KR20200089427A - Shock absorber - Google Patents

Abstract

A shock absorber is disclosed. The shock absorber according to an embodiment of the present invention includes: a cylinder having a reservoir chamber between an inner tube and an outer tube; a piston for separating the inner tube into a tension chamber and a compression chamber; a piston rod connected to the piston; and a rod guide coupled to the top of the cylinder to guide the movement of the piston rod. The rod guide includes: a connection passage for connecting the reservoir chamber and the tension chamber to each other; and a rod guide check valve that allows the fluid in the compression chamber to flow into the tension chamber through the reservoir chamber during a compression stroke, and controls the opening and closing of the connection passage to prevent the fluid from the tension chamber from flowing into the connection passage during a tension stroke.

Description

Shock absorber {SHOCK ABSORBER}

The present invention relates to a shock absorber, and more particularly, to a shock absorber used in a suspension device.

In general, the shock absorber supports the weight of the vehicle body and at the same time suppresses and attenuates the vibration transmitted from the road surface to the vehicle body and forms a major component of the vehicle suspension system.

This shock absorber absorbs and mitigates vibration energy in the vertical direction of the wheel (wheel) due to road irregularities, thereby preventing vibration from being directly transmitted to the vehicle body. The shock absorber as described above includes a cylinder and a piston rod slidably accommodated in the cylinder, the cylinder is connected to the wheel side through a suspension arm, etc., the piston rod is connected to the vehicle body side, and a piston is connected to the lower end of the piston rod. . Accordingly, the shock absorber may perform a function of suppressing and damping vibration transmitted from the road surface to the vehicle body while repeatedly performing a compression stroke and a rebound stroke when the vehicle is driving on an irregular road surface. . Here, the piston divides the inside of the cylinder into a compression chamber and a tension chamber to control flow paths and flow rates of the flow paths that selectively allow the flow of the working fluid according to the extension and contraction of the shock absorber. The piston allows the fluid to move in one direction by the pressing force of the disc, but the disc is opened or closed with respect to the flow path due to a pressure difference between chambers due to expansion or contraction of the shock absorber. Therefore, a problem arises in that the hydraulic pressure area of the piston generating a damping force is reduced by the flow paths formed in the piston.

Korea Patent Publication No. 2006-0102691 (published on September 28, 2006)

Embodiments of the present invention are to provide a shock absorber that can generate a large force even at a small pressure.

According to an aspect of the present invention, a cylinder having a reservoir chamber between an inner tube and an outer tube, a piston inserted into the inner tube to divide the inner tube into a tension chamber and a compression chamber, a piston rod connected to the piston, and It includes a rod guide coupled to the upper portion of the cylinder to guide the movement of the piston rod, the rod guide is a connecting flow path for communicating the reservoir chamber and the tension chamber with each other and during compression stroke, the fluid in the compression chamber is the reservoir chamber A rod guide check valve may be provided to control the opening and closing of the connecting flow path to allow the flow through the tension chamber and to prevent the fluid of the tension chamber from flowing into the connecting flow path.

In addition, the rod guide check valve includes a rod guide disc installed to selectively shield the connection flow path, and an elastic body elastically supporting the rod guide disc in a direction in which the load guide disc seals the connection flow path.

In addition, a rod guide cap coupled to the rod guide so as to form an accommodation space accommodating the rod guide check valve may be formed, and the rod guide cap may be formed with a hole communicating the tension chamber and the accommodation space.

In addition, the rod guide includes a small diameter portion coupled to the inner tube, and a large diameter portion having an extended diameter than the small diameter portion to be coupled to an upper cap coupled to the outer tube, and the connecting passage has one end communicating with the reservoir chamber It includes a horizontal passage formed in the large diameter portion and a vertical passage formed in the small diameter portion so that one end is connected to the other end of the horizontal passage and the other end communicates with the tension chamber.

In addition, the piston is characterized in that the check valve for allowing the fluid in the compression chamber to flow into the tension chamber during the compression stroke of the piston is not provided.

