JPWO2018003435A1 - High pressure fuel supply pump - Google Patents

Abstract

Provided is a high-pressure fuel supply pump capable of regulating the stroke of a valve body retainer without providing an adjuster for regulating the stroke of the valve body retainer. Therefore, the relief valve holder is disposed on the outer circumferential side, and the first inner circumferential portion formed on the relief seat side and the first inner circumferential portion are formed on the downstream side of the relief valve and have a cross-sectional area than the first inner circumferential portion. And the relief valve holder includes a throttle forming portion forming a set gap with the first inner circumferential portion, and a first inner side in the valve closed state of the relief valve. A flow passage forming portion formed at a position facing the circumferential portion and moving to a position facing the second inner circumferential portion in the valve opening state of the relief valve, the flow passage forming portion and the second inner circumferential portion The gap between them was configured to be larger than the set gap.

Description

  The present invention relates to a high pressure fuel supply pump, and more particularly to a high pressure fuel supply pump provided with a relief valve mechanism.

Among internal combustion engines such as automobiles, in a direct injection type in which fuel is directly injected into the combustion chamber to the combustion chamber, a high pressure fuel supply pump for pressurizing the fuel is widely used. As background art of this high-pressure fuel pump, there is JP-A-2009-114868. The relief valve structure of the high pressure fuel pump is configured to have a squeezing effect on the gap between the housing in the fuel passage and the valve presser in the fuel passage in which the fluid flows from the high pressure side to the low pressure side. As a result, the pressure in the high-pressure pipe can be rapidly reduced by causing the stroke in the valve-opening direction to be largely stroked by the differential pressure generated on the high pressure side and the low pressure side of the valve body presser.
(See Patent Document 1).

JP, 2009-114868, A

  However, in the technique of Patent Document 1, the stroke amount of the valve body presser is larger than that without the squeeze effect, and when the adjuster for controlling the stroke of the valve body presser is not provided, the valve body presser is closed in the valve closing direction. It may cause the relief spring to bias. If the adjuster is provided, the relief valve may be enlarged, the mass may increase, the cost may be increased, and the commercial value may be impaired.

  An object of the present invention is to provide a high-pressure fuel supply pump capable of regulating the stroke of the valve body presser and allowing the valve body to make a large stroke without providing an adjuster for regulating the stroke of the valve body presser.

In order to solve the above-mentioned problems, the present invention is
“A discharge passage for discharging the fuel pressurized by the pressure chamber;
A relief passage connecting the discharge passage and the pressurizing chamber or a suction passage of the pressurizing chamber;
A relief valve for opening and closing a relief sheet of the relief passage;
A relief valve holder for holding the relief valve;
A relief spring for biasing the relief valve holder from the downstream side to the upstream side of the relief valve;
The relief valve holder is disposed on the outer circumferential side, and is formed on the downstream side of the relief valve with respect to the first inner circumferential portion formed on the side of the relief sheet and the first inner circumferential portion. A housing having a second inner periphery with a large cross-sectional area,
The relief valve holder is formed at a throttle forming portion forming a set gap with the first inner circumferential portion, and at a position facing the first inner circumferential portion in the valve closing state of the relief valve. A flow passage forming portion moving to a position facing the second inner circumferential portion in the valve opening state of the relief valve;
The high pressure fuel supply pump, wherein a gap between the flow passage forming portion and the second inner circumferential portion is larger than the set gap. It is characterized by ".

  According to the present invention configured as described above, it is possible to provide a high-pressure fuel supply pump capable of regulating the stroke of the valve body retainer without providing an adjuster for regulating the stroke of the valve body retainer. Other configurations, operations and effects of the present invention will be described in detail in the following embodiments.

FIG. 1 is an overall longitudinal cross-sectional view of a high pressure fuel supply pump according to a first embodiment of the present invention. FIG. 5 is a cross-sectional view from another angle of the high pressure fuel supply pump of the first embodiment. FIG. 2 is a cross-sectional view perpendicular to the plunger axial direction of the high pressure fuel supply pump of the first embodiment, and a center of an inlet port axis of fuel and a center of an outlet port axis of fuel. FIG. 1 is an overall system view including a high pressure fuel supply pump. 1 is a cross-sectional view of a relief valve mechanism according to a first embodiment of the present invention. It is a detail drawing of the relief valve mechanism of the first example in which the present invention was carried out. It is an external view of a relief valve member. It is detail drawing of the relief valve mechanism of 2nd Example. It is an external view of the relief valve member of 3rd Example. It is detail drawing of the relief valve mechanism of 3rd Example. It is detail drawing of the relief valve mechanism of 3rd Example.

  Hereinafter, an embodiment according to the present invention will be described using the drawings.

Hereinafter, examples of the present invention will be described.
The configuration and operation of the system will be described using FIG. FIG. 4 is a view showing the overall configuration of a system including the high pressure fuel supply pump according to the present invention.

A portion surrounded by a broken line shows a main body 1A of a high pressure fuel supply pump (hereinafter referred to as a high pressure pump) 1 (see FIG. 1), and the mechanism and parts shown in the broken line are integrated with the high pressure pump main body 1A. Indicates that it is incorporated.
The fuel of the fuel tank 20 is pumped up by the feed pump 21 and is sent through the suction pipe 28 to the suction joint 10a of the pump body (pump body) 1A. The fuel that has passed through the suction joint 10a reaches the suction port 30a of the electromagnetic suction valve 30 that constitutes the capacity variable mechanism through the pressure pulsation reduction mechanism 9 and the suction passage 10b. The pulsation preventing mechanism 9 will be described later.

