JP6546453B2 - Damping valve and shock absorber - Google Patents

Description

  The present invention relates to a damping valve and a shock absorber.

  The shock absorber is, for example, interposed between the vehicle body and the wheel of the vehicle to exert a damping force to suppress the vibration of the vehicle body and the wheel. The damping force exerted by the shock absorber is exerted by a damping valve and affects the ride comfort of the vehicle, so a shock absorber equipped with a damping valve having a damping force adjustment function has been developed.

  In the shock absorber having adjustable damping force, for example, a cylinder, a piston slidably inserted in the cylinder, a piston rod movably inserted in the cylinder and coupled to the piston, and the cylinder An expansion side chamber and a compression side chamber partitioned by the piston inside, an expansion side port and a compression side port provided in the piston to communicate the expansion side chamber and the compression side chamber, and a pressure side laminated on the expansion side chamber side of the piston to open and close the pressure side port Leaf valve, expansion side leaf valve stacked on the compression side chamber side of the piston to open and close the expansion side port, bypass path bypassing the expansion side port and the compression side port to communicate the expansion side chamber with the pressure side chamber, bypass path And a needle valve provided in the US patent application Ser. And a damping valve is constituted by a pressure side leaf valve, an expansion side leaf valve, and a needle valve.

  In such a damping valve, the needle valve forms an orifice, and the needle valve can change the effective flow area of the variable orifice formed in the bypass passage. When the piston moves at a low speed relative to the cylinder, the pressure in the expansion side chamber or the compression side chamber does not reach the opening pressure of the expansion side leaf valve or the pressure side leaf valve. The expansion and contraction chambers are moved back and forth through the variable orifices of Therefore, in this shock absorber, the effective flow area of the variable orifice in the damping valve is changed, and the damping force characteristic is a characteristic of the damping force to the piston velocity when the piston velocity is a low velocity region. Can be adjusted.

  Further, in this damping valve, a coil spring is provided on the back side of the pressure side leaf valve, and the pressure side leaf valve is pressed against the piston by the biasing force exerted by the coil spring. The coil spring is, in particular, interposed between the pressure-side leaf valve and the spring receiver so that it can be moved axially by means of a control rod provided in the piston rod. By changing the position of this spring support, the biasing force of the coil spring can be adjusted, and the valve opening pressure of the pressure side leaf valve can be changed. Therefore, in this shock absorber, since it is possible to adjust the valve opening timing of the compression side leaf valve and the damping force characteristics after opening in the contraction stroke, the damping force when the piston speed moves in the middle to high speed region Characteristics can be adjusted.

JP, 2009-264411, A

  However, in the conventional damping valve, adjustment of damping force characteristics when the piston speed is in the middle and high speed region can be adjusted only on the contraction stroke side, and a coil spring is used, so the entire length of the damping valve (shaft Direction length) becomes longer.

  In addition, if the overall length of the damping valve is increased, the stroke length of the shock absorber may be shortened if the damping valve is provided on the piston portion or base valve portion of the shock absorber. If the overall length of the shock absorber is increased in order to secure the stroke length, then mounting on a vehicle or the like will deteriorate.

  Therefore, the present invention has been made to improve the above-mentioned problems, and the object of the present invention is to reduce the overall length while reducing the piston force in the middle and high speed region on the extension stroke side as well. It is an offer of the damping valve which can realize the structure which enables adjustment of a characteristic. Another object of the present invention is to provide a shock absorber capable of adjusting the damping force characteristic when the piston speed is in the middle to high speed region without sacrificing the stroke length.

In order to solve the problems described above, in the damping valve of the solution means of the present invention, a valve disc having a port and an annular valve seat provided on the outer periphery of the port, an outer periphery supported by the annular valve seat and an inner periphery An annular leaf valve which is separated from the valve disc and stacked on the valve disc and is seated on the annular valve seat to open and close the port, and a supporting member which is movable close to the valve disc and supports the inner periphery of the leaf valve And a shaft member upstanding from the valve disc and on the outer periphery of which the leaf valve is mounted, and the support member has a cylindrical portion mounted for axial movement on the outer periphery of the shaft member. It is characterized in that it supports the inner circumference on the opposite side of the valve disc . The damping valve according to claim 2 is a valve disc having a port, an annular valve seat provided on the outer periphery of the port, and an annular leaf stacked on the valve disc and seated on the annular valve seat to open and close the port. A valve, a support member which is movable on the valve disc and supports the inner periphery of the leaf valve and is capable of adjusting the initial deflection of the leaf valve, an axis rising from the valve disc and having the leaf valve mounted on the outer periphery The support member has a cylindrical portion mounted so as to be movable in the axial direction on the outer periphery of the shaft member, and the cylindrical portion supports the inner periphery of the leaf valve on the side opposite to the valve disc . According to the damping valve configured as described above, it is possible to adjust the valve opening pressure of the leaf valve without requiring the installation of a coil spring that biases the leaf valve. Furthermore, the valve opening pressure of the leaf valve can be adjusted with a very simple configuration.

The damping valve according to claim 3 is annular and has a valve disc having a port and an annular valve seat provided on the outer periphery of the port, and the outer periphery is supported by the annular valve seat and the inner periphery is separated from the valve disc The support member includes an annular leaf valve stacked on the disc and seated on the annular valve seat to open and close the port, and a support member capable of being closely moved to the valve disc and supporting the inner periphery of the leaf valve. A flange-like support which is inserted in the valve disc so as to be movable in the axial direction and on which the leaf valve is mounted on the outer periphery, and which is provided on the mounting shaft to support the inner periphery of the leaf valve on the opposite valve disc side And a unit. The damping valve of the fourth aspect is annular, and a valve disc having a port and an annular valve seat provided on the outer periphery of the port, and laminated on the valve disc and seated on the annular valve seat to seat the port. An annular leaf valve that opens and closes, and a support member that can move in and out of the valve disc and supports the inner periphery of the leaf valve and can adjust an initial deflection amount of the leaf valve. It has a mounting shaft portion which is inserted axially movably and on the outer periphery of which the leaf valve is mounted, and a flange-like support portion which is provided on the mounting shaft portion and supports the inner periphery of the leaf valve on the opposite valve disc side. It is characterized by According to the damping valve configured as described above, it is possible to adjust the valve opening pressure of the leaf valve without requiring the installation of a coil spring that biases the leaf valve. Furthermore, the valve opening pressure of the leaf valve can be adjusted with a very simple configuration. This damping valve is applicable to both the piston portion and the base valve portion of the shock absorber.

Furthermore, the shock absorber according to claim 5 comprises a cylinder, a piston as a valve disc, an expansion side chamber and a pressure side chamber defined in the cylinder by the piston, a piston rod inserted into the cylinder and connected to the piston, Is equipped with a damping valve. When the shock absorber is configured in this way, it is possible to adjust the valve opening pressure of the leaf valve without causing the lengthening of the entire length of the shock absorber, without requiring the installation of a coil spring for energizing the leaf valve. This will also improve the ease of installation on vehicles.