In addition, the piston is provided with a tensile flow path and a compression flow path to allow the flow of fluid between the tension chamber and the compression chamber during the sudden reciprocating movement of the piston, and each outlet of the tension flow path and the compression flow path has a ring-shaped disc. It can be opened and closed respectively by a tension disk and a compression disk provided in a plurality of stacked form.

In addition, the shock absorber is provided with a separate tube installed between the inner tube and the outer tube, a rebound solenoid valve coupled to the separator tube and connected to the intermediate chamber formed by the separator tube, and coupled to the inner tube to the compression chamber It is characterized in that it is a semi-active suspension including a compression solenoid valve.

In addition, the shock absorber is coupled to the inner tube and a rebound solenoid valve coupled to the intermediate tube formed by the separator tube, and a separate tube installed between the inner tube and the outer tube, the separator tube, and the inner tube It is characterized in that it is an active suspension (active suspension) including a pump having a compression solenoid valve connected to the compression chamber, a first discharge port in communication with the intermediate chamber and a second discharge port in communication with the compression chamber.

In the embodiments of the present invention, the hydraulic pressure area of the piston is increased during the tension stroke or the compression stroke of the shock absorber, so that a large force can be generated at a small pressure.

1 is a cross-sectional view showing a shock absorber according to an embodiment of the present invention.
FIG. 2 is an enlarged view of part A of FIG. 1.
FIG. 3 is an enlarged view of a portion B of FIG. 1.
4 is an enlarged view of part C of FIG. 1.
5 is an exploded perspective view of a rod guide part according to an embodiment of the present invention.
6 illustrates a fluid flow during tension stroke of a shock absorber according to an embodiment of the present invention.
7 shows a fluid flow during compression stroke of a shock absorber according to an embodiment of the present invention.
8 shows a shock absorber according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as examples in order to sufficiently convey the spirit of the present invention to those skilled in the art to which the present invention pertains. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly describe the present invention, parts irrelevant to the description are omitted in the drawings, and in the drawings, the width, length, and thickness of components may be exaggerated for convenience. Throughout the specification, the same reference numbers refer to the same components.

1 is a cross-sectional view showing a shock absorber according to an embodiment of the present invention, FIG. 2 is an enlarged view of a portion A of FIG. 1, and FIG. 3 is an enlarged view of a portion B of FIG. 1, and FIG. 4 1 is an enlarged view of a portion C of FIG. 1, and FIG. 5 is an exploded perspective view of a rod guide portion according to an embodiment of the present invention.

1 to 5, the shock absorber 10 according to an embodiment of the present invention has a dual structure of the inner tube 21 and the outer tube 22, and the cylinder 20 is filled with fluid, the inner tube (21) is installed to be able to slide up and down within, the inner tube (21) piston 30, which divides the inner space into a tension chamber (24) and a compression chamber (25), and one end is connected to the piston (30), The piston rod 40 at which the other end protrudes out of the cylinder 20, the base valve assembly 50 installed at the lower side of the inner tube 21, and the piston rod 40 at the upper side of the cylinder 20 move up and down. It includes a rod guide 60 to guide.

In addition, the upper cap 11 and the base cap 12 are coupled to the upper and lower portions of the cylinder 20, respectively.

Between the outer pipe 22 and the inner pipe 21, a separate tube 23 forming the intermediate chamber 26 is installed. The separate tube 23 is connected with a rebound solenoid valve 13 for varying the damping force during the tensile stroke of the piston 30.

The intermediate chamber 26 formed by the separator tube 23 communicates with the tension chamber 24 and the rebound solenoid valve 13 coupled to the separator tube 23. To this end, a tension chamber communication hole 27 is formed on the upper side of the inner tube 21 to allow fluid flow between the tension chamber 24 and the intermediate chamber 26.

Outside the separate tube 23 is formed between the outer tube 22 and the separator tube 23, compensating for changes in the internal volume of the tension chamber 24 and the compression chamber 25 according to the reciprocating motion of the piston 30 The reservoir chamber 28 is formed.

A compression solenoid valve 14 for varying the damping force during the compression stroke of the piston 30 is connected to the inner tube 21.

The compression chamber 25 communicates with the compression solenoid valve 14 through the compression chamber communication hole 29 formed at the lower side of the inner tube 21.

The piston 30 is disposed inside the inner tube 21 to divide the upper and lower parts of the inner tube 21 into a tension chamber 24 and a compression chamber 25, and is coupled to the piston 30 to upper the inner tube 210 The extended piston rod 40 penetrates the rod guide 60 and protrudes out of the upper cap 11.

Here, the reservoir chamber 28 is filled with fluid while connected to the accumulator, and the tension chamber 24, the compression chamber 25, and the intermediate chamber 26 are also filled with fluid.

The piston 30 presses the fluid filled in the compression chamber 25 or the tension chamber 24 while reciprocating inside the cylinder 20.

In the piston 30, when the piston 30 reciprocates, the existing check valve structure for allowing fluid flow between the tension chamber 24 or the compression chamber 25 is removed, thereby forming a check valve. It is configured to generate a large force at a small pressure by resolving the reduction in the hydraulic pressure area of the piston 300, and the flow of fluid between the tension chamber 24 and the compression chamber 250 according to the reciprocating movement of the piston 30 is a rod guide. It is configured to be made through (60).

On the other hand, in the piston 30, when excessive pressure is generated in the tension chamber 24 or the compression chamber 25 due to the sudden reciprocating movement of the piston 30, the tension chamber 24 and the compression chamber 25 are exceeded. ) To allow the flow of fluid between the piston tension passage 31 and the piston compression passage 32 is formed.

In the piston tension passage 31 and the piston compression passage 32, the inlets 31a, 32a are respectively located at a position radially distant from the center of the piston 30, and the outlets 31b, 32b are of the piston 30. It is formed to be inclined to the piston 30 so as to be positioned radially close to the center.

The piston tension passage 31 is opened so that the inlet 31a communicates with the tension chamber 24, and the outlet 31b is provided closed by the tension disk 33, and the piston compression passage 32 is an inlet 32a. ) Is opened to communicate with the compression chamber 25 and the outlet 32b is provided closed by the compression disk 34.

The tension disk 33 and the compression disk 34 are each provided in a form in which a plurality of ring-shaped disks are stacked, and are elastically deformed by the pressure of the fluid flowing through the piston tension passage 31 or the piston compression passage 32. Allow fluid flow. In this case, the tension disk 33 and the compression disk 34 are provided to be able to deform when excessive pressure is generated in the tension chamber 24 or the compression chamber 25.

Through this, as the structure of the existing check valve is removed from the piston 30, when the piston 30 reciprocates, the entire inner diameter of the inner tube 21 acts as a hydraulic area to generate a large force even at a small pressure. The fluid flow between the tension chamber 24 and the compression chamber 25 during the reciprocating movement of the 30 is made by adding the function of a check valve to the rod guide 60.

Meanwhile, a lower bracket 15 connected to the axle is connected to the lower end of the base cap 12, and an upper bracket connected to the vehicle body is provided at the upper end of the piston rod 40.

In addition, an oil seal 16 for preventing oil leakage is installed on the upper side of the piston rod 40.

The base valve assembly 50 is coupled to the lower portion of the inner tube 21.

The base valve assembly 50 separates the inside of the reservoir chamber 28 and the inner pipe 21 formed between the outer pipe 22 and the inner pipe 21 while the reservoir chamber 28 and the inner pipe 21 are separated. It includes a base valve body 51 is formed with a flow path to allow the flow of fluid in the furnace.

The base valve body 51 is provided with a base compression flow path 52 and a base tension flow path 53 that allow the flow of oil during compression stroke and tension stroke of the shock absorber.

The upper side of the base valve body 51 is coupled to the base upper disc 54 for opening the upper end of the base tensile flow path 53 during tensile stroke while blocking the upper end of the base tensile flow path 53, and the base upper disc 54 ), the retainer 54a, the spring 54b, and the washer 54c are sequentially coupled.

The lower portion of the base valve body 51 is coupled to the base lower disc 55 for controlling the damping force by opening the base compression flow path 52 during the compression stroke while blocking the lower end of the base compression flow path 52.

The base lower disc 55 is provided in a form in which a plurality of ring-shaped discs are stacked, and a slit 55a is formed at the edge of the ring-shaped disc located adjacent to the lower end of the base valve body 51 and the base lower disc 55 A retainer 55b and a washer 55c are sequentially coupled to the lower portion.

A pressure chamber 56 is formed at a lower portion of the base valve body 51, and a fluid in the compression chamber 25 is introduced into the pressure chamber 56 through the base compression flow path 52 during compression stroke.

During the compression stroke of the piston 30, the fluid in the compression chamber 25 moves while opening the base lower disk 55 downward while moving to the pressure chamber 56 along the base compression flow path 52, and this During the process, a damping force due to the resistive force of the fluid is generated.

On the other hand, during the tension stroke of the piston 30, while the fluid in the pressure chamber 56 moves to the compression chamber 25 through the base tension passage 53, the base upper disk 54 is pushed upward and opened. .

The rod guide 60 includes a cylindrical body 62 having a hollow 61 to guide the vertical movement of the piston rod 40, and reduces friction when the piston rod 40 moves in the inner circumference of the hollow 61 A bush 63 for installation is provided.

The bush 63 is made of a hollow cylindrical shape formed of a material having a low coefficient of friction, and is coupled to the inner circumference of the hollow 61 of the piston rod 40.

The body 62 of the rod guide 60 may be formed in a cylindrical shape having a step. The rod guide 60 is a body composed of a small diameter portion 62b coupled to the upper side of the inner tube 21 and a large diameter portion 62a having a larger diameter than the small diameter portion 62b and coupled with the upper cap 11 It includes 62, the lower side of the small diameter portion 62b, the rod guide cap 66 is coupled to cover the lower portion of the small diameter portion 62b.

A connecting passage 67 for communicating the reservoir chamber 28 and the tension chamber 24 is formed in the body 62 of the rod guide 60.

The connecting passage 67 is a horizontal passage 67a formed through the radial direction of the rod guide 60 inside the large-diameter portion 62a of the rod guide 60 and the small-diameter portion 62b of the rod guide 60 It is formed in the end of the horizontal passage (67a) includes a vertical passage (67b) formed through the axial direction of the body (62).

The horizontal passage 67a has one end communicating with the reservoir chamber 28 formed between the outer tube 22 and the inner tube 21, and the vertical passage 67b has one end communicating with the other end of the horizontal passage 67a and the other end. Is in communication with the tension chamber (24).

A rod guide check valve 64 is installed at the other end of the vertical passage 67b to selectively open and close the vertical passage 67b to allow one-way flow of fluid.

The rod guide check valve 64 includes an elastically deformable rod guide disc 64a and an elastic body 64b elastically supporting the rod guide disc 64a.

The load guide check valve 64 allows the fluid in the reservoir chamber 28 to flow into the tension chamber 24 through the connecting passage 67 during the compression stroke of the shock absorber, and in the tension stroke of the shock absorber. The fluid of (24) is blocked from flowing into the connecting passage (67).

The rod guide disk 64a may be formed of an elastically deformable ring-shaped disk, or a plurality of ring-shaped disks may be stacked, and can be closely supported to the opening of the vertical passage 67b by a washer, a retainer, or the like. have.

In addition, a plurality of cut grooves formed in a predetermined length in the radial direction of the rod guide disc 64a may be disposed at a predetermined interval along the circumferential direction to secure a flow rate on the outer circumference of the rod guide disc 64a.

The elastic body 64b is disposed under the rod guide disc 64a, and elastically presses the rod guide disc 64a in a direction in which the rod guide disc 64a seals the vertical passage 67b.

The elastic body 64b includes a coil spring, one end of which is supported by the rod guide disk 64a, and the other end of which is supported by the rod guide cap 66.

The rod guide disk 64a and the elastic body 64b are accommodated in the inner accommodation space 65 of the rod guide cap 66 coupled to the small diameter portion 62b. Here, the accommodation space 65 means a space between the head 66a of the rod guide cap 66 and the lower end of the small diameter portion 62b.

The rod guide cap 66 is made of a cylindrical shape with an open top coupled to the small diameter portion 62b of the rod guide 60, and the elastic body 64b has both ends of the rod guide disk 64a and the rod guide cap ( 66) is supported by the head 66a

In this rod guide cap 66, the inner circumference of the side wall 66b may be coupled to the outer circumference of the small-diameter portion 62b by screwing, caulking, press-fitting, or the like.

In the center of the head 66a of the rod guide cap 66, a through hole 66c through which the piston rod 40 penetrates is formed, and the fluid discharged from the connecting passage 67 is drawn through the through hole 66c through the tension chamber ( 24).

Separately, a separate hole 66d may be formed in the side wall 66b or head 66a of the rod guide cap 66 for mutual communication between the inside of the rod guide cap 66 and the tension chamber 24. .

On the other hand, the outer circumferential surface of the piston rod 40 is provided with a stopper 41 for limiting the moving width of the piston rod 40 by limiting the upward movement of the piston rod 40.

The stopper 41 may be formed of a material having elasticity so as to mitigate the impact when colliding with the rod guide cap 66.

Hereinafter, the operation of the shock absorber according to the embodiment of the present invention will be described.

Referring to FIG. 6, during the tension stroke of the shock absorber, the piston 30 rises as the piston rod 40 rises. Then, the fluid filled in the tension chamber 24 flows into the intermediate chamber 26 through the tension chamber communication hole 27, and the fluid flowing into the intermediate chamber 26 passes through the rebound solenoid valve 13 to the reservoir chamber ( 28) and then flows through the base valve assembly (50) and enters the compression chamber (25). At this time, since the connecting passage 67 formed in the rod guide 60 is blocked by the rod guide disk 64a pressed by the elastic body 64b, the fluid in the tension chamber 24 is a reservoir chamber through the connecting passage 67 It does not flow into (28).

Also, during the compression stroke of the shock absorber, the piston 30 also descends as the piston rod 40 descends, as shown in FIG. 7. Then, the fluid filled in the compression chamber 25 flows into the compression solenoid valve 14 through the compression chamber communication hole 29 and then passes through the reservoir chamber 28 to the connecting flow path 67 formed in the rod guide 60. Inflow. Then, the fluid flowing into the connecting passage 67 is discharged to the receiving space 65 by pushing the load guide disk 64a downward and opening it, and then, through the hole 66d of the load guide cap 66, the tension chamber (24).

Therefore, when the tension stroke or compression stroke of the shock absorber does not flow the fluid between the tension chamber 24 and the compression chamber 25 through the piston 30, the hydraulic pressure area of the piston 30 increases to increase the pressure at a small pressure. It is possible to generate force.

Hereinafter, a shock absorber in which a road guide according to an embodiment of the present invention is applied to an active suspension will be described. Hereinafter, the same reference numerals are assigned to components having the same function, and detailed description is omitted.

8 is a configuration in which a rod guide according to an embodiment of the present invention is applied to an active suspension, and the fluid is configured to be supplied to the tension chamber 24 or the compression chamber 25 by the pump 70.

For example, the first discharge port 71 of the pump 70 is connected to the separate tube 23 to communicate with the intermediate chamber 26, and the second discharge port 72 of the pump 70 is the compression chamber 25 It is connected to communicate.

That is, the fluid supplied from the first discharge port 71 of the pump 70 can be supplied to the tension chamber 24 through the tension chamber communication hole 27 through the intermediate chamber 26, and the fluid of the pump 70 is The fluid supplied from the second discharge port 72 may be supplied to the compression chamber 25 through the pump communication hole 73 formed in the inner tube 21.

Therefore, when the shock absorber is supplied to the tension chamber 24 through the intermediate chamber 26 when the fluid supplied through the first discharge port 71 of the pump 70 is operated in the active mode of the compression stroke, the piston 30 ) Descends, and the fluid in the compression chamber 25 flows into the compression solenoid valve 14 through the compression chamber communication hole 29 and then passes through the reservoir chamber 28 to connect the flow path 67 formed in the rod guide 60 ). Then, the fluid flowing into the connecting passage 67 is discharged to the receiving space 65 by pushing the rod guide disk 64a downward and pushing it downward to open the tension chamber through the hole 66d of the rod guide cap 66. (24).

In the above, specific embodiments have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and those skilled in the art to which the invention pertains may perform various modifications without departing from the gist of the technical spirit of the invention described in the claims below.

10: shock absorber, 13: rebound solenoid valve,
14: compression solenoid valve, 20: cylinder,
21: inner tube, 22: outer tube,
23: separate tube, 24: tension chamber,
25: compression chamber, 26: intermediate chamber,
28: reservoir chamber, 30: piston,
40: base valve assembly, 60: rod guide,
62: body, 64: rod guide check valve,
64a: rod guide disc, 64b: elastic body,
65: accommodation space, 66: road guide cap,
67: connecting passage, 67a: horizontal passage,
67b: vertical passage, 70: pump.

Claims (8)

A cylinder having a reservoir chamber between the inner tube and the outer tube, a piston inserted into the inner tube to divide the inner tube into a tension chamber and a compression chamber, a piston rod connected to the piston, and to guide movement of the piston rod Includes a rod guide coupled to the top of the cylinder,
In the rod guide, a connecting flow path for mutually communicating the reservoir chamber and the tension chamber and allowing the fluid of the compression chamber to flow into the tension chamber during the compression stroke, and during the tension stroke, the fluid of the tension chamber is allowed. A shock absorber is provided with a load guide check valve that controls opening and closing of the connection flow path so as to block the flow into the connection flow path. According to claim 1,
The load guide check valve is a shock absorber including a rod guide disc installed to selectively shield the connection flow path, and an elastic body elastically supporting the load guide disc in a direction in which the load guide disc seals the connection flow path. According to claim 2,
And a rod guide cap coupled to the rod guide to form an accommodation space accommodating the rod guide check valve,
The rod guide cap is a shock absorber in which a hole communicating the tension chamber and the accommodation space is formed. According to claim 2,
The rod guide includes a small-diameter portion coupled to the inner tube, and a large-diameter portion having an extended diameter than the small-diameter portion to be coupled to an upper cap coupled to the outer tube,
The connection passage is a shock absorber including a vertical passage formed at the large diameter portion so that one end communicates with the reservoir chamber, and a vertical passage formed at the small diameter portion so that one end is connected to the other end of the horizontal passage and the other end communicates with the tension chamber. According to claim 1,
A shock absorber that is not provided with a check valve to allow fluid in the compression chamber to flow into the tension chamber during the compression stroke. The method of claim 5,
The piston is provided with a tensile flow path and a compression flow path to allow the fluid to flow between the tension chamber and the compression chamber during the sudden reciprocation of the piston, and each outlet of the tension flow path and the compression flow path has a plurality of ring-shaped discs. A shock absorber that can be opened and closed by a tension disk and a compression disk provided in a stacked form, respectively. According to claim 1,
The shock absorber is a separator tube installed between the inner tube and the outer tube, a rebound solenoid valve coupled to the separator tube and connected to an intermediate chamber formed by the separator tube, and coupled to the inner tube to be connected to the compression chamber A shock absorber, characterized in that it is a semi-active suspension including a compression solenoid valve. According to claim 1,
The shock absorber is a separating tube installed between the inner tube and the outer tube, a rebound solenoid valve coupled to the separator tube and connected to an intermediate chamber formed by the separator tube, coupled to the inner tube, and the A shock absorber comprising an compression solenoid valve connected to the compression chamber, a pump having a first discharge port communicating with the intermediate chamber and a second discharge port communicating with the compression chamber.

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