JP2792506B2 - Fuel supply device for internal combustion engine - 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 supply device for an internal combustion engine suitable for use in a direct injection internal combustion engine.

[0002]

2. Description of the Related Art As a fuel system of an internal combustion engine, fuel supplied from a low-pressure fuel pump is pressurized by a high-pressure fuel pump.
There is a fuel supply device referred to as an in-cylinder injection type or a direct injection type (direct injection type) in which this pressurized high-pressure fuel is directly injected into a cylinder by a fuel injection valve. This in-cylinder injection type fuel supply device is widely used in diesel engines, but an in-cylinder injection type fuel supply system has also been proposed for a fuel system of a spark ignition type engine (generally, a gasoline engine). For example, it is known from JP-A-7-83134.

As a high-pressure fuel pump used in such a fuel supply device, there are, for example, a swash plate type axial piston pump, a single cylinder reciprocating piston pump (single plunger pump) and the like. These high-pressure fuel pumps have a pump drain that returns the leaked fuel to a fuel tank in order to prevent the fuel leaking from a piston drive unit that pressurizes and supplies the fuel from accumulating inside the pump and preventing the pump internal pressure from excessively increasing. A passage (leak passage) is provided. Based on the presence of the drain passage, in particular, in a swash plate type axial piston type high pressure fuel pump, the pump internal pressure is increased by fuel leaking from a piston drive unit provided around the axis of a rotating shaft that rotates by receiving the rotational force of the engine. It is prevented that the oil seal rises excessively and the oil seal provided at the end of the rotating shaft is turned up. If the seal of the high-pressure fuel pump is strong (high pressure resistance), the drain passage is not always necessary. However, since the cost of the pump is high, a seal with a weak seal (low pressure resistance) is usually used. As described above, the drain passage is provided to reduce the cost. In a high-pressure fuel pump of a type in which the pump itself is cooled by the fuel, the drain passage may be provided as a passage for returning the fuel leaked inside the pump for cooling the pump to the fuel tank.

[0004]

However, when a high-pressure fuel pump having a drain passage is used in the fuel system, the low-pressure fuel inside the pump and the low-pressure fuel passage returns to the fuel tank via the drain passage after the engine is stopped. Therefore, the pressure is not maintained, and the fuel pressure inside the pump and the low-pressure fuel passage is instantaneously reduced to the atmospheric pressure or the vicinity of the atmospheric pressure. As a result, the temperature at which the fuel vaporizes (vaporization point) corresponding to the fuel pressure at that time decreases, and even if the temperature rises slightly after the engine is stopped, the vaporization point is exceeded, and vapor is generated inside the pump and the low-pressure side fuel passage. This causes a problem that the restartability deteriorates.

In the pressure accumulating type fuel injection system, there is a technique for suppressing a sudden drop of fuel discharged from an injector from a high pressure to an atmospheric pressure by a pressure reducing valve provided in a leak pipe to prevent generation of vapor. JP-A-5-337
No. 41 discloses this. However, this technique is to prevent generation of vapor in a leak pipe from an injector, and does not disclose any technical idea for solving the above-mentioned problem.

The present invention has been made in view of the above points, and in a fuel supply device having a fuel pump having a drain passage, the pressure in the fuel pump is maintained when the internal combustion engine is stopped to suppress generation of vapor. It is another object of the present invention to provide a fuel supply device for an internal combustion engine that has improved high-temperature restartability.

[0007]

According to a first aspect of the present invention, there is provided a fuel injection valve provided between a fuel injection valve and a fuel tank provided in an internal combustion engine. And a fuel passage configured as a circulation circuit that returns from the fuel injection valve to the fuel tank again,
A holding unit that is provided in an upstream portion of the fuel passage near the fuel tank, and that allows fuel to pass only from the upstream side to the downstream side of the fuel passage; and a holding unit that is disposed in an engine room and includes the fuel injection valve of the fuel passage. A fuel pump provided between the holding means and supplying fuel to the fuel injection valve;
A pressure control means provided in the fuel passage to regulate the pressure of the fuel discharged by the fuel pump to a predetermined pressure; a drain passage for returning a portion of the fuel in the fuel pump to the fuel tank; Pressure regulating means that allows fuel to pass only from the upstream side to the downstream side of the drain passage at a set pressure or more, the set pressure of the pressure control means being lower than the set pressure of the pressure control means, Further, the fuel passage between the holding means and the pressure control means is set to a saturated vapor pressure equal to or higher than the set vapor temperature of the fuel which becomes a set temperature at which a maximum engine temperature can be reached after the stop of the internal combustion engine. Things.

