KR101387642B1 - Shock absorber - Google Patents

Abstract

The present invention relates to a shock absorber, wherein a piston having an discharge flow path is formed inside a housing in which a working fluid can be accommodated, and a spring for providing an elastic force to the piston, wherein the spring is provided with a bending portion, and the bending portion is An end portion of the spring is formed to be bent toward the center of the discharge flow path to block a portion of the discharge flow path, and the discharge ball located in the discharge flow path is caught by the bending portion and does not exit the discharge flow path. One side of the bending portion may be located at the edge of the discharge passage and the other side may be positioned past the center of the discharge passage.

Description

Shock Absorber

The present invention relates to a shock absorber.

In general, a shock absorber is a device that mitigates an impact applied to an object, and is installed and used for shock alleviation in a vehicle and a production line.

The shock absorber is configured to receive a high viscosity working fluid therein to mitigate the impact on the piston rod, and is typically configured to cushion the subsequent impact by moving the piston to its original position by the elastic repulsive force of the compression spring. do.

Such a shock absorber includes a housing in which a working fluid is received and the piston is movably coupled, an end cover positioned on one side of the housing, and positioned between the end cover and the piston and away from the end cover. And a spring for imparting a rod, a rod cover positioned on the other side of the housing and connected to the piston, and a bumper stopper fixed to prevent the rod cover from being separated from the housing.

In addition, flow paths through which the working fluid passes are formed in the piston and the end cover in the longitudinal direction, respectively. Each of the flow paths is provided with a check ball that regulates the flow of the working fluid passing through the flow path. The check ball does not leave the flow path by a snap ring coupled to the flow path.

Such a snap ring is generally formed in a circular shape and the predetermined position is cut off. The broken part is formed with a hole for removal, and when the force is applied to the snap ring pliers with the operation tool provided at the end of the snap ring plier inserted into the hole, the gap between the broken parts of the snap ring is opened or closed. Will be taken.

In order to couple the snap ring to the flow path, it is inconvenient to use a dedicated tool such as a snap ring pliers.

Patent Registration No. 10-877613 (2008.12.30.) Utility Model Registration No. 20-310305 (2003.03.31.)

The present invention provides a shock absorber for easily fixing a ball that interrupts the flow of a working fluid.

According to one embodiment of the present invention, a shock absorber includes a piston in which a discharge flow path is formed and a spring that provides an elastic force to the piston, and a banding part is formed in the housing in which the working fluid can be accommodated. The bending part is formed in a shape in which the end of the spring is bent toward the center of the discharge flow path to block a portion of the discharge flow path, and the discharge ball located in the discharge flow path is caught by the bending portion and does not exit the discharge flow path. One side of the bending portion may be located at the edge of the discharge passage and the other side may be positioned past the center of the discharge passage.

In the shock absorber according to another embodiment of the present invention, a piston in which a discharge flow path is formed and a spring that provides an elastic force to the piston are disposed in a housing in which a working fluid can be accommodated, and the spring has a bending portion formed therein. The banding part is formed in a shape in which the end of the spring is bent toward the center of the discharge flow path to block a portion of the discharge flow path, and the discharge ball located in the discharge flow path is caught by the bending portion and does not exit the discharge flow path. The piston may have an insertion groove connected to the discharge passage therein, and an end portion of the spring and the bending portion may be located at the insertion groove.

Shock absorber according to another embodiment of the present invention, a housing that can accommodate the working fluid, a piston disposed inside the housing, the discharge passage is formed inside, is connected to one side of the piston and the incision groove is formed An extension protrusion having an extension flow passage connected to the discharge passage, and a spring that imparts elastic force to the piston and is connected to the extension protrusion. The spring is formed with a bending portion, the bending portion is formed in a form in which the end of the spring is bent toward the center of the discharge flow path to block a portion of the discharge flow path, the extension protrusion is inserted into the spring, The banding part may be inserted into the extension flow path through the cutting groove to prevent the discharge ball located in the discharge flow path from being caught by the banding part and exiting from the discharge flow path.

According to another embodiment of the present invention, a shock absorber includes a piston having a discharge flow path on one side of a housing within which a working fluid can be accommodated, and a spring that provides an elastic force to the piston, and at one side of the spring to the discharge flow path. A banding part is formed to prevent the discharge ball positioned from the discharge passage from being discharged from the discharge passage. An end cover is formed on the other side of the housing to face the piston and has an inflow passage formed therein, and the inflow ball positioned at the inflow passage is the inflow passage. At least a portion of the end cover of the end cover may be bent in the direction of the inflow passage so as not to be separated from the recess.

A shock absorber according to another embodiment of the present invention includes a piston having a discharge passage and a spring for applying an elastic force to the piston at one side of a housing within which a working fluid can be accommodated, and at one side of the spring, the discharge passage. A banding part is formed to prevent the discharge ball located at the exit from the discharge flow path, and an end cover having an inflow flow path formed on the other side of the housing facing the piston is disposed on the other side of the spring. A blocking portion may be formed to prevent the inflow ball from leaving the inflow passage.

According to another embodiment of the present invention, a shock absorber includes an end cover having an inflow passage communicating with an interior of the housing and a piston having an outlet passage in a housing in which working fluid can be accommodated. At least a portion of the end of the end cover is bent in the inflow path direction so that a ball does not escape from the inflow path.

According to an embodiment of the present invention, a banding portion is formed in a spring that provides elastic force to the piston, and the banding portion does not escape the check ball located in the inner passage of the piston. Since the end of the spring is bent to prevent the separation of the check ball by using the bending portion formed in the form can be omitted the coupling of the conventionally used snap ring to facilitate the assembly of the shock absorber.

According to the embodiment of the present invention, since the recess is formed in the end cover, the check ball located in the flow path formed in the end cover does not leave the flow path. As a result, the use of a snap ring can be eliminated, thereby simplifying the assembly of the shock absorber.

1 is a cross-sectional view of a shock absorber according to an embodiment of the present invention;
FIG. 2 is an exploded perspective view of the end cover, the spring, and the piston shown in FIG. 1. FIG.
3 is a perspective view of the end cover, the spring, and the piston shown in FIG.
4 is a side view of the spring shown in FIG.
5 is an exploded perspective view showing another embodiment of the piston shown in FIG.
6 is an exploded perspective view of the piston and the spring shown in FIG.
7 is an operational state diagram of the shock absorber shown in FIG.
8 is a cross-sectional view showing a state in which a working fluid is injected into the shock absorber.
9 is a perspective view showing a state in which the blocking portion is formed in the spring shown in Figure 2 as another embodiment of the present invention.

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.

Then, a buffer according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.

1 is a cross-sectional view showing a shock absorber according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the end cover, the spring, and the piston shown in Figure 1, Figure 3 is an end cover, spring, shown in Figure 2 And piston coupling perspective view.

1 to 3, the shock absorber 1 according to the present embodiment includes a housing 10, an end cover 30, a piston 40, and a spring 50.

An operating space 11 penetrated along the longitudinal direction is formed inside the housing 10. A viscous working fluid may be accommodated in the working space 11. The rod cover 20 is disposed at one side of the working space 11. A storage space 21 is formed between the rod cover 20 and the inner circumferential surface of the working space 11, and an accumulator is disposed in the storage space 21. The working fluid is stored in the storage space 21. However, the storage space 11 can be omitted. The inside of the rod cover 20 penetrates along the longitudinal direction.

One side of the housing 10 is coupled to the bumper stopper 22 for fixing the rod cover 20 so as not to be separated from the working space (11). The inside of the bumper stopper 22 penetrates along the longitudinal direction.

Such a bumper stopper 22 is formed along the periphery of the bumper body portion 22a and the bumper body portion 22a which are in close contact with one side of the housing 10 and at least partially inserted into the housing 10. It includes a widened tube portion 22b. The dilating part 22b is gradually enlarged as it moves away from the bumper body part 22a, and is inserted into the inner circumferential surface of the housing 10.

On the other hand, in the case of the expansion pipe portion 22b, the bumper body portion 22a is not opened until the bumper body portion 22a is coupled to the housing 10. The opening of the expansion pipe portion 22b is inserted into the interior of the housing 10 by the bumper body portion 22a being inserted into the housing 10 and contacting the rod cover 20.

The rod cover 20 is provided with an expansion pipe portion 20a for opening the expansion pipe portion 22b. The expansion tool 20a is gradually inclined from one side to the other side. The expansion pipe portion 22b is opened while being in contact with the inclined portion of the expansion pipe tool portion 20a.

Since the dilated expansion part 22b is inserted into the inner surface of the housing 10, the bumper stopper 22 is not easily separated from one side of the housing 10. Accordingly, the bumper stopper 22 can firmly fix the rod cover 20 to the inside of the housing 10.

The end cover 30 is coupled to the other side of the housing 10. At least a portion of the end cover 30 is inserted into the working space 11. At this time, at least a part of the end cover 30 is caught by the step formed in the inner circumferential surface of the housing 10 and is no longer inserted into the working space 11.

