JP2018128007A - High pressure pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a high pressure pump capable of suppressing vibration of an electromagnetic drive unit with respect to a housing. SOLUTION: An electromagnetic drive unit 60 is provided on the other end side of a needle 55, and has a coil 63 formed in a tubular shape and having a shaft along the axis of the needle 55, and a coil 63 formed of a magnetic material. It has a yoke 64 provided to cover the coil 63, and when the coil 63 is energized, the needle 55 is driven in the valve closing direction of the suction valve 52, and the suction valve 52 can be closed. The tubular member 40 is formed in a cylindrical shape by a magnetic material, has an outer diameter smaller than the outer diameter of the yoke 64, and is provided on the radial outer side of the needle 55 so that the shaft is along the axis of the needle 55. It is connected to 60. The vibration damping member 80 is provided between the housing 20 and the electromagnetic drive unit 60 on the radial side of the tubular member 40, and can suppress the vibration of the electromagnetic drive unit 60 with respect to the housing 20. [Selection diagram] Fig. 1

Description

  The present invention relates to a high-pressure pump that pressurizes and discharges fuel.

  Conventionally, a high pressure pump that pressurizes fuel and supplies the pressurized fuel to an internal combustion engine is known. For example, Patent Document 1 discloses a high-pressure pump including a suction valve for adjusting the amount of fuel sucked into a pressurizing chamber and an electromagnetic drive unit for controlling opening and closing of the suction valve. .

JP2015-148231A

  In the high-pressure pump of Patent Document 1, the electromagnetic drive unit is provided at the end of a cylindrical member that protrudes in a cylindrical shape from a housing having a pressurizing chamber. The electromagnetic drive unit generates an electromagnetic force when opening and closing the suction valve, and reciprocally moves the needle contacting the suction valve in the axial direction. The high-pressure pump includes a plunger that reciprocates in the axial direction and pressurizes the fuel in the pressurizing chamber. Therefore, when the high-pressure pump is operated, the electromagnetic drive unit becomes a mass at the end of the cylindrical member, and there is a possibility that the electromagnetic drive unit vibrates relative to the housing. This may cause noise from the high-pressure pump due to vibration.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a high-pressure pump that can suppress vibration of an electromagnetic drive unit with respect to a housing.

The high-pressure pump (10) according to the present invention includes a housing (20), a plunger (11), a suction valve (52), a needle (55), an electromagnetic drive unit (60), a cylindrical member (40), and a damping member (80, 87).
The housing has a fuel chamber (300) and a pressurizing chamber (200) communicating with the fuel chamber.
The plunger is provided so as to be capable of reciprocating in the axial direction, and can pressurize the fuel in the pressurizing chamber.
The intake valve allows the flow of fuel between the fuel chamber and the pressurization chamber when the valve is opened, and can block the flow of fuel between the fuel chamber and the pressurization chamber when the valve is closed.
One end of the needle is located inside the housing, the other end is located outside the housing, and one end is provided so as to be able to contact or connect to the suction valve.

The electromagnetic drive unit is provided on the other end side of the needle. The electromagnetic drive unit is formed into a cylindrical shape by winding a conducting wire (631), and a coil (63) provided so that the axis is along the axis of the needle, and a yoke (which is formed of a magnetic material and covers the coil) 64, 641, 642), and when the coil is energized, the needle can be driven in the valve closing direction or valve opening direction to close or open the valve.
The cylindrical member is formed in a cylindrical shape from a magnetic material, has an outer diameter smaller than the outer diameter of the yoke, and is provided on the radially outer side of the needle so that the shaft is along the axis of the needle, and connects the housing and the electromagnetic drive unit. Yes.
The damping member is provided on the radially outer side of the cylindrical member between the housing and the electromagnetic drive unit, and can suppress vibration of the electromagnetic drive unit with respect to the housing.

  In the present invention, the vibration of the electromagnetic drive unit relative to the housing, such as when the high-pressure pump is operated, can be suppressed by the damping member provided on the radially outer side of the cylindrical member between the housing and the electromagnetic drive unit. Thereby, noise generated from the high-pressure pump due to vibration can be suppressed.

Sectional drawing which shows the high pressure pump by 1st Embodiment. The perspective view which shows the cover, yoke, and damping member of the high pressure pump by 1st Embodiment. The schematic diagram which shows the cross section in the cylinder member and damping member of the high pressure pump by 1st Embodiment. The figure which looked at FIG. 3 from the arrow IV direction. The graph which shows the relationship between the level and the frequency of the noise which generate | occur | produce from the high pressure pump by 1st Embodiment, and a comparative example. The top view which shows the damping member of the high pressure pump by 2nd Embodiment, and its vicinity. The top view which shows the damping member of the high pressure pump by 3rd Embodiment, and its vicinity. The top view which shows the damping member of the high pressure pump by 4th Embodiment, and its vicinity. The top view which shows the damping member of the high pressure pump by 5th Embodiment, and its vicinity. The top view which shows the damping member of the high pressure pump by 6th Embodiment, and its vicinity. The schematic diagram which shows the cross section in the cylinder member and damping member of the high pressure pump by 7th Embodiment. The schematic diagram which shows the cross section in the cylinder member and damping member of the high pressure pump by 8th Embodiment. The figure which looked at FIG. 12 from the arrow XIII direction. The schematic diagram which shows the cross section in the cylinder member and damping member of the high-pressure pump by 9th Embodiment. The top view which shows the damping member of the high pressure pump by 10th Embodiment, and its vicinity. The top view which shows the damping member of the high pressure pump by 11th Embodiment, and its vicinity. The schematic diagram which shows the cross section in the cylinder member and damping member of the high pressure pump by 12th Embodiment. The figure which looked at FIG. 17 from the arrow XVIII direction. The schematic diagram which shows the cross section in the cylinder member and damping member of the high pressure pump by 13th Embodiment. The figure which looked at FIG. 19 from the arrow XX direction. The schematic diagram which shows the cross section in the cylinder member and damping member of the high pressure pump by 14th Embodiment. The figure which looked at FIG. 21 from the arrow XXII direction. A sectional view showing a high-pressure pump by a 15th embodiment.

Hereinafter, high-pressure pumps according to a plurality of embodiments will be described with reference to the drawings. Note that, in a plurality of embodiments, substantially the same components are denoted by the same reference numerals, and description thereof is omitted. In the plurality of embodiments, substantially the same constituent parts have the same or similar operational effects.
(First embodiment)
A high-pressure pump according to the first embodiment is shown in FIG.
The high-pressure pump 10 of the present embodiment is attached to an engine head 18 of an internal combustion engine (hereinafter referred to as “engine”) 9 of a vehicle (not shown).

  Gasoline as fuel is stored in a fuel tank mounted on the vehicle. A fuel pump (not shown) pumps up and discharges fuel in the fuel tank. The supply fuel pipe 101 connects the fuel pump and the high-pressure pump 10. As a result, the fuel pumped and discharged by the fuel pump flows into the high-pressure pump 10 via the supply fuel pipe 101.

  The engine 9 is provided with a high-pressure pump 10 and a fuel rail. The engine 9 is, for example, a 4-cylinder gasoline engine. The fuel rail is provided in the engine head 18 of the engine 9. A fuel injection valve (not shown) is provided so that the nozzle hole is exposed in the combustion chamber of the engine 9. Four fuel injection valves are provided in accordance with the number of cylinders of the engine 9. Four fuel injection valves are connected to the fuel rail.

The high pressure pump 10 and the fuel rail are connected by a high pressure fuel pipe 102. The fuel flowing into the high-pressure pump 10 from the supply fuel pipe 101 is pressurized by the high-pressure pump 10 and supplied to the fuel rail via the high-pressure fuel pipe 102. Thereby, the fuel in the fuel rail is kept at a relatively high pressure. The fuel injection valve opens and closes according to a command from an ECU (not shown) and injects fuel in the fuel rail into the combustion chamber of the engine 9. Thus, the fuel injection valve is a so-called direct injection (DI) fuel injection valve.
As shown in FIG. 1, the high-pressure pump 10 includes a housing 20, a plunger 11, a suction valve unit 50, a cylindrical member 40, an electromagnetic drive unit 60, a discharge unit 17, a vibration damping member 80, and the like.
The housing 20 includes an upper housing 21, a lower housing 22, a cylinder 23, a holder support 24, a cover 30, and the like.
The upper housing 21, the lower housing 22, the cylinder 23, and the holder support portion 24 are made of a metal such as stainless steel, for example.

  The upper housing 21 is formed in a substantially rectangular parallelepiped shape. The upper housing 21 has a hole 211, a suction hole 212, and a discharge hole 213. The hole 211 is formed so as to penetrate the center of the upper housing 21 in a cylindrical shape. The suction hole 212 is formed in a cylindrical shape so as to connect one end face in the longitudinal direction of the upper housing 21 and the hole 211. The discharge hole 213 is formed in a cylindrical shape so as to connect the other end face in the longitudinal direction of the upper housing 21 and the hole 211.

  The lower housing 22 is formed in a substantially plate shape. The lower housing 22 has a hole 221 and a hole 222. The hole 221 is formed so as to penetrate the center of the lower housing 22 in a cylindrical shape in the plate thickness direction. The lower housing 22 is provided in contact with the upper housing 21 so that the hole 221 is coaxial with the hole 211 of the upper housing 21. A plurality of holes 222 are formed around the hole 221 so as to penetrate the lower housing 22 in the plate thickness direction.

  The cylinder 23 has a cylinder hole 231. The cylinder hole 231 is formed in a cylindrical shape so as to extend from one end face of the columnar member to the other end face. That is, the cylinder 23 is formed in a bottomed cylindrical shape having a cylindrical portion and a bottom portion that closes one end of the cylindrical portion.

  The cylinder 23 passes through the hole 221 of the lower housing 22 and is provided integrally with the upper housing 21 and the lower housing 22 so that the outer wall on the bottom side is fitted into the hole 211 of the upper housing 21. The cylinder 23 has a suction opening 232 and a discharge opening 233. The suction opening 232 is formed so as to connect the end of the cylinder hole 231 on the bottom side and the suction hole 212 of the upper housing 21. The discharge opening 233 is formed to connect the end of the cylinder hole 231 on the bottom side and the discharge hole 213 of the upper housing 21. That is, the suction opening 232 and the discharge opening 233 are formed to face each other with the axis of the cylinder 23 interposed therebetween.

  The holder support portion 24 is formed so as to extend in a substantially cylindrical shape from the periphery of the hole portion 222 of the lower housing 22 to the side opposite to the upper housing 21. In the present embodiment, the holder support portion 24 is formed integrally with the lower housing 22. The holder support portion 24 is formed so as to be coaxial with the cylinder 23 on the radially outer side of one end of the cylinder 23.

  The plunger 11 is formed in a substantially cylindrical shape from a metal such as stainless steel. The plunger 11 has a large diameter part 111 and a small diameter part 112. The small diameter portion 112 has an outer diameter smaller than that of the large diameter portion 111. The plunger 11 is provided such that the large diameter portion 111 side is inserted into the cylinder hole portion 231 of the cylinder 23. A pressurizing chamber 200 is formed between the inner wall of the cylinder 23 of the cylinder hole 231 and the end of the plunger 11 on the large diameter portion 111 side. That is, the housing 20 has a pressurizing chamber 200. The pressurizing chamber 200 is connected to the suction opening 232 and the discharge opening 233. Here, the cylinder 23, the upper housing 21, and the lower housing 22 of the housing 20 correspond to the “pressurizing chamber forming portion” in the claims.

  The outer diameter of the plunger 11 is formed slightly smaller than the inner diameter of the cylinder 23, that is, the diameter of the cylinder hole 231. Therefore, the plunger 11 can reciprocate in the axial direction in the cylinder hole 231 while the outer wall slides with the inner wall of the cylinder 23. When the plunger 11 reciprocates in the cylinder hole 231, the volume of the pressurizing chamber 200 increases or decreases.

In the present embodiment, the seal holder 14 is provided inside the holder support portion 24. The seal holder 14 is formed in a cylindrical shape from a metal such as stainless steel. The seal holder 14 is provided such that the outer wall is fitted to the inner wall of the holder support portion 24. The seal holder 14 is provided so as to form a substantially cylindrical clearance between the inner wall and the outer wall of the small diameter portion 112 of the plunger 11. An annular seal 141 is provided between the inner wall of the seal holder 14 and the outer wall of the small diameter portion 112 of the plunger 11. The seal 141 is composed of a fluororesin ring on the inner diameter side and a rubber ring on the outer diameter side. The thickness of the fuel oil film around the small-diameter portion 112 of the plunger 11 is adjusted by the seal 141, and fuel leakage to the engine 9 is suppressed. An oil seal 142 is provided at the end of the seal holder 14 opposite to the cylinder 23. The oil seal 142 adjusts the thickness of the oil film around the small-diameter portion 112 of the plunger 11 and suppresses oil leakage.
A variable volume chamber 201 whose volume changes when the plunger 11 is reciprocated is formed between the step surface between the large diameter portion 111 and the small diameter portion 112 of the plunger 11 and the seal 141.

  Here, an annular space 202 that is an annular space is formed between the lower housing 22, the outer wall of the cylinder 23, the inner wall of the holder support portion 24, and the seal holder 14. The annular space 202 is connected to the hole 222 of the lower housing 22. The annular space 202 is connected to the variable volume chamber 201 via a cylindrical space between the inner wall of the seal holder 14 and the outer wall of the cylinder 23.

A substantially disc-shaped spring seat 12 is provided at an end of the plunger 11 opposite to the large diameter portion 111 of the small diameter portion 112. A spring 13 is provided between the seal holder 14 and the spring seat 12. The spring 13 is, for example, a coil spring, and is provided so that one end is in contact with the spring seat 12 and the other end is in contact with the seal holder 14. The spring 13 urges the plunger 11 to the side opposite to the pressurizing chamber 200 via the spring seat 12.
When the high pressure pump 10 is attached to the engine head 18 of the engine 9, the lifter 5 is attached to the end of the small diameter portion 112 of the plunger 11 opposite to the large diameter portion 111.

When the high-pressure pump 10 is attached to the engine 9, the lifter 5 contacts the cam 4 of the cam shaft that rotates in conjunction with the drive shaft of the engine 9. Thereby, when the engine 9 is rotating, the plunger 11 reciprocates in the axial direction by the rotation of the cam 4. At this time, the volumes of the pressurizing chamber 200 and the variable volume chamber 201 change periodically.
The cover 30 is made of a metal such as stainless steel. The cover 30 includes a cover cylinder portion 31, a cover bottom portion 32, and the like.

The cover cylinder part 31 is formed in a cylindrical shape. More specifically, the cover cylinder part 31 is formed in a substantially octagonal cylinder shape. The cover bottom portion 32 is formed integrally with the cover tube portion 31 so as to close one end of the cover tube portion 31. That is, the cover 30 is formed in a bottomed cylindrical shape. In the present embodiment, the cover 30 is formed, for example, by pressing a plate-like member. Therefore, the cover 30 has a relatively small thickness.
The cover 30 has cover openings 35 and 36.

  The cover openings 35 and 36 are each formed in a cylindrical shape so as to connect the inner wall and the outer wall of the cover tube portion 31. The cover opening 35 and the cover opening 36 are formed so as to face each other with the axis of the cover cylinder 31 interposed therebetween.

The cover 30 accommodates the upper housing 21 on the inner side, and an end portion of the cover cylinder portion 31 opposite to the cover bottom portion 32 is provided so as to contact the surface of the lower housing 22 on the upper housing 21 side. The cover 30 forms a fuel chamber 300 between the upper housing 21, the lower housing 22, and the cylinder 23. Here, the end part of the cover cylinder part 31 and the lower housing 22 are joined over the whole area in the circumferential direction by welding, for example. Thereby, the space between the cover tube portion 31 and the lower housing 22 is kept liquid-tight. The cover 30 is provided so that the cover opening 35 corresponds to the suction hole 212 of the upper housing 21 and the cover opening 36 corresponds to the discharge hole 213 of the upper housing 21.
As described above, the cover 30 covers at least a part of the cylinder 23, the upper housing 21 and the lower housing 22, and forms a fuel chamber 300 between the cylinder 23, the upper housing 21 and the lower housing 22.

  The cover 30 is provided with an inlet 8 (see FIG. 2). The inlet 8 is provided between the cover opening 35 and the cover opening 36 of the cover cylinder part 31. The inlet 8 is formed in a cylindrical shape, and is provided so that one end thereof is connected to the outer wall of the cover cylinder portion 31. The inlet 8 is provided so that the inner space communicates with the fuel chamber 300. A supply fuel pipe 101 is connected to the other end of the inlet 8. Thereby, the fuel discharged from the fuel pump flows into the fuel chamber 300 via the supply fuel pipe 101 and the inlet 8.

  The suction valve portion 50 is provided in the suction hole portion 212 of the upper housing 21. The suction valve portion 50 includes a valve seat portion 51, a suction valve 52, a valve stopper 53, a spring 54, a needle 55, a needle support portion 56, a spring 57, a movable core 58, and the like.

  The valve seat portion 51 is formed in a cylindrical shape from, for example, a metal such as stainless steel, and is provided so that the outer wall is fitted to the wall surface of the suction hole portion 212 of the upper housing 21. An annular suction valve seat 511 is formed outside the central hole on the surface of the valve seat 51 on the pressurizing chamber 200 side.

  The suction valve 52 is formed in a substantially disk shape from a metal such as stainless steel, and is provided on the pressure chamber 200 side with respect to the valve seat portion 51. The suction valve 52 is provided such that an outer edge portion of one end face thereof can come into contact with the suction valve seat 511. When the intake valve 52 is separated from the intake valve seat 511, the intake valve 52 opens to allow the fuel flow in the intake hole 212. On the other hand, when the suction valve 52 comes into contact with the suction valve seat 511, the suction valve 52 is closed and the flow of fuel in the suction hole 212 can be shut off. Hereinafter, the direction of movement when the intake valve 52 is opened is referred to as “valve opening direction”, and the direction of movement when the intake valve 52 is closed is referred to as “valve closing direction”.

The valve stopper 53 is formed, for example, in a substantially disc shape from a metal such as stainless steel, and the outer edge portion is provided so as to fit into the wall surface of the suction hole portion 212 of the upper housing 21. The valve stopper 53 is provided on the pressure chamber 200 side with respect to the suction valve 52. The suction valve 52 is provided between the suction valve seat 511 and the valve stopper 53 so as to reciprocate in the axial direction, that is, in the valve opening direction or the valve closing direction. The suction valve 52 can come into contact with the valve stopper 53 at the surface on the pressurizing chamber 200 side. The valve stopper 53 can restrict movement of the suction valve 52 in the valve opening direction when the suction valve 52 comes into contact.
The spring 54 is, for example, a coil spring, and is provided between the suction valve 52 and the valve stopper 53. The spring 54 biases the suction valve 52 toward the suction valve seat 511.
The cylindrical member 40 is formed in a substantially cylindrical shape by, for example, a magnetic material. The cylindrical member 40 is inserted through the cover opening 35 of the cover 30 and is provided so that one end is screwed into the suction hole 212 of the upper housing 21.

The upper housing 21 is formed with a hole 214 that connects the suction hole 212 and the fuel chamber 300. The fuel in the fuel chamber 300 can flow into the pressurizing chamber 200 via the hole 214, the inside of the valve seat 51, the periphery of the suction valve 52, and the suction opening 232.
The outer wall of the tubular member 40 and the periphery of the cover opening 35 of the cover 30 are joined over the entire circumferential direction of the tubular member 40 by, for example, welding. Thereby, the space between the cover opening 35 and the outer wall of the cylindrical member 40 is kept liquid-tight.
The needle support portion 56 is formed in a cylindrical shape from a metal such as stainless steel, and is provided so that the outer wall is fitted to the inner wall of the cylindrical member 40.

  The needle 55 is formed in a rod shape from a metal such as stainless steel, and the outer wall is slidably provided on the inner wall of the needle support portion 56. The needle support portion 56 supports the needle 55 so as to be capable of reciprocating in the axial direction. One end of the needle 55 can abut on the center of the end surface of the suction valve 52 on the side opposite to the pressurizing chamber 200. Here, one end of the needle 55 is located inside the cover 30 of the housing 20, and the other end is located outside the cover 30 of the housing 20. The needle 55 is provided such that its axis is substantially orthogonal to the cylinder 23 and the axis Ax1 of the plunger 11. Further, the cylindrical member 40 is provided on the radially outer side of the needle 55 so that the axis is along the axis of the needle 55.