The shock absorber according to claim 6 is provided at a piston nut as a shaft member for fixing a piston as a valve disk to a piston rod, a support member screwed to the piston nut, and an end of a cylinder to close the cylinder end. The cap is provided with a fitting portion on one of the cap and the support member, and the fitting hole can be fitted non-rotatably to the other of the cap and the support member. The valve opening pressure of the leaf valve can be easily adjusted by rotating the piston rod.

The shock absorber according to claims 7 and 8 includes a tank whose inside communicates with the inside of the cylinder, a valve case as a valve disc which is provided in the tank and divides the inside of the tank into a reservoir and a pressure side chamber, and a valve case. And a leaf valve which is stacked on the valve case and whose inner periphery is supported by the support member. In this case, compared to the case where the damping valve for adjusting the valve opening pressure of the leaf valve is provided at the end of the cylinder, it can contribute to shortening the overall length of the shock absorber, and the shock absorber can be mounted on a vehicle etc. Improve further.

A shock absorber according to a ninth aspect of the present invention is directed to a tank in which the inside communicates with the inside of the cylinder, a valve case as a valve disc which is provided in the tank and divides the inside of the tank into a reservoir and a pressure side chamber. Support member and a leaf valve stacked on the reservoir side of the valve case and supported by the support member on the inner periphery, the tank has a lower cap whose end is closed, and the valve case is inside the tank The support member supports the inner periphery of the leaf valve on the reservoir side at the support portion, and is screwed to the lower cap through the valve case and the lower cap. In this case, the support member can be accessed from the outside of the shock absorber, the valve opening pressure adjustment of the leaf valve can be easily performed from the outside of the shock absorber, and the adjustment of the damping force characteristic of the contraction stroke of the shock absorber becomes easy.

  From the above, according to the damping valve of the present invention, it is possible to adjust the damping force characteristic when the piston speed is in the middle and high speed region even on the extension stroke side while shortening the overall length. Further, according to the shock absorber of the present invention, it is possible to adjust the damping force characteristic when the piston speed is in the middle to high speed region without sacrificing the stroke length.

It is a longitudinal cross-sectional view of a buffer with which the damping valve of one embodiment was applied. It is an enlarged sectional view of a piston portion of a shock absorber to which a damping valve of one embodiment is applied. It is an expanded sectional view of a tank part of a buffer with which a damping valve of one embodiment was applied. It is an expanded sectional view of a piston portion of a buffer to which one modification of a damping valve of one embodiment was applied. It is a figure which shows the damping force characteristic of the buffer to which the damping valve of one Embodiment was applied.

  Hereinafter, the present invention will be described based on the embodiments shown in the drawings. As shown in FIGS. 1 and 2, the shock absorber D in one embodiment is divided by the cylinder 1, the piston 2 slidably inserted in the cylinder 1, and the piston 2 in the cylinder 1. The expansion side chamber R1 and the compression side chamber R2, the annular expansion side piston valve 4 stacked on the piston 2, the support member 15 capable of moving around the piston 2 and supporting the inner periphery of the expansion side piston valve 4, and the inside A cylindrical tank T communicated with the cylinder 1, a valve case 6 provided in the tank T for dividing the inside of the tank T into a reservoir R and a pressure side chamber R2, and an annular base valve stacked on the valve case 6 And a support member 16 which can be moved to the valve case 6 and supports the inner periphery of the base valve 7.

  Further, in the case of this shock absorber D, the expansion side piston valve 4 is configured by a leaf valve, and the piston 2 is a valve disc, and the piston 2 and the expansion side piston valve 4 stacked on the piston 2 and the support member 15 The damping valve V1 is configured, and the base valve 7 is a leaf valve. The valve case 6 is a valve disc, and the valve case 6 and the base valve 7 stacked on the valve case 6 and damping member 16 dampen. The valve V2 is configured, and two damping valves V1 and V2 are provided.

  Then, the cylinder 1 is filled with a liquid such as hydraulic oil. Further, a free piston F is slidably inserted in the tank T, the reservoir R is divided into a liquid chamber L and an air chamber G by the free piston F, and the liquid described above is stored in the liquid chamber L. The air chamber G is filled with gas. As the liquid, in addition to the hydraulic oil, for example, a liquid such as water or an aqueous solution can be used.

  Each part will be described in detail below. The lower end of the cylinder 1 in FIG. 1 is closed by a cap 17 connecting the cylinder 1 to the tank T. A piston 2 is slidably inserted in the cylinder 1, and the inside of the cylinder 1 is divided by the piston 2 into an expansion chamber R 1 and a compression chamber R 2. Further, an outer cylinder 18 is provided on the outer periphery of the cylinder 1, and an annular passage 19 is formed between the cylinder 1 and the outer cylinder 18.

  The cap 17 is cylindrical and has a bottomed cylindrical cap main body 17a screwed to the lower end of the outer cylinder 18 in FIG. 1 and a side of the cap main body 17a protruding laterally in FIG. A connecting portion 17b to be connected, a first communication passage 17c provided in the connecting portion 17b to communicate the reservoir R in the tank T with the inside of the cylinder 1, and a connecting portion 17b provided in the connecting portion 17b And a second communication passage 17d to be communicated. The cap body 17a is fitted to the cylinder 1 and screwed to the outer cylinder 18, so that the inside of the cylinder 1 and the annular passage 19 are not communicated in the cap body 17a. Further, at the center of the bottom portion of the cap main body 17a, a hexagonal fitting portion 17e is provided in a plan view (an axial direction view) projecting into the cap main body 17a.

An annular rod guide 9 is fitted to the upper end of the cylinder 1 and the outer cylinder 18 in FIG. 1 and the extension chamber R1 is communicated with the annular passage 19 by the passage 9a provided in the rod guide 9. . Further, in the middle of the second communication passage 17d, a check valve 20 which allows only the flow of the liquid from the inside of the tank T to the expansion side chamber R1 is provided. Therefore, the flow of liquid directed from expansion side chamber R1 to the tank T through the annular passage 19, but Ru is prevented by the check valve 20, the opposite flow is adapted to be tolerated.

  Returning back, the piston rod 3 is movably inserted into the cylinder 1, and the piston 2 is connected to the tip of the piston rod 3. Specifically, the piston rod 3 has a small diameter portion 3a provided on the lower end side in FIG. 1 and a screw portion 3b provided on the outer periphery of the lower end in FIG. 1 which is the tip of the small diameter portion 3a.

  Further, the upper end side of the piston rod 3 in FIG. 1 is projected outward through the inside of a rod guide 9 mounted on the upper end of the cylinder 1 in FIG. The rod guide 9 is provided with a cylindrical bush 10 on its inner periphery, supports the piston rod 3 inserted in the bush 10, and axially moves the piston rod 3 in the vertical direction in FIG. To guide you. Further, a seal member 11 for sealing between the cylinder 1 and the outer cylinder 18 and the piston rod 3 is stacked above the rod guide 9 in FIG. 1 to keep the inside of the cylinder 1 and the annular passage 19 fluid tight. I'm tired.