[0008] The fuel pump pressurizes the fuel in the fuel tank during operation of the internal combustion engine and supplies the fuel to the fuel injection valve through the fuel passage. The fuel pressure supplied to the fuel injection valve is regulated by pressure control means. Fuel that has leaked into the fuel pump from the sliding surface of the piston drive unit inside the fuel pump, the piston reciprocating surface, or the like is returned to the fuel tank through the drain passage and the pressure regulating means in the drain passage. Since the set pressure of the pressure adjusting means is set lower than the set pressure of the pressure control means, the fuel leaking into the fuel pump during operation of the fuel pump, that is, during operation of the internal combustion engine, impairs the function of the drain passage. Without returning to the fuel tank through the drain passage and the pressure regulating means. Further, the set pressure of the pressure adjusting means is equal to or higher than the saturated vapor pressure corresponding to the set temperature of the fuel at which the fuel passage between the holding means and the pressure control means reaches a set temperature at which the engine maximum temperature can be reached after the internal combustion engine is stopped. When the internal combustion engine is stopped and the fuel pump is stopped, the fuel pressure from the fuel tank to the fuel pump is equal to or higher than the saturated vapor pressure by the fuel passage holding means and the drain passage pressure regulating means. Is held. As a result, even if the fuel temperature rises due to the heat of the engine after the engine stops, generation of vapor in the fuel passage and the fuel pump is prevented. As a result, high-temperature restartability when the engine is restarted after the engine is stopped is improved.

The invention according to claim 2 is provided between a fuel injection valve provided in the internal combustion engine and a fuel tank, from the fuel tank to the fuel injection valve, and from the fuel injection valve to the fuel tank again. A fuel passage configured as a return circulation circuit, a low-pressure fuel pump provided in an upstream portion of the fuel passage near the fuel tank, and a low-pressure fuel pump and the fuel injection disposed in an engine room in the fuel passage. A high-pressure fuel pump provided between the valve and
Holding means provided in series with the low-pressure fuel pump in a fuel passage on the upstream side of the high-pressure fuel pump to allow fuel to pass only from the upstream side to the downstream side of the fuel passage; and a fuel pressure discharged from the low-pressure fuel pump. Low pressure adjusting means for adjusting the fuel pressure at a first set pressure, and a second set pressure provided in the fuel passage downstream of the high pressure fuel pump to increase the fuel pressure discharged from the high pressure fuel pump higher than the first set pressure. High-pressure adjusting means, a drain passage for returning a part of the fuel in the high-pressure fuel pump to the fuel tank, and a drain passage provided in the drain passage, and only at a set pressure or more from the upstream to the downstream of the drain passage. Pressure adjusting means for allowing fuel to pass therethrough, wherein a set pressure of the pressure adjusting means is lower than a first set pressure of the low pressure adjusting means, and at least a pressure between the low pressure fuel pump and the high pressure adjusting means. Serial in which a fuel passage is configured to set on the saturated vapor pressure corresponding to the set temperature of the fuel serving as the set temperature may reach the engine maximum temperature after the internal combustion engine is stopped.

