. But accord- M N ing to the usual method of setting out racks P c D and pinions, the pitch line of the rack is the V locus of contact, and the action on one side of the line of centres is confined to a constant H point in the rack tooth, which is thus subjected to rapid wear. This disadvantage may be abridged by reducing the length of the teeth of the pinion, but it may also be entirely avoided by taking a constant generating circle, and employing it to describe cycloidal flanks for the rack teeth by rolling on its pitch line, and then by describing the faces of the teeth of the pinion with the same generating circle, in the manner before described. By this simple modification, the contact will no longer be confined to the pitch line of the rack, but will be distributed over the flanks of its teeth and these, it may be observed, may be made of any length desired, by regulating the diameter of the generating circle accordingly. If the generating circle have a diameter equal to the radius of the pinion, the flanks of the pinion-teeth will then be radial, and this form may 1. also be modified by taking a circle of greater or less diameter. To determine the pitch circle of the pinion, let D represent the distance through which the rack is to be moved by each tooth of the pinion, and let these teeth be in number = N; then will the rack be moved through the space N X D during one complete revolution of the pinion. Now the rack and Digitized by Google 828 GEERING. pinion are to be driven by the action of their teeth, as they would by the contact of the circumference of the pitch circle of the pinion with the plane face of the rack, 80 that the space moved through by the rack during one complete revolution of the pinion must precisely equal the circumference of the revolv- ing pitch circle; consequently, calling R the radius of the pitch circle of the pinion, we will have NXD 2 = R = N X D Two of these quantities being given, the other immediately becomes known. Thus, let D=2 inches, and N = 13, then =4.188 inches. Annular wheel and pinion.-An annular wheel is one having its teeth formed within its periphery, and consequently the pinion works internally. In this arrangement, the form of the teeth may be de- termined according to the principles already explained, with very slight modification in their practical application. Thus, in Fig. 2068, let AB be the centres of the wheel and pinion; and let c be the point of contact of the pitch circles. The epicycloid m described by the circle having a diameter = B c, gives the lateral form of the tooth of the wheel, limited as before by a radius drawn to the middle of the thickness of the tooth; and an arc described from the centre B, with radius A n, cuts the circumference B c at a point which determines the side of the tooth of the pinion at n. But if we attempt to apply the same process to finding the face of the tooth of the pinion as we have employed in determining the flank of the wheel-teeth, we shall find that the construction will either not give the side of the tooth as the arcs do not meet, or it will give it a position upon the radius A c on the same side as the face cm. From this, then, it appears that the teeth of the wheel will have no flanks, and that their outline will consist simply of faces. From this it follows that the pinion would not drive the wheel uniformly according to the required condition, and in consequence we must find another curve for the faces of the teeth of this last. Now if we trace the epicycloid by a point c of the circle to centre A in the figure, rolling it exter- nally upon the circumference of the circle on B, it will give the outline of a tooth capable of fulfilling the condition of uniformity of action at any point of the circumference of the circle on A. Should the teeth engage before the line of centres, the tooth of the wheel would necessarily act constantly at that point and cause great wear, particularly as this species of geering is usually employed in conveying the motion of water-wheels where it is exposed to incessant wetting and vibration. In practice it is found sufficiently accurate to substitute for the epicycloidal method above described for finding the form of the face of the tooth of the pinion, the more convenient mode of defining it by an are of a circle drawn from the root of the tooth, with a radius equal to the chord of the pitch. When the teeth do not engage until they arrive at the line of centres, the faces of the teeth of the pinion may be entirely suppressed, leaving the flanks only, which are alone acted upon by the teeth of the wheel. This may be uniformly done, at least when the pitch of the pinion is small, and when the wheels are more than strong enough for the power which they are required to transmit. In such cases the following method of setting out the teeth of the pair may be adopted with safety. 2069. 2068. B d a P of m m n n c mg In Fig. 2068, let A be the centre of the wheel, and B the centre of the pinion as before. From the point c of contact of the two pitch circles mark off the arcs c a, b, equal respectively to the pitch of the pinion and wheel join a B and b a, and bisect this last; from the point of bisection raise a perpendicu- lar, and the point d, where this meets the pitch circle of the wheel, will be the centre from which the arc a b, defining the side of the tooth of the wheel, may be struck. The flank of the tooth of the pinion is determined by the two radii which limit its thickness and meet in B. To define the length of the teeth, it is sufficient to describe a circumference with the radii Ar, Bn, leaving sufficient bottom clear- Digitized by Google GEERING. 829 ance and the extremities of the teeth of the pinion, and the bottoms of those of the wheel, ought to be rounded off by ares drawn with a radius equal to the chord of the pitch taken upon the pitch circle of the pinion. By this method it will be seen that the strength of the pinion-teeth is greatly reduced, and ought therefore only to be applied when the power to be transmitted is comparatively light, and when the wheel drives the pinion. It is consequently not recommended for general practice. The epicycloidal method, explained for external wheels, may, on the contrary, be applied in all cases, observing that in the case considered, the space answers to the tooth, and conversely, the tooth to the space; 80 that keeping this distinction in view, the forms of the teeth may be determined with as much readiness as if the pair were of the ordinary kind of spur-geer. The teeth may also be set out with the Odontagraph, if that instrument be in use in the pattern shop. There is one property of the internal pinion which may be here pointed out, namely, the diminished friction which attends its working, as compared with an external pinion of the same diameter. To render this obvious, let PP, Fig. 2069, be the pitch circle of the wheel, QQ the pitch circle of an internal pinion, and Q'Q' that of an external pinion of equal diameter. Then supposing the wheel to drive, and that it moves until the point a arrives at b; by this advance, the same point of the pinions will have arrived respectively at d and c of the circles Q Q and Q'Q', having both moved over a space equal to ab. Now it is manifest that the distance from b to c is less than the distance from b to d; but these distances may be assumed as the measure of the amount of slide of the teeth of the respective pinions in moving to their new position; for whatever may be the actual amount of slide, it must evidently be in the ratio of bc to bd, since these quantities measure the velocity of the sliding contact of the pair; and since, when the circumstances are otherwise identical, the friction is as the space passed over. It is, therefore, evident that the internal pinion has less friction than the external one; and the same figure may be employed to show that it has a larger arc of contact with the wheel, and is, therefore, other things being equal, stronger than the external pinion. Teeth of bevel-wheels.-When a cone is made to revolve upon the surface of another fixed cone, in such a manner that their summits always coincide, the curve which is generated by a point in the cir- cumference of the rolling cone is a kind of epicycloid, which will plainly lie on the surface of a sphere whose centre is the common apex of the cones, and whose radius is equal to the slant side of the rolling cone. From this property the curve is termed the spherical epicycloid; and if the cone roll on the concave surface of the base, the curve produced is denominated the spherical hypocycloid. 2070. R h h a t m B To apply this definition, let there be two cones in contact along their slant sides A c, Fig. 2070; and let c A a be any other cone, having its line of contact coinciding with A c, and having its apex at A; the axes of these three cones will then be in the same plane A RB. The circumferences will also be at the same distance A c from A, and will lie on the surface of a sphere whose centre is A and radius A c. Now, suppose the three cones to revolve above their respective axes with the same relative velocity Digitized by Google 830 GEERING. as would be produced by the rolling contact of their surfaces, it is clear that the line of contact will constantly be Ac, and calling a A c, Fig. 2070, the describing cone, a line db upon the circumference of the surface of this directed to the common apex A, will generate one surface fbdt on the outside of the cone A c m, and another surface dehb on the inside of the cone c Ar. These surfaces will touch along the describing line b; for since f d b is generated by the rolling of the generating cone on the cone m Ac, the motion of db is at every instant perpendicular to the line of contact A c, and therefore the normal plane at d to the surface generated by that line, must pass through the line of contact A c In like manner the normal plane to the surface h e db will pass through the line of contact of the cones, and consequently the surfaces must touch along db. Now, under these conditions, it is clear that if the rotative motion of the cone m A c be communicated by teeth to the cone c A r by their contact action, the teeth being generated by the describing cone a A c, the motion will be the same as that produced by the rolling contact of the conical surfaces, for at the beginning of the motion ft and e h coincide with the line of contact Ac; and since the arcs cf, ce, de- scribed by the bases of the cones, are, respectively, equal to d, and therefore to each other. 3 2071. 4, € k y 4 In practice the portion of spherical surfaces occupied by these arcs, when employed as teeth, are narrow belts of the cones extending only a small distance within the circle of the bases, and therefore cones tangent to the sphere along cm and cr may be substituted for the sphere itself without practical error. Thus draw R c B perpendicular to the line of contact A c, and intersecting the axes of the two cones at B and R; then B R revolving about A B will generate a conical surface tangent to the sphere along the base cm; and the same line R B revolving about A R will generate a conical surface tangent to the sphere along the base cr of the cone c Ar. And since the arc df, which really lies in the spherical surface, is very short, it may be supposed, without sensible error, to lie in the sur- face of the tangent cone c Bm, and to be described with a circle whose diameter is equal to that of the base of the describing cone. And, in like manner, the arc d e may be supposed to be similarly de- scribed upon the surface of the tangent cone c Ar. These principles furnish us with a ready mode of obtaining the form of the teeth of a pair of bevel- Digitized by Google GEERING. 831 wheels. Thus let AP and AQ be the axes of the shafts between which the motion is to be trans- mitted. The angular velocities with which the two shafts are driven being determined, draw A D such that it divides the angle PA Q into two parts, proportional to the numbers of teeth in the wheels respectively, or inversely proportional to the angular velocities or numbers of turns per minute of the wheels on the shafts. If we conceive the line A D to revolve about the axis AP, at the same angle PAD, the conical surface A DE will evidently be described, a portion of which, E d, is represented in Fig. 2071. Similarly, by the revolution of the line A D about the axis AQ, the conical frustum F fd will be described. It is obvious, therefore, that these two cones, communicating the motion by simple contact, will transmit motion in the given ratio, and hence they are termed the primitive cones, and have an obvious analogy to the primitive circumferences or pitch circles of spur-wheels. In the interior of their mass the flanks and spaces are conceived to be formed, and upon their surfaces are placed the projecting faces of the teeth-the returning surfaces and F n of the cones, or the crowns, as they are termed, are defined by inverted conical surfaces formed upon the bases DE and DF; they are short frusta of the cones BDE and CDF, the common apex of which is determined by the line BDC drawn at right angles to AD. To perceive the propriety of this form of the crown, it is only necessary to consider that the ends of the teeth Em and Fn will thus always be square with the sur- face of the primitive cones, and they will geer most completely into each other. The other ends of the teeth are defined in like manner by the conical recesses and dcf, which are parallel to the exterior surfaces of the crowns; the line bdc being, like the exterior line, at right angles to A D. It appears, then, that the true forms of the teeth may be described with facility upon the surfaces of the cones DEB and DFC; and for our present purpose of representing the forms of these teeth upon a plane surface, it is only necessary to conceive those surfaces spread out or developed upon a plane. Now, the development of a cone, that is, the form assumed by the superficies when laid out flat, is a sector of a circle, of which the radius is equal to the slant height of the cone, and the arc equal to the circumference of the cone at the base. In the case before us, therefore, if a circular arc DG be described from the centre C with the radius CD, it will be the development of a portion of the base, and the sector CDG will likewise be the development of a portion of the cone; and by describing an arc kg with the radius Ck or Cg, the annular space contained between k and DG will be the de- velopment of the crown of the wheel. It is upon this annular segment, then, that the forms of the teeth may be drawn precisely as if it was a part of a spur-wheel; and if we suppose a piece of sheet copper or other suitable material to be cut into the form of the teeth, and wrapped upon the crown of the wheel, the outline which could thus be traced off would represent the true forms of the teeth of the bevel-wheel. The breadth being settled by the same rules as for spur-wheels, it is obvious that the teeth must follow the taper of the cone towards the point A. Draw dk parallel to A C, and from the centre C describe the arc then, as before, the segment Ckg will be the development of a portion of the cone and upon this segment the forms of the upper ends of the teeth may be described. Lines drawn from the teeth on the are DG to the centre C, will determine the magnitude of the teeth on the arc kg, and the teeth may thence be described, as in the figure. The largest diameter DF is reckoned the diameter of the wheel, and, similarly, DE is said to be that of the pinion. The process which we have detailed for describing the teeth of the wheel is pre- cisely the same as that for describing the teeth of the pinion. It is unnecessary, therefore, to particu- larize further, than that Fig. 2071 shows the teeth of the pinion drawn similarly to those of the wheel, upon the arcs D H and ih. That the teeth thus formed will work truly together, becomes obvious, when we reflect that if any two exceedingly thin wheels, with the form of teeth described, had been taken in a plane perpendicu- lar to A D passing through the point D and having their centres in the axes of the given wheels, they would work truly together, and their angular velocities would be in the given ratio. Now it is evident that the portion of each of the conical surfaces which is at any instant passing the line k i is at that instant revolving in the plane perpendicular to A D which passes through the point D, the one surface revolving in that plane about the axis A C, and the other about the axis A B. Those portions of the teeth of the wheels which lie in these two conical surfaces will, therefore, drive one another truly, at the instant when they are passing through the line ki, if they be cut of the form which they must have had, in order that they might drive one another truly and with the required angular velocity, had they acted entirely in the plane perpendicular to AD and about the given axes. But this is precisely the forms in which the teeth are supposed to be cut, and therefore those portions of the bevel teeth which lie in the conical surfaces will drive one another truly at the instant they are passing through the line ki and, therefore, they will drive one another truly through a small arc on either side of that line, which is the condition required, since it is only through an exceedingly small distance on either side of that line that any two given teeth remain in contact. It therefore follows, that those portions of the teeth which lie in the conical surfaces Df, De, work truly with one another throughout the whole breadth of the conical belt. If the radius of the base of the frustum be called R, and the radius of its developed circle be r; also if the semi-angle C A D of the rolling cone = Θ; then = R Θ Hence the action of the teeth in any bevel- COS wheel is equal to that of a spur-wheel whose radius = cos Θ' R and if N be the number of teeth in the bevel-wheel, N Θ will be the number of those in the spur-wheel of equal action. Thus if 0 = 50°, cos then R = 64279 1 = 1.556, and therefore the action of a bevel-wheel of 50° is fully equivalent to CO3 that of a spur-wheel having a radius one-half greater, and consequently a half more teeth. Digitized by Google 832 GEERING. This, then, is a reason for the superior action of bevel-wheels, as compared with spur-wheels of the same number of teeth; for spur-wheels always act the better the more teeth they have, and it appears that the bevel-wheel is always equivalent in its action to a spur-wheel of a greater radius, and conse- quently a greater number of teeth. When a pair of bevel-wheels have equal numbers of teeth, and have their axes at right angles to each other, they are termed mitre-wheels. In this case Θ = 45° and COS 0 = 70711 ; therefore taking 1 radius equal unity, we have = 14; in words, the action of a meter-wheel is nearly equivalent to cos 0 that of a spur-wheel, with half as many teeth. Skew-bevels.-When the axes are inclined to each other, and yet do not meet in direction, and it is proposed to connect them by a single pair of bevels, the teeth must be inclined to the base of the frusta to allow them to come into contact. 2072. To find the line of contact upon a given frustum of the tangent- cone; let the Fig. 2072 be the plane of the frustum; a the centre. Set off ae equal to the shortest distance between the axes, (called the eccentricity,) and divide it in c, 80 that a c is to ec as the mean radius of the frustum to the mean radius of that with which it is to work draw p perpendicular to ac, and meeting the circumference of the conical surface at m; perform a similar operation on the base of the frustum by drawing a line parallel to c m and at the same distance ac from the centre, meeting the circumference in p. The line pc is then plainly the line of direction of the teeth. We are also at liberty to employ the equally inclined line cq in the op- posite direction, observing only that, in laying out the two wheels, the pair of directions be taken, of which the inclinations corres- pond. Fig. 2073 renders this mode of laying off the outlines of the wheels at once obvious. In this figure the line a e corresponds to the line marked by the same letters in Fig. 2072; and the division of it at c is determined in the manner directed. The line c m being thus found in direction, it is drawn 78 2073. indefinitely to d. Parallel to this line and from the point c draw e to e, and in this line take the centre of the second wheel. The line c m d gives the direction of the teeth; and if from the centre a with radius at a circle be described, the direction of any tooth of the wheel will be a tangent to it as at c. Digitized by Google GEERING. 833 And similarly if a centre e be taken in the line E d, and with radius e d = c e a circle be drawn, the direction of the teeth of the second wheel will be tangents to this last, as at d. Having thus found the direction of the teeth, their outlines may be described exactly as in the case of ordinary bevel-wheels, and with equal exactness and facility. Wheel and tangent screw.-This is often a very convenient and ready mode of reducing a high velocity. To determine the form of the teeth of the wheel and thread of the screw, it may be remarked that, from the nature of the screw, the section of its thread, made by a plane passing through its axis, is everywhere the same; and that if a series of such sections of the entire screw be made by planes at equal angular distances round the circle, a set of figures, resembling a double rack, will be obtained alike in the number and form of their teeth, but in which the teeth will approach nearer and nearer to the extremity of the screw. Now, while revolving, the screw successively brings these sections into operation upon the whole teeth, producing exactly the same effect as if the screw were pushed endlong without rotation, in the manner of a rack. But this supposition furnishes a ready mode of obtaining the forms of the wheel-teeth and thread of the screw, upon the principle of the rack and pinion. In Fig. 2074 a c is the line of centres of the wheel and screw. The screw is shown in section by a plane cutting it in the line of its axis. Now, the screw being considered a driving rack, it passes a tooth of the wheel during each revolution, and therefore the point a will, at the end of a revolution of the screw, be the point b; but the thread must necessarily have continued in contact with the tooth while passing from a to b. Now, if it be required that the thread of the screw shall be in contact with the tooth at a point only, the tooth will be straight, and its obliquity equal to the pitch of the screw. But if it be desired that the thread shall be in contact with the entire side of the tooth, the outline of the wheel-teeth must be different in every section perpendicular to the axis of the wheel. The required form will be found by making such series of sections of the screw as proposed, and adapting the portion of the side of the tooth to that particular section with which it is intended to work. And since in every section two or even three teeth may be in simultaneous contact, the screw may be in contact along the entire side of those teeth. 2074. P P P P In practice, then, the form of the tooth must be determined for the respective sections of the screw, as in the case of the rack; and the thread of the screw may obviously take the same sloped form if great strength be required. To find the diameter of a wheel, driven by a tangent-screw, which is required to make one revolution for a given number of turns of the screw, it is obvious, in the first place, that when the screw is single- threaded, the number of teeth in the wheel must be equal to the number of turns of the screw. Conse- quently, the pitch being also given, the radius of the wheel will be found by multiplying the pitch by the number of turns of the screw during one turn of the wheel, and dividing the product by 6-28. When a wheel-pattern is to be made, the first consideration is the determination of the diameter to suit the required speed; the next is the pitch which the teeth ought to have 80 that the wheel may be in accordance with the power which it is intended to transmit; the next, the number of the teeth in relation to the pitch and diameter; and, lastly, the proportions of the teeth, the clearance, length, and breadth. The size and proportions of the wheel being thus settled, the operation of constructing the pattern is ready to be undertaken. Let us, in the first place, assume that the wheel is to be a radial one with six 105 Digitized by Google 834 GEERING. arms, and here it must be premised, that the number of arms increases according to the diameter of the wheel-thus, with occasional deviation: Wheels from 11 to 31 feet diameter have 4 arms. " from 31 to 5 feet diameter have 5 " " from 5 to 84 feet diameter have 6 " " from 81 to 16 feet diameter have 8 " " from 16 to 24 feet diameter have 10 " It is assumed in the numbers of this table, that the wheels are cast complete, the boss supporting the arms, and these last the rim with the teeth cast upon it. The cases of deviation are those in which the wheels are very small, and cast with a continuous web, instead of radial arms, and where the wheels are required to be particularly light, and to possess great accuracy: it is in this case preferable to increase the number of arms, so that they may be made thinner, and thereby incur less risk of the rim being drawn out of form during the cooling of the metal In arm-wheels the rim is always built of segmental pieces, cut out of plank of convenient thickness, to an external radius equal to the pitch radius of the wheel, which allows a depth equal to the flanks of the teeth for dressing. A templet or mould is, in the first place, made of thin, well-seasoned and dry board, and by this the form of the building segments is drawn upon the wood from which they are to be cut. Suppose that the rim is of such breadth that six thicknesses of wood are required to make it up; then four segments are cut of the requisite breadth and to the same internal radius, and two of them to an internal radius less than the former by at least as much as the intended thickness of the rim. With these segments the rim is to be built in the following manner :- A circular plate of wood, with an iron centre on the back of it, usually with an internal screwed boss on the centre of it, having the same pitch of thread as the thread of the screw on the projecting end of the lathe-spindle, is prepared and turned up truly on the face. A circle is also described upon it to indicate the pitch line of the wheel, and to this circle the exterior arcs of the rough segments are to be adjusted. Thus prepared, the first course of segments are planed true on one side, and fitted with sprigs upon the plate, their ends accurately jointed together, glued, and sprigged. When the glue is in some de- gree set, the plate is put upon the spindle of the lathe, and the segmental ring is turned true on the flat side; but the interior and exterior circumferences are left in their rough state. The plate is then removed from the lathe-spindle-usually a simple spindle with not more than two speeds upon it. Another course of the segments is now dressed with the plane on one side, and built upon the first. This course is bedded with glue and sprigged to the first course, observing that the joints of this course do not coincide with those of the first, but that all the former joints are covered by the whole wood O2 the last-laid course. The glue being allowed time to set, the plate is again put upon the lathe-spindle, and the face of the ring is dressed as before, still leaving the circumferences in their rough state. The segments of these two courses are of the same breadth, but the next course to be laid must have the increased breadth necessary to form the web or feather of the rim; this, as already stated, is usually made equal in breadth to the thickness of the rim. This course will, therefore, project inwards over the ring formed by the two courses already laid. In other respects, however, it is not different, and it is laid and fastened in exactly the same manner as the second course. Two courses are laid of these broader segments; afterwards two others of segments of the same breadth as the two courses first laid. This done, the building of the rim is complete, and a cross sec- tion of it would present the appearance shown by the part a dbc, Fig. 2075, and an arc of it in elevation 2075. 2076. a 3 c 6 5 4 3 R 2 1 c a d is represented by the part A b, Ba, Fig. 2076. In Fig. 2075 the courses are numbered in the order in which they are supposed to be laid, the layers 3 and 4 being those which are intended to form the web of the rim. This process being completed, and the face-plate placed on the lathe-spindle, the exterior edge of the rim and half the interior circumference, that is, the interior of the three courses marked 4, 5, 6, are turned true to the required form. The rim is then taken off the face-plate and reversed: but is now fastened to the plate by screws passed from the back of the plate into the edge of the rim. In this position the interior of the other half of the breadth of the rim is dressed, that is, the inner circumfer- ences of the layers 1, 2, 3, when the rim is ready to have the arms fitted into it. In being dressed, the web or feather formed by the two middle layers, 3 and 4, is diminished in thickness, till at their edge they are together exactly of the same thickness as the arms which are to be put into the pattern; and a good practical rule is, to make these equal in thickness to seven-eighths of that of the rim of the wheel In breadth they ought to be equal, at least, to the breadth of the rim, when this is calculated according to the rule of maximum strength already pointed out, and Digitized by Google GEERING. 835 towards the centre should be increased to Iths of that breadth. More commonly they are made equal in breadth to the rim, and tapered to fths of that breadth at their extremities. The breadth of the arms being determined, they are to be fitted into the rim by a half-check upon the web, which is done by checking out at six points, answering to the number of the arms, the breadth of an arm in the web layer marked 3. The extremities of the arms are then checked to the same depth, and fitted into their places with a little glue, and two short but strong screw-nails at each end. The mode of fitting the arms together is different in different shops; but the easiest mode is to fit a double arm in the manner described-that is, an arm extending through the diameter, and having a half-check at the middle of its length cut to the proper angle to receive the second double arm extend- ing, like the first, through the complete diameter. These being fitted in, two half-length arms are then inserted, butting into the wide angles left at the centre between the arms already fitted. Fillets are next inserted to fill up and round off the acute angles, both at the centre and extremities of the arms these are intended to give additional strength to the wheel, and to facilitate the extraction of the pattern from the sand in the process of moulding. Were the acute angles left open, the sand would be ready to break down and give the wheel an uncouth and rough appearance, a result which is to be guarded against in all kinds of moulding, and more especially in wheels. The flat arms being thus fitted in, the next operation is to insert a centre, upon which the boss or eye of the pattern may be at any time built according to the size necessary for the particular wheel to be cast off the pattern. The centre is formed of two hexagons, one laid on each side, and built of six separate pieces, or made of single solid blocks of half the depth of the rim, so that on each side the centre projects beyond the plane of the rim by half the thickness of the flat arms. The centre is firmly screwed together, and to the arms of the pattern; and on one side-the side which is intended to be uppermost in the process of moulding-a flat plate of iron, usually of the same form as the centre itself, is indented and fastened with screws to the wood. This plate has a hole in the centre, intended to admit an iron prong for starting and lifting the pattern out of the sand. The next operation is to attach the feathers of the arms. These are placed along the middle of the flat arms, the planes of the two being at right angles to each other, so that their cross section at any point is represented by +. The breadth of the feathers diminishes from the centre towards their extremities, in exactly the same ratio as the flat arms; at the centre they are half the width of the rim, and consequently stand flush with the depth of the centre, but at the extremities which meet the rim the width is reduced a sixth. Fillets are fitted in to fill up the angles which the ends thus form with the inside of the rim, for the reasons already stated. Small running fillets are likewise fitted into the angles which they form with the flat arms. The interior of the pattern may now be considered as finished; and it may be remarked that it is always desirable to have the arms completely fitted and secure, before commencing to turn the exte- rior of the rim; for should the rim be dressed on the outside previously to the arms being put in- which is practised by some makers-it is hardly possible to prevent its springing, and being thrown out of truth. By the process described, the arms are fitted in while the exterior of the rim is in its rough state, and consequently, although it should slightly spring, the external and most important cir- cumference will be brought to the truth in the after process of turning. The rim is also stronger and less liable to be thrown from the truth, while in the rough state, than it is after being finished to the thickness. After the arms are fitted into the interior of the wheel, and finished in the manner described, it is taken from the face-plate; a hard-wood plate, with a centre for the lathe-spindle, is screwed upon the eye of the pattern; it is then placed in the lathe, and the exterior of the rim is turned to the required thickness. In this process it receives a very slight bevel-usually from an eighth to a tenth of an inch in a foot-to allow it to draw cleanly from the sand in the process of moulding. About the same frac- tion is allowed upon the diameter of the pattern for contraction of the metal in cooling. The next part of the operation is to cut the dovetail seats of the teeth. The form of these recesses is shown in Fig. 2076, beneath the teeth. They extend completely across the breadth of the rim, and are intended to receive the dovetail pieces (bd, Fig. 2075) on which the teeth are fixed. The dovetail pieces are themselves made of hard wood, and besides being otherwise convenient, they serve to bind the several layers of the rim firmly together. These pieces are, in the first place, accurately fitted into the seats and marked, so that every piece may be replaced inserted into the proper groove to which it was fitted; the rough pieces of which the teeth are to be formed—these being cleaned with the plane on one side-are then fitted, each with a dovetail fastened by screws to its dressed side; and being cut nearly to the proper length, they are fitted into their places by the dovetails, which are made with a slight taper, 80 that they can be the more easily driven in its seat, and taken out again when required. The blocked teeth being thus all placed and partially fixed upon the circumference of the pattern, this is again placed on the lathe for the pur- pose of dressing off the ends and points of the teeth. This done, the pitch circle of the wheel is finally marked off upon the ends of the teeth with a fine point. The pattern is now ready to have the form of the teeth drawn in, as represented in Fig. 3, by an arc of the rim, at this stage, with the outlines of the teeth also drawn. In this figure the pitch line is denoted by the dotted circle pp, and the form of the teeth is denoted by the shaded portions of the rectangular blocks. The various methods of obtaining the outline have already been fully explained. To finish the pattern, it therefore only remains to dress off the teeth to the forms indicated, and to fix the dovetails permanently in their beds. This last is easily effected by a film of glue; and if the teeth are to be finished by the wheel-cutting machine, it ought to be performed previous to placing the pattern in the lathe for the purpose of dressing the ends and points of the teeth, and consequently before pitching them. But when the teeth are to be finished by hand, the order of the operation is that described and the most commonly practised. In finishing the teeth by hand, they are removed in succession, by driving out the dovetails, one only Digitized by Google 836 GEERING. at a time; the unshaded portions of the block are then accurately dressed off by concave and convex guge-planes adapted to the purpose; the dovetail is then fitted into its bed with a film of glue; and the tooth is complete. Every tooth is treated in exactly the same manner, until the whole number be dressed and fastened upon the circumference of the rim. But unless the operation of fixing the teeth be performed with care, there is danger of twisting the rim and throwing it out of truth.-To guard against this, the safest practice is to take always in succession the pair of teeth opposite to each other on the circumference: that is, having fitted a tooth on one side of the pattern, the tooth opposite to it on the other side ought to be the next taken, so that any tendency of the glueing to twist the rim at one point will be neutralized by an opposite tendency in fitting the next tooth-The wheel pattern may now be considered complete. It is to be remarked, that in making the pattern of a cast-iron wheel, it is necessary to take into account the nature of the material: the pattern must not only be of such a proportion of parts as to be sufficiently strong, calculated by the series of the parts; it must also be 80 proportioned that the fluid metal, when poured into the mould, shall set in every part as nearly as possible at the same instant. For if the parts contain disproportionate quantities of metal, it is plain that the thinner parts will cool more quickly than the others; and as cooling is attended with contraction, the parts of the casting will be put upon strain, from their contracting irregularly and faster at one point than at another; and if the irregularity be carried to a certain extent-and the limits are not wide-the cast- ing, on being removed from the mould, will be found fractured through some of the thinner and first cooled and first contracted parts. Thus, one of the most common errors is to put too much thickness into the boss of the wheel, and in consequence it not unfrequently happens that the arms are drawn away from the rim. To avoid this, the metal round the eye ought never to be more, in arm-wheels, than twice the thickness of the rim; that is, equal to the pitch of the teeth, and this is quite sufficient in strength to resist the driving of the keys in fitting the wheel on the shaft, provided this operation be done with ordinary skill and care. To prevent the bad effects of unequal contraction, the arms are sometimes made of a curved form. When the wheel is very light in proportion to its diameter, the arms are advantageously made with a double curve like the old letter f, which admits extension to a certain extent, depending on the elasticity of the material, in the direction of its length, without fracture. The rules and directions which apply 2077. to spur-wheels, likewise apply, with C slight technical modifications, to bevel- wheels. The mode of laying down the working drawings of a pair of this kind has been already explained and figured in relation to the manner of obtaining the form of the teeth; and the proportion of parts may be depicted in connection with the same drawing, by substituting for the primitive cones there given, a section of the pair as represented in Fig. 2077. Here A P is the common pitch line of the pair, determined as before de- scribed; and BP, CP are the radii of the wheels. The breadth of the rim of the wheel is marked off from P B towards A, and through that point the P perpendicular bb' is drawn. Another perpendicular to the same line is drawn through the point P, and of course parallel to bb'. Upon these perpendiculars to the pitch line AP, the lengths of the teeth are set off, and also the thickness of the rims, as indicated by the lines a b, a'b'. The distance a a' will be the length of the tooth plus the bottom clearance; the space inclosed between a or a' and the pitch line the length of the flank of the tooth; and from the pitch line to the dotted lines at a and a' is the measure of the addendum of the teeth. The thicknesses of the rim and arms are in the same relation as for spur-wheels; but in this case they are not placed opposite the middle of the rim and boss as before, but entering on one side of the smallest diameter of the wheel, with the feather entire and projecting outwards, 80 that a cross section of the arm complete would present the appearance T. the horizontal line indicating the face-arm, or web, and the vertical piece the feather of the same. The boss or centre of the wheel is built in the manner already described, and of the same relative proportions, but altogether on the side which is furthest from the apex of the ideal cone, of which the wheel is a frustum. The feather of the arm is inserted upon the same side, and is of equal breadth to the face-arm. This is commonly sweeped by a double curve, as in the diagram, Fig. 2077, but often it is simply tapered from the rim till it meets the central boss, which, in well- proportioned wheels, is usually equal to the breadth of the rim plus the thickness of the face-arm. The mode of building the rim, which, with the exception of the teeth, forms the only practical differ- ence between wheels of this class and spur-wheels, will be understood from Figs. 2078 and 2079. which show the order of position of the segmental rings in plan and section. The segments of the ring marked 4 being cut to the proper breadth, according to the thickness of the wood used, they are sprigged to the face-plate, and dressed on their exterior surface, as before explained. But in the oper- ation of dressing, their internal edge is commonly cut away to the diameter at which the next course Digitized by Google GEERING. 837 marked 2 is to be laid. This operation is not indeed essentially necessary, but it affords to the workman a better guide than a mere surface line described with the required radius, and is done without trouble The succeeding courses are sprigged and glued on in succession, every succeeding course being increased in diameter according to the angle which the side of the cone forms with the axis; in other words, accord- ing as the bevel of the wheel is more or less. Usually, the first two courses are flush on their inside circumference, as shown in the sectional diagram of Fig. 2079. The rim being thus built, is next to be dressed on its inner circumference to the diameter required. This done, the face-arms are half-checked into the 2078. radial part of the ring marked 3, ex- actly as in the case of the spur-wheel pattern. The centre and feathers of + 3 2 1 the arms are inserted in succession, and 2079. before the rim is removed from the face-plate. But as soon as these oper- 4 ations are completed, a centre-plate is 3 fitted to the pattern, and concentric a with it; the face-plate is then removed, 1 and the pattern is fitted on the lathe by the centre-plate, for the purpose of having the face of the rim turned. This must necessarily be true to the required bevel, and therefore implies additional care on the part of the workman whose usual method is quite exact. In the first place, he turns down the edge of the course marked 1 to the required diameter; then having fixed for the apex of the imaginary cone a point or edge, he applies a straight-edge from time to time during the process of turning, when it is evident that so soon as his straight-edge coincides with the whole breadth of the rim, and at the same time touches the apex and base of the cone, the operation of turning is complete, and not before this coincidence is attained. An easier method is, however, to turn the greatest and least diameters in succession-with which the drawings furnish bim-and afterwards to dress down the face of the rim until a short straight-edge touches the two diameters at the same time, and consequently coincides with the face of the rim throughout its whole breadth. If this be not deemed sufficiently exact, a mould may be formed from the drawing of two slips of wood so joined together as to coincide at the same time with the face-arm and face of the rim; the greater of the two diameters being struck, as in the method first proposed, it is evident that the mould will, on being applied, coincide with the lines on which it was found only when these agree with the drawing. The rim being finished by one or other of the methods described, the next part of the operation is to make the dovetail-grooves which are to receive the dovetails of the teeth. These are cut with the same attention to accuracy of taper as was used to determine the bevel of the rim; for as the teeth ought manifestly to diminish in thickness as they extend towards the apex of the cone, where, if con- tinued to that point, they would vanish, it is consistent with the general character of the work, although not essentially necessary, that the dovetails upon which they are to be fastened take the same tapered form. As in the spur-wheel patterns, those dovetails ought to pass through and take hold of each of the several courses of segments of which the rim is built, and thereby act as keys to bind them per- manently together. When the dovetails are fitted and the teeth fastened to them, they are firmly driven into their seats; and the teeth are dressed in the lathe on the ends and points to the required size. The external and internal pitch lines, that is, lines coinciding with the surface of the imaginary cone of which the wheel is a frustum, are drawn upon the ends of the teeth. Upon these lines the centres of the teeth are marked off. next their thickness, and lastly their form is described either by the method of curves, or by pattern teeth shaped according to the mode of development already explained. The dovetails are then driven out, and the body of the teeth accurately dressed to the curves traced on the ends. But this part of the operation ought to be performed in the successive manner directed for spur- wheels, and with the same attention and precaution to prevent the twisting of the rim, which is almost invariably the result when the teeth are fitted consecutively. It very seldom happens that two castings are to be made from the same pattern with the same sizo and form of eye. It becomes therefore necessary to have a ready mode of altering the size and form of the centre according to the size and form of the eye wanted. This is provided for by making the original and solid centre smaller than any boes likely to be required for a wheel of the particular pitch. This allows of a temporary centre being built around the original one, of the particular size wanted and as the eye is always taken out by a core, a print of corresponding diameter is sprigged on to guide the founder in the size and also in the setting of his core. It is also necessary often to have the boss and arms more on one side of the wheel than the other, a case which cannot be provided for by making these loose. To modify the pattern for a casting of this kind, the difference is made up temporarily, on the side to which the increase is desired, by pieces simply sprigged to the proper arms and centre of the pattern; the quantity to be removed from the other side is then carefully marked off by chalk lines drawn upon the feathers of the arms and round the centre; and when the pattern is moulded, the parts so chalked off are filled up in the sand. If Digitized by Google 838 GEERING. the modification, however, be of such extent as to alter the position of the face-arms, it then becomes necessary entirely to inclose the arms with thin board, forming a species of box, of a depth determined on the one side by the position of the arms and centre of the pattern, and on the other by the position which they are to occupy in the casting. The pattern being moulded in this condition, there is left only large open spaces for the arms and centre; and into these the new arms and centre are built by cores formed by core-boxes made to the particular shape and size desired. This is perhaps one of the greatest niceties of green sand moulding. For wheels of small diameter and pitch, it is now becoming a general practice to use metal patterns, of cast-iron and brass. In works where small machinery is made, and which are commonly provided with wheel-cutting machines, the rim is usually made of sufficient thickness to allow the teeth to be out upon it, and yet to leave the proper thickness of metal for strength between the bottoms of the spaces, and the web-plate which connects the rim with the eye-boss of the wheel. Sometimes also the same method is adopted with wheels which are crossed-out. This method admits of greater accuracy than that described for large wheels; for before proceeding to cut the teeth of the wheel, the casting may be accurately adjusted to a centre in the lathe, and have the strength of its parts at the same time exactly proportioned to the pitch of the teeth. The centre wheel thus admits of being polished, a process which not only improves the appearance, but likewise insures correctness of the work. The mode of constructing the pattern of a mortise-wheel, differs from the ordinary routine for toothed patterns in little more than the omission of the teeth. The rim is however made wider than that of a toothed wheel of the same pitch, by twice the thickness of tooth; and its thickness is double that of the ordinary toothed rim. The manner of construction is this: The rim is built and dressed, and has the arms and centre fitted into it as already described. The dovetails are also fitted into the corresponding grooves in the rim but these, instead of having teeth fixed upon them, carry simply their pieces to serve as core-prints to guide the founder in laying in his cores to make the mortises for receiving the tails or tenons of the teeth. These prints are made in length equal to the breadth of the teeth, and in breadth equal to their thickness. When the pattern is moulded the prints leave their impressions in the sand, and these are filled by cores of corresponding size and of a depth equal to the thickness of the rim. The rim of the casting being carefully faced up, or dressed in the lathe, is ready to be cogged. The cog-tenons are in the first place fitted tightly into the mortises of the rim; the wheel is then put into the lathe and the points of the teeth and ends of the tenons are dressed off in precisely the same way as the wooden teeth of a wheel-pattern the pitch lines of the wheel are then run upon them with a point, and the curves of the teeth being described, the cogs are ready to be taken out and finished bv hand; or the wheel may be put into the wheel-cutting machine, and cut to the form and pitch required. Wooden cogs, it will be seen from the rules already given for the strength of the teeth of wheels, ought to be thicker than iron teeth in the proportion of the cube of 14 to the cube of 12; the difference is commonly made greater, and perhaps correctly, as the strain falls principally upon the necks of the tenons of the teeth. This allows of the iron teeth of the wheel with which the cogs are to geer, to be dressed to the exact form and thickness, and polished on their acting surfaces, to prevent injurious abrasion of the wooden cogs. By dressing, the iron teeth are however diminished in strength, and consequently a pair of wheels of the kind here described ought to be made fully more strong than wheels of the ordinary kind. When wheels are beyond a certain size, it becomes necessary to cast them in segments, which are afterwards united to form the complete wheel. The pattern of the rim of a wheel of this kind consists of a single segment of which the required number of castings are made. The segment is provided at the ends with the requisite means of connecting the parts together, and to the arms which are also commonly cast separately, and bolted to the rim and centre. As the rim in this case may be cast of any degree of thickness without risk of injury to the wheel, it is commonly made with recesses to re- ceive the ends of the arms, which are fixed in their places by keys, bolts, or both, according to the mode of construction preferred by the maker. The segments are also sometimes, and advantageously, dove- tailed into each other on the inside at the ends, and the arms are fitted also by dovetail-checks and bolts to the middle of their length. This mode of fitting requires great accuracy of workmanship, but when well executed it possesses a degree of neatness which cannot be otherwise attained. The arms are fitted in the same manner to the centre. Another mode is to cast each segment with an arm attached to the middle of its length, and to fit these upon the centre in the way described. Thus if the wheel have eight arms, the rim will be com- posed of eight segments, and the centre will be cast with an equal number of recesses to receive the ends of the arms. When the wheels again are of an intermediate size, too large to be cast in one piece, yet not larger than will admit of their being cast in two parts, they are then cast in halves, each half complete in itself from the circumference to the centre. These halves are then fitted together to form the complete wheel. The manner of fitting is various. The common way is to cast each half with strong flanges throughout the whole diameter, and to bolt these together. Wheels constructed in this way, must of necessity have an even number of arms, 80 that the division may be effected through the middle of an arm running through the diameter of the wheel. The two flanges, that is, the flange of each segment, will form the feather of that arm, but double the thickness of the ordinary feather. We have seen wheels put together in three pieces in this way very satisfactorily, but the difficulty of fitting is then very considerably increased. It is also not uncommon to cast the segments with strong flanges only at the rim and centre, and to trust to these alone to hold the segments of the wheel to- gether. This greatly reduces the work of fitting, and we do not see that sufficient strength could not thus be attained. With respect to the material of the patterns of wheels, it is only necessary to observe that the com- mon practice of using white pine for the arms and rim, and hard wood for the teeth, and their dovetails, Digitized by Google GEERING. 839 is both economical in point of time and expense. But in all cases where the teeth are expected to require no dressing after leaving the sand, it is of importance that those of the pattern be formed with the utmost accuracy, and have a smooth surface. And it may be here observed, that unless in the circumstances referred to, it is not desirable, in point of economy of wear, to dress the teeth, at least to the extent of removing the cast surface, which is by far the hardiest and most durable part, and after working some time, it takes likewise a smoother surface than can be given to the softer metal beneath. The surfaces ought, however, to be cleaned of any imbedded sand, and excrescences which may be found adhering to them when taken out of the sand; and it is also of advantage to run-up, or clean the points of the teeth in the lathe when the wheel is small. The key-seats of the eye are usually cut by the slotting machine, and of a breadth proportioned to the size of the eye, and not to the pitch or diameter of the wheel. Shafting is a department of mill-work which embraces some of the most important considerations within the compass of practical dynamics. If on the one hand shafting be too light, it will be of little importance that the wheels are accurately made, and proportioned to the power conveyed; the tremor and hobbling gait to which an overburdened condition of the shaft-geer invariably gives rise, will speedily destroy their adjustment by irregular wearing of the teeth. The bush-brasses at the same time suffer, and the evil is aggravated till ultimately a sudden failure at some important point sets the whole at rest. On the other hand, if the shafting be made too heavy, an unnecessary expense is in- curred in the construction; and, what is usually of more importance, and in most cases of more serious consequence, a waste of power is occasioned by the unnecessary friction and wear produced by the superfluous weight at the journals and footsteps. Both extremes are thus to be avoided with equal care. One important feature of our modern practice is the higher velocities at which the main shafts are impelled. By this means the geering can be made lighter for the same power, and therefore more durable, since the friction and inertia are diminished, and the impulsion thereby rendered more steady and uniform. The power of the prime mover is therefore economized; and if that power be derived from steam, a corresponding saving is effected in the maintenance of the engine; and if water power be employed, a proportionally greater quantity of machinery can be impelled by the same waterfall. Hence the principles which ought to guide the engineer in the construction of a system of shaft and wheel geering is, to regulate the connections in such a manner that the inertia of the mass and the friction of the motion may be reduced to a minimum, and to effect this purpose the velocities and strength of the parts must be adjusted to one another, and to the speeds of the machines in which the power is to be expended. But before entering upon the investigation of the practical bearings of this general principle, it may be necessary to glance briefly at the various kinds of shafting employed by the millwright and engineer. As respects material, there is only the choice between wood and iron; and the forms are chiefly cylin- drical and square, but sometimes octagonal. When large wooden shafts are employed, as they some- times still are, especially as axles of wooden water-wheels, they are commonly made of one solid log, with gudgeons inserted into their ends, according to a method to be subsequently described. But the scarcity of large timber has not unfrequently led to the substitution of shafts built of planks, and these, when properly made and of sufficient strength, have been found little less durable, and much less expensive. Iron shafts are of two varieties-forged and cast. Those of large size are commonly of cast-iron, while smaller shafts and spindles are formed of malleable iron. The form most common to both is that of a cylindrical solid; but often they are square, sometimes octagonal, and occasionally hexagonal. Cast-iron shafts are also not unfrequently made with ribs upon their peripheries, and then they are called feathered shafte-probably from the slight resemblance which they bear to the feathered part of an arrow. Cylindrical shafts of large size are also sometimes cast tubular, and they are then termed hollow shafts. The subjoined figures represent the forms of cross section most commonly adopted in shafts of the respective materials, iron, malleable and cast, and wood. a 2080. Maileable iron, cast-iron, wood. 2081. Cast-iron. In respect of these forms, the cylindrical is in general to be preferred, not that it possesses greater strength, as is commonly supposed, for the same weight of materials, but because it is the simplest and the most elegant in appearance when mounted. Feathered shafts, as they are commonly made, although their strength to withstand lateral pressure be augmented by the breadth of the feathers, are very rarely free of tremor from want of substance between the feathers, and unequal distribution of the material around their axes. It is, however, an error to assume, with Tredgold and others, that the circle is the only form of section which gives to the axes the property of offering in every direction the same resist- ance to flexure; for it might readily be proved geometrically that the square section must offer the Digitized by Google 840 GEERING. same resistance to flexure in the direction of its sides and diagonals; and what is true of the square, is equally true of a great number of other figures which may be formed by combining symmetrically the circle and square. The hollow cylindrical form admits of being adopted only in shafts of the very largest class, and for the same weight of material is greatly the strongest form that can be employed, and the best adapted to resist the combined action of torsion and cross strain. It is difficult to make a casting of a tubular form below a certain diameter with the necessary accuracy and, therefore, in shafts of small diameter it is much greater economy to make them solid. The sections represented above, Figs. 2080 and 2081, must be understood to be those of the body- parts of the shafts; but the shaft is very seldom uniform throughout its length even when cylindrical, and never when of any other form; for whatever be the figure of the body-part, the journals must always have a circular section, and every shaft must-as will be subsequently seen-have at least one journal or gudgeon on which it revolves. If the shaft be one of a line leading the power to some dis- tant point from the source of motion, it will likewise have its extremities adapted to couple with the shafts between which it is placed; and if intended to carry a wheel or belt-pulley, it is commonly pro- vided with a boss on which the same is keyed. In very large shafts the boss may be replaced by four snugs projecting from the periphery to receive the keys, and when the shaft is of cast-iron and square, as shown by the section marked a, the part to receive the wheel takes frequently the form of section marked b. The following cut, Fig. 2082, illustrates the usual form of a cylindrical iron shaft, on which a wheel is to be keyed at the enlarged part b, denominated the wheel-boss, and which is to be coupled to another shaft at the part c, by what is termed a half-lap coupling, to be afterwards described. The journal is marked a, and has the same diameter as the body-part of the shaft marked d. 2082. b d In ordinary shafting, the gudgeons are now always formed of the same piece as the shaft, and turned. But in ordinary water-wheels the axles are formed of cast-iron, usually hollow, with independent gud- geons fitted into their extremities; and when made of wood, the gudgeons must of necessity be inserted. The drawings in Fig. 2083 show the general form of a hollow cast-iron axle for a water-wheel, with two modes of fitting the gudgeons. The form of gudgeon fitted into the end marked A is peculiarly adapted to axles of this kind, on account of its simplicity. The metal of the shaft is here thickened 2083. B B c A internally to a distance equal to the interior diameter, and three ribs cast in it have key-seats cut in their faces. The gudgeon marked a has three arms cast or forged upon it, (according as it is made of cast or wrought iron,) of the same length as the ribs on the interior of the shaft; and these being dressed in the lathe at the same time that the gudgeon is turned, are correspondingly key-seated. A wrought- iron hoop being driven red-hot upon the end of the shaft to prevent it from splitting, the arms of the gudgeon are adjusted in their places and keyed tight, the keys having as little taper as can conveniently be allowed for fitting. They are thus less likely to become loose in their seats. Sometimes the gudgeon is provided with four arms, but it is commonly admitted that the mode de- scribed is preferable, because with three arms the keys must all bear equally, whereas when four are employed it is difficult to obtain a uniform tightness of the set. The form of gudgeon shown at B is more applicable to a vertical than to a horizontal shaft, although employed indifferently with both. The shaft is in this case cast with a projecting flange round its ex- tremity, of the same diameter as a similar flange cast upon the gudgeon. The interior of the end of the shaft is, in the first place, bored out truly cylindrical, and the flange is at the same time faced. The flange of the gudgeon is likewise faced, and a piece cast on the back of it is turned to fit into the turned part of the end of the shaft; the two flanges are then brought together and secured in tight metallic contact by bolts and nuts. In this form of gudgeon the pivot is sometimes formed of wrought-iron or steel, and fitted into the flange and socket, which must of necessity be cast. This allows of the pivot part being replaced when worn out, at less expense than if the whole consisted of one piece. To render this a good and lasting arrangement, it would be necessary to make the socket of the Digitized by Google GEERING. 841 gudgeon of considerable length, and to bind the two flanges together by a hoop of malleable iron, em- bracing both their circumferences, and put on red-hot. When the shafts are of small diameter these contrivances are not usually employed; the part of the gudgeon which enters the shaft is formed as a solid cylinder, in the surface of which the key-seats are formed; the cylinder fits loosely into the end of the shaft, and is made tight by the keys, as in the first method described. The shaft, with its gudgeons fitted, is then put into the lathe, and the pivots are turned truly concentric with the body-part, and of the strength desired, the original diameters being usually much greater to allow for any inaccuracy in the fitting. This is also sometimes practised with shafts of the larger class; but more commonly the gudgeon part alone is dressed in the lathe, and the adjustment intrusted to the fitter, who can adapt his keys to obviate any small inequalities due to the casting. The form of gudgeon most approved of for wooden water-wheel axles is that known as the cross-tail gudgeon, which consists of a pivot piece projecting from the centre of a cross, roughly represented by F in side elevation, and by + on end. The vertical pieces forming the tails are let into mortises cut in the end of the shaft, and the pivot coinciding with the axis of the shaft, the mortises are filled up on each side of the neck by pieces of wood. A strong malleable-iron hoop is then wedged tightly on the end of the shaft, in order to fasten and retain the pivot of the gudgeon in its parallel position. This gudgeon has also been made with only two cross-tails; and in well-finished work the tails, whether two or four, pass within a malleable-iron ring, which embraces the shaft at the point where they project to the circumference of the shaft: this ring being made slightly less in diameter when cold, is fitted in its place at a temperature of red heat, and contracting, embraces the tails and shaft tightly. The second ring at the end is made of full size, and fixed by wedges. As an additional security, the arms of the cross are sometimes fixed by screws, which pass through into the wood of the shaft. The arms are in this case made thicker, and do not enter 80 far into the shaft. The screws by which they are fastened are made of considerable length, and the distance being noted to which they will pass into the timber, mortises are cut at these points large enough to receive nuts suitable to the bolts. The nuts being dropped into their places, opposite to the screwed ends of the bolts, they are screwed up by a spanner, and thereby hold the arms tightly in their place. By these and similar means the gudgeon can be made for a time quite fast; but when it is consid- ered that the direction of the stress which tends to loosen it is continually changing, and that such stress being exerted on wood, a material which is comparatively very easy and permanently compressed, it is not difficult to perceive that the fastening of gudgeons must have been a matter of much importance to the older millwrights, and that with all their care and ingenuity they seldom succeeded in rendering them firm and lasting. Accordingly several modifications of the schemes described have from time to time been resorted to with indifferent success. The best of these is undoubtedly that of Robert Hughes, described in the Transactions of the Society of Arts, (vol. xxxi. p. 223.) It consists in casting the gudgeon with cross-arms, which fit into notches in an octangular box of cast-iron which has been previously fixed on the end of the shaft." The contrivance is represented by Figs. 2084 and 2085, in which A represents (in section) a portion of the end of a wooden shaft of an octangu- 2085. 2084. lar form; it is long enough to reach across the pit in which the water-wheel works, and, a B having a gudgeon at each end, is supported a b b and revolves upon them in proper bearings. B B is the cast-iron box accurately fitted on d the end of the shaft, and being wedged tight, C C C prevents the wood from splitting as effectu- d ally as any hoops can do. Upon the end of the box is a projecting flange a a, with four a b b B notches to receive the cross-arms bb, dd of a the gudgeon C. This cross is firmly attached to the box by four screw-bolts, which pass through the flange and the ends of the cross-arms. The figure in section (in which the cross and box are represented separately to show more clearly the mode of putting them together) explains a further precaution which is necessary for strength; and which consists in the inside face of the cross having projections ee, which enter the end of the box, and keep the pivot truly in the centre, and prevent any lateral strain on the bolts, which have thus merely to hold the gudgeon fast to the end of the box. When a gudgeou, fitted according to this method, becomes worn out so as to require replacement, it can be removed by taking off the four nuts, and a new one applied; the gudgeon also being of small dimensions, the cylindrical part admits of being conveniently turned in a lathe, which is a considerable advantage." This gudgeon involves nevertheless a considerable deal of workmanship, and the real practical advan- tage which it possesses over the common cross-tail gudgeon is simply, that it does not require the end of the shaft to be impaired by mortising, and affords the means of renewing the gudgeon when the pivot becomes worn out, with more facility and without injury to the shaft. The stress to which water-wheel gudgeons are subject is generally of a lateral and simple character. The gudgeons have manifestly all the weight of the shaft, wheel, and sometimes the water, to sustain, and ought, therefore, to be made sufficiently strong for that purpose; but they ought obviously to be as little as possible increased in diameter beyond the required strength, and a proper allowance for wear to insure durability. In practice it is common to make the length of the gudgeon equal to the diameter. Establishing this as a principle, from experiments on the strength of iron, we deduce the following practical rules:- Find the weight in pounds to be supported by each gudgeon, extract the square root of the 106 Digitized by Google 842 GEERING. number. and that root divided by 25 when the gudgeon is cast-iron, and by 26 when it is wrought- iron, will give the diameter and length of the gudgeon from the shoulder to the extremity expressed in inches. Example.-The gross weight on the gudgeons of a water-wheel is 86,800 lbs. ; required their diameter, the gudgeons being cast-iron ! The gross weight being 86,800 lbs., that upon each gudgeon will be 43,400 lbs., and 43400 = 20832667, which divided by 25 gives 8.3336 inches for the diameter of the gudgeon. The actual diameter of the gudgeons is in this case 8.5 inches, and they have worked in cast-iron bearings for upwards of twelve years, the bushes being only once and lately renewed during that period. With respect to the strength of shafts generally, there are different circumstances to be considered in the calculation. It frequently happens, in examining the conditions under which the shaft is to be placed, even when the stress is manifestly compounded of lateral pressure and torsion, that one of these may be neglected in the calculation of the strength. Thus the effect of lateral pressure is to produce deflection, which must be provided against, and ought not to exceed 100 th of an inch in one foot of length; if, therefore, the dimension requisite to give this degree of transverse stiffness be greater than is required for the twisting power brought on at the circumference, this latter strain may obviously be dis- regarded; and conversely, when the torsion is great and the lateral pressure insignificant, as in the case of vertical shafts, the effect of the former only requires to be considered. And again, when the shafts are long, and have the power and resistance acting at their extremities, it is not enough that the body part of the shaft be sufficiently stiff to prevent deflection beyond the proper limit; it must have sufficient dimensions to prevent twisting beyond a certain quantity; and in estimating the effect of torsion, it is not so much the shaft itself which ought to be considered as the journal, which is constantly exposed to wear, and which is thereby rendered more liable to rupture. In examining successively the amount and effect of these species of stress, and the circumstances under which their intensity is developed separately and in combination, the first part of the inquiry which naturally claims attention is the degree of strength requisite to withstand lateral stress. In this inquiry it is not the ultimate transverse strength, but the stitfness of the shaft which claims attention in other words, the resistance which the material offers to bending by its own and any superadded pressure tending to deflect it from the straight line. Now, the shaft being square, if d = the depth or side of the square in inches, L = the length of the shaft in feet, W = the weight or pressure upon it in lbs., δ = the deflection at the middle of the shaft in inches, M = the modules of elasticity then 1°. When the shaft is supported at both ends, and the stress is intermediate, = M or d= 432 δ } That is, in words-Multiply the weight upon the shaft in lbs. by the cube of the length expressed in feet, and by 432, and divide the product by the value of M, multiplied by the assumed amount of deflection s to be allowed: the fourth root will express in inches the depth of the side of the shaft when the transverse section is square. Or the square root will express the area in square inches of the cross section when the shaft has any other form. This rule answers for any material of which the weight of the modulus of elasticity M is known. In its general form it is, however, laborious, from the magnitude of the numerical quantities involved fixing upon particular values of M for the different materials to be employed, and also fixing the maximum value of d, it may be greatly simplified. In shafting, as already remarked, the deflection should not exceed 100 th of an inch for every foot of length; hence, L For wood-Taking M generally 1,500,000 lbs. and s = 100 L inches. Then for square shafts, d being the depth of the side of the square in inches, (A) And for round shafts, d being the diameter in inches, (B) IL For cast-iron.-Taking M 18,000,000 lbs. and δ = 100 L inches. When the section is square, d being the depth of side, (C) When the section is round, d being the diameter, d'= 240 (D) 240 III. For wrought-iron-Taking :24,500,000 lbs. and δ 8=100 = 100 L inches as before. Digitized by Google GEERING. 843 When the section is square and d the side, (E) When the section is round and d the diameter, (F) 2°.