KR102244756B1 - Chamber type tensile tester for tensile test in high pressure hydrogen environment - Google Patents

Abstract

The present invention relates to a chamber-type tensile tester capable of efficiently and stably testing mechanical properties of a material under high pressure, such as a component, or the like, used in a device for producing, transporting, or storing a gas under high pressure. According to the present invention, a chamber-type tensile tester for a tensile test in high-pressure hydrogen environment comprises an upper plate having a through-hole in a straight linear form passing through the center of each of upper and lower ends, an upper cylinder having a fastening device for fixing an upper portion of a specimen in a pin fastening method at a lower portion, and installed in a form of passing through the through-hole and lifted by hydraulic pressure for a purpose of a tensile test of the specimen, and a lower cylinder having an inner groove formed to a certain depth from an upper end, having a fixing device for automatically fixing a lower portion of the specimen to a bottom of the inner groove thereof, and lifted for a purpose of closing or opening the inner groove and fixing or separating the specimen in a state of being installed vertically below the upper plate.

Description

Chamber type tensile tester for tensile test in high pressure hydrogen environment

The present invention relates to a tensile tester used for a tensile test on a specimen in a high-pressure hydrogen environment, and more particularly, a material such as a component used in a device for producing, transporting, or storing high-pressure gas. It relates to a chamber-type tensile tester designed for the purpose of efficiently and stably testing the mechanical properties of a high-pressure condition.

Recently, as the demand for high-pressure gas increases, the demand for physical property tests on materials such as parts used in devices for producing, transporting, or storing high-pressure gas is also increasing.

Such physical property tests are mainly carried out under standard test conditions that satisfy room temperature or atmospheric pressure. However, since it is impossible to confirm the inherent properties of a material that only develops under high pressure only by testing under such standard test conditions, the actual use environment of the material. In order to obtain the result of the physical property test suitable for, the composition in a high pressure state using gas is essential.

However, in order to perform the physical property test under high pressure, an existing tensile tester must be installed inside the chamber. However, this method makes it difficult to fix the specimen to the tensile tester, and various kinds of poisoning or temporary failures in the process of replacing or removing the specimen. Problems may occur, and in particular, if the gas used for high pressure formation inside the chamber is flammable such as hydrogen, propane or butane, the risk is further increased.

Therefore, there is a need for a way to perform a stable physical property test on a specimen even under high pressure, and in this regard, “material property measurement apparatus under high pressure environment using ultrasonic waves” in Korean Patent Publication No. 10-1333184, Korea Inventions such as “material property measurement device in high pressure environment” of Registration Patent Publication No. 10-1367644 and “material property measurement device in high pressure environment using electrical resistivity” of Korean Patent Publication No. 10-1456587 have been proposed and disclosed. There is a bar.

First, the Republic of Korea Patent Publication No. 10-1333184 discloses a housing provided with a chamber, a pedestal provided at the bottom of the housing to mount a specimen, at least one jig capable of proximity adjustment to a specimen mounted on the pedestal, and a lower portion of the jig. It is configured to include a sensor insertion port that fits and fixes the ultrasonic sensors while being equipped, and an ultrasonic sensor that senses and transmits ultrasonic signals to the outside while in contact with the specimen, so that the physical properties of the specimen can be reliably and accurately measured even in a high-pressure environment. An invention has been proposed for a device that enables it.

In addition, the Republic of Korea Patent Publication No. 10-1367644 includes a driving motor, a pinion gear, a rack gear, etc., a first measuring member for measuring the ultrasonic and electrical resistivity of the material, and the ultrasonic wave measured by the first measuring member An invention has been proposed for a device configured to include a second measuring member for measuring the physical properties of the material using the electrical resistivity value so as to accurately measure the physical properties of the industrial equipment material exposed to a high pressure environment.

In addition, the Republic of Korea Patent Publication No. 10-1456587 discloses a housing in which a chamber is provided, a base plate provided at the bottom of the housing to mount the specimen, and the electrical resistivity measurement data of the specimen in a state in contact with the specimen at a constant pressure. An invention has been proposed for a device configured to include a transmitting electrical resistivity sensing unit and the like, so that a change in physical properties inside a specimen can be grasped.

However, all of the conventional inventions as described above are for detecting damage or cracks in a specimen placed under high pressure using a sensor such as an ultrasonic sensor and measuring electrical resistivity. Among the mechanical properties of the material constituting the specimen, tensile strength and yield point , There is a problem that cannot be applied to a tensile test for measuring the modulus of elasticity, etc.

Therefore, by solving all the above problems, there is a need for an invention of a device that enables efficient and stable testing of the mechanical properties of materials such as parts used in devices for producing, transporting, or storing high-pressure gas. It is the actual situation.

Republic of Korea Patent Publication No. 10-1333184 (Nov. 20, 2013) Republic of Korea Patent Publication No. 10-1367644 (2014. 02. 20.) Republic of Korea Patent Publication No. 10-1456587 (October 24, 2014)

The chamber-type tensile tester for a tensile test in a high-pressure hydrogen environment according to the present invention is a proposed invention to solve the above problems,

There is a problem in that it is impossible to confirm the inherent physical properties of the material, which is manifested only in a high pressure state by a tensile test on a specimen in a standard test condition using an existing tensile tester

When an existing tensile tester is installed inside the chamber for the purpose of creating a high-pressure state, it is difficult to fix the specimen to the tensile tester, and various problems such as poisoning by residual gas or temporary failure in the process of replacing or removing the specimen Can occur,

Conventional inventions presented for the purpose of measuring the physical properties of materials under high pressure are to detect damage or cracks of materials placed under high pressure using sensors such as ultrasonic sensors, and measure electrical resistivity, so the mechanical properties of materials Since there is a problem that cannot be applied to the tensile test for measuring tensile strength, yield point, and modulus of elasticity, the purpose of this is to propose a solution.

The present invention is to achieve the above object,

An upper plate having a straight through hole penetrating through the center of each of the upper and lower ends; An upper cylinder having a fastening device for fixing the upper part of the specimen in a pin-fastening manner, provided at a lower portion, and installed in a form penetrating through the through hole, and lifted by hydraulic pressure for the purpose of a tensile test of the specimen; And, an internal groove of a certain depth is formed from the top, a fixing device for automatically fixing the lower part of the specimen to the bottom surface of the internal groove is provided, and fixing or separating the specimen in a state installed vertically below the upper plate. A lower cylinder that moves up and down for the purpose of closing or opening the inner groove; It presents a chamber-type tensile tester for a tensile test in a high-pressure hydrogen environment, characterized in that it is configured to include.

In this case, the fixing device may include a first fixing part provided with a magnet at a predetermined height on one side thereof; A first horizontal hole and a second horizontal hole of a predetermined height are formed on both sides, respectively, in a state installed spaced apart from the first fixing part at a predetermined interval, and a connection hole is formed between the both sides, and is moved up and down by external force. A second fixing part provided with an elevating part connecting or disconnecting the first horizontal hole and the second horizontal hole; A third horizontal hole or a horizontal groove having the same height as the first horizontal hole and the second horizontal hole is formed, and is installed spaced apart from the second fixing part at regular intervals, so that a space in which the lower part of the specimen is inserted between them is provided. A third part to form; And, the whole or part of the head is composed of a magnet, and the distal end of the body is installed horizontally in a form that is fitted into the first horizontal hole, so that the elevating portion rises so that the first horizontal hole and the second horizontal hole are connected to each other. A'T'-shaped fixing pin that moves in a horizontal direction by a repulsive force with a magnet provided in the first fixing part when connected; It characterized in that it is configured to include.

The chamber-type tensile tester for a tensile test in a high-pressure hydrogen environment according to the present invention,

The upper plate and the lower cylinder are configured to form a chamber integrally, and the upper and lower parts of the specimen can be easily fixed by using a fastening device and a fixing device inside the chamber. The effect of being able to efficiently and stably test the mechanical properties of a material under high pressure is generated.

1 is a perspective view of a chamber-type tensile tester for a tensile test in a high-pressure hydrogen environment according to the present invention.
2A and 2B are flowcharts illustrating a process of fastening a specimen to a fastening device of an upper cylinder.
3 is an exemplary view showing a state in which an upper plate and a lower cylinder integrally form a chamber, and a specimen is fixed using a fastening device and a fixing device.
4A to 4C are flow charts showing a process of fixing the lower part of the specimen using the fixing device of the lower cylinder.
Figure 5 is an exemplary view showing a state in which a specimen is destroyed inside a chamber by a tensile test using the present invention.

The present invention relates to a tensile tester used for a tensile test on a specimen in a high-pressure hydrogen environment, and more specifically,

An upper plate 100 having a straight through hole penetrating through the center of each of the upper and lower ends; An upper cylinder 110 having a fastening device 111 for fixing the upper portion of the specimen in a pin-fastening manner, provided at the lower portion, and installed in a form penetrating through the through hole to lift the specimen by hydraulic pressure for the purpose of a tensile test of the specimen; And, an internal groove of a certain depth is formed from the top, a fixing device 210 for automatically fixing the lower part of the specimen to the bottom surface of the internal groove is provided, and in a state installed vertically below the upper plate 100 A lower cylinder 200 for lifting or lowering for the purpose of fixing or separating the specimen and closing or opening the internal groove; It relates to a chamber-type tensile tester for a tensile test in a high-pressure hydrogen environment, characterized in that configured to include.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIG. 1, the upper plate 100 is a cover-shaped structure that forms one chamber integrally with the lower cylinder 200, and a straight through hole is formed at the center of each of the upper and lower ends. A portion of the upper cylinder 110, which is formed in a penetrating shape and used for fixing and tensioning a specimen, can be installed in a shape penetrating the through hole.

At this time, the upper plate 100 may have at least one straight supply hole formed around the through hole, and at least one supply port corresponding to each of the at least one supply hole may be provided. A gas supply pipe for supplying a gas such as hydrogen may be fastened to one or more supply ports.

Accordingly, a high-pressure state is formed by gas such as hydrogen sequentially supplied through a gas supply pipe, a supply port, and a supply hole inside the chamber in which the upper plate 100 and the lower cylinder 200 are integrally formed. It can be, and one for securing the airtightness of the chamber by firmly maintaining the state in which the upper plate 100 and the lower cylinder 200 are combined at the lower end of the upper plate 100 and the upper end of the lower cylinder 200 The above flanges 101 and one or more flange holes 201 may be formed in various shapes as shown in FIG. 1.

On the other hand, one side of the upper plate 100 may be connected to one or more fixing means for firmly fixing the upper plate 100 in a state horizontal to the ground at a certain height, and instead of this, a gas supply pipe and a supply port The combination of can be used in a manner for firmly fixing the upper plate 100 in a horizontal state.

In addition, the upper cylinder 110 is a component used for fixing and tensioning a specimen in a chamber in which the upper plate 100 and the lower cylinder 200 are integrally formed, as shown in FIG. As shown, a part of the hydraulic cylinder that is installed to pass through the through hole of the upper plate 100 and is raised and lowered by hydraulic pressure is provided, but a fastening device 111 for fixing the upper part of the specimen through a pin fastening method is provided at the lower portion thereof. It is characterized by being.

At this time, as shown in Figs. 2A and 2B, the fastening device 111 is a device configured to fix the upper part of the specimen by a manual pin fastening method similar to a conventional tensile tester, and the upper plate 100 It is positioned so as to be spaced apart from the lower end of the cylinder by a predetermined distance so that a sufficient moving distance of the lower cylinder 200 for conducting a tensile test can be secured.

In addition, as shown in Figs. 1 and 3, the lower cylinder 200 is a cylindrical structure that forms one chamber integrally with the upper plate 100, and an internal groove of a predetermined depth is formed from the top. By being configured in a shape, when one chamber is formed integrally with the upper plate 100, a space in which a tensile test occurs can be formed in a state of high pressure inside the chamber.

At this time, as shown in FIGS. 1 and 3, a fixing device 210 is provided on the bottom surface of the inner groove so that the upper part is fixed by the fastening device 111 when the lower cylinder 200 is raised. The lower part of the specimen in the state can be fixed, and a pin fastening method is used as a method of fixing the lower part of the specimen, but the pin fastening method by the fastening device 111 in the type and shape of the pin and the specific fastening method, etc. It makes a significant difference.

Specifically, as shown in FIGS. 4A to 4C, the fixing device 210 includes a first fixing part 211 provided with a magnet at a predetermined height on one side, and a constant from the first fixing part 211. A first horizontal hole 212 and a second horizontal hole 213 of a predetermined height are formed on both sides, respectively, and a connection hole 214 is formed between the both sides by an external force. It is characterized in that it comprises a second fixing portion 216 provided with a lifting portion 215 for elevating and connecting or disconnecting the first horizontal hole 212 and the second horizontal hole 213.

In addition, the fixing device 210 includes a third horizontal hole 217 having the same height as the first horizontal hole 212 and the second horizontal hole 213 or the second fixing part in a state in which a horizontal groove is formed. The third fixing part 218 is installed spaced apart from 216 at a certain interval to form a space in which the lower part of the specimen is inserted, and the whole or part of the head is composed of a magnet, and the distal end of the body is the first. The first fixing part 211 is installed horizontally in a form fitted into the horizontal hole 212, and when the lifting part 215 rises and the first horizontal hole 212 and the second horizontal hole 213 are connected to each other, the first fixing part 211 ) Characterized in that it is configured to include a'T'-shaped fixing pin 219 that moves in the horizontal direction by a repulsive force with a magnet provided in).

That is, in the fixing device 210, the first fixing part 211, the second fixing part 216, and the third fixing part 218 are installed in parallel with each other, and the fixing pin 219 is It is installed in a form that is fitted horizontally into the first horizontal hole 212, and a repulsive force by a magnet provided in the first fixing part 211 acts on the head side of the fixing pin 219, which is entirely or partially composed of a magnet. The state is the basic state, but the movement of the fixing pin 219 by the repulsive force is configured to be determined by the lifting of the lifting part 215 by the action of an external force.

At this time, the action of the external force for lifting the lifting part 215 occurs as the lower part of the specimen is inserted into the space formed between the second fixing part 216 and the third fixing part 218, The detailed structure of the second fixing part 216 for this is as follows.

That is, as shown in Figs. 4A to 4C, the second fixing part 216 is spaced apart from the first fixing part 211 at a certain interval in a state in which the first horizontal hole 212 of a certain height is formed. One side to be installed and a second horizontal hole 213 having the same height as the first horizontal hole 212 is formed, an operation hole 220 is formed under the second horizontal hole 213, and external force The operation part 221 of the seesaw structure operated by the other side part provided in a form in which a part of the operation hole 220 protrudes to the outside, and the first horizontal hole 212 and the second horizontal hole A connection hole 214 corresponding to (213) is formed and is installed between the one side and the other side, and is lifted and lowered by the operation unit 221, and the first horizontal hole 212 and the second horizontal hole ( It characterized in that it is configured to include a lifting unit 215 for connecting or disconnecting 213) with each other.

In addition, the operation part 221 has a fixed shaft 222 installed horizontally in a direction crossing the length direction of the operation hole 220, and one end portion and the other end portion toward the outside of the operation hole 220 It is characterized in that it is configured to include a rotating part 223 that rotates at a certain angle by an external force with the fixed shaft 222 as an axis while being installed to protrude.

In addition, the elevating part 215 is a connection part 224 configured to connect the upper part of each of the one side and the other side of the second fixing part 216, in a vertical direction at the lower end of the connection part 224 A spring 225 to be fastened, and a connection hole 214 in a horizontal direction is formed, and a communication part 226 that is raised and lowered by the operation part 221 in a state connected to the lower part of the spring 225 It is characterized by that.

Accordingly, as shown in FIGS. 4A to 4C, the second fixing part 216 and the third fixing part 216 and the third When the lower portion of the specimen is inserted into the space formed between the fixing portions 218, the lower portion of the specimen presses the one end portion of the rotating portion 223 protruding outward in one direction among both directions of the operation hole 220. do.

At this time, the rotation part 223 is axially rotated with the fixed shaft 222 as an axis, and the other end of the rotation part 223 protruding outward in the other direction among the two directions of the operation hole 220 is the communication part By pushing up the 226, the first horizontal hole 212, the connection hole 214, and the second horizontal hole 213, which were disconnected from each other, can be connected in a horizontal direction.

In addition, a magnet is provided at the lower portion of the specimen and at the distal end of the rotating portion 223, so that the specimen and the rotating portion 223 are in close contact with each other through an attractive force acting between the two magnets.

Thereafter, the fixing pin 219 is directed toward the third fixing part 218 due to a repulsive force due to the interaction between the magnet constituting the whole or part of the head and the magnet provided in the first fixing part 211. Is moved, its end portion sequentially passes through the connection hole 214, the second horizontal hole 213, the lower portion of the specimen, and the third horizontal hole 217, and the head thereof passes through the second fixing portion 216 ), it stops and firmly fixes the lower part of the specimen.

At this time, the spring 225 constituting the elevating part 215 is compressed between the communication part 226 and the connection part 224 as the communication part 226 rises, so that the specimen is broken by tensile force or When the fixing pin 219 returns to its original state by an external force in a state separated between the second fixing part 216 and the third fixing part 218, the communication part 226 is lowered.

Accordingly, the fixing pin 219 in the state in which the end portion is inserted into the first horizontal hole 212 is restricted by the communication portion 226 despite the repulsive force acting on the head, and the lower cylinder ( When the lower portion of the specimen is re-inserted into the space formed between the second fixing part 216 and the third fixing part 218 by the rise of 200), it may be operated again according to the above-described sequence.

On the other hand, the specimen in which the upper part is fixed by the fastening device 111 and the lower part is fixed by the fixing device 210 has a shape as shown in FIG. 5 by the rise of the upper cylinder 110 by hydraulic pressure. It may be broken, and mechanical properties such as tensile strength, yield point, and modulus of elasticity can be derived through the time until breakage occurs and the magnitude of the applied hydraulic pressure.

The embodiments introduced above are provided by way of example in order to sufficiently convey the technical idea of the present invention to those of ordinary skill in the technical field to which the present invention pertains, and the present invention is based on the above-described embodiments. It is not limited and may be embodied in other forms.

In order to clearly describe the present invention, parts irrelevant to the description are omitted from the drawings, and in the drawings, the width, length, thickness, etc. of components may be exaggerated or reduced for convenience.

In addition, the same reference numbers throughout the specification indicate the same elements.

100: upper plate → 101: flange
110: upper cylinder → 111: fastening device
200: lower cylinder → 201: flange groove
→ 210: fixing device 211: first fixing part
→ 212: 1st horizontal hole 213: 2nd horizontal hole
→ 214: connection hole 215: elevating part
→ 216: second fixing part 217: third horizontal hole
→ 218: third fixing part 219: fixing pin
→ 220: operation hole 221: operation part
→ 222: fixed shaft 223: rotating part
→ 224: connection part 225: spring
→ 226: Communication department
S: specimen
P: pin
M: magnet

Claims (4)

An upper plate 100 having a straight through hole penetrating through the center of each of the upper and lower ends;
An upper cylinder 110 having a fastening device 111 for fixing the upper portion of the specimen in a pin-fastening manner, provided at the lower portion, and installed in a form penetrating through the through hole to lift the specimen by hydraulic pressure for the purpose of a tensile test of the specimen; And,
An internal groove of a certain depth is formed from the top, a fixing device 210 for automatically fixing the lower part of the specimen to the bottom surface of the internal groove is provided, and the specimen is installed vertically below the upper plate 100. A lower cylinder 200 for lifting or lowering for the purpose of fixing or separating and closing or opening the inner groove; It characterized in that it is configured to include,
The fixing device 210,
A first fixing part 211 provided with a magnet at a predetermined height on one side thereof;
A first horizontal hole 212 and a second horizontal hole 213 having a predetermined height are formed on both sides of the first fixing part 211 in a state spaced apart from the first fixing part 211, respectively, and a connection hole between the both sides of the first horizontal hole 212 and the second horizontal hole 213 A second fixing part 216 provided with a lifting part 215 for lifting or lowering the first horizontal hole 212 and the second horizontal hole 213 in a state in which 214 is formed;
A third horizontal hole 217 having the same height as the first horizontal hole 212 and the second horizontal hole 213 or a horizontal groove is formed, and is installed spaced apart from the second fixing part 216 at regular intervals. A third fixing portion 218 that forms a space in which the lower portion of the specimen is inserted therebetween; And,
The whole or part of the head is composed of a magnet, and the distal end of the body is installed horizontally in a form that is fitted into the first horizontal hole 212, so that the lifting part 215 rises and the first horizontal hole 212 A'T'-shaped fixing pin 219 that moves in a horizontal direction by a repulsive force with a magnet provided in the first fixing part 211 when the second horizontal hole 213 is connected to each other; Chamber-type tensile tester for a tensile test in a high-pressure hydrogen environment, characterized in that configured to include.
delete The method of claim 1,
The second fixing part 216,
One side of the first horizontal hole 212 of a certain height is formed to be spaced apart from the first fixing part 211 at a certain interval, and
A second horizontal hole 213 having the same height as the first horizontal hole 212 is formed, an operation hole 220 is formed under the second horizontal hole 213, and a seesaw structure operated by an external force The other side of which the operation part 221 of is provided in a form in which a part of the operation hole 220 protrudes outward,
And a connection hole 214 corresponding to the first horizontal hole 212 and the second horizontal hole 213 is formed and installed between the one side and the other side by the operation part 221. A chamber type tensile tester for a tensile test in a high-pressure hydrogen environment, characterized in that it includes an elevating part 215 that lifts and descends and connects or disconnects the first horizontal hole 212 and the second horizontal hole 213 with each other. .
The method of claim 3,
The operation part 221,
A fixed shaft 222 installed horizontally in a direction crossing the length direction of the operation hole 220; And,
A rotating part 223 that rotates at a predetermined angle by external force with the fixed shaft 222 as an axis in a state in which one end part and the other end part protrude toward the outside of the operation hole 220; It characterized in that it is configured to include,
The elevating part 215,
A connection part 224 configured to connect an upper part of each of one side and the other side of the second fixing part 216;
A spring 225 which is vertically fastened to the lower end of the connection part 224; And,
A communication part 226 having a connection hole 214 in a horizontal direction and being connected to the lower part of the spring 225 and moving up and down by the operation part 221; Chamber type tensile tester for a tensile test in a high-pressure hydrogen environment, characterized in that configured to include.

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