KR101332466B1 - High speed tensile tester and high speed tensile testing method using the same - Google Patents

Abstract

The present invention relates to a tensile tester equipped with a specimen mounting guide for guiding the fixing position of a specimen and, more particularly, to a tensile tester equipped with a specimen mounting guide, which can arrange a specimen regardless of the width or shape of a grip unit by being in contact with the side surface of a gauge mark of the specimen and does not restrict the installation of an additional measuring device by minimizing the contact with the specimen. The tensile tester prepared by the present invention is to measure properties of matter by including a pair of grip devices placed at the top and the bottom and vertically applying tensile force to a tensile test specimen fixed to the grip devices. The tensile tester comprises a rail groove which is formed at one side of the pair of grip devices and formed in parallel with the surface of the tensile test specimen; a guide body which is movably mounted along the rail groove; and a contact strip which is fixed to the guide body and formed toward the side surface of a gauge mark of the test specimen.

Description

High Speed Tensile Tester and High Speed Tensile Test Method Using the Same {High Speed Tensile Tester and High Speed Tensile Tester Method]

The present invention relates to a high speed tensile tester, and more particularly, it is possible to reduce the length of the specimen, and in particular, a high speed tensile tester and a high speed tensile test method using the same, which can improve the reliability by preventing the shaking of the specimen and the shaking during impact. It is about.

As safety is a concern, crash stability is being enhanced in automobiles. In order to secure the collision stability of the sunshade, a computer simulation is performed. At this time, the collision analysis is performed using dynamic property data rather than static property data.

High speed tensile tester is manufactured and used for the purpose of securing such dynamic property data. Unlike the static tensile tester, the high speed tensile tester is designed to compensate the speed by fixing the tensile test specimen after acceleration of the grip part in consideration of the acceleration section.

1 to 3 schematically show a conventional high speed tensile tester, Figure 1 shows the front of the high speed tensile tester, Figure 2 shows the side of the high speed tensile tester, Figure 3 is the lower body in the high speed tensile tester It shows when is lowered.

1 to 3, in the case of the conventional high speed tensile tester, the lower main body 110, the grips 120a and 120b, the wedge 130, the pre-tension bolt 140, and the hydraulic pressure The cylinder 150, the load sensing unit 160, and the jaws (Jaw, 410) are included.

The lower main body 110 is connected to the hydraulic cylinder 150, and is raised and lowered by the hydraulic cylinder. The lower main body 110 is guided by the pin 170 when descending and descends, and descends to the head of the pin 170.

The grips 120a and 120b are composed of an upper grip 120a and a lower grip 120b, and the lower grip 120b is coupled to have some specimen margin 101 'at the bottom thereof.

The wedge 130 has a hole through which the specimen can pass.

The pretension bolt 140 is in the tightened state in close contact with the lower body 110 and the wedge 130 to prevent the lower body of the lower body, in the loosened state so that the lower body 110 is instantaneously lowered.

The load sensing unit 160 senses a load when the wedge 130 falls freely by the lower main body 110 and repeatedly lifts and lowers the lower main body 110 while applying an impact to the lower grip 120b. .

The jaw 410 has a specimen margin 101 when the wedge 130 falling freely by a load when the lower main body 110 is lowered, impacts the lower grip 120b, that is, a tensile force on the specimen 101. Grip ').

The specimen 101 is designed to be sufficiently long in consideration of the portion to be gripped by the jaws 410, that is, the specimen margin 101 ′.

In the case of the high speed tensile tester illustrated in FIG. 1, as described above, the lower main body 110 descends at a moment by loosening of the pretension bolt 140 to perform a high speed tensile test.

At this time, when the jaw 410 of the lower main body is separated from the wedge 130 without gripping the specimen at the beginning of the test, the specimen margin 101 'is caught, so that the friction between the specimen margin 101' and the jaw 410 is reduced. This occurs, and also slip occurs between the specimen margin (101 ') and the jaws (410), in order to ensure the reliability must be carried out a number of experiments to perform the test.