  Then, as shown in FIG. 2, an annular piston 2 as a valve disc is mounted on the outer periphery of the small diameter portion 3 a of the piston rod 3. Specifically, the piston 2 includes an expansion side port 2a as a port communicating the expansion side chamber R1 with the pressure side chamber R2, and a pressure side port 2b communicating the expansion side chamber R1 with the pressure side chamber R2. Further, an expansion side valve seat 2c as an annular valve seat that protrudes downward in FIG. 2 from the outer periphery of the expansion side port 2a is provided at the lower end of the piston 2 in FIG. An annular pressure side valve seat 2d is provided which protrudes upward in FIG. 2 from the outer periphery of the pressure side port 2b.

  At the upper end of the piston 2 in FIG. 2, an annular spacer 13 and a collar 14, which are attached to the outer periphery of the small diameter portion 3 a of the piston rod 3, are stacked. Further, at the upper end of the piston 2 in FIG. 2, a pressure side piston valve 5 is mounted which is mounted on the outer periphery of the collar 14 and which opens and closes the pressure side port 2b. The collar 14 is provided with a cylindrical portion 14a and a flange 14b provided on the outer periphery of the upper end of the cylindrical portion 14a in FIG. The compression side piston valve 5 is configured by laminating several annular plates, and is mounted on the outer periphery of the cylindrical portion 14 a of the collar 14, and the small diameter portion 3 a of the piston rod 3 is mounted on all of the collar 14, the spacer 13 and the piston 2. Assembled around the The piston 2, the spacer 13 and the collar 14 are fixed to the small diameter portion 3a by a piston nut 12 as a shaft member screwed to the screw portion 3b.

  When the pressure side piston valve 5 fixes the collar 14 and the piston 2 to the small diameter portion 3a of the piston rod 3, the inner periphery of the upper surface in FIG. 2 which is the back is supported by the flange 14b and the lower surface in FIG. The outer periphery is supported by the compression side valve seat 2d to provide initial deflection. The pressure side piston valve 5 is allowed to bend on the outer circumference side with the outer circumference of the contact surface to the above-mentioned back surface of the flange 14b as a fulcrum, and when it bends, the pressure side port 2b can be opened. Therefore, when the piston 2 moves downward in FIG. 1 with respect to the cylinder 1, the pressure of the compression side chamber R 2 that is compressed and rises acts on the compression side piston valve 5 via the pressure side port 2 b. Exerts a force to bend upward in FIG. Then, when the pressure in the pressure side chamber R2 exceeds the valve opening pressure set by the initial deflection of the pressure side piston valve 5, the pressure side piston valve 5 bends so as to separate from the pressure side valve seat 2d and open the pressure side port 2b. At this time, the pressure side piston valve 5 allows movement of the liquid from the pressure side chamber R2 to the expansion side chamber R1, and provides resistance to the flow of the liquid. On the contrary, when the piston 2 moves upward in FIG. 1 with respect to the cylinder 1, the pressure side piston valve 5 is pressed against the pressure side valve seat 2d under the pressure of the expansion side chamber R1 which is compressed and rises, and the pressure side port 2b To block the movement of liquid from the expansion side chamber R1 to the pressure side chamber R2.

  The piston nut 12, which is a shaft member, has a bottomed cylindrical nut portion 12a, a flange 12b provided at the piston end which is the upper end in FIG. 2 of the nut portion 12a, and a lower end in FIG. And a screw part 12c provided on the outer circumference from the middle to the middle. Further, the flange 12b has, for example, a shape other than a circular shape such as a hexagonal shape in plan view (axial direction) so that the flange 12b can be gripped by a tool, and the screw portion 3b provided in the small diameter portion 3a Tightening of the piston nut 12 is possible.

  The piston 2 is attached to the lower end in FIG. 2 of the piston 2 in the range which is the outer periphery of the nut portion 12a of the piston nut 12 and does not cover the screw portion 12c. The expansion side piston valve 4 which seats and opens and closes the expansion side port 2a is laminated | stacked. The expansion side piston valve 4 is a leaf valve configured by laminating a plurality of annular plates in this example, and the number of annular plates can be appropriately changed according to a desired damping force characteristic.

  Further, a support member 15 is attached to the screw portion 12 c of the piston nut 12. The support member 15 has a cylindrical portion 15a in which a screw groove is formed on the inner periphery, a bottom portion 15b closing the lower end of the cylindrical portion 15a in FIG. 2, and a plan view opening from the lower end in FIG. And a hexagonal fitting hole 15c.

  When mounted on the piston nut 12, the support member 15 supports the inner periphery of the lower surface in FIG. 2, which is the side opposite to the valve disc of the expansion side piston valve 4, at the upper end in FIG. Then, the axial position of the upper end of the cylindrical portion 15a of the support member 15 in FIG. 2 is disposed upward in FIG. 2 relative to the axial position of the seat surface on which the expansion piston valve 4 of the expansion valve seat 2c is seated. It is like that. In this way, the expansion piston valve 4 is supported by the support member 15 on the inner periphery of the back surface which is the side opposite to the valve disc, and the outer periphery of the upper surface in FIG. Deflection is given. Then, when the support member 15 is rotated relative to the piston nut 12, the support member 15 can move in the axial direction toward and away from the piston 2 in the manner of a feed screw. That is, the support member 15 is mounted on the outer periphery of the piston nut 12 which is a shaft member so as to be movable in the axial direction, and supports the inner periphery of the expansion side piston valve 4 which is a leaf valve on the opposite valve disc side. It is supposed to In addition, in order to move the support member 15 in the axial direction with respect to the piston nut 12 which is a shaft member, a structure other than screwing of both may be adopted.

  Then, the expansion side piston valve 4 is allowed to bend on the outer peripheral side with the outer circumference of the contact surface to the above-mentioned back surface of the cylindrical portion 15a of the support member 15 as a fulcrum, and when it bends, the expansion side port 2a can be opened. There is. Therefore, when the piston 2 moves upward in FIG. 1 with respect to the cylinder 1, the pressure of the expansion side chamber R1 compressed and raised acts on the expansion side piston valve 4 via the expansion side port 2a, and the expansion side The piston valve 4 exerts a force to bend downward in FIG. Then, when the pressure in the expansion chamber R1 exceeds the valve opening pressure set by the initial deflection of the expansion piston valve 4, the expansion piston valve 4 flexes and is separated from the expansion valve seat 2c to open the expansion port 2a. Open. At that time, the expansion side piston valve 4 allows movement of the liquid from the expansion side chamber R1 to the pressure side chamber R2, and provides resistance to the flow of the liquid. On the other hand, when the piston 2 moves downward in FIG. 1 with respect to the cylinder 1, the expansion side piston valve 4 is compressed by the pressure of the compression side chamber R2 that is rising and is pushed against the expansion side valve seat 2c to expand The side port 2a is closed to block the movement of liquid from the pressure side chamber R2 to the expansion side chamber R1.