During operation of the internal combustion engine, the high-pressure fuel pump further pressurizes the fuel supplied from the fuel tank to the fuel passage by the low-pressure fuel pump and supplies the fuel to the fuel injection valve. The fuel pressure discharged from the low-pressure fuel pump is adjusted by low-pressure adjusting means, and the fuel pressure supplied to the fuel injection valve is adjusted by high-pressure adjusting means. The fuel leaking into the high-pressure fuel pump is returned to the fuel tank through the drain passage and the pressure regulating means in the drain passage. Since the set pressure of the pressure adjusting means is set lower than the set pressure of the low pressure adjusting means, the fuel leaking into the high pressure fuel pump during operation of the high pressure fuel pump, that is, during operation of the internal combustion engine, is reduced by the function of the drain passage. Is returned to the fuel tank through the pressure regulating means in the drain passage without being damaged. Further, the saturated vapor pressure corresponding to the set temperature of the fuel at which the set pressure of the pressure adjusting means is at least the set temperature at which the fuel passage between the low pressure fuel pump and the high pressure adjusting means can reach the engine maximum temperature after the internal combustion engine is stopped. Due to the above setting, when the internal combustion engine stops and the low-pressure fuel pump and the high-pressure fuel pump stop, the fuel pressure in the fuel passage from the fuel tank to the high-pressure fuel pump is reduced by the low-pressure adjusting means and the drain passage. The pressure is maintained at or above the saturated vapor pressure by the pressure regulating means. Thus, even if the fuel temperature rises due to the heat of the engine after the engine is stopped, the generation of vapor in the fuel passage and the high-pressure fuel pump is prevented, and the high-temperature restartability after the engine is stopped is improved.

Normally, the fuel pressure of the fuel passage on the suction side of the high-pressure fuel pump, that is, the fuel passage on the low-pressure side, is, for example, about 2.5 to 2.5 in consideration of the improvement of startability by low-pressure injection and the reduction of piping cost.
It is set to 6 atm. Therefore, it is preferable that the set pressure of the pressure adjusting means of the drain passage is set to, for example, about 2 to 3 atm (particularly about 2 atm).

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to Embodiments 1 and 2. (Embodiment 1) FIG. 1 shows a schematic configuration of a fuel supply apparatus for an internal combustion engine to which the present invention is applied, in particular, a fuel supply apparatus for a direct injection gasoline engine. In the figure, a fuel supply device 1
A fuel tank 2 and a delivery pipe 4 for supplying high-pressure fuel to a fuel injection valve 3 provided in an engine (not shown) are connected by a fuel passage 5. The fuel passage 5 includes a low-pressure fuel passage 6, high-pressure fuel passages 7, 8, a return passage 9, and the like. In the low-pressure fuel passage 6, a filter 15 is connected to an upstream end, and a low-pressure fuel pump 16, a check valve (low-pressure holding means) 17 and a fuel filter 18 are sequentially connected downstream of the filter 15, and a downstream end has a high pressure. It is connected to the suction port of the fuel pump 20. Low pressure fuel passage 6
A low-pressure fuel passage 10 is connected between a downstream side of the fuel filter 18 and a downstream side of the return passage 9.
A low-pressure regulator (low-pressure adjusting means) 19 is connected to the low-pressure fuel passage 10.

The discharge port of the high-pressure fuel pump 20 is provided with a check valve 2
5, connected to an upstream end of the delivery pipe 4 via a high-pressure fuel passage 7, and a downstream end of the delivery pipe 4 is connected to a high-pressure regulator (high-pressure adjusting means) 2 via a high-pressure fuel passage 8.
6 is connected. The high-pressure regulator 26 is connected to the fuel tank 2 via the orifice 27 and the leak passage 9. The fuel passage 5 passes from the fuel tank 2 through the low-pressure fuel pump 16, the low-pressure fuel passage 6, the high-pressure fuel pump 20, the high-pressure fuel passage 7, the delivery pipe 4, the high-pressure fuel passage 8, the high-pressure regulator 26, and the leak passage 9. 2 is configured as a circulation circuit.
Note that the delivery pipe 4 also constitutes a part of the high-pressure fuel passage. The fuel injection valve 3 is connected to the delivery pipe 4
Is injected into the cylinder of the engine. The delivery pipe 4 has one fuel injection valve 3.
Although not shown, the fuel injection valves 3 are juxtaposed by the number of cylinders of the engine. The fuel injection valves 3 of each cylinder are controlled to be opened by an electronic control unit (not shown).

