KR102292331B1 - High Temperature Tensile Correction Jig Enabling Axis Alignment to High Tensile Test Specimens - Google Patents

Abstract

A high-temperature tensile compensation jig for axial alignment according to the present invention includes a pair of jig grips for gripping both sides of a tensile test specimen, wherein the pair of jig grips includes a fixed grip for gripping one side of the tensile test specimen; and a moving part grip for gripping the other side of the tensile test specimen in a state in which it is disposed against the fixed part grip based on the tensile test specimen, wherein the pair of jig grips are each inserted into the tensile test specimen It includes a jig body in which a fixing chamber is formed, a cover part detachably coupled to the fixing chamber, and a fastening member having a function of binding the jig body and the cover part, and a tensile test specimen bitten by the fixing part grip. It is characterized in that the center of one side and the center of the other side of the tensile test specimen bitten by the grip of the moving part are aligned to prevent non-uniform deformation of the tensile test specimen during the test through the high temperature tensile correction jig.

Description

High Temperature Tensile Correction Jig Enabling Axis Alignment to High Tensile Test Specimens

The present invention relates to a high-temperature tension correction jig, and more particularly, when a position change is performed in a state of holding a specimen applied for a tensile test using a fixed grip and a moving grip, both sides of the specimen It relates to a high temperature tension compensating jig that performs axial alignment while aligning the center.

Thermal material testing, such as compression and tension, is a useful method to evaluate material properties in a high-temperature environment, and can measure changes in various properties such as temperature, load, displacement, and time. The high-temperature tensile test is a useful method for evaluating the static load capacity of a material under tensile load for a short period of time. Relative measurements between different materials can be made, and the values for local stress concentrations and stress excesses are accommodated. In the case of thermal material testing, the deformation behavior characteristics of specimens are generally sensitive to strain rate and temperature, so care must be taken when testing.

The Gleeble 3800-GTC, a specific equipment for analyzing the deformation behavior of specimens in such a thermal environment, has windows installed in the front and rear directions of the test chamber to facilitate observation of deformation behavior during material testing in a high-temperature environment, and a semi-high-speed camera. It is possible to use DIC (OMA-GOM's ARAMIS) equipment, which is a deformation behavior measuring equipment that uses

However, in the case of a specimen having a polygonal shape, when an experiment is performed using an existing jig, the observed cross-section of the specimen is oriented in the up/down direction of the chamber, and the deformation of the target cross-section using the DIC equipment through the windows located in the front/rear direction It becomes difficult to observe the behavior.

The correction jig proposed to solve the above difficulties uses the existing jaws as it is, and improves the specimen mounting part of the correction jig to correct the target specimen cross-section in the front/rear direction of the chamber. However, when the jig is rotated 90 degrees, the load acting up and down the specimen observation section disappears, which makes it difficult to fix the specimen and align the axis. Maintaining the specimen's fixation and axial alignment is one of the important factors in the axial load test, and if the centers are not aligned, the deformation of the material becomes non-uniform, which is directly related to the reliability of the test.

Axial alignment is maintained only when the center of the specimen bitten by the grip of the fixed part and the center of the specimen bitten by the grip of the moving part are aligned. It could be an important technical issue.

Referring to the existing Korean Patent Nos. 10-1267711 and No. 10-1510606, technical details regarding a jig for aligning a tensile specimen capable of aligning the tensile specimen are provided.

(Patent Document 1) KR 10-1267711 B

(Patent Document 1) KR 10-1510606 B

The present invention provides axial alignment while aligning the centers of both sides of the specimen when a load is applied to a specimen applied for a tensile test for improved observation of a fracture cross section of a material in a state of being gripped using a fixed grip and a moving grip. It is to provide a high-temperature tension correction jig that makes it possible.

A high-temperature tensile correction jig for axial alignment according to the present invention for achieving the above object includes a pair of jig grips for gripping both sides of a tensile test specimen, and the pair of jig grips is the Fixed grip gripping one side; and a moving part grip for gripping the other side of the tensile test specimen in a state in which it is disposed against the fixed part grip based on the tensile test specimen, wherein the pair of jig grips are each inserted into the tensile test specimen It includes a jig body in which a fixing chamber is formed, a cover part detachably coupled to the fixing chamber, and a fastening member having a function of binding the jig body and the cover part, and a tensile test specimen bitten by the fixing part grip. It is characterized in that the center of one side and the center of the other side of the tensile test specimen bitten by the grip of the moving part are aligned to prevent non-uniform deformation of the tensile test specimen during the test through the high temperature tensile correction jig.

