KR101955717B1 - Airtight test method for projectile application - Google Patents

Abstract

The present invention relates to a method of testing a projectile airtightness, and more particularly, to a method of testing airtightness of a projectile with limited space due to assembly and disassembly, wherein airtightness of the projectile can be maintained even after the airtightness test, The present invention relates to a method of testing airtightness of a projectile in which follow-up is easy.

Description

{Airtight test method for projectile application}

The present invention relates to a method of testing a projectile airtightness, and more particularly, to a method of testing airtightness of a projectile with limited space due to assembly and disassembly, wherein airtightness of the projectile can be maintained even after the airtightness test, The present invention relates to a method of testing airtightness of a projectile in which follow-up is easy.

The airtightness test of piping (including piping and components therefor) which receives liquid pressure and fluid containing liquid phase and gaseous pressure can be performed by a pressure drop method which confirms whether the pressure decreases for a certain period of time under applied pressure.

The pressure drop method for the airtightness test of the above-described piping is disclosed in Korean Patent Laid-Open Publication No. 10-2009-0045559 ("Pressure Drop Test Kit for Piping ", 2009.05.08.).

A method of performing the airtightness test of a pipe using the above-described pressure drop method will be described in detail with reference to FIG.

As shown in FIG. 1, in the method of performing the airtightness test of the pipe 1 using the pressure drop method, in a state in which internal pressure is applied to the pipe 1 by using a pressurized gas (for example, helium) (Leakage) of helium is detected by using a He detector 3 at a test site 1-1 where the same leakage as the connection portion of the pipeline 1 may occur frequently. I will test whether.

In order to utilize the pressurized gas such as helium, pressurized gas is supplied from the pressurized gas storage unit 2-1 where the pressurized gas is stored, and a pressure control unit 2-2 and a valve 2-3 ) Or the like can be tested through the pressurizing portion 2 to determine whether the portion 1-1 under test is airtight using the pressure drop method in the piping 1.

FIG. 2 is a view showing a method of performing the airtightness test using the pressure drop method when a large number of components constituting the piping 1 are present and a large number of test sites 1-1 including the connection portion of the piping 1 are present.

As shown in FIG. 2, when the pressure drop is confirmed by using the pressure drop method in the case where the number of the test target portions 1-1 is large in the piping 1, It is confirmed whether leakage of helium occurs in the region 1-1, and the confirmed region 1-1 is subjected to follow-up to maintain airtightness.

However, if the pipeline is a projectile with limited installation space, there is a problem in that it is not easy to follow up after confirming the airtightness using the pressure drop method shown in FIGS. 1 and 2. FIG.

More specifically, when the projectile needs to take a follow-up action (replacing and repairing the sealing portion of the projectile pipe) immediately after confirming the leak through the airtightness test, It is not only difficult to disassemble, but also has a disadvantage that it needs to be disassembled to a large assembly unit at the top of the launch vehicle.

Korean Patent Publication No. 10-2009-0045559 ("Pressure Drop Test Kit for Piping ", 2009.05.08.)

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a method of testing airtightness of a projectile with limited space due to assembly and separation, And to provide a test method of a projectile-applied airtight test in which the measures are easy.

The airtightness test method for projectile application according to the present invention includes the steps of forming airtightness to form airtightness on the outer circumferential surface of the airtight object to confirm the airtightness of the projectile; A fluid injecting step of injecting a fluid into the airtight body; And measuring fluid molecules injected and diffused in the fluid injecting step at an open end of the projectile.

In addition, the airtight body is a plastic bag.

Further, the fluid is characterized by being helium.

In addition, the fluid injecting step uses a tubular injection device capable of injecting fluid into the airtight body.

The fluid molecule measurement step is characterized by measuring the diffusion of a molecule using a fluid molecule measurement device.

The airtightness test method of the projectile according to the present invention is advantageous in that the airtightness of the projectile can be tested more easily than the conventional pressure drop method in which the airtightness of the projectile is tested and a separate device for maintaining the pressure inside the projectile is required .

