KR101450307B1 - Shock absorber - Google Patents

Abstract

The present invention is characterized in that a first piston, a pilot valve, a second piston and a tension retainer are sequentially coupled to a piston rod reciprocating in a cylinder, the upper side of the second piston is embedded in the first piston, A second pressure chamber formed in the second piston, a third pressure chamber formed between the first and second pistons, and a fourth pressure chamber formed in the tension retainer, The present invention relates to a shock absorber capable of reducing the length of the entire machining portion and reducing the overall size of the apparatus and reducing the cost.

Description

Shock absorber {SHOCK ABSORBER}

The present invention relates to a shock absorber, and more particularly, to a shock absorber capable of improving ride comfort by reducing a damping force from a very low speed section to a high speed section, reducing the length of the entire machining portion, The present invention relates to a shock absorber that can be used as a shock absorber.

Generally, the shock absorber supports the weight of the vehicle body and also suppresses and damps the vibration transmitted from the road surface to the vehicle body. This contributes to the improvement of the ride quality, the protection of the cargo, and the protection of various parts of the vehicle.

Generally, a shock absorber is composed of a cylinder filled with a working fluid (oil), a piston rod reciprocally connected to the body side, a piston valve coupled to the lower end of the piston rod and sliding in the cylinder, Respectively.

In this conventional shock absorber, one passage is formed inside the cylinder by the piston valve. However, such a structure has a limitation in decreasing the damping force in the high-speed section because it is difficult to increase the cross-sectional area of the passage.

In addition, the conventional shock absorber has a problem in that the riding feeling is deteriorated due to a sudden change in damping force at a blow-off point.

In order to overcome the limit of the structure in which one flow path is formed, a shock absorber employing a piston valve that forms two flow paths is known.

However, since the shock absorber having the piston valve having the two flow paths is stacked on the piston valve, there is a problem that the overall height of the device increases as the length of the processed portion increases.

In addition, the shock absorber provided with the piston valve having the two flow paths lacks the tuning factor in the extremely low speed section, so there is no room for tuning.

In addition, since the shock absorber having the piston valve with two flow paths can not infinitely increase the diameter of the hole for forming the compression and tensile flow path of the piston valve, there is a limitation in realizing the degressive characteristic at high speed have.

Patent Application No. 10-2007-0049256 Patent Application No. 10-2007-0067515 Japanese Patent Application Laid-Open No. 2010-38348

It is an object of the present invention to improve ride comfort by reducing damping force from a very low speed section to a high speed section, And to provide a shock absorber capable of reducing the cost.

In order to solve the above-mentioned problems, the present invention is characterized in that it comprises a first pressure chamber which is coupled to an end side of a piston rod reciprocating in a cylinder and formed by a plurality of tension channels passing vertically, A first piston which forms an upwardly recessed internal space; A pilot valve coupled to the piston rod and disposed in the inner space, for selectively opening and closing a lower end portion of the tension passage; A connecting tension channel connected to the piston rod and having an upper side accommodated in the inner space and disposed at a lower portion of the first piston and vertically penetrating the connecting tensile channel, A second piston forming a second pressure chamber communicating with the first piston; And a fourth pressure chamber coupled to the piston rod and disposed at a lower portion of the second piston, the fourth pressure chamber being formed by an extended tension passage connected to the connection tension passage. And a disc valve assembly which is coupled to the piston rod and disposed at a lower portion of the tension retainer and opens and closes the passage while permitting shape deformation in communication with the extended tension passage, And a third pressure chamber formed between the inner circumferential surface of the first piston and the outer circumferential surface of the second piston forming the inner space together with the plurality of compression flow paths, And an intake valve that opens and closes a passage communicating with the compression passage and the tension passage.

Here, the shock absorber forms an operation flow path for interconnecting the first pressure chamber, the second pressure chamber, and the extension tension flow path in the extremely low speed and low speed sections, And a damping force is generated while passing through the disc valve assembly.

In this case, the disc valve assembly includes a disc-S formed with a slit communicating with the elongated tension channel along an edge thereof and closely disposed on a lower side of the tension retainer, and a plurality of unit disks Wherein the shock absorber forms an operating passage for interconnecting the first pressure chamber, the second pressure chamber and the extension tension passage in the middle speed and the high speed section, and the first pressure When the pressure of the chamber is higher than that of the second pressure chamber, the pilot valve is opened and the bypass passage connected to the third pressure chamber and the inside of the cylinder is formed.

The shock absorber may include a stepped portion formed to be stepped smaller than the diameter of the piston rod along the outer circumferential surface of the end portion of the piston rod and a step portion coupled to the stepped portion and disposed on the upper side of the first piston, Wherein the intake valve is connected to the step portion and is disposed on a lower portion of the washer and on the upper side of the first piston, the intake valve communicating with the washer to allow a shape deformation, The first piston, the pilot valve, the second piston, the tension retainer, and the disc valve assembly are sequentially coupled along the vertical direction of the step portion.

The shock absorber may further include a washer coupled to an end of the piston rod and disposed on the upper side of the first piston, the washer being in communication with the compression passage and the tension passage, Further comprising a spacer disposed between the valve and spaced apart from the washer and the intake valve while limiting an upper and lower length of the shape of the intake valve, the intake valve being coupled to the lower portion of the washer And is disposed on the upper side of the first piston, and allows the deforming of shape by communicating with the washer.

According to the present invention having the above-described structure, the first pressure chamber is formed by the first piston, the second pressure chamber is formed by the second piston with the built-in pilot valve, and the third pressure A chamber is formed and a fourth pressure chamber is formed by the tension retainer to allow the working fluid to selectively flow through the first, second, third and fourth pressure chambers, thereby smoothly and constantly reducing the damping force from the extremely low speed section to the high speed section The ride comfort can be improved.

The third pressure chamber is formed between the second piston and the first piston stacked in the form that the upper side is embedded in the first piston, thereby reducing the length of the entire processed portion and reducing the overall height of the device. It is possible to realize a compact design and a cost reduction.

1 is a cross-sectional schematic view showing the overall configuration of a shock absorber according to an embodiment of the present invention.
FIG. 2 is a cross-sectional conceptual view showing a flow of a working fluid in a very low speed and a low speed section during a tensile stroke of a shock absorber according to an embodiment of the present invention.
3 is a cross-sectional conceptual diagram showing a flow of a working fluid in a middle speed and a high speed section during a tensile stroke of a shock absorber according to an embodiment of the present invention.
4 is a cross-sectional schematic view showing a flow of a working fluid during a compression stroke of a shock absorber according to an embodiment of the present invention.

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

1 is a schematic cross-sectional view illustrating the overall configuration of a shock absorber according to an embodiment of the present invention.

The first piston 100, the pilot valve 300, the second piston 200, the tensile retainer 400, and the disc valve assembly 500 are connected to the piston rod 700 in the cylinder 800, It is possible to recognize that the structure is equipped with

The first piston 100 is coupled to an end of the piston rod 700 reciprocating in the cylinder 800 and includes a first pressure chamber C1 formed by a plurality of tension channels 101 passing through the cylinder 800 And the lower side is opened to form an internal space recessed upward.

The pilot valve 300 is coupled to the piston rod 700 and disposed in the inner space, and selectively opens and closes the lower end of the tension channel 101.

The second piston 200 is connected to the piston rod 700 and the upper side is accommodated in the inner space and disposed at the lower portion of the first piston 100 and connected to a plurality of tensile flow paths 101, 201 are vertically penetrated and the upper side is opened to form the second pressure chamber C2 communicating with the inner space.

The third pressure chamber C3 includes a plurality of compression flow passages 102 passing through the first piston 100 in the up and down direction and an inner peripheral surface of the first piston 100 forming the inner space, A space between the outer circumferential surfaces of the base plate 200 is formed.

The tensile retainer 400 includes a fourth pressure chamber (not shown) formed by an extended tension passage 401 coupled to the piston rod 700 and disposed below the second piston 200 and connected to the connection tension passage 201 C4.

The disc valve assembly 500 is coupled to the piston rod 700 and disposed at the lower portion of the tension retainer 400 and communicates with the extension tension passage 401 to open and close the passage while permitting shape deformation.

It is needless to say that the present invention can be applied to the embodiment having the above-described configuration, and the following various embodiments can be applied.

The disc valve assembly 500 includes a disc-S 510 in which a slit 511 communicating with a tension channel 401 extending along the edge is formed and closely disposed on the lower side of the tensile retainer 400, And a main disk 520 in which a plurality of unit disks 521 are stacked on the lower side of the main disk 520.

The shock absorber S further includes a stepped portion 701 formed along the outer circumferential surface of the end portion of the piston rod 700 so as to be stepped smaller than the diameter of the piston rod 700.

The shock absorber S further includes a washer 710 coupled to the stepped portion 701 and disposed on the upper side of the first piston 100 and communicating with the compression passage 102 and the tension passage 101 .

The shock absorber S is coupled to the stepped portion 701 and is disposed at a lower portion of the washer 710 and above the first piston 100 so that the shock absorber S can communicate with the washer 710, 102 and an intake valve 720 for opening and closing a flow path communicating with the tension flow path 101.

Here, the washer 710, the intake valve 720, the first piston 100, the pilot valve 300, the second piston 200, the tensile retainer 400, the disk valve assembly 500 Are sequentially coupled along the vertical direction of the step portion 701. [

At this time, the end of the stepped portion 701 is fixedly closed in order by the finishing washer 740 and the finishing nut 750.

The washer 710 and the intake valve 720 are disposed between the washer 710 and the intake valve 720 so as to restrict the vertical length of the shape of the intake valve 720, It is preferable to further include a spacer 730 that separates the light emitting device.

On the other hand, the shock absorber S is connected to the first pressure chamber C1, the second pressure chamber C2 and the extension tension channel 401 at the extremely low speed and the low speed section, (D).

Accordingly, the working fluid in the cylinder 800 passes through the disk valve assembly 500 through the working flow path D and generates a main damping force.

3, the shock absorber S forms the working flow path D as shown in FIG. 2 even in the medium-speed and high-speed sections as shown in FIG. 3 during the tensile stroke. When the pressure in the first pressure chamber C1 is lower than the pressure in the second pressure chamber C2, The pilot valve 300 is opened and the bypass passage B connected to the third pressure chamber C3 and the cylinder 800 is formed.

Accordingly, the bypass passage B is connected to the portion of the compression passage 102 of the third pressure chamber C3 to prevent a sudden pressure drop, and at the same time, the abrupt change of the damping force is gradually and gently performed, It is also possible to prevent a sudden closure.

On the other hand, in the compression stroke, the shock absorber S is provided with a compression first working flow F1 through which the working fluid flows through the third compression chamber C3 and a second working pressure F1 from the lower side of the third compression chamber C3, The compression second working flow F2 flowing through the first compression chamber C1 is formed, so that the damping force can be smoothly and uniformly reduced from the extremely low speed to the high speed section.

As described above, according to the present invention, it is possible to improve the ride quality by reducing the damping force from the extremely low speed section to the high speed section, and also to provide a shock absorber capable of reducing the length of the entire machining part, Which is the basic technical idea.

It will be apparent to those skilled in the art that many other modifications and applications are possible within the scope of the basic technical idea of the present invention.

100 ... First piston
101 ... Tension Euro
102 ... compressed air
200 ... second piston
201 ... connection tension oil
300 ... Pilot valve
400 ... tensile retainer
401 ... extended tension oil
500 ... disk valve assembly
510 ... disk-S
511 ... slit
520 ... main disk
521 ... unit disk
700 ... Piston rod
701 ... stepped portion
710 ... Washer
720 ... intake valve
730 ... Spacer
740 ... Finishing Washer
750 ... Finishing nut
800 ... cylinder
B ... Bypass Euro
C1 ... first pressure chamber
C2 ... second pressure chamber
C3 ... third pressure chamber
C4 ... fourth pressure chamber
D ... working channel
F1 ... Compressed first working flow
F2 ... Compressed first operating oil

Claims (5)

And a first pressure chamber (C1) formed by a plurality of tension channels (101) vertically penetrating and connected to an end side of a piston rod (700) reciprocating in the cylinder (800) A first piston (100) forming an upwardly recessed internal space;
A pilot valve (300) coupled to the piston rod (700) and disposed in the inner space, for selectively opening and closing a lower end of the tension passage (101);
A connecting tension channel 201 coupled to the piston rod 700 and having an upper side accommodated in the inner space and disposed at a lower portion of the first piston 100 and connected to the plurality of tension channels 101, A second piston (200) penetrating upward and downward and forming a second pressure chamber (C2) whose upper side is opened to communicate with the internal space;
A fourth pressure chamber C4 coupled to the piston rod 700 and disposed at a lower portion of the second piston 200 and formed by an extended tension passage 401 connected to the connection tension passage 201, A tension retainer 400 provided thereon; And
And a disc valve assembly 500 coupled to the piston rod 700 and disposed at a lower portion of the tensile retainer 400 to open and close the flow passage while allowing the deformable passage 401 to be deformed,
A plurality of compression flow passages 102 passing through the first piston 100 in the vertical direction and an inner circumferential surface of the first piston 100 forming the inner space and an outer circumferential surface of the second piston 200 And a third pressure chamber (C3) formed by the space of the second pressure chamber
And an intake valve (720) disposed on the upper side of the first piston (100) for opening and closing a passage communicating with the compression passage (102) and the tension passage (101).
The method according to claim 1,
The shock absorber
(D) for interconnecting the first pressure chamber (C1), the second pressure chamber (C2) and the extension tension passage (401) in the extremely low speed and low speed sections,
Wherein the working fluid in the cylinder (800) passes through the operation valve (500) through the working flow path (D) to generate a damping force.
The method according to claim 1,
The disk valve assembly 500 includes:
(510) formed with a slit (511) communicating with the elongated tension channel (401) along the edge and closely disposed on the lower side of the tension retainer (400)
And a main disk 520 having a plurality of unit disks 521 stacked on the lower side of the disk-S 510,
The shock absorber
(D) for interconnecting the first pressure chamber (C1), the second pressure chamber (C2), and the extension tension passage (401) at intermediate and high speed sections,
When the pressure of the first pressure chamber C1 is higher than that of the second pressure chamber C2, the pilot valve 300 is opened and connected to the inside of the third pressure chamber C3 and the cylinder 800 And a bypass flow path (B) is formed.
The method according to claim 1,
The shock absorber
A stepped portion 701 formed on the outer circumferential surface of the piston rod 700 so as to be stepped smaller than the diameter of the piston rod 700,
Further comprising a washer (710) coupled to the stepped portion (701) and disposed on the upper side of the first piston (100) and communicating with the compression passage (102) and the tension passage (101)
The intake valve 720 is coupled to the stepped portion 701 and disposed below the washer 710 and above the first piston 100 to allow for a shape change in communication with the washer 710 ,
The first piston 100, the pilot valve 300, the second piston 200, the tensile retainer 400, and the disk valve assembly 500 are mounted on the upper and lower portions of the stepped portion 701 Wherein the shock absorber is sequentially coupled along the first direction.
The method according to claim 1,
The shock absorber
A washer 710 coupled to an end of the piston rod 700 and disposed above the first piston 100 and communicating with the compression passage 102 and the tension passage 101,
The washer 710 and the intake valve 720 are coupled to the piston rod 700 and are disposed between the washer 710 and the intake valve 720 and restrict the vertical length of the intake valve 720, Further comprising a spacer 730 that separates the valves 720 from each other,
The intake valve 720 is coupled to the piston rod 700 and is disposed below the washer 710 and above the first piston 100, And a shock absorber.

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