A drain port of the high-pressure fuel pump 20 has a pump drain passage (hereinafter simply referred to as a “drain passage”) 11.
Is connected to the return passage 9 downstream of the orifice 27. The orifice 27 is a high pressure regulator 2
High-pressure fuel pressurized upstream of the high-pressure regulator 2
When the fuel is drained from the fuel tank 6 to the fuel tank 2, if the fuel pressure suddenly drops to the atmospheric pressure, the fuel will boil under reduced pressure, so that the pressure is reduced in two stages. A pressure regulating means, for example, a check valve 30 is connected to the drain passage 11. The check valve 30 is preferably provided as close as possible to the drain port of the high-pressure fuel pump 20.
The orifice 21 connected to the drain passage 11 in the vicinity of the drain port of the high-pressure fuel pump 20 leaked from the piston drive unit (sliding unit) for pressurizing and supplying the fuel of the high-pressure fuel pump 20 into the pump housing. This is a representation of a leak portion where the fuel reaches the drain passage 11 in an easy-to-understand manner, and indicates difficulty in flowing.

When a pump of a type cooled by low-pressure fuel is used as the high-pressure fuel pump 20,
As shown by the dotted line, the upstream end of the cooling passage 22 is connected to the low-pressure fuel passage 6 near the suction port of the high-pressure fuel pump 20, and the downstream end is connected to the drain passage 11 upstream of the check valve 30. Thereby, a part of the low-pressure fuel supplied to the low-pressure fuel passage 6 flows through the cooling passage 22, the orifice 23, the high-pressure fuel pump 20, the drain passage 11, the check valve 30, the return passage 9, and the fuel tank 2; The high-pressure fuel pump 2
Cool 0.

The low-pressure fuel pump 16 is, for example, an electric feed pump and is housed in the fuel tank 2 together with the check valve 17. The check valve 17 allows the low-pressure fuel discharged from the low-pressure fuel pump 16 to the low-pressure fuel passage 6 to pass only from the upstream side to the downstream side. The low-pressure regulator 19 regulates the fuel pressure in the low-pressure fuel passage 6 so as to maintain the fuel pressure at a predetermined pressure, and the valve opening pressure is set to a first set pressure, for example, 0.3 MPa (about 3 MPa).
Pressure). Then, the fuel pressure in the low-pressure fuel passage 6 is reduced by the check valve 17 and the low-pressure regulator 19.
The set pressure is maintained at 0.3 MPa.

The high-pressure fuel pump 20 is composed of, for example, a swash plate type axial piston pump, and is driven by an engine. Since the high-pressure fuel pump 20 is driven by the engine, the high-pressure fuel pump 20 is disposed near the engine in the engine room, and is preferably mounted on the engine body for reasons such as the ease of assembly and shortening of the high-pressure fuel passages 7 and 8. Is preferably performed. When the return passage 9 is set to pass near the high-pressure fuel pump 20, the drain passage 11 can be shortened accordingly.

The check valve 25 allows the high-pressure fuel discharged from the high-pressure fuel pump 20 to the high-pressure fuel passage 7 to pass only from the upstream side to the downstream side. The high-pressure regulator 26 regulates the fuel pressure in the fuel injection valve 3, that is, the delivery pipe 4, and maintains the fuel pressure at a predetermined pressure, and sets the valve opening pressure to a second set pressure, for example, 5 MPa (about 50 atm). Have been. Then, the fuel pressure in the delivery pipe 4 is maintained at the set pressure 5MP by the check valve 25 and the high-pressure regulator 26.

The check valve 30 in the drain passage 11 is for maintaining the fuel pressure in the high-pressure fuel pump 20 at a predetermined pressure (low pressure) after the engine is stopped.
Fuel flow is allowed only from the zero side to the leak passage 9 side.
The valve opening pressure of the check valve 30 is lower than the fuel pressure of the low-pressure fuel passage 6, that is, the set pressure of the low-pressure regulator 19 (0.3 MPa, about 3 atm). The fuel passage 5 has a set temperature (for example, 80 ° C.) at which the maximum temperature of the engine can be reached after the engine stops, and a pressure at which the saturated vapor pressure becomes equal to or higher than the saturated vapor pressure corresponding to the set temperature, for example, 0.2 MPa (about 2 MPa). Pressure). Thereby, the high pressure fuel pump 20
The fuel leaked from the piston drive unit (sliding portion) into the pump housing and the fuel for cooling can be returned to the fuel tank 2 through the leak passage 11 at the time of the operation.

The reason why the fuel passage 5 between the low-pressure fuel pump 16 and the high-pressure regulator 26 can reach the maximum temperature of the engine after the engine is stopped is that the high-pressure fuel pump 20 and the drain passage 11 are connected to the engine room as described above. Of which
Particularly, since the high-pressure fuel pump 20 and the drain passage 11 are arranged near the engine, the temperature of the high-pressure fuel pump 20 and the drain passage 11 rises to the maximum temperature of the engine when the engine is stopped.

The valve opening pressure (0.2 MPa) of the check valve 30 is:
The fuel passage 5 between the fuel tank 2 and the fuel injection valve 3 includes a low-pressure fuel pump 16, a check valve 17, a high-pressure fuel pump 20, a low-pressure regulator 19, a high-pressure regulator 26, and the like.
This is the valve opening pressure when the high-pressure fuel pump 20 is interposed in the drain passage 11 of the high-pressure fuel pump 20 in a fuel system having the drain passage 11.

However, as for the fuel system, the fuel system described above does not have the low-pressure fuel pump 16 and the low-pressure regulator 19, that is, the fuel system has a non-return to the fuel passage 5 between the fuel tank 2 and the fuel injection valve 3. The present invention is also applicable to a configuration including the valve 17, the high-pressure fuel pump 20, and the high-pressure regulator 26. In the fuel system having such a configuration, when the check valve 30 is interposed in the drain passage 11 of the high-pressure fuel pump 20, the valve opening pressure of the check valve 30 is lower than the set pressure of the high-pressure regulator 26, And check valve 17 and high pressure regulator 2
6 (specifically, a portion located upstream of the check valve 25 and disposed in the engine room),
The pressure in the passage in the high-pressure fuel pump 20 near the engine is set to a pressure that is equal to or higher than the saturated vapor pressure corresponding to the set temperature of the fuel that has a set temperature that can reach the maximum temperature of the engine after the engine is stopped.

The fuel pressure in the low-pressure fuel passage 6 (low-pressure fuel pressure)
Is to improve the startability by low pressure injection and to improve the fuel passage (piping)
0.25 to 0.6MPa in consideration of cost reduction
(About 2.5 to 6 atm). Therefore, the set pressure (valve opening pressure) of the check valve 30 is 0.2 to less than this.
It is preferable to set the pressure to about 0.3 MPa (about 2 to 3 atm). For example, when the fuel pressure in the low-pressure fuel passage 6 is 0.3 MPa (about 3 MPa).
When the pressure is set to (atmospheric pressure), the valve opening pressure of the check valve 30 is set to 0.2 MPa (about 2 atm).

The operation will be described below. Simultaneously with the start of the engine, the low-pressure fuel pump 16 is started to pressurize and discharge the fuel in the fuel tank 2,
To supply. The low-pressure fuel pump 16 starts at the same time as the start of the engine, and stops at the same time as the stop of the engine.
The low-pressure fuel supplied to the low-pressure fuel passage 6 is filtered by the filter 18.
Is supplied to the high-pressure fuel pump 20. The fuel pressure in the low-pressure fuel passage 6 is regulated by the low-pressure regulator 19 to the set pressure (0.3 aMP, about 3 atm). The high-pressure fuel pump 20 is driven by the engine, re-pressurizes the low-pressure fuel supplied from the low-pressure fuel passage 6, discharges it as high-pressure fuel, and supplies it to the delivery pipe 4 through the check valve 25 and the high-pressure fuel passage 7. The high-pressure fuel supplied to the delivery pipe 4 is injected and supplied into the cylinder from the fuel injection valve 3 whose valve opening is controlled by the electronic control unit.

When the high-pressure fuel pump 20 is operated, the fuel leaking into the pump housing from a piston driving portion (sliding portion) for supplying fuel under pressure is discharged to the drain passage 11. Since the valve opening pressure of the check valve 30 is set lower than the set pressure of the low-pressure regulator 19, the fuel leaked from the high-pressure fuel pump 20 flows through the check valve 30 to the return passage 9, Returned to tank 2.

