KR102212052B1 - Multi-axis fatigue test jig constituting fatigue testing device - Google Patents

Abstract

According to the present invention, a multi-axis fatigue test jig for forming an axial-load fatigue testing device comprises: a hydraulic chuck (110); an adapter (120) detachably coupled to the hydraulic chuck (110); a bolt chuck (130) detachably coupled to the adapter (120); and a multi-axis punch fixing module (200) coupled to the bolt chuck (130). The multi-axis punch fixing module (200) includes: a fixed body (210) through which a punch fixing hole (214) is formed; an upper separation prevention block (220) coupled to an open upper portion of the punch fixing hole (214) to function to prevent upward separation of a coupled specimen; and a side separation prevention block (230) coupled to an open side of the punch fixing hole (214) to function to prevent lateral separation of the coupled specimen. The punch fixing hole (214) is formed in the longitudinal direction of the fixed body (210) to be linearly extended from the hydraulic chuck (110) in a radial direction. A punch (P) inserted into the punch fixing hole (214) is arranged to be adjusted in distance in the radial direction from the axial center of the hydraulic chuck (110). A movement prevention dummy having a predetermined shape is disposed on the punch fixing hole (214) based on the inserted punch (P) so that the inserted specimen is fixed at a specific position, and thus various loads are provided through various axes. Therefore, the limitations of testing that occur when the testing is performed on an axis rather than the central axis can be overcome.

Description

Multi-axis fatigue test jig constituting fatigue testing device}

The present invention relates to a jig for a multi-axis fatigue test, and more particularly, when a test is performed on an axis other than the central axis on a axial fatigue tester, there is a limitation of the test. It is about.

Fatigue tester is a tester that secures the stability and durability of various structures and materials. Static strength, dynamic strength and fatigue characteristics are measured by measuring the load, stress and displacement of the main part by applying a load of waveform similar to the actual to the test object and observing the failure process It is a test device to obtain.

Axial-loaded fatigue testing machine fixes test specimens of the same size to a axial-load type fatigue testing machine and applies a cyclic stress-type load to derive the results. A hydraulic chuck is used.

The bolt chuck is a structure to fix the specimen using multiple bolts, and is suitable for high-strength specimens, but the workability is poor because a large number of bolts must be tightened and loosened.

In the case of a hydraulic chuck applied to a axial fatigue tester, a jaw is operated by hydraulic pressure to make the work easier as a structure to fix the specimen, and a jaw for a circular specimen and a jaw for a plate specimen can be applied to the jaw. On the other hand, in the case of a hydraulic chuck, there is a problem in that the jaws are broken or not rigidly fixed to the high strength specimen.

Depending on the type of specimen, the bolt chuck and the hydraulic chuck are alternately used each time, so it is cumbersome and requires a lot of force, and because human force is used, a result value error occurs, resulting in shear stress, which is an error.

Referring to the existing Korean Patent Registration Nos. 10-1006083 (Fatigue Tester for Thin Films) and No. 10-0382290 (Fatigue Test Equipment for Specimens), fatigue for thin films that can perform a fatigue test by repeatedly applying tensile force to a specimen Provides technical details about the testing machine.

(Patent Document 1) KR 10-1006083 B

(Patent Document 1) KR 10-0382290 B

The present invention has limitations when testing is performed on an axis other than the central axis on the axial fatigue tester. To compensate for this, the jaw in the hydraulic chuck applied to the axial fatigue tester is removed, and detachable. It is to provide a axial fatigue tester having a structure that adjusts the axial direction in which the load is applied by fastening the hydraulic chuck adapter and controlling the number of dummy coupled on the empty space formed in the multiaxial fatigue test jig.

