JP2015068472A - Pressure buffer device and damping force generating mechanism - Google Patents

Abstract

PROBLEM TO BE SOLVED: To adjust the damping force in a partition member generated in accordance with movement in one direction and another direction with a simple configuration.SOLUTION: A pressure buffer device 1 comprises a cylinder for storing liquid, a piston 30 for partitioning into a first liquid chamber Y1 and a second liquid chamber Y2 storing the liquid in a space in the cylinder, a second oil passage 412 formed in the piston 30 and making liquid flowing from the first liquid chamber Y1 to the second liquid chamber Y2 in accordance with movement of the piston 30 in one axial direction flow in a specific direction, a first oil passage 411 and an inversion oil passage 41R for making the liquid flowing from the second liquid chamber Y2 to the first liquid chamber Y1 in accordance with movement in another axial other direction of the piston 30 flow along a specific direction, a damping valve 42 for controlling flow of the liquid in the second oil passage 412 and the first oil passage 411, and load imparting means that imparts a load to the damping valve 42 in a direction in which the damping valve 42 closes the second oil passage 412 and the first oil passage 411 and is capable of varying the load of the damping valve 42.

Description

  The present invention relates to a pressure buffer device and a damping force generation mechanism.

  Suspension devices for vehicles such as automobiles are equipped with a pressure buffer using a damping force generation mechanism to appropriately reduce vibration transmitted from the road surface to the vehicle body during traveling and improve riding comfort and handling stability. ing. The pressure buffer device includes, for example, a partition member that is movably provided in the cylinder and partitions the inside of the cylinder, a rod member that is connected to the partition member, and a liquid that is provided in the cylinder and moves along with the movement of the partition member. A damping force generating member that provides resistance to the flow and generates a damping force is provided. Further, in the pressure buffer device, a damping force is generated in each partition member as the rod member moves in one direction and the other direction.

  As a prior art described in the publication, as shown in FIG. 14, the shock absorber is partitioned into a lower chamber 94 </ b> A and a reservoir chamber 94 </ b> B by a piston 93 provided at the end of the cylinder 91. The piston 93 is formed in the base 932 of the piston 93, and is provided with a communication hole 931 that allows the lower chamber 94A and the reservoir chamber 94B to communicate with each other, and a valve 95 that can open and close the communication hole 931 to provide a damping force. ing. A technique is disclosed in which the pressing member 96 provided to face the valve 95 moves and the valve 95 is pressed against the base 932 to change the set load of the valve 95 to change the damping force in the attenuator. (For example, refer to Patent Document 1).

JP 7-091476 A

By the way, in the conventional technique described in Patent Document 1, for example, the pressing member is pressed only against a valve provided on one side in the axial direction of the piston to change the damping force. However, in the conventional technique, the damping force cannot be adjusted in the valve disposed on the side where the pressing member is not provided. In other words, even if the damping force of the fluid flow generated by the operation toward one direction of the partition member can be adjusted, the damping force of the fluid flow generated by the operation toward the other direction cannot be adjusted. there were.
In the conventional technique, if the damping force generated along with the movement of the partition member in one direction and the other direction is adjusted, the configuration of the apparatus has to be complicated.

  An object of this invention is to implement | achieve the adjustment of the damping force in the division member which arises with the movement of the one direction and the other direction with a simple structure.

For this purpose, the present invention provides a cylinder for storing liquid and a first liquid chamber and a second liquid chamber which are provided so as to be movable in the axial direction in the cylinder and store the liquid in the space in the cylinder. A partition member that is formed in the partition member, and a first flow path that allows liquid to flow from the first liquid chamber to the second liquid chamber in a specific direction as the partition member moves in one direction in the axial direction; A second flow path formed in the member and configured to flow a liquid from the second liquid chamber toward the first liquid chamber along a specific direction as the partition member moves in the other direction in the axial direction; Control means for controlling the flow of liquid in the first flow path and the second flow path by opening and closing the second flow path, and a load applied to the control means in a direction in which the control means closes the first flow path and the second flow path. And a load applying means configured to change the load of the control means. A pressure damper.
By adopting such a configuration, it is possible to apply a load to the control means in a direction in which both the first flow path and the second flow path are closed only by applying a load to the control means in a single direction by the load applying means. Therefore, it is possible to realize the adjustment of the damping force in the partition member that occurs with the movement in both the one direction and the other direction with a simple configuration.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to implement | achieve adjustment of the damping force in the division member which arises with the movement of the one direction and the other direction with a simple structure.

It is a figure which shows schematic structure of the suspension apparatus of this embodiment. 1 is an overall configuration diagram of a hydraulic shock absorber according to an embodiment. (A) And (b) is a disassembled perspective view of the piston part of Embodiment 1. FIG. FIG. 4 is an enlarged view around a piston portion indicated by an arrow IV in FIG. 2. FIG. 3 is an exploded perspective view of the attenuation unit according to the first embodiment. FIG. 3 is an enlarged view around a bottom valve portion indicated by an arrow VI in FIG. 2. (A) And (b) is a figure for demonstrating operation | movement of a hydraulic shock absorber. FIG. 6 is a diagram for explaining a piston portion of a second embodiment. It is a disassembled perspective view of the attenuation unit of Embodiment 2. FIG. 10 is a diagram for explaining the operation of the hydraulic shock absorber according to the second embodiment. It is a figure for demonstrating the piston part of Embodiment 3. FIG. FIG. 10 is a diagram for explaining the operation of the hydraulic shock absorber according to the third embodiment. It is a figure for demonstrating the piston part of Embodiment 4. FIG. It is a figure for demonstrating the variable structure of the conventional damping force.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
(Embodiment 1)
FIG. 1 is a diagram illustrating a schematic configuration of a suspension device 100 according to the present embodiment.
[Configuration and Function of Suspension Device 100]
As shown in FIG. 1, the suspension device 100 includes a hydraulic shock absorber 1 and a coil spring 2 disposed outside the hydraulic shock absorber 1. In the suspension device 100, the coil spring 2 is held by the spring seat 3 and the spring seat 4 provided at both ends. The suspension device 100 includes a bolt 5 for attachment to a vehicle body and the like, and a wheel side attachment portion 6 provided at a lower portion of the hydraulic shock absorber 1.
In the following description, the lower side in the drawing in the axial direction of the suspension apparatus 100 shown in FIG. 1 is referred to as “one side”, and the upper side in the drawing is referred to as “the other side”.

  Further, the suspension device 100 includes a bump rubber 7 that is press-fitted into the outer periphery of a rod portion 20 (described later) that protrudes from the other side of the hydraulic shock absorber 1. The suspension device 100 includes a bellows-shaped dust cover 8 that covers a part of the end portion of the hydraulic shock absorber 1 and the outer periphery of the rod portion 20 protruding from the hydraulic shock absorber 1. Furthermore, the suspension device 100 includes a plurality of (two in this embodiment) mount rubbers 9 that are arranged in the vertical direction on the upper end side of the rod portion 20 and absorb vibration.

FIG. 2 is an overall configuration diagram of the hydraulic shock absorber 1 of the present embodiment.
[Configuration and function of hydraulic shock absorber 1]
As shown in FIG. 2, the hydraulic shock absorber 1 includes a cylinder portion 10, a rod portion 20 that is provided so that the other side protrudes outside the cylinder portion 10 and one side is slidably inserted into the cylinder portion 10. The piston portion 30 provided at one end portion of the rod portion 20 and the bottom valve portion 50 disposed at the one end portion of the cylinder portion 10 are provided.

(Configuration and function of cylinder part 10)
The cylinder part 10 includes a cylinder 11, an outer cylinder 12 provided outside the cylinder 11, and a damper case 13 provided further outside the outer cylinder 12. The cylinder 11, the outer cylinder 12 and the damper case 13 are arranged concentrically (coaxially).

  The cylinder portion 10 includes a bottom portion 14 that closes one end of the damper case 13 in the axial direction, a rod guide 15 that guides the rod portion 20, oil leakage in the cylinder portion 10, and into the cylinder portion 10. An oil seal 16 for preventing foreign matter from entering, and a bump stopper cap 17 attached to the other end of the damper case 13.

The cylinder 11 (cylinder) is formed in a thin cylindrical shape with one side and the other side opened. One end of the cylinder 11 is closed by the bottom valve portion 50, and the other end is closed by the rod guide 15. The cylinder 11 accommodates oil as an example of a liquid inside.
The cylinder 11 is provided with a piston portion 30 (a damping force generating mechanism) so as to be slidable in the axial direction with respect to the inner peripheral surface. And the piston part 30 partitions into the 1st oil chamber Y1 and the 2nd oil chamber Y2 which accommodate the oil of the space in the cylinder 11. FIG. In the present embodiment, the first oil chamber Y <b> 1 is formed on one side of the piston part 30, and the second oil chamber Y <b> 2 is formed on the other side of the piston part 30.
Further, the cylinder 11 has a cylinder opening 11 </ b> H that opens in the radial direction on the other side and on one side of the rod guide 15. The cylinder opening 11H connects the second oil chamber Y2 of the cylinder 11 and a communication path L described later. The cylinder opening 11H allows oil to flow between the second oil chamber Y2 and the communication path L.

  The outer cylinder 12 is formed in a thin cylindrical shape with one side and the other side opened. The outer cylinder 12 is provided outside the cylinder 11 and inside the damper case 13. In addition, the outer cylinder 12 is arranged such that the inner circumference has a predetermined interval with respect to the outer circumference of the cylinder 11. The outer cylinder 12 forms a communication path L through which oil can flow between the outer cylinder 12 and the cylinder 11. The communication path L is an oil path between the first oil chamber Y1, the second oil chamber Y2, and a reservoir chamber R described later.

