KR101187037B1 - Damping force variable valve - Google Patents

Abstract

The present invention relates to a variable damping force valve, characterized in that a retainer guide for forming a guide flow path for guiding fluid from the high pressure chamber of the shock absorber to the inside of the retainer at the top of the retainer is fixed to the upper circumferential surface of the upper end of the spool guide. .

Spool Guide, Retainer, Retainer Guide, Guide Flow

Description

Damping force variable valve {DAMPING FORCE VARIABLE VALVE}

1 is a longitudinal sectional view of a damping force variable valve according to an embodiment of the present invention.

2 is an exploded cross-sectional view of an essential part of the damping force variable valve according to the embodiment of the present invention.

Description of the Related Art [0002]

2: valve housing 10: solenoid drive unit

20: Spool Guide 30: Spool

40: retainer 50: main disk

60 back pressure chamber 70 retainer guide

The present invention relates to a damping force variable valve, and more particularly, to a damping force variable valve configured to continuously vary the damping force in a damping force variable shock absorber.

In general, the shock absorber of the vehicle is installed in a moving means such as a vehicle to absorb and mitigate the vibration or shock transmitted from the wheel in contact with the road surface during the driving.

The shock absorber is preferably appropriately adjusted damping force characteristics in order to improve the ride comfort and steering stability of the vehicle according to the road surface, driving conditions and the like. For example, during normal driving, the damping force of the shock absorber is preferably lowered to sufficiently absorb the vibrations caused by the unevenness of the road surface and improve the riding comfort, and to suppress the change in attitude of the vehicle body during turning, acceleration, braking, and high speed driving. It is desirable to increase the damping force in order to improve steering stability.

To this end, recently, a damping force variable shock absorber configured to properly adjust the damping force characteristics by varying the damping force using a pilot control damping force variable valve has been developed.

In the damping force variable shock absorber, the oil in the piston loss passes through the damping force variable valve during the tension stroke and flows into the reservoir chamber while forming the damping force by the resistance, and during the compression stroke, the oil in the piston compartment flows into the reservoir check valve. After passing through, it passes through the damping force variable valve and flows into the reservoir chamber by forming the damping force by the resistance.

In general, the damping force variable valve of the damping force variable shock absorber is a pilot control method that controls the pressure-flow characteristic by solenoid driving, and continuously controls the damping force variable. The damping force at the tension stroke and the compression stroke at the solenoid current is controlled. Configured to increase or decrease the damping force. For example, the damping force variable valve of the pilot control method by the solenoid drive controls the damping force at the tension stroke and the damping force at the compression stroke in soft mode or hard mode by solenoid current control. This damping force control is achieved by controlling the back pressure formation and regulation of the back pressure chamber in which the spool moving in accordance with the solenoid drive is formed behind the disk valve.

As described above, the damping force variable shock absorber is provided externally with a damping force variable valve configured so that damping force control is performed by adjusting the back pressure to the disk valve of the spool moving in accordance with the solenoid drive.

The damping force variable valve is installed at the lower end of the valve housing, the upper end of which is coupled to the outer side of the shock absorber. The spool guide, the spool guide which is inserted into the spool guide so as to be movable upward and downward and whose lower end abuts against the pressure rod of the solenoid drive unit, and whose upper end abuts the coil spring interposed on the plug provided at the lower end of the spool guide, and the outer circumferential surface of the spool guide. And a main disk provided at the lower portion of the retainer and formed at a lower portion of the retainer to form a back pressure chamber. In addition, a retainer guide is formed at an upper portion of the retainer to form a guide flow path for guiding fluid from the high pressure chamber of the shock absorber to the inside of the retainer, and a nut for fixing the retainer is provided at the outer peripheral surface of the upper end of the spool guide.

In order to prevent the retainer guide from deviating from the damping force variable valve when pressure is applied to the retainer guide, a flat part is formed at the edge of the retainer guide and a step is formed at the upper end of the valve housing so that the flat part of the retainer guide is In contact with the stepped portion, the upward movement of the retainer guide was limited.

However, the structure in which the flat portion of the retainer guide and the stepped portion of the valve housing are in contact with each other has a problem that a defect occurs in sealing of the O-ring portion due to the relative tolerance of the flat portion of the retainer guide and the stepped portion of the valve housing. In order to prevent this, the flat portion of the retainer guide and the step portion of the valve housing must be processed very precisely, which causes a problem in that the manufacturing cost increases.

Accordingly, the present invention is to solve the problems of the prior art, and if the flat portion of the retainer guide is formed at the edge of the retainer guide and the stepped portion is formed at the upper end of the valve housing, the flat portion of the retainer guide does not contact the step portion of the valve housing. It is also an object of the present invention to provide a damping force variable valve configured to limit the upward movement of the retainer guide.

In order to achieve the above object, the damping force variable valve of the present invention is a retainer guide for forming a guide flow path for guiding fluid from the high pressure chamber of the shock absorber to the inside of the retainer at the upper part of the retainer on the upper outer peripheral surface of the spool guide. It is characterized in that fixed.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a longitudinal sectional view of a damping force variable valve according to an embodiment of the present invention. In the damping force variable valve according to the present embodiment, the retainer guide is fixed to the upper outer peripheral surface of the spool guide. As shown, the damping force variable valve 1 according to the present embodiment includes a solenoid drive unit 10, a spool guide 20, a spool 30, a retainer 40, and a main disk 50. Consists of.

The solenoid drive unit 10 is fixedly installed at the lower end of the valve housing 2, the upper end of which is coupled to the outside of the shock absorber, and the pressure rod that moves up and down in accordance with the current change of the solenoid 11 and the solenoid 11. 13 is provided in the drive block 15.

The spool guide 20 is a hollow cylindrical rod and is provided at the tip of the drive block 15 of the solenoid drive unit 10. A plug 21 is installed at an upper end of the spool guide 20, and a coil spring 23 is embedded under the plug 21. The spool guide 20 has a plurality of connection ports through which fluid flows. The plurality of connection ports include an inflow connection port 20a, a bypass connection port 20b, and a back pressure connection port 20c. do.

The inflow connection port 20a may include a retainer 40 and a main disk to introduce a portion of the hydraulic oil introduced into the space between the retainer 40 and the main disk 50 between the spool guide 20 and the spool 30. It is in communication with the space between 50).

The bypass connection port 20b bypasses a part of the hydraulic oil flowing into the space between the retainer 40 and the main disk 50 downstream of the main disk 50 without undergoing attenuation by the main disk 50. It communicates with the bypass passage 45 so that it may be.

The back pressure connecting port 20c communicates with the back pressure chamber 60 so that a part of the hydraulic oil flowing into the space between the retainer 40 and the main disk 50 flows into the back pressure chamber 60.

In the spool guide 20 according to the present invention, as shown in detail in FIG.

The spool 30 is configured to be inserted in the spool guide 20 to be sealed up and down. The lower end of the spool 30 abuts against the pressure rod 13 of the solenoid drive unit 10, and the upper end of the spool 30 is a coil spring 23 interposed on a plug 21 installed at the lower end of the spool guide 20. ). The spool 30 includes first and second large diameter portions 31 and 33 and a small diameter portion 32.

The retainer 40 is installed on the outer circumferential surface of the spool guide 20, and the inflow passage 41, the discharge passage 43, and the bypass passage 45 are formed therethrough.

The main disk 50 is disposed to cover the inflow passage 41 at the rear of the retainer 40 so as to directly face the hydraulic oil passing through the inflow passage 41 to generate a damping force. That is, the main disk 50 is opposed to the hydraulic fluid flowing through the inlet passage 41, and the hydraulic fluid is flowed back toward the discharge passage 43 while being turned back in the process of opposing.

In addition, an inner slit is formed inside the main disk 50 to allow a part of the hydraulic oil passing through the inflow passage 41 to flow in a direction other than the discharge passage 43. The inner slit is in constant communication with the inflow connecting port 20a of the spool guide 20. For the sake of clarity, it will be understood that the inner slit is formed inside the main disk 50 although the member number is not indicated on the component corresponding to the inner slit in the drawing.

The bypass passage 45 directly communicates the bypass connection port 20a of the spool guide 20 with the discharge passage 43.

The main disk 50 is installed under the retainer 40 to form a back pressure chamber 60 between the rear drive block 15.

The outer slit is formed outside the main disk 50. The outer slit is in constant communication with the discharge passage 43. The hydraulic oil introduced into the back pressure chamber 60 flows to the discharge passage 43 through the outer slit. For the sake of clarity, it will be understood that the outer slits are formed on the outer side of the main disk 50 although the reference numerals are not indicated on the components corresponding to the outer slits in the drawings.

In addition, a retainer guide 70 is formed at an upper portion of the retainer 40 to form a guide flow path for guiding fluid from the high pressure chamber of the shock absorber to the inside of the retainer 40, which is shown in detail in FIG. As shown, the female screw portion 75 is formed on the inner circumferential surface of the retainer guide 70, and the female screw portion 75 of the retainer guide 70 is coupled to the male screw portion 25 formed on the upper circumferential surface of the upper end of the spool guide 20. The retainer guide 70 is fixed to the upper part of the retainer 40 by fixing the retainer guide 70 to the upper outer peripheral surface of the spool guide 20. The present invention has a structure in which the retainer guide 70 is fixed to the spool guide 20 while removing the conventional nut member.

The upper end of the retainer guide 70 is formed with a connection port 71 connected to the high pressure chamber of the shock absorber to introduce fluid from the high pressure chamber of the shock absorber. In order to guide the fluid from the 71 to the inside of the retainer 40, a guide flow path 73 is formed which communicates from the connection port 71 to the inflow passage 41 inside the retainer 40.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the present invention as defined by the appended claims. And should not be construed as limiting the scope of the present invention, but rather should be construed as exemplifying the invention.

As described above, according to the damping force variable valve of the present invention, the retainer guide is fixed to the upper outer peripheral surface of the spool guide to limit the upward movement of the retainer guide, so that a flat portion is formed at the edge of the retainer guide and the upper end of the valve housing There is no need to form a stepped portion in the retainer guide so that the flat portion of the retainer guide abuts on the stepped portion of the valve housing, thereby eliminating the need for a precision machining process for forming the abutted portion in the retainer guide and the valve housing. Since it can be deleted, the structure of the valve housing is simplified and manufacturing cost is reduced.

In addition, in the related art, since the flat portion of the retainer guide abuts on the stepped portion of the valve housing, an outlet passage for transferring the fluid through the discharge passage of the retainer to the low pressure chamber should be formed in the retainer guide. However, in the present invention, the retainer guide fits into the valve housing. Since the structure does not reach, there is naturally a space for the fluid to pass between the retainer guide and the valve housing, so there is no need to install a separate outlet passage in the retainer guide.

Claims (3)

A retainer guide is fixed to the upper circumferential surface of the spool guide to form a guide flow path for guiding fluid from the high pressure chamber of the shock absorber to the inside of the retainer at the top of the retainer, The upper end of the retainer guide is formed with a connection port connected to the high pressure chamber of the shock absorber, And a guide flow passage formed in the retainer guide to communicate from the connection port to an inflow passage inside the retainer. The method according to claim 1, An internal thread portion is formed on an inner circumferential surface of the retainer guide, Damping force variable valve, characterized in that the male thread formed on the outer peripheral surface of the upper end of the spool guide. delete

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