KR100745353B1 - Reservoir guide of the damping force adjustable shock absorber - Google Patents

Abstract

The present invention relates to a reservoir guide of a damping force variable shock absorber for a vehicle.

In the reservoir guide of the damping force variable shock absorber provided outside the separator tube for guiding and ejecting oil discharged from the supply oil port formed in the housing of the variable damping force variable valve to the storage compartment, the shape of a pressed elliptic tube having an open end is provided. And a supply side port portion, which is a circular hole connected to the supply oil port on the upper surface, guides the oil ejected from the supply oil port to flow through the inside to flow out into the storage chamber, and protrudes on the separator tube. It is characterized in that it is provided with a fitting hole portion for fixed mounting by simply fitting the port portion of the compression side.

Therefore, the size is small, the weight is reduced, and the mounting thereof is simple, and the manufacturing cost can be reduced and the productivity can be improved.

Description

Reservoir guide of variable damping force type shock absorber {RESERVOIR GUIDE OF THE DAMPING FORCE ADJUSTABLE SHOCK ABSORBER}

1 is a cross-sectional view of a conventional damping force variable shock absorber,

2 is a view showing a state where the reservoir guide is mounted on the outside of the separator tube in the conventional damping force variable shock absorber;

3 is a cross-sectional view of the mounting state of FIG.

4 is a view showing a state in which a reservoir guide according to the present invention is mounted outside the separator tube,

5 is a perspective view showing a reservoir guide according to the present invention,

6 is a cross-sectional view taken along the line AA ′ of FIG. 5;

7 is a cross-sectional view of the mounting state of FIG.

<Description of the symbols for the main parts of the drawings>

1: Shock absorber 2: External view

3: inner tube 3a, 3b: communication hole

4: Storage Room 5: Body Valve

5a: tension passage 5b: compression passage

6: piston 6a: tension passage                 

6b: compression passage 7: piston rod

8: Separator tube 8a, 8b: Fluid passage

8a-1: tension side port portion 8b-1: compression side port portion

9: sealing member 10a: tension chamber

10b: compression chamber 11: reservoir guide

11a: supply side port portion 12: caulking point

20: damping force variable valve 21: housing

22: tension oil port 23: compression oil port

24: supply oil port 25: tension variable valve

26: compression variable valve 27: spool rod

28a: upper side flow path 28b: lower side flow path

29 solenoid actuator 30 spool

110: reservoir guide 110a: supply side port portion

110b: fitting hole

The present invention relates to a reservoir guide of a damping force variable shock absorber for a vehicle. More specifically, the present invention relates to a reservoir guide of a shock absorber. This invention relates to a reservoir guide of a damping force variable shock absorber that is fixedly mounted on the separator tube side by a simple fitting type rather than a caulking method.

In general, a shock absorber mounted on a suspension of a vehicle is installed between the axle and the vehicle body to absorb vibrations or shocks received by the axle from the road surface to improve ride comfort. Oil and / or gas is filled.

Such a shock absorber has a damping force variable type shock absorber that can adjust the damping force characteristics appropriately to improve ride comfort or maneuvering stability according to the road surface and driving conditions. It has a form provided with a damping force variable valve for.

1 is a cross-sectional view of a conventional damping force variable shock absorber.

The shock absorber 1 is a double tube including a coaxial inner tube 3 and an outer tube 2, and a storage chamber 4 is formed between the inner tube 3 and the outer tube 2. Inside the inner tube 3, a piston 6 fixed to the lower end of the piston rod 7 is provided so as to be able to slide up and down so that the inside of the inner tube 3 is provided with an upper tension chamber 10a and a lower compression chamber. It divides into (10b). The upper end of the piston rod (7) extends through the upper end of the inner tube (3) and the outer tube (2), the body valve (5) separating the compression chamber (10b) and the storage chamber (4) is an inner tube ( 3) is installed at the bottom.

In addition, a compression passage 6b and a tension passage 6a are formed in the piston 6 so that the tension chamber 10a and the compression chamber 10b communicate with each other, and the body valve 5 has a compression chamber 10b and a storage chamber ( The compression passage 5b and the tension passage 5a are formed to communicate 4).                         

A separator tube 8 is also coaxially arranged to surround the outer circumferential surface of the inner tube 3 so that the annular fluid passages 8a and 8b between the inner tube 3 and the separator tube 8 are both upper, lower and middle. It is formed up and down by the three sealing members (9), the fluid passage (8a, 8b) is respectively through the tension chamber (10a) and through the communication holes (3a, 3b) provided on the upper and lower sides of the inner tube (3), respectively. It communicates with the compression chamber 10b.

Furthermore, the damping force variable valve 20 is mounted on one side of the outer tube 2, and the damping force variable valve 20 has three connection ports formed in the housing 21, that is, the tension oil port 22 and the compressed oil port. (23) and the fluid passageway (8a, 8b) and the storage chamber (4) through the supply oil port 24, the fluid flowing through the fluid passage (8a, 8b) and the compression chamber (10b) and the storage chamber (4) ) To change the damping force.

In addition, a tension variable valve 25 and a compression variable valve 26 are installed in the housing 21 of the damping force variable valve 20, and the central variable portions of the tension variable valve 25 and the compression variable valve 26 pass through them. The cylindrical spool rod 27 is mounted in one state, and the spool rod 27 communicates with the tension variable valve 25, the compression oil port 23, and the compression variable valve 26 and the supply oil port 24. Flow paths 28a and 28b are formed on the upper and lower sides, respectively, and inside the spool rod 27, the spool 30 is installed to be linearly movable by the solenoid actuator 29 attached to the opening side of the housing 21. The damping force is varied by changing the area of the flow paths 28a and 28b according to the application of the current to the solenoid actuator 29 to adjust the ejection pressure of the oil.

The conventional damping force variable shock absorber (1) having such a configuration works as follows.

First, when the piston rod 7 is compressed, the oil of the compression chamber 10b is moved to the tension chamber 10a through the compression passage 6b of the piston 6 and at the same time the compression passage 5b of the body valve 5 The damping force is generated while being moved to the storage compartment 4 through), and during tensioning, the oil of the tension chamber 10a is moved to the compression chamber 10b through the tension passage 6a of the piston 6 and at the same time the storage compartment ( The oil of 4) is moved to the compression chamber 10b through the tension channel 5a of the body valve 5 to generate a damping force.

In addition, the damping force is changed by the damping force variable valve 20 mounted on one side of the outer tube (2). In the tension stroke, the solenoid actuator 29 moves the spool 30 to the spool rod 27. The oil passage 22a of the upper side flow path 28a is opened, and the oil inside the tension chamber 10a passes through the fluid passage 8a of the upper side to form a tension oil port 22 formed in the housing 21 of the damping force variable valve 20. After flowing through the upper flow path 28a, which is opened by the spool 30, through the compressed oil port 23 of the housing 21 and into the fluid passage 8b on the lower side, The damping force is varied in a manner that is ejected into the chamber 10b.

On the other hand, during the compression stroke, the solenoid actuator 29 moves the spool 30 to open the lower flow path 28b of the spool rod 27, and the oil inside the compression chamber 10b is the fluid passage on the lower side. After passing through 8b and flowing through the compressed oil port 23 formed in the housing 21 of the damping force variable valve 20, the housing 21 passes through the lower side flow path 28b opened by the spool 30. The damping force is varied in a manner that is ejected to the storage compartment 4 through the supply oil port 24 of the).

In the damping force variable shock absorber 1 as described above, as shown in detail in FIGS. 2 and 3, the separator tube 8 is a tension side which is a circular hole connected to the tension oil port 22 and the compression oil port 23. The port portion 8a-1 and the compression-side port portion 8b-1 are formed to protrude from each other, and the cylindrical reservoir guide 11 having an end opening to surround the outer side thereof is mounted with a slight gap. In the reservoir guide 11, a supply side port portion 11a, which is an elliptical hole connected to the supply oil port 24, protrudes.

The role of the reservoir guide 11 is that a large amount of noise and bubbles are generated when oil having a high flow rate ejected from the damping force variable valve 20 through the supply oil port 24 is immediately ejected into the large space of the storage compartment 4, A gap is formed between the separator tube 8 to guide the oil ejected from the supply oil port 24 through the gap so as to flow out from the end to the storage chamber 4.

The reservoir guide 11 is inserted so as to surround the separator tube 8, and then a plurality of locations (mainly three points) of the outer circumferential surface are inserted into the separator tube through a caulking method to form a caking point 12. 8) is fixed to the side.

However, although the conventional reservoir guide 11 performs its function smoothly but is fixedly coupled by a caulking method, a separate caulking apparatus and a process are required, and a manufacturing process may inevitably be caused during a machining process. There was a problem that the cost is increased.

In addition, it has a cylindrical shape surrounding the separator tube (8), because the size is large, the material cost is excessively excessive, and the weight is heavy, there was also a problem of increasing the overall weight of the shock absorber (1).

The present invention was devised to solve the above-mentioned problems, and is simply fixed to the separator tube side by a simple fitting type rather than a caulking method, and its size is small so that the damping force can be reduced in weight, cost and productivity. The purpose is to provide a reservoir guide for a variable shock absorber.

The present invention for achieving the above object, in the reservoir guide of the damping force variable shock absorber is provided on the outside of the separator tube to guide the oil discharged from the supply oil port formed in the housing of the variable damping force valve to the storage chamber, the end portion In the form of a pressed oval tube with an opening, a supply side port portion, which is a circular hole connected to the supply oil port on an upper surface, guides the oil ejected from the supply oil port to flow through the inside and flows out into the storage compartment, It provides a reservoir guide of a damping force variable shock absorber, characterized in that it is integrally provided with a fitting hole portion for fixed mounting by simply fitting in the compression-side port portion protruding on the separator tube.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

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

Prior to the description, the same reference numerals are given to the same components as in the related art, and detailed description thereof will be omitted.

4 to 7 show the reservoir guide of the damping force variable shock absorber according to the present invention.

The reservoir guide 110 according to the present invention is not cylindrical in shape surrounding the separator tube 8 but is individually mounted on the separator tube 8 at the supply oil port 24 in a small size, the shape of which is open at the end. In the form of a pressed elliptic tube, a supply side port portion 110a which is an elliptical hole connected to the supply oil port 24 is formed on the upper surface of the predetermined position, and the separator tube ( The fitting hole 110b is formed so as to correspond to the compression-side port portion 8b-1 protruding on the 8), and the fitting hole 110b is connected to the compression-side port portion 8b-1 on the separator tube 8. By press-fitting, it can be fixed to the separator tube 8 side.

Therefore, the reservoir guide 110 is formed to cover only a part of the separator tube 8 without covering the entire circumference, and in the related art, the supply oil port 24 is provided through a gap formed between the separator tube 8 and the reservoir guide 110. Oil is ejected from the flow guide) flows, but according to the present invention, the oil flows into the reservoir guide 110 inside the reservoir (4) at the end.

In the related art, the separator tube 8 is fitted to surround the separator tube 8 and then fixed to the separator tube 8 side by caulking a number of locations along the circumference, but according to the present invention, the separator tube 8 is provided through the fitting hole 110b. By simply fitting into the compression side port part 8b-1, it becomes simple to fix and mount.

As a result, the oil having a high flow rate ejected from the supply oil port 24 is discharged directly to the large space of the storage compartment 4 as in the related art, while smoothly performing its original function of preventing noise and bubbles from being generated. Small material cost is low and weight can be reduced, and it can be simply fixed and mounted on the separator tube 8 side by simple fitting type instead of caulking method. Savings and productivity.

As a preferred example of the reservoir guide according to the present invention in FIG. 5, the upper and lower surfaces are illustrated in a horizontal form, but the upper and lower surfaces are rounded in parallel so that the upper and lower surfaces are in close contact with the outer circumferential surface of the separator tube 8 which is curved in a circular shape. Of course, it can also be in jin form.

In the foregoing description, it should be understood that those skilled in the art can make modifications and changes to the present invention without changing the gist of the present invention as merely illustrative of a preferred embodiment of the present invention.

According to the present invention, it is possible to achieve the effect that the size is small, light weight, and the mounting thereof is simple, thereby reducing manufacturing cost and improving productivity.

Claims (1)

In the reservoir guide of the damping force variable shock absorber provided on the outside of the separator tube in order to guide the oil discharged from the supply oil port formed in the housing of the variable damping force variable valve to the storage chamber, In the form of a pressed elliptical tube with an open end, a supply side port portion, which is a circular hole connected to the supply oil port on the upper surface, guides the oil ejected from the supply oil port to flow through the inside and flows out into the storage compartment. And a fitting hole part integrally fixed to the compression-side port part protruding on the separator tube to be fixedly fitted by a simple fitting method.

Images