  The damper case 13 is formed longer than the cylinder 11 and the outer cylinder 12. And the cylinder 11 and the outer cylinder 12 are accommodated inside in the axial direction and the radial direction. Further, the damper case 13 is arranged with a predetermined interval on the inner periphery with respect to the outer periphery of the outer cylindrical body 12. The damper case 13 forms a reservoir chamber R (liquid reservoir chamber) between the outer casing 12 and the damper case 13. The reservoir chamber R absorbs oil in the cylinder 11 and supplies oil into the cylinder 11 to compensate for the volume of oil corresponding to the forward and backward movement of the rod portion 20.

  The bottom portion 14 is provided at one end portion of the damper case 13 and closes the one end portion of the damper case 13. The bottom portion 14 supports the bottom valve portion 50. Further, the bottom portion 14 supports the cylinder 11 and the outer cylindrical body 12 at one end portion in the axial direction of the damper case 13 via the bottom valve portion 50.

  The rod guide 15 is a thick cylindrical member having an opening 15H at the center. The rod guide 15 is attached to the other end of the cylinder 11 and the outer cylinder 12. And the rod guide 15 supports the rod part 20 so that the movement to an axial direction is possible via the bush 15B provided in the opening part 15H.

The oil seal 16 is a member in which a resin such as rubber is integrated with the inner and outer circumferences of a ring such as a metal, and is fixed to the other end of the damper case 13.
The bump stopper cap 17 is provided so as to cover the outside of the damper case 13 at the other end of the damper case 13. The bump stopper cap 17 protects the other end portion of the hydraulic shock absorber 1 when receiving a collision with the bump rubber 7 (see FIG. 1) during the compression stroke of the suspension device 100.

  And the hydraulic shock absorber 1 of this embodiment is provided with the damping force generation mechanism (piston part 30) which is provided in the cylinder (cylinder 11) which accommodates a liquid and generate | occur | produces damping force, as shown in FIG. . The damping force generation mechanism is provided so as to be movable in the axial direction in the cylinder, and includes a first liquid chamber (first oil chamber Y1) and a second liquid chamber (second oil chamber) that store the liquid in the space in the cylinder. Y2) and a partition member (piston housing 31) that is partitioned into the partition member, and a liquid that moves from the first liquid chamber to the second liquid chamber as the partition member moves in one direction in the axial direction is specified. The first flow path (second oil passage 412) that flows in the direction and the liquid that is formed in the partition member and moves from the second liquid chamber to the first liquid chamber as the partition member moves in the other direction in the axial direction. The second flow path (first oil path 411, reverse flow path 41R) that flows along the specific direction, the first flow path and the second flow path are opened and closed, and the liquid in the first flow path and the second flow path And a control means (attenuation valve 42) for controlling the flow. Furthermore, the hydraulic shock absorber 1 of the present embodiment is configured so that the control means applies a load to the control means in a direction to close the first flow path and the second flow path and is configured to be able to change the load of the control means. (Moving means 23, transmission member 22, preset valve unit 32 and pressing member 43). Hereinafter, these configurations will be described in detail.

(Configuration and function of rod part 20)
The rod portion 20 includes a rod member 21 that is a hollow rod-shaped member, a transmission member 22 provided inside the rod member 21, and a moving means 23 provided on the other side of the rod member 21.

The rod member 21 has a through hole 21H penetrating in the axial direction. Moreover, the rod member 21 has one side attachment part 21a provided in the edge part of one side, and the other side attachment part 21b provided in the edge part of the other side.
The one side attachment portion 21 a is configured by a spiral groove formed on the outer periphery of the rod member 21 and functions as a bolt. And the piston part 30 is attached to the one side attaching part 21a. The other side attachment portion 21 b is configured by a spiral groove formed on the outer periphery of the rod member 21 and functions as a bolt. And the predetermined member for attaching the suspension apparatus 100 to vehicle bodies, such as a motor vehicle, is attached to the other side attachment part 21b.

  The transmission member 22 is a solid rod-shaped member. The outer diameter of the cross section cut in the direction orthogonal to the axial direction of the transmission member 22 is formed smaller than the inner diameter of the through hole 21 </ b> H of the rod member 21. The transmission member 22 is provided so as to be movable in the axial direction inside the rod member 21. Further, the transmission member 22 is provided such that one end portion thereof can come into contact with a later-described spool 321 of the piston portion 30.

  The moving means 23 moves the transmission member 22 and applies a load to a preset valve unit 32 described later via the transmission member 22. Then, as will be described later, a load is applied to the damping valve 42 via the preset valve unit 32. At this time, a direction in which a later-described damping valve 42 receives a load from the preset valve unit 32 is set to a single direction. Therefore, in the present embodiment, as the moving means 23 for applying a load, a means for applying a load only in a single direction to a later-described damping valve 42 is used. Although the mechanism of the moving means 23 for moving the transmission member 22 is not particularly limited, in the present embodiment, for example, a linear actuator that converts the rotational motion of the motor into a linear motion using a mechanism such as a screw is used. Used.

(Configuration and function of piston part 30)
FIG. 3A and FIG. 3B are exploded perspective views of the piston portion 30 of the first embodiment. 3A shows the piston portion 30 as viewed from one side, and FIG. 3B shows the piston portion 30 as viewed from the other side.
FIG. 4 is an enlarged view around the piston portion 30 indicated by the arrow VI in FIG.
FIG. 5 is an exploded perspective view of the attenuation unit 40 of the first embodiment.
As shown in FIG. 3, the piston part 30 includes a piston housing 31 that accommodates the members constituting the piston part 30 and oil inside, a preset valve unit 32 that extends in the axial direction on the other side of the piston housing 31, and It has a check valve unit 33 through which the preset valve unit 32 is passed in the axial direction, a damping unit 40 provided on one side of the preset valve unit 32, and a lock piece 34 provided on one side of the damping unit 40. .

  Further, as shown in FIG. 4, in the piston portion 30 of the present embodiment, in the piston housing 31, the other side oil chamber P <b> 1 partitioned by the preset valve unit 32 and the check valve unit 33, the preset valve unit 32, the check An intermediate oil chamber P2 defined by the valve unit 33 and the damping unit 40 and a one-side oil chamber P3 defined by the damping unit 40 and the lock piece 34 are formed.

  The piston housing 31 is a hollow member that is open on one side and closed on the other side. The piston housing 31 has a connection portion 311 provided at the center portion in the radial direction on the other end and a housing oil passage 312 disposed on the outer side in the radial direction with respect to the connection portion 311. . Further, as shown in FIGS. 3A and 3B, the piston housing 31 includes a piston ring 313 on the outer periphery on the other side.

As shown in FIG. 4, the connecting portion 311 is a through-hole penetrating in the axial direction. Then, one end of the rod portion 20 and the other end of the preset valve unit 32 are inserted into the connection portion 311. The connection portion 311 is screwed to the one side attachment portion 21a (see FIG. 2) of the rod member 21. Further, the inner diameter of the connecting portion 311 is larger than the outer diameter of the receiving portion 321R of the spool 321 described later of the transmission member 22 and the preset valve unit 32. Therefore, in the connection portion 311, the transmission member 22 and the spool 321 are provided so as to be movable in the axial direction.
As shown in FIGS. 3A and 3B, the housing oil passage 312 is formed in a plurality (for example, six in this embodiment) in the circumferential direction. And as shown in FIG. 4, the housing oil path 312 connects the 2nd oil chamber Y2 and the other side oil chamber P1.

  The piston ring 313 is attached to a groove formed on the outer periphery of the piston housing 31. The piston ring 313 is provided in slidable contact with the inner peripheral surface of the cylinder 11. The piston ring 313 reduces the frictional resistance between the cylinder 11 and the piston housing 31.

  The preset valve unit 32 includes a spool 321 extending in the axial direction, a collar 322 attached to the outside of the spool 321 on the other side of the spool 321, and a second collar 323 attached to the outside of the spool 321 on one side of the collar 322. A preset valve 324 (elastic member) attached to the spool 321, a valve stopper 325 provided on one side of the preset valve 324, and a ring 326 attached to one side of the valve stopper 325.

The spool 321 is provided on the other side and receives a transmission member 22, a hollow portion 321 </ b> L formed on one side of the receiving portion 321 </ b> R, and an opening in the radial direction at the other end of the hollow portion 321 </ b> L. A spool opening 321H is provided.
The receiving portion 321R is inserted into the connecting portion 311 of the piston housing 31. And the receiving part 321R is in contact with one end of the transmission member 22. As will be described later, when the transmission member 22 receives a load, the entire spool 321 moves by receiving the load from the transmission member 22 at the receiving portion 321R. The hollow portion 321L is connected to the spool opening portion 321H on the other side, opens on one side, and communicates with a later-described bolt opening portion 442 of the damping unit 40. The hollow portion 321L allows oil to flow between the other-side oil chamber P1 and the bolt opening 442. The spool opening 321H connects the hollow part 321L and a collar opening 322H described later.

The collar 322 is a member formed in a substantially cylindrical shape. The collar 322 is screwed to the spool 321. The collar 322 includes a collar opening 322H that opens in the radial direction, and a contact portion 322J that is provided at one end.
The collar opening 322H is provided to face the spool opening 321H, and communicates the other-side oil chamber P1 and the spool opening 321H. The contact portion 322J is a portion formed with a larger outer diameter than other portions of the collar 322. The contact portion 322J is in contact with the other end portion of the second collar 323.

  The second collar 323 has a valve contact portion 323 </ b> V having a larger outer diameter on one side compared to other portions of the second collar 323. The second collar 323 contacts the contact portion 322J of the collar 322 on the other side, and contacts the preset valve 324 at the valve contact portion 323V on the other side.

  The preset valve 324 is configured by superimposing a plurality of disk-shaped metal plates having openings 324B through which the spool 321 is passed. The preset valve 324 is sandwiched between the second collar 323 and the valve stopper 325 and fixed to the spool 321.

The valve stopper 325 presses the preset valve 324 from one side toward the valve contact portion 323V of the second collar 323.
The ring 326 is attached to a groove formed on the outer periphery of the spool 321. The ring 326 fixes the valve stopper 325 in the axial direction. The ring 326 is fixed on one side of the spool 321, and the collar 322 is fixed on the other side of the spool 321. As a result, the second collar 323, the preset valve 324, and the valve stopper 325 sandwiched between the spool 321 and the ring 326 are fixed to the spool 321. Accordingly, the spool 321, the collar 322, the second collar 323, the preset valve 324, the valve stopper 325, and the ring 326 move together in the axial direction when receiving a load from the transmission member 22 as will be described later.

  The check valve unit 33 is provided on one side of the check valve seat 331, a check valve 332 provided on the other side of the check valve seat 331, a holding bolt 333 and a nut 334 for holding these members. And a lock nut 335.

The check valve seat 331 is a member formed in a substantially disc shape. Then, the check valve seat 331 is attached so that the other end of the step 31C formed on the inner periphery of the piston housing 31 is hooked.
Further, the check valve seat 331 has an opening 331H formed at the center and a plurality of oil passages 331R formed in the axial direction. The spool 321 and the second collar 323 are inserted into the opening 331H. The oil passage 331R forms an oil passage between the other-side oil chamber P1 and the intermediate oil chamber P2.

  The check valve 332 is a disk-shaped metal plate material having a bolt hole 332 </ b> B through which the spool 321 and the second collar 323 pass in the center. The check valve 332 is pressed against the other end of the check valve seat 331 by the holding bolt 333. The check valve 332 has an inner diameter and an outer diameter that can cover the other end of the oil passage 331R of the check valve seat 331.

The holding bolt 333 and the nut 334 sandwich and hold the check valve seat 331 and the check valve 332.
The lock nut 335 has a threaded portion that fits into a thread groove formed on the inner periphery of the piston housing 31 on the outer periphery. The lock nut 335 presses the check valve seat 331 from the one side toward the step portion 31C on the other side. The lock nut 335 fixes the entire check valve unit 33 by fixing the check valve seat 331 in the axial direction.

  The damping unit 40 includes a valve seat 41 having a plurality of oil passages, a damping valve 42 (control means, control member) provided on the other side of the valve seat 41, and a pressing member 43 (on the other side of the damping valve 42). Contact member) and holding bolts 44 and nuts 45 for holding these members.

  The valve seat 41 is a member formed in a bottomed cylindrical shape having an opening 41H that opens toward one side on the inside. Further, the valve seat 41 has a step portion 41C on the outer periphery. Further, the valve seat 41 includes a bolt hole 413 formed in the axial direction for passing the holding bolt 44, a first oil passage 411 formed in the axial direction outside the bolt hole 413 in the radial direction, And a second oil passage 412 formed in the axial direction on the further outer side in the radial direction than the first oil passage 411.

The opening 41 </ b> H forms a reverse oil passage 41 </ b> R that is a space defined by the recess 343 of the lock piece 34. The reverse oil passage 41 </ b> R connects a bolt opening 442 (described later) of the holding bolt 44 and the first oil passage 411. And the inversion oil path 41R has the function to reverse the direction of the flow of the oil which flowed in, for example from the other side, and to flow to the other side.
As shown in FIG. 5, the stepped portion 41 </ b> C is a portion formed by making the outer diameter of one side larger than the other side of the valve seat 41. Then, as shown in FIG. 4, the stepped portion 41 </ b> C is hung from one side on a stopper ring 414 that is mounted in a groove formed on the inner periphery of the piston housing 31.

  As shown in FIG. 5, a plurality of first oil passages 411 and second oil passages 412 are formed at equal intervals in the circumferential direction. The other end portions of the first oil passage 411 and the second oil passage 412 are arranged in the radial direction on the other side of the valve seat 41, respectively.

The first oil passage 411 has a smaller cross section than the second oil passage 412, and is provided with a larger number (for example, twelve in this embodiment) than the second oil passage 412. As shown in FIG. 4, the first oil passage 411 has one side communicating with the reverse oil passage 41R and the other side communicating with the intermediate oil chamber P2. The first oil passage 411 forms an oil passage between the reversal oil passage 41R that flows according to the open / close state of the damping valve 42 and the intermediate oil chamber P2.
As shown in FIG. 5, the second oil passage 412 has a larger cross section than the first oil passage 411 and is provided with a smaller number (for example, six in this embodiment) than the first oil passage 411. Further, as shown in FIG. 4, the second oil passage 412 has one side communicating with the one side oil chamber P3 and the other side communicating with the intermediate oil chamber P2. The second oil passage 412 forms an oil passage between the one-side oil chamber P3 and the intermediate oil chamber P2 that flows according to the open / close state of the damping valve 42.

  As shown in FIG. 5, the damping valve 42 is a metal plate formed in an annular shape having a bolt hole 42 </ b> B through which the holding bolt 44 passes at the center. As shown in FIG. 4, the damping valve 42 is pressed against the other end of the valve seat 41 by a holding bolt 44. Further, the damping valve 42 has an inner diameter and an outer diameter that can cover the other ends of the first oil passage 411 and the second oil passage 412 of the valve seat 41. The damping valve 42 opens and closes the first oil passage 411 and the second oil passage 412 according to the oil flow.

As shown in FIG. 5, the pressing member 43 is a member formed in a substantially cylindrical shape. As shown in FIG. 4, the pressing member 43 is supported by an after-mentioned guide portion 441 of the holding bolt 44 so as to be slidable in the axial direction. The pressing member 43 includes a first pressing portion 431 and a second pressing portion 432 having a cross section divided into two on one side, and a contacted portion 433 formed on the other side.
The first pressing portion 431 and the second pressing portion 432 are portions that are pressed against the other side of the damping valve 42. The first pressing portion 431 is provided at a position facing the first oil passage 411 in the damping valve 42. The second pressing portion 432 is provided at a position facing the second oil passage 412 in the damping valve 42. The contacted portion 433 has an outer diameter substantially equal to the outer diameter of the preset valve 324 and forms a portion that receives contact with the preset valve unit 32.

In the present embodiment, the preset valve unit 32 is configured such that the pressing member 43 applies a load to the damping valve 42 via the preset valve 324. Therefore, the pressing member 43 is configured to apply a constant load to the damping valve 42 by the load applied from the preset valve unit 32. In particular, in the present embodiment, the damping valve 42 is configured to be constantly pressed by the elastic force of the preset valve 324 via the pressing member 43.
In addition, the damping force generated by the damping valve 42 can be changed by changing the load applied to the damping valve 42 by the preset valve unit 32 via the pressing member 43. The variable damping force of the damping valve 42 will be described in detail later.

  As shown in FIG. 5, the pressing member 43 is provided with a plurality of openings 434 that open in the radial direction. These openings 434 form an oil flow path to the outside of the pressing member 43 with respect to the space formed by the pressing member 43 and other members. Then, when adjusting the damping force by moving the pressing member 43 as described later, the movement of the pressing member 43 is not affected by the pressure difference between the inside and outside of the pressing member 43, or the pressing member 43 is Friction is reduced by supplying oil between the contacting members.

  As shown in FIG. 4, the holding bolt 44 and the nut 45 sandwich and hold the valve seat 41 and the damping valve 42. Further, the holding bolt 44 has a guide portion 441 and a bolt opening 442. The guide portion 441 has an outer diameter substantially equal to the inner diameter of the contacted portion 433 of the pressing member 43. And the guide part 441 guides the pressing member 43 so that the movement to an axial direction is possible. The bolt opening 442 is a through hole formed in the axial direction of the holding bolt 44. One end of the spool 321 is inserted into the other side of the bolt opening 442. Further, the bolt opening 442 communicates with the reversal oil passage 41R on one side.

  In the first embodiment, the second oil passage 412 of the valve seat 41 functions as a “first flow passage”, and the first oil passage 411 and the reverse oil passage 41R of the valve seat 41 function as a “second flow passage”. To do.

As shown in FIGS. 3A and 3B, the lock piece 34 has a protruding portion 341 on the other side and a large-diameter portion 342 having an outer diameter larger than that of the protruding portion 341 on one side.
The protruding portion 341 is a portion protruding in the axial direction toward one side. The protruding portion 341 is inserted inside the opening 41H of the valve seat 41. Further, the protrusion 341 is formed with a recess 343 that is recessed in the axial direction forming the above-described reversal oil passage 41R. In this embodiment, the recess 343 has a surface facing the other side, and the surface facing the other side reverses the flow of oil flowing from the other side to the other side.
As shown in FIGS. 3A and 3B, the large diameter portion 342 has a plurality of oil passages 344 formed in the circumferential direction. The oil passage 344 forms an oil passage between the first oil chamber Y1 and the one-side oil chamber P3. Further, the large diameter portion 342 is formed with a screw portion that fits into a screw groove formed in the piston housing 31.
As shown in FIG. 4, the lock piece 34 presses the valve seat 41 from one side toward the stopper ring 414 on the other side. The lock piece 34 fixes the entire damping unit 40 in the axial direction by fixing the valve seat 41.

