KR20220081031A - Tightness test system and test method for valve - Google Patents

Abstract

The gas tightness test system for a fluid control valve of the present invention includes a jig in which a valve fixing part to which a high-pressure container mounting part of a fluid control valve is screwed is formed, and a valve fixing part on a lower surface of the jig to apply a test gas to a set pressure. A gas supply unit for supplying to the jig, a chamber member disposed to be movable in a vertical direction on the upper surface of the jig to form a sealed chamber when in close contact with the upper surface of the jig, and a hydraulic operation unit for linearly moving the chamber member in the vertical direction and a vacuum pressure generating unit connected to the jig to form a vacuum pressure inside the chamber, and a gas leak inspection unit connected to the jig to detect whether the test gas leaks inside the chamber, In addition to performing the airtight test of the valves, it is possible to perform the airtight test of the valve mounting part where the valve is mounted on the valve body, thereby shortening the test time and improving the precision of the test.

Description

TIGHTNESS TEST SYSTEM AND TEST METHOD FOR VALVE

The present invention relates to a gas tightness test system for a fluid control valve that tests the tightness of a fluid control valve that controls the flow of raw material gas when the raw material gas stored in the high pressure container is filled in the high pressure container or supplied to the gas use part to check whether there is a defect. .

Currently, in the case of a hydrogen fuel cell system, a fluid control valve is installed in the high-pressure container in which the raw material gas is stored to control the flow of raw material gas when the high-pressure container is filled with the raw material gas, and when the raw material gas stored in the high-pressure container is supplied to the gas user Controls the flow of raw material gas.

The fluid control valve can precisely control the flow of raw material gas according to electrical signals, maintain a constant pressure of the fluid stored in the pressure vessel, and explode when the hydrogen fuel cell vehicle overturns or fire occurs. should be able to prevent

A conventional valve for a fluid control system is mounted on a high pressure cylinder and connected between a first region having a first pressure and a second region having a second pressure, as disclosed in US Patent No. 7,309,113 B2 (December 18, 2007). a valve body having a main flow passage formed thereon; a filter installed on the inlet side connected to the main flow passage; a manual valve installed in a portion communicating with the main flow passage to manually open and close the main flow passage; It includes a solenoid valve installed in the communicating back pressure passage to open and close the back pressure passage according to an electrical signal, and a shuttle valve installed in the main flow passage to block the main flow passage when overpressure occurs and open the main flow passage when normal pressure is reached. do.

In such a fluid control valve, since various valves are mounted on the valve body in a screw-coupled manner, it is essential to perform an airtight test after the valve is manufactured.

US Registered Patent US 7,309,113 B2 (2007 Dec. 18)

Accordingly, it is an object of the present invention to provide a leak-tightness test system for a fluid control valve that tests the leak-tightness of the fluid control valve to determine whether it is defective.

Another object of the present invention is to perform a tightness test of all valves mounted on the valve body in one test system, as well as perform an airtight test of the valve mounting part where the valve is mounted on the valve body, thereby reducing the test time and precision of the test To provide a tightness test system for fluid control valves that can improve

In order to achieve the above object, the gas tightness test system for a fluid control valve of the present invention includes a jig in which a valve fixing part to which the high-pressure container mounting part of the fluid control valve is screwed is formed, and the valve fixing part is connected to the lower surface of the jig for test gas A gas supply unit for supplying a gas to the fluid control valve at a set pressure, a chamber member disposed to be movable in a vertical direction on the upper surface of the jig and forming a sealed chamber when in close contact with the upper surface of the jig, and the jig is connected to the chamber It includes a vacuum pressure generator for forming a vacuum pressure therein, and a gas leak tester connected to the jig to detect whether the test gas leaks into the chamber.

A sealing packing member for sealing the inside of the chamber may be mounted on the upper surface of the jig at a portion in contact with the lower surface of the jig.

The jig is in the form of a disk, and a valve fixing part to which the fluid control valve is sealingly screwed is formed to pass therethrough, and a hole for providing a vacuum pressure providing vacuum pressure into the chamber and a gas leak connected to the gas leak test part A hole for inspection may be formed to pass through.

As the test gas, a gas in which 95% nitrogen and 5% helium are mixed is used and the supply pressure may be formed in a range of 100 bar to 110 bar.