In addition, due to friction and slippage between the specimen margin 101 'and the jaws 410 at the beginning of the test, the shaking of the initial high-speed tensile data is severe, and it is difficult to measure the initial data value corresponding to the elastic deformation section.

Then, when the strength of the pretension bolt 140 for holding the wedge 130 is changed in the steel grade and thickness of the specimen, there is a hassle to adjust the tightening state of the pretension bolt every test.

In addition, in consideration of the specimen margin 101 ', there is a problem in that the length of the specimen itself is sufficiently long.

Background art related to the present invention is a method of adjusting the grip gap of the high-speed tensile tester disclosed in Republic of Korea Patent Publication No. 10-2005-0098416 (published on October 12, 2005).

An object of the present invention is to provide a high-speed tensile tester that can improve the reliability by suppressing the phenomenon, such as friction, slipping of the specimen by enabling a high-speed tensile test in the state of holding the specimen in advance unlike the conventional high-speed tensile tester.

Another object of the present invention is to provide a method for performing a high speed tensile test using the above high speed tensile tester.

High speed tensile tester according to an embodiment of the present invention for achieving the above object is an upper grip for fixing the top of the specimen; A lower grip fixing the lower portion of the specimen; A lower body repeating the ascending and descending and impacting the lower grip when descending; And a load sensing unit configured to sense a tensile load acting on the specimen when the lower main body impacts the lower grip, wherein the tensile force is applied to the specimen by the impact received when the lower main body descends. It features.

In this case, the lower grip is a first portion for fixing the specimen, a second portion extending downwards from the first portion, and the second portion is located at the end of the lower body, the first impact of the lower body lowered It can contain three parts.

High speed tensile tester according to another embodiment of the present invention for achieving the above object is an upper grip for fixing the top of the specimen; A lower grip fixing a lower portion of the specimen and having a damper formed thereon; A lower main body repeating the ascending and descending and impacting the damper of the lower grip when descending; And a load sensing unit configured to sense a tensile load acting on the specimen when the lower main body impacts the damper of the lower grip. The tensile force is applied to the specimen by the impact received when the lower main body descends. The vibration generated during the impact by the damper is suppressed.

In this case, the lower grip is a first portion for fixing the specimen, a second portion extending downwards from the first portion, and the second portion is located at the end of the lower body, the first impact of the lower body lowered It can contain three parts.

In this case, the damper is preferably formed on the upper surface of the third portion of the lower grip.

In the high-speed tensile test method according to an embodiment of the present invention for achieving the above another object, the specimen is fixed to the lower grip by applying a shock to the lower grip while repeating the lifting and lowering of the lower body using the high-speed tensile tester presented above It is characterized by applying a tensile force to the.

According to the high-speed tensile tester according to the present invention, by holding the specimen from the beginning, it is possible to prevent the sliding of the specimen and the lower grip. In addition, it is possible to reduce the length than the specimen used in the conventional high-speed tensile test, it is possible to ensure a sufficient specimen from the same size plate.

In addition, according to the high-speed tensile tester according to the present invention, it may include a damper in order to prevent the initial impact is transmitted, in this case it can minimize the shaking phenomenon due to the initial impact.

Figure 1 shows the front of a conventional high speed tensile tester.
Figure 2 shows the side of a conventional high speed tensile tester.
Figure 3 shows when the lower body is lowered in the conventional high speed tensile tester.
Figure 4 shows the state when the lower body is not lowered in the high speed tensile tester according to an embodiment of the present invention.
Figure 5 shows the state when the lower body is lowered in the high speed tensile tester according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments and drawings described in detail below.

However, it is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. It is intended that the disclosure of the present invention be limited only by the terms of the appended claims.

Hereinafter, a high speed tensile tester having excellent reliability and a high speed tensile test method using the same according to the present invention will be described in detail.

Figure 4 shows the state when the lower body is not lowered in the high speed tensile tester according to an embodiment of the present invention. Figure 5 shows the state when the lower body is lowered in the high speed tensile tester according to an embodiment of the present invention.

4 and 5, the high speed tensile tester according to the present invention includes an upper grip 520, a lower grip 530, a lower body 540, and a load sensing unit 550.

