KR200460111Y1 - rupture disc assembly - Google Patents

Abstract

The present invention relates to a new type of ruptured disc assembly capable of precisely destroying a destructive sensor at the same time as a ruptured disc is ruptured and also providing a stable installation structure for the destructive sensor.

To this end, the present invention relates to a rupture disk provided on a fluid inflow / outflow side in a pressure vessel, in which a plurality of rupture grooves are formed to rupture when the pressure in the pressure vessel is out of a set pressure range, And a part of the rupture disk is installed so as to pass through the rupture groove while being formed on the rupture direction side surface of the rupture disk and a distance formed by the length of the rupture disk is larger than a distance of the width, Wherein the destruction sensor is installed such that the longitudinal direction of the destruction sensor is perpendicular to the bending direction of the rupture portion due to the rupture of the rupture disk.

Rupture disk, destruction sensor, installation direction, reinforcement ring

Description

Rupture disc assembly

The present invention relates to a new type of ruptured disc assembly capable of precisely destroying a destructive sensor at the same time as a ruptured disc is ruptured and also providing a stable installation structure for the destructive sensor.

Generally, a ruptuer disc assembly is used as a safeguard in a system in which 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 bursting disc is ruptured for the safety of the system so that safety accidents can be prevented through the release of the fluid in the system.

In particular, the rupture disk assembly is provided with a rupture sensor so that the rupture time of the rupture disk can be accurately recognized, so that additional safeguards can be performed by the user.

At this time, the destruction sensor is installed on the side of the rupture disk in the rupture direction side, and when the rupture disk is ruptured, the destruction sensor can be broken by the bending deformation of the rupture portion of the rupture disk.

However, the above-mentioned conventional general failure sensor is installed without consideration of the rupture shape and the rupture direction of the rupture disk, so that the rupture sensor can not be short-circuited at the correct time.

Particularly, in the case of a burst disk configured to rupture even under a slight pressure change, if the burst type is not largely formed, the failure sensor is merely extended but not destroyed.

In addition, the above conventional conventional rupture disk assembly has a problem in that there is a large concern that the rupture disk assembly is disconnected from the rupture disk assembly because there is no separate structure for supporting the signal cable drawn out from the rupture sensor.

The present invention has been made in order to solve various problems of the prior art described above, and it is an object of the present invention to provide an apparatus and a method for accurately destroying a destruction sensor simultaneously with the destruction of a burst disk, Which is a new type of rupturing disc assembly.

In order to accomplish the above object, the rupture disk assembly of the present invention is provided with a rupture disk provided at a fluid inflow / outflow side in a pressure vessel and having a plurality of rupture grooves ruptured when a pressure in the pressure vessel is out of a predetermined pressure range, And a signal cable is tightly fixed on the film. A part of the rupture disk is disposed to cross the rupture direction side surface of the rupture disk, and a length of the rupture disk is longer than a width of the rupture disk, The breaking sensor is installed such that the longitudinal direction of the breaking sensor is perpendicular to the bending direction of the rupture part due to the rupture of the rupturing disc.

Here, on the rupture direction side surface of the rupturable disc, the rupture disc is in close contact with a portion of the rupture disk provided in the pressure vessel, and a portion corresponding to the rupture portion of the rupture disk, which is the inner portion, And a reinforcing ring for supporting the installation of the rupture disk while being formed.

At this time, a supporting end for supporting a part of the lead-out signal cable is formed to protrude from a portion of the peripheral side of the reinforcing ring on a side of a direction in which the signal cable of the destruction sensor is drawn out.

In addition, the connection terminals are further provided at both sides of the support end, wherein coupling ends are formed so as to be bent so as to be coupled with a connector to which the signal cable is connected.

In addition, a supporting end for supporting a part of the lead-out signal cable is protruded from a peripheral portion of the rupture disk on a side of a direction in which the signal cable of the destruction sensor is drawn out.

The rupture disk assembly according to the present invention as described above is constructed such that the installation direction of the rupture sensor is installed along a direction perpendicular to the rupture direction of the rupture disk, so that the rupture sensor can be quickly short-circuited when the rupture disk is ruptured, It is possible to precisely recognize and acquire information about the bursting time of the bursting disc caused by the failure.

In addition, the rupture disk assembly according to the present invention has an effect of preventing unwanted short-circuiting between the signal cable of the destruction sensor and the connector due to the additional structure of the reinforcing ring or the supporting end.

Hereinafter, a preferred embodiment of a rupture disk assembly of the present invention will be described with reference to FIGS. 1 to 4 attached hereto.

Prior to the description, the rupture disk assembly according to the present invention is installed by a separate holder (upper holder and lower holder) 21 and 22 on the pipeline of the vent pipe 20 through which the fluid flows in or out of the pressure vessel As an example.

1, the rupture disk assembly according to an embodiment of the present invention includes a rupture disk 100, a destruction sensor 200, and a reinforcing ring 300. As shown in FIG.

This will be explained in more detail for each configuration.

