US1769675A - Fuel injection and atomization by stream impact - Google Patents
Fuel injection and atomization by stream impact Download PDFInfo
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- US1769675A US1769675A US182968A US18296827A US1769675A US 1769675 A US1769675 A US 1769675A US 182968 A US182968 A US 182968A US 18296827 A US18296827 A US 18296827A US 1769675 A US1769675 A US 1769675A
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- air
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M67/00—Apparatus in which fuel-injection is effected by means of high-pressure gas, the gas carrying the fuel into working cylinders of the engine, e.g. air-injection type
- F02M67/02—Apparatus in which fuel-injection is effected by means of high-pressure gas, the gas carrying the fuel into working cylinders of the engine, e.g. air-injection type the gas being compressed air, e.g. compressed in pumps
Definitions
- One of the principal objects of the present invention is to provide a means and method for producing rapid and thorough mixing of fluid fuels in the combustion spaces of internal combustion engines.
- Another object of the present invention is to increase the efliciency and scope of application of the solid injection method of introducing heavy oil fuel into internal combustion engines.
- FIG. 1 is a central section through a cylinder of an engine according to the present invention.
- Fig. 2 is a central section, somewhat diagrammatic in character, of an apparatus according to the present invention and in which the engine of Fig. 1 is combined with a recuperator and an external air compressor.
- 10 is the Working cylinder of an internal combustion engine having a head 12. Air for supporting combustion in the combustion space or chamber 14 in the upper end of cylinder 10 is introduced into space 14 from above through a downwardly flaring port 16 in the upper head 12. The air going into the chamber 14 is preferably compressed and preferably heated to the temperature of ignition of the fuel to be used.
- the present invention is not limited to compressing the air for combustion ex- IUEL INJECTION AND ATOMIZATION BY STREAM IMPACT 1927. Serial No. 182,968.
- the apparatus as illustrated is designed for the use of hot compressed air and is consequently provided with an enlargement or boss 20 on the outside of the head 12 within which is an air chamber 22 for the reception of the preheated compressed air and which is introduced into the chamber 22 through pipe 24:.
- the valve 20 is placed to control the flow of air from chamber 22 to the port 16.
- the fuel is introduced into the stream of air flowing through port 16.
- the engine illustrated is provided with two chambers 26, 26 within the head 12. Chambers 26 lie alongside of and partly surround the port 16.
- Fuel under pressure is introduced into the chambers 26, two ducts 28, 28 being provided in the boss 20 for this purpose.
- the heavy oil or other fuel to be used in the engine is conducted to the ports 28 through suitable pipes.
- N 0 air or other substance of vaporous or gaseous nature under conditions existing in the ports of fuel valves 30 is introduced into chambers 26.
- the atomization of the heavy fuel oil by valves therefore is that due solely to the liquid pressure of the oil at said valves.
- the method of injection employed is therefore that commonly referred to as solid inj ection.
- the fuel is permitted to escape from the chambers 26 at desired intervals through ports in the walls 29,29 between the chambers 26 and port 16. Walls 29 flare outwardly in the direction of flow of the air through port 16.
- the fuel ports just mentioned are normally closed by needle valves 30, 30 which are opened at the proper times and for the desired intervals by suitable mechanism not shown.
- the valves 30 are at the ends of spindles 32, 32 whose axes are at right angles to walls 29 and, when extended, intersect at a point preferably either within or without the port 16, depending upon the exact nature of the superposed conditions of combustion, but, at any rate, within the air stream which is passing thru or which has passed through the port 16. Consequently, when the valves 30 are drawn back from their seats to permit the admission of fuel into port 16, the resulting streams of. fuel are inclined forwardly in the direction of flow of the air.
- the fuel streams intersect and the particles of the two streams collide with impact, thus producing an atomizing action in addition to that naturally occurring at the needle valves.
- the valve 18 is timed to be open throu'gh the interval during which valves 30 are open. Consequently the fuel is injected into a stream of moving air and the thorough mixing of the air and fuel is promoted not only by the turbulence caused by spraying two streams of fuel into the air stream at angle to its path, but also by the additional atomization and turbulence caused by the impact of the streams of fuel.
- the present invention is not limited, in its broadest aspect to causing imact between particles in the two streams of uel, although this is preferred.
