JP3102266B2 - Gas engine fuel injector cooling system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel injection valve cooling apparatus for a gas engine (such as a natural gas engine).

[0002]

2. Description of the Related Art In a fuel injection type engine having a fuel injection valve in an intake system, the fuel injection valve receives heat from the engine. In a normal gasoline engine, gasoline is circulated between the fuel tank and the fuel injection valve, so even if the fuel injection valve receives heat from the engine, it will be cooled by gasoline, so there is no problem. Then, since there is no such function and the fuel is gas, the fuel injection valve is not cooled and the electromagnetic coil of the fuel injection valve overheats,
There is a risk that desired operating characteristics cannot be obtained.

Therefore, in a gas engine, it is necessary to cool the fuel injection valve. As a conventional fuel injection valve cooling device, for example, there is one disclosed in Japanese Patent Application Laid-Open No. 61-118554. This is because the fuel injection valve is covered with a cover so that a space is formed between the fuel injection valve and its outer surface, and a temperature sensor that detects a temperature around the fuel injection valve or a temperature correlated with the temperature is used. ,
An electric fan that is operated when it is determined that the ambient temperature of the fuel injection valve is higher than a predetermined temperature is provided so that cooling air supplied by the electric fan is guided to a space between the fuel injection valve and the cover. I have to.

[0004]

However, if such a conventional fuel injection valve cooling device is used for a gas engine, an electric fan, a temperature sensor,
Attached devices such as timers and relays are required, which complicates the operation, increases the cost, and requires maintenance and inspection of these control circuits.

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide a fuel injection valve cooling device for a gas engine which can be simply constructed without using an electric fan or the like.

[0006]

SUMMARY OF THE INVENTION Accordingly, the present invention is directed to a gas engine having a pressure reducing valve for reducing the pressure of gaseous fuel and a fuel injection valve for supplying the reduced pressure gaseous fuel to the engine. While filling the compression side cavity with refrigerant,
A cooling space is formed surrounding the fuel injection valve, and two communication passages are provided for communicating the back pressure side cavity of the pressure reducing valve and the cooling space of the fuel injection valve. Each of these communication passages is provided with a check valve. The refrigerant is circulated between the back pressure side cavity of the pressure reducing valve and the cooling space of the fuel injection valve.

The pressure reducing valve includes a valve element for opening and closing a gas fuel passage, a diaphragm connected to the valve element for receiving a pressure on the downstream side of the valve element in a valve closing direction, and a diaphragm connected to the valve element. It is preferable that the back pressure side cavity is separated from the gas fuel passage by a diaphragm and the coil spring is disposed in the back pressure side cavity.

The outside of the coil spring disposed in the back pressure side cavity of the pressure reducing valve may be surrounded by a cylindrical partition plate. Further, it is preferable that a cylindrical space closing member is disposed inside the coil spring disposed in the back pressure side cavity of the pressure reducing valve.

[0009]

The gas fuel is depressurized by the pressure reducing valve, but the pressure drop at this time removes heat from the surroundings, so that the temperature of the pressure reducing valve drops by about 50 ° C. at the maximum. Utilizing this temperature drop, the refrigerant exchanges heat in the back pressure side cavity of the pressure reducing valve. In addition, the refrigerant is circulated by utilizing the back pressure of the back pressure side cavity of the pressure reducing valve and exerting a pump action between the back pressure and the check valve.

That is, the refrigerant is cooled by heat exchange in the back pressure side cavity of the pressure reducing valve, and the refrigerant is directed from one of the communication passages to the cooling space of the fuel injection valve by the pumping action by the back pressure. Used for cooling. Then, the refrigerant whose temperature has increased due to the cooling of the fuel injection valve returns to the back pressure side cavity of the pressure reducing valve from the other communication path, and is cooled again by heat exchange.

[0011] By such a circulation cycle, not only can the fuel injection valve be cooled, but also the pressure reducing valve is heated, so that icing and sticking thereof can be prevented. In particular, when the pressure reducing valve is a diaphragm type, heat can be exchanged at the diaphragm portion, and a pump action can be exerted by the diaphragm. In addition, the refrigerant acts as a damper for the diaphragm, thereby reducing operating noise. .

Further, by surrounding the outside of the coil spring disposed in the back pressure side cavity of the pressure reducing valve with a cylindrical partition plate, the flow in the back pressure side cavity is regulated, and the contact area between the refrigerant and the diaphragm is reduced. By increasing the heat exchange efficiency, the cooling effect can be enhanced. In addition, the volume of the refrigerant in the back pressure side cavity is reduced by arranging a columnar space closing member inside the coil spring arranged in the back pressure side cavity of the pressure reducing valve, and the pump discharge capacity by the diaphragm is improved. By doing so, the cooling effect can be enhanced.

[0013]

Embodiments of the present invention will be described below. 1 to 3 show one embodiment of the present invention. FIG. 1 is a schematic view of a main part of a natural gas engine. Gas fuel from a cylinder 1 is supplied to a fuel injection valve 3 after being decompressed by a pressure reducing valve 2.