  The spring 57 is a coil spring, for example, and is provided inside the needle support portion 56. One end of the spring 57 is in contact with the needle 55 and the other end is in contact with the needle support portion 56. Thereby, the spring 57 urges the needle 55 toward the suction valve 52 side.

The urging force of the spring 57 is set larger than the urging force of the spring 54. Therefore, when no external force other than the spring 57 acts on the needle 55, the suction valve 52 is urged toward the pressurizing chamber 200 by the spring 57 and the needle 55. At this time, the suction valve 52 is separated from the suction valve seat 511 and opened.
The movable core 58 is formed in a substantially cylindrical shape by, for example, a magnetic material, and is provided so as to be fitted to the other end of the needle 55.

The electromagnetic drive unit 60 is provided on the other end side of the needle 55 and the cylindrical member 40. The electromagnetic drive unit 60 is connected to the other end side of the cylindrical member 40. That is, the cylindrical member 40 connects the housing 20 and the electromagnetic drive unit 60.
The electromagnetic drive unit 60 includes a magnetic diaphragm unit 61, a fixed core 62, a coil 63, a yoke 64, a connector 65, and the like.

  The magnetic aperture 61 is formed in a substantially cylindrical shape by using, for example, a nonmagnetic material. The magnetic aperture 61 is provided on the side opposite to the upper housing 21 with respect to the cylindrical member 40 so as to be coaxial with the cylindrical member 40. Here, the end surface of the movable core 58 opposite to the suction valve 52 is located inside the magnetic throttle unit 61.

  The fixed core 62 is formed in a substantially cylindrical shape with, for example, a magnetic material. The fixed core 62 is provided on the opposite side of the cylindrical member 40 with respect to the magnetic diaphragm 61 so as to be coaxial with the magnetic diaphragm 61. In a state where the spring 57 urges the needle 55 toward the pressurizing chamber 200 and the suction valve 52 is separated from the suction valve seat 511, a gap is formed between the fixed core 62 and the movable core 58.

  The coil 63 has a conducting wire 631. The conducting wire 631 is formed in a linear shape by an electric conducting material such as copper. The coil 63 is formed in a substantially cylindrical shape by winding a conducting wire 631. The coil 63 is provided on the radially outer side of the magnetic throttle unit 61 and the fixed core 62 so as to be coaxial with the fixed core 62. That is, the coil 63 is provided such that the axis thereof is along the axis of the needle 55.

  The yoke 64 has yokes 641 and 642. The yoke 641 is formed in a bottomed cylindrical shape from, for example, a magnetic material. The yoke 641 is provided coaxially with the coil 63 so as to cover the coil 63. The bottom of the yoke 641 is in contact with the fixed core 62.

The yoke 642 is formed in a plate shape and an annular shape, for example, from a magnetic material. The yoke 642 is provided so as to close the opening end of the yoke 641 and to have an inner edge fitted to the outer peripheral wall of the other end of the cylindrical member 40. Here, the inner edge part of the yoke 642 and the outer peripheral wall of the cylindrical member 40 are joined by welding, for example.
The cylindrical member 40 has an outer diameter smaller than that of the yoke 641.

  The connector 65 is formed so as to protrude radially outward from a notch formed in a part of the yoke 641 in the circumferential direction. The connector 65 has a terminal 651. The terminal 651 is electrically connected to the conducting wire 631 of the coil 63. The harness 6 is connected to the connector 65. Thereby, electric power is supplied to the coil 63 via the harness 6 and the terminal 651.

  The coil 63 generates electromagnetic force when energized via the harness 6 and the terminal 651 in response to a command from the ECU. As a result, magnetic circuits are formed in the yokes 641 and 642, the cylindrical member 40, the movable core 58, and the fixed core 62, avoiding the magnetic aperture 61. Thereby, the movable core 58 is sucked together with the needle 55 to the fixed core 62 side. Therefore, the suction valve 52 moves to the suction valve seat 511 side by the biasing force of the spring 54. As a result, the suction valve 52 contacts the suction valve seat 511 and closes. As described above, when the coil 63 is energized, the electromagnetic drive unit 60 generates electromagnetic force, drives the needle 55 in the valve closing direction of the suction valve 52, and can close the suction valve 52.

When the coil 63 is not energized, the intake valve 52 is open, and the fuel chamber 300 is in communication with the pressurizing chamber 200. At this time, when the plunger 11 moves to the cam 4 side, the volume of the pressurizing chamber 200 increases, the fuel in the fuel chamber 300 flows into the suction hole 212, and the fuel is pressurized via the suction opening 232. Inhaled into chamber 200.
Further, when the plunger 11 moves to the side opposite to the cam 4 with the suction valve 52 opened, the volume of the pressurizing chamber 200 decreases, and the fuel in the pressurizing chamber 200 passes through the suction opening 232. And flows to the suction valve 52 side.

When the coil 11 is energized while the plunger 11 is moving to the opposite side of the cam 4, the intake valve 52 is closed and the flow of fuel between the fuel chamber 300 and the pressurizing chamber 200 is shut off. The
When the plunger 11 further moves to the side opposite to the cam 4 with the intake valve 52 closed, the volume of the pressurizing chamber 200 further decreases, and the fuel in the pressurizing chamber 200 is pressurized.
Thus, when the plunger 11 is moving to the side opposite to the cam 4, the amount of fuel pressurized in the pressurizing chamber 200 is adjusted by closing the suction valve 52 by the electromagnetic drive unit 60.
Thus, in this embodiment, the suction valve part 50 and the electromagnetic drive part 60 comprise the normally open type valve apparatus.
The discharge portion 17 is provided in a state of being inserted into the cover opening portion 36 of the cover 30 and the discharge hole portion 213 of the upper housing 21. The discharge unit 17 has a discharge unit main body 171.

  The discharge part main body 171 is formed in a substantially cylindrical shape with a metal such as stainless steel. The discharge part main body 171 is provided in a state where one end is screwed into the discharge hole part 213 of the upper housing 21. The outer wall of the discharge part main body 171 and the periphery of the cover opening part 36 of the cover 30 are joined over the whole area of the discharge part main body 171 in the circumferential direction, for example, by welding. Thereby, the space between the cover opening 36 and the outer wall of the discharge unit main body 171 is kept liquid-tight.

The other end of the discharge unit main body 171 is connected to the high-pressure fuel pipe 102. As a result, the fuel that has flowed from the supply fuel pipe 101 into the fuel chamber 300 via the inlet 8 of the high-pressure pump 10 is pressurized in the pressurization chamber 200 and passes through the inside of the discharge unit main body 171 to the high-pressure fuel pipe 102. Discharged. The high-pressure fuel discharged to the high-pressure fuel pipe 102 is supplied to the fuel rail via the high-pressure fuel pipe 102.
Inside the discharge portion main body 171, a valve seat portion 71, a discharge valve 72, a spring 73, a relief valve 75, a spring 76 and the like are provided.

  The valve seat portion 71 is formed in a substantially cylindrical shape from a metal such as stainless steel. The valve seat portion 71 is provided so that the outer wall is fitted to the inner wall of the discharge portion main body 171. The valve seat 71 has a discharge valve passage 711, a discharge valve seat 712, a relief valve passage 713, and a relief valve seat 714.

  The discharge valve passage 711 is formed so as to connect the surface of the valve seat 71 on the side of the pressurizing chamber 200 and the surface on the opposite side of the pressurizing chamber 200. The discharge valve seat 712 is formed in an annular shape around the discharge valve passage 711 that opens to the center of the surface of the valve seat 71 opposite to the pressurizing chamber 200.

The relief valve passage 713 is formed so as to connect the surface of the valve seat 71 on the side of the pressurizing chamber 200 and the surface opposite to the pressurizing chamber 200. Here, the relief valve passage 713 does not communicate with the discharge valve passage 711. That is, the relief valve passage 713 and the discharge valve passage 711 are formed so as not to communicate with each other. The relief valve seat 714 is formed in an annular shape around a relief valve passage 713 that opens to the center of the surface of the valve seat 71 on the pressure chamber 200 side.
The discharge valve 72 is formed in a substantially disk shape, and an outer edge portion of one end face is provided so as to be in contact with the discharge valve seat 712. The spring 73 is a coil spring, for example, and urges the discharge valve 72 toward the discharge valve seat 712.

  When the pressure of the fuel in the pressurizing chamber 200 increases to a predetermined value or more, the discharge valve 72 resists the urging force of the spring 73 and the pressure of the fuel on the high pressure fuel pipe 102 side of the discharge valve 72. Move to the side. As a result, the discharge valve 72 is separated from the discharge valve seat 712 and opened. Therefore, the fuel on the pressure chamber 200 side with respect to the valve seat portion 71 is discharged to the high-pressure fuel pipe 102 side via the discharge valve passage 711 and the discharge valve seat 712.

  The relief valve 75 is formed in a substantially disk shape, and an outer edge portion of one end face is provided so as to be able to contact the relief valve seat 714. The spring 76 is a coil spring, for example, and urges the relief valve 75 toward the relief valve seat 714.

When the fuel pressure on the high pressure fuel pipe 102 side rises to an abnormal value with respect to the valve seat 71, the relief valve 75 resists the biasing force of the spring 76 and the fuel pressure on the pressure chamber 200 side of the relief valve 75. Then, it moves to the pressurizing chamber 200 side. As a result, the relief valve 75 is separated from the relief valve seat 714 and opened. Therefore, the fuel on the high pressure fuel pipe 102 side with respect to the valve seat portion 71 is returned to the pressurizing chamber 200 side via the relief valve passage 713 and the relief valve seat 714. Such an operation of the relief valve 75 can suppress the fuel pressure on the high-pressure fuel pipe 102 side from becoming an abnormal value.
In the present embodiment, the high-pressure pump 10 further includes a pulsation damper 15 and a support member 16.

The pulsation damper 15 is formed by, for example, combining two circular dish-shaped metal thin plates and joining the outer edges by welding. Inside the pulsation damper 15, a gas of a predetermined pressure such as nitrogen or argon is sealed.
The pulsation damper 15 is provided between the upper housing 21 and the cover bottom 32 in the fuel chamber 300.
The support member 16 is formed in an annular shape, and the outer wall is provided so as to fit into the inner wall of the cover tube portion 31 of the cover 30. The support member 16 supports the pulsation damper 15 in the fuel chamber 300.

  In the present embodiment, the joint between the cylinder 23 and the upper housing 21 forming the pressurizing chamber 200, the joint between the upper housing 21 and the tubular member 40, and the joint between the upper housing 21 and the discharge portion main body 171. Since the cover 30 covers each joint so that the portion is located in the fuel chamber 300, even if high-pressure fuel leaks from the pressurizing chamber 200, it can be retained in the fuel chamber 300.

In the present embodiment, the high-pressure pump 10 is attached to the engine 9 such that the holder support portion 24 is fitted in the attachment hole portion 180 of the engine head 18 (see FIG. 1). The high pressure pump 10 is fixed to the engine 9 by fixing the lower housing 22 to the engine head 18 with bolts or the like. Here, the high pressure pump 10 is attached to the engine 9 in such a posture that the axis Ax1 of the plunger 11 is along the vertical direction.
The damping member 80 includes a first member 81 and a second member 82 (see FIGS. 2 to 4). The first member 81 and the second member 82 are made of, for example, a nonmagnetic material.

The first member 81 and the second member 82 are formed in a shape obtained by cutting a cylindrical member on a plane including an axis. That is, each of the first member 81 and the second member 82 is formed such that a cross section by a plane orthogonal to the axis of the cylindrical member has an arc shape (see FIG. 3).
The damping member 80 is formed such that the circumferential ends of the first member 81 and the second member 82 are in contact with each other. Therefore, the damping member 80 is formed in a substantially cylindrical shape (see FIGS. 3 and 4).

  2-4, the 1st member 81 and the 2nd member 82 are provided so that the cylinder member 40 may be pinched | interposed. That is, the vibration damping member 80 is provided on the outer side in the radial direction of the cylindrical member 40 between the cover 30 of the housing 20 and the electromagnetic drive unit 60. Here, the first member 81 and the second member 82 are provided so as to be aligned in the surface direction of the virtual plane Vp1 orthogonal to the axis Ax1 of the plunger 11, that is, in the horizontal direction. More specifically, the first member 81 and the second member 82 are provided such that a virtual plane Vp2 including the axis Ax1 of the plunger 11 and orthogonal to the virtual plane Vp1 is sandwiched between end portions in the circumferential direction ( (See FIGS. 3 and 4).

The damping member 80 is provided so that the outer edge portion is positioned outside the virtual cylindrical surface Vt1 including the outer peripheral wall of the coil 63 (see FIG. 3). The damping member 80 has an outer diameter smaller than that of the yoke 641. In addition, the cylinder member 40 is located inside the virtual cylindrical surface Vt1.
Both ends of the vibration damping member 80 can come into contact with the cover 30 and the electromagnetic driving unit 60 of the housing 20 (see FIGS. 1, 2, and 4).
The damping member 80 has an inner diameter that is substantially the same as the outer diameter of the cylindrical member 40, and an inner peripheral wall can abut on the outer peripheral wall of the cylindrical member 40. Here, the damping member 80 is provided to be movable relative to the tubular member 40.

In the present embodiment, one end of each of the first member 81 and the second member 82 is welded and fixed to the outer wall of the cover 30 so that the first member 81 and the second member 82 cannot move relative to the cover 30. Also, the other end of each of the first member 81 and the second member 82 is fixed to the yoke 642 of the electromagnetic drive unit 60 so that the first member 81 and the second member 82 cannot move relative to the electromagnetic drive unit 60. That is, the vibration damping member 80 is provided so that both ends thereof are connected to the cover 30 and the electromagnetic drive unit 60 of the housing 20.
In the present embodiment, the upper and lower portions of the vibration damping member 80 in the vertical direction are chamfered in a planar shape (see FIG. 2). 3 and 4, for the sake of simplicity, the vibration control member 80 is schematically shown without displaying the chamfering.

  In the present embodiment, in the manufacturing process, for example, the cylindrical member 40 integrated with the electromagnetic driving unit 60 is screwed into the suction hole 212 of the upper housing 21, and the outer peripheral wall of the cylindrical member 40 and the outer wall of the cover 30 are welded. Thereafter, the damping member 80 is assembled so as to sandwich the first member 81 and the second member 82 from both sides of the tubular member 40. Thereafter, both end portions of the damping member 80 in the axial direction are welded to the outer wall of the cover 30 and the yoke 642.

Next, the operation of the high-pressure pump 10 of this embodiment will be described with reference to FIG.
"Inhalation process"
When the supply of power to the coil 63 of the electromagnetic drive unit 60 is stopped, the suction valve 52 is urged toward the pressurizing chamber 200 by the spring 57 and the needle 55. Therefore, the suction valve 52 is separated from the suction valve seat 511, that is, opened. When the plunger 11 moves to the cam 4 side in this state, the volume of the pressurizing chamber 200 increases, and the fuel on the side opposite to the pressurizing chamber 200 with respect to the suction valve seat 511, that is, the fuel on the fuel chamber 300 side, Inhaled to the 200 side.

“Weighing process”
When the plunger 11 moves to the opposite side of the cam 4 with the intake valve 52 opened, the volume of the pressurizing chamber 200 decreases, and the fuel in the pressurizing chamber 200 is in the fuel chamber with respect to the intake valve seat 511. Returned to the 300 side. When electric power is supplied to the coil 63 during the metering step, the movable core 58 is sucked together with the needle 55 toward the fixed core 62, and the suction valve 52 comes into contact with the suction valve seat 511 and closes. When the plunger 11 moves to the side opposite to the cam 4, the amount of fuel returned from the pressurizing chamber 200 to the fuel chamber 300 side is adjusted by closing the intake valve 52. As a result, the amount of fuel pressurized in the pressurizing chamber 200 is determined. When the intake valve 52 is closed, the metering process for returning the fuel from the pressurizing chamber 200 to the fuel chamber 300 is completed.

"Pressurization process"
When the plunger 11 further moves to the side opposite to the cam 4 with the intake valve 52 closed, the volume of the pressurizing chamber 200 decreases, and the fuel in the pressurizing chamber 200 is compressed and pressurized. When the pressure of the fuel in the pressurizing chamber 200 becomes equal to or higher than the opening pressure of the discharge valve 72, the discharge valve 72 is opened, and the fuel is discharged from the pressurizing chamber 200 to the high-pressure fuel pipe 102 side, that is, the fuel rail side. The

  When the supply of power to the coil 63 is stopped and the plunger 11 moves to the cam 4 side, the suction valve 52 is opened again. As a result, the pressurization process for pressurizing the fuel is completed, and the suction process in which the fuel is sucked from the fuel chamber 300 side to the pressurization chamber 200 side is resumed.

  By repeating the above “suction process”, “metering process”, and “pressurization process”, the high-pressure pump 10 pressurizes and discharges the fuel in the fuel chamber 300 and supplies it to the fuel rail. The amount of fuel supplied from the high-pressure pump 10 to the fuel rail is adjusted by controlling the power supply timing to the coil 63 of the electromagnetic drive unit 60 and the like.

  When the plunger 11 reciprocates when the intake valve 52 is open, such as the above-described “suction process” and “metering process”, the volume of the pressurizing chamber 200 increases or decreases with the fuel in the fuel chamber 300. Pressure pulsation may occur due to. The pulsation damper 15 provided in the fuel chamber 300 can be elastically deformed according to the change in the fuel pressure in the fuel chamber 300, thereby reducing the pressure pulsation of the fuel in the fuel chamber 300.

  Further, when the plunger 11 is reciprocating, pressure pulsation due to increase or decrease of the volume of the variable volume chamber 201 may occur. Also in this case, the pulsation damper 15 can be elastically deformed in accordance with the change in the fuel pressure in the fuel chamber 300, thereby reducing the pressure pulsation of the fuel in the fuel chamber 300.

  Further, when the plunger 11 reciprocates, the volume of the variable volume chamber 201 increases or decreases, so that fuel flows between the fuel chamber 300 and the hole 222, the annular space 202, and the variable volume chamber 201. As a result, the cylinder 23 and the plunger 11 that are heated to high temperatures due to the heat generated by sliding between the plunger 11 and the cylinder 23 and the heat generated by pressurizing the fuel in the pressurizing chamber 200 can be cooled by the low-temperature fuel. . Thereby, the burn-in of the plunger 11 and the cylinder 23 can be suppressed.

  Further, part of the fuel that has become high pressure in the pressurizing chamber 200 flows into the variable volume chamber 201 via the clearance between the plunger 11 and the cylinder 23. Thereby, an oil film is formed between the plunger 11 and the cylinder 23, and seizure of the plunger 11 and the cylinder 23 can be effectively suppressed. The fuel that has flowed into the variable volume chamber 201 from the pressurizing chamber 200 returns to the fuel chamber 300 via the annular space 202 and the hole 222.

  In this embodiment, since the cam 4 rotates when the engine 9 continues to operate, the plunger 11 reciprocates up and down in the axial direction, that is, in the vertical direction. Therefore, vibration may occur in the housing 20 of the high-pressure pump 10. Further, when the electromagnetic drive unit 60 is operated, the needle 55, the movable core 58, and the suction valve 52 reciprocate in the axial direction of the needle 55, so that the high-pressure pump 10 may vibrate. Further, the high-pressure pump 10 may vibrate due to the vibration of the vehicle. Thereby, there exists a possibility that noise may generate | occur | produce from the high pressure pump 10 resulting from a vibration.

  Here, in the electromagnetic drive unit 60, the outer diameter of the yoke 64 is larger than the outer diameter of the cylindrical member 40, and becomes a mass at the end of the cylindrical member 40 opposite to the housing 20. There is a risk of relative vibration in the direction.

  In the present embodiment, a damping member 80 is provided on the radially outer side of the tubular member 40 between the cover 30 of the housing 20 and the electromagnetic drive unit 60. The damping member 80 is provided so that both ends thereof can contact the cover 30 and the electromagnetic driving unit 60 of the housing 20. In addition, each of the first member 81 and the second member 82 is fixed by being welded to the outer wall of the cover 30 so that the first member 81 and the second member 82 cannot move relative to the cover 30. Also, the other end of each of the first member 81 and the second member 82 is fixed to the yoke 642 of the electromagnetic drive unit 60 so that the first member 81 and the second member 82 cannot move relative to the electromagnetic drive unit 60. Therefore, when the engine 9 is operated and when the electromagnetic drive unit 60 is operated, the vibration of the electromagnetic drive unit 60 with respect to the housing 20 is suppressed by the damping member 80 between the electromagnetic drive unit 60 and the housing 20. That is, the vibration damping member 80 can suppress the vibration of the electromagnetic drive unit 60 with respect to the housing 20. Thereby, the noise generated from the high-pressure pump 10 due to vibration can be suppressed.