The jig body has an overall quadrangular truncated cone shape in which the cross-sectional area of the pair of jig grips tends to increase from one side facing each other to the other side.

When the cover part is coupled in a state where the tensile test specimen is inserted into the jig body, a plurality of buffer spaces are formed on both sides based on the tensile test specimen, and the plurality of buffer spaces are tensioned through the jig body and the cover part. While holding the test specimen, hollow buffer spaces formed on both sides of the tensile test specimen are formed.

As described above, the high-temperature tensile correction jig that enables axial alignment according to the present invention is a specimen applied for a tensile test for improving the observation of fractured cross-sections of materials in a state of being held using a fixed grip and a moving grip. When performing a position change, the axis alignment is performed while aligning the centers of both sides of the specimen.

That is, the high-speed camera measurement is facilitated through the rotation of the tensile grip gripping both sides of the test specimen.

The present invention improves the reliability of the test by uniformly aligning the centers of both sides of the specimen through stable fixation of the specimen for tensile test and maintaining axial alignment, thereby making the deformation of the material uniform.

1 shows a jig body constituting a pair of grips constituting a high-temperature tensile compensating jig.
2 shows the shape of the cover part detachably coupled to the fixing chamber formed in the jig body.
3 shows a state in which a tensile test specimen is fastened on a high-temperature tensile compensating jig.
Figure 4 shows a state in which the coupling portion of the specimen is projected in a state in which the tensile test specimen is fastened on the high-temperature tensile compensating jig.
5 shows an improved stress distribution state through axial alignment and load distribution in the process of providing a load to a tensile test specimen through a high-temperature tensile compensating jig.
6 shows a measuring chamber in which a high-temperature tensile compensating jig according to the present invention is installed.
7 shows a state in which a tensile test specimen is held in a measurement chamber using a conventional high-temperature tensile correction jig.
8 shows a state in which a tensile test specimen is held in a measurement chamber using a high-temperature tensile compensating jig according to the present invention.

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 embodied in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art It is provided for complete disclosure. In the drawings, like reference numerals refer to like elements.

In this specification, the high-temperature tensile correction jig according to the present invention is installed and used in a tensile tester as an example, but the present invention is not limited thereto. It also belongs to the present invention to be installed and used in all devices for fixing the specimen, such as a testing machine other than a tensile testing machine.

Hereinafter, a high-temperature tensile correction jig installed and used in a tensile tester will be described with reference to the drawings.

The high-temperature tensile correction jig 10 constituting the tensile tester to enable axial alignment of the tensile test specimen in the present invention includes a pair of jig grips 100 and 200 for gripping both sides of the tensile test specimen.

A pair of jig grips 100 and 200 includes a fixed grip 100; and a moving part grip 200 for holding the other side of the tensile test specimen in a state in which it is arranged to oppose the fixed part grip based on the tensile test specimen. The fixed part grip and the moving part grip are symmetrical to each other.

Hereinafter, the fixed part grip 100 will be mainly described, and the moving part grip will be replaced with the description of the fixed part grip.

The fixing part grip 100 includes a jig body 110 in which a fixing chamber 120, which is a space into which the tensile test specimen 1 is inserted, is formed, and a cover part 130 detachably coupled to the fixing chamber 120. and a fastening member 140 serving to bind the jig body 110 and the cover part 130 .

Stable alignment is performed by aligning the center of one side of the tensile test specimen (1) bitten by the fixed part grip (100) and the center of the other side of the tensile test specimen (1) bitten by the moving part grip (200), and a high-temperature tensile correction jig is applied. Prevents non-uniform deformation of tensile test specimens during testing.