In the airtight test method for a fluid control valve, the fluid control valve is mounted on a jig and when the setting for the airtight test is completed, a low-pressure test gas is injected into the fluid control valve from the gas supply to perform a tightness test of the fluid control valve in a low pressure state. In the first airtight test step and the first air tightness test, if the fluid control valve is confirmed to be normal, the manual valve is in the open state and the solenoid valve is closed. When the airtightness of the solenoid valve is confirmed to be normal in the 2nd airtight test step of performing the airtight test of In the 3rd airtight test step of injecting into the valve to test the airtightness of the manual valve, and when it is confirmed that the airtightness of the manual valve is normal in the 3rd airtight test, the outlet valve is sealed, the solenoid valve and the manual valve are opened It includes a fourth air tightness test step of checking for leaks in the valve mounting part to which the valve is screwed.

The first air tightness test step includes the steps of mounting the fluid control valve on the jig, lowering the chamber member, and forming a sealed chamber by closely adhering to the jig, and injecting the test gas into the fluid control valve at a low pressure; It may include forming a vacuum pressure set therein, and measuring the amount of gas leakage for a set time.

In the second air tightness test step, the manual valve is opened and the solenoid valve is closed, and a high-pressure test gas is injected into the fluid control valve to act on the closed solenoid valve, and the inside of the chamber It may include the steps of forming a set vacuum pressure, and measuring the amount of gas leakage for a set time.

The third air tightness test step includes the steps of putting the manual valve in a closed state and the solenoid valve in an open state, injecting a high-pressure test gas into the fluid control valve to act on the manual valve in a closed state, and inside the chamber It may include the steps of forming a set vacuum pressure, and measuring the amount of gas leakage for a set time.

The fourth air tightness test step includes the steps of opening the manual valve and the solenoid valve, sealing the outlet pipe through which gas is discharged or filled, and injecting high-pressure test gas into the fluid control valve to form a flow path formed in the valve body. It may include the steps of allowing the test gas to act on a valve mounting portion on which a plurality of various valves are mounted, forming a vacuum pressure set inside the chamber, and measuring the amount of gas leakage for a set time.

As described above, the air tightness test system of the fluid control valve of the present invention performs the air tightness test of all valves mounted on the valve body in one test system, as well as the air tightness test of the valve mounting part where the valve is mounted on the valve body. This can shorten the test time and improve the precision of the test.

1 is a cross-sectional view of a fluid control valve according to an embodiment of the present invention.
2 is a cross-sectional view of a system for testing the tightness of a fluid control valve according to an embodiment of the present invention.
3 is a flowchart illustrating a method for testing the airtightness of a fluid control valve according to an embodiment of the present invention.
4 is a flowchart illustrating a primary air tightness test method of a fluid control valve according to an embodiment of the present invention.
5 is a flowchart illustrating a secondary air tightness test method of a fluid control valve according to an embodiment of the present invention.
6 is a flowchart illustrating a third air tightness test method of a fluid control valve according to an embodiment of the present invention.
7 is a flowchart illustrating a fourth air tightness test method of a fluid control valve according to an embodiment of the present invention.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings. In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the content throughout this specification.

As shown in FIG. 1 , the fluid control valve 100 according to an embodiment includes a valve body 10 mounted in a high-pressure container in which raw material gas is stored and a plurality of flow paths through which the raw material gas passes, the valve body 10 , and the valve body. A manual valve 12 mounted on (10) to manually open and close the flow path, a solenoid valve 14 mounted on the valve body 10 to automatically open and close the flow path according to an electrical signal, and the valve body (10) The inlet pipe 16 and 18, which is installed at the part inserted into the high-pressure container of When the temperature of the high-pressure container rises in the event of a fire due to a fire, a Pressure Relief Device 22 that releases the raw material gas in the high-pressure container to the outside to prevent the high-pressure container from exploding, and the raw material gas in the high-pressure container to the outside and a bleed valve 24 for venting.

A high-pressure container mounting portion 26 having a male screw portion is formed in the valve body 10 to be screw-coupled to the high-pressure container.

The inlet pipes 16 and 18 include a first inlet pipe 16 for filling the source gas into the high-pressure vessel, and a second inlet pipe 18 through which the source gas stored in the high-pressure vessel is discharged.

The flow path of the valve body 10 is a first flow path 30 connecting between the first inlet pipe 16 and the manual valve 12, and a second inlet pipe 18 and a solenoid valve 14. It includes a second flow path 32 and a third flow path 34 connecting between the manual valve 12 and the outlet pipe 20, and the first flow path 30 and the second flow path 32 are connected to the solenoid valve ( 14) through which they communicate with each other.

