KR100714828B1 - A pressure fatigue tester - Google Patents

Abstract

The present invention relates to a compressive fatigue tester for measuring the compressive fatigue life of a specimen by repeatedly generating a compressive load for a predetermined time using a mechanical element such as a connecting rod or a crankshaft of a vehicle, and more particularly to a cam at a force point. The lever is provided to move up and down to generate a displacement in the press at the working point to exert the compressive load on the specimen, and the compressive load of the press at the working point can be easily changed by changing the position of the lever support point. It has a structure in which the support point of the lever is moved, and the compression fatigue tester having a support point moving structure that can change the compressive force by the cam method that can easily adjust the size of the compression load to be tested according to the material of the specimen.

According to the invention, the force generating portion including a cam rotated by the drive device; A fixing part provided with a fixing jig for fixing the specimen; In the compression fatigue tester configured to include a force acting portion having a pressing piece for applying a force generated by the cam to the specimen, a lever is installed between the pressing piece and the cam is moved, the both ends of the lever Are respectively connected to the pressing piece and the cam, and are provided with a compression fatigue tester to easily change the pressing force applied to the specimen by the movement of the supporting point.

 Compression Fatigue Tester, Crowbar, Lever, Support Point, Cam

Description

Compression fatigue tester having a supporting point moving structure that can change the compressive force by cam method {A pressure fatigue tester}

1 is a perspective view of the present invention

2 is a longitudinal cross-sectional view of the present invention;

Figure 3 is a state diagram of the movable support of the present invention

4 is a state in which the compression load acts

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

1: motor 2: cam

3: force generating portion 4: specimen

5: fixing jig 6: fixing part

7: pressure piece 8: force acting portion

9: lever 10: pressurizer

11: spring 12: pin

13: support point pin 14: lever support

15: guide rail 16: movable support

17: bearing 18: screw

100: tester

The present invention relates to a compressive fatigue tester for measuring the compressive fatigue life of a specimen by repeatedly generating a compressive load for a predetermined time using a mechanical element such as a connecting rod or a crankshaft of a vehicle, and more particularly to a cam at a force point. The lever is provided to move up and down to generate a displacement in the press at the working point to exert the compressive load on the specimen, and the compressive load of the press at the working point can be easily changed by changing the position of the lever support point. It has a structure in which the support point of the lever is moved, and the compression fatigue tester having a support point moving structure that can change the compressive force by the cam method that can easily adjust the size of the compression load to be tested according to the material of the specimen.

Conventional compression fatigue tester using the eccentric rotation of the cam has a configuration of a cam eccentrically rotated by the drive motor, a fixing jig for fixing the specimen, and a pressure port connected to the cam to exert a compression load on the specimen. Therefore, the cam actuates the pressure port to pressurize the specimen, so that the compression load is applied to the specimen.

In the fatigue test by compressive load, the mechanical properties are different according to the material of the specimen. Therefore, when the compressive load of appropriate size is applied according to the material of the specimen, the test can be carried out in a stable state because no excessive load is applied.

However, in the conventional structure as described above, while the pressure port is displaced in the vertical direction by the cam which rotates eccentrically, the compression load is generated, and the displacement in the vertical direction is constant by being directly connected to the cam having a predetermined shape. The magnitude of the compressive load generated was constant. This means that the selected compressive load could not be applied according to the material of the specimen.

Therefore, conventionally, the compression load imposed on the specimen could not be simply changed, and there was a problem in that the cam had to be replaced to change the compression load according to the specimen.

An object of the present invention is to solve the problems described above, so as to easily adjust the size of the compressive load to be tested according to the material of the specimen, by moving up and down by the cam at the force point causing the pressor displacement on the specimen at the working point Provided is a compression fatigue tester having a lever for exerting a compressive load, and having a support point moving structure capable of changing the compressive force by a cam method, in which the compressive load at the acting point can be easily changed by changing the lever support point.

Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

The present invention provides a force generating part 3 including a cam 2 rotated by a driving device such as a motor 1, a fixing part 6 having a fixing jig 5 for fixing the specimen 4, and a cam. In the compression fatigue tester 100 configured to include a force acting portion 8 having a press piece 7 so that the up and down motion generated by (2) exerts a compressive load on the specimen 4, the specimen 4 It is a structure that can easily change the compressive force applied to.

Therefore, the present invention is characterized in that it is configured to change the vertical displacement by using the principle of the lever to move the support point of the lever. That is, a lever 9 is provided between the pressing piece 7 and the cam 2 to move the supporting point, and both ends of the lever 9 are connected to the pressing piece 7 and the cam 2, respectively. , It is characterized by easily changing the pressing force acting on the specimen (4) by the movement of the supporting point.

Between the lower portion of the pressing piece 7 and one end of the lever 9, there is attached a pressurizer 10 in which the pressing force is changed according to the displacement amount, which pressurizer 10 is a spring 11 or an air-filled cylinder. Formed. The connection of the lower end of the pressurizer 10 and the lever 9 is rotated by the pin 12, so that it has a structure that can be moved vertically during the rotational movement around the support point of the lever (9).

The lever 9 is slidably penetrated by the lever support 14 provided with the support point pin 13 so that the support point is moved, and the support point pin 13 is moved along the guide rail 15. It has a structure rotatably installed on the movable support 16.

Therefore, the present invention can easily adjust the size of the compressive load to be tested according to the material of the specimen (4), the force generated by the cam (2) in the force generating portion (3) acting as a force point, the working point Compression load is applied to the specimen 4 in the force acting portion 8, which serves as a position of the supporting point pin 13, which acts as a supporting point of the lever 9. It can be easily changed by the, can be adjusted appropriately according to the specimen (4) to perform the compression fatigue test can be performed stably while preventing the excessive load imposed more than necessary.

The specimen 4 is fixed to the fixing jig 5 of the specimen fixing part 6 as shown in FIG. The fixing jig 5 is set to a position of an appropriate height in order to set the minimum value of the pressing force to be applied according to the size or material of the specimen (4). The height setting is fixed by adjusting the position by a mechanical manual operation such as a handle or a drive by a motor when the cam 2 is located at the top dead center.

A pressing force should be applied to the fixed specimen 4, and the pressing member 7 is pressed against the specimen 4, and a pressurizer 10 having a pressing force changed in accordance with the displacement amount is provided at the lower portion of the pressing piece 7. Is installed. The pressurizer 10 is fastened with a pin 12 at one end of the lever 9.

Therefore, the lever 9 performs the same movement as the lever around the supporting pin 13, the displacement of one end of the lever 9 causes the displacement of the pressurizer 10, and the displacement of the pressurizer 10 is the force. The test load is applied to the specimen (4).

Therefore, the compression fatigue tester 100 is composed of a compression spring 11 or a cylinder filled with air, and the displacement amount adjustment of the compression fatigue tester 100 is made by adjusting the position of the support point pin 13 which is a feature of the present invention. Lose.

First, the operation of the force generating unit 3 for generating a force by operating the lever 9 will be described. As shown in FIGS. 1, 2 and 4, the cam 2 is operated by the operation of the motor 1. 4, the lever 9 is operated by the cam 2 around the support pin 13, and the pin 12, which is the other end of the lever 9, is pressed by the pressurizer 10. ), The pressing piece 7 installed on the upper side of the pressurizer 10 presses the specimen 4.

The seesaw operation of the lever 9 is performed by inserting the lever 9 into the lever support 14 as shown in FIGS. 1 and 4, and the lever support 14 is moved by the support pins 13. ) Is built into. Of course, the support point pin 13 is supported by the bearing 17 to the movable support 16 is smoothly rotated. In addition, the lever support 14 has a structure in which the lever 9 is used as a guide to move in a sliding manner, and a bearing such as a metal bearing is provided on the friction surface of the lever support 14 and the lever 9 to facilitate sliding. It may be installed.

