KR20020004067A - Fatigue and twist tester for wires - Google Patents

Abstract

PURPOSE: A composite fatigue tester of a wire is provided to obtain composite stress like actual conditions of a wire, for testing and analyzing the actual using characteristics of the wire by testing the characteristics of a side of the wire. CONSTITUTION: A tester(1) consists of a frame(11), a fixing unit(12) transferring torsional stress generated by a motor to a wire with fixing the wire, a curve test rod(13) rotating to left/right by the moor, and a support unit(14) used as a point of action of a load applied by a weight(16) connected to a side of the wire. When a wire to be tested is selected, the wire is cut into proper length. An end of the wire is completely put into the bore of a casing of the fixing unit, and a fitting piece is inserted into the casing through the lower part of the casing. The fixed wire is inserted through the bore of the support unit via a curve roller, and a weight corresponding to a load necessary for test is connected to the other end of the wire. Thereby, the wire is tested. The tester tests the moving characteristics of a wire under composite stress conditions like actual using conditions by applying horizontal stress and vertical stress to the wire as well as tests curve fatigue and torsional stress. Thereby, the tester checks all of characteristics of the wire through single test.

Description

Fatigue and twist tester for wires}

The present invention relates to an apparatus for inspecting a composite durability of a wire, and more particularly, to a composite fatigue performance including twist resistance of a wire by simultaneously applying repeated bending stress and torsional stress and tensile stress to a wire specimen to be inspected. It relates to a composite fatigue tester of the wire for inspecting.

In general, the inspection of the physical properties of the wire is a tensile test, fatigue test, torsion test, etc., each test is performed individually by using a dedicated tester for the test. In particular, the twisted wire is more important to fatigue resistance and torsion resistance than to tensile load, but the fatigue resistance against bending motion is tested because each of these characteristics is performed separately. It is difficult to grasp the complex characteristics of the torsional and torsional characteristics.

In other words, each physical property of the wire can refer to each test value, and it is difficult to grasp the comprehensive property. Each of the above tests is currently performed by dividing the complex external stresses acting on the wires into different types of simplified stresses and applying the same type of stress to the wire specimens as divided and simplified stresses. Since each test is intended to identify only one property of the wire, it is only possible to understand the properties of the fragmented wire.

Therefore, with the conventional tester, it is not possible to comprehensively grasp the characteristics of the wire with respect to the actual use conditions of the wire in which the tensile force, the bending stress, the torsion, etc. are combined.

As described above, the conventional tester can examine only the characteristics of one side of the wire, and simultaneously apply complex stresses such as the actual conditions of the wire to examine and compare the actual use characteristics of the wire. It is an object of the present invention to provide a composite tester that can.

1 is a perspective view of the tester of the present invention.

Figure 2 shows the assembly state of the components of the tester of the present invention,

(A) is a plan view of the testing machine,

(B) is an assembled sectional view of the support tool,

(C) is an assembly cross section of the fixture.

3 is a control block diagram of the tester of the present invention.

((Explanation of symbols for main parts of drawing))

11.Frame 12. Fixture

12C. Insert 13.Bending Test Rod

13A. Inertia weight 13B. Bend roller

14. Support

The above object of the present invention is achieved by being provided with a forward / reverse rotation motor and a fixture for a torsion test, and a forward / reverse rotation motor and a bending roller for a bending test.

The wire fixture provided at one end of the composite fatigue tester of the present invention is a wire fixture using the shape of a wedge, and is a structure in which the wire is fixed by itself by a tensile force applied to the wire without a separate fixing means such as a bolt. A motor capable of reverse rotation is connected to impart repetitive torsional stress on the wire under test.

The bending roller attached to the bending test rod mounted on the central part of the testing machine of the present invention is composed of one or three rollers, and one or three of the central rollers are positioned so that the degree of bending applied to the wire can be adjusted. It is possible to change.

And, the other end side of the bending test rod is not attached to the bend roller is an arc-shaped tooth is attached, and the toothed to the center of the fixing pin by the disk-shaped cog wheel to be rotated forward / reverse by the forward / reverse rotation motor The flexural test rod is a structure that allows the rotational movement within a right and left predetermined angle range of the test rod longitudinal axis perpendicular to the longitudinal axis of the frame.

