KR20200062798A - Test device for metallic materials resistant to hydrogen embrittlement - Google Patents

Abstract

Disclosed is a test device for hydrogen embrittlement of metal. According to the present invention, the test device for hydrogen embrittlement of metal comprises: a housing in which a circular space unit is formed to be opened on one side in the housing, and an installation hole is formed on the floor; a sample fixing member in which one end of a metal test sample is fixed on one end, and which is fixed on and coupled to the installation hole so that one end of the sample fixing member is located in the space unit and the other end is located outside the housing; a piston which is movably installed in the space unit by being configured such that the other end of the metal test sample is fixed in an area facing the sample fixing member; a cover member which is coupled to the housing to close the space unit; and a connection member of which one end is maintained airtight to penetrate the cover member and then, be coupled to the piston, and the other end is located outside the cover member to be connected to a tension tester. A tension test can be conducted on the metal test sample in a hydrogen atmosphere by connecting the other end of the connection member to one side of the tension tester or connecting the other end of the connection member to one side of the tension tester, connecting the other end of the sample fixing member to the other side of the tension tester, and then supplying hydrogen to the space unit. According to the present invention, the tension of the metal test sample can be conducted by installing the metal test sample in the housing and supplying high-pressure hydrogen to the space unit of the housing such that changes in the characteristics of the metal can be measured in the hydrogen atmosphere.

Description

Metallic hydrogen embrittlement tester {TEST DEVICE FOR METALLIC MATERIALS RESISTANT TO HYDROGEN EMBRITTLEMENT}

The present invention relates to a hydrogen embrittlement test apparatus for metal, and more specifically, it is possible to measure a change in properties of a metal generated by embrittlement of a metal at a high temperature or high pressure gas or a low temperature and high pressure gas, and control the temperature inside the housing. The present invention relates to a hydrogen embrittlement test apparatus for metals that can significantly reduce the weight, volume, and accessories of the test apparatus, shorten the installation time, and reduce the risk of gas leakage.

In general, metal materials exposed to high-pressure hydrogen or liquid hydrogen are damaged by the metal structure due to the penetration of hydrogen into the metal and the formation of air bubbles accompanying reactions with impurities or impurities. For direct measurement of the degree of damage, it is common practice to perform a material dynamics test in a hydrogen atmosphere. That is, the test piece is mounted in a container in which a high-pressure hydrogen atmosphere is formed, and both ends of the test piece are engaged with a push-pull rod to transmit a compressive or tensile load to the test piece from an all-round material tester. The form is common.

The push-pull rod of a container containing high-pressure hydrogen gas is equipped with the load generated by the material tester without loss of load due to friction between the container and the rod in a well-sealed state with an O-ring or sealant. It is necessary to transmit to the test piece, and when load loss is unavoidable, compensation for the load is required. Therefore, in order to perform a high pressure test of 100MPa or more due to the conflict between precise mechanical load transmission and airtightness problems, a system such as an autoclave of an expensive all-purpose tester fusion type or complicated test equipment such as high hydrogen pressure and precision control of mechanical load and Techniques are needed.

As a solution to this, studies have been conducted to examine the behavior of the test specimen after charging a small amount of hydrogen using the ampoule test specimen. However, when using such a conventional hydrogen-filled ampoule type test piece, the inner surface of the test piece interacts with hydrogen gas, but the outer surface is exposed in the air, and thus has a disadvantage in that a deformation behavior different from that of a hydrogen atmosphere appears.

In addition, as shown in FIGS. 1 and 2, because the size of the autoclave is very large, the preparation time for the test is very long and dangerous, and also because of the large volume of the autoclave, the risk of leakage occurring in the sealing area is also The autoclave with a large and complex structure has a problem of replacing expensive consumables due to frequent repairs.

As a conventional technique for solving this problem, Korean Registered Patent No. 10-1154189 (announcement date: June 18, 2012) discloses an ampoule test piece with a built-in linear hydrogen material and a tensile test method using the same. There was a problem in that the temperature could not be set, and the pressure or leak of the supplied gas could not be detected.

. Korea Registered Patent No. 10-1154189 (Announcement date: 2012.06.18)

An object of the present invention is a hydrogen embrittlement test of a metal capable of tensile testing a metal test specimen exposed to a hydrogen atmosphere so that high-temperature high-pressure hydrogen or low-temperature high-pressure hydrogen is embrittled in the metal to measure changes in properties of the metal. It is intended to provide a device.

Another object of the present invention is to provide a hydrogen embrittlement test apparatus for a metal having a simple structure, which can improve assembly properties and control the temperature inside the housing.

In addition, the problems to be solved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly understood by those skilled in the art from the following description. Will be understandable.

The object is, in accordance with the present invention, the interior is formed so that the circular space portion is opened to one side, the housing is formed with an installation hole on the bottom; A specimen fixing member configured to be fixed to one end of the metal test specimen at one end and fixedly coupled to the installation hole so that one end is located in the space portion and the other end is located outside the housing; A piston configured to be fixed to the other end of the metal test specimen in an area facing the specimen holding member and movably installed in the space portion; A cover member coupled to the housing to close the space portion; And a connecting member having one end through which the cover member passes through the cover member to be coupled to the piston, and the other end is located outside the cover member to be connected to the tensile tester, and the other end of the connecting member is attached to one side of the tensile tester. And connect the other end of the connecting member to one side of the tensile tester, connect the other end of the specimen fixing member to the other side of the tensile tester, and supply hydrogen to the space to supply the metal test specimen in a hydrogen atmosphere. It is achieved by a hydrogen embrittlement test apparatus of a metal, characterized in that it can be subjected to a tensile test.

A flow path for a heat medium is formed in the housing, and an inlet and an outlet of the flow path are connected to a heat exchanger, and a heat medium oil circulates through the flow path through operation of the heat exchanger to adjust the test temperature in the space. .

A gas supply nozzle for supplying hydrogen to the space part is installed through the housing, and a pressure sensor may be provided in the gas supply nozzle.

In the housing, a temperature sensor for sensing the temperature of the space portion to adjust the test temperature in the space portion may be installed through.

In the piston, a balance hole is formed to apply the same pressure to both sides of the piston when hydrogen is supplied to the space at a high pressure, and the balance hole is such that the space and the inside of the cover member communicate with each other. It can be formed through the piston.

In the cover member, a gas detection passage for sensing hydrogen exposed inside the cover member may be provided.

According to the present invention, after installing the metal test specimen inside the housing, by supplying high-pressure hydrogen to the space portion of the housing to tension the metal test specimen in a hydrogen atmosphere, it is possible to measure the change in the properties of the metal exposed to the hydrogen atmosphere. It is possible to provide an effect.

In addition, by circulating the heat medium oil inside the housing, it is possible to control the temperature of the space portion where the metal test specimen is located. That is, it is possible to provide an effect of increasing the accuracy of the test by arbitrarily adjusting the test temperature of the metal test specimen.

In addition, the cover member is provided with a gas detection passage capable of detecting hydrogen, thereby detecting hydrogen leaking from the space and ending the test when the amount of leakage is detected, thereby providing an effect of improving safety. .

In addition, the hydrogen embrittlement test apparatus of the metal according to the present invention has a simple structure, and it is possible to provide an effect of easy operation, such as easy assembly and easy replacement.

1 and 2 is a photograph showing a tensile test apparatus according to the prior art.
Figure 3 is an exploded perspective view showing a metal hydrogen embrittlement test apparatus according to the present invention.
Figure 4 is a perspective view of the bonding state of the hydrogen embrittlement test device of the metal shown in FIG.
5 is a cross-sectional view taken along line AA in FIG. 4.
6 is a schematic cross-sectional view for explaining the operation of the hydrogen embrittlement test apparatus of the metal shown in FIG. 3.
7 is a block diagram illustrating the operation of the hydrogen embrittlement test apparatus of the metal shown in FIG. 3.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

In addition, the terminology used herein is for describing the embodiments and is not intended to limit the present invention. In the present specification, the singular form also includes the plural form unless otherwise specified in the phrase. As used herein,'comprises' and/or'comprising' does not exclude the presence or addition of one or more other components.

