US334152A - Attoehes - Google Patents

Description

Patented Jafi. 12 1886.

BABGOOK.

. AIR 0R GAS ENGINE.

(No Model.)

INVENTGR /4//J A? fla ware/ BY I ATTORNEY I I G. l

N, PETERS. PhohrLilhugmpher, Walh'mgton. D. C.

WITNESSES:

FICE.

GEORGE H. BABOOOK, OF PLAINFIELD, NEYV JERSEY.

AIR 0R GAS ENGINE.

SPECIFICATION forming part of Letters Patent No 334.152, dated January 12, 1886.

Application filed April es, 1.884.

To all whom it nmy concern.-

Be it known that I, GEORGE H. BABOOOK, of the city of Plainfield, county of Union,and State of New Jersey, have invented certain new and useful Improvements in Air or Gas Engines, of which the following is a specification, reference being bad to the accompanying drawings, forming part of the same.

Before proceeding to a description of myinvention I will observe that there are two classes of air-enginesone known as the Stirling Engine in which a given quantity of air is alternately heated and cooled, producing a variation in pressure, and thus developing energy, and the other is what is known as the Ericsson Engine in which a quantity of atmospheric air is taken in, heated, expanded, and rejected at each revolution.

My invention relates to the first class, in which the same air is alternately heated and cooled in the engine, which offers the advantage, by using a highly-compressed fluid, of securing a large power within a small space, and also the advantage of a higher efficiency of the fluid, owing to a less loss of heat.

There is also another division by which airengines may be classed, the first, A, known as the Cailey Engine, in which the products of combustion are used directly within the cylinder, which secures a high rate of economy over the second class, 13, comprising those in which the air is heated by conversion through a heating-surface. Hitherto no practically successful effort has been made to combine this class A with the Stirling engine in which the same air is alternately heated and cooled.

My invention relates to such a combination whereby the advantages of both classes are attained in one engine,with additional advantages due to the combination.

In the drawings, Figure 1 is a vertical section of an engine embodying my invention, and Figs. 2 and 3 details to be hereinafter referred to.

The frame-work and base-plate of the engine are not peculiar,and need not be specifically described.

Serial No. 129,574. (No model.)

gers are made in the well-known manner of similar engines, having a deep portion filled with some non-conducting substance to protect the wearing-surface from the direct ac tion of the heated fluid. The lower portions, A B of these cylinders are surrounded by water-jackets,for conveying away the surplus heat thereof and keeping the surfaces sufficiently cool to admit lubrication.

' O is what is known asa regenerator, consisting of a collection of plates, of iron or other material, with small interstices through which the fluid passes on its way to and from the hot end of the cylinder, which regenerator serves the purpose of retaining a portion of the heat of the hot gases and restoring the same to the cold gasesin a manner well known in similar engines.

D is a refrigerator, consisting of a series of small tubes surrounded by water, through which the air passes on its Way to the cold end of the cylinder for the purpose of taking out such heat from the air as has not been absorbed by the regenerator, also a well-known device.

E is the crank -shaft, having two cranks placed at an angle to each other and connected in the ordinary way to the two pistons A and B, transmitting their power and controlling the time of their motions. Fig. 3 shows the relation of these cranks one with the other. I find in practice that the angle of seventy-five degrees gives the best results, but this may be varied as circumstances require.

F is a furnace wherein the combustion takes place, and having passages f, connecting it with the interior of the cylinders A and B. This furnace F may be of any size and burn any fuel as is found to be practicable; but I prefer to make it, as shown, quite small, and to burn therein some form of hydrocarbon fuel, as hereinafter described.

- G is a pump automatically operated by a connection with the engine, and here shown as connected with an eccentric, H, on the main shaft E, for the purpose of'supplying the fuel to the furnace F. The connection of this pump G with the shaft is shown more fully in Fig. 2, in which the eccentric H is connected to one end of a link, I, the other end of which is jointed to adistance-rod, H, attached to the shaft or any other convenient stationary point. It will be seen that by the variation of the position of the link I relative to the plunger G any amount of stroke may be given to the I such water at will. I also provide with the plunger G from the full throw of the eccentric to nearly or quite none. The length of the distance-rod H bears such relation to the plunger G and the eccentric H that the plunger G is caused to approach to nearly the inner end of thebarrel of the pump G ateach stroke, whatever may be thelength of the stroke. Instead of varying the stroke of thepump G, the same object may be attained by connecting therewith a vessel containingapiston or other means for varying the size thereof, into which vessel a portion of the gas within the pump G may be allowed to expand asit is compressed, and the amount of fuel pumped into the engine may thereby be reduced. The position of the piston within this vessel or supplementary chamber may be determined by a governor, so as to automatically control the amount of gas delivered while the stroke of the pump remains constant. Y

The Valves g and g are of ordinary construction, and need not be specifically described. A pipe, K, leads from the pump G to the furnace F.

