KR101371759B1 - Apparatus for testing specimen - Google Patents

Abstract

Disclosed is an apparatus for testing a specimen, including: a grip which is fixed to the top and the bottom of a specimen to apply a tensile force or a compressive force to the specimen; a pair of grip guides which are in contact with both sides of the specimen, elongated towards the center of the specimen; and a jig housing formed with a through-hole through which the specimen penetrates, guide holes which are formed on both sides of the through-hole and through which the grip guides pass, fluid inlet parts which are formed on both sides facing each other to apply hydraulic pressure to both surfaces of the specimen, and a flow path formed inside.

Description

Specimen Tester {APPARATUS FOR TESTING SPECIMEN}

The present invention relates to a specimen test apparatus that can perform the test accurately by preventing the specimen from tilting or bending during the compression or tensile test.

Recently, many efforts have been made to expand the ultra high tensile steel to reduce the weight of the automobile body, but due to the high yield strength of the material, a considerable amount of springback occurs during cold press, which is causing difficulties in securing dimensional quality and securing mass productivity.

Computer simulation is used to review these problems in advance and reflect them in mold and process design.However, if the softening due to the Baosinger effect cannot be accurately measured and calculated in the computer simulation, the calculation is performed. The result is very different from the amount of springback that occurs after the actual press.

Accordingly, in order to measure the Bao Singer effect, an experiment which repeats the tensile test and the compression test of the metal plate is currently applied, but the plate test piece has a very small cross-sectional size compared to the length in the longitudinal direction. Bending deformation easily occurs, making precise testing difficult

Currently, as a technique for solving such a problem, a method of attaching metal guides on both sides of a test piece is applied.

These are bolted together with the metal strain relief jig in front of and behind the specimen equilibrium. Apply oil to reduce friction between the jig and the specimen.

However, the closer the jig is to the specimen in order to reduce the degree of deformation of the specimen, the greater the friction between the specimen and the jig, and the greater the impact on the final test result.

The space between the specimen grip and the anti-bending jig on both ends of the specimen must be spaced as long as the specimen is compressed. This space is fine for the center portion of the specimen, but deformation may occur to affect the experimental results.

On the other hand, the conventional KR10-2011-0104162 A "Fatigue tester capable of tensile-compression and torsion test" is a "main body 11 is provided with an actuator 100 for applying a load to the specimen, and the main body 11 and In the fatigue tester including a crosshead 12 is installed in the opposite position and the jig 14, 15 for fixing the specimen between the main body 11 and the crosshead 12, the actuator 100 Is connected to the jig 15 and driven forward and backward by the following transverse flux linear motor 130 and transmits the thrust generated by the transverse flux linear motor 130 and the rotational force generated by the following rotary motor 160 to the specimen. An actuator rod 110 for applying tension, compression, and torsional load, a frame 120 installed to fix the front and rear positions with respect to the traveling direction of the actuator rod 110 in the main body 11, and the actuator rod. Between 110 and frame 120 A lateral flux linear electric motor 130 configured to drive the actuator rod 110 forward and backward from the frame 120 having a fixed front and rear position, and installed to enable rotational force transmission to the actuator rod 110. Rotation motor 160 for driving the rotation; drive control of the lateral flux linear motor 130 and the rotary motor 160 and thrust control of the lateral flux linear motor 130 and rotational force control of the rotary motor 160. And a controller to perform; a fatigue tester capable of tensile-compression and torsion testing.

However, even with such equipment, it is difficult to prevent minute lateral deformation during compression of the specimen. And there was a problem that the friction between the jig and the test piece fixed affects the test result.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as an admission that the prior art is known to those skilled in the art.

KR 10-2011-0104162 A

The present invention has been proposed to solve the above problems, and an object thereof is to provide a specimen test apparatus that can accurately perform the test by preventing the specimen from tilting or bending during the compression or tensile test.

