KR102279699B1 - A rupture disc assembly for a fire extinguisher - Google Patents

Abstract

The present invention proposes a bursting disk assembly for a fire extinguisher. In the rupture disk assembly of the present invention, the rupture disk 18 is installed inside the valve body having a tubular shape in which the upper valve body 12 communicating with the outside air and the lower valve body 14 connected to the inside of the fire extinguisher are connected to each other. do. The support hinge 20, which is in surface contact with the upper surface of the rupture disk 18 to which the reference pressure to rupture is set, can increase the rupture pressure of the rupture disk by making surface contact with the upper surface of the rupture disk in the radial direction, and one end of the rupture disk is attached to the valve body. It is connected with the hinge axis as the center, and a locking jaw is formed at the other end. And the plunger 42 of the solenoid actuator 40 is caught in the locking groove of the rocker 32 to prevent the rocker 32 from moving outward by the force of the spring. When the plunger 42 is released from the locking groove, the rocker 32 is spaced apart from the support hinge, and the support hinge 20 is spaced apart from the rupture disk 18 while rotating upward. In this state, the rupture disk 18 is ruptured by the set pressure inside the fire extinguisher.

Description

A rupture disc assembly for a fire extinguisher

The present invention relates to a rupture disk assembly, and more particularly, to a rupture disk assembly for a system fire extinguisher configured to be ruptured by a filling pressure of an extinguishing liquid when the hinge is removed according to an electrical signal.

The rupture disk assembly refers to a device that, when the pressure of a predetermined internal space exceeds a reference value, ruptures the rupture disk and discharges high-pressure gas to the outside. This rupture disk assembly has a variety of uses, and is also applied to a system fire extinguisher that performs automated fire extinguishing.

The rupture disk assembly applied to the system fire extinguisher is generally configured so that the extinguishing fluid built in the fire extinguisher can be ejected to the outside by rupturing the rupture disk with an impact or the like based on a specific electrical signal. However, this type of rupture disk assembly for a fire extinguisher is undesirable because the configuration for applying an impact to the rupture disk is rather complicated.

It is an object of the present invention to provide a bursting disk assembly for a fire extinguisher that can secure sufficient operational reliability while having a simple configuration.

The rupture disk assembly of the present invention includes a valve body in which an upper valve body and a lower valve body connected to the inside of the fire extinguisher are connected to each other and having a tubular shape, and a rupture disk installed inside the valve body and having a ruptured reference pressure, there is. Then, on the upper surface of the rupture disk, a support hinge is in radial contact with the upper surface of the rupture disk, thereby increasing the rupture pressure of the rupture disk. The support hinge is connected to the valve body about the hinge axis and is rotatable, and the other end is provided with a locking protrusion.

And by using a solenoid actuator, the rocker is caught with the locking jaw of the support hinge to support the rupture disk like a support hinge against the internal set pressure of the fire extinguisher, and by releasing the locking jaw of the support hinge, the support hinge becomes the rupture disk. It can be spaced apart from the rupture disk and can be controlled to rupture the rupture disk against the internal pressure of the fire extinguisher.

And the spring generates an elastic force so as to release the locking state of the locker caught on the locking jaw of the support hinge. Here, the rocker caught on the upper surface of the locking jaw of the support hinge to keep the support hinge in surface contact with the upper surface of the rupture disk, the plunger is separated from the locking groove formed in the rocker by the solenoid actuator, the support hinge can be opened upward.

According to another embodiment, the fastening member that catches the upper surface of the locking jaw of the support hinge and keeps the support hinge in surface contact with the upper surface of the rupture disk is moved from the state caught on the upper surface of the locking jaw of the support hinge to the released state using a solenoid actuator. It is constructed so that the support hinge can be opened.

According to the above embodiment, when the support hinge is in surface contact with the upper surface of the rupture disk, the rupture pressure of the rupture disk is set to be high, and when the support hinge is spaced apart from the upper surface of the rupture disk, the rupture pressure of the rupture disk is set to decrease. is set Therefore, when the support hinge is opened upward by an electrical signal, the rupture disk may be immediately ruptured by the internal pressure of the fