JP6894778B2 - Intake cooling system for supercharged engine - Google Patents

Description

The present invention relates to an intake air cooling system for a supercharged engine.

Generally, a supercharged engine is equipped with a supercharger that sucks in air for combustion, and a heat exchanger is arranged on the downstream side of the compressor of the supercharger to cool and condense the sucked air by heat exchange with a refrigerant. After that, the suction air is supplied into the cylinder.

FIG. 5 shows the shape of a general two-stroke engine, and FIG. 6 shows an intake / exhaust system of a general supercharged engine.

The engine 1 has a tubular liner 2, an outer garment 3 that engages and holds a stepped portion on the outer periphery of the liner 2 with an opening at the center of the upper wall 3a, and an opening 3b that opens to the right in FIG. 5 of the outer garment 3. The scavenging reservoir 4 to be mounted and the hollow cylinder lid 5 mounted on the upper surface of the liner 2 are provided. Further, the engine 1 includes an exhaust valve housing 6 mounted from above in the central opening of the cylinder lid 5.

A cylindrical piston 7 is fitted in the hollow portion (inner circumference) of the liner 2 so as to be movable up and down. The piston 7 is held by the liner 2 and the outer garment 3 by holding the piston rod 8 extending downward in the stuffing box 9 mounted in the center of the collar portion 3c provided on the lower inner side of the outer garment 3. A plurality of scavenging ports 2a are formed on the side wall of the liner 2 so as to face the hollow portion 3d connected to the opening 3b of the outer garment 3. The scavenging port 2a takes in the intake air 10 from the hollow portion 3d of the outer garment 3 into the liner 2 with the piston 7 at the bottom dead center.

The exhaust valve housing 6 is formed with an exhaust passage 6a that extends diagonally upward from the bottom that opens into the combustion chamber 11. Further, an exhaust valve rod 13 having an exhaust valve 12 at the lower end is pivotally supported in the exhaust valve housing 6 so as to be vertically movable. The exhaust valve 12 opens and closes the combustion chamber 11 and the exhaust passage 6a. The exhaust valve rod 13 moves up and down by the exhaust valve drive unit 14, and opens and closes the combustion chamber 11 and the exhaust passage 6a by the exhaust valve 12. The exhaust valve housing 6 is connected to the turbine 17 of the supercharger 16 via the exhaust gas flow path 15.

In the supercharger 16, the turbine 17 and the compressor 18 are directly connected by a shaft. The compressor 18 is connected to an air flow path 20 that takes in air 19 from the outside and a compressed air flow path 21 that sends air 19 compressed by the compressor 18, and the compressed air flow path 21 is a heat exchanger that cools the intake air. It is connected to 22. The heat exchanger 22 is attached to the inside of the scavenging reservoir 4 attached to the outer garment 3.

Next, the operation of the engine 1 having such a configuration will be described.

In the case of a diesel engine, fuel is injected into the air compressed by the piston 7 that moves from the bottom dead center to the top dead center in the liner 2 to burn (explode) the engine. Due to this explosion, the piston 7 moves from the top dead center to the bottom dead center. In this way, when the piston 7 makes one reciprocation (two strokes = two strokes), one cycle of operation is completed.

Further, in the case of an Otto engine such as a gasoline engine or a gas engine, the air-fuel mixture is burned (explosion) by igniting the air-fuel mixture compressed by the piston 7 that moves in the liner 2 from the bottom dead center to the top dead center. Let me. Due to this explosion, the piston 7 moves from the top dead center to the bottom dead center. In this way, when the piston 7 makes one reciprocation (two strokes = two strokes), one cycle of operation is completed.

The exhaust gas 23 passes through the exhaust valve housing 6 when the exhaust valve rod 13 is opened, further drives the turbine 17 from the exhaust main pipe 24 through the exhaust gas flow path 15, and is discharged to the outside. Although the uniflow type 2-stroke engine is shown in FIG. 5, the scavenging method is not limited to the uniflow type, and may be a cross scavenging type or a loop scavenging type.

Since the turbine 17 is directly connected to the compressor 18, the compressor 18 is also driven by the drive of the turbine 17. By rotating the compressor 18, air 19 is taken in from the air flow path 20, compressed, and sent to the compressed air flow path 21. After that, the compressed and high-temperature air 19 passes through the heat exchanger 22 via the compressed air flow path 21, is cooled, and is supplied to the engine 1 as the intake air 10 via the intake flow path 25. There is.

Here, in a supercharger, it has been considered to use the axial rotational force to drive other components.

As a conventional technique for utilizing the shaft rotational force of a supercharger, there is known a technique in which a generator is provided at the shaft end of the supercharger as shown in Patent Document 1 and is linked to an electric power system.