In addition, the inflow passage 31 penetrates through the inside of the end cover 30 along the longitudinal direction. The inflow flow path 31 is formed in multistage form. The inflow passage 31 is connected to the working space 11. The working fluid may flow into the working space 11 through the inflow passage 31. One end of the inflow passage 31 is provided with a stopper for intermitting the inflow passage 31, and an inlet ball 32 which prevents the working fluid introduced into the working space 11 from leaking through the flow passage again on the other side of the inflow passage 31. ) Is arranged. At this time, the inflow ball 32 is located in the flow path portion having the largest diameter among the inflow flow path 31 of the multi-stage. The passage portion having the largest diameter is connected to the working space 11. In addition, the flow path diameter of the portion where the inflow ball 32 is located is larger than the diameter of the inflow ball 32. The inflow ball 32 located in the flow path portion having the largest diameter is in close contact with the flow path portion having a small diameter by the fluid pressure in the working space 11.

In addition, at least a part of the end of the end cover 30 of the portion having the largest diameter is bent toward the inflow passage 31 to form the depression 33. The depression 33 protruding in the inflow path 31 prevents the inflow ball 32 from being separated from the inflow path 31.

The end of the end cover 30 is bent in the direction of the inflow channel 31 to form the depression 33, and the depression 33 prevents the inflow ball 32 from being separated from the inflow channel 31. Use of ball fixing means is omitted. Accordingly, it is possible to reduce the manufacturing cost of the shock absorber and further minimize the assembly process.

On the other hand, the end cover 30 is fixed to the inner surface of the housing 10 in the portion of the housing 10 where the end cover 30 is located so that the end cover 30 is not separated from the inside of the housing 10. Detachable member 61 in contact with each other, a fixing member 62 whose tip portion penetrates the detachment preventing member 61 and contacts the end surface of the end cover 30, and the fixing member 62 and the end cover 30 can be separated. It comprises a connecting member 63 for connecting. The connecting member 63 penetrates through the fixing member 62 and is coupled to at least a portion of the inflow passage 31. In addition, the connecting member 63 serves as a stopper to intercept the inflow passage 31 while detachably connecting the fixing member 62 and the end cover 30.

The piston 40 is located in the working space 11 and is located between the rod cover 20 and the end cover 30. The piston 40 can move linearly in the working space 11. The piston 40 is coupled to the rod 40 and the operating rod 46 penetrating the interior of the bumper stopper 22. A bumper head 47 is coupled to the end of the actuating rod 46. When an external force is applied to the bumper head 47, the piston 40 can move linearly in the working space 11.

The discharge passage 41 penetrates the piston 40 along the longitudinal direction. The discharge flow passage 41 is formed in a multistage form. On the other hand, an insertion groove 41a connected to the discharge passage 41 is formed at one inner side of the piston 40. The insertion groove 41a is connected to the inflow passage 31 of the end cover 30 through the working space 11.

At least a portion of the outer circumferential surface of the piston 40 is formed with a piston flow passage 40a along the longitudinal direction. The piston flow passage 40a faces the housing flow passage 10a formed on the inner circumferential surface of the working space 11. However, the piston passage 40a may deviate from the housing passage 10a during linear movement. A connecting groove 10b is formed along the circumferential direction on the inner circumferential surface of the working space 11 so that the piston passage 40a can be connected to the housing passage 10a even when the piston passage 40a is removed from the housing passage 10a. It is.

  According to the moving direction of the piston 40, the working fluid of the working space 11 may pass through the discharge passage 41, the piston passage 40a, and the housing passage 10a. On the other hand, in the discharge flow path 41, the discharge ball 42 which intercepts the working fluid passing through is arrange | positioned. In addition, the diameter of the flow path of the portion where the discharge ball 42 is located is larger than the diameter of the discharge ball 42. When the piston 40 moves in the direction of the end cover 30, the discharge ball 42 is in contact with the passage portion having a small diameter.

Meanwhile, as illustrated in FIGS. 5 and 6, an extension protrusion 43 protruding in the direction of the end cover 30 is formed on one surface of the piston 40 facing the end cover 30. The outer circumferential diameter of the extending protrusion 43 is smaller than the inner circumferential diameter of the working space 11.

An extension passage 44 connected to the discharge passage 41 is formed inside the extension protrusion 43. In addition, the extension protrusion 43 is formed with a cutting groove 45 along the longitudinal direction. The cutaway groove 45 is connected to the extension passage 44.

