KR101338205B1 - testing device for rupture disc - Google Patents

Abstract

The present invention relates to a new type of bursting apparatus for bursting discs for bursting of bursting discs, which is applied to an annual bursting apparatus in which two or more bursting discs are ruptured in sequence, such as an inflator.
To this end, the present invention provides an intensifier for generating and providing a high pressure fluid; In addition, the main frame and the main frame having a seating desk, and the seating desk of the main frame and the primary bursting disk and the secondary bursting disk are spaced apart from each other to form a high-pressure fluid provided from the pressure intensifier. And a plurality of pressure sensors configured to rupture each of the rupture disks sequentially so that the rupture test module performs a test on the rupture of each of the rupture disks, and a pressure sensor configured to sense pressure in a space where each rupture disk of the rupture test module is installed. An annual burst test apparatus for a burst disk is provided, comprising: an annual burst test device having a.

Description

Annual rupture testing apparatus for ruptured discs

The present invention relates to a rupture test apparatus for a rupture disc, and more particularly, to an annual rupture test apparatus for rupture test of a rupture disc that is applied to a device in which two or more rupture discs are sequentially ruptured, such as an inflator.

In general, a rupture disc is mainly used as a safety device in a system in which a gas or liquid fluid is stored.

That is, when the pressure in the system in which the fluid is stored exceeds the set pressure, the rupture disk is ruptured for the safety of the system so that a safety accident can be prevented through the release of the fluid in the system.

Of course, the above-mentioned rupture disk is mainly used in the safety device of the fluid system, as described above, but also widely used as a component of the device for instantaneous gas supply, such as an inflator.

That is, a burst disk is installed at both ends of the pressure storage tank of the device requiring the gas to seal the filling gas inside the storage tank, and then the instantaneous burst of the burst disk is induced by the operation request to fill the filling gas inside the storage tank. By releasing the momentary necessary gas is supplied to the device.

 In particular, in recent years, various types of annual bursting bursting devices have been provided in which a plurality of bursting disks are provided such as an inflator applied to an airbag device of a vehicle, thereby allowing the annual bursting to occur.

On the other hand, the rupture disk applied to the annual bursting rupture device as described above was necessary for the burst test in order to perform the prediction of the accurate burst pressure, accordingly, as previously disclosed in Patent No. 10-0805263 An apparatus is provided.

However, the conventional rupture test apparatus as described above is a structure that performs only a rupture test for a single ruptured disk, and the test for the annual ruptured rupture apparatus of a structure in which a plurality of ruptured disks are ruptured annually is not made correctly. There was a problem that could not be.

In other words, the annual bursting rupture apparatus is installed so that a plurality of rupture disks are spaced apart from each other, and when one rupture disk is ruptured, the other rupture disk is sequentially ruptured. Since it is not a structure for testing the burst by providing it instantaneously, the test for the annual burst device was not accurately performed.

The present invention has been made to solve the various problems according to the prior art described above, an object of the present invention is to provide a new type of rupture test of the rupture disk applied to the annual rupture apparatus in which two or more rupture disks are sequentially ruptured An annual burst test apparatus for a burst disk is provided.

Annual burst test device for a rupture disk of the present invention for achieving the above object is an intensifier for generating and providing a high-pressure fluid; In addition, a main frame having an appearance desk and a seating desk of the main frame and a primary bursting disk and a secondary bursting disk are spaced apart from each other to use the high pressure fluid provided from the intensifier. And a plurality of pressure sensors configured to rupture each of the burst disks sequentially so that a burst test module for testing a burst of each burst disk and a pressure in each of the burst disks of the burst test module are installed. Annual rupture tester having: characterized in that it comprises a.