The jig body 110 may have an overall shape such that the pair of jig grips 100 and 200 have a quadrangular truncated pyramid shape in which the cross-sectional area tends to gradually increase from one side facing each other to the other side. That is, starting from a rectangular bottom surface having a relatively narrow cross-section, the cross-sectional area may be gradually increased while maintaining the rectangular cross-section at a more uniform ratio.

When the cover part 130 is coupled in a state in which the tensile test specimen 1 is inserted into the jig body 110, a plurality of buffer spaces 115 and 135 are formed on both sides of the tensile test specimen as a reference.

The plurality of buffer spaces 115 and 135 refer to hollow buffer spaces formed on both sides of the tensile test specimen in a state in which the tensile test specimen is gripped through the jig body 110 and the cover portion 130. A pair of buffer spaces are formed on both sides, respectively.

Specifically, the jig body 110 includes a plurality of first contact surfaces 111 and a plurality of first contact surfaces 111 and a plurality of spaced apart formed on the inner surface of the jig body such that one surface of the tensile test specimen is placed on the fixed chamber 120, which is a space into which the tensile test specimen is inserted. A plurality of first buffer spaces 115 are formed between the first contact surfaces 111 to form a groove on the inside of the jig body, and at the same time, a coupling hole 116 that is screwed so that the ends of the fastening members are coupled. The first buffer space 115 may be formed to be longer than the width direction of the plurality of first contact surfaces 111 .

The plurality of first buffer spaces 115 are spaces in contact with one side of the tensile test specimen held through the jig body 110 and the cover part 130, and are spaced from the first contact surface 111 of the jig body. It is a space in which a groove is formed inside the body.

A vertical length of the buffer space may be formed to be longer than a length direction of the plurality of first contact surfaces.

It may be preferable that the plurality of first buffer spaces 115 are formed such that the width of the pair of jig grips 100 and 200 becomes gradually smaller from one side to the other side of the jig body 110 facing each other. That is, as an example, the widths of the pair of buffer spaces constituting the plurality of first buffer spaces 115 may be d1 and d2, respectively, and d1 is set to be larger than d2. In addition, in the case of the coupling holes 116 screw-formed in the plurality of buffer spaces 115 , the width of the coupling holes 116 gradually decreases from one side of the jig body 110 to the other side.

On the other hand, a hemispherical free space 113 is formed on the inner surface of the jig body 110 in the upper and lower portions of the fixing chamber 120 .

On the other hand, even in the case of the cover part 130, it may be a space in which a groove is formed inside the cover part from the surface where the other end surface of the tensile test specimen abuts.

The cover part 130 is fastened at the same time that a groove is formed on the inside of the cover part 130 between the plurality of second contact surfaces 131 and the plurality of second contact surfaces 131 spaced apart so that the other surface of the tensile test specimen is placed. It includes a plurality of second buffer spaces 135 in which the through-holes 136 are formed so that members can be coupled to each other.

It may be preferable that the plurality of second buffer spaces 135 are formed to have a width gradually decreasing from one side to the other side. That is, as an example, the widths of a pair of buffer spaces constituting the plurality of second buffer spaces may be d1 and d2, respectively, and d1 is set to be larger than d2. In addition, in the case of the through-holes 136 formed in the plurality of second buffer spaces 135 , the widths of the through-holes 136 are also formed to gradually decrease from one side of the jig body 110 to the other side.

As described above, upon coupling between the jig body 110 and the cover part 130, a pair of buffer spaces arranged in the direction from the center to the end of the tensile test specimen are arranged in a shape in which the width gradually becomes narrower. Through this, it is possible to stably grip the tensile test specimen.

The fastening member 140 is inserted through the through hole 136 formed in the cover 130 in a state in which the tensile test specimen is inserted between the jig body 110 and the cover 130, and at the same time the tensile test specimen is inserted. It is screwed into the coupling hole 115a formed in the jig body 110 through the specimen fixing hole 3 formed in (1). On the through hole formed in the cover part, a dowel pin function is performed through counterbore processing.

The fastening member 140 is in the form of a hexagon socket head cap screw (M6, BS 4168) that enables the fixing of the cover part 130 to the jig body 110 and the axial alignment of the tensile test specimen 1 . Through this, the plate specimen bitten by the pair of jig grips 100 and 200 is aligned in the axial direction in a state in which the vertical load received from the existing grip is divided by the pair of dowel pins, and the load received from one existing dowel pin is divided into two to improve the stress distribution.

5 shows an improved stress distribution state through axial alignment and load distribution in the process of providing a load to a tensile test specimen through a high-temperature tensile compensating jig.

It can be seen that the stress gradually increases symmetrically and uniformly from both ends to the center of the tensile test specimen held through a pair of grips. That is, the high-temperature tensile correction jig of the present invention prevents non-uniform stress fluctuations in a state in which axial alignment is performed with respect to the held tensile test specimen.

As described above, the high-temperature tensile correction jig that enables axial alignment according to the present invention is in the state of holding the specimen applied for a tensile test to improve the observation of fractured cross-sections of a material using a fixed grip and a moving grip. When performing a position change, the axis alignment is performed while aligning the centers of both sides of the specimen.

6 shows a measuring chamber in which a high-temperature tensile compensating jig according to the present invention is installed. 7 shows a state in which a tensile test specimen is held in a measurement chamber using a conventional high-temperature tensile correction jig. 8 shows a state in which a tensile test specimen is held in a measurement chamber using a high-temperature tensile compensating jig according to the present invention.

In the past, when measuring the cross section of the tensile test specimen through the monitoring window 11 installed in the front of the measurement chamber 10, only the narrow side of the test specimen was checked as shown in FIG. 7, which made it difficult to measure.

As shown in FIG. 8, the wide surface of the test specimen is checked using the high-temperature tensile compensating jig according to the present invention, so that the deformation behavior of the target cross-section can be observed smoothly.

The high-temperature tensile compensation jig that enables axial alignment according to the present invention changes the position of a specimen applied for a tensile test to improve the observation of fractured cross-sections of materials in a state of being gripped using a fixed grip and a moving grip. In this case, axial alignment is performed while aligning the centers of both sides of the specimen.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: high temperature tension correction jig
100,200: jig grip
110: jig body
120: fixed chamber
130: cover part
140: fastening member

Claims (3)

In the high-temperature tensile correction jig constituting the tensile tester to enable axial alignment of the tensile test specimen,
The high-temperature tensile correction jig includes a pair of jig grips for gripping both sides of the tensile test specimen,
The pair of jig grips includes a fixed grip for gripping one side of the tensile test specimen; and a moving part grip for gripping the other side of the tensile test specimen in a state in which it is disposed to face the fixed part grip based on the tensile test specimen;
Each of the pair of jig grips,
It includes a jig body in which a fixing chamber, which is a space into which the tensile test specimen is inserted, is formed, a cover part detachably coupled to the fixing chamber, and a fastening member having a function of binding the jig body and the cover part,
When the cover part is coupled in a state where the tensile test specimen is inserted into the jig body, a plurality of buffer spaces are respectively formed on both sides based on the tensile test specimen, and when the jig body and the cover part are coupled, a tensile test specimen is formed. A plurality of buffer spaces arranged in the direction from the center to the end of the
A hemispherical free space is formed on the inner surface of the jig body on the upper and lower parts of the fixing chamber,
The fastening member is inserted through a through hole formed through counterbore processing in the cover portion, and at the same time passes through a specimen fixing hole formed in a tensile test specimen and is screwed into a coupling hole formed in the jig body, on the fixing chamber Pairs are arranged in a line along the longitudinal direction of the tensile test specimen to enable axial alignment of the tensile test specimen,
The center of one side of the tensile test specimen bitten by the grip of the fixed part and the center of the other side of the tensile test specimen bitten by the grip of the moving part are aligned to prevent non-uniform deformation of the tensile test specimen during testing through the high-temperature tensile correction jig. characterized by,
High temperature tension correction jig.
The method of claim 1,
The jig body has an overall quadrangular truncated shape in which the cross-sectional area tends to gradually increase from one side of the pair of jig grips facing each other to the other side,
High temperature tension correction jig.
The method of claim 1,
The plurality of buffer spaces form hollow buffer spaces formed on both sides of the tensile test specimen in a state of holding the tensile test specimen through the jig body and the cover portion,
High temperature tension correction jig.

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