(Configuration and function of bottom valve unit 50)
FIG. 6 is an enlarged view around the bottom valve portion 50 indicated by the arrow VI in FIG.
As shown in FIG. 6, the bottom valve unit 50 includes a first valve body 51 having a plurality of oil passages, a pressure side valve 521 provided on one side of the first valve body 51, and the other side of the first valve body 51. An extension side valve 522, a valve stopper 53 that is positioned on the other side of the extension side valve 522 and presses the extension side valve 522, and a bolt 56 and a nut 57 that hold these members. The bottom valve portion 50 has a plurality of oil passages, a second valve body 54 disposed on one side of the first valve body 51, and a check valve 55 provided on one side of the second valve body 54. Have Further, the bottom valve portion 50 has a base member 58 disposed on one side of the check valve 55.
And the bottom valve part 50 is provided in the edge part of the one side of the hydraulic shock absorber 1, and divides the reservoir chamber R and the 1st oil chamber Y1.

  The first valve body 51 has a substantially disk-shaped disk-shaped part 51a, and is formed to extend in the axial direction from the outer peripheral edge of the disk-shaped part 51a toward one side, and has a larger outer diameter than the disk-shaped part 51a. And a cylindrical portion 51b. The first valve body 51 is attached to one end of the cylinder 11 and the outer cylinder 12.

  In the disc-like portion 51a, a bolt hole 511B formed in the axial direction for passing the bolt 56, a first oil passage 511 formed in the axial direction outside the bolt hole 511B in the radial direction, and a first oil And a second oil passage 512 formed in the axial direction outside the passage 511 in the radial direction. A plurality of first oil passages 511 and second oil passages 512 are formed at equal intervals in the circumferential direction, and communicate between the first oil chamber Y1 and a space 511S described later.

The cylindrical portion 51b forms a space 511S inside the cylinder. A second valve body 54 is provided in the space 511S. Furthermore, an opening 511H that opens in the radial direction is provided at one end of the cylindrical portion 51b. The opening 511 </ b> H is provided to face the outer cylinder 12. And the flow path of the oil which flows toward the connection path L through the groove | channel 511T from the inner side of the space 511S is formed.
In addition, the first valve body 51 has a groove 511T formed in the axial direction on the outer circumference of the disc-like portion 51a and the cylindrical portion 51b. The groove 511 </ b> T is disposed to face the communication path L formed between the cylinder 11 and the outer cylinder 12. The groove 511 </ b> T allows oil to flow with the first valve body 51 sandwiched at one end of the communication path L.

The compression side valve 521 is configured by overlapping a plurality of disc-shaped metal plates in which bolt holes 521B through which the bolts 56 are passed are formed. Further, the pressure side valve 521 can block the first oil passage 511, and the second oil passage 512 has an outer diameter that does not block. The pressure side valve 521 enables opening and closing of one side of the first oil passage 511 formed in the first valve body 51 and always opens one side of the second oil passage 512.
The expansion side valve 522 is a disk-shaped metal plate material in which a bolt hole 522B through which the bolt 56 is passed is formed. Further, the expansion side valve 522 has an oil hole 522H formed at a position corresponding to the first oil passage 511. The expansion side valve 522 always opens the other side of the first oil passage 511 formed in the first valve body 51 and allows the other side of the second oil passage 512 to be opened and closed.

The second valve body 54 has a protruding portion 54a formed on one side and a concave portion 54b formed on the other side. The second valve body 54 is attached by inserting a recess 54 b into the space 511 </ b> S of the first valve body 51.
The second valve body 54 has a through hole 54H penetrating in the axial direction in the protruding portion 54a, and an oil passage 541 disposed radially outside the through hole 54H and penetrating in the axial direction.

  The check valve 55 is a disk-shaped metal plate material in which an opening 55B through which the protruding portion 54a of the second valve body 54 passes is formed. The check valve 55 can open and close one side of the oil passage 541 of the second valve body 54.

The base member 58 includes a first opening 58H1 that is open on the other side, a second opening 58H2 that is open on the one side, and a third opening 58H3 that opens in the radial direction on one side.
The first opening 58H1 has an inner diameter substantially equal to the outer diameter of the protrusion 54a of the second valve body 54, and the protrusion 54a is inserted therein. The second opening 58H2 has an inner diameter larger than that of the first opening 58H1, and forms a space 58S through which oil flows between the bottom opening 14 and the damper case 13. Further, the through hole 54H of the second valve body 54 communicates with the second opening 58H2. The third opening 58H3 communicates the second opening 58H2 and the reservoir chamber R.

[Operation of hydraulic shock absorber 1]
FIG. 7A and FIG. 7B are diagrams for explaining the operation of the hydraulic shock absorber 1. FIG. 7A is a diagram showing the oil flow during the compression stroke, and FIG. 7B is a diagram showing the oil flow during the expansion stroke.
First, the flow of oil during the compression stroke of the hydraulic shock absorber 1 will be described.
As shown in FIG. 7A, when the piston part 30 moves to one side in the axial direction with respect to the cylinder part 10 as indicated by a white arrow, the oil in the first oil chamber Y1 is moved by the movement of the piston part 30. Is pushed, and the pressure in the first oil chamber Y1 rises.

  Then, the oil flows from the oil passage 344 of the lock piece 34 to the one-side oil chamber P3 by the pressure of the oil in the first oil chamber Y1 that is increased by the movement of the piston portion 30 in one axial direction. Further, the oil flows from the one side oil chamber P3 to the second oil passage 412 of the damping unit 40. Thus, the damping valve 42 bends against the pressing force received from the pressing member 43 by the pressure increased by the oil flowing in the specific direction from one side of the axial direction to the other side in the second oil passage 412. Mu Then, the oil in the second oil passage 412 flows into the intermediate oil chamber P2 while pushing the damping valve 42 open. A damping force is generated by the resistance generated when the oil flows through the second oil passage 412 and the damping valve 42.

Further, the oil that has flowed into the intermediate oil chamber P <b> 2 flows into the oil passage 331 </ b> R of the check valve unit 33. The check valve 332 is bent by the oil pressure that increases in the oil passage 331R. Then, the oil in the oil passage 331R flows into the other oil chamber P1 while pushing the check valve 332 open. Furthermore, the oil that has flowed into the other oil chamber P1 flows through the housing oil passage 312 of the piston housing 31 to the second oil chamber Y2.
As described above, as the piston part 30 moves in one direction, an oil flow from the first oil chamber Y1 to the second oil chamber Y2 is generated, and the second oil passage 412 and the damping valve are generated in the oil flow. A damping force is generated by controlling with resistance provided by 42.

  Further, in the bottom valve portion 50, the first valve body passes through the oil hole 522H of the expansion side valve 522 by the oil pressure in the first oil chamber Y1 increased by the movement of the piston portion 30 in one axial direction. The oil flows through the first oil passage 511 of the 51. Then, the pressure side valve 521 is bent by the pressure of the oil increased in the first oil passage 511, and the oil flows from the first oil passage 511 to the space 511S while pushing the pressure side valve 521 open. Further, the oil that has flowed into the space 511 </ b> S flows into the oil passage 541 of the second valve body 54. The check valve 55 bends due to the oil pressure increased in the oil passage 541. Then, the oil flows from the oil passage 541 to the communication passage L through the opening 511H and the groove 511T while pushing the check valve 55 open. The oil that has flowed into the communication path L flows into the second oil chamber Y2 from a cylinder opening 11H (see FIG. 2) formed on the other side of the cylinder 11.

  Further, in the bottom valve portion 50, the oil that has flowed into the space 511 </ b> S flows into the through hole 54 </ b> H of the second valve body 54. The oil that has flowed into the through hole 54H flows into the space 58S. Furthermore, oil flows from the space 58S to the reservoir chamber R through the third opening 58H3.

Next, the flow of oil during the extension stroke of the hydraulic shock absorber 1 will be described.
As shown in FIG. 7B, when the piston part 30 moves to the other side in the axial direction with respect to the cylinder part 10 as indicated by a white arrow, the oil in the second oil chamber Y2 is moved by the movement of the piston part 30. Is pushed, and the pressure in the second oil chamber Y2 rises.
Note that even if oil tries to flow from the cylinder opening 11H (see FIG. 2) through the communication path L, the check valve 55 does not open the oil path 541 because the oil flow is in the direction of closing the check valve 55. Therefore, no oil flows from the second oil chamber Y2 to the first oil chamber Y1 through the communication path L.

The oil flows from the housing oil passage 312 of the piston housing 31 to the other side oil chamber P1 by the pressure of the oil in the second oil chamber Y2 increased by the movement of the piston portion 30 toward the other side in the axial direction. Further, oil flows from the other side oil chamber P1 to the hollow portion 321L through the collar opening 322H and the spool opening 321H.
Note that the pressure of the other side of the check valve 332 of the check valve unit 33 is relatively higher than the one side where the oil passage 331R is located due to the oil flowing into the other side oil chamber P1. Therefore, the check valve 332 does not open the oil passage 331R, and no oil flows through the check valve unit 33.

Then, the oil that has flowed into the hollow portion 321L flows through the bolt opening 442 to the reversal oil passage 41R. Thus, the oil that has flowed in the direction from the other side in the axial direction to the one side is reversed in the reverse oil passage 41R and flows in the direction from the one side in the axial direction to the other side. Then, the oil flows from the reverse oil passage 41R to the first oil passage 411 of the valve seat 41 along the flow in a specific direction in the second oil passage 412 during the compression stroke described above.
The damping valve 42 bends against the pressing force received from the pressing member 43 by the oil pressure increased in the first oil passage 411. Then, the oil in the first oil passage 411 flows into the intermediate oil chamber P2 while pushing the damping valve 42 open. A damping force is generated by the resistance generated when oil flows through the first oil passage 411 and the damping valve 42.

Note that negative pressure is generated in the first oil chamber Y <b> 1 as the piston portion 30 moves in the other direction. Further, as described above, the first oil passage 411 is bent so that the damping valve 42 is opened from the inside in the radial direction, so that the outside of the damping valve 42 is also opened, and the other side of the second oil passage 412 is also opened. It has become. Therefore, the oil that has flowed into the intermediate oil chamber P2 flows into the adjacent second oil passage 412. Then, the oil flows from the second oil passage 412 to the one side oil chamber P3. Further, the oil that has flowed into the one-side oil chamber P3 flows through the oil passage 344 to the first oil chamber Y1.
As described above, with the movement of the piston portion 30 in the other direction, an oil flow from the second oil chamber Y2 to the first oil chamber Y1 is generated, and the first oil passage 411 and the damping valve are generated in the oil flow. A damping force is generated by controlling with resistance provided by 42.

[Variation of damping force]
Subsequently, the change of the damping force in the hydraulic shock absorber 1 will be described.
For example, as shown in FIG. 2, the transmission member 22 is pushed into the one side by a certain amount by the moving means 23. As shown in FIG. 4, the spool 321 moves to one side by the movement of the transmission member 22 to one side. Along with this, the preset valve 324 fixed to the spool 321 is pushed into one side. The pressing member 43 applies a load to the damping valve 42 from the other side to the one side by moving the pressing member 43 to one side while the preset valve 324 is elastically deformed. In the present embodiment, the damping valve 42 opens the first oil passage 411 or the second oil passage 412 by bending toward the other side. Therefore, the load that the pressing member 43 applies the damping valve 42 from the other side to the one side is increased, so that the damping valve 42 is difficult to open.

  On the other hand, the transmission member 22 is pulled out to the other side by the moving means 23. Then, the spool 321 moves to the other side by the movement of the transmission member 22 to the other side. As a result, the load applied to the pressing member 43 by the preset valve 324 fixed to the spool 321 decreases. As a result, the load applied by the pressing member 43 to the damping valve 42 is reduced, so that the damping valve 42 is easily opened.

  As described above, in the present embodiment, by moving the transmission member 22, the load applied by the pressing member 43 to the damping valve 42 is changed, and the ease of deformation of the damping valve 42 is adjusted, thereby changing the hydraulic pressure. The damping force in the shock absorber 1 can be changed.

  In the present embodiment, a single damping valve 42 generates a damping force in the oil flow in the extension stroke and the compression stroke. Further, by simply moving the transmission member 22 and the like in only one direction relative to the single damping valve 42, it is possible to collectively adjust the damping force in the flow in both the expansion stroke and the compression stroke. Therefore, the device configuration for adjusting the damping force is simplified. Thus, in the hydraulic shock absorber 1 of the present embodiment, adjustment of the damping force in the piston portion 30 that occurs in association with movement in both the one direction and the other direction of the piston portion 30 can be realized with a simple configuration.

  Further, as shown in FIGS. 3A and 3B, the hydraulic shock absorber 1 according to the present embodiment has the above-described preset valve unit 32, check valve unit 33, and damping unit from one side of the piston housing 31. Since it can be easily assembled simply by inserting 40 in order and fixing by the lock piece 34, it is excellent also in assemblability.

  Furthermore, in this embodiment, since the moving amount of the transmission member 22 can be changed continuously instead of stepwise, the strength of the damping force can be changed continuously. Further, in this embodiment, the valve opening load of the damping valve 42 is not transmitted by the pressure between the actual members of the transmission member 22, the preset valve unit 32, the pressing member 43, and the damping valve 42, for example, instead of transmission of pressure such as liquid. Therefore, the response speed when controlling the damping force can be increased.

Further, in the first embodiment, by using the damping valve 42 formed in a substantially annular shape, the pressure receiving areas that receive the oil pressure in the damping valve 42 can be made equal in both the expansion stroke and the compression stroke. it can. Accordingly, it is possible to easily set the damping force in both the expansion stroke and the compression stroke.
In other words, since the damping valve 42 according to the first embodiment can perform the damping force operation in both the expansion stroke and the compression stroke, the check valve 76 provided in the hydraulic shock absorber 1 according to the second embodiment described later is provided. Can be eliminated.

(Embodiment 2)
Next, the hydraulic shock absorber 1 according to the second embodiment will be described. The hydraulic shock absorber 1 according to the second embodiment is different in configuration from the piston portion 30 according to the first embodiment. In the following, members similar to those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 8 is a view for explaining the piston part 60 of the second embodiment.
FIG. 9 is an exploded perspective view of the attenuation unit 70 of the second embodiment.

As shown in FIG. 8, the piston portion 60 includes a piston housing 31, a preset valve unit 32, a check valve unit 33, a damping unit 70 provided on one side of the preset valve unit 32, and a lock piece 34. doing.
The damping unit 70 includes a valve seat 71 having a plurality of oil passages, a damping valve 72 (control means, control member) provided on the other side of the valve seat 71, and a pressing member 73 provided on the other side of the damping valve 72. The holding bolt 74 and the nut 75 for holding these members, and the check valve 76 provided on one side of the valve seat 71 are provided.

  The valve seat 71 is a member formed in a bottomed cylindrical shape having an opening 71H that opens toward one side on the inside. Further, the valve seat 71 has a stepped portion 71C on the outer periphery. The opening 71H and the stepped portion 71C have the same functions as the opening 41H and the stepped portion 41C of the first embodiment. The opening 71H forms a reverse oil passage 71R that is a space defined by a recess 343 of the lock piece 34 described later.

  Further, the valve seat 71 includes a bolt hole 713 formed in the axial direction for passing the holding bolt 74, an inner oil passage 710 formed in the axial direction outside the bolt hole 713 in the radial direction, and an inner oil The first oil passage 711 and the second oil passage 712 are formed in the axial direction on the further outer side in the radial direction than the passage 710. Further, the first oil passage 711 and the second oil passage 712 are disposed at substantially equal distances from the center in the radial direction.

  As shown in FIG. 9, a plurality of inner oil passages 710 are formed at equal intervals in the circumferential direction. A plurality of first oil passages 711 and second oil passages 712 are also formed at equal intervals in the circumferential direction. Further, the first oil passage 711 and the second oil passage 712 are alternately arranged in the circumferential direction.

  The inner oil passage 710 has a smaller cross section than the first oil passage 711 and the second oil passage 712, and is provided with more numbers (for example, 12 in this embodiment) than the first oil passage 711 or the second oil passage 712. . As shown in FIG. 8, the inner oil passage 710 has one side communicating with the reverse oil passage 71R and the other side communicating with the intermediate oil chamber P2. The inner oil passage 710 forms an oil passage between the reversal oil passage 71R that flows according to the open / close state of the damping valve 72 and the intermediate oil chamber P2.

The first oil passage 711 and the second oil passage 712 have a larger cross section than the inner oil passage 710 and are provided in fewer numbers (for example, six in this embodiment) than the inner oil passage 710.
As shown in FIG. 9, one side of the first oil passage 711 is recessed in the axial direction from the end on one side of the second oil passage 712, and the other side is from the end on the other side of the second oil passage 712. Also protrudes in the axial direction. Further, as shown in FIG. 8, the first oil passage 711 can communicate with one side oil chamber P3 on one side and communicate with the intermediate oil chamber P2 on the other side. The first oil passage 711 forms an oil passage between the one-side oil chamber P3 and the intermediate oil chamber P2 that flows according to the open / close state of the damping valve 72.

  As shown in FIG. 9, the second oil passage 712 has one side protruding in the axial direction from one end portion of the first oil passage 711, and the other side having a shaft more than the other end portion of the first oil passage 711. It is depressed in the direction. Further, as shown in FIG. 8, the second oil passage 712 can communicate with one side oil chamber P3 on one side and with the intermediate oil chamber P2 on the other side. The second oil passage 712 forms an oil passage between the one-side oil chamber P3 and the intermediate oil chamber P2 that flows according to the open / close state of the damping valve 72.

  In the second embodiment, the first oil passage 711 of the valve seat 71 functions as a “first flow passage”, and the inner oil passage 710 and the reverse oil passage 71R of the valve seat 71 function as a “second flow passage”. .

As shown in FIG. 9, the damping valve 72 is a disk-shaped metal plate material having a bolt hole 72 </ b> B through which the holding bolt 74 is passed at the center. Further, the damping valve 72 has a concave portion 721 and a convex portion 722 formed on the outer peripheral portion, and an annular portion 723 inside the radial direction of the concave portion 721 and the convex portion 722.
As shown in FIG. 9, the damping valve 72 is formed so that the concave portion 721 faces the second oil passage 712, and the convex portion 722 can cover the other end of the first oil passage 711. It has a diameter. The annular portion 723 has a radial width that can cover the other end of the inner oil passage 710.
The damping valve 72 is pressed against the other end of the valve seat 71 by the holding bolt 74. The damping valve 72 always opens the other end of the second oil passage 712, and opens and closes the other end of the inner oil passage 710 and the first oil passage 711 according to the flow of oil.