Referring again to FIGS. 1 to 3, the spring 50 is positioned between the end cover 30 and the piston 40 and imparts elastic force to move the piston 40 away from the end cover 30. do.

One side of the spring 50 is inserted into the insertion groove 41a. At the end of the spring 50 inserted into the insertion groove 41a, a bending portion 51 is formed to block a portion of the discharge passage 41 so that the discharge ball 42 does not escape from the discharge passage 41. As shown in FIG. 4, the bending part 51 is bent vertically toward the center SC of the spring 50 at the end of the spring 50. At this time, the bending part 51 passes through the center SC of the spring 50 and is located below the center SC of the spring 50.

Meanwhile, as shown in FIGS. 5 and 6, when the extension protrusion 43 is formed on the piston 40, an end portion of the spring 50 may be coupled to the extension protrusion 43. At this time, since the outer circumferential surface diameter of the extension protrusion 43 is smaller than the inner circumferential surface diameter of the spring 50, the extension protrusion 43 is inserted into the spring 50. And the bending part 51 is located in the extension flow path 44 through the cutting groove 45. The bending portion 51 positioned in the extension passage 44 blocks the discharge passage 41 so that the discharge ball 42 does not escape from the discharge passage 41.

As such, the bending portion 51 of the spring 50 prevents the discharge ball 42 from escaping from the discharge passage 41, so that ball fixing means such as a snap ring (not shown) may not be used.

On the other hand, the other side of the spring 50 is in contact with one surface of the end cover (30). The other end portion of the spring 50 may be formed with a blocking portion 52 (see FIG. 9) having the same shape as the bending portion 51. When the blocking portion 52 is formed at the other end of the spring 50, the end portion of the end cover 30 is cut out so that the blocking portion 52 may be positioned in the inflow passage 31.

The blocking portion 52 may be positioned in the inflow passage 31 through the cut portion of the end cover 30. Since the blocking portion 52 is positioned in the inflow passage 31, the inflow ball 32 is caught by the blocking portion 52 so that the inflow ball 32 does not fall out of the inflow passage 31.

As such, when the blocking portion 52 is formed at the other end of the spring 50, the depression formed in the end cover may be omitted.

As described above, due to the simple configuration such as the bending part 51, the blocking part 52, or the depression part 33, separation of the balls located in the discharge passage 41 and the inflow passage 31 may be prevented.

Referring to FIGS. 7 and 8 again, the operation of the above-described shock absorber will be described.

First, referring to a) of FIG. 7, when an external force is applied to the bumper head 47, the piston 40 moves in the direction of the end cover 30. At this time, as the pressure of the working fluid located in the one side working space 11a between the end cover 30 and the piston 40 is increased by the moving piston 40, the inlet ball 31 has a smaller diameter in the inlet flow path 31. The discharge ball 42 is in close contact with the flow path portion, and the discharge ball 42 is in close contact with the flow path portion having a small diameter in the discharge flow path 41.

 In this state, the working fluid of the one side working space 11a passes through the piston passage 40a and the housing passage 10a to the other operating space 11b and the storage space 21 between the piston 40 and the rod cover 20. Go to. The movement of the working fluid allows the piston 40 to move gradually toward the end cover 30. And the spring 50 is compressed.

Next, referring to b) of FIG. 7, when the external force applied to the bumper head 47 is removed, the compressed spring 50 is restored to its original state to impart elastic force to the piston 40. The piston 40, which has received the elastic force, moves in a direction away from the end cover 30. That is, the piston 40 is moved in the direction of the rod cover 20. At this time, the pressure of the working fluid located in the other working space (11b) is increased. The working fluid whose pressure is high will press the discharge ball 42 which is blocking the discharge flow path 41. The pressurized discharge ball 42 falls on the end portion of the discharge passage 41 having a smaller diameter, thereby opening the discharge passage 41. The working fluid located in the other working space 11b may be introduced into the one working space 11a through the open discharge passage 41, the housing passage 10a, and the piston passage 40a.

The discharge ball 42 away from the end of the discharge passage 41 tries to move to the one side working space 11a along the working fluid. At this time, the discharge ball 42 is in contact with the bending portion 51 blocking the discharge flow path 41, the discharge ball 42 is not separated from the discharge flow path (41).

Next, referring to FIG. 8, when the injection of the working fluid into the operating space of the shock absorber is required for the first time or afterwards, the connecting member 63 coupled to the end cover 30 is removed. At this time, since the inflow ball 32 is in contact with the end of the flow path having a small diameter, the working fluid of one side working space 11a does not leak to the outside through the inflow flow path 31.

