KR20200139957A - Apparatus for testing durability of bush - Google Patents

Abstract

The present invention relates to an apparatus for testing the durability of a bushing. The apparatus comprises: a cylinder body having a first fluid filling part and a second fluid filling part communicating with each other; a downward piston installed in the cylinder body to be able to rise and lower along the first fluid filling part; a bushing gripper holding a bushing assembly and seated on the downward piston; a pressing member pressing the bushing gripper downward to restrict the flow of the bushing assembly, and moving the downward piston downward; and an upward piston installed in the cylinder body to be able to be raised and lowered along the second fluid filling part, and raised by the flow of a working fluid inside the cylinder body when the piston moves downward, so as to press the bushing assembly upward. Therefore, the reliability of test results can be ensured.

Description

Bush durability test device{APPARATUS FOR TESTING DURABILITY OF BUSH}

The present invention relates to a bush durability test apparatus, and more particularly, to a bush durability test apparatus for measuring the durability of a bush against a pressing force acting in the axial direction.

In general, a vehicle bush is applied to a subframe of a vehicle, and the subframe of the vehicle has a structure in which a bush is coupled to an end of the frame portion. The bush includes a cylindrical bush portion with a hollow inside and open both ends in the axial direction, and a bush body portion coupled to the inside of the bush portion. In testing the durability of the bush, an arbitrary one of the subframes that have been manufactured is selected and tested.

Conventionally, the bush unit is seated on a pipe-shaped pedestal having an inner diameter corresponding to the inner diameter of the bush unit, and the bush main body is pressed downward from the upper side with a pressing pipe having a diameter smaller than the inner diameter of the bush unit, thereby pushing the bush main body toward the pipe-shaped pedestal side. have.

However, the frame portion of the subframe and the bush are integrally and rigidly joined by welding, so when separating the bush to be subjected to the durability test from the subframe, in order to remove the bush from the subframe without damaging the bush, the subframe After cutting the end to which the middle bush is coupled, a cumbersome pre-preparation process is performed in which the frame portion is further cut and separated to prevent interference due to the flange portion formed to protrude from the bush or the frame portion coupled with the bush.

Therefore, there is a need to improve this.

The background technology of the present invention is disclosed in Korean Patent Registration No. 10-0350134 (registered on Aug. 13, 2002, title of invention: vehicle suspension bush durability test apparatus).

An object of the present invention is to provide a bush durability test apparatus capable of ensuring the reliability of test results while the durability test of a bush can be made more easily and efficiently.

The bush durability test apparatus according to the present invention comprises: a cylinder body having a first fluid filling portion and a second fluid filling portion in communication; A downward piston mounted to the cylinder body so as to be elevated along the first fluid filling part; A bush gripper that holds a bush assembly and is seated on the downward piston; A pressing member for pressing the bush gripper downward to restrain the flow of the bush assembly and moving the downward piston downward; And an upward piston installed in the cylinder body so as to be elevating along the second fluid filling part, and being raised by the flow of the working fluid inside the cylinder body when the downward piston descends and pressing the bush assembly upwardly. It features.

The cylinder body includes: a cylinder portion having the first fluid filling portion and the second fluid filling portion formed therein; A partition wall portion formed inside the cylinder portion and partitioning the first fluid filling portion and the second fluid filling portion; And a flow hole portion formed to pass through the partition wall portion and forming a flow path of the working fluid.

The bush assembly may include a bush part held by the bush gripper; A bush body part coupled to the inside of the bush part and pressed upward by the upward piston; A bush coupling portion having a cross-sectional shape of a closed loop structure, a width greater than that of the bush portion, and coupled to an outer surface portion of the bush portion; And a bush gap formed between the bush part and the bush coupling part in a direction perpendicular to the axial direction of the bush part, wherein one end of the bush gripper is inserted into the bush coupling part and the bush A first gripper in contact with the part and the other end of which is seated on the downward piston from the outside of the bush coupling part; And a second gripper disposed to face the first gripper with the bush part therebetween, and passing through the bush gap and contacting the first gripper.

The bush gripper may include: a first gripper press-contacted to one side of the bush assembly; A second gripper disposed to face the first gripper with the bush assembly interposed therebetween, and partly disposed to overlap the first gripper; And a gripper fastening member penetrating the overlapping portion between the first gripper and the second gripper.

The first gripper may include a first bush contact part in contact with one side of the bush assembly; A first seating and holding portion connected to the first bush contact portion, seated on the downward piston, and held between the downward piston and the pressing member by a pressing force of the pressing member; And a first fixing hole formed to pass through the first seating and holding part, through which the gripper fastening member passes.

The second gripper may include a second bush contact part in contact with the other side of the bush assembly; A second seating and holding portion connected to the second bushing contact portion, seated on the downward piston, and held between the downward piston and the pressing member by a pressing force of the pressing member; An overlapping arm part extending from the second bushing contact part toward the second gripper and disposed to overlap the second gripper; And a second fixing hole formed to pass through the overlapping arm and through which the gripper fastening member passes.

The upward piston may include a pressure piston mounted on a partition wall portion of the cylinder body and elevating along the second fluid filling portion; And a bush pressing unit having a shape capable of passing through the inside of the bush assembly in the axial direction, seated on the pressing piston, moving in the same displacement as the pressing piston, and pressing the bush assembly upward. do.

The bush durability test apparatus according to the present invention stably applies an upward pressing force to the bush assembly by passing through a simple test process of applying a downward force to a pressing member in a state where the bush assembly is held by a bush gripper and seated on a downward piston. While making it possible to test the durability of the bush assembly.

Accordingly, according to the present invention, by placing a pipe-shaped pedestal under the cylindrical bush portion of the conventional bush assembly and partially applying a downward force only to the bush body portion coupled to the inside of the bush portion, the bush body portion is pushed toward the pipe-shaped pedestal side and separated. Compared to the existing ones, there is no need to go through the cumbersome pre-process of separating and separating the flange part formed protruding from the outer surface of the bush part or the frame part connected to the bush part from the bush part, making the durability test of the bush more convenient and efficient. I can.

In addition, in the present invention, the downward force of the pressing member acts as a fixing force that fixes the bush gripper and the bush part in the upper position of the downward piston, and the direction is shifted upward through the inside of the cylinder body and transmitted to the upward piston It is possible to fundamentally prevent the occurrence of upward slip of the bush part due to the upward force acting on the body part. Accordingly, it is possible to prevent the occurrence of noise in the test result due to the slip of the bush portion, and it is possible to secure the reliability of the test result.

1 is a perspective view schematically showing a bush durability test apparatus according to an embodiment of the present invention.
2 is a conceptual diagram illustrating a structure of a bush assembly that is a test object of a bush durability test apparatus according to an embodiment of the present invention.
3 is a cross-sectional perspective view schematically illustrating a bush durability test apparatus according to an embodiment of the present invention.
4 is an exploded perspective view schematically showing a bush durability test apparatus according to an embodiment of the present invention.
5 is a cross-sectional perspective view of a main part schematically showing a cylinder body of a bush durability test apparatus according to an embodiment of the present invention.
6 is an operating state diagram illustrating the operation of the bush durability test apparatus according to an embodiment of the present invention.

Hereinafter, an embodiment of a bush durability test apparatus according to the present invention will be described with reference to the accompanying drawings. In this process, thicknesses of lines or sizes of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, and may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is a perspective view schematically showing a bush durability test apparatus according to an embodiment of the present invention, and FIG. 2 is to explain the structure of a bush assembly that is a test object of the bush durability test apparatus according to an embodiment of the present invention. 3 is a schematic cross-sectional perspective view illustrating a bush durability test apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the bush durability test apparatus 1 according to an embodiment of the present invention includes a cylinder body 10, a downward piston 20, a bush gripper 30, a pressing member 40, and an upward piston 50. ).

The cylinder body 10 is a device that generates hydraulic pressure for applying a load to the bush assembly 2, and the working fluid is filled therein, and the first fluid filling section 12 and the second fluid filling section 13 communicate with each other. Is formed. The downward piston 20 is installed to be elevating in the first fluid filling part 12 of the cylinder body 10.

The bush gripper 30 is seated on the downward piston 20 by holding the bush assembly 2 as a test object. The bush assembly (2) has a cylindrical or cylindrical shape, and the bush gripper (30) is pressed around the outer periphery of the bush assembly (2) and is firmly coupled to the bush assembly (2).

The pressing member 40 presses the bush gripper 30 downward toward the downward piston 20 to constrain the flow of the bush assembly 2 and moves the downward piston 20 downward. The upward piston 50 is installed to be elevating in the second fluid filling part 13 of the cylinder body 10.

When the downward piston 20 descends, the working fluid inside the first fluid filling portion 12 flows toward the second fluid filling portion 13 and upwards to the upward piston 50 located in the second fluid filling portion 13 The force is applied. As the upward piston 50 rises by this action, the bush assembly 2 located on the upper side is pressed upward.

In general, the vehicle bush is applied to the subframe 3 of the vehicle, as shown in FIG. 2, and the subframe 3 of the vehicle has a structure in which a bush (not shown) is coupled to the end of the frame unit 4 Have. In testing the durability of the bush, any one of the subframes 3 that have been manufactured is selected and tested.

Since the frame part 4 and the bush are integrally and rigidly coupled by welding, precise mutual separation is difficult. Therefore, in testing the durability of the bush, by cutting the end of the sub-frame 3 to which the bush is coupled, the bush is separated from the sub-frame 3 without damaging the bush. Accordingly, as shown in Fig. 2, the bush assembly 2, which is a test object of the bush durability test apparatus 1 according to an embodiment of the present invention, is a bush part 2a, a bush body part 2b, It has a structure including a bush coupling portion 2c and a bush clearance portion 2d.

The bush portion 2a has a cylindrical shape in which the inside is hollow and both ends in the axial direction are open. The bush part 2a has a circumference of its outer surface in pressure contact with the bush gripper 30 and is integrally coupled with the bush gripper 30. The bush gripper 30 is seated on the downward piston 20 with the bush gripper 30 attached to the circumference of the bush part 2a, and by pressing the pressing member 40, the bush part 2a becomes a downward piston. It is held in the correct position corresponding to the upper central part of (20).

The bush body part 2b is coupled to the inside of the bush part 2a, and the lower part contacts the upward piston 50. During the operation of the present invention, while the bush part 2a is held in the correct position, the bush body part 2b is subjected to an upward pressing force by the upward piston 50. In the description of the present invention, a component of a vehicle having a structure in which only the bush portion 2a and the bush body portion 2b are coupled to each other is referred to as a'bush'.

The bush durability test apparatus 1 according to the present invention is for testing the coupling force between the bush part 2a and the bush body part 2b, and the bush body part 2b is in the state of holding the bush part 2a as described above. ) By intensively applying a pressing force in the axial direction, the bush body portion 2b is separated from the bush portion 2a. A value corresponding to the load applied to the pressing member 40 of the bush assembly 2 at the time when the bush body 2b is separated from the bush 2a can be determined as the durability of the bush assembly 2.

The bush coupling part (2c) is a device part corresponding to the end of the frame part (4) combined with the bush from the sub-frame (3), has a cross-sectional shape of a closed loop structure, and a width that is larger than the diameter of the bush part (2a) It is coupled to the outer surface of the bush (2a).

A bush clearance part 2d is formed to be hollow between the bush part 2a and the bush coupling part 2c. The bush clearance portion 2d is formed to penetrate in a direction perpendicular to the axial direction of the bush portion 2a, and communicates with the inside of the bush coupling portion 2c. The bush gripper 30 uses a bush engaging portion 2c formed to protrude around the bush portion 2a and a bush gap portion 2d as a locking jaw or a guider to be rigid without flow around the bush portion 2a. Pressure-welded and fixed.

FIG. 4 is an exploded perspective view schematically illustrating a bush durability testing apparatus according to an embodiment of the present invention, and FIG. 5 is a cross-sectional view schematically showing a cylinder body of a bush durability testing apparatus according to an embodiment of the present invention. Figure 6 is a perspective view, Figure 3 is an operating state diagram illustrating the operation of the bush durability test apparatus according to an embodiment of the present invention.