In addition, the other end of the tester of the present invention is provided with a wire support hole formed with a wire passing hole so that the test object wire which is fixed to the fixture passes through the bending roller, and then imparts appropriate tension to the wire. The left and right positions of the support can be changed to adjust the weight of the test conditions applied to the wire by adjusting the distance between the flexural test rod and the support.

Details of the object and the technical constitution according to the present invention configured as described above, including the effect and effects thereof will be clearly understood by the following description with reference to the drawings showing a preferred embodiment of the present invention.

1 is a perspective view of the wire composite fatigue tester of the present invention excluding the control unit and the attached motor,

As shown, the tester 1 of the present invention includes a frame 11, a fixture 12 which is a medium for fixing the wire and at the same time transferring the torsional stress applied by the forward / reverse rotation motor to the wire, To the weight test rod 16 connected to one end of the wire while converting the movement of the wire due to the pendulum movement of the bending test rod into a vertical linear movement by the reverse rotation motor. It consists of a support 14 that acts as a point of action for the tensile load imparted by it.

The frame has a 'c' shape opened in an upward direction, and a wire passing groove (11B of FIG. 2) through which a test object wire passes near one end of the bottom surface 11A, and one side of which the fixture is supported at the other end is opened. Passing grooves (11C in Fig. 2) are formed in the frame length direction, respectively.

As can be seen in FIG. 2, in which the fixture 12 and the support 14 are assembled, the support groove 14 side passage groove 11B has a frame end side blocked, and the fixture 12 side passage groove. 11C is a state where the frame end side is open.

That is, unlike the support 14, which is placed on the bottom of the frame and can be separated by sliding between the support fixture 11E and the bottom of the frame, in order to separate the fastener 12 from the frame, to prevent the fastener from being lifted during the test. In order to remove the fixture 12 by sliding the fixture 12 from the frame 11 because the fixture fixing piece 11D is attached to the upper end of the frame and the fixture 12 penetrates the frame bottom 11A. The frame end side of the groove 11C is to be opened.

The fixture 12 is composed of a casing 12B having a cylindrical shape in which the inner diameter is constantly increased in one direction of the axis, and an insertion piece 12C having a wedge-shaped longitudinal section. The insertion piece is composed of at least two segments, and when the insert is in close contact, its outer circumferential shape has a conical shape, and the inner diameter of the casing gradually increases from top to bottom so as to be in close contact with the outer circumferential surface of the conical insert. Therefore, when a force pushing the insertion piece upward while the wire 15 is inserted between the insertion pieces is applied, the gap between the insertion pieces is tightened to fix the wire. The fixing bolt 12A is fixed to the frame of the fixture. By When the insert is in close contact with each other, a space 12D having a trumpet-shaped cross section is formed on an upper portion of the insert as shown in FIG. 2C, which will be described below.

The support 14 is also a cylindrical shape like the fixture, but the diameter of the inner circumferential surface is a trumpet that becomes smaller from top to bottom, which is a space 12D at the top of the insertion piece when the insertion piece 12C of the fixture 12 is in close contact with each other. The reason for this is that when one end of the test object wire is fixedly moved, it is to prevent bending such as bending by the contact surface between the fixture and the support. The distance 17 between the support and the bend test rod and the distance 18 between the fixture and the bend test rod can be adjusted by moving the support and the fixture to the left and right within a predetermined range on the bottom of the frame. Is fixed by the fixing bolts 14A and 12A. Thus adjusting the distance between the support and the fixture and the bending test rod is to control the degree of bending given to the wire under test.

The bending test rod 13 has an arced tooth 13A for left and right pivoting movements attached to one end thereof, and three bending rollers 13B for bending testing being attached to the other end thereof with a fixed pin 13C in the center portion thereof. By being fixed to the frame 11 so as to rotate left and right, the bending test rod by the disc-shaped gear wheel 13D which is geared to the circular arc 13A and gears forward / reverse rotation by the forward / reverse rotation motor The fixed pin is used as the axis of rotation, and the bending motion is applied to the wire under test by performing a motion having an arcuate trajectory, that is, a left and right pivoting motion, within a predetermined left and right angle range. In addition, among the three bend rollers 13B, the center roller is a structure capable of adjusting the height in order to adjust the degree of bending applied to the wire to be tested. In order to adjust the height of the bending roller is adjustable, it is preferable to be able to adjust the height of one of the two even when the two rollers are provided.