The upper grip 520 fixes the top of the specimen 501.

The lower grip 530 fixes the lower portion of the specimen 501 and exerts a tensile force on the specimen 501 by the impact received when the lower body 540 descends.

In the present invention, unlike the prior art, the lower grip 530 is fixed to the lower portion of the specimen 501 in advance, thereby suppressing friction or slippage between the specimen 501 and the lower grip 530 during impact. In addition, in the present invention, since the lower grip 530 grips the specimen in advance, it is not necessary to place the specimen margin (101 'of FIG. 1) as in the prior art, so that the specimen can be made relatively short.

The lower grip 530 applied to the present invention more specifically includes a first portion 530a, a second portion 530b, and a third portion 530c.

The first portion 530a is a portion for fixing the specimen 501.

The second portion 530b extends downward from the first portion 530a in the form of a bar.

The third portion 530c is positioned at the end of the second portion 530b and is subjected to a shock by the lower body 540 when the lower body 540 descends to exert a tensile force on the specimen 501.

In addition, a damper 535 is formed on the upper surface of the third portion 530c, and when the lower main body 540 descends, the damper 535 may suppress occurrence of vibration when the lower main body 540 receives an impact, particularly an initial impact. have. 4 and 5 illustrate an example in which an upper surface of the third portion 530c is formed as an inclined surface, but an upper surface of the third portion may be formed as a horizontal surface.

On the other hand, in the case of the lower grip 530, as the weight increases, it is possible to lower the natural frequency of the tensile tester itself, in this case, there is an effect that can more suppress the vibration generated during the impact.

The lower main body 540 repeatedly moves up and down by a hydraulic cylinder (not shown), etc., and impacts the lower grip 530, more specifically, the third part 530 c of the lower main body 530 when lowered. This impact results in a tensile force on the specimen 501.

If the lower body 540 is a form that can be easily raised and lowered, it is not limited to the example shown in Figures 4 and 5 may have a variety of forms. However, the lower body 540 has a surface in contact with the lower grip 530 when lowered, corresponding to the upper surface of the third portion 530c of the lower grip, as shown in the example shown in FIG. It is desirable to.

The load sensing unit 550 senses a tensile load acting on the specimen 501 when the lower body 540 impacts the lower grip 530. 4 and 5 illustrate an example in which the load sensing unit 550 is disposed on the upper body 520, but is not necessarily limited thereto.

In the case of the present invention, in order to make a high speed, it is common to the point that the lower body is repeated by lifting and lowering using a hydraulic cylinder or the like.

However, in the case of the present invention, the specimen is in a state of being fixed to the lower grip from the beginning of the test. Therefore, it is possible to prevent occurrence of friction or slippage between the specimen and the lower grip during the impact of the lower body and the lower grip due to the lowering of the lower body. Therefore, the high speed tensile test can be performed stably and reliably from the beginning.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill 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 appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

501 Psalm 520 Upper Grip
530: lower grip 530a: first part
530b: second part 530c: third part
535: damper 540: lower body
550: load detection unit

Claims (6)

delete delete An upper grip securing the top of the specimen;
A lower grip fixing a lower portion of the specimen and having a damper formed thereon;
A lower main body repeating the ascending and descending and impacting the damper of the lower grip when descending; And
And a load sensing unit configured to sense a tensile load acting on the specimen when the lower main body impacts the damper of the lower grip.
The lower grip may include a first portion for fixing the specimen, a second portion extending downward from the first portion, and a third portion positioned at the end of the second portion and impacted when the lower body is lowered. To include, wherein the first portion is disposed outside the lower body, the damper is formed on the upper surface of the third portion of the lower grip, the upper surface of the third portion is formed to have an inclined surface,
The tensile force is applied to the specimen by the impact received when the lower body descends, and the vibration generated during the impact by the damper is suppressed.
delete delete A high-speed tensile test method using the high-speed tensile tester according to claim 3, applying a tensile force to a specimen fixed to the lower grip by applying an impact to the lower grip while repeatedly raising and lowering the lower body.

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