3 to 5, a cylinder body 10 according to an embodiment of the present invention includes a cylinder portion 11, a partition wall portion 14, and a flow hole portion 18.

A first fluid filling portion 12 and a second fluid filling portion 13 are formed inside the cylinder portion 11. The second fluid filling portion 13 is formed to be hollow in a cylindrical shape at the center of the cylinder portion 11, the first fluid filling portion 12 is interposed by the partition 14, and the second fluid filling portion ( 13) is formed to be hollow in a cylindrical shape outside the radial direction.

The partition wall portion 14 is formed to partition the first fluid filling portion 12 and the second fluid filling portion 13 inside the cylinder portion 11. 3 and 5, the partition wall portion 14 according to an embodiment of the present invention includes a partition wall body portion 15, a stopper portion 16, and a piston seating portion 17.

The partition wall body portion 15 has a cylindrical shape that divides the first fluid filling portion 12 and the second fluid filling portion 13, and a flow hole portion 18 through which fluid can pass is formed. The stopper unit 16 is a device unit that limits the upward movement of the upward piston 50, that is, forms a locking jaw capable of restraining the upward movement, and the second fluid filling unit 13 on the partition wall main unit 15 It is formed to protrude into the inside of. The piston seating portion 17 is a device portion in which the upward piston 50 is seated, and is formed on the partition wall body portion 15.

The flow hole 18 is a device that forms a flow path of the working fluid, and is formed to penetrate through the partition 14. The working fluid inside the cylinder portion 11 is transferred to the first fluid filling portion 12 or the second fluid filling portion 13 through the flow hole portion 18 according to the strength of the downward force acting on the downward piston 20. It can flow freely.

3 and 4, the bush gripper 30 according to an embodiment of the present invention includes a first gripper 31, a second gripper 32, and a gripper binding member 33.

The first gripper 31 is press-contacted to one side of the outer circumference of the bush assembly 2. One end of the first gripper 31 is in contact with the circumference of the bush part 2a by inserting and passing through the inside of the bush coupling part 2c. The other end of the first gripper 31 is seated on the downward piston 20 outside of the bush coupling portion 2c. Referring to FIG. 4, a first gripper 31 according to an embodiment of the present invention includes a first bush contact part 311, a first seating and holding part 312, and a first fixing hole 314.

The first bush contact 311 has a shape of a semicircular groove corresponding to the outer surface of the bush assembly 2 and contacts one side of the bush 2a. The first bush contact part 311 is inserted into the bush coupling part 2c and contacts one side of the bush part 2a.

The first seating and holding portion 312 is connected to the first bush contact portion 311 and is seated on the downward piston 20 from the outside of the bush coupling portion 2c. The upper portion of the first seating holding part 312 is in contact with the pressing member 40 and held between the downward piston 20 and the pressing member 40 by the pressing force of the pressing member 40. The first fixing hole 314 is formed to pass through the first seating and holding part 312 in the transverse direction.

The second gripper 32 is disposed to face the first gripper 31 with the bush assembly 2 interposed therebetween, and a part of the second gripper 32 is disposed to overlap the first gripper 31. The second gripper 32 is disposed to face the first gripper 31 with the bush part 2a interposed therebetween, and contacts the first gripper 31 through the bush clearance part 2d. 4, the second gripper 32 according to an embodiment of the present invention includes a second bush contact part 321, a second seating and holding part 322, an overlapping arm part 323, and a second fixing hole part 324. ).

The second bush contact part 321 has a shape of a semicircular groove corresponding to the outer surface of the bush assembly 2 and contacts the other side of the bush part 2a. The second seating and holding portion 322 is connected to the second bush contact portion 321 and is seated on the downward piston 20. The upper portion of the second seating holding part 322 is in contact with the pressing member 40 and held between the downward piston 20 and the pressing member 40 by the pressing force of the pressing member 40.

The overlapping arm portion 323 extends from the second bush contact portion 321 toward the second gripper 32 and is disposed to overlap the second gripper 32 in the transverse direction. A pair of overlapping arm portions 323 extend side by side. The second fixing hole portion 324 is formed to penetrate in the transverse direction at a position corresponding to the first fixing hole portion 314 among the overlapping arm portions 323.

