KR101992129B1 - Shock absorber - Google Patents

Abstract

The present invention relates to a shock absorber, which comprises a housing having a housing space in which a housing space having a connected piston space and a space for placement is formed and whose sectional area changes, an actuating rod disposed inside the housing and partially exposed to the outside of the housing, Wherein the piston space has a first flow space connected to one side of the piston and a second flow space connected to the other side of the piston, And the first flow space and the second flow space are connected to each other through the housing flow path.

Description

SHOCK ABSORBER

The present invention relates to a shock absorber.

The shock absorber accommodates a working fluid having a viscosity inside and mitigates the impact applied to the working rod. The piston which is connected to the working rod can be moved to the original position by the elastic repulsive force of the elastic member after the shock is relaxed, so that the shock to be subsequently applied can be buffered.

Such a shock absorber 1 includes a housing 2 in which a working fluid can be received therein, a piston 3 movably disposed inside the housing 2, and a piston 3 An elastic member 4 which is connected to the housing 2 and is exposed to the outside of the housing 2 and which is located in the housing 2 and which applies an elastic force to the piston 3 so as to extend the working rod 4 out of the housing 2 5). The impacted working rod 4 is moved into the housing 2. At this time, the piston 3 receives the pressure of the working fluid to relieve the impact applied to the working rod 4. [

On the other hand, the housing 2 includes an inner tube 21 in which the piston 3 is disposed, and an outer tube 22 surrounding the inner tube 21. A housing flow path 23 is formed between the inner tube 21 and the outer tube 22. The first piston space 31 connected to one side of the piston 3 is connected to the housing passage 23 through a plurality of orifice holes 21a formed in the inner tube 21 and connected to the other side of the piston 3 The second piston space 32 is connected to the housing passage 23 through a return hole 21b formed in the inner tube 21. [

When the piston 3 is located on the other side of the inner tube 21 and an impact is applied to the operating rod 4 in a state in which the operating rod 4 is drawn out of the housing 2, And moves in one direction from the other side of the inner tube (21). The working fluid accommodated in the first piston space 31 receives pressure from the piston 3 and flows into the housing passage 23 through the orifice hole 21a and then flows through the return hole 21b into the second piston space 32, Respectively. The flow rate of the working fluid is controlled according to the interval and the diameter of the orifice holes 21a and the buffering force is controlled according to the flow rate of the working fluid passing through the orifice hole 21a.

Since the housing 2 includes the inner tube 21 and the outer tube 22, the outer peripheral diameter of the shock absorber 1 becomes larger and the inner tube 21 is disposed inside the outer tube 22, Respectively. Since the outer peripheral diameter of the piston 3 must be equal to the inner peripheral diameter of the inner tube 21, the sectional area of the piston 3 is limited.

Patent Registration No. 10-877613 (December 30, 2008) Registration Practical Utility Model No. 20-310305 (March 31, 2003)

The present invention provides a technique for controlling the flow rate of the working fluid and minimizing the length of the piston by changing the sectional area of the housing passage formed in the housing of the shock absorber.

The shock absorber according to an embodiment of the present invention includes a housing having a housing passage having a piston space and an arranging space connected to each other, the housing passage having a variable cross sectional area formed therein, a working rod having a part of the operating rod exposed inside the housing, Wherein the piston space has a first flow space connected to one side of the piston and a second flow space connected to the other side of the piston, the housing flow channel being connected to the piston of the housing, And the first flow space and the second flow space are connected to each other through the housing flow path.

The housing flow path may include a first flow path having a predetermined length and a cross sectional area unchanged, and a second flow path connected to the first flow path and varying in cross sectional area.

The cross-sectional area of the second flow path may gradually decrease from the first flow path.

The length of the first flow path may be shorter than the length of the piston, and the length of the piston may be shorter than the length of the second flow path.

The shock absorber may further include an elastic member disposed in the first flow space, and an elastic guide disposed between the elastic member and one side of the piston, wherein one side of the actuating rod is connected to the elastic guide through the piston And the elastic member may apply an elastic force to the piston so that the actuating rod is drawn out of the housing.

And one end of the actuating rod may be formed with a latching groove in which the elastic guide is engaged and fixed along the circumferential direction.

Wherein the piston has a through hole formed therethrough along a longitudinal direction thereof and the operating rod has a first portion passing through the arrangement space and a second portion connected to the first portion and passing through the through hole, Wherein a piston step is formed at a boundary between the first portion and the second portion so as to close the through hole in contact with the side surface of the piston and between the outer periphery of the second portion and the perimeter of the through hole And a working fluid can flow through the gap when the piston's step is separated from the piston.

According to the embodiment of the present invention, since the first flow space connected to one side of the piston and the second flow space connected to the other side of the piston are connected through the housing flow path formed along the longitudinal direction at the inner circumference of the housing, Can be omitted. The outer diameter of the housing can be reduced by omitting the inner tube and the number of parts can be reduced.

According to the embodiment of the present invention, when the flow passage is formed on the outer circumference of the piston, the piston must be longer than a predetermined length in consideration of the flow rate of the working fluid flowing from the first flow space to the second flow space. However, since the flow path of the working fluid in the first flow space to the second flow space is formed in the inner periphery of the housing, the length of the piston can be minimized. By minimizing the length of the piston, the concentricity of the piston and the housing can be precisely matched.

According to the embodiment of the present invention, since the length of the piston is minimized, the contact area between the piston and the inner circumference of the housing can be minimized, so that friction with the housing can be minimized when the piston moves, .

According to the embodiment of the present invention, when the flow path is formed on the outer periphery of the piston, the outer periphery of the piston is formed into a shelf and then transferred to a milling machine to form a flow path. However, since the flow path is formed in the inner periphery of the housing, (The arrangement space and the piston space), it is possible to process the oil passage directly around the inner periphery, which makes it easier to form the oil passage on the piston.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing the interior of a shock absorber according to an embodiment of the present invention; FIG.
Fig. 2 is an exploded perspective view of Fig. 1; Fig.
3 is a cross-sectional view taken along line III-III of Fig. 1; Fig.
4 is an enlarged view of a portion A in Fig.
FIG. 5 is a sectional view taken along line VV of FIG. 1; FIG.
Fig. 6 is an operational view showing a state where an impact is applied to the operating rod of Fig. 3; Fig.
Fig. 7 is an operation diagram showing a state in which the impact is released to the operation rod of Fig. 6; Fig.
8 is a schematic view showing a conventional shock absorber.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

A buffer according to an embodiment of the present invention will now be described with reference to FIGS. 1 to 5. FIG.

1 is an exploded perspective view of FIG. 1, FIG. 3 is a cross-sectional view taken along line III-III of FIG. 1, and FIG. 4 is a cross- Fig. 5 is a cross-sectional view taken along line VV in Fig. 1; Fig.

1 to 5, the shock absorber 100 according to the present embodiment includes a housing 110, a working rod 120, and a piston 130. [

The housing 110 has a predetermined length and a screw is formed on the outer periphery. The shock absorber 100 may be engaged with an object to be installed using a screw of the housing 110. The inside of the housing 110 is formed with an injection hole 111, a piston space 112, and a placement space 113 which are connected to each other.

The injection hole 111 is formed at one side of the housing 110 so that the working fluid can be injected into the piston space 112 through the injection hole 111. The injection hole 111 is coupled with a cap 111a for preventing leakage of the working fluid.

The piston space 112 is formed between the injection hole 111 and the placement space 113. The diameter of the piston space (112) is smaller than the diameter of the arrangement space (113). An operation rod cover step 113a is formed between the piston space 112 and the arrangement space 113. [

A housing passage 114 is formed around the piston space 112 along the longitudinal direction of the housing 110. The circumferential surface of the housing passage 114 is curved and connected to the piston space 112 when viewed from the housing passage 114 in the sectional view of the housing 110 cut along the circumferential direction. The housing passage 114 is formed along a portion of the circumferential direction at a portion of the inner periphery forming the piston space 112.

The housing passage 114 is formed around the other side of the piston space 112 and has a predetermined length and is connected to the other end of the first passage 114a and the other end of the first passage 114a, And a second flow path 114b having a length.

Sectional area of the first flow path 114a does not change and the cross-sectional area of the second flow path 114b decreases as the distance from the first flow path 114a increases. The length of the second flow path 114b is longer than the length of the first flow path 114a.

A fixed space 115, which is smaller than the diameter of the piston space 112, is formed between the injection hole 111 and the piston space 112.

An operation rod cover 160, an operation rod 170, a washer 180, a bumper stopper 190, and the like are disposed in the arrangement space 113, one side of which is in contact with the operation rod cover step 113a. One end of the operation rod cover 160 is connected to the piston space 112 and the other end of the operation rod cover 160 is connected to the incision groove 161 in a direction from the center to the outer side. And a plurality of cutting grooves 161 are formed at intervals along the circumferential direction. The fluid in the piston space 112 may be introduced into the accumulator 162 of the actuation rod cover 160 through the cutout groove 161.

The bumper stopper 190 is located at the end of the arrangement space 113 and is screwed around the arrangement space 113. A hermetic member 170a for preventing the leakage of the working fluid is coupled between the periphery of the arrangement space 113 and the outer circumferences of the operating rod cover 160 and the bumper stopper 190 and the inner circumference of the arrangement space 113. [

One end of the operation rod 120 is located in the piston space 112 through the bumper stopper 190, the washer 180, the operation rod 170 and the operation rod cover 160, . The impacted actuating rod 120 can move into the housing 110.

The operation rod 120 is connected to the first portion 121 and the first portion 121 which overlap with the bumper stopper 190, the washer 180, the operation rod 170, the operation rod cover 160 And a second portion (122) located in the piston space (112). Between the first portion 121 and the bumper stopper 190, a hermetic member 170b for hermetic sealing is disposed.

The first portion 121 is formed to have the same diameter as a whole, and the second portion 122 is formed of a plurality of stages with different diameters. The piston 122 is formed with a diameter difference between the second portion 122 and the first portion 121 because the diameter of the second portion 122 is smaller than the diameter of the first portion 121. [ A guide step 124 is formed in the predetermined portion of the second portion 122 and a catching groove 125 is formed in the end of the second portion 122 along the circumferential direction.

The piston 130 is disposed in the piston space 112 and the outer periphery thereof is in contact with the periphery of the piston space 112. The piston space 112 is defined by the piston 130 as a first flow space 112a connected to one side of the piston 130 and a second flow space 112b connected to the other side of the piston 130. [ The piston 130 may move from the second flow space 112b to the first flow space 112a when the operating rod 120 moves into the housing 110. [

When the piston 130 is positioned in the second flow space 112b, the other side of the piston 130 may be in contact with one side of the operating rod cover 160. The piston step 123 can contact the other side of the piston 130 as the actuation rod 120 moves into the housing 110. [

The piston 130 has a shorter length than the first flow path 114a. Also, the length of the piston 130 is shorter than the length of the second portion 122.

A through hole 131 through which the second portion 122 passes is formed in the piston 130. The diameter of the through hole 131 is larger than that of the second portion 122 and a gap 131g is formed between the circumference of the through hole 131 and the second portion 122.

The guide step 124 is located in the through hole 131 of the piston and the through hole 131 includes a first hole 131a and a second hole 131b having different diameters. The first hole 131a is connected to the second flow space 112b and the second hole 131b is connected to the first flow space 112a. The working fluid in the second flow space 112b may flow into the second hole 131b through the first hole 131a. The connection between the first hole 131a and the second flow space 112b may be blocked when the other side of the piston 130 contacts the piston step 123. [

The shock absorber 100 according to an embodiment of the present invention may further include an elastic guide 140 and an elastic member 150.

The elastic guide 140 is disposed in the piston space 112 and contacts one side of the piston 130. The elastic guide 140 includes a guide body 141 through which the second portion 122 passes, a fixing piece 142 formed at one side of the guide body 141 and inserted into the engagement groove 125, And a flange 143 formed on the other side of the piston 130 and contacting one side surface of the piston 130.

The elastic guide 140 can move along the actuating rod 120 when the actuating rod 120 is moved by the fixed piece 142 inserted and fixed in the locking groove 125. [ One side of the elastic piston 130 may be separated from the elastic guide 140 when the other side of the piston 130 contacts the piston 123 due to the engagement of the actuating rod 120 and the fixing piece 142.

A flow passage hole 145 is formed in the elastic guide 140 in contact with one side surface of the piston 130 in the direction of the flange 143 from the center. A plurality of flow holes 145 are formed at intervals along the circumferential direction of the elastic guide 140. The flow hole 145 connects the second hole 131b and the first flow space 112a. The working fluid in the second hole 131b may flow into the first flow space 112a through the flow hole 145. [

One end of the elastic member 150 is inserted into the fixing space 115 and the other end thereof contacts the flange 143 while surrounding the outer circumference of the guide body 141. The elastic member 150 applies an elastic force such that the elastic guide 140 abuts against one side of the piston 130 and the guide step 124. The other side of the piston 130 can be in contact with the operation rod cover 160 and the other side of the operation rod 120 can be exposed to the outside of the housing 110 by the elastic force of the elastic member 150. The elastic member 150 can be compressed when the piston 130 moves from the second flow space 112b to the first flow space 112a due to the operation rod 120. [

Next, the operation of the buffer described above will be described with reference to Fig. 6 and Fig.

First, a state in which the operating rod 120 moves into the housing 110 will be described with reference to FIG.

6A), the elastic guide 140 is brought into contact with the piston 130 and the guide step 124 by the elastic force of the elastic member 150, and the piston 130 is in contact with the operation rod cover 160 And a portion of the other side of the operation rod 120 is exposed to the outside of the housing 110. The first flow space 112a is connected to the second hole 131b through the flow passage hole 145 and the piston step 123 is separated from the other side of the piston 130. [

6 (b), the impacted impact rod 120 moves into the housing 110, and the guide step 124 presses the elastic guide 140 when the operation rod 120 moves, The guide 140 is separated from the piston 130 and the piston step 123 contacts the other side of the piston 130 to close the first hole 131a. At this time, one side of the piston 130 may apply pressure to the working fluid stored in the first flow space 112a. The working fluid in the first flow space 112a can flow into the through hole 131 through the space between the elastic guide 140 and the piston 130 and the piston step 123 can close the first hole 131a, And the working fluid of the through hole 131 can not flow into the second flow space 112b. The movement of the piston 130 causes the elastic member 150 to be compressed.

The working fluid in the first flow space 112a is moved by the pressure applied by the piston 130 to the space between the piston 130 and the operation rod cover 160 via the housing flow path 114, do. At this time, the piston 130 moves to one side of the piston space 112 in proportion to the flow rate of the working fluid, and the working rod 120 gradually flows into the housing 110 to mitigate the impact.

The sectional area of the second flow path 114b of the housing flow path 114 becomes narrower as the distance from the first flow path 114a becomes smaller so that the piston 130 moves out of the first flow path 114a As the second flow path 114b is overlapped, the flow rate of the working fluid can be reduced. As the piston 130 moves away from the first flow path 114a and overlaps with the second flow path 114b, the moving speed decreases. Accordingly, as the operating rod 120 also moves into the housing 110, the speed is gradually reduced while receiving a large pressure.

A portion of the working fluid introduced into the second flow space 112b can be moved into the operation rod cover 160 through the cutout groove 161. [

Referring to FIG. 6D, the elastic member 150 is in a compressed state due to the movement of the piston 130. When the impact applied to the operation rod 120 is released, the elastic member 150 can expand.

Next, referring to FIG. 7, a state in which the operating rod 120 moves from the inside to the outside of the housing 110 will be described.

7A, when the elastic member 150 completely absorbs the impact applied to the actuating rod 120, the piston 130 is moved out of the second flow path 114b so that the elastic member 150 is compressed, The guide 140 and the piston 130 are spaced apart and the piston step 123 abuts the piston 130.

7B, when the shock applied to the actuating rod 120 is released, the compressed elastic member 150 expands and the elastic guide 140 moves in the direction of the piston 130, Touch. At this time, the other side of the piston 130 is pressurized by the working fluid in the second flow space 112b, and at the same time, the operating rod 120 is also moved by the movement of the elastic guide 140. Thus, So that the first hole 131a is connected to the second flow space 112b. The other side surface of the piston 130 constantly applies pressure to the working fluid in the second flow space 112b.

7C, the working fluid in the second flow space 112b, which is pressurized by the piston 130, moves to the first flow space 112a along the gap 131g and the flow passage hole 145 . Also, the working fluid in the second flow space 112b can move to the first flow space 112a through the first flow path 114a and the second flow path 114b. The piston 130 moves in the direction of the operation rod cover 160 in proportion to the flow rate of the working fluid moving from the second flow space 112b to the first flow space 112a and the operation rod 120 moves in the direction of the housing 110, And is drawn out. On the other hand, as the piston 130 moves toward the operating rod cover 160, the cross-sectional area of the second flow path 114b overlapping with the piston 130 increases, thereby increasing the flow rate of the working fluid. The movement of the piston 130 and the drawing speed of the operating rod 120 can be increased. So that the operating rod 120 can quickly return.

7D, when the piston 130 contacts the operating rod cover 160, the operating rod 120 is not exposed to the outside of the housing 110, and the elastic member 150 maintains the expanded state do.

The first fluid space 112a connected to the one side of the piston 130 and the second fluid space 112b connected to the other side of the piston 130 are disposed along the longitudinal direction at the inner circumference of the housing 110, And is connected through the formed housing passage 114, so that the conventional inner tube can be omitted. The outside diameter of the housing 110 can be reduced by omitting the inner tube and the number of parts can be reduced.

When the flow passage is formed on the outer circumference of the piston 130, the piston 130 needs to be longer than a predetermined length in consideration of the flow rate of the working fluid flowing from the first flow space 112a to the second flow space 112b do. However, since the flow path of the working fluid in the first flow space 112a to the second flow space 112b is formed in the inner circumference of the housing 110, the length of the piston 130 can be minimized. The length of the piston 130 can be minimized and the concentricity of the piston 130 and the housing 110 can be exactly matched.

In addition, since the length of the piston 130 is minimized, the contact area between the piston 130 and the inner circumference of the housing 110 can be minimized, and friction with the housing 110 can be minimized when the piston 130 moves The movement of the piston 130 can be smoothly performed.

When the oil passage is formed on the outer circumference of the piston 130, the outer diameter of the piston 130 must be machined into a lathe and transferred to a milling machine to form the oil passage. Since the oil passage is formed around the inner circumference of the housing 110, It is possible to process the oil passage directly on the inner diameter after machining the inner diameter (arrangement space, piston space) of the oil chamber 110, so that machining can be made easier than forming the oil passage on the piston.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

100: shock absorber 110: housing
111: injection hole 111a: cap
112: piston space 112a: first flow space
112b: second flow space 113: arrangement space
113a: Operation rod cover step 114:
114a: first flow path 114b: second flow path
115: fixed space 120: working rod
121: first part 122: second part
123: piston step 124: guide step
125: engaging groove 130: piston
131: Through hole 131a: First hole
131b: second hole 131g: gap
140: elastic guide 141: guide body
142: Fixing piece 143: Flange
145: flow hole 150: elastic member
160: working rod cover 161: incision groove
162: Accumulator 170: Operable
170a, 170b: Hermetic member 180: Washer
190: Bumper stopper

Claims (7)

A housing having a connected piston space and an arrangement space,
An operating rod disposed inside the housing and partially exposed to the outside of the housing;
A piston which is movably disposed in the piston space and in which a through hole penetrating along the longitudinal direction is formed,
/ RTI >
The operating rod
A first portion passing through the arrangement space and
A second portion connected to the first portion and penetrating the through hole,
/ RTI >
Wherein a piston step is formed at a boundary between the first portion and the second portion to close the through hole in contact with the side surface of the piston, and a gap is formed between the outer circumference of the second portion and the peripheries of the through holes , And when the piston step is released from the piston, the working fluid can flow through the gap
buffer. The method of claim 1,
The housing channel
A first flow path having a predetermined length and a cross-sectional area unchanged, and
A second flow path connected to the first flow path,
Containing
buffer. 3. The method of claim 2,
And the cross-sectional area of the second flow path gradually decreases as the distance from the first flow path increases. 4. The method of claim 3,
Wherein the length of the first flow path is shorter than the length of the piston, and the length of the piston is shorter than the length of the second flow path. 3. The method of claim 2,
An elastic member disposed on one side of the piston,
And an elastic guide disposed between the elastic member and one side of the piston
Further comprising:
One end of the operating rod is connected to the elastic guide through the piston, and the elastic member applies elastic force to the piston so that the operating rod is drawn out of the housing
buffer. The method of claim 5,
Wherein the elastic rod is formed at one side of the operation rod along a circumferential direction. The method of claim 1,
Wherein the piston space has a first flow space connected to one side of the piston and a second flow space connected to the other side of the piston, the housing flow path being formed at least in part along the longitudinal direction around the piston space of the housing, The first flow space and the second flow space are connected through the housing flow path
buffer.

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