In addition, the burst test module constituting the annual burst tester is fixedly installed on the upper surface of the seating desk of the main frame, the lower base and the fluid flow passage is formed to receive and supply the high-pressure fluid generated in the pressure intensifier, and the lower It is installed to be spaced apart from the upper surface of the base, the primary middle plate is formed to form a first communication hole communicating with the fluid flow passage, and is installed to be spaced apart from the upper surface of the primary middle plate, and communicates with the first communication hole A second middle plate formed with a second communication hole formed thereon, and an upper base formed to be spaced apart from the upper surface of the second middle plate, and having a discharge hole for discharging a high pressure fluid while communicating with the second communication hole; Lower base, the primary middle plate, the secondary middle plate and the upper base In addition to supporting the lifting movement of the lifter to be separated from each other selectively characterized in that it is configured to include.

In addition, the secondary middle plate is characterized in that the fluid inlet for providing a separate high-pressure fluid is further formed so that the inside of the second communication hole is maintained at a set pressure.

In addition, the lifting unit is installed so as to sequentially pass through the lower base, the primary middle plate, the secondary middle plate and the upper base support rod for supporting the lifting movement of the above configuration, the lower base and the 1 A plurality of restorations provided between the secondary middle plates, between the primary middle plate and the secondary middle plate, and between the secondary middle plate and the upper base, respectively, to provide a restoring force so as to space apart from each other; Installed on the seating desk of the main frame is characterized in that it comprises a pressing unit for providing a pressing force to selectively move the upper base downward.

In addition, the restoring body may be maintained in a compressed state on each opposing surface between the lower base and the primary middle plate, between the primary middle plate and the secondary middle plate, and between the secondary middle plate and the upper base. In addition to providing a space that is characterized in that each receiving groove is formed to prevent the departure of the restoring body.

In addition, the primary burst disk is interposed between the fluid outlet side of the first communication hole formed in the primary middle plate and the fluid inlet side of the second communication hole formed in the secondary middle plate, the secondary burst disk It is characterized in that it is interposed between the fluid outlet side of the second communication hole formed in the secondary middle plate and the fluid inlet side of the discharge hole formed in the upper base.

The pressure sensor may include a first pressure sensor installed on the first middle plate and sensing pressure in the first communication hole, and a second pressure sensor installed on the second middle plate and sensing pressure in the second communication hole. It is characterized by including a pressure sensor.

In addition, each of the opposing surfaces between the lower base, the primary middle plate, the secondary middle plate and the upper base is characterized in that the guide unevenness to guide the close contact with each other is formed.

The annual burst test apparatus for the burst disk of the present invention as described above has the effect that the burst test of the burst disk by the instantaneous ultra-high pressure is possible and the annual burst test of the two burst disks is enabled.

In particular, the annual burst test apparatus for the burst disk of the present invention has the effect that the overall structure is simple, the detachable to each burst disk can be made smoothly, and the accurate installation of each burst disk is possible.

In addition, the annual burst test apparatus for the burst disk of the present invention is capable of controlling the ultra-high pressure gas supply in addition to the instantaneous burst test, and also because of the control of the filling pressure in the primary burst disk and the secondary burst disk, environmental testing of various conditions Has the possible effect.

1 is a schematic configuration diagram illustrating an annual burst test apparatus for a burst disk according to a preferred embodiment of the present invention;
2 is a cross-sectional view illustrating a tear test module of the annual burst test device for a bursting disc according to a preferred embodiment of the present invention.
3 is a plan view showing the lifting unit of the tear test module of the annual burst test device for a bursting disc according to a preferred embodiment of the present invention
4 to 8 is a state diagram showing for explaining the process of installing two burst disks in the burst test module of the annual burst test apparatus for a burst disk according to a preferred embodiment of the present invention

Hereinafter, a preferred embodiment of the annual burst test apparatus for a rupture disk of the present invention will be described in more detail with reference to FIGS. 1 to 8.

As shown in FIG. 1, the annual burst test apparatus for the bursting disc according to the embodiment of the present invention includes a pressure intensifier 10 and an annual burst tester 20.