First, the rupture disk 100 is a series of structures that are installed on the fluid flow-out side of a pressure vessel (not shown) and rupture when the pressure in the pressure vessel is out of a set pressure range.

In this case, the fluid inlet / outlet side of the pressure vessel refers to a vent pipe 20 through which a fluid flows in or out of a pressure vessel. For example, 20 (upper and lower holders) 21, Of course, the rupturable disc 100 may be installed directly on the pipe connector without using the separate holder.

In addition, the set pressure range means a range of pressure that is set according to the use purpose of the pressure vessel. If the pressure range is exceeded, there is a possibility that the safety of the pressure vessel may be dangerous.

The rupture disk 100 includes an installation end 110 formed in a plate shape and a rupturing end 120 forming a ruptured inner side.

In this embodiment, the rupturing end 120 is formed in a flat plate shape. However, the rupturing end 120 may be formed in a dome shape if necessary.

The rupturing end 120 is formed with a plurality of rupture grooves 121, 122, 123, and 124 that are ruptured by the excess pressure. At this time, each of the rupture grooves 121 refers to a groove for determining the rupture shape of the rupturable disc 100.

In this embodiment, the rupture grooves 121, 122, 123, and 124 are formed along the circumferential direction of the rupturing end 120, and the rupturing grooves 121, 122, 123, and 124 are spaced apart from each other by a predetermined distance. .

In this case, the predetermined distance between the rupture grooves 121, 122, 123 and 124 is a distance for determining the rupture pressure and the rupture direction of the rupture disk 100. If the distance between the rupture disk 100 and the rupture disk 100 is relatively short, The rupture disc 100 can be bent without generating debris on the basis of the distance between the rupture disc 100 and the corresponding portion. The region 131 in which the distance between the two rupture grooves is set to be relatively large is usually one, and the rest is set to be relatively adjacent.

Next, the destruction sensor 200 is configured to detect whether or not the rupture disk 100 is ruptured.

The destruction sensor 200 includes a thin film 210 and a signal cable 220 which is tightly fixed to the side of the film 210 so as to be reciprocated via one end of the film 210 . That is, when the rupture disk 100 is broken, the film and the signal cable are destroyed and the signal is broken, so that the rupture time can be accurately sensed.

At this time, the signal cable 220 is connected to the control device (e.g., a computer, etc.) (not shown) by the connector 230 so that the signal can be transmitted.

The breakage sensor 200 is formed to have a larger length L than the width D of the breakage sensor 200. The breakage sensor 200 is formed to cross the rupture direction side surface of the rupture disc 100, 121, 122, 123, and 124, respectively.

Particularly, in the embodiment of the present invention, as shown in FIG. 3, the destruction sensor 200 is installed such that the longitudinal direction thereof is perpendicular to the bending direction of the rupture portion due to rupture of the rupture disk 100 present. That is, a portion 131 between the two rupturing grooves 121 and 122 formed so as to be relatively distant from each other among the rupture grooves 121, 122, 123, and 124 formed in the rupturable disc 100, (132) are perpendicular to the longitudinal direction of the destruction sensor (200).

This structure allows the destruction sensor 200 to be provided with a tensile direction due to the rupture of the rupture disk 100 to be directed in a direction perpendicular to the longitudinal direction of the destruction sensor 200, So that the tensile force generated in the rupture can be minimized so that the fracture sensor 200 can be destroyed more quickly and smoothly.

That is, if the longitudinal direction of the fracture sensor 200 and the rupture direction of the rupturable disc 100 are set to be the same direction as shown in FIG. 4, even if a shear force due to rupture of the rupturable disc 100 is provided, 200 may be pulled along the longitudinal direction thereof and may not be easily short-circuited. Therefore, it is most preferable that the width direction of the fracture sensor 200 in which the distance for tensile can be minimized is set in the same direction as the rupture direction of the rupture disk 100.

Next, the reinforcing ring 300 supports the installation of the rupture disk 100 and supports the installation of the connector 230 connected to the signal cable 220 of the destruction sensor 200 It is a series of configurations to perform.

The reinforcing ring 300 is formed in an annular shape having an inner portion opened, and is installed in close contact with a portion of the peripheral portion of the rupturable disc 200 that is installed in the pressure vessel.

At this time, the rupturing end 120 of the rupturable disc 100 is exposed to the outside through the opened inner portion of the reinforcing ring 300.

A portion of the circumferential side of the reinforcing ring 300 on the side in which the signal cable 220 of the destruction sensor 200 is drawn out is provided with a supporting end 310 are protruded. The supporting end 310 supports the connection portion between the signal cable 220 and the connector 230 so that the signal cable 220 is not short-circuited due to the flow of the connector 230 .

Particularly, it is suggested that the coupling ends 310 are provided at both sides of the coupling ends 310 to be bent so as to be able to flexibly join the signal cables 220. That is, by preventing the flow of the signal cable 220 and the flow of the connector 230 by the binding stage 320 described above, an undesired short circuit to the connection portion between the signal cable 220 and the connector 230 And to resolve the concerns of

Hereinafter, the operation of the rupturable disc assembly according to the preferred embodiment of the present invention described above will be described in more detail.