This means that when the lever 9 is rotated about the support point pin 13, the pin 12, which is the other end of the lever 9, is to be circularly moved about the support point pin 13. However, in the present invention, since the movement of the pin 12 is restricted only up and down, the lever 9 slides in the lever support 14 functioning as the support point pin 13 so that the pin 12 does not have a problem of vertical movement. Function.

As shown in FIG. 4, the larger the upward displacement of the lever 9, the greater the force exerted by the pressurizer 10 on the pressing piece 7 and the specimen 4, in the present invention, the upward displacement of the lever 9. To the position of the support point pin (13) to change the test load acting on the specimen (4).

That is, the test load is changed by moving the supporting point of the lever 9 by using the principle of the lever, which is achieved by moving the supporting point pin 13 serving as the supporting point of the lever. The support point pin 13 is installed on the lever support 14 which is slidably moved along the lever 9, and the lever support 14 is pivotally fastened to the movable support 16 which is moved along the guide rail 15. have.

Accordingly, as shown in FIGS. 1 and 3, the movable support 16 is moved by various moving means made of a combination of a handle, a worm, and a worm gear. The moving means illustrated in the figure is an embodiment of rotating the screw 18 by screw 18, and screwing the screw 18 and the moving support 16 to move the moving support 16.

In this way, the support point can be moved, so that the force applied to the specimen 4 can be changed. That is, as shown in FIG. 3, when the moving support 16 is moved to the right by rotating the screw 18, the lever support 14 installed in the moving support 16 simultaneously moves to the right along the lever 9. As a result, the support point pin 13 is moved to the right.

When the support point pin 13 is moved to the right as described above, the length of the lever 9 on the left side becomes longer as the center of the support point pin 13 as shown in FIG. 4, and eventually the lever 9 on the pressurizer 10 side. The amount of vertical displacement at the end becomes large. Therefore, such an increase in the displacement amount increases the elastic force of the pressurizer 10, which is represented as an increase in the test load action force of the test piece (4).

That is, in the case of the pressurizer 10 composed of the spring 11, the vertical displacement amount of the lever 9 becomes the displacement amount of the spring 11, and the increase of the displacement amount of the spring 11 acts to increase the elastic force of the spring. This is the compression test load acting on the specimen (4).

On the contrary, in order to apply a small pressing force to the test piece 4, the lever support 14 may be moved to the test piece 4 side.

The present invention thus achieved provides a configuration in which the lever 9, which operates on the principle of the lever, is linked to the cam 2 so that the magnitude of the variable compressive load acting on the specimen 4 can be easily adjusted. The fatigue test is stably performed because the load applied to 4) is prevented from applying excessive loads.

Claims (4)

A force generating portion 3 including a cam 2 rotated by a drive device; A fixing part 6 having a fixing jig 5 for fixing the test piece 4; In the compression fatigue tester 100 comprising a; the pressing piece 7, comprising a force acting portion 8 having a pressing piece 7 for applying the force generated by the cam 2 to the test piece 4. A lever 9 is provided between the cam 2 and the support point to move the support points, and both ends of the lever 9 are connected to the pressing piece 7 and the cam 2, respectively. 4) Compression fatigue tester having a support point moving structure that can change the compressive force by the cam method, characterized by easily changing the pressing force applied to 4). The support point movement structure according to claim 1, wherein a compression force can be changed by a cam method with a pressurizer 10 whose pressing force is changed according to the displacement amount between the lower portion of the pressing piece 7 and one end of the lever 9. Compression Fatigue Tester. 2. The lever (9) according to claim 1, wherein the lever (9) is slidably installed on the lever support (14) on which the supporting point pin (13) is installed, so that the rotational movement of the lever (9) is smooth even when the pin (12) is constrained by the vertical movement. And, the lever support 14 is a compression fatigue tester having a support point moving structure that can change the compressive force by the cam method installed to be rotated by the fastening of the support point pin (13) to the moving support 16 to be moved. The compression fatigue tester according to claim 2, wherein the pressurizer (10) has a support point moving structure capable of changing the compressive force by a cam method composed of a spring (11) or an air-filled cylinder.

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