Lis an air-pump, for the purpose of supply ing air for the proper combustion of the fuel within the furnace F. It is of ordinary construction, having valves H and plunger L, and is driven, preferably, by an eccentric, M, on the main shaft. The stroke of this pump L may be made tovary in the same manner as the pump G, or the amount of air supplied thereby may be otherwise varied, as described above in connection with the said pump G; but I prefer that it should have a constant stroke, as shown. A pipe, N, leads from the air-pump L to the furnace F.

Any of the well known means may be employed for igniting the fuel within the furnace; but when the interior of the furnace, which consists of a refractory substance, like fire-brick, has once become heated to incandescent temperature the fuel will ignite spontaneously upon coming in contact therewith.

I provide a valve, 0, in the passage a, through which the air passes to and from the cold end of the changing-cylinder A, which valve is operated by an eccentric, O, mounted on the main shaft, or by other means. This valve is similar to the slide-valve of a single-acting steam-engine, and admits a portion of the air or actuating-fluid from the passage a at each revolution into the annular space 1), formed between the cylinder 13 and the trunk of the plunger B. This annular, space may bear any desired proportion of area to the area of the cylinder B to admit of any desired expansion to the portion'of the air which is admitted thereto by the valve 0. The passage a is formed with a depression or pocket, a in which any water condensed from the products of combustion will accumulate, and in which the valve 0 is situated, so that when any water accumulates therein it will be blown out on the opening of the valve 0. A pet-cock, X, is also provided for removing passage a a th rottle-valve, P, by closing which more or less the resistance of the passage of the air or gas from the cold to the hot end of the cylinder A, or vice versa, may be increased or diminished. The stem ofthis valve P extends'out through a proper stuffing-box, and is connected through an arm, 1), to a centrifugal governor, Q, whereby the valve 1? is caused to be operated automatically by the varying speed of the engine.

Another centrifugal governor, B, Fig. 2, is connected to the distance-rod H in such a manner that when the speed of the engine increases the link I is drawn over to reduce the throw of the plunger G, and thereby decreases the supply of fuel to the furnace F. This governor R, instead of being attached to the distance-rod H, may be connected to a variable chamber communicating with the pump G, or with any other means for controlling the so ply of gas to the furnace.

Iprefer to graduate the two governors R and Q relatively to each other in such a manner that the: governor R shall have completed its action before the speed has increased to such an extent as to cause the governor Q to operate the valve P, so that in controlling the speed of the engine the amount of fuel supplied to the furnace F will be thus reduced to a minimum, and if that be not sufficient then the throttle-valve P will be brought into action to increase the internal resistance of the engine.

The operation of the engine is as follows: The interior of the cylinders A and B, the regenerator 0, tubes D, and passage a and furnace F, all communicating, are first filled with a volume of atmospheric air or other gas at any desired pressure by a pump or otherwise. The engine being turned over by hand or by any other convenient means, the plunger Ais caused to descend and force the air which is below it through the refrigerator D and re generatorO into the upper portion of the cylinder A. At the same time the fuel pump Gand air-pump L deliver aportion of gas or other fuel with the necessary oxygen for its combustion into the furnace F, whereit is ignited, and the products of combustion, passing through the ports f, mingle with the air or gas within the engine, causing the whole to become heated and the pressure thereof to ,ipcrease. This forces the plunger B to descend, exerting the energy derived from such pressure upon the crank E The plunger A now returns by the revolution of the crankshaft and crank E, forcing the heated air or gas in the upper part of the cylinder A down through the regenerator O, which absorbs the larger part of the heat therein through the refrigeratorD, which takes away the balance of that heat into the lower end of the cylinder A thus reducing the temperature and the pressure, when by the revolution of the crank E the plunger 13 is forced back into the cylinder B, driving all the air therein,a1so through the regenerator-O and refrigerator 1), into the lower part of the cylinder A. The valve 0 having opened for A is now brought again to the lower end ofthe changing cylinder, forcing the cold air therefrom around through the refrigerator D and regenerator G into the upper end of the cylinder A, in which passage it has taken up the heat which was stored in the regenerator O and beenincreased in pressure. At the same time the fuel pump G and air pump L have delivered another supply of fuel to the furnace F, and the products of combustion from it have passed in and mingled with the air or gas within the engine, still further increasing its heat and pressure, by which the plunger 13 is forced outward, as before. This cycle of operations continues regularly with each revolution. The valve 0 is so arranged that it will admit only a definite amount of air from the passage a into the annular space I), which volume is less than the volume of the pump L. It will therefore be seen that so long as the pressure within the passage a bears the same inverse ratio to the volume of air admitted into space I) that the atmospheric pressure bears to the volume of the pump L, the quantity of fluid within the engine will remain constant. It will also be seen when the valve 0 is adjusted to admit into the annular space b a definitely smaller volume of air than the volume of the air-pump L that if the pressure in the engine A B is such that this volume of air so admitted into I) does not weigh the same as the volume of air which is pumped into the furnace F through the pump L, the pressure in A B must increase with each stroke until the equilibrium between the amount of air delivered by the pump L and the amount of air removed by the valve 0 is secured.

The furnace F may be heated up before starting the engine by building a fire within the same, or by a gas-jet, or by introducing a live hot coal just before starting the engine. It may alsoin some cases be made sufficiently large to receive a quantity of solid fuel, in which case the pump G can be dispensed with, the pump L furnishing air for the combustion of the fuel within the furnace as rapidly as the needs of the engine require.

The advantages due to my invention are, the heat, being applied directly to the gases within the engine, is all utilized, with the exception of the small proportion, usually about one-tenth, which is rejected through the refrigerator D or is lost by radiation. That is taken from the cold end of the engine after it has passed through the regenerator C, wherein a large portion of its heat has been stored or trapped. This air-therefore carries off none of the heat supplied to the engine, as does the exhaust of an ordinary gas-engine or any form of the Oailey engine heretofore known. By the use of the same fluid in the engine, stroke after stroke, it requires but a small proportion of the highly-heated products of combustion to be mingled therewith in order to impart the required amount of heat. The air-pump L is therefore small in proportion to the capacity of the engine, and the loss from compressing a large amount of air at each stroke is saved, and the cost of compressing the air compressed by the pump -L is nearly repaid by the expansion of the air in the annular space b. It is evident that this annular space I) can be replaced by an independent piston working in another cylinder; or it could be replaced by inclosing the lower portion of the pump L; but I prefer to employ the annular space, as shown. V

A difficulty which attends nearly all air and gas engines exists in consequence of the resistance of the compression of the air in the cyl inder in some portion of the revolution, and this difficulty increases greatly in engines in which a high pressure is used.

One of the advantages due to my invention is that the engine may be started at atmospheric pressure with little resistance, and after a few revolutions the pressure will accumulate in consequence of the pump L putting in more air than the valve 0 lets out, which will continue until the proper pressure is attained and the engine is ready to work at its full load. It is evident also that the governors Q and R might be replaced by asingle governor, so arranged as to act first upon the link I, and secondly upon the throttle-valve P; but such an arrangement forms part of a separate application for patent which I make coincident herewith. The serial number of said application is 129,504; and I hereby disclaim the invention which I have claimed therein. I also disclaim in this application the method herein described of operating an air or gas engine, as such method is embraced by my application No. 170,120, filed June 29, 1885.

In practice it will probably be found best to employ two such engines as herein described, working upon opposite cranks or through beams, so that the normal pressures upon the working-pistons will balance each other, and the working-piston B will therefore not be compelled to be forced back against the back pressure by the momentum of the fly-wheel. I have preferred, however, to represent it in this case as a single engine for the sake of simplicity in the drawings.

I do not claim the use of working and changing plungers in combination with themselves or with the regenerator or refrigerator, as shown.