The multi-axial fatigue test jig for the axial fatigue test apparatus according to the present invention for achieving the above object is a hydraulic chuck 110, an adapter 120 detachably coupled to the hydraulic chuck 110, the adapter Includes a bolt chuck 130 detachably coupled to 120 and a multiaxial punch fixing module 200 coupled to the bolt chuck 130, and the multiaxial punch fixing module 200 includes a punch fixture 214 A fixed body 210 formed therethrough; An upper separation prevention block 220 that is coupled and fastened on the open upper portion of the punch fixture 214 and serves to prevent separation of the combined punch from the upper portion; And a side separation prevention block 230 which is coupled and fastened on the open side of the punch fastener 214 to prevent lateral separation of the combined punch, wherein the punch fastener 214 includes the fixed body By being formed along the longitudinal direction of 210, the hydraulic chuck 110 has a structure extending in a straight line along the radial direction, and the punch P inserted into the punch fixture 214 is the hydraulic chuck 110 It is arranged to be adjustable in the radial direction from the center of the axis of the inserted punch (P) by arranging a dummy for preventing movement of a predetermined shape on the punch fixture 214 based on the inserted punch (P) It is characterized in that it is fixed to provide various loads through various axes.

The fixed body 210 includes a bolt chuck coupling body 211 coupled to the bolt chuck 130, and a punch fixture 214 to which a punch is coupled while extending to one side of the bolt chuck coupling body 211. The punch coupling body 212 includes a stepped portion 215 bent inwardly on the lower end of the punch fixture 214.

The punch (P) has a predetermined punch groove (G) is formed to conform to the shape of the step portion 215 protruding inward from the lower end of the punch fixture 214, the step protruding on the punch groove (G) In a state in which the part 215 is slidably inserted, the position of the punch can be adjusted.

As described above, the present invention removes the jaws in the hydraulic chuck applied to the axial fatigue tester, and is coupled to the empty space formed in the multiaxial fatigue test jig in a state in which the hydraulic chuck adapter for high hardness specimens that can be detached is fastened. It is characterized by overcoming the limitation of the test that occurs when the test is performed on an axis other than the central axis on the axial fatigue tester by adjusting the direction of the load applied through the method of controlling the number of dummy.

1 shows an embodiment of a jig for a multiaxial fatigue test constituting a fatigue test apparatus.
2 shows an embodiment of a multi-axial punch fixing module constituting a multi-axial fatigue test jig.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only the present embodiments make the disclosure of the present invention complete, and the scope of the invention to those of ordinary skill in the art. It is provided to be fully informed. In the drawings, the same reference numerals refer to the same elements.

In the present specification, the multi-axial fatigue test jig according to the present invention is installed and used in a fatigue tester, but the present invention is not limited thereto. It belongs to the present invention that it is installed and used in all devices that fix the specimen, such as other testing machines other than the fatigue testing machine.

Hereinafter, a jig for a multiaxial fatigue test installed and used in a fatigue tester will be described with reference to the drawings.

In the present invention, the fatigue tester is provided with a jig 100 for a multiaxial fatigue test. The multi-axial fatigue test jig 100 is arranged along the vertical direction, so that the end of the punch P is firmly fixed. The present invention combines one end of a punch (P) on a multiaxial fatigue test jig, and in a state in which a jig for fixing the specimen is arranged so as to face the multiaxial fatigue test jig with the punch in the vertical direction, It can be designed to perform a fatigue test by pressing the specimen bonded onto the specimen fixing jig through a punch.

On the other hand, in the present invention, the fatigue tester may be arranged to face a pair of multi-axial fatigue test jigs. In the above state, it can be designed to perform a fatigue test by applying a axial load in a state in which both ends of the specimen to be fatigue test are joined on a pair of multiaxial fatigue test jigs.

The multiaxial fatigue test jig 100 includes a hydraulic chuck 110, an adapter 120 detachably coupled to the hydraulic chuck 110, a bolt chuck 130 detachably coupled to the adapter 120, and a multiaxial punch fixing module Includes 200.

The hydraulic chuck 110 is formed between the body 111 and the first coupling wall portion 112 and the second coupling wall portion 113 and the first and second coupling wall portions formed to face each other on the lower portion of the body 111 A coupling space 115 is provided.

The hydraulic chuck 110 includes a moving body (not shown) that moves up and down by hydraulic pressure on the inner bottom of the body 111. The adapter 120 is detachably coupled to and fixed to the hydraulic chuck 110 by a moving body. That is, on the inner lower end of the body 111 to which the adapter 120 is coupled, a moving body that is operated to move up and down by hydraulic pressure is disposed to be retractable while being accommodated. When the adapter 120 enters the body 111, the moving body retreats into the body 111 to prevent interference between the moving body and the adapter 120, and after the adapter 120 enters the body 111, the moving body Fixing is performed by pressing the lower end of the adapter 120 that has been drawn out from the body 111 and entered.