Japanese Unexamined Patent Publication No. 2012-137017

However, in the one disclosed in Patent Document 1, since the rotation speed of the turbocharger is not constant, it must be once converted to direct current by a converter and then converted to alternating current by using an inverter in order to link with the system. There wasn't.

Therefore, in order to utilize the axial rotational force, there is a drawback that the system becomes complicated.

The present invention has been made in view of the above-mentioned conventional problems. It is possible to utilize the axial rotational force of the turbocharger with a simple structure and lower the intake air temperature, and the intake air temperature is higher than usual. It is intended to provide an intake air cooling system for a supercharged engine that can be operated without reducing efficiency even in the case of a case.

The present invention includes a supercharger that rotates a turbine with exhaust gas from the engine and sends air compressed by a compressor directly connected to the turbine to the engine as intake air, and a supercharger that is compressed by the compressor of the supercharger to a high temperature. The first heat exchanger that cools the intake air, the refrigerant compressor that is connected to the shaft of the supercharger and is driven by the shaft rotational force of the supercharger to compress the refrigerant, and the refrigerant compressor. First heat exchange between a refrigerant liquefaction heat exchanger that liquefies the refrigerant downstream, an expander that vaporizes the liquefied refrigerant downstream of the refrigerant liquefaction heat exchanger, and a refrigerant vaporized downstream of the expander. in which according to the intake air cooling system of a turbo-engine, characterized in that example Bei and a second heat exchanger for exchanging heat of the cooled air in the vessel.

The intake cooling device of the supercharged engine includes a speed reducer that reduces the number of revolutions transmitted from the supercharger to the refrigerant compressor, and the shaft of the supercharger and the refrigerant compressor via the speed reducer. It can be configured to connect the shafts.

In the intake air cooling device of the supercharged engine, the refrigerant compressor is preferably a Rishorum type compressor.

In the intake air cooling device of the supercharged engine, the refrigerant compressor is preferably a roots type compressor.

According to the intake air cooling device of the supercharged engine of the present invention, it is possible to utilize the shaft rotational force of the supercharger with a simple structure and lower the intake air temperature, even when the intake air temperature is higher than usual. It can have an excellent effect that it can be made possible to drive without reducing efficiency.

It is a layout drawing of the heat exchanger in this invention. It is an intake / exhaust system diagram in this invention. It is an enlarged sectional view of the main part which shows the 1st Example of the intake air cooling system of the supercharged engine of this invention. It is an enlarged sectional view of the main part which shows the 2nd Example of the intake air cooling system of the supercharged engine of this invention. It is sectional drawing of a general 2-stroke engine. It is an intake / exhaust system diagram of a general supercharged engine.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 to 3 are the first examples of the intake air cooling device of the supercharged engine of the present invention, and the parts having the same reference numerals as those in FIGS. 5 and 6 in the drawings represent the same objects.

In the case of the first embodiment, as shown in FIGS. 1 to 3, the intake cooling device of the supercharging engine includes an air flow path 20 that takes in the air 19 and a compressor 18 that compresses the air 19 sent from the air flow path 20. The compressed air flow path 21 through which the air 19 compressed by the compressor 18 passes, the first heat exchanger 22 for cooling the compressed air 19 sent through the compressed air flow path 21, and the first heat. It is rotated by an intake flow path 25 through which the intake air 10 cooled by the exchanger 22 passes, an exhaust gas flow path 15 through which the exhaust gas 23 generated from the engine 1 passes, and an exhaust gas 23 sent through the exhaust gas flow path 15. It is equipped with a turbine 17.

Further, in the case of the first embodiment, as shown in FIGS. 1 to 3, the intake cooling device of the supercharging engine includes a refrigerant compressor 27 that compresses the refrigerant 26 and a refrigerant 26 that is compressed by the refrigerant compressor 27. A refrigerant flow path 28 that passes through, a refrigerant liquefaction heat exchanger 29 that liquefies the refrigerant 26 that is sent through the refrigerant flow path 28, and an expander that vaporizes the refrigerant 26 that has been liquefied by the refrigerant liquefaction heat exchanger 29. A second heat exchanger 31 and a second heat exchanger 30 that exchange heat with the refrigerant 26 vaporized by the expander 30 and the intake air 10 cooled by the first heat exchanger 22 sent through the intake flow path 25. A refrigerant flow path 32 for flowing the refrigerant 26 from the heat exchanger 31 to the refrigerant compressor 27 is provided.

A compressor 18 is arranged in the air flow path 20, a first heat exchanger 22 is provided on the downstream side of the compressor 18 via a compressed air flow path 21, and an intake flow path 25 is provided on the downstream side of the first heat exchanger 22. A second heat exchanger 31 is provided via the engine 1 to supply the intake air 10.

Further, a turbine 17 is provided on the downstream side of the engine 1 via an exhaust gas flow path 15.

Then, a refrigerant liquefaction heat exchanger 29 is provided on the downstream side of the refrigerant compressor 27 via the refrigerant flow path 28, an expander 30 is provided on the downstream side of the refrigerant liquefaction heat exchanger 29, and the expander 30 is downstream. A second heat exchanger 31 is provided on the side, and the second heat exchanger 31 and the refrigerant compressor 27 are connected via the refrigerant flow path 32.

Further, in the case of the first embodiment, as shown in FIG. 2, the turbine 17 and the compressor 18 are directly connected by a shaft in the supercharger 16, and the refrigerant compressor 27 is also the turbine 17 like the compressor 18. It is characterized in that it is directly connected to the shaft and is configured so that the shaft rotational force of the supercharger 16 can be transmitted to the refrigerant compressor 27.

Next, the operation of the first embodiment will be described.

The exhaust gas 23 generated from the engine 1 passes through the exhaust gas flow path 15 and passes through the supercharger 16 to give a rotational force to the turbine 17.

Since the turbine 17 and the compressor 18 are directly connected by a shaft in the supercharger 16, the compressor 18 also rotates as the turbine 17 rotates, and the air 19 is taken in from the air flow path 20 by the rotation of the compressor 18. , Compressed and sent to the compressed air flow path 21.

After that, the compressed air 19 of the compressed air flow path 21 passes through the first heat exchanger 22 and is cooled, and is sent to the second heat exchanger 31 as the intake air 10 through the intake flow path 25, and is the second. The intake air temperature is further lowered by the second heat exchanger 31 so that it is supplied to the engine 1. In order to further lower the intake air temperature by the second heat exchanger 31, the temperature of the refrigerant 26 flowing through the second heat exchanger 31 must be lower than the temperature of the refrigerant flowing through the first heat exchanger 22. Must be.

As shown in FIG. 3, since the refrigerant compressor 27 is directly connected to the shaft of the compressor 18, the refrigerant compressor 27 also rotates as the compressor 18 rotates.

Then, as the refrigerant compressor 27 rotates, the refrigerant 26 flowing from the refrigerant flow path 32 is compressed by the refrigerant compressor 27 and sent to the refrigerant flow path 28.

Subsequently, the refrigerant 26 passing through the refrigerant flow path 28 is liquefied via the refrigerant liquefaction heat exchanger 29.

After that, the liquefied refrigerant 26 is vaporized by the expander 30, then supplied to the second heat exchanger 31 and exchanges heat with the intake air 10 sent from the intake flow path 25 to form the refrigerant flow path 32. It circulates through the refrigerant compressor 27 side.

As described above, since the refrigerant compressor 27 is directly connected to the turbine 17 of the supercharger 16 and the shaft of the compressor 18, it can be driven by utilizing the shaft rotational force of the supercharger 16.

Further, since the heat exchanger 29 for liquefying the refrigerant, the expander 30, and the second heat exchanger 31 are provided, the intake air 10 cooled by the first heat exchanger 22 is further subjected to the second heat exchanger 31. Can be cooled.

As described above, the intake cooling device of the supercharged engine of the first embodiment described above contains the first heat exchanger 22 for cooling the intake air 10 compressed by the supercharger 16 and the high temperature, and the refrigerant 26. The refrigerant compressor 27 to be compressed, the refrigerant liquefaction heat exchanger 29 that liquefies the refrigerant 26 downstream of the refrigerant compressor 27, and the expansion that vaporizes the liquefied refrigerant 26 downstream of the refrigerant liquefaction heat exchanger 29. The refrigerant compressor includes a vessel 30, a second heat exchanger 31 that exchanges heat between the refrigerant 26 vaporized downstream of the expander 30 and the intake air 10 cooled by the first heat exchanger 22. Since 27 is connected to the shaft of the supercharger 16 so that the shaft rotational force of the supercharger 16 can be transmitted to the refrigerant compressor 27, the axial rotational force of the supercharger 16 is used. The refrigerant compressor 27 can be driven, and the intake air 10 cooled by the first heat exchanger 22 can be further cooled by the second heat exchanger 31.

In this way, it is possible to utilize the axial rotational force of the turbocharger 16 with a simple structure and lower the intake air temperature, and it is possible to operate without lowering the efficiency even when the intake air temperature is higher than usual. obtain.

FIG. 4 is a second embodiment of the intake air cooling device of the supercharged engine of the present invention, and in the drawings, the parts having the same reference numerals as those in FIG. 3 represent the same objects.

In the case of the second embodiment, instead of configuring the compressor for refrigerant 27 to be directly connected to the shaft of the supercharger 16 as in the first embodiment, the number of revolutions transmitted from the supercharger 16 to the compressor 27 for refrigerant is increased. The shaft of the turbocharger 16 and the shaft of the compressor for refrigerant 27 are connected to each other via a speed reducer 33 for reducing the speed, and as shown in FIG. 4, an existing reshorm type compressor is used as the compressor for refrigerant 27. In addition to being used, the shaft of the compressor 18 and the compressor for refrigerant 27 are connected via the speed reducer 33.

An existing roots type compressor can also be used as the refrigerant compressor 27.

Next, the operation of the second embodiment will be described.

Even if the supercharger has a low ^{rotation speed, it rotates at a high speed of 10000 min -1} or more. Therefore, the speed transmitted from the supercharger 16 to the refrigerant compressor 27 is reduced by the speed reducer 33 to drive the refrigerant compressor 27. By rotating the refrigerant compressor 27, the refrigerant 26 from the refrigerant flow path 32 is compressed and sent to the refrigerant flow path 28.

In this way, since the compressor 27 for refrigerant is connected to the turbine 17 of the supercharger 16 and the shaft of the compressor 18 via the speed reducer 33, the supercharger even if the rotation speed of the supercharger 16 is high. It is possible to drive the compressor for refrigerant 27 in a state where the rotation speed is suppressed by utilizing the axial rotational force of 16.

Further, since the existing Rishorum type compressor is used as the refrigerant compressor 27, a higher compression ratio can be obtained as compared with the centrifugal type compressor while suppressing vibration and noise.

Then, as in the first embodiment, the refrigerant liquefaction heat exchanger 29, the expander 30, and the second heat exchanger 31 are provided, so that the intake air 10 cooled by the first heat exchanger 22 is the first. It can be further cooled by the second heat exchanger 31.

As described above, the intake cooling device of the supercharged engine of the second embodiment includes a speed reducer 33 that reduces the number of revolutions transmitted from the supercharger 16 to the refrigerant compressor 27, and the speed reducer 33. The shaft of the supercharger 16 and the shaft of the refrigerant compressor 27 are connected to each other via the Further, in the case of the second embodiment, the refrigerant compressor 27 is a Rishorum type compressor. With this configuration, even if the rotation speed of the supercharger 16 is high, it can be driven in a state where the rotation speed of the compressor 27 for refrigerant is suppressed by utilizing the axial rotational force of the supercharger 16 and vibration. A higher compression ratio can be obtained compared to a centrifugal compressor while suppressing noise and noise.

In this way, in the second embodiment as well as in the first embodiment, it is possible to utilize the axial rotational force of the supercharger 16 and lower the intake air temperature with a simple structure, and when the intake air temperature is higher than usual. However, it may be possible to operate without reducing efficiency.

The intake cooling device of the supercharged engine of the present invention is not limited to the above-described embodiment, and the supercharged engine is limited to a diesel engine or an Otto engine such as a gasoline engine or a gas engine. However, the scavenging method is not limited to the uniflow type, and may be a transverse scavenging type or a loop scavenging type, and it goes without saying that various changes can be made without departing from the gist of the present invention. is there.

10 Intake 16 Supercharger 22 Heat exchanger (first heat exchanger)
26 Refrigerant 27 Refrigerant compressor 29 Refrigerant liquefaction heat exchanger 30 Expander 31 Second heat exchanger 33 Reducer

Claims (4)

A supercharger that rotates a turbine with exhaust gas from the engine and sends air compressed by a compressor directly connected to the turbine as intake air to the engine.
A first heat exchanger that cools the intake air compressed by the compressor of the turbocharger and becomes hot.
A refrigerant compressor that is connected to the shaft of the turbocharger and is driven by the shaft rotational force of the turbocharger to compress the refrigerant.
A refrigerant liquefaction heat exchanger that liquefies the refrigerant downstream of the refrigerant compressor,
An expander that vaporizes the liquefied refrigerant downstream of the refrigerant liquefaction heat exchanger,
Intake air cooling system of a turbo-engine, characterized in that example Bei and a second heat exchanger for exchanging heat of the cooled air by the refrigerant and a first heat exchanger vaporized downstream of the expander. A speed reducer that reduces the number of revolutions transmitted from the supercharger to the refrigerant compressor is provided.
The intake cooling device for a supercharged engine according to claim 1, wherein the shaft of the supercharger and the shaft of the refrigerant compressor are connected to each other via the speed reducer. The intake cooling device for a supercharged engine according to claim 2, wherein the refrigerant compressor is a Rishorum type compressor. The intake cooling device for a supercharged engine according to claim 2, wherein the refrigerant compressor is a roots type compressor.

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