  Next, the effect of suppressing noise from the high-pressure pump 10 by the damping member 80 will be described with reference to FIG. In FIG. 5, the level of noise generated from a high-pressure pump according to a comparative embodiment that does not include the damping member 80 (hereinafter referred to as “noise level”) is indicated by a broken line, and the high-pressure pump 10 of the present embodiment that includes the damping member 80 is illustrated. The noise level is indicated by a solid line. As shown in FIG. 5, in the present embodiment, the noise level is greatly reduced particularly in a predetermined frequency range as compared with the comparative embodiment. This is probably because the vibration level of the electromagnetic drive unit 60 with respect to the housing 20 is suppressed by the damping member 80, and thus the noise level is reduced.

  In the present embodiment, since the damping member 80 is formed of a nonmagnetic material, the damping member 80 is provided in order to suppress the vibration of the electromagnetic drive unit 60 relative to the housing 20 or the size of the damping member 80 is increased. Increasing the size does not affect the characteristics and performance of the electromagnetic drive unit 60.

As described above, (1) the high-pressure pump 10 of the present embodiment includes the housing 20, the plunger 11, the suction valve 52, the needle 55, the electromagnetic drive unit 60, the tubular member 40, and the damping member 80.
The housing 20 includes a fuel chamber 300 and a pressurizing chamber 200 that communicates with the fuel chamber 300.
The plunger 11 is provided so as to be capable of reciprocating in the axial direction, and can pressurize the fuel in the pressurizing chamber 200.
The intake valve 52 allows the flow of fuel between the fuel chamber 300 and the pressurizing chamber 200 when the valve is opened, and can block the flow of fuel between the fuel chamber 300 and the pressurizing chamber 200 when the valve is closed. It is.
One end of the needle 55 is located inside the housing 20, the other end is located outside the housing 20, and one end is provided so as to be able to contact the suction valve 52.

The electromagnetic drive unit 60 is provided on the other end side of the needle 55. The electromagnetic drive unit 60 includes a coil 63 formed in a cylindrical shape by winding a conducting wire 631 and having a shaft provided along the axis of the needle 55, and a yoke 64 formed of a magnetic material and provided to cover the coil 63. When the coil 63 is energized, the needle 55 can be driven in the valve closing direction of the suction valve 52 to close the suction valve 52.
The cylindrical member 40 is formed in a cylindrical shape from a magnetic material, has an outer diameter smaller than the outer diameter of the yoke 64, and is provided on the outer side in the radial direction of the needle 55 so that the axis is along the axis of the needle 55. 60 is connected.
The vibration damping member 80 is provided between the housing 20 and the electromagnetic drive unit 60 on the radially outer side of the cylindrical member 40, and can suppress vibration of the electromagnetic drive unit 60 with respect to the housing 20.

  In the present embodiment, the vibration of the electromagnetic drive unit 60 relative to the housing 20 when the high-pressure pump 10 is actuated by the damping member 80 provided on the radially outer side of the cylindrical member 40 between the housing 20 and the electromagnetic drive unit 60. Can be suppressed. Thereby, the noise generated from the high-pressure pump 10 due to vibration can be suppressed.

Further, (2) in the present embodiment, the vibration damping member 80 is made of a nonmagnetic material. Therefore, even if the damping member 80 is provided to suppress the vibration of the electromagnetic driving unit 60 relative to the housing 20 or the size of the damping member 80 is increased, the characteristics and performance of the electromagnetic driving unit 60 are affected. There is no.
Thus, in the present embodiment, vibration of the electromagnetic drive unit 60 relative to the housing 20 can be suppressed without affecting the characteristics of the electromagnetic drive unit 60.

  (3) In the present embodiment, the damping member 80 is provided so that at least a part thereof is positioned outside the virtual cylindrical surface Vt1 including the outer peripheral wall of the coil 63. Therefore, the effect of suppressing the vibration of the electromagnetic drive unit 60 relative to the housing 20 can be further enhanced.

(4) In the present embodiment, the vibration damping member 80 is provided so as to be connected to the housing 20 and the electromagnetic driving unit 60. Therefore, when the electromagnetic drive unit 60 vibrates with respect to the housing 20, the force generated by the vibration acts on the connection portion between the vibration damping member 80, the housing 20 and the electromagnetic drive unit 60. Thereby, the effect which suppresses the vibration of the electromagnetic drive part 60 with respect to the housing 20 can be heightened further.
Moreover, (5) In this embodiment, the damping member 80 is formed in the cylinder shape. Since the damping member 80 has a simple shape, the damping member 80 can be easily manufactured.
Moreover, (6) In this embodiment, the damping member 80 has the 1st member 81 and the 2nd member 82 of cross-sectional arc shape.
The first member 81 and the second member 82 are provided so as to sandwich the tubular member 40 therebetween.
Therefore, the first member 81 and the second member 82 of the damping member 80 can be easily assembled in the manufacturing process.

  (14) In the present embodiment, the vibration damping member 80 is provided so as to be relatively movable with respect to the tubular member 40. Therefore, when the electromagnetic driving unit 60 vibrates with respect to the housing 20, the vibration damping member 80 can be moved relative to the cylindrical member 40.

  In the present embodiment, one end of each of the first member 81 and the second member 82 of the vibration damping member 80 is fixed to the outer wall of the cover 30 so as not to move relative to the cover 30. Further, the other end of each of the first member 81 and the second member 82 of the vibration damping member 80 is fixed to the yoke 642 of the electromagnetic drive unit 60 so that it cannot move relative to the electromagnetic drive unit 60.

  (16) In the present embodiment, the housing 20 includes a cylinder 23 as a pressurizing chamber forming portion, an upper housing 21 and a lower housing 22, a cover 30, and a cover opening 35. The cylinder 23 forms a pressurizing chamber 200. The cover 30 covers at least a part of the cylinder 23, the upper housing 21, and the lower housing 22 so that the pressurizing chamber 200 is positioned inside, and forms a fuel chamber 300 between the cylinder 23, the upper housing 21, and the lower housing 22. doing. The cover opening 35 is formed so as to connect the inner wall and the outer wall of the cover 30. In this configuration, the volume of the fuel chamber 300 can be made relatively large.

  One end of the cylindrical member 40 is connected to the upper housing 21 via the cover opening 35. The damping member 80 is provided between the cover 30 and the electromagnetic driving unit 60. Therefore, the vibration of the electromagnetic drive unit 60 with respect to the housing 20 can be suppressed while the cover 30 is enlarged to increase the volume of the fuel chamber 300.

(Second Embodiment)
A part of the high-pressure pump according to the second embodiment is shown in FIG. The second embodiment is different from the first embodiment in the configuration of the vibration damping member 80.
The first member 81 of the damping member 80 has movement restricting portions 811 and 812. The second member 82 of the vibration damping member 80 has movement restricting portions 821 and 822.

  The movement restricting portion 811 of the first member 81 is formed on a virtual plane Vp3 orthogonal to the axis of the damping member 80 so as to face the yoke 642 of the electromagnetic driving portion 60. The movement restricting portion 812 of the first member 81 is formed on the virtual plane Vp3 so as to face the cover 30 of the housing 20 on the opposite side of the movement restricting portion 811 across the shaft of the vibration damping member 80.

  The movement restricting portion 821 of the second member 82 is formed on the virtual plane Vp3 so as to face and contact the movement restricting portion 811. The movement restricting portion 822 of the second member 82 is formed on the virtual plane Vp3 so as to face and contact the movement restricting portion 812 on the opposite side of the movement restricting portion 821 across the axis of the vibration damping member 80.

  With the above configuration, when the first member 81 moves toward the electromagnetic drive unit 60 with respect to the second member 82, the movement restricting unit 811 contacts the movement restricting unit 821, and the movement toward the electromagnetic drive unit 60 is restricted. The Further, when the second member 82 moves to the electromagnetic drive unit 60 side with respect to the first member 81, the movement restricting unit 822 contacts the movement restricting unit 812, and the movement to the electromagnetic drive unit 60 side is restricted.

Further, when the first member 81 moves toward the housing 20 relative to the second member 82, the movement restricting portion 812 contacts the movement restricting portion 822, and the movement toward the housing 20 is restricted. Further, when the second member 82 moves toward the housing 20 with respect to the first member 81, the movement restricting portion 821 contacts the movement restricting portion 811 and the movement toward the housing 20 is restricted.
As described above, the movement restricting portions 811, 812, 821, and 822 can restrict the relative movement of the first member 81 and the second member 82 in the axial direction of the vibration damping member 80.
The second embodiment is the same as the first embodiment except for the points described above.

  As described above, (7) in the present embodiment, the vibration damping member 80 has the movement restricting portions 811, 812, 821, 822 that can restrict the relative movement between the first member 81 and the second member 82. ing. Therefore, the relative movement between the first member 81 and the second member 82 can be suppressed during the operation of the high-pressure pump 10 and the vibration of the electromagnetic drive unit 60 relative to the housing 20 can be further effectively suppressed.

(Third embodiment)
A part of the high-pressure pump according to the third embodiment is shown in FIG. The third embodiment is different from the second embodiment in the configuration of the vibration damping member 80.
The first member 81 of the vibration damping member 80 further includes movement restricting portions 813 and 814. The second member 82 of the vibration damping member 80 further includes movement restricting portions 823 and 824.

  The movement restricting portion 813 of the first member 81 is formed on a virtual plane Vp4 orthogonal to the axis of the vibration damping member 80 so as to face the cover 30 of the housing 20. The movement restricting portion 814 of the first member 81 is formed on the virtual plane Vp4 so as to face the yoke 642 of the electromagnetic driving portion 60 on the opposite side of the movement restricting portion 813 across the axis of the vibration damping member 80.