Specimen test apparatus according to the present invention for achieving the above object, the grip is respectively fixed to the upper and lower ends of the specimen to apply a tensile or compressive force to the specimen; A pair of grip guides provided on the grips and in close contact with both sides of the specimen and extending toward the center of the specimen; And a through hole through which the specimen penetrates, guide holes through which the grip guide penetrates on both sides of the through hole, and fluid introduction portions are formed on opposite sides of the specimen so that hydraulic pressure can be applied to both sides of the specimen. It is formed; jig housing.

Insertion groove is formed at the specimen side end of the grip, the grip guide is located in the insertion groove and the grip guide is in close contact with the specimen guide pin is inserted with the grip guide in the insertion groove can be fixed to the grip guide. .

The jig housing may have a box shape in which an inner space is emptied and fluid may be filled into the inner space to form a flow path.

The jig housing is composed of one side and the other part divided into one side and the other side of the specimen centered on the specimen, one side and the other part can be assembled to secure the specimen.

The one side part is formed with a through hole and a guide hole up and down, and the other part is formed with a guide hole up and down, and when assembling one side part and the other part, guide holes may be connected to both sides of the one through hole. .

The fluid injected into the jig housing may be a high viscosity fluid.

The fluid may be a toothpaste.

According to the specimen test device having the structure as described above, by applying a narrow guide to the front and back of the compression test piece, the anti-bending jig is mounted in the center to apply a hydraulic pressure to the front and back of the test piece to suppress the deformation of the entire test piece with minimal friction during the compression test Accurate compression test results can be obtained.

In the prior art, the deformation of the jig attaching part can be prevented, but in the process, as the test piece is in close contact with the metal jig, friction in proportion to the force occurs, and thus, accurate compressive stress / strain data cannot be derived.

And the part between the metal jig and the specimen grip could not prevent the deformation of the specimen during compression. In the present invention, even if the liquid in the jig hardly pressurizes the specimen during compression, the friction between the liquid and the specimen hardly occurs, so that a narrow guide is installed between the grip part and the anti-bending jig to prevent deformation with minimal friction, thereby providing accurate stress. / Deformation data can be derived.

1 to 3 show the jig housing of the present invention.
4 to 6 is a view showing a specimen test apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings looks at the specimen test apparatus according to a preferred embodiment of the present invention.

1 to 3 is a view showing a jig housing of the present invention, Figures 4 to 6 is a view showing a specimen test apparatus according to an embodiment of the present invention.

Specimen testing device of the present invention, the grip 400 is fixed to the upper and lower ends of the specimen 300 to apply a tensile or compressive force to the specimen 300; A grip guide 500 provided in pairs on the grip 400 and in close contact with both sides of the specimen 300 and extending toward the center of the specimen 300; And a through hole 120 through which the specimen 300 penetrates, and guide holes 122 and 124 through which the grip guide 500 penetrates on both sides of the through hole 120, respectively, to both sides of the specimen 300. It includes a fluid introduction portion (110, 210) is formed on each side facing each other so that the hydraulic pressure can be applied, the jig housing (1000) formed with a flow path therein.

In the case of the present invention, the specimen 300 is basically fixed in the grip. However, in the case of the grip 400, only the fixing in the vertical direction is performed, rather than directly fixing both sides of the specimen 300. In addition, the side fixing of the specimen 300 is mainly made in the grip guide 500, in the case of the grip guide 500 only serves to hold this, it does not hold to the extent that excessive friction occurs.

On the other hand, the fixing to the side to prevent the side deformation of the specimen 300 is to perform the fluid supplied from the injection tube (H). Therefore, by applying a narrow grip guide 500 to the front and back of the compression specimen 300 and applying hydraulic pressure to the front and rear of the specimen, the deformation of the entire specimen can be suppressed with minimal friction during the compression test, thereby obtaining accurate compression test results. .

