JP2006170351A - Valve structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a valve structure capable of securing a sufficient flow rate even when a cracking pressure is increased.
SOLUTION: In a valve structure including a valve body 3 in which a port 1 is formed and a plate-like valve body 10 that is energized and stacked on the valve body 3 to close the port 1, the plate-like valve body 10 and the valve body 3 are provided. An adjustment member 15 for adjusting the pressure receiving area of the plate-like valve body 10 is interposed between the pressure receiving area and the pressure receiving area can be changed by an area where the adjustment member 15 wraps around the port 1.
[Selection] Figure 1

Description

  The present invention relates to an improved valve structure.

  Conventionally, in this type of valve structure, for example, an annular groove which is embodied in a piston portion of a shock absorber and which is called a window communicating with each port is formed at an outlet end of a port provided in the piston portion. It is known to open and close a port by opening and closing a window with a laminated leaf valve.

  The radial width dimension of the window is set to be larger than the diameter of the port, and the laminated leaf valve is formed by laminating several annular plate-like valves and provided on the outer peripheral side of the window. It is in contact with an annular valve seat.

Therefore, the pressure receiving area of the laminated leaf valve is the opening area of the window, that is, the flow path area (see, for example, Patent Document 1).
Japanese Patent Laying-Open No. 2004-257507 (paragraph number 0019, FIG. 1)

  By the way, in the shock absorber, it may be better to increase the damping force in a region where the piston speed is low.

  In the region where the piston speed is low, when the damping force is increased, it is conceivable to increase the pressure when the leaf valve is separated from the valve seat, that is, the cracking pressure. As a method of increasing the cracking pressure, There is a method of reducing the pressure receiving area of the leaf valve.

  However, in order to reduce the pressure receiving area in the conventional valve structure, the opening area of the window must be reduced. However, if the window is reduced, the diameter of the port must be reduced. In this case, a sufficient flow rate cannot be secured.

  Accordingly, the present invention was devised in order to improve the above-described problems, and its object is to provide a valve structure that can ensure a sufficient flow rate even when the cracking pressure is increased. That is.

  In order to solve the above-described object, the valve structure in the first problem solving means of the present invention includes a valve body in which a port is formed, and a plate-like valve body that is energized and stacked on the valve body to close the port. The valve structure is characterized in that an adjustment member for adjusting the pressure receiving area of the plate-like valve body is interposed between the plate-like valve body and the valve body.

  Furthermore, the valve structure in the second problem-solving means includes a valve body in which an annular window communicated with a port and an outlet end of the port is formed, and a plate-shaped valve body that is energized and stacked on the valve body to close the window In the valve structure having the above-described configuration, an adjusting member for adjusting a pressure receiving area of the plate-like valve body is interposed between the plate-like valve body and the valve body.

  The valve structure in the third problem solving means includes a piston in which an annular window communicated with a port and an outlet end of the port is formed, and a plate-like valve body that is energized and stacked on the piston to close the window. The valve structure is characterized in that an adjustment member for adjusting the pressure receiving area of the plate-like valve body is interposed between the plate-like valve body and the piston.

  According to the invention of each claim, the pressure receiving area of the plate-shaped valve body can be adjusted by the size of the area where the adjustment member wraps on the window or the port, thereby reducing the cracking pressure of the plate-shaped valve body. Can be adjusted.

  The flow rate when the piston speed becomes medium and high is ensured by the adjustment member separating from the port outlet end and the port being fully opened, and when the piston speed becomes medium and high, the flow rate is insufficient and is more than necessary. There is no concern that a damping force will be generated and the ride comfort in a vehicle equipped with a shock absorber will be deteriorated.

  Therefore, a sufficient flow rate is ensured even when the cracking pressure is increased.

  In addition, the cracking pressure of the plate-shaped valve body can be easily changed depending on the area where the adjustment member wraps on the window or port, and the cracking pressure can be reduced by replacing the adjustment member while maintaining the shape of the valve body as it is. Since the adjustment can be performed, it is not necessary to make the shape of the valve body special, so that the production cost is also improved.

  In addition, the cracking pressure can be increased by reducing the pressure-receiving area, thereby generating the required damping force even when the piston speed is very low in the shock absorber in which the valve structure is embodied. In addition, the damping force when the piston speed is in the low speed range can be increased compared to the damping force of the conventional valve structure, and the riding comfort in the vehicle can be improved.

  The valve structure of the present invention will be described below with reference to the drawings. FIG. 1 is a longitudinal sectional view of a piston portion of a shock absorber in which a valve structure according to an embodiment is embodied. FIG. 2 is a partially enlarged plan view of a piston in which the valve structure is embodied.

  As shown in FIG. 1, the valve structure of the present invention is embodied in a piston portion of a shock absorber, and has a ring body as a valve body having a plurality of ports 1 and a window 2 that is an annular groove communicating with each port 1. Piston 3, a leaf valve 10 that is a plate-like valve body that opens and closes the downstream end of the port 1, an adjustment member 15 interposed between the piston 3 and the leaf valve 10, and the leaf valve 10 is connected to the piston 3. And a spring 20 biased in the direction.

  On the other hand, a shock absorber in which this valve structure is embodied is well known and will not be described in detail, but specifically, for example, a cylinder 30 and a head member (not shown) for sealing the upper end of the cylinder 30. ), A piston rod 31 slidably penetrating a head member (not shown), a piston 3 provided at an end of the piston rod 31, an upper chamber R1 defined by the piston 3 in the cylinder 30 and a lower chamber The chamber R2 is configured to include a sealing member (not shown) that seals the lower end of the cylinder 30.

  The piston 3 includes an annular disk portion 4 and a sliding contact portion 5 that extends from the outer peripheral side of the disk portion 4 and slidably contacts the inner periphery of the cylinder 30. Are formed at the lower end of the disk portion 4 in the drawing, and a plurality of compression side ports 6 formed on the outer peripheral side of the port 1. An annular window 2 that communicates the outlet end of each port 1 and an annular valve seat 7 on which a leaf valve 10 is seated on the outer peripheral side of the window 2 are provided.

  A valve stopper 34, a spacer 35, a pressure side leaf valve 36, and the piston 3 are inserted into the reduced diameter portion 32 of the piston rod 31 from the top in FIG. Each member is fixed to the piston rod 31 by a piston nut 37 screwed to the provided screw portion 33.

  The piston nut 37 includes a cylindrical portion 38 having a screw portion 39 screwed to the screw portion 33 on the inner peripheral side, and a screw portion 41 extending from the lower end of the cylindrical portion 38 in the drawing. The head part 40 is provided.

  On the other hand, the adjustment member 15 is formed in an annular shape and is accommodated in the window 2, and is inserted slidably on the outer periphery of the cylindrical portion 38 of the piston nut 37 on the inner peripheral side thereof. The piston nut 37 can be moved up and down.

  Further, the adjustment member 15 is set so as to reduce the opening area at the outlet end of the port 1, that is, to wrap in the port 1 when contacting the bottom surface 2 a of the window 2.

  In turn, the leaf valve 10 is formed in an annular shape, and a plurality of sheets are laminated to form a laminated leaf valve. Specifically, the leaf valve 11 facing the port 1 and having a C-shaped long hole, A leaf valve 12 including four arc-shaped elongated holes that are stacked on the leaf valve 11 and provided at equal intervals in the circumferential direction, and a choke that communicates the elongated hole with the outer periphery, and the leaf valve 12 is stacked. When the piston speed is low during expansion / contraction of the shock absorber, the hydraulic oil in the cylinder 30 passes through the choke in the leaf valve 12 and bends and attenuates the leaf valve 13. When a force is generated and the piston speed is high during expansion and contraction of the shock absorber, the entire leaf valve 10 can be bent to generate a damping force.

  The shape of the choke or the long hole is not limited to this, and may be set so as to generate an optimum damping force according to the specifications of the shock absorber. A stamped orifice is formed in the valve seat 7. In this case, the leaf valves 11, 12, and 13 may not be formed with chokes or long holes, but may be simply formed as ring-plate shaped leaf valves.

  The piston nut 37 is inserted on the inner peripheral side of the leaf valve 10, and the leaf valve 11 arranged at the uppermost stage in the drawing is brought into contact with the adjusting member 15 and the valve seat 7.

  Accordingly, the port 1 can be opened and closed by the leaf valve 10 being seated on and off the valve seat 7.

  Further, the cylindrical portion 38 of the piston nut 37 is inserted into the annular spacer 45, the valve stopper 21, the spring 20 and the spring receiver 22 in order from the top in the drawing, and each member is fixed to the piston nut 37 with the nut 46. Yes.

  With the above configuration, the adjusting member 15, the leaf valve 10, and the spacer 45 are urged toward the disk portion 4 side of the piston 3 by the spring 20.

  Further, the pressure receiving area of the leaf valve 10 is such that the leaf valve 10 is in contact with the adjusting member 15, so that the adjusting member 15 wraps from the opening area of the window 2 to the opening area of the window 2 as shown in FIG. 2. This is the area divided by the area.

  Therefore, in the valve structure embodied in the piston portion, the pressure receiving area of the leaf valve 10 which is a plate-like valve body can be adjusted by the size of the area where the adjustment member 15 is wrapped in the window 2. It is.

  When the shock absorber extends, the hydraulic fluid moves from the upper chamber R1 to the lower chamber R2 through the port 1, but when the piston speed is low, the leaf valve 10 is seated on the valve seat 7. Set to maintain.

  When the piston speed reaches a predetermined speed, the leaf valve 10 is bent and separated from the valve seat 7, and the leaf valve 10 opens the port 1.

  The cracking pressure when the leaf valve 10 bends and separates from the valve seat 7 is determined by the pressure receiving area, and the cracking pressure can be increased as the pressure receiving area is smaller.

  That is, in this valve structure, the cracking pressure can be increased by reducing the pressure receiving area, and as shown in FIG. 3, the required damping force even when the piston speed is very low. Further, the damping force a in the low speed region indicated by the solid line in the figure can be made larger than the damping force b of the conventional valve structure indicated by the broken line in the figure.

  Therefore, if a shock absorber in which this valve structure is embodied is mounted on a vehicle, the ride comfort in the vehicle can be improved.

  When the pressure difference between the upper chamber R1 and the lower chamber R2 reaches the cracking pressure, the leaf valve 10 bends and separates from the valve seat 7 as described above. When the pressure difference in R2 increases, that is, the piston speed increases, the hydraulic oil pushes down the leaf valve 10 as a whole against the spring force of the spring 20 in FIG.

  At this time, the hydraulic oil pushes down the adjusting member 15 together with the leaf valve 10 downward in FIG. 1, and the adjusting member 15 is separated from the bottom surface 2a of the window 2 and detached from the outlet end of the port 1. The flow path area at port 1 is the opening area of port 1.

  That is, the flow rate when the piston speed becomes medium and high is ensured by fully opening the port 1, and when the piston speed becomes medium and high, the flow rate becomes insufficient and an excessive damping force is generated. There is no concern that the riding comfort of the vehicle equipped with the device will be deteriorated.

  Therefore, in this valve structure, a sufficient flow rate can be ensured even when the cracking pressure is increased.

  Further, the cracking pressure of the leaf valve 10 which is a plate-like valve body can be easily changed by the area where the adjustment member 15 wraps on the window 2, and the shape of the piston 3 which is the valve body remains the existing shape as it is, and the adjustment member Since the cracking pressure can be adjusted by replacing 15, it is not necessary to make the piston shape special, so that the production cost is also improved.

  Furthermore, since the pressure receiving area is adjusted by the adjusting member, the valve seat is burred during drilling to form the port, compared with the method of reducing the pressure receiving area by reducing the width of the window, and the burr is formed. There are no problems such as requiring additional work to remove or increasing the number of processing steps.

  In addition, in the place mentioned above, although the adjustment member 15 is comprised by one component, you may comprise this by laminating | stacking several annular thin plates.

  In the present embodiment, the inner peripheral side of the leaf valve 10 is biased toward the piston 3 by the spring 20, but the shape of the valve stopper 21 is changed to change the outer peripheral side of the leaf valve 10. You may make it energize.

  Further, in the present embodiment, the window 2 is provided in order to apply the pressure uniformly to the leaf valve 10 in the valve opening direction, but the plate-like valve body is applied directly to the outlet end of the port without providing the window 2. In the case of contact, if the adjustment member is provided so as to wrap around the port, the pressure receiving area of the plate-like valve body can be adjusted, so that the effect of the present invention is lost in this case as well. Absent.

  From the above description, the case where the valve structure of the present invention is embodied in the piston portion of the shock absorber has been described, but it is needless to say that the valve structure may be embodied in the base valve portion.

 This is the end of the description of the embodiment of the present invention, but the scope of the present invention is of course not limited to the details shown or described.

It is a longitudinal cross-sectional view of the piston part of the shock absorber in which the valve structure in one embodiment was embodied. It is a partial enlarged plan view of a piston in which a valve structure is embodied. It is a figure which shows the attenuation | damping characteristic of the buffer with which the valve structure was embodied.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Port 2 Window 2a Bottom face 3 Piston 4 which is a valve body 4 Disc part 5 Sliding contact part 6 Pressure side port 7 Valve seat 10 Leaf valve 11, 12, 13 which is a plate-shaped valve body Leaf valve 15 Adjustment member 20 Spring 21, 34 Valve stopper 22 Spring receiver 30 Cylinder 31 Piston rod 32 Reduced diameter portion 33 Screw portion 35 Spacer 36 Pressure side leaf valve 37 Piston nut 38 Tube portion 39 Screw portion 40 Head portion 41 Screw portion 45 Spacer 46 Nut R1 Upper chamber R2 Lower chamber

Claims (3)

In a valve structure including a valve body in which a port is formed and a plate-shaped valve body that is energized and stacked on the valve body to close the port, the pressure receiving area of the plate-shaped valve body between the plate-shaped valve body and the valve body A valve structure characterized in that an adjustment member for adjusting the pressure is interposed. In a valve structure comprising a valve body formed with an annular window communicating with a port and an outlet end of the port, and a plate-shaped valve body that is energized and stacked on the valve body to close the window, the plate-shaped valve body and the valve A valve structure characterized in that an adjustment member for adjusting a pressure receiving area of a plate-like valve body is interposed between the body and the body. In a valve structure including a piston formed with an annular window communicating with a port and an outlet end of the port, and a plate-shaped valve body that is urged and stacked on the piston to close the window, the plate-shaped valve body and the piston A valve structure characterized in that an adjusting member for adjusting a pressure receiving area of a plate-like valve element is interposed therebetween.

Images