  As shown in FIG. 9, the check valve 76 is a disk-shaped metal plate material having a bolt hole 76 </ b> B through which the protruding portion 341 of the lock piece 34 passes at the center. In addition, the check valve 76 has an outer diameter that can cover one end of the second oil passage 712 of the valve seat 41. The check valve 76 is pressed against one end of the valve seat 71 by the lock piece 34. The check valve 76 opens and closes one end of the second oil passage 712 according to the oil flow. Further, the check valve 76 always opens an end portion on one side of the first oil passage 711 that is recessed in the axial direction on one side of the valve seat 71.

The pressing member 73 is a member formed in a substantially cylindrical shape. The pressing member 73 is supported so as to be slidable in the axial direction by a later-described guide portion 741 of the holding bolt 74. Further, as shown in FIG. 9, the pressing member 73 includes a first pressing portion 731 and a second pressing portion 732 that are divided into two sections on one side, a contacted portion 733 provided on the other side, and a radius. And a plurality of openings 734 that open in the direction.
The first pressing portion 731 and the second pressing portion 732 are portions that are pressed against the other side of the damping valve 72. The first pressing portion 731 is provided at a position facing the inner oil passage 710 in the damping valve 72. In addition, the second pressing portion 732 is provided at a position facing the first oil passage 711 and the second oil passage 712 in the damping valve 72. The contacted portion 733 has an outer diameter substantially equal to the outer diameter of the preset valve 324 and constitutes a portion that receives the contact of the preset valve unit 32.

  The holding bolt 74 and the nut 75 sandwich and hold the valve seat 71 and the damping valve 72. In addition, the holding bolt 74 has a guide portion 741 and a bolt opening 742. The guide part 741 has an outer diameter substantially equal to the inner diameter of the contacted part 733 of the pressing member 73. And the guide part 741 guides the pressing member 73 inside the pressing member 73 so that the movement to an axial direction is possible. The bolt opening 742 is a through hole formed in the axial direction of the holding bolt 74. One end of the spool 321 is inserted into the other side of the bolt opening 742. Further, one side of the bolt opening 742 communicates with the reverse oil passage 71R.

[Operation of Hydraulic Shock Absorber 1 of Embodiment 2]
FIG. 10 is a diagram for explaining the operation of the hydraulic shock absorber 1 according to the second embodiment.
In the following description, the flow of oil in the piston part 60 having a configuration different from that of the first embodiment will be mainly described. In FIG. 10, the oil flow during the compression stroke is indicated by a solid arrow, and the oil flow during the expansion stroke is indicated by a dashed arrow.
First, the flow of oil during the compression stroke of the hydraulic shock absorber 1 will be described.
Oil flows from the oil passage 344 of the lock piece 34 to the one-side oil chamber P3 due to the pressure of the oil in the first oil chamber Y1 increased by the movement of the piston portion 60 in the axial direction. Further, the oil flows from the one side oil chamber P3 to the first oil passage 711 of the damping unit 70. Thus, the convex portion 722 (see FIG. 9) of the damping valve 72 is pressed against the pressing member 43 by the pressure increased by the oil flowing in the specific direction from the one side to the other side in the axial direction in the first oil passage 711. Bends against the pressing force received from. Then, the oil in the first oil passage 711 flows into the intermediate oil chamber P2 while pushing the damping valve 72 open. A damping force is generated by the resistance generated when oil flows through the first oil passage 711 and the damping valve 72.
Of the oil that has flowed into the one-side oil chamber P3, the oil that has flowed into the second oil passage 712 flows in the direction in which the check valve 76 is closed. Accordingly, the check valve 76 keeps the second oil passage 712 closed, and no oil flows through the second oil passage 712.

  The subsequent oil flow is the same as in the first embodiment. As described above, with the movement of the piston portion 30 in one direction, an oil flow from the first oil chamber Y1 to the second oil chamber Y2 is generated, and the first oil passage 711 and the oil flow are generated in the oil flow. A damping force is generated by controlling the damping valve 72 with resistance.

Next, the flow of oil during the extension stroke of the hydraulic shock absorber 1 will be described.
Oil flows from the housing oil passage 312 of the piston housing 31 to the other side oil chamber P1 due to the pressure of the oil in the second oil chamber Y2 increased by the movement of the piston portion 60 in the other axial direction. Further, oil flows from the other side oil chamber P1 to the hollow portion 321L through the collar opening 322H and the spool opening 321H.

Further, the oil that has flowed into the hollow portion 321L flows through the bolt opening 742 into the reverse oil passage 71R. Thus, the oil that has flowed in the direction from the other side in the axial direction to the one side is reversed in the reverse oil passage 71R and flows in the direction from the one side in the axial direction to the other side. Then, the oil flows from the reverse oil passage 71R to the inner oil passage 710 of the valve seat 71 along the flow in the specific direction in the first oil passage 711 during the compression stroke described above.
The oil pressure increased in the inner oil passage 710 is received by the annular portion 723 (see FIG. 9) of the damping valve 72, and the damping valve 72 bends against the pressing force received from the pressing member 73. Then, the oil in the inner oil passage 710 flows into the intermediate oil chamber P2 while pushing the damping valve 72 open. A damping force is generated by the resistance generated when oil flows through the inner oil passage 710 and the damping valve 72.

Here, when the piston part 60 moves in the other direction, a negative pressure is generated in the first oil chamber Y1. On the other hand, since the pressure of the oil in the other side oil chamber P1 is increasing, the check valve 332 is not opened. Further, the recess 721 (see FIG. 9) of the damping valve 72 is opposed to the other end of the second oil passage 712, and the other side of the second oil passage 712 is not blocked. Therefore, when the pressure of the oil in the intermediate oil chamber P2 increases, the oil that has flowed into the intermediate oil chamber P2 flows into the adjacent second oil passage 712. Then, the oil flows from the second oil passage 712 to the one side oil chamber P3. Further, the oil that has flowed into the one-side oil chamber P3 flows through the oil passage 344 to the first oil chamber Y1.
As described above, with the movement of the piston portion 60 in the other direction, an oil flow from the second oil chamber Y2 to the first oil chamber Y1 is generated, and the inner oil passage 710 and the damping valve 72 are generated in the oil flow. A damping force is generated by controlling with resistance.

  In the hydraulic shock absorber 1 to which the second embodiment is applied, the load applied to the damping valve 72 by the preset valve 324 and the pressing member 73 can be changed by moving the transmission member 22 to one side. And it is possible to collectively change the damping force in the flow in both directions of the extension stroke and the compression stroke.

(Embodiment 3)
Next, the hydraulic shock absorber 1 according to the third embodiment will be described. The hydraulic shock absorber 1 according to the third embodiment is different from the piston portion 30 according to the first embodiment in configuration. In the following, members similar to those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
FIG. 11 is a view for explaining the piston portion 80 of the third embodiment.

As shown in FIG. 11, the piston portion 80 is provided on the piston housing 31, the preset valve unit 82, the first damping unit 83 provided on one side of the preset valve unit 82, and the other side of the preset valve unit 82. A second attenuation unit 84 and a lock piece 85 are provided.
In the piston portion 80 of the third embodiment, in the piston housing 31, the other-side oil chamber P4 partitioned by the preset valve unit 82 and the first damping unit 83, the preset valve unit 82, the first damping unit 83, and the first The intermediate oil chamber P5 defined by the two damping units 84 is formed.

The basic configuration of the preset valve unit 82 is the same as that of the preset valve unit 32 of the first embodiment. The preset valve unit 82 according to the third embodiment includes a spool 321, a collar 322, a second collar 323, a preset valve 324, a valve stopper 325, a ring 326, and a second preset valve 827 (elastic member) between the spool 321 and the collar 322. ).
The second preset valve 827 is configured by superimposing a plurality of disk-shaped metal plates each having an opening 827B through which the spool 321 is passed. The second preset valve 827 is sandwiched between the contact portion 322J of the collar 322 and the other end portion of the second collar 323 and fixed to the spool 321.

The first damping unit 83 includes a valve seat 831 having a plurality of oil passages, a pressure side damping valve 832 (control means) provided on the other side of the valve seat 831, and a pressing member 833 provided on the other side of the pressure side damping valve 832. (Contact member) and holding bolts 834 and nuts 835 for holding these members.
The valve seat 831 is a member formed in a bottomed cylindrical shape having an opening 831H that opens toward one side on the inside. Further, the valve seat 831 has a corner portion 831C on the outer periphery. Further, the valve seat 831 has a bolt hole 831B formed in the axial direction for passing the holding bolt 834, and an oil passage 831Y formed in the axial direction outside the bolt hole 831B in the radial direction.
The opening 831H forms an intermediate oil chamber P5. The corner portion 831C is a portion for fixing the valve seat 831 in the piston housing 31 in the axial direction.
A plurality of oil passages 831Y are formed at equal intervals in the circumferential direction. The oil path 831Y allows oil to flow between the other oil chamber P4 and the intermediate oil chamber P5.

  The compression side damping valve 832 is a disk-shaped metal plate material having a bolt hole 832B through which the holding bolt 834 is passed in the center. The compression side damping valve 832 is pressed against the other end of the valve seat 831 by the holding bolt 834. As shown in FIG. 11, the compression side damping valve 832 has an outer diameter that can cover the other end of the oil passage 831 </ b> Y of the valve seat 831. The compression side damping valve 832 opens and closes the other side of the oil passage 831Y according to the flow of oil.

  The pressing member 833 is a member formed in a substantially cylindrical shape. The pressing member 833 is supported by a guide portion 834G (described later) of the holding bolt 834 so as to be slidable in the axial direction. The pressing member 833 contacts the compression side damping valve 832 on one side and is pressed against the second preset valve 827 on the other side.