The two coupling wall portions 112 and 113 are inclined so as to get closer to each other toward the ends (upper and lower ends in the drawing). Accordingly, the coupling space 115 formed between the two coupling wall portions has a shape that becomes narrower toward the end. The adapter 120 is accommodated and coupled to the coupling space 115 formed between the two coupling wall portions.

The adapter 120 that slides into the coupling space 115 formed between the two coupling wall portions 112 and 113 is fixed on the lower central portion of the body 111. That is, the moving body that has been retracted on the body 111 on the fixing groove (not shown) formed in the slidingly moved adapter 120 is pulled out, and the adapter 120 can be seated by fastening it on the fixing groove. Let's do it.

The adapter 120 is detachably coupled to the hydraulic chuck 110, and the bolt chuck 130 is detachably coupled to the adapter 120.

The adapter 120 is a generally columnar shape that can be accommodated in the coupling space 115 formed on the hydraulic chuck 110, and the inclined portion 121 and the inclined portion 121 to be narrowed closer to each other from the top to the bottom It has an exposed portion 123 extending in the direction. The inclined portion 121 has an appropriate inclination so as to be in close contact with the inner surfaces of the two coupling wall portions 112 and 113. Through the above structure, when the adapter 120 is coupled to the hydraulic chuck 110, the inclined portion 121 is accommodated in the coupling space 115 through a sliding movement, and the exposed portion 123 is a bolt chuck ( 130) has a state protruding outwardly of the adapter 120 for easy coupling.

The bolt chuck 130 may be a member having a cylindrical shape having a predetermined thickness, and a center through hole through which a first bolt (not shown) is coupled so that the bolt chuck 130 is detachably coupled to the adapter 120 ( (Not shown) and a plurality of peripheral through-holes 132 through which a second bolt (not shown) is coupled so that the bolt chuck 130 is detachably coupled to the multi-axis punch fixing module 200. The plurality of peripheral through-holes 132 may have a structure formed in a radial shape based on a center through-hole formed through the central portion of the bolt chuck 130. That is, after fixing the bolt chuck 130 on the adapter 120 through the center through hole, the multi-axis punch fixing module 200 is fixed to the bolt chuck 130 through a plurality of peripheral through holes 132. Have.

The multi-axial punch fixing module 200 is coupled to the fixed body 210 through which the punch fixture 214 is formed, and on the open upper part of the punch fixture 214, and functions to prevent the upper separation of the combined punch. It includes the prevention block 220 and a side separation prevention block 230 that is coupled and fastened on the open side of the punch fixture 214 to prevent lateral separation of the combined punch.

The fixed body 210 includes a bolt chuck coupling body 211 coupled to the bolt chuck 130 through a plurality of peripheral through-holes 132, and a punch in a state extended to one side of the bolt chuck coupling body 211. The punch coupling body 212 having the punch fixture 214 formed therethrough, the bolt chuck coupling body 211, the fastening hole 213 communicating with some of the plurality of peripheral through holes 132, and the punch fixture 214 It includes a stepped portion 215 bent inwardly on the lower end. The punch coupling body 212 has a structure extending in a radial direction from the hydraulic chuck 110 to the bolt chuck 130.

The punch fixture 214 is formed along the longitudinal direction of the punch coupling body 212 and, as a result, has a structure extending in a straight line along the radial direction from the hydraulic chuck 110 to the bolt chuck 130. That is, the punch P fastened on the punch fixture 214 is disposed so as to be able to adjust the distance along the radial direction from the axial center of the hydraulic chuck 110.

Punch (P) has a predetermined punch groove (G) is formed to conform to the shape of the step portion 215 protruding inward from the lower end of the punch fixture 214, the step portion protruding on the punch groove (G) ( In a state where 215 is slidably inserted, the position of the punch can be adjusted. That is, the punch P for the fatigue test is slidable along the longitudinal direction of the punch coupling body 212 while being inserted into the punch fixture 214. In order to fix the inserted punch P in a specific position in the above state, a dummy for preventing movement of a predetermined shape is disposed on the punch fixture 214 based on the inserted punch P. The dummy for preventing movement is a shape that can be seated through the protruding stepped portion 215, and a plurality of piles of pieces may be used. For example, the plurality of piles may be in the shape of a plate having a rectangular shape having a predetermined thickness inserted on each punch fixture 214.

