KR20200069704A - System for testing of stress corrosion cracking - Google Patents

Abstract

The present invention relates to a stress corrosion cracking test system which is to measure stress corrosion cracking by applying a tensile force to a specimen made of a metal. According to the present invention, the stress corrosion cracking test system comprises: a test cabinet (100) having a test space formed therein and a plurality of test devices (300) installed in the test space; a gas supply device (200) installed outside the test cabinet (100) and supplying test gas to the test devices (300); the test devices (300) having a corrosion test solution and the test gas supplied to the inside, and applying a tensile force to a specimen fixed to the inside; a thermostat (400) installed on the outside of the test cabinet (100) and constantly maintaining the temperature of the test solution of the test devices (300); and a neutralization tank (500) installed at one side of the test space and storing, therein, a neutralization solution for neutralizing the test gas discharged from the test devices (300). The stress corrosion cracking test system can greatly improve reliability in measurement results and work efficiency.

Description

System for testing of stress corrosion cracking

The present invention relates to a stress corrosion cracking test system, and more particularly, to a stress corrosion cracking test system for measuring stress corrosion cracking by adding a tensile force to a metal material specimen.

In general, metal materials such as carbon steel and stainless steel generate stress corrosion cracking when exposed to a specific environment.

In particular, metal materials used for various structures or facilities that are exposed to a wet acid environment for a long time or subjected to tensile loads must have excellent corrosion resistance and tensile strength, and these metal materials are corrosive solutions such as salt water and corrosive gases such as sulfide gas. Stress corrosion cracking test is performed under the test conditions to determine whether it is suitable for the application.

An example of a technique for testing the performance of these materials is disclosed in documents 1 to 2 below.

Patent Document 1 is a test apparatus for measuring stress corrosion cracking by applying a tensile force to a specimen seated in a corrosion bath, the test tank filled with a test gas; A test section having a corrosion tank connected to a gas tank portion through a gas transfer pipe, a specimen, a fixing member fixing the upper and lower portions of the specimen, and a load cell sensing deformation of the specimen; It includes one or more neutralization traps having an inlet through which the test gas discharged from the corrosion tank enters, and an outlet through which the test gas is neutralized with a neutralization solution stored therein, and exits to the outside. Disclosed is a stress corrosion cracking test apparatus characterized in that the gas transfer pipe is arranged to be immersed in a neutralization solution, and a bubbling member is disposed inside the neutralization trap to increase the neutralization reaction between the neutralization solution and the test gas. .

Patent Document 2 is a hydrogen tank crack corrosion test apparatus equipped with a test tank containing a test solution for neutralization of hydrogen gas discharged from the test tank, and a neutralization tank containing a neutralization solution for neutralization of the emulsified gas discharged from the test tank. In, the test tank has a dual structure that is installed in a constant temperature tank provided to circulate and store water heated from the outside, and the test tank, the constant temperature tank, and the neutralization tank are made of a transparent glass material. Test tanks and neutralization tanks are disclosed.

However, in the prior art as described above, there was a problem in that a gas leak accident occurs because a toxic gas such as hydrogen sulfide is not safely handled in the corrosion test process, thereby causing the researchers performing the test to suffocate the gas. There was. In addition, the reliability of the test results is also affected because the test must be stopped to repair the gas when it starts to leak.

In addition, since most of the conventional corrosion cracking test systems are not systemized, it is impossible to continuously test a large number of specimens, so there is a problem that the test time is long.

Republic of Korea Registered Patent Publication No. 10-0900881 (2009.05.27. registration) Republic of Korea Utility Model Publication No. 20-0378385 (Registered on Feb. 2005)

The present invention has been devised to solve the problems as described above, stress corrosion cracking test that can safely treat toxic gases, such as hydrogen sulfide, which require special management as a corrosion gas used in stress corrosion cracking measurement, in a test cabinet. The purpose is to provide a system.

In addition, it is an object of the present invention to provide a stress corrosion cracking test system that enables continuous testing by systemizing various test-related devices such as nitrogen/hydrogen sulfide supply, heating fluid supply, and neutralizing test gas.

In addition, it provides a stress corrosion cracking test system that can easily connect hoses connected to each line through a modular distribution line in which the supply and discharge lines of the fluid for maintaining the temperature of the test gas and the test solution are modulated. There is a purpose.