The working fluid is injected into the inflow passage 31 with the connecting member 63 removed. At this time, since the pressure of the working fluid being injected is higher than the working fluid pressure of the one side working space 11a, the inflow ball 32 is separated from the end of the flow path having a smaller diameter of the inflow flow path 31 so that the inflow flow path 31 is opened. By opening the inflow passage 31, the working fluid may be injected into the one side working space 11a. On the other hand, the inlet ball 32 is separated from the end of the flow path of the small diameter of the inlet flow path 31 tries to move to one side working space (11a) along the injection fluid. The moving inlet ball 32 is in contact with the recess 33 and cannot be separated from the inflow passage 31.

As such, the balls 32 and 42 are not separated from the flow paths 31 and 41 by the bending portion 51 of the spring 50 and the depression 33 of the end cover 30. Since the same configuration as the conventional snap ring for preventing the separation of the 32 and 42 does not need to be coupled to each of the flow paths 31 and 41, the assembly of the shock absorber can be simplified.

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.

1: shock absorber 10: housing
11: working space 20: rod cover
21: storage space 22: bumper stopper
30: end cover 31: inflow passage
32: inflow ball 33: depression
40: piston 41: discharge flow path
41a: insertion groove 42: discharge ball
43: extension protrusion 44: extension flow path
45: incision groove 46: operating rod
47: bumper head 50: spring
51: banding section SC: center

Claims (6)

In the housing in which the working fluid can be accommodated, a piston having a discharge flow path and a spring for applying an elastic force to the piston are disposed, and the spring has a bending portion formed therein, and the bending portion has an end portion of the spring discharged. It is formed to be bent toward the center of the flow path to block a portion of the discharge flow path, one side of the bending portion is located at the edge of the discharge flow path and the other side is located beyond the center of the discharge flow path, discharge ball located in the discharge flow path Is a buffer that is caught in the bending portion and does not exit from the discharge passage. In the housing in which the working fluid can be accommodated, a piston having a discharge flow path and a spring for providing an elastic force to the piston are disposed, and the spring has a bending portion formed therein, and the bending portion has an end portion of the spring discharged. It is formed to be bent toward the center of the flow path to block a portion of the discharge flow path, the discharge ball located in the discharge flow path is caught in the banding portion does not exit from the discharge flow path, the piston and the discharge flow path therein A shock absorber having an insertion groove formed therein, wherein the end portion of the spring and the bending portion are positioned in the insertion groove. A housing in which working fluid can be received,
A piston disposed inside the housing and having a discharge passage formed therein;
An extension protrusion connected to one side of the piston and having an incision groove formed therein and having an extension flow passage connected to the discharge flow passage inward;
A spring that imparts elastic force to the piston and is connected to the extension protrusion
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The spring is formed with a bending portion, the bending portion is formed in a form in which the end of the spring is bent toward the center of the discharge flow path to block a portion of the discharge flow path, the extension protrusion is inserted into the spring, And the banding part is inserted into the extension flow path through the cutout groove so that the discharge ball located in the discharge flow path is caught by the banding part so as not to escape from the discharge flow path. On one side of the housing within which the working fluid can be accommodated, a piston having a discharge flow path and a spring for providing an elastic force to the piston are disposed, and on one side of the spring, a discharge ball located in the discharge flow path is separated from the discharge flow path. A banding part is formed to prevent the cover, and an end cover having an inflow flow path facing the piston is disposed at the other side of the housing, and at least an end portion of the end cover to prevent the inflow ball located in the inflow flow path from escaping the inflow flow path. And a portion of which is bent in the direction of the inflow passage to form a depression. On one side of the housing within which the working fluid can be accommodated, a piston having a discharge flow path and a spring for providing an elastic force to the piston are disposed, and on one side of the spring, a discharge ball located in the discharge flow path is separated from the discharge flow path. A banding part is formed to prevent the inside of the housing, and an end cover formed with an inflow flow path facing the piston is disposed at the other side of the housing, and an inflow ball located at the inflow flow path is prevented from being separated from the inflow flow path at the other side of the spring. A shock absorber having a blocking portion formed therein. An end cover having an inlet flow passage communicating with the interior of the housing is located in a housing in which a working fluid can be received, and a piston having an outlet flow passage, so that the inlet ball located inside the inflow passage does not escape from the inflow passage. At least a portion of an end of the cover is bent in the direction of the inflow passage.

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