-If the stress be uniformly distributed over the length of a square shaft it will produce the same deflection of the shaft in the middle as #ths of that weight applied at that point. And if W be the weight of the shaft itself, and it be otherwise unloaded, the deflection produced by its own weight will be, L-For cast-iron shafts when square, 25000 (G) And when the shaft is cylindrical and solid, 150000 d (H) IL-In wrought-iron shafts when square, 336000 (I) And when the shaft is cylindrical and solid, 198000 (J) As an example of the application of these rules, let it be required to determine the deflection at the middle of the length of a 8 inch wrought-iron round shaft of 15 feet length betwixt its bearings: Here L = 15, and therefore L⁴=50625, 3, and therefore d=9; Hence, δ = 198000 1782000 50625 03157 inch. The converse of this case frequently occurs; that is, having determined the diameter of the shaft, and assumed a maximum amount of deflection to be allowed, what may be the distance between the bearings 1 Let the maximum deflection be 100 th of an inch for every foot of length, that is, 8=1/00 = inches on the whole length; then from equation, (G) L = 2560 (K) (H) L = 1500 (L) (I) L = 3360 (M) (J) L = 1980 (N) Thus, let the diameter d = 3 inches, as in the last example, the shaft being of wrought-iron and a solid cylinder; then from equation (N) we have L= V 1980 x 9 = 2619 feet the distance between the bearings, on the condition that the deflection of the shaft by its own weight shall not exceed Tooth of an inch for each foot of the length. This being 26 feet in all, the deflection at the middle will be 26=1 inch nearly, which is a safe allowance, in ordinary cases, on this length of shaft. Again, if the torsion be very small, and it be more convenient, and possibly more economical, to adjust the diameter of the shaft to the limit of deflection than the length of the shaft, this being fixed, then, assuming the value of s as before, we obtain from equation L' (K) = 2560 ~ (0) L' (L) d = ~ (P) 1500 L' (M) d = (Q) 3360 L' (N) d = (R) 1980 Thus, the length between the bearings being 30 feet, what ought to be the size of a cast-iron square Digitized by Google 844 GEERING. shaft in which the deflection shall not exceed 30 X -01 = ·3 inch at the middle of the length 1 In this case the rule is equation, (0,) whence, d = 2560 30" = 3-2542 inches, the side of the square, the area of the cross section of the shaft being 1059 square inches. The distances between the bearings given in these examples are not, however, such as would be adopted in practice; but simply show the limits in reference to the deflection of the shaft by its own weight. The spring to which a shaft is always liable in working, from irregularities in the power and resistance, even when its deflection is far within the limit prescribed, renders bearers in general not more than 10 feet apart necessary to prevent vibration; these are usually of a less substantial charac- ter than those in the immediate vicinity of the working points. III. It is sometimes found unavoidably necessary in a system of geering to overhang a wheel or belt pulley, leaving only one end of the shaft supported, while the stress falls upon the other. The equa- tion for the stiffness within the elastic limit is in this case, 6912 When L = the length of the shaft from the point of pressure to the bearing expressed in feet, and M the weight of the modulus in lbs., d and δ have the same values as before. Now, in cast-iron, the value of M was before assumed = 18,000,000 lbs.; therefore, when the shaft is cylindrical, (the only case which it is necessary to consider) we shall have (S) When s 100 inches. This equation determines the least diameter of the journal, which is never greater than that of the shaft. Again, the value of M for wrought-iron is 24,500,000 lbs.; hence, for round shafts of that material, II (T) 2085 When s 100 L inches as before. As an example of this case, let it be required to determine the diameter of the journal of a mallea- ble iron shaft on which a belt pulley is overhung, at a distance of 21 feet from the journal ! Let the weight of the pulley be 180 lbs. and the tension of the belt, when driving, 320 lbs. Here L = 2.5 feet, and W = (180 + 320) lbs. = 500 lbs. Hence, d' = 21 500 = 14881, And d = = 12.21 = 3-49 inches, the diameter required. In this equation it is presumed that no flexure of the shaft takes place beyond the journal, and, to fulfil that condition-which is necessary to save the bearing, and avoid undue friction-the shaft must either be made very strong or have only a short distance between the first and second bearings. Thus, suppose a pulley overhung on the shaft, to prevent the shaft from springing between the proper bear- ings, an intermediate bearing is placed at a short distance behind the bearing nearest the pulley, which prevents upward flexure, and thereby saves the pillows adjoining the stress. It may also be here ob- served that the distance between the bearings which our rules seem to allow are greater than is com- monly practised in modern mill-work; steadiness of motion is much desired, and, as friction is not increased by the number of bearings, provided these be properly made and fixed, it is reckoned good economy rather to multiply the bearings than to risk even the small amount of deflection which we have taken as a safe limit. We have hitherto referred only to two forms of shafts-square and round and these solid. But the same rules may be considered to apply generally to any other forms of solid section ; for knowing the side of a square shaft of a given strength, the cross sectional area of any shaft of equivalent strength is thereby approximately determined, however different in form. Mr. Tredgold's rule for the strength of hollow shafts within the elastic limit, the cylinder being sup- ported at the ends, is WL and is thus expressed verbally Fix on some proportion between the diameters; let the external diam- eter be to the internal as 1 is to N; the number N will always be a decimal, and ought not to ex- ceed 0.8." Then multiply the length L in feet by the weight W to be supported in lbs. Also, multi- ply 500 by the difference between 1 and the fourth power of N, and divide the product of the length and the weight by the last product, and the cube root of the quotient will be the exterior diameter d of the shaft in inches. The interior diameter will be the number N multiplied by the exterior diameter, and half the difference of the diameters will be the thickness of metal As an example of the application of this rule, let it be required to find the dimensions of a hollow shaft for a water-wheel, which, including the weight of the water in the buckets, weighs 44,800 lbs. the whole length of the shaft is 8 feet, from which, deducting 5 feet, the width of the wheel, leaves 3 feet for the length of the bearing: required the exterior and interior diameters of the shaft! Digitized by Google GEERING. 845 Making N=7, its fourth power is 2401; and = Therefore, we have by the rule, 44,800 500 X X -76 3 = 354 in the nearest whole number; and the cube root of 354 is 7, the exterior diameter n inches; and 7 inches X 7=49 inches, the interior diameter. When the shaft is supported at the ends, and the stress is not in the middle of the length, but at distances p and q from the respective ends, the rule becomes, Thus, let the weight of a wheel and other pressure on the shaft be 36,000 lbs. = W; the distance of the point of stress from the bearing at one end being 8 feet = and the distance from the other bear- ing 1.5 foot = and let N = required the exterior and interior diameters of the shaft The fourth power of 8 is 409; and 1 = 591. Therefore, by the rule 4 X 86,000 X 3 X 15 500 45 and the cube root of 485 is 786 = the exterior diameter in inches; and 7.86 inches X 8 = 6.3 inches, the interior diameter. These rules give the strength of hollow shafts within the elastic limit, but when the deflection is restricted to a given amount, the diameter must be determined from the rule diameter of solid shaft =D; the diameter of a hollow shaft of the same stiffness as the shaft of diameter d. The second species of stress to which shafts are liable is torsion. The question of torsion divides itself into two cases as applied to shafts; for, if the shaft be very short, the amount of twist will only be limited by the ultimate strength of the material, but in ranges of shafting of considerable length, the angle of torsion must necessarily be confined within certain limits, depending upon the degree of accuracy of motion, requisite in the particular instance. In the first case it is usually the strength of journal which is to be determined, for the journal being of sufficient diameter to resist the force applied to it tangentially, the body part of the shaft will be in no danger of rupture from that cause, since it has at least equal strength, and is not subject to wear; and, moreover, the ultimate strength must ob- viously, as respects torsion, be independent of the length-provided, indeed, the length be not less than the diameter of the shaft. For shafts of which the lengths are small, and in which the angle of torsion may consequently be neglected, we have the following rules: I. For solid shafts to resist torsion-Equations (S) and (T). Find the pressure in lbs. acting upon the shaft at the circumference of the wheel or pulley receiving or transmitting the power: multiply that pressure by the radius of the wheel or pulley, that is, by the leverage at which it acts; if the shaft be cast-iron, divide that product by 125, but, if malleable iron, divide it by 140; and extract the cube root of the quotient; this root expresses in inches the diameter of shaft corresponding to the given pressure and leverage. II. For hollow cast-iron shafts, the thickness of metal being 1-5th of the diameter-Equation (W). Find, as before, the product of the pressure and leverage: divide that product by 109, and take the cube root of the quotient as the required diameter in inches. For particular cases in which a different thickness of metal is employed, the equation, of which the rule is only another form of expression, must be reduced to find the proper divisor. Thus, supposing the thickness of metal to be fixed at 1-7th of the diameter, then - therefore, 125 which must be taken as the divisor instead of 109 when the thickness of metal is reduced from 1-5th to 1-7th of the diameter of the shaft. These rules are necessary and sufficient to determine the strength of short shafts to resist twisting, and, consequently, ought to be employed in calculating the strength of journals; but in shafts of great length in comparison with their diameters the angle of torsion becomes an important element in the investigation. Now, if the extension which the material will bear by twisting without injury when the length is taken as unity be assumed, For cast-iron 1200 1 For wrought-iron 1400 1 then the value of 0 in our fundamental equation, that is, the angle of torsion, will be, 2284 L For cast-iron 1000 d For wrought-iron 1965 1000 d L in which L is the length of the shaft in feet; d the diameter in inches; and 0 the angle of torsion in degrees of a circle. Digitized by Google 846 GEERING. The rule, moreover, indicates the condition that the angle of torsion is as the length directly, and the diameter inversely; and may, therefore, be adjusted with precision to the degree of accuracy with which the motion of the first mover must be transmitted. Taking the modulus of elasticity of the two varieties of iron at the same values as before, our funda- mental rule becomes, for round shafts of LRW cast-iron and solid = 53.5 (S) LRW " and hollow 53.5 LRW wrought-iron and solid = 71.3 0 (T) LRW " and hollow The data usually attainable in practice are the power which the shaft is required to transmit, the lever- age at which the power acts, and the length of the shaft; it then remains to fix the degree of torsion which may be permitted without injuriously affecting the regularity of the motion: these quantities being settled, the rules expressed by (S) and (T) for solid cylindrical shafts are thus applied: Multiply the power in lbs. by the leverage at which it acts, and by the length of the shaft, both in feet; divide the product obtained by 535 or 71.3 times the number of degrees in the angle of torsion allowed, according as the shaft is of cast or wrought iron; and the fourth root of the quotient will be the diameter of the shaft in inches. Thus, by a line of shafting of 40 feet length, the power transmitted is 500 lbs. acting at the circum- ference of pulleys of 1 foot radius: required the diameter so that the angle of torsion shall not exceed 2 degrees at the extremity, the shafts being wrought-iron Here 500 X 40 X = 20000 and 713 X } 20000 then II 140-25. 142.6 And the fourth root of 14025 is 3:44, so that the shafting would be made 31 inches diameter-which is the actual case. The rule for hollow shafts differs from that given only in this, that the thickness of metal in relation to the diameter must be assigned as before explained; and for square shafts, the rule differs only in having different coefficients of the angle of torsion. These rules are sufficient to meet all the cases of calculation which occur in practice relative to the strength of shafts; but the mode of expression often causes considerable previous computation to determine the value of the power transmitted in lbs., as here required. The more common and conve- nient mode is, therefore, to estimate the strength and sizes of the shafting by the horse-power trans- mitted, and the velocity. According to this measure, from what has already been explained in respect of velocity, it will be perceived that the resistance must be estimated as the horse-power directly, and as the number of revolutions inversely, since, with a given power, the velocity must be greater, as the resistance is less. Thus, the resistance due to 32 horse-power on a journal making 50 revolutions per minute will strain it to the same, and only to the same extent, as the resistance due to 16 horse-power acting on a journal which makes only 25 revolutions in the same unit of time; for 32 16 50 = 25 And, in all cases, when the horse-power, divided by the velocity, gives the same quo- tient, the stress is the same. If the rule contained in equation (S) for cast-iron shafts be reduced to the notation corresponding to the dynamical unit of power, it assumes the form, 25.5 (U) in which H represents the number of horse-power transmitted by the shaft, and n the number of turns which it makes in a minute; L and Θ are respectively the length and angle of torsion expressed in feet and degrees as before. From the rule in equation (T) for wrought-iron shafts we have the form, (VC) These rules will apply to the ordinary kinds of shafting, and where it is necessary to keep the amount of torsion in view but, in cases where less exactness is required, the simpler rules furnished by Robertson Buchanan may be adopted. These rules are intended to comprehend three classes, as-1st. Steam-engine fly-wheel shafts; 2d. Shafts in immediate connection with water-wheels; and 3d. Shafts for ordinary internal mill-geering. The following are the rules: 3 1st class d = X 400 - 3 H 2d class d II X 200 H 3d class d 3 II X 100 These rules are stated to be derived from "observation of shafts in actual use, and of acknowledged Digitized by Google GEERING. 847 good proportions; and for short shafts, they express pretty nearly the practice of some of our best millwrights; but, in his last edition of the Essays on Mill-work, the rule for cylindrical cast-iron shafts is = X 240 Couplings.-Couplings are of necessity employed in a line of shafting when of greater length than is found practicable to cast or forge in one continued shaft. They are also frequently required in cases where one length of the shaft would suffice, for the purpose of occasionally disconnecting parts of the geering beyond a certain point of the line; and likewise for connecting and disconnecting particular machines. The most simple species of connection is the square coupling. In this the end of the shafts to be connected are made square, and are embraced by a square coupling-box, the internal surface of which is fitted exactly to the squares of the shafts. A box is divided into two parts, which close together diagonally upon the shaft, and are provided with flanges at their junction, by means of which they are bolted together, and to secure the shafts, 80 that one cannot turn without driving the other. The coupling is sometimes made quite plain; embracing the shafts like the one now described and, when occasion requires it, the box may be slipped back on one shaft, to leave it clear of the other, thereby admitting of the motion being discontinued, or of one or both being removed for repairs or alterations. An objection to this arrangement of a rigid square coupling at once suggests itself, when we reflect that, although the motion would go on all very smoothly so long as the shafts remained mathemati- cally true to each other, when the one of them wears down in its bearings faster than the other, or when the wearing is in different directions, it must follow, that in some part of the revolution the shaft is lifted off its bearings, where there are two bearings, one on each side, and unsteady motion is pro- duced, together with further straining and wearing of the couplings. This objection, it is true, applies principally to the shafts of heavy mill-work; but it is only for such purposes almost exclusively that this form of coupling is employed; in small machinery it is only occasionally employed. A variety of the square coupling consists in having fitting-strips, or projections along the corners of the square parts of the shafts. The square form of the shaft is in this case virtually preserved, and there is the advantage of the coupling being fitted with greater facility, while the strain is concentrated upon the corners of the shaft. The round coupling is, in some respects, open to the same objections as the square coupling. It will be understood from Fig. 2086, which represents it in section. In this the ends of the shafts are made cylindrical, and meet together, with flat ends, under a round coupling fitted truly upon them, and secured to them by pins 2086. a and b at right angles to one another. This joint may be made with greater pre- cision and much less expensively than the b other, as the parts may all be accurately turned and fitted together. It is clear, however, that, as the strain is concen- trated on the pins and holes, these parts must wear out soon; at the same time, it is easy to renew the pins, though, obviously, they cannot be made to fit the holes so accurately as they did at first. This coupling is not often used for heavy shafting, on account of the objection just stated, though we think it might readily be applied to lighter shafts. The half-lap joint, represented in Fig. 2087, affords a neat and compact method of coupling. The shafts, being cylindrical at the ends, are formed with semi-cylindrical ex- 2087. tremities, and fitted together 80 that the tongue of the one fits into the recess of the other; the cylindrical form is thereby completed, and the joint is covered with a thimble or ring secured to it by a key. This species of coupling is formed partly by turning and partly by plan- ing. The coupling bosses are first turned with great accuracy; they are next planed on their flat surfaces to an exact semi-cylindrical form. The coupling-box being turned externally, and bored out to a gage, is fitted upon them by adjustment of the flat faces of the laps with the file; the key-seats are then cut, and the key fitted, when the operation is complete. The operations are thus attended with considerable expense; but the accuracy and durability, and likewise the elegance of the coupling, fully compensate for the labor bestowed on its original construction. For convenience of disengaging the connection, the boss of the shaft nearest the prime mover is pro- vided with a thin ruff, to which the coupling-box is driven up, and which prevents it from passing off in that direction; the adjacent boss of the other shaft is left plain, and from this end the key is driven. To disengage the coupling. the key is driven back by a drift passing over the ruff, above which the end of the key rises in thickness; the box is then driven back in the same direction, that is, towards the left in the figure, and relieves the laps. The shaft thus disengaged, when lifted out of contact with the tongue of the other, will cease to be impelled, and consequently the motion of all the geering behind that point will be discontinued. The coupling shown in Figs. 2088 and 2089 is constructed of two cast-iron plates, a a and bb, keyed one on the end of each of the shafts. The plate a is formed with two segmental openings in it, which will be better understood from Fig. 2089 at cc; these openings are intended to receive corresponding Digitized by Google 848 GEERING. projections on the face of the plate b, as represented in the section; and thus the shafts become engaged. The rim of the plate a over- a laps and embraces the circumference of the other plate, and thus they are preserved exactly concentric. b b This coupling, applicable to shafts with two bearings, one on each side of 2088. the coupling, is simple and durable. It is easly adjusted, and may be dis- connected without difficulty. Fig. 2090 is another combination of disks suitable for couplings with only one bearing. The disk b is keyed on one shaft, and is recessed on the face, to receive the smaller disk c; this disk is sunk flush with the face of the other, and is screwed tightly up to it by b b means of the ring a, which is bolted to the disk b, and secures that marked c. Between the three plates, a, b, and a c, annular pieces of leather are interposed, which bring them all to a proper bearing. This combination, termed a friction coupling, is useful for preventing breakage of the connections in case of a sudden stoppage or reversal of the motion. It is plain that the holding power of the coupling depends 2089. simply upon the tightness with which the disks are screwed together, and the consequent frictional force of the surfaces C of leather and metal. Of late years, in this country, turned wrought-iron shafts have been very generally adopted in manufactories and workshops: the coupling in most common use for connection is the faced coupling, Figs. 2091 and 2092. This coupling a consists of two parts, one of which being firmly keyed to a the end of each of the shafts to be connected, the faces are then brought together, and securely united by bolts. In fitting this coupling, considerable care is requisite. Each part of the coupling is first turned and drilled, then driven hot on to its shaft, reduced a little in diameter to receive c it, or forced on by screws. It is then strongly secured by a key or keys to the shaft. The shaft is now put into a lathe, and the coupling is faced ; that is, the faces of the coupling which are to be bolted together are turned, so that they are perfect planes, at right angles to the shaft. The bolt-holes on the two portions should correspond exactly. They are therefore drilled on a chuck, with an index; the holes are made slightly tapering, and the bolts, fitting tightly, are driven in by smart blows of a hammer, and secured by nuts. Faced couplings, thus fitted, afford com- 2090. 2091. a b 2092. a 0 b plete and firm connections. The chief objection to their employment lies in their stiffness or rigidity. They are, therefore, mostly used to connect wrought-iron shafts, when the elasticity of the shafts obviates the inconveniences resulting from little, and sometimes unavoidable, settlements or inequalities of the bearings. Another form of permanent coupling is that known as Hooke's Universal Joint, from the name of Digitized by Google GEERING. 849 the inventor, Dr. Robert Hooke. The object of this coupling is to unite shafts which are inclined to each other in the line of direction, and which do not, therefore, admit of being rigidly con- nected, as in ordinary cases. This coupling is very commonly employed in light machinery, as in steeple clocks, for taking off the index-motion, and is then usually constructed by forming an are on the two extremities which it is intended to connect, and to form the joint by a central cross 6+3; the extremities of the ark on the end of 2093. one shaft being jointed to the arms a a, 4 and the extremities of the arc on the other shaft on the arms b b, at right angles to the former. But this simple mode of con struction is not adequate to the purposes for which the coupling is required in a line of shaft-geering; in this case, al- though the principle is not in any way changed, the construction is much more substantial. Figs. 2093 and 2094 rep- resent a form of it adapted to heavy strains. A is a strong disk keyed on the end of each shaft carrying a pair of 2094. bearings for the reception of the gud- geons formed on the extremities of the cross. Fig. 2094 is a face view of one of the disks, showing the cross in its place, with its alternate journals disen- gaged. In this illustration the shafts are shown at nearly the limit of the angle to which the single joint ought to be applied. This angle ought not exceed fifteen degrees when a higher angle is introduced, the rotatory motion be- comes very sensibly irregular, and the friction is greatly increased. This defect may be obviated by using a double joint. With the view of admitting the disengagement of the connection, in cases of sudden steppage or reversal, the coupling, Fig. 2095, is sometimes employed. In this instance, the shaft is supposed to be continuous, and the coupling may be termed a disengaging coupling ; a and b are the two parts of the coupling, formed on the acting faces into alternate projections and recesses, such as they correspond with, and exactly fit into each other when in geer. The part a is, 2095. in this example, cast on a spur-wheel, from a which the motion of the shaft is supposed to be taken off. Both of the parts a and b are, to a certain extent, loose on the shaft; the b former being capable of moving round on it, c €0 though deprived of longitudinal motion by washers and pins marked e. and the latter being free to slide on the shaft, though pre- vented from turning on it by a sunk key, which slides in a slit inside the clutch or slid- a ing piece b. The mechanism is put into geer by means of the handle d, which terminates in a fork with cylindrical extremities c, and it is obvious, that by the contact of the flat faces of a and b, the latter will immediately carry with it the other part at the same speed as the shaft. Supposing, now, that the mo- tion of the wheel a is suddenly accelerated, the oblique faces of the couplings immediately fall out of contact, and slide free of each other, leaving the couplings clear, and the shaft free to continue in motion. In the old form of this contrivance, known as the sliding bayonet clutch, the part b, instead of the tooth-like projections on the face, had two or more prongs which laid hold of corresponding snugs cast on the face of the part a-which, moreover, was usually a broad belt pulley introduced with a view to modify the shock on the geering on throwing the clutch into action. In an older form still the pulley was made to slide end-long on the shaft. A form analogous to this was known as the "lock pulley." Instead of the end-long motion common to the other modes, the parts were "locked" together by a bolt fixed upon the side of the pulley, and which, when shifted towards the axis, engaged with an arm of a cross, of which the part b, in Fig. 2095, is the modern representative. The bolt was wrought by means of a key and stop, the turning of the key throwing back the bolt, and thereby unlocking and disengaging the pulley. The form of coupling represented by Fig. 2095 is particularly applicable when the impelling power 107 Digitized by Google 850 GEERING. is derived from two sources-a circumstance which frequently occurs in localities affording water power to some extent, and yet not in sufficient abundance for the demands of the work. The deficiency is usually supplied by a steam-engine; and the two powers are concentrated in the main line of shafting by a coupling of the kind depicted. In cases of this kind, the speed of the shafting being fixed, and the supply of water inconstant, the power of the water-wheel ought to be thrown upon the wheel a a, and that of the engine upon the shaft at another point. By this arrangement, the speed of the line can be exactly regulated by working the engine to a greater or less power, according to the supply of water. The proper speed of the water-wheel will likewise be maintained, which is of importance in economizing the water power. The same form of coupling is also used occasionally for engaging and disengaging portions of the machinery. But for this purpose the object is to obtain a mode of connection by which the motion may be commenced without shock; for it is a law in mechanics that when a body is struck by another in motion, some time elapses before it is diffused from the point struck through the other parts; conse- quently, if the parts receiving the blow have not sufficient elasticity and cohesive force to absorb the whole momentum of the striking body till the motion be transmitted to the centre of rotation, fracture of the body struck must necessarily ensue. Hence, in a system of mechanism, any parts intended to be acted upon suddenly by others in full motion ought not only to be strong, but they ought to be ca- pable of yielding on the first impulse of the impelling force with as little resistance as possible, and gradually bring the whole weight into motion. The common mode of driving by belts and pulleys accomplishes this object very satisfactorily. In this the elasticity of the belt comes into action; and should this be inadequate, it has the liberty of slipping on the pulleys, till, by the friction between the sliding surfaces, the belt gradually brings the quiescent pulley into full motion. This mode of connection is unexceptionable when the power to be transferred is not great; but its application to large machinery is attended with inconvenience. When the belt connection is employed, the provision of the fast and loose pulley is the most simple and effective form yet devised for the purpose. It consists simply of two pulleys in juxtaposition on the same axis-the one fast, and the other loose, 80 that the belt which transmits the motion may be shifted at pleasure upon one pulley or the other, by that means putting in or out of motion the axis upon which they are placed. The driving pulley-that is, the pulley on the shaft from which the mo- tion is derived-ought to be equal in breadth to the two on the second shaft; and these last ought to have their rims slightly rounded or swelled in the middle to prevent the belt slipping off-which it is apt to do when the rims of the pulleys are flat. This curious property is of great practical importance, and has obviated all those clumsy appendages formerly required to keep the belt from being thrown. This mode of driving is not, however, always convenient; and, accordingly, many attempts have been made to accomplish the same with wheels. Perhaps the best of these is the method of friction cones, a 2096. d b b represented in Fig. 2096. The two parts of this coupling, c and d, are arranged on the shaft b, in the same manner as we have described under the preceding figure. a is a shaft driven by means of bevel- geer off the main shaft b, its motion being derived from the latter shaft through the coupling. c is an interior cone cast upon the back of the bevel-wheel; d is an exterior cone having the same taper as the cone c, such that by means of the handle e it may be moved into contact with the interior cone. The surfaces being supposed to be well fitted to each other, the cone d will, by its friction, drive the cone c, and thereby also the upright shaft. When either of the shafts a or b is accidentally stopped, the cones immediately fall out of geer, and the connection is broken. They are held in geer by means of a screw, or more commonly, and perhaps better, by a weight. This coupling works very well, if properly adjusted at first; but requires some nicety in communi- cating the exact degree of taper to the cones; for if, on the one hand, the taper be too small, they are liable to adhere into each other too firmly, and on the other hand, if the taper be too great, they do not possess sufficient frictional force to keep them in contact. Another mode of accomplishing the same purpose in small machinery, by means of an epicyclic train, is represented by Fig. 2097. In this the shaft A A is continuous, and supposed to be that through which the motive power is transmitted. The wheel a is fast, but those marked b and c run loose on Digitized by Google GEERING. 851 this shaft. The two pinions d d have their bearings in the wheel c c, and geer with the two opposite bevel-wheels, a and b. (One of these pinions only is requisite to complete the motion; the second being introduced merely to maintain the equipoise of the system.) If now motion be given to the shaft A A, it is clear that the wheel b, which is loose, will be made to revolve in the contrary direction to the wheel a which is fixed, by means of the carriers dd; but no motion of the wheel c, if slightly opposed, will ensue; and so long as this last remains at rest, the wheels a and b will have the same angular velocity in opposite directions. But if the motion of the wheel b be opposed by means of a friction gland e, which can be tightened by means of the T-screw marked f to any degree required, the teeth of that wheel will serve as fulcra to the carrier pinions dd, which, becoming levers of the second kind, with the resistance at their axes, they will carry round the wheel c with half the velocity of the prime mover a; and geering with the wheel h, on the main spindle of the machine to be impelled, will transfer to it the motion which itself receives. We have supposed the wheel b to be held absolutely still; but it is ob- vious that it may be brought gradually to rest by means of the friction gland; and as the wheel c can attain motion only as the motion of the wheel b is reduced, and can attain its full speed only when b is brought to rest, it is clear that the wheel h, and, consequently, the machine, may be brought into action without the slightest degree of shock; and, moreover, may be driven at any velocity less than the max- imum, that may be desired. 2097. 2098. d c a a A A c C Another mode of obviating shock in starting machinery, which has been long in use, is represented by Fig. 2098. On the shaft B is fixed a drum or pulley which is embraced by a friction-band a as tightly as may be found necessary; this band is provided with projecting ears, with which the prongs b b of a fixed cross on the driving-shaft A can be shifted into contact. This cross can be shifted end-long on its shaft A, but is connected to it by a sunk key, 80 that being thrown into geer with the ears of the friction- band, the shaft being in motion, the band slips round on its pulley until the friction becomes equal to the resistance, and the pulley gradually attains the motion of the clutch. The arms and sockets c c, which are keyed firmly on the shaft A, are used to steady the prongs and to remove the strain from the shifting part. This contrivance is susceptible of very extensive application even in large machinery, and may be variously modified. If the tension of the band be properly adjusted, all shock will be obviated, and the pulley, and, consequently, its shaft, brought into motion in the same easy way as by a belt. The principle of this arrangement is frequently and very advantageously applied directly to the wheels themselves through which the power is conveyed. Such wheels are termed friction-wheels, and their form and mode of operation will be readily understood. The wheel to which this arrangement is to be applied is usually the largest one of the train, and is made with an eye as large as can conve- niently be used. This eye is accurately bored out and made of such a diameter as to fit a centre or friction-wheel, which is turned truly cylindrical, and is furnished with projecting flanges bearing against the face of the large wheel In the eye of the wheel, between each arm, small recesses are made, and into these are fitted pieces of brass. Pinching screws bear upon the back of these pieces, and regulate the pressure to which it may be deemed necessary to subject the wheel. It is obvious that, should the resistance at the teeth of the wheel at any time exceed this preseure, the central part, or friction-wheel, will revolve and leave the wheel itself stationary, thus saving the machinery from fracture. An ex- ample of the application of this arrangement, which will be familiar to most readers, is seen in dredging machinery, which, having frequently occasion to encounter such intractable objects as rocks and trunks of large trees, would be constantly liable to destruction but for this simple and very efficient contrivance. There is still another mode of accomplishing the same end, which is worthy of notice, on account of its simplicity. The contrivance to which we refer consists is transferring the motion of one pulley to a second in contact with it, by means of friction alone. The oldest and best known arrangement on this principle is to make the contact at the circumferences, which are usually composed of end-wood, SO that the pulleys may be considered as wheels with indefinitely small teeth. The objection to this arrangement is the amount of friction produced at the journals by the pressure necessary at the point of contact of the circumferences to prevent slipping. To obviate this objection it has been attempted, w.! partid success, to make the pulleys concentric, and to bring the two contiguous sides into Digitized by Google 852 GEERING. contact. This modification has been used in hoisting tackle; but while it avoids the friction on the journals, it brings into action an end-long pressure which must be counteracted, and which, consequently brings into operation a corresponding frictional force. Still there are many cases in which it might be employed with advantage. Bearings.-Another important feature in a system of mill-geering is the mode of supporting the shaft- ing-the form, arrangement, and general adaptation of the plumber-blocks and steps, and their supporting apparatus. These are manifold in their proportion and construction-depending, as they do, in a great measure, on the taste of the engineer and the circumstances in which they are employed. Even the length of journal in relation to its diameter is far from being a fixed quantity; and as the journals de- termine the length of the pillows or brasses employed, these last are equally indefinite in their propor- tions. The range of variation is gradually becoming less as the principle of friction is becoming better known; but still we find journals made equal in length and diameter; and others having a length equal to their circumference. These proportions, except for particular cases, are extremes to be avoided. Without attempting to establish a general rule for the length to be given to bearings, under all cir- cumstances, it may be observed, that the pressure upon the pillows or steps ought in no case to exceed 1,000 lbs. on the square inch of rubbing surfaces. Within this limit the wear of the brasses is moder- ate; but, when a less intense pressure can conveniently be attained by increasing the amount of sur- face, without a countervailing evil, it ought to be adopted, even to half the pressure stated. To calcu- late every particular case which occurs in practice, and to adapt the patterns to it, would, however, be attended with an amount of labor and expense which it is found necessary to avoid; and, accordingly, the mode commonly adopted is to fix upon two extreme cases, and to proportion the intermediate lengths to these. Thus, taking a journal of 2 inches diameter, and another 12 inches; and suppose 4 inches to be taken as a proper length for the former and 19 inches for the latter; then the lengths for intermediate diameters may be assigned by arithmetical progression. Thus, between 2 inches and 12 inches there are 40 quarters, and between 4 inches and 19 inches there are 120 eighths; consequently, for every increment of & inch of diameter, we have a corresponding increment of I inch of length of journal. The common material employed for pillows is a composition of copper and tin, in the proportion of 12 to 1. This alloy is much harder than common brass, and is supposed to work with cast and wrought iron with less friction, and to be more durable than most other compounds. Cast-iron pillows, espe- cially when cast in iron moulds, and when the rubbing surfaces are made large in proportion to the pressure upon them, are not inferior in any respect to the bush-metal commonly employed-the fric- tion is, indeed, rather less than greater, and being harder, they are still more lasting. But when the pressure is so great as to produce abrasion of the surfaces when left occasionally without a proper sup- ply of oil, the wearing process, thus commenced, goes on increasing, and the surfaces never afterwards acquire the necessary polish. In this the bush-metal has an advantage, for although abrasion has pro- ceeded a certain way, when the lubrication is again perfect, the pillows take a new polish as perfect as before, and the abrasion ceases. Wooden pillows are also sometimes employed with advantage. Box-tree and lignum vitae were long in use, but those woods, besides being much more expensive, are far inferior for the purpose to home-grown beech. We have known journals which, with ordinary metal pillows, were ever liable to heat, run for many years on beech-wood without manifesting any tendency of that kind. Pure tin is, perhaps, of all other substances, that which produces the least friction with iron; but its softness has prevented it being very extensively employed. When the pressure upon the rubbing sur- faces exceeds very moderate limits, the tin yields to it, and becomes extended in the direction of the length of the pillow. A mode of obviating this difficulty has been patented in the United States by Mr. Babbitt; it consists in placing the soft metal in a species of casing of cast-iron, of the common form of the half pillow, but with ledges round its concave surface, which thus presents a recess of a depth corresponding to the size of the pillow-from 1th inch to an inch in very large diameters. This recess is filled with the soft metal, which is retained by the ledging of the casing, and prevented from yielding and becoming extended by the pressure on its surface. 2101. 2099. 2102. 2100. The material used by Mr. Babbitt is not pure tin, but a soft alloy, in which lead predominates, and which, besides answering all the purposes of tin, has the advantage of being greatly cheaper. A patent for a composition-metal has lately been obtained by Mr. Fenton; it is harder than Mr. Babbitt's metal equally fusible, and still cheaper, and has been found very efficient as bush-metal in Digitized by Google GEERING. 853 railway engines. It is simply a compound of tin and zinc, with a little copper to harden it and a very excellent composition of the sort may be made of equal parts of the two former metals and a sixteenth by weight of antimony to give hardness. Forms of plumber-blocks and pillows, very commonly adopted for heavy shafts, are shown by Figs. 2099, 2100, 2101, and 2102. In this the pillows are made octagonal to prevent their turning round with the shaft, and are cast with flanges on their ends to prevent longitudinal displacement. This form has, however, been departed from by some of our best millwrights. Instead of casting the brasses with flanges and plane faces, they are cast of a cylindrical form, and with two snugs at the middle of their length, which, entering corresponding recesses in the plumber-block, retain them securely in their places when the cover is fixed. By this arrangement they are more easily fitted, contain less useless metal, and have a lighter appearance. The plumber-block itself, also, admits of being bored out to the size of the pillows; whereas, with the octagonal form, the faces require to be planed to the required angles-a much more expensive process. 2104. 2103. The plumber-block consists of a sole and cover, which, when practicable, are independently bolted together, the heads of the cover-bolts being countersunk in the sole. The cover is made to check accurately within the cheeks of the block, the surfaces being planed true to each other, 80 that the stress upon the bolts is reduced to a minimum. The sole has two projecting ends by which to bolt it in its place, as shown in Fig. 2103, and elsewhere. The figure specified is an example of a plumber- block with what is denominated a false or shell cover-a form often adopted for economy when the pressure is entirely down. In this case there is only one brass, the cover part being cast with side pro- jections resembling the ends of a brass, and with projections on its upper surface resembling the nuts and ends of bolts of the regular form represented by Fig. 2099. This cover is not fitted, but is simply laid loosely in its place, and serves merely to preserve the journal from sand and similar injurious matters. 2105. 2106. The form of pedestal represented under the footstep-bridge by Fig. 2107, is one of the best examples, combining strength, elegance, and simplicity of make. It is in every way appropriate for its purpose. The base and cover fit together with a degree of symmetry and character which are not found in the examples above referred to; and the amount of fitting is much reduced. The base and cap being checked together by planing, they are fixed in their relative position by the cover-bolts, and bored out to the extreme diameter of the brasses. But instead of a uniform concave surface, the interior of the base and cap have a circular recess of small depth occupying about a half of their breadth, 80 that the bored parts occupy about a fourth of the breadth of the concave surface on each side of this recess; the object of this is to avoid the necessity of turning the exterior of the brasses for an equal extent at the middle of their length, and, therefore, allows of their being provided with spugs as already noticed, Digitized by Google 854 GEERING. 'to secure them from turning round in their places with the journal. The brasses being turned to fit their position in the pedestal, they are bored out concentrical with the outer circle; and the points of the cap-bolts and the nuts being dressed, the plumber-block is ready to be bolted in its place. The foundation-plate, upon which the sole of the pedestal rests, is usually provided with snugs, set so much apart as to allow of a wooden key being driven between them and the ends of the pedestal- sole. The bolt-holes in the sole and foundation are also made oblong, to allow of a small amount of adjustment in setting the pedestal; and, to obtain this latitude of adjustment laterally, and also in the direction of the axis of the brasses, the holes are lengthened in the sole and foundation in the corres- ponding directions. Adjustment is attained vertically by allowing for a given thickness of wood to be placed under the sole of the pedestal, and which can be increased or diminished at pleasure to obviate any small inaccuracy of workmanship. 2107. In ordinary mill-work pedestals are usually pro- vided with some form of cast-iron foundation-plate upon which they are fixed. This is exemplified by Figs. 2103, 2104, 2106, 2108, and 2107 and it fre- quently happens that much ingenuity is necessary to compose what is technically denominated a wall- box or fixing for the proper reception of the number of pedestals required by a confluence of shafting to a point. Fig. 2104 affords an example of one of the most common and simplest forms of wall-box, being intended to carry only one pedestal for a shaft which may be supposed either to pass through the wall into which the frame is inserted at that point, or to terminate there. If intended to carry the end of a shaft. it is usually made in the form of a rect- angular box with the bottom into the wall, and with a shelve at a convenient height to receive the sole of the pedestal, the breadth of which determines the depth of the box. But when the shaft passes com- pletely through the wall, the box is simply a rect- angular frame, corresponding in depth with the thickness of the wall into which it is inserted and with the cross-shelve, for the purpose before stated. This makes a neat, convenient, and substantial fixing, and one which is in constant requisition. Fig. 2108 gives an example of a pedestal wall-plate, and which serves the same purpose as the wall- box above described, when the shaft terminates at the wall and does not pass through it. This species of fixing is simply a bracket bolted to the wall by three bolts which pass completely through and are secured on the outside by wall-washers, bonnets, or stars. These are merely plates of cast-iron, some- times with radial arms to increase the amount of bearing surface, with holes through their centres, to receive the ends of the bolts, which being screwed, are retained by nuts passed over them in the usual manner. Commonly the bolts are entered from the outside, which is generally advisable for conve- 2108. 2110. 2109. 2110f. nience and safety. The wall-washers serve the purpose of increasing the amount of surface of the wall acted upon, and thereby allow the bolts to be screwed up more tightly; and the more friable the material of the wall is, the larger these ought manifestly to be made. For brick walls a very common proportion between the size of bolt and bonnet, estimated by diameter, is one to six. For dressed stone walls, the proportion may be somewhat less; but for rubble work the stellar form ought to be preferred. The bracket is provided with a projecting sole upon which the pedestal rests, and which is supported Digitized by Google GEERING. 855 at the middle of its length by a rib cast upon it. The sole has a snug at each end, between which the pedestal is keyed, and holes through it to receive the pedestal-bolts. Fig. 2109 represents another form of wall-bracket. This form is employed for carrying a shaft along a wall, and projects sufficiently to allow space for any wheels and pulleys which may be upon the shaft to work clear of the wall. The bearing is in this case formed in the bracket itself, and the cover is held in its place by two bolts secured in the cheeks of the block by cotterals. As this species of bracket does not allow of any adjustment at the bearing, and as it would be diffi- cult to adjust, if fitted directly upon the wall, it is usually provided with a wall or ground-plate, as shown in the figure. This plate is, in the first place, secured to the wall by wall-bolts and washers, in the manner above described; and the bracket is then adjusted and fixed upon it by bolts and keys, in the same manner that the simple pedestal is secured to its seat. But sometimes, and judiciously, its bolts also pass entirely through the wall, and serve to maintain the stability of both foundation and bracket. Figs. 2110 to 2112 are forms of pendent brackets intended to carry lines of shafting along the ceiling of a building. Fig. 2111 is the simplest form, and is often used to carry the weight of the shaft at points intermediate to those at which the power is taken off, but sometimes also it is the only species of bracket employed when the shafting is light. It is easily fitted, and has very commonly only an under pillow for the shaft, and no cover; but when the shaft has an upward pressure-which it must at any point where motion is transferred to or from it by toothed geer, whose line of contact is in the horizon- tal plane,-a species of block-brass is fitted into it and retained by a cotter, as shown in the figure. The ends of this block are checked, and the back of it has a groove to receive the edge of the cotter; it is thus effectually prevented from moving on end, and may be forced downwards upon the shaft by ad- vancing the cotter, which is made of a tapering form for that purpose. 2111. 2112. This form of gallows has, however, no other recommendation than cheapness. It is inelegant in the last degree, and deficient in stability, is easily twisted out of position in consequence of the oblique action of the weight upon it ; and, moreover, the hook into which the brasses are fitted being usually narrow-another feature of economy always associated with it-the brasses soon become loose and allow a hobbling motion of the shaft, not more unpleasant to witness than it is injurious to all the con- nections of the line, and to the accurate transfer of the power at the working points. 2114. 2113. A B Fig. 2112 represents a gallows of a more substantial character, but still inelegant in appearance, and, in some respects, inconvenient. The weight being equally and directly borne by the two supporting points, it possesses all the advantages of strength; it may be provided with a cover and cover-brass, which are necessary when the bracket is placed in the vicinity of a pair of wheels which geer together. The form of bracket has the manifest inconvenience that the shaft cannot be taken out of its place except by moving it end-long. Figs. 2110 and 21101 are two views of a form of pendent bracket, which combines to a considerable extent the two requisites of strength and simplicity. The pillar and expanded base of this bracket are cast hollow, as indicated by the dotted lines in Fig. 21104. The cover is fitted to the pillar by planed faces which check together, leaving space to receive a bevel-edged key which holds the cover in its place when the stress is entirely down wards; but when the bracket is intended to be placed in the vicinity of two geering-wheels, the cover and projection on which the under pillow rests are provided Digitized by Google 856 GEERING. with snugs through which a nib-bolt, as it is technically called, passes and assists the key in retaining the cover in its place. This form of pendent is also convenient to the millwright as a pattern. In the two forms above described, any difference of length is attended with extensive alteration of the pattern, but in this, the stalk of the pattern is made at least as long as there is any probability of its ever being required a series of ferules are then turned to fit upon the stalk, and of the requisite outside diameter; the necessary number of these are put on to make up the length less the length of the octagonal part which forms the bearing; this part is formed of cast-iron, and has also a hole through it to receive the stalk, and when put on and fixed in the proper position the bracket is ready to be moulded, any part of the stalk which may be projecting through being cut of in the sand. The process of moulding is likewise simple, and no core-box is required, except when the bracket has a double bearing, which is always the case when it is intended for a point at which a bevel pair meet. The only objection to this form of bracket is the oblique direction in which the strain falls upon the holding bolts, and which might be obviated by making the cover one piece with the stem, and checking the under bearing to it by a strong dovetail and single holding-bolt, the office of which would simply be to prevent end-long motion. Pendent brackets such as those here described, are sometimes cast with vertical soles, prepared to bolt to beams; but more frequently the soles are horizontal; and in that case are bolted to grounds of planking fixed between two adjoining beams by wood-screws. When the brackets can be attached to beams, that mode of fixing is, however, to be preferred and in that case the sole ought to be formed with a projecting rib to bear against the under side of the beam, and relieve the bolts as much as possible of strain. The kinds of bearings described are all designed to support shafts placed horizontally; but in almost every system of geering there is one large vertical shaft from which the minor horizontal shafts derive their motion. The bottom extremity of the vertical shaft is supported on a species of bearing techni- cally named a foot-step, of which Fig. 2107 represents a specimen. In this case, the motion is usually transferred by a pair of bevel-wheels, as represented by Fig. 2001, and more completely still by the arrangement shown in Fig. 2115. In this last the first shaft is marked H; on this is the spur pinion Q 2115. F D E 4 B C G L K H WHITHEY.SC. which geers with the equally pitched wheel F on the horizontal shaft K. On the other extremity of this shaft is the bevel-wheel C, which geers with a similar wheel on the vertical shaft and through this last wheel motion is communicated to the equal wheel B and the geering on the right. The arrangement represented by Fig. 2001 is strictly analogous-the horizontal shaft being the driver and the vertical shaft the carrier of the motion to the superior parts of the factory. In these arrangements the foot-step of the vertical shaft is carried upon an arch, technically a foot- bridge, of which Fig. 2107 gives a front view, and Fig. 2115 a side view: Fig. 2001 shows a section of the same through the foot-step box. This bridge rests on a foundation-plate of cast-iron, which in turn is fixed upon a stone foundation more or less substantial, according to the weight and stress which are to be resisted. The pedestal of the horizontal shaft ought to be supported on the same foundation sole: for, if supported on a separate sole, the foundation bolts, and possibly the foundation itself, will in all probability be soon destroyed by the twisting action of the wheels at the fixed points. The foot- step box occupies the summit of the arch; three sides of it are cast upon the bridge, but the fourth side, which forms the door, is a separate casting, attached by four bolts which pass right through from back to front of the box, hollow rolls being cast on the two opposite sides for that purpose. In Fig. 2107 the door is supposed to be removed to show the interior arrangement; Fig. 2001 gives a transverse section through the door, showing its thickness; and Fig. 2115 shows the door in its place and fixed by its bolts. This door is fitted with great exactness, and the whole interior of the box-at least a sufficient bearing surface of it at the angles-is chipped and filed true: a foot-plate as in Fig. 2001, and sometimes a species of box solid above, and sometimes both, is fitted into the bottom of the box. This plate or pillow is first planed and in fitting, its superior surface is set truly square with the sides of the box. The surface of the plate is frequently steeled by case-hardening when the end of the shaft is intended to be rested immediately upon it, as shown in the drawings referred to; but more commonly it is simply a plato of cast-iron on which the bottom of the cup-formed brass is supported. In these drawings the brass is supposed to be without bottom, and to embrace the cylindrical end of the shaft, and support it laterally. This arrangement has its advantages, in so far as the foot-plate can easily be Digitized by Google GEERING. 857 replaced when worn out; and the brass may be formed in halves, which will allow it also to be replaced with little difficulty. But more commonly the brass has the form of a deep cup, interiorly while, exteriorly, it is made in size exactly to fit the box. On one side-that from which the wheel acts-a recess is left in the interior to receive and retain oil in considerable quantity, so that the lubrication may be abundant and prevent heating. With every attention to lubrication it is, however, very difficult, when the weight upon the step is great, to prevent its becoming hot, evaporating the oil, and destroying the rubbing surfaces. Various modes of remedying the evil have been attempted; but the best expe- dient hitherto tried is to enlarge the surface as much as convenient. Formerly, the end of the shaft was greatly reduced to form the foot-often, indeed, a pin was inserted and made to serve the functions of a foot; but at present the foot is formed on the same principle as any other bearing-namely, with as much bearing surface as the diameter will allow. But even this is often found too little, and the next resource is to continue the wheel boss and give the foot a conical form, thereby increasing the supporting surface as much as circumstances will admit. We have also seen attempts to line the brass step with ribs of steel to increase its durability; but without success. A step made on Babbitt's principle, and lined with soft metal, would, in our opinion, offer a better chance of success than any scheme which has hitherto been attempted. But the experi- ment remains to be made on a proper scale, and with sufficiently good workmanship, to test the principle thoroughly before its being adopted very extensively in mill-work. Among the more ingenious of the older contrivances for rendering foot-bearings durable was that of attaching a hardened steel plate to the extremity of the foot by a square tang, which was driven hard into a corresponding hole in the foot. On the under side of this disk a groove was cut across, the better to distribute the oil which found its way to the bottom of the step by vertical grooves cut in it. This was found to work very well when there was little lateral stress upon the shaft; but ultimately gave place to an arrangement which is sometimes adopted in modern work, and which consists in inserting a steel pivot into the lower end of the shaft. When this pivot is bound in its place by a malleable-iron ring put on hot, the arrangement is one of the best which can be adopted; but the original mode of simply boring a hole in the end of the shaft and inserting the pivot, without any further lateral support, left the foot very weak and inadequate to sustain any considerable amount of lateral stress. Another scheme, also sometimes put in practice in modern work, when the shaft is very large, is to make the foot turn on conical rollers, on the same principle as horizontal shafts are sometimes made to turn on parallel friction rollers to diminish the amount of friction, by converting a rubbing into a rolling motion, with only the sliding action of the small axes which retain the rollers in their places. The cones, however, require very accurate workmanship, and therefore become expensive. and are, moreover, very liable to get out of order; they are, in consequence, very seldom employed. A modification of the conical rollers, consisting of a single ball placed under the foot of the shaft, although very rarely tried in mill-work, seems to offer advantages more than equivalent to the additional workmanship which it would entail, by dividing the motion, in some measure, between the shaft and itself, and leaving an open space to receive oil, which would tend materially to keep the foot cool. This arrangement is almost universally adopted in vertical sugar-mills, and is found to answer, although in process of time the ball does become flattened, and, accordingly, requires to be replaced. The scheme of the late Mr. Bramah, of supporting the pivot entirely on water, the pressure of which was to be maintained by a small forcing-pump and stop-cock, would, if all tear and wear could be avoided, be perfect; but unfortunately it holds out little prospect of being successfully applied to the end in question, although there appears little doubt that it will ultimately be found both practicable and efficient as applied to railway turn-tables, in which the bearing surface is large, and the only prob- lem to be resolved is the diminution of friction. Water has been successfully applied to keep the common foot-step cool, by simply perforating the foot- box and running a stream constantly through it. An example of this may be seen at the Deanston mills. Sizes and proportions of bolts.-The bolts employed in securing together the pedestals and parts of the fixings of shaft-geering constitute another important element in mill-work. Bolts may be generally described as pins having a head formed on one end, and the other end screwed externally to enter an internally screwed ring, technically named a nut. When the bolt is passed through holes placed oppo- sitely in two pieces, a thin ring or washer being first placed on the screwed end of the bolt, if the nut be then put on and screwed tightly down upon the washer the two pieces will be held firmly together between this last and the head, the body of the bolt, or part between, serving as the medium through which the force is maintained by one surface upon that opposite. Bolts are denominated according to their diameters of the body part, +inch, §-inch, 4-inch, I-inch, 1-inch, 14-inch, &c., bolts; the particular diameter being determined in any case by the supposed tension to which the bolt will be exposed. It is rarely that this force can be estimated even approximately; but assuming it to be known, the tension ought not to exceed 11 ton on the square inch of section. Therefore, if we designate by T the tension in tons, that is, the effort tending to separate the head and nut by tearing the body part of the bolt asunder, and the diameter in inches by D, we have the simple formula, D=&VT. Thus, supposing the known tension to be nine tons, then, D=1/9=2} inches, the diameter of the bolt necessary to resist that pressure. The number of consecutive threads in an inch, that is, the pitch of the screw, is regulated by the di- ameter of the bolt. For small bolts of about +inch the pitch is usually about a sixth of the diameter, but relatively decreases inversely with the increase of diameter. The following table is that of the dies and taps of an extensive millwright and engineering establish ment in Glasgow, and it does not differ sensibly from the numbers adopted in some other works. 108 Digitized by Google 858 GEERING. The depth of the thread is also a matter of importance. The section of thread most approved of for strength and easy motion of the nut is an equilateral triangle, thus 4, the bevelled sides being equal be- tween themselves and to the base or pitch. Bolts of larger diameter than those Diameter of Threads in an Diameter of Threads in an named in the annexed table are usually screw in inches. inch. screw in inches. inch. chased in the screw-cutting lathe, and in that case the thread is commonly made 12 11 5 of a rectangular section; but such bolts to 11 11 41 are very rarely required in mill-work, t 10 2 41 and when they do happen to be employ- # 84 21 4 ed, it is under such circumstances as re- 1 8 21 4 move them from the ordinary class of bolts 1g 71 21 st and the proportions therein recognized. 11 7 21 st The length of the body of the bolt 1] 6} 21 8 must, of course, depend upon circum- 11 6 3 3 stances; but a certain proportion is ob- 11 51 served between the diameter and the sizes of head and nut. For common bolts the head is usually square, and the nut six-paned, that is, has six facets on its periphery. Sometimes, also, the head has the same form, and occasionally it is made round, and for particular purposes it is conical, but oftener pyramidal. When of this shape, it is intended to be flush or even with the surface of the piece into which the bolt is inserted, and it is then said to be countersunk. The cover-bolts of pedestals are of this form, being necessarily flush with the sole of the pedestal. The thickness of the head when of the usual form is from two-thirds to three- fourths of the diameter of the bolt; and the diameter of its circumscribed circle is double of the primary diameter. The thickness of the nut is usually made sufficient to contain from eight to ten threads, the smaller having proportionally the greater depth. The part of the body towards the head, equal in length to a third of the whole, is usually made square, and the remaining part or two-thirds is round and of this a portion equal at least to double the thickness of the nut is screwed. Sometimes, however, as in pedestal cover-bolts, the whole length of the body is cylindrical, the bolt being prevented from turning round when the nut is being screwed up by the pyramidal countersunk head. Although the length of bolts generally can only be assigned for particular cases, those adapted for particular sizes of pedestals may be given. These, it is true, will vary with the particular form of pe- destal used; but the sizes given in the following table will be found very generally applicable for those of good proportions. Diameter of Diameter of bolts. Holding. Cover. Double-ended. journal. Inches. Inches. Inches. Inches. Inches. Inches. 11 31 41 21 5 11 CORP 31 41 21 5 2 onto 34 5 21 6 21 4 4 57 21 61 21 4 51 21 61 24 41 61 8 71 8 8 41 64 3 74 31 8 4b 71 3g 81 31 at-s 41 8 34 84 34 1 41 81 31 9 4 1 5 9 34 91 41 11 51 91 4 101 41 11 6 101 41 101 41 11 61 101 41 111 5 11 61 11 41 111 51 11 61 111 41 121 51 11 6g 12 5 12} 54 11 64 121 51 18 6 11 7 13/ 51 134 61 11 7t 131 51 14} 61 1f 71 14 54 15 64 14 81 14} 6 16 7 1f 81 15 61 16} 71 2 87 151 61 17 71 2 9 16t 61 171 71 21 91 161 7 18 8 21 91 171 71 184 81 21 91 181 74 191 81 21 10 191 8 201 9 2g 101 20 84 21 91 21 11 201 81 22 Digitized by Google GIG. 859 The heads of bolts intended for wood are commonly segments of a sphere; and the bolt is not often provided with a nut, the holding being in the wood itself. But sometimes, when the wood is thin, the screw is passed sufficiently far through to take a broad wash and nut above it, an arrangement which gives strength in proportion to the acting surface. Guide pulleys.-It frequently happens, when the power is to be conveyed by a belt, that the connec tion cannot be obtained directly, in consequence of the relative positions of the shafts, which may be placed obliquely to one another; and sometimes other parts of the geering, machinery, cross-beams of the building, and the like, come between the points to be connected, and by their intervention prevent the belt from passing immediately from one point to the other. Under these circumstances, it is ne- cessary to pass the belt over guide pulleys. An example of the common guide-pulley frame is given in Figs. 2113 and 2114. The axes of the pulleys are adjustable in the frame B to any required angle within a certain range in a common plane, which is parallel with a plane passing through the driving axis and perpendicular to the plane of the driven shaft. When the belt, therefore, passes from the driver over one of the guide pulleys and is returned upon the other, the bight will be thrown into a plane at right angles to the normal plane, and a pulley placed in that plane, its axis coinciding with it, will be driven by the belt without any ten- dency to change its plane of action. We have supposed the beams to be parallel and perpendicular to one another; but the arrangement may be adapted to other positions by placing the guide pulleys in different planes; and in order to allow of further accommodation, the frame may be made adjustable at the point of attachment to the beam at D. The above treatise on geering has been taken from the Engineer and Machinist's Assistant, and is generally admitted to be the best yet published. GEODESY, literally signifies the division of the earth, in which sense it is synonymous with land surveying; but it is usually employed in a more general sense to denote that part of practical geometry which has for its object the determination of the magnitude and figure either of the whole earth, or of any given portion of its surface. In this sense it comprehends all the geometrical or trigonometrical operations that are necessary for constructing a map of a country, measuring the lengths of degrees, &c. In order to construct an accurate map, or determine the form and dimensions of a country, it is necessary, in the first place, to determine the absolute distances between the several stations or points secondly, to determine the azimuths of the lines thus measured, that is, their situation with respect to the meridian; and thirdly, the differences of latitude and longitude of the stations. The operations necessary for de- termining the absolute distances, comprehending the measurement of a base, the observation of angles, the computation of the sides of the triangles, and their reduction to the same level, are called the geodesical or geodetical operations; while those which are required for determining the azimuths and latitudes are called the astronomical operations. The determination of the figure and dimensions of the earth is a problem of very great importance to astronomy and geography, and has accordingly at all times been a subject of much interest to mathematicians; but it is only since towards the middle of the last century that operations on an adequate scale for its solution have been undertaken in differ- ent parts of the world. GERMAN SILVER. An alloy composed of copper, nickel, and zinc, in various proportions, accord- ing to the purposes for which it is to be used. As a substitute for silver, it should be composed of 25 parts of nickel, 25 of zinc, and 50 of copper. An alloy better adapted for rolling, has a larger propor- tion of copper, 60 parts, and less of zinc, 20. For castings, as candlesticks, bells, &c., 20 of nickel, 20 of zinc, 60 of copper, and 8 of lead. The analysis of the true German silver from the mines of Hildburg- hausen, gives of copper 40·4 parts, nickel 316, zinc 25.4, iron 2-6. GIG, for napping cloth. Fig. 2116 geer end of gig. Fig. 2117 is a front elevation of gig. The cloth to be napped is first wound on the roller c', passed down over the two straining rollers d' d', 2116. , the cloth roller c. By means of the shaft c, which is mounted at each end with two slipping clutches ff, c' is thrown out of geer, and the lower roller c thrown in. The cloth is then drawn down- Digitized by Google 860 GILDING. 2117. wards over the revolving drum b, which is set with teazles, as seen in Fig. 2118, until the whole length has passed over. 2118. The action of the two cloth rollers is then reversed, c' being thrown into geer, and the cloth passes back again over the teazles, and this is continued until the nap is sufficiently raised. The straining roller d' may be adjusted to give more or less strain on the cloth at will. GILDING is the covering, with a plate or film of gold, metallic or other surfaces. The application is either for utility, as where it prevents the oxidation of drinking or other vessels for domestic use, of watch-springs, and the steeled parts of small machinery; or for ornament, as in picture and japan frames. Its use under the former of these aspects is daily extending. Gilding is effected by several different processes. 1. By means of an amalgam of gold and mercury, which is best made by heating pure mercury in a black-lead crucible to near the boiling point, and adding one-sixth or one-seventh in weight of fine gold in very thin plates, first brought to a red-heat. The mixture is then stirred, until the gold is dis- solved and well incorporated with the quicksilver. When cooled, the resulting mass is subjected to gentle pressure in soft porous leather, which separates the excess of mercury; and there remains in the skin a yellowish silvery-looking substance, which is the amalgam. In gilding silver, this amalgam is rubbed over the surface, which is first well cleaned, and the mer- cury is then driven off, by exposing the article operated on to a clear charcoal fire. It is then to be burnished. The surface of copper and brass, after being cleaned, may be rubbed over with a solution of proto- nitrate of mercury, which is decomposed, and leaves a thin pellicle of metallic mercury to amalgamate upon the surface. This insures the union of the gold amalgam, which is then rubbed on, heated and burnished, as before. In this mode surfaces may be completely coated with an exceedingly small proportion of gold, as is shown in the case of brass buttons, of which 144 may be covered on both sides with the consumption of not more than five grains of gold. In gilding iron and steel with amalgam, a solution of mercury in nitrous acid is previously applied. A deposit takes place of mercury in close contact with the surface, even if it does not appreciably amalgamate with the iron. It facilitates the adhesion of the gold amalgam, which is applied and treated as before. This method for iron and steel cannot be recommended; for the nitrous acid Digitized by Google GILDING. 861 liberated attacks the surface, and impairs its polish; and the heat, besides, necessary for driving off the mercury, injures the temper of the metal. Cutting instruments, therefore, or any that require to be tempered, should not be gilded in this manner. The application of gold leaf to such instruments for the same end is similarly objectionable for the same reasons. Another process for iron and steel consists in applying a solution of sulphate of copper previous to rubbing on the gold amalgam or laying on the gold leaf. This is as exceptionable, and for similar reasons, as the former method. 2. Better than either of the last-mentioned, at least for iron and steel, is the process with etherealized gold. In this a solution of gold is made in nitro-muriatic acid, and there is added to it twice as much sul- phuric ether. The mixture must be shaken, and then allowed to repose, when the ether with the chloride of gold will separate from the remaining liquid, and rest above it. This dark-colored ethereal solution is poured off from the light-colored liquid beneath, and can be preserved for use in tight bottles, excluded from light. When applied, it is with a very fine brush, or camel's hair pencil; the ether evaporates immediately, leaving a coating of gold. This is burnished after being heated. The adhesion is more perfect, however, if the article be raised to a temperature approaching redness. 3. A mode of gilding silver is sometimes practised, which consists in reducing to ashes linen rags that have been previously dipped in a solution of chloride of gold, and rubbing them on the surface to be gilt with a piece of leather, cork, or with the finger. The fine particles of gold will thus adhere to the silver. The article is then washed to receive the adhering ashes, and burnished. This is a simple and easy method, and consumes but little gold. Brass or copper may be readily gilt, by being dipped in a dilute neutral solution of chloride of gold, and then washed and burnished. For the preparation of the chloride of gold, see GOLD. 4. A process analogous to this last was patented in 1836 by Elkington, an English gilt toy-maker, and is well adapted for small articles. It consists in immersing them in a hot solution of chloride of gold, to which has been added a considerable excess of bicarbonate of potash. 5. By far the neatest and most unobjectionable among the chemical methods of gilding is the galvanic process, proposed first in 1840 by De la Rive. Since then it has received, in the hands of various per- sons, modifications facilitating and extending its application. For these and other details, see ELECTRO- METALLURGY. Gilding is also effected: 6. Mechanically, by covering with gold-leaf, which comprehends a very extensive range of applica- tion. Thus, the principal metals may be gilt; thus, several natural or artificial earths, such as marble, plates, and porcelain, objects in glass, leather, paper or pasteboard, and wood, may be made to assume entirely, or in part, the appearance and some of the physical advantages of gold. For work intended to be out of doors, or exposed to the weather, a sizing is first applied, made of boiled linseed-oil and red ochre. On this the gold-leaf is laid. This is the oil-gilding of the older treatises. In gilding glass or porcelain, powdered gold is mixed to a proper consistence with a solu- tion of borax in water, and applied with a soft brush or pencil. The articles are then heated in an oven to a temperature sufficient to burn off the gum and vitrify the borax, whereby the gold is cemented to the surface. Then it must be well burnished. The general method of using gold in pow- der (for the various preparation of which, see GOLD) was known and described in the earlier treatises as gold japanning. But in the true japanning, the gold was protected by a varnish, and not burnished. Leather is gilt by dusting the surface with powdered mastic, upon which the gold-leaf is applied and burnished. The lettering and other emblems on bound books is generally done without sizing, by applying the gold-leaf to the leather, and imprinting with the stamps or types moderately warm. In lettering on muslin, mastic or isinglass is better to be applied. Paper, or parchment, is gilt by applying a thin coat of gum, or size, laying on the gold-leaf before the coat is perfectly dry, and burnishing, as before. The edges of books are best gilt by applying to them in the press a thin size of one part powdered rock-candy and four parts Armenian bole, mixed with the white of egg then the gold-leaf is put on and burnished. Articles in wood, such as picture and mirror frames, are best treated with a sizing prepared from clippings of vellum or parchment, boiled in water to a stiff jelly, and mixed with Paris white, plaster of Paris, or yellow ochre. For gold inks, permanent and sympathetic, see INK. False gilding, is the application, for cheapness, of other substances than pure gold, in which, how- ever, the appearance of that metal is more or less imitated. For this purpose is used Dutch leaf, (which is copper gilt, and then beaten out,) and silver, and tinfoil. The Dutch leaf has the appearance, at first, of true gold, which may be secured and continued by a coat of transparent varnish. Silver and tinfoil assume the appearance of gold by means of a varnish or lacker composed of aloes, gum-sandarac, and white resin, (the resin being about as much as the other two ingredients, whose propositions are nearly equal,) which are boiled in their own weight of linseed-oil. When well boiled to a syrup, about a half per cent. of red-lead is added, and the liquor strained through a flannel bag. This was the method formerly used for the leather hangings of apartments, beautiful specimens of which are still seen in Europe. These hangings have long gone out of vogue, but will probably be recalled. For what concerns the details of the art of gilding, the precautions to be taken in the several pro- cesses, the apparatus and implements employed by the practical workman, and the method of pro- ducing different characteristics in the work-frosting, deading, &c., &c-reference must be had to larger treatises and manuals ; among which may be mentioned chiefly, D'Arcet Mémoire sur l'A: de Dorer. Paris. 1818. That the ancients practised this art, though in a more expensive manner than W', do, is apparent from the Egyptian and Etruscan remains, which date back three thousand years, and more. Pliny the Elder has left fine details of its state in the first century of our era. As well 's can be made out in Digitized by Google 862 GIN. the uncertainty of weights and measures, the thinnest gold-leaf then was about twenty-two times thicker than what can be made now. The methods were the same in principle as our own. Marble, and articles that would not bear heat, were coated with white of egg; wood, with divers kind of glue; al! generally termed leucophoron. Metals were gilded with native or prepared quicksilver (hydrargyrum), and the various washes of salt, vinegar, and alum are also mentioned. (Plin. Hist. Nat. xxxiii. 20.) The relics of Herculaneum, for instance, show that the success of these ancient processes, whether due to labor or otherwise, is far more than proportionate to what might be expected from our superiority in theoretical science. GIMBALS, or GIMBOLS. A piece of mechanism consisting of two brass hoops or rings which move within one another, each perpendicularly to its plane, about two axes placed at right angles to each other. A body suspended in this manner, having a free motion in two directions at right angles, will assume the vertical position: hence the apparatus is employed for suspending portable or mountain barometers, sea-compasses, &c. GIN. This term is applied in mechanics to various and widely differing machines, to engines for raising great weights, driving piles, &c., as well as those employed in cleansing of cotton and wool, and its preparation for the market or for carding. The most simple, as well as the most ancient, cotton- gin is the roller gin, which consists of fluted rollers about five-eighths of an inch in diameter, and from nine to sixteen inches long, placed parallelly in a frame, which keeps them almost in contact. The rollers revolve in opposite directions the cotton is drawn through between the rollers, whilst the seeds are prevented from passing from the narrowness of the space. This machine is still used for the finer and longer stapled cottons but the operation is tedious and expensive; and the saw-gin, invented by Eli Whitney, in 1793, from its general use, and its wondrous effects on the extension of cotton cultiva- tion, and influence on manufactures and commerce, may now claim distinction and consideration almost exclusively as the cotton-gin. In its main features this machine still continues as first invented by Whitney; but in various details and workmanship, it has been the subject of many improvementa. Fig. 2120 represents a perspective view of a cotton-gin, constructed by Bates, Hyde & Co., of the Eagle 2120. o a @ 0 D Cotton-Gin Manufactory, Bridgewater, Mass., who are the owners of several patented improvements on the machine, and from whom we take the following drawings and descriptions. Fig. 2121 is a section of the gin. The frame of the machine is made either of wood or iron, usually of wood, with tenons and mortises, and screwed together firmly with joint-bolts. The sides are ceiled with boards inside the timber, and the top ceiling above the brush is made in one piece, 80 as to be readily removed. The grate-fall, or breast, into which the seed cotton is thrown, is formed with ends, or heads, of cast- iron, and pear-shaped; the lower and back side being composed of cast-iron grates, screwed firmly to the wood-work of the breast; the saws projecting through the interstices between the grates, from one to two inches; the upper and back part of the grate-fall, called the "hollow," is hung upon hinges, and may be raised or lowered at pleasure, and fastened in any desired position by joint-bolts through the grate-fall heads. The seed-board makes the front part of the breast, and stands nearly perpendicular, leaving a space between it and the grates for the discharge of the seed; it is hung upon pivots at the top at each end, 80 that the bottom may be swung outward and the hopper emptied at any time. When in place, the bottom is fastened by small slide-bolts. The position and angle of the seed-board may be readily varied and adjusted, bv altering the position of the slides upon which the pivots rest. These slides are fixed to the grate-fall heads by small bolts passing through slots, having a nut outside. The grate-fall, or breast, is hung to the front top timber of the frame, by stout hinges above the saw-cylinder. and the lower part rests upon two short screws in the front piece. That part of the hinge, or butt, which is attached to the top timber is 80 fixed as to slide up or down by means of slots and an adjusting screw, and is fastened in the desired position by bolt-nuts. The saw-cylinder is made of wooden staves, about two inches thick, upon an iron shaft, and turned in a lathe of a uniform diameter; and, by the application of a small saw, when in the lathe, grooves Digitized by Google GLASS. 863 are formed to receive the saw-segments, which are made of the best cast-steel, and inserted and fastened into these grooves. There is a set of wooden grates behind the saw-cylinder, and a row of hair, or bristles, called the "moter," to separate the false seeds, motes, and dirt from the ginned cotton. The brush is made of about twenty inches diameter, cylindrical, having slits lengthwise between 2121. a, Grate-fall head, or end of breast. I b, Seed-board. a Saw-cylinder. d, Saw. a " Patent detached grate." f, Screw or bolt on which the grate-fall rests. 8. Back board, to which are attached the back grates and 66 patent moter." m Grate-fall hollow, which is hung upon hinges, and THy be raised or lowered at pleasure. i, Sliding-butt, by means of which the saw-tooth may be made to assume any desired angle with the curved surface or front of the grate. j, " Patent brush." k, Sliding mote-board. 4 Bottom board. K the rows of bristles, and a hole around the shaft to receive the air as the brush revolves; and a rapid cen- trifugal motion is given to the air, which is forced out with great power between the rows of bristles. Behind the brush is an opening, the length of the frame, into the lint-room, and beneath the brush a sliding-board, called the mote-board, which may be slid back or forward for the purpose of regulating the draft of the gin, and properly separating the motes, dirt, and leaf from the clean cotton. In the saw-gin, as ordinarily constructed, the cotton is liable to collect in the spaces or interstices between the grates, and around them above the saws, thus choking or clogging the grate, and pre- venting the rising and free escape of the roll of seed-cotton. The patent detached grate, instead of being attached directly to the wood part of the breast at the top, has an arm or brace extending out behind, through which it is screwed to the wood, so that the top of the grate stands out and is detached from the wood, and has a space behind of a quarter inch, or more, between it and the wood, and also a space between it and the adjacent grates; so that there is no chance for the cotton to collect above the saws, and the choking is entirely avoided. Many efforts have been made so to improve the saw-gin, as to separate from the fibres of cotton motes and other impurities. By some this has been essayed by means of rotating brushes acting on the fibres, and carrying them from the grate to the stripping-brush, rotating in a reverse direction to the saws. Some have used stationary brushes, through which the saws carry the fibres to be stripped of motes and other impurities. The objection to these is, that they act on the cotton only when upon the teeth of the saws, and therefore, instead of separating the motes and other impurities from the fibres to which they adhere, sometimes with considerable tenacity, the fibres are drawn out with the motes, thus occasion- ing considerable loss of cotton. The object of the moter is to avoid this loss, and to hold on to the motes or other impurities, as the fibres are stripped from the saws by the stripping-brush, the fibres being under the operation of both brushes at the same time. The moter also more effectually stops the current of air generated by the rotation of the stripping-brush from acting on the fibres before they are cleaned, than if located at a greater distance from the point of action of the stripping brush. GLASS.-The varieties of glass are usually classified according to their technical uses, as follows: A. Bottle-glass, which comprises all glass worked into the form of vessels, &c. It is subdivided, accord- ing to the purity of the metal of which it is composed, into Ordinary bottle-glass, consisting of silica 60, potash or soda 3·1, lime 22.3, alumina 8, and oxide of iron 4. Glass used for medicinal bottles, composed of silica 716, soda 10-6, lime 10, alumina 3, and a very little protoxide of iron. White bottle-glass, for bottles, tumblers, tubes; containing silica 717, soda or potash 15, and lime 10. B. Windown-glass, composed of silica 70, potash or soda 15.2, lime 13·3, and alumina 1.82. C. Plate-glass, composed of silica 72, soda or potash 17, lime 6.4, and alumina 2-6. This variety only differs from the preceding by the greater purity and freedom from color of the materials. D. Flint-glass, used for grinding, &c., composed of silica, potash, and oxide of lead. E. Crystal, for optical purposes, composed of silica 592. or boracic acid, potash 9, and lead 28. F. Strass. The mass composing the imitations of precious stones, consisting of silica 44, potash 12, with the largest amount of oxide of lead 43, and colored by various metallic oxides. The pigments Digitized by Google 864 GLASS. used by artists in glass and porcelain, are also included under this head; they are easily fusible glass fluxes, consisting of lead and boracic acid, which can be colored in any manner that is required. G. Enamel, composed of silica, soda, and oxide of lead, but rendered opaque by oxide of tin or anti- mony. These proportions are not adhered to strictly, but vary greatly in different specimens. Some of these varieties of glass are in themselves colored, as the dark-brown or green bottle-glass the light-green bottle-glass, used by chemists; all the varieties mentioned can, however, be colored artificially. Of the material for glass-making.-In so extensive a branch of manufacture as that of glass, it is quite impossible to prepare or obtain the ingredients in a state of chemical purity previous to fusing them together; certain crude products of art and nature are therefore used, in which the ingredients are contained in some suitable form of combination, and it is left to the process of melting to eject the impurities in a more or less complete manner. In order to understand the nature of this process, and the recipes for mixing the ingredients of the different varieties of glass, it is necessary previously to become acquainted with the crude products which are used in the glass-house for affording silica and the bases. Silicic acid-Silica is very abundant in nature, but is seldom sufficiently pure for the manufacture of the finest colorless glass. Rock crystal is frequently used for those glasses which are employed as pigments by glass painters. Heated to redness and thrown into water, the state of aggregation of this substance is 80 changed, that it can easily be reduced to powder. Massive quartz and flint are treated in the same manner. Sand, however, is the most general and economical source of silica, and renders the process of grinding unnecessary. The great variations in the purity of this material, render a care- ful selection necessary for the different kinds of glass. Potash and soda.-The alkali used in the manufacture of ordinary colored glass, (e. g. bottle-glass,) is obtained, as far as the potash is concerned, from common ashes, and the soda from the ashes of sea- plants, or refuse soda. Better kinds of glass are made with crude potashes and soda-ash, and the best from purified potashes and soda-ash. Lime.-Every kind of limestone is applicable to the manufacture of glass that is not too poor after being burnt and slaked. When a glass mixture contains more lime than the silica which it comprises is capable of saturating, the excess attacks the material of the crucible, and extracts silica from it; the crucibles are thus quickly eaten away and rendered useless. It is consequently not advisable to em- ploy more than 20 parts of lime for 100 parts of sand. Lead-Lead-glass is fused from a mixture containing litharge or minium, (red-lead.) The latter substance is preferred, on account of its finer state of division. Discolorizing matters.-White glass seldom or never turns out quite colorless by itself, even when proper proportions and the purest materials for the mixture have been employed in its production. There are always two antagonistic elements to contend with, carbon, or carbonaceous matters, and iron, which have to be overcome by the so-called discolorizing material. Peroxide of manganese, arsenic, and saltpetre, belong to this class of substances. In all cases the color is removed by oxidation. Broken glass, or cullet.-Fragments of old glass require particular notice as an indispensable addi- tion to the ingredient of the crucible. The waste glass in the glass-house, and that collected in the neighborhood, is carefully sorted, cleaned, ground, and incorporated with the mixture for similar kinds of glass. These fragments exert a very beneficial action-in addition to the advantage derived from their being reconverted into glass vessels-by inciting fusion and by aiding the union of the bases with the silicic acid. Of the fuel.-The furnaces employed in glass-houses are intended not only to combine chemically the ingredients of the glass mixture at a glowing heat, but also serve to retain the glass after fusion in a proper state of fluidity for working. Again, the reheating of the different vessels during working, which is always effected in the glass- furnace, requires imperatively a flame fire. That kind of fuel will naturally have the preference which produces the most intensely hot flame, and causes the least amount of damage to the glass and to the sides of the furnace from the deposition of ash. In Germany, wood is generally employed, and in some few places peat; in England and France, coal; in this country, both wood and coal. The best air-dried wood would fall far short of producing the desired effect, in consequence of the water which it contains, (from 15 to 20 per cent.) In has been the practice to bake the air-dried wood in a furnace until the whole of its water has been volatilized. Even this precaution is not perfectly effectual unless soft woods are selected containing a large proportion of hydrogen; and these are cleft into very small billets. Finely cleft wood burns more rapidly and without smoke by coming into more extensive con- tact with air, it evolves its heat in less time, and although a greater amount of heat is not produced by its means, that heat which is produced, is more intense. The furnaces.-The construction of the melting furnaces in a glass-house is attended with many diffi- culties, against which it is almost impossible to provide; and the wear and tear becomes a serious item to the manufacturer. The furnace is erected over a large flue, or cave as it is technically termed, very strongly constructed, and 5 or 6 feet high. On each side of the grate-room, in which the flue terminates, a bank is raised, termed the siege, on which the pots are placed, 80 that the fire lies, as it were, below the bottom of the pots, and in the centre of the furnace, but stretching through its whole length. The sides of the fur- nace are a little higher than the top of the pot, and the arch, or crown, is made as low as possible, to be consistent with durability. Openings are made in the sides of the furnace, opposite to each pot, and above all, a high cone is erected for the purpose of draught. In all kinds of glass, except flint, these openings are the only exit for the flames or heat into the cone, and the heat striking directly against the roof or arch of the furnace, is reverberated down upon the pots, finally escaping through these openings or working holes." This necessitates a great loss of heat, which is obviated in some degree in the flint-glass furnace, where the exit is by means of a flue or chimney, the entrance into which is Digitized by Google GLASS. 865 low down in the side of the furnace, 80 that the heat is compelled to encircle the whole pot before it can escape. The sides of the furnace are constructed of bricks, formed in moulds made for the purpose. The best fire-clay, mixed with the remains of old pots coarsely ground, is the material employed for making these bricks. No cement is employed in the arch of the roof; the expansion of the stone, and the par- tial fusing of the interior surfaces afterwards, binds the whole sufficiently well together. The pots.-These crucibles, or pots, are next in importance to the furnaces, and every care is taken in their production. The best fire-clay, mixed with varying proportions of the remains of the old pots, is employed, and the tempering, or previous preparation of the mixture, requires great attention. By means of levers worked through different openings of the furnaces, the pot is brought into its proper position, and is then "glazed," as it is technically termed, before being filled with materials; 2. c. some old glass is thrown into it, and spread over the sides in the melted state; this then penetrates to the depth of a few lines, into the substance of the pot, and forms a hard, difficultly fusible glass, which protects the pot from the further action of the materials. Preparation of the materials.-It has already been stated that a great saving of fuel and time is effected by intimately mixing the materials in the most minute state of division. The materials are either mixed together in heaps, or, better, in the slowly revolving barrels similar to those employed in the powder-mills. Melting.-When the melting point is attained, the simply calcined or fritted mixture is introduced, but not all at once. The mass of glass which a pot will hold, occupies before fusion, in the state of a mixture, twice the space of the melted glass. One-third of the mixture is first introduced through the working-holes, by means of shovels, and the other two-thirds are added successively, when the previous portion appears thoroughly melted. During the whole period of the melting, the stokers keep the furnace well supplied with fuel, 80 as to prevent any portion of the grates becoming uncovered, since a rush of cold air from below would probably split some of the pots from top to bottom. During this operation, the founders are engaged in observing the progress of the fusion, by taking from time to time proofs, or drops, from the pots, by means of a short rod, flattened at one end, and examining whether any undissolved grains of sand are perceptible on cooling, and whether the mass, which still contains a quantity of air-bubbles, appears uniform throughout. At the close of the melting process, the contents of the pot are not by any means pure, or equally mixed. The solid matter is indeed all dissolved, but the mass of glass is full of small bubbles of gas, presents a spongy rather than a dense appearance, and is not yet in a state fit for working. The surface is also covered by a layer of so-called glass-gall. 2122. S i i W A A i i S Fining.-The last part of the process of glass-making is now arrived, which is termed the fining, and the object of this is the removal of the air-bubbles and impurities, such as undissolved grains of sand, &c., from the chemically finished glass, in order to prepare it for working. This process is a simple separation of the beterogeneous substances by subsidence, in which the heavier particles settle down to the bottom, and the gas-bubbles rise and disperse on the surface of the melted mass. During this time, which always comprises several hours, no chemical change occurs, with the exception of the vola- tilization of a little alkali; but the proofs drawn by the founder are much more uniform in texture and freer from bubbles, until, at length, the whole is recognized as thoroughly fined. The mass of glass which is now ready, can only be formed into vessels when it possesses a certain state of consistency, 109 Digitized by Google 866 GLASS. and this is entirely dependent upon a fixed temperature which has been very much exceeded during this period. The working, consequently, does not immediately follow the fining process, but a period intervenes, during which the heat of the furnace is allowed to sink to that temperature at which the glass is in the best condition for working or blowing. Observations with Wedgwood's Pyrometer have shown the proper temperature for working to be 70°. Bottle-glass.-All kinds of hollow articles, as bottles, drinking vessels, preserving glasses, chimney glasses for lamps. goblets, tubes, and chemical vessels in general, from the finest Bohemian glass for cutting and grinding, to the ordinary green bottle-glass, are included under this head. , Glass furnace.-The arrangement of an ordinary glass furnace is shown in Figs. 2122, 2123, 2124, and 2125. The figures represent a four-sided furnace, intended for six glass-pots, and when constructed in an appropriate manner, can be used for all kinds of glass belonging to this class. Fig. 2122 rea- 2123. e e e t m 772 u resents a horizontal section at the height of the sieges or seats. Fig. 2123 a perpendicular section through the teazing-arch. Fig. 2124 is also a perpendicular section through the sieges, and Fig. 2125 is a front view with a section of the fritting-kiln. 2124. v e e u и 7 n x x x There are four side-kilns connected with the main furnace A, in the shape of four wings, viz. two cooling or annealing furnaces B B, and two fritting-kilns CC. Above the foundation, in which the drains xxx are excavated, the sole-stone w is placed, which forms the bottom of the fire-room. The two fire-places and grates m m are situated above the ash-pits y, and are exactly opposite to each other; Digitized by Google GLASS. 867 they are supplied with fuel from the arches bb and dd, whilst the flames from the two extremities meet in the fire-room g, Fig. 2124, and enter together the space a a occupied by the pots uuuu, and- reverberating from the four-sided arch-escape at last through the flues c, eight inches in width, into the side ovens, of which two c c can be heated by separate fires kk; the damper S', Fig. 2125, shuts off the flame from the furnace A when required. The uprights iiii separate the working spaces of the glass-blowers, who obtain access to the glass in the pots through the working-holes e c. Imme- diately below these are the openings r r, which can be opened for removing the pots, when broken or worn out, from the sieges, to which they often adhere. In order to retain the heat in the furnace, the 2125. Z Z S working-holes are made as narrow as possible, and consequently much smaller than the pots; when it is necessary to change the latter, they are removed through the side arches, of which there are two in every furnace, and these are kept constantly bricked up, except when actually in use. Chimneys l are sometimes erected over one or more of the working-holes to carry off the heat and the vapors from the pots; these, however, are not essential, and are not often used. The side-kilns are accessible by the doors SSS. Wood is placed on the scaffolding 22 to dry. The cupola or arch v is walled over with ordinary bricks, and the corners are filled with sand and earth. The round melting-furnaces, although very commonly used, are not so commodious as those of quad- rangular form under the same circumstances. Bottle-glass-Composition.-In choosing ingredients for this kind of glass, economy is the chief object; color and appearance are here of no moment. The following examples are calculated for 100 lbs. of sand. For Champagne bottles Ordinary green English bottle- according to Jahkel. bottle-glass. glass. 200 lbs. felspar. 72 lbs. of lime. 100 lbs. lixiviated ashes. 20 " lime. 280-278 " lixiviated wood-ashes. 40- 90 " kelp. 15 " common salt. 30- 40 " wood-ashea. 125 " iron slag. 80-100 " clay. 100 " cullet. Mechanical operations.-The manufacture of bottles affords a good instance of the dexterous manip- ulations which are practised in blowing glass. The most important instrument is the pipe," Fig. 2126. 2126. c This is a tube composed of wrought-iron, 4 to 5 feet long, 1 inch thick, and about t inch in the bore, having R knob at each end, the one of which a serves as a mouth-piece, whilst to the other b the melted glass is attached. To protect the workmen from the heat of the metal. a wooden handle c, about a foot in length, surrounds the upper part. As soon as the working-holes are opened the workman attaches as much melted glass to the end of the pipe b as he considers necessary for the production of a single bottle. By dipping the previously warmed pipe into the pot, a little glass remains attached to b; after turning this in the air before the hole, until it is cooled, and blowing slightly into it to render it hollow, a fresh layer of glass may be attached to it in the pot; to this, a third is added in the same manner until the ball at the end of the pipe has accumulated to a sufficient size. That this ball may become uniformly tractable in the subsequent forming, it is held by the workman in the flame of the furnace through the working-hole; it is then brought into one of the round concavities of the marver, (constructed at different times from a stone, marble or cast-iron plate,) where the ball gradually assumes the form of a pear-shaped vessel, Fig. 2127. It acquires this shape by the constant rotary motion given by the workman to the pipe whilst the cooling and stiffening of the mass is rendered uniform by the marver, and is prevented shrinking together by constantly blowing into the pipe with very little force. The mass of metal (metal is the technical term applied to glass during working) must be equably dis- tributed round the axis of the pipe, and advanced in front of its mouth, being connected with it only by a short neck. Thus far advanced, the glass has again become cool and is rewarmed by insertion into the working- hole, in such a manner that the front part receives the chief portion of the heat and becomes the Digitized by Google 868 GLASS. softer. The pear-shaped vessel is now lengthened by the blower, and its form is approached to that of a bottle by a threefold operation; by blowing into the tube with greater force, by swinging (backwards and forwards, in the manner of a pendulum) and by a simultaneous constant rotary motion of the pipe round its axis. The globular form which the glass tends to assume under the influence of the blowing, is converted into a long thin egg-shape by the swinging motion, Fig. 2128. The rotation round the 2127. 2129. axis of the pipe is an essential part of every operation in glass-blowing. The glowing mass of glass creates a power- 2128. 1 ful current of air in an upward direction, and the lower portion becomes cooled in consequence much more than the upper. This naturally creates an inequality in the resistance offered to the blowing, and the upper portion would be more expanded than the lower if the cooling influence were not allowed to act upon all parts of the surface alike by the re- volving motion of the pipe, and this is particularly the case when the pipe has to be held in a horizontal position. The mould a (a simple cylindrical hollow block of wood or iron) is d placed at the side of the workman who is blowing the pear- shaped vessel into this he inserts the vessel as soon as it has acquired the proper thickness, in the manner represented at Fig. 2129, and by blowing forcibly into the tube, he presses the glass firmly against the sides of the mould, whilst, by a kind of jerking motion, the neck is drawn out to the proper length. The unfinished bottle is again warmed in the work- ing-hole in such a manner that the lower part only is heated, whilst the other parts remain comparatively cool. In the mean time, another workman or a boy has attached a small quantity of glass to another pipe or rod of iron, called the punty, which is also kept hot in the working-hole. Both workmen now stand opposite to each other; and whilst the pipes are kept constantly turning, the punty is forcibly pressed against the middle of the lower part of the bottle which is thus forced inwards, and an even edge is produced, upon which the bottle may stand steadily. The bottle remains for some moments between the two instruments, Fig. 2130, until, by the application of cold iron or a drop of water, the neck can be separated from the pipe. This sudden separa- 2130. tion is an operation of constant recurrence in the glass-house, and is effected by a sudden change a (c of temperature produced at the point of separa- tion in the hardened glass, either by the cold application of a drop of water, or by the powerful heat of a red-hot iron or thread of liquid glass from the pot. The point of separation must often be re- heated in order to fly on the application of cold water. The bottle is now supported by the punty, as shown at a, Fig. 2130, so that the neck can be warmed. and the sharp edges melted round without softening the other parts. A rotating motion is now given to the red-hot neck, the pipe being rolled backwards and forwards upon the knees of the workman. The rim for strengthening the neck is formed from a drop of glass taken from the pot by the edge of the flask and wrapped round the mouth in the form of a thick thread. The bottle, which is now finished, Fig. 2131, is immediately carried by the punty-rod to the annealing-oven by a boy, pushed into its proper place, and the punty-rod is lastly detached from the bottom of the bottle by a sudden sharp jerk. The place where the 2131. punty was attached is perceptible in every bottle blown in this manner by the sharp edges where the fracture occurred. Large round bottles are blown without the use of a mould, and when of very large size, like the carboys for sulphuric acid, the aid of steam is called in, by spirting a mouthful of water into the interior, and holding the mouth of the pipe with the thumb. Attempts have consequently been made by many inventors to furnish the bottle-maker with a mould of such construction as would enable him to secure the formation of a bottle, perfect both as regards form and capacity, at one single operation, without reliance upon his own correctness of sight. The use of moulds of this description, like that of Rickets, which is easily managed, affords a great saving of time, and renders the repeated heating of the bottles unnecessary. The mould consists of a body which forms the belly of the bottle and of four other parts, a fixed bottom-piece with a movable piston for forming the concavity, and two movable pieces for the neck. Two treadles set these different parts in motion. As soon as the work- man has introduced the hollow lengthened globe into the belly of the mould, by pressing with his foot upon the first treadle, be brings up the neck-piece, then forces the glass into contact with all parts of the mould by a powerful blast, and finishes the bottle by working the second treadle which forces the pestle against the bottom. On the removal of the pipe, the rim of the neck is all that remains to be perfected. Champagne bottles require to be made more than usually strong in consequence of the pressure exerted by the carbonic acid enclosed within them, and they are particularly liable to fracture during the bottle-fermentation of the wine. Yet they will often withstand a pressure of 40 atmospheres, and upwards, (= 600 lbs. on the square inch.) Crown-glass.-The purest and most beautiful glass is the white crown-glass," manufactured in the Bchemian glass-houses for grinding and polishing. Intended for articles of luxury and art more than for the supply of the ordinary wants of life, the purity and absence of color in the mass is naturally Digitized by Google GLASS. 869 heightened by the grinding and polishing, and is combined with an elegance of form which would be thrown away upon a less pure material. Glass, for the purposes of the grinder, is better prepared by the use of proper moulds than by simple blowing, partly because the forms are frequently not 80 simple as to admit of their being made by hand, and partly because the various grooves and projections upon the surface can be roughly given by means of a mould without adding to the difficulty of blowing, and time and trouble is thus saved in the laborious operation of grinding. The moulds and the mode of using them resemble. in every respect, those which will be described under flint-glass or crystal. Windoo-glass-Properties-Although window-panes may be made from any kind of bottle-glass that is not too much colored, just as many articles of bottle-glass are actually prepared from window- glass; yet, with reference to the object in view, a very marked difference is made in the mixture of ingredients. The amount of lime in the mixture must not be too small, that the panes may not be sub- ject to become opaque when exposed to the atmosphere, whilst, on the other hand, any composition that has a tendency to devitrification would be a serious evil, as the glass has to be successively heated a great many times before it acquires the proper form for window-panes. Production of window-glass.-The mechanical production of window-glass is effected with the pipe, either by blowing a hollow cylinder, which is cut open and flattened out, in a special operation, (sheet or broad glass,) or by distending, with the aid of centrifugal force, a more globular-shaped vessel attached directly to the pipe (crown-glass.) Sheet-glass.-Cylinder-blowing.-The operation of blowing cylinders commences as usual with the collection of a sufficient quantity of metal from the pot at the end of the pipe. A massive glass ball is thus attached round the nob of the pipe which must be pushed forward with a flatting-iron until an annular groove is produced as at a. This operation completed, the blower rounds the ball on the marver, and distends it slightly by blowing. It then assumes the form represented in Fig. 2132, from which it will be seen that the mass of glass is thickest in front, as from that part it has to be distended and lengthened into a cylinder. In the subsequent operations, it first assumes the width of the future cylinder and then the length. With this object in view, the workman, after having rewarmed the ball of glass, holds it perpendicularly above his head, and blows into it. The heavy bottom yielding with less ease to the blast, admits of the distension of the width, and a flattened bottle is formed, Fig. 2133. As soon as the proper width is attained, the pipe is quickly inverted, so that the ball is under- most, and an incessant swinging motion is then kept up with a constant blast. Further distension is thus effected, but from the bottom only, as the thinner sides have by this time cooled, and in conse- quence of the swinging motion in the direction of the length, so that the bottle acquires the form repre- sented in Fig. 2134, by the time that the glass has so far cooled as to be no longer expansible. If the swinging were admitted, the bottle would be distended in all directions, and present the form indicated by the dotted line. By repeated warming, swinging, and blowing, the form Fig. 2135 is gradually pro- duced, which is then the proper length of the cylinder. It is then conical. and terminated by a semi- circle, in the middle of which, at c, is the thinnest part of the vessel. When the workman blows air into the pipe, and closes the aperture with his thumb before withdrawing the pipe from his mouth, the air expands and exerts great tension upon the sides of the cylinder; if the weakest part, at c, is now held in the flame it will be blown out and burst. The cylinder having thus been opened as represented in Fig. 2136, the next object is to extend the somewhat uneven and thick margin of the aperture, and reduce it to the proper dimensions, whilst at the same time the other parts are straightened and acquire a uniform diameter, as is shown in Fig. 2137. Prominent portions which may sometimes project, are cut away with the scissors. 2135. 2136. 2137. 2134. 2132. 2133. o According to the size of the cylinder, it may be either blown at once, or it will require to be reheated several times. When very long and wide cylinders are blown, the lower portion is liable to become too thin; an extra portion of glass must then be incorporated with it before the opening process. The neck and curvature where the pipe was attached to the cylinder have now to be removed, in order to spread the whole out in the form of a plate, and the cylinder must be cut open lengthwise. The cylinder. supported by an assistant upon a wooden rod, is, therefore. turned round two or three times in the curve of a bent iron, heated to redness, as shown in Fig. 2138, and a drop of water is Digitized by Google 870 GLASS. allowed to fall upon the heated line, which fractures the glass and detaches the cap. In a similar manner, but in a straight direction, a crack is made longitudinally, and the cylinder is then prepared for spreading or flatting, Fig. 2139. 2138. 2139. Furnaces constructed purposely, in separate buildings, are necessary for this operation, the principal parts of which are shown in horizontal section over the sole in Fig. 2140. The arched space A which extends the whole length of the furnace, comprising the ash-pit a, and the grate r; the former is accessible by the door b, the stokage is performed through d. The flame enters the upper space through the apertures cccc, and first plays upon the flatting-hearth C before entering the annealing or cooling furnace B, which is also heated directly by the fire, when it escapes through the flue or channel D, by which the cylinders are introduced to be subsequently removed at i. The flatting-hearth and the cooling-furnace are connected with each other by a low-arched, wide aperture E, for the passage of the plates, as well as by a smaller, higher opening g, for the admission of the flame. The heat in the in- terior can easily be regulated by pushing plates over the apertures c c, and opening or closing the aperture k. The flattener stands in front of the aperture l, the workman engaged at the cooling-furnace before m, and an assistant in front of i, who pushes the cylinders 000 o along the railway p. 2140. , S c s c c B q C c m The most essential part of the furnace, however, is the spreading-plate or flatting-stone q and - This must be perfectly even, without any roughness or inequalities which would scratch the glass or make it lumpy; it must be inalterable in the fire, and of a size somewhat larger than the flattened cylinders. A plate of this description is usually manufactured from fire-proof clay mixed with cement, (either ground fragments of burnt clay of the same kind, or fine sand, or ground quartz) strongly beaten during drying, then burnt, and lastly ground smooth; it is laid upon a bed of sand and in con- tact with a second table of the same sort in the cooling-oven. To make quite sure that no injury shall be sustained by the plates upon the flatting-stones, it is customary to cover this previously with a Lager. This is the name given to a thick plate of glass expressly blown for this purpose. These lagers are soon devitrified, which is of no moment, 80 long as the surface remains smooth; this, how- ever, does not last long, and frequent renewal of the lager becomes necessary. Lastly, to prevent the cylinders from attaching themselves to the lager, the flattener, in some manufactories, throws a handful of lime into the furnace, which is carried as fine dust by the flame and spread over the lager. The temperature in the flatting-furnace must only be just sufficient to soften the cylinders; whilst in the cooling-furnace it must not attain that point. The spreading operation is commenced by introducing the cylinders into the warming-tube D. The further the cylinders are pushed forward by those succeeding them the more they become heated, until they begin to soften on reaching the flatting-stone. They are then taken by the workman with a rectangular bent iron, and placed upon the lager with the cut side uppermost, where they open of Digitized by Google GLASS. 871 themselves, and are easily straightened and made even. For this latter purpose, a rod of iron, furnished at the end with a wooden polisher, Fig. 2141, is employed, and this is dipped into water each time it is used. When all the curvatures and lumps have been reduced, the sheet is pushed back- 2141. wards into the annealing-oven, where it cools down and is placed in an upright leaning po- sition by another workman. Between every 30 or 40 sheets, an iron rod s 8 8 is inserted, and the operation is continued until the whole fur- nace is filled. Fig. 2142, 1 is an elevation of a flatting- furnace in section, with three annealing-arches of the ordinary description. Fig. 2143, 2 is a ground plan of the same. Fig. 2144, 3 and 4 are elevations of two end views of the flatting-furnace. a b is the spreading-furnace divided into two compartments by the partition c; dd are two sets of fire-bars, on which wood must be burnt; e is the spreading or flatting stone of the furnace, which must be perfectly smooth and even; i is an opening through which the cylinder is placed in the furnace previous to being laid on the flatting- stone e; h is the opening through which the workman spreads the cylinder into a flat sheet of glass; f is the opening through which the sheet of glass is removed to the table or bed g, in the compartment b. The upper side of the table g is made of stone, similar to that employed as the flattening surface. It is fixed to an iron frame-work on wheels, and is kept at a proper degree of heat by remaining in the furnace, as shown in the drawing. The carriage runs on a railway in front of the annealing-arches, where the sheet is transferred in the usual way. 2142. 1 a The cylinder is placed on the flatting-stone, and is split lengthwise by passing a red-hot iron bar k from end to end, having previously sprinkled a little charcoal powder on the inner surface of the cyl- inder. It is now spread out into a sheet by pressing the same on the flatting-stone, by means of a small block of elder-wood, fixed on an iron bar m. The temperature at which the flatting is performed is such, that the operation does not occupy more than a minute. 2143. 2 a e Two improvements have been introduced in this operation. One consists in making part of the floor of the compartment a to consist of a movable stone about 10 inches in diameter, on which the cylinder is placed. It is gradually exposed on all sides to the action of the fire, by causing the stone to revolve on its axis, and thus the objection to the previous plan is avoided where one side of each cylinder became so much hotter than the other. 2144. 3 m Crown-glass.-In the manufacture of crown-glass, in circular disks, a flattened vessel is first blown in front of a furnace specially constructed for the purpose, and this is converted, without any interruption of the process, into a round disk, thickened in the centre. Digitized by Google 872 GLASS. Figs. 2145, 2146, and 2147 show a ground plan of the melting-furnaces and the elevation of an end and side; aaaa are the stone pillars which carry the cone; 6666 the walls of the furnace; cc the grate-bars upon which the fuel lies; dd the "sieges," or position which the melting-pots occupy, one opposite each opening eee; g is an elevation of the sides ff; and h an elevation of the ends ii of the furnaces; kk k are temporary openings to enable the workinen to insert large iron levers to assist in placing the pots, which are carried on a machine, in a red-hot state, into the furnace through the other temporary opening 1. 2145. a a b b i b b a 2146. 2147. th e l g k k k When a certain weight of glass, a, Fig. 2148, has been collected or gathered from the pots on the end of an iron tube b, it is fashioned into a peculiar form, as shown in the figure, on a solid plate of cast iron c, also called a marver, although used for a different purpose to that mentioned previously. Pre- vious to the operation of marvering," the workman cools the iron pipe, which has become heated by being exposed in the melting- furnace. 2148. The marver c is placed on rollers for the convenience of moving it from place to place as required. When the mass of glass has assumed the proper form, a boy blows through the iron b tube, while the workman continues to roll the ball upon the marver. During the previous operation of "marvering," the mass of glass is fashioned so as to give the outer extremity a conical form, the extreme end of which becomes the outer axis of the globe during X the operation of blowing. This outer axis is called the 'bullion," and during the expanding of the globe, the workman rolls this X bullion along a straight edge. The piece of glass, after the above operation, is reheated, in the blowing-furnace, and expanded by the workman blowing through the iron pipe, until it is so far cooled as to require another 'heat." When it has been blown to the proper size, Fig. 2149, 2, it is again exposed to the heat of the furnace, when the workman, resting the pipe on an iron support, during which time the neck remains cool, causes the Digitized by Google GLASS. 873 glass globe, by a peculiar motion of the pipe, to assume the shape shown in the figure, 3. This last operation is technically termed 'bottoming the piece." It is then removed to a framing, Fig. 2150, where it rests on its edge on some ground charcoal and cinders a. Another workman then attaches a strong iron rod with a quantity of melted glass at its end, to the centre of the piece, as at b. The " blower" now touches the neck of the piece at c, with an iron rod previously dipped in water, and by a smart blow on the iron tube d, detaches the piece, leaving the neck open, as shown at 4. 1 2149. 2 3 The " piece" is now removed to the flashing-furnace." The thick neck is first heated at the opening, whence a powerful flame is issuing. Fuel is placed on the grating for the purpose of warming the " piece," while the neck is heated from the larger furnace through an opening in the side. As soon as the neck is sufficiently soft, a boy inserts a flat iron tool through the nose-hole, to smooth the roughness left in the neck by breaking it off as described above. When the neck has been sufficiently heated at the nose-hole, the bell-shaped vessel is brought in front of another opening, where it receives the full heat of the flame, and the pipe is then made to revolve with the greatest possible rapidity. The action of this rotary motion upon the softened glass is easily conceived. The centrifugal force communicates to the particles of glass a tendency to fly off at a tangent, and to arrange themselves in a circular plane perpendicular to the axis of rotation. The mouth being the softest part, first expands, and this quickly increases until the whole suddenly opens into one sheet of glass, Fig. 2151, of about 6 feet in diameter, which, with the exception of the central 2150. 2151. b portion, is of nearly uniform thickness. It is obvious that a sheet of such dimensions must quickly fold together in the soft state, if the rotary motion is not kept up. The workman, therefore, continues the rotation after the removal of the sheet from the flame of the furnace, until it reaches the annealing-oven, where it is placed on a small circular bench, and is detached from the rod by means of a pair of strong shears, leaving a mark called the bullion," or bull's-eye. Another workman, who has charge of the annealing, now raises the table" of glass upon a large fork-like instrument, and carries it to an upright position in the annealing-arch, Fig. 2152. The tables stand thus on their edges, upon two strong parallel iron supports, which run the whole length of the annealing-kiln. 2152. a The glass, after remaining in the kiln for a considerable timo, during which the cooling has been carefully regulated, is withdrawn, so as to enable a workman to go inside and hand out each table on the outside to an assistant. Plate-glass.-The operation of blowing and flatting glass for mirrors is similar to that already described for window-glass, with some slight modifications rendered necessary by the greater size of the plates. The casting of plate-glass is a perfectly distinct operation. The thickness of these plates, which are often 10 feet and more in length, must of necessity corre- spond with their extension and that the light may be perfectly reflected from the metallic surface at the back, they must be as transparent and colorless as possible. To conform to such important con- ditions, the composition must consist of the purest ingredients, and afford a glass, the surface of which is quite unalterable when exposed to the air; if this is not the case, the plate becomes dull, loses its polish, and with this its transparency. 110 Digitized by Google 874 GLASS. The following drawings of a plate-glass furnace exhibit the manner in which the fusing-pots are arranged, and also how they are inserted and removed. Fig. 2153 is a horizontal section at the height of the sieges to the right of xy, and somewhat lower to the left, through the holes for the cuvettes. Fig. 2154 is a perpendicular section through the line x y. The melting-furnace is surrounded by four side-furnaces aaa, used for burning and heating the pots, and 80 arranged that the whole length 2153. m m m 0 i i 0 a B B x a n n of the sides with the siege a is left open and free of access. Thus the two remaining sides are only accessible by the narrow passages B B, and these are connected with the large apertures bb. These apertures are used for the insertion of the pots c, and, at the same time, for stoking the fire; for the latter purpose they would be too large, and allow too much heat to be lost; they are consequently bricked up above and closed in front by slabs of clay, with the exception of the small apertures e c. À grate is indispensable when coal is used, but this is not the case when wood is the ordinary fuel. 2154. B B SU n a T S s The flame travels from the melting-furnace, after passing between the sieges, and heating the pots cc, and the cuvettes i, through the flues 00 into the side-furnaces A. Two rows of holes are left in the free sides of the furnace. By means of the upper working-holes m m m, the melting-pots are accessible for the purposes of ladling; through the two lower holes nn, the cuvettes are inserted or removed upon the iron slabs pp, which must consequently be exactly upon the same level as the sieges. All the holes can be closed by movable plates at pleasure. The draught can be regulated through rr, and the ash collects in 8 8. Mr. Bessemer has lately proposed a new method of casting plate-glass in sheets, by pouring the glass in the melted state directly from the pots between two rollers, placed at a certain distance from each other. so as to ensure a uniform thickness throughout. This is an invention which must commend itself to many in our country, as this art is but young even in England, and scarcely known here, but which must yet be extensively manufactured, as the means are not wanting, and the material is abundant in many of our states. At present our valuable plates are imported, and Germans are the artisans that are mostly employed in England. There are plenty of them in this country, and doubtless many good artisans capable of managing this business. Digitized by Google GLASS. 875 The pot-furnace and machinery for this process are entirely novel and very different from those in common use, and as the invention is likely to be carried out in practice, a notice of the most important parts of Mr. B.'s patent will not be out of place here. The furnace employed is a reverberatory furnace, Fig. 2155, with a low arch and descending flue d The flame proceeding from the grate a, plays upon the surface of the materials in the pot e, in the fire-space b. The arch is formed at that part which is most exposed to the heat, and the alkaline vapors from the mixture, of hollow bricks ccc, over which a draught of cold air is caused to play, by connecting the space above the furnace with the ascending main chimney. The object of this cooling, which is of course attended with a loss of heat, is to prevent 2155. etlel 0 a ////////// d tears, consisting of the fusible product of the action of the alkaline vapors upon the ingredients of the bricks, from forming on the arch, and falling into the glass during fusion. The pot, c, is of very large dimensions, as large indeed at the lip on the one side as the width of the plates, which it is proposed to cast with it. It is set upon a siege composed of large masses of fire-stone, and these are cemented to- gether, as well as the pot upon them, by some bottle-glass, which, in the fused state, enters the crevices and binds the whole firmly together upon the strong-ribbed cast-iron frame g. This frame moves upon four wheels h upon a railway to, which extends beyond the furnace to the rolling machinery, to be described immediately. Thus pot, siege, and frame are all wheeled in and out of the furnace at once, as will be seen 2156. by reference to the section, Fig. 2156, where jj represent the hollow bricks, or masses of stone, by the removal of which a free in- gress and egress is allowed the whole car- riage on the continuation of the rail. The pot and carringe fill the entire recess in the b furnace, and the flame playing upon the top does not much affect the iron frame of the carriage through the bad conducting-stones which form the bed of the pot. Fig. 2157 is a longitudinal section through the middle of the frame-work and machinery, by means of which the pot and siege are raised, and the melted glass poured out between the rollers. The carriage consists of a strong-ribbed iron frame, mounted on four small flanged wheels which run on two rails. The upper side has a recess into which blocks of soap-stone, or fire-brick, are fitted into an iron frame. In the upper part of these blocks recesses are made for the melting-pots to sit snugly, and a quantity of broken bottle-glass is laid on the top of the blocks, and they are heated till the glass melts and cements the joints of the blocks together, and while this glass is yet in a fluid state, the carriage is removed a moment from the furnace to receive the melting-pot which is brought in a white-heat from the pot-arch, set in the midst of the fluid glass. and the carriage then returned to the furnace. On afterwards using the pot, as the bottom is very thick and the heat only having access to it through the materials which it may contain, the bottle-glass used to cement the pot to the bed or recess is found not to be too cold to be brittle, nor 80 hot as to allow the pot to slip from the carriage. Fig. 2158 is a side elevation of the machine, with the pot and carriage in their position after being removed from the furnace. Fig. 2157 is a longitudinal section showing the pot in an elevated position and partly emptied. Fig. 2159 is a longitudinal section of one of the rollers and stuffing-boxes, showing how the water is made to enter and leave while they are in motion. aa is a side framing of cast-iron secured by the cross-pieces c, and also by the stretchers ec, between the side-frames a a. The rollers f and g are placed in suitable bearings fitted to the side-frames, and are made to move to and from each other by means of screws, which force the brasses H and roller f near to the roller g. A Digitized by Google 876 GLASS. piece of iron is placed between the brasses and the frame, and according as it is exchanged for one of more or less thickness so will it cause the rollers to be nearer or further apart, and thus regulate the thickness of the glass. The roller f is also provided with wheels jj at each end, and the roller g also with wheels at each end within the side framing. In addition to these wheels, the axis of the roller f has on the outside of the framing a large bevel-wheel m, driven by a pinion 90, 2158. $ C X on the end of an upright shaft p, driven by an underlying shaft from the main driver. The upper part of the shaft p is supported by a bracket q, projecting from the side-frame; near the upper part of the framing there are two plummer-blocks r, which form a support to the pins which project from the side of a piece of tilting-frame. There are two of these pieces t, one on each side of the ma- 2157. K # INEM 12@ WA cch or chine, and they are connected together by a third piece u, by bolts. The frame when thus put together is supported by pins 38, and occupies nearly the entire width between the side-frames a a. The lower part of the piece 1 has a segment of a tooth-wheel formed on it and centred on the pins 8, so that the Digitized by Google GLASS. 877 tilting-frame may move a portion of a circle on these pins. The piece и has two small ribs or rails extending across and cast upon it, which form a continuation of the rails which conduct to the furnace. X is a shaft extending across the frame supported by plumber-blocks y, attached to the side-frames e, which shaft x has pinions z upon it geering with the segment of the tilting-frame t. The shaft x is also elongated to a convenient distance, and supported at its extremity by a frame of two side pieces con- nected by stretchers. The upper part of the frame carries two plummer-blocks and a shaft the shaft having a handle and a pinion upon it, which geers into a large spur-wheel on the shaft X. By turning round the handle on X it forcibly raises the tilting-frame with any object that may be placed on it. There is an opening in the tilting-frame through which the axis of the roller g passes; and this roller is sufficiently long to allow the required movement of the tilting-frame. The rollers are supplied in this machine with water to keep them cool; the water is conveyed below the floor to the pipe 1; at 2, there is a branch which leads off from 1 to the axis of the roller g, which it enters through the stuffing- box; the tube 1, proceeding further upwards, bends over and forms another stuffing-box 4, which allows the upper roller f to move a small distance horizontally, to alter the thickness of the plate. The water 2159. I enters the axis of the roller f by passing through the stuffing-box 5; the axis of the roller is not hollow throughout, but the hollow part of it terminates at 6, Fig. 2159, where there are two side holes bored at right angles to it, which allow the water to pass into and occupy the large hollow space in the body of the roller. By a similar contrivance the water is allowed to flow out of the opposite end of the roller, passing through the stuffing-boxes 8, 9, and, descending the pipe, is conveyed away under ground. A strong curved plate K extends the entire width between the said frames, fitting closely up to the roller g, and secured to the frames by lugs. On this plate the sheets of hot glass slide down towards the flat ted, but which is broken off in the cuts; the side of the melting-pot nearest to the machine has a curved lip, so as to overhang the roller g nearly as far as the centre. The pin 8 of the tilting- frame is at its centre a little above the upper side of the roller g, so that the lip of the pot being in the position shown in Fig. 2157, it does not shift from that spot far, as it may be tilted up. The mode of operating with this apparatus is as follows: When the glass is in a fit state for casting, the dccr is removed by a crane from the mouth of the furnace, and by the assistance of an iron hook the carriage and its pot are easily rolled forward upon the rails before mentioned to the tilting-frame t; then they occupy the position shown in Fig. 2158. The carriage and its pot are now moved forwards until the set screws M come in contact with the carriage the office of these screws is to regulate the extent to which the lip of the pot shall overhang the roller g, 80 that when a new pot is used its proper position for pouring may be adjusted. The screws M pass through stout lugs N, cast on the piece "; the handle on X being turned, the pot will be elevated, as shown in Fig. 2157, when the glass passing between the rollers will be formed into sheets. When the pot is emptied it is again lowered and re- turned to the furnace for a repetition of the preceding operations; the roller f is furnished with a rib on its circumference, which is the whole of the roller; this at each revolution cuts the glass off into lengths. Lead or flint glass (so called because flint was first employed in the manufacture) is peculiarly adapted for articles of luxury, such as goblets, chandeliers, decanters, &c., from the ease with which it is ground or cut, from its brilliant lustre, high refracting power, and perfect freedom from color. The mass which is used for this purpose is called, in a more limited sense of the word, crystal, (from its resemblance to rock crystal,) and it excels the Bohemian grinding-glass (crown-glass) with reference to refractive power and easy fusibility, although the latter is harder and more completely colorless. As nearly all the articles composed of flint-glass, or crystal, require to be ground, in order to exhibit their greatest brilliancy, they must be constructed in a very massive form; there is consequently more necessity for avoiding all sources of color, and for preparing the glass from oxide of lead, potash, and silica alone. The fusion occupies six or eight hours, and the fining, which is very much facilitated by the easy fusibility and the purity of the materials. requires about the same time. During working, the glass must be protected from the smoke of the furnace, and iron must not be brought into contact with it, as it otherwise infallibly becomes of a dark-brown color. Iron is dissolved by the glass, taking the place of the lead, which separates as metal in the most minute state of division. The construction of furnaces and melting-pots in manufacturing flint-glass are somewhat different from those employed in the other descriptions of glass. Fig. 2160 is a ground-plan of the melting-furnace; CCC are the pots which are situated at equal distances between the pillars or piers E E which support the exterior dome. a a are the openings in two of the piers for charging with fuel. Fig. 2161 is designed to show how the heat is carried round the pot in its exit from the furnace. The pots are covered with a hood-shaped top, and these fit the working-holes of the furnace, 80 that the smoke and heat cannot escape in the same way as in the usual glass-furnaces ; a is the pot with the top Digitized by Google 878 GLASS. b; c is the roof of the furnace; d the "siege" on which the pots are placed; and e e a flue, low down, which passes between the furnace and the cone till it reaches a point f where it enters the cone itself; g, Fig. 21614, is a front view of the pot and arch of the cone, which allows the workmen to approach the opening in the fur- nace, against which the mouth of the pot is placed; h is an opening direct from the outside into the flue, for the purpose of 2161. keeping it clean. Fig. 2162 is a general view of the melting-furnace, cone, 0 2160. a E c c e F c c a c c 21614. E c c and working-holes. It consists of two domes, AA, B B, one within the other, of which the interior one is flat, and. the exterior of considerable altitude, terminating in a high chimney. The only connection between the domes is by the flues G G, which are situated one on each side of the crucibles, 80 that they receive the whole body of the flame as it passes from the fire-place to the exterior dome, and thence to the chimney. 2162. 2163. B B G G G G Z G x x Z a F Flint-glass is either formed by simple blowing with the pipe, by blowing in moulds, or by moulds alone; in every case the form can be improved, as is generally done, by grinding, &c. The moulds are carefully constructed of brass or iron, and are somewhat wider at the upper part, when of simple construction, that the pieces may be easily removed, or are composed of more than one piece when projecting parts are to be moulded. A mould of the latter description is represented in Digitized by Google GLASS. 879 Fig. 2164, intended for a decanter; a section of the mould is shown in Fig. 2168. The bottom e and the sides a of the body form the lower and larger part of the mould, and are held together by the screws the upper smaller part consists of two halves, meet- 2164. ing in the line zz, which open after the fashion of a pair of tongs when turned upon the hinge That they may not be extended h more than is necessary, the two wings are impeded by the plugs o fixed to the ring i. The workman introduces the glass globe g, attached to the pipe, into the body of the mould, the neck portion being thrown open, and blows with great force into the m globe, as soon as the neck portion has been closed by an at- 0 tendant, and fixed by the screw m, (the female screw belonging i to which projects at n.) The glass is now forced, by the pressure, n against the sides of the mould, and extends in the form of a cap at g, above the margin, where the pipe is detached in the direc- tion of x x. The cylinder 1, and another similar one, more at the back, are intended for the insertion of wooden handles. Massive pieces, such as plates, are formed by pouring melted glass between two plates of metal composing the mould, and the excess of glass is squeezed out from the crevices by applying weights to the mould. All articles of fliut-glass, whether blown, moulded, or pressed, require annealing previous to cutting or grinding, and as they are frequently constructed of very different thickness, two kilns, which can be heated to different temperatures, are requisite; the larger and thicker pieces require that the kiln should be much hotter than is necessary for thinner pieces. These kilns are long, low buildings, arched over on the top. The various articles are all placed on sheet-iron trays. These trays are put into the kiln, through the opening in front, and are all connected together by hooks, by which means they can be moved by a chain, worked by windlass or similar machinery, to the further end of the kiln, and are thus gradually withdrawn from the hottest part, and, having arrived at the further extremity, are re- moved at a temperature little above that of the atmosphere. Moulded or pressed glass never exhibits its full amount of lustre, nor even the degree of sharpness of the metallic mould the glass, which is never limpid in its liquid state, is first cooled by contact with the metallic surface, and is thus prevented penetrating into the sharp corners of the mould, nor does it even accommodate itself perfectly to the flat sides. For this reason, the surface of moulded glass is not even, but always more or less curved, and the edges are not sharn; but the use of moulds as a pre- paratory step to grinding, is of great advantage to the grinder, as the vessel acquires a perfectly regular form, and, although in a crude state, presents all the prominent and receding facets to be perfected at the lathe. The ordinary utensils used in grinding or cutting glass, are disks of iron, sandstone, or copper, which revolve in a kind of lathe; their edges, which are sharp, angular, or rounded, are supplied with sand for rough grinding, and with emery for fine grinding. Similar disks of tin, wood, or cork, used with pumice-stone or colcothar, are employed for polishing the glass. It is obvious that not only disks with very different edges will be required, but also disks of very different dimensions, from 8 to 10 inches in diameter, (I to t of an inch in thickness.) For inscribing initials, designs, &c., disks of copper of the size of a cent are employed, with oil and emery; the finest incisions are made with copper pencils, either pointed or ending in a button or small disk. Bessemer has lately taken out a patent in England (1848) for the manufacture of plates, sheets, and panes of glass, which is of sufficient importance to merit a place here in full. This invention relates, first, to the arranging of machinery for washing, drying, and sifting sand, and afterwards grinding or crushing the same in combination with the other materials employed for making sheets, plates, or panes of glass. Secondly, to the employing an additional pair of rollers to the ma- chinery now used to roll glass into sheets. Thirdly, to a method of heating annealing-kilns or lears. Fourthly, to a method of smoothing or polishing plates, sheets, or panes of glass, whereby an endless belt or strap (charged with polishing material) is made to pass rapidly in contact with the surface of the glass, and to traverse slowly across it in a direction at right angles to the line of its quick motion; and lastly, to a method of producing plates or tables of glass of the description known as crown-glass, in such a way that the centre of the table shall not have a bullion or knob as usual. First, with re- gard to the method of washing, drying, and sifting sand, and afterwards grinding or crushing the same in combination with chalk, alkali, charcoal, or other matters used for making sheets, panes, or plates of glass. To accomplish this object, the patentee uses the apparatus represented in Fig. 2165, a longitu- dinal section of the apparatus; Fig. 2166 a longitudinal or side elevation, and Fig. 2167 a plan of the same. The letters of reference denote the same parts wherever they recur in each of the figures. A, is a cylindrical iron vessel, having an annular trough or channet formed around its upper edge at A'; this channel is strengthened by brackets A", and has a flange at its upper edge A3, to which the mouth of the vessel B is attached by bolts; this mouth-piece has three arms B', B', and B', meeting in the centre boss C, which is bushed with brass, and so shaped internally as to form a bearing and support for the shaft D, which has a conical collar at D', resting in the brass bush C, to prevent its dropping downwards. As the lower extremity of it has no support, the bush C is elongated upwards so as to form an oil-cup, and is covered by the piece C', which revolves upon the shaft, and prevents any sand from falling into the oil. The shaft D passes upwards to any convenient height, where it turns in other bearings, and has keyed upon it a bevelled wheel, into which are geered two other bevelled wheels, mounted on a shaft proceeding from any first mover. The office of these wheels, but which are not shown in the engraving, is to communicate a rotatory motion to the shaft D, in either direction, by the shifting of a clutch in the manner well understood and practised in reversing geer. The shaft D is Digitized by Google 880 GLASS. provided with a number of radiating arms or blades E, placed at such an inclination as to form each a portion of a spiral, and will therefore have a tendency when revolving in one direction to lift any mat- ters they may be moving among, and also have a tendency when revolving in the opposite direction to press such matters downwards. F is a pipe to convey water from an elevated reservoir into the lower part of the vessel A; this pipe is provided with a cock at F' and handle F. In Fig. 2165, it will be seen that the vessel A and its mouth-piece B, although screwed together at the outer flange A', do not come in contact at A', whereby a circular space or opening is left all round the vessel, communicating with the trough A'. The action of this part of the apparatus is as follows The sand to be used for making glass is conveyed along the floor G, of the upper room, and emptied into the vessel A, until the vessel is at least two-thirds filled; the shaft D is then put in motion in the di- rection to lift the charge; at the same time, the cock F' is opened, and water is allowed to flow upwards through the body of sand, while the blades E keep lifting and turning it over. As soon as the water R M I on A K X A N 2105. 2156. X 5G N 50 44 M 3 26 33 27 reaches the outlet A', it flows over into the trough A', carrying with it such foreign matters as are soluble in water, or easily mechanically mixed therewith: the water is allowed to escape from the trough by the pipe H, leading to a culvert underground. When the water flows off clear, the cock F' is closed and the throttle-valve J is turned at right angles to the position shown in Fig. 2165, and the shaft D being caused to revolve in an opposite direction, the sand will be forced downwards and expelled into the wood-back or cistern K. The valve J being again closed, the operation may be repeated. The valve J is a disk of wood covered at its periphery with leather, in order to make it water-tight, and moves on an axis I, and has a handle L, by which it is moved when required. The vessel A is fastened by a lower flange M, to the transverse timbers N, inserted in the walls of the building, and is further Digitized by Google GLASS. 