  The initial deflection given to the expansion side piston valve 4 is an adjustment element that sets the valve opening pressure at which the expansion side piston valve 4 opens the expansion side port 2a as described above. In the damping valve V1, since the support member 15 is axially movable with respect to the piston nut 12, it can move in a far and near direction with respect to the piston 2, and the axial support position of the inner periphery of the expansion side piston valve 4 can be changed. When the axial support position of the inner periphery of the expansion piston valve 4 is changed, the initial deflection amount of the expansion piston valve 4 can be adjusted. Therefore, in the damping valve V1 of the present invention, the opening pressure of the expansion side piston valve 4 can be adjusted by moving the support member 15 closer to the piston 2. In addition, since the expansion side piston valve 4 is mounted on the outer periphery of the nut portion 12a of the piston nut 12 and in a range not covered by the screw portion 12c, the axial support position can be changed smoothly. The support member 15 supports the inner periphery of the side opposite to the valve disc of the expansion side piston valve 4, but is fixedly supported on the inner periphery of the expansion side piston valve 4 and integrated with the expansion side piston valve 4 It is also good. That is, the support member 15 may move the axial position of the inner periphery of the expansion side piston valve 4 in the axial direction with respect to the piston 2 which is a valve disc.

  Further, when the piston rod 3 is pushed into the cylinder 1 and the shock absorber D is contracted most, the fitting portion 17e provided on the cap 17 can be fitted in the fitting hole 15c of the support member 15 There is. When the piston rod 3 is rotated with respect to the cylinder 1 in a state where the fitting portion 17e is fitted in the fitting hole 15c, the support member 15 is prevented from rotating by the cap 17 and the support member 15 is Relative to the piston nut 12 connected to the. When the support member 15 rotates relative to the piston nut 12, the support member 15 moves closer to the piston 2, so the initial deflection amount given to the expansion piston valve 4 can be adjusted by the rotation operation of the piston rod 3. Thus, the valve opening pressure of the expansion side piston valve 4 can be adjusted by the external operation of the piston rod 3 without disassembling the shock absorber D. Although the fitting hole 15c is provided in the support member 15 and the fitting portion 17e is provided in the cap 17 as described above, the fitting portion protruding toward the cap 17 is provided in the support member 15 on the contrary. The cap 17 may have a fitting hole. In addition, the shapes of the fitting holes 15c and the fitting portions 17e in plan view (axial direction view) may be limited to a hexagonal shape as long as they can be fitted to each other and relatively stopped from rotating. Rather, it can adopt shapes other than circular.

  When it is not necessary to adjust the valve opening pressure of the expansion side piston valve 4 by the external operation of the piston rod 3, that is, the valve opening pressure adjustment is required at the time of tuning. In the case where it is necessary to disassemble the shock absorber D in case of adjusting the valve opening pressure, as shown in FIG. 4, the fitting hole 15c and the fitting portion 17e are eliminated from the support member 15 and the cap 17. You may In this case, by screwing the screw B in contact with the bottom of the nut portion 12a of the piston nut 12 to the bottom 15b of the support member 15, the support member 15 is screwed to the nut 12a of the piston nut 12 It becomes possible to prevent 15 loosening.

  Subsequently, a tank T is connected to the side of the connecting portion 17b of the cap 17 in FIG. The tank T includes a cylindrical tank body 21, an upper cap 22 for closing the upper end of the tank body 21 in FIG. 1, and a lower cap 23 for closing the lower end of the tank body 21 in FIG. 1.

  Further, a valve case 6 as a valve disc is provided in the tank T, and the inside of the tank T is partitioned into a reservoir R on the upper side in FIG. 1 and a space on the lower side in FIG. ing. Then, this space communicates with the lower chamber in FIG. 1 with respect to the piston 2 in the cylinder 1 by the first communication passage 17c, and forms a pressure-side chamber R2 in cooperation with this chamber. Therefore, the valve case 6 divides the inside of the tank T into the reservoir R and the pressure side chamber R2. A free piston F is slidably inserted in the tank body 21. The free piston F divides the reservoir R into a lower liquid chamber L and an upper air chamber G in FIG. . The liquid chamber L in the reservoir R communicates with the annular passage 19 communicated with the expansion side chamber R1 via the second communication passage 17d. As described above, the check valve 20 which allows only the flow of the liquid from the inside of the tank T to the expansion side chamber R1 is provided in the middle of the second communication passage 17d, the liquid flowing from the reservoir R to the expansion side chamber R1 Only flow is allowed.

  As described above, the liquid chamber L provided in the reservoir R is filled with liquid, and the air chamber G is filled with gas, but the gas is filled via the air valve 24 provided on the upper cap 22. Since the air valve 24 can supply and discharge gas into the reservoir R, the pressure in the reservoir R can be freely adjusted.

  The valve case 6 is annular, and includes a discharge port 6a as a port communicating the reservoir R and the pressure side chamber R2, and a suction port 6b communicating the reservoir R and the pressure side chamber R2. Then, as shown in FIG. 3, the valve case 6 has a through hole 25 a interposed between the step 21 a provided on the inner periphery of the tank body 21 and the lower cap 23 attached to the tank body 21. It is clamped by the provided cylindrical spacer 25 and fixed in the tank T. The lower cap 23 is screwed on the inner periphery of the lower end of the tank body 21 in FIG. 3, and the lower cap 23 is screwed into the tank body 21 to exert an axial force on the valve case 6 through the spacer 25 The valve case 6 can be fixed to the tank T. Since the spacer 25 is provided with the through hole 25a as described above, the communication between the discharge port 6a, the suction port 6b, and the pressure side chamber R2 is secured.

  Further, a discharge side valve seat 6c as an annular valve seat that protrudes upward in FIG. 3 from the outer periphery of the discharge port 6a is provided at the upper end in FIG. 3 of the valve case 6 An annular suction side valve seat 6d is provided which protrudes downward in FIG. 3 from the outer periphery of the suction port 6b.

  An assembly pipe 26 having a flange 26a at the upper end in FIG. 3 is inserted into the inner periphery of the valve case 6, and a screw 26b is formed on the outer periphery of the tip of the assembly pipe 26 which is the lower end in FIG. It is provided. Then, at the lower end of the valve case 6 in FIG. 3, an annular check valve 27 is mounted on the outer periphery of the assembly pipe 26 and is separated from and seated on the suction side valve seat 6 d to open and close the suction port 6 b. It is done.

  The check valve 27 is formed of a single annular plate and is mounted on the outer periphery of the assembly pipe 26 together with an annular spacer 28 having a diameter smaller than that of the check valve 27. The check valve 27 is sandwiched between a nut 29 screwed on the outer periphery of the tip of the assembly pipe 26 and a flange 26 a of the assembly pipe 26, and is assembled to the valve case 6 in an inner periphery fixed state. When the check valve 27 is assembled by being stacked on the valve case 6 in this manner, the inner periphery of the lower surface in FIG. 3, which is the rear surface, is supported by the spacer 28, and the outer periphery of the upper surface in FIG. Sitting on the side valve seat 6d, the suction port 6b is closed. The check valve 27 is allowed to bend on the outer peripheral side with the outer periphery of the contact surface of the spacer 28 to the above-described back surface as a fulcrum, and when it bends, the suction port 6 b can be opened.