Hereinafter, the process of installing the punch (P) in the fatigue testing machine will be described.

First, in a state in which a pair of multiaxial fatigue test jigs 100 constituting the fatigue testing machine are symmetrically arranged to face each other along the vertical direction, the length of the punch P and the length of the punch groove G formed in the punch P Adjust the distance between the multi-axial fatigue test jig 100 according to the arrangement. Adjustment of the distance between the multi-axial fatigue test jig 100 is enabled through an actuator coupled along the axial direction of the hydraulic chuck 110 constituting each multi-axial fatigue test jig 100.

In the state where the separation prevention blocks 220 and 230 are removed from the multi-axis punch fixing module 200, the punch groove G formed in the punch P and the stepped portion 215 formed in the punch fixture 214 are aligned with each other, Insert P) in a slidable way.

In order to fix the inserted punch (P) on a position spaced apart from the axis center of the hydraulic chuck 110 by a specific distance, a dummy for preventing movement of a predetermined shape is placed on the punch fixture 214 based on the inserted punch (P). To place.

Thereafter, the upper separation prevention block 220 is disposed on the open upper portion of the punch fixture 214 into which the punch (P) and the movement preventing dummy are inserted, and side separation is prevented on the open inlet of the punch fixture 214 In a state where the block 230 is coupled to prevent separation of the specimen, a fatigue test during axial load is performed.

As described above, the present invention removes the jaws in the hydraulic chuck applied to the axial fatigue tester, and is coupled to the empty space formed in the multiaxial fatigue test jig in a state in which the hydraulic chuck adapter for high hardness specimens that can be detached is fastened. By controlling the axial direction of the load through the method of controlling the number of piles, the limitation of the test that occurs when the test is performed on an axis other than the central axis on the axial fatigue tester is overcome.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

100: jig for multi-axis fatigue test
110: hydraulic chuck
111: body
112: first coupling wall portion
113: second coupling wall portion
115: combined space
120: adapter
130: bolt chuck
132: peripheral through-hole
200: multi-axis punch fixing module
210: fixed body
211: bolt chuck combined body
212: punch coupling body
213: fastening hole
214: punch fixture
215: step
220: Top separation prevention block
230: side separation prevention block

Claims (3)

In the multi-axis fatigue test jig used in the axial fatigue tester
The multi-axial fatigue test jig,
A hydraulic chuck 110, an adapter 120 detachably coupled to the hydraulic chuck 110, a bolt chuck 130 detachably coupled to the adapter 120, and a multi-axis coupled to the bolt chuck 130 Including a punch fixing module 200,
The multi-axis punch fixing module 200,
A fixed body 210 through which the punch fixture 214 is formed;
An upper separation prevention block 220 that is coupled and fastened on the open upper portion of the punch fixture 214 to prevent separation from the upper portion of the combined specimen; And
Includes; a side separation prevention block 230 that is coupled and fastened on the open side of the punch fixture 214 to prevent lateral separation of the combined specimen
The punch fixture 214 has a structure extending in a straight line along a radial direction from the hydraulic chuck 110 by being formed along the longitudinal direction of the fixing body 210,
The punch (P) inserted on the punch fixture 214 is arranged to be adjustable in a radial direction from the axial center of the hydraulic chuck 110, and the punch fixture ( 214), characterized in that by disposing a dummy for preventing movement of a predetermined shape, the inserted specimen is fixed on a specific position to provide various loads through various axes,
Jig for multi-axis fatigue test.
The method of claim 1,
The fixed body 210 includes a bolt chuck coupling body 211 coupled to the bolt chuck 130, and a punch fixture 214 to which a specimen is coupled while extending to one side of the bolt chuck coupling body 211. A punch coupling body 212, including a step portion 215 bent inwardly on the lower end of the punch fixture 214,
Jig for multi-axis fatigue test.
The method of claim 2,
The punch (P) has a predetermined punch groove (G) is formed to conform to the shape of the step portion 215 protruding inward from the lower end of the punch fixture 214, the step protruding on the punch groove (G) In a state in which the part 215 is slidably inserted, it is possible to adjust the position of the specimen,
Jig for multi-axis fatigue test.

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