881 steadied at the part where it passes through the upper floor G. The cistern K has a slanting bottom to facilitate the drawing off of that portion of the water which is admitted with the sand at the lower end. There is a fine grating of pierced zinc P, covered with felt, 80 as to prevent the sand being car- ried off by the water which flows through the pipe 0 into a drain. The cistern K is supported on tim- pers R, and others placed crosswise at R'; one side of the cistern has a rectangular opening S, behind which is placed an agitator T, mounted on an axis T', which extends through the sides of the cistern, and carries at one end the pulley-wheel U, which is put in motion in the following manner. Beneath the rafters V, of the upper floor G, is the shaft W, receiving motion from any first mover by a strap passed over the drum X; this shaft is supported in plummer-blocks Y, bolted to the rafters V, and carries a pulley Z, from which a catgut or other band passes over the guide-pulley Z', and on to the pulley-wheel U, and thereby causing the agitator I to revolve in the direction of the arrows and expel a portion of the wet sand on to the drying-plate: a is a plate of copper, or galvanized iron, having a raised edge a' on each side to prevent the sand from falling off; beneath it is the furnace b: a fire is made at c, and the 2167. products of combustion are allowed to flow under the plate a, as shown by arrows, and to descend the downward flue d, into an underground flue, leading to a chimney. On each side of the plate a there are small bracketed projections e, on which are bolted the bearings f; in these bearings the cranks g are caused to revolve by means of the worm-wheels h, which are 0 keyed on the crank g, and are geered into worms ii on the 9 shaft j: this shaft revolves in bearings kk, and has a pulley- wheel l fixed upon it, which receives motion from another pul- ley-wheel m. On the shaft to a light iron frame n is supported 16 by the cranks g; this frame has a number of scrapers p fixed crosswise upon it, 80 that the frame n, which always moves parallel with the plate a, by the motion of the cranks, is made to dip its scrapers into the sand at every revolution of the crank, and to impel it forward on the plate, turning it over, 44 and always advancing it in little heaps, further along the hot plate. The speed of this part of the apparatus is to be 80 reg- ulated that the moisture is evaporated by the time it arrives at q, where it falls from the plate a, on to a sieve r, in a dry state. 05 The wire sieve r is hung upon a joint at s, and has a small shaft t below it: this shaft has upon it a tappet-wheel и, which A lifts up the sieve a short distance and lets it fall suddenly in N M quick succession, 80 as to shake the sand through it on the in- clined bottom of the bin v. The shaft of the tappet receives its motion from the pulley x, on the shaft w, which, by means of a band, communicates with the pulley-wheel y, keyed on the shaft t. Such matters as shells, stones, &c, as are mixed with the sand and are too large to pass through the sieve r, fall off from it into the trough w, which is raised in the centre at w', and allows any matters falling into it to roll into the ves- sels 2, from which they are to be removed, as occasion may a require. The sand, by the operations just described, arrives in the bin v freed from small earthy particles by washing, and screened from all larger particles than grains of sand, and be- ing in a dry state is now fit for the grinding operation; and to facilitate its removal to the mill, and to regulate the quantity forming one charge, the following contrivance is resorted to. The sand is first raised by means of the archimedean screw 2 into the receiving-hopper 3. This screw has a central shaft 4, passing, at its lower end, through the bottom of the bin v, and resting in a bearing 5, let into a block of stone 6, below the floor. The upper end of the screw-shaft rests in a plummer- by block 7, bolted to one of the rafters V. Near the top of the screw there is a bevelled wheel 8, which is actuated by another wheel 9 on the shaft W. The rotary motion thus transmitted causes the sand to ascend the spiral path of the screw, in a manner well understood when applied to other purposes, and finally to discharge itself into the receiving-hop- per 3, which is secured to one of the rafters V, by an iron strap 10. Below the receiving-hopper there is another hopper 11, of larger dimensions, having its bottom in- clined to one side, where it terminates in a wide spout 11*. This hopper 11 is not fixed like the one above it, but is supported on scale bearings at 12, projecting from an iron plate 13, bolted to the hop- per 11. There is one of these pieces on each side of the hopper resting on the forked end of the arms 14*; these arms are keyed on to a shaft 14, which is supported in bearings 15#, formed on the two iron standards 15; the standards are bolted on to a raised piece of masonry 16, and are steadied at their upper ends by a stretcher 17, extending across from one to the other. From the centre of the shaft 14 there projects a lever 18, the end of which is screwed and passes through the adjustable weight 19; in 111 Digitized by Google 882 GLASS. order to prevent the hopper 11 from tilting over, it has an arbor 20, projecting downwards from the under side of it; at the lower end of the arm, there is a roller 21, which moves up and down between two guide-bars 22; 23 is a support for the weight 19 to rest upon. The hopper 11 thus supported, forms a sort of weighing-machine, in which the quantity of'sand required for one charge of the mill is determined. Its operation is as follows:-The apparatus being in the position represented in the drawings, the sand is seen flowing from the receiving-hopper 3 through an opening in the bottom of it. This opening is provided with a plug 24, formed with hollow sides, in the manner usually practised with the tails or spindles of cone-valves; but as these hollows or flutes do not extend the whole length of the plug, it is capable of entirely closing the orifice if pulled down. This plug is attached to a small chain and rod 25. Now 80 soon as the accumulated weight of sand in the hopper 11 is sufficient to counterbalance the weight 19, it will do so, and will lower itself until the stop 20# reaches the guide- bars 20, where it will rest. In moving down, the hopper will draw down the plug 24, by means of the chain 25, and prevent any more sand entering it. During the time the plug-hole is shut, the sand, which is regularly brought up by the screw, will accumulate in the hopper 3. In order to regulate the exact weight of sand in the hopper 11, the weight 19 may be screwed fur- ther off, or nearer to the axis of the lever. 16 is a piece of masonry, raised above the general level of the floor; on it is placed the horizontal bed-stone 26. This bed-stone is part of an edge-stone mill, constructed on the general principle of such mills. 27 is a vertical shaft, running in a brass step 28, at its lower end, and passing up through the floor above, where it is supported by another bearing, and carries on its upper end a bevel-wheel geering with another bevel-wheel on a shaft, actuated by any first-mover. These wheels the patentee has not shown in the drawings, but they are well understood. The brass step 28 is elongated upwards, forming a sort of tubular oil-cup; surrounding the shaft, there is another tubular piece 29, closed up at top, and attached to the shaft. This tube 29 is inverted over the oil-cup, and reaches nearly down to the bed-stone, 80 as to prevent any powder working into the oil-cup. To the outside of the tube 29, there are attached two curved plates or scrapers, shown at 30, Fig. 2167, for the purpose of removing the materials from the centre of the bed, and distributing them in the path of the stones 31. On the shaft 27, there are four cast-iron arms, united by a central boss fitted loosely to the shaft 27, but made to turn with it. In consequence of a projection or feather 32, two of the arms 33 carry with them the edge-stones 31, mounted with proper bearings, through which the arms pass. In rolling over any matters in their path, these stones can rise up, carrying with them the arms and boss on the shaft 27. The other two arms 34 carry at the extremity two small axles 35. These axles have at their lower ends the scrapers 35#, by which the materials under operation are brought from the curb or outer iron ring 36, into the path of the "runners." When one charge of materials has been ground, they are removed to the receiving-box 27. For this purpose, a portion of the iron curb 36* is mounted on a joint 38. An elongation of the joint- pin is seen at 39, where it extends through the receiving-box 37, and has a lever and weight 38, for the purpose of retaining it either up or down. When it is moved down, as at 36*, it allows the ground materials to be passed into the receiving-box. The better to accomplish this end, the handles 39 have to be pulled in the opposite direction to that shown in the drawing, 60 as to reverse the scrapers 35#, as shown by dots in Fig. 2167. The scrapers then cause the materials to pass through the opening in the curb 36*. When this is accomplished, the jointed piece 36* of the curb is moved upwards, and retained in that position by the counter-weight 38, the scrapers 35* are restored to their former posi- tion, and the mill is in readiness for another charge of materials. To do this, the sliding-door 40 of the hopper 11 is lifted up by the handle, and the charge of sand weighed in the hopper 11 is allowed to fall into the curb surrounding the bed-stone. The diminution of weight in the hopper 11 will allow it to ascend into the position shown in the drawing. When it is emptied, the slide 40 is to be shut down, and the plug 24 lifted up so as to allow the accumulated sand in the receiving-hopper 3 to fall into it. The refilling of the hopper 11 takes place while the grinding of the former charge is going on. When the sand is nearly reduced to the required degree of fineness, the soda, potash, or other alkaline matters, are to be added, and also the chalk, lime, charcoal, or other matters required in glass-making, each in their proper proportions according to the description of glass intended to be made. The materials are to be left in the mill until the greater part, if not the whole, of the matters are ground to a fine powder, when they are discharged into the receiving-box, as before described. He here remarks, that when alkaline salts are used, their water of crystallization should first be driven off by exposing them to heat. The next operation to be performed is, to separate any imperfectly ground portions of the materials, and to return them back to the mill to be again operated upon. This may be returned and worked with the next charge each time. Below the box 37 is fixed a plummer-block 41, which receives one end of the shaft 42, the other end being supported in a plummer-block 43, attached to the case 44 of the holting or dressing apparatus. The shaft 42 has fixed upon it a number of brushes 45, arranged so as to touch the wire-gauze drum 46, as they revolve in a similar manner to that already practised in dressing flour and other matters. Such particles as are fine enough to pass through the wire-gauze fall into the bin 47; but those particles which are too coarse to pass out at the end of the drum at 48, are conducted by the spout 49 into the receptacle 50, and may be re-ground as before mentioned. The shaft 42 receives its motion from a bevel-wheel 51 on the archimedean screw 2, which geers into the wheel 52 on the shaft 42. The wire-gauze cylinder may be made to vary in fineness, according to the desire of the manufacturer: but that which the patentee prefers is a range of fineness between five thousand and ten thousand holes in the superficial inch. The wire-drum is supported by hoops 53 which sur- round it, and is further protected externally by its case, 44. The shaft 42, at the part where it passes through the receiving-box 37, is provided with inclined blades, which, as they revolve, assist in bringing fresh supplies of materials through the opening 37* into the wire-drum. The dressed or finished materials which fall into the lower part 47* of the bolting or dressing apparatus, are raised to the upper floor by means of an archimedean screw 54, in the way already described for elevating the sand. Digitized by Google GLASS. 883 This screw is shown in elevation, its internal structure not differing from those in general use for raising malt and other materials. In Fig. 2167 it is shown as being cut off on the line A B of Fig. 2165, 80 as not to obstruct the view of the rest of Fig. 2167. The screw 54 receives motion from a pulley-wheel 55 on the shaft W, the band from which passes over a pulley-wheel 56, on the screw-shaft, the band being directed in a proper course by the intermediate guide-pulleys 57. The screw, after passing through the upper floor, (where it is shown broken off,) may either be made to deliver the prepared materials on to the floor, or by raising them a little higher, deliver them into a large bin or other recep- tacle, the upper end of the screw being supported in a similar manner to that used to support the screw 2 at 7. Having ground or crushed the materials above mentioned, the callet or broken glass is supplied, as heretofore, in the manufacture of like glass. The advantages of this method of preparing the materials to be used in the manufacture of sheets, plates, or panes of glass, are, first, a saving in manual labor in the operation of washing, drying, sifting, and weighing; and secondly, the minute mechanical division of the various matters used will facilitate their chemical action, and therefore save both time and expense in their formation into glass. Secondly, with regard to the use of an additional pair of rollers to such machines as are used to roll glass into sheets, for the purpose of either rendering the cast or rolled plate more smooth and uniform, or for the purpose of impressing or embossing any designs thereon. Thirdly, with regard to his method of annealing and of heating annealing-kilns or lears, by the introduction therein of air, heated in pipes or other suitable apparatus, after the manner prac- tised in heating air for hot blast in the manufacture of iron, which consists in an apparatus for annealing sheets, plates, or panes of glass. Fourthly, with regard to a method of smoothing or polishing plates, sheets, or panes of glass, by an endless belt or strap charged with polishing material, which belt is made to pass in contact rapidly over the surface of the glass, and to traverse slowly across it in a direc- tion at right angles to the line in which the belt moves over the drums that impel it. The improvements under this head consist in an apparatus for smoothing or polishing the surface of glass after it has been ground in the usual manner. For this purpose he constructs the machine or apparatus in such a way that the polishing-rubber or frictional surface passes rapidly and continually in one direction over the surface of the glass, and is made also to traverse slowly backward and forward crosswise over the same surface, the glass being laid on a stationary table of slate or other suitable material. Process of manufacturing flint-glass and crown-glass for optical purposes.-P. L. Guinand, senior, of Brennets, in Switzerland, was the first who discovered a special process for this manufacture; and be has succeeded in manufacturing crown-glass equal in quality to flint-glass that is to say, free from strise, from bubbles, from threads, and which does not attract moisture. The invention of M. Guinand, senior, consists in working and stirring the material while in a state of fusion, by means of a tool made of the same material as the crucible or glass-pot. He made a hollow cylinder of fire-clay of the same height as the crucible, closed at its lower extremity, open above, with a flat ledge all round of several centimetres in width. Having heated this cylinder red-hot, he placed it in the melted glass; then, by meaus of a long bar of iron, bent to a right angle at a distance of some centimetres from its extremity, which he introduced into the cylinder of fire-clay, he worked and stirred the glass, by giving the bar a horizontal rotary motion. For the manufacture of flint-glass, and of crown-glass, he adopted a circular furnace, in the centre of which is placed the crucible or glass-pot, all the parts of which are exposed to the same temperature; and covered crucibles are adopted, because with crucibles of this form there is no danger of the glass being spoiled by particles of the fuel, or by drops, or tears from the crown or arch of the furnace. The success of the operation depends very much on the form and proportions of the furnace and crucible. Figs. 2178 to 2170 represent the furnace, the crucible, the cylinder of fire-clay, the bent iron bar and its support. Flint-glass, of the usual density, similar to that used for table-seta, decanters, &c., is composed, ordinarily, of 300 parts of sand, of 200 parts of deutoxide of lead, and 100 parts of sub-carbonate of potash. The density of this flint-glass is from 3.1 to 32. The following composition, expressed in kilogrammes, gives the quantity necessary to fill the crucible: sand, 100 kil.; deutoxide of lead, 100 kil; sub-carbonate of potash, 30 kil. This composition gives a very white flint-glass, of a density of from 3.5 to 3-6, and which is perfectly suitable for opticians. It is not necessary to use either lime or arsenic, the only effect of which would be to diminish the whiteness of the material. Details of the operation for flint-glass.-The crucible is to be heated in a special furnace kept for the purpose, and when at a white heat, it is to be introduced, in the usual manner, into the melting-fur- nace, which has been brought to the same temperature. This operation cools the furnace and the cru- cible. The furnace must be re-heated in order to bring it to the highest possible temperature before introducing the materials. This takes about three hours. The throat of the crucible, which has beeu closed with two stoppers to prevent the entrance of smoke, is then opened, and about 10 kilogrammes introduced; one hour after, about 20 kilogrammes more; then. two hours after, 40 kilogrammes. Each time the crucible must be re-closed with the greatest care, and nothing must be put in until the coal on the grate ceases to give out any smoke. At the end of from eight to ten hours, the whole of the com- position will have been introduced. The crucible is left without being opened for about four hours then the stoppers are removed for the purpose of introducing the cvlinder of fire-clay, which has been heated separately to a white heat in the same furnace, and kept at that temperature until placed in the crucible: care is to be taken to keep it perfectly clean and free from ashes. At this period, the flint- glass is melted, but it still contains bubbles. Nevertheless, the bent iron bar is introduced into the cylinder, and the first stirring is given, which serves to coat the cylinder with glass, and to effect a more intimate mixture. In about three minutes, the iron bar is white-hot; it is taken out, and the ledge Digitized by Google 884 GLASS. of the cylinder is placed on the edge of the crucible. This cylinder, being specifically lighter than the glass, floats slightly inclined, because its upper ledge is outside of the glass. The two stoppers are 80 replaced as not to push the ledge of the cylinder into the glass, and the stirring up of the fire is recommenced. Five hours afterwards, a fresh stirring up with a single iron bar takes place, the glass is already well refined, and then from hour to hour there is a stirring, each time with a single irom bar ; great care being taken that at each stirring there shall be no smoke in the furnace, and that the lower doors of the furnace are closed. After having thus used six iron bars, from 25 to 80 centimetres in thickness of coal is thrown on the grate, which forms a mass quickly reduced to coke, and which allows the furnace to cool, without exposing the grate uncovered. The various openings of the furnace are unclosed; the whole furnace and the crucible thus gradually and slowly cool. This operation tends to cause the bubbles which are not yet disengaged to rise to the surface. At the end of two hours this operation is finished; the furnace is again brought to the melting beat. After five hours of the highest temperature, the glass has resumed its greatest fluidity, the bubbles have disappeared, the grates are completely closed below, and the great (brassage) stirring commences-that is to say, as soon as one iron bar is hot, another is substituted for it, and on so for about two hours. At the end of this time the material has acquired a certain consistence, the stirring is not executed without difficulty then the last iron bar is taken out, the cylinder is removed from the crucible, which is very carefully closed, as well as the chimneys and openings, except a small hole of two centimetres, to permit the escape of the gas, which may have remained in the fuel. When the disengagement of gas ceases, the furnace is entirely closed, and it is suffered to cool, which takes about eight days. The door of the furnace is then removed, the crucible, with its contents, taken out, usually in a single mass, except some fragments which become detached round it. The only object now is to make use of this mass and these fragments, the mode of doing which we will explain directly, after having given the details of the operation for crown-glass, which, as may be supposed, has a great analogy with the preceding. Manufacture of crown-glass.-After many experiments, the following composition is found to be the best white sand, 120 kil.; sub-carbonate of potash, 35 kil.; sub-carbonate of soda, 20 kil; chalk, 15 kil.: arsenic, 1 kil. The crucible having been placed in the furnace, as for flint-glass, the introduction of all the materials is to be completed in about eight hours, four or five hours after which the cylinder is to be introduced, and the first stirring takes place; then, every two hours, a stirring with a single iron bar ; six are to be executed in this way. The furnace is to cool very slowly for two hours, after which it is to be re-heated for seven hours, this glass regaining its heat with much more difficulty than flint-glass. The great 1 A 2168. 2169. o El D 3 c G B G A B PH B c C B 2170. M E 4 2171. . os H 2 a L & B e ) Д N a THE Fig. 2168. Horizontal projection of the furnace and crucible. Fig. 2170. Section along the line EF, Fig. 2168; that is to say, along the flue. Fig. 2169. Vertical section along the line CD of the plan. Fig. 2171. Vertical section along the line A B of the plan. stirring then takes place, which lasts about an hour and a quarter. The crucible, the chimneys and the openings are to be closed, as for flint-glass, and the whole is left to cool. Very commonly, as with flint glass, a mass and several fragments are obtained. Digitized by Google GLYPHOGRAPHY. 885 Parallel faces are made on the sides of the mass, whether of flint-glass or crown-glass, in order to examine the interior, and to see how it should be divided, for it is never free from strise, which are usually found collected in one portion of it. After this examination, it is sawed into parallel slices, or trans- verse sections, in accordance with the observations made. Faces are also polished on the fragments, for the purpose of examining them, and disks are made of them in accordance with their weight; for this purpose, they are first heated in a furnace, and then introduced into a muffle, where only the heat necessary to enable us to mould them is given. If the fragment is irregular, it is partially rounded by the nippers, and then, with other nippers, it is placed in a mould, under a lever press, which gives it the exact form of the mould, after which it is taken out with the nippers and carried to the an- nealing-arch. The same letters mark the same objects in all the Figs. A, foundation or support of the covered cruci- ble B. C C, walls of the furnace. DD, openings through which coal is thrown on the grate. E, arch or crown of the furnace. F, door or opening through which the crucible B is introduced and taken out; there is a small opening in this. G G, six chimneye. H, an opening. I, hole to facilitate the placing the cru- cible on its support. K, bent iron bar, for working the fire-clay cylinder. L, support, with a roller across, on which the bar K is supported. M, hole, with a stopper, through which the coal is thrown. N, hole, with a stopper, through which the grate is cleared. 0, hood of sheet-iron, under which the chimneys terminate. a a, grate of the furnace. b, throat of the crucible. c, level of the melted glass. d, fire-clay cylinder for stirring. e, opening. ff, bars supporting the grate. g, door of the opening e. GLUE, is prepared from the clippings of hides, hoofs, &c. These are first washed in lime-water, and afterwards boiled and skimmed; the solution is then strained through baskets, and gently evaporated to a due consistency; then cooled in wooden moulds, cut into slices and dried upon nets. Good glue is semi-transparent, deep brown, and free from spots and clouds. When used it should be broken in pieces, and steeped for twenty-four hours in cold water, by which it softens and swells; the soaked pieces are then melted over a gentle fire, or, what is better, in a water bath, and in that state applied to the wood by a stiff brush. Glue will not harden in a freezing temperature, the stiffening depending upon the evaporation of its superfluous water. The chemical properties of glue are those of an impure gelatine. The only machinery used in the manufacture are the three coppers, upon different levels, in which the skins, &c., are boiled. The uppermost copper, being acted upon by the waste heat of the chimney, provides warm water in the most economical way; the second contains the crude materials, with water for dissolving them; and the third receives the solution to be settled. The last vessel is double, with water contained between the outer and inner one, and discharges its contents by a stop-cock. The last- made solution has about one five-hundredth part of alum, in powder, usually added to it, with proper agitation, after which it is left to settle for several hours. GLYPHOGRAPHY, recently invented, is an electrotype process, enabling the artist to become the engraver of his own work. The manipulation is thus minutely described by the inventor, Palmer: A piece of ordinary copper-plate, such as is used for engraving, is stained black on one side, over which is spread a very thin layer of a white opaque composition, resembling white wax both in its nature and appearance: this done, the plate is ready for use. In order to draw properly on these plates, various sorts of points are used, which remove, wherever they are passed, a portion of the white composition, whereby the blackened surface of the plate is ex- posed, forming a striking contrast with the surrounding white ground, so that the artist sees his effect at ouce. The drawing, being thus completed, is put into the hands of one who inspects it very carefully and minutely, to see that no part of the work has been damaged or filled in with dirt or dust; from thence it passes into a third person's hands, by whom it is brought in contact with a substance Laving a chem- ical attraction or affinity for the remaining portions of the composition thereon, whereby they are heightened ad libitum. Thus, by a careful manipulation, the lights of the drawing become thickened all over the plate equally, and the main difficulty is at once overcome; a little more, however, remains to be done. The depth of these non-printing parts of the block must be in some degree proportionate to their width; consequently, the larger breadths of lights require to be thickened on the plate to a much greater extent, in order to produce this depth. This part of the process is purely mechanical, and easily accomplished. It is indispensably necessary that the printing surfaces of a block prepared for the press should project in such relief from the block itself as shall prevent the probability of the inking-roller touching the interstices of the same whilst passing over them. This is accomplished in wood engraving by cutting out these intervening parts, which form the lights of the print, to a sufficient depth; but in glyphography the depth of these parts is formed by the remaining portions of the white composition on the plate, analogous to the thickness or height of which must be the depth on the block, seeing that the latter is in fact (to simplify the matter) a cast, or reverse, of the former. But if this composition were spread on the plate as thickly as required for this purpose, it would be impossible for the artist to put either close, fine, or free work thereon; consequently the thinnest possible coating is put on the plate previously to the drawing being made, and the required thickness obtained ultimately as described. The plate thus prepared is again carefully inspected through a powerful lens, and closely scrutinized, to see that it is ready for the next stage of the process, which is, to place it in a trough, and submit it to the action of a galvanic battery, by means of which copper is deposited into the indentations thereof, and, continuing to fill them up, it gradually spreads itself all over the surface of the composition, until a sufficiently thick plate of copper is obtained, which, on being separated, will be found to be a perfect cast of the drawing which formed the clichée. Lastly, the metallic plate thus produced is soldered to another piece of metal to strengthen it, and then mounted on A piece of wood to bring it to the height of the printer's type. This completes the process and the phographic block is now ready for the presa. Digitized by Google 886 GOLD. It should, however, have been stated previously, that if any parts of the block require to be lowered, st is done with the greatest facility in the process of mounting. One manifest advantage which glyphography has over etching and wood engraving is, that the artist makes his drawing as he intends it to appear. No reversing is necessary the work during the progress of drawing is as immediately conspicuous as if it were done upon paper with a black-lead pencil. Com- pared with wood engraving, with which it comes into direct competition, it seems susceptible of more delicacy, and is not more expensive than wood engraving of approximate quality. GOLD. (Syn. Anglo-Sax, gold: Dutch, goud: Germ., gold: Goth., gulths: Icel, gull: Dan. and Swed., guld: Tart., goltz Pol., zloto Gr., chrysos: Lat,, aurum: Ital., Span., Port., oro: Fr., or Welch, aur: Pers., zuraljin Hind., sonnau: Arab., dahaba: Heb, Chald., Sum, zahav.) In its native state, this metal has never been found pure, but always alloyed with silver; and it frequently contains copper in addition. The proportion of silver is, from less than one per cent. up to an amount that ren- ders it, more properly, an ore of silver. Copper, when present, is usually in very small quantity. Pure gold is unalterable by atmospheric agents, and consequently, preserves its beauty and lustre indefinitely. This fact, taken in connection with the facility of working the native metal, must have attracted the notice of man at a very early period. As a consequence, we find it spoken of in the most remote rec- ords of history. Physical properties.-Pure gold has considerable lustre; less, however, than steel, silver, mercury, or platinum, but more than copper, tin, and lead. In masses, it has a bright yellow color, very slightly tinged with red; but when beaten into leaves exceedingly thin, it becomes translucent, and assumes R greenish tint. It was suggested by Vauquelin that its true color is blue, and that the appearance of green is due to a mixture of yellow rays, reflected from the thin leaf of gold. Buisson cites many ex- periments to prove that when reduced to an impalpable powder, by electricity or otherwise, the color of gold is purple. It seems, therefore, that savans have not yet been able to agree as to what is the true color of this long-known substance. Pure gold is softer than silver, and possesses malleability and ductility in a greater degree than any other. metal. It may be beaten into leaves so thin as to require 251,154 folds to make one inch in thickness. The coating of gold upon ordinary gold lace is yet thinner; because in making it, a small cylinder of silver is covered with 1-48th its weight of gold, and drawn into wire, which is rolled until 11.8 feet in length weigh but one grain. Reaumur covered a cylinder of silver with 1-360 its weight of gold. It was drawn into a wire of which 6 feet weighed one grain; and then rolled to a width of 1-48th of an inch, which increased its length to 7.5 feet; and yet the silver was so completely covered that the microscope failed to detect the least appearance of it. The tenacity of gold is less than that of platinum, copper, and iron. A weight of 1733 lbs. is suffi- cient to break a wire whose diameter is 0-0784 inch, or nearly 1-13th of an inch. Its tenacity is les- sened by hammering; but its stiffness and elasticity are increased. The tenacity may be restored by exposing the metal to sufficient heat. A temperature barely enough for fusion renders it brittle; it must be more strongly heated to recover its ductility entirely. It also becomes brittle when suddenly cooled. It expands upon being heated more than silver and copper, and less than iron and mercury. Whilst passing from the liquid to the solid state, it contracts more than any other metal. A volume which is 1. at a temperature of 32° F., becomes 100146 at 212° F. According to Berthier, the specific gravity of gold after melting, is 19-258, which is increased to 19367, if the metal has been much hammered. Berzelius gives 19:40 to 19-65, and other experi- menters obtained results between these extremes. We are disposed to adopt 193 for melted gold, and from that to 19:65 for hammered gold, according to the amount of compression. Its atomic weight is 1243'013, oxygen being unity, and 1992 in a system where hydrogen is taken as unity. It conducts heat more rapidly than any other metal, and is a better conductor of electricity than any other, except copper. Chemical properties and compounds.-The chemical symbol of this metal is Au. When it is heated to about 2016° F., it enters into fusion; and when completely liquid, assumes a bluish green color. It cannot be volatilized at the temperature of our hottest furnaces but when ex- posed to the compound blowpipe, it is converted into vapor, which will gild a silver plate held above it. It may be also volatilized by the sun's rays, in the focus of a very powerful burning lens. In very fine powder, it becomes incandescent, at the temperature of 122° F. Gold does not oxidate at ordinary temperatures, nor in the hottest furnaces; but a slight oxidation takes place when exposed in thin leaves to the lens, burning mirror, compound blowpipe, or a galvanic battery of ample heating power. In a vacuum, the electric spark divides it into a very minute powder. Few of the acids act on gold singly. Nitric acid, when concentrated and boiling, exerts a feeble though sensible action. Nitrous acid also attacks it. Sulphuric acid, even if highly concentrated and boiling, produces no effect whatever. Selenic acid dissolves gold, and is converted into selenious acid. It was observed by Proust, that when in an extremely minute state of division, gold was dissolved in very small proportion, by concentrated and boiling nitric acid. Mixtures of nitric acid with hydrochloric, hydrobromic, hydriodic, and some other acids, dissolve it readily, and form chlorides, bromides, and iodides of gold. It may also be dissolved, and a chloride formed, by treating it with a mixture of 4 parts nitric acid and 1 part sal ammoniac, or any other alkaline hydrochlorate. The same result may be attained by using hydrochloric acid, mixed with any nitrate whatever. Alkaline solutions have no action upon gold; but in the dry way, and at a high temperature, (though insufficient for fusion,) it has been shown by Buchner that divers oxygenated substances give out their oxygen to gold, or determine its absorption from the atmospheric air. Digitized by Google GOLD. 887- Tenant has proved that when nitrate of potash is heated with finely divided gold, the latter is sensi- bly attacked and a combination of oxide of gold and potash is formed-a circumstance that should be borne in mind by artists who purify their gold filings by this means. The gold which combines with the alkali, may be recovered again by treating the alkaline mass with water; when the whole of the gold will be precipitated in a fine powder. With borax, at a red heat, the color of the surface of gold is rendered lighter, but the ordinary color is restored again by heating it to redness, with either nitrate of potash or common salt. This was known to the ancients. Exposed to heat whilst covered with charcoal in powder, the surface assumes a beautiful shade of yellow; but whether by the formation of a carburet, has not yet been determined. Sulphur and selenium do not act on gold at any temperature, nor does the vapor of hydrosulphuric acid; but the alkaline persulphurets readily form sulphurets with gold, both in the humid and dry way. Phosphorus and arsenic, aided by heat, combine directly with it. Gaseous and liquid chlorine also act upon it, and the latter dissolves it readily. Iodine has no perceptible effect, further than to tarnish the surface. Hydriodic acid dissolves it. Oxides.-The affinity of gold for oxygen is less than that of any metal. They combine in two pro- portions, constituting the protoxide and peroxide of gold; and there is some reason to believe, with Berzelius, in the existence of an intermediate oxide of a purple color, containing twice the amount of oxygen of the protoxide. Protoxide of gold is obtained by mixing a cold solution of caustic potash with protochloride of gold. It has a deep green color, and soon decomposes spontaneously into metallic gold and its peroxide; which also occurs upon the application of acids, with which the protoxide never forms salts. It consists of gold 96.13 Oxygen 3.87 Peroxide of gold may be formed in several ways; but the best mode, according to Pelletier, is to heat magnesia or oxide of zinc in slight excess, with a solution of perchloride of gold, and wash the residuary matter with nitric acid. If concentrated acid be used, we have the anhydrous peroxide; but with diluted acid, the hydrated peroxide is produced. This peroxide has a styptic, metallic taste, re- tains its oxygen very feebly, and forms salts only with concentrated nitric, sulphuric, and acetic acids. The addition of water to these solutions precipitates the gold, either as an oxide or in the metallic state. Peroxide of gold combines with vitreous substances in fusion, and communicates the beautiful yellow color 80 much admired in artificial gems and stained or colored glasses. Although the term peroxide of gold is usually applied, we might perhaps more properly rank it with the acids, and designate it by the term auric acid. It does not form stable compounds with other acids, but, like them, combines with metallic oxides, forming a class of salts called aurates. The solu- tions of these are usually colorless, or nearly so; but may be tinged yellow by the addition of other acids. The oxygenated acids produce precipitates of hydrate or peroxide of gold, having a violet color more or less deep, or even black, according to the strength of the solutions. The aurates of soda, potash, and baryta, are very soluble in water: the solutions are colorless, and have an alkaline reaction. The aurate of magnesia is slightly soluble in water, but more so if chloride of magnesium be present. When solid it is easily decomposed by nitric acid, which produces very pure peroxide of gold, or its hydrate, according to the strength of the acid. The purple powder of cassius, so much used to produce a fine purple color in artificial gems, enamels, and glass, is sometimes classed with the aurates, although it probably does not contain auric acid. Chemists are not agreed in regard to the precise nature of this valuable compound of gold, but our limits do not permit the discussion of the question here. There are several different processes by which it can be prepared; and it varies in its tints accord- ing to the method adopted. Buisson gives the following as the best to produce a beautiful purple color :-(a) Dissolve 1 part granulated tin in hydrochloric acid, avoiding an excess of the latter. (b) Dissolve 2 parts tin in a mix- ture of 3 parts nitric and 1 part hydrochloric acid; taking care, ns before, that the solution be exactly neutral. (c) Make a neutral solution of 7 parts gold in a mixture of 1 part nitric and 6 parts hydro- chloric acid. Dilute the last solution with a large quantity of water, and mix it with the deutochloride of tin (b), and then add the solution of protochloride (a), drop by drop, until the precipitate shall assume the desired purple color. An excess of the protochloride (a) changes the color of the powder to brown, and an excess of the deutochloride (b) gives it a violet tint. As soon as the desired color is attained, the liquid should be decanted, and the precipitate washed to prevent further change in its color. It retains water when heated to 212° F. Its composition, according to Buisson, is, Gold 28.5 Deutoxide of tin 65.9 Chlorine 5.2 The chlorine in this specimen might all have been removed if it had been sufficiently washed. Berzelius analyzed a specimen of a fine purple; which contained, Gold 28.35 Deutoxide of tin 64.00 Water 7.65 Digitized by Google 888 GOLD. Oberkampt found two specimens to consist of, Clear purple. Violet color. Gold 795 398 Oxide of tin 20.5 60.2 These results show wide differences in composition. It gives a beautiful purple color to glass, which sometimes disappears by fusion, but reappears in a smoky flame. Besides this, several other colors are produced in glass by mixtures with the purple powder. With oxide of silver we have a deep crimson, and with oxide of antimony a deep brown. Other compounds, giving a purple color to fused glass, may be formed by mixing solutions of chloride of gold with protonitrate of tin, chloride of antimony, or of bismuth, or even protosulphate of iron. Sulphurets of gold-There are two sulphurets, both of which are reduced to the metallic state, at a low red-heat. The protosulphuret is dark brown. or nearly black; and is obtained by passing sulphuretted hydro- gen gas through a hot solution of chloride of gold. It consists of Gold 92.51 Sulphur 749 The deutosulphuret has at first a dark yellow color, which becomes brown when dried. It is pre- pared by passing sulphuretted hydrogen gas into a cold solution of chloride of gold, and consists of, Gold 8047 Sulphur 1953 Phosphuret of gold is prepared by passing an excess of phosphuretted hydrogen gas into a solution of gold. At first the metal is precipitated, which at length combines with the phosphorus. The com- pound is black, without metallic lustre. It is more fusible than metallic gold itself; and, after being melted, becomes of a grayish white color, crystalline and brittle with a granular fracture. Fulminating gold-There are two different kinds of this compound, both of which were supposed to be aurates of ammonia; but Dumas has shown that nitrogen also exists in them. The first has a dark gray color, and is prepared by digesting a solution of chloride of gold with am- monia, and carefully drying the precipitate 80 as to lessen the danger of explosion. At a little above 212° F. it explodes with great violence from a slight blow, or from friction. It consists of Gold 7760 Nitrogen 5.56 Ammonia 6.65 Water 11.25 The second species is of a deep yellow color, and is made by digesting the chloride of gold in a alight excess of ammonia, and drying as before. At the temperature of 212° F, when suddenly heated, it detonates most violently; but after having been very slowly heated to 266°, the temperature may be raised to 300°, and even 320°, before it will explode. Great caution is requisite on the part of those who prepare or handle these and other fulminating compounds, and the many terrible accidents which have occurred, should warn all but experienced manipulators from meddling with them in any manner. Chlorides.Gold combines in two proportions with chlorine. Protochloride of gold is prepared by cautiously evaporating a solution of the perchloride to dryness on a sand bath, and heating the residue at the temperature of melting tin (frequently stirring with a glass rod) until it ceases to give off chlorine. It forms a white saline mass, slightly tinged with yellow. It is insoluble in, nor does it color cold water, if free from perchloride. It is little subject to decompo- sition at ordinary temperatures, if secluded from the light and kept dry; but both light and heat de- compose it into perchloride and metallic gold; and boiling water very promptly does the same. It consists of Gold 91.51 Chlorine 8-49 Perchloride of gold may be obtained by dissolving pure gold in thin leaves or fine powder, in a mix- ture of 1 part (by measure) pure nitric acid with 4 parts pure hydrochloric acid, and cautiously evap- orating the excess of acid. It is soluble in water, and the solution is yellow; but becomes pale if there be an excess of acid. It is decomposed by degrees, if exposed to light; and, at a red-heat, the chlorine is driven off, leaving the gold. It consists of Gold 6518 Chlorine 3482 Metallic gold is precipitated from its solution by phosphorus, and most of the metals and the salts of iron. The salts of tin in solution produce purple precipitate. If gold be precipitated by means of a solution of caustic potash in alcohol, we obtain it in an extremely minute state of division, suited for painting, for gold inks, and other purposes. The solution of this perchloride in ether is used for gilding the surfaces of iron and steel; the dura- bility of which is increased by previously immersing the article for one or two minutes in a solution of silver or copper, so as to cover it with a thin pellicle of either of these metals. The gilded surface must then be well burnished. Digitized by Google GOLD. 889 Perchloride of gold unites with most of the metals to form compounds called double chlorides, which our limits will not permit us to notice. Bromide of gold, when dried, has a blackish color, without metallic lustre. It dissolves readily in water, and gives to it a deep red color; which is also that of the crystals produced from the solution. It consists of Gold 468 Bromine 532 Iodide of gold is insoluble in cold water, and slightly soluble at 212° F. It has a greenish yellow color, and consists of Gold 34.5 Iodine 65.5 Alloys of gold-When 12 parts manganese and 88 parts gold are melted together, an alloy is pro- duced, having a pale yellowish gray color, with considerable lustre and hardness, and little ductility. Its fracture is granular and spongy. It is less easily fusible than gold, and the manganese may be completely separated by roasting. Iron and gold have a strong affinity for each other, and the latter may be united in all proportions with steel or cast-iron. Gold may be used for soldering iron. An alloy with 8 per cent. of iron is of a pale yellowish gray color, very ductile and tenacious, and harder than gold. With from 15 to 20 per cent. of iron, the alloy is gray, and will take a very beautiful polish. It is used in jewelry under the name of gray gold. When 75 to 80 per cent. of iron is alloyed with gold, it has the color of silver, and is so hard as to be applicable to the purposes of cutting instruments. Cobalt readily unites with gold, and forms alloys of a dull yellow color, which are brittle when the proportion of cobalt is 1-60th. Nickel and gold have a brass yellow color, and are also brittle. Copper has a great affinity for gold, and combines in all proportions. It heightens the color of gold, and increases its hardness, whilst its ductility is somewhat impaired. The maximum hardness is at- tained with 1-18th copper. These alloys being more fusible than gold, are used for soldering this metal. The alloy called jewellers' gold should contain at least 746 of gold. In France, according to Ber- thier, it varies from 92 to 25 per cent. In Great Britain, 18 carats or 75 per cent. is the standard for jewellers' gold: although the proportion of this metal is rarely 80 much. In Sweden, it is 76.6 per cent., it being there, as in most parts of Europe, regulated by law. In the United States, the standard of gold is not subjected to any legal provision, except in regard to coin, which must contain 9 parts gold to 1 alloy of which alloy, at least one half must be silver. In Great Britain, the coin consists of 11 parts gold and 1 copper; and in France, 10 parts of gold and 1 part of copper. In order to deepen the color of gold alloyed with silver, artists have a mode of alloying a small por- tion of copper with the surface only, which is done in the following manner: 1 OZ. of yellow wax is melted, and there is added to it a mixture of 2 OZ. calcined alum, 12 OZ. red chalk, 2 OZ. verdigris, and 2 OZ. peroxide of copper, (copper scales.) The four last named must be ground to an impalpable pow- der, completely mixed with the melted wax, and moulded into sticks for use. After the surface of the gold is well rubbed over with these sticks, the article must be exposed to heat sufficient to burn off the wax entirely. It is then burnished, and washed with a liquor composed of one pint of water to 2 OZ. ashes produced by calcining argal or crude tartar, 2 OZ. common salt, and 4 OZ. sulphur. Antimony unites easily with gold, and produces alloys of a color more or less pale, according to the proportions used. They are brittle, and have a dull granular fracture. The presence of a very minute proportion of antimony destroys the ductility of gold. It was from this faculty to render brittle, which antimony exerts over all the other metals, that the earlier chemists gave it the title of regulus, or little king. To its sulphuret was given the name of lupus metallorum, because, in the purification of gold, its feeble affinity allowed it to yield the sulphur to the inferior metals, while itself combined with the gold. The sulphuret is still used for the same purpose. Tin forms with gold compounds more fusible than the latter; they are ductile when cold, but crum- ble at a red heat, if the proportion of tin be as much as 1-37th. With 1-12th tin the alloy is of a pale yellow color, but slightly ductile, and has an earthy fracture. Zinc, in small proportion, renders gold brittle; even its vapors sensibly produce this effect on gold in fusion. With 1.10th zinc the alloy is very brittle. and has the color of brass. With t zinc it is white, very hard, and takes a high polish. Hellat asserts that an alloy of seven parts zinc and one part of gold is entirely volatilized in a furnace. Bismuth forms with gold brittle alloys of a brassy color. The vapor of bismuth is also sufficient to diminish the ductility of gold. Lead forms alloys with gold which are brittle in every proportion. It requires but one part of lead in 500,000 of gold to alter sensibly its ductility. An alloy consisting of one part lead and twelve parts gold is extremely brittle, and has a dull granular fracture similar to that of porcelain. Silver and gold may be united by rapid fusion in all proportions; but if the fused mass be very slowly cooled, part of the silver, in combination with a small proportion of gold, separates and floats upon the surface, leaving beneath an alloy of five parts gold and one part silver. The alloys of these metals are more fusible than gold, and have 9 greenish tinge even 5 per cent. of silver produces a decided change of color. The proportions used for the green gold of the jewellers are 708 of gold, and 29.2 of silver. These alloys are very ductile, and are harder, more elastic, and more sonorous than either of the metals themselves. The maximum bardness is attained when the proportion of silver is one-third. Platinum may be united with gold in all proportions; but to produce an alloy completely homo- geneous, it should be exposed to a very high temperature, 80 as to effect a perfect fusion. These alloys 112 Digitized by Google 890 GOLD. are ductile and elastic. When they contain from 7 to 10 per cent. of platinum the color is dull yellow, like tarnished silver. With 1-5th it exactly resembles platinum; with 1-17th platinum it is in appear- ance not distinguishable from gold. Platinum and silver together combine with gold in all proportions, forming double alloys which are ductile, and possess more stiffness and elasticity than alloys of gold and silver only. Platinum is sometimes introduced into an alloy of silver, gold, and copper, called doré, and it is not easy to detect the fraud. Palladium and gold form alloys with less ductility than that of the pure metals. They have a gran- ular structure, and vary in color from white to gray. With equal parts it is nearly white, and a very small proportion lessens the color of gold. Rhodium and gold form alloys, according to Del Rio, which are brittle, unless the proportion of the former be very small, when it hardens the gold without impairing its ductility. With 1-7th rhodium the color is unaltered-a striking difference between its effects and those of platinum and palladium upon gold. Iridium, in being alloyed with gold, but slightly affects its color, and produces ductile alloys. Osmium also forms ductile alloys with gold. Arseniurets of gold (as alloys of arsenic with gold are termed) may be formed by exposing heated gold to the vapor of arsenic. The gold absorbs a very small proportion, but retains it with so strong an affinity that it cannot be entirely separated even at a very high temperature. This alloy is brittle. Tellurium may be combined with gold artificially, by treating the latter in solution with telluretted hydrogen gas. The native combinations of these metals found in Transylvania will be noticed among the ores of gold. Mercury and gold form alloys called amalgams. They may be formed by immersing or agitating gold in mercury, which dissolves it even at common temperatures; but the combination is hastened by heat. An alloy saturated with gold and compressed in chamois skin is white, and at first soft, but soon becomes solid. It crystallizes in four-sided prisms, and contains two parts of gold and one of mercury. When sufficiently soft to be kneaded between the fingers, it contains SIX or seven parts mercury and one of gold. Amalgams are used in gilding, (q. v.) Mineralogical Occurrence of Gold. 1. Native metallic gold. 2. Gold containing rhodium. 3. Gold with silver and tellurium. 4. Gold with silver, tellurium, and lead. 5. The same as the last, with the addition of antimony. 6. Gold in iron and copper pyrites and Galena, usually in very small proportion. 1. Native metallic gold.-It is in this state that nearly all the gold obtained by man is found; but, as has been already stated, never entirely apart from other metals. It varies in color from gold yellow to brass yellow, grayish and greenish yellow, depending upon the nature and proportion of the metals with which it is alloyed. It occurs in grains, scales, threads, and plates, and also in masses from a few grains in weight to several ounces; and in a few rare instances lumps have been found weighing many pounds. It also occurs in small crystals having the form of the cube, or its derivatives. Its specific gravity varies according to the proportion of other metals with which it is alloyed, and is much less than would be calculated from that of the pure metals. Boussingault and others have endeavored to show that the silver contained in native gold is united in definite proportions. We think, however, this view is altogether untenable, in the face of the fact that the numerous analyses which have been made show that the silver in native gold exists in all propor- tions, from less than one per cent. and upwards, until it constitutes more than half the weight of the native alloy. The following table gives the composition of specimens from the principal gold regions now worked in various parts of the world. SPECIFIC LOCALITY. GOLD. SILVER. ANALYST. GRAVITY. 1 Schabrowski, Siberia (copper 35) 98.96 0.16 Rose. 2 Saxony 9690 2:00 Lampadius. 8 Upper California 9570 not stated. U.S. Mint. 4 Scharlausch, Siberia * 95.00 480 Rose. 5 Boruschka, " * 94.40 480 17060 " 6 Brazil (0:15 platinum) 9400 5.85 D'Arcet. 7 Bellembugeush, Siberia 93.50 6:40 Rose. 8 Peros Pawlosk, " 92.60 7.10 " 9 Upper California 92.10 not stated. U.S. Mint. 10 Kuslinski, Siberia 9190 800 Rose. 11 Ufaley, " 9140 8.50 " 12 Upper California 92:10 not stated. U. S. Mint. 13 " " loss in melting 0.38 9070 880 Rivot, Paris. 14 " " 9050 880 U.S. Mint. 15 Kurchwa, Siberia 9030 960 Rose. 16 Czarwo Nuolajewesk, Siberia 8940 10:00 17480 a Digitized by Google GOLD. 891 SPECIFIC LOCALITY. GOLD. SILVER. ANALYST. GRAVITY. 17 Besolk, Siberia 8870 11:30 Rose. 18 Malposo, New Grenada 88.58 11.42 Boussingault. 19 Upper California 8850 not stated. U.S. Mint. 20 Llano, New Grenada 88.24 1176 14706 Boussingault. 21 Baja, " 8815 11.85 " 22 Rio Sucio, " 87.94 12-06 14690 " 23 Upper California 8750 not stated. U.S. Mint. 24 Gasuschka, Siberia 87.30 12:30 Rose. 25 Petro Powlowsk 86.50 18:20 16870 " 26 Burburu, Transylvania 8510 1470 Boussingault. 27 Ojas, New Grenada 8450 15.50 " 28 Boruschka, Siberia 88.90 16.10 17060 Rose. 29 Trinidad, New Grenada 8240 1760 Boussingault. 30 Upper California 81.20 not stated. U. S. Mint. 31 African gold dust (11.80 copper) 78.00 948 Thomson. 34 Titisibi, New Grenada 74.00 26.00 Boussingault. 35 Guano, " 73.68 2632 " Marmato, " in cubic and octahedral 36 73.45 26.55 12666 " crystals in a vein of pyrites in syenite 37 Otromma, N. Grenada, in octahedral crystals 73.40 26.60 " 38 Santa Rosa, " 6493 3507 14149 " 39 Transylvania, in cubic crystals 64.52 35.48 " 40 Schlangenberg, Siberia 5400 36.00 Klaproth. 41 " " 28.00 72.00 Fortia. Those marked (*) contained traces of copper. No. 41, containing 72 per cent. of silver, would be classed more properly with native silver. So far as is yet known the gold from California is alloyed with silver only; the oxide of iron, separ- ated in melting, exists in the minute cavities and fissures in the scales, and adheres to the surface only. The average loss in melting is stated to be about 21 per cent., which, as the assays were made from the melted metal, would somewhat reduce the per centage of gold. Although obtained over a large extent of country, the California gold from the western slope of the Sierra Nevada has more uniformity in its composition than that of other gold regions, from which a sufficient number of specimens have been analyzed to enable us to form an opinion. This will appear from the following table giving the maximum and minimum proportions, which have been found to exist in some of the most important localities. Maximum. Minimum. California 9570 81:20 Siberia 98.96 28.00 South America, (New Grenada, &c.) 8858 6493 One specimen from Siberia contained nearly 99 per cent. of gold, and 3 per cent. of silver and copper, Deing the purest native gold yet known. The gold of the western slope of the Andes contains more alloy than that of Siberia or California. Of the other regions the analyses reported hitherto consist generally of a single specimen, or of 80 few that no deduction can be made from them. An opinion seems to have prevailed in California, that the gold from the affluents of Feather river was purer than that from the districts further south, but the assays at the United States Mint do not confirm this opinion; on the contrary, they show that the average rate of purity seems about equal throughout the region. The usual range after melting is from 87.5 to 90.5 per cent. of pure gold. The general average is between 88.5 and 89. per cent. If, therefore, the value of the silver be added, it would appear that the average value of the gold from California differs little from the standard for the gold coin of the United States. 3, 4, and 5. Telluric ores of gold-In the metalliferous districts of Transylvania a considerable amount of gold is obtained from ores consisting of combinations of tellurium with several other metals. The following indicates the composition of the most important of these: Sp. gravity. Gold. Silver. Copper. Antimony. Lead. Sulphur. Tellurium. Observer. 1 5-723 30-00 10:00 60 Klaproth. 2 10678 2675 8.50 1950 0.50 4475 " 3 8-918 900 0.50 1:30 5400 3. 32.20 " 4 750 1. 46'00 2.50 26:40 Brandes. 5 6840 670 180 4'50 6310 1170 13. Berthier. The first variety crystallizes in small rhomboidal prisms. It is soft, with an irregular fracture, and of the color of steel. Digitized by Google 892 GOLD. The second is white, tinged with yellow. In some cases it is in lamellæ, but appears granular in others, and crystallizes in four-sided rectangular prisms and in small lamellæ. The third has a deep leaden-gray color, approaching that of specular oxide of iron, with a very shining lustre. It is soft, slightly flexible, has a lamellated structure, and crystallizes in hexagonal plates slightly elongated. The fourth closely resembles in appearance the third, from which it differs little in composition. Although the fifth differed little in external appearance from the two last, it will be observed that in the relative proportions of its constituents there is a considerable variation. 6. Gold in iron and copper pyrites, and in galena.-The native sulphuret of iron 80 generally con- tains traces of gold as to occasion the remark by Gahn, that it was rare to meet with a specimen of this mineral from which gold was entirely absent. The same may also be said, in a great measure, of the native sulphurets of copper and iron, or copper pyrites, and the sulphuret of lead, or galena, although it is probable that it does not 80 uniformly apply to the two latter, and especially the last. Geological distribution of gold, and its localities.With the exception of iron, (and possibly copper,) it may safely be asserted that the geological districts within which gold occurs embrace a larger aggre- gate area than those of any other metal. And yet the proportion of gold to that of the substances from which it must be separated for the use of mankind is 80 extremely minute, that the cost of eliminating it must necessarily be such as to maintain a very high commercial value for this metal in all future times. Native gold occurs in veins which intersect hypogene or igneous, as well as metamorphic rocks; but the veins in the former have hitherto almost always proved too poor in metal to be worked with profit, unless in connection with other metals. Among the metamorphic rocks, especially in talcose alates, we find the auriferous veins most numerous as well as most productive. And although the veins in porphyries, trap, and other hypogene rocks, usually are much less rich in metal than the slates, yet the veins in these are little productive, or do not contain gold at all, where these rocks occupy extensive areas without intrusive rocks forced up be- tween or around them. These conclusions are sustained by the fact of this being the geological structure of all the districts in the world known to contain gold, under circumstances that permit it to be extensively availed of for the uses of mankind. The gold-bearing veins usually consist of quartz. of a texture so firm and hard as to require a large expenditure in mining it, compared with the value of the metal obtained; more especially when it is worked to considerable depths below the surface, where atmospheric agents have not impaired the solidity and firmness of the vein-stone. These, like all true veins, are generally inclined at a considerable angle from the plane of the horizon, and are often vertical, or nearly so. In thickness they vary considerably: the same vein is sometimes contracted to a width of an inch or less, whilst at other points it is expanded in thickness to many yards. They extend downwards to greater depths than the miner has ever reached. The gold occurs sometimes disseminated throughout portions of the vein in minute scales, often 80 small as to be invisible to the naked eye; then again it is found in scales, plates, or amorphous masses, varying in size from the smallest visible dimensions to those having considerable weight. These are sometimes irregularly distributed throughout the vein-stone, but most commonly extend within parts of the vein, or upon its sides. Small crystals of gold also occur in the cavities of the vein-stone. Iron pyrites usually accompanies native gold, and sometimes also copper pyrites, both containing some gold disseminated within them, and not chemically combined. By far the larger proportion of gold hitherto has been procured from the deposits of diluvium and alluvium, in the valleys and ravines which have been formed in those regions where metallic veins existed prior to the formation of such valleys and ravines. The gold in these transported deposits (or drift, as they may be termed) formerly existed in those portions of the veins destroyed by the operations of nature producing these denudations, and which often result in the formation of glens, ravines, and narrow valleys. This destruction and re-formation are incessantly going on; but during the present geological period with less energy than in that earlier era called the drift period by geologists. Now, as then, carbonic acid and oxygen, aided by heat and water, are the chief agents by which the rocks and stony matters are disintegrated. The currents of water in hilly and mountainous districts have usually considerable rates of descent, 80 as readily to float off the more finely-divided portions in sand and mud, as well as to remove the larger gravel and boulders. The only substances possessing specific gravities too great to be moved far from whence they were liberated, are the heavier metals and some of their oxides. The weight of gold is such that it is rarely transported far from the veins. It is true, that when in minute scales or powder, part of it is carried off during floods, by adhering to the passing sands, but it is rarely deposited in available quantities, except in close proximity to the veins in which it existed. Notwithstanding the apparently large quantity of gold hitherto procured in the drift matters, from the most remote periods, we may safely assume that it bears an infinitely small proportion to what yet remains imprisoned within the rocks at no greater distance from the surface than has already been reached by the industrious miner in other researches. The small amount of space occupied by the ravines and valleys of excavation in metalliferous regions, compared with that remaining below and between them, clearly proves the correctness of this opinion. But those who found hopes of wealth upon gold mining should not, because of the existence of these vast stores, suppose that the mining of them must of course be advantageous; on the contrary, the sad experience of the world has almost always shown exactly the reverse. The principal cause of this result is the enormous cost of blasting and removing the hard, intractable vein-stone which, in most instances, embraces the gold, and this, too, in narrow, confined places under ground. Even after this is brought out of the mine there arc additional expenses of large amount Digitized by Google GOLD. 893 incurred in machinery, labor, and materials for reducing it to powder, and separating the gold with the aid of mercury. When the mine is pursued to a considerable distance below the surface, there is a heavy additional expense incurred in keeping it free from water, as well as in bringing up the mined materials. After all this is done the miner finds, in most cases, the proportion of gold is too small to pay the expenses; and yet the allurements of gold mining are such as often to cause the parties to persist until they are ruined, whilst they are each day expecting a brilliant result. At the present time a few veins are said to be worked in Virginia, and other parts of the gold region of our Atlantic slope, with reasonable profit. In Peru and Chili gold is rarely obtained in this manner; indeed, the unproductiveness of the aurif- erous veins in that region has given rise to a common saying there, that to work a gold mine is certain ruin;" and they add, a silver mine is altogether uncertain, whilst a copper mine is certain gain." In Siberia the veins are rarely worked with advantage, and almost the whole amount of gold ob- tained in that country is procured from the drift. Nature, in the latter case, does the mining, leaving it for man to separate the metal mixed with and covered by the sedimentary matters. As these deposits are of moderate thickness, they are liable to be soon exhausted of their gold when extensively worked. This has frequently occurred where the proportion of metal was enough to pay the cost of working, as in Europe, in Asia, (except Siberia,) and in most parts of South America, Mexico, and the Atlantic slope of the United States. It is but a short time since the Siberian gold attracted attention, and being very extensively deposited, it still continues productive. Gold has been collected upon the western slope of the coast range of mountains in Upper California for more than 40 years; but previous to the spring of 1848 it was not known to exist upon the Sierra Nevada. The numerous false representations and romances, published in reference to the gold of that region, and to the facility of gathering it, brings to mind the excitement that was produced more than three hundred years ago by the abundance of gold which Pizarro and his fellow-brigands obtained in their marauding expedition to Peru, by robbing the unoffending natives. From all the knowledge we can gather at this day, it would appear that the narrow and deep ravines in Upper Peru must have been rich in gold, and yet all worth working out, which had not been collected by the natives, was soon exhausted by their conquerors, who made slaves of the conquered, and compelled them to dig and wash for the metal. Much of it had been collected and was in possession of the Incas and their subjects, as may be inferred from the statement of the quantity offered as a ransom by the ill-used captive Inca, Atalhuapa; which was to fill with gold the room in which he was confined to a mark on the wall as high as a man could reach. In a very short time his part of the contract was nearly completed, when his cruel captors divided the spoils and put the Inca to death. When melted up the amount was found to be equal in effective value to about nine millions of our dollars. With all this apparent abundance of gold at the time of the conquest, the supplies im- ported into Spain soon dwindled; and but for the discovery of certain veins extremely rich in silver, the importance of Peru in reference to the precious metals would have declined at a much more rapid rate than actually happened. Pieces of gold weighing more than a few ounces have rarely been met with in nature, yet some of considerable size have been recorded. The largest piece hitherto known was found in the drift near La Pas, in Peru, in the year 1730, and weighed a little more than 59 lbs. Troy. It was not uniform in composition, and the different parts varied in the proportion of gold from 75 to 95.8 per cent. Next in size was found in Sonora, Mexico, a lump weighing 486 lbs. In Siberia, according to Humboldt, pieces have been found also of large size; the largest weighed 27 lbs., and is in the Imperial Museum. Others were found weighing as follows: 26-25 lbs., 16.64 lbs., 20 lbs, 1425 lbs., and 11 lbs. Troy. One piece weighing 28 lbs. was found in 1828 at Reid's mines, Cabarras county, North Carolina, and another also weighing 13 lbs. It was often asserted in newspapers during the year 1849 that large masses of gold had been picked up in California; 28 pound lumps were often reported, probably because one of that weight had been found elsewhere, but no well-authenticated weight had been found as late as October. 1849, exceeding 81 OZ., or 6.75 lbs. Troy. More recently the newspapers in New York state the receipt of a lump in this city, weighing 18 lbs. The largest yet received at the mint of the United States is the one above noticed, weighing 675 lbs. The similarity in geological structure of the chief gold regions is such that we may with reasonable certainty expect its occurrence wherever this structure exists; or, in other words, wherever there are extensive formations of talcose slates, accompanied to a greater or less extent by intrusive rocks. For instance, Tyson, more than twelve years since, announced in the Transactions of the Maryland Academy of Science, that the talcose slates of Maryland would be found to contain gold; and within two years past it has been found in Montgomery county, and may be expected in the other counties to the north- eastward. A few years later, Dana, when with the Exploring Expedition in California and Oregon, noticed that the formations justified the expectation of the existence of gold, as has been since realized. The principal gold region begins on the north, just about the southern limit of Mr. Dana's opportunities of observation, because the party travelled along the Sacramento valley southward of Mount Shasty. It lies upon the western slope of the Sierra Nevada, which is a plain rising from the eastern edge of the Sacramento valley to the summit of the Sierra, with an elevation of about 8000 feet in from 50 to 70 miles. The chief rivers, rising near the summit, form almost torrents, with average rates of descent, of from 100 to 180 feet to the mile. The deep ravines which have been furrowed out by the flowing waters have others opening into them, which have also their affluents 60 numerous that the whole flank is everywhere intersected by glens and ravines, and presents the appearance of being composed through- Digitized by Google 894 GOLD. out of isolated conical peaks, each rising higher upon approaching the summit of the Sierra; above the ordinary height of which there are several very elevated volcanic peaks. This flank from the valley upwards, to no great distance from the summit, is composed of argillite, talcose, chloritix, and hornblende slates, with intrusive masses consisting of trap, porphyry, syenite, serpentine, and other igneous rocks, which have been protruded through the slates in many places. This constitutes the gold region (the main one) of California. The outcrops of veins of quartz are very numerous throughout the district, and many of them, with- out doubt, contain gold; but as late as October, 1849, none had been fully opened, except at one spot on the Maripoosa river, an affluent to the southern part of the San Joaquin. It is from the abundance of the fragments of quartz, which form these outcrops, and which are often spread to a considerable width on each side of the vein, that the popular notion has arisen of a vast superstratum of quartz rock, containing veins of gold, resting upon a substratum of talcose slates," and which has nearly supplanted a former fancy equally incorrect; that of the gold having been scattered over the country by volcanic action." The rapidity with which the slate rocks are disintegrated, from the causes before noticed, and the finely divided state into which they are resolved, causes them to be carried off with great facility by the annual floods even in the present day; but during the greater inundations of the drift periods the scouring out of ravines must have been much more rapidly effected. The result, however, up to the present time, has been to form innumerable ravines, mostly having very steep declivities and of every depth, from those of small size up to that of the north branch of the American river, which has in some places worn its bed down at least 3500 feet below the adjacent highlands. It is very probable that the rocks which once existed in the spaces now constituting the ravines, and which have been broken up and removed to form them, formerly made up at least one-tenth of the whole mass of the metalliferous district, within 1000 feet of the surface of the sloping highlands. The quartz being the principal vein-stone, and resisting the action of atmospheric causes, is little sub- ject to disintegration. It is, however, liable to be separated into fragments, such as are commonly known as flint-stones, and which are found of all sizes in irregular angular fragments on and near the surface of the ground, wherever veins or beds of this stone occur in the rocks beneath. Examples of these are common in most parts of the world, and are familiar to every one in the region between the great tertiary and cretaceous district of the Atlantic slope of the United States, and the eastern limits of the mountains. Whilst the metamorphic rocks are readily crumbled down and washed off by the waters, but few of these fragments of quartz are carried off, other than those that chance to fall into ravines, through which rapid streams of water flow; consequently, they continue to accumulate and extend upon the surface. This great amount of denudation may be considered practically, a natural mining operation upon a most extensive scale. Nature has thus liberated the gold and left it among the drift in the ravines and small valleys. The metal most abounds in the inferior parts of the drift, for the reason that during former periods of greater inundations every thing of greater specific gravity than the heavier metals was driven through and out of these ravines by the force of the waters. As the strength of these floods became less the larger boulders were left, and finally those of smaller size and gravel and sand. It was conjectured by many who have not attended to geological pursuits, that this metal, whose weight is so many times heavier than water, or even stony substances, had been washed from an Eldorado at the summit of the Sierra Nevada; and many a gold-seeker searched as diligently for this fancied spot as did the Spaniards in Peru, who thought 300 years ago it was near the summit of the Andes. The weight of gold is such that whilst its gravitating force lends aid to the waters in forcing it down the steep hill-sides into the ravines, it is amply sufficient to resist all currents which ever prevail along them. This conclusion is fully confirmed by not finding gold, of any moment, in the drift, out of the regions in which the auriferous veins occur, or at a distance from them. Such is the fact on the affluents to the Sacramento and San Joaquin rivers from the Sierra Nevada; corresponding also with what has been observed in every other gold region in the world. It is, however, possible that the pul- verized portions of the metal were carried away to a small extent, adhering to the passing sands, as before said. An impression seems to prevail in this country that the drift in which the gold of California is found is mainly sand, but this is rarely the case in California or elsewhere, except, perhaps, with the minute scales from Africa, called gold-dust, which name is most inappropriately applied by many to the scales and small pieces from California; where the drift of the gold region mainly consists of gravel and coarse sand, filling the interstices between boulders, many of which are of large size. The beds of the ravines are usually very narrow, and the drift resting upon them is from 2 or 3 to 16 feet deep. In some places the bottom of a ravine expands in width, and the lessened velocity of the waters over these during high freshets permits the deposit of sand, but these do not usually contain 80 large a pro- portion of gold as an equal area of the bed of the narrow ravines. The seemingly large amount of gold obtained in some of the ravines in California is to be attributed to many causes, that may be briefly noticed. 