- the fuel is ignited as it enters the chamber from port 16. It will be seen that the combustion produced is non-explosive, the mixture of fuel and air burning at the same rate at which it enters chamber 14. In case the air is not sufliciently preheated to ignite the fuel, the air and fuel mixture is ignited by means (not shown) within chamber 14 to cause combustion in the chamber. The burning of the fuel in chamber 14 pushes down piston 34 with the roduction of power in the usual manner. roducts of combustion are exhausted from chamber 14 through port 38 controlled by the exhaust valve 36.
- Both valves 18 and 36 are normally held closed by springs 40 and 42 respectively but are opened at the pro er instants and held open for proper perio s of time by suitable mechanism not shown.
- the heat for preheating the air introduced through port 16 is obtained from the heat in the gases exhausted from chamber 14.
- a suitable arrangement for carrying out the transfer of heat from the exhaust to the combustion air is illustrated diagrammatically in Fi 2.
- the air for supporting com ustion in cylinder 10 is first drawn in from the atmosphere into an air compressor 44, illustrated also as being preferably of the pistoned type.
- the air enters the cylinder of compressor 44 through port 46 and is compressed in the cylinder in the usual manner.
- the compressed air leaves compressor 44 through port 48 and is conducted through pipe 50, coil 52 and pipe 24 to the intake port 16 of cylinder 10. Air is heated while in the coil 52 which forms a part of a recuperator having a casing 54.
- Hot ases for heating the coil 52 are conducte from the exhaust port 38 ofcylinder 10 through pi e 56 to the in erior of the casing 54. A ter transferring most of the heat to the air within coil 52 the'exhaust gases pass from the casing. 54 to the atmosphere through the port 58. i Y
- the piston of compressor 44 s operated from the shaft (not shown) of the engine including cylinder 10, the compressor thusforming'a part of the engine.
- the method includin atomizing a plurality of streams of fiui fuel into an air stream entering the combustion space of an internal combustion engine and under conditions producing turbulence, and burning the resulting mixture of air and fuel as the said mixture is formed in said space.
- the method includin atomizing by solid injection a plurality o streams of fluid fuel into an air stream entering the combustion space of an internal combustion engine and under conditions producin turbulence and burning resulting mixture 0 air and fuel as said mixture is formed in said space.
- the method including atomizlng a plurality of streams of fluid fuel into a stream of air heated to the temperature of ignition as said air stream is entering the combustion space of an internal combustion engine and under conditions producing turbulence, and burning the resulting mixture of air and fuel as the mixture is formed in said space.
- the method includin atomizing by solid injection, a plurality of streams of fluid fuel into a stream of air heated to the temperature of ignition of said fuel as said air stream is entering the combustion space of an internal combustion engine and under conditions producing turbulence, and burning the resulting mixture of air and fuel as said mixture is formed in said space.
- the method including atomizing a plu-' stream entering the combustion space of an internal combustion engine and under conditions producing impact in said fuel streams, and burning the resulting mixture of air and fuel as said mixture is formed in said space.
- the method includin atomizing by solid injection, a plurality 0 streams of fluid fuel into an air stream entering the combustion space of an internal combustion engine and under conditions producing impact of said fuel streams, and burning the resulting mixture of air and fuel as said mixture is formed in said space.
- the method including atomizing a plura-lity ofstreams of liquid fuel into an air stream heated to the temperature of ignition of said fuel as said air stream is entering the combustion space of an internal combustion engine and under conditions producing impact and burning the resulting mixture of air and fuel as said mixture is formed in said space.
- the method including atomizing a plurality of streams of liquid fuel into an air stream as said air stream is entering the combustion space of an internal combustion engine, the path of said fuel streams being inclined to that of said air streams whereby turbulent mixing of the air and fuel is produced.
- the method including rojectin ,a lurality of streams of finely ivided uid uel into an air stream as said air stream is entering the combustion space of an internal combustion engine.
- a combustion chamber having an air port therein, means for creating a current of air passing into said chamber through said port, and means for spraying fuel in a plurality of streams into said air stream and in directions inclined forwardly in the direction of motion of the air stream.
- the method including PIOjGCtlI ⁇ ? a uid plurality of. streams of finely divided fuel into an air stream as said air stream is entering the combustion space of an internal combustion engine, while maintaining conditions producing turbulent mixing ofsaid air and fuel streams.
- the method including projectiqlg a plurality of streams of finely divided uid uel into an air stream as said air stream is entering the combustion space of an internal combustion engine, the direction of said fluid streams being inclined forwardly in the direction of flow of said air stream.
Description
U Y 1930- R. E. BRUCKNER 1,769,675
FUEL INJECTION AND ATOMIZAITON BY STREAM IMPACT Filed April 11, 1927 40 r Z4 42 i Z? figigi/zgkisjm Z0 J& Z6 1| I, x am H i 4 AI -31; y K Z6 //46 29% gfi/d Z419 M i g ,7
Patented July 1, 1930 UNITED STATES PATENT OFFICE ROBERT EARLL BRUCKNER, OF HASTINGS UPON HUDSON, NEW YORK, ASSIGNOR TO 'DOHERTY RESEARCH COMPANY, OF NEW YORK, N. Y., A CORPORATION OF DELA- WARE Application filed April 11,
It is recognized that the pressure in internal combustion engines of the heavy oil type seldom follows a smooth curve during combustion. This is an indication of irregular burning. Pulsations of pressure are themselves undesirable and, further, the irregular burning increases the amount of unburned fuel in the exhaust for given speeds and fuel rates of injection of fuel. I
One of the principal objects of the present invention is to provide a means and method for producing rapid and thorough mixing of fluid fuels in the combustion spaces of internal combustion engines.
Another object of the present invention is to increase the efliciency and scope of application of the solid injection method of introducing heavy oil fuel into internal combustion engines.
Other objects and advantages of the present invention will be obvious to those skilled in the art from the following description, the novel features of the invention being pointed out particularly in the appended claims.
One form of apparatus according to the present invention, and one adapted to carry out the method according to the present invention, is illustrated in the accompanying drawing in-which Fig. 1 is a central section through a cylinder of an engine according to the present invention.
Fig. 2 is a central section, somewhat diagrammatic in character, of an apparatus according to the present invention and in which the engine of Fig. 1 is combined with a recuperator and an external air compressor.
In the drawing, 10 is the Working cylinder of an internal combustion engine having a head 12. Air for supporting combustion in the combustion space or chamber 14 in the upper end of cylinder 10 is introduced into space 14 from above through a downwardly flaring port 16 in the upper head 12. The air going into the chamber 14 is preferably compressed and preferably heated to the temperature of ignition of the fuel to be used. However, the present invention is not limited to compressing the air for combustion ex- IUEL INJECTION AND ATOMIZATION BY STREAM IMPACT 1927. Serial No. 182,968.
ternally of the working cylinder or to heating the air prior to its introduction to the combustion chamber. The flow of air to and through the port 16 is controlled by an inlet valve 18. The apparatus as illustrated is designed for the use of hot compressed air and is consequently provided with an enlargement or boss 20 on the outside of the head 12 within which is an air chamber 22 for the reception of the preheated compressed air and which is introduced into the chamber 22 through pipe 24:. As illustrated, the valve 20 is placed to control the flow of air from chamber 22 to the port 16. According to the present invention the fuel is introduced into the stream of air flowing through port 16. For this purpose, the engine illustrated is provided with two chambers 26, 26 within the head 12. Chambers 26 lie alongside of and partly surround the port 16. Fuel under pressure is introduced into the chambers 26, two ducts 28, 28 being provided in the boss 20 for this purpose. The heavy oil or other fuel to be used in the engine is conducted to the ports 28 through suitable pipes. N 0 air or other substance of vaporous or gaseous nature under conditions existing in the ports of fuel valves 30 is introduced into chambers 26. The atomization of the heavy fuel oil by valves therefore is that due solely to the liquid pressure of the oil at said valves. The method of injection employed is therefore that commonly referred to as solid inj ection. The fuel is permitted to escape from the chambers 26 at desired intervals through ports in the walls 29,29 between the chambers 26 and port 16. Walls 29 flare outwardly in the direction of flow of the air through port 16. The fuel ports just mentioned are normally closed by needle valves 30, 30 which are opened at the proper times and for the desired intervals by suitable mechanism not shown. The valves 30 are at the ends of spindles 32, 32 whose axes are at right angles to walls 29 and, when extended, intersect at a point preferably either within or without the port 16, depending upon the exact nature of the superposed conditions of combustion, but, at any rate, within the air stream which is passing thru or which has passed through the port 16. Consequently, when the valves 30 are drawn back from their seats to permit the admission of fuel into port 16, the resulting streams of. fuel are inclined forwardly in the direction of flow of the air. Also, the fuel streams intersect and the particles of the two streams collide with impact, thus producing an atomizing action in addition to that naturally occurring at the needle valves. The valve 18 is timed to be open throu'gh the interval during which valves 30 are open. Consequently the fuel is injected into a stream of moving air and the thorough mixing of the air and fuel is promoted not only by the turbulence caused by spraying two streams of fuel into the air stream at angle to its path, but also by the additional atomization and turbulence caused by the impact of the streams of fuel. It will be understood,
therefore, that the present invention is not limited, in its broadest aspect to causing imact between particles in the two streams of uel, although this is preferred.