  Therefore, when the piston 2 moves upward in FIG. 1 with respect to the cylinder 1, the check valve 20 of the second communication passage 17d is kept closed, so the liquid is compressed from the expansion side chamber R1 to the pressure side chamber R2. Move to Further, since the liquid corresponding to the volume of the piston rod 3 exiting from the cylinder 1 runs short in the cylinder 1, the check valve 27 opens and the liquid running short from the reservoir R is supplied into the cylinder 1 via the suction port 6b. Be done. On the other hand, when the piston 2 moves downward in FIG. 1 with respect to the cylinder 1, the check valve 27 is pressed against the valve case 6 by the pressure of the compression side chamber R2, thereby closing the suction port 6b. The movement of liquid from the chamber R2 to the reservoir R is blocked.

  Further, a support member 16 is inserted into the assembly pipe 26. The supporting member 16 is axially movable in the valve case 6 and provided at the upper end in FIG. 3 of the mounting shaft portion 16a on which the annular base valve 7 as a leaf valve is mounted on the outer periphery and the mounting shaft portion 16a. A flange-like support portion 16b, a screw portion 16c provided on the outer periphery of the lower end in FIG. 3 which is an end opposite to the end provided with the support portion 16b of the mounting shaft 16a, and a drawing of the mounting shaft 16a 3 and a tool insertion hole 16d opened from the lower end.

  The mounting shaft portion 16a of the support member 16 has the support portion 16b directed to the upper reservoir R side in FIG. 3 and the screw portion 16c directed to the pressure side chamber R2 side in FIG. 3 downward, and into the valve case 6 from the screw portion 16c side. It is inserted into the attached assembly pipe 26. The lower cap 23 has an annular shape, and a screw portion 23a is formed on the inner circumference, and the lower end of the mounting shaft portion 16a of the support member 16 in FIG. The screw 16 c is screwed into the screw portion 23 a of the lower cap 23. The lower end of the mounting shaft 16a of the support member 16 penetrates the lower cap 23 and faces outward, so that a tool (not shown) can be inserted from the outside into the tool insertion hole 16d. . The shape of the plan view (axial view) of the tool insertion hole 16d is a hexagon so that it can correspond to this with a hexagonal wrench as a tool, but the support member 16 is operated by the operation of the tool inserted into the tool insertion hole 16d. Any shape other than circular and conforming to the tool may be used so that it can be rotated about the axis.

  When the support member 16 configured in this way is rotated about the axis with respect to the lower cap 23 by a tool (not shown) described above, the support member 16 axially moves relative to the lower cap 23 in a feed screw manner. The lower cap 23 is fixed to the tank body 21 together with the valve case 6, so that the support member 16 can be axially moved relative to the valve case 6 by the rotation operation of the above-mentioned support member 16, and relative to the valve case 6 Thus, the support portion 16b can be moved in the vertical direction in FIG.

  A seal ring 30 which is in sliding contact with the inner periphery of the lower cap 23 is attached to the outer periphery of the attachment shaft portion 16a of the support member 16, so that the inside of the tank T is maintained liquid-tight.

  The valve case 6 is mounted on the outer periphery of the mounting shaft portion 16a of the support member 16 at the upper end in FIG. 3 and is seated on the discharge side valve seat 6c as an annular valve seat to discharge the discharge port 6a. An annular base valve 7 which is opened and closed is stacked. In this example, the base valve 7 is a leaf valve configured by laminating a plurality of annular plates, and the number of annular plates can be appropriately changed according to a desired damping force characteristic.

  When the base valve 7 is thus mounted on the support member 16 and stacked on the valve case 6, the support portion 16b of the support member 16 supports the inner periphery of the upper surface in FIG. . Then, the axial position of the lower end in FIG. 3 of the support portion 16b of the support member 16 is disposed lower in FIG. 3 than the axial position of the seat surface on which the base valve 7 of the discharge side valve seat 6c is seated. ing. In this case, the base valve 7 is supported by the support member 16 on the inner periphery of the back surface which is the side opposite to the valve disc, and the outer periphery of the lower surface in FIG. 3 which is the front is supported by the discharge side valve seat 6c. Given.

  The base valve 7 is allowed to bend on the outer peripheral side with the outer periphery of the contact surface of the support portion 16 b of the support member 16 to the above-mentioned back surface as a fulcrum, and when it bends, the discharge port 6 a can be opened. Therefore, when the piston 2 moves downward in FIG. 1 with respect to the cylinder 1, the pressure of the compression side chamber R2 that is compressed and rises acts on the base valve 7 via the discharge port 6a, and the base valve 7 is shown in FIG. 3 Demonstrate the force to bend upward in the middle. Then, when the pressure of the compression side chamber R2 exceeds the valve opening pressure set by the initial deflection of the base valve 7, the base valve 7 deflects and leaves the discharge side valve seat 6c to open the discharge port 6a. At that time, the base valve 7 allows movement of the liquid from the pressure side chamber R2 to the reservoir R, and provides resistance to the flow of the liquid. On the contrary, when the piston 2 moves upward in FIG. 1 with respect to the cylinder 1, the base valve 7 is maintained in the state of being seated on the discharge side valve seat 6c because the pressure side chamber R2 is decompressed. To block the movement of liquid from the reservoir R to the pressure side chamber R2.

  The initial deflection given to the base valve 7 is an adjustment element that sets the valve opening pressure at which the base valve 7 opens the discharge port 6a as described above. In this damping valve V2, since the support member 16 is axially movable to the valve case 6, it can be moved in a perspective manner with respect to the valve case 6, and the axial support position of the inner periphery of the base valve 7 can be changed. Then, when the axial support position of the inner periphery of the base valve 7 is changed, the initial deflection amount of the base valve 7 can be adjusted. Therefore, in the damping valve V2 of the present invention, the opening pressure of the base valve 7 can be adjusted by moving the support member 16 closer to the valve case 6. The support member 16 supports the inner periphery of the side surface opposite to the valve disc of the base valve 7, but may be integrated with the base valve 7 by supporting the inner periphery of the base valve 7 in a fixed manner. That is, the support member 16 may move the axial position of the inner periphery of the base valve 7 in the axial direction with respect to the valve case 6 which is a valve disc. Further, the adjustment of the valve opening pressure of the base valve 7 can be performed by the rotation operation of the support member 16, and the aforementioned adjustment can be easily performed from the outside of the shock absorber D.