1. The main gold region extends along the western flank of the Sierra Nevada a distance exceeding 500 miles, with a mean width of perhaps 35 miles. There is reason to believe that scarcely any ravine of importance within this extent has escaped the probing operations of the gold-seekers. It was, how- ever. chiefly upon the portion between the parallels of 36° and 40°, that the great army of operators spread themselves during the year 1849. The area of this portion of the district is nearly 10,000 square miles. and it is believed that within it the drift has been probed to the bottom almost every where upon the beds of the ravines in search of rich diggings. The gold-digger is very rarely satisfied at any spot, and is almost incessantly changing his location and digging holes in hopes of finding one of the rich Digitized by Google GOLD. 895 spots that are often reported, but rarely found. By this means the best places for working are soon found, and their treasures rapidly exhausted. 2. The existence of the gold was first ascertained in February, 1848; and the official letter of Gov. Mason stated the number working in July of that year amounted to 4000. In the year following an immigration amounting to 100,000 persons took place; and as the larger portion could find no other means of support, they were compelled to occupy themselves at the gold-diggings. It is clear, there- fore, that the operatives in this way within the first two years greatly exceeded the numbers that ever flocked to any other auriferous district before known, in 80 short a period. 3. The gold liberated from the veins by the natural causes before noticed, has readily found its way into the beds of the ravines. Their declivities are usually very steep, and they are narrow, especially those of great length, and through which large bodies of water flow during the seasons of rains and melting snows. The gold that formerly existed in the veins, within the space now occupied by these ravines, has been left under and beside the streams which flow perennially through some of them, and during part of the year through others. It is apparent almost, but might be shown by calculation, that amounts greatly larger than seem to have been procured from the drift of any of these ravines, might have been deposited without there having been a single vein containing a workable proportion of metal A considerable quantity, it is true, has been gathered from some localities, but upon calculating the solid contents of a vein which once extended across any of those enormous ravines, we shall learn how small an average proportion of gold in the vein-stone may leave a large deposit of metal. Take, as one of medium size in that region, a ravine of 1000 feet deep, and whose acclivities are 30°, and we shall find, if we assume the vein to have been only one yard thick, the destroyed portion would equal nearly 200,000 cubic yards, weighing more than 4500 pounds per cubic yard. If it contained, at a mean, gold to the value of one cent only in a pound of the vein-stone, this single vein should have left near it in this one ravine, gold to the value of nine millions of dollars. And yet auriferous veins are very numerous in that region, 80 that gold occurs in the drift of almost every one of the ravines, which everywhere intersect the district. From what has now been said, it is manifest that the circumstances under which the gold in the drift was found in these gorges and ravines, have allowed it to be collected more readily than if it had been mixed with the sedimentary deposits of wide valleys, where the proportion of gold must always be small The sudden occupation of them by a vast crowd of operators might have been expected to pro- duce a large amount in the aggregate; but to the parties themselves it has been far less than they were led to expect, from the many false statements which have been continually published. The results in Peru and Chili, where the gold occurred under circumstances closely resembling those in California, must be expected in the latter country, and within a much shorter period. The present irregular and unartistical mode of operating in California must, in a great measure, soon cease of necessity. But upon a reduction of the price of labor in that country, systematic modes of procuring the gold will be practised by skilful persons, under whose directions these deposits will be worked over again, yielding perhaps more gold than was obtained at first. The mode of calculation we have given demonstrates the absurdity of the statements so widely cir- culated of the existence of vast rock formations of quartz containing gold to the value of $2 50 to $3 00 per pound of the rock," as this vein-stone has been improperly termed. It is quite possible that single specimens may have yielded these proportions, but such isolated instances should not be con sidered as representing an average productiveness of a vein, which cannot be ascertained until after working it to a considerable extent. They vary greatly in their course, so that a vein must either be worked for many years from one point, or in numerous places, before any one can safely or prudently state its average yield. A vein has been opened on the Maripoosa river, an affluent to the San Joaquin, which is said, from good authority, to present better prospects than usual. In Brazil native gold is obtained in moderate amount from a recently formed conglomerate, called there Cascalho, in which diamonds also occur. Chili and Peru have been already referred to. Ecuador and New Grenada contain also portions of the extensive gold region of the Andes. Nearly all the principal mining districts of the world occasionally produce gold in some proportion, (usually very small,) whilst being worked for silver, copper, lead, and other metals. In Hungary and Transylvania a considerable amount is obtained and it is in the latter country that the tellurets of gold occur, which were noticed among the ores of gold. It also exists in connection with silver and copper in many of the mines of Mexico and South America. The mines of Saxony, and of the Hartz mountains, produce a small quantity of this metal. It also occurs as native gold at Wick- low, in Ireland, and in minute proportion in the lead ores of North Wales. Spain was celebrated for its gold mines of former days, but produces a very little at present. Recently a gold region has been discovered in Australia, which is represented in accounts from that country to be promising. In the old-settled countries of Southern Asia and its larger islands, gold was procured in remote ages. They produce very little in the present day. A vein of quartz with gold was mined in France some years, in the valley of Oysans, but finally abandoned, because of its poverty. Gold is occasionally collected in the eastern part of that country, near a few streams. Piedmont contains gold mines, some of which are still worked. Veins containing auriferous sul- phuret of iron are worked at Macuguana, near Monte Rosa. More than 20 years ago quite a gold fever was produced in the United States by the finding of this metal in the northwestern part of Georgia. It was traced in a northeasterly direction into South and North Carolina, and finally through Virginia into Maryland. The ravines being of moderate dimensions, it did not require a long time to exhaust the most productive, and the veins are not extensively worked. Digitized by Google 806 GOLD. The geological structure of this gold region of the Atlantic slope is similar, in great measure, to that of California and other districts producing gold. Talcose slates are the prevailing rocks which, whero they extend into Maryland and Pennsylvania, are less interrupted by intrusive rocks, and as far as appears are less metalliferous than those southwestward. In addition to the large pieces before noticed, that were found in this region, many others of smaller size have also been procured from the sedimentary deposits. At this time it is impossible to form a correct opinion as to which of the two districts contain the richest veins, notwithstanding all that has been said of California, where ravines have been scoured out to an enormous depth. Those.i the Atlantic gold region bear but small proportion in size to the former. It is therefore quite possible that those of California may have received their supply of gold from veins not richer in metal than those of our Southern States. It is very probable that the average depth of the ravines in the main gold region in California is ten times greater than those in the Atlantic district, and if 80, should contain a quantity of gold in the same proportion, provided the veins be equally rich in each case. This mode of investi- gating the industrial importance of gold regions should not be overlooked by those interested in the subject. It has been recently announced that gold has been discovered in the talcose slates of Pennsylvania, and a few years since it was found in Canada. The list of localities might be much extended, but those already given are sufficient to illustrate our former observation in reference to the extensive distribution of gold upon the earth. Extraction, separation, and assaying of gold-When gold occurs native in sedimentary deposits, whose component parts are not held together by a cement. as in the cascalho of Brazil, there is required at first but a small outlay of capital for collecting it, and the fact that individuals can operate inde- pendently of each other, has usually caused a great rush of gold-seekers to every newly discovered locality of this kind. These busy themselves in hunting out and digging holes in the drift to find rich places, which are first worked, and at last these independent operators abandon the half-worked and the poorer spots, to such as apply science, skill, and combinations of labor and machinery, enabling them to obtain the metal from deposits too poor to reward the others. Such has been the case elsewhere, and similar results must necessarily follow in California at no distant period. The most simple means used for separating gold from the drift matters, after they have been dug up, is to pick out the boulders and larger gravel, and wash the remaining gravel and sand with water in a suitable pan or vessel. The pan in most common use is of thick tin-plate, about fifteen inches in diameter at the top, and four inches deep, with sides inclined about 30° from the perpendicular. About one quart of the materials is taken at a time, with a suitable proportion of water; and a rotatory motion is given to the pan sufficient to throw out the sand, whilst the gold remains in it, water being added from time to time. If any gravel remain in the pan, it is picked out. The gold remaining is usually mixed with ferruginous grains, and is collected and dried. A very common mode of separating the gold from these grains is, by blowing the latter out after being dried, which occasions a considerable loss in the minute scales of gold. When, as is often the case, these grains consist of magnetic oxide of iron, they may all be gotten rid of; but when, as sometimes happens, the specular oxide or chromiferous iron are present, they cannot be removed in this way, because the magnet does not attract either of them. The pan, in skilful hands, is convenient for the more locomotive part of the gold-diggers, or those who work alone. These often also make use of small cradles or rockers, which can be transported upon mules or horses. The simplest form of the rocker is a quadrangular box, open at the top, and from three to eight, or even ten, feet long, and ten to eighteen inches wide as well as high. At one end, which is slightly ele- vated, there is a coarse sieve placed at the top to separate the gravel. Several small strips of wood or iron are nailed across the bottom to check the too rapid motion of the solid matter towards the lower end of the machine, so as to permit all the fine scales of gold to subside. In using the rocker, the materials to be washed are thrown on the sieve, and water supplied by hand or otherwise. A rapid rocking motion is now given, and the water escaping at the lower end carries off the sand and earth, leaving the gold in the rocker with the ferruginous grains. These ordinary rockers can hardly be considered an improvement upon the pan-washing and, in fact, any mode is defective in which mercury is not used to separate the ferruginous grains without loss of the precious metal. This may be used in any rocker made of or lined with iron in such manner as completely to prevent the escape of the mercury. The rocker in common use at the gold mines in Virginia is the only one that seems completely adapted to the purpose, and is equally well suited for operating upon gold in sand and gravel, or upon vein-stones reduced sufficiently fine for washing and amalgamating. It is made of large size, and effectually pre- vents all loss of either gold or mercury. The sieves are of cast-iron, with holes of proper size. This machine has been introduced into California, and found very effective. The subjoined drawings represent the improved 2172. d rocker. 1 a Fig. 2172 is a perspective view. ri a a 2 Fig. 2173 is a longitudinal section through the a a axis of the machine. Fig. 2174 shows a cross section at hk. a, Ribs of strong oak, about two inches square. d d, Staves screwed to the ribs, so as (with the ends) to form a tight box, with a semi-cylindrical a 9 bottom. g c, Cast-iron supports, upon which the box rests. a', Cast-iron plates secured by spikes or screw-bolts to the two pieces of timber g. There are elliptical holes in these plates, bevelled on the upper surface, 80 as to receive the lower terminal Digitized by Google GOLD. 897 pieces of the supports c, and permits a rocking motion to be given to the machine by raising and depress- mg the handle i, which fits into the socket h. l, A perforated plate of cast-iron, with holes one-half or three-quarters of an inch in diameter, so as to permit the passage of sand and small gravel. The retained gravel and stones are thrown out after each charge has been washed. To facilitate this, a gate is placed at m, which may be attached by means of hinges, or may slide in grooves at the sides. k, A partition reaching from the top of the box to a little below the perforated plate l. Its use is to prevent the escape of the water and earthy matters, which are thrown on the sieve or perforated plate. The machine is then briskly rocked, by alternately raising and depressing the handle i, until the water, which is constantly supplied, passes through the small opening o, clear, or nearly so. The small openings shown in Fig. 2173 in the bottom of the box are closed with plugs, whilst the 2174. 2173. m a n d 1 a d d d , o a & g operation is going on, and when the gold (or amalgam, if mercury be used) is to be taken out, the plugs may be cautiously drawn out, so as to permit the water between the ribs to escape without losing the precious metal. The box may be of wood, but for permanent locations, it should be constructed of very thick sheet- iron, or, rather, thin boiler-plate. Native gold in veins of quartz is usually more or less mixed with iron pyrites, and sometimes with pyritous copper. The ore, after being picked over by hand, is reduced to a coarse powder in a stamping, or other mill, and agitated in a rocker with mercury, whilst the earthy matters are washed off with water. In the north of Italy, principally at Macugnagna and Vinzone, there are many factories for the separation of gold from an auriferous pyrites. The pyrites is crushed in horizontal mills to the size of a pea, and then ground with mercury and water for twenty-four hours. These ores contain only from 0-00001 to 0-0005 of gold. In all cases where mercury is used in separating the gold from impurities, the amalgam should be pressed in a chamois skin or buckskin, which separates a portion of the mercury. What remains in the skin is distilled in an iron retort and the mercury condensed in a receiver. The gold is left as a spongy mass, which is melted to drive off any minute portion of mercury that may have remained after distillation. If silver be present in the ore, it will be found alloyed with the gold. It is unnecessary to describe in this article the processes for separating gold contained in the various silver ores which are principally worked for that metal. In these the gold is obtained alloyed with silver and other metals; and the means of effecting it will be described at length in the article SILVER (q. v.); under which also the means of separating gold from galena will be noticed, because it is similar precisely to those made use of in operating upon argentiferous galena. In fact, silver always exists in these ores. Upon this branch of the subject it remains to treat of the means of determining the presence of gold as it occurs in nature, and in what proportion to the accompanying foreign matters. There are numer- ous ways of effecting this; but we shall only notice one very simple method, which, at the same time, gives the most accurate results. This is by the use of a glass tube, about one foot long, closed at one end, and whose internal diameter is three-fourths or seven-eighths of an inch, not too large to be stopped with the thumb. This may be about one-half or one-third filled with the auriferous sand or powdered vein-stone, and a few grains of mercury, and a little water added after which the tube is to be well shaken for some time, so that all the gold may be dissolved by the mercury. Water is then repeatedly poured in and out, whilst the tube is inclined and gently shaken, in order to get rid of the sand. The gold, if any be present, will have formed an amalgam with the mercury; the latter may be driven off by heating over the fire in an iron spoon, or any other convenient iron utensil. In assaying an auriferous pyrites in this manner, more accurate results are obtained if the pyrites be previously roasted and reduced to a fine powder, although most of the gold may be obtained without the roasting. These tubes may be graduated so as to show the proportion to the bushel, or any other measure, they will contain when filled to a proper height. One whose internal diameter is 806 of an inch (rather more than 13 of an inch) would contain 111 of a bushel when filled with material to the height of six inches Two such tubes, with a very small iron bottle containing mercury and a small delicate spring-balance of little cost, and to weigh not more than three to five grains, may be secured in a wooden case, and furnish a very portable, convenient, and accurate means of determining the proportion of gold in sedimentary deposits or in vein-stones, if the means of powdering the latter be accessible. The separation of gold and silver from other metals will be more fully treated of under the head of SILVER; but we shall indicate briefly in this place the most efficient and accurate means of separating gold from native alloys, as well as those artificial compounds usually met with. Goldsmiths and other artists, in order to purify their filings and other matters containing gold alloyed or mixed therewith, frequently do nothing more than melt it in contact with nitrate of potash, (saltpetre but when it is desired to bring the gold nearly to purity, it is fused in a crucible, and then from two to 113 Digitized by Google 898 GOLD. four parts sulphuret of antimony (the lupus metallorum) gradually added. Sometimes it is necessary to fuse the gold several times, in order to separate all other metals completely. Even silver may be thus separated from gold. But, to get rid of the antimony, it must now be fused with nitrate of potash, which completely separates it. Although we can thus procure gold in a very pure state, there is apt to be a little loss; and if silver be present with other metals, it is an expensive process to recover the silver from the mixed sulphurets which are formed. The separation of gold from silver is completely effected either by means of pure nitric acid or nitro- muriatic acid, according to the relative proportions of these metals in the alloy. If the metal contains less than fifteen per cent. of silver, all the gold may be obtained in solution as chloride of gold. When the proportion of silver exceeds 80 per cent., all the silver may be dissolved out by nitric acid, leaving the gold unacted upon; its quantity may then be determined by weighing. If, however, great accuracy be desired, it should be dissolved in nitromuriatic acid, and to the neutral solution, protosulphate of iron added, which will precipitate the gold in a state of purity. Alloys of gold, containing between fifteen and eighty per cent. of silver, should be fused with three times their weight of lead, and the fused mass treated with nitric acid in sufficient quantity to dissolve out all the metals likely to be present, except the gold. This fusion may be effected readily in a porcelain crucible over an Argand spirit-lamp. If, however, platinum be present, there should be added to the solution of gold in nitromuriatic acid, chloride of potassium, which will precipitate the platinum as a double chloride. The gold may then be precipitated by protosulphate of iron in a state of purity as before directed. Jewellers often judge approximative of the proportion of alloy in gold, by means of the touchstone. Stones of several kinds are used for this purpose, but pieces of polished trap or basalt are preferred. A number of small bars or needles (not less than ten) are prepared of gold, having known proportions of alloy. A mark or trace is made upon the surface of the stone with a piece of gold for assay upon this trace a drop of nitric acid is placed; the same is done with the try-needles successively. The pro- portion of gold is inferred to be the same as in that needle whose trace on the stone is similarly affected by nitric acid. Those who are skilled in the use of the blowpipe can readily detect with it the most minute propor- tions of gold, silver, and other metals in ores or alloys; and in the cases of gold, silver, and copper even the per centage of the metal may be ascertained with considerable accuracy, although the quantity operated upon does not exceed one grain. The method of using this important instrument, and applying it to the detection of metals, will be given under the title of METALLURGY, (q. v.) It is common to express the proportion of gold in an alloy by the words fineness. Thus, in the lan- guage of assayers, when they say 18 carats fine, or 750 thousands fine, they mean that 18 parts out of 24, or 750 in 1000, consist of pure gold. The method of stating the fineness of gold by carats has been discarded at the Mint of the United States, and at some of those in Europe. The subjoined table gives the equivalents of carats in decimal parts, unity being twenty-four carats: Carats. Decimals. Carats. Decimals. Carats. Decimals. 1 0.042 9 0375 17 0.707 2 0083 10 0.417 18 0.750 8 0.125 11 0.459 19 0.792 4 0.167 12 0.500 20 0.833 5 0.208 13 0.542 21 0.875 6 0.250 14 0583 22 0.917 7 0.292 15 0.625 23 0.958 8 0333 16 0.666 24 1000 Uses of gold-The use of gold in coin, and the various applications of it to ornamental and useful purposes in the arts and in domestic economy, will come in necessarily under appropriate titles. Here will be noticed only its medicinal employment. Preparations of this metal have been used in medicine for a long time, and were thought more cffi- cacious in former times than in the present day, when mercury seems in great measure to have sup- planted its use. Occasionally, however, it is revived upon the publication of new experiments. It is yet retained in pharmacopoeias, but is little regarded by the medical profession. The compounds of this metal used in medicine are the following: Chloride of gold, in doses of 10 to to of a grain. Iodide " " to to 1/2 " Cyanide a " 1/2 to 10 « Oxide " " t to 1 grain. Purple powder of cassius TO to T's of a grain. Metallic gold in powder, precipitated by protosulphate of iron, t to 1 grain. All the above, except the oxide and metallic gold, are poisonous if several grains be administered at a dose. The Homosopathic physicians also use preparations of gold in the infinitely small doses pre- scribed by their system. Annual supplies of gold-Professor Ansted, of London, made, in 1848 an estimate of the supplies Digitized by Google GOLD. 809 of this metal from all sources, at the beginning of this century, which appears quite reliable, and which reduced from pounds sterling to dollars, is presented in nearest round numbers as follows. Of course minute accuracy cannot be expected in such a table. Dollars. Europe 900,000 Northern Asia 370,000 Mexico 1,200,000 New Grenada 3,250,000 Peru 530,000 Potosi and provinces east of the Andes, excluding Brazil 350,000 Chili 2,000,000 Brazil 4,750,000 Total 13,350,000 The same authority has furnished the following, showing the anticipated supply in 1849. Dollars. Europe, excluding Russia 968,000 Siberia 19,360,000 Asia, excluding Siberia 2,420,000 Africa 1,936,000 North America 968,000 South America 5,808,000 Total 31,460,000 The actual supply probably exceeds this estimate; for the amount from California before the close of that year is not included. It will be noticed that, in less than fifty years, the annual supply from America fell off about 27 per cent. There has been an increase in Europe, and a considerable trade in gold from Africa, which had ceased to export this metal fifty years since. Notwithstanding the falling off from South America, the aggregate supply had increased nearly two hundred and forty per cent, mainly owing to the product of gold-washing in the Ural and in Siberia. The supplies from this source began, for the Ural, in 1819, when gold to the value of 437,000 dollars was produced, and they have steadily increased to the pres- ent time, when it may be estimated at little short of twenty millions of dollars. The average from the Russian possessions for 28 years to 1846 inclusive, is 5,540,000 dollars, but the product of the year 1846 was greater than the whole amount for the 10 years from its beginning in 1819 to 1829, (the epoch of the discovery in Siberia,) viz. 18,702,750 dollars. An addition is now to be made to the amount of gold supplied to commerce from the washings in California. There is no small difficulty in forming a correct estimate in this case, in consequence of the tendency to exaggeration 80 generally manifested by most writers. The washings commenced in the spring of 1848, and, as has already been stated, the number of opera- tors three months afterwards, was estimated by Governor Mason at 4000. They must have rapidly increased, if one may judge by the vast emigration from all quarters, which was estimated to amount to little short of 100,000 persons during the year 1849, and which still continues. However great may be their dislike to washing and digging for gold, after they experimentally realize the operation, the larger portion of them will, for a time at least, be compelled to engage in it as a means of support, and thus swell the supply for the present year greatly beyond what can be expected in any future year. The whole amount from the commencement, for the two years ending upon the 14th May, 1850, received at the United States Mint from California, is $15,675,452 Add amount purchased by artists or retained as specimeus 324,548 Estimated value of gold, excluding coin exported from California 5,000,000 Amount produced in two years $21,000,000 It is very common to see estimates of much larger amounts than we have given; and upon the arri- val of a steamer from the Isthmus of Darien, with the mail or passengers, from California, we have always an estimate of 2 or 3 times the quantity of the precious metal, which is subsequently stated in the published returns of the United States Mint; where, it is manifest, nearly all received in this coun- try is sent for coining. The allowance we have made for that sent from California to foreign countries, is far more likely to be over than under the actual sum, as might be shown if our limits would permit. There are reasons for believing that of the 21 millions produced, about 15 millions were collected during the year 1849. From the number of persons who will be engaged at the washings during the present year, (1850,) it is possible that the amount collected may reach 20 millions, although the exhaustion of many of the most productive localities during the last year renders it not very likely, notwithstanding that the number of operators may be larger. The exhaustion of most of the ravines containing gold in available proportions, at the present or even at a much lower price for labor in Cali- fornia, will probably happen during this year, and many persons will either occupy themselves in other pursuits within the country or leave it. We may expect, therefore, a considerable falling off in the supplies for 1851 and 1852, and thereafter; and that it would not be prudent to expect more than 10 or 12 millions per annum after the last-named year, unless, contrary to experience in every other gold region hitherto explored, the rich quarries of gold" of some writers, or, in other language, the veins of quarts containing gold in that region, shall prove highly productive. Digitized by Google 900 GOLD-BEATING. The report of Mr. Tyson's Geological reconnoissance, published among the documents of Congress, fully confirms the observations of Prof. Ansted, in the paper before quoted, in which be says, It is quite certain that the deposits, (in California,) if so rapidly worked, must be rapidly showing symptoms of exhaustion, for such deposits are neither inexhaustible, nor are they soon recruited; and the mines, vaunted as they now are, will be found to resemble other mining operations, and can by no means be expected to yield, continuously, large supplies without great labor, risk, and expense." Anticipating supplies of gold to an immense amount from California, many persons have occupied themselves in speculating upon the effects likely to result in regard to the value of property generally. This subject belongs, properly, to our article MINT, (q. v.) but it may be stated in this connection, that all fears of extraordinary reduction in the value of gold from this cause are altogether groundless. The labor and other items of the cost of procuring gold in California, as in all other gold regions, is so great as to guard most effectually against over-production. A very small reduction in its commer- cial value would materially lessen the production in the many localities where the expenses are even now little, if any less, than the value of the precious metal produced. GOLD-BEATING is the art of preparing what is well known under the name of gold leaf, in which gold is hammered or beaten into plates, whose average thickness at the present day may be taken at 350000 of an inch. An art which affords so remarkable a result, in rendering tangible a space which is invisible, well deserves mention here. The extreme malleability and ductility of gold, no doubt, brought an art like this into use very soon after the metal was known, and at a very early period in the world's history. The overlayings" which are spoken of in the Book of Exodus (chap. xxvi., dc.) were, most likely, of gold-leaf in some of the instances at least such appears to have been the opinion of the writers of the Septuagint. The gilding of Egyptian remains, which many of us have seen, and which are, undoubtedly, of leaf in a re- spectable at tenuation. may carry the art back to a remoter epoch even. It appears to have been no novelty to the heroes of the Trojan war, or, at least, to the Rhapsodists, who, seven and twenty centuries since, sang their deeds; and, finally, Pliny, about our era, gives particulars whereby we may judge of the state of the art, then long and extensively applied. This author has, in this respect, been either hastily read or partly misunderstood, and thus errors of a very opposite character have crept into statements made or handed on by respectable authorities. Thus, Buonarotti, for instance, infers that the least thickness of gold-leaf the Romans could make was twenty- two times greater than ours; while Ure, apparently quoting Pliny, would make the modern gold-leaf eleven hundred times more thin. In point of fact, the reduction of Pliny's measures, will give, as the average thinness of Roman gold-leaf, 78727 of an inch, (for he says that it is not the thinnest,) or about three times as thick as we make it now. No account remains of the methods practised by the ancients for this purpose; but there can be little doubt that they were similar to, though with less efficient means than, our own, which are more the result of patience and skill than of science or civilization. The first notice that we have of the process dates back to the ninth century, when a German monk, Theophilus, speaks of the employment of parchment as an envelope to protect the surface, and of the use of red ochre or chalk (our workmen at this day very often call it talc) to prevent the leaves from sticking. Parchment, or vellum, must soon have been found too thick to answer the end perfectly; but the introduction of what is called gold- beaters' skin, (by the French artists, baudruche, and by the Germans goldschlägerhaut,) which is pre- pared from one of the membranes (the peritoneal) of the larger intestines (the сœсит) of the OX, is of uncertain date. It is affirmed by some to have been originally an Irish discovery; but the precise mode of preparation is kept as a sort of mystery by the few persons who furnish the article for gold-beaters. The general principles of the mode are, however, very well understood. The particular secret would hardly be worth the trouble of penetrating. To manufacture gold-leaf, the metal is required in theory to be in a state of purity. All alloy is at the expense of malleability. But in practice, this is rarely, if ever, attained, and the usual fineness is that of coin, which in France and the United States is ninety per cent.; in Great Britain 911 per cent. and in Bavaria, where the principal amount of gold-beating in Germrny is done, 9710 per cent. fine. In France it was stated, thirty years ago, that the most approved practice was to mix equal parts of old Spanish coin and pure gold, which would result in an average proportion of 95% per cent. fine. Below 75 per cent. fine, the manufacture would be, in labor and waste, a losing business. The principal aim of alloying, when it is done of design, seems to be in the production of a variety of color-silver making the leaf pale, copper deepening the tint. These effects are more particularly noticed in the article GOLD; they are similar in the leaf as in the more solid masses; only in the state of tenuity, the green and purple tinge spoken of there is more easily excited and more vividly displayed. Whatever may be the character and degree of alloy, the manipulations of the gold-beater are the same in kind, and will be now briefly described. 1. Casting.-The metal is placed, with a little borax to promote fusion, in a black-lead crucible, or crucibles, and set in a furnace. When perfectly melted, it is poured into cast-iron moulds, three or four inches long, three-quarters of an inch wide. and about half an inch deep, and holding each about one thousand grains of metal. These moulds are made with faces a little concave, to allow the cast to draw easily; and before pouring, they are heated, and rubbed with linseed-oil or tallow on the inside, to drive off moisture and promote an easy separation. When sufficiently cool, the ingot is taken out, and re-heated in an open fire, or a small annealing-furnace, by which it is softened, and the adhering grease driven off. 2. Laminating.-In older times, this was effected entirely by the hand-hammer now a flatting-mill or laminating rolls are employed. The French still use, however, a preliminary forging upon a steel anvil, (of three inch by four inch sides,) with a hammer of about three pounds weight. The face of this hammer is about one inch and a half square, and its handle about six inches and a half. With this they bring down the thickness of the ingot to one-sixth or one-seventh of an inch. The English Digitized by Google GOLD-BEATING. 901 perform the whole of the operation in the rolls. As the success of the work and the excellence of the leaf ultimately depend a good deal upon the uniformity of the lamination, care is taken to use a proper and accurate machine. These machines have been successively improved; until now there is little, if any thing, left to be desired. During the hardening processes of lamination and forging, if the latter be employed, the riband has to be frequently annealed, to prevent cracking. Formerly, the lamination was thought sufficient which had brought the thickness down to 3'3 of an inch, with a width of one inch and the balance was done by hand, cutting the riband into lengths of one inch and a half, piling twenty- four of the lengths evenly together, and forging them all at once till they came square. This is the practice with some of the French and German gold-beaters to this day: but others, having access to more perfect machinery, continue its application to the lamination until the thickness is brought to about 700 of an inch. As dimensions like this cease to be appreciable, the degree of lamination is estimated by weight; and the direction usually is, to bring it down until a square inch of riband weighs six grains and a half; in this state it is ready for the beating proper. 3. Beating.-The implements and fixtures for this are, an anvil, hammers, skins, shears, parting- knives, &c. The anvil is a block of marble, weighing 250 or 300 pounds, or more, at pleasure, with a face of nine inches to one foot square, carefully made even and smooth. This is set in a frame wood- work, strong and solid, and upon a firm foundation. A ledge, five or six inches high, runs round three sides of the frame; to the remaining side an apron of leather is attached, which is lifted by the work- man. The object of all this is to catch and retain fragments of the precious metal. The hammers are, ordinarily, four in number, varying in weight. Their faces are from three to five inches in diameter, and slightly convex. The weight of the first or flat hammer is about fifteen pounds; the second (which the French term the commencing-hammer) weighs from six to eight pounds; the third, or spreading- hammer, with a smaller face, and more convex, weighs about five pounds only; and the last, or finishing- hammer, is again a heavy one of ten or twelve pounds, with quite a convex face. The skins are of parchment and vellum and the intestine already spoken of, cut (the two former) into squares of about four inches, and (the last) of five inches. Besides these, there are packing-boxes, also of parchment, made on a form, and cemented together, open at two opposite ends, and in pairs, so that one will elip into the other, by which the open ends are closed. The knives are pieces of cane, set into a frame, both four-square and cruciform, with sharpened edges that divide the attenuated leaf, better than any other implement, by pressure downwards only. When the leaf becomes very thin, any other motion would drag it. Provided with these and other tools that do not require special mention, the workman lays off the riband (which comes from the laminating, as nearly as possible, one inch in width) into lengths also of one inch. This he does with dividers or a scale, and cuts off, afterwards, with shears. This is on the supposition that the rolling has been uniform, and equal surfaces therefore should give equal weights. He then arranges these squares into piles of generally 150 pieces, interposing between each leaf a piece of the vellum before spoken of, and placing the gold-leaf as near as may be in the centre of the vellum, with their edges even. About twenty extra-vellums are placed on top and at bottom, and the pack is then of proper size to be pushed smoothly into one of the parchment envelopes, which is then in its turn pushed into its mate, and the whole thus enclosed on all four sides. The pack is then laid on the marble anvil, and beaten until the small gold-leaf is extended to the size of the vellum. It is in the judicious uniformity of direction and force of the blows that the skill of the workman is displayed. Great dexterity is, in fact, attained: the hammer is shifted from hand to hand for relief without inter- fering with the regularity of the stroke; and when it is recollected that the absolute effect of the aver- age hammer with the average blow is equivalent to the steady pressure of about 2800 pounds on the square inch, there will be seen to be need for discretion in the application of such a force. During the beating. the pack is frequently turned, 80 as to beat on the bottom as well as the top, (as a skilful workman will do without losing the stroke,) and also folded or rolled in the hand, to secure a proper detachment of the surfaces. It is also opened from time to time to watch the effect, and shift the leaves from the centre to the outsides, that the pressure may be uniform. When the gold has been extended to the size of the vellums, about sixteen times its original dimensions, it is taken out, cut up into four squares, repacked as before, only with gold-beaters' skin instead of vellum, and beaten over until similarly extended again. The caution of folding the pack to loosen the leaves is more necessary even now than before, and 80 of opening and shifting. When it has attained the size of the skins, it is removed, parted into squares again, but this time with the cane, repacked and rebeaten as before into leaves of three to three and a half inches square. It is estimated that the aggregate surface of the leaves is now 192 times larger than it was originally; and their thickness may be taken at 140hno of an inch, which is about the average of English gold-leaf, and corresponds to an extension of about 100 square feet to the ounce. But the operation is frequently carried further by repeated beatings till an ounce is extended over 160 square feet, corresponding to 8 calculated thickness of of an inch nearly. The French gold-beaters claim-and their statement of weight worked on and number of leaves produced warrants the claim-to carry it down ordinarily much further than this; and our statement at the beginning of 330000 of an inch is, probably, even within the average result, and much within the possible limits, of malleability, if these were, without regard to expense of time and waste of metal, the only points to be reached. The French workmen are also very precise in the number of pieces, both of leaf and of baudruche and vellum, which go to the packs in each of the five several steps that comprise their beating. As the fruit of experience, no doubt, they have ascertained the number which best suits the respective implements. The English and Germans pack in different numbers, it may be supposed with the same reason; but the principles of the operation are, in all, the same. When the leaf is considered as finished, the last thing is, to put it in the square books, such as we see in commerce. These are made of smooth paper, frequently reddish-colored, on purpose to heighten the lustre of the gold, and well rubbed with Armenian bole, to prevent adhesion. There are two sizes; Digitized by Google 902 GONIOMETER. one about 41, the other 34 inches square. The pack, withdrawn from its parchment envelopes, is held by one of its angles; and, with a pair of wooden pliers, each leaf is withdrawn, and laid, aided by the breath, upon a leathern cushion, where, with the cane knives, it is parted at once or successively into four pieces, the size of the book. These pieces are then similarly transferred to the book, each between separate leaves. The book holds, very uniformly, twenty-five leaves of gold. When filled, it is pressed hard with a piece of wood of its own size, 80 as to bring its edges close; and with a piece of linen any projecting pieces of gold-leaf are readily wiped off. Afterwards, the books are put up in packages of a dozen ordinarily, for sale. The French artists allow between three and four days for finishing four ounces of gold. They esti- mate the loss in trimmings, waste leaves, &c., at fifty per cent, and consider the remaining two ounces poids de marc, (964-10 grains English,) as yielding 12,600 leaves of the smallest size; but there is no authentic experiment of weighings and measurings in this respect. The parchment employed is used as it comes from the manufacturer, only cutting out of the sheets those parts, of suitable size, which are softest and of most uniform thickness. The vellum, which is procured of the finest and softest, is not further treated than by well washing it in cold water, drying it in the air under a press, and then powdering it with finely calcined and reduced selenite. Whether the implement used for this has any special influence will not be affirmed or denied; but the uniform practice, in France at least, is to use a hare's-foot. The preparation of gold-beaters' skin, from the colon of the OX, has been already spoken of as a secret endeavored to be maintained by the few who furnish the article. Whatever their processes may be, the gold-beater is accustomed to test and treat it still further for himself. Thus, he first sweats it, by placing it between a fold of foolscap; making a pile of many pieces, he treats it to a hearty hammering until it ceases to give out any grease to the paper. Next, he moistens it with an infusion of nutmeg, cinnamon, or other spicy aromatics, with the view of preserving it, dries it in the air, moistens again as often as he sees fit, and finally dries and presses it for use. Since the introduction of creosote, this (as well as may be judged from the odor of some recent skins) has been applied, and no doubt more effectually. After the skins have served some time, (some seventy or eighty beatings, for instance,) they become inspissated, or wiry, or both, and no longer allow the proper extension of the gold. This may be cured by laying them a half day between leaves of paper wetted with Rhenish or Moselle wine, or even vine- gar and water. When thoroughly moistened, they are placed between layers of parchment, enveloped and beaten until dry. This beating frequently takes a whole day. They are then powdered with selenite. and fit for use. While yet fresh, the skin is very liable to be affected by moisture which it absorbs from the atmos- phere. They must be, therefore, always dried before using, which in France is done by heat in a screw-press. Care is taken not to desiccate too much, which withers and causes it to crack under the hammer. The methods which have been described here are also applicable in their measure to silver, copper, and platinum. A sort of gold-leaf, called party gold-leaf, is sometimes used, made with a combination of gold and silver. Separate leaves are taken of these metals, the silver being about three times as thick as the gold, heated and laminated together, so as to produce an alloy or welding of their surfaces. The resulting party-colored riband is then beaten as if it were all of gold. Its extensibility is, of course, not so great. There is another false gold-leaf, which is better known as Dutch gold-leaf. It is, in fact, a riband of brass, wash-gilded, (see GILDING,) sheared into leaves, and then beaten in the manner, and with more or less of the precautions, that have been described. When new, it is difficult to be distinguished from true gold-leaf; but it is soon tarnished by the air, and is unfit for any gilding that is not to be varnished. GONIOMETER. (Gr. yours, angle, and METPOV, measure.) An instrument for measuring angles, and more particularly the angles formed by the faces of crystals. The instrument, chiefly used by miner- alogists, was invented by Dr. Wollaston. It consists of a brass circle graduated on the edge, and fur- nished with a vernier, by which the divisions may be read correct to a minute. The circle moves in a vertical plane, and is supported on a stand. The axis of the circle is a hollow 2175. tube, within which is a smaller axis, fitting 80 tightly that when turned round it A carries the other axis, and consequently the wheel, along with it, unless the latter E is purposely prevented from moving. The interior axis is furnished with a milled head a, and the exterior with a milled head b; 80 that when the head a is held B and b turned, the circle may be moved independently of the smaller axis; and when b is held and a turned, the smaller axis may be turned independently of the circle. Attached to the end of the smaller axis is a sort of universal joint, capable of being fixed in different positions by means of screws. The crystal to be examined is attached to the joint at c by a little soft wax, and placed so that its edge shall be parallel to the axis of motion; which adjustment is obtained by placing it 80 that the image of some horizontal object, as the bar of a window, successively reflected from the two faces of the crystal, coincides with another horizontal line seen by direct vision. When this adjustment has been made, the instrument is turned till the horizontal object is seen reflected from one of the faces. The smaller axis is then held fast, and the other turned till the index of the vernier points to the zero of the graduated limb. The circle is then turned round, along with the smaller axis, till the same object is seen in the same position by reflection from the other face of the crystal; when the arc passed through by the circle is obviously the supplement of the angle formed by the two faces of the crystal. In order, how- ever, to avoid calculation, the supplements of the angles are marked on the limb, 80 that the angle to be measured is read off immediately. The name Goniometer is also applied to a surveying instrument, somewhat similar to a Theodolite Digitized by Google GOVERNORS. 903 GOVERNORS. The theory of the operation of the common centrifugal governor will be found at p. 545, under the head of ENGINES. We here introduce various forms of application of the same princi- ples, together with other contrivances to accomplish the same object. All the work required of the governor, Figs. 2176, 2177, 2178, is to ring a bell, and to indicate upon a dial the velocity of rotation of millstones. This mechanism consists of a vertical wrought-iron axis A A, revolving in bearings BB, bolted to the wall of the mill, and carrying, towards its upper extremity, a pulley C, which receives motion from the main driving-shaft. To this axis is fixed a brass socket b, to which are jointed the two flat arms a a, terminated by the governor balls, and attached, about the middle of their length, by the two double links cc, to the sliding-socket d, made in halves and connected together by two small bolts. To this latter are also attached the two slender vertical rods ee, which traverse the pulley C, and convey the action of the governor to a sliding-disk D, provided with a projecting arm or catch, of such length as to come into contact, should the machinery exceed or fall short of its proper speed, with either of the two levers ff, which have their common centre of motion in a short vertical axis, and are attached at their opposite ends by slender wires to two sockets mounted upon a horizontal axis E; each of these sockets carries a bell, which, by the arrangement described, is rung when the catch on the disk D strikes either of the levers ff. To the sliding-socket d is fixed a forked rod, having one of its branches formed into teeth like a rack; this rack geers with a small pin- ion, Fig. 2178, carrying upon its axis an index, which points out upon the graduated dial F, 2176. the speed at which the millstones are revolv- ing. Thus, should the velocity of the prime mover relax, the vertical axis A partaking of this diminished motion, the balls collapse, the B socket d is pressed downwards, and the rack & causes the index to move from right to left. The opposite effect is produced by an increase of the speed; (these different positions being indicated by the dot lines in the figures.) At the same time the bell is sounded by the ap- paratus which surmounts the governor; and 2178. the attendant, by a glance at the dial, is made aware of the change in the velocity of the ma- chinery, for which he has to compensate by altering the degree of proximity of the upper 2177. and lower stones. It is sufficiently well known to our mechanical readers that the action of the governor is in no way affected by the weight of the balls, further than that these should be made of a size proportionate to the A resistance to be overcome; accordingly, in the case now before us, the work which the gov- ernor is destined to perform being very slight, the balls may be made of extreme lightness. Fig. 2179 is an example of the original form of the governor as introduced by Watt. The distinguishing peculiarity of this form of gov- ernor consists in the connecting links cc, being situnted overhead, and attached to the arms aa, by prolongations of the latter, which pass through a square part of the upright spindle A, to which they are both jointed by one pin. 2180. When at rest the balls are usually received into arms g g, curved to suit their surfaces, by which means the rods are relieved from all unnecessary strain. Fig. 2180 is a representation of a centrifugal governor, adapted to a small high-pressure crank-overhead engine. In this species of en- gine the governor is usually made to revolve in a short column B, cast in a piece with a forked bracket embracing the crank-shaft, and its spindle A A is driven by a pair of bevel-wheels from the crank-shaft. The spindle is surmounted by a double brass socket b, attached to it by means of a pin; and to this socket are jointed the arms a a, which, as well as the connecting links c c, are, in this example, finished in the lathe. The sliding brans socket d, to which the lower ends of the links cc are connected, is formed with a groove, into which is inserted the forked end of a lever D, having its centre of motion in a small wrought-iron column bolted to an arm projecting from the column B. From the opposite end of this lever depends the slender rod e, connecting it immediately with the throttle-valve lever, which, by this simple construction, is at once made to rise or fall, as the balls collapse or diverge in obedience to the varying speed of the engine. This is a type of the most common form of the centrifugal governor in use at the present day. Digitized by Google 904 GOVERNORS. Fig. 2181 is an example of a very excellent arrangement of the conical pendulum governor which is frequently adopted in highly finished engines. The peculiarity of this form consists in the connecting- rod e, being attached directly to the sliding-socket d, without the intervention of the forked lever. For this purpose the upper portion of the spindle A A is bored out truly cylindrical, to a point somewhat below the range of the sliding-socket d. This last is attached by means of a cotter to a small cylindri- cal hollow piece, which fits accurately into the interior of the spindle, and is consequently made to rise and fall with the socket d, a long slot being formed in the spindle to allow the cotter to traverse up and down. The lower end of the rod e is jointed to this interior piece by means of a swivel, 80 as to rise and fall with it, without being affected by its rotatory motion. At the top of the governor spindle, the rod e is guided in its motion by being made to pass through the small brass vase which surmounts the whole apparatus, and should it be required to be of any considerable length, the necessary rigidity may be imparted by fixing a weight to it, as shown in the figure. 2186. 2189. 2187. 2190. 2191. As in the example last under notice, the arms and links of this governor are finished in the lathe, as also the double cup g, into which the balls are received when the engine is at rest. In Fig. 2181 the Digitized by Google GOVERNORS. 905 balls are shown in section, in order to exhibit the mode usually adopted for adjusting their position upon the arms a a. The form of governor represented by Fig. 2182 appears to be worthy of favorable consideration, on account of the principles on which it acts, and of the extreme simplicity and economy of its construction. The vertical spindle A A, which may be set in motion either by a pulley or by bevel-wheels in the usual manner, is surmounted by two equal horizontal arms a a, furnished with stops at their extremi- ties. The governor balls run freely to and fro upon these arms by means of internal friction-rollers, and are drawn towards the common centre in the spindle A, by means of cords or steel ribands ii, passing over two pulleys at G, and attached at their lower ends to the sliding-collar d, in which works the forked end of the lever DD, which conveys the action of the governor to the throttle-valve. A spiral spring embracing the vertical spindle presses at its lower extremity against the sliding-collar d, and its pressure is regulated by a sliding-stop h, which can be fixed at any required elevation upon the spindle by a set screw. The stop h having been set 80 as to cause the spring to press down the collar d with any approved force, and the throttle-valve opened to any required extent, the engine is set in motion. Should its speed exceed the stipulated rate, the increased centrifugal force will cause the two balls to diverge, and raising the collar d, will partially close the throttle-valve and diminish the supply of steam, when, the motion being checked, the spring will press down the collar and cause the balls to collapse until the desired rate of motion is obtained. 2182. 2179. 2181. & 3 A D D 0.0 A A P 2183. 2184. D 2185. H H D a The degree of force exerted by the spring will always require to be adjusted to suit the nature of the work thrown upon the engine, because a small quantity of steam only will be required when the work is light, and a larger quantity when it is heavy. while the speed should in each case be the same, which conditions can be fulfilled with great facility and admirable precision by the use of this kind of governor. Fig. 2183 represents a simple and compact modification of the centrifugal governor. Here the balls, instead of being suspended upon arms of a length proportioned to the velocity at which the engine is required to move, are fitted to traverse from and towards their common centre in the spindle A, upon the arms HH, which revolve with the latter, and are formed into circular arcs of a curvature deter- mined by the same circumstances with the length of the suspending arms in the ordinary governor. By this means it is obvious that the horizontal plane of the rotation of the balls will vary with the vary- ing speed of the engine, in precisely the same way as in the conical pendulum governor; and the ver- tical motion thus generated is transferred directly to the sliding-socket d, which commands the throttle- valve lever. For this purpose, it is necessary that each of the balls should be made in halves and riveted together with a wrought-iron pin, as shown in the section, Fig. 2183; a space being left between the hemispheres to admit of the slotted arms a a, which are cast in a piece with the sliding-socket d, and through which the connecting pins are fitted to pass freely, but without allowing any play. The last variety of the centrifugal governor which remains to be noticed is that represented in Figs. 114 Digitized by Google 906 GOVERNORS. 2184 and 2185 the former being a sectional elevation, and the latter a plan of a governor constructed by M. Bourdon, of Paris, the peculiarity of which consists in the axis of rotation being horizontal instead of vertical The main advantage proposed to be attained by this system is the more convenient trans- mission of the motion of the prime mover, whether by wheel-work or by pulleys. The principle of its action is the same as that of the common governor. The spindle A A is of cast-iron, the part to the left being hollow, while the middle portion is formed into a species of open frame-work, enclosing the principal part of the mechanism. It revolves in ordi- nary plummer-blocks B B, and is set in motion by the cone pulley C. The arms a a which carry the governor balls, are supported upon a short axis working on the points of two steel pins, screwed into the central part of the spindle and secured by jam-nuts; this axis carries also a toothed sector c, work- ing into a similar sector upon another short axis to which is fixed a lever d; the slender connecting- rods jj, traversing the hollow part of the spindle, and supported by the guides kk, serve to convey the motion of this lever to the throttle-valve geer, which is provided with suitable arrangements for adjust- ing the action of the governor upon the throttle-valve. The air-reservoir or bellows governor.-This apparatus is of French origin, a patent having been granted to the inventor, M. Molinié, of Saint-Pons, in 1838. The principle on which its action depends, con- sists in causing the engine to force a quantity of atmospheric air into a reservoir with a movable cover through which the air escapes, the aperture being 80 regulated by an adjustable valve, that it shall only escape at a given rate. Should the speed of the engine exceed or fall short of the prescribed limit, the air is forced into the reservoir faster in the one case and slower in the other than it can escape through the valve; consequently the movable cover is raised or depressed, and, by means of suitable connections, partially closes or opens the throttle-valve. The advantages proposed by this system are, first, greater regularity and steadiness of action than is attainable by the common governor, combined with equal delicacy; and, secondly, a more considerable range or amount of motion available for the purpose of regulation. Fig. 2186 is an external elevation, Fig. 2187 a sectional elevation, (on a plane at right angles to the former,) and Fig. 2188 a sectional plan of this apparatus. The working parts are enclosed within a cylindrical vessel, the sole being formed of a cast-iron disk A, supported upon four small columns aa, and the cover, of a cast-iron capital or cornice C; these are bound together by the four pilasters BB, having recesses formed on their edges for the reception of cylindrical sheet-iron panels, which thus admit of being removed at pleasure, when it is necessary to examine or repair the internal parts. In Figs. 2186 and 2187 these panels are shown partially re- moved. Two small wrought-iron columns DD are also fixed to the sole-plate, and serve to support a cylin- drical cast-iron vessel E, the bottom plate of which is provided with two apertures guarded by the flap-valves d and g, which open alternately for the purpose of giving admission to the air which is forced into the receiver E by the double bellows F F; these are respectively supplied with air from the sur- rounding atmosphere by the apertures b and f, similarly furnished with flap-valves, the former being situated in the sole-plate A, and the latter in the movable piece G; the stream of air generated in the lower bellows passing through the upper by means of an elastic leather tube or copper pipe c. The cover of the fixed receiver E is formed of a movable cylindrical disk H, attached to the former by leather, in the manner of an ordinary bellows, and thereby admitting of being elevated or depressed, according to the degree of condensation of the air within the receiver; this is regulated by means of a small conical hole h, guarded by a pointed screw i, properly secured from turning, after being adjusted 80 that the air forced into the receiver when the engine is at its normal velocity, shall just have liberty to escape, and consequently hold the movable cover suspended. Motion is communicated to this ap- paratus by means of two rods 11, fixed to the movable intermediate piece G, and attached by means of the connecting-rods m m to cranks formed on the shaft I, which is set in motion by a belt from the prime mover working over the fast and loose pulleys JJ. A round rod K, screwed into the movable cover H, serves to convey the motion generated by the governor to the throttle-valve or sluice-geering, as the case may be. On this rod is fixed a ball L, which, for the sake of adapting the governor to the varying circumstances in which it may be placed, is usually made hollow and partially filled with lead. Fig. 2189 is a representation of a mode employed by M. Molinié, for rendering his governor most advantageously applicable to regulating the supply of water to a hydraulic motor. Besides the regular sluice-gate, he makes use of an additional valve N', to which, by means of the cord and pulleys shown in Fig. 2186, he attaches the governor. The face of this valve is bent into a cylindrical form, and it is jointed by rods to a central point considerably behind the sluice-face O'. By this means the strain arising from the pressure of the water against the back of the valve is counteracted, and the action of the governor rendered sufficiently delicate. Fig. 2190 represents the connection of this governor with the throttle-valve of a steam-engine. The efficient operation of this governor depends entirely on the perfection of the mechanism by which the escape of the air from the receiver E is regulated. The simple contrivance detailed is altogether inadequate, as it is neither self-adjusting nor theoretically perfect in any circumstances, as will be ob- vious from the consideration that the volume of any fluid escaping by a given orifice depends not only on the section of that orifice, but also on the velocity of the escape; 80 that the higher the velocity, the aperture remaining the same, the greater will be the volume of issuing fluid. To compensate for this circumstance, M. Molinié has devised an arrangement at once simple and effectual. Instead of the pointed screw i, he makes use of a conical pin i', see Fig. 2194, which is at- tached by nuts to the movable cover H. It is fitted to move in the interior of a brass tube h', fixed to the stationary part of the air receiver, and close at the bottom, while the top is pierced with a hole of the exact size of the thick part of the pin. The air passes by an adjustable aperture into the interior of this tube; and according as the cover H is more or less elevated or depressed, the area of the aperture of escape is proportionally increased or diminished. By this ingenious contrivance, not only is the the- Digitized by Google GOVERNORS. 907 oretical defect above alluded to corrected, but a great additional advantage is obtained in the more rapid and energetic action of the governor. Figs. 2191, 2192, and 2193 represent two different modifications of the vane governor. The principle of its action consists in the atmospheric resistance to rapid motion being employed to counteract the force of gravity. The form represented in Fig. 2191 is that which illustrates the principle most clearly. On the crank- shaft is fixed 11 drum or pulley o, and underneath it, or in any convenient situation, is placed an axis carrying a small grooved pulley, to which are attached two or more fans or vanes PP. The former communicates motion to the latter by means of an endless band or belt, which is also passed over two friction-wheels, the first of which is attached to the weighted rod r, which commands the throttle valve lever p, and the other to a gravitating weight q, suspended freely on the opposite side of the axis. The area of the vanes PP, and the weight of the ball q, are 80 adjusted in relation to each other that the latter is just sufficient to drive round the resisting vanes at a certain velocity, exactly corresponding with the normal speed of the engine. Any increase of that speed, instead of accelerating the motion of the vanes, (the atmospheric resistance being nearly uniform,) tends to raise the weight and diminish the supply of steam passing through the steam-pipe N, and any relaxation of it allows the weight to de- scend, and thereby opens the throttle-valve in a corresponding proportion. 1 2192. 2188. x a D at 2193. N 2194. 2195 2196. X 2195. 2197. Figs. 2192 and 2193 are a side and end elevation of an arrangement in which this principle is carried out in a more practical and more generally applicable form. It consists of an upright spindle 8 8, sup- ported in suitable bearings in a cast-iron standard R, placed, in the usual manner, over the crank-shaft Q of the engine, upon which is keyed a bevel-wheel, driving a pinion on the foot of the upright spindle, whereby a rapid rotatory motion is given to it. The upper part of the spindle is formed into a screw or worm, the threads of which slope at an angle of about 45°, and upon which a heavy bush or nut q is fitted to move easily. This bush, which is usually formed into a ball, and corresponds in its functions with the suspended Digitized by Google 908 GRAIN SEPARATORS. weight q in the previous example, has attached to it two or more projecting arms furnished with vanes PP; these are so fitted upon the arms as to be capable of being set nearer to or further from the spindle, as circumstances may require; they also admit of being turned upon the arms in an oblique direction, as shown by the dotted lines in Fig. 2193, in order to diminish the atmospheric resistance. The weighted nut is connected to the throttle-valve by means of a double link and swivel K, and by levers and rods M M, n n, in the usual manner. From the above description it will be seen that when the spindle s is driven in the direction tending to raise the nut q, the latter with its attached vanes will be carried round with it, and at the same velo- city, until and so long as the resistance of the air against the vanes corresponds with the gravitating power of the weighted nut. But when the velocity of the engine, and consequently that of the spindle 8, is increased beyond that point, the atmospheric resistance against the vanes will exceed the gravitating power of the nut and its mountings, and cause them to ascend upon the screwed spindle, and thus, by means of the connecting-rods and levers K M, n p, will diminish the supply of steam passing through the steam-pipe N to the engine. If, on the other hand, the velocity of the spindle is reduced below that required by the resistance of the vanes to overcome the gravitating tendency of the nut q, the latter will then descend upon the spindle, and thereby increase the passage for the supply of steam. The speed of the engine may be permanently varied at pleasure, by adjusting the vanes upon their supporting arms, 80 as to increase or diminish the gravitating power of the nut to the required extent. The chronometric governor.-This is the name given to Figs. 2195 and 2196, by its inventor, Mr. C. W. Siemens, of Berlin. The principle of its action appears to be an admirable and perfect one, involv- ing as it does the happy idea of so combining the invariable motion of an independent pendulum with the varying speed of the engine or other motor, as to make the former correct instantaneously the fluctuations of the latter. Fig. 2195 is an elevation, and Fig. 2196 a section of this apparatus, which is set upon a bracket SS bolted to the wall of the engine-house, and supported by a frame-work TT, consisting of four small columns and a circular entablature. The differential velocity between the engine and the revolving pendulum Y is obtained by means of the three bevel-wheels t, u, and v; this last is firmly connected, by an upright spindle and grooved arm w, with the upper extremity of the pendulum, produced through the ball and socket joint, which forms its point of suspension and revolution. The under wheel t is fixed to the pulley U, which is driven by the engine with its uncertain velocity, and in the contrary direction to the motion of the wheel v. Both these wheels move in geer with the third bevel-wheel 26, which runs perfectly free upon its axis, and is also permitted to travel round the perpendicular socket forming the bearing of the others. It is obvious that if t and v revolve in contrary directions, but with equal velo- cities, the wheel u will also revolve on its axis, but will not change its angular position; while any difference in speed between t and v will cause the wheel u to follow the direction of the faster, which will at once alter the supply of steam, the arm x being attached to the throttle-valve contained within the steam-pipe N, by means of the lever and adjustable connecting-rod p and y. Another arm attached to the axis of the wheel u, on the opposite side of the perpendicular socket, is connected by means of the rod z to a lever working between two adjustable stops ZZ, which serve to confine the range of the throttle-valve within convenient limits. To maintain the motion of the pendulum a constant power is required, resembling that of the falling weight in an ordinary clock. This power is supplied by the weight r, which tends constantly to pull the wheel u to one side; and this strain being borne equally by the wheels t and v, causes the latter, and with it the pendulum Y, to revolve, while the former, revolving in the contrary direction, is constantly engaged to raise the weight back again into its proper position. In practice it has been found that the power necessary for maintaining the action of the pendulum is much less than that required to effect the movement of the valve; and accordingly Mr. Siemens has adopted the principle of driving the pendulum with an excess of power, which shall be neutralized by friction apparatus when not wanted, and shall be allowed to act freely when the governor requires its assistance to move the valve. This is effected as follows: Surrounding the grooved arm w is situated a conical ring W, cast with the framing TT, and accurately bored out; against the interior of this "absorbing ring" a small piece of steel accurately fitted into the open end of the grooved arm w is pressed by the short end of the pendulum rod X, a spring being interposed for the purpose of letting the pressure come on gradually. It is evident that whenever there is an excess of driving weight which causes divergence in the axis of rotation, the surface of the steel rubber and of the fixed ring will be pressed together with a force exactly sufficient to balance the excess; and 80 soon as the pendulum falls back towards a smaller arc of rotation it will relieve the friction apparatus, and permit an increased supply of power to overcome the resistance of the valve. A second spiral spring is laid within the grooved arm w, behind the point of the pendulum, for the purpose of preventing the latter from drop- ping into its perpendicular position, and to facilitate its starting with the engine. The adjustment of the valve is effected at the very instant that the equilibrium between the power and load is disturbed; an advance of 1-50th of a revolution of the fly-wheel is found sufficient to close the valve entirely. By converting the friction apparatus into a regular break, the power of the governor may be increased; and in this way it may be applied for the regulation of water-wheels, and such steam-engines as are furnished with variable expansion geer, which are better regulated by increasing or diminishing the amount of expansion than by throttling the steam. GRAIN SEPARATORS. This machine is an improvement on grain separators, invented by Ben- jamin D. Sanders, of Hollyday's Cove, Va., and it is designed to separate the impurities in threshed grain upon the reverse principle from the action of the common grain separators, or winnowing machines. Instead of blowing or forcing by the blower, the chaff, &c., from the good grain, he forms a vacuum the power of which can be regulated at will, to raise the chaff, and every thing specifically lighter than the good grain up into a receiver or light grain-hopper, while the good grain is never raised off the screens, but passes over them and falls into a granary below. A, is a frame to sustain the blower, which is Digitized by Google GRAVITY, SPECIFIC. 