The gripper binding member 33 is a device that binds the first gripper 31, the second gripper 32, and the bush assembly 2 to each other, and has a pin shape and a first gripper 31 and a second gripper 32 Pass through the overlapping portion of the transverse direction. The gripper binding member 33 constrains the flow of the first gripper 31 and the second gripper 32 by continuously penetrating the first fixing hole portion 314 and the pair of second fixing hole portions 324, The bush assembly (2) is bound between the first gripper (31) and the second gripper (32).

3 and 4, the upward piston 50 according to an embodiment of the present invention includes a pressing piston part 51 and a bush pressing part 52.

The pressure piston portion 51 is seated on the partition wall portion 14 of the cylinder body 10, more specifically, the piston seat portion 17. The pressure piston part 51 has a structure in which a lower end located inside the second fluid filling part 13 and an upper end extending outside of the second fluid filling part 13 protrude in a radial direction, and the second It is raised and lowered along the fluid filling part 13.

The pressing piston part 51 is maintained in a state in which a downward force is not applied to the pressing member 40, that is, in a state in which its upper end is seated on the piston seating part 17 in a standby state. When a downward force is applied to the pressing member 40, the pressing piston part 51 may be moved upward until its lower end is caught by the stopper part 16.

The bush pressing portion 52 is a device portion in contact with the bush body portion 2b, and has a shape capable of passing through the inside of the bush portion 2a in the axial direction, and is seated on the pressing piston portion 51. The bush pressing portion 52 has a cylindrical shape having a diameter smaller than the inner diameter portion of the bush portion 2a, and may be installed upright on the upper portion of the pressing piston portion 51. The bush pressing unit 52 is disposed between the pressing piston unit 51 and the bush assembly 2 and is moved with the same displacement as the pressing piston unit 51, and directly exerts an upward force on the bush assembly 2 Let it.

6, when a downward force is applied to the pressing member 40, the downward force acting on the pressing member 40 passes through the bush gripper 30, and acts on the downward piston 20 below the bush gripper 30. As the downward piston 20 descends, the working fluid inside the first fluid filling part 12 flows toward the second fluid filling part 13, and the upward piston 50 located in the second fluid filling part 13 ) To move upward. As the upward piston 50 rises, the bush body portion 2b of the bush assembly 2 positioned above it is pressed upward.

The bush durability test apparatus 1 according to the present invention is for testing the coupling force between the bush part 2a and the bush body part 2b, and the above and the above are performed while holding the bush part 2a by the bush gripper 30. Likewise, by intensively applying a pressing force in the axial direction to the bush body part 2b, the bush body part 2b is separated from the bush part 2a, and the bush body part 2b is separated from the bush part 2a. At this point, a value corresponding to the load applied to the pressing member 40 of the bush assembly 2 can be determined as the durability of the bush assembly 2.

According to the bush durability test apparatus 1 according to the present invention having the configuration as described above, the bush assembly 2 is held by the bush gripper 30 and mounted on the downward piston 20 to the pressing member 40. By going through a simple test step of applying a downward force, it is possible to test the durability of the bush assembly 2 while stably applying an upward pressing force to the bush assembly 2.

Accordingly, the present invention puts a pipe-shaped pedestal under the cylindrical bush portion 2a of the conventional bush assembly 2, and partially downwards only the bush body portion 2b coupled to the inside of the bush portion 2a. Compared with the conventional method in which the bush body part 2b is pushed away from the pipe-shaped pedestal side by applying a force, a flange part formed to protrude from the outer surface part of the bush part 2a or the frame part 4 coupled with the bush part 2a There is no need to go through a cumbersome pre-process of separating and detaching) from the bush, so the durability test of the bush can be made more easily and efficiently.

In addition, according to the present invention, the downward force of the pressing member 40 acts as a fixing force to fix the bush gripper 30 and the bush part 2a in the correct position above the downward piston 20, and the cylinder body 10 ), the direction is turned upward and transmitted to the upward piston 50, so that the upward slip of the bush part 2a is prevented from occurring due to the upward force acting on the bush body part 2b. . Accordingly, generation of noise in the test result due to slip of the bush portion 2a can be prevented, and reliability of the test result can be secured.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only illustrative, and those of ordinary skill in the field to which the technology pertains, various modifications and other equivalent embodiments are possible. I will understand. Therefore, the true technical protection scope of the present invention should be determined by the following claims.

