KR101366820B1 - Rupture disk - Google Patents

Abstract

The present invention relates to a ruptured disk, and more particularly, a ruptured hollow is formed so that the ignition propulsion module of the rocket can be installed through the center of the ruptured disk provided between each chamber of the rocket having a multi-stage propulsion chamber It's about disks.
To this end, the present invention is a rupture disk installed between each chamber of the rocket having a multi-stage propulsion chamber, the rupture disk is a dome portion provided with a rupture groove for adjusting the burst pressure of the rupture disk, and the circumference of the dome portion It is formed along the flange is coupled to the inner wall surface of the chamber and the hollow is formed in the center of the dome is coupled to the ignition propulsion module of the rocket.

Description

Rupture Disk {RUPTURE DISK}

The present invention relates to a ruptured disk, and more particularly, a ruptured hollow is formed so that the ignition propulsion module of the rocket can be installed through the center of the ruptured disk provided between each chamber of the rocket having a multi-stage propulsion chamber It's about disks.

In general, a rupture disk is used as a safety device in a device in which a fluid in a gas or liquid state is stored.

In particular, when the pressure inside the chemical reactor or the fluid storage tank becomes too large, there is a risk that the chemical reactor or the fluid storage tank may explode.

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, thereby preventing a safety accident through the release of the fluid in the device.

Prior art in this regard is Republic of Korea Patent Publication No. 10-2010-0081794 (published on July 15, 2010, rupture disk assembly).

SUMMARY OF THE INVENTION An object of the present invention is to provide a ruptured disk having a hollow formed between multiple propulsion chambers provided in a rocket and to which an ignition propulsion module of a rocket provided through the propulsion chambers can be installed.

In particular, it is possible to control the burst pressure of the ruptured disk in which the hollow is formed, and to provide a burst disk that can be ruptured at a constant pressure even when the ignition propulsion module is coupled to the hollow.

And when the rupture disk is ruptured in the state in which the ignition propulsion module is coupled to the hollow to provide a rupture disk that the pressure to rupture the rupture disk can be kept constant while the hollow to which the ignition propulsion module is coupled is not broken There is this.

In order to solve the above problems,

The ruptured disk according to the present invention has a dome portion provided with a rupture groove for adjusting the rupture pressure of the ruptured disk, a flange formed along the circumference of the dome portion and coupled to the inner wall surface of the chamber and formed in the center of the dome portion It includes a hollow to which the ignition propulsion module of the rocket can be coupled.

In particular, the rupture groove is composed of a first groove portion formed in the circumferential direction from the center of the rupture disk and a second groove portion formed along the circumference of the hollow.

In addition, the rupture disk is provided with a coupling portion provided to have a thicker cross section of the dome portion while the upper surface is flat between the hollow and the second groove portion.

In addition, the rupture groove is provided with a through hole at both ends, the shape of connecting the through hole, it may be divided into two or more formed.

The dome portion is further provided with a dimple protruding in the opposite direction between the tear groove.

In addition, the dome portion may be provided with a reinforcement portion protruding from the circumference of the hollow to the upper portion and / or the lower portion.

According to the solution of the above problems,

The present invention has the effect of maintaining the bursting pressure at which the bursting disk is ruptured even when the ignition propulsion module of the rocket is coupled to the hollow formed in the center of the dome of the bursting disk.

In addition, when the bursting disc is ruptured, the periphery close to the hollow and the hollow are not broken, thereby preventing a malfunction of the ignition propulsion module coupled to the hollow.

In particular, the second groove portion formed to surround the hollow and the coupling portion provided with a thicker cross section is provided to prevent the breakage of the hollow and the coupling portion while improving the effect that the burst pressure of the rupture disk can be kept constant. There is an advantage.

1 shows a plane of a bursting disc according to the invention;
FIG. 2 is an enlarged view of a portion where a hollow is formed in FIG. 1; FIG.
3 shows a cross section of a ruptured disc according to the invention.

Hereinafter, a ruptured disc according to the present invention with reference to the accompanying drawings.

1 is a view showing a plane of a rupture disk according to the present invention, Figure 2 is an enlarged view showing a hollow portion in Figure 1, Figure 3 is a view showing a cross section of the rupture disk according to the present invention. .

In general, the bursting disk 100 prevents a safety accident by preventing the boosting of the fluid while the bursting disk 100 is ruptured when the fluid in a gas or liquid state rises to a constant pressure.

The rupture disk 100 is installed between the propulsion chamber of the multi-stage in the propulsion device of the rocket is also used to open the fuel injection hole for injecting the fuel as the ignition propulsion module of the rocket in each chamber of the stage.

The rupture disk 100 according to the present invention is used in the propulsion apparatus of the rocket as described above. Referring to FIG. 1, the dome portion 120 having a rupture groove 110 for adjusting the rupture pressure of the rupture disk 100 is provided. And a hollow formed along the circumference of the dome part 120 and formed at the center of the flange 130 and the dome part 120 coupled to the inner wall surface of the chamber to which the ignition propulsion module of the rocket can be coupled. 140).

The rupture groove 110 is composed of a first groove 111 formed in the circumferential direction from the center of the rupture disk 100 and a second groove 112 formed along the circumference of the hollow 140.

In addition, through holes 113 are formed at both ends of the rupture groove 110, that is, the first groove 111 and the second groove 112, so that the rupture groove 110 connects the pair of through holes 113. It is formed to.

In addition, the rupture groove 110 may be formed by dividing the rupture groove 110 into two or more according to the size of the rupture disk 100 or the bursting pressure.

It is possible to control the bursting pressure of the bursting disc 100 by dividing the through hole 113 and the bursting groove 110.

A portion corresponding to the hollow 140 and the second groove 112 of the dome part 120 is further provided with a coupling part 150 having a flat top surface and having a thicker cross section than other portions of the dome part 120.

The coupling part 150 is an area to which the ignition propulsion module of the rocket is coupled, and when the rupture disk 100 is ruptured, the rupture disk 100 is designed to rupture at a specific pressure due to the portion where the ignition propulsion module is coupled. It is formed to have a thicker cross section so as not to rupture or to rupture at a pressure below it.

In addition, as shown in FIG. 2 to prevent abnormal rupture due to the coupling part 150 when the rupture disk 100 is ruptured, the second disk is spaced apart from the circumference of the coupling part 150 by a predetermined distance. The groove 112 is formed. Because of this, when the ruptured disk 100 is ruptured, the portion extending up to the hollow 140 with the boundary of the second groove 112 does not affect the rupture condition of the ruptured disk 100.

The burst disk 100 may further include a dimple 160.

3 is a cross-sectional view of the ruptured disk 100. Referring to FIG. 1, the dome portion is formed inside the portion formed by the first groove portion 111 and the second groove portion 112 in the dome portion 120. Referring to FIG. The dimple 160 is formed to protrude in the opposite direction to 120.

That is, when the dome portion 120 is formed to be convex upward, the dimple 160 has a portion of the dome portion 120 formed to be convex downward.

The circumference of the hollow 140 may be provided with a reinforcing part 170 formed to protrude to the upper and / or lower portion of the dome part 120.

The reinforcement part 170 is for facilitating and firmly coupling the ignition propulsion module of the rocket inserted into the hollow 140, and forming a screw thread on the inner surface of the rocket propulsion module as necessary to securely secure the screw coupling. You can also

As such, by using the rupture disk 100 according to the present invention to form a hollow 140 in the ruptured disk 100 to combine the other device, such as the ignition propulsion module of the rocket disclosed in the present invention to the hollow 140. There is an advantage to this.

At this time, the coupling portion 150 having a thicker cross-section than the other portion of the dome portion 120 is provided around the hollow 140 to rupture disk near the hollow 140 during the rupture of the rupture disk 100 ( 100, that is, a portion corresponding to the coupling part 150 may be left.

In particular, the second groove portion 112 is formed around the coupling portion 150, so that the coupling portion 150 does not affect the rupture of the rupture disk 100, so that the rupture pressure of the rupture disk 100 is increased. And the bursting time can be kept constant.

In other words, when other devices such as the ignition propulsion module of the rocket illustrated in the present invention are coupled to the hollow 140 by fastening or welding, it may cause uneven burst pressure and burst time of the rupture disk 100. You can avoid the problem.

It will be understood by those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is self-evident.

100: bursting disk 110: bursting groove
111: first groove portion 112: second groove portion
113: through hole 120: dome
130: flange 140: hollow
150: coupling portion 160: dimple
170: reinforcement

Claims (7)

In the burst disk which is installed between each chamber of the rocket is provided with a multi-stage propulsion chamber,
The bursting disc,
A dome portion having a tear groove for adjusting the tear pressure of the tear disk;
A flange formed along a circumference of the dome and coupled to an inner wall of the chamber; And
And a hollow formed in the center of the dome portion to which the ignition propulsion module of the rocket can be coupled. The method according to claim 1,
The tear groove,
A first groove formed in the circumferential direction at the center of the rupture disk; And
A rupture disk, characterized in that consisting of; a second groove formed along the circumference of the hollow. The method according to claim 2,
The bursting disc,
And a coupling part provided to have a thicker cross section of the dome part while the upper surface is flat between the hollow and the second groove part. The method according to claim 1,
The rupture groove,
A through-hole provided at both ends and having a shape for connecting the through-holes. The method according to claim 1,
The tear groove,
Burst disk, characterized in that can be divided into two or more. The method according to claim 1,
The dome portion,
And a dimple protruding in the opposite direction between the tear grooves formed in the dome portion. The method according to claim 1,
In the dome part,
Bursting disc, characterized in that it can be provided; a reinforcing part is formed to protrude to the upper and lower portion of the dome around the hollow.

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