909 confined in the cylinder C. B is the shaft to drive the blower by the drum below. D is an air-tight trunk connected with the blower, and E a horizontal trunk, and F a perpendicular trunk, which is placed above the receiving-hopper of the uncleaned 2198. grain. G is the receptacle for the good clean grain. J N is the place where the uncleaned grain is intro- duced, the opening of which is regulated by a slide. E This uncleaned grain falls on to an inclined screen O. The whole is air-tight above to the blower, which is placed on the opposite end of the air-tight trunk, or D K it may be termed trunks." There is no way for the M air to get in but under the screen 0, passing through it, when the blower is in: motion. K is the hopper into which falls the very light grain, or those impuri- 0 ties not lighter than the chaff. J is a slide to let them 1 out. L is a case through which the chaff is blown af- И ter being drawn down the trunk D, and through the A B blower. M is a slide to regulate the power of the blow- er. The trunk F is wider at the top than bottom, 80 as c to have a stronger current exerted upon the screw. The blower being set in motion, a vacuum will be formed in the trunk above; therefore a current of air will rush from below through the screen, carrying up the stuff specially lighter than the good grain, the power of the blower being regulated for this pur- pose. According as the impurities are forced to a distance above the centre of gravity, 80 is the power to elevate them required to be greater. By this machine, the different qualities of grain and the im- purities are separated, more distinctly upon the principle mentioned than by any other. The good grain is deposited in a granary by itself, the very light in the hopper K, and the chaff completely driven out of the machine. GRAPHOMETER. Fig. 2199 represents this instrument as constructed by B. Pike, Jr., Broadway, New York. The error arising from the use of an instrument, where the whole dependence is placed on the needle, being frequently influenced by local attractions, has rendered it necessary for some other method to be employed to measure angles with accuracy; among these, the common theodolite with four sights has taken the lead. It is simple in its construction, and easy in its use. Fig. 2199 represents the graph- 2199. ometer, a brass plate or part of a circle about twelve inches in diam- eter, graduated on its edge from 0 to 180 degrees; in the opening be- tween the moving centre and the graduated arc, is a compass about four inches in diameter; two sights are fixed on the graduated arc, one at 0 and the other at 180°. Per- pendicular to the plane of the in- strument, there is a movable limb attached to the limb of the arc, but a little shorter, and having the ex- tremities slanted off, one of which forms a nonius, subdividing the degrees on the limb to minutes, and having two sights, one at each end in each sight there is a large and a small aperture, placed alternately, the large aperture in one sight being always opposed to the narrow aperture in the other; underneath the plate is a spring to fit on the pin of a ball and socket, which fixes it the single or three-legged staff, as may be required. In the figure the ball and socket are represented detached from the instrument. The four-sighted theodolite is the same instrument, except that the circle is entire, and the compass is placed in the centre of the circle. GRAVITY, centre of. The centre of gravity of any body or system of bodies is that point about which the body or system, acted upon only by the force of gravity, will balance itself in all positions: or it is a point which, when supported, the body or system will be supported, however it may be sit- uated in other respects. The centre of gravity of a body is not always within the body itself: thus the centre of gravity of a ring is not in the substance of the ring, but in the axis of its circumscribing cylinder; and the centre of gravity of a hollow staff, or of a bone, is not in the matter of which it is constituted, but somewhere in its imaginary axis; every body, however, has a centre of gravity, and so has every system of bodies. Varying the position of the body will not cause any change in the centre of gravity; since any such mutation will be nothing more than changing the directions of the forces, without their ceasing to be parallel; and if the forces do not continue the same, in consequence of the body being supposed at different distances from the earth, still the forces upon all the moleculæ vary proportionally, and their centre remains unchanged. See CENTRE OF GRAVITY. GRAVITY AND GRAVITATION. These terms are often used synonymously, to denote the mutual tendency which all bodies in nature have to approach each other. See FORCE, CENTRE OF GRAVITY, and ATWOOD'S MACHINE. GRAVITY, SPECIFIC. The specific gravity of a body is the ratio of its weight to an equal volume of some other body assumed as a conventional standard. The standard usually adopted for solids and liquids is rain, or distilled water, at a common temperature. Digitized by Google 910 GRAVITY, SPECIFIC. In bodies of equal magnitudes the specific gravities are directly as the weights, or as their densities. In bodies of the same specific gravities the weights will be as the magnitudes. In bodies of equal weights the specific gravities are inversely as the magnitudes. The weights of different bodies are to each other in the compound ratio of their magnitudes and specific gravities. Hence it is obvious that of the magnitude, weight, and specific gravity of a body, any two of these being given, the third may be found. Ex. 1. The weight of a marble statue being 748 pounds avoirdupois, required the number of cubic feet, &c., which it contains, the specific gravity of marble being 2.742. Since a cubic foot of marble weighs 2742 ounces, we have, water being taken as 1000, As 2742 : 748 X 16 : 1, 436 feet. Ex. 2. Required the weight of a block of granite whose length is 63 feet, and breadth and thickness each 12 feet, the specific gravity of granite being 2-625. Here 63 X 12 X 12 = 9072 feet then again, As 1: 9072 2.625 : 23813900 ounces, or 664 tons 9 cwt. A body immersed in a fluid will sink if its specific gravity be greater than that of the fluid if it be less, the body will rise to the top, and be only partly immerged; and if the specific gravity of the body and fluid be equal, it will remain at rest in any part of the fluid in which it may be placed. When a body is heavier than a fluid it loses as much of its weight when immersed as is equal to a quantity of the fluid of the same bulk or magnitude. If the specific gravity of the fluid be greater than that of the body, then the quantity of fluid displaced by the part immerged is equal to the weight of the whole body. And hence, as the specific gravity of the fluid is to that of the body, 80 is the whole magnitude of the body to the part immerged. The specific gravities of equal solids are as their parts immerged in the same fluid. The specific gravities of fluids are as the weights lost by the same immerged solid. To find the specific gravity of a body.-This may be done generally by means of the hydrostatic balance, which is contrived for the easy and exact determination of the weights of bodies, either in air or when immersed in water or other fluid, from the 2200. difference of which the specific gravity of both the solid and fluid may be computed D B d 1. When the body is heavier than water.-Weigh it both out of water and in water; then say, as the weight lost in water is to the whole or absolute weight, so is the specific gravity of water to that of the body. To do this, suspend the body by a hair to the short arm of the hydrostatic steelyard represented in Fig. 2200. Then weigh it in the air, by sliding it on this arm, until it balances any convenient weight hung at A; the long arm being graduated into any convenient number of equal parts. Then immerse the body in water, and weigh it by sliding the weight from A to C. Then as the division between A and C, is to the whole number of divisions on A B, 80 is unity to the specific gravity of the body with reference to the fluid in which it was immersed. 2. When the body is lighter than water.-In this case attach to it a piece of another body heavier than water, so that the mass compounded of the two may sink together. Weig the denser body and the com- pound body separately, both out of the water and in it; and find how much each loses in the water by subtracting its weight in water from its weight in air; and subtract the less of these remainders from the greater: then use this proportion, as the last remainder is to the weight of the light body in air, so is the specific gravity of the water to the specific gravity of the body. 3. When the specific gravity of a fluid is required.-Take some body of known specific gravity; weigh it both in and out of the fluid, and find the loss of weight in the fluid, by taking the difference of these two; then say, as the whole or absolute weight is to the loss of weight, so is the specific gravity of the solid to the specific gravity of the fluid. By a fortunate coincidence it happens that a cubic foot of rain-water weighs 1000 avoirdupois ounces; and, consequently, assuming this as the specific gravity of rain-water, and comparing all other bodies with this, the same numbers that express the specific gravity of bodies will denote the weight of a cubic foot of each in avoirdupois ounces. Specific Gravities of different Bodies. Metals. Ounces. Ounces. Copper, not hammered 7788 Antimony, crude 4064 the same wire-drawn 8878 glass of 4946 ore of soft copper, or natural ver- molten 6702 digris 3572 Arsenic, glass of, natural 3594 Gold, pure, of 24 carats, melted, but not molten 5763 hammered 19258 native orpiment 5452 the same hammered 19362 Bismuth, molten 9828 Parisian standard, 22 car, not ham'd. 17486 native 9020 Iron, cast 7207 ore of, in plumes 4371 bar, either hardened or not 7788 Brass, cast, not hammered 8396 Steel, neither tempered nor hardened 7838 ditto, wire-drawn 8544 hardened, but not tempered 7840 cast, common 7824 tempered and hardened 7818 Cobalt molten 7812 ditto, not hardened 7816 blue, glass of 2441 Iron, ore prismatic 7355 Digitized by Google GRAVITY, SPECIFIC. 911 Ounces. Ounces. Iron, ore specular 5218 Pearl, virgin oriental 2684 ditto, lenticular 5012 Pebble, onyx 2664 Lead, molten 11352 stained 2587 ore of, cubic 7587 Prasium 2581 ditto, horned 6072 Sardonyx, pure 2603 ore of black-lead 6745 Schorl, octabedral 3226 ore of white-lead 4059 tourmalin of Ceylon 3054 ditto ditto vitreous 6558 antique basaltes 2923 Manganese striated 4756 Brazilian emerald 3156 Molybdena 4738 Stone, paving 2416 Mercury, solid or congealed 15632 cutlers' 2111 fluent 13568 grind 2143 precipitate, red 8399 mill 2484 brown cinnabar 10218 red cinnabar 6902 Various Stones, Earths, dc. Nickel, molten 7807 Alabaster, oriental white 2780 ore of, called Kupfer-nickel of Saxe. 6648 ditto semi-transparent 2762 Platina, crude, in grains 15602 yellow 2699 purified, not hammered 19500 stained brown 2744 ditto hammered 20337 veined 2691 ditto wire-drawn 21042 Amber, yellow transparent 1078 ditto rolled 22069 Ambergris 926 Silver, virgin, 12 deniers, fine, not hammer'd. 10474 Amianthus, long 909 ditto, hammered 10511 short 2313 Tin, pure 7291 Asbestos, ripe 2578 ore of, red 6935 starry 3073 ore of, black 6901 Basaltes from Giants' Causeway 2864 ore of, white 6008 Bitumen of Judea. 1104 Tungsten 6066 Brick 2000 Uranium 6440 Chalk 2790 Wolfram 7119 Gypsum, opaque 2168 Zinc, molten 7191 semi-transparent 2306 Glass, green 2642 Precious Stones. white 2892 Beryl, or aqua-marine oriental 3549 bottle 2733 ditto, occidental 2723 fluid 3329 Chrysolite of the jewellers 2782 Granite 2613 to 2956 of Brazil 2692 Hone, white razor 2876 Crystal, pure rock 2653 Lapis nephriticus 2894 Diamond 3530 Lazuli 3054 Brazilian 3444 Hæmatites 4360 Emerald of Peru 2775 Calaminaris 5000 Garnet 4063 Judaicus 2500 volcanic, 24 faces 2468 Manati 2270 Girasol 4000 Limestone 3179 Hyacinth, common 3687 Marble 2700 Jargon of Ceylon 4416 Obsidian stone 2348 Quartz 2624 to 8750 Peat, hard 1329 Ruby, oriental 4283 Phosphorus 1714 Brazilian 3531 Porcelaine, Sevres 2146 Sapphire, oriental 3994 China 2385 of Puys 4077 Porphyry 2750 Brazilian 3131 Pyrites, coppery 4954 Spar, white sparkling 2595 ferruginous cubic 3900 red ditto 2438 ditto, round 4101 green ditto 2704 ditto, of St. Domingo 8440 blue ditto 2698 Serpentine 2500 green and white ditto 3105 semi-transparent, fibrous 3000 adamantine 8873 Slate, common 2672 Topaz, oriental 4011 new 2854 pistachio ditto 4061 black-stone 2186 Brazilian 3586 flesh polished 2766 Vermilion 4230 Stalactite, transparent 2324 opaque 2478 Silicious Stones. Stone, pumice 915 Agate 2620 prismatic basaltes 2722 Chalcedony, common 2616 touch 2415 Cornelian 2612 common 2520 Flint 2594 rag 2470 Jade, white 2950 rotten 1981 Jasper 2359 to 2816 hard paving 2460 Opal 2114 Sulphur, native 2033 Digitized by Google 912 GRAVITY, SPECIFIC. Ounces. Ounces, Sulphur, molten 1991 Wine, Bourdeaux 994 Talc, black crayon 2089 Madeira 1038 yellow 2655 Port 997 black 2900 Canary 1033 white 2704 Liquors, Oils, dc. Resins, Gums, Animal Substances, &c. 1841 Aloes, socotrine 1380 Acid, sulphuric hepatic 1359 ditto, highly concentrated 2125 nitric Asafœtida 1328 1271 Bees-wax, yellow 965 ditto, highly concentrated 1580 white 969 muriatic 1194 Bone of an ox 1656 red, acetous 1025 Butter 942 white, acetous 1014 distilled ditto Calculus humanus 1700 1010 fluoric ditto 1240 1500 acetic ditto 1434 1063 1558 Camphor 989 phosphoric formic 994 Copal, opaque 1149 Madagascar 1060 Alcohol, commercial 837 Chinese 1063 highly rectified 829 Crassamentum, human blood 1126 mixed with water, Dragon's blood 1205 15-16ths alcohol 853 " Elemi 1018 14-16ths 867 13-16ths " 882 Fat, beef 923 " Galbanum 1212 12-16ths 895 " Gamboge 1222 11-16ths 908 10-16ths " Gum, ammoniac 1207 920 Arabic 1452 9-16ths " 932 Euphorbia 1124 8-16ths " 943 " seraphic 1201 7-16ths 952 6-16ths " 960 tragacanth 1316 " bdellium 1372 5-16ths 967 " 973 Scammony of Smyrna 1274 4-16ths 3-16ths " 979 Gunpowder, shaken 933 836 2-16ths " 985 in a loose heap " solid 1745 1-16th 992 897 Honey 1450 Ammoniac, liquid Beer, pale 1023 Indigo 769 brown 1034 Ivory 1826 Cider Juice of liquorice 1723 1018 of Acacia 1515 Ether, sulphuric 739 nitric Labdanum 1186 909 muriatic Lard 948 730 acetic Mastic 1074 866 Myrrh 1360 Milk, woman's 1020 cow's Opium 1336 1032 Serum of human blood 1030 ass's 1036 ewe's 1041 Spermaceti 943 goat's Storax 1110 1035 Tallow 942 mare's 1034 cow's clarified 1019 Terra Japonica 1398 Oil, essential, of turpentine 870 Wax, shoemakers' 897 ditto, of lavender 894 ditto, of cloves Woods. 1036 ditto, of cinnamon 1044 Alder 800 of olives 915 Apple-tree 793 of sweet almonds 917 Ash, the trunk 845 of filberts 916 Bay-tree 822 linseed 940 Beech 852 of walnuts 923 Box, French 912 of whale 923 Dutch 1328 of hempseed 926 Brazilian red 1031 of poppies 924 Cedar, wild 596 rapeseed 919 Palestine 613 Turpentine, liquid 991 Indian 1315 Urine, human 1011 American 561 Water, rain 1000 Citron 726 distilled 1000 Cocoa-wood 1040 sea (average) 1026 Cherry-tree 715 of Dead Sea 1240 Cork 240 Wine, Burgundy 992 Cypress, Spanish 644 Digitized by Google GRINDING MACHINE. 913 Ounces. Ounces. Ebony, American 1331 Medlar 944 Indian 1209 Mulberry, Spanish 897 Elder-tree 695 Oak, heart of, 60 years old 1170 Elm, trunk of 671 Olive-tree 927 Filbert-tree 600 Orange-tree 705 Fir, male 550 Pear-tree 661 female 498 Pomegranate-tree 1354 Hazel 600 Poplar 383 Jasmine, Spanish 770 white Spanish 529 Juniper-tree 556 Plum-tree 785 Lemon-tree 708 Quince-tree 705 Lignum-vitæ 1833 Sassafras 482 Linden-tree 604 Vine 1327 Logwood 913 Walnut 671 Mastick-tree 849 Willow 585 Mahogany 1063 Yew, Dutch 788 Maple 750 Spanish 807 Weight and Specific Gravity of different Gases. Fahrenheit's Thermometer 55°. Barometer 30 inches. Specific Gravity. Wt. Cub. Foot. Atmospheric air 1.2 5250 grains. Hydrogen gas 01 43.75 Oxygen gas 1.435 627812 Azotic gas 1.182 517125 Nitrous gas 1-4544 636383 Ammoniac gas 7311 319832 Sulphureous acid gas 2-7611 1207978 In this table the weights and specific gravities of the principal gases are given, as they correspond to a state of the barometer and thermometer which may be chosen for a medium. The specific gravity of any one gas to that of another will not exactly conform to the same ratio under different degrees of heat and other pressures of the atmosphere. And if common air, the standard, be taken at unity (1), chlorine oxymuriatic acid will be 2.500, and hydrogen 0.069 whence we conclude that chlorine is 21 times heavier than hydrogen, and this last is 14 times lighter than common air. For, to arrive at the absolute weight of the gases, we have only to assume 100 cubic inches of atmospheric air to weigh 30.5 grains, and as there are 1728 cubical inches in a cubic foot, the simple proportion 100 : 30-5 grains : : 1728 : 527-04 grains, the weight of a cubic foot of common air. And for any other gas, it is only necessary to observe its specific gravity in relation to that of common air; for example, chlorine has a specific gravity of 25; hence a cubic foot of chlorine will weigh 21 times as much as a cubic foot of common air; for 52704 X 21 = 13176 grains, the weight of a cubic foot of chlorine. To determine the weight of any gas lighter than common air, we also compare their specific gravities thus, the specific gravity of ammoniacal gas is 0-5, and that of atmospheric air being = 1, we have 1 : 0.5 : 1728 : 8640, or simply 1728 ÷ 2 = 864 grains, for the weight of a cubic foot of ammoniacal gas; and so on for all the other gaseous bodies, as they are arranged in the following table. If atmospheric air be taken at unity (1), then the various gases will stand as under :- Atmospheric air 1-000 Hydrogen 0.69 Ammoniacal gas 0.500 Muriatic acid 1.284 Carbonic acid 1527 Nitric oxide 1041 Carbonic oxide 0.972 Nitrogen 0.972 Carburetted hydrogen 0972 Nitrous acid 2-688 Chlorine 2.500 Nitrous oxide 1527 Chlorocarbonous acid 3-472 Oxygen 10111 Ohloroprussic acid 2.152 Phosphuretted hydrogen 0-902 Cyanogen 1805 Prussic acid 0.987 Euchlorine 2·440 Subcarburetted hydrogen 0-555 Fluoboric acid 2871 Subphosphuretted ditto 0972 Fluosilicic acid 3632 Sulphuretted ditto 1.180 Hydriodic acid 4846 Sulphureous acid 2222 GRINDING MACHINE, double. By Messrs. Nasmyth, Gaskell and Co. The object of the machine represented by Figs. 2201, 2202, and 2203, is to grind up the faces of the different parts of machinery, when a great surface is required to be made perfectly smooth; to accomplish which, this contrivance has been used. Figs. 2201, 2202, and 2203, severally show a side elevation, an end elevation, and a plan of a double- face grinding machine, the one side being a repetition of the other. To the two cast-iron cross-frames a an 115 Digitized by Google 914 GRINDING MACHINE. are bolted two large plummer-blocks for carrying the main shaft, having at each extremity the circular frames divided into twelve compartments, in which are placed the grinding stones f, each being adjust- able by the small set screws m round its circumference. On the top of the cross-frames a, are placed two longitudinal frames bb, made also of cast-iron, for supporting the long bed-frames cc, and also the self-acting apparatus furnished to this machine. Two motions, the one at right angles to the other, are given by the alides d working along the beds c, and also the face-plates e for carrying the work, by which it is brought into contact with the grinding stones. Pits are made to allow the wheels, for car- rying the stones, to work in. 2201. BR HP & MAY 7 c Я 6 f b a 976 & B The self-acting motion given to the work being faced, by means of which it slides along the bed c while the grinding stones are revolving on their axes, is thus obtained: on the main shaft next to the driving-riggers or pulleys g, is a worm l, which, as it revolves, works a worm-wheel represented by the dotted lines in Fig. 2202, thus communicating the motion to the upright spindle from this it is carried by the bevel-wheels to the spindle running horizontally the whole length of the machine, having at each extremity three small bevel-wheels. The action of this apparatus is thus, supposing the slide to be travelling in the direction towards the small bevel-wheels, two of which are required for the pur- pose, while the third or outer one runs freely on the spindle, without producing any effect, the small 2202. 8 R h 2 m b I b a a 8 clutch being disengaged from it; on the travelling slide d is fixed a stud or pin h'; a long rod h of the same length as the bed c, is movable in two stud-bearings fixed to it. As the slide d travels, the pin h' comes into contact with a second stud or pin adjusted to any position on the rod h, according to the length of the motion required, which must naturally press it forward, and thereby throw out the clutch on the end of the spindle, which being shifted from one bevel-wheel to the other, disengages that which had been at work before, while it engages the outer one, that had been running loosely on the spindle; by this curious contrivance, the screw for working the slide revolves in a contrary direction, and instead of drawing the slide d towards it, sends it back. A counterbalance weight n is connected to the ex- tremity of the rod h, for keeping it in a steady position while this operation is being performed. The tappet-wheel k, fixed on the end of the screw for advancing the other slide e, is also worked by a pin on the same rod h, whereby the work is advanced to the face of the grinding stone; it is on the upper part of the slide e that the work is fixed. A substantial foundation, consisting of stone-work, is prepared for receiving the two frames aa, and to which they are firmly bolted down by strong hold- ing-bolts. Digitized by Google GRINDING MILL. 915 Another mode of performing this same operation might be adopted, by fastening a whole grindstone into the chucks, and passing a bolt through two surface plates of two feet diameter each, one on the middle part of each face of the grindstone, by which means they would be more effectually secured in their places. 2203. i 13 b of to c m A a a h e € 9 e . . References to Figs. 2201, 2202, and 2203. a, cross-frames or standards. m Rods for reversing motion by means of tappet A' and b, Longitudinal frames. i, Clutches. [clutches d. c, Bed-plates. j, Bevel-wheels for working slides. d, Cross-slides. k, Tappet-wheels. a Slides or face-plates for carrying work. 1, Worm on main shaft for working bevel-geer j. f, Grindstones. m. Screws for setting stones. 8, Driving-riggers. m, Counterbalance weights. GRINDING MILL, Bogardus' Eccentric. This is a machine the invention of which is due to Mr. Bogardus, of New York. The following are some of the advantages of mills worked on this principle:- 1. The peculiar motion of the plates will, of itself. discharge the ground substance, so that many sub- stances can be ground thereby which would altogether choke other mills. 2. In other mills, argiven point in one of the plates continually describes the same circle on the other; but in this milkst traverses on the other plate at an infinite variety of angles, every point within two concentric circles apart from each other, twice the distance of the centres of the plates, thereby rendering the wear and tear of the plates uniform, and preserving the grinding action of every point. 3. In other mills, the grinding power of each point increases with its distance from the centre; but in this mill, every point from the centre to the circumference has the same grinding power. A con- siderably smaller mill will, therefore, effect a given purpose, and the eccentric mill is therefore more portable than other mills. 4. The ever-changing action of the mill, and the quick discharge of the substance ground, prevent it from becoming heated, so that the eccentric mill may be profitably employed in grinding substances which, in other mills, would be either spoiled or deteriorated in quality-or, by their melting, be im- possible to be ground. If other mills were driven with that speed which can be safely applied to the eccentric mill, they would be made red-hot in a few minutes. These mills have been successfully introduced for the following purposes:-Hulling rice, coffee, and olives. Grinding grain of all kinds; paints of all kinds, in water or in oil; iron, zinc, copper, and gold ores, plumbago and manganese, bones for manure, and bones for refining sugar, flint and quartz, char- coal, plaster, putty, printers' inks, drugs and dye-stuffs, snuffs, mustard, coffee, spices, loaf sugar, starch, gums, resins, asphaltum, India-rubber, flax-seed, and oil-cake, &c., &c. Of the substances enumerated, some cannot be ground at all by other mills; in short, the eccentric mills are more economical in the power required to drive them, and in the labor of tending them; they are less costly for the work they do, and more portable; they are capable of being applied to purposes for which other mills are useless; and the tear and wear is trifling. The mill should run to the right, and make not less than three hundred revolutions per minute. Nearly any quantity can be ground by increasing the speed. The mill is regulated to grind fine and coarse by the under-screw, on which the end of the shaft revolves; turning the screw to the left, will bring the plates together and cause the mill to grind finer. The regulating screw is held firmly in any posi- tion by a small screw placed against its side. There are three reservoirs, which should be well supplied with oil. The first is on the top of the upper plate: two or three table-spoonfuls of oil should be poured into this reservoir through a small hole made in the top of the mill for that purpose. The second res- ervoir is the box, through which the man shaft passes; this is just under the spout of the mill. This reservoir should be filled with tallow so that it may supply itself. There is also a small hole in the back part of the mill, through which oil can be poured into this reservoir, if requisite. The third reser- Digitized by Google 916 GRINDSTONES. voir is the step in which the main shaft revolves, that may be filled with oil. The feeding is regulated by a shoe acting against the tube of the upper plate, which causes the shoe to vibrate; this, with the slide in the hopper, regulates the quantity fed into the mill. Screw holes are made round the rim of the hopper, for the purpose of extending its size to any dimensions required. The mill can be taken apart, cleaned, and the plates changed (if necessary) in a few minutes. Fig. 2204 represents a front elevation of one of the mills applied by Mr. Bogardus to the grinding of moist or liquid substances. 2204. U 0 A is an upright cast-iron frame, carrying three projecting brackets, as seen at B. The upper revolv- ing plate is seen at C; it is driven by the pulley D; beneath this plate is placed the lower separate re- volving plate, at a distance from it to suit the nature of the material to be ground. The centre of mo- tion of the latter plate is placed about an inch out of the centre of the upper one; it is driven merely by friction generated by the abrasion of the substance in process of grinding between the plates. An adjusting screw F is placed beneath the lower plate for the purpose of setting the latter at the proper distance from the upper plate. GRINDSTONES. A well-known tool, used in nearly all branches of the mechanic arts for grind- ing to an edge, point, or face the various tools used in manufacturing, and also in various hardware manufactories for reducing metallic surfaces. Digitized by Google GRIST-MILL. 917 Grindstones vary in size according to the purpose for which they are intended. In grinding to a smooth surface large saws, axes, scythes, swords, and all heavy cutlery, heavy stones are used, weighing sometimes from two to three tons; these are secured on wrought-iron shafts, and the workman applies his weight to the article on the stone. Grindstones are brought to this country from France and England, and they are obtained in Nova Scotia, Ohio, and elsewhere in this country in small quantities. The sandstone from which they are almost entirely composed is split out of the quarry by wedges, and dressed on the sides by chisel and hammer. Many of these require no side dressing. A square hole, in proportion to the weight, is cut in the centre, and the stone marked from this centre; the face is then chipped down, as near as may be, to its intended circumference, and sent to market. After mounting and wedging the stone upon its axle, it is chipped off at the prominent points and then rough-turned. The heavy stones in particular requiring great care in the hanging and trimming, that they may run smoothly. GRIST-MILL, Barber's Patent Metallic. This is the invention of Mr. Asa Barber, and patented in June, 1847. The mill is capable of grinding corn in the ear, and can also grind all other kinds of grain; 2205. c B I E и D K F A and although it has metal grinders, never requiring to be sharpened, it is 80 constructed and the cooling surfaces so arranged that the grain is not heated. By a two-horse power it it capable of grinding from eight to ten bushels per hour. 2206. o V Description. A is the frame. B is the hopper. C are stays connected with the longitudinal beam of the frame supporting the hopper. E is a large revolving cylinder, covered with a wire cloth Digitized by Google 918 GUAGE for bolting. F is a fly-wheel. G is a band-wheel or pulley, driven by a band from the main driver to propel the shaft H, which has a small pinion on it meshing into cogs or a large cog rim I of the large cylinder E. J is a small pulley on H, which drives by a band the shaft (not seen) of an interior scraper. K K are two angular boards, to guide the ground meal into the granary. This is a sectional view, and does not show all the interior, but merely the grinding surfaces. B is a revolving iron grooved roller, made of a series of cast grooved rings secured to the shaft. This shaft is made to sit and revolve in 0, a concave iron grooved bed which is stationary. D is a shoulder with teeth to grind the cob as it leaves the hopper before being submitted to the grinding operation of the revolving roller B. Suppose these two sections to be placed in the inside of E, with B revolving above and in the concave bed O. Now the grain enters in the hopper, and the revolving roller being set in mo- tion, it will easily be perceived that the grain will be carried into and between the roller and the bed, and discharged through the channels or grooves on C. Still the meal thus ground has to be bolted. This is done in a most simple manner. As E is revolved the fine meal falls through the bolting-cloth at the bottom, and the coarse is carried round and falls down into the mill above, to be ground over again By this way of grinding the revolving grinder and the bed need not be in such close contact as other grinding mills must be, and the large revolving surface of E keeps the meal perfectly cool and allows the interior of the mill to be quite open to the atmosphere. There is a scraper which is revolved by the band from I, at the right of Fig. 2205, which scraper keeps the grooves of the roller or bed from getting clogged. GUAGE, STEAM. An instrument for showing the pressure of steam or other fluids. For a full description of Stillman's guages, see article MANOMETER. 2207. 0 L U P G H c D E F A S GUAGE. Steam and Water-safety Guage, for Steam-boilers, patented by A. S. LYMAN. Two of these guages are exhibited in Fig. 2207, which, though very similar in construction and principle, are intended for very different purposes-the one to indicate the pressure of the steam, and the other as a water-guage, giving alarm when the water falls below the proper level. In these guages, which act by the condensation of air in a glass tube, it is well known, as ordinarily constructed, that the divisions on the scale are all dissimilar, by reason of the glass tube being parallel throughout. To indicate one atmosphere, the air is forced into one-half the length of the tube, the mercury rising a corresponding distance; the next atmosphere being indicated by one-half the preceding rise of the mercury. By constructing the glass tubes E and F, of a form as shown in the figure, the divisions on the scale may be brought to approximate equal distances. The bulbs E and F are nearly filled with colored alcohol, which prevents the mercury from rising above 0 in the scale, and by its oxide defacing the Digitized by Google GUAGE. 919 inner surface of the glass. The guage F is that for indicating the steam pressure, and is connected by the pipe h with the steam space in the boiler. This terminates in a chamber L, from which a pipe G depends, communicating with the mercury cup I of the guage. This pipe always contains a column of water, which remains cold, and prevents the communication of heat to the guage, to avoid its fracture from sudden expansion, as is frequently the case in ordinary guages. The cham- ber L has also a valve, in which, when the pressure of steam in the boiler becomes excessive, or above a certain point, it will blow off through a steam-whistle. The other guage E, instead of communicating with the water space, is connected by the pipe C with a steam-tight box S. filled with water and placed above the flue B of the boiler A. A column of water in the pipe D also intervenes between the steam and the mercury in the cup K. The connecting chamber o has a siphon pipe P, filled with water, which is pressed upwards by the steam against a flexible diaphragm Q of vulcanized India-rubber, or other suitable material. On this diaphragm a plunger I, with an area six or eight times larger than that of the valve M, rests, and according to the pressure of the steam will exert more or less upward force on the lever R, and when in excess it will exert a force on the lever M, and assist in raising that lever, should it accidentally adhere to its seat, thereby preventing the possibility of an accident from such cause, the lever R being unerring in its action, by the means described. It is well known that when the water falls too low in the boiler, the steam is sometimes heated 80 as to melt common solder in the steam-pipe; that is, to 475°, but not being saturated with water, it presses no higher than ordinarily. This box S, supplied with water and immersed in such steam, would com- press the air in the water-guage indicator E with a force of over five hundred pounds per inch, as the water or steam in this box and its guage cannot escape. But as soon as the point considered as the limit of safety is reached, whether caused by low water or high pressure of steam, the pressure of the water on the diaphragm Q raises the valve M, as stated, and gives the alarm. The pipes containing the cold water columns G, D, and P are lined with a thick coating of India-rubber, in order to prevent the pipe bursting from expansion by frost. A thermometer U is appended to these guages for refer- ence in subtracting from, or adding to, the indicated pressure, to compensate for the expansion and contraction at the different degrees of heat, 72° temperature being assumed as zero, from which, for every eight degrees below that temperature, one pound is deduced, as exhibited by the sign minus," and vice versd, a like addition is made, as shown by the sign "plus," by which the true degree of pressure in the boiler is obtained. GUAGE, TELEGRAPHIC STEAM-Dun's. Fig. 2208 represents so much of a steam-boiler as is necessary for our description. A tube descends into the boiler just below the proper water-line, and is secured to the sides. The branch C is fixed to the upper end, into which two tubes, B and N, are fixed. The tubes and the branch C are filled with mercury to a fixed level at the proper temperature of the boiler. In the tube N is a wire set in such a manner that its lower end, which should be of platina, will come just above the quicksilver in the tube when it stands at the height which will be caused by 2908. silm- 0 the heat which should produce the pressure of steam desired in the boiler, and at starting, the appara- tus is to be adjusted when the steam is at the working pressure in the boiler; and when the wire is so adjusted it is fixed by the set-screw O. From the upper end of the wire in the tube N, proceeds the wire to the bell apparatus PQ for the engineer, and at RS in the office; thence the wire proceeds to the battery A L. By this arrangement. when the heat in the boiler rises above that which is proper for producing the desired pressure of steam in the boiler, the quicksilver expands, and coming in contact with the platina wire, completes the electric circuit, and the bells will continue to ring. If desired, the tube N may have a graduated scale to indicate the temperature at sight. Digitized by Google 920 GUNS. GUDGEON. The extremity of a horizontal shaft of a water-wheel, that runs in the collar. Every gudgeon, in order to avoid unnecessary friction, should be made as small in diameter as possible, con- sistently with the requisite strength and durability. The cube root of the weight of a water-wheel in hundred weights, is nearly equal to the diameter in inches of a cast-iron gudgeon sufficiently strong to support such wheel. For wooden water-wheels, multiply the diameter in feet by the width also in feet, to which add the square of half the diameter; the cube root of the sum will be nearly equal to the diameter of the gudgeon in inches. It has been inferred from experiment that gudgeons of the same size, of cast and of wrought iron, are capable, at a medium, of sustaining weights without flexure, in the proportion of 9 to 14. See GEERING, page 841. GUNS. Every best finished gun usually passes through fifteen or sixteen hands, each of which con- stitutes almost a distinct trade; although two or three branches are often combined, or subdivided, according to the extent of business. They may be arranged in the following order:- 1. Barrel forger; 2. lock and furniture forger; 3. barrel borer and filer; 4. lock filer; 5. furniture filer; 6. ribber and breecher; 7. stocker 8. screwer-together; 9. detonator; 10. stripper and finisher; 11. lock finisher; 12. polisher and hardener; 13. engraver; 14. browner; 15. stock polisher. The barrel-making being also divided into several branches. The first process in the manufacture of musket or common barrels is the making what are techni- cally called skelps. The skelp is a piece of iron about one foot long, but thicker and broader at one end than at the other; and the barrel of a musket is formed by forging out such pieces to the proper dimensions, and then folding or bending them round into a cylindrical form until the edges overlap, so that they can be welded together. It is then placed in a furnace, raised to a welding heat, and taken out, when a triblet or cylinder of iron being placed in it, it is passed quickly through a pair of rollers. The effect of this is, that the welding is performed at a single heating, and the remainder of the elonga- tion necessary for bringing it to the length of a musket-barrel is performed in a similar manner, but at a lower temperature. This method of welding is far less injurious to the texture of the iron, which is now exposed only once, instead of three or four times to the welding heat. The barrels for fowling-pieces are of various kinds, as stub, stub-twist, wire-twist, and Damascus-twist, and sometimes a combination of the two latter ones, as well as another description called stub-Damas- cus. These are the best varieties, but a number of inferior kinds are made, which are only employed for very common guns. In order to make stub-iron, old horse-shoe nails, called stubs, are collected, then packed closely to- gether, and bound with an iron hoop, so as to form a ball about ten or twelve inches in circumference which, being put into a furnace or forge-fire, and raised to a welding heat, is united by hammering, and drawn out into bars of convenient lengths, for the purposes intended. This method is adopted for the locks, furniture, and breechings of all best guns, and is to a certain extent practised for barrels, though not so much as formerly, more expeditious methods being employed on a las ge scale. The most approved modern method of converting them into gun-barrels, (after carefully sorting and picking them, to see that no cast-iron or impurities are mixed with them,) is first to put about half a hundred weight into a large cast-iron drum or cylinder, crossed internally with iron bars, through the centre of which a shaft passes, which is connected by a strap with the steam-engine, and the revolution of the drum actually polishes the nails by their friction against each other; they are then sifted, by which every particle of dust is removed. The steel intended to be mixed with them is clipped by means of large shears, worked by the engine into small pieces, corresponding in size to the stubs, and afterwards cleansed by a similar process. About 40 lbs. are thrown on to the inclined hearth of an air-furnace, where they are puddled or mixed together with a long iron rod, and withdrawn in a mass called a bloom, almost in a state of fusion, to be welded under a hammer of three tons weight, by which it is formed into a long square block: this being put in, at another door of the same air-furnace, is raised to a bright red-heat, and drawn out under a tilt-hammer of a ton and a half weight, into bars of a proper size to pass the rollers, by means of which it is reduced to rods of the required size. The air- furnace having two doors prevents any loss of time, as the moment one ball of stubs is withdrawn, another charge is put in, and the two operations go on together, keeping both hammers employed. The iron thus produced is very tough, and free from specks or grays, but stubs are hardly ever used alone, as they were formerly, being too soft therefore, a portion of steel is mixed with them, which varies from one-eighth to one-half of the whole mass. It need hardly be remarked, that the advantage to be derived from the use of horse-shoe nails does not arise from any virtue in the horse's hoof, as some have imagined, but simply because good iron is, or ought to be, originally employed for the purpose, otherwise the nails will not drive into the hoof; and the iron, being worked much more, is freed from its impurities, which can only be effected by repeated workings. When gun-barrels are manufactured from stub-iron by a process similar to that of musket-barrels, they merely exhibit a mottled appearance on the application of acids. It is also usual to make what are called stub barrels from scrap iron cut into small pieces by means of shears worked by the engine. It would be difficult to define what scrap iron is, or what it is not, being composed of every thing in iron that has previously been manufactured, as well as of the cuttings from the various manufactories; these are sorted and employed in preparing iron of various qualities, known by the names of wire-twist, Damascus-twist, stub-twist, charcoal iron, threepenny skelp iron, twopenny skelp, &c. The object of preparing iron from small pieces, is to cross and interweave the fibres in every possible direction, and thus greatly to increase its tenacity. Very few plain stub barrels are now made, as iron of inferior quality, when twisted, finds a more ready sale. For the finest description of barrels, a cer- tain proportion of scrap steel, such as broken coach-springs, is cut into pieces and mixed with the iron by the operation called puddling, by which the steel loses a considerable portion of its carbon, and be- comes converted into mild steel, uniting readily with the iron, and greatly increasing the variegation and beauty of the twist. In whatever manner the iron may be prepared, the operation of drawing it out into ribands for twisting is the same. This is effected by passing the bars, while red-hot, between Digitized by Google GUNS. 921 rollers until extended several yards in length, about half an inch wide, and varying in thickness accord- ing to whichever part of the barrel it may be intended to form: these ribands are cut into convenient lengths, each being sufficient to form one-third of a barrel one of these pieces is made red-hot and twisted into a spiral form, by placing one end in the prong of an iron rod, which passes through a frame, and is turn 1 by a handle, the riband being prevented from going round without twisting by means of an iron ba. placed parallel to the revolving rod. The spiral thus formed is raised to a welding heat, and dropped on to a cylindrical iron rod, which being struck forcibly on the ground, (jumped,) the edges of the spiral unite, and the welding is then completed by hammering on the anvil: the other spirals are added according to the length of the barrel, and the forging is finished by hammering regularly all over. The ends of each spiral should be turned up and united at each junction of the spirals, to avoid the confusion in the twist occasioned by merely dropping one spiral on another; but this is rarely done. Wire-twist, of any degree of fineness, may be obtained by welding alternate laminæ of iron and steel, or iron of two qualities, together; the compound bar thus formed is drawn into ribands, and twisted in the same manner as the preceding. The operation of twisting the iron not only increases the beauty of the barrel, but adds considerably to its strength by opposing the longitudinal direction of the fibres to the expansion that takes place in the act of firing. The iron called Damascus, from its resemblance to the celebrated Oriental barrels and sword-blades, is now manufactured by welding 25 bars of iron and mild steel alternately, each about 2 feet long, 2 inches wide, and 1 of an inch thick; and having drawn the whole mass into a long bar, or rod, 1 of an inch square, it is then cut into proper lengths of from five to six feet; one of these pieces being made red-hot, is held firmly in a vice, or in a square hole, to prevent it from turning, while the other end is twisted by a brace, or by machinery, taking care that the turns are regular, and holding those parts which turn closer than others with a pair of tongs; the rod is by this means shortened to half its original length, and made quite round. If only two pieces are employed to form the riband, one is turned to the right, and the other to the left; these being laid parallel to each other, are united by welding, and then flattened; but if three square rods are used, the centre one is turned in a contrary direction to the outside ones, and this produces the handsomest figure. By these operations the alternations of iron and stecl change places at every half revolution of the square rod composed of twenty-five laminæ; the external layers winding round the interior ones, thus forming, when flattened into a riband, irregular concentric ovals or circles. The fineness of the Damascus depends on the number and thickness of the alternations; and the figure of the riband when brought out by acids resembles that of a curled ostrich feather; but when wound into a spiral form, and united on its edges by jumping, the edges bend round and the figure is completed. This is sometimes veneered on common iron; and they often wind a thin riband of Damascus, or superior iron, round iron of the worst quality; even gas tubing is considered good enough, when coated in this manner, to form gun-barrels of a very low price with a high-priced appearance. Stub Damascus is merely one square rod of Damascus iron twisted and flattened into the riband for forming the barrel. Damascus and wire-twist is a riband of each, twisted together to make a greater variety but there is no quality so good as the best regular stub-twist. The Swedish iron, known by the mark CCND, and coach-springs, form an excellent combination for Damascus barrels. The next operation to forging is rough boring this is usually performed by machinery. A long square bit, attached to a rod, revolves with great rapidity, while the barrel is pressed forward by a crooked lever, one end of which the work- man holds, and passes the other end along a series of nails or pegs, driven into the top edge of the trough or bench, on which the barrel is placed, thus forcing the barrel forward along the boring-bit. Water is kept constantly flowing over the barrel during the process, otherwise the heat generated by the friction would soon soften the bit, and render it useless. The outsides are then ground on very broad stones turned by the engine; the workman site on a kind of wooden horse, firmly chained to the floor; a sloping board, nearly in contact with the grindstone, is placed before him, against which he leans, and rests the barrel; a long iron rod passes through the barrel, and projects at each end, suffi- ciently to form handles, and at the same time an axis, on which the barrel rotates more or less freely, according to the degree of pressure against the board. By moving it regularly sideways, the whole surface is ground over. It is evidently impossible to finish barrels with any great accuracy on a grind- stone, though most of the barrels that are made into guns in Birmingham are merely smoothed up after this process-an appearance of regularity being given to them at the muzzle by filing; but if trans- verse sections were made at different distances, they would be found very unequal in substance, as is always the case with musket and other common barrels, although some of the grinders are able to finish with considerable accuracy. It is in the ground and rough-bored state that most of the best bar- rels are sent to the finishing gun-smith, where, after being set perfectly straight, they are fixed on a movable carriage, which is drawn gradually forward along a level surface or railway, by means of a weight and pulleys; the boring-bit being fixed in a square hole in the axis of a fly-wheel which is turned by hand or by steam machinery, while the barrel slowly advances until the bit passes out at the opposite end to that at which it entered. The same square bit is made to enlarge the bore to the required size by the addition of a spill, which is simply a long thin piece of wood slightly taper, flat on one side and round on the other this being placed along one side of the bit, causes it to cut on two angles only, and the size of the caliber may be very gradually increased by the interposition of strips of writing-paper between the spill and the bit. After the barrel is correctly bored, the external part is turned in a lathe; a steel mandril being introduced at each end. The barrel is thus rendered perfectly correct and equal in every part. The barrel being tapped that is, screwed at the breech end, and the plug fitted, is now proved with a charge of powder proportioned to the weight of a leaden ball that fits the bore; this is always five or six times the ordinary load; besides which, it is forced with water, as minute defects, invisible to the eye and not affected by the proving, are thus easily detected. When false-breeched, ribbed, stocked, and screwed together, the barrel is bored for shootin 1, and smoothed out- side. Double barrels have a flat struck along the inner side of each, previous to laying them together; 116 Digitized by Google 922 GUNS. about four inches of the breech end is brazed, or hard soldered, and the remainder of the length soft soldered; the upper and under ribs being soldered on at the same time. The progressive stages of best gun-making may be briefly enumerated in the following order, sup- posing the lock and barrel to be already made. The lock and barrel being jointed to each other, (if the plan require it,) are given to the stocker, who lets them into the wood, which ought to have been pre- viously cut out of the plank at least two or three years, in order to be perfectly seasoned. The next work- man is the screwer-together, who lets in all the furniture and puts in all the screws: when this is done, the gun is detonated by another workman who fits the cock, and finishes the external part of the breeching. The barrel then goes to the barrel-maker to smooth and bore for shooting, and the gun is returned to the screwer-together. From him it passes to the stripper and finisher, who takes the whole to pieces and corrects any trifling errors of preceding workmen. The barrel is engraved, browned; an operation performed by producing successive coatings of rust on the surface, and brushing them off as they arise with a fine steel wire scratch-brush, until the required color be obtained, which usually takes a week, and is effected by a solution of metallic salts, combined with nitric ether; during this process the lock and furniture are polished, engraved, blued, and hardened, and the stock is oiled and polished. The hardening is performed by stratifying the various parts in an iron pan, with animal charcoal, pre- pared from bone and ivory-dust, or old shoes the whole is then exposed to a full red-heat for about an hour, or according to the size of the work, the pan is withdrawn from the fire, and the contents thrown into water. The surface of the iron becomes converted into steel by the absorption of the carbon, and beautiful colors are produced, the variegation of the color being affected by the quantity of the iron. The whole of the parts now return to the finisher, and the gun is completed. Rifled barrels are only used for throwing balls; they are always much thicker and heavier than other barrels, in order to render the aim more steady, as well as to admit of cutting the grooves with safety. Rifling consists in cutting a number of grooves in a spiral direction down the inside of a barrel, usually from seven to fifteen, dividing the interior surface into lands and furrows, the sunk parts being called the furrows, and the original surface left, the lands. In order to diminish friction, as well as to impress the ball more readily, the lands ought to be narrower than the furrows. The object of rifling is to give to the ball a rotation coincident with the line of its flight, and thus to correct the variable ro- tation which every ball, passing freely along a smooth-bored barrel, receives from its friction against the sides. The latter rotation never can coincide with the axis of the barrel, but must have a tendency to deflect the ball from the line of aim, according to the last impulse it may receive on quitting the barrel. Rifling also corrects any inequality in the density of the ball itself, by causing it to present alternately every part of its surface in its passage through the air. The usual method of rifling a barrel is by means of a long square bar, or rod of steel, which is twisted to the required degree of curvature, and then accurately ground with oil and emery in square holes, 80 as to render every portion of its length precisely equal in curvature, which operation requires consid- erable care and time. There are generally several rods of this kind to each rifling-bench, of different curves, 80 as to vary from three-fourths of a turn, to a turn and a half, in three feet; but should any other curve be required for experimental purposes, a new rod must be made for each, which becomes expensive. A rod of this description is correctly fitted into square holes, in two puppets, or heads, similar to those of a lathe, through which it can be freely drawn backward and forward by means of a cross handle, turning on its centre, to which is attached a dividing-plate to regulate the cuts or grooves. The barrel being bored perfectly true, is fixed to the end of a long bench opposite to, and in a direct line with, the rifling-rod at the other end. A piece of wood is turned to fit the barrel, in which a longitu- dinal groove is sunk to receive the cutter, which is made of tempered steel, and has ten or twelve sloping teeth in it. The piece of wood screws on to the rifling-rod by means of an iron ferrule; and at the commencement the teeth of the cutter only project very slightly beyond the surface of the wood. The cylinder of wood being entered into the barrel, the rifling-rod is pushed forward, and the projecting teeth of the cutter make a faint groove in a spiral direction down the inside of the barrel: the rod is worked backward and forward, until the teeth cease to cut, when the wood is withdrawn, and the rod turned an equal division of a circle by means of the dividing-plate, according to the number of grooves intended to be made: it is again entered, and another faint groove cut, and so on, until all the grooves are sunk to the same depth as the first. The wood is again withdrawn, and the cutter elevated a little, by taking it out of the groove in the wood, and placing underneath one or two slips of writing- paper soaked in oil; the cutter being replaced, the same operation is repeated as at first, and the grooves are gradually cut to the desired depth by the successive addition of thin slips of paper. When the rifling is completed, an iron rod is placed in the centre of the barrel, and melted lead poured in, 80 as to occupy about eight inches of the barrel; which lead, of course, takes a perfect cast of the interior, and is afterwards charged with oil and fine emery, and drawn up and down the barrel to polish the in- side, and remove the sharp edges left by the cutter. This operation is called draw-boring. A barrel can be as accurately rifled by this means as by any other, if the rods be correctly made; but an improvement in rifling machines has been made, by which the twisted rod is altogether dis- pensed with, and any required curvature given by a round rod. The principal advantage of this machine is the facility it affords of varying the curvature of the spirals at pleasure, from a straight line to two turns in three feet. A long square horizontal bar, which moves at each end in segments of a circle, is attached to the centre of the bench: this bar can be fixed at any angle of inclination: above this is a carriage freely traversing a railroad, and in the middle of this carriage is the dividing-plate and rifling-rod, the latter being made to turn by means of a pinion-wheel and rack-work, which slides on the horizontal bar as the carriage is pushed backward and forward; all the other arrangements of wood and cutter being the same as with the twisted rod. This machine is now generally employed for best rifles, and the old plan for military rifles. Machinery for the stocking of muskets has been adopted to a considerable extent in Europe and in Digitized by Google GUN-BARRELS. 923 this country; the barrel, lock, and furniture being entirely let into the wood by this means. The machinery for turning gun-stocks, used only, we believe, in the manufactory of muskets, differs but little from the lathe for turning irregular bodies; of which machine two examples are given under the article LATHE, which see. The following machine for turning gun-barrels is in general use in the foreign govern- ment workshops. GUN-BARRELS, Lathe for Turning. The object of this machine is to perform an operation entirely different from that produced by the several motions of the common turning-lathe. In this case, the curve required to be turned, on the whole length of the musket-barrel, is of an irregular form. This, as will be seen by Figs. 2209, 2210, 2211, and 2212, is effected by a very simple contrivance, as follows: 2209. 2210. FAY & GULICK. 61 The bed b is secured by three bolts a' a' a' to the side frames or standards a a, which have also fixed to them a tank o for receiving the waste oil and the iron turnings from the barrel being turned; on the top of the bed is placed the headstock frame i, for carrying the several parts of the machinery and on the mandril d are the tight and loose pulleys for giving motion to the machine: the centre c' of this mandril is adjusted by the back centre c". By the two sets of spur-wheels and pinions a double motion is produced, the forward by f and the backward by g, which are alternately worked by means of the small clutch h, thus giving a revolving motion to the square-threaded screw.j for advancing the tool- Digitized by Google 924 GUN-BARRELS. frame l along the barrel to be turned; this motion is made self-acting by means of two small bars PP fixed to the clutch-lever, having projecting pieces on their sides, with which the frame 1 comes in con- tact, and pressing against them, draws them and engages the clutch in the wheels for giving the oppo- site motion, while the object of the handle h' is to disengage it by hand. The spindle on which these small wheels are fixed runs freely in brass bearings fitted to the headstock i. On the opposite end of the machine is the headstock m, having an adjustable centre c', worked by the screw and handle m", and may be fixed in any required position by a small set-screw m""; this head can be moved along the bed b, to suit the length of any barrel n, and by the cross-bar and bolts m' may be secured to it. The musket-barrel to be turned is slid on the long bar or mandril n', which it fits very tightly. One end of this mandril is then dropped in the chuck e for carrying it round, while it is centred at both ends in the centre pieces c' c'. 2211. References of Figa. 2209, 2210, 2211, and 2212. a, Standards for supporting the bed. a, Bed of machine. a Tight and loose pulleys. d, Mandril with centre pieces c' c' and back centre c". a, Chuck. f, Spur-wheels and pinions for producing the forward mo- tion. 8. Spur-wheels and pinions for producing the backward motion. 4, Double clutch for changing the motions worked by the lever h'. is Headstocks. j, Square-threaded screw for working alternately the frame 1 for carrying the tool. k, Curved bar screwed to the side of bed. I Frame or chuck for carrying the tools r and securing the barrel in its proper position by means of the rack segment " and the vertical rack and weight i". m, Movable headstocks fixed to the bed by cross-bar and bolts m', the centre c working through it by the screw and handle m", which may be fixed by a set- screw m". m, Barrel being turned fixed on a long mandril or bar n'. o, Tank for receiving the turnings and waste oil, fixed to the standards. P, Sliding-bars fixed to the clutch at one end, by which means the machine is made self-acting. 2212. The most curious part of this machine is the frame 1 for holding the tools, and likewise the barrel of the musket being turned which latter operation is rendered rather difficult from the irregular shape of the barrel. Fig. 2211 shows a section, looking at the frame i, which consists of a back plate, on the face of which is a brass piate with the eccentric grooves shown by the dotted lines struck from different centres; between the latter plate and the back plate are four dies sliding in V'a, having ribs working in the above grooves, which, not being concentric, press them against the barrel, and thereby hold it firmly while the tools l' are turning it; but as the diameter of the barrel alters, it is necessary to loosen the dies, in order to allow the frame i, of which they form part, to slide along the bed on its V's. This is thus effected a curve bar or template k, suitable to the curve required by the barrel, is firmly screwed to the side of the bed, its upper edge k, Fige. 2211 and 2212, being of the shape of a V, on which the lower part of the rack 1"" slides, the upper part working at the same time in the V's screwed to the projection given to the back plate 1 by three screws. Thus the motion produced by the curve of the bar k is transmitted through the rack and the segment " to the grooved plate on which the latter is fixed; the result of this is the tightening or loosening the four dies, which must naturally be the case, as they have ribe working in the grooves, which they are compelled to follow. By the weight sus- pended from the vertical rack, any irregular motion that might take place is entirely obviated, it being kept firmly working on the upper surface of the curved bar k, while the small handle is provided for the purpose of raising it by hand when required. There are two tools l', Fig. 2211, fixed to one of the four dies already described; the one farthest from the frame 1 is for rough turning, while the other follows it, giving the finishing cut. A small bearing is provided on the bed for supporting the outer end of the screw j, and the standards are well secured to the floor by bolts for that purpose. Digitized by Google GUN-BARRELS. 925 This machine is capable of turning and finishing three barrels per hour; and similar machines are in use at the Armory of Enfield, and twelve of them, in conjunction with a complete set of machinery for making muskets, are at work in the Imperial Armory at Constantinople, besides machines for the French government, and for the Pasha of Egypt. Jennings' Patent American Rifle.-This weapon is, without doubt, the simplest, and at the same time one of the most perfect and effective of breech-loading arms. The gunpowder is contained within the ball, which is elongated for that purpose, something in the shape and appearance of a sewing thim- ble, closed at the end by a perforated cork. The range of the gun is very great, while from its sim- plicity it may be used for a long time without cleaning. The inventor is now engaged in simplifying the machinery of the lock still more, and arrangements have been perfected for manufacturing them on a large scale. The appearance of the gun is 80 like the common percussion gun that an engraving is not necessary. The following description and reference to the mechanism of the lock will be sufficient. The agent for the sale of these weapons is C. P. Dixon, 177 Broadway, New York. To raise the hammer or cock.-Put the right thumb on the hammer, and the right forefinger in the trigger-ring, and as the hammer is raised push the trigger-ring forward, or in other words, when the thumb and finger are 80 placed, the simple turning of the hand, the thumb back and the finger forward, brings down the toggle 4, Fig. 2213, which is behind the breech-pin, (this is necessary from the fact that a spring in the breech-pin 1 catches in the tumbler of the lock as the hammer is raised, breaking the breech-pin 2213. out from any stick there may be in the bar- rel,) and allows the breech-pin to be forced quite back; the cartridge can then be placed in the opening on the side of the lock, then, by pulling the trigger-ring 3 back, the car- tridge is forced into the barrel, taking at the same time a priming (percussion pill) from the magazine on top, (which will hold from 50 to 70 pills,) and throws up the toggle in the rear of the breech-pin, when a harder pull fires the piece, which is effected by forcing the fire from the pill, through the touch-hole into the hole in the centre of the cork, in the car- tridge. It is well to put in a cork or small wad to hold the first cartridge back against the breech-pin, though this is not absolutely necessary; after the first discharge this is not required, as the cork is left in the barrel, and is pushed out by each succeeding cartridge. To clean the rifle.-Knock the pin out that secures the barrel to the breech, take off the barrel and the lock-the forward screw to the lock having a slight mark to distinguish it from the other-then take out the separate parts. When cleaned, put in first the button with the countersunk side down, 2214. 2215. then the breech-pin, dropping it in 80 that the tail of the button will come between the two pins on the top of the breech-pin; then the pinion 2 with the dotted tooth in the last tooth of the breech-pin when it is clear forward, on which there is also a dot; then put in the trigger-rack, placing it as far back as it will go, then the toggle; then put on the lock, leaving the breech-pin clear forward, as only in this position will the end of the spring in the breech-pin fit into its place on the tumbler. The Prussian breech-loading rifle.-The Prussian rifle, known by the name of the Zund Nadel, (darting needle,) has a number of points about it very different from all other breech-loading fire-arms, but we will state three of them before describing the engravings, to make the description easier to un- derstand. First, it uses a different cartridge and no detonating powder, but a friction needle-darting needle, (zund nadel,) which pierces the bottom of the cartridge and ignites the powder by a friction combustible priming. All this is done inside, and it is certainly as efficacious in wet as in dry weather. Second, an air-chamber behind the cartridge, in which the expanded air acts to force out the ball. Third, the sliding breech-pin, and the manner of operating and fastening it in an inclined butt of the breech. Fig. 2216 is a view of the breech-pin separated from the barrel. Fig. 2217 is a longitudinal vertical section, showing the interior. Fig. 2218 is the cartridge. A is the picket bullet; B the friction combustible priming; C the paper- machie case. Fig. 2219 is a plan view of the rifle, and Fig. 2220 a side view. The same letters refer to like parts. here is a tube behind the breech of the barrel, forming a chamber, and there is a slot on its top for the Digitized by Google 26 GUN-BARRELS. breech-pin to slide in. The breech-pin can be taken out entirely by unscrewing the cap Y. This IS best seen in Fig. 2220: A is the barrel; it is enlarged at the breech to receive the breech-pin, the office of which is to open to put in the cartridge, and shut to enclose it perfectly, &c. B is the breech-pin with a short screw C, Fig. 2216, on its forward end, which, by a quarter turn, locks into the breech-butt of the barrel. G is a handle to operate the sliding breech-pin, which is of a tubular form. The breech- pin slides in the tube D. F is a projecting piece of the breech-pin, to guide the said pin when the cap Y is off and the pin put in the tube, also to guide it back and forth. The forward end H of the tube D is made of the form of the segment of a helix, 80 inclined that when the sliding breech-pin is pushed forward, after the cartridge is inserted in the breech-butt of the barrel, and then turned to the right to screw into the breech of the barrel, the forward shoulder of the projection F acting on the said inclined 2216. X 2218. 3 A' 2217. recess, will aid the thread in forcing in the breech-pin, and, during the discharge, will aid the screw- thread in resisting the recoil. In this way the breech-pin is held firmly in its place during the discharge of the piece-a very important combination indeed. The forward end of the breech-pin is a strong hollow air-chamber I, behind the cartridge, and the air contained therein is expanded by the combustion in the cartridge, and aids to force out the ball; this is in accordance with scientific experiments. In the centre of this hollow chamber is a projecting piece in which is drilled a centre hole, through which the darting steel-needle K projects and slides, Fig. 2217. This is the needle that pierces the cartridge and inflames the priming. The needle is secured to a small fly-spring carrier, something like that kind used in small guns for juveniles. L is this carrier; it has a coiled spring o abutting against its forward end, the dots, Fig. 2217. and abutting with its back end against a collar of the breech-pin, seen inside of the catch P of the carrier, which is attached by a screw to the head M of the needle. To load, the handle G is turned to the left, and the breech-pin drawn back in the top alot of the tube, when the carrier disk P is caught by the sear R of the trigger, the carrier held, and the cartridge is inserted in the butt of the 2219. c 2220. barrel. The breech-pin is then moved forward, and the shoulder turned into the inclined recess. By drawing the trigger S the carrier is disengaged, and the spring darts the needle K into the end of the cartridge to effect the discharge. U, Fig. 2216, is a ring of the tube, into which the breech-pin slides accurately, the said ring being placed forward of the disk P of the carrier. V is a bar which fite into the slot of the tube, and when the breech-pin is forced home and this bar pushed forward. it covers up the slot, and its forward end is fitted to enter a recess W in the breech-pin. When the breech-pin is locked in its place. and the bar V pushed in its place, there is thus a most effective bracing to prevent the breech-pin yielding in the least to the recoil of the discharger. X is a spring fitted into a recess of Digitized by Google GUN-BARRELS. 