In addition, the test method for projectile-applied airtightness test according to the present invention can test the airtightness of the projectile and maintain the airtightness of the projectile using the minimum device. Therefore, even if the leakage of the pipeline is confirmed, There is no need to perform work.

In addition, the test method for projectile-applied airtightness test according to the present invention is advantageous in that it can test whether airtightness of a projectile is tested, and can maintain airtightness and can be advantageously applied to a projectile which is disadvantageous in disassembly and reassembly according to space constraints.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a conventional airtightness testing method of a pipe,
FIG. Another drawing showing the airtightness test method of a pipe.
3 is a view illustrating a method of testing a projectile applied airtightness according to the present invention,
4 is another diagram illustrating a method of testing a projectile applied airtightness according to the present invention.
5 is a view showing a procedure of a method of testing a projectile-applied airtightness according to the present invention.

Hereinafter, a method of testing a projectile-applied airtightness test according to the present invention having the above-described characteristics will be described in detail with reference to the accompanying drawings.

Prior to this, terms and words used in the present specification and claims should not be construed in a conventional or dictionary sense, and the inventor should appropriately define the concept of the term to describe its invention in the best possible way The present invention should be construed in accordance with the spirit and concept of the present invention.

It is therefore to be understood that the embodiments described herein and the arrangements shown in the drawings are only the most preferred embodiments of the present invention and that various equivalents and modifications may be substituted for them at the time of the present application .

FIG. 3 is a view showing a method of testing a projectile airtightness test according to the present invention, FIG. 4 is a view showing another method of testing a projectile airtightness test according to the present invention, FIG. Fig.

3 to 5, a projectile-applied airtightness testing method (S1000) according to the present invention is a pipeline in which a gas or a liquid fluid flows, (Confidentiality) of the product.

The projectile-applied airtightness testing method (S1000) according to the present invention includes a hermetically sealed body forming step (S100) for forming an airtight body (300), a fluid injecting step (S200) for injecting a fluid into the airtight body (300) (S300) of measuring a fluid molecule diffused at an open end of the fluid molecule (100).

The airtightness forming step S100 is a step of forming an airtightness body 300 capable of maintaining airtightness with the outside on the outer circumferential surface of the airtightness target portion 110 for confirming the airtightness of the projectile 100 .

As described above, the above-described projectile 100 is a general type of pipe through which the fluid flows, but it is needless to say that various forms of the fluid can be smoothly flowed therein.

The hermetic sealing part 110 may be a connecting part (flange of a pipe) or the like for forming the projectile 100 in which the fluid inside the hermetic sealing part 110 may be frequently leaked. In this case, It is a matter of course that any portion may be applicable as long as it is a region where leakage of water is likely to occur.

At this time, it is preferable that the hermetic body 300 is formed of various materials without limiting the hermetic sealing part 110 from the outside so long as it can maintain airtightness from the outside.

However, the hermetic body 300 in the projectile-applied airtightness testing method (S1000) according to the present invention may use a plastic bag.

That is, by forming the airtight body 300 according to the present invention with a plastic bag, not only the airtightness of the airtightness target portion 110 can be maintained, but also the storage of the airtightness body 300 is easy And it is advantageous that the airtightness body 300 is easily installed in the airtightness target portion 110.

The fluid injecting step (S200) injects fluid into the hermetic body (300).

In this case, it is preferable that the fluid is made of helium. However, if it is possible to easily detect the airtightness test of the projectile 100 in addition to helium as one embodiment of the airtightness testing method (S1000) according to the present invention, It is of course possible to inject it as a substance.

In this case, the fluid injecting step (S200) may use a tubular injecting device (240) capable of injecting fluid into the airtight body (300), wherein the injecting device (240) It is preferable that the capillary tube 300 is formed of a capillary tube or the like which can be injected into the airtight body 300.

However, the injector 240 is not limited thereto, and various embodiments are possible if the fluid can be injected into the hermetic body 300 so as to have a constant pressure and flow rate.