In order to achieve the above object, the stress corrosion cracking test system according to the present invention includes a test cabinet 100 in which a test space is formed, and a plurality of test devices 300 are installed in the test space; A gas supply device 200 installed outside the test cabinet 100 and supplying a test gas to the test device 300; Corrosion test solution and test gas is supplied to the inside, the test apparatus 300 for adding a tensile force to the specimen fixed therein; A thermostat 400 installed on the outside of the test cabinet 100 and maintaining a constant temperature of the test solution of the test apparatus 300; And a neutralization tank 500 installed on one side of the test space and in which a neutralization solution for neutralizing the test gas discharged from the test apparatus 300 is stored.

In addition, a duct 130 for sucking air inside the test cabinet and discharging it is installed at an upper portion of the test cabinet 100, and a scrubber 131 for collecting particles floating in the gas is installed in the duct 130. It characterized in that the connection.

In addition, it is installed inside the test cabinet 100, it characterized in that it comprises a plate 140 for dividing the test cabinet into a test space and a receiving space.

In addition, a support means 150 for supporting the test apparatus 300 is installed on an upper portion of the plate 140, and the support means 150 are installed at a predetermined interval on the upper portion of the plate 140. It characterized in that it comprises a vertical frame 151, and a support plate 152 horizontally installed on the top of the vertical frame (151).

In addition, in front of the support means 150, a control panel 600 is installed in a number corresponding to the number of installations of the test apparatus 300, and the control panel 600 is a test supplied to the test apparatus 300. A gas control unit 610 for supplying or blocking hydrogen sulfide and nitrogen as gases; A temperature control unit 620 for controlling the temperature of the fluid for maintaining the test temperature; And a test gas flow meter 630 for measuring the flow rate of the test gas.

In addition, a plurality of distribution lines 700 in which a plurality of capillaries are arranged parallel to each other at regular intervals is installed on the plate 140.

Also, the distribution line 700 includes a nitrogen supply line 710 and a hydrogen sulfide supply line 720 which are respectively connected to the gas supply device 200; And a fluid supply line 730 and a fluid discharge line 740, which are respectively connected to the thermostat 400 and are provided with check valves 750 on one side.

In addition, the gas supply device 200 is connected between the nitrogen supply source and the test device 300 nitrogen supply pipe 210 for supplying nitrogen; And a hydrogen sulfide supply pipe 220 connected between a hydrogen sulfide supply source and a test apparatus 300 to supply hydrogen sulfide.

In addition, the test apparatus 300 is characterized in that a plurality of test tanks 310 are configured to be arranged in a horizontal series at regular intervals.

In addition, on one side of the thermostat 400, a fluid supply pipe 410 for supplying the heated fluid to the test apparatus 300, and a fluid discharge pipe 420 for supplying the test apparatus 300 to discharge the circulated fluid. It is characterized by being connected.

As described above, the stress corrosion cracking test system according to the present invention can safely treat toxic gases such as hydrogen sulfide in the test cabinet, greatly improving the environment in the laboratory, and preventing researchers from being exposed to gas leakage accidents. have.

In addition, various test-related devices such as nitrogen/hydrogen sulfide supply, heating fluid supply, and test gas neutralization, which are individually installed, can be systemized to enable continuous testing, greatly reducing test time while improving reliability and work on measurement results. It has the effect of greatly improving the efficiency.

In addition, since a plurality of supply and discharge related hoses are arranged through a distribution line, there is an effect that the hose arrangement is convenient and space utilization is excellent.

1 is a front view showing a stress corrosion cracking test system according to the present invention.
Figure 2 is a side view showing a stress corrosion cracking test system according to the present invention.
Figure 3 is a perspective view showing a main portion of a stress corrosion cracking test system according to the present invention.
4 is a perspective view showing a distribution line according to the present invention.
5 is a front view showing a test apparatus according to the present invention.
Figure 6 is a perspective view showing a neutralization tank according to the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to explain in detail that a person skilled in the art to which the present invention pertains can easily implement the present invention.

1 and 2, the stress corrosion cracking test system according to the present invention has a test space formed therein, a test cabinet 100 in which a plurality of test devices 300 are installed in the test space; A gas supply device 200 installed outside the test cabinet 100 and supplying a test gas to the test device 300; Corrosion test solution and test gas is supplied to the inside, the test apparatus 300 for adding a tensile force to the specimen fixed therein; A thermostat 400 installed on the outside of the test cabinet 100 and maintaining a constant temperature of the test solution of the test apparatus 300; And a neutralization tank 500 installed on one side of the test space and in which a neutralization solution for neutralizing the test gas discharged from the test device 300 is stored.

The present invention is to mount a variety of test-related devices (test equipment, thermostats, neutralization tanks, etc.) applied for stress corrosion cracking test in a test cabinet to enable safe and convenient testing.

In particular, it has been improved to prevent leakage of toxic gases, such as hydrogen sulfide, used for the test corrosion gas, into the laboratory, and it is possible to continuously test by systemizing the test-related devices.

Conventional stress corrosion cracking testers have inconveniences such as connection due to movement because test tanks, constant temperature baths, and neutralization baths are individually installed and must be directly connected to each device with hoses. This takes, there was a problem that manpower was generated. In particular, there is a problem that requires a fairly large installation space in the test room for the individual installation and hose connection of each device. In addition, during the corrosion test, a toxic gas such as hydrogen sulfide was not safely handled, resulting in a gas leak accident, which caused researchers to undergo tests to suffocate the gas.

To solve this, the present invention is a gas supply device 200 for supplying nitrogen and hydrogen sulfide inside the test cabinet 100 with a test space formed therein, a number of test devices 300 for measuring stress corrosion cracking of a specimen ), a thermostat 400 for maintaining a constant temperature of the test solution, and a neutralization tank 500 for neutralizing the test gas.

A viewing window 110 made of a transparent material is formed on the front upper portion of the test cabinet 100.

Therefore, the inside of the test space of the test cabinet 100 can be observed through the formation of the viewing window 110, so that the test state can be confirmed. The viewing window is preferably made of a sliding opening/closing method for maintenance and inspection of various devices, and can be configured to slide in various ways according to test conditions and design specifications. In addition, a packing is installed between the see-through window and the frame to close the gap to ensure airtightness.

Doors 120 are installed to be opened and closed at the front and side of the test cabinet 100.

The test cabinet 100 is formed to be separated into a test space and a receiving space by a plate 140, which will be described later, where various piping lines and valves connected to a neutralization tank, etc. are arranged in the receiving space. Therefore, it is possible to facilitate maintenance and inspection of various piping lines and valves through the door 120.

The upper portion of the test cabinet 100 is provided with a duct 130 for sucking the air inside the test cabinet and discharging it to the outside.

A scrubber 131 for collecting particles floating in the gas is connected to the duct 130.

It is necessary to install a duct in order to prevent the air in the laboratory from being contaminated by the gas generated during the test process and to maintain a pleasant environment. However, in the prior art, when a toxic gas leaked during a stress corrosion cracking measurement process in a laboratory, there was a problem that researchers were exposed without defense.

In order to solve this, the present invention is installed on the upper portion of the test cabinet 100, the duct 130 is installed to suck the toxic gas generated inside the test cabinet through the duct, and then collects it through a scrubber 131. This significantly improves the environment in the laboratory and prevents researchers from being exposed to gas leaks.

As shown in Figure 3, the present invention is installed inside the test cabinet 100, and includes a plate 140 for dividing the test cabinet into a test space and a receiving space.

A support means 150 for supporting the test apparatus 300 is installed on the upper part of the plate 140, and the support means 150 is provided with a plurality of vertical frames installed at regular intervals on the upper part of the plate 140. 151 and a support plate 152 horizontally installed on the top of the vertical frame 151.

The test cabinet 100 is provided with a plurality of test devices 300 and various piping lines, hoses, and the like connected to the test devices. Accordingly, in order to organize various piping lines and hoses, a distribution line 700 is installed in the present invention, and a space must be formed for installation of the distribution line.

To this end, a table-shaped support means 150 composed of a vertical frame 151 and a support plate 152 is installed on the plate 140. Therefore, by installing the distribution line into the space formed by the support means, various hoses can be easily connected to the distribution line, and maintenance is convenient.

In front of the support means 150, a control panel 600 is installed in a number corresponding to the number of installations of the test apparatus 300, respectively.

A plurality of test devices 300 are disposed at regular intervals on the support plate 152 of the support means 150. Therefore, a control panel for controlling the operation of each test device should also be installed. To this end, in front of the support means 150, each control panel 600 is installed in a number corresponding to the number of installations of the test apparatus, so that individual control of the test apparatus is possible.

The control panel 600 includes a gas control unit 610 for supplying or blocking hydrogen sulfide and nitrogen, which are test gases supplied to the test apparatus 300; A temperature control unit 620 for controlling the temperature of the fluid for maintaining the test temperature; And a test gas flow meter 630 for measuring the flow rate of the test gas.

The gas control unit 610 includes a three-way valve to quickly change direction, and the opening and closing of the three-way valve is controlled manually or automatically. The gas control unit 610 is connected to the nitrogen supply line 710 and the hydrogen sulfide supply line 720 of the distribution line 700, which will be described later, with a hose or the like, respectively.

The temperature control unit 620 includes a 2-way valve, and the opening and closing of the 2-way valve is controlled manually or automatically. The temperature control unit 620 is connected to the fluid supply line 730 and the fluid discharge line 740 of the distribution line 700, which will be described later, with a hose or the like.

The gas control unit 610 and the temperature control unit 620 controls valve opening and closing by a switch that is operated manually or automatically, and is tested under the corrosion cracking test conditions of the specimen by the gas control unit 610 and the temperature control unit 620. It can be controlled to be the set temperature and gas concentration in the tank. Accordingly, it is possible to accurately and easily measure the corrosion cracking property test of the specimen in an environment in which a corrosive gas is mixed with the fluid.

Meanwhile, a certain amount of test gas must be supplied to the test tank in which the test solution is stored. Therefore, a test gas flow meter 630 for displaying the test gas flow rate is installed on the control panel. The researcher needs to check the test gas capacity supplied to the test tank, which can be visually observed through the test gas flow meter.

A plurality of distribution lines 700 in which a plurality of capillaries are arranged parallel to each other at regular intervals are installed at the upper portion of the plate 140.

In the present invention, a gas supply device 200, a thermostat 400, a neutralization tank 500, and a plurality of test devices 300 are installed, and various piping lines, hoses, etc. are connected to these devices. Therefore, when connecting a plurality of hoses through the distribution line 700 manufactured in a manifold method, it is easy to connect to a corresponding test apparatus without being entangled with each other and easy maintenance. In particular, the distribution line 700 is preferably made of a stainless steel pipe with strong corrosion resistance.

4, the distribution line 700 includes a nitrogen supply line 710 and a hydrogen sulfide supply line 720 connected to the gas supply device 200, respectively; And a fluid supply line 730 and a fluid discharge line 740, which are respectively connected to the thermostat 400 and are provided with check valves 750 on one side.

Nitrogen must be supplied to the test tank of the test apparatus 300 to remove dissolved oxygen from the test solution and remove residual hydrogen sulfide after the test. To this end, a nitrogen supply line 710 for supplying nitrogen to the test tank is connected to the gas supply device 200.

In addition, a corrosion gas must be supplied to the test tank for the corrosion test of the specimen. To this end, a hydrogen sulfide supply line 720 for supplying hydrogen sulfide to the test tank is connected to the gas supply device 200.

In addition, the test solution supplied to the test tank should be maintained at a constant temperature. To this end, the fluid supply line 730 and the fluid discharge line 740 for supplying and discharging the fluid heated by the thermostat 400 to the test tank are respectively connected to the thermostat 400. The check valve 750 flows the fluid in only one direction and prevents backflow when the fluid stops, thereby preventing fluid leakage.

The gas supply device 200 is connected between the nitrogen supply source and the test device 300 nitrogen supply pipe 210 for supplying nitrogen; It is connected between the hydrogen sulfide supply source and the test apparatus 300 to supply hydrogen sulfide hydrogen sulfide supply pipe (220).

The nitrogen supply pipe 210 and the hydrogen sulfide supply pipe 220 are disposed outside the test cabinet 100 and are respectively connected to a nitrogen storage tank filled with nitrogen and a hydrogen sulfide storage tank filled with hydrogen sulfide. That is, one end of the nitrogen supply pipe 210 is connected to the nitrogen storage tank, the other end is connected to the nitrogen supply line 710 of the distribution line 700. In addition, one end of the hydrogen sulfide supply pipe 22 is connected to the hydrogen sulfide storage tank, and the other end is connected to a hydrogen sulfide supply line 720 of the distribution line 700. Gas control switches 230 for controlling the flow rates of nitrogen and hydrogen sulfide may be installed at one side of the nitrogen supply pipe 210 and the hydrogen sulfide supply pipe 220.

As shown in FIG. 5, the test apparatus 300 includes a test tank 310 to which a supply line and a discharge line of a test gas, a test solution and a fluid are connected, and a specimen is fixed therein; A breaking detection unit 320 installed on one side of the test tank 310 to detect whether the specimen is broken or not; A circulation pipe 330 installed inside the test tank 310 and circulating fluid therein; It is installed inside the test tank 310, the fixing part 340 for supporting both ends of the specimen respectively; An application means 350 installed on the test tank 310 to provide tensile force; And a proof spring 360 installed outside the test tank 310 and deformed by manipulation of the applying means 350.

The test tank 310 is preferably formed of a transparent glass material. Synthetic resins, such as FRP, PVC, and acrylic, do not have a dense structure due to the nature of the material, so that the gas can permeate to change the substrate of the test solution in the test tank 310, for example, dissolved oxygen, and reaction with the solution may occur. It can give an error. On the other hand, the glass material does not change the substrate of the test solution contained therein because the tissue is dense and the gas does not penetrate well and does not react with the solution. Various hoses connected to the test tank 310 are made in a one-touch method, so connection and management are easy.

A temperature sensor for measuring the temperature of the test solution stored in the test tank may be installed on one side of the test tank 310. Although not shown in the drawing, a test solution supply pipe (not shown) for supplying a test solution in which dissolved oxygen is removed is connected to one side of the test tank 310.

The fracture detection unit 320 is installed on the upper portion of the test tank 310, a detection switch 321 for detecting whether the specimen is broken or not; It includes; a sensing cable 322 for transmitting the detection signal of the detection switch 321 to the control system.

The circulation pipe 330 is preferably formed in a spiral shape, and a hose for fluid supply is connected to one side, and a hose for fluid discharge is connected to the other side. Therefore, the fluid heated by the thermostat 400 is supplied to or discharged from the circulation pipe 330, so that the test temperature of the test tank can be kept constant.

The applying means 350 includes a working nut 352 coupled to the shaft 351 passing through the proof ring 360, and a bearing is provided between the proof ring 360 and the working nut 352.

A base 370 having a predetermined height is installed under the proof ring 360.

The test apparatus 300 is filled with a corrosion gas and a test solution inside the test tank 310 to give a tensile force to the specimen in a state where the specimen is exposed to a corrosion environment.

That is, when the operating nut of the applying means 350 is operated, the proof ring is compressed while descending along the axis, and a predetermined tensile force is applied to the specimen by the restoring force of the proof ring.

Meanwhile, the test apparatus 300 is configured such that a plurality of test tanks 310 are arranged in a horizontal series at regular intervals.

Therefore, by arranging a plurality of the test tanks 310 in a horizontal series, it is possible to shorten the test time and simultaneously test various corrosion conditions applied to a plurality of specimens.

One side of the thermostat 400 is connected to a fluid supply pipe 410 for supplying the heated fluid to the test device 300 and a fluid discharge tube 420 for supplying the test device 300 to discharge the circulated fluid. .

A heater and a circulation pump are built in the thermostat 400, and the temperature of the fluid is raised to a set temperature through heating by the heater and circulation operation by the circulation pump. Therefore, the temperature of the test solution stored in the test tank can be kept constant by supplying the fluid (water) heated by the thermostat to the test tank 310 of the test apparatus 300 to circulate and discharge it. To this end, a fluid supply pipe 410 and a fluid discharge pipe 420 are respectively connected to one side of the thermostat 400 to supply or discharge the heated fluid. In addition, a flow control switch 430 for controlling the flow rate of the fluid may be installed at one side of the fluid supply pipe 410 and the fluid discharge pipe 420.

As shown in Figure 6, the neutralization tank 500 is to neutralize the test gas discharged from the test apparatus 300 to meet the environmental standards to convert into a non-toxic gas state that can be released into the atmosphere, packing on the top of the neutralization tank The inserted cover 510 is combined to be sealed, and a sodium hydroxide solution, which is a test gas neutralizer, is stored therein.

On one side of the neutralization tank 500, a plurality of gas inlets 520 are formed so that the test gas discharged from the test tank 310 flows, and a gas for discharging the neutralized gas by the neutralization solution inside the neutralization tank The outlet 530 is formed.

The test gas is precipitated through a chemical reaction with a neutralizing solution, and when the neutralizing solution is replaced, the precipitate is discharged through a discharge pipe together with the neutralizing solution.

The neutralization tank 500 is preferably formed of a transparent glass material so that the replacement cycle of the neutralization solution can be visually confirmed.

A pressure valve 540 for controlling the internal pressure of the neutralization tank 500 is installed on one side of the cover 510.

The reason for installing the pressure valve 540 is to automatically discharge gas when an overpressure occurs in the neutralization tank in consideration of the properties of the glass material.

Although the present invention has been described with reference to the accompanying drawings and preferred embodiments, it is apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the present invention. Therefore, the scope of the invention should be construed by the claims set forth to cover examples of many of these variations.

100: test cabinet 110: viewing window
120: door 130: duct
131: scrubber 140: plate
150: support means 151: vertical frame
152: support plate 200: gas supply device
210: nitrogen supply pipe 220: hydrogen sulfide supply pipe
230: gas control switch 300: test device
310: test tank 320: fracture detection unit
321: Sensing switch 322: Sensing cable
330: circulation pipe 340: fixing part
350: authorization means 351: axis
352: working nut 360: proof ring
370: stand 400: thermostat
410: fluid supply pipe 420: fluid discharge pipe
430: flow control switch 500: neutralization tank
510: cover 520: gas inlet
530: gas outlet 600: control panel
610: gas control unit 620: temperature control unit
630: Test gas flow meter 700: Distribution line
710: nitrogen supply line 720: hydrogen sulfide supply line
730: fluid supply line 740: fluid discharge line
750: check valve

Claims (10)

A test cabinet 100 in which a test space is formed, and a plurality of test devices 300 are installed in the test space;
A gas supply device 200 installed outside the test cabinet 100 and supplying a test gas to the test device 300;
Corrosion test solution and test gas is supplied to the inside, the test apparatus 300 for adding a tensile force to the specimen fixed therein;
A thermostat 400 installed on the outside of the test cabinet 100 and maintaining a constant temperature of the test solution of the test apparatus 300; And
It is installed on one side of the test space, the neutralization tank 500 for storing a neutralizing solution for neutralizing the test gas discharged from the test apparatus 300; stress corrosion cracking test system comprising a.
The method according to claim 1,
A duct 130 for sucking air inside the test cabinet and discharging it to the outside is installed at the top of the test cabinet 100, and a scrubber 131 for collecting particles floating in the gas is connected to the duct 130. Stress corrosion cracking test system characterized in that the.
The method according to claim 1,
A stress corrosion cracking test system, which is installed inside the test cabinet (100), and includes a plate (140) separating the test cabinet into a test space and a receiving space.
The method according to claim 3,
The support means 150 for supporting the test apparatus 300 is installed on the upper portion of the plate 140,
The support means 150 includes a plurality of vertical frames 151 installed at regular intervals on the upper portion of the plate 140, and a support plate 152 horizontally installed on the top of the vertical frame 151. Stress corrosion cracking test system.
The method according to claim 4,
In front of the support means 150, a control panel 600 is respectively installed in a number corresponding to the number of installations of the test apparatus 300,
The control panel 600 includes a gas control unit 610 for supplying or blocking hydrogen sulfide and nitrogen, which are test gases supplied to the test apparatus 300;
A temperature control unit 620 for controlling the temperature of the fluid for maintaining the test temperature; And
Stress corrosion cracking test system comprising a; test gas flow meter (630) for measuring the flow rate of the test gas.
The method according to claim 3,
A stress corrosion cracking test system characterized in that a plurality of distribution lines 700 in which a plurality of capillaries are arranged parallel to each other at regular intervals is installed on the upper portion of the plate 140.
The method according to claim 6,
The distribution line 700 includes a nitrogen supply line 710 and a hydrogen sulfide supply line 720 which are respectively connected to the gas supply device 200;
Stress corrosion cracking test system, characterized in that it comprises a; a fluid supply line 730 and a fluid discharge line 740, which are respectively connected to the thermostat 400 and are provided with check valves 750 on one side.
The method according to claim 1,
The gas supply device 200 is connected between the nitrogen supply source and the test device 300 nitrogen supply pipe 210 for supplying nitrogen;
And a hydrogen sulfide supply pipe (220) connected between a hydrogen sulfide supply source and a test apparatus (300) to supply hydrogen sulfide.
The method according to claim 1,
The test apparatus 300 is a stress corrosion cracking test system, characterized in that a plurality of test tanks 310 are configured to be arranged in a horizontal series at regular intervals.
The method according to claim 1,
A fluid supply pipe 410 for supplying the heated fluid to the test apparatus 300 and a fluid discharge pipe 420 for supplying the test apparatus 300 to discharge circulated fluid are connected to one side of the thermostat 400. Stress corrosion cracking test system characterized in that the.

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