  The shock absorber D is configured as described above, and the operation thereof will be described below. First, the operation of the extension stroke of the shock absorber D in which the piston 2 moves upward in FIG. 1 with respect to the cylinder 1 will be described. In the extension stroke of the shock absorber D, the expansion side chamber R1 is compressed by the piston 2 by the movement of the piston 2 relative to the cylinder 1, and the pressure side chamber R2 is expanded. The pressure in the expansion side chamber R1 to be compressed is increased, and when this pressure reaches the valve opening pressure of the expansion side piston valve 4, the expansion side piston valve 4 is bent to open the expansion side port 2a, and the inside of the expansion side chamber R1 is The liquid moves to the pressure side chamber R2 via the expansion side port 2a. The expansion side chamber R1 communicates with the liquid chamber L of the reservoir R through the second communication passage 17d, but the check valve 20 is closed to shut off the liquid, and the liquid directly from the expansion side chamber R1 to the liquid chamber L Is not discharged. Further, in the extension stroke of the shock absorber D, the piston rod 3 withdraws from the cylinder 1, so there is not enough liquid in the cylinder 1 for the volume of the piston rod 3 withdrawing from the cylinder 1. Due to the pressure reduction in the pressure side chamber R2, the check valve 27 bends downward in FIG. 3 to open the suction port 6b, and the above-mentioned shortage of liquid is supplied from the liquid chamber L of the reservoir R to the pressure side chamber R2. And since the expansion side piston valve 4 gives resistance to the flow of the liquid, the inside of the expansion side chamber R1 is boosted, the pressure side chamber R2 becomes almost equal pressure with the reservoir R, and the pressure difference between the expansion side chamber R1 and the pressure side chamber R2 And the shock absorber D exerts a damping force to suppress the extension operation.

  Here, as described above, in the shock absorber D, since the valve opening pressure of the expansion side piston valve 4 can be adjusted, the piston speed which is the speed of the piston 2 with respect to the cylinder 1 is in the middle and high speed You can adjust the damping force characteristics of the Specifically, since the valve opening pressure of the expansion side piston valve 4 can be adjusted, as shown in FIG. 5, the point at which the characteristic of the expansion side piston valve 4 appears with respect to the piston speed and the magnitude of the damping force It can be adjusted with the variable width of. Within the variable range, the damping force characteristic can be adjusted to move the damping force characteristic of the expansion piston valve 4 in parallel in the vertical direction, as shown in FIG. In FIG. 5, when the piston speed is in a low speed range, the damping force characteristic by the orifice appears, and when the expansion side piston valve 4 is opened, the characteristic of the expansion side piston valve 4 appears. Although not shown, the orifice is provided, for example, in the piston 2 or the expansion piston valve 4.

  Next, the operation of the contraction stroke of the shock absorber D in which the piston 2 moves downward in FIG. 1 with respect to the cylinder 1 will be described. In the contraction stroke of the shock absorber D, the pressure side chamber R2 is compressed by the piston 2 by the movement of the piston 2 with respect to the cylinder 1, and the expansion side chamber R1 is expanded. The pressure in the compression side chamber R2 to be compressed rises, and when this pressure reaches the valve opening pressure of the base valve 7 and the pressure side piston valve 5, the base valve 7 and the pressure side piston valve 5 bend to discharge the discharge port 6a and the pressure side port 2b. Is released, and the liquid in the pressure side chamber R2 moves to the reservoir R and the expansion side chamber R1. In the contraction stroke of the shock absorber D, since the piston rod 3 intrudes into the cylinder 1, the volume of liquid invading the cylinder 1 of the piston rod 3 in the cylinder 1 becomes excessive. The excess liquid is discharged from the pressure side chamber R2 to the liquid chamber L of the reservoir R by the opening of the discharge port 6a of the base valve 7. If the amount of liquid flowing from the pressure side chamber R2 to the expansion side chamber R1 does not reach the expansion amount of the expansion side chamber R1 due to the opening of the pressure side port 2b of the pressure side piston valve 5, the check valve 20 is opened and the second connection is made. The liquid is supplied from the liquid chamber L to the expansion side chamber R1 through the passage 17d. Thus, in the contraction stroke of the shock absorber D, the generation of vacuum in the expansion chamber R1 is suppressed. Then, since the base valve 7 and the pressure side piston valve 5 provide resistance to the flow of liquid, the pressure in the pressure side chamber R2 is boosted, and the pressure in the expansion side chamber R1 becomes lower than the pressure in the pressure side chamber R2. As described above, since the differential pressure is generated between the pressure side chamber R2 and the expansion side chamber R1, the shock absorber D exerts a damping force that suppresses the contraction operation.

  Here, as described above, in the shock absorber D, since the valve opening pressure of the base valve 7 can be adjusted, the damping force characteristic in the middle and high speed region of the piston can be adjusted at the contraction operation time. Specifically, since the valve opening pressure of the base valve 7 can be adjusted, as shown in FIG. 5, the point at which the characteristic of the base valve 7 appears with respect to the piston speed and the magnitude of the damping force It can be adjusted. Within the variable range, the damping force characteristic can be adjusted to move the damping force characteristic of the base valve 7 in parallel in the vertical direction, as shown in FIG. In FIG. 5, when the piston speed is in the low speed range, the damping force characteristic by the orifice appears, and when the base valve 7 is opened, the characteristic of the base valve 7 appears. Although not shown, the orifice is provided, for example, in the valve case 6 or the base valve 7. Further, since the adjustment of the damping force characteristic at the time of the contraction operation is performed by the damping valve V2, the pressure side piston valve 5 may be a check valve which does not provide resistance to the flow of the liquid. However, when the pressure side piston valve 5 is used, the pressure side chamber R2 can be quickly boosted during the contraction stroke of the shock absorber D, so that the damping force generation responsiveness is improved.

  As described above, in the damping valve V1 of the present invention, the support position of the expansion-side piston valve 4 as the leaf valve is adjusted by the support member 15 which can approach the piston 2 as the valve disc. The valve opening pressure of the expansion piston valve 4 can be adjusted without requiring the installation of a coil spring for biasing the expansion piston valve 4. Therefore, according to the damping valve V1 of the present invention, while shortening of the entire length of the damping valve V1 is possible, it is possible to adjust the damping force characteristics when the piston speed is in the middle and high speed region even on the extension stroke side. . Further, according to the damping valve V1 and the shock absorber D of the present invention, the total length of the damping valve V1 can be shortened, and the stroke length can be secured without causing the overall length of the shock absorber D to increase. Without making it possible to adjust the damping force characteristics when the piston speed is in the middle and high speed region. Further, according to the shock absorber D of the present invention, the overall length of the shock absorber D does not have to be long, so the mountability of the shock absorber D on a vehicle or the like is also improved.

  The damping valve V1 is provided with a piston nut 12 as a shaft member upstanding from the piston 2 and having the expansion side piston valve 4 mounted on the outer periphery, and the support member 15 is mounted on the outer periphery of the piston nut 12 so as to be movable in the axial direction. Since the cylindrical portion 15a is provided and the cylindrical portion 15a supports the inner periphery of the expansion side piston valve 4 on the opposite side of the valve disc, the valve opening pressure of the expansion side piston valve 4 can be adjusted with a very simple configuration.

  Furthermore, the shock absorber D is inserted into the cylinder 1, the piston 2 as a valve disc, the expansion side chamber R1 and the pressure side chamber R2 partitioned in the cylinder 1 by the piston 2 and the cylinder 1, and the tip is inserted into the piston 2 And a piston nut 12 as a shaft member screwed to the end of the piston rod 3 to fix the piston 2 to the piston rod 3, and laminated on the pressure side chamber R2 side of the piston 2 An expansion side piston valve 4 as a leaf valve mounted on the outer periphery of the cylinder, a support member 15 screwed to the piston nut 12, and a cap 17 provided at an end of the cylinder 1 to close the cylinder end. A fitting portion is provided on one of the cap 17 and the supporting member 15, and the fitting portion can be fitted non-rotatably to the other of the cap 17 and the supporting member 15. When a hole is provided, the opening pressure of the expansion piston valve 4 can be easily adjusted by rotating the piston rod 3 outside the shock absorber D, and the adjustment of the damping force characteristic of the expansion stroke of the shock absorber D becomes easy. .

  Further, the damping valve V2 has a valve disc as the valve case 6 and is provided with a support member 16 which can be moved close to the valve case 6 and supports the inner periphery of the base valve 7 as a leaf valve. Since the axial support position of the inner circumference of 7 is adjusted, it is possible to adjust the valve opening pressure of the base valve 7 without requiring the installation of a coil spring for energizing the base valve 7. Therefore, in the damping valve V2 of the present invention, it is possible to adjust the damping force characteristic when the piston speed is in the middle to high speed region on the contraction stroke side while shortening the total length of the damping valve V2. According to the damping valve V2 and the shock absorber D of the present invention, the total length of the damping valve V2 can be shortened, and the stroke length can be secured without causing the overall length of the shock absorber D to increase. In addition, it is possible to adjust the damping force characteristic when the piston speed is in the middle to high speed region. Further, according to the shock absorber D of the present invention, the overall length of the shock absorber D does not have to be long, so the mountability of the shock absorber D on a vehicle or the like is also improved.

  The damping valve V2 can be installed at the end of the cylinder 1 of the shock absorber D. Specifically, the valve case 6 may be attached to the end of the cylinder 1, the fitting portion 17e of the cap 17 may be eliminated, and the pressure side chamber R2 and the reservoir R in the tank T may be partitioned. In this case, the tank 9 and the passage 9a of the rod guide 9 may be eliminated, and an annular gap (annular passage 19 in FIG. 1) between the cylinder 1 and the outer cylinder 18 may be used as the reservoir R. In this case, if the mounting shaft portion 16a of the support member 16 is made to penetrate the cap 17, the valve opening pressure adjustment of the base valve 7 in the damping valve V2 can be performed from outside the shock absorber D. In this case, one of the support member 16 and the support member 15 is provided with a fitting hole, and the other is provided with a fitting portion insertable into the fitting hole, and the support member 16 is rotated by a tool to rotate the piston rod 3 The support member 15 is rotated to adjust the valve opening pressure of the expansion side piston valve 4 by the operation from the outside of the shock absorber D.

  Furthermore, in the damping valve V2, the valve case 6 as a valve disc is annular, the support member 16 is axially movable in the valve case 6, and the base valve 7 as a leaf valve is mounted on the outer periphery Since the mounting shaft portion 16a to be mounted and the flange-like support portion 16b provided on the mounting shaft portion 16a to support the inner periphery of the base valve 7 on the opposite side of the valve disc are provided, the base valve is very simple. The valve opening pressure of 7 can be adjusted.

  Further, the structure of the damping valve V2 may be used for the piston portion of the shock absorber D. In this case, the piston rod 3 is hollow, and the support member 16 is inserted in the piston rod 3 in a direction opposite to that of FIG. 3 so that the support portion 16 b can support the inner periphery of the expansion piston valve 4. Just do it. In this way, the mounting shaft portion 16 a of the support member 16 can be accessed from the outside of the shock absorber D from the upper end opening of the piston rod 3, and the support member 16 is moved in the axial direction with respect to the piston rod 3. The support portion 16b can be moved toward and away from it. Therefore, the inner peripheral support position of the expansion side piston valve 4 can be moved in the axial direction by the rotation operation of the support member 16, and the valve opening pressure adjustment of the expansion side piston valve 4 can be performed from outside the shock absorber D.

  Furthermore, in the case of this shock absorber D, it is possible to adjust the opening pressure of the expansion side piston valve 4 that exerts a damping force at the extension stroke of the shock absorber D and the base valve 7 that exerts the damping force at the contraction stroke. It is possible to adjust the damping force characteristics of both the expansion and contraction of the vessel D.

  Further, in the case of this shock absorber D, the cylinder 1, the piston 2 inserted in the cylinder 1, the expansion side chamber R 1 and the pressure side chamber R 2 partitioned in the cylinder 1 by the piston 2, the inside communicates with the inside of the cylinder 1 A tank T, a valve case 6 as a valve disc which is provided in the tank T and divides the inside of the tank T into a reservoir R and a pressure side chamber R2, a support member 16 which can be approached to the valve case 6; A damping valve V2 for adjusting the valve opening pressure of the base valve 7 is provided at the end of the cylinder 1 and has a base valve 7 as a leaf valve which is stacked on the valve case 6 and whose inner periphery is supported by the support member 16. Compared with the case where it is provided, it can contribute to shortening of the total length of the shock absorber D, and the mountability of the shock absorber D on a vehicle etc. is further improved.

Then, in the case of this shock absorber D, the cylinder 1, the piston 2 inserted in the cylinder 1, the expansion side chamber R 1 and the pressure side chamber R 2 partitioned in the cylinder 1 by the piston 2 and the inside communicate with the inside of the cylinder 1 , A valve case 6 as a valve disc provided in the tank T to divide the inside of the tank T into a reservoir R and a pressure side chamber R 2 , a support member 16 capable of making the valve case 6 accessible, and a valve The valve case 6 is provided with a base valve 7 as a leaf valve stacked on the reservoir R side of the case 6 and supported on the inner periphery by the support member 16 and a lower cap 23 closing the end of the tank T. Is fixed inside, the base valve 7 is stacked on the reservoir R side of the valve case 6, and the support member 16 supports the inner periphery of the base valve 7 on the reservoir R side by the support portion 16b. The mounting shaft portion 16 a is screwed to the lower cap 23 through the valve case 6 and the lower cap 23. Therefore, the support member 16 can be accessed from the outside of the shock absorber D, the valve opening pressure adjustment of the base valve 7 can be easily performed from the outside of the shock absorber D, and the adjustment of the damping force characteristic of the contraction stroke of the shock absorber D becomes easy.

  Having thus described the embodiments of the present invention, the scope of the present invention is not limited to the precise details shown or described.

Reference Signs List 1 cylinder 2 piston (valve disc) 2a extension side port 2c extension side valve seat (annular valve seat) 3 piston rod 4 · · · Extension side piston valve (leaf valve), 6 · · · Valve case (valve disc), 6a · · · Discharge port (port), 6c · · · Discharge side valve seat (annular valve seat), 7 · · · Base valve (leaf valve), 12 ... piston nut (shaft member) 15, 16 ... support member, 15a ... cylinder part, 15c ... fitting hole, 16a ... mounting shaft part, 16b ··· Support section, 17 ··· Cap, 17e ··· Fitting section, 23 ··· Lower cap, R ··· Reservoir, R1 ··· Extended side chamber, R2 ··· Pressure side chamber, T ··· ··tank,

Claims (9)

A valve disc having a port and an annular valve seat provided on an outer periphery of the port;
An annular leaf valve which has an outer periphery supported by the annular valve seat and an inner periphery spaced apart from the valve disc and stacked on the valve disc and seated on the annular valve seat to open and close the port;
A support member which is movable to and from the valve disc and supports the inner periphery of the leaf valve ;
And a shaft member upstanding from the valve disc and mounted on the outer periphery of the leaf valve,
The damping member has a cylindrical portion mounted so as to be movable in the axial direction on the outer periphery of the shaft member, and the cylindrical portion supports the inner periphery on the opposite side of the valve disc of the leaf valve. . A valve disc having a port and an annular valve seat provided on an outer periphery of the port;
An annular leaf valve stacked on the valve disc and seated on the annular valve seat to open and close the port;
A supporting member which is movable in the vicinity of the valve disc to support the inner periphery of the leaf valve and which can adjust an initial deflection amount of the leaf valve ;
And a shaft member upstanding from the valve disc and mounted on the outer periphery of the leaf valve,
The damping member has a cylindrical portion mounted so as to be movable in the axial direction on the outer periphery of the shaft member, and the cylindrical portion supports the inner periphery on the opposite side of the valve disc of the leaf valve . A valve disc which is annular and has a port and an annular valve seat provided on the outer periphery of said port;
An annular leaf valve which has an outer periphery supported by the annular valve seat and an inner periphery spaced apart from the valve disc and stacked on the valve disc and seated on the annular valve seat to open and close the port;
And a support member which is movable in the vicinity of the valve disc and supports the inner periphery of the leaf valve.
The support member is axially movably inserted into the valve disc and mounted on an outer periphery of the mounting shaft portion on which the leaf valve is mounted, and the mounting shaft portion is provided on the opposite valve disc side of the leaf valve And a flange-like support portion for supporting the circumference
Damping valve characterized by. A ring-shaped, a valve disk having a port and an annular valve seat provided on an outer periphery of the port,
An annular leaf valve stacked on the valve disc and seated on the annular valve seat to open and close the port;
And a support member which is movable in the vicinity of the valve disc to support the inner periphery of the leaf valve and which can adjust an initial deflection amount of the leaf valve.
Wherein the support member, the the valve in the disk is inserted axially movably mounting shaft portion of the leaf valve is mounted on the outer peripheral, the provided mounting shaft portion of the counter-valve disc side of the leaf valve damping valve, characterized in that it comprises a flange-shaped support portion for supporting the periphery. With the cylinder,
A piston inserted into the cylinder;
An expansion side chamber and a pressure side chamber defined in the cylinder by the piston;
A piston rod inserted into the cylinder and coupled to the piston;
And a damping valve according to any one of claims 1 to 4,
A shock absorber characterized in that the valve disc is the piston. With the cylinder,
An annular piston inserted into the cylinder;
An expansion side chamber and a pressure side chamber defined in the cylinder by the piston;
A piston rod inserted into the cylinder and having a tip inserted into the piston;
A piston nut screwed to an end of the piston rod to fix the piston to the piston rod;
Damping valve,
And a cap provided at an end of the cylinder to close the cylinder end.
The damping valve is
A valve disc having a port and an annular valve seat provided on an outer periphery of the port;
An annular leaf valve stacked on the valve disc and seated on the annular valve seat to open and close the port;
A shaft member which rises from the valve disc and is mounted on the outer periphery of the leaf valve;
Support that supports the inner periphery of the leaf valve on the side opposite to the valve disc, which has a cylindrical portion that can be moved close to the outer periphery of the shaft member. Having a member,
The valve disc is the piston;
The shaft member is the piston nut;
The cylindrical portion of the support member is screwed to the piston nut;
The leaf valve is stacked on the pressure side chamber side of the piston,
A shock absorber is provided with a fitting portion on one of the cap and the support member, and a fitting hole on the other of the cap and the support member, the fitting portion being non-rotatably fittable. . With the cylinder,
A piston inserted into the cylinder;
An expansion side chamber and a pressure side chamber defined in the cylinder by the piston;
A tank whose inside communicates with the inside of the cylinder;
A valve case provided in the tank to divide the inside of the tank into a reservoir and the pressure side chamber;
And an attenuated valve,
The damping valve is
A valve disc having a port and an annular valve seat provided on an outer periphery of the port;
An annular leaf valve which has an outer periphery supported by the annular valve seat and an inner periphery spaced apart from the valve disc and stacked on the valve disc and seated on the annular valve seat to open and close the port;
A support member which is movable in the vicinity of the valve disc and supports the inner periphery of the leaf valve;
A shock absorber characterized in that the valve disc is the valve case. With the cylinder,
A piston inserted into the cylinder;
An expansion side chamber and a pressure side chamber defined in the cylinder by the piston;
A tank whose inside communicates with the inside of the cylinder;
A valve case provided in the tank to divide the inside of the tank into a reservoir and the pressure side chamber;
Equipped with a damping valve,
The damping valve is
A valve disc having a port and an annular valve seat provided on an outer periphery of the port;
An annular leaf valve stacked on the valve disc and seated on the annular valve seat to open and close the port;
And a support member which is movable in the vicinity of the valve disc and which supports the inner periphery of the leaf valve and which can adjust an initial deflection amount of the leaf valve.
The valve disc is used as the valve case
A shock absorber characterized by With the cylinder,
A piston inserted into the cylinder;
An expansion side chamber and a pressure side chamber defined in the cylinder by the piston;
A tank whose inside communicates with the inside of the cylinder;
A valve case provided in the tank to divide the inside of the tank into a reservoir and the pressure side chamber;
Equipped with a damping valve,
The damping valve is
A valve disc which is annular and has a port and an annular valve seat provided on the outer periphery of said port;
An annular leaf valve stacked on the valve disc and seated on the annular valve seat to open and close the port;
A mounting shaft which is inserted into the valve disk so as to be movable in the axial direction and is mounted on the outer periphery of the leaf valve, and is mounted on the mounting shaft and is mounted opposite the leaf valve. And a support member having a flange-like support portion for supporting the inner periphery on the valve disc side,
The tank is cylindrical and has a lower cap closing the end,
The valve disc is used as the valve case and fixed in the tank.
The leaf valve is stacked on the reservoir side of the valve case,
The support member supports the inner periphery of the leaf valve on the reservoir side by the support portion, and the mounting shaft portion is screwed to the lower cap through the valve case and the lower cap. Shock absorber.

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