This application is based on and incorporates herein by reference Japanese Patent Application No. 2007-330123 filed on Dec. 21, 2007.
The present invention relates to a fuel injection pump including a low-pressure pump portion for pumping fuel from a fuel tank and a fuel pressure regulating valve for regulating pressure of fuel discharged from the low-pressure pump portion.
A conventional fuel injection pump applied to an accumulator fuel injection system for a diesel engine is disclosed in JP-A-2000-240531.
The fuel injection pump disclosed in JP-A-2000-240531 includes a low-pressure pump portion, a fuel pressure regulating valve (return valve), and a high-pressure pump portion. The low-pressure pump portion (feed pump portion) pumps fuel from a fuel tank. The fuel pressure regulating valve (return valve) regulates pressure of fuel discharged from the feed pump portion. The high-pressure pump portion further pressurizes fuel, which is discharged from the feed pump portion, and press-feeds the fuel to a common rail, which stores the fuel at high-pressure.
The return valve opens and returns fuel from the downstream of the feed pump portion to the upstream of the feed pump portion when pressure of fuel discharged from the feed pump portion becomes greater than predetermined pressure. The return valve is inserted to a mounting hole (mounting portion) provided in a pump housing as an outer shell of the fuel injection pump, thereby the return valve is mounted to the fuel injection pump.
However, the pump housing of the fuel injection pump disclosed in JP-A-2000-240531 includes the high-pressure pump portion and the feed pump portion. The pump housing is formed with multiple fuel passages and a mounting portion to which a component such as the feed pump portion is mounted. Therefore, interference between fuel passages and the mounting hole, in which the return valve in pump housing is inserted, needs to be avoided when the mounting hole is formed. Accordingly, manufacturing of the mounting hole is complicated.
In view of the present problem, the present inventor filed the Japanese patent application No. 2007-21378 to propose a structure in which the mounting hole, to which the return valve is inserted, is formed in the feed pump cover (low-pressure pump cover), which is a separate component from the pump housing. In the present structure of the fuel injection pump, workability of the mounting hole is enhanced compared with JP-A-2000-240531 in which the mounting hole is formed in the pump housing.
The low-pressure pump cover functions as an outer shell of the feed pump portion. The low-pressure pump cover is fixed to the pump housing by using a bolt or the like while accommodating a rotatable member of the feed pump portion. Specifically, a trochoid rotor of a trochoid pump as the feed pump portion is accommodated in the low-pressure pump cover.
In short, the low-pressure pump cover functions as a part of the feed pump portion. In addition, the low-pressure pump cover also functions as a mounting member used for mounting the feed pump portion to the pump housing. The low-pressure pump cover accommodates the rotatable member of the feed pump. Therefore, high dimensional accuracy of, for example, tens of microns is required to the low-pressure pump cover when the inside of the low-pressure pump cover is manufactured.
Therefore, the outline of the low-pressure pump cover may be complicated for being chucked when the inside of the low-pressure pump is manufactured. Moreover, when the mounting hole, to which the return valve is inserted, is formed after manufacturing the inside of the low-pressure pump cover with high accuracy, the inside of the low-pressure pump cover may be deformed. Accordingly, in the fuel injection pump according to the Japanese patent application No. 2007-21378, workability of the mounting hole may not be sufficiently enhanced.
In view of the foregoing and other problems, it is an object of the present invention to produce a fuel injection pump in which workability of a mounting portion of a fuel pressure regulating valve is enhanced.
According to one aspect of the present invention, a fuel injection pump comprises a low-pressure pump portion configured to pump fuel from a fuel tank. The fuel injection pump further comprises a pressure regulating valve configured to control pressure of fuel discharged from the low-pressure pump portion. The fuel injection pump further comprises a high-pressure pump portion configured to pressurize fuel discharged from the low-pressure pump portion to press-feed the fuel. The fuel injection pump further comprises a valve cover having a mounting portion, which is configured to be mounted with the pressure regulating valve. The high-pressure pump portion includes a cylinder, a movable member, and a camshaft. The cylinder defines a high-pressure pump chamber for compressing fuel. The movable member is configured to move to pressurize fuel in the high-pressure pump chamber to press-feed the fuel. The camshaft is configured to move the movable member. The low-pressure pump portion includes a rotatable member and a pump cover. The rotatable member is rotatable integrally with the camshaft. The pump cover accommodates the rotatable member. The pump cover is fixed to the pump housing. The valve cover is a separate component from the pump housing and the pump cover.