Among the accompanying drawings, FIG. 3 is an exploded perspective view showing a metal hydrogen embrittlement test apparatus according to the present invention, FIG. 4 is a perspective view of a metal hydrogen embrittlement test apparatus shown in FIG. 2, and FIG. 5 is FIG. 4 It is a cross section of AA line.

3 to 5, the metal's hydrogen embrittlement test apparatus 10 according to the present invention supplies high-temperature high-pressure hydrogen or low-temperature high-pressure hydrogen to the space where the metal test specimen 100 is installed to test the metal. To test the hydrogen embrittlement of the metal test specimen 100 by conducting a tensile test in a state where (100) is exposed to hydrogen, the circular space portion 22 is formed inside to open to one side, and installed on the floor The housing 20 is provided with a ball 24, and one end of the metal test specimen 100 is fixed at one end so that one end is located in the space 22 and the other end is located outside the housing 20. 24) is a piston that is fixedly coupled to the specimen holding member 70 and the other end of the metal test specimen 100 is fixed to the region facing the specimen holding member 70 so as to be movably installed in the space 22 30, the cover member 40 coupled to the housing 20 so as to close the space 22, and one end is airtight and coupled to the piston 30 through the cover member 40, the other end Is located outside the cover member 40 and includes a connecting member 50 connected to the tensile tester 200.

The hydrogen embrittlement test apparatus 10 of such a metal will be described in more detail.

The housing 20 is to support each component and to allow the piston 30 and the connecting member 50 to linearly move in the space portion 22, and the circular space portion 22 is disposed on one side. It is formed to be open, and an installation hole 24 is formed at the bottom.

In this housing 20, as shown in FIGS. 3 to 5, a flow path 26 for circulating the heat medium is formed. The flow path 26 is formed to circulate the heat medium oil for raising or lowering the temperature of the space portion 22. And the inlet and outlet of the flow path 26 is connected to the heat exchanger 300. When the heat exchanger 300 is operated by the flow path 26, the heat medium oil circulates through the flow path 26 to control the test temperature in the space 22. At this time, when the heat exchanger 300 lowers the temperature of the heat medium oil, the temperature of the space part 22 will be lowered to the set temperature, and when the temperature of the heat medium oil is increased, the temperature of the space part 22 will be increased to the set temperature. .

The housing 20 is provided with a temperature sensor 60 for measuring the temperature in the space 22, as shown in FIG. The temperature sensor 60 is installed to penetrate the housing 20 so that the sensing end is exposed to the space 22.

Meanwhile, as illustrated in FIGS. 5 and 7, when the above-described temperature sensor 60 senses the temperature of the space 22, the control unit 90 receives the temperature detection signal sensed by the temperature sensor 60. Based on this, the heat exchanger 300 can be controlled. That is, it is possible to increase or decrease the temperature of the space portion 22 by controlling the heat exchanger 300 based on the temperature value of the space portion 22 sensed by the temperature sensor 60, and the metal test by this configuration It is possible to control the test temperature of the specimen 100.

A gas supply nozzle for supplying high-temperature high-pressure hydrogen or low-temperature high-pressure hydrogen (limited to hydrogen in this embodiment, but not limited thereto, and various gases may be applied) to the housing 20 ( 80) is installed through. The gas supply nozzle 80 is for pressurizing the high temperature high pressure hydrogen or the low temperature high pressure hydrogen supplied from the hydrogen supply unit (not shown) to the space portion 22. In addition, the gas supply nozzle 80 is provided with a pressure sensing sensor 82 for sensing the pressure of hydrogen supplied or the pressure in the space 22.

The specimen fixing member 70 is for fixing one end of the metal test specimen 100, and a fixing groove 72 is formed at one end 74 so that one end of the metal test specimen 100 is fixed, and the fixing groove ( 72) is formed is one end 74 is located in the space portion 22, the other end 76 is fixedly coupled to the installation hole 24 to be located outside of the housing 20. The specimen fixing member 70, one end 74 is made of a cylindrical shape, the other end 76 is formed with a smaller diameter than the one end 74, the outer peripheral surface of the other end 76 is formed with a thread, the housing 20 After being inserted through the space portion 22 inlet, the other end 76 penetrates the installation hole 24 and is exposed to the outside, and is fixedly coupled to the housing 20 by a nut 78. And, an airtight packing is installed between the inner circumferential surface of the installation hole 24 and the outer circumferential surface of the other end 76. At this time, the metal test specimen 100 is fixed to the fixing hole 72 of the specimen fixing member 70 by various fixing means.

Meanwhile, one end of the metal test specimen 100 may be coupled by being fastened to a fixing groove 72 formed at one end 74 of the specimen fixing member 70.

The specimen holding member 70 configured as described above may or may not be fixed to the tensile testing device 200 by the fixing means.

The piston 30 is installed in the space portion 22 to allow reciprocating motion in a linear direction from the space portion 22 of the housing 20, and a metal test specimen (in the region facing the specimen fixing member 70) It is configured to be fixed to the other end of 100) is installed to be movable in the space portion (22). An airtight packing is installed on the outer circumferential surface of the piston 30. Then, the other end of the metal test specimen 100 is inserted into the center of the surface facing the specimen holding member 70 to form a fixing groove 32 to be fixed, and one end of the connecting member 50 is provided in the center of the opposite side. A coupling groove 34 for inserting and fixing is formed. At this time, the other end of the metal test specimen 100 may be fastened by being fixed to the fixing groove 32 of the piston 30, and one end of the connecting member 50 may be fastened to the coupling groove 34 to be coupled.

Further, in the piston 30, a balance hole 36 for dispersing the pressure acting on the piston 30 when hydrogen is supplied to the space portion 22 at a high pressure, the space portion 22 and the cover member 40 It is formed to penetrate through the interior of the. That is, in the state where the tensile tester 200 is not operated, the high pressure hydrogen supplied to the space portion 22 acts only on one surface (the side of the installation hole) of the piston 30 to cover the piston 30, the cover member 40 Since it is in a state of applying pressure pushing toward the side, in order to solve this, the high pressure hydrogen gas supplied to the space part 22 is formed by penetrating the balance hole 36 in the direction in which the connecting member 50 pulls on the piston 30. It moves to the inside of the cover member 40 through the balance hole 36 so that pressure is applied to the other surface of the piston 30. Therefore, since the pressure inside the space portion 22 and the cover member 40 is the same, so that the pressure applied to both sides of the piston 30 is the same, the piston 30 can achieve a force balance. Accordingly, the tensile test of the metal test specimen 100 with the tensile tester 200 can be performed more accurately.

The cover member 40 is coupled to the inlet side of the space portion 22 of the housing 20 to close the space portion 22. Since the cover member 40 is fastened and coupled to the housing 20, it can be easily assembled and disassembled, and an airtight packing is installed between the end face of the housing 20 and the inner surface of the cover member 40. . Since the cover member 40 is coupled to the housing 20, the separation of the piston 30 installed in the space 22 is prevented.

In the above-described cover member 40, a through hole 48 for penetrating the connecting member 50 is formed in the center. It is natural that the through-hole 48 is provided with an airtight packing. In addition, a gas detection passage 42 is provided for detecting hydrogen that is excessively exposed from the space portion 22 into the cover member 40. The gas detection passage 42 is connected to a gas detection sensor 44 (gas detector). Therefore, when the gas detection sensor 44 detects hydrogen exposed inside the cover member 40, the tensile test can be terminated to ensure safety. In other words, hydrogen supplied to the space 22 through the balance hole 36 flows into the inside of the cover member 40. However, when more than a predetermined amount of hydrogen flows into the inside of the cover member 40, the gas detection sensor 44 can detect this and terminate the tensile test.

The connecting member 50 is for connecting the piston 30 and the tensile tester 200, one end of which is airtight and coupled to the piston 30 through the cover member 40, and the other end of the cover member ( 40) is located outside and is connected to the tensile tester (200). It is natural that an airtight packing is installed on the outer circumferential surface of the connecting member 50 and the movable area of the cover member 40.

Since the above-described tensile testing apparatus 100 is a known technique, detailed description thereof will be omitted.

Hereinafter, the operation of the metal hydrogen embrittlement test apparatus 10 will be described.

First, one end of the metal test specimen 100 is coupled to the specimen holding member 70, the other end is coupled to the piston 30, and then inserting the specimen holding member 70 into the space 22 to install the hole (24 ) So that the other end 76 is exposed. A nut is fastened to the other end 76 exposed to the outside of the housing 20 through the installation hole 24 to firmly fix the specimen fixing member 70 to the housing 20.

Subsequently, the connecting member 50 is fixed to the opposite surface of the piston 30 (the surface facing outward based on the space portion). At this time, the connecting member 50 may be assembled to the piston 30 before inserting the piston 30 into the space 22.

When assembly of the piston 30 to which the metal test specimen 100 is coupled and the specimen holding member 70 is completed, the cover member 40 is fastened to the housing 20 to be coupled. At this time, the other end of the connecting member 50 is exposed to the outside.

Meanwhile, the temperature sensor 60 and the gas supply nozzle 80 are installed in the housing 20, and the pressure sensor 82 is installed in the gas supply nozzle 80.

In addition, the gas detection passage 42 of the cover member 40 is connected to the gas detection sensor 44, and the flow path 26 is connected to each line of the heat exchanger 300.

In this process, the assembly of the metal's hydrogen embrittlement test apparatus 10 is completed. The assembly has a small number of components of the metal hydrogen embrittlement test apparatus 10 and is compact and the assembly structure is simple, so the installation or assembling of the metal test specimen 100 can be quickly and easily performed.

Subsequently, the other end of the connecting member 50 is fixed to one side (the upper part based on FIG. 5) of the tensile testing machine 200, and the other end 76 of the specimen fixing member 70 is the other side of the tensile testing machine 200 ( It is connected to the lower part based on FIG. 5 to install the hydrogen embrittlement test device 10 of the metal on the tensile tester 200.

In this embodiment, the connecting member 50 and the specimen fixing member 70 are respectively fixed to the upper and lower portions of the tensile tester 200, but are not limited thereto, and the fixed position according to the structure of the tensile tester 200. May vary. That is, after connecting the other end of the connecting member 50 to the top of the tensile tester 200, the jig or the like supports the cover member 40 to a part of the tensile tester 200, and the other end of the specimen fixing member 70 ( 76) may be carried out a tensile test by tensioning the connecting member 50 in the unfixed state.

When the installation of the hydrogen embrittlement test apparatus 10 of the metal is completed through the above-described process, as shown in FIGS. 6 and 7, the heat exchanger 300 is operated to allow the heat medium to circulate through the flow path 26, thereby The temperature of the space 22 where the test specimen 100 is located is raised or lowered to a set temperature. This can be achieved by controlling the circulation of the heat medium by controlling the heat exchanger 300 by the control unit 400 based on the temperature value of the space 22 detected by the temperature sensor 60.

When the temperature of the space portion 22 is set to the test temperature and reaches the set temperature, the gas supply nozzle 80 is opened to supply high-pressure hydrogen to the space portion 22 to expose the metal test specimen 100 to hydrogen. The space portion 22 is formed in a hydrogen atmosphere.

Subsequently, the tensile tester 200 is operated to cause the tensile tester 200 to pull the connecting member 50.

In this process, the metal test specimen 100 located in the space 22 can be subjected to a tensile test in a state of being exposed to high pressure hydrogen. Of course, a tensile test may be performed after a predetermined time has elapsed in a hydrogen atmosphere.

On the other hand, when the tensile strength of the metal test specimen 100 is broken by the operation of the tensile tester 200, the damage behavior of the metal test specimen 100 is measured in a small atmosphere of the metal test specimen 100.

In the process of the above-described test, when the hydrogen leaks into the gas detection passage 42, the gas detection sensor 44 detects it. The control unit 400 terminates (stops) the tensile test when the gas detection sensor 44 detects hydrogen.

As described above, the hydrogen embrittlement test apparatus 10 of the metal according to the present invention, the specimen fixing member 70 and the metal test specimen 100, the piston 30 and the connecting member 50 are assembled one by one and the housing ( 20) is installed inside, fixing the specimen holding member 70 to the housing 20 with a nut, and the assembly process of coupling the cover member 40 to the housing 20 can be quickly and easily performed. In addition, by circulating the heat medium oil in the flow path 26 of the housing 20, the test temperature of the space portion 100 in which the metal test specimen 100 is located can be adjusted, thereby allowing the metal test specimen 100 to be more accurately within a hydrogen atmosphere. The tensile test of

In the foregoing, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and it is common knowledge in the field of this technology that various modifications and modifications can be made without departing from the spirit and scope of the present invention. It is obvious to those who have it. Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should belong to the claims of the present invention.

10: metal hydrogen embrittlement test apparatus 20: housing
22: space 24: installer
26: Euro
30: piston 36: balance hole
40: cover member 50: connecting member
100: metal test specimen 200: tensile tester
300: heat exchanger 400: control unit

Claims (6)

It is formed so that a circular space part is opened to one side inside, and a housing is formed with an installation hole at the bottom;
A specimen fixing member configured to be fixed to one end of the metal test specimen at one end and fixedly coupled to the installation hole so that one end is located in the space portion and the other end is located outside the housing;
A piston configured to be fixed to the other end of the metal test specimen in an area facing the specimen holding member and movably installed in the space portion;
A cover member coupled to the housing to close the space portion; And
Once this is kept airtight and coupled to the piston through the cover member, the other end is located outside the cover member and includes a connecting member connected to a tensile tester,
Connect the other end of the connecting member to one side of the tensile tester, or connect the other end of the connecting member to one side of the tensile tester, connect the other end of the specimen fixing member to the other side of the tensile tester, and then add hydrogen to the space. Characterized in that it is possible to perform the tensile test of the metal test specimen in a hydrogen atmosphere by supplying,
Metal hydrogen embrittlement test equipment. According to claim 1,
In the housing,
It is characterized in that the flow path for the heat medium is formed, the inlet and the outlet of the flow path are connected to a heat exchanger, and the heat medium oil circulates through the flow path to control the test temperature in the space part by the operation of the heat exchanger.
Metal hydrogen embrittlement test equipment. According to claim 1,
In the housing,
A gas supply nozzle for supplying hydrogen to the space is installed through, and the gas supply nozzle is provided with a pressure sensor,
Metal hydrogen embrittlement test equipment. According to claim 2,
In the housing,
Characterized in that the temperature sensing sensor for sensing the temperature of the space to adjust the test temperature in the space is installed through,
Metal hydrogen embrittlement test equipment. According to claim 1,
The piston,
When hydrogen is supplied to the space portion at a high pressure, a balance hole is formed to apply the same pressure to both sides of the piston, and the balance hole penetrates the piston so that the space portion and the inside of the cover member communicate with each other. Characterized by being formed,
Metal hydrogen embrittlement test equipment. According to claim 1,
The cover member,
Characterized in that a gas detection passage for detecting hydrogen exposed inside the cover member is provided,
Metal hydrogen embrittlement test equipment.

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