  The holding bolt 834 and the nut 835 sandwich and hold the valve seat 831 and the compression side damping valve 832. Further, the holding bolt 834 has a guide portion 834G and a bolt opening portion 834H. The guide portion 834G has an outer diameter substantially equal to the inner diameter of the pressing member 833. The guide portion 834G guides the pressing member 833 so as to be movable in the axial direction. The bolt opening 834 </ b> H is a through hole formed in the axial direction of the holding bolt 834. One end of the spool 321 is inserted into the other side of the bolt opening 834H.

The second damping unit 84 includes a valve seat 841 having a plurality of oil passages, an extension side damping valve 842 (control means) provided on the other side of the valve seat 841, and a pressing provided on the other side of the extension side damping valve 842. It has a member 843 (contact member), and a holding bolt 844 and a nut 845 for holding these members.
The valve seat 841 is a member formed in a bottomed cylindrical shape having an opening 841H that opens toward one side on the inside. Further, the valve seat 841 includes a bolt hole 841B formed in the axial direction for passing the holding bolt 844, an oil passage 841Y formed in the axial direction outside the bolt hole 841B, and an oil passage 841Y. And an outer oil passage 841L formed in the axial direction further outside in the radial direction.
The opening 841H forms a reverse oil passage 841R that is a space defined by the recess 853 of the lock piece 85. The reverse oil passage 841R connects a later-described bolt opening 844H of the holding bolt 844 with the oil passage 841Y.
A plurality of oil passages 841Y are formed at equal intervals in the circumferential direction. The oil passage 841Y allows oil to flow between the intermediate oil chamber P5 and the reverse oil passage 841R.

  In the third embodiment, the oil path 831Y of the first attenuation unit 83 functions as the “first flow path”, and the oil path 841Y and the reverse oil path 841R of the second attenuation unit 84 function as the “second flow path”. To do.

  The extension-side damping valve 842 is a disk-shaped metal plate material having a bolt hole 842B through which the holding bolt 844 is passed at the center. The extension side damping valve 842 is pressed against the other end of the valve seat 841 by the holding bolt 844. As shown in FIG. 11, the extension side damping valve 842 covers the other end of the oil passage 841Y of the valve seat 841, and has an outer diameter that does not cover the outer oil passage 841L. The extension side damping valve 842 opens and closes the other side of the oil passage 841Y according to the flow of oil.

  The pressing member 843 is a member formed in a substantially cylindrical shape. The pressing member 843 is supported so as to be slidable in the axial direction by a later-described guide portion 844G of the holding bolt 844. The pressing member 843 comes into contact with the expansion side damping valve 842 on one side and is pressed against the preset valve 324 on the other side.

  The holding bolt 844 and the nut 845 sandwich and hold the valve seat 841 and the extension side damping valve 842. In addition, the holding bolt 844 has a guide portion 844G and a bolt opening portion 844H. The guide portion 844G has an outer diameter substantially equal to the inner diameter of the pressing member 843. The guide portion 844G guides the pressing member 843 so as to be movable in the axial direction. The bolt opening 844H is a through hole formed in the axial direction of the holding bolt 844. One end of the spool 321 is inserted into the other side of the bolt opening 844H.

The lock piece 85 has a protruding portion 851 on the other side and a large diameter portion 852 having an outer diameter larger than that of the protruding portion 851 on one side.
The protruding portion 851 is a portion protruding in the axial direction toward one side. The protrusion 851 is inserted inside the opening 841H of the valve seat 841. In addition, the protrusion 851 is formed with a recess 853 that is recessed in the axial direction to form the above-described reverse oil passage 841R.
As shown in FIG. 11, the large diameter portion 852 is formed with a plurality of oil passages 854. The plurality of oil passages 854 are arranged at substantially equal intervals in the circumferential direction. The oil path 854 forms an oil flow path between the first oil chamber Y1 and the oil path 841Y of the second damping unit 84. Further, the large diameter portion 852 is formed with a screw portion that fits into a screw groove formed in the piston housing 31.
Then, the lock piece 85 presses the valve seat 841 from one side toward the valve seat 831 of the first damping unit 83 on the other side. The lock piece 85 fixes the entire second damping unit 84 in the axial direction by fixing the valve seat 841.

[Operation of Hydraulic Shock Absorber 1 of Embodiment 3]
FIG. 12 is a diagram for explaining the operation of the hydraulic shock absorber 1 according to the third embodiment.
In the following description, the oil flow in the piston portion 80 having a configuration different from that of the first embodiment will be mainly described. In FIG. 12, the oil flow during the compression stroke is indicated by solid arrows, and the oil flow during the expansion stroke is indicated by dashed arrows.
First, the flow of oil during the compression stroke of the hydraulic shock absorber 1 will be described.
Oil flows from the oil passage 854 of the lock piece 85 to the outer oil passage 841L due to the pressure of the oil in the first oil chamber Y1 increased by the movement of the piston portion 80 in one axial direction. Then, oil flows from the outer oil passage 841L to the intermediate oil chamber P5. Further, oil flows from the intermediate oil chamber P5 to the oil passage 831Y of the first damping unit 83.

Thus, the pressure-side damping valve 832 bends against the pressing force received from the pressing member 833 by the pressure increased by the oil flowing in the specific direction from one side of the axial direction to the other side in the oil passage 831Y. . Then, the oil in the oil passage 831Y flows into the other oil chamber P4 while pushing and opening the compression side damping valve 832. A damping force is generated by resistance generated when oil flows through the oil passage 831Y and the compression side damping valve 832.
Note that the oil pressure raised in the intermediate oil chamber P5 acts in a direction to close the extension side damping valve 842 of the second damping unit 84. Therefore, the extension side damping valve 842 keeps the oil passage 841Y closed, and no oil flows through the oil passage 841Y.

The oil that has flowed into the other oil chamber P4 flows through the housing oil passage 312 of the piston housing 31 into the second oil chamber Y2.
As described above, as the piston portion 80 moves in one direction, an oil flow from the first oil chamber Y1 to the second oil chamber Y2 is generated, and the oil path 831Y and the pressure side damping valve 832 are generated in the oil flow. A damping force is generated by controlling with resistance.

Next, the flow of oil during the extension stroke of the hydraulic shock absorber 1 will be described.
Oil flows from the housing oil passage 312 of the piston housing 31 to the other side oil chamber P4 due to the pressure of the oil in the second oil chamber Y2 increased by the movement of the piston portion 80 in the other axial direction. Further, oil flows from the other side oil chamber P4 to the hollow portion 321L through the collar opening 322H and the spool opening 321H.

The oil that has flowed into the hollow portion 321L flows through the bolt opening 844H into the reverse oil passage 841R. The oil that has flowed in the direction from the other side in the axial direction to the one side in this way is reversed in the reverse oil passage 841R and flows in the direction from the one side in the axial direction to the other side. Then, oil flows from the reverse oil passage 841R to the oil passage 841Y of the second damping unit 84 along the flow in the specific direction in the outer oil passage 841L during the compression stroke described above.
Then, the expansion side damping valve 842 bends against the pressing force received from the pressing member 843 by the oil pressure increased in the oil passage 841Y. Then, the oil in the oil passage 841Y flows into the intermediate oil chamber P5 while pushing the extension side damping valve 842 open. A damping force is generated by the resistance generated when the oil flows through the oil passage 841Y and the extension side damping valve 842.

Here, when the piston part 80 moves in the other direction, the pressure of the oil in the other side oil chamber P4 is increased, and the pressure side damping valve 832 of the first damping unit 83 is not opened. Accordingly, the oil that has flowed into the intermediate oil chamber P5 flows into the outer oil passage 841L. Then, oil flows from the outer oil passage 841L to the oil passage 854. Further, oil flows from the oil passage 854 to the first oil chamber Y1.
As described above, with the movement of the piston portion 80 in the other direction, an oil flow from the second oil chamber Y2 to the first oil chamber Y1 is generated, and the oil passage 841Y and the expansion side damping valve are generated in the oil flow. A damping force is generated by controlling the resistance by applying a resistance 842.

  In the hydraulic shock absorber 1 to which the third embodiment is applied, the pressing member 833 is applied to the compression side damping valve 832 via the preset valve 324 by moving the preset valve unit 82 in one direction by the transmission member 22. The load applied by the pressing member 843 to the extension side damping valve 842 can be changed via the second preset valve 827 by changing the load. As described above, the damping force in the flow in both the expansion stroke and the compression stroke can be adjusted at once by simply moving the preset valve unit 82 in a single direction.

In the first embodiment, for example, a load is applied from the spool 321 to the pressing member 43 via an elastic member such as the preset valve 324, but the pressing member 43 is applied via an elastic member such as the preset valve 324. The application of a load is not limited.
However, in the hydraulic shock absorber 1 according to the first embodiment, for example, by providing the preset valve 324, for example, even if the load is not applied to the transmission member 22 by the moving unit 23, the pressure is constant by the elastic force of the preset valve 324 itself. A load is applied to the pressing member 43. Then, the damping force of the damping valve 42 is stabilized so that the load applied by the pressing member 43 to the damping valve 42 is always a certain level or more regardless of external conditions such as the moving means 23.

  Further, for example, due to the dimensional tolerance of each member constituting the piston portion 30, there is a possibility that a gap is generated between the members, or conversely, the members are pressed too much between the members, and the pressing by a predetermined load cannot be controlled. On the other hand, in this embodiment, a dimensional tolerance can be absorbed by interposing the preset valve 324, and the reliability of the damping force generation in the hydraulic shock absorber 1 can be improved.