1: bush durability test device 2: bush assembly
2a: bush part 2b: bush body part
2c: bush coupling part 2d: bush clearance part
3: subframe 4: frame part
10: cylinder body 11: cylinder part
12: first fluid filling unit 13: second fluid filling unit
14: bulkhead part 15: bulkhead body part
16: stopper part 17: piston seating part
18: flow hole 20: downward piston
30: bush gripper 31: first gripper
32: second gripper 33: gripper binding member
40: pressure member 50: upward piston
51: pressing piston part 52: bush pressing part
311: first bush contact portion 312: first seating holding portion
314: first fixing hole 321: second bush contact
322: second seating holding portion 323: overlapping arm portion
324: second fixed hole

Claims (7)

A cylinder body formed to communicate with the first fluid filling portion and the second fluid filling portion;
A downward piston mounted to the cylinder body so as to be elevated along the first fluid filling part;
A bush gripper that holds a bush assembly and is seated on the downward piston;
A pressing member for pressing the bush gripper downward to restrain the flow of the bush assembly and moving the downward piston downward; And
And an upward piston installed in the cylinder body so as to be elevating along the second fluid filling part, when the downward piston is lowered by the flow of the working fluid inside the cylinder body, and pressurizing the bush assembly upwardly Bush durability test device characterized by.
The method of claim 1,
The cylinder body,
A cylinder portion having the first fluid filling portion and the second fluid filling portion formed therein;
A partition wall portion formed inside the cylinder portion and partitioning the first fluid filling portion and the second fluid filling portion; And
And a flow hole portion formed to penetrate through the partition wall portion and forming a flow path of the working fluid.
The method of claim 1,
The bush assembly,
A bush part held by the bush gripper;
A bush body part coupled to the inside of the bush part and pressed upward by the upward piston;
A bush coupling portion having a cross-sectional shape of a closed loop structure, a width greater than that of the bush portion, and coupled to an outer surface portion of the bush portion; And
Includes; a bush gap formed between the bush portion and the bush coupling portion in a direction perpendicular to the axial direction of the bush portion,
The bush gripper,
A first gripper whose one end portion is inserted into the bush coupling portion and is in contact with the bush portion, and the other end is seated on the downward piston from the outside of the bush coupling portion; And
And a second gripper disposed to face the first gripper with the bush part therebetween, and in contact with the first gripper through the bush clearance part.
The method of claim 1,
The bush gripper,
A first gripper press-contacted to one side of the bush assembly;
A second gripper disposed to face the first gripper with the bush assembly interposed therebetween, and partly disposed to overlap the first gripper; And
And a gripper fastening member penetrating the overlapping portion of the first gripper and the second gripper.
The method of claim 4,
The first gripper,
A first bush contact part in contact with one side of the bush assembly;
A first seating and holding portion connected to the first bush contact portion, seated on the downward piston, and held between the downward piston and the pressing member by a pressing force of the pressing member; And
And a first fixing hole formed to pass through the first seating and holding part and through which the gripper fastening member passes.
The method according to claim 4 or 5,
The second gripper,
A second bush contact part in contact with the other side of the bush assembly;
A second seating and holding portion connected to the second bushing contact portion, seated on the downward piston, and held between the downward piston and the pressing member by a pressing force of the pressing member;
An overlapping arm part extending from the second bushing contact part toward the second gripper and disposed to overlap the second gripper; And
And a second fixing hole formed on the overlapping arm to pass through and through which the gripper fastening member passes.
The method of claim 1,
The upward piston,
A pressurizing piston mounted on the partition wall portion of the cylinder body and elevating along the second fluid filling portion; And
And a bush pressing unit having a shape capable of passing through the inside of the bush assembly in an axial direction, seated on the pressing piston, moving in the same displacement as the pressing piston, and pressing the bush assembly upwardly. Bush durability test device.

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