The test method using the tester of the present invention is as follows.

Once the wire to be tested is selected, cut it to an appropriate length and completely penetrate one end of the wire into the inner diameter of the fixture casing from which the insertion piece is separated, and then insert the insertion piece into the casing through the casing inlet and insert the wire. Fix it. The test preparation is completed by passing the fixed wire through the bending roller to the inner diameter of the support and connecting the weight corresponding to the load required for the test to the other end of the wire.

Although not shown in FIG. 1, the flexural test rod and the fixture of the present invention tester is connected to the forward / reverse rotation motor, and the rotational movement within the left and right ranges of the flexural test rod for flexural stress and the fixture for imparting torsional stress. The forward / reverse rotation movement is possible, and the operation control of the tester of the present invention is performed as shown in the control block diagram shown in FIG. 4.

That is, the speed control of the bending test motor 43 and the torsional stress motor 44 is made in the control unit 41, the operation state of the two motors at the same time the left and right pendulum movement of the bending test rod and the fixed / The forward / reverse rotation speed of each motor which is a reverse torsional speed is shown on the display unit 42.

As described above, the composite fatigue tester of the wire of the present invention can not only perform the bending fatigue test and the torsional stress test at the same time, but also the bending test rod itself has a longitudinal axis coinciding with the weight of the wire by the left and right pivoting movements. In addition to the stress, lateral stresses that do not coincide with the wire axis are applied to the wire under test, so that the behavior of wires under complex stress conditions such as actual use conditions can be identified in one tester.

In addition, since the bending test and the torsion test can be performed separately, the test for various kinds of wire characteristics can be performed in one tester, thereby improving the efficiency of the wire characteristic test inspection work.

Claims (7)

A composite fatigue tester for wires, the tester is centered on a frame, a fixture mounted on one side of the frame to fix one end of the wire to be tested, and a torsional stress applied to the fixed wire, and a fixing pin fixed to the center of the frame. The left and right rotational movements, the upper part of the bending test rod is provided with a roller in contact with the target wire and the other end of the frame is mounted on the other end of the movement of the test target wire due to the rotational movement of the bending test rod is converted into linear motion The composite fatigue tester of the wire, characterized in that consisting of a support serving as a functioning point for the tensile load given by the weight suspended on the other end of the wire to be tested. According to claim 1, wherein the fastener is composed of a cylindrical outer casing of which the inner diameter increases in one direction of the axis and the insertion piece is wedge-shaped longitudinal section, the insertion piece is composed of at least two segments, the insertion piece is in close contact When the outer shape of the close contact insert is conical shape, the inner diameter of the casing is a composite fatigue tester of the structure that gradually increases from top to bottom in close contact with the outer peripheral surface of the conical insert. The wire fatigue tester of claim 2, wherein the fastener is connected to a motor capable of forward / reverse rotation to impart repetitive torsional stress to the wire to be tested. The complex fatigue tester of claim 1, wherein the support has a cylindrical shape, but a diameter of the inner circumferential surface thereof is a trumpet shape that decreases from top to bottom. According to claim 1, wherein the bending test rod has an arcuate tooth for the left and right rotational movement is attached to one end thereof, three bending rollers for the bending test is attached to the other end, the center roller of the three bending rollers Composite fatigue tester of the wire, characterized in that the adjustable height structure. According to claim 1, wherein the bending test rod has an arcuate tooth for the left and right rotational movement is attached to one end thereof, two bending rollers for the bending test is attached to the other end, one of the two bending rollers Composite fatigue tester of the wire, characterized in that the height can be adjusted. According to claim 1, wherein the bending test rod has an arc-shaped tooth for the left and right rotational movement is attached to one end thereof, one bending roller for the bending test is attached to the other end, the bending roller is the height adjustment Composite fatigue tester of the wire, characterized in that possible structure.