First, when the pressure inside the pressure vessel is a normal pressure, the rupture disk assembly according to the embodiment of the present invention maintains a normal installation state.

That is, the rupture disk 100 blocks fluid flow to the inside and the outside of the pressure vessel, thereby maintaining the pressure vessel inside the pressure vessel within a predetermined pressure range.

If the pressure inside the pressure vessel exceeds the set pressure range in the above-described steady state, the rupturing end 120 of the rupturable disc 100 is ruptured on the basis of the forming region of the rupturing groove 121 formed therein, do.

In this process, the rupturing portion of the rupturable disc 100 is short-circuited to the destruction sensor 200 provided on the bending direction side surface of the rupturing disc 100 as a blade.

Considering that the longitudinal direction of the destruction sensor 200 is perpendicular to the bending direction of the rupturing portion of the rupturing disc 100, the destruction sensor 200 is disposed in the width direction of the rupture sensor 200, The tensile force is generated due to the rupture of the breakage sensor 100. Considering that the length of the fracture sensor 200 in the width direction is extremely short, the actual tensile force is almost insignificant, so that the breakage sensor 200 can be easily broken.

Therefore, according to the rupture of the bursting disc 100, the fluid in the pressure vessel can be discharged to the outside through the vent pipe 20, thereby preventing the explosion due to the excessive pressure inside the pressure vessel.

In addition, by short-circuiting the signal cable 220 constituting the destruction sensor 200, the user can accurately recognize the abnormal occurrence of the pressure vessel through the control device.

Meanwhile, the rupture disk assembly according to the present invention is not limited to the structure of the above-described embodiment.

For example, the structure of the reinforcing ring 300 of the rupture disk assembly of the above-described embodiment may be omitted.

That is, instead of the reinforcing ring 300, the supporting end 310 may be formed at one end of the rupturable disc 100 to have the same function as that of the reinforcing ring.

5, the supporting end 310 serves to protect the signal cable 220 of the destruction sensor 200, and the destruction sensor 200 (see FIG. 5) In which the signal cable 220 is drawn out.

As a result, even if the pressure inside the pressure vessel exceeds the set pressure through the above-described series of processes, the rupture disc assembly can be ruptured smoothly according to the present invention. Therefore, there is a risk of safety accidents such as explosion of the pressure vessel And the breakage sensor 200 can be short-circuited simultaneously with the breakage of the breakage disc 100, so that the abnormality of the pressure vessel can be detected as soon as possible.

1 is a schematic exploded perspective view illustrating a rupture disk assembly according to a preferred embodiment of the present invention;

FIG. 2 is a state diagram illustrating an installation state of the bursting disc assembly according to a preferred embodiment of the present invention. FIG.

3 is a plan view for explaining an installation structure for a fracture sensor of a rupturable disc assembly according to a preferred embodiment of the present invention

FIG. 4 is a view for explaining an undesirable mounting structure for a failure sensor of a rupture disk assembly according to a preferred embodiment of the present invention;

5 is a perspective view illustrating another embodiment of the rupture disk among the rupture disk assemblies according to the preferred embodiment of the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

20. Vent tube 100. Rupture disk

110. Installation stage 120. Rupture stage

121, 122, 123, 124. Rupture groove 200. Destruction sensor

210. Film 220. Signal cable

230. Connector 300. Reinforcing ring

310. Support end 320. Bonding end

Claims (5)

A rupture disk provided at a fluid inflow / outflow side in the pressure vessel and having a plurality of rupture grooves ruptured when a pressure in the pressure vessel is out of a predetermined pressure range, And a signal cable is tightly fixed on the film of the thin film, and a part of the rupture disk is disposed so as to traverse the rupture direction side surface of the rupture disk and passes through the rupture groove, A destruction sensor that is short-circuited when the rupture disk is broken, The rupture disk is provided on the side of the rupture direction of the rupture disk and is in close contact with a portion of the peripheral side of the rupture disk that is provided in the pressure vessel and a portion corresponding to the rupture portion of the rupture disk, And a reinforcing ring for supporting the installation of the bursting disc while being formed, Wherein the destruction sensor is installed such that the longitudinal direction of the destruction sensor is perpendicular to the bending direction of the rupturing portion due to the rupture of the rupture disk, A supporting end for supporting a part of the lead-out signal cable is formed to protrude from a peripheral portion of the reinforcing ring on a side of a direction in which the signal cable of the destruction sensor is drawn out, And a coupling step formed to be bent so as to be coupled with a connector to be connected. delete delete delete The method according to claim 1, Wherein a supporting end for supporting a part of the lead-out signal cable is protruded from a portion of the circumferential portion of the rupture disk on a side of a direction in which the signal cable of the rupture sensor is drawn out.

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