Specifically, the grip 400 is fixed to the upper and lower ends of the specimen 300 to apply a tensile or compressive force to the specimen 300, respectively. The grip is intended to mainly fix only the upper and lower ends of the specimen as shown in Figures 4 to 5 and the main role is to transmit the compressive force in the vertical direction.

In addition, the grip 400 is provided in pairs, and a grip guide 500 is provided to be in close contact with both sides of the specimen 300 and extend toward the center of the specimen 300. The grip guide performs minimal friction and only serves to hold the specimen. That is, to correctly set the specimen through the grip guide 500, and finally pressurizing the side force so that the specimen 300 is not bent to be by the hydraulic pressure.

In addition, a through hole 120 through which the specimen 300 penetrates is formed, and guide holes 122 and 124 through which the grip guide 500 penetrates are formed at both sides of the through hole 120, and both sides of the specimen 300 are extended. The fluid introduction parts 110 and 210 are formed on opposite sides so that hydraulic pressure can be applied thereto, and a jig housing 1000 having a flow path is provided therein.

In detail, the jig housing 1000 has a box shape in which an inner space is emptied, and fluid is filled into the inner space to form a flow path.

That is, since the fluid is filled in the inside of the jig housing 1000 and imparts a hydraulic pressure, the hydraulic pressure is actuated on both sides of the specimen so that the specimen 300 is compressed or tensioned in a vertical state without bending.

On the other hand, the jig housing 1000 is composed of one side part 100 and the other part 200 divided into one side and the other side of the specimen 300 around the specimen 300, one side part 100 And the other part 200 is assembled to fix the specimen 300.

In addition, the one side part 100 is provided with a through hole 120 and a guide hole 122 up and down, and the other part 200 is formed with a guide hole 124 up and down, one side part 100 and the other side. When assembling the part 200, guide holes 122 and 124 are connected to both sides of one through-hole 120.

In the case of Figure 1 shows one such part, Figure 2 shows the other part, Figure 3 is a top view of a state in which one side and the other part is coupled.

The one side part 100 and the other side part 200 are formed in a rectangular box shape, and the inside thereof is emptied to form a flow path and the hydraulic pressure is filled therein.

In addition, fluid introduction parts 110 and 210 are formed at one side part 100 and the other part 200 to form a hydraulic pressure, and the fluid introduction parts 110 and 210 face each other at one side part 100 and the other part 200. One side and the other side of the 300 is formed so as to apply hydraulic pressure vertically. This effectively transmits the deformation preventing force to the specimen (300).

Meanwhile, the one side part 100 is provided with a through hole 120 and a guide hole 122 up and down, and the other part 200 is formed with a guide hole 124 up and down, and the one side part 100 and the other part are formed. When assembling the 200, guide holes 122 and 124 are connected to both sides of one through-hole 120.

Through this, the specimen 300 is located in the through-hole 120, the grip guide 500 in close contact with the specimen 300 is located in the guide hole 122 to slide up and down and perform a compression / tensile test .

On the other hand, the insertion groove 420 is formed at the end of the specimen 300 side of the grip 400, the grip guide 500 is located in the insertion groove 420, the grip guide 500 is in close contact with the specimen 300 After the guide pin 520 is inserted into the insertion groove 420 with the grip guide 500 may be fixed to the close contact of the grip guide 500.

That is, as shown in Figures 4 to 5, the insertion groove 420 is formed at the end of the grip 400, the grip guide 500 is to be inserted into the insertion groove 420 basically. In addition, the grip guide 500 is glided in the insertion groove 420 so as to hold the grip guide 500. The grip guide 500 closely adheres to the specimen 300. By being inserted, the insertion groove 420 is full and the grip guide 500 is in close contact with the specimen 300. Through this process, a setting for initially fixing the specimen 300 is made, and during the test, to prevent the buckling of the specimen through the pressure of the fluid.

On the other hand, the fluid injected into the jig housing 1000 is a high viscosity fluid by the specimen through a minimum friction force? Support the side. Preferred embodiments of such fluids may use toothpaste.