Here, the intensifier 10 is a device for generating and providing a high pressure fluid (eg, high pressure air) required for a burst test, and includes a gasbooster 11 capable of boosting the fluid and a high pressure fluid. It is configured to include a receiver (receiver tank) 12 and various switches and valves (not shown) to control the air pressure.

Particularly, in the embodiment of the present invention, the gas booster 11 is configured to have a specification capable of increasing pressure to 1500 bar and the receiver 12 is configured to have a specification capable of storing a high pressure fluid of 1500 bar or more.

The annual burst tester 20 is a device in which the annual burst test of the two burst disks 31 and 32 is performed, and is provided separately from the booster 10.

In the embodiment of the present invention, the annual burst tester 20 is proposed to include a main frame 100, a burst test module 200 and a plurality of pressure sensors (310, 320).

Here, the main frame 100 is configured to have a seating desk 110 as a portion forming the appearance of the annual burst tester 20, the burst test module 200 received from the intensifier 10 The bursting test of each of the bursting disks 31 and 32 using a high pressure fluid is provided in the seating desk 110 of the main frame 100, and the pressure sensors 310 and 320 are provided at the bursting test module ( Each burst disk 31, 32 of the 200 is provided to sense the pressure in the space provided.

The burst test module 200 includes a lower base 210, a primary middle plate 220, a secondary middle plate 230, as shown in FIG. 2. It is configured to include an upper base 240 and the lifting portion, which will be described in more detail for each configuration as follows.

First, the lower base 210 is a portion fixedly installed on an upper surface of the seating desk 110 of the main frame 100, and a fluid flow to a central portion thereof to receive and supply a high pressure fluid from the intensifier 10. The passage 211 is formed through the vertical direction.

Next, the primary middle plate 220 is a portion which is spaced apart from the upper surface of the lower base 210.

In this case, a first communication hole 221 communicating with the fluid flow passage 211 of the lower base 210 is formed in a central portion of the primary middle plate 220 in a vertical direction.

In addition, one of the pressure sensors 310 and 320 of each of the pressure sensors 310, 320 is installed to sense the pressure in the first communication hole (221).

Next, the secondary middle plate 230 is a portion which is spaced apart from the upper surface of the primary middle plate 220.

A second communication hole 231 communicating with the first communication hole 221 of the primary middle plate 220 is formed in the central portion of the secondary middle plate 230 in a vertical direction. The interior of the second communication hole 231 formed in the secondary middle plate 230 serves as a storage space in which a separate high pressure fluid is stored. In this case, the separate high pressure fluid refers to a high pressure fluid that replaces a gas for use other than a gas that ruptures the primary rupture disk 31, such as argon gas provided into the airbag when the inflator is used. it means.

On the circumferential surface of the secondary middle plate 230 is a fluid inlet 232 is filled with a separate high-pressure fluid into the second communication hole 231 to maintain the inside of the second communication hole 231 at a set pressure It is formed more. In this case, the high-pressure fluid filled in the second communication hole 231 is provided by driving the intensifier 100 as an example, but a fluid compressor (not shown) separate from the intensifier 100 is used. You can also create

In addition, the other pressure sensor 320 of each of the pressure sensors (310, 320) is installed to sense the pressure in the second communication hole (231).

On the other hand, the secondary middle plate 230 is not limited to being composed of only one as shown in the embodiment.

That is, although not shown, the secondary middle plate 230 may be configured to enable an annual burst test of three or more burst disks by configuring two or more plurality so that the burst disks may be additionally installed between each other. .

Next, the upper base 240 is a portion which is spaced apart from the upper surface of the secondary middle plate 230.

The upper base 240 has a discharge hole 241 through which the high pressure fluid is discharged while communicating with the second communication hole 231 of the secondary middle plate 230. At this time, the discharge hole 241 is in communication with the second communication hole 231 while the fluid inlet side is located in the central portion of the upper base 240 and the fluid outlet side is the circumferential surface of the upper base 240 It is formed to pass through.