When the engine stops, the low-pressure fuel pump 16 and the high-pressure fuel pump 20 stop at the same time. The fuel pressure in the low-pressure fuel passage 6 from the fuel tank 2 to the high-pressure fuel pump 20 is maintained at the predetermined pressure (about 3 atm) by a check valve 17 and a low-pressure regulator 19. In addition, the drain passage 11 of the high-pressure fuel pump 20 is closed by the check valve 30 and is maintained at the valve opening pressure (about 2 atm) of the check valve 30. The pressure in the high-pressure passages 7 and 8 is maintained by a check valve 25 and a high-pressure regulator 26.

That is, the valve opening pressure of the check valve 30 is, as described above, the fuel pressure of the low-pressure fuel passage 6, that is, the low-pressure regulator 1
9 (0.3 MPa, about 3 atm) and a fuel passage between the low-pressure fuel pump 16 and the high-pressure regulator 26 (specifically, an upstream passage of the check valve 25 and the inside of the engine room). In particular, when the passage in the high-pressure fuel pump 20 near the engine reaches the set temperature (80 ° C.) at which the maximum temperature of the engine can be reached after the engine is stopped, the saturated vapor pressure is equal to or higher than the saturated vapor pressure corresponding to the temperature. (0.2 MPa, about 2 atm). Therefore, the fuel pressure in the low-pressure fuel passage 6, the high-pressure fuel pump 20, and the drain passage 11 is maintained at or above this pressure (about 2 atm). Thereby, after the engine stops, the high-pressure fuel pump 2
Even if the fuel temperature within 0 increases, generation of vapor in the high-pressure fuel pump 20 is prevented. Thus, in the high-temperature state immediately after the engine is stopped, the startability when the engine is started again, that is, the high-temperature startability is improved.

In FIG. 1, a low pressure regulator 31 as shown in FIG. 2 may be used in place of the check valve 30 as a pressure regulating means provided in the pump drain passage 11. Also in this case, the valve opening pressure of the low pressure regulator 31 may be set to the valve opening pressure of the check valve 30 described above. The check valve 17 is
It may be provided integrally with the low-pressure fuel pump 16 or may be arranged upstream of the low-pressure fuel pump 16. (Embodiment 2) FIG. 3 shows a second embodiment of the present invention. still,
In the figure, the same members as those in FIG. In FIG. 3, a delivery pipe 4 ′ is a delivery pipe of a type whose downstream end is closed,
The discharge port 0 is connected to the upstream end of the delivery pipe 4 ′ via the check valve 25 and the high-pressure fuel passage 7, and is connected to the high-pressure fuel passage 7 downstream of the check valve 25 and upstream of the delivery pipe 4 ′.
Is connected to the upstream end of the high-pressure fuel passage 8. Therefore,
The delivery pipe 4 'does not constitute a part of the circulation path of the high-pressure fuel passage unlike the delivery pipe 4 of the first embodiment.
Other configurations are the same as those of the first embodiment shown in FIG.

The high-pressure fuel discharged from the high-pressure fuel pump 20 is supplied to the high-pressure fuel passage 7, the delivery pipe 4 'and the high-pressure fuel passage 8 through the check valve 25. Then, the high-pressure fuel in the delivery pipe 4 ′ is injected from the injector 3 into the cylinder. The fuel pressure in the delivery pipe 4 ′ and the high-pressure fuel passages 7 and 8 is regulated by a regulator 26.

In the fuel system having such a configuration, since the delivery pipe 4 'does not form a circulation path of the high pressure fuel passage, the high pressure fuel passage 8 shown in FIG. The high-pressure fuel passage 8 reaching 26 can be shortened, so that the cost of the high-pressure fuel passage 8 can be reduced, and the cost of the fuel system can be reduced accordingly.

[0031]

As described above, according to the invention, in the fuel system provided with the fuel pump having the drain passage, the drain passage is provided with the pressure adjusting means for passing the fuel only from the upstream side to the downstream side. Thus, the generation of vapor in the fuel passage and the fuel pump when the engine is stopped can be suppressed without impairing the function of the pump drain passage, and the high-temperature startability of the engine can be improved. In addition, since the function of the drain passage is not impaired, the fuel pump is prevented from being damaged such as turning up of an oil seal, the durability is improved, and an inexpensive pump with low sealing performance can be used. Thus, the cost of the fuel supply device can be reduced.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a first embodiment of a fuel supply device for an internal combustion engine according to the present invention.