The electromagnetic suction valve 30 is provided with an electromagnetic coil 308. When the electromagnetic coil 308 is not energized, the anchor (electromagnetic plunger) 305 and the suction valve body 301 are biased by the biasing force of the difference between the biasing force of the anchor spring 303 and the biasing force of the valve spring 304, as shown in FIG. As shown in, it has moved to the right. At this time, the suction valve body 301 is biased in the valve opening direction, and the suction port 30 d is in an open state.
The biasing force of the anchor spring 303 and the biasing force of the valve spring 304 are as follows:
The biasing force of the anchor spring 303 is set to be the biasing force of the valve spring 304.

  On the other hand, when the electromagnetic coil 308 is energized, the anchor 305 moves to the left in FIG. 4 and the anchor spring 303 is compressed. The suction valve body 301 attached to the tip of the anchor 305 so that the tip of the anchor 305 contacts coaxially closes the suction port 30 d by the biasing force of the valve spring 304. The suction port 30 d is a fuel passage (fuel flow passage) connecting the pressurizing chamber 11 of the high pressure pump 1 and the suction port 30 a.

Hereinafter, the operation of the high pressure pump 1 will be described.
When the plunger 2 is displaced downward in FIG. 4 and is in the suction stroke state due to the rotation of a cam described later, the volume of the pressure chamber 11 increases and the fuel pressure in the pressure chamber 11 decreases. When the fuel pressure in the pressure chamber 11 becomes lower than the pressure in the suction passage 10b (the suction port 30a) in this process, the fuel flows into the pressure chamber 11 through the suction port 30d in the open state.

  When the plunger 2 ends the suction stroke and shifts to the compression stroke, the plunger 2 shifts to the compression stroke (a state of moving upward in FIG. 1). Here, the electromagnetic coil 308 remains in the non-energized state, and no magnetic biasing force acts on the anchor 305. Thus, the suction valve body 301 remains open due to the biasing force of the anchor spring 303.

  In the compression stroke, the volume of the pressure chamber 11 decreases with the compression movement of the plunger 2. However, in this state, the fuel once sucked into the pressurizing chamber 11 is returned to the suction passage 10b (the suction port 30a) through the suction valve body 301 in the open state again. Therefore, the pressure in the pressure chamber 11 does not rise. This process is called a return process.

  In this state, when a control signal from the engine control unit 27 (hereinafter referred to as an ECU) is applied to the electromagnetic suction valve 30, a current flows in the electromagnetic coil 308 of the electromagnetic suction valve 30. At this time, a magnetic biasing force acts on the anchor 305, and the electromagnetic plunger 305 moves to the left in FIG. 4 so that the anchor spring 303 is compressed. As a result, the biasing force of the anchor spring 303 does not act on the suction valve body 301, and the biasing force of the valve spring 304 and the fluid force by the fuel flowing into the suction passage 10b (suction port 30a) work. Therefore, the suction valve body 301 closes and closes the suction port 30d.

  When the suction port 30d is closed, the fuel pressure in the pressure chamber 11 rises with the upward movement of the plunger 2 from this point on. Then, when the fuel pressure in the pressure chamber 11 becomes equal to or higher than the fuel pressure on the fuel discharge port 12 side, high pressure discharge of the fuel remaining in the pressure chamber 11 is performed via the discharge valve mechanism 8. The high pressure fuel discharged to the discharge joint 12 side is supplied to the common rail 23. This stroke is called a discharge stroke.

  That is, the compression stroke (the rising stroke from the lower start point to the upper start point) of the plunger 2 consists of a return stroke and a discharge stroke. Then, by controlling the energization timing of the electromagnetic coil 308 of the electromagnetic suction valve 30, the amount of high pressure fuel to be discharged can be controlled. If the timing for energizing the electromagnetic coil 308 is advanced, the proportion of the return stroke in the compression stroke becomes smaller and the proportion of the discharge stroke becomes larger. That is, the fuel returned to the suction passage 10b (the suction port 30a) decreases, and the fuel discharged at high pressure increases.

  On the other hand, if the timing for energizing the electromagnetic coil 308 is delayed, the proportion of the return stroke in the compression stroke becomes large, and the proportion of the discharge stroke becomes small. That is, the amount of fuel returned to the suction passage 10b increases, and the amount of fuel discharged at high pressure decreases.

The energization timing of the electromagnetic coil 308 is controlled by a command from the ECU 27.
By configuring as described above, by controlling the energization timing of the electromagnetic coil 308, it is possible to control the amount of high pressure discharged fuel to the amount required by the internal combustion engine.

  A discharge valve mechanism 8 is provided at the outlet of the pressure chamber 11. The discharge valve mechanism 8 includes a discharge valve seat surface (discharge valve seat portion) 8a, a discharge valve 8b, and a discharge valve spring 8c. In the state where there is no fuel pressure difference between the pressure chamber 11 and the fuel discharge port 12, the discharge valve 8b is pressed against the discharge valve seat surface 8a by the biasing force of the discharge valve spring 8c, and is in a closed state. The discharge valve 8b opens against the discharge valve spring 8c only when the fuel pressure in the pressure chamber 11 becomes larger than the fuel pressure on the discharge joint side constituting the discharge port 12. When the discharge valve 8 b is opened, the fuel in the pressurizing chamber 11 is discharged at high pressure to the common rail 23 through the fuel discharge port 12.