I claim as my invention-- 1. In an air or gas engine in which the same actuating fluid is repeatedly heated and cooled, the combination, with a furnace communicating by ports or passages with the hot chamber behind the working piston or plunger, and within which chamber the actuatingfluid is expanded while doing work, of a regenerator for intermittingly cooling the said fluid after it has done its work, said regenerator retaining the heat for subsequent use, and a valve for removing the water condensed from said products of combustion, substantially as set forth.

2. In an air or gas'engine in which the same actuating fluid is repeatedly heated and cooled, the combination, with a furnace communicating by ports or passages with the chamber containing the said fluid, so that the products of combustion may mingle with and thus heat the same, of a valve for removing the water which may be condensed from the said products of combustion, substantially as set forth.

3. In an air or gas engine in which the same actuating fluid is alternately heated and cooled, and in which hot products of combustion are mingled with said fluid within the engine, the combination of avalve for removing a portion of the cooled fluid from the engine at intervals, and a pocket or reservoir for colleeting the water which may be condensed from the products of combustion, substantially as set forth.

4. In an air or gas engine in which the same actuating fluid is repeatedly heated and cooled, the combination of a piston or plunger for changing the fluid to or from the hot and cool portions of the engine, a hot chamber in which the products of combustion are eX- panded, a furnace communicating with said hot chamber and adapted to mingle hot products of combustion with the fluid therein, a working piston or plunger operating in said hot chamber and adapted to utilize directly the expansive energy of the heated fluid, and a valve for removing the water condensed from said products of combustion, substantially as set forth.

5. In an airor gas engine in|which the same actuating fluid is repeatedly heated and cooled, the combination of a piston or plunger for changing the fluid to or from the hot and cold portions of the engine, a working piston or plunger for directly utilizing the expansive energy of the heated fluid, a hot chamber in which said working-piston operates, a furnace communicating with the said hot charm-- ber, a regenerator arranged to retain a portion of the heat of the fluid when the latter is on its way from the hot to the cool portion of the engine, and to restore the heat to said fluid on itsreturn to the hot portion of the engine, and a valve for removing the water which may be condensed from said products of combustion, substantially as set forth.

6. In an air or gas engine in which the same actuating fluid is repeatedly heated and cooled, the combination of a piston or plunger for changing the fluid to or from the hot and cold portions of the engine, a working piston or plunger for directly utilizing the expansive energy of the heated fluid, a hot chamber in which said working-piston operates, a furnace communicating with the said hot chamher, a regenerator arranged to retain a portion of the heat of the fluid when the latter is on its way from the hot to the cool portions of the engine, and to restore the heat to said fluid on its return to the hot portion of the engine, a refrigerator for conveying away such portions of the heat as is not stored up by the regenerator, and a valve for removing the water condensed from the products of combustion, substantially as set forth.

7. In an air or gas engine in whichthe same actuating fluid is alternately heated and cooled, a contracted chamber or passage through which the said fluid is forced as it passes to and from the hot and cold ends of the engine, said chamber or passage being provided with a valve adapted to regulate the facility or speed of passage of the said fluid, substantially as set forth.

8. In an air or gas engine in which the same actuating fluid is alternately heated and cooled, a contracted chamber or passage through which the said fluid is forced as it passes to and from the hot and cool ends of the engine, said chamber or passage being provided with a valve for regulating the speed of passage of said fluid, combined with a governor for automatically controlling said valve, substantially as set forth.

9. In an air or gas engine in which the same actuating fluid is alternately heated and cooled, the combination of a furnace communicating with the chamber containing the said fluid, and thus adapted to mingle hot products of combustion with the latter, one or more measuring devices, as air-pumps, for regulating the supply of hot products of combustion, and a valve for regulating the resistance of the fluid in its passage to or from the hot and cool ends of the engine, substantially as set forth.

10. In an air or gas engine in which the same actuating-fluid is alternately heated and cooled, the combination, with a furnace communicating with the chamber containing the said fluid, and thus adapted to mingle the hot products of combustion with the latter, one or more automatically-controlled measuring devices, as air-pumps, for regulating the supply of the hot products of combustion, a valve for regulating the resistance of the fluid in its passage to or from the hot and cool ends of the engine, and a governor for automatically controlling said valve, substantially as set forth.

GEO. H. BABGOGK. WVitnesses:

CHAS. ELKIN, J NO. Soorr.

IIS

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