The valve body 10 is provided with a valve mounting portion 38 in which a female screw portion is formed so that various valves, inlet and outlet pipes and pressure relief devices described above are mounted by screwing, and various valves are screwed to each valve mounting portion. is fixed

Such a hydraulic control valve is provided with an airtight inspection system for inspecting whether each valve operates normally without airtightness and whether the airtightness of the valve mounting unit 38 is maintained.

As shown in FIG. 2, the airtight inspection system according to an embodiment includes a jig 50 in which the valve fixing part 52 to which the high-pressure container mounting part 26 of the fluid control valve 100 is screwed is formed, and the jig. The gas supply part 54 connected to the valve fixing part 52 on the lower surface of the 50 and supplying the test gas, and the jig 50 are disposed to be movable in a straight line in the vertical direction on the upper surface of the jig 50 on the upper surface of the The chamber member 60 forming the sealed chamber 62, the hydraulic operation part 64 for linearly moving the chamber member 62 in the vertical direction, and the jig 50 are connected to the chamber 62 inside. It includes a vacuum pressure generating unit 66 that forms a pneumatic pressure, and a gas leakage inspection unit 68 connected to the jig 50 to detect whether the test gas leaks inside the chamber 62 .

The jig 50 is formed in the form of a disk, and a sealing packing member 70 is mounted on a portion in contact with the chamber member 60 on the upper surface. to do it

In the jig 50 , a hole 72 for providing a vacuum pressure connected to the vacuum pressure generator and a pipe is formed to pass through, and a hole portion 74 for a gas leak test connected to the gas leak tester is formed to pass through. For the test gas, a mixture of 95% nitrogen and 5% helium is used, and the gas leak tester checks the amount of helium leak to check whether there is a gas leak.

The gas supply unit 54 is connected to the valve fixing unit 52 and the pipe 80 , and a pressure gauge 84 for measuring the supply pressure of the test gas is mounted on the pipe 80 .

The upper surface of the chamber member 60 is connected to the hydraulic operation unit 64 and a space for forming the chamber 62 is formed, and a flange portion 82 that is in close contact with the upper surface of the jig 50 is formed at the lower end. .

A test method of the airtight inspection system according to an embodiment of the present invention configured in this way will be described below.

3 is a flowchart of a gas tightness inspection method according to an embodiment of the present invention.

First, the fluid control valve 100 is mounted on the jig 50 (S10). That is, the high-pressure container mounting part 26 of the fluid control valve 100 is screwed to the valve fixing part 52 formed in the jig 50 and fixed.

When the setting of the fluid control valve in the airtight test device is completed, a low pressure test gas is injected into the fluid control valve 100 from the gas supply unit 54 to check whether the airtightness of the fluid control valve 100 is maintained at low pressure. Car air tightness test is performed (S20).

When it is confirmed that the fluid control valve 100 is normal in the first airtight test, the manual valve 12 is in an open state and the solenoid valve 14 is in a closed state, and then the high-pressure test gas is transferred to the fluid control valve 100. A secondary airtight test of testing the airtightness of the solenoid valve 14 by injection is performed (S30).

If it is confirmed that the airtightness of the solenoid valve 14 is normal in the second airtight test, the manual valve 12 is closed and the solenoid valve 14 is opened, and then the high-pressure test gas is applied to the fluid control valve 100 A third airtight test is performed to test the airtightness of the manual valve 12 by injecting it into the (S40).

When it is confirmed that the airtightness of the manual valve 12 is normal in the third airtight test, the outlet valve 20 is sealed, the solenoid valve 14 and the manual valve 12 are opened, and various valves are screwed into the valve mounting part. A fourth airtight test to check the leakage in (38) proceeds (S50).

The first air tightness test will be described in detail. 4 is a flowchart of the first airtight test.

After the fluid control valve 100 is mounted on the jig 50 and the hydraulic operation unit 64 is operated, the chamber member 60 descends and is in close contact with the jig 50 to form a sealed chamber 62 (S11). ).

In this state, the gas supply unit 54 is operated to inject the test gas into the fluid control valve 100 at a low pressure. At this time, the pressure of the test gas is supplied at a low pressure of 11 to 14 bar (S12).

And a vacuum pressure set inside the chamber 62 is formed (S13). That is, the vacuum generator 66 connected to the jig 50 is operated to form a vacuum pressure set inside the chamber 62 .

In this state, the amount of gas leakage is measured for a set time (S14). That is, the test time is maintained for about 10 to 20 seconds, and the gas leak tester 68 checks whether the test gas has leaked into the chamber 62 . At this time, the gas leak inspection unit 68 uses equipment for inspecting helium gas, and the helium gas leak rate is 1,35*10 ^-3 atm.cc/s as a set value, and if it is less than this set value, it is judged as normal, and if it is more than the set value, it is defective judge

The second air tightness test will be described in detail. 5 is a flowchart of the secondary air tightness test.

If it is confirmed that there is no leakage of the fluid control valve when low-pressure test gas is injected in the first airtight test, proceed with the second airtight test.

In the second airtight test, after the second air tightness test is completed, the chamber member is raised to expose the fluid control valve, the manual valve 12 is opened, and the solenoid valve 14 is closed (S21).

In this state, the test gas is injected into the fluid control valve 100 (S22). The test gas is injected at a high pressure of 875 bar to 885 bar. When the pressure of the test gas reaches the set pressure, the chamber member 60 is lowered to seal the chamber 62, and a vacuum pressure set inside the chamber 62 is formed (S23).

In this state, the amount of gas leakage is measured for a set time (S24). That is, the test time is maintained for about 10 to 20 seconds, and the gas leak tester 68 checks whether the test gas has leaked into the chamber 62 .

Since the test gas is in a state acting on the solenoid valve 14 , when the gas leak test unit 68 detects a gas leak, the failure of the solenoid valve 14 can be confirmed.

The third air tightness test will be described in detail. 6 is a flowchart of the third air tightness test.

In the third airtight test, the manual valve 12 is placed in a closed state, and the solenoid valve 14 is placed in an open state (S31). That is, a connector for power connection is connected to the solenoid valve 14 , and power is applied to the solenoid valve 14 to make it open.

In this state, the test gas is injected into the fluid control valve 100 (S32). The test gas is injected at a high pressure of 875 bar to 885 bar. When the pressure of the test gas reaches the set pressure, after disconnecting the connector connecting the solenoid valve 14, the chamber member 60 is lowered to seal the chamber 62, and the vacuum pressure set inside the chamber 62 to form (S33).

At this time, when the connector is disconnected from the solenoid valve 14, the solenoid valve 14 returns to the closed state, but the test gas is injected through the first flow path 30, and the high-pressure test gas acts on the manual valve 12. .

In this state, the amount of gas leakage is measured for a set time (S34). That is, the test time is maintained for about 10 to 20 seconds, and the gas leak tester 68 checks whether the test gas has leaked into the chamber 62 .

Since the test gas is in a state acting on the manual valve 12 , when the gas leak test unit 68 detects a gas leak, the failure of the manual valve 12 can be confirmed.

The 4th air tightness test will be described in detail. 7 is a flowchart of the fourth airtight test.

In the fourth airtight test, the manual valve 12 and the solenoid valve 14 are opened, and the outlet pipe 20 from which gas is discharged or filled is sealed (S41).

Then, a high-pressure test gas is injected into the fluid control valve 100 so that the test gas acts on the valve mounting part 38 on which a plurality of various valves are mounted through a plurality of flow paths formed in the valve body 10 (S42). .

The test gas is injected at a high pressure of 875 bar to 885 bar, and when the pressure of the test gas reaches the set pressure, the chamber member 60 is lowered to seal the chamber 62, and the vacuum pressure set inside the chamber 62 to form (S43).

In this state, the amount of gas leakage is measured for a set time (S44). That is, the test time is maintained for about 10 to 20 seconds, and the gas leak tester 68 checks whether the test gas has leaked into the chamber 62 .

Since the test gas has acted on the valve mounting unit to which each valve is mounted through a plurality of flow paths, when the gas leak test unit 68 detects a gas leak, the failure of the valve mounting unit 38 can be confirmed.

In this way, the airtight test system for a fluid control valve according to an embodiment of the present invention is a gas leak test system in one airtight test system, whether gas leakage, manual valve leakage, solenoid valve leakage, and various valves are mounted at low pressure. It is possible to check the leakage of the valve mounting part, so that the test time can be shortened and the test precision can be improved.

In the above, the present invention has been illustrated and described with examples of specific preferred embodiments, but the present invention is not limited to the above-described embodiments, and within the scope of not departing from the spirit of the present invention, common knowledge in the art to which the invention pertains Various changes and modifications will be possible by those who have

10: valve body 12: manual valve
14: solenoid valve 16,18: inlet pipe
20: outlet pipe 26: high-pressure vessel mounting part
50: jig 52: valve fixing part
54: gas supply unit 60: chamber member
62: chamber 64: hydraulic actuation part
66: vacuum pressure generating unit 68: gas leak inspection unit

Claims (12)

a jig in which a valve fixing part to which the high-pressure container mounting part of the fluid control valve is screwed is formed;
a gas supply unit connected to the valve fixing unit on the lower surface of the jig to supply the test gas to the fluid control valve at a set pressure;
a chamber member disposed to be movable in a straight line on the upper surface of the jig and forming a sealed chamber when in close contact with the upper surface of the jig;
a hydraulic operation unit for linearly moving the chamber member in the vertical direction;
a vacuum pressure generator connected to the jig to form a vacuum pressure inside the chamber; and
Airtightness test system for a fluid control valve including a gas leak tester connected to the jig to detect whether the test gas leaks inside the chamber. According to claim 1,
Airtightness test system for a fluid control valve in which a sealing packing member for sealing the inside of the chamber is mounted on the upper surface of the jig at a portion in contact with the lower surface of the jig. According to claim 1,
The jig is in the form of a disk, and a valve fixing part to which a fluid control valve is sealedly screwed is formed to pass through the jig, and a hole for providing a vacuum pressure providing vacuum pressure into the chamber and a gas leak connected to a gas leak inspection part Airtightness test system for fluid control valves in which a hole for inspection is formed to pass through. According to claim 1,
The test gas is a gas containing 95% nitrogen and 5% helium, and the supply pressure is 100bar to 110bar. 5. The method of claim 4,
The gas leak test unit is a gas tightness test system for a fluid control valve in which a helium detection system for detecting helium is used. When the fluid control valve is mounted on the jig and the setting for the tightness test is completed, a first airtight test step of injecting a low-pressure test gas from the gas supply to the fluid control valve to perform a tightness test of the fluid control valve in a low pressure state;
If it is confirmed that the fluid control valve is normal in the first airtight test, the manual valve is in the open state and the solenoid valve is in the closed state, and then high-pressure test gas is injected into the fluid control valve to conduct the air tightness test of the solenoid valve. air tightness test step;
If it is confirmed that the airtightness of the solenoid valve is normal in the second airtight test, the manual valve is closed and the solenoid valve is open. secondary air tightness test stage; and
If the airtightness of the manual valve is confirmed in the 3rd airtight test, the 4th airtight test step is performed to seal the outlet valve and check the leakage in the valve mounting part where various valves are screwed with the solenoid valve and manual valve open. Airtightness test method for fluid control valves, including. 7. The method of claim 6,
The first airtight test step includes the steps of mounting the fluid control valve on the jig, lowering the chamber member, and forming a sealed chamber by adhering to the jig;
injecting the test gas at a low pressure into the fluid control valve;
forming a vacuum pressure set inside the chamber; and
A gas tightness test method for a fluid control valve comprising the step of measuring the amount of gas leakage for a set time. 8. The method of claim 7,
If the pressure of the test gas is 11 to 14 bar, the set time is 10 to 20 seconds, and the gas leakage is 1,35*10 ^-3 atm.cc/s or more, the leak test method for a fluid control valve is judged as defective. 7. The method of claim 6,
The second airtight test step is to set the manual valve in an open state, and the solenoid valve in a closed state;
injecting a high-pressure test gas into the fluid control valve to act on the closed solenoid valve;
forming a vacuum pressure set inside the chamber; and
Measuring the amount of gas leakage for a set time; Airtightness test method for a fluid control valve comprising a. 10. The method of claim 9,
The pressure of the gas for the test is 875 bar ~ 885 bar airtight test method for a fluid control valve. 7. The method of claim 6,
The third airtight test step is to put the manual valve in the closed state, and the solenoid valve in the open state;
injecting a high-pressure test gas into the fluid control valve to act on the closed manual valve;
forming a vacuum pressure set inside the chamber; and
Measuring the amount of gas leakage for a set time; Airtightness test method for a fluid control valve comprising a. 7. The method of claim 6,
The fourth airtight test step includes: sealing the outlet pipe through which gas is discharged or filled with the manual valve and the solenoid valve in an open state;
injecting a high-pressure test gas into the fluid control valve so that the test gas acts on a valve mounting part on which a plurality of various valves are mounted through a flow path formed in the valve body;
forming a vacuum pressure set inside the chamber; and
Measuring the amount of gas leakage for a set time; Airtightness test method for a fluid control valve comprising a.

Images