  The movement restricting portion 823 of the second member 82 is formed on the virtual plane Vp4 so as to face and contact the movement restricting portion 813. The movement restricting portion 824 of the second member 82 is formed on the virtual plane Vp4 so as to face and contact the movement restricting portion 814 on the opposite side of the movement restricting portion 823 across the axis of the vibration damping member 80.

  With the above configuration, the movement restricting portions 813, 814, 823, and 824 can restrict the relative movement of the first member 81 and the second member 82 in the axial direction of the vibration damping member 80. Therefore, in the third embodiment, relative movement between the first member 81 and the second member 82 can be more effectively regulated as compared to the second embodiment.

(Fourth embodiment)
A part of the high-pressure pump according to the fourth embodiment is shown in FIG. The fourth embodiment is different from the first embodiment in the configuration of the damping member 80.
The first member 81 of the vibration damping member 80 has movement restricting portions 815 and 816. The second member 82 of the vibration damping member 80 has movement restricting portions 825 and 826.

  The movement restricting portion 815 of the first member 81 is formed on a virtual plane Vp5 that inclines and intersects with the axis of the vibration damping member 80 so as to face the yoke 642 of the electromagnetic driving portion 60. The movement restricting portion 816 of the first member 81 is hypothesized to intersect with the axis of the vibration damping member 80 so as to face the cover 30 of the housing 20 on the opposite side of the movement restricting portion 815 across the axis of the vibration damping member 80. It is formed on the plane Vp6.

The movement restricting portion 825 of the second member 82 is formed on the virtual plane Vp5 so as to face and contact the movement restricting portion 815. The movement restricting portion 826 of the second member 82 is formed on the virtual plane Vp6 so as to face and contact the movement restricting portion 816 on the opposite side of the movement restricting portion 825 across the axis of the vibration damping member 80.
With the above configuration, the movement restricting portions 815, 816, 825, and 826 can restrict the relative movement of the first member 81 and the second member 82 in the axial direction of the vibration damping member 80.

(Fifth embodiment)
A part of the high-pressure pump according to the fifth embodiment is shown in FIG. The fifth embodiment differs from the fourth embodiment in the configuration of the damping member 80.
The first member 81 of the vibration damping member 80 further includes movement restricting portions 817 and 818. The second member 82 of the vibration damping member 80 further includes movement restricting portions 827 and 828.

  The movement restricting portion 817 of the first member 81 is formed on a virtual plane Vp7 that inclines and intersects with the axis of the vibration damping member 80 so as to face the cover 30 of the housing 20. The movement restricting portion 818 of the first member 81 is inclined to the axis of the damping member 80 so as to face the yoke 642 of the electromagnetic driving unit 60 on the opposite side of the movement restricting portion 817 across the axis of the damping member 80. It is formed on the intersecting virtual plane Vp8.

  The movement restricting portion 827 of the second member 82 is formed on the virtual plane Vp7 so as to face and contact the movement restricting portion 817. The movement restricting portion 828 of the second member 82 is formed on the virtual plane Vp8 so as to face and contact the movement restricting portion 818 on the opposite side of the movement restricting portion 827 across the shaft of the vibration damping member 80.

  With the above configuration, the movement restricting portions 817, 818, 827, and 828 can restrict the relative movement of the first member 81 and the second member 82 in the axial direction of the vibration damping member 80. Therefore, in the fifth embodiment, relative movement between the first member 81 and the second member 82 can be more effectively regulated as compared to the fourth embodiment.

(Sixth embodiment)
A part of the high-pressure pump according to the sixth embodiment is shown in FIG. The sixth embodiment is different from the first embodiment in the configuration between the first member 81 and the second member 82 of the vibration damping member 80.

  The sixth embodiment further includes an intermediate elastic member 91. The intermediate elastic member 91 is made of an elastically deformable material having an elastic modulus of a predetermined value or less, such as rubber. The intermediate elastic member 91 is formed, for example, in a rectangular plate shape, and is provided between both end portions of the first member 81 and the second member 82 in the circumferential direction. That is, a total of two intermediate elastic members 91 are provided so as to sandwich the shaft of the damping member 80.

The intermediate elastic member 91 is compressed in the plate thickness direction by the circumferential end of the first member 81 and the circumferential end of the second member 82. Therefore, a frictional force acts between the intermediate elastic member 91 and the first member 81 and the second member 82. Thereby, when the first member 81 and the second member 82 move relative to each other in the axial direction of the vibration damping member 80, the intermediate elastic member 91 is elastically deformed. Accordingly, relative movement between the first member 81 and the second member 82 is suppressed. Here, the intermediate elastic member 91 provided between the first member 81 and the second member 82 functions as a damper, and can attenuate the vibration of the electromagnetic drive unit 60 relative to the housing 20.
The configuration of the sixth embodiment is the same as that of the first embodiment except for the points described above.

  As described above, (8) the present embodiment further includes the intermediate elastic member 91. The intermediate elastic member 91 is provided between the first member 81 and the second member 82 and can be elastically deformed. The intermediate elastic member 91 provided between the first member 81 and the second member 82 functions as a damper and can attenuate the vibration of the electromagnetic drive unit 60 relative to the housing 20. Therefore, the vibration of the electromagnetic drive unit 60 with respect to the housing 20 can be more effectively suppressed. Thereby, the noise which generate | occur | produces from the high pressure pump 10 resulting from a vibration can be suppressed more effectively.

(Seventh embodiment)
A part of the high-pressure pump according to the seventh embodiment is shown in FIG. The seventh embodiment is different from the first embodiment in the configuration of the vibration damping member 80.

The first member 81 and the second member 82 are provided so as to be aligned in the surface direction of the virtual plane Vp2 including the axis Ax1 of the plunger 11 and the axis of the cylindrical member 40, that is, in the vertical direction. More specifically, the first member 81 and the second member 82 sandwich an imaginary plane Vp1 that includes the axis of the tubular member 40 and is orthogonal to the axis Ax1 of the plunger 11 and the imaginary plane Vp2 between circumferential ends. Provided.
The configuration of the seventh embodiment is the same as that of the first embodiment except for the points described above.

(Eighth embodiment)
A part of the high-pressure pump according to the eighth embodiment is shown in FIGS. The eighth embodiment differs from the first embodiment in the configuration of the vibration damping member 80.
The damping member 80 is formed in a substantially cylindrical shape from, for example, a nonmagnetic material. That is, the vibration damping member 80 has a shape such that the first member 81 and the second member 82 described in the first embodiment are integrally formed.
In the present embodiment, the damping member 80 has its inner edge welded to and fixed to the outer peripheral wall of the cylindrical member 40 so that it cannot move relative to the cylindrical member 40.

In the present embodiment, in the manufacturing process, for example, the damping member 80 is provided on the cylindrical member 40 integrated with the electromagnetic drive unit 60, and the end of the damping member 80 is welded to the yoke 642, and the inner edge portion of the damping member 80 is Is welded to the outer peripheral wall of the tubular member 40. Thereafter, the cylindrical member 40 integrated with the electromagnetic drive unit 60 and the damping member 80 is screwed into the suction hole 212 of the upper housing 21, and the outer peripheral wall of the cylindrical member 40 and the outer wall of the cover 30 are welded.
The configuration of the eighth embodiment is the same as that of the first embodiment except for the points described above.

As described above, (5) in the present embodiment, the damping member 80 is formed in a cylindrical shape. Since the damping member 80 has a simple shape, the damping member 80 can be easily manufactured.
(15) In the present embodiment, the vibration damping member 80 is fixed to the cylindrical member 40 so as not to move relative to the cylindrical member 40. Therefore, the relative movement between the vibration damping member 80 and the cylindrical member 40 can be suppressed during the operation of the high-pressure pump 10 and the vibration of the electromagnetic drive unit 60 with respect to the housing 20 can be further effectively suppressed.

(Ninth embodiment)
A part of the high-pressure pump according to the ninth embodiment is shown in FIG. The ninth embodiment differs from the eighth embodiment in the configuration of the vibration damping member 80.

  The vibration damping member 80 has a notch 85. The cutout portion 85 is formed so as to cut out a part of the substantially cylindrical damping member 80 in the circumferential direction. The width of the notch 85 is set to be slightly larger than the outer diameter of the tubular member 40. Therefore, the vibration damping member 80 can be attached to the cylindrical member 40 via the notch 85.

In the present embodiment, in the manufacturing process, for example, the cylindrical member 40 integrated with the electromagnetic driving unit 60 is screwed into the suction hole 212 of the upper housing 21, and the outer peripheral wall of the cylindrical member 40 and the outer wall of the cover 30 are welded. Thereafter, the vibration damping member 80 is attached to the tubular member 40 from the upper side in the vertical direction via the notch 85. Thereafter, both end portions of the damping member 80 in the axial direction are welded to the outer wall of the cover 30 and the yoke 642. Furthermore, the notch 85 of the damping member 80 and the cylindrical member 40 are welded.
The ninth embodiment is the same as the eighth embodiment except for the points described above.

  As described above, (9) In the present embodiment, the vibration damping member 80 has the notch 85 in a part in the circumferential direction. Therefore, the vibration damping member 80 can be attached to the cylindrical member 40 via the notch 85. Thereby, the high-pressure pump 10 that can suppress the vibration of the electromagnetic drive unit 60 relative to the housing 20 can be easily manufactured.

(10th Embodiment)
A part of the high-pressure pump according to the tenth embodiment is shown in FIG. The tenth embodiment is different from the eighth embodiment in the configuration between the damping member 80, the housing 20, and the electromagnetic driving unit 60.

The tenth embodiment further includes an end elastic member 92. The end elastic member 92 is made of an elastically deformable material having an elastic modulus of a predetermined value or less, such as rubber. The end elastic member 92 is formed, for example, in the shape of an annular plate, and on the radially outer side of the tubular member 40, between the one end in the axial direction of the vibration damping member 80 and the cover 30 of the housing 20, and the vibration damping member 80. Between the other end in the axial direction and the yoke 642 of the electromagnetic drive unit 60. That is, a total of two end elastic members 92 are provided.
In the present embodiment, the damping member 80 is provided so as to be movable relative to the tubular member 40.