  Thus, the fuel introduced to the suction joint 10a is pressurized to a high pressure by the reciprocating motion of the plunger 2 in the pressurizing chamber 11 of the pump main body 1A, and the necessary amount of fuel is pressure-fed from the fuel discharge port 12 to the common rail 23. .

  Direct injectors 24 (so-called direct injectors) and a pressure sensor 26 are mounted on the common rail 23. The direct injection injector 24 is mounted according to the number of cylinders of the internal combustion engine, and opens and closes the valve according to the control signal of the engine control unit (ECU) 27 to inject fuel into the cylinder (combustion chamber) of the internal combustion engine. .

  The pump body 1A is further provided with a relief valve mechanism 100. The relief valve mechanism 100 is provided with a relief passage (return passage) 101 communicating the downstream side of the discharge valve 8b with the pressure chamber 11, separately from the discharge passage 110, bypassing the discharge valve mechanism 8. . The discharge passage 110 discharges the fuel pressurized in the pressure chamber 11. The relief passage (return passage) 101 is configured to connect the discharge passage 110 and the pressure chamber 11, but not the pressure chamber 11 but connecting the discharge passage 110 and the suction passage (10a, 10b). It may be configured as follows. The relief passage 103 is provided with a relief valve 103. The relief valve 103 restricts the flow of fuel to only one direction from the discharge passage 110 to the pressurizing chamber 11.

  The relief valve 103 is pressed against the relief valve seat 104 by a relief spring 102 that generates a pressing force (biasing force). When the pressure difference between the fuel pressure in the pressurizing chamber 11 and the fuel pressure in the discharge passage 110 exceeds the specified pressure, the relief valve 103 is released from the relief valve seat 104 and is opened. It is set to.

When an abnormal high pressure is generated in the common rail 23 etc. due to a failure of the direct injection injector 24 or the like, the pressure difference between the fuel pressure in the discharge passage 110 and the fuel pressure in the pressurizing chamber 11 becomes equal to or more than the opening pressure of the relief valve 103 The valve 103 opens. When the relief valve 103 is opened, the fuel of the common rail 23 at the abnormally high pressure is returned from the relief passage 101 to the pressurizing chamber 11.
Thereby, high pressure part piping, such as common rail 23, is protected.

  The configuration and operation of the high pressure fuel supply pump will be described in more detail with reference to FIGS. 1 to 3 in addition to FIG. 4 described above. FIG. 1 is an overall sectional view showing a high-pressure fuel supply pump according to a first embodiment of the present invention, cut in the axial direction of a plunger. FIG. 2 is a general cross-sectional view of another angle of the high-pressure fuel supply pump according to the first embodiment of the present invention, which is a cross-sectional view at the suction joint axial center. FIG. 3 is an overall sectional view showing the high pressure fuel supply pump of the first embodiment according to the present invention by cutting in a direction perpendicular to the axial direction of the plunger, in the fuel inlet axis center and the discharge port axis center FIG.

  In general, the high pressure pump is fixed in close contact with the plane of the cylinder head 41 of the internal combustion engine using a flange 1e (see FIG. 3) provided on the pump body 1A. An O-ring 61 is fitted into the pump body 1A in order to keep the cylinder head 41 and the pump body 1A airtight.

  A cylinder 6 is attached to the pump body 1A to guide the forward and backward movement of the plunger 2 and to form a pressure chamber 11 therein. Further, the pressure chamber 11 is communicated with the electromagnetic suction valve 30 for supplying fuel and the discharge valve mechanism 8 (see FIG. 3) for discharging the fuel from the pressure chamber 11 to the discharge passage. A passage 11a (see FIG. 3) is provided.

  At the lower end of the plunger 2 is provided a tappet 3 which converts the rotational movement of the cam 5 attached to the camshaft of the internal combustion engine into vertical movement and transmits it to the plunger 2. The plunger 2 is crimped to the tappet 3 by a spring 4 through a retainer 15. As a result, the plunger 2 can be moved up and down (reciprocated) up and down with the rotational movement of the cam 5.

  Further, the plunger seal 13 (see FIG. 1) held at the lower end portion of the inner periphery of the seal holder 7 is installed in the state of slidably contacting the outer periphery of the plunger 2 at the lower end portion in the drawing of the cylinder 6 . As a result, the blowby gap between the plunger 2 and the cylinder 6 is sealed to prevent the fuel from leaking to the outside of the pump. At the same time, lubricating oil (including engine oil) for lubricating the sliding portion in the internal combustion engine is prevented from flowing into the inside of the pump body 1 through the blow-by gap.

  The fuel pumped up by the feed pump 21 (see FIG. 4) is sent to the pump main body 1A via the suction joint 10a connected to the suction pipe. The damper cover 14 forms the low pressure fuel chambers 10b and 10c by being coupled to the pump body 1A, and the fuel having passed through the suction joint 10a flows in. A fuel filter 120 is attached upstream of the low pressure fuel chambers 10b and 10c, for example, by press-fitting the pump body 1A in order to remove foreign substances such as metal powder contained in the fuel. The suction joint 10a and the low pressure fuel chambers 10b and 10c constitute a low pressure fuel passage 10 through which low pressure fuel flows.

  A pressure pulsation reducing mechanism 9 is installed in the low pressure fuel chambers 10b and 10c to reduce the pressure pulsation generated in the high pressure pump 1 from spreading to the fuel piping 28. When the fuel once sucked into the pressure chamber 11 is returned to the suction passage 10b (suction port 30a) again through the open valve body 301 for volume control, it is returned to the suction passage 10b (suction port 30a) Pressure pulsation is generated in the low pressure fuel chambers 10b and 10c by the fuel thus generated. However, this pressure pulsation is absorbed and reduced by the pressure pulsation reducing mechanism 9.

  The pressure pulsation reducing mechanism 9 is formed of a metal damper 9a in which two corrugated disc-like metal plates are laminated on the outer periphery thereof and an inert gas such as argon is injected therein. The pressure pulsation is absorbed and reduced by the expansion and contraction of the metal damper 9a. 9b is a mounting bracket for fixing the metal damper 9a to the inner peripheral portion of the pump body 1A.

  The electromagnetic coil 308 of the electromagnetic suction valve 30 is connected to the ECU 27 via a terminal 307. By repeating the energization and non-energization of the electromagnetic coil 308, the opening and closing of the suction valve body 301 is controlled. The electromagnetic suction valve 30 is a variable control mechanism that controls the flow rate of fuel by opening and closing the suction valve body 301. When the electromagnetic coil 308 is not energized, the urging force of the anchor spring 303 is transmitted to the suction valve body 301 via the anchor 305 and the anchor rod 302 formed integrally with the anchor 305.

  A valve spring 304 is provided to face the biasing force of the anchor spring 303. The valve spring 304 is installed inside the suction valve body 301. The biasing force of the anchor spring 303 and the biasing force of the valve spring 304 are set as described above. As a result, the suction valve body 301 is biased in the valve opening direction, and the suction port 30 d is in an open state. At this time, the anchor rod 302 and the suction valve body 301 are in contact at a portion shown by 302b (state shown in FIG. 1).

The magnetic biasing force generated by energization of the electromagnetic coil 308 is set such that the anchor 305 overcomes the biasing force of the anchor spring 303 on the stator 306 side and has a suctionable force.
When the electromagnetic coil 308 is energized, the anchor 305 moves to the side of the stator 306 (left side in the drawing), and the stopper 302a formed at the end of the anchor rod 302 abuts on the anchor rod bearing 309 and is locked. The amount of movement of the anchor 305 and the amount of movement of the suction valve body 301 are as follows:
The clearance is set such that the amount of movement of the anchor 301> the amount of movement of the suction valve body 301. Therefore, when the stopper 302a is in contact with the anchor rod bearing 309, the contact portion 302b between the anchor rod 302 and the suction valve body 301 is opened. As a result, the suction valve body 301 is biased to a closed state by the valve spring 304, and the suction port 30d is closed.

  The electromagnetic suction valve 30 is provided with a suction valve seat member 310 so that the suction valve body 301 can close the suction port 30 d to the pressurizing chamber 11. A suction valve seat 310 a is formed on the suction valve seat member 310. The suction valve seat member 310 is inserted into the cylindrical boss portion 1b while keeping the air tight and is fixed to the pump main body 1A. When the electromagnetic suction valve 30 is attached to the pump body 1A, the suction port 30a and the suction passage 10b are connected.

  The discharge valve mechanism 8 has a discharge valve seat surface 8a provided in the pump body 1, a discharge valve member 8b provided with a bearing 8e so as to be capable of holding a reciprocating slide at the center, and a bearing of the discharge valve member 8b. It has a discharge valve guide member 8d provided with a slidable central shaft 8f.

  The discharge valve member 8b is in contact with the discharge valve seat surface 8a to form an annular contact surface 8f which can be oil-tightly maintained.

  The discharge valve spring 8c is provided to bias the discharge valve member 8b in the valve closing direction.

  With such a configuration, the inclination of the discharge valve member 8b can be suppressed, and the discharge valve member 8b can be axially slidably supported, so that the discharge valve member 8b can be reliably seat portion It is possible to abut on (the discharge valve seat surface 8a).

  The discharge valve mechanism 8 is configured by sealing the discharge valve guide member 8d to the pump main body 1 by press fitting, for example. The discharge valve mechanism 8 acts as a check valve that restricts the fuel flow direction.

  Next, the configuration and operation of the relief valve mechanism 100 will be described in detail.

  The relief valve mechanism 100 is accommodated in an accommodation hole (accommodation recess) 1C formed in the pump body 1A. The accommodation hole 1C is in communication with the pressure chamber 11 through the communication hole 11b. That is, the relief passage (return passage) 101 is in communication with the pressurizing chamber 11 via the relief valve mechanism 100 through the communication hole 11 b.

  The relief valve mechanism 100 includes a relief valve housing 105 integrated with the relief valve seat 104, a relief valve 103, a relief valve presser 107, a relief spring 102, and a relief spring adjuster 106. The relief valve mechanism 100 is assembled outside the pump housing 1 as a subassembly.

  First, the relief valve 103, the relief valve presser 107, and the relief spring 102 are sequentially inserted into the relief valve housing 105 in order, and the relief spring adjuster 106 is press-fitted and fixed to the relief valve housing 105. The set position of the relief spring 102 is determined by the fixing position of the relief spring adjuster 106. The valve opening pressure of the relief valve 103 is determined by the set load of the relief spring 102.

The details of the relief valve mechanism 100 will be described with reference to FIG. The relief valve presser 107 (relief valve holder) is biased from the downstream side to the upstream side of the relief valve 103 by the relief spring 102, and holds the relief valve 103. The relief valve housing 105 is disposed on the outer peripheral side of the relief valve presser 107 (relief valve holder), and is a relief valve 103 than the first inner circumferential portion 15 a and the first inner circumferential portion 15 a formed on the relief valve seat 104 side. And a second inner circumferential portion 15b having a larger cross-sectional area than the first inner circumferential portion 15a. When the relief valve 103 is closed, a setting gap 20 a is formed between the first inner circumferential portion 15 a of the relief valve housing 105 and the throttle forming portion 17 a of the relief valve presser 107. A stroke in which the relief valve presser 107 can open the valve without changing the set gap 20a is defined as an initial stroke (St1). Furthermore, the stroke in which the relief valve presser 107 moves beyond the initial stroke is defined as a secondary stroke (St2). In the secondary stroke (St2), a gap 20b is formed between the second inner peripheral portion 15b of the relief valve housing 105 and the flow passage forming portion 17b on the relief valve sheet 104 side of the throttle forming portion 17a. Ru.
The relationship between the set gap 20a and the gap 20b is
It is set so that the setting gap 20a <the gap 20b.

That is, the relief valve presser 107 (relief valve holder) is formed at a position facing the first inner circumferential portion 15a when the relief valve 103 is closed and the second inner circumferential portion 15b when the relief valve 103 is opened. And the flow path formation part 17b which moves to the position which opposes.
Further, as described above, the gap 20b between the flow passage forming portion 17b of the relief valve presser 107 (relief valve holder) and the second inner circumferential portion 15b is configured to be larger than the set gap 20a.

In other words, when the relief valve 103 is in the closed state, it is set between the relief valve presser 107 (relief valve holder) and the relief valve housing 105 disposed on the outer peripheral side of the relief valve presser 107 (relief valve holder). The gap 20a is formed as the largest flow path.
When the relief valve 103 is in the open state, a flow passage of a gap 20 b larger than the set gap 20 a is formed between the relief valve presser 107 (relief valve holder) and the relief valve housing 105 as a maximum flow passage.

  With such a configuration, the throttling effect by the set gap 20a can be obtained in the initial stroke (St1). The differential pressure between the upstream side and the downstream side of the relief valve presser 107 generated by the throttling effect is high on the upstream side of the relief valve presser 107 and low on the downstream side. It occurs. As a result, the relief valve presser 107 can be greatly stroked in the valve opening direction. That is, the gap between the relief valve housing 105 and the relief valve presser 107 is enlarged with the stroke of the relief valve presser 107. When the gap widens, the squeeze effect is reduced, and the force generated in the valve opening direction of the relief valve retainer 107 is reduced. That is, by adjusting the initial stroke having the squeeze effect and the secondary stroke having the weak squeeze effect, the stroke of the relief valve presser 107 can be regulated without providing an adjuster.

  On the other hand, in the secondary stroke (St2), since the gap 20b is enlarged, the reduction of the throttling effect is reduced. The pressure difference between the upstream side and the downstream side of the relief valve presser 107 generated by the throttling effect is reduced, so the force of the relief valve presser 107 in the valve opening direction is reduced and the relief valve presser 107 in the valve opening direction. The stroke can be suppressed.

As shown in FIGS. 5 to 6, in the outer cylindrical surface 17c of the relief valve presser 107, a plurality of (for example, three) notch portions 17d are formed so as to form the throttle forming portion 17a and the flow path forming portion 17b. It is provided. Of the outer cylindrical surface 17c, in the surface where the notch portion 17d is not provided, the length is set so as to always slide even in the secondary stroke (St2).
That is, the throttle forming portion 17a of the relief valve presser 107 (relief valve holder) is formed at a position facing the first inner circumferential portion 15a even when the relief valve 103 is open, and between the first inner circumferential portion 15a The set gap 20a is formed. As a result, it is possible to prevent an erroneous operation in which the relief valve presser 107 comes off from the first inner circumferential portion 15a during the secondary stroke (St2) and the relief valve presser 107 is not accommodated again in the first inner circumferential portion 15a.

  The second inner circumferential portion 15b of the relief valve housing 105 and the flow path forming portion 17b of the relief valve retainer 107 are both inclined. Further, the relief valve presser 107 (relief valve holder) is a sloped portion (a flow path is formed to be inclined toward the inner peripheral side from the cylindrical portion (the throttle forming portion 17a) and the cylindrical portion (the throttle forming portion 17a) toward the relief valve seat 104 Part 17b). The cylindrical portion forms the throttle forming portion 17a, and the inclined portion forms the above-described flow path forming portion 17b. When the relief valve 103 is closed, the relief valve press 107 functions as a guide when being accommodated again in the first inner circumferential portion 15a, and the collision resistance and wear resistance of the relief valve press 107 can be secured.

  As shown in FIG. 5, the inner peripheral portion of the relief valve housing 105 is formed with a recessed portion (second inner peripheral portion 15b) which is recessed from the first inner peripheral portion 15a to the outer peripheral side, and the relief valve 103 opens. When the presser 107 (relief valve holder) moves in the opening direction and valve opening direction, the upstream side and the recessed portion (second inner circumferential portion 15b) from the upstream outer peripheral end 17e of the relief valve presser 107 (relief valve holder) Communicate to form the flow path.

FIG. 7 shows an external view of the relief valve presser 107. A notch 17 d is formed in the third inner circumferential portion 17 c of the relief valve retainer 107. Relief valve retainer 107 by notch 17 d
A plurality of inclined portions (flow path forming portions 17b) are formed on the outer peripheral side of the (relief valve holder). It is desirable in terms of production that there are three inclined portions (flow path forming portions 17b). Then, similarly, three aperture forming portions 17a are formed between two adjacent inclined portions (the second inner circumferential portion 15b). In other words, a plurality of flow path forming portions 17b are formed in the relief valve presser 107 (relief valve holder), and the throttle forming portion 17a is formed between two adjacent flow path forming portions 17b.

  Further, when the relief valve presser 107 (relief valve holder) is viewed from the axial direction of the relief valve 103, the outer periphery of the throttle forming portion 17a is formed larger than the outer periphery of the flow passage forming portion 17b. The throttle forming portion 17 a is formed in a predetermined region of the relief valve presser 107 (relief valve holder) in the axial direction of the relief valve 103. The flow passage forming portion 17 b is formed in an area smaller than the above-described predetermined area of the relief valve presser 107 (relief valve holder) in the axial direction of the relief valve 103.

  The flow passage forming portion 17b of the relief valve holder 107 is formed by an inclined portion which is inclined toward the inner peripheral side from the throttle forming portion 17a which forms the set gap 20a with the first inner peripheral portion 15a. A boundary between the throttle forming portion 17a and the flow path forming portion 17b is disposed at a position overlapping the first inner circumferential portion 15a in the valve closed state of the relief valve 103, and disposed on the inner circumferential side of the first inner circumferential portion 15a Be done.

  As shown in FIG. 7, the relief valve holder 107 is formed with a convex portion which is convex on the downstream side in the relief flow path, and the relief spring 102 is wound and held on the outer peripheral side of the convex portion. The outer cylindrical surface 17c on the upstream side with respect to the convex portion is guided to face the first inner circumferential portion 15a. Although the axial length of the convex portion is set to be slightly larger than that of the outer cylindrical surface 17c, it may not be necessarily configured as such depending on the length of the spring back winding. The relief spring 102 is wound and supported by the relief spring stopper 106. The number of turns of the relief spring 102 at this time is set so as to be more than one turn. The natural frequency of the relief spring 102 can be adjusted by setting the number of turns, and damage due to surging can be prevented. In addition, when the number of turns of the spring is large, the seating of the spring is stabilized, so the lateral force acting on the relief valve press 107 is reduced, and the friction between the outer cylindrical surface 17c and the first inner circumferential portion 15a of the relief valve housing 105. Since the force can be reduced, the wear resistance of the relief valve presser 107 can be secured.

  The relief valve mechanism 100 thus formed into a unit is fixed by press-fitting the relief valve housing 105 into the inner peripheral wall of the accommodation hole (cylindrical through hole) 1C provided in the pump main body 1A. Then, the discharge joint 12a forming the fuel discharge port 12 is fixed so as to close the accommodation hole 1C of the pump main body 1, and fuel can be prevented from leaking from the high pressure pump 1 to the outside, and at the same time connection with the common rail 23 is possible. Do.

The accommodation hole 1C and the accommodation hole 1D are connected by the discharge passage 110 as shown in FIG.
Thus, the discharge passage 110 is in communication with the fuel discharge port 12 through the accommodation hole 1C.

  When the volume of the pressure chamber 11 starts to decrease due to the movement of the plunger 2, the pressure in the pressure chamber 11 increases with the decrease of the volume. When the pressure in the pressurizing chamber finally becomes higher than the pressure in the discharge flow passage 110, the discharge valve mechanism 8 opens, and the fuel is discharged from the pressure chamber 11 to the discharge flow passage 110. From the moment when the discharge valve mechanism 8 is opened to immediately after, the pressure in the pressure chamber 11 overshoots and becomes extremely high. This high pressure also propagates into the discharge flow channel 110, and the pressure in the discharge flow channel 110 also overshoots at the same timing.

  Here, if the outlet of the relief valve mechanism 100 is connected to the suction flow passage 10b, the pressure overshoot in the discharge flow passage 11 causes the pressure difference between the inlet and the outlet of the relief valve 103 to be a relief valve. It becomes larger than the valve opening pressure of the mechanism 100, and the relief valve 103 malfunctions.

  On the other hand, in the present embodiment, since the outlet of the relief valve mechanism 100 is connected to the pressurizing chamber 11, the pressure in the pressurizing chamber 11 acts on the outlet of the relief valve mechanism 100. The pressure in the discharge channel 110 acts on the inlet. Here, since the pressure overshoot occurs at the same timing in the pressurizing chamber 11 and the discharge flow path 110, the pressure difference between the inlet and the outlet of the relief valve 103 is equal to or higher than the opening pressure of the relief valve 103. Never be That is, the relief valve 103 does not malfunction.

  When the volume of the pressure chamber 11 starts to increase due to the movement of the plunger 2, the pressure in the pressure chamber 11 decreases as the volume increases, and becomes lower than the pressure in the suction passage 10b (the suction port 30a). In this state, the fuel flows into the pressurizing chamber 11 from the suction passage 10b (the suction port 30a). When the volume of the pressure chamber 11 starts to decrease again due to the movement of the plunger 2, the fuel is pressurized to a high pressure and discharged by the above mechanism.

Next, the case where an abnormal high voltage occurs in the common rail 23 or the like due to a failure or the like of the direct injector 24 will be described in detail.
If the direct injection injector fails, that is, if the injection function is stopped and the fuel sent to the common rail 23 can not be supplied into the combustion chamber of the internal combustion engine, the fuel accumulates between the discharge valve mechanism 8 and the common rail 23 Becomes an abnormally high pressure. In this case, if the pressure rises gradually, an abnormality is detected by the pressure sensor 26 provided on the common rail 23, and feedback control is performed on the electromagnetic suction valve 30, which is a capacity control mechanism provided on the suction passage 10b (suction port 30a). Safety function to reduce the discharge amount is activated. However, instantaneous abnormal high pressure can not be dealt with by feedback control using this pressure sensor 26.

  In addition, when the electromagnetic suction valve 30 breaks down and does not function as it is at the maximum capacity state, the discharge pressure becomes abnormally high in an operating state where a large amount of fuel is not required. In this case, even if the pressure sensor 26 of the common rail 23 detects an abnormal high pressure, the abnormal capacity can not be eliminated because the displacement control mechanism itself is broken.

  When such an abnormal high pressure occurs, the relief valve mechanism 100 of this embodiment functions as a safety valve.

  When the volume of the pressure chamber 11 starts to increase due to the movement of the plunger 2, the pressure in the pressure chamber 11 decreases as the volume increases. At this time, when the pressure at the inlet of the relief valve mechanism 100, that is, the discharge flow path 110 becomes higher than the pressure at the outlet of the relief valve 103, that is, the pressure chamber 11, the relief valve mechanism 100 Opens. Due to the opening of the relief valve mechanism 100, the fuel which has an abnormally high pressure in the common rail 23 is returned to the inside of the pressurizing chamber 11. As a result, even when an abnormal high pressure occurs, the high pressure piping system such as the common rail 23 does not exceed the specified pressure, and the high pressure piping system such as the common rail 23 is protected.

The second embodiment of the present invention will be described below. The description of the same contents as those of the first embodiment will be omitted.
As shown in FIG. 8, in the first embodiment, the relief valve housing 105 has a third inner circumferential portion 15 c having a smaller cross-sectional area than the second inner circumferential portion 15 b. The relief spring stopper 106 is press-fit into the inner peripheral portion of the third inner peripheral portion 15 c. That is, the relief valve housing 105 has the third inner circumferential portion 15 c formed on the downstream side of the relief valve 103 than the second inner circumferential portion 15 b. And the cross-sectional area of the 3rd inner peripheral part 15c is comprised so that it may become smaller than the largest cross-sectional area of the 2nd inner peripheral part 15b. Further, the relief valve housing 105 is press-fit and fixed in a horizontal direction in a hole formed in the pump body 11 forming the pressurizing chamber 11 on the outer peripheral side of the third inner circumferential portion 15 c.

Specifically, the relief valve housing 105 has a third inner circumferential portion 15c which is formed closer to the pressurizing chamber 11 or the suction passage (10a, 10b) than the second inner circumferential portion 15b. The third inner circumferential portion 15c is formed so that the cross-sectional area is smaller than the maximum cross-sectional area of the second inner circumferential portion 15b.
The relief valve unit 100 is configured by integrating the relief valve 103, the relief valve holder 107, the relief spring 102, and the relief valve housing 105. In the relief valve unit 100, the outer peripheral side of the third inner peripheral portion 15c is press-fitted and fixed to the hole portion of the pump body forming the pressurizing chamber 11. By doing this, since the press-fit portion thickness of the relief valve housing 105 can be secured, the pressure input of the relief spring stopper 106 can be increased.
The high-pressure fuel supply pump according to claim 1, wherein the flow passage forming portion of the relief valve holder is an inclined portion which is inclined toward the inner peripheral side from a throttle forming portion which forms a setting gap with the first inner peripheral portion.

The third embodiment will be described below with reference to FIGS. The description of the same contents as in the first and second embodiments will be omitted.
By providing the counterbore hole 15d in the relief valve housing 105, the inner cylindrical surface 15e of the relief valve housing 105 can always guide the throttle forming portion 17a of the relief valve retainer 107 even in the secondary stroke (St2). Become. Although four countersunk holes 15d are provided as an example in FIG. 9, one or more countersunk holes may be provided theoretically.
Also, as for the shape of the counterbore hole, a square shape or the like may be used instead of a round hole.

As shown in FIG. 11, in the initial stroke (St1), a setting gap 20a is formed between the first inner peripheral portion 15a of the relief valve housing 105 and the throttle forming portion 17a of the relief valve presser 107, and the secondary stroke In (St2), a gap 20b is formed between the second inner circumferential portion 15b of the relief valve housing 105 and the inner cylindrical surface 15f of the back facing hole 15d.
By setting the setting gap 20a and the gap 20b in the same manner as in the first embodiment, the notch 17d of the relief valve retainer 107 may not be provided. With such a structure, the notch portion of the relief valve retainer 107 does not need to be machined 17 d, so that the manufacturing cost can be reduced.

  In the configuration of the present embodiment, since the setting gap 20a is instantaneously switched to the gap 20b, the clearance effect is reduced at the moment when the relief valve pressing member 107 reaches the secondary stroke. The stroke of 107 can be reduced.

  According to the above-described invention, the valve body presser can be made to make a large stroke without providing an adjuster that regulates the stroke of the valve body presser.

The present invention is not limited to the embodiments described above, but includes various modifications.
For example, the embodiments described above are described in detail in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the configurations. Further, with respect to a part of the configuration of the embodiment, it is possible to add, delete or replace the configuration of the other embodiment.

  1A: pump body, 2: plunger, 6: cylinder, 6c, 6c ': annular projection, 6d: annular recess (annular groove), 8: discharge valve mechanism, 9: pressure pulsation reduction mechanism, 30: electromagnetic suction valve, 100 ... relief valve mechanism.