Next, the lifting unit supports the lifting movement of the lower base 210, the primary middle plate 220, the secondary middle plate 230, and the upper base 240, and optionally between the respective components. As a portion to be spaced apart by a, it comprises a plurality of support rods 251, a plurality of restoration body 252 and the pressing portion.

Each of the supporting rods 251 of the lower base 210 and the primary middle plate 220 and the secondary middle plate 230 and the upper base 240 in a plan view as shown in FIG. It is installed so as to sequentially penetrate both circumferential portions, respectively, and serves to support the lifting movement of the above components.

In addition, the restoration body 252 is between the lower base 210 and the primary middle plate 220, between the primary middle plate 220 and the secondary middle plate 230, and the When there is no external force provided between the car middle plate 230 and the upper base 240, respectively, and serves to provide a restoring force so as to separate the corresponding components from each other, in the embodiment of the present invention An example is composed of a coil spring of.

In addition, a receiving groove for providing a space in which the restoration body 252 is maintained in a compressed state, and at the site where the restoration body 252 is provided, to prevent the external departure of the restoration body 252 ( 213, 233, and 234 are respectively formed correspondingly, and each receiving groove (213, 233, 234) is preferably formed while forming an isometric angle between the portions through which the support rods 251 pass in plan view.

In addition, the pressing portion is installed on the seating desk 110 of the main frame 100 serves to provide a pressing force to selectively move the upper base 240 downward, the pressing cylinder 261 and the pressing plate ( 262). At this time, the pressure cylinder 261 is installed so that the rod 261a is entered in the vertical direction on the upper side of the upper base 240, the pressure plate 262 is installed at the end of the rod 261a It is formed to press the upper surface of the upper base 240.

Meanwhile, two burst disks 31 and 32 are provided, and one of the burst disks (hereinafter, referred to as “primary burst disk”) 31 is formed in the first middle plate 220. Interposed between the fluid outlet side of the ball 221 and the fluid inlet side of the second communication hole 231 formed in the secondary middle plate 230, and another burst disk (hereinafter referred to as "second burst disk") 32 is interposed between the fluid outlet side of the second communication hole 231 formed in the secondary middle plate 230 and the fluid inlet side of the discharge hole 241 formed in the upper base 240.

Particularly, in the embodiment of the present invention, each of the opposing surfaces between the lower base 210, the primary middle plate 220, the secondary middle plate 230, and the upper base 240 guides a close contact with each other. To guide projections (216, 225, 226, 235, 236, 245) are presented, characterized in that each formed correspondingly.

The guide irregularities 216, 225, 226, 235, 236, 245 are in close contact with each other as the lower base 210, the primary middle plate 220, the secondary middle plate 230, and the upper base 240 are pressed by a pressing unit. When it is made to serve to guide the close contact with each other to the correct position.

In this case, the guide unevenness (216, 225, 226, 235, 236, 245) is most preferably formed in an inclined structure that is reduced in diameter toward the center.

In the following, the annual burst test procedure using the annual burst test apparatus for the bursting disc according to the preferred embodiment of the present invention configured as described above will be described in more detail in that order.

First, in the initial state before the installation of each of the burst disks 31 and 32, the pressing force by the pressing unit is not provided as shown in FIG. 4, and thus, between the lower base 210 and the primary middle plate 220. , The restoration body 252 provided between the primary middle plate 220 and the secondary middle plate 230, and between the secondary middle plate 230 and the upper base 240, respectively, provides the restoring force while providing the restoring force thereof. Keep the configurations spaced apart from each other.

Primary rupture between the fluid outlet side of the first communication hole 221 formed in the primary middle plate 220 and the fluid inlet side of the second communication hole 231 formed in the secondary middle plate 230 in the above state. Secondary rupture is provided between the disk 31 and the fluid outlet side of the second communication hole 231 formed in the secondary middle plate 230 and the fluid inlet side of the discharge hole 241 formed in the upper base 240. Install the disk 32. This is as shown in Figure 5 attached.

Then, after the rupture disks 31 and 32 are installed, the pressurizing cylinder 261 constituting the pressurizing portion is driven so that the pressurizing plate 262 pressurizes the upper base 240.

In this case, the upper base 240 is in contact with the secondary middle plate 230 while being gradually moved downward by the pressing force of the pressing plate 262, the secondary middle by the continuous pressing force of the pressing plate 262. The plate 230 is in contact with the primary middle plate 220, and subsequently the primary middle plate 220 is in contact with the lower base 210.

In this case, since the upper base 240, the secondary middle plate 230 and the primary middle plate 220 are guided by the support rod 251 constituting the lifting portion, its stable downward movement is made, in particular, the respective components Guide grooves 216, 225, 226, 235, 236, 245 formed on opposite surfaces between 210, 220, 230, and 240 coincide with each other in the correct position. This is the same as in FIGS. 6 and 7.

After the burst disks 31 and 32 are installed as described above, the high pressure fluid is filled into the second communication hole 231 formed in the secondary middle plate 230 as shown in FIG. 8.

At this time, the pressure of the high pressure fluid filled in the second communication hole 231 is provided through the burst pressure of the primary burst disk 31 and the burst pressure of the secondary burst disk 32 and the intensifier 10. It is set in consideration of the pressure of the high pressure fluid. In other words, considering that the pressure in the second communication hole 231 provides a force that resists the burst pressure of the primary burst disk 31, the pressure of the secondary burst disk 32 is not sufficient. When the high pressure fluid is provided through the intensifier 10 while being set to, the pressure is set such that the primary bursting disk 31 can be accurately ruptured at the set pressure.

Subsequently, an annual burst test of each of the burst disks 31 and 32 is performed by providing a high pressure fluid into the fluid flow passage 211 of the lower base 210 through the operation control of the intensifier 10.

That is, the high pressure fluid generated from the intensifier 10 is stored in the receiver, in which the instantaneous high pressure fluid is provided to the primary burst disk 31 by opening the valve (not shown). When the primary burst disk 31 exceeds its critical point, the primary burst disk 32 is ruptured, and the secondary burst disk 32 receives the instantaneous high-pressure fluid by the burst of the primary burst disk 31 and ruptures it sequentially. In this process, the pressure change is recorded while being sensed by each pressure sensor (310,320) is to be an annual burst test for the two burst disk (31,32).

Then, when the annual rupture test for the two rupture disks 31 and 32 is completed through the above process, the high pressure fluid is no longer provided to the fluid flow passage 211 by closing the valve, and then pressurization forming the pressurization part. The cylinder 261 is driven to cause the pressure plate 262 to release the pressure on the upper base 240.

Accordingly, the upper base 240 is spaced apart from the secondary middle plate 230 by receiving a restoring force of the restoring body 252 located between the secondary middle plates 230 and together with the primary middle plate. 220 also receives the restoring force of the restoring body 252 positioned between the second middle plate 230 and the lower base 210 to receive the restoring force of the second middle plate 230. ) And the lower base 210 to return to the original state.

As described above, the annual burst test apparatus for the burst disk according to the embodiment of the present invention enables the burst test of the burst disks 31 and 32 by the instantaneous ultrahigh pressure and the annual burst test of the two burst disks 31 and 32. This has the advantage made possible.

On the other hand, the annual burst test apparatus for the bursting disc of the present invention is not limited to that which can be implemented only with the structure of the above-described embodiment.

That is, various modifications may be made depending on the test conditions or the surrounding environment. For example, between the lower base 210 and the primary middle plate 220, the fluid flow passage 211 and the first communication hole 221 may be separated. By installing an additional burst disk (not shown), it is possible to omit the intensifier 10, or may be configured to provide an ultra-high pressure fluid to the primary burst disk 31 instantaneously. .

As such, the annual burst test apparatus for the burst disk of the present invention can be said to be a useful invention that can be applied in various forms as well as the annual burst test of the accurate burst disk.

10. Intensifier 11. Gas booster
12. Receiver 20. Annual burst tester
31. Primary Burst Disc 32. Secondary Burst Disc
100. Main Frame 110. Seating Desk
200. Burst Test Module 210. Lower Base
211. Fluid flow passages 220. Primary middle plate
221. First communication hole 230. Second middle plate
231. Second communication hole 232. Fluid inlet
240. Upper base 241. Outlet
251. Support Rod 252. Restoration Body
261.Pressure Cylinder 262.Pressure Plate
213,233,234. Accepted Home 216,225,226,235,236,245. Irregularities
310, 320. Pressure sensor

Claims (8)

An intensifier for generating and providing a high pressure fluid; And,
The main frame having a seating desk and a seating desk of the main frame and the primary bursting disk and the secondary bursting disk are spaced apart from each other by using a high pressure fluid provided from the pressure intensifier while forming an exterior. A bursting test module configured to rupture the bursting disks sequentially so that the bursting test module conducts a test of the bursting of each bursting disc, and a plurality of pressure sensors each sensing a pressure in a space in which the bursting disc of the bursting test module is installed. A tester;
Burst test module,
A lower base fixedly installed on an upper surface of a seating desk of the main frame, and having a fluid flow passage formed to receive and supply the high pressure fluid generated by the intensifier;
A primary middle plate which is spaced apart from the upper surface of the lower base and is formed with a first communication hole communicating with the fluid flow passage;
A secondary middle plate which is installed on the upper surface of the primary middle plate so as to be spaced apart from each other and is formed with a second communication hole communicating with the first communication hole;
An upper base installed spaced apart from an upper surface of the secondary middle plate and having a discharge hole for communicating with the second communication hole and discharging a high pressure fluid; and
A lifting unit for supporting the lifting movement of the lower base, the primary middle plate, the secondary middle plate, and the upper base, and selectively allowing the lifter to be selectively spaced apart from each other;
The second middle plate, the annual burst test device for a bursting disc, characterized in that the fluid inlet for providing a separate high-pressure fluid is formed so that the inside of the second communication hole is maintained at a set pressure.
delete delete The method of claim 1,
The elevating portion
A support rod configured to sequentially penetrate the lower base, the primary middle plate, the secondary middle plate, and the upper base to support the lifting movement of the above components;
A plurality of restoring forces are provided between the lower base and the primary middle plate, between the primary middle plate and the secondary middle plate, and between the secondary middle plate and the upper base, respectively, to provide a restoring force to each other. With the restoration of,
An annual burst test device for a bursting disc, characterized in that it comprises a pressing unit which is provided on the seating desk of the main frame to provide a pressing force to selectively move the upper base downward. 5. The method of claim 4,
Each opposing surface between the lower base and the primary middle plate, between the primary middle plate and the secondary middle plate, and between the secondary middle plate and the upper base
An annual burst test device for a rupture disk, wherein each receiving groove is provided to prevent space from leaving the restoring body while providing a space for maintaining the compressed state. The method of claim 1,
The primary burst disk is interposed between the fluid outlet side of the first communication hole formed in the primary middle plate and the fluid inlet side of the second communication hole formed in the secondary middle plate,
And the secondary burst disk is interposed between the fluid outlet side of the second communication hole formed in the secondary middle plate and the fluid inlet side of the discharge hole formed in the upper base. The method of claim 1,
The pressure sensor is
A first pressure sensor installed on the first middle plate and sensing pressure in the first communication hole;
And a second pressure sensor configured to sense the pressure in the second communication hole while being installed on the secondary middle plate. The method of claim 1,
An annual rupture testing apparatus for a rupture disc, wherein guide and irregularities for guiding a close contact with each other are respectively formed on opposite surfaces between the lower base, the primary middle plate, the secondary middle plate, and the upper base.

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