The two end elastic members 92 are respectively compressed in the plate thickness direction by both axial ends of the damping member 80, the cover 30 of the housing 20, and the yoke 642 of the electromagnetic drive unit 60. When the damping member 80 moves relative to the cylindrical member 40 in the axial direction, the end elastic member 92 is elastically deformed. Therefore, relative movement between the vibration damping member 80 and the tubular member 40 is suppressed. Here, the end elastic member 92 provided between both ends of the vibration damping member 80 and the housing 20 and the electromagnetic drive unit 60 functions as a damper and can attenuate the vibration of the electromagnetic drive unit 60 with respect to the housing 20. it can.
The configuration of the tenth embodiment is the same as that of the eighth embodiment except for the points described above.

  As described above, (13) the present embodiment further includes the end elastic member 92. The end elastic member 92 is provided between the damping member 80 and the housing 20 and between the damping member 80 and the electromagnetic driving unit 60 and is elastically deformable. The end elastic member 92 provided between the damping member 80 and the housing 20 and between the damping member 80 and the electromagnetic drive unit 60 functions as a damper, and vibrates the electromagnetic drive unit 60 with respect to the housing 20. Can be attenuated. Therefore, the vibration of the electromagnetic drive unit 60 with respect to the housing 20 can be more effectively suppressed. Thereby, the noise which generate | occur | produces from the high pressure pump 10 resulting from a vibration can be suppressed more effectively.

(Eleventh embodiment)
A part of the high-pressure pump according to the eleventh embodiment is shown in FIG. The eleventh embodiment differs from the tenth embodiment in the configuration of the damping member 80 and the like.
The vibration damping member 80 has a plurality of divided members 801. The dividing member 801 is formed in a substantially annular shape by using, for example, a nonmagnetic material. Three split members 801 are provided so as to be aligned in the axial direction of the tubular member 40.

  The eleventh embodiment further includes an intermediate elastic member 93. The intermediate elastic member 93 is formed of an elastically deformable material having an elastic modulus of a predetermined value or less, such as rubber. The intermediate elastic member 93 is formed in, for example, an annular plate shape, and is provided between the three divided members 801 on the radially outer side of the tubular member 40. That is, a total of two intermediate elastic members 93 are provided.

  The two intermediate elastic members 93 are each compressed in the plate thickness direction by a plurality of divided members 801. When the split member 801 moves relative to the cylindrical member 40 in the axial direction, the intermediate elastic member 93 is elastically deformed. Therefore, relative movement between the split member 801 of the damping member 80 and the tubular member 40 is suppressed. Here, the intermediate elastic member 93 provided between the plurality of divided members 801 functions as a damper, and can attenuate the vibration of the electromagnetic drive unit 60 relative to the housing 20.

The tenth embodiment is provided between one end in the axial direction of the damping member 80 and the cover 30 of the housing 20 and between the other end in the axial direction of the damping member 80 and the yoke 642 of the electromagnetic drive unit 60. Similar to the embodiment, an end elastic member 92 is provided.
The eleventh embodiment is the same as the tenth embodiment except for the points described above.

  As described above, (10) In the present embodiment, the vibration damping member 80 has a plurality of divided members 801 provided so as to be aligned in the axial direction of the tubular member 40. The present embodiment further includes an intermediate elastic member 93. The intermediate elastic member 93 is provided between the plurality of divided members 801 and can be elastically deformed. The intermediate elastic member 93 provided between the plurality of divided members 801 functions as a damper and can attenuate the vibration of the electromagnetic drive unit 60 relative to the housing 20. Therefore, the vibration of the electromagnetic drive unit 60 with respect to the housing 20 can be more effectively suppressed. Thereby, the noise which generate | occur | produces from the high pressure pump 10 resulting from a vibration can be suppressed more effectively.

(Twelfth embodiment)
A part of the high-pressure pump according to the twelfth embodiment is shown in FIGS. The twelfth embodiment differs from the first embodiment in the configuration of the damping member.
The damping member 87 is formed in a rectangular plate shape by using, for example, a nonmagnetic material. That is, the damping member 87 is formed in a long shape.
The damping member 87 is provided around the cylindrical member 40 so that the longitudinal direction is parallel to the axis Ax1 of the cylindrical member 40. Four damping members 87 are provided at equal intervals in the circumferential direction of the tubular member 40.

  Each of the plurality of damping members 87 is welded and fixed to the outer wall of the cover 30 such that one end in the longitudinal direction cannot be moved relative to the cover 30. Further, the other ends in the longitudinal direction of each of the plurality of damping members 87 are fixed to the yoke 642 of the electromagnetic drive unit 60 so that they cannot move relative to the electromagnetic drive unit 60. That is, the plurality of damping members 87 are provided so that both ends thereof are connected to the cover 30 and the electromagnetic driving unit 60 of the housing 20.

  Each of the plurality of damping members 87 is provided in such a posture that the plate thickness direction is parallel to a tangent line of an imaginary circle passing through the outer peripheral wall of the tubular member 40. Here, the damping member 87 is separated from the outer peripheral wall of the cylindrical member 40 (see FIGS. 17 and 18).

Note that two of the four damping members 87 are located on a virtual plane Vp1 orthogonal to the axis Ax1 of the plunger 11. The remaining two are located on a virtual plane Vp2 that includes the axis Ax1 of the plunger 11 and is orthogonal to the virtual plane Vp1.
Further, the damping member 87 is provided so that a part in the short direction is located outside the virtual cylindrical surface Vt1 including the outer peripheral wall of the coil 63 (see FIG. 17).

In this embodiment, since the damping member 87 is formed in a plate shape, when the electromagnetic drive unit 60 vibrates with respect to the housing 20, the damping member 87 is elastically deformed so as to bend. Therefore, the damping member 87 provided between the housing 20 and the electromagnetic drive unit 60 functions as a damper and can attenuate the vibration of the electromagnetic drive unit 60 with respect to the housing 20.
The configuration of the twelfth embodiment is the same as that of the first embodiment except for the points described above.

As described above, (11) in the present embodiment, the damping member 87 is formed in a long shape, and a plurality of damping members 87 are provided around the cylindrical member 40 so that the longitudinal direction is parallel to the axis of the cylindrical member 40. ing.
A plurality of damping members 87 provided radially outside the cylindrical member 40 between the housing 20 and the electromagnetic drive unit 60 can suppress vibration of the electromagnetic drive unit 60 relative to the housing 20 when the high-pressure pump 10 is operated. It is.

  (12) In the present embodiment, a plurality of damping members 87 are provided at equal intervals in the circumferential direction of the tubular member 40. Therefore, the vibration of the electromagnetic drive unit 60 with respect to the housing 20 can be uniformly suppressed in the circumferential direction of the cylindrical member 40.

(13th Embodiment)
A part of the high-pressure pump according to the thirteenth embodiment is shown in FIGS. The thirteenth embodiment differs from the twelfth embodiment in the configuration of the damping member.

Each of the plurality of damping members 87 is provided in such a posture that the surface direction is parallel to the tangent of the virtual circle passing through the outer peripheral wall of the cylindrical member 40 (see FIG. 19). That is, the damping member 87 is provided so that the end surface faces the outer peripheral wall of the cylindrical member 40.
Further, the damping member 87 is provided so that all the parts are located outside the virtual cylindrical surface Vt1 including the outer peripheral wall of the coil 63 (see FIG. 19).

  In this embodiment, since the damping member 87 is formed in a plate shape, when the electromagnetic drive unit 60 vibrates with respect to the housing 20, the damping member 87 is elastically deformed so as to bend. Therefore, as in the twelfth embodiment, the damping member 87 provided between the housing 20 and the electromagnetic drive unit 60 can function as a damper and can attenuate the vibration of the electromagnetic drive unit 60 relative to the housing 20.

  In the present embodiment, the damping member 87 is provided so that the end surface faces the outer peripheral wall of the tubular member 40, and the direction of the damping member 87 with respect to the tubular member 40 is different from that of the twelfth embodiment. Therefore, compared to the twelfth embodiment, when the electromagnetic drive unit 60 vibrates with respect to the housing 20, the damping member 87 of the thirteenth embodiment is easily bent. Therefore, the effect of attenuating the vibration of the electromagnetic drive unit 60 relative to the housing 20 can be enhanced.

(14th Embodiment)
A part of the high-pressure pump according to the fourteenth embodiment is shown in FIGS. The fourteenth embodiment differs from the twelfth embodiment in the configuration of the damping member.

The damping member 87 is formed so that the end portion in the short direction abuts the outer peripheral wall of the tubular member 40. The damping member 87 is welded and fixed to the outer peripheral wall of the tubular member 40 so that the end in the short direction cannot be moved relative to the tubular member 40.
The configuration of the fourteenth embodiment is the same as that of the twelfth embodiment except for the points described above.

(Fifteenth embodiment)
FIG. 23 shows a high-pressure pump according to the fifteenth embodiment. The fifteenth embodiment differs from the first embodiment in a part of the configuration of the high-pressure pump 10.
In the fifteenth embodiment, the hole 214 shown in the first embodiment is not formed in the upper housing 21. Instead, a hole 401 is formed in the tubular member 40. The hole 401 is formed so as to connect the inner peripheral wall and the outer peripheral wall of the cylindrical member 40 inside the outer peripheral wall of the cover cylindrical portion 31. Therefore, the hole 401 connects the suction hole 212 and the fuel chamber 300. For example, four hole portions 401 are formed at equal intervals in the circumferential direction of the tubular member 40.

  In the present embodiment, a welding ring 400 is provided on the outer side in the radial direction of the cylindrical member 40 outside the cover cylindrical portion 31. The welding ring 400 is formed in a substantially cylindrical shape with metal, for example. The welding ring 400 is formed so that the end portion on the pressurizing chamber 200 side extends outward in the radial direction, and is in contact with the periphery of the cover opening 35 on the outer peripheral wall of the cover cylinder portion 31. The welding ring 400 is welded to the outer peripheral wall of the cover tube portion 31 over the entire range in the circumferential direction at the pressurizing chamber 200 side, and the portion on the opposite side to the pressurizing chamber 200 is spanned over the entire range in the circumferential direction. It is welded to the outer peripheral wall of the cylindrical member 40. Thereby, the fuel in the fuel chamber 300 is prevented from leaking to the outside of the cover 30 through the gap between the cover opening 35 and the outer peripheral wall of the cylindrical member 40.