Claims (16)

A discharge passage for discharging the fuel pressurized by the pressure chamber;
A relief passage connecting the discharge passage and the pressurizing chamber or a suction passage of the pressurizing chamber;
A relief valve for opening and closing a relief sheet of the relief passage;
A relief valve holder for holding the relief valve;
A relief spring for biasing the relief valve holder from the downstream side to the upstream side of the relief valve;
The relief valve holder is disposed on the outer circumferential side, and is formed on the downstream side of the relief valve with respect to the first inner circumferential portion formed on the side of the relief sheet and the first inner circumferential portion. A housing having a second inner periphery with a large cross-sectional area,
The relief valve holder is formed at a throttle forming portion forming a set gap with the first inner circumferential portion, and at a position facing the first inner circumferential portion in the valve closing state of the relief valve. A flow passage forming portion moving to a position facing the second inner circumferential portion in the valve opening state of the relief valve;
The high pressure fuel supply pump, wherein a gap between the flow passage forming portion and the second inner circumferential portion is larger than the set gap. In the high pressure fuel supply pump according to claim 1,
The throttling portion of the relief valve holder is formed at a position facing the first inner circumferential portion even in the valve opening state of the relief valve, and the high pressure fuel forming the set gap with the first inner circumferential portion Supply pump. In the high pressure fuel supply pump according to claim 1,
The relief valve holder has a cylindrical portion and an inclined portion which inclines toward the inner peripheral side from the cylindrical portion toward the side of the relief sheet, and the cylindrical portion forms the throttle forming portion, and the inclined portion A high pressure fuel supply pump in which a flow passage forming portion is formed. In the high pressure fuel supply pump according to claim 3,
The high pressure fuel supply pump, wherein the relief valve holder is formed with a plurality of the inclined portions, and the throttling formation portion is formed between two adjacent inclined portions. In the high pressure fuel supply pump according to claim 1,
The high pressure fuel supply pump, wherein a plurality of the flow passage forming portions are formed in the relief valve holder, and the throttling formation portion is formed between two adjacent flow passage forming portions. In the high pressure fuel supply pump according to claim 1,
The high pressure fuel supply pump, wherein the relief valve holder is viewed from the axial direction of the relief valve, and the outer periphery of the throttle forming portion is larger than the outer periphery of the flow passage forming portion. In the high pressure fuel supply pump according to claim 1,
The throttle forming portion is formed in a predetermined region of the relief valve holder in the axial direction of the relief valve, and the flow passage forming portion is formed in a region smaller than the predetermined region of the relief valve holder in the axial direction of the relief valve High pressure fuel supply pump. In the high pressure fuel supply pump according to claim 1,
The high pressure fuel supply pump according to claim 1, wherein the housing is formed on the downstream side of the relief valve with respect to the second inner peripheral portion and has a third inner peripheral portion smaller in sectional area than the second inner peripheral portion. In the high pressure fuel supply pump according to claim 8,
The high pressure fuel supply pump in which the housing is press-fitted and fixed to a pump body in which an outer peripheral side of the third inner peripheral portion forms the pressurizing chamber. In the high pressure fuel supply pump according to claim 8,
The housing has a third inner circumferential portion formed closer to the pressure chamber than the second inner circumferential portion and having a smaller cross-sectional area than the second inner circumferential portion.
The relief valve unit is configured by integrating the relief valve, the relief valve holder, the relief spring, and the housing.
The relief valve unit is a high pressure fuel supply pump in which an outer peripheral side of the third inner peripheral portion is press-fitted and fixed to a pump body forming the pressurizing chamber. In the high pressure fuel supply pump according to claim 1,
The high-pressure fuel supply pump according to claim 1, wherein the flow passage forming portion of the relief valve holder is an inclined portion which is inclined toward the inner peripheral side from a throttle forming portion which forms a setting gap with the first inner peripheral portion. In the high pressure fuel supply pump according to claim 1,
The flow passage forming portion of the relief valve holder is constituted by an inclined portion which is inclined toward the inner peripheral side from the throttle forming portion which forms a setting gap with the first inner peripheral portion, and the throttle forming portion The high-pressure fuel is disposed at a position where the boundary between the flow passage forming portion and the flow passage forming portion overlaps the first inner peripheral portion in the valve closed state of the relief valve, and is disposed on the inner peripheral side of the first inner peripheral portion. Supply pump. A discharge passage for discharging the fuel pressurized by the pressure chamber;
A relief passage connecting the discharge passage and the pressurizing chamber or a suction passage of the pressurizing chamber;
A relief valve for opening and closing a relief sheet of the relief passage;
A relief valve holder for holding the relief valve;
A relief spring for biasing the relief valve holder from the downstream side to the upstream side of the relief valve;
A setting gap is formed between the relief valve holder and the housing disposed on the outer peripheral side of the relief valve holder when the relief valve is closed, and when the relief valve is opened, the relief valve holder and the housing A high pressure fuel supply pump in which a flow passage having a gap larger than the set gap is formed between the two. In the high pressure fuel supply pump according to claim 13,
The housing is formed with a recessed portion which is recessed toward the outer peripheral side, and the relief valve is opened and the relief valve holder moves to the set opening degree and the valve opening direction, and is upstream from the upstream outer peripheral end of the relief valve holder The high pressure fuel supply pump in which the said side and the said recessed part connected and the said flow path was formed. In the high pressure fuel supply pump according to claim 14,
The said recessed part is the high pressure fuel supply pump formed in multiple numbers by the outer peripheral side of the said housing. In the high pressure fuel supply pump according to claim 1 or 13,
A high pressure fuel supply pump comprising a relief spring stopper which supports the relief spring by being wound by the relief spring, and the relief spring is wound more than one turn with respect to the relief spring stopper.

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