The pressure reducing valve 2 is configured as shown in FIG. The housing 20 has a fuel inlet 21 and a fuel outlet 22
A valve seat 24 is formed in the middle of the gas fuel passage 23 between them. A valve body 25 is opposed to the valve seat 24, and the valve body 25 is connected to a diaphragm 27 via a shaft 26. One surface of the diaphragm 27 faces the gas fuel passage 23 on the downstream side of the valve body 25, and receives the pressure on the downstream side of the valve body 25 in the valve closing direction of the valve body 25.

The other surface side of the diaphragm 27 forms a back pressure side cavity 28. The back pressure side cavity 28 has a diaphragm.
A coil spring 29 for urging the valve body 27 in the valve opening direction is disposed. In addition, 30 is a spring retainer on the diaphragm 27 side, 31 is a spring guide on the diaphragm 25 side,
32 is a spring retainer on the fixed wall side, and 33 is a spring force adjusting screw.

In this pressure reducing valve 2, the fuel outlet 22 side,
That is, when the pressure on the downstream side of the valve body 25 is low, the diaphragm 27 is displaced downward by the spring 29, the valve body 25 is separated from the valve seat 24, and the gas fuel flows between the valve seat 24 and the shaft 26. Then, it goes to the fuel outlet 22 side (the broken line state in FIG. 3). Thus, when the pressure on the fuel outlet 22 side, that is, the pressure on the downstream side of the valve element 25 increases, when the pressure specified by the coil spring 29 is reached, the diaphragm 27 is displaced upward and the valve element 25 is As a result of sitting on the part 24, the gas fuel stops flowing (solid line state in FIG. 3). By the above-mentioned repetition, the gas fuel has a function of flowing the gas fuel at a constant reduced pressure.

Here, the back pressure side cavity 28 of the pressure reducing valve 2
Is filled with a coolant such as water or oil.
Is provided, and a cooling space 5 is formed between the fuel injection valve 3 and the cover 4. Further, two communication paths 6A and 6B are provided for communicating the back pressure side cavity 28 of the pressure reducing valve 2 and the cooling space 5 of the fuel injection valve 3, and these communication paths 6A and 6B are provided.
In this configuration, check valves 7A and 7B are interposed respectively to circulate the refrigerant between the back pressure side cavity 28 of the pressure reducing valve 2 and the cooling space 5 of the fuel injection valve 3.

The check valves 7A and 7B are provided with a back pressure side cavity 28.
Are provided near the connecting portions of the communication paths 6A and 6B for
Here, the check valve 7B serves as a suction valve and the check valve 7A
Functions as a discharge valve. Further, the communication passage 6B on the suction side is opened on the fixed wall side far from the diaphragm 27 of the back pressure side cavity 28, and the communication passage 6A on the discharge side is shifted toward the diaphragm 27 to open.

Next, the operation will be described. Gas fuel is pressure reducing valve 2
At this time, heat is taken from the surroundings due to the pressure drop at this time, so that the temperature of the diaphragm 27 portion of the pressure reducing valve 2 drops by about 50 ° C. at the maximum. Utilizing this temperature drop, the refrigerant is diaphragmed in the back pressure side cavity 28 of the pressure reducing valve 2.
Heat exchange with 27. The back pressure (vertical displacement) of the diaphragm 27 in the back pressure side cavity 28 of the pressure reducing valve 2 is used, and the refrigerant is circulated by exerting a pump action between the back pressure and the check valves 7A and 7B.

That is, the refrigerant is cooled by the heat exchange with the diaphragm 27 in the back pressure side cavity 28 of the pressure reducing valve 2, and the refrigerant is pumped by the vertical displacement of the diaphragm 27 and the pump action by the check valves 7A and 7B. The liquid is discharged from the discharge-side communication passage 6A while being suctioned from the suction-side communication passage 6B. Then, the refrigerant is directed to the cooling space 5 of the fuel injection valve 3 from the communication passage 6A on the discharge side, and is used for cooling the fuel injection valve 3. The refrigerant whose temperature has increased due to the cooling of the fuel injection valve 3 is:
The air is returned from the communication passage 6B on the suction side to the back pressure side cavity 28 of the pressure reducing valve 2 and cooled again.

The fuel injection valve 3 can be cooled by such a circulation cycle. Conversely, since the pressure reducing valve 2 is heated, it is possible to prevent freezing and sticking of the pressure reducing valve 2. Since water and oil as refrigerants are originally used in the engine, there is no need for a new auxiliary device, and since they are liquids, they have a large heat capacity and are incompressible, so a slight pump discharge is required. Even with its capacity, it can provide sufficient circulation and heat exchange.

