KR100970205B1 - A Load-testing Apparatus for Connecting-Pin - Google Patents

Abstract

The present invention relates to a load test device for connecting pins that can check the damage of the connection pin supporting the load of the various industrial equipment or apparatus, for this purpose, the support means for supporting both ends of the frame and the connection pin is fixed to the frame And, it is made to include a hydraulic force to apply a repetitive load by pulling the connection pin, characterized in that the load load assembly for applying a repetitive load to the connection pin is connected to the end of the hydraulic force.

Hydraulic presser, test, fatigue load, frame, connecting pin

Description

Connecting pin load tester {A Load-testing Apparatus for Connecting-Pin}

The present invention relates to a load test device for connecting pins that can check whether a connection pin supporting loads of various industrial equipment or equipment is broken. It is adopted through two blocks and hydraulic presses, and the rollers utilizing high-strength materials are applied to the blocks to minimize wear of the different load load points and reaction force points applied to the two blocks in close contact with the connecting pins. In addition, it relates to a connection pin load test apparatus of a structure that can prevent the sealing damage problem of the hydraulic pressure force generated by the alignment is twisted by installing the hydraulic pressure force perpendicular to the connecting pin.

In general, a variety of industrial equipment or devices or tracked vehicles are equipped with a lot of connecting pins for supporting the load.

These connection pins are very important to support the load of a device, a facility or a vehicle, and when broken, it is impossible to operate a device of a device, a facility, or a vehicle.

Because of this, the connecting pin is made of high strength steel because it bears the load.

However, there is no device capable of testing and predicting the life and strength of the connection pins produced as one of these important parts.

The present invention has been devised in view of the above problems, and an object of the present invention is to adopt a four-point bending test setup method that approximates the cause of a connection pin break through four blocks and a hydraulic press, and also closely adhere to the connection pin. In order to minimize the wear of the different load load points and reaction force points applied to each of the two blocks, all rollers utilizing high-strength materials are applied to the blocks, and the hydraulic force is installed vertically downward with respect to the connecting pins. The present invention provides a connecting pin load test apparatus having a structure that can prevent the sealing damage problem of the hydraulic pressure generator caused by the twist.

Furthermore, an object of the present invention comprises a frame, a support means fixed to the frame to support both ends of the connecting pin, and the hydraulic force to apply a repeated load by pulling the connecting pin, the end of the hydraulic pressure To provide a connection pin load test device, characterized in that the load load assembly for applying a cyclic load to the connection pin is connected.

According to the connecting pin load test apparatus according to the present invention, the four-point bending test setup method is adopted through four V blocks and hydraulic presses, and also different load loads applied to each of the two V blocks in close contact with the connecting pins. In order to minimize the wear of the point and the reaction force support point, the rollers utilizing the cemented carbide material are applied to the V-blocks so that the environment that is close to the actual cause of the connection pin breakage of the connection pin can be constructed.

In addition, by installing the hydraulic presser vertically downward with respect to the connecting pin has a feature that can prevent the sealing damage problem of the hydraulic presser caused by the alignment is twisted.

In addition, there is an advantage in that the strength of the connection pins can be measured by testing the connection pins.

Prior to explaining the present invention, the connecting pin load test apparatus of the present invention may be installed by fixing the hydraulic force on the ceiling while spaced apart from the ground, and may also be installed by fixing the hydraulic force in the horizontal direction on the ground, and also on the ground Of course, the hydraulic press can be installed vertically.

In the embodiment of the present invention will be described an example in which the hydraulic pressure vertically installed on the ground.

Hereinafter, the connection pin load test apparatus according to the present invention will be described in detail together with the accompanying drawings.

1 is a perspective view of a connecting pin load test apparatus according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the main part of FIG.

As shown in Figures 1 and 2, the embodiment of the present invention relates to a connection pin load test apparatus 100 that can determine whether the connection pin supporting the load of various industrial equipment or equipment.

The connecting pin load test apparatus 100 adopts a four-point bending test setup method that approximates the actual connection pin failure cause through four blocks and a hydraulic press, and is in close contact with the connecting pins and applied to each two blocks. In order to minimize wear of other load points and reaction points, the rollers utilizing high-strength materials are applied to the block, and the hydraulic force generated as the alignment is twisted by installing the hydraulic force vertically downward with respect to the connecting pin. The structure can prevent the sealing damage problem.

In this case, the block may be configured in various forms such as a V block or a U block to partially accommodate the connection pin, and hereinafter, referred to as a V block.

The connection pin load test apparatus 100 is largely composed of two parts, which is a support means 40 for supporting the connection pin 200 and the hydraulic pressor 20 to repeatedly apply the load to the connection pin 200. ) Is composed of a load load assembly 30 connected thereto.

Wherein the support means 40 is installed spaced apart from the ground, such a structure is possible in the frame. The frame consists of a support frame 11, a support frame 12, and a horizontal frame 13.

The support frame 11 is in close contact with the ground, and a pair of strut frames 12 are vertically upright fixed to the upper surface of the support frame 11 at intervals from each other.

The horizontal frame 13 is coupled to the upper end of the support frame 12, and the support means 40 supporting both ends of the connection pin 200 is coupled to the upper surface of the horizontal frame 13.

In addition, the hydraulic presser 20 is fixed to the upper surface of the support frame 11 and is disposed between the holding frame 12 is configured to apply a repetitive load to the connecting pin 200 in a vertical downward direction.

The hydraulic pressor 20 is configured to apply a repetitive load to the connecting pin 200 through the load load assembly 30 is installed at the end.