In addition, an apparatus for injecting a fluid such as helium into the airtight body 300 includes a fluid storage unit 210 in which a fluid is stored, a fluid storage unit 210 in which the fluid stored in the fluid storage unit 210 is maintained at a constant pressure And a fluid injection unit 200 including a pressure control unit 220 and a valve 230, which are formed to supply the fluid into the hermetic body 300 with a flow rate.

The fluid injection unit 200 includes the fluid reservoir 210, the pressure control unit 220, and the valve 230, which are described above. .

The fluid molecule measurement step S300 is a step of measuring the fluid molecules injected into the hermetic body 300 in the fluid injection step S200 at an open end of the projectile 100. [

That is, in the step of measuring the fluid molecules (S300), when fluid leaks due to damage or breakage of the airtight object 110 of the projectile 100, fluid molecules of the fluid injected into the airtight body 330, It is possible to test the airtightness at the airtight subject 110 by measuring the presence or the amount of diffusion of the dispersed fluid molecules.

In this case, the fluid molecule measurement step S300 may measure the diffusion of fluid molecules using the fluid molecule measurement device 400, and in the projectile airtightness test method S1000 according to the present invention, The fluid molecule measuring apparatus 400 can be used as a helium molecule measuring apparatus (He detector).

4, when a plurality of airtight sealing target portions 110 of the projectile 100 are formed, the fluid molecule measuring device 400 may include a fluid molecule measuring device (not shown) disposed at one open end of the projectile 100, It is preferable that the fluid molecule measurement device 400 is provided on at least one confidential target site 110 in order to find the confidential target site 110 that leaks out of the confidential target site 110.

The locations and positions of the fluid molecule measuring device 400 are determined depending on the size of the projectile 100, the type of fluid flowing inside the projectile 100, and the airtightness target portion 110 formed on the projectile 100, The number and position of the position where the fluid molecule measuring apparatus 400 is placed may vary depending on various test factors, and thus various embodiments are possible, and thus the present invention is not limited thereto.

As described above, the projectile-applied airtightness testing method (S1000) according to the present invention is a method for testing airtightness of the airtight object part (110) of the projectile body (100) 110 to perform the airtightness test, which is advantageous compared with the airtightness test using the conventional pressure drop method.

Particularly, the projectile-applied airtightness testing method (S1000) according to the present invention is a method in which airtight sealing target portion 110 is hermetically sealed by airtight sealing body 300 so that even if leakage occurs at airtight sealing target portion 110, There is an advantage that it is not necessary to immediately take subsequent measures such as disassembly and repair of the confidential object 110. [

This means that the projectile 100 can be moved to a place where the space is unrestricted in the future by keeping airtight without taking immediate follow-up action of the projectile 100 having space constraints, There is an advantage that it can take.

S1000: Airtight test method for launch vehicle application
S100: airtight body forming step
S200: fluid injection step
S300: fluid molecule measurement step
100: Projectile
110: Confidential area
200: fluid injection part
210:
220:
230: Valve
240: injection device
300: air tight
400: fluid molecule measuring device

Claims (5)

An airtightness forming step (S100) of forming a hermetic body (300) as a plastic bag capable of maintaining airtightness on the outer circumferential surface of the airtight object portion (110) for confirming airtightness of the projectile (100);
A fluid injecting step (S200) of injecting fluid into the airtight body (300) by using an injection device (240) in the form of a scanning tube capable of injecting a fluid into the airtight body (300); And
The presence or the amount of diffusion of the fluid molecules diffused into the projectile 100 of the fluid injected in the fluid injecting step S200 is selected from among the open ends of the projectile 100 and the interior of the airtight subject 110 And a fluid molecule measurement step (S300) of measuring at least one of the fluid molecules with the fluid molecule measurement device (400).
delete The method according to claim 1,
The fluid
Lt; RTI ID = 0.0 > helium. ≪ / RTI >
delete delete

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