927 the breech-pin, and it has a projecting catch (not seen) which passes into a hole in the breech-pin, to drop before the carrier when it is drawn back, to hold the carrier during the act of loading, to prevent accidents by the touch of the trigger; but when the gun is loaded, by pushing forward the bar V, the needle-carrier is relieved from this to be under the complete control of the trigger. Z is an incline on the bar that goes under the spring X, and draws out the stop in the interior when the bar V is pushed forward. All this is done at the breech. The gun itself is compact and simple. The whole of the light cavalry of the Prussian army are to be provided with it. The inventor is Mr. Charles Hartung, of Prussia, now of New York. The assignee is John B. Klein, Esq., of Laight street, New York. It is patented in the United States. Colt's improvements in fire-arms, patented in 1849, consist in certain improvements upon that con- struction of guns and pistols which has a cylindrical revolving breech-piece, provided with a series of parallel chambers for containing a series of charges, which charges, by the revolution of the breech upon its shaft, may be successively brought into a line with the bore of the barrel, and be severally discharged through the same. In the following figures the improvements constituting the present invention are shown as applied to this construction of fire-arms, which formed the subject of a patent granted to the present patentee on the 22d of October, 1835. Fig. 2221 shows a pistol made according to this invention; Fig. 2222 is a side view, showing the lock- frame and recoil-shield in section; and Fig. 2223 is a longitudinal section, taken through the middle of the breech and barrel. a is the breech, containing six chambers, as shown in the end view, Fig. 2224, in the back of each of which a nipple is fitted, as shown in end view at Fig. 2225, and in section at Fig. 2223, to receive a percussion cap for firing the charge. This breech is supported by and is capable of turning on a spindle or arbor b, which is welded or fastened to and forms one piece with the recoil- shield c*, it being in a line parallel to the axis of the barrel. The shield is itself a continuation of the lock-frame c, the whole being formed out of one solid piece of metal By referring to the longitudinal section, Figa. 2222 and 2223, and to the cross section, Fig. 2226, the peculiar construction of this lock- frame and shield will be readily understood. The shield c* stands up at right angles to the frame c, and forms a round head (somewhat like a bolt-head) to its shaft b. The upper part of the shield is recessed to receive the hammer d, when it is thrown forward to effect the discharge of the pistol; and a recess is also made in the piece of metal which constitutes the lock-frame and shield, (see Fig. 2222,) to receive the parts which respectively revolve the breech to bring round the charges in a line with the barrel e, and lock the breech to the frame for the purpose of insuring that the charges shall be in a line with the barrel before the firing takes place. When the pistol is on half-cock, or in the position shown at Fig. 2223, the breech is free to turn round on its arbor in the direction of the arrow, Figs. 2221 and 2222. It may then be loaded and primed with facility, without being removed from its place, as was formerly requisite in charging this construction of revolving-breech fire-arms; a free space being left in front of the mouths of the chambers, as will be seen by referring to the end view of this breech, Fig. 2224, which shows the sectional area of the barrel and its appendages in dotted lines. The barrel e is supported in its place by the end of the spindle b, fitting into a socket in a bracket-piece, forming one piece with the barrel, as shown best at Fig. 2223. Against the end of this socket the spindle is made to abut, and thus to determine the exact position of the barrel with respect to the face of the revolving breech. To keep the barrel secure in its place, a key f is introduced through slots in the bracket or projecting piece of the barrel, and through the spindle b, its upper edge acting on the forward end of the slot in the spindle, and its lower edge acting upon the lower end of the slots in the bracket of the barrel, the effect of which is to draw the barrel towards the cylinder breech and lock-frame as the key is pressed in; and pins, projecting from the end of the lock-frame, enter corresponding recesses in the bracket piece of the barrel. The key f has a spring-catch, which rises when the key is forced home," and, by its turned-up end coming in contact with the edge of the slot through which it has been passed, it will prevent the key from getting loose and shaking out of its place by the concussion of the firing. This object is further insured by the insertion in the barrel-piece of the screw 1, the head of which would come in contact with the turned-up end of the catch, if it had escaped past the edge of the slot, and prevent it from dropping, or even being drawn out; this screw must, therefore, be removed before the key can be displaced. Jointed to the bracket part of the barrel, by a pin 2, is a lever g, which is kept up in a position parallel to the barrel by a spring-catch at its other end taking into a catch on the lower side of the barrel. To this lever a plunger h is connected by a pin 8, taking into a slot on the outer end of the plunger. The inner end of the plunger slides in a guide made for it in the bracket-piece of the barrel. This plunger is intended to act as a ramrod, and to drive the bullets or cartridges into the several chambers of the breech, consecutively as they are brought in a line with the plunger. To effect this the catch of the lever g is disengaged. and the lever is brought into the position shown by dots in Fig. 2222; the plunger is thereby driven forward and made to ram the bullet (which has been previously inserted in the end of the chamber, now brought in a line with the plunger) down into its proper place in the chamber; the plunger is then drawn back, and the next succeeding chamber brought in a line therewith, when the lever g is again brought into the dotted position, to thrust the plunger forward and ram down another charge and thus successively all the charges are acted upon. By referring to the drawing, Fig. 2223, it will be seen that the mouths of the chambers and the inner end of the barrel are chamfered at their edges. This bevelling of the edges of the chambers is to pre- vent the lateral discharge between the breech and the barrel from igniting the powder in the other loaded chambers; for the ignited matter, by coming into contact with the bevelled edge as it crosses the mouths of the chambers, will be deflected outward and effectually thrown off, and be prevented from reaching the powder in the chambers. The bevelling of the end of the barrel is intended to pre- vent its cutting the ball in its passage from the chamber. At Figs, 2226 and 2227 it will be seen that a hollow is made in one side of the shield c#: the object of this is to expose the ends of the nipples as the breech is revolved, and thus to allow of the percussion Digitized by Google 928 GUN-BARRELS. caps being readily placed thereon. The hammer a turns on a pin 4, in the lock-frame c; and it is pro- vided with stops or catches for the end of the trigger to abut against, as usual, and hold it at whole or half-cock, as required. To the hammer is jointed a hand-catch i, with the spring k attached, Fig. 2222, which is pressed forward into contact with ratchet-teeth formed on the end of the breech, and allows the hand-catch to recede for passing below a second tooth of the ratchet. l is a rocking lever, supported by a pin in the lock-frame c, and carrying at one end a bolt, which is intended to enter, at certain times, into the recesses 5 5 in the periphery of the breech, a bearing-spring m, Fig. 2228, giving it always a tendency to rise for that purpose. The other end of this lever is made thin, 80 as to be capable of yielding laterally and recovering its position, thus allowing a stud 6 (which projects from the hammer and has a chamfered or bevelled face) to pass the lever without disturbing the position of the bolt-end when the hammer moves forward to fire the charge; and yet, when the hammer is drawn back, to pre- sent an obstruction to the stud 6, and be thereby tipped into the position shown at Fig. 2223, which movement will unlock the breech. As long as the hammer remains at half-cock the breech will be free to turn upon its spindle for the purpose of being loaded; but when the stud has passed the end of the lever, the spring m will again force the bolt of the lever into its original or locking position. The action 2228. 2221. 0000 2226. 8 2223. LESS of drawing back the hammer to its furthest extent (the bolt being first relieved) will raise the hand- catch i, which, being brought in contact with a ratchet-tooth on the breech, will turn the breech round in the direction of the arrow, Fig. 2222, to the extent of one tooth, and thus bring up a loaded chamber in a line with the barrel ; and, in succession, the act of cocking will bring all the loaded chambers in like manner round in a line with the barrel and hammer to be discharged. In order to insure the insertion of the bolt of the lever I into the recesses 5 5 as they severally come round, and thereby to hold the breech firmly while the discharge takes place, a shallow channel or guide is formed up to the edge of each, as shown in the figures, which will make the bolt feel its way to the recess and enter it more certainly than if it were required to fall into the recess suddenly. To prevent the fouling of the spindle and breech, a helical groove is formed upon the spindle, as shown at Fig. 2223, the edges of Digitized by Google GUN-COTTON. 929 which will more effectually prevent the smoke from passing between the breech and spindle than if the whole periphery of the spindle were in contact with the breech; and at the same time these edges will, as the breech is rotated, scrape off any matters that may have become deposited in the central bore of the breech, and deposit it in the grooves. By this means the contact surfaces will be kept clean, and the breech, which would otherwise foul after a few discharges and become fixed, will be free to turn on its spindle, for a long period, without requiring any cleaning. Fig. 2228 represents in side view, and Fig. 2229 in plan view, a rifle, carbine, musket, or shot-gun, with revolving breech. As the several improvements before described, with reference to the pistol, are equally applicable to guns for military and sporting purposes, the patentee gives merely a descrip- tion of the modified arrangement of apparatus for ramming down the charges, as represented at Figa. 2228 and 2229. In this instance, instead of the plunger being applied below the barrel, it is attached to the side thereof. a is a bracket projecting from the side of the barrel, and to it the lever b is jointed by a pin 1. c is the plunger, having at about the middle of its length a joint 2; it is forked at one end, and embraces the lever b, to which it is jointed by a pin 3, and the cylindrical end of the plunger works between guide-pins 4 4 on the barrel. d is a spring-catch. riveted to the plunger c, and capable, when the lever b is laid parallel with the barrel, of taking into a notch cut in the bracket a. By means of this spring the ramming apparatus, when not required to be used, is retained in the position shown at Fig. 2228; but by drawing the lever b into the position shown at Fig. 2229, the catch will be imme- diately disengaged from the notch. The patentee claims, First, making the lock-frame and recoil-shield in one and the same piece, whereby all possibility of the parts getting loose after repeated discharges is prevented. Secondly, the general arrangement of the lock and apparatus for turning and locking the rotating cylinder breech, Thirdly, the general arrangement of the parts, whereby the operations of loading and priming may be effected without disconnecting the breech, as was heretofore requisite. Fourthly, the application to guns and pistols of the lever apparatus for ramming down the charges into the several chambers with great expedition and effect-the same being a substitute for the loose ramrod, Fifthly, the chamfering .he mouths of the chambers and the inner end of the barrel; also the grooving of the periphery of the breech-spindle; likewise the making sunk-guides to the locking recesses on the periphery of the breech; and, further, the means of insuring the proper position of the barrel with respect to the face of the breech. GUN-COTTON. To Professor Schönbein, the entire credit is due of discovering and making known the various useful purposes to which gun-cotton may be applied, although its actual discovery dates from a period prior to that when Schönbein published his experiments. In 1883, M. Braconnot observed, when starch was heated for a short time in strong nitric acid, until complete solution had been effected, and the solution was poured into a large quantity of cold water, that a white pulverulent amorphous substance gradually subsided, which, on being dried, was highly combustible, and burnt without leaving any residue. This substance was called xyloidine. M. Pelouze, in 1838, repeated the experiments of Braconnot, and found that paper, linen, cotton, and other ligneous substances, when submitted to the action of strong nitric acid, (sp. gr. 1-5,) for a few minutes, and then well washed with water and dried, possessed the same properties as xyloidine, without having lost, however, their original form and appearance. M. Pelouze was inclined to believe with chemists in general, that this was only another form of the same substance; he also threw out a surmise, that the substance might be applicable to certain useful purposes, especially in artillery. The same chemist, in conjunction with others, has, however, since shown, that these two substances are not identical. That the substance prepared by immersing paper, linen, cotton, &c., in nitric acid, contains more oxygen, and consequently more nitric acid than the xyloidine of Braconnot, and the name of pyroxyline or pyroxyle has consequently been given to it. The gun-cotton of Schönbein is probably this latter substance, or some body closely allied to it. The plan adopted for the manufacture of this compound is as follows: cleansed cotton is immersed m a mixture composed of equal parts of concentrated nitric and sulphuric acids, or, according to Schöng bein, of 3 parts sulphuric acid, and 1 of nitric acid, of sp. gr. 15, for about 10 to 15 minutes, and in order to prevent accidents, no portion of the cotton should be above the level of the liquid. The acid should then be pressed out, and the cotton which remains impregnated with it is well washed with water, until no acid reaction is perceptible to the tongue; it is now dried rapidly at a temperature not exceeding 212° F. Care should be taken, in drying this substance, to allow a free current of air to pass over it, and to spread out the cotton as much as possible, in order to prevent its forming into dense masses, which are much more liable to explode. It is, indeed, probable, that the method of drying in stoves, practised at first in Messrs. Hall's manufactory, was the cause of the explosion which occurred there, and which cost several persons their lives. No minute description of the mode of preparing gun-cotton upon a manufacturing scale has been published up to this period, and the foregoing notice, which indicates the plan practised by M. Susane, at the Direction des Poudres et Saltpêtres, must suffice to give a general view of the process, which is no doubt carried out with slight differences, although the same in principle, in the different manufactories. With regard to the composition of gun-cotton, nothing certain is established. The analyses which have been made of it, and which are numerous, do not accord, and tend rather to prove that several products may result from the action of nitro-sulphurio acid upon cotton, paper, dic., depending, amongst other things, upon the state of concentration of the acids used, the time of immersion, &c. The properties of gun-cotton are very extraordinary, and create a greater degree of astonishment, in consequence of its outward appearance bearing the strictest resemblance to ordinary cotton wool, which, however, is not so harsh to the feel. It is insoluble in water both hot and cold, and when removed and dried, is found to have lost none of its original properties; acids have also no action upon it, and this effectually distinguishes it from xyloidine. The best solvent for gun-cotton is acetic ether, and this sub- stance may be used for rendering it perfectly pure. It explodes violently when heated to 356° F,, or 117 Digitized by Google 930 GUNPOWDER. on ignition, leaving scarcely any residue, and creating very little smoke. The temperature at which it is thus decomposed, is 80 much below that at which gunpowder explodes, that the cotton may be lightly placed upon the surface of gunpowder, and detonized by a red-hot wire without setting fire to the pow- der. Friction of the ordinary kind will not explode gun-cotton, but when placed on an anvil, and pow- erfully struck with a hammer, the heat generated by the stroke causes it to detonate. With reference to the projectile force of gun-cotton, as compared with gunpowder, there appears reason to apprehend that its action, in its present form, is too rapid, and resembles too much that of the fulminates, to ren- der it applicable to the purposes of artillery. The gaseous products from its combustion are also such as cannot be altogether resisted by fire-arms, although, if air be absent, no great amount of corrosion can ensue; and as it has been found that gun-cotton impregnated with chlorate of potash or nitre has a still more powerful effect than that prepared in the usual manner, the addition of these substances would at the same time tend to modify the corrosive action of the acid products of combustion. As a substitute for gunpowder in all mining and blasting operations, however, the superior local force of the powder-cotton will be highly valuable; and it has indeed been found to effect as much as four times its weight of powder. In the pyrotechnic art it will probably also be extensively used, and paper pre- pared by the method of Pelouze, and moistened with solutions of nitrate of strontia, sulphate of copper, and nitrate of baryta, yields very beautiful red, green, and white fires. GUN METAL A species of brass employed in casting cannon, and used also in the wearing parts or joints of machinery. This alloy should consist of 9 parts of copper and 1 of tin, but no zinc. It answers well for valves. GUNPOWDER, description of machines used in the proof of. Cannon pendulum and its ballistic pendulum, of the Washington Arsenal, Figs. 2230 and 2231. The pendulum-block.-The pendulum-block is of cast-iron, in the form of a hollow frustrum of a cone, with a hemispherical bottom. In order to give it the requisite strength, the block is closely hooped with wrought-iron over all the conical part, except in the places where it is embraced by the suspension straps; for this purpose the block was first turned, and the hoops were accurately reamed in a lathe, and then shrunk on to their places, using in this operation only heat enough to set the hoops closely to the cast-iron. 2230. 2231. In order to facilitate the adjustment of the centre of oscillation of the pendulum, by throwing the weight as far as possible from the axis of motion, the block was made thicker on the lower side than on the upper, by placing the core of the hollow part above the centre of figure, thereby bringing the centre of gravity of the block 0.5 inch below its axis. The opening in the face of the block is partially closed by an iron plate, which is held fast by bolts set in the block, and which serves to retain the sand used for filling the hollow of the block. In the centre of this plate is a circular opening 16 inches in diameter, through which the ball passes, and the point struck by the ball is marked by the hole made in a sheet of lead, (of about 31 lbs. to the square foot,) which is placed over the opening in the plate and retained by a washer, or smaller iron plate, bolted to the large one; vertical and horizontal scales, drawn on the face of the small plate, serve, by means of an easy reference, to measure the position of the point struck by the centre of the ball. Manner of forming the core of the pendulum-block.-The hemispherical bottom of the core is formed of a block of lead, which serves to counterpoise the weight of the front part of the pendulum-block, and facilitates the adjustment of the axis in a horizontal position, by bringing the centre of gravity of the Digitized by Google GUNPOWDER. 981 system nearly in the middle point between the suspension straps; this lead forms also a sort of cushion. to receive the impact of the balls, and to prevent them from striking against the cast-iron, in case they should penetrate through the sand which forms the chief part of the core of the pendulum-block. The sand which receives the impact of the balls is contained in cases made of strong leather stretched over iron frames; the frame consists of two wrought-iron hoops, connected together by ribe of the same material; the diameter of each hoop is 0.75 inch less than that of the core, at the place which it is to occupy each hoop is made in three segments, and the corresponding segments of the two hoops which form one frame, are connected together, each pair, by three ribe of square iron welded to the hoops. The leather which covers these frames is brought over the outer faces of the hoops and secured there by rivets, the sections of each hoop being connected together by the leather covering only. When the sand is compressed by the ball, the case or bag expands laterally, until it is supported by the sides of the pendulum-block. The ends of these cases are closed with boards of soft wood, about 1 inch thick; those which form the bottom, or smaller end of the case, rest on iron pins which are set on the inside of the smaller hoop; and those which form the head, or larger end, are kept in place by small nails driven into wooden plugs in holes on the inside of the large hoop. In order to fill the case or bag, it is placed on its small end, and the boards forming the bottom are laid down on the pins intended to support them; if there are any openings through which the sand might escape, they are closed with shavings, &c. The sand is then put in and settled with a small rammer, such as a piece of an implement staff: when nearly filled, the bag is placed on the platform of a balance, and its weight properly adjusted, after which the head is fastened in as before mentioned. Four of these bags form a set for filling the pendulum-block the first or smallest one is 15 inches high the second, 14 inches; the third and fourth, each 12 inches; an interval of about 3 inches is thus left at the mouth of the block, which serves to admit any compensating weights that may be required to make up the proper charge. These weights are in the form of large rings, made of iron of different sizes, according to the weight required. The vacant space in the mouth of the block is requisite also for con- taining the sand displaced by the shot. A small portion of this sand escapes through the hole made by the ball in the sheet of lead on the face of the block. The placing of the sand-bags in the block is facilitated by the use of a pair of large hooks, or tongs, attached to a tackle and fall, suspended from the roof of the pendulum-shed and hanging just in front of the block: when not in use they are drawn aside, out of the way of the pendulum, and hung on a hook driven into the frame of the shed. Manner of suspending the pendulum-block.-The block is suspended by means of four straps of wrought-iron attached to a horizontal shaft of the same material. The shaft terminates at each end in knife edges, made of hardened steel welded to the iron. These knife edges are rounded on a radius of 0-06 inch; inside of the knife edges, the shaft has cylindrical bearings which are turned with great care; the lower lines of the knife edges are in the surface of these cylinders produced, and consequently the axes of motion, at the two extremities of the shaft, are in the same right line. The suspension straps terminate, at their upper ends, in collars which are accurately bored to fit the cylindrical bearings on the shaft. In the lower parts of these collars are slots, which fit on correspond- ing projections on the shaft and prevent the straps from turning the collars of the straps are also pre-sed firmly, by means of keys, against the shoulders of the shaft. The two inner straps, from each end of the shaft, pass to the front end of the pendulum-block; the outer ones, to the rear end. The inner straps are straight, from the collars on the shaft to a point near the block where they take a di- rection perpendicular to the axis of the block, which they embrace between the shoulders provided for them. The outer straps are curved just below the shaft, 80 that at the distance of about 5 feet from the axis, the two straps from each end of the shaft are brought into the same plane, passing nearly through the axis of the block. The work should be fitted together in such a manner that the line joining the centres of the two col- lars for the pendulum-block, which are thus formed by the two pairs of straps, shall be in a plane per- pendicular to the axis of the shaft at its middle point, and shall be also perpendicular to a plane pass- ing through the axis of the shaft and the middle point of the line in question, which line coincides with the axis of the block. The pair of straps which embrace the front part of the block approach, above and below the block, within 8 inches of each other, and are kept apart by iron transoms which terminate at each end in bolts that pass through the straps, and are held by nuts on the outside. The other pair of straps come together within 2 inches, and the bolts which serve to press them against the block pass through the flattened heads of two large transverse bolts, the other ends of which are cut with a screw-thread. The ends of these bolts pass through holes in the transoms of the front pair of straps, and the bolts have strong screw- threads cut on their whole length, for a purpose which will be hereafter explained. Between the pendulum-block and the shaft, the two straps from each end of the shaft are firmly connected together by two pairs of flat braces, having shoulders which bear against the edges of the straps; the upper braces are bolted to the straps, and they are connected together by a large cross-bolt which passes through the middle of each; the lower braces are connected with the straps, and with each other, by means of cross-bolts. All of these cross-bolts have bevel-washers against their shoulders inside, and under the nuts, outside of the braces. Supports of the pendulum.-The knife edges of the shaft rest in V's formed in dies of hardened steel, which are set in cast-iron seats these seats are bolted down to large cast-iron plates, resting on the tops of two stone piers, to which the plates are secured by long bolts let into the stone. On the upper sides of the plates there are projecting ledges, between which the seats for the V's are placed, and the position of these seats is regulated by means of wedges inserted between them and the projections on the plates. The bolt-holes in the seats are made of an oblong form. in order to admit of adjustment Digitized by Google 932 GUNPOWDER. so that the two V's of each pair shall be in the same horizontal line, and that these lines, in the two pendulums, shall be parallel to each other. The bottom parts of the V's are rounded on a radius 1-10th of an inch; and the inclination of the sides is 80 arranged, with reference to that of the planes of the knife edges, as to allow the pendulum to vibrate through an are of 30°. The parallelism of the two shafts is verified by means of two plumb-lines, suspended to the ends of a needle attached to each shaft in a direction perpendicular to its axis. Four other plumb-lines are suspended in the axis of the gun and block, (on the front and rear of each,) and when the adjustment is perfect, these eight plumb-lines should hang in the same plane. Measurement of the arc of vibration.-The vibration of the pendulum is measured on a brass limb, placed under the axis of the block and supported by wrought-iron chairs set in stone posts. A alider, also of brass, moves on this limb, and is held at any point by the pressure of a light spring; the slider is moved by an index attached to a bar connected with the lower ends of the suspension straps. The limb is graduated in degrees and minutes, and the slider has a vernier which reads to two seconds. The zero of the are is placed in the vertical plane passing through the axis of motion, and the face of the index is also in this plane when the axis of the block is horizontal, or situated in the line of fire. In order to have the means of verifying the adjustment of the limb, at any time, if necessary, two hollow centres are screwed into the under side of the shaft, near each end, for the purpose of suspending two plumb-lines that shall hang in the vertical plane through the axis of motion. Gun pendulum.-The suspension-frame, the supports, and the general arrangement of the gun pen- dulum, are similar to those of the ballistic pendulum, and it is therefore necessary to describe only the manner of attaching the gun to the frame. In order to provide for mounting guns of any calibre below a 32-pounder, the diameter of the circular parts of the suspension straps is sufficiently large to admit collars of cast-iron which may be adapted to the gun and made to fit on the trunnions, having shoulders to receive the straps; but the 32 and 24- pounder guns, heretofore attached to the pendulum, having been made for the purpose, the projecting pieces, to form the shoulders for the straps, were cast on the guns. In order to facilitate the adjust- ment of the centre of oscillation of the pendulum, and also to have a gun which shall be perfectly safe to use, with any charge up to 1 the weight of the shot, the 24-pounder has been made on the same model as the 32-pounder, and the trunnions are omitted, as the piece is designed for use with the pen- dulum exclusively. Adjustment of the centre of gravity and of the centre of oscillation.-The two systems being nearly symmetrical, with reference to the vertical planes through the axis of motion and the axis of the gun or block, the centre of gravity of each pendulum was found nearly in the intersection of these vertical planes, when the axis of the gun or block is horizontal; it is therefore necessary to provide only for cor- recting the deviations caused by variations in the charge of the gun, or of the block. For this purpose, adjusting weights are placed on the large screw-bolts which connect the front and rear straps above and below the gun and the block; by sliding these weights backwards or forwards, the position of the vertical line containing the centre of gravity is easily adjusted. These weights effect another very im- portant purpose, in the adjustment of the centre of oscillation of the system, so as to make it coincide with the axis of the gun or block. The weight of the gun and block being very great, in comparison with that of the suspension-frame, the centres of oscillation were found to be nearly at the proper height, and the adjustment of them was readily effected by placing weights on the lower screw-bolt, which has the effect of lowering the centre of oscillation; the upper screw-bolt would be made use of in the same manner, in case the centre of oscillation should be found, by any change of circumstances, to be too low. These screw-bolts are flat- tened, or planed off, at the sides, in order to allow the weights to slide on them more readily. The weights are cylinders of various heights, having slits of the thickness of the screw-bolt, to facilitate placing and removing them. The slits are lined with thick sheet-iron to prevent the weight from being cut by the screw, and the height of the slit is 80 regulated (for convenience in calculation) as to bring the centre of gravity of the weight in the axis of the bolt on which it rests. The weights are made of lead, with about 6 per cent. of tin; they are moved on the bolt, and are also held in place, when set, by means of large nuts with handles, of which there are two on each bolt. To prevent these nuts from being pressed into the weights by their reaction in the recoil of the pendulum, broad iron washers are placed between the weights and the nuts, and the front weight for each pendulum is made of a shell of cast-iron 1 inch thick, filled with lead. Weight of the pendulums.-The weight was ascertained to be as follows:- lbs. Weight of gun-frame complete 2,811 " 32-pounder gun 7,689 Total of gun pendulum 10,500 ballistic pendulum-frame complete 2,847 a pendulum-block, (empty) 6,368 " face-plates and bolts for do. 143 Total ballistic pendulum 9,358 Position of the centres of gravity of the pendulums.-The position of the centre of gravity of each system was determined by balancing the frame complete on the edge of a square steel bar, placed parallel to the axis of the shaft. The place of the centre of gravity of the gun and the block being known, that of the whole system is easily calculated. Digitized by Google GUNPOWDER. 983 The results of this calculation were verified by actually balancing, in a horizontal position, the whole pendulum, with the gun and block in place. Gun. Block. Inches. Inches. Distance from the axis of motion to the centre of gravity of the frame 1128 114'13 Distance to the centre of gravity of the gun or pendulum-block, (empty) 195 1955 Distance to centre of gravity of the system, (by calculation) 112.8 X 2811 + 195 X 7689 = 172994 10,500 2847 X 11413 + 6368 X 195.5 + 143 X 195 170787 9358 Distance to centre of gravity of the system, by trial 1728 1708 Do. mean; taken as the true distance 172.9 1708 The height of the centre of gravity of each pendulum in this condition being known, it is easy to make the necessary correction for the addition of the adjusting weights, and for the weight of the core of the block. For this purpose it is sufficient to observe that the centre of gravity of the adjusting weights, being in the axis of the lower screw-bolts, is, in the gun pendulum, at 215 inches from the axis of motion, and in the ballistic pendulum, at 219 inches. The centre of gravity of the hemisphere of lead in the bottom of the pendulum-block is in the axis of the block, or 195 inches from the axis of motion and that of the conical part of the core is 0.66 inch above the axis of the block, or 19434 inches from the axis of motion. In the gun pendulum, when adjusted for use with the 32-pounder gun, a weight of 667 pounds was placed on the lower screw-bolt. In the ballistic pendulum there were lbs. a hemisphere of lead in the block, weighing 6261 an oak board over the lead 91 a sheet of lead on the face 8 4 sand-bags 965 adjusting weights on the lower screw-bolt 789 Under these circumstances, the distance of the centre of gravity of the gun pendulum from the axis is 10,500 X 172.9 + 667 X 215 1,958,963 = 175.41 in., 11,167 11,167 and that of the centre of gravity of the ballistic pendulum, 9858 X 1708 + 648 X 195 + 975 X 19434 + 789 X 219 2,084,162-5 = = 17729 in. 11,756 lbs. 11,756 The results of these calculations and measurements may be at any time verified, and in case of a change in the pendulums, they may be corrected, by practically ascertaining the moment of the system, i e., the product of the weight into the distance of its centre of gravity from the axis of motion and this moment is a factor which enters into the formula for the computation of the initial velocity of the ball. To ascertain the moment of the pendulum without dismounting it, it is sufficient to determine by trial the weight which, acting at a given distance from the axis, will sustain the system, out of a verti- cal position, at such an angle that the direction in which this weight acts shall be perpendicular to the line drawn from the centre of the axis of motion to the centre of gravity of the system. If a be the angle which this latter line then makes with the vertical, w the weight which balances the system, and d the distance at which it acts from the centre of motion, then will the moment of the pendulum be sin.a = P9. Position of the centre of oscillation-The lengths of pendulums being to each other as the squares of the times of vibration, or inversely as the squares of the number of vibrations in a given time, the distance of the centre of oscillation from the axis of motion is determined by observing the number of vibrations made by the pendulum in any given time, or the number of seconds required for a given number of vibrations of the pendulum. In the present instance this was determined by observing, with a chronometer which beats half seconds, the time required for 500 vibrations of the pendulum, commencing in an arc of about one degree and a half. The length of the seconds pendulum at Washington, (latitude 38° 53' 23",) being 391 in, the distance of the centre of oscillation of a pendulum vibrating 500 times in n seconds, will be n2 X 391 = ; 500' and in order that L shall be equal to 195 in., or that the centre of oscillation shall be in the line of fire of the pendulum-gun, n must be = 1116.5 seconds. In the gun pendulum, this adjustment of the time of vibration is effected by placing an additional weight of 667 lbs. on the lower screw-bolt, as above mentioned, in ascertaining the position of the centre of gravity. In the ballistic pendulum, when ready for use and loaded as above stated, the time required Digitized by Google 934 GUNPOWDER. for 500 vibrations is 1116 seconds, and the position of the centre of oscillation is at 1948 in. from the axis. When the position o' of the centre of oscillation is accurately ascertained, for any given condition of the system, the additional weight W, requisite to bring that centre into any other position, o may be computed very nearly by the formula w-pg(o-o), Pg being the actual moment of the pendulum, and d the distance of the additional weight from the axis of motion. In consequence of the lightness of the frames, in proportion to the whole weight of the pendulums, they are found to possess a great degree of sensibility when vibrating in an arc of 14°, they lose about 36" in one vibration; in an arc of 4°, about 25". When set in motion in an are of 12°, the gun pendulum continued to vibrate about 24 hours, and the pendulum-block (empty) about 30 hours. Distance between the pendulums.-It was ascertained that, at the distance of 48 feet from the muzzle of the gun, the pendulum would be but slightly affected by the blast, and it was therefore determined to place the axes of the two pendulums 55 feet apart. In order to intercept the blast of the gun as much as possible, a fixed screen of 2-inch oak plank is placed 17 feet in front of the face of the pendulum-block, having a hole in it 12 inches diameter for the passage of the ball. The protection afforded by this screen is such, that with a blank charge of t from the 32-pounder gun, the vibration of the pendulum-block does not exceed 45"; which vibration, if pro- duced by the impact of a ball, would require a velocity of only 0.85 feet. The penetration of the 32-pounder balls, in the sand of the pendulum-block, is about 4 feet. It is found that, in consequence of the great and sudden compression of the sand, produced by balls moving with great velocities, the penetration does not increase with the charge; but the pressure against the sides and bottom of the block is necessarily greater with higher charges, and under these circumstances, the mass of lead in the bottom of the block is 80 much compressed and battered as to make it inexpe- dient to fire with high charges (1 or I) from the 82-pounder gun, without filling the block with some material affording a greater resistance than sand. Service of the pendulums.-Open all the doors and windows of the sheds; observe whether the nuts of the several connecting-bolts are screwed up tight, and whether the shoulders of the knife edges swing clear of the seats. Wipe out the V's and oil them with a small quantity of clear oil. 1st. The ballistic pendulum.-Load the pendulum-block with the sand-bags, driving them in with handspikes, 80 as to make them bear on each other; put on the face-plates with the sheet of lead pre- viously adjusted between them. Adjust, if requisite, the position of the centre of oscillation of the pendulum, and in order to maintain this adjustment, let the sand-bags be always filled to the same weight as at first. If this cannot be done, make up the correct total weight by placing some of the iron rings within the mouth of the block Wipe the graduated are and move the adjusting weights on the lower screw-bolt, 80 that, the pendu- lum being at rest, its index shall be in contact with the slider when the latter stands at zero; in this position the axis of the block is horizontal: see that the nuts on the screw-bolts are set firmly against the adjusting weights. After the gun is fired, two men stop the vibrations of the pendulum-block, checking them gradually with the hand, (or with a rope thrown over the breech,) and taking care not to displace the alider on the arc. Note the arc of vibration. Take off the face-plates and ascertain the position of the point struck by the centre of the ball, by referring the extremities of the vertical diameter of the hole made by the ball to the graduated scales on the outer plate. If necessary, note also the lateral deviation of the shot. Withdraw the sand and the ball, dc.; clean out the block with the rake and brush provided for the purpose. 2d. The gun pendulum.-The centre of oscillation is supposed to have been properly adjusted. Wipe out the gun, insert the cartridge, push it home with the rammer, and measure the length which it occupies in the bore by means of the graduated brass scale set in the rammer-staff for that purpose; insert the shot, ram it home and measure in the same manner the height of the whole charge prick the cartridge, and prime with a tube having a short piece of quick-match inserted in the cup, in order to give time for withdrawing the linstock before the gun recoils. A quill or paper tube is preferable for priming with, as the metal tubes are driven with considerable force against the sides, or the roof, of the shed. Wipe the graduated are and adjust the index of the pendulum as before, taking care that the nuts on the screw-bolt are set firmly against the adjusting weights. Before giving the order to fire, be sure that both pendulums are at rest and in their true positions. After the discharge, note the arc of recoil. Two men stop the vibrations of the pendulum by throwing a rope over the breech of the gun against the suspension-frame; in this manner they are less apt to twist the frame than when acting directly with the bands against the gun. Clean out the gun and prepare for another charge. During the firings the pendulums should be carefully observed, to see if any derangement occurs in the position of the shafts in their V's, or in the stability of the frames, the tightness of the nuts, dec. Formula for computing the velocity of the ball from the recoil of the pendulums.-1. By the ballistic pendulum.-The formula for the velocity with which the ball strikes the pendulum block is bi where V is the required velocity of the ball in a second; Digitized by Google GUNPOWDER. 935 p the weight of the pendulum; g the distance of its centre of gravity o the distance of its centre of oscillation } from the axis of i the distance of the point of impact motion; b the weight of the ball; A the angle of first vibration of the pendulum; G the measure of the force of gravity, = 32-155 ft., at Washington. The demonstration of the correctness of this formula is given in Hutton's Mathematical Tracts. In our pendulums the axis of the gun and that of the pendulum-block are adjusted on the same hori- zontal line, when the pendulums are at rest; therefore the ball strikes very near to the axis of the block, and in order to prevent any shock on the axis of suspension, the centre of oscillation of the system is made to coincide also very nearly with the axis of the pendulum-block, and this adjustment is main- tained by renewing the core of the block and restoring the pendulum after each shot to its original con- dition; hence the values of o and i in the above formula are very nearly equal, and the quantity Pg being very great in comparison with bi, no sensible error will be caused by assuming i = o in the first term under the radical sign; the formula then becomes sin. Moreover, in practice with balls of the same kind and calibre, the variations in the value of b are confined within narrow limits. On this account, and in consideration of the great inequality between the terms pg and b i, we may, in the case just mentioned, assign to bi, in the numerator of the above expression, a constant value equal to the mean weight of the balls multiplied by the mean distances of the points struck from the axis of suspension. By this assumption the whole term becomes constant for one set of experiments, and the formula is perfectly adapted to logarithmic com- putation. In making the calculations of the velocity for a case of extreme variation in the value of bi, it was found that the error produced by the above transformation of the formula, and by assuming a constant mean value for P + bi, is so small that it may safely be disregarded. Since 2 sin. = chord of A, it is obvious from the formula, that, all other circumstances being equal, the velocity of the ball is proportional to the chord of the arc of vibration of the pendulum. 2. Computation of the velocity of the ball by the recoil of the gun pendulum.-The formula for this purpose is taken from the Report of experiments on gunpowder at Metz. The formula is, 2 sin. c N ; in which w' is the required initial velocity of the ball; p' the weight of the gun pendulum; g' the distance of its centre of gravity i' the distance of the axis of the gun } from the axis of o' the distance of its centre of oscillation suspension; A' the angle of vibration of the pendulum; b' the weight of the ball and wad; D the diameter of the bore of the gun; d the diameter of the ball; c the weight of the charge of powder; c' the weight of the cartridge, including the bag; G the force of gravity, = 32.155 ft.; N a constant factor, of the same kind as g', G, &c., to be determined by experiment. There are obvious causes of error and uncertainty which may prevent the results of this calculation of the velocity from coinciding in all cases with those obtained by means of the ballistic pendulum, even after allowance is made for the loss of velocity occasioned by the resistance of the air whilst the ball is passing from the gun to the pendulum-block. The principal one of these causes is the uncertainty of the value t v', assumed for the mean velocity of the inflamed gunpowder in the bore of the gun. It is certain also that a considerable portion of the elastic fluid escapes through the windage of the ball, and therefore the mass of fluid behind the ball is less than that of the charge of powder; but this loss of fluid is in some measure compensated by the greater velocity of the part which passes by the ball. The effect now under consideration must likewise be modified by the quality of the gunpowder and the quantity of the charge, even within the usual limits of practice, and these circumstances probably exert a still greater influence on the value of the quantity N in the term c N. Capt. Mordecai found that the results of his experiments with the 32-pounder and 24-pounder guns were well represented by giving to N a mean value of 1600 feet. This value of N does not appear to apply equally well to the computation of the velocities of balls of very small calibre; for the intensity of the heat, and consequently the elastic force of the fluid, generated by the combustion of the charge, increase in a greater proportion than the direct ratio of the quantity of powder, and the value of N must therefore vary with the charge of powder, and also with the length and calibre of the gun and the density of the ball. However, as in ordinary practice with the cannon pendulum, the variations in the value of N cannot be great, and as the quantity c N is much smaller in value than the other term in the numerator of the formula for the Digitized by Google 936 GUNPOWDER. velocity, no considerable error arises from assigning to that coefficient a constant mean value, as above stated. Manner of loading the gun.-Of the balls-The shot and shells used in these experiments were of an intermediate gage between the large and the small gage, c. g.: For the 32-pounder gun, between 6-235 in. and 6.27 in. and for the 24-pounder gun, between 5-66 in. and 5.70 in. With the exception of some of the first 32-pounder shot, those used in the experiments were ham- mered shot. Each shot was floated in mercury, and the upper extremity of the axis passing through its centre of gravity was marked with a centre-punch. For the sake of brevity, the axis of the ball which passes through the centre of gravity will be designated as the principal axis. Of the wads-The wads ordinarily used in the experiments are grommets, or rings formed of a single strand of packing yarn, about t inch thick, such as is used for the packing of pistons in machinery this yarn is soft and very slightly twisted. The diameter of the grommet is a little less than that of the ball, to which it is attached by four leather straps about 1 inch wide, each pair crossing the other at right angles, and being tied on the ball with twine strings; the grommet has also a cross of twine to assist in placing it and to preserve its form. The thickness of the leather straps is nearly equal to half the windage of the ball. The average weight of a grommet with straps is, for the 32-pounder ball, 0·1 lb.; for the 24-pounder, 0.08 lb. The grommet is placed on the lighter hemisphere of the ball, in a direction perpendicular to its prin- cipal axis. Of the cartridges.-The cartridge-bags are made of closely woven twilled woollen stuff; they are cut with a circular bottom like those for field service, and sewed on a cylindrical former of the regulation size, the diameter of the former being for the 32-pounder gun 5-9 in., and for the 24-pounder 5.85 in. Of the manner of loading.-The cartridge being inserted, is pressed firmly with the rammer against the bottom of the bore, and its height measured. The ball is then placed with one of the leather straps resting on the lower side of the bore, the grommet outside, 80 that the heavier hemisphere of the ball is next to the powder. The leather straps not only retain the grommet, but also support the ball nearly in the centre of the bore. In order to prevent the ball from being detached from the grommet, it was pushed to its place with the end of the rammer-staff, which caused it to slide on the bottom of the bore instead of rolling; the rammer being then turned, the height of the whole charge is measured. The difference between the height of the cartridge and that of the whole charge is less than the diameter of the ball, because the centre of the ball lies above the neck of the cartridge, and consequently the bottom of the ball passes beyond the tie of the cartridge and rests against the powder. After the discharge the gun is cleaned with a cylindrical brush made of stiff bristles, and then wiped out with a common woollen sponge. The gun is washed after each series of rounds with the same powder, (generally after 3 rounds,) and is then wiped with a dry sponge. The muskct pendulum.-The frame for supporting the musket-barrel consists of two parallel bare of iron, connected together by a transom at each end; each of these bars has an ear coutaining a trunnion- hole to receive the trunnions of the musket-barrel, which are fitted into a solid cylinder of iron that is substituted for the breech-screw of the musket; the barrel is held in its place and adjusted by means of four set-screws passing horizontally through the bars of the frame, one pair near each end of it; a fifth set-screw, passing vertically through the front transom, serves to adjust the musket-barrel in a horizontal position when the frame is horizontal This frame is suspended by means of four iron rods, Fig. 2232; at the lower end of each rod is a shackle which is bolted to the transoms of the barrel-frame, and a similar shackle serves to connect the rods above with the shaft of the pendulum; the screws cut in the ends of each rod, to unite it with the shackles, are right and left hand screws respectively, 80 that by turning the rod, the distance of the frame from the shaft is increased or diminished at pleasure, and in this manner the height of the axis of the barrel is readily adjusted when once adjusted, the rods are held fast by nuts screwed up against the shackles, to prevent the rods from turning. The shaft of the pendulum is a flat bar of steel, at each end of which is a knife-edge well hardened and tempered. The parts of this pendulum are 80 arranged that, when it is at rest, the frame is nearly horizontal; the slight adjustment requisite for making it exactly horizontal is effected by means of leaden weights, supported by a small bolt screwed into the rear transom of the frame; a thumb-screw nut serves to keep these weights in place, by pressing them up against the transom. The knife-edges of the shaft rest in V's of hardened steel, which are set in cast-iron hangers connected by a plate, and this plate is secured by four bolts to another plate, also of cast-iron, which is firmly bolted and braced to a brick wall. The arc of vibration is measured on a brass limb, which is clamped to an iron plate, on which it can slide in a circular direction, 80 that the zero of the limb may be properly adjusted; the iron plate is supported by a frame of wrought-iron secured to the wall, and furnished with four set-screws which serve to adjust the arc to the proper distance from the knife-edges; a slider moves in a groove in the brass limb, and is retained at any part of the limb by the pressure of a slight spring. In the vibration of the pendulum the slider is moved by an index attached to a bar which is fastened, at a suitable height, to two of the rods of the pendulum-frame. The radius of the graduated arc is 573 inches: each degree of the brass limb is divided into six parts, and the vernier on the slider subdivides these parts into minutes. The ballistic pendulum.-This pendulum is composed of a hollow conical block of bronze, suspended by two iron straps to a shaft formed of a flat bar of steel, with knife-edges like those of the musket pendulum; a brace between the straps serves to stiffen them, and into one end of this brace is screwed the index which moves the slider on the brass limb for measuring the vibration of the pendulum. Digitized by Google GUNPOWDER. 937 An iron clamp, of a simple construction, presses a circular wooden plate against the face of the pen- dulum, Fig. 2233, and the point struck by the ball is marked by the perforation of this wooden plate. The core of the pendulum-block consists of, 1st. A block of hard wood, turned to fit the bottom part of the pendulum-block. 2d. A conical block of lead, faced with a plate of iron, occupying nearly the centre of the core. 3d. A block of hard wood, turned and cut to such a length as just to fill the pendulum-block, and to bear against the face-plate. These blocks were made of well-seasoned hickory, accurately adjusted to the proper weight by boring holes in them, which were, when necessary, filled with plugs of lead. This weight is such as to keep the axis of the block horizontal when the pendulum is at rest. The wooden face-plate was used for many rounds, the balls always striking in a hole one inch in diameter, in the centre of the plate. 2233. 2234. The arrangements for suspending the ballistic pendulum and for measuring the vibration are the same as those for the musket pendulum. The distance between the axes of the two pendulums is ten feet; the muszle of the musket is six feet from the face of the pendulum-block. A screen of boards, having a hole two inches in diameter for the passage of the ball, is placed two feet in front of the ballistic pendulum, to intercept the wads and the blast of the charge. The pendulums are attached to the south side of a brick wall, and covered by a wooden shed. Service of the pendulums.-After numerous experiments on the manner of londing the musket-barrel, it was determined to adopt nearly the same method that is pursued in ordinary service. The charges are weighed with an accurate balance and put into small tin canisters: to load the piece, the charge is poured into a small copper or tin charger attached to the end of a ramrod the musket- barrel is inverted over it, the vent being previously stopped with a brass wire; the barrel and charger are then again reversed together, and the charge of powder is shaken out into the bottom of the barrel. The ball is wrapped, as for a common cartridge, in a rectangle of ball-cartridge paper, 3 in. X 45; the paper is choked tight over the ball, and also slightly choked below, to prevent the ball from falling out. Instead of merely inserting the hall, with the paper, over the powder, the paper is first formed into a wad, in a manner nearly uniform, by putting the cartridge-case, with the paper down, into a piece of musket-barrel, and pressing on the ball with a wooden rammer, which crumples the paper neatly into a sort of sabot. In loading, the paper is inserted next to the powder; the ball is followed up with the rammer, which is of steel, and weighs 11 pounds; this rammer is then raised six inches and let fall on the charge once the height of the charge was always measured by a graduation on the rammer, in order to guard against error in loading. The balls were prepared by means of dies, adapted to an ordinary punching machine, and were made very nearly exact in size, form, and weight. After each discharge, the musket-barrel is taken from its frame, and wiped carefully with dry rags; it is washed generally after five rounds. The set-screws on one side of the frame being undisturbed, the direction of the barrel requires no other adjustment, after being once set, than to be pressed up gently, but firmly, by means of the screws on the other side of the frame. The charge is fired with a piece of quick-match in the vent. The wooden block into which the ball is fired is 45 inches long; with a charge of even 100 grains the musket-ball generally penetrates through this block, (of hickory wood,) and is flattened against the iron plate with which the lead block is faced; the lead and the wooden core are usually wedged slightly against the sides of the block, and have to be driven out through a hole left in the bottom of the pendulum-block for that purpose. 118 Digitized by Google 938 GUNPOWDER. Elements for computing the velocity of the ball.-The formulse for this purpose are the same as those before given for the large pendulums. The constant elements of the calculations, in the usual condition of the pendulums, are as follows: 1. For the Ballistic Pendulum. Total weight of pendulum P = 55 lbs. Distance of centre of gravity from knife-edges g = 614 in. Time of 1000 oscillations 1379 seconds. Distance of centre of oscillation from knife-edges o = 74354 Force of gravity G = 38586 Distance of the axis of the block, or usual point of impact, from the knife-edges i = 79. in. Weight of the ball of 0.64 inches diameter b = 0.05679 lbs. do. do. 0.65 do. = 0.05861 Log. V(pg + bi)(pgo+bi) { for ball 0.64 in = 43279424 12bi for ball 0.65 in = 43142795 The variations in the point of impact being very small, its distance has been regarded as constant, in the decominator as well as in the numerator of the formula; but in case of any considerable variation the correction is easily made in the above logarithms, by adding or subtracting, as the case may be, the difference between the logarithm of 79 and that of the true value of i. 2. For the Musket Pendulum. Total weight of pendulum = 88.94 lbs. Distance of centre of gravity from knife-edges g' = 43.85 in. Time of 1000 oscillations 1297 seconds. Distance of centre of oscillation from knife-edges o' = 65.77 Force of gravity G = 385.86 Distance of axis of barrel from knife-edges 79. Log. 12 3.1175821 Mean weight of the rectangle of cartridge paper, (3 in. X 45 in.) in which the ball is wrapped 10-5 gra. Diameter of the bore of the musket-barrel 069 in. No value that can be assigned to the quantity N in the formula will produce results of equal accu- racy when applied to different kinds of gunpowder, and in all cases it appears that the value of N is much smaller for the musket than for the cannon pendulum. This would appear to be the natural con- sequence of variations in the force or intensity of the flame produced by the combustion of various kinds of powder; that powder which acts with the greatest force on the ball whilst it is near the bottom of the musket-barrel, having been more thoroughly consumed at the first moment of ignition, will probably have a smaller proportional expansive force remaining, after the ball has left the barrel, than the pow- der, which, burning with less energy at first, continues to develop its force as the ball passes through the barrel; and this difference of effect becomes greater in proportion as the length of the barrel is increased, and the absolute quantity of powder in the charge diminished. The apparatus for closing the vent was suggested by that proposed for Mr. Colson's eprouvette, in the fourth number of the Mémorial de Artillerie." The apparatus is represented in Figs. 2234 and 2235 it consists of a block of wrought-iron, hollowed out on the under part to fit the gun, and having a small hole through it to correspond with the vent of the gun when the block is in place; this block is bored longitudinally, 2234. to receive a hollow conical plug of cast-steel, which is ground to fit tight in its place when pushed down to the bottom of the bore in the block; the plug has also a transverse hole, or vent, through it, which corresponds with that in the block when the plug is drawn out about 0.4 inches from the bottom of its lodgment in the block, 80 that, in that position, there is a direct communication open with the bore of the gun. The hollow plug is charged with a small quantity of fine, quick (sporting) powder, over which a paper wad is rammed; it is then placed in the position above described, and the charge is fired by means of a small piece of quick-match inserted in the upper part of the vent in the iron block; the 2235. charge in the gun is ignited with certainty, although there is no priming in the proper vent of the piece; but before the explosion of the charge, the conical plug has recoiled to the bottom of its lodgment, and effectu- ally closed the vent. After the discharge the plug is again driven out, through a hole made for the purpose in the bottom of the iron block; the plug should be fitted 80 as to bear against the bottom at nearly the same time that it becomes wedged in its seat, otherwise too great a force is required to drive it out; on the other hand, if the plug touches the bottom before it binds on the sides, it will fly out again, and not produce the desired effect. Conclusions-The following are some of the practical conclusions which Capt. Mordecai has arrived at by his experiments at the Washington Arsenal. With regard to the proof of gunpowder.-The only reliable mode of proving the strength of gunpow Digitized by Google GUNPOWDER. 939 der is to test it, with service charges, in the arms for which it is designed; for which purpose the ballistic pendulums are perfectly adapted. Although the present tendency to the use of cannon of very large calibre would make the proof by means of a 32-pounder or 24-pounder gun more satisfactory than by using a piece of smaller calibre, it does not seem to be necessary to resort to those heavy guns for obtaining a correct indication of the relative force of different kinds of powder. Such an indication is not given by a 1-pounder gun; but the experiments at Metz have shown that the 12-pounder gun classes the powders in the same order of strength as the 24-pounder; and further experiments may, perhaps, prove that a long gun of yet smaller calibre, a 9-pounder or a 6-pounder, will give corresponding results. I should propose, for the usual proof of gunpowder, to make use of the cannon pendulum alone; employing a gun of the smallest cal- ibre which will give correct results, and firing the balls into a bank of earth, which would not make them unfit for ordinary service. In the 24-pounder gun, new cannon powder should give, with a charge of 4th, an initial velocity of not less than 1600 feet to a ball of medium weight and windage. For the proof of powder for small arms, the small ballistic pendulum is a simple, convenient, and accurate instrument. The cost of the apparatus might be reduced by dispensing, in most cases, with the musket pendulum, and simply firing the ball into the ballistic pendulum-block, from a barrel set in a permanent frame. The initial velocity of the musket-ball, of 0-05 inches windage, with a charge of 120 grains, should be With new musket powder, not less than 1500 feet With new rifle powder, not less than 1600 feet; With fine sporting powder, not less than 1800 feet. The common eprouvettes are of no value as instruments for determining the relative force of different kinds of gunpowder. Of the hygrometric test of gunpowder.-Although the projectile force of gunpowder is the most im- portant quality to be attended to in the proof and inspection, its capability of being long preserved without much deterioration, and of resisting the effects of such exposure as it is subject to in service, must be regarded as of little less importance. This quality should, therefore, be tested either by com- paring the quantity of moisture absorbed, under similar circumstances, by the powder which may be under trial, and by other powder of approved good quality, or by the application of a simple chemical test of the purity of the saltpetre, as it is on this circumstance chiefly that the capacity of the powder to resist the action of a moderate degree of moisture depends. Of the proportions of the ingredients of gunpowder.-The proportions used in making our best pow- der, 76-14-10, and the English proportions, 75-15-10, appear to be favorable to the strength of powder, and not sensibly disadvantageous in other respects; but the ordinary variations in the propor- tions of cannon powder are scarcely appreciable by their effects on its force. Of the mode of manufacture.-The powder of greatest force, whether for cannon or small arms, is produced by incorporation in the cylinder mills," under heavy rollers. In this manufacture, the essen- tial operations are the separate pulverization of the materials, their incorporation by the cylinder mills alone, and the formation into cake by moderate pressure, on thick cakes. The time of running the mills on a given charge must depend partly on the weight of the rollers; but the diminution of this time by means of previous mixture of the ingredients for several hours, in the dust-barrels, appears to impart to the powder a degree of density which, although attended, perhaps, with somewhat increased force in the cannon, is injurious to other valuable qualities of the powder, and especially to its capability of resisting the effects of exposure to moisture. The pounding mill is capable of producing powder of nearly equal force to the cylinder-mill powder, but for that purpose it must be worked not less than 14 or 16 hours, and even then, unless it is pressed, the grain is hardly sufficiently firm to bear, without injury, the jolting of ammunition wagons. Of the density of gunpowder.-The density should not be less than 850; it is not easy, and perhaps not necessary, to establish an absolute maximum of density, on account of the differences caused by accidental variations in the size and form of the grains; but it does not appear necessary or advisable that the gravimetric density should exceed 920. Of the sizes of grain for gunpowder.-If it should not be deemed incompatible with the convenience of service to multiply the varieties of powder for special purposes, there would probably be an advan- tage in using very large-grained powder (such as that designated by A. 0) for 18-inch mortars, and for the heavy sea-const howitzers, in which enormous charges of powder are used. By this means the strain on the gun would be diminished, and the velocity of the ball perhaps increased. For musket powder, by the present standard gages- All the grains should pass through No. 4; About one-half through No. 5; Nearly one-fourth through No. 6. This would give about 2000 or 2500 grains of powder in 10 grains Troy. For rifle powder, all the grains should pass through No. 6. There would then be about 12,000 or 15,000 grains of powder in 10 grains Troy. Of the charges for cannon and small arms.-For cannon, the charge of fth the weight of the ball, with powder of the standard strength proposed, impresses on the ball a sufficient velocity for all the ordinary purposes of service. For any purpose, even for a breaching battery, the advantage gained by using a charge greater than dd the weight of the ball is unimportant, and by no means compensates for the inconvenient recoil, and the destructive strain on the gun and carriage, dic. But as the habitual charge in the French and other services is d, and the battering charge t the weight of the ball, it may be well to compare the effects of these charges of French powder with that of the charges which Capt. Mordecai proposes to substitute for them. For this comparison a glance at the following table will suffice. Digitized by Google 940 GUNTER'S CHAIN. The French 30-pounder corresponds very nearly, in diameter and length of bore, with our 82-pounder. The windage of the balls used in the French experiments is somewhat greater than that of the balls used in Capt. M.'s experiments, but the difference is not very important. Calibre of Place of experiment. Kind of powder. Charge. Velocity of ball Remarks. gun. at the pendulum. Feet. Esquerdes 80-pound. French pounding mill 1513 Mean with 4 kinds of Washington a. 1535 Arsenal 32-pound. A. Cylinder mill powder. 1611 Esquerdes 24-pound. French pounding 1677 Mean of 40 rounds, Metz " mill, 11 hours 1575 with 2 kinds powder. Washington 1570 as a. Powd. made at Mets, Arsenal A. 1687 1836. Metz 24-pound. French pounding mill 1772 Ditto. Washington " A. 1833 For small arms the following charges are proposed: For the percussion musket. with the proposed musket powder, 110 grains. For the percussion rifle, 75 grains. For the percussion pistol, 30 grains of rifle powder. Of cartridges for cannon.-For the purpose of diminishing the strain on the gun, Capt. M. proposes that the principle of increasing the length of the cartridge, by reducing its diameter, should be adopted for heavy guns. The diameters of the cartridge formers may be established as follows: Calibre 42 32 24 18 Diameter of cartridge former Inches 6. 5.5 5. 46 Of the loss of force by windage.-Bring the results into one view, as in the following table: Powder of one Ball. Differences. Ratio of difference. Calibre of kind. gun. Weight. Windage. Velocity. Of windage. Of velocity. Of windage. Of velocity. Lbs. Inch. Feet. Inch. Feet. 24-pound. " 0.007 1578 " of -115 1459 0.108 119 " " -245 1332 238 246 2.28 207 " " 355 1197 348 381 3-22 3.20 " 6 -115 1749 as " 245 1596 0-13 153 06 " 355 1465 .24 284 185 186 By taking the difference between the first windage and each of the others, in each set of experiments, and the corresponding differences of velocity, and then dividing each of these differences by the first of its series, we obtain the ratios between the several differences of windage, and between the correspond- ing differences of velocity. These ratios approach 80 nearly to equality as to authorize the conclusion that the differences in the velocities of balls of different diameters are proportional to the differences of windage; or, in other words, that the loss of velocity by windage is proportional to the windage. Of the loss of force by the vent of the gun.-The loss of velocity in consequence of the escape of gas through the vent of a cannon is inappreciable, in comparison with the unavoidable variations produced by other causes: 80 far as this effect is concerned, it would be nearly useless to close the vent in firing the gun. Of the effect of wads.-In the service of cannon, heavy wads over the ball are, in all respects, inju- rious. For the purpose of retaining the ball in its place, light grommets should be substituted for junk or hay wads, and the latter should be used only for proving guns, for firing hot shot, or for saving the bore of the gun from injury by placing them between the powder and ball, in order to change the seat of the ball, from time to time, and prevent the formation of a lodgment. In small arms, on the other hand, it is of great importance, for developing the full force of the charge, that there should be a good wad over the powder, unless the ball has but very little windage, as in the rifle. GUNTER'S CHAIN, 80 called from its reputed inventor, is the chain commonly used for measuring land. It is 66 feet or 4 poles in length, and is divided into 100 links, each of which is joined to the adjacent one by three rings; and the length of each link, including the connecting rings, is 792 inches Digitized by Google GUTTA PERCHA. 941 The advantage of this measure consists in the facility which it affords to numerical calculation. The English acre contains 4840 square yards; and Gunter's chain being 22 yards in length, the square of which is 484, it follows that a square chain is exactly the tenth part of an acre. A square chain again contains 10,000 square links, 80 that 100,000 square links are equal to an acre; consequently, the con- tents of a field being cast up in square links, it is only necessary to divide by 100,000, or to cut off the last five figures, to obtain the contents expressed in acres. GUNTER'S LINE. A logarithmic line engraved on scales, sectors, &c, serving to perform the mul- tiplication and division of numbers instrumentally, as a table of logarithms does arithmetically. The numbers are usually drawn on two separate rulers aliding against each other. In rough calculations this line affords considerable facilities. GUNTER'S SCALE is a large plain scale, having various lines of numbers engraved on it, by means of which questions in navigation are resolved with the aid of a pair of compasses. On one side of the scale the natural lines (as the line of chords, the line of sines, tangents, rhombs, dc.) are placed, on the other the corresponding logarithmic ones. GUTTA PERCHA, or, more properly, Gutta Tuban, is the concrete juice of a tropical tree, and is drawn, at certain seasons of the year, like the sap of the sugar-maple, by tapping the tree. The mode in which the natives obtain the gutta is by cutting down the trees of full growth and ring- ing the bark at distances of about twelve to eighteen inches apart, and placing a cocoanut-shell, spathe of a palm, or such like receptacle, under the fallen trunk to receive the milky sap that immediately exudes upon every fresh incision. This sap is collected in bamboos, taken to their houses, and boiled in order to drive off the watery particles and inspissate it to the consistence it finally assumes. Al- though the process of boiling appears necessary when the gutta is collected in large quantity, if a tree be freshly wounded, a small quantity allowed to exude, and it be collected and moulded in the hand, it will consolidate perfectly in a few minutes, and have all the appearance of the prepared article. When it is quite pure the color is of a grayish white, but as brought to market it is more ordinarily found of a reddish hue, arising from chips of bark that fall into the sap in the act of making the inci- sions, and which yield their color to it. The great peculiarity of this substance, and that which makes it 80 eminently useful for many purposes, is the effect of boiling water upon it. When immersed for a few minutes in water above 150° Fah., it becomes soft and plastic, so as to be capable of being moulded to any required shape or form, which it retains upon cooling, and regains its original toughness and flexibility. The gutta percha is soluble, but not by the same agents as India-rubber. The fixed oils are all unctuous substances, and acids have no influence upon it. This property renders it very valuable for purposes of machinery, where, when used for driving-bands, as it is most extensively, it is constantly brought in contact with oils and grease. Gutta percha may be manufactured by moulding, stamping, embossing, casting, or any other known process or processes, into various articles of use; as glass and picture frames, cornices, mouldings, and other architectural ornaments, panelling, mosaics, &c.;" in a word, it may be worked into any form, and almost any color may be given, from the simplest to the most complex. Cornices of the most elaborate designs, in imitation of several kinds of wood, are manufactured of it; and from the toughness of the material, even the most delicate representations of foliage are not liable to injury. Copies of old oak panelling taken in the gutta percha, have preserved every trace of the original; the grain of the wood, its abrasion by age, its color and pattern, and all with the utmost fidelity. Impressions taken from coins and medallions are really beautiful; and statues may be copied by it with great truth and at a comparatively small cost. Its capabilities of application to 80 many of the staple articles of our country, aside from its employ- ment in the department of the ornamental arts, gives to its manufacture an almost boundless extent. Something may be judged of the truth of this statement by running the eye over the following list of articles, which by no means exhausts the range of gutta percha: Machine belts and bands; gas-pipes and water-pipes; speaking-pipes; the insulating of telegraph wires; saddles and harness of all kinds; trays, fancy boxes, tables, pumps, boxes, and valves; book- binding, vellum, balls, water-proof roofing, inkstands, drinking-cups, canes, whips, flasks, hate, caps, boots, shoes, clothing; decorations for houses and ship-cabins; chairs; lining for bread casks for sea voyages; air-tight coffins; linings for water-tanks; powder kegs, for the transportation of powder in water soda fountains, gasometers, bottles, pictures, and looking-glass frames. It also recommends itself to the attention of the medical faculty; and as scientific persons give the subject the attention that humanity demands, it will be found to possess valuable properties, superior for many purposes to any other substance. It has already been approved for bougies, catheters, stetho- scopes, nipple-shells, handages, and splints. This latter article is invaluable from the facility with which it adapts itself, when made plastic in boiling water, to the form of the limb; for preserving the strength of medicines of a volatile nature, and in the application of galvanism or electricity to the healing art, it can be made a valuable agent, being a perfect non-conductor. For marine and national purposes, the field is most extensive; as an inside sheathing for ships, for buoys, and beacons, it is supposed to resist for all time the vermin that is 80 destructive in southern waters. Army and navy equipments, canvas, deck-covers, car-covers, sails, and rigging, are rendered impervious to water and dampness, preventing mildew and rot. It is of a light color, and not injured by climate or a tropical sun. For cannon-covers, water-tanks, life-boats, and many other applications, it is destined to supersede metal and India-rubber. It will also be found superior to glue in its adhesive properties, and to the gums generally, as a basis for various varnishes, sizings and paints, being weather-proof and not liable to crack. Gutta percha is a perfect non-conductor of electricity, and, as above stated, is used for the insulating of telegraph wires; in Prussia the wires are covered with the gutta and embedded in the earth, and afford by far the best and surest means of preserving telegraphic communication. Various experiments have been made to ascertain its strength when mixed with other matters and Digitized by Google 942 GUTTA PERCHA. also as to what pigments would mix with it without rendering it brittle or deteriorating its qualities. From these it appeared that the only pigments that could altogether be relied on to be used with gutta percha, were orange lead, rose pink, red-lead, vermilion, Dutch pink, yellow ochre, and orange chrome. Under the influence of heat and pressure, gutta percha would spread to a certain extent, and more so if mixed with foreign matters. All the mixtures composed of gutta percha and other substances which had been subjected to experiment, except that containing plumbago, were found to increase its power of conducting heat; but in its pure state gutta percha was an excellent non-conductor of electricity. The best composition for increasing the pliability of gutta percha was that formed in conjunction with caoutchouc tar, and next in order that of its own tar; and the best material at present known for moulding and embodying was obtained by mixing gutta percha with its own tar and lamp-black. Dri- ving-bands for machinery are thus made, and shoe soles and heels are stamped out of similar sheets of gutta percha. In making tubes or pipes of gutta percha or any of its compounds, a mass of gutta per- cha, after being thoroughly masticated, is placed in a metal cylinder furnished with a similar piston, by which it is pressed down into an air-box, kept hot with steam, which has at its lower end a number of perforations, through which the plastic material is forced into a cup, whence it passes out, round a core, into the desired tubular form, and thence through a gage to the required size, and into a receiver of cold water, being drawn to the other end of a long trough by a cord passing round a pulley at the far end of the trough, and returning to the person in attendance on the machine, who gradually draws the pipe away from the air machine. Thus tubes of considerable length and diameter are made to a very great extent, and are used for the conveyance of water, liquids, and gas. The machinery for working the crude gutta percha is constructed and worked as follows: Fig. 2236 is a side elevation of the slicing machine; Fig. 2237 a front elevation of it; and Fig. 2238 a sectional elevation A on the line a b of Fig. 2237. A A represents the frame-work; B is a circular iron plate, of about five feet diameter, in which are three slots, into which are inserted three radial knives, in a similar manner to the irons of an ordinary plane or spoke-shave. Bª is a shaft, to the end of which the plate B is attached, and by means of which it is made to revolve at any desired velocity, motion being communicated to the shaft from a steam-engine, or any other convenient first mover, through the medium of geering or drums. D is an inclined shoot, down which the lumps of crude gutta percha are dropped against the knives of the re- volving plate B, by which they are cut into slices of a thickness corresponding to the degree of projec- tion given to the knives. The slices are afterwards collected, and put into a vessel filled with hot water, where they are left to soak till they feel soft and pliable to the touch. 2237. 2236. 2238. (i D B D B A A 22 The knives are represented in the drawings as being straight; but where the gutta percha to be cut happens to be of a more than usually hard or intractable quality, it is advantageous to substitute knives of a curved or reaping-hook form, on account of their more gradual mode of action. Fig. 2239 is a longitudinal elevation in section of the machinery through which the gutta percha is passed, after having been steeped as aforesaid in the hot-water vessel till it has become soft and pliable to the touch. T is a large tank, which is divided into three compartments tet, of which t1 and tª are filled with water to the height of the line xy, and ts with water to the height of the line x 2. FFF are three breakers or rollers, with serrated blades inserted in them in a direction parallel to their length, which are mounted transversely over the tank T, and revolve clear of the water. In front of each of these breakers there is a pair of fluted feeding-rollers G' G'. H' is a funnel-shaped shoot. through which the softened pieces of gutta percha, after being taken from the hot-water vessel, are passed to the feeding rollers G1 of the first breaker F1. H' is an inclined endless web, which revolves on two rollers a a, and dips at its lower end into the water, while at its upper end it comes opposite the space between the feeding-rollers of the breaker F2. H' is a second inclined endless web, which bears the same relation to the third breaker FS as H' to F. K is a mincing cylinder, with radial blades (similar to that used in paper-mills for the conversion of rags into pulp) which is mounted transversely over the third compartment t³ of the tank, but at a lower elevation than the breakers F¹ F' Fᵃ, so that one-half of it shall always be immersed in the water in that compartinent. L is an edge-plate, 80 fixed that the blades of the cylinder K shall, in revolving, come into such close parallelism with it, as to pro- duce, by their approximate conjunction, a scissor-like sort of action on any matters which may come in contact with it. The mincing-cylinder K has, like the breakers F¹ F* F, an endless web H, and a pair of feeding-rollers G' attached to it. M is a rotary agitator, which is wholly immersed in the water Digitized by Google GUTTA PERCHA. 948 of the compartment ts. N is a revolving endless web, which stretches in an inclined direction athwart the whole depth of the water in t3, and subdivides (as it were) the compartment to into two divisions. R R, R R, are a series of pairs of rollers, mounted transversely over the after part of the compartment t, at such an elevation that the under rollers revolve under the water, and the upper just free of it. SS are a series of tables or benches, placed between the pairs of rollers, for the purpose of supporting the gutta percha in its passage from one to the other. V 2239. H z The action of this machinery, 80 far as it has been thus described, is as follows: The feeding-rollers G', the carrying-rollers of the endless webs H2 H' and Hª, and the rollers R R, are all made to revolve in a forward direction, or from left to right of the machine, as represented in Fig. 2239, while the breakers F' F'F', the mincing-cylinder K, and agitator M are made to revolve in the opposite direction. (The mechanical contrivances by which these movements are affected are omitted from the figure, as being all of a common and well-understood description.) The breakers and mincing-cylinder should revolve at the rate of from 600 to 800 revolutions a minute, but the feeding- rollers and endless webs need not move faster than at about a sixth of that rate. The first series of rollers R R should revolve at the rate of from fifteen to twenty revolutions per minute, and the others may be made to exert a drawing or stretching effect on the materials passed between them, by causing one, two, or more of the last pairs in the series to revolve at a greater velocity than the preceding ones. As the crude gutta percha is presented by the feeding-rollers G' to the action of the first breaker F', it is broken up into shreds or fragments, and considerable quantities of earthy and other extraneous mat- ters are beaten out of and disengaged from it, the whole falling in a mingled mass into the water be- neath, (that, viz. which is contained in the compartment t1 of the tank,) where the different materials assort themselves according to their specific gravities. Such pieces as consist of pure gutta percha, or in which gutta percha predominates, float on the surface of the water, while most of the earthy and other extraneous matters sink to the bottom. The revolving endless web H' then draws towards it the floating gutta percha, and carries it upwards to the second set of feeding-rollers G', mounted over the second compartment t of the tank, from which rollers it is delivered to the second breaker F'. to un- dergo a repetition of the process which has been just described. in order to its being further disentangled and purified. From the surface of the water in the compartment t, the gutta percha is carried up the inclined endless web H' to the rollers G, which deliver it to the third breaker F' over the compart- ment tˢ, by which it is a third time broken up. in order to any remaining impurities being separated from it. The inclined endless web H' next carries it forward to the rollers G, which present it to the revolving cylinder K, by the blades of which it is cut or minced into a multitude of very thin alivers, which, as they fall into the water in t³, are thrown forward in the direction of the agitator M. As this agitator revolves in a direction opposite to that in 1 which the floating mass of gutta percha is moving. it forces the gutta percha down into the water, and to take a circuitous course through it towards the large K endless web N, whereby it is washed free from any dirt which may have collected upon it in passing 2240. through the preceding operations. By the endless web N, the gutta percha is next moved onwards to the series of rollers R R, R R; and from the last pair A G F H of the series, the gutta percha is raised by an endless a revolving web o to a pair of metal pressing and fin- D ishing rollers Y1 Y', which are set by adjusting screws to a distance from one another equal to the L E thickness of the sheet or band into which it is now desired that the gutta percha should be compressed. F After passing through between Y'Y', the sheet or band is carried back over the topmost of these roll- 11 B ers Y2, and then over the wooden drum U, to be wound on a taking-up roller V. As it is turning back over the roller Y'. a sheet of cloth, or any other material suitable for joining with it, may be led in, as shown at W, and, by being pressed in conjunction with it between Y2 and the drum U, it will be firmly united to it. Digitized by Google 944 GUTTA PERCHA. The water in all the compartments of the tank T should be used cold. When the crude gutta percha happens to have a foetid smell, as is not unfrequently the case, mix with the water a solution of com- mon soda, or of chloride of lime. + 8766 2241. In effecting the combination of sulphur and sulphurets with gutta percha, expose the gutta percha, after it has been cleansed and purified and reduced to a sheet state, to the combined action of steam of a high temperature, and the vapors of orpiment (or other volatile sulphuret) and sulphur, (mixed in the proportions last hereinbefore specified,) in an apparatus of the description represented in Fig. 2240. A is a strong metallic chamber set in the brick-work BB, into which the materials to be sulphu- Digitized by Google HAMMER. 945 retted are placed. C is a steam-tight cover or door, which is secured to the top of the chamber by screw bolts, 80 that it may be unscrewed and removed as occasion may require. D is a common high-pressure steam-boiler. E is a strong metal pot into which the orpiment, or other sulphuret, and sulpbur are placed. d a lid or cover through which the materials are introduced; and E' a fireplace by which the pot is heated. F is a pipe leading from the boiler into the head of the pot E; and a a cock by which it is opened and closed. G' is a pipe leading from the top of the pot E to the chamber A, and b a cock by which it is opened and closed. H is a safety-valve attached to the boiler, and K a safety- valve attached to the chamber A. I is a thermometer to indicate the temperature. The mode of operating with the apparatus is as follows :-The boiler-furnace is first lighted, and when the safety valve indicates an approach to a temperature of 280° Fah, the other furnace is lighted which is to volatilize the orpiment and sulphur. The cocks a and b are then opened, and the steam allowed to pass off through the pipes F and G, and head of the pot E, into the chamber A, containing the mate- rial, in order that they may be thoroughly heated before being sulphuretted. After a short time fumes from the orpiment and sulphur begin to ascend and mingle with the steam. In this state I leave mat- ters for a period varying from half an hour to two hours, according to the thickness of the materials operated upon. I then close, by means of the cock b, the passage to the chamber A, draw or damp the fires, raise the safety-valve K, and when the chamber À has been cleared of vapors, remove the sulphuretted materials. The safety-valve H is kept, all the time the sulphuretting process is going on, at a little higher pressure than the safety-valve K, in order that there may be a current in the direction of the chamber A. L is a cock by which the condensed water, which accumulates in the chamber A, is drawn off. The calenders, represented by Figs. 2241 and 2242, as used in the manufacture of driving-bands and sheets of gutta percha, at the Gutta Percha Works of Brooklyn, New York, have rolls 6 feet 4 inches in length, and 22 inches in diameter, and each roll will weigh about 7000 pounds. The rolls are heated by steam. GYRATION, the centre of, is that point in which, if all the matter contained in a revolving system were collected, the same angular velocity will be generated in the same time by a given force acting at any place as would be generated by the same force acting similarly in the body or system itself. The distance of the centre of gyration from the point of suspension, or the axis of motion, is a mean proportional between the distances of the centres of oscillation and gravity from the same point or axis. If S represent the point of suspension, G the place of the centre of gravity, o that of the centre of oscillation, and R that of the centre of gyration. Then, SR=VSO.SG and so. =a constant quantity for the same body and the same plane of vibration. 9943. HAMMER, ANDERSON'S patent. In this hammer, the claw, as will be seen by the cut, extends to the handle and clasps it with a strong ring, which makes it impossible, in drawing nails, for the handle to give way, draw out, or become loose. The face of the patent hammer will thus always remain true, it being kept at the same angle with the handle. Six different sizes are now made, weighing from half a pound to one and a half pounds. HAMMER, steam. JAMES NASMYTH'S patent steam-hammer. Before pro- ceeding to describe the principle, mode of action, and constructive details of the direct-action steam-hammer, it may be proper to make a few remarks on the ordinary forge-hammers, 80 that the nature of the advantages possessed by the steam-hammer may be more clearly understood. In all forge-hammers previously in use, the force necessary to set them into operation had to be transmitted in a very indirect manner,-for whether a water-wheel or steam-engine were the moving power, the requisite lifting and falling action of the hammer had to be produced by the employment of rotatory motion, thus rendering necessary the use of wheels, shafts, cams, and other cumbrous details, which, together with the apparatus requisite to connect the various parts of the machinery, and give due strength and solidity to the whole, not only caused great outlay and sacrifice of valuable space, but also occasioned much loss of power, by reason of the very circuitous manner in which the force of the prime moving agent had to travel ere it reached its final destination, and came forth in blows from the forge-hammer. Great inconvenience, also, was found to result from having a considerable portion of the working machinery close to the hammer, as thereby a very serious impediment was offered to the free execution of the work. And when we add to this very limited range in the clear fall of an ordinary forge-hammer, (seldom, in any case, exceeding 18 inches,) causing the force of the blow to decrease in a very rapid ratio, with a moderate increase in the diameter or depth of the work and when we take into consideration the fact that, in consequence of the helve of the hammer working on a centre or joint, its face is parallel to that of the anvil only at one particular distance; and finally, when to this list of inconveniences we add that in the ordinary forge-hammer we possess no power or control over the force of its blows, but are compelled to make the best use we can of them, whether they be adapted to our purpose at the time or otherwise, we find inherent in the very principle of such hammers, a combina- tion of evils and inconveniences that only excite surprise that they should have been suffered to exist for so great a length of time. This remark is most strikingly applicable in the case of those forge-hammers which receive their power from a steam-engine, inasmuch as the power in question originates in the motion of the piston, in the very state and condition in which, for the purpose of hammering, we desire it ultimately to be, namely, as a straight up and down motion; so that instead of causing this reciprocating action of the piston-rod to pass through all the complex media of beam, connecting-rod, crank and cam shaft, for no 119 Digitized by Google 946 HAMMER. other purpose than to cause it to act in the same manner as at first,-if we dispense with all this mare of intermediate machinery, and simply invert the steam cylinder 80 as to bring its piston-rod out at the bottom of the cylinder, and attach it directly to a block of iron working in guides right over the anvil- 2244. R 1 c 111 UHII THE III. N z G face, we shall then have obtained all the grand essentials of a forge-hammer in its simplest and most obvious, and, at the same time, as experience has demonstrated, in its most perfect and efficient form. Such is the Direct-Action Steam-Hammer, and such considerations as the preceding led to the inven- tion of this machine. Digitized by Google HAMMER. 947 Some idea of its efficiency in shingling puddled balls may be formed from the fact, that one of 30 cwt., which has been for nearly two years in constant operation at the Gartness Works of the Monkland Iron Company, in the West of Scotland, works off with perfect ease the constant produce of from 18 to 20 puddling furnaces. For this duty the steam-hammer is found to be peculiarly adapted, as it can be made to act for the first few strokes as a squeezer, to bring the puddled ball to a neat cubical form; after which it may be made to deal out upon it such energetic blows as secures the entire expulsion of all cinder and other non-metallic impurities, the absence of which, to a greater or less extent, mainly determines the quality of wrought-iron. In short, in every process where either blows of the most enormous energy, or slight taps of the utmost gentleness are required, either continuously or in all grades of variation from the one extreme to the other, the steam-hammer offers facilities which have never hitherto been obtained from any mechanical contrivance for such purposes. Fig. 2244 represents a side elevation of the steam-hammer, exhibited in full operation, the hammer- block, valve-geer, and other working parts being disposed in the positions which they occupy at the termination of a stroke. Fig. 2245 is a general plan corresponding to the above. Fig. 2246 is an end elevation, and Fig. 2247 a vertical transverse section of the machine. Fig. 2248 is a sectional elevation of a portion of the machine, showing the positions of the hammer- block, valve-geer, and other working parts when the hammer is raised for a fresh stroke. The framing of the steam-hammer consists of two strong cast-iron standards A A, bolted and further secured by keys to a broad base-plate BB, embedded in the solid masonry forming part of the floor of the forge. The standards are surmounted, and their upper extremities united by a species of entabla- ture C, in which the steam-passages and valve-face are formed, and to the upper surface of which the steam cylinder D is bolted. The piston-rod E is fitted to work vertically through a stuffing-box in the centre of this entablature, and its lower extremity is directly attached to the mass of cast-iron F, form- ing the hammer-block, which is guided to a strictly vertical and rectilinear course by being made to work freely in planed guides formed on the interior surfaces of the standards A A. The hammer a itself is inserted into a dovetail recess in the bottom of the block F, where it is retained by wooden packing and iron wedges; while the anvil b is in a similar manner-secured to the anvil-block G, which is a mass of cast-iron of such weight as effectually to oppose, by its inertia, the momentum of the ham- mer, and prevent the force of the blows from being dissipated. Such are the main features of this machine; from which it will be at once understood that, if we can provide the means of rapidly raising the hammer-block to a sufficient elevation, and then as rapidly letting it fall down upon, and 80 give a blow to the work placed upon the anvil, we have all that is requisite to produce a forge-hammer in its simplest, and, at the same time, its most powerful and per- fect form. The duty above adverted to, of raising the hammer-block, is performed by the direct application of the elastic force of steam. For this purpose, the steam is led on to the machine by the steam-pipe H, communicating with a neighboring high-pressure boiler; a throttle, or shut-off valve c, inclosed within the valve-box I, being situated close to its junction with the main steam-valve chest J, and brought within the control of the attendant workman by means of the rod and lever dd. The alternate admis- sion of the steam into the cylinder by the port and its escape therefrom by the passage g, and waste steam-pipe K, are regulated by means of the alide-valve e, which may either be worked by hand, or, through the intervention of the self-acting mechanism to be hereafter specified, by the action of the machine itself. The piston L, which is strongly constructed of malleable iron, and fitted with a single packing ring, works steam-tight within the cylinder D; and being directly attached by the piston-rod E to the hammer-block F, it will be obvious that, on the admission of steam of sufficient elastic force beneath the piston, we are supplied with the means of raising the hammer-block to any required height within the range of the machine; while by opening the communication between the under side of the piston and the external atmosphere, the action of gravity will be unimpeded, and the hammer will de- scend upon the work placed on the anvil, and discharge a blow upon it, energetic in proportion to the weight of the hammer-block, and the height from which it has fallen. And as, by these simple means, there is no practical inconvenience in supplying the power to raise a hammer-block of 5 or 6 tons weight to an elevation of 7 or 8 feet above the anvil, some idea may be formed of the vast energy of the blows given out by such a mass of iron falling rapidly through 80 great a space, and discharging the whole of its momentum upon the work placed below on the anvil to re- ceive it. In the case of the old system of forge or helve hammers, about one-third only of the total weight of the hammer was effective, the other two-thirds resting on the pivot-standards; 80 that, in this point of view, the proportion between the blow of a steam-hammer and that of a helve-hammer is nearly 8 to 1 in favor of the former. It will be seen, further, that the anvil-face and hammer-face are at all times parallel to each other, whatever be the height or distance between them. The practical value and importance of this prop- erty, which is inherent in the principle of the steam-hammer, has been duly appreciated by all who have had experience of the working of this machine. With a view to prevent any risk of the piston striking the cylinder-cover when working to the full, or very highest stroke of the hammer, a very simple but effective air or steam recoil spring is provided, by having the cylinder-cover screwed down quite air-tight, so that as soon as the piston passes, in its upward motion, the holes hh, the air or steam remaining above is shut up in the upper chamber; and as it has no means of escape, it acts as a most perfect spring in arresting any further rise of the piston; and has, besides, the important advantage of converting into increased downward velocity of action the undue upward action, which might otherwise have proved not only useless, but destructive. The in- crease of energy in the blows which can be obtained by this simple means is a point of considerable importance. It is scarcely necessary to remark that, in the emergency above adverted to, the aper- tures h h act as safety-valves for the issue of the main body of the steam, which escapes through the passage ii, into the exhaust or waste steam-pipe K. Digitized by Google 948 HAMMER. 2246. M M 7 i z 2248. RUN o O D R 1 R$1 Q i I H. C P H K R d' X W C R N 00 P T 17 a a T % 0 S A z Y G 2 39 K B 2245. D e K A c D I MODERT. so M H Plan of Fig. 2244 on preceding page. Digitized by Google HAMMER. 949 Another point of constructive detail worthy of special notice is, the peculiar mode adopted for con- necting the piston-rod to the hammer-block. This is one of the most important details in the entire invention, and without which no practical success would have attended it. Had the piston-rod been attached to the hammer in the ordinary mode of attaching pistons to the machinery of a 2247. steam-engine or such like, namely, by a cotter, or by screwing the rod into the hammer, or such other solid, unyielding mode, the effect of the blow or fall, at each stroke of the hammer, would have been that the piston-rod and piston (being composed of a considerable mass of materials) would have themselves acted as a hammer, and would have discharged their momentum upon the means of fastening, and this with such de- structive effect as to break through all such solid, unyielding means of resistance, after a few blows. This was foreseen from the first as an action to be prevented, and accordingly, in my original drawing, already adverted to, a remedy was pro- vided, which experience has proved to be entirely D effectual. This contrivance consists in placing, in a cylin- drical recess formed in the body of the hammer- block, and under the knob i, on the end of the J 0 piston-rod, a series of pieces of hard wood, or other slightly elastic material, as in Fig. 2246. The effect of this arrangement is to allow the momentum of the piston and piston-rod to de- posit itself in such a comparatively gradual man- " ner as to cause the concussion arising from the most severe and energetic blows of the hammer to have not the slightest evil effects on the piston and rod; it is, in fact, the very same expedient 0 to which nature has had recourse for the pur- pose of obviating those unpleasant and destruc- tive shocks and vibrations which we should ex- perience at every step or stamp of the foot, had no cartilage been provided between the joints of our bones. It is surprising to observe by how small an amount of elasticity, from the employ- ment of such compressible material, the evil effect of violent shocks may be removed. The connection of the piston-rod and hammer-block is secured by means of the two keys kk, driven very firmly above the knob or button j, a layer or two of the elastic material being interposed for the purpose of neutralizing any shock in the con- trary direction. We shall now proceed to describe the mechan- ism by which the height of the fall of the ham- mer, and consequent intensity of the blow, may be modified according to circumstances, and the machine made perfectly self-acting. The requisite alternating motion of the steam- valve e is produced in the following manner :- The valve-spindle l is prolonged upwards and attached to a small solid piston m, working within a short cylinder M, bolted to the main steam cylinder D. A small portion of steam is supplied above the piston m, by a slender copper tube n, communicating with the steam valve- chest J; by this arrangement it will be seen that, unless counteracted by some superior force, the pressure of the steam upon the piston m will tend to keep the valve e constantly depressed, in which position the steam-port f is full open. This counteracting force is supplied by the action of the hammer itself; for, by means of the tap- pet N, (which is bolted to the hammer-block,) coming into sliding contact, when the latter is raised, with the small friction-roller o, mounted on the end of a bent lever 00, the screwe I ro I l'. which is jointed to the opposite end of that lever, is depressed, and that motion being co unrinicate I to the valve-spindle 1, through the intervention of the connecting-rod Q and valve-lever R. the steam- Digitized by Google 950 HAMMER. valve e is raised, thus cutting off all further ingress of steam under the piston, and almost at the same instant permitting the escape of that which had served to raise the hammer. By this simple contri- vance the upward motion of the hammer is made the agent for its own control in that respect. By com- paring the relative positions of the parts referred to, as exhibited in Figs. 2244 and 2248, the nature of the motion above described will be at once most fully understood. To obviate the injurious effects of the shock of the tappet N against the lever o, a connection is provided at p, on a similar principle to that formerly described in reference to the connection of the piston-rod and the hammer-block; and in order to restrict the downward travel of the valve to the proper point, a check or buffer-box S is pro- vided, consisting of a small cylinder bolted firmly to the framing of the machine, within which a circular nut, screwed on the lower end of the rod P, works as a piston, a few leather washers being interposed between the latter and the close or upper end of the cylinder. It may be here remarked, that it is by no means necessary to continue the admission of steam under the piston until the termination of the upward stroke, or lift of the hammer, seeing that the velocity which the hammer-block has acquired in its upward motion makes it continue to ascend after the fur- ther ingress of the steam has been arrested. This circumstance is a source of considerable economy of steam, as we have by such action (as well as by that due to the expansive energy of the steam) an effect as to height of lift of the hammer, greater than that which is due to the actual expenditure of steam at its original pressure. It is worthy of remark, also, that as the over-running action above alluded to will necessarily increase in proportion to the velocity of ascent of the bammer-block, this cir- cumstance will, to a considerable extent, compensate for the increased expenditure of steam due to that increased velocity. From the above description it will be obvious, that the lift of the hammer, and consequent intensity of the blows, depends simply upon the position of the lever o, in relation to that of the hammer-block when at its lowest point. Therefore, if we can provide the means of altering the distance between these two points, we shall have it in our power to modify permanently the force of the blows to any required extent within the range of the machine. This condition is most completely satisfied by the arrangement of mechanism employed by me, and which is clearly represented in the figures. The rod P which conveys the action of the lever 0 to the valve-lever R, is screwed throughout the greater part of its length, and is 80 adjusted in its bearings, as to be susceptible of rotatory as well as vertical motion. This motion of rotation is imparted to it by means of a handle fixed to a short axis, working in a bracket T bolted to the framing, and actuating a pair of small bevel-wheels q q. The nut through which the screw works forms the point of attachment between the rod P and the lever O, the connection being effected by means of a short intermediate rod for the sake of insuring parallelism of motion. A pair of small spur-wheels r, (through the first of which the rod P works by means of a sunk feather,) serve to transmit the angular motion of the rod P to a similar screwed-rod U, situated parallel to and at a short distance from the former; the nut of the screw U forms the fulcrum or centre of motion of the lever O, and the pitch of the threads of both screws being equal, though formed in con- trary directions to each other, it is obvious that, on turning the handle, the lever o and all its appen- dages will be simultaneously raised or depressed, and consequently the lift of the hammer regulated to any required extent, and its amount altered with the utmost ease and precision. The pin which forms the centre of motion of the lever o is protected and secured from lateral strains by the cast-iron guides V and W, seen most distinctly in the sectional plan, Fig. 2245. A most essential part of the self-acting geer remains yet to be noticed. It is obvious that, were no provision made for the retention of the steam-valve in the position into which it is thrown by the up- ward motion of the hammer-block, the latter would not be permitted to have its due effect in the accomplishment of its work; for, as soon as it descended 80 far as to relieve the end of the lever o from contact with the tappet N, the valve would resume the position into which it is constantly solicited by the action of the steam-spring at M, and the descent of the blow would be impeded by the return of the steam into the cylinder, before the hammer had completed its fall. To obviate this inconvenience, a simple but most effectual contrivance has been applied. Towards the lower extremity of the valve- screw P a shoulder is formed, against which a short lever w, called the trigger, is constantly pressed by the spring x, 80 that when the rod P is depressed by the action of the lever O, it is arrested by the trigger and retained in that position until the blow has been struck. This delicate and most important part of the mechanism is very carefully constructed, the point of the trigger, and the shoulder against which it acts, being formed of steel, and hardened to resist wear. To release the valve-screw from the trigger, and so permit the return of the valve into the position requisite for effecting a fresh stroke, the following mechanism has been adopted on the front of the hammer-block, Figs. 2244 and 2248, a lever X, called the latch-lever, is fitted to work freely on a pin passing through the body of the hammer-block. That portion of the latch-lever which is most remote from the valve-geer is considerably heavier than the opposite end, and is constantly pressed upwards by means of a spring. The lighter end is brought into contact with a long bar 88, called the parallel bar, the extremities of which are suspended upon two small bell-cranks tt, whose other arms are con- nected by means of a slender rod u, Fig 2247, forming a species of parallel motion, for the purpose of adapting this geer to come into efficient operation, at whatever point in the range of the hammer its blow may be arrested. A small connecting-rod v, between the lower bell-crank and a short lever on the axis of the trigger w, completes this part of the mechanism. The action of this geer is of a very peculiar nature, and is admirably adapted to fulfil the object in- tended. At the instant the hammer gives a blow to the work upon the anvil, the effect of the concus- sion is to cause the momentum of the heavy end of the lever X to overcome the upward pressure of the spring, and thereby to protrude its opposite end against the edge of the parallel bar 8, which motion, though but slight in amount, is yet adequate, through the arrangements above described, to throw back the trigger from contact with the valve-screw, and leave the latter free to obey the impulse of the steam- spring in the readjustment of the valve into its original position. Digitized by Google HAT-MAKING. 951 These various movements, which have taken 80 long to describe, are all performed in less than half a second, and consequently the action of the hammer is proportionally rapid. The construction of the self-acting geer is so arranged as to admit of advantage being taken, when circumstances render it desirable, of the very action to obviate which the trigger w is introduced. When it is desired to strike a gentle blow, such as is frequently required during particular stages in the prog- ress of a piece of work, it is not requisite, for this purpose, to change the position of the valve-lever O. All that has to be done is to hold back the point of the trigger 20, by its handle y; this permits the valve to reopen and let the steam in under the piston L, at the instant the tappet N has fallen away from contact with the lever O. The effect of this is, that a quantity of steam is admitted into the cylin- der under the piston, which serves as a cushion, by which the violent fall of the hammer is arrested, and its momentum modified to any extent, or at the pleasure of the person in charge of the handles. The handle z, is for the purpose of placing the steam-valve also under his control, and, for his further convenience in the management of the hammer, a platform Y and hand-rail Z are erected against the framing of the machine. A modification of the frame of this machine has been made at the Washington Navy Yard, one sup- port only being used, by which means access is had to the anvil on all sides except that occupied by the support. HAMMER, Tilt or Trip. See TILTING. HARVESTER. An agricultural machine for reaping and gathering in grain, much used in the western country. There are many forms of them, known in this part of the country as REAPERS, which see. HAT-MAKING embraces two distinct kinds of manufacture, felted and covered hats; the covering of the latter being sometimes silk, and at other times cotton. Felted hats comprehend two classes, differing chiefly in the materials used in making, the process being nearly identical. The lower class is marked by inferior ingredients, unmixed with beaver, and embraces wool, plated, and short-nap hats. Wool hats are made entirely of coarse native wool and hair stiffened with glue. Plates have a nap or pile rather finer than their body, and are sometimes water-proof stiffened. Short naps are distin- guished from plates by additional kinds of wool, viz. hare's back, seal, neuter, musquash, (Muscovy cat,) and are all water-proof stiffened. The second class may be said to comprehend two orders, called stuff and beaver hate. The first in- cludes mottled and stuff bodies. The latter term is not used generally, as all stuffs are understood to be of this sort when mottled is not expressed. Mottled bodies are made chiefly of fine wool, and inferior rabbit down or coney wool. Stuff bodies consist of the best hare, Saxony, and red wools, mixed with Cashmere hair and silk. Stuff hats are napped, that is, covered with pile of mixed seal, neuter, hare- back, inferior beaver, and musquash. Beaver hats are, or ought to be, napped with beaver only the lower priced qualities with brown wooms taken from the back; the more valuable kinds with cheek and white wooms, being the finest parts of the fur found on the belly and cheeks of the beaver. The apparatus and terms used in making felted hats, which it is necessary to describe briefly, are the bow, basket, hurdle, battery, and planks. The bow is about six feet long, usually made of ash, thick enough not to be elastic. The handle is called the stang. The bmo-string is a strong catgut cord tensely fastened. The hurdle is a fixed bench, with three enclosing sides, to prevent the stuff being flittered off in bowing. The basket is of light wicker-work, about twenty by twenty-two inches in size. The battery consists of the kettle and the planks. which are inclined planes, usually eight in number, one only being appropriated to each workman. The half of each plank next the kettle is lead, the upper half is mahogany. The first process in hat-making is bowing the stuff or furs, which are weighed out to a proportionate scale, and laid on the hurdle, immediately under the bow, which is suspended by a pulley. The bow is held firmly with the left hand, rather towards the breech-end, not edgewise, but on its side, with the string in contact with the stuff, the clotted and adherent portions of which are separated into single fibres, and attain a loose, flocky, mixed condition by the continued vibration of the bow-string, caused by a very rapid succession of touches with the bow-stick. It is then divided as nearly as possible, and one-half laid aside, whilst the other is again bowed. In this second operation, partly by the bowing, but chiefly by the gather- ing, or patting use of the basket, the stuff is loosely matted into a conical figure, about fifty by thirty-six inches, called a bat. In this formation care is taken to work about two-thirds of the wools down to- wards what is intended for the brim, which being effected, greater density is induced by gentle pressure with the basket. It is then covered with a wettish linen cloth, upon which is laid the hardening skin, a piece of dry half-tanned horse-hide. On this the workman presses or bakes for seven or eight minutes, until the stuff shall have adhered closely to the damp cloth, in which it is then doubled up, freely pressed with the hand, and laid aside. By this process, called basoning, (from a metal plate er bason, used for like purposes in making wool hats,) the bat has become compactly felted and thinned towards the sides and point. The other half of the flocked stuff is next subjected to precisely the same proceedings, after which, a cone-shaped slip of stiff paper is laid on its surface, and the sides of the bat folded over its edges to its form and size. It is then laid paper-side downward upon the first bat, which is now replaced on the hurdle, and its edges transversely doubled over the introverted side-lays of the second bat, thus giving equal thickness to the whole body. In this condition it is reintroduced between folds of damp linen cloth, and again hardened, 80 as to unite both halves, the knitting together of which is quickly effected. The paper is now withdrawn, and the body being folded into three plies, is removed to the plank or battery-room. In the battery the liquor is scalding heat, composed of pure soft water, with about half a gill of oil of vitriol as an astringent. Herein the body is imbrued, and withdrawn to the plank to partly Digitized by Google 052 HAT-MAKING. cool and drain, when it is unfolded, rolled gently with a pin tapering towards the ends like a liquor horse, turned, and worked with in every direction, to toughen, shrink, and at the same time prevent adhesion of its sides. Stopping or thickening the thin spots which now appear on looking through the body, is carefully performed, by additional stuff daubed on by successive supplies of the hot liquor from a brush frequently dipped into the kettle, until the body be shrunk sufficiently, (about one-half,) and thoroughly equalized. When quite dried, stiffening is performed with a brush dipped into a glutinous pulpy composition, and rubbed into the body; the surface intended for the inside having much more imposed than the outer, while the brim is made to absorb many times the quantity applied to any other part. This viscous matter contains proofing, or those ingredients which render the hat water- proof. On being again dried, the body is ready to be covered, and is once more taken to the battery. The first cover of beaver or napping, which has been previously bowed, is equally strewed on the body, and patted upon with the brush charged with the hot liquor, until incorporated; the cut ends only being the points which naturally intrude. Here the body is put into a coarse hair-cloth dipped and rolled in the hot liquor, until the beaver is quite worked in. This is called rolling off, or ruffing. A stripe for the brim round the edge of the inside, is treated in like manner, and is thus prepared for the second cover, which is applied and inworked in like manner: the rolling, &c., being continued until the whole has become incorporated, and a clean, regular, close, and well-felted hood is the result. The dry hood, after having the nap beat up and freed, is clipped to the length which may be thought best, by means of common shears. A clipping machine, invented nearly four years ago in Scotland, is now very generally preferred, and doubtless will soon everywhere supersede the ordinary process; much greater regularity, speed, and certainty being secured by it. When the nap is thus disposed of, the hood is soaked in the battery kettle, and then drawn down on a block to the size and shape wanted, firmly tied at the bottom with a cord, around which the brim is left in a frilled condition. Dyeing is the next step. A suit, or six dozen, are put into the dye-kettle at a time, all on the crown- blocks already mentioned, and allowed to remain three-quarters of an hour in the liquor, which is kept as near as possible one degree below the boiling point. These being taken out and set in the yard to cool, another suit is introduced for a like period, and the various suits are 60 treated at least twelve times in successive order. Each of the first four introgressions of every suit is accompanied by about seven pounds of copperas, and two pounds of verdigris. The body is then washed and brushed out in changes of hot water, until no coloring can be recognized in it. When thus thoroughly cleansed, it is steamed on a block shaped as the hat is wished to be when complete; and in the finishing shop by neavy (21-pound) heated irons and moisture, the frilled brim is shrunk until rendered quite level, the nap gently raised all over with a fine wire card, and brushed and ironed smooth in the uniform direc- tions. The tip, a thin lath-sheet, is then fitted and stuck to the inside of the crown, and robbined or secured all round the edges by stripes of prepared paper. When thus got down, it is sent to the picker, who, with tweezers, extracts the kemps, or "gray hairs," which are a few of those thick fibres peculiar to the fur of amphibious animals, that have escaped the search of the machine used in blowing the beaver, 80 as to separate them from its fine parts. This being carefully accomplished, it is transferred to the finisher, who, with a plush cushion, a brush, and hot iron, imparts to it that bright sleeky lustre. The shaper then rounds the brim with a knife and notched segment to the breadth wanted; and shapes it in varied styles by means of a hot iron and damp, with about a foot length of rope, over which the curl is laid. The trimming is next done, when the tipper-off corrects the twists, smooths the ruffled nap caused by trimming, and papers it up with tissue and cartridge, which com- pletes it for the retailer. Silk hats are made upon bodies of wool, stuff, willow, straw, and Leghorn plait, and cambric and woollen cloth, although chiefly on felted wool bodies, which are dipped in glue size, wrung out, blocked, and dried. The tip is then fitted and robbined, when a flour-box, charged with powdered shell-lac and rosin in like quantities, is used to strew equally its grainy mixture on the external surface of the shell, so called from being the frame-work. This is burned in by hot irons, first on the top, which passes through to the lath-tip within; then on the upper brim, the sides, and, finally, the under brim. When this is hardened it is coated with thick ordinary flour-paste, which is dried, and the shell again blocked and smoothed; then once more glue-sized outside, dried, and varnished, which prepares it for covering. The shag for the sides is cut across the web, in a ratio of obliquity increased by inferiority. This cross part is sown to a circular piece for the crown, whilst the brims are singly patched together. These preparations being completed, the top-side or upper brim is first stuck, then the crown, next the sides, and, finally, the under brim. Sticking is effected simply by the heat of the iron passing through the covering and melting the varnished surface. In the finish of this manufacture, the most particular part is the side-seam, which is disposed of thus The selvidge end is cut perpendicularly from top to brim, by a sharpened pallet-knife, the nap having been previously brushed clear off its edge. The other selvidge end is then stuck and cut with the utmost nicety, in close parallel with the other. It is then finished very much in the same manner as a beaver hat. The above-mentioned method of making hat-bodies is now mostly superseded in this part of the country by the adoption of machinery, the manual labor being confined to the getting up the hat, and is a distinct business; the hatter for the most part purchasing his hat-bodies far cheaper than he can make them. The machinery is very simple. The fur or hair of which the felt is to be made, after being cleaned and lightly beat up, by passing through a kind of winnowing machine, is delivered to a boy, who spreads the fur very lightly and in small quantities on an endless web before him, which, passing between rollers, carries the fur into the body of the machine, where it encounters a cylindrical brush in rapid motion, which separates the hair or fur completely, throwing it towards a contracted opening in the sides of the cylinder-case. This opening, about an inch wide at top and nearly three inches at bottom, is in height equal to the cone of the hat-body. Immediately in front, and close to this opening, Digitized by Google HAY AND CORN CUTTER. 958 is placed a perforated copper cone, the perforations 80 small, and in such number, as almost to render the surface of the cone, from base to apex, a wire-gauze surface. This cone is open at the bottom and placed on an opening equal to its base, which opening is in communication with a fan or blast, so arranged as to exhaust the interior, or "suck," 80 to speak, the air through the meshes of the copper cone. The hair or fur in its divided state, thrown towards this opening in the cylinder-case, is brought under the influence of the powerful draught towards and through the cone; the latter at the same time slowly revolving on its axis, exposes all its sides to the opening, and the hair is driven against it with such force as to adhere for the time, and receive and retain on all sides, as it revolves, the fine particles of hair as they are drawn from the cone. In the space of half a minute a dry hat-body is formed on the copper cone; this is immediately enveloped by a wetted felt, and the whole immediately removed, and its place supplied by a fresh copper while the first is being stripped of its now wet felt. The whole operation is performed with wonderful dispatch, the hat-body resulting from it being ex- ceedingly light and uniform in texture, and requires but little labor before it is in condition to be trans- ferred to the hands of the batter for working up. In this manner any form of felt may be made. The opening in the cylinder-case being of flexible metal, admits of adjustment to the wants of the particular form of the felt to be constructed. The application of this principle is universal in the manufacture of felt. HAY AND CORN OUTTER. J. ROMAN'S rotary and vibrating self-feeding cutter, patented June 20th, 1848, is well adapted to farmers in cutting hay, straw, and corn fodder, and grinding the latter to any fineness required, without any more power comparatively added. It has decided advantages: First, it presents more edge of knife, and nearer to the centre, therefore having all advantages of the power both in cutting and grinding. In ordinary machines it presents from three to five feet of edge; this depends on the diameter of the knives used, as the last part of the cut is effected with as much ease as the first. This is owing to the vibration of the box, and the rotary motion of the knife at the same time, as the substance, whilst being cut, is not a greater distance than five inches from the centre shaft. 2249. 1 JUNE 20 1848. A B C a M K' C' D a T 6 S G C" a A E R 0 A A' D J. ROMAN'S PATENT. 2 This machine may be adapted to the use of bookbinders, for the purpose of cutting paper or the edges of books, and for harness-makers or shoemakers. It is also well adapted to the cutting of dried or fresh meat and bread, and can, with advantage, be used in almost every branch of the useful arts in which fibrous or texile substances have to be cut to any great extent, 9950 as there can be a series of knives on the same shaft, 80 as to expedite the business required; and, also, the knife or knives may be serrated or B smooth, best adapted to the substances required to be cut. The operator takes hold of handle H and turns it, which revolves the crank F and G and the wheel D; the wheel D geers into pinion I, which A revolves the knife B and the balance-wheel J, which are on the shaft K; the crank F, in the mean time, through the connecting-rod L, vibrates the holder or box C by the arm M, alternately before and to one side of the knife at the same time; at the same time the crank G, through the agency c of the connecting-rod N, depresses the lever o and the ratchet-dog Q which hooks upon and turns the wheel R, and with it the feed-rollers S advance the fodder or substances required to be cut every time the feed- box or holder, during its vibrations, moves to one side of the knife. HEART-WHEEL A contrivance for converting a uniform circular motion into a uniform rectilinear motion. It is much employed in the machinery of the cotton and flax manufacture, and is formed after the following manner: Draw a line A B equal in length to the required ex- 120 Digitized by Google 954 HEAT. tent of the alternating rectilinear motion, and divide this line into any number of equal parts, the more the better. From the centre, C, round which the heart-wheel is to move, with any distance (which need not be great) describe the semicircle A bc, and divide it into the same number of equal parts as the line AB. From the centre draw radii passing through each of these points, and extend them a considerable way beyond the circumference. Next from the centre C take the distance to the first division on the line A B, and lay off that distance on the first radius, passing through the division on the semicircle, then take the second, third, fourth, &c., divisions from the centre C in succession on the line A B, and lay them off successively on the second, third, fourth, &c., radii, then will a line drawn through all these points on the radii be the face of one half of the wheel. The other half is formed after the same manner. The curve of the face of the wheel is in this case the spiral of Archimedes, but the alternating rectilinear motion may be made to follow any given law besides that of uniformity, by changing the nature of the curvature of the face of the wheel, which may be easily done by making the divisions on the line A B increase or diminish from the centre or the ends, and constructing the figure in other respects as before. HEAT. Heat, in the ordinary application of the word, signifies, or rather implies the sensation ex- perienced upon touching a body hotter, or of a higher temperature, than the part or parts which we bring into contact with it: in another sense, it is used to express the cause of that sensation. To avoid any ambiguity that may arise from this double use of the same expression, it is usual and proper to employ the word caloric to signify the principle or cause of the sensation of heat. On touching a hot body, caloric passes from it, and excites the feeling of warmth: when we touch a body having a lower temperature than our hand, caloric passes from the hand to it, and thus arises the sensation of cold. Caloric is usually treated of as if it were a material substance; but, like light and electricity, its true nature has yet to be determined. Caloric passes through different bodies with different degrees of velocity. This has led to the division of bodies into conductors and non-conductors of caloric: the former includes such bodies as metals which allow caloric to pass freely through their substance, and the latter comprises those that do not give an easy passage to it, such as stones, glass, wood, charcoal, &c. Table of the relative Conducting Power of different Bodies. Gold 1000 Platinum 981 Silver 973 Copper 898 Iron 374 Zinc 363 Tin 304 Lead 180 Marble 24 Porcelain 122 Fire-brick 11 Fire-clay 11.4 With Water as the Standard Water 10 Elm 32 Pine 39 Ash 31 Lime 39 Apple 28 Oak 33 Ebony 22 Relative Conducting Power of different Substances compared with each other, Hares' fur 1.315 Cotton 1046 Eider-down 1-305 Lint 1032 Beavers' fur 1-296 Charcoal 937 Raw silk 1.284 Ashes (wood) 927 Wool 1.118 Sewing-silk 917 Lamp-black 1.117 Air 576 Relative Conducting Power of Fluids. Mercury 1·000 Proof spirit 312 Water 357 Alcohol (pure) 232 Radiation of caloric.-When heated bodies are exposed to the air, they lose portions of their heat, by projection in right lines into space, from all parts of their surface. Bodies which radiate heat best, absorb it best. Radiation is affected by the nature of the surface of the body; thus, black and rough surfaces radiate and absorb more heat than light and polished surfaces. Table of the Radiating Power of different Bodies. Water 100 Blackened tin 100 Lamp-black 100 Clean " 12 Writing-paper 100 Scraped " 16 Glass 90 Ice 85 India-ink 88 Mercury 20 Bright lead 19 Polished iron 15 Silver 12 Copper 12 Reflection of caloric differs from radiation, as the caloric is in this case reflected from the surface without entering the substance of the body: hence the body which radiates, and consequently absorbs most caloric, reflects the least, and vice versd. Latent caloric is that which is insensible to the touch, or incapable of being detected by the thermom- eter. The quantity of heat necessary to enable ice to assume the fluid state is equal to that which Digitized by Google HEAT. 955 would raise the temperature of the same weight of water 140°; and an equal quantity of heat is set free from water when it assumes the solid form. If 5f lbs. of water, at the temperature of 32°, be placed in a vessel communicating with another one, (in which water is kept constantly boiling at the temperature of 212°,) until the former reaches this temperature of the latter quantity, then let it be weighed, and it will be found to weigh 6} lbs., showing that 1 lb. of water has been received in the form of steam through the communication, and reconverted into water by the lower temperature in the vessel. fow this pound of water, received in the form of steam, had, when in that form, a temperature of 212'. It is now converted into the liquid form, and still retains the same temperature of 212°, but it has caused 57 lbs. of water to rise from the temperature of 32° to 212°, and this without losing any temperature of itself. It follows, then, that in returning to the liquid state, it has parted with 5f times the number of degrees of temperature between 32° and 212°, which are equal 180°, and 180° X 51 = 990°. Now this heat was combined with the steam; but as it was then not sensible to a thermometer, it was called Latent. It is manifest, then, that a pound of water, in passing from a liquid at 212° to steam at 212°, receives as much beat as would be sufficient to raise it through 990 thermometric degrees, if that heat, instead of becoming latent, had been sensible. The sum of the sensible and latent heat of steam is always the same at any one temperature; thus, 990° + 212° = 1202°. If to a pound of newly fallen snow were added a pound of water at 172°, the snow would be melted, and 32° will be the resulting temperature, 138° of heat becoming latent in the melted snow. Latent Heat of various Substances. Fluids. Vapors. Ice 140° Steam 990° Sulphur 144 Vinegar 875 Lead 162 Ammonia 860 Beeswax 175 Alcohol 442 Zinc 493 Ether 302 Sensible caloric is free and uncombined, passing from one substance to another, affecting the senses in its passage, determining the height of the thermometer, and giving rise to all the results which are attributed to this active principle. See STEAM. It is frequently desirable to convert the degrees of heat, as indicated by one thermometer, into its equivalent as denoted by another. The following rules will serve this purpose for the thermometers in general use:- To reduce the degrees of a Fahrenheit thermometer to those of Reaumur and of the centigrade the zero of the Reaumur scale being at the freezing point, and 80° at the boiling point, whilst the zero of the centigrade is at the freezing point, and 100° at the boiling. See THERMOMETER. Fahrenheit to Reaumur.-Rule.-Multiply the number of degrees above or below the freezing point by 4, and divide by 9. Thus, 212° - 32 = 180 X 4 = 720 ÷ 9 = 80, Ans. + 24° 32 = 8 X 4 = 32 ÷ 9 = 3.5, Ans. or 3.5 below zero. Fahrenheit to centigrade.-Rule.-Multiply the number of degrees above or below the freezing point by 5, and divide by 9. Thus, 212° 32 = 180 X 5 = 900 ÷ 9 = 100, Ans. Or multiply the degrees of Fahrenheit by 444 for reducing them to Reaumur, and by 555 for reducing them to centigrade. Medium heat of the globe is placed at 50°; at the torrid zone, 75°; at moderate climates, 50°; near the polar regions, 36°. The extremes of natural heat are from 70° to 120°; of artificial heat, from 91° to 36,000°. Evaporation produces cold, because caloric must be absorbed in the formation of vapor, a large quantity of it passing from a sensible to a latent state, the capacity for heat of the vapor formed being greater than that of the fluid from which it proceeds. Evaporation proceeds only from the surface of the fluids, and therefore, other things equal, must depend upon the extent of surface exposed. When a liquid is covered by a stratum of dry air, evaporation is rapid, even when the temperature is low. Table of Effects upon Bodies by Heat. Fahrenheit. Fahrenheit. Cast-iron, thoroughly smelted 2754° Lead, melts 594° Fine gold, melts 1983 Bismuth, melts 476 Fine silver, melts 1850 Tin, melts 421 Copper, melts 2160 Tin and bismuth, equal parts, melt 283 Brass, melts 1900 Tin 8 parts, bismuth 5, and lead 2, melt 212 Red heat, visible by day 1077 Alcohol, boils 174 Iron, red-hot in twilight 884 Ether, boils 98 Common fire 790 Human blood (heat of) 98 Iron, bright-red in the dark 752 Strong wines, freeze 20 Zinc, melts 740 Brandy, freezes 7 Quicksilver,"boils 630 Mercury, melts -89 Linseed oil boils 600 Digitized by Google 956 HEDDLES. Wedgewood's zero is 1077° of Fahrenheit, and each of his degrees is equal to 130° of Fahrenheit. Expansion of Solids. At 218°, the length of the bar at 32° considered as I-0000000. Glass 0008545 Gold 0014950 Platina 0009542 Copper 0017450 Cast-iron 0011112 Brass 0019062 Steel 0011899 Silver 0020100 Marble *0011041 Fire orick *0004928 Forged iron 0012575 Lea 1 0028436 Granite 0007894 Zin 0029420 To find the expansion in surface or in volume, it must be remembered that each dimension of a solid experiences a similar proportional expansion. Table of the Expansion of Air by Heat.-By Mr. DALTON. Fahrenheit. Fahrenheit. Fahrenheit. 32° 1000 50° 1043 80° 1110 83 1002 55 1055 85 1121 34 1004 60 1066 90 1132 35 1107 65 1077 100 1152 40 1021 70 1089 200 1854 45 1032 75 1099 212 1376 Melting Point of Alloys. Lead 2 parts, tin 8 parts, bismuth 5 parts, melts at 212° " 1 " « 4 " " 5 " melts at 246 a 1 " " 1 " melts at 286 " 2 « " 1 " melts at 336 a 2 " " 8 " melts at 334 " 8 " as 1 " melts at 892 " 2 « " 1 " common solder, melts at 475 " 1 " " 2 " soft solder, melts at 360 Boiling points.The boiling point of water, from 27 to 31 inches of the mercurial column, varies 165° for every inch, being at 80 inches 212° and on this variation is founded the apparatus for deter- mining altitudes. Comparative Heat from various Fuels. 1 lb. of tolerably good coal will raise the temperature of 60 lbs. of water from 32° to 212°. 1 lb. of kiln or perfectly dried wood will effect the same on 35 lbs. 1 lb. of wood simply dried in the air " " 26 lbs. 1 lb. charcoal " " 79 lbs. Turf of good quality yields as much heat for equal weights as wood, and the heat it gives out by radiation whilst burning has been considered even greater than that of wood. For the various methods of applying heat to the warming of buildings, see article WARMING. HEDDLES, Machine for making Weavers'. This machine is the invention of Mr. KASSIMIR VOGEL, of Lowell, Massachusetts. The object of the machine is to make weavers' heddles from the thread, casting the loop by braiding instead of knotting, and performing triple the amount of work, and better than can be done by hand. A patent is also secured for the peculiar eye of the heddle, so that both machine and its results are protected. Description.-Fig. 2251 is a perspective view, and shows gangs of different heddles winding on the beams. A A is the iron framing. B are the driving and slack pulleys. C is the lever to geer and un- geer. EE are the bobbins, with the thread to make the heddles. There is a small shaft under the bed of E, which, by small cog-wheels on the same, operate and revolve the bobbins by geering into F. II are the heddles after the eye is formed, winding up on the beams LL The gang of wheels at the left are for the purpose of connecting the shafts of the beams to be driven by the main shaft below. The number of eyes to the foot in the heddles can be increased or diminished by the geering of these small wheels. K is a small bearing for the shaft of L, and J is the shaft with a screw cut on part of it. This is for winding the heddle gradually along the beam, and as K is a grooved and wormed faced pulley driven slowly by the small gang of wheels at the right, the shaft J is wormed slowly through its bear- ings, carrying the beam to let the heddles wind one after another on the same. The heddles are formed of a double cord, which is twisted by the bobbins revolving. and the eyes or loops are formed by the bobbins being interlocked, braiding the two strands at the two points which form the eye of the heddles. The section views will explain the operations better in detail. As the same letters indicate like parts on all the following engravings, we shall describe them col- lectively. Fig. 2252 is a side elevation. Fig. 2253 is a top view of the revolving tables and spindles. Fig. 2254 is an end elevation. Fig. 2255 is a view of the under side of the machine, showing the geer- ing by which the tables that carry the spindles are made to revolve. Digitized by Google HEDDLES. 957 A is the heddle-beam. BBBB are revolving spool-frames or tables. C represent the spool-spin- dles. a are slots in the spool-tables. Each table has six slots or spindle recesses, but only three are occupied at once with the spindles. As the tables revolve, three slots are occupied with spindles and three are empty alternately, and an occupied slot in one is brought opposite to an empty recess in its 2251. c L I I I I I J L A K B E H. F H A A fellow-table, as seen in Fig. 2253. The tables BB constitute one pair, and the tables B 2, B 3, another, forming two distinct harness, one on each side on two beams, but driven by the same geering. The yarn is put on the spindles C, and passes through a hole in the top of the fiyers D, or over a depression, Fig. 2252, to hold it in its place, and then passes under c, a recurved wire, that has a perforated weight M. 2252. J Q II P n 0 K D c c c 0 N B B E E J I H F F dd at each end. The flyers pass through these holes, and the legs serve as guides to the weights. This is to take up the slack of the yarn. The spindles have each a groove in their lower parts, adapted to slide into the recesses of the tables when the recesses coincide. The platform EE has circular cavities for the lower ends of the spindles. FF, Fig. 2252, are fast and loose pulleys to drive the Digitized by Google 958 HEDDLES. shaft G. A bevel-wheel H, on G, gives motion to the revolving spool-tables by toothed wheels, as seen at Fig. 2255. The bevel-wheel I, Fig. 2252, gives motion to the heddle-beams by geering into J, on the shaft K. This shaft carries a worm-wheel, which geers into M to drive A. N is an eccentric on K 2253. A of P c a B B N a E E L c B B c a P A to vibrate g, a shipper, which shifts the spindles from one table to another; the opposite ends of g operate on two pairs of tables. A connecting-rod with N vibrates the shippers. N is connected with K, and turns with it by clutch-pins, and when these are not engaged the shafts turn without N. ii, Fig. 2254, is a pin that passes through N, projecting out above and below, nearly in contact with K. There 2254. L M I M P 0 K i 0 M m. " F are two clutch-pins on K, either of which may be brought in contact with i, as the eccentric-wheel is made to slide up and down on the shaft. 0, Figs. 2252 and 2254, is a forked lever with its fulcrum at e Its fork ends m m embrace N, the eccentric, and raise and lower it at proper times. nn is a spiral spring attached to the forked lever, serving to draw it inwards to depress the eccentric and make it Digitized by Google HELIOTROPE. 959 clutch with the lever clutch-pin. On the wheel M are cams or lifting pieces pp, which, when they come in contact with the end of 0, force it out and raise N, the eccentric, so as to engage with the upper clutch-pin at the required time, as will be understood by Fig. 2254. The axis of A is P, a screw, Fig. 2252, tapped into the frame of the machine and moves A endwise as it revolves, to wind the heddles, as they are made spirally on the beams. q is the smooth axis of A, on which the beam slides, moved by the screw on the guide-rods rr. QQ are rods that may be inserted in grooves in A. The semi-diameter of A must be of the length of the heddles. After the number of heddles for a harness have been made, grooved pieces may be slipped over Q and glued upon them to embrace the twisted strands, or any other mode may be adopted. The shipper connecting-rod h, (which looks like an n,) Figs. 2252 and 2253, has a hinge-joint t, to allow it to be lifted from the shipper g. The small bevel- wheel J, on the shaft K, is one-third of the diameter of the driving-wheels, when there are three spindles on the table, and therefore makes the changes of the spindles in the recesses in one revolution of the revolving spool-tables. If there were four spindles in the table, the wheel J would be one-fourth the diameter of the driving-wheel, &c. 9955. E E a I H To explain its operation, Fig. 2251 exhibits a different arrangement of mechanical parts from the sec- tion views, but they are just the mechanical equivalents to accomplish the same thing. Heddle or harness making is the formation of eyes by two cords being knotted together. These eyes must be formed at regular distances on the harness. This machine forms two cords by BB, revolving and twist- ing the yarn on the three spindles, one by each table revolving, the cord winding at the same time as it is twisted on the beam A. Now to form four eyes on the heddles every revolution of the beam, look at Fig. 2253. If the strands that make the two cords were interlocked at certain periods, eight times during the revolution of A, that four eyes would be formed by the strands of the two cords being thus at certain points braided into one another. This is the way this machine does its work, and this can be done by the forked lever in Fig. 2254 shifting the shipper, or by cams on the inside of the upper geer-wheel of Fig. 2251. To make the spindles in c interlock to braid the eyes. The cams or clutch operate the shipper g, so that instead of vibrating from side to side, as now seen in Fig. 2253, touching the spindles outside, it is (the shipper) stopped by the resting of the eccentric one-sixth of the revolu- tion of the tables, and then it will be easily perceived that the shipper will take into the inside of the spindle e and throw it into the empty recess a of the other table, which coincides, thus interlocking the threads and braiding the two cords together into one, forming an eye of the heddle by braiding instead of knotting. It will be observed, too, that the clutch can be changed by cams, to operate the shipper, to make as large or as many eyes in a foot as may be desired: but the changing or passing of the spindles from one table to another must be performed by the shipper twice for one eye, according to the length of the eye, and they are not shifted again until A has revolved the distance wanted to form the base of a new eye for the harness. HELIOTROPE Reflecting Lantern, used by Major J. D. GRAHAM as meridian marks for great distances, in 1841, while tracing the due north line from the monument at the source of the river St. Croix. The lantern was constructed by Messrs. Henry N. Hooper & Co. of Boston, under Maj. G's directions. It was similar in form to the Parabolic Reflector Lantern, sometimes used in light-houses, but much smaller, 80 as to be portable. The burner was of the argand character, with a cylindrical wick, whose transverse section was half an inch in diameter, supplied with oil in the ordinary manner. This was placed in the focus of a para- bolic reflector, or paraboloid, of sheet-copper, lined inside with silver about 1-20th of an inch in thick- ness, polished very smooth and bright. The dimensions were as follows: Inches. Diameter of the base of frustrum of reflector 16. Distance of vertex from base 8-75 Distance of focus from vertex 2.25 Diameter of cylindrical burner 50 Diameter of a larger burner which was never used, but which, by an adapting piece, could be easily substituted 1.25 Digitized by Google 960 HELIOTROPE. The instrument answered the purpose for which it was intended admirably well, and was of great use in tracing the due north line. While it occupied the station at Park's Hill, 15 feet above the sur- face of the ground, or 828 feet above the sea, in the latter part of September and early part of October, 1841, the light from it was distinctly seen with the naked eye at night, when the weather was clear, from Blue Hill, whose summit, where crossed by the meridian line, is 1071 feet above the sea, the intervening country averaging about 500 feet above the sea, and the stations being 36 miles apart. The light appeared to the naked eye, at that distance, as bright, and of about the same magnitude, as the planet Venus. Viewed through the transit telescope, of 48 inches focal length, it presented a luminous disk, of about 30 seconds of an are in diameter. The wick employed by Major G. was considerably smaller than that usually made, even for parlor lamps; and to this cause is attributed, in a great measure, the perfection with which the parallel rays were transmitted from the reflecting parabolic surface, 80 as to make them visible at 80 great a distance. Though a greater quantity of light is generated by a larger wick, the portion of rays reflected in a direction parallel to the axis, and which alone come to the eye, is the smaller as the flame transcends the focal limit. The size of wick most advantageous for use may easily be determined by experiment. The smaller is its transverse section. provided it is only large enough to escape being choked up by the charred particles, even one-third, or perhaps one-fourth of an inch, the further the light would be visible. Lanterns of this description might be used with great advantage as station-marks in extensive trigo- nometrical surveys, requiring primary triangles of great length of sides. A revolving motion might be given to the lanterns, 80 as to make the light transmitted from them visible from many different stations within short intervals of time. Their simplicity, and the ease with which they are managed, would perhaps give them, for such purposes, a great advantage over the Drummond or Bude lights, even though they be not so brilliant as the latter. The heliotrope, which is employed in the day-time, was made by order of Mr. Hassler, at the instru- ment shop of the coast-survey office. It was a rectangular parallelogram of good German plate-glass, 1 4-5ths by 1 1-5th inch in size, giving an area of reflecting surface of 2100 square inches. This also was seen at the distance of 36 miles. END OF VOL I. 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