If the air introduced into chamber.14 is at the ignition temperature of the fuel being used, the fuel is ignited as it enters the chamber from port 16. It will be seen that the combustion produced is non-explosive, the mixture of fuel and air burning at the same rate at which it enters chamber 14. In case the air is not sufliciently preheated to ignite the fuel, the air and fuel mixture is ignited by means (not shown) within chamber 14 to cause combustion in the chamber. The burning of the fuel in chamber 14 pushes down piston 34 with the roduction of power in the usual manner. roducts of combustion are exhausted from chamber 14 through port 38 controlled by the exhaust valve 36.
Both valves 18 and 36 are normally held closed by springs 40 and 42 respectively but are opened at the pro er instants and held open for proper perio s of time by suitable mechanism not shown. I
Preferably the heat for preheating the air introduced through port 16 is obtained from the heat in the gases exhausted from chamber 14. A suitable arrangement for carrying out the transfer of heat from the exhaust to the combustion air is illustrated diagrammatically in Fi 2. In Fig. 2, the air for supporting com ustion in cylinder 10 is first drawn in from the atmosphere into an air compressor 44, illustrated also as being preferably of the pistoned type. The air enters the cylinder of compressor 44 through port 46 and is compressed in the cylinder in the usual manner. The compressed air leaves compressor 44 through port 48 and is conducted through pipe 50, coil 52 and pipe 24 to the intake port 16 of cylinder 10. Air is heated while in the coil 52 which forms a part of a recuperator having a casing 54. Hot ases for heating the coil 52 are conducte from the exhaust port 38 ofcylinder 10 through pi e 56 to the in erior of the casing 54. A ter transferring most of the heat to the air within coil 52 the'exhaust gases pass from the casing. 54 to the atmosphere through the port 58. i Y
Preferably the piston of compressor 44 s operated from the shaft (not shown) of the engine including cylinder 10, the compressor thusforming'a part of the engine.
While I have illustrated no means for operating the valves of cylinder 10 or of the compressor 44, such means are well-known in the arts of internal combustion engines and of air compressors and "need no description herein to enable those skilled in the art to practice the invention. Also, it is well known to supply fluid fuels such as heavy oil, to internal combustion engines under pressure and to control the injection of the fuel into the combustion space by means of needle valves. Suitable means for o erating the needle valves 32, 32 are there ore well-known and are not described herein in detail.
While a single embodimentof the present invention has been illustrated and described herein in detail, it will be understood that the present invention is not limited to details of construction, arrangement or operation except in so far as such details are clearly and positively included in the appended claims.
Having thus described my invention I claim:
1. The method includin atomizing a plurality of streams of fiui fuel into an air stream entering the combustion space of an internal combustion engine and under conditions producing turbulence, and burning the resulting mixture of air and fuel as the said mixture is formed in said space.
2. The method includin atomizing by solid injection a plurality o streams of fluid fuel into an air stream entering the combustion space of an internal combustion engine and under conditions producin turbulence and burning resulting mixture 0 air and fuel as said mixture is formed in said space.
3. The method including atomizlng a plurality of streams of fluid fuel into a stream of air heated to the temperature of ignition as said air stream is entering the combustion space of an internal combustion engine and under conditions producing turbulence, and burning the resulting mixture of air and fuel as the mixture is formed in said space.
4. The method includin atomizing by solid injection, a plurality of streams of fluid fuel into a stream of air heated to the temperature of ignition of said fuel as said air stream is entering the combustion space of an internal combustion engine and under conditions producing turbulence, and burning the resulting mixture of air and fuel as said mixture is formed in said space.
5. The method including atomizing a plu-' stream entering the combustion space of an internal combustion engine and under conditions producing impact in said fuel streams, and burning the resulting mixture of air and fuel as said mixture is formed in said space.
6. The method includin atomizing by solid injection, a plurality 0 streams of fluid fuel into an air stream entering the combustion space of an internal combustion engine and under conditions producing impact of said fuel streams, and burning the resulting mixture of air and fuel as said mixture is formed in said space.
7. The method including atomizing a plura-lity ofstreams of liquid fuel into an air stream heated to the temperature of ignition of said fuel as said air stream is entering the combustion space of an internal combustion engine and under conditions producing impact and burning the resulting mixture of air and fuel as said mixture is formed in said space.
8. The method of introducing fuel and air into an internal combustion engine comprising setting up a stream of air passing into a combustion space of the engine and injecting into said stream near its point of entrance into said space, a plurality of streams of fuel, said fuel streams bemg atomized as they enter said air stream and being projected along intersecting paths whereby impact of fuel particles is produced in said air stream.
9. The method including atomizing a plurality of streams of liquid fuel into an air stream as said air stream is entering the combustion space of an internal combustion engine, the path of said fuel streams being inclined to that of said air streams whereby turbulent mixing of the air and fuel is produced.
10. The method including rojectin ,a lurality of streams of finely ivided uid uel into an air stream as said air stream is entering the combustion space of an internal combustion engine.
15. In an apparatus of the class described,
the combination of a combustion chamber having an air port therein, said port flaring outwardly in the direction of motion of air through the port, and means for atomizing a plurality of streams of liquid fuel through the flaring walls of said port alon lines substantially at right angles to the aring wall of the port and into a stream of air passing into said chamber.
16. In an apparatus of the class described, the combination of a combustion chamber having an air port therein, means for creating a current of air passing into said chamber through said port, and means for spraying fuel in a plurality of streams into said air stream and in directions inclined forwardly in the direction of motion of the air stream.
In testimony whereof I aflix my signature.
ROBERT EARLL BRUCKNER.
11. The method including PIOjGCtlI}? a uid plurality of. streams of finely divided fuel into an air stream as said air stream is entering the combustion space of an internal combustion engine, while maintaining conditions producing turbulent mixing ofsaid air and fuel streams. I
12. The method including projectiqlg a plurality of streams of finely divided uid uel into an air stream as said air stream is entering the combustion space of an internal combustion engine, the direction of said fluid streams being inclined forwardly in the direction of flow of said air stream.
13. The method of infusing an air stream I III
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US182968A US1769675A (en) | 1927-04-11 | 1927-04-11 | Fuel injection and atomization by stream impact |
Applications Claiming Priority (1)
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US182968A US1769675A (en) | 1927-04-11 | 1927-04-11 | Fuel injection and atomization by stream impact |
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US1769675A true US1769675A (en) | 1930-07-01 |
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US182968A Expired - Lifetime US1769675A (en) | 1927-04-11 | 1927-04-11 | Fuel injection and atomization by stream impact |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2522456A (en) * | 1948-11-13 | 1950-09-12 | Mallory Marion | Internal-combustion engine |
US3980056A (en) * | 1971-07-23 | 1976-09-14 | Werner Kraus | Fuel injection device |
US4476821A (en) * | 1982-12-15 | 1984-10-16 | Robinson Thomas C | Engine |
-
1927
- 1927-04-11 US US182968A patent/US1769675A/en not_active Expired - Lifetime
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2522456A (en) * | 1948-11-13 | 1950-09-12 | Mallory Marion | Internal-combustion engine |
US3980056A (en) * | 1971-07-23 | 1976-09-14 | Werner Kraus | Fuel injection device |
US4476821A (en) * | 1982-12-15 | 1984-10-16 | Robinson Thomas C | Engine |
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