  In the present embodiment, a welding ring 170 is provided on the outer side of the cover cylinder part 31 and on the outer side in the radial direction of the discharge part main body 171. The welding ring 170 is formed in a substantially cylindrical shape with metal, for example. The welding ring 170 is formed so that the end portion on the pressurizing chamber 200 side extends outward in the radial direction, and is in contact with the periphery of the cover opening 36 on the outer peripheral wall of the cover cylinder portion 31. The welding ring 170 is welded to the outer peripheral wall of the cover tube portion 31 over the entire range in the circumferential direction at the end on the pressurizing chamber 200 side, and the portion on the side opposite to the pressurizing chamber 200 extends over the entire range in the circumferential direction. It is welded to the outer peripheral wall of the discharge part main body 171. Thereby, the fuel in the fuel chamber 300 is prevented from leaking to the outside of the cover 30 via the gap between the cover opening 36 and the outer peripheral wall of the discharge unit main body 171.

In the present embodiment, the relief valve 75 is formed in a rod shape. Further, the end face of the relief valve 75 on the relief valve seat 714 side is formed in a tapered shape, and the relief valve seat 714 is formed in a tapered shape corresponding to the end face.
In the present embodiment, two pulsation dampers 15 are provided in the fuel chamber 300. The two pulsation dampers 15 are provided between the upper housing 21 and the cover bottom 32 in the fuel chamber 300 so as to overlap in the axial direction.
In the present embodiment, the holder support portion 24 is formed separately from the lower housing 22.

  In the present embodiment, as in the first embodiment, the first member 81 and the second member 82 of the vibration damping member 80 are provided so as to sandwich the tubular member 40 therebetween. However, the present embodiment is different from the first embodiment in that a part of the end face on the cover 30 side of the first member 81 and the second member 82 is formed so as to be recessed corresponding to the shape of the welding ring 400. .

The configuration of the present embodiment is the same as that of the first embodiment except for some differences in shape except for the points described above.
In the present embodiment, as in the first embodiment, a damping member 80 capable of suppressing the vibration of the electromagnetic drive unit 60 relative to the housing 20 is disposed radially outside the cylindrical member 40 between the housing 20 and the electromagnetic drive unit 60. Is provided. Therefore, vibration of the electromagnetic drive unit 60 with respect to the housing 20 can be suppressed when the high-pressure pump 10 is operated. Thereby, the noise generated from the high-pressure pump 10 due to vibration can be suppressed.

(Other embodiments)
In the above-described embodiment, an example in which the needle 55 and the suction valve 52 are formed separately has been described. On the other hand, in another embodiment of the present invention, the needle 55 and the suction valve 52 may be integrally formed. That is, the needle 55 may be formed so that one end is connected to the suction valve 52.

  Moreover, in the above-mentioned embodiment, the suction valve part 50 and the electromagnetic drive part 60 showed the example which comprises the normally open type valve apparatus. On the other hand, in other embodiment of this invention, the suction valve part 50 and the electromagnetic drive part 60 may comprise the normally closed type valve apparatus.

In the above-described embodiment, an example in which at least a part of the damping member is provided so as to be located outside the virtual cylindrical surface Vt1 including the outer peripheral wall of the coil 63 has been described. On the other hand, in another embodiment of the present invention, all of the damping members may be provided so as to be located inside the virtual cylindrical surface Vt1.
In another embodiment of the present invention, the damping member may form a gap between at least one of the housing and the electromagnetic drive unit. Moreover, the damping member is not limited to a nonmagnetic material, and may be formed of any material such as a magnetic material.

  In the eleventh embodiment described above, the example in which the vibration damping member 80 includes the three divided members 801 has been described. On the other hand, in another embodiment of the present invention, the vibration damping member 80 may include two or four or more divided members 801.

  In the tenth and eleventh embodiments described above, an example in which the end elastic member 92 is provided both between the vibration damping member 80 and the housing 20 and between the vibration damping member 80 and the electromagnetic drive unit 60 is shown. It was. On the other hand, in another embodiment of the present invention, the end elastic member 92 is provided on one side between the damping member 80 and the housing 20 or between the damping member 80 and the electromagnetic drive unit 60. Also good.

  Further, in the above-described twelfth, thirteenth, and fourteenth embodiments, the example in which four damping members 87 are provided at equal intervals in the circumferential direction of the tubular member 40 has been described. In contrast, in another embodiment of the present invention, any number of damping members 87 may be provided in the circumferential direction of the tubular member 40, or may be provided at unequal intervals.

  Further, the above-described plurality of embodiments may be combined in any way as long as there are no structural obstruction factors. For example, the seventh embodiment and the second embodiment are combined, and the movement restricting portions 811, 812, 821, and 822 are formed on the first member 81 and the second member 82 that are vertically aligned in the vertical direction. Further, for example, in the high-pressure pump 10 of the fifteenth embodiment, the damping members 80 and 87 shown in the second to fourteenth embodiments may be applied.

  In the above-described embodiment, the housing 20 covers the cylinder 23 that forms the pressurizing chamber 200, covers a part of the cylinder 23 so that the pressurizing chamber 200 is positioned inside, the cylinder 23, the upper housing 21, and the lower housing 22. And a cover opening 35 connecting the inner wall and the outer wall of the cover 30, and one end of the cylindrical member 40 is connected to the upper housing 21 via the cover opening 35. An example of connection is shown. On the other hand, in another embodiment of the present invention, the cover 30 may be provided so as to cover the upper surface of the upper housing 21 and the cylinder 23 without forming the cover opening 35 in the cover 30. In this case, the pressurizing chamber 200 is located outside the cover 30, the fuel chamber 300 is formed between the cover 30, the upper housing 21 and the upper surface of the cylinder 23, and the tubular member 40 is located outside the cover 30. Will be connected.

In another embodiment of the present invention, the high-pressure pump may be applied to an internal combustion engine other than a gasoline engine, such as a diesel engine. Moreover, you may use a high pressure pump as a fuel pump which discharges fuel toward apparatuses other than the engine of a vehicle.
Thus, the present invention is not limited to the above-described embodiment, and can be implemented in various forms without departing from the gist thereof.

DESCRIPTION OF SYMBOLS 10 High pressure pump, 11 Plunger, 20 Housing, 200 Pressurization chamber, 300 Fuel chamber, 40 Cylinder member, 52 Intake valve, 55 Needle, 60 Electromagnetic drive part, 63 Coil, 631 Conductor, 64, 641, 642 Yoke, 80, 87 Damping member

Claims (16)

A housing (20) having a fuel chamber (300) and a pressurizing chamber (200) communicating with the fuel chamber;
A plunger (11) provided so as to be reciprocally movable in the axial direction and capable of pressurizing fuel in the pressurizing chamber;
An intake valve (52) that allows a fuel flow between the fuel chamber and the pressurizing chamber when the valve is opened and shuts off a fuel flow between the fuel chamber and the pressurizing chamber when the valve is closed. )When,
A needle (55) provided with one end positioned inside the housing, the other end positioned outside the housing, and one end capable of contacting or connecting to the suction valve;
A coil (63) provided on the other end side of the needle and formed in a cylindrical shape by winding a conducting wire (631) and provided with a shaft along the axis of the needle, and a coil formed of a magnetic material. A yoke (64, 641, 642) provided to cover the coil, and when the coil is energized, the needle is driven in the valve closing direction or valve opening direction of the suction valve, and the suction valve is closed or An electromagnetic drive (60) that can be opened;
It is formed in a cylindrical shape with a magnetic material, has an outer diameter smaller than the outer diameter of the yoke, and is provided on the radially outer side of the needle so that the shaft follows the axis of the needle, and connects the housing and the electromagnetic drive unit. A cylindrical member (40),
A damping member (80, 87) provided between the housing and the electromagnetic drive unit on a radially outer side of the cylindrical member and capable of suppressing vibration of the electromagnetic drive unit with respect to the housing;
A high pressure pump (10) comprising:   The high-pressure pump according to claim 1, wherein the damping member is made of a nonmagnetic material.   3. The high-pressure pump according to claim 1, wherein at least a part of the damping member is disposed outside a virtual cylindrical surface (Vt <b> 1) including an outer peripheral wall of the coil.   The high-pressure pump according to any one of claims 1 to 3, wherein the damping member is provided so as to be able to contact or connect to the housing or the electromagnetic driving unit.   The high-pressure pump according to any one of claims 1 to 4, wherein the damping member (80) is formed in a cylindrical shape. The vibration damping member has a first member (81) and a second member (82) having an arcuate cross section,
The high-pressure pump according to claim 5, wherein the first member and the second member are provided so as to sandwich the cylindrical member therebetween.   The high-pressure pump according to claim 6, wherein the vibration damping member includes a movement restricting portion (811 to 818, 821 to 828) capable of restricting relative movement between the first member and the second member.   The high-pressure pump according to claim 6, further comprising an intermediate elastic member (91) provided between the first member and the second member and capable of elastic deformation.   The high-pressure pump according to claim 5, wherein the vibration damping member has a notch (85) in a part in a circumferential direction. The vibration damping member has a plurality of divided members (801) provided so as to be aligned in the axial direction of the cylindrical member,
The high-pressure pump according to claim 5, further comprising an intermediate elastic member (93) provided between the plurality of divided members and capable of elastic deformation.   The said damping member (87) is formed in the elongate shape, and two or more are provided around the said cylindrical member so that a longitudinal direction may become parallel with the axis | shaft of the said cylindrical member. The high-pressure pump according to item.   The high-pressure pump according to claim 11, wherein a plurality of the damping members are provided at equal intervals in the circumferential direction of the cylindrical member.   The end elastic member (92) which is provided in at least one between the said damping member and the said housing or between the said damping member and the said electromagnetic drive part, and is further provided with an elastically deformable end part (92). The high pressure pump according to any one of 12.   The high-pressure pump according to any one of claims 1 to 13, wherein the damping member is provided so as to be relatively movable with respect to the cylindrical member.   The high-pressure pump according to any one of claims 1 to 13, wherein the vibration damping member is fixed to the cylinder member so as not to move relative to the cylinder member. The housing covers a pressure chamber forming portion (21, 22, 23) that forms the pressure chamber, and covers at least a part of the pressure chamber forming portion so that the pressure chamber is located inside the pressure chamber. A cover (30) that forms the fuel chamber with the formation part, and a cover opening (35) that connects the inner wall and the outer wall of the cover;
The cylindrical member has one end connected to the pressurizing chamber forming portion via the cover opening,
The high-pressure pump according to any one of claims 1 to 15, wherein the damping member is provided between the cover and the electromagnetic drive unit.

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