FIG. 2 is a diagram showing another example of the pressure adjusting means used in the pump drain passage of the fuel supply device of FIG.

FIG. 3 is a configuration diagram showing a second embodiment of the fuel supply device for an internal combustion engine of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Fuel supply device 2 Fuel tank 3 Fuel injection valve 4, 4 'Delivery pipe 5 Fuel passage 6, 10 Low pressure fuel passage 7, 8 High pressure fuel passage 9 Return passage 11 Pump drain passage (leak passage) 16 Low pressure fuel pump 17, 25 Check valve 19 Low pressure regulator 20 High pressure fuel pump 26 High pressure regulator 30 Check valve (pressure adjusting means) 31 Low pressure regulator

────────────────────────────────────────────────── (5) Continuation of the front page (51) Int.Cl. ⁶ Identification symbol FI F02M 55/02 350 F02M 55/02 350E 350G (56) References JP-A-7-83134 (JP, A) JP-A-5-83134 33741 (JP, A) JP-A-9-4498 (JP, A) JP-A-5-321178 (JP, A) JP-A-61-34345 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) F02M 37/00

Claims (2)

(57) [Claims] 1. A circulation circuit is provided between a fuel injection valve provided in an internal combustion engine and a fuel tank, from the fuel tank to the fuel injection valve, and from the fuel injection valve back to the fuel tank. A fuel passage provided in an upstream portion of the fuel passage near the fuel tank, the holding means being configured to allow fuel to pass only from an upstream side to a downstream side of the fuel passage; and a fuel passage disposed in an engine room. A fuel pump provided between the fuel injection valve and the holding means to supply fuel to the fuel injection valve; and a fuel pump provided in the fuel passage, the pressure of the fuel discharged by the fuel pump being adjusted to a predetermined pressure. Pressure control means for adjusting pressure; a drain passage for returning a part of the fuel in the fuel pump to the fuel tank; provided in the drain passage, and upstream of the drain passage at a set pressure or higher. Pressure regulating means for passing fuel only from the downstream to the downstream side, the set pressure of the pressure regulating means is lower than the set pressure of the pressure control means, and between the holding means and the pressure control means A fuel supply device for an internal combustion engine, wherein the fuel passage is set to a saturated vapor pressure equal to or higher than the set temperature of the fuel at which a set temperature capable of reaching the engine maximum temperature after the internal combustion engine is stopped. 2. A circulation circuit is provided between a fuel injection valve provided in an internal combustion engine and a fuel tank, from the fuel tank to the fuel injection valve, and from the fuel injection valve back to the fuel tank. A low-pressure fuel pump provided in an upstream portion of the fuel passage near the fuel tank; and a low-pressure fuel pump disposed in an engine room, between the low-pressure fuel pump and the fuel injection valve in the fuel passage. A high-pressure fuel pump provided; holding means provided in series with the low-pressure fuel pump in a fuel passage upstream of the high-pressure fuel pump to allow fuel to pass only from an upstream side to a downstream side of the fuel passage; A low-pressure adjusting means for adjusting a fuel pressure discharged from a fuel pump at a first set pressure; and a high-pressure fuel provided in the fuel passage downstream of the high-pressure fuel pump. High pressure adjusting means for controlling the pressure of the fuel discharged from the pump at a second set pressure higher than the first set pressure; a drain passage for returning a part of the fuel in the high pressure fuel pump to the fuel tank; Pressure regulating means for allowing fuel to pass only from the upstream side to the downstream side of the drain passage at a pressure equal to or higher than a set pressure, wherein the set pressure of the pressure adjuster is lower than the first set pressure of the low pressure adjuster. And at least a saturated vapor pressure corresponding to the set temperature of the fuel at which the fuel passage between the low-pressure fuel pump and the high-pressure adjusting means has a set temperature that can reach an engine maximum temperature after the internal combustion engine is stopped. A fuel supply device for an internal combustion engine, comprising: