KR101913142B1 - Damping force adjusting device for shock absorber and shock absorber assembly including the same - Google Patents

Abstract

The present invention provides a damping force varying mechanism for a shock absorber capable of improving the ease of mounting a shock absorber by reducing a projection height of a damping force varying mechanism from a shock absorber and a shock absorber assembly including the same. A damping force varying mechanism for a shock absorber mounted on the outside of a shock absorber, the damping force varying mechanism comprising: a damping force variable valve mounted outside the shock absorber; There is provided a damping force varying mechanism for a shock absorber comprising an actuator connected in parallel to the damping force variable valve.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a damping force varying mechanism for a shock absorber, and a shock absorber assembly including the damping force varying mechanism.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a damping force varying mechanism for a shock absorber and a shock absorber assembly including the shock absorber assembly. More particularly, the present invention relates to a damping force varying mechanism for a shock absorber which is mounted outside the shock absorber, And a shock absorber including the variable mechanism.

Generally, a shock absorber is a device mounted on a vehicle to attenuate, alleviate or suppress vibration transmitted from a road surface during running of the vehicle or rolling, nose up-down, hives, etc. caused by the behavior of the vehicle.

2. Description of the Related Art In recent years, with the development of automotive technology, there has been an increasing demand for a damping force variable shock absorber capable of varying the damping force as needed, such as the running state of a vehicle.

1 shows an external damping force variable shock absorber assembly in which a damping force generating mechanism is mounted on the outside of a shock absorber as an example of a damping force variable shock absorber.

As shown in the drawing, a shock absorber 50 of a conventional external damping force variable shock absorber assembly 100 includes an inner cylinder 52 whose lower end can be connected to an axle, And a piston rod 54 provided so as to reciprocate in the inner cylinder 52.

The inner cylinder 52 is filled with a working fluid such as gas or oil, and the outer cylinder 56 is disposed on the outer side thereof. A rod guide 57 and a body valve 58 are provided at the upper and lower ends of the inner cylinder 52 and the outer cylinder 56, respectively. The inner cylinder 52 is provided with a piston valve 55 which is coupled to one end of the piston rod 54 and divides an internal space into a rebound chamber 60 and a compression chamber 62. An upper cap 59a and a base cap 59b are installed on the upper and lower portions of the outer cylinder 56, respectively.

A reservoir chamber 64 is formed between the inner cylinder 52 and the outer cylinder 56 to compensate for the volume change in the inner cylinder 52 due to the reciprocating movement of the piston rod 54, The working fluid flow between the reservoir chamber 64 and the compression chamber 62 is controlled.

A damping force variable valve 70 for changing the damping force of the shock absorber 50 and a damping force variable valve 70 connected in series with the damping force variable valve 70 are provided at one side of the outer cylinder 56, A variable mechanism is mounted. A power line 85 for supplying power is connected to one side of the solenoid actuator 80.

An intermediate tube 68 communicating with the rebound chamber 60 of the inner cylinder 52 is provided between the inner cylinder 52 and the outer cylinder 56 to communicate with the rebound chamber 60 of the inner cylinder 52 Pressure side Ph connected to the reservoir chamber 64 and the low-pressure side Pl connected to the reservoir chamber 64 are formed.

Referring to FIG. 2, an external damping force variable shock absorber assembly 100 including a solenoid actuator 80 installed at one side of a shock absorber 50 and connected in series to a variable valve 70 and a variable valve 70, Sectional view of the damping force varying mechanism 90 of FIG.

The variable valve 70 includes a solenoid actuator 80 and a solenoid actuator 80. The solenoid actuator 80 is provided in the housing 71 with a spool rod 72 having a plurality of flow paths communicating with the fluid, And a spool 73 for opening and closing the respective flow paths is provided. To this end, the solenoid actuator 80 is provided with a pressing rod 82 operated by a solenoid 84 to start the spool 73. A spring 83 is provided at the rear of the pressing rod 82 to bring the pressing rod 82 into close contact with the spool 73.

The spool rod 72 is provided with a first ring disk 73a serving as a fixed orifice and a lower retainer 74 including a connection port 74a for allowing the flow of fluid to be installed thereon.

A second ring disk 75 serving as a main valve is provided on the upper portion of the lower retainer 74. The second ring disk 75 separates the pilot chamber 77 formed on the upper portion of the lower retainer 74 from the high pressure side Ph. An upper retainer 76 including a connection port 76a for allowing fluid to flow is provided in the upper portion of the lower retainer 74. [

A nut 78 is engaged with the spool rod 72 and binds the lower retainer 74 and the upper retainer 76. A spring 79 is interposed between one end of the spool rod 72 and the spool 73 so that the spool 73 is brought into close contact with the pressing rod 82 of the solenoid actuator 80.

Here, the series connection of the solenoid actuator 80 and the variable valve 70 is connected by the housing 71 of the variable valve 70.

The damping force adjusting mechanism 90 having such a configuration adjusts the position of the pressing rod 82 in accordance with the current supplied to the solenoid 84 through the power line 85 so that the position of the spool 73 in the spool rod 72 The flow rate of the fluid flowing through the damping force variable valve 70 is changed so that the rebound damping force and the compression damping force of the shock absorber 50 can be increased or decreased.

However, since the damping force varying mechanism 90 mounted on the outer side of the shock absorber 50 has the damping force variable valve 70 and the solenoid actuator 80 connected in series, the height of the damping force varying mechanism 90 is large, The height projected from the shock absorber 50 is large. Therefore, when the shock absorber assembly 100 is mounted on a vehicle, it occupies a large space in the vehicle, and in some cases, the mounting space can not be mounted narrowly or the structure of the periphery of the mounting position must be changed, There is a problem that the mounting of the absorber assembly 100 is not easy.

SUMMARY OF THE INVENTION The present invention is conceived to solve the problems as described above, and it is an object of the present invention to provide a damping force variable mechanism for a shock absorber capable of improving the ease of mounting of a shock absorber assembly by reducing a projection height of a damping force varying mechanism from a shock absorber And to provide a shock absorber assembly.

According to an aspect of the present invention, there is provided a damping force varying mechanism for a shock absorber mounted on the outside of a shock absorber, the damping force varying mechanism comprising: a damping force variable valve mounted outside the shock absorber; There is provided a damping force varying mechanism for a shock absorber comprising an actuator connected in parallel to the damping force variable valve.

The actuator may be connected in parallel by the damping force variable valve and the connection housing.

The actuator may be a solenoid actuator.

The operating rod of the solenoid actuator may further include force transmitting means for transmitting a translational motion to the damping force variable valve.

The damping force variable valve may include a spool rod having a passage formed therein and a spool capable of being displaced in the spool rod.

The operating rod of the solenoid actuator may further include force transmitting means for transmitting a translational motion to the damping force variable valve.

The force transmitting means may be a bridge.

The bridge may include a connecting portion and a pressing portion for pressing the spool.

The axis of the actuating rod and the axis of the spool rod may be arranged side by side on the same plane.

According to another aspect of the present invention, there is provided a damping force varying mechanism for a shock absorber having any one of the above features; And a shock absorber on the outside of which a damping force varying mechanism for the shock absorber is mounted.

1 is a partial cross-sectional view of a shock absorber assembly including a damping force adjustment mechanism according to the prior art,
2 is a sectional view of a damping force adjusting mechanism of a shock absorber according to the prior art,
3 is a sectional view of a damping force adjusting mechanism of a shock absorber according to an embodiment of the present invention;

Hereinafter, an embodiment of the present invention will be described by way of example with reference to the drawings. The same or similar components or components as those of the prior art will be described with reference to Figs. 1 and 2, and a detailed description thereof will be omitted for the sake of brevity.

Referring to Fig. 3, there is shown a schematic cross-sectional view of a damping force varying mechanism 90a for a shock absorber according to an embodiment of the present invention. As shown in the figure, the damping force varying mechanism 90a is provided on the outer side of the shock absorber 50, i.e., on the outer side of the abdominal wall structure, like the damping force varying mechanism 90 of the prior art shown in Fig. Can be connected to the intermediate tube 68 which is attached to the outer surface of the cylinder 56 and the inner cylinder 52 to form the annular passage 69.

The damping force varying mechanism 90a includes a damping force variable valve 70a for changing the flow rate of the working fluid to be flowed. For example, the damping force variable valve 70a has a reservoir 64 formed between the inner cylinder 52 and the outer cylinder 56, that is, the low pressure side Pl and the annular passage 69, that is, the high pressure side Ph So as to regulate the damping force by regulating the flow rate of the fluid flowing from the annular passage 69 to the reservoir 64.

For example, the damping force variable valve 70a is provided inside the valve housing 71a and includes a spool rod 72 in which a plurality of flow paths are formed, an operation rod 62 of a solenoid actuator 80a to be described later, A spool 73 which is pressurized by the force transmitting means 10 and changes its position in the spool rod 72 to open and close each of the passages and a spool 73 which is in close contact with the force transmitting means 10, And a spring 79 mounted in the rod 72 to press the spool 73. The spool rod 72 is provided with a first ring disk 73a serving as a fixed orifice and a lower retainer 74 having a connection port 74a for allowing fluid to flow. A second ring disk 75 serving as a main valve is provided on the upper portion of the lower retainer 74. The second ring disk 75 separates the pilot chamber 77 formed on the upper portion of the lower retainer 74 from the high pressure side Ph. An upper retainer 76 is provided on the upper portion of the lower retainer 74 and includes a connection port 76a for allowing fluid to flow. A nut 78 is engaged with the spool rod 72 to bind the lower retainer 74 and the upper retainer 76.

The damping force varying mechanism 90a includes a solenoid actuator 80a and a solenoid actuator 80a which are disposed in parallel with the damping force variable valve 70a and generate actuating force necessary for valve actuation of the damping force variable valve 70a, And a force transmission means (10) for transmitting the operating force generated in the damping force variable valve (70a).

The solenoid actuator 80a is disposed in parallel with the damping force variable valve 70a, that is, on the side of the damping force variable valve 70a, and the solenoid actuator 80a is disposed in series with the damping force variable valve 70a The height at which the damping force varying mechanism projects from the shock absorber can be reduced. Therefore, the shock absorber assembly including the damping force adjusting mechanism 90a according to the embodiment of the present invention can be mounted in a narrow space, for example, when mounted on a vehicle, have.

In this embodiment, the solenoid actuator 80a is coupled to the variable valve 70a by the connection housing 20a. However, the present invention is not limited thereto, and for example, the actuator 80a may be fixed to the outside of the shock absorber 50. [ The connection housing 20a includes a solenoid cover portion 21 for accommodating a solenoid actuator 80a and a connection housing 20 for connecting the solenoid cover portion 21 to the valve housing 71a and accommodating the force transmitting means 10, (20).

The solenoid actuator 80a includes a solenoid 84 and an actuation rod 62.

The force transmitting means 10 is means for transmitting a pressing force generated in the operating rod 62 of the solenoid actuator 80a to the spool 73 of the damping force variable valve 70a. In this embodiment, . One end of the bridge 10 is connected to the operation rod 62 and the bridge 10 is also translated according to the translation movement of the operation rod 62. The bridge 10 includes a pressing portion 61 at the other end and the pressing portion 61 is connected to the operating rod 62 through the connecting portion 11.

In the configuration as described above, the operating rod 62 is operated in the opposite direction to that in the case where the solenoid actuator is serially connected to the damping force variable valve, so that the damping force variable valve can be adjusted in the same manner as in the prior art.

The protrusion 12 is provided in the connection part 11 and the protrusion 24 is provided in the middle part 22 of the connection housing 20 so that the compression spring 30 can be disposed therebetween. have. The compression spring 30 presses the pressing portion 61 of the bridge 10 so as to be in close contact with the spool 73.

The translational movement of the operating rod 62 of the solenoid actuator 80a leads to the translational movement of the connecting portion 11 of the bridge 10 and the translational movement of the connecting portion 11 leads to the translational movement of the pressing portion 61. [ The translational motion of the pressing portion 61 leads to the translational movement of the spool 73 of the damping force variable valve 70a to change the flow path of the spool rod 72 so that the flow rate of the fluid passing through the damping force variable valve 70a becomes can be changed.

The solenoid actuator 80a is arranged in parallel with the damping force variable valve 70a such that the actuating rod 62 and the spool 73 are substantially parallel to each other, 62 and the axis of the spool 73 may be arranged at an arbitrary angle in an angle range of 0 degree to 90 degrees on the same plane. The connecting portion 11 of the bridge 10 and the operating rod 62 are connected integrally with each other by an inclined cam so that the operating rod 62 is moved horizontally Direction translational motion can be converted to the vertical translational motion of the connection portion 11. [

As a further alternative, it is also possible that a part of the projection 12 is rotatably connected to the projection 24 of the connecting housing 20 instead of the bridge 10 to be translated. In this case, the connecting portion 11 and the operating rod 62 may not be integrally connected but may be rotatably connected, and the pressing portion 61 and the connecting portion 11 may be rotatably connected.

In the above-described embodiment, the solenoid actuator 80a is used to move the spool 73 of the damping force variable valve 70a, but the present invention is not limited thereto. Instead of the solenoid actuator 80a, Other actuators, such as hydraulic cylinders, which may induce, may also be mounted.

As described above, the shock absorber assembly according to the present invention can reduce the height of the damping force varying mechanism mounted on the shock absorber by arranging the actuators in parallel in the damping force variable valve, and can be easily mounted .

As described above, the embodiments of the present invention described above are intended to facilitate understanding of the present invention. It is to be understood that variations and modifications which can readily be made by those skilled in the art, for example, changing to damping force variable valves It will be apparent that the invention may be practiced in this embodiment without departing from the scope of the invention.

10: force transmission means
11: Bridge connection
20: connection housing
21: Solenoid cover part
23: Housing connection
50: Shock absorber
52: Inner cylinder
55: Piston
56: outer cylinder
57: Road Guide
60: rebound chamber
61:
62: Operation rod
64: reservoir chamber
68: intermediate tube
69: annular passage
70; 70a: variable damping force valve
71: housing
71a: valve housing
72: spool rod
73: spool
80; 80a: Solenoid actuator
90: Variable damping force mechanism
100: Shock absorber assembly

Claims (10)

A damping force varying mechanism for a shock absorber mounted on the outside of a shock absorber,
A damping force variable valve mounted on the outside of the shock absorber;
And an actuator disposed in parallel with the damping force variable valve,
The actuator is a solenoid actuator,
The solenoid actuator includes a solenoid and an actuation rod,
And a force transmitting means for transmitting a pressing force generated in the operating rod of the solenoid actuator to the damping force variable valve. The damping force varying mechanism for a shock absorber according to claim 1, wherein the actuator is connected in parallel with the damping force variable valve and the connecting housing. delete delete The damping force variable mechanism for a shock absorber according to claim 1, wherein the damping force variable valve comprises a spool rod in which a passage is formed and a spool which can be displaced in the spool rod. delete The damping force varying mechanism for a shock absorber according to claim 1, wherein the force transmitting means is a bridge. The damping variable variable mechanism for a shock absorber according to claim 7, wherein the bridge includes a connecting portion and a pressing portion for pressing a spool which can be displaced in the spool rod in which the flow path is formed. The damping force variable mechanism for a shock absorber according to claim 5, wherein the axis of the actuating rod of the solenoid actuator and the axis of the spool rod are arranged side by side on the same plane. A damping force varying mechanism for a shock absorber according to any one of claims 1, 2, 5, and 7 to 9; And
And a shock absorber on the outside of which the damping force varying mechanism for the shock absorber is mounted.

Images