In the present structure, interference between the mounting portion, the multiple fuel passages provided in pump housing and the like need not be considered when the mounting portion is manufactured. In addition, deformation caused in the inside of the low-pressure pump cover need not be considered when the mounting portion is manufactured. Consequently, manufacturing of the mounting portion of the return valve can be sufficiently facilitated, compared with the fuel injection pump disclosed in JP-A-2000-240531.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings;
The present first embodiment will be described with reference to
The common rail 1 serves as an accumulating unit for accumulating high-pressure fuel supplied from the fuel injection pump 3 and holding the high-pressure fuel at target rail pressure. An unillustrated control unit (ECU) determines the target rail pressure in accordance with an operating condition such as a throttle position of an accelerator and rotation speed of the diesel engine. The common rail 1 is further provided with a pressure limiter 1a, which is configured to open so as to release fuel pressure in the common rail 1 when fuel pressure in the common rail 1 exceeds predetermined upper limit. The fuel flowing from the pressure limiter 1a returns into the fuel tank 4 through a fuel pipe 1b.
Each injector 2 serves as a fuel injection unit for injecting high-pressure fuel into the combustion chamber of the diesel engine. Each injector 2 is supplied with high-pressure fuel from the common rail 1 through a high-pressure pipe 2a. Fuel supplied from the common rail 1 is not partially injected, and the part of supplied fuel is returned as surplus fuel to the fuel tank through a fuel pipe 2b. The injector 2 is connected with an ECU, and thereby an injection timing and an injection amount are controlled according to a control signal transmitted from the ECU.
The fuel injection pump 3 will be described with reference to
As show in
As shown in
Referring to
A fuel filter 12 is provided to the downstream of the feed pump portion 5 for filtering fuel discharged from the feed pump portion 5. A relief valve 13 is further provided to the downstream of the feed pump portion 5. The relief valve 13 is configured to open, i.e., communicate therethrough when pressure of the fuel applied to the fuel filter 12 becomes equal to or greater than predetermined pressure. Fuel, which is fed from the feed pump portion 5, is partially returned to the fuel tank 4 through a fuel pipe 13a in response to opening of the relief valve 13. The fuel filter 12 is provided outside the fuel injection pump 3 and connected with the fuel injection pump 3 via a fuel pipe. In the present structure, fuel is discharged from the feed pump portion 5, and the fuel once flows outside the fuel injection pump 3. Subsequently, the fuel again flows into the fuel injection pump 3 after being filtered through the fuel filter 12. The fuel filter can be applied with pressure of fuel discharged from the feed pump portion 5. Therefore, the fuel filter 12 may have a filtering mesh less than that of each of the pre-filter 8 and the gauze filter 10, so that the fuel filter 12 may have a filtering performance higher than that of each of the pre-filter 8 and the gauze filter 10. Thus, the fuel filter 12 is capable of removing particulate foreign matters, moisture, and the like, which cannot be removed using the pre-filter 8 and the gauze filter 10.
Furthermore, a return passage 14 is connected to a passage between the feed pump portion 5 and the fuel filter 12 inside the fuel injection pump 3 so as to return fuel to the upstream of the feed pump portion 5. The return passage 14 is provided with the return valve 15 (
As shown in
Further, as shown in
As show in
The orifice 16 serves as a throttle unit configured to throttle the fuel passage 12a, which extends from the fuel filter 12 to the inlet control valve 7, thereby restricting flow of fuel through the fuel filter 12. A passage between the orifice 16 and the inlet control valve 7 in the fuel passage 12a is connected with a passage between the gauze filter 10 and the feed pump portion 5 through a fuel passage 12b. The fuel passage 12b is provided with a regulator valve 17. The regulator valve 17 includes a mechanical structure similar to that of the return valve 15, and is capable of controlling pressure of fuel downstream of the orifice 16 at pressure equal to or less than predetermined pressure. The fuel passage 12b is connected with a fuel passage 12c through which fuel flows from the upstream of the inlet control valve 7 to a cam chamber 64 of the high-pressure pump portion 6. The high-pressure pump portion 6 is connected with the downstream of the inlet control valve 7 through a fuel passage 7a. The fuel passage 7a is further connected with a fuel passage 7b through which fuel returns to the upstream of the gauze filter 10 through an orifice 18. In the present structure, when, for example, the inlet control valve 7 closes, surplus fuel is capable of returning from the downstream of the inlet control valve 7 to the upstream of the feed pump portion 5.
As shown by the portion boxed with the two-dot chain line in
Referring to
Next, the structure of the rear cover 70 according to the present embodiment is described with reference to
Further, as shown in
Next, an operation of the fuel feed apparatus is described. First, the camshaft 61 of the high-pressure pump portion 6 rotates in conjunction with the operation of the diesel engine in the vehicle. The camshaft 61 is connected with the feed pump portion 5, so that the camshaft 61 transmits driving force to the feed pump portion 5. The feed pump portion 5 is transmitted with the driving force, thereby pumping fuel from the fuel tank 4 through the inlet pipe 4a. In the present operation, fuel passes through the pre-filter 8 and the gauze filter 10 in this order, thereby being filtered. The fuel press-fed from the feed pump portion 5 is further filtered through the fuel filter 12, and the fuel flows into the inlet control valve 7 after passing through the fuel passage 12a. The ECU controls the opening of the inlet control valve 7 by transmitting the control signal, so that fuel flows into the high-pressure pump portion 6 through the fuel passage 7a by an amount sufficient for the operation of the diesel engine of the vehicle.
The cam 63 rotates together with the camshaft 61, thereby axially actuating the plunger 62 in the high-pressure pump portion 6. The plunger 62 moves toward the camshaft 61 in the cylinder 3b by being axially actuated, so that the high-pressure pump chamber 65 increases in volume and decreases in pressure. In the present operation, the inlet valve 66 opens to draw fuel from the downstream of the inlet control valve 7 into the high-pressure pump chamber 65 after passing through the fuel passage 7a and the inlet passage 65a in order. Alternatively, the plunger 62 moves away from the camshaft 61 in the cylinder 3b, so that the high-pressure pump chamber 65 decreases in volume, thereby compressing fuel drawn into the high-pressure pump chamber 65. When pressure of the compressed fuel becomes greater than the predetermined pressure, the outlet valve 67 opens, so that fuel is press-fed from the high-pressure pump chamber 65 into the common rail 1 after passing through the outlet passage 65b and the fuel passage 1c in order. Thus, the common rail 1 accumulates high-pressure fuel. The high-pressure fuel accumulated in the common rail 1 is injected into the combustion chamber of the diesel engine through the injector 2, which is manipulated in accordance with the control signal transmitted from the ECU.
As follows, an operation effect of the fuel feed apparatus will be described. According to the fuel injection pump 3 in the present embodiment, the mounting hole 70a, to which the return valve 15 is attached, is formed in the rear cover 70. The rear cover 70 is a separate component from both the pump housing 3a and the feed pump cover 53. The definition of the separate may include individual and distinct. That is, the rear cover 70 (valve cover) is a separate component from the pump housing 3a and the feed pump cover 53 (low-pressure pump cover), regardless of being combined or not.
Therefore, interference with the multiple fuel passages and the like provided in the pump housing 3e and deformation of the interior of the feed pump cover 53 need not be considered when the mounting hole 70a is manufactured. Consequently, manufacturing of the mounting hole 70a of the return valve 15 can be sufficiently facilitated. In addition, the fuel outlet port 70b, from which the feed pump portion 5 press-feeds fuel, and the communication passage 70e, which communicates the fuel outlet port 70b with the pressure receiving side of the valve element portion 15b of the return valve 15, are formed in the rear cover 70. Therefore, an additional pipe for communicating the fuel outlet port 70b of the feed pump cover 53 with the pressure receiving side of the valve element portion 15b need not be provided. Thus, the fuel injection pump can be avoided from increasing in size. Further, the longitudinal direction of the return valve 15 is substantially at a 90 degree angle with respect to the axial direction of the camshaft 61. In the present structure, the longitudinal direction of the return valve 15 is substantially in parallel with the wall surface of the pump housing 3a, to which the feed pump portion 5 is fixed. Therefore, the fuel injection pump can be restricted from being enlarged because of mounting of the return valve 15 to the rear cover 70. Further, both the rear cover 70 and the feed pump cover 53 are fixed to the pump housing 3a by using the bolts 80. Therefore, the rear cover 70 and the feed pump cover 53 can be easily fixed. Furthermore, the rear cover 70 and the feed pump cover 53 are configured as separate components. Therefore, the hardness of the material of the rear cover 70 may be lower than the hardness of the material of the feed pump cover 53. In short, the rear cover 70 may be formed from a material, which is excellent in workability, compared with the feed pump cover 53. In the present structure, workability of the mounting hole 70a can be further enhanced.
In the first embodiment, the axial direction (longitudinal direction) of the mounting hole 70a of the return valve 15 is at an angle with respect to the axial direction of the camshaft 61 in the rear cover 70. By contrast, in the present second embodiment, as shown in
Each of
As described above, according to the first embodiment, the fuel injection pump 3 is applied to the accumulator fuel injection system, which includes the fuel filter 12 at the downstream of the feed pump portion 5. On the other hand, in the present third embodiment as shown in the
In the present structure, fuel discharged from the feed pump portion 5 directly flows into the fuel passage 12a without flowing out of the fuel injection pump 3. Furthermore, the return valve 15 is also omitted, and therefore the regulator valve 17 is attached to the mounting hole 70a of the rear cover 70. The fuel passage inside the rear cover 70 is also modified in response to the above modification. The structure of the fuel injection pump other than the feature of the present embodiment is substantially equivalent to that of the first embodiment. Even in the present third embodiment, in which the regulator valve 17 is provided to the mounting hole 70a of the rear cover 70, workability of the mounting hole 70a can be sufficiently enhanced similarly to the first embodiment. In addition, the fuel injection pump can be restricted from being enlarged.
The structure of the fuel injection pump according to the first to third embodiments may be arbitrary modified. For example, the fuel injection pump may be variously modified, as follows.
(1) In the above embodiments, a trochoid pump is employed as the feed pump portion 5. However, the feed pump portion is not limited to a trochoid pump. For example, as shown in
(2) In the above embodiments, the high-pressure pump portion 6 is a single-type high-pressure pump having the two plungers 62 opposed to each other radially via the camshaft 61. Alternatively, the high-pressure pump portion 6 may be a tandem-type high-pressure pump having four plungers 62 arranged around the camshaft 61 with respect to the rotative direction thereof.
(3) In the above embodiments, either the return valve 15 or the regulator valve 17 is inserted and mounted to the rear cover 70. Alternatively, both the return valve 15 and the regulator valve 17 may be mounted to the rear cover 70.
(4) In the first embodiment, the return passage 14 is directly connected with the passage between the downstream (outlet) of the feed pump portion 5 and the upstream (inlet) of the feed pump portion 5. However, the physical relationship among the feed pump portion 5 and other components is not limited to the above example. Fuel may be returned from the downstream of the fuel filter 12 to the upstream of the feed pump portion 5, for example.
(5) In each of the above embodiments, the fuel injection pump is applied to the accumulator fuel injection system, i.e., an inlet control accumulator fuel injection system including the inlet control valve 7 for controlling flow of fuel to be compressed using the high-pressure pump portion 6. Alternatively, the fuel injection pump may be applied to an accumulator fuel injection system capable of controlling flow of press-fed fuel to the common rail by controlling valve-close timing of an outlet valve of a variable flow high-pressure pump, i.e., a pre-stroke control accumulator fuel injection system.
(6) In the above embodiments, as shown in
In the above embodiments the longitudinal direction of the fuel pressure regulating valve is at an angle with respect to the axial direction of the camshaft. The present definition is not limited to the structure in which the longitudinal direction of the fuel pressure regulating valve is at the 90 degree angle with respect to the axial direction of the camshaft. The present definition includes a structure in which the longitudinal direction of the fuel pressure regulating valve is inclined with respect to the axial direction of the camshaft. That is, the inclination angle between the longitudinal direction of the fuel pressure regulating valve and the axial direction of the camshaft may be arbitrary determined.
The above structures of the embodiments can be combined as appropriate. Various modifications and alternations may be diversely made to the above embodiments without departing from the spirit of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
2007-330123 | Dec 2007 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4453522 | Salzgeber | Jun 1984 | A |
6289875 | Shinohara et al. | Sep 2001 | B1 |
6722864 | Suzuki et al. | Apr 2004 | B2 |
7080631 | Hanyu | Jul 2006 | B2 |
20030221552 | Onishi et al. | Dec 2003 | A1 |
20050100448 | Graf et al. | May 2005 | A1 |
20060169251 | Mori et al. | Aug 2006 | A1 |
20080178845 | Shimai | Jul 2008 | A1 |
Number | Date | Country |
---|---|---|
02-146254 | Jun 1990 | JP |
2-191863 | Jul 1990 | JP |
2003-172230 | Jun 2003 | JP |
2003-269342 | Sep 2003 | JP |
2004-332645 | Nov 2004 | JP |
2007-146862 | Jun 2007 | JP |
Number | Date | Country | |
---|---|---|---|
20090159054 A1 | Jun 2009 | US |