Here, if the hydraulic presser 20 is installed on top of the connecting pin 200 and configured to apply a repeated load to the connecting pin 200 in the vertical downward, the cylinder 21 constituting the hydraulic presser 20 It is not preferable because of the problem that the seal in the hydraulic pressurizer 20 is broken as the alignment is twisted between the piston rod 22 and the piston rod 22.

Meanwhile, the load load assembly 30 is installed to penetrate through the horizontal frame 13, and the center portion of the horizontal frame 13 guides the load load assembly 30 which is lifted and lifted by the hydraulic presser 20. The opening 131 is formed.

Here, the load load assembly 30 is composed of a load load block 31 which is spaced apart from each other through the four connecting rods 32, and a guide block 33 which is lifted and guided in the opening 131.

In this case, two first V blocks 311 for applying a two-point (②③) load to the connection pin 200 are coupled to the bottom surface of the load load block 31.

Meanwhile, the support means 40 installed on the upper surface of the horizontal frame 13 to support both ends of the connecting pin 200 includes two fixed blocks 41 coupled to the upper surface of the horizontal frame 13 and the Two second V blocks 43 coupled to an upper surface of each fixed block 41 and supporting two points (①④) of both ends of the connecting pin 200, and an upper surface of each fixed block 41; Is coupled to the support block 42 for inserting the end of the connecting pin 200 is configured.

Looking at the configuration as described above, the connection pin 200 may implement four load points received on the actual connection pin 200 through the first V block 311, the second V block 43.

In addition, the support means 40 is further coupled to the anti-rotation block 44 corresponding to the shape of the groove 210 formed on both sides of the connecting pin 200, the connecting pin 200 to the vibration caused by the repeated load It is a structure that can prevent the rotation.

In this structure, since the cross section of the pin 200 is generally circular, it rotates between the first and second V blocks 311 and 43 during the fatigue load, and there is a problem that the load point and the support point change frequently. In order to improve this, the grooves 210 are processed at both ends of the pin 200, and the grooves are installed in contact with the rotation preventing block of the support means 40. This prevents the rotation of the pin 200 during the fatigue test, it is a structure that can be implemented a test that the maximum stress can be applied to the desired portion.

In addition, the connection pin 200 has a high-strength material, and the first V block 311 and the second V block 43 in close contact with the connection pin 200 may cause wear. Can be. Therefore, the high strength roller 50, which is similar to or stronger than the connecting pin, is further coupled to the inclined surfaces of the first V block 311 and the second V block 43 to prevent wear due to repeated fatigue loads.

Meanwhile, a load cell 231 is mounted on the hydraulic pressurizer 20 so that the load applied to the connecting pin 200 can be adjusted.

Hereinafter, the operation of the connecting pin load test apparatus according to the present invention will be briefly described together with the accompanying drawings.

Figure 3 is an operation of the connecting pin load tester according to 1.

As shown in FIG. 3, first, the yield point of the connection pin 200 is measured through the load cell 231 to operate the hydraulic pressurizer 20.

Then, the piston rod 22 is moved into the cylinder 21, and two first V blocks 311 coupled to the load load assembly 30 are instantaneously at two points (②③) of the connecting pin 200. Load is applied (first V block shown in FIG. 2).

 Then, the connecting pin 200 is bent at a moment by forming two point (①④) reaction support points by the two second V blocks 43, and at the same time, the connecting pin 200 returns horizontally due to the elastic return force of the connecting pin 200.

By applying such a repeated load tens of thousands to millions of times it is possible to measure the fatigue strength of the connection pin (200).

Through the test apparatus as described above, it is possible to measure the strength according to the material of the connecting pin, and also to know the damage part due to the repeated load.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, various other modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

1 is a perspective view of a connection pin load test apparatus according to an embodiment of the present invention,

Figure 2 is an exploded perspective view of the main part of Figure 1,

3 is an operation of the connecting pin load test apparatus according to FIG.

<Description of the symbols for the main parts of the drawings>

11: support frame 12: holding frame

13: horizontal frame 131: opening

20: hydraulic press 21: cylinder

22: piston rod 231: load cell

30: Load Load Assembly 31: Load Load Block

311: first V block 32: connecting rod

33: guide block

40: support means 41: fixed block

42: support block 43: second V block

44: anti-rotation block

50: cemented carbide roller

100: load test device for connecting pin

200: connecting pin 210: groove

Claims (5)

It comprises a frame, the support means 40 is fixed to the frame for supporting both ends of the connecting pin 200, and the hydraulic pressure force 20 to apply the repetitive load by pulling the connecting pin 200, At the end of the hydraulic presser 20, a load load assembly 30 for applying a repeating load to the connection pin 200 is connected. The load load assembly 30 is composed of a load load block 31 and a guide block 33 spaced apart from each other through the four connecting rods 32, the connection pin 200 on the bottom of the load load block 31 Connecting pin load test apparatus, characterized in that the two first block (311) for applying a two-point load to). delete The method of claim 1, The support means 40 is coupled to two fixed blocks 41 and upper surfaces of the respective fixed blocks 41 and two second blocks 43 for supporting two points at both ends of the connecting pin 200. And a support block (42) coupled to the upper surface of each of the fixed blocks (41) for inserting an end of the connection pin (200). The method of claim 3, wherein The support means 40 is a connection pin load test device, characterized in that the anti-rotation block 44 is further coupled to the shape corresponding to the groove portion 210 formed on both sides of the connection pin 200. The method of claim 3, wherein The inclined surface of the first block 311 and the second block 43 in close contact with the connecting pin 200, the high-strength roller 50 is further coupled to prevent wear due to repeated fatigue load Pin load tester.

Images