For example, as in the third embodiment, a compression side damping valve 832 that causes attenuation during the compression stroke and an extension side damping valve 842 that causes attenuation during the extension stroke are configured by separate members, and these are configured in the axial direction. Although it arrange | positions in a different position, when it comprises a valve | bulb separately, it is not limited to arrange | positioning those valves in a different position in an axial direction.
For example, you may arrange | position the valve | bulb which produces attenuation | damping at the time of a compression stroke, and the valve | bulb which produces attenuation | damping at the time of an expansion stroke in a different position in the radial direction which is a direction crossing an axis | shaft. Specifically, one annular valve having an inner opening and another annular valve having an outer diameter smaller than that of the first valve are arranged inside the first valve. And it is comprised so that the flow of the oil in a piston part produced with the movement of one direction of a piston part and another direction may be controlled with respect to one valve and another valve, and damping force is generated. In this case, for example, the length of the piston portion in the axial direction can be shortened as compared with the third embodiment.

(Embodiment 4)
FIG. 13 is a view for explaining the piston portion 130 of the fourth embodiment.
FIG. 13A is an overall view of the piston portion 130 of the fourth embodiment, and FIG. 13B is an overall view of the piston portion 30 of the first embodiment.
In the first to third embodiments described above, in the piston portion 30 of the first embodiment shown in FIG. 13B, for example, the preset valve unit 32 is moved to the “other side” in the axial direction by the moving means 23 (see FIG. 1). Although the configuration in which the pressing member 43 and the damping valve 42 are moved in the pressing direction from the “upper side in FIG. 13” to the “one side” (lower side in FIG. 13) is used as an example, the present invention is not limited to this. For example, like the piston part 130 of the fourth embodiment, the preset valve unit 132 is moved in the direction opposite to the preset valve unit 32 of the first embodiment, and the preset valve unit 132 is moved to “one side” (for example, lower in FIG. 13). Side) to the “other side” (for example, the upper side in FIG. 13).

  In the piston portion 130 of the fourth embodiment, as shown in FIG. 13A, the piston portion 130 moves in the direction from one side to the other side that occurs in the piston portion 130 as the piston portion 130 moves from the other side to “one side”. A flow path (second flow path) that reverses the flow of oil and flows from the other side to one side (specific direction) is formed in the piston portion 130. Then, on one side of the flow path, a valve is provided that closes the flow path from one side to the other side and opens and closes one side of the flow path. Further, the oil flow path (first flow path) flowing from the other side to the one side (specific direction) generated in the piston section 130 as the piston section moves from one side to the “other side” is also A valve is provided on one side of the flow path so as to close the flow path from one side to the other side, and opens and closes one side of the flow path.

  Specifically, in the fourth embodiment, a third oil chamber Y3 (first liquid chamber) and a fourth oil chamber Y4 that are provided so as to be movable in the axial direction in the cylinder 11 and store oil in the space in the cylinder 11 are stored. A piston housing 131 (compartment member) partitioned into (second liquid chamber) and a third oil chamber formed in the piston housing 131 and moved in one direction toward the other side in the axial direction of the piston housing 131 An oil path 1412 (first flow path) for flowing oil from Y3 to the fourth oil chamber Y4 in the direction from the other side to the one side (specific direction) and the piston housing 131 are formed in the shaft of the piston housing 131. Inverted oil passage 1 that flows oil from the fourth oil chamber Y4 to the third oil chamber Y3 along the direction from the other side to the one side (specific direction) as the other direction moves toward one side in the direction. 1R and oil path 1411 (second flow path), oil path 1411 and oil path 1412 are opened and closed, damping valve 142 that controls the flow of oil in oil path 1411 and oil path 1412, and damping valve 142 are oil paths 1411 and a preset valve unit 132 configured to apply a load to the damping valve 142 in a direction to close the oil passage 1412 and change the load of the damping valve 142, and a moving means (load applying means) for moving the preset valve unit 132; have.

The preset valve unit 132 applies a load only in one direction toward the other side with respect to the damping valve 142. In the fourth embodiment, the pressing member 143 is moved from one side to the other side by moving the pressing member 143 disposed on one side of the damping valve 142 toward the other side by the preset valve unit 132. The damping valve 142 closes the oil passage 1411 and the oil passage 1412.
Further, the preset valve unit 132 includes a preset valve 1324 that is an elastic member, and applies a load to the damping valve 142 via the preset valve 1324.

  The oil passage 1412 allows oil introduced into the piston housing 131 from the other side of the piston housing 131 to flow toward one side of the piston housing 131, and the oil passage 1411 and the reverse oil passage 141 </ b> R are provided on one side of the piston housing 131. Then, the oil introduced into the piston housing 131 is reversed to flow toward one side. And the damping valve 142 is comprised by the single member, and opens and closes the oil path 1411 and the oil path 1412 from one side.

  As described above, in the hydraulic shock absorber 1 to which the fourth embodiment is applied, compared to the piston portion 130 of the first embodiment shown in FIG. The positions of the pressing member 143 that applies a load to the valve 142 and the damping valve 142, the position of the preset valve 1324 that transmits the load of the pressing member 143, and the movement direction of the preset valve unit 132 and the like are reversed in the vertical direction. In short, when the preset valve unit 132 is moved in the “pulling direction” from one side to the other side by the load applying means, the relationship between the flow path for flowing oil during the compression stroke and the flow path for flowing oil during the expansion stroke Is reversed compared to the case where the preset valve unit 32 of the first embodiment is moved in the “pressing direction” from one side to the other side.

  The configuration described as the fourth embodiment is based on the hydraulic shock absorber 1 according to the first embodiment, and the load application direction of the transmission member 22 is changed from “push direction” to “pull direction”; and The example of reversing the flow path for flowing the oil during the compression stroke and the expansion stroke has been described. However, the present invention is not limited thereto, and the hydraulic shock absorber 1 according to the second embodiment or the third embodiment is used as a basic configuration. The load application direction of 22 may be changed from the “pushing direction” to the “pulling direction”, and the flow path through which oil flows during the compression stroke and the expansion stroke may be reversed. Then, as described above, by moving in the “pulling direction” from one side to the other side, the valve is pressed from one side to the other side to adjust the ease of deformation of the valve, The damping force in the shock absorber 1 may be changed.

  In any of the above embodiments, the hydraulic shock absorber 1 (pressure shock absorber) has a so-called triple pipe structure, but is not limited thereto, and may have a so-called double pipe structure. Furthermore, the bottom valve portion 50 is not limited to the structure shown in the above embodiment, and may have other shapes and configurations as long as the function as a damping mechanism is satisfied.

DESCRIPTION OF SYMBOLS 1 ... Hydraulic shock absorber, 10 ... Cylinder part, 11 ... Cylinder, 20 ... Rod part, 30 ... Piston part, 31 ... Piston housing, 32 ... Preset valve unit, 33 ... Check valve unit, 34 ... Lock piece, 40 ... Damping Unit: 41 ... valve seat, 41R ... reverse oil passage, 42 ... damping valve, 43 ... pressing member, 411 ... first oil passage, 412 ... second oil passage

Claims (8)

A cylinder containing liquid;
A partition member which is provided so as to be movable in the axial direction in the cylinder, and which divides into a first liquid chamber and a second liquid chamber for storing a liquid in a space in the cylinder;
A first flow path formed in the partition member and configured to flow a liquid from the first liquid chamber to the second liquid chamber in a specific direction as the partition member moves in one direction in the axial direction;
A second flow path formed in the partition member and configured to flow a liquid from the second liquid chamber toward the first liquid chamber along the specific direction as the partition member moves in the other direction in the axial direction. ,
Control means for opening and closing the first flow path and the second flow path to control the flow of liquid in the first flow path and the second flow path;
A load applying means configured to apply a load to the control means in a direction in which the control means closes the first flow path and the second flow path, and to change the load of the control means;
A pressure buffering device.   The pressure buffering device according to claim 1, wherein the load applying means applies a load only in one direction to the control means.   The pressure buffer device according to claim 1, wherein the load applying unit applies a load to the control unit via an elastic member. The first flow path causes the liquid introduced into the partition member from one side of the partition member to flow toward the other side of the partition member,
The pressure buffer according to claim 1, wherein the second flow path causes the liquid introduced into the partition member from the other side of the partition member to flow in the reverse direction toward the other side.   The pressure buffer device according to claim 1, wherein the control means includes a single control member that opens and closes the first flow path and the second flow path from the other side. The other side channel port of the first channel and the other channel port of the second channel are arranged side by side on the partition member,
The control means is disposed on the other side of the partition member,
The load applying means includes a contact member that contacts the control means on the other side of the control means, and a moving means that moves the contact member from the other side toward the one side. The pressure damper as described. The other-side channel port of the first channel and the other-side channel port of the second channel are arranged side by side in the radial direction of the partition member,
The pressure buffer device according to claim 6, wherein the control means is formed in an annular shape so as to be capable of opening and closing the first flow path and the second flow path. A partition member provided in a cylinder so as to be movable in an axial direction, and dividing into a first liquid chamber and a second liquid chamber for storing a liquid in a space in the cylinder;
A first flow path formed in the partition member and configured to flow a liquid from the first liquid chamber to the second liquid chamber in a specific direction as the partition member moves in one direction in the axial direction;
A second flow path formed in the partition member and configured to flow a liquid from the second liquid chamber toward the first liquid chamber along the specific direction as the partition member moves in the other direction in the axial direction. ,
Control means for opening and closing the first flow path and the second flow path to control the flow of liquid in the first flow path and the second flow path;
A damping force generation mechanism comprising:

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