FIG. 4 shows another embodiment. In this embodiment, the outside of the coil spring 29 arranged in the back pressure side cavity 28 of the pressure reducing valve 2 is surrounded by a cylindrical partition plate 34, and the refrigerant is circulated only outside the partition plate 34, thereby reducing the pressure. The flow of the refrigerant in the compression side cavity 28 is regulated. Thereby, the contact area between the refrigerant and the diaphragm 27 is increased, and the heat exchange efficiency is improved, so that the cooling effect can be enhanced.

In this embodiment, the communication path 6 on the suction side is
B is opened to the fixed wall side far from the diaphragm 27 of the back pressure side cavity 28, and the communication passage 6A on the discharge side is likewise a back pressure side cavity.
28 is opened to the fixed wall side far from the diaphragm 27. This also regulates the flow of the refrigerant so as to increase the contact area of the refrigerant with the diaphragm 27, thereby enhancing the cooling effect.

FIG. 5 shows still another embodiment. In this embodiment, a cylindrical space closing member 35 is disposed inside a coil spring 29 disposed in a back pressure side cavity 28 of the pressure reducing valve 2.
Is enlarged to form a space closing member 35. As a result, the volume of the refrigerant in the back pressure side cavity 28 of the pressure reducing valve 2 can be reduced, and the volume of the refrigerant is reduced as compared with the area of the diaphragm 27. Therefore, the pump discharge performance of the diaphragm 27 is improved. And the cooling effect can be enhanced.

[0025]

As described above, according to the present invention, since the temperature reduction of the existing pressure reducing valve and the pump action are used, a complicated circuit and auxiliary equipment are not required, and the cooling effect can be obtained with a simple structure. In addition, since the temperature decreases in proportion to the flow rate of the pressure reducing valve, the fuel can be reliably cooled when the fuel injection valve is driven, and further, the effect of preventing icing of the pressure reducing valve can be obtained.

In addition, by using the diaphragm of the diaphragm type pressure reducing valve, the refrigerant acts as a damper for the diaphragm, and the operating noise can be reduced. In addition, by surrounding the outside of the coil spring disposed in the back pressure side cavity of the pressure reducing valve with a cylindrical partition plate,
By regulating the flow path of the refrigerant, the heat exchange efficiency at the diaphragm can be increased.

Further, by disposing the cylindrical space closing member inside the coil spring disposed in the back pressure side cavity of the pressure reducing valve, the volume of the refrigerant in the privet in the pressure reducing valve is reduced as compared with the area of the diaphragm. Therefore, the pump action can be enhanced.

[Brief description of the drawings]

FIG. 1 is a schematic view of a main part of a natural gas engine showing one embodiment of the present invention.

FIG. 2 is a sectional view of the pressure reducing valve in the embodiment.

FIG. 3 is a diagram showing the operation of a pressure reducing valve.

FIG. 4 is a cross-sectional view of a pressure reducing valve showing another embodiment of the present invention.

FIG. 5 is a cross-sectional view of a pressure reducing valve showing still another embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 1 cylinder 2 pressure reducing valve 3 fuel injection valve 4 cover 5 cooling space 6A, 6B communication passage 7A, 7B check valve 25 valve element 27 diaphragm 28 back pressure side cavity 29 coil spring 31 spring guide 34 partition plate 35 space closing member (large size) Spring guide)

──────────────────────────────────────────────────続 き Continued on the front page (72) Eiji Inada, Inventor Nissan Motor Co., Ltd., 2 Takaracho, Kanagawa-ku, Yokohama, Kanagawa Prefecture 12664 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) F02M 39/00-71/04 F01P 3/16 F02M 21/02

Claims (4)

(57) [Claims] 1. A gas engine comprising a pressure reducing valve for reducing the pressure of a gaseous fuel and a fuel injection valve for injecting the reduced pressure of the gaseous fuel to the engine. A cooling space is formed surrounding the valve, and two communication passages are provided for communicating the back pressure side cavity of the pressure reducing valve and the cooling space of the fuel injection valve, and a check valve is interposed in each of these communication passages. A fuel injection valve cooling device for a gas engine, wherein a refrigerant is circulated between a back pressure side cavity of the pressure reducing valve and a cooling space of the fuel injection valve. 2. The pressure reducing valve according to claim 1, further comprising: a valve element for opening and closing a gas fuel passage; a diaphragm connected to the valve element for receiving pressure downstream of the valve element in a valve element closing direction; 2. The gas according to claim 1, further comprising a coil spring biasing in a direction, wherein the back pressure side cavity is separated from a gas fuel passage by a diaphragm, and the coil spring is disposed. Engine fuel injector cooling system. 3. The cooling system for a fuel injection valve of a gas engine according to claim 2, wherein the outside of the coil spring disposed in the back pressure side cavity of the pressure reducing valve is surrounded by a cylindrical partition plate. 4. The fuel injection valve cooling device for a gas engine according to claim 2, wherein a cylindrical space closing member is disposed inside a coil spring disposed in a back pressure side cavity of the pressure reducing valve.