Since high viscosity fluids have a significantly lower coefficient of friction than conventional metal jigs, test errors due to friction between the liquid and the specimen can be neglected. At the same time, it has high viscosity, which can apply pressure to the specimen more efficiently than the existing hydraulic pressure and prevent leakage of liquid due to jig gap. In addition, in the front and rear jig housing, the specimen through hole and the guide hole portion may be provided with a gap preventing rubber to prevent fluid leakage.

Through such a configuration, since both ends of the specimen are subjected to a small deformation force when the specimen is compressed, the deformation of the specimen can be prevented by only a narrow grip guide without covering the entire specimen. And the narrower the grip guide, the smaller the friction with the specimen can minimize the impact on the experimental results. The inner surface of the guide, that is, the part in contact with the specimen, may attach a low friction coefficient intermediate such as Teflon tape. The length of the grip guide should preferably be set so that it can overlap with the guide hole by 1 ~ 2mm starting from the specimen grip. The grip guide is movable inside the jig housing through the guide hole of the jig housing.

According to the specimen test device having the structure as described above, by applying a narrow guide to the front and back of the compression test piece, the anti-bending jig is mounted in the center to apply a hydraulic pressure to the front and back of the test piece to suppress the deformation of the entire test piece with minimal friction during the compression test Accurate compression test results can be obtained.

In the prior art, the deformation of the jig attaching part can be prevented, but in the process, as the test piece is in close contact with the metal jig, friction in proportion to the force occurs, and thus, accurate compressive stress / strain data cannot be derived.

And the part between the metal jig and the specimen grip could not prevent the deformation of the specimen during compression. In the present invention, even if the liquid in the jig hardly pressurizes the specimen during compression, the friction between the liquid and the specimen hardly occurs, so that a narrow guide is installed between the grip part and the anti-bending jig to prevent deformation with minimal friction, thereby providing accurate stress. / Deformation data can be derived.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

1000: jig housing 120: through hole
122,124: Information Hall 300: Psalms
400: grip 500: grip guide

Claims (7)

A grip 400 fixed to the top and bottom of the specimen 300 to apply tensile or compressive force to the specimen 300;
A grip guide 500 provided in pairs on the grip 400 and in close contact with both sides of the specimen 300 and extending toward the center of the specimen 300; And
Through holes 120 through which the specimen 300 penetrates are formed, and guide holes 122 and 124 through which the grip guide 500 penetrates are extended to both sides of the through hole 120, and the hydraulic pressure is applied to both sides of the specimen 300. And a fluid introduction portion (110, 210) formed on both sides facing each other so as to be applied thereto, and a jig housing (1000) having a flow path formed therein. The method according to claim 1,
Insertion groove 420 is formed at the end of the specimen 300 side of the grip 400, the grip guide 500 is located in the insertion groove 420 and the grip guide 500 is in close contact with the specimen 300 Guide pin 520 is inserted into the insertion groove 420 together with the grip guide 500, the specimen test device, characterized in that the close contact of the grip guide 500 is fixed. The method according to claim 1,
The jig housing (1000) is a test box, characterized in that the inner space is empty box shape and the fluid is filled into the inner space to form a flow path. The method according to claim 1,
The jig housing 1000 is composed of one side part 100 and the other part 200 divided into one side and the other side of the specimen 300 with respect to the specimen 300, and the one side part 100 and the other side. Specimen testing device, characterized in that the part 200 is assembled to fix the specimen (300). The method of claim 4,
The one side part 100 is provided with a through hole 120 and a guide hole 122 up and down, and the other part 200 is formed with a guide hole 124 up and down, and the one side part 100 and the other part ( Specimen testing device, characterized in that the guide holes (122,124) are connected to both sides of the through-hole 120 when the assembly of the 200. The method according to claim 1,
Specimen testing device, characterized in that the fluid injected into the jig housing 1000 is a high viscosity fluid. The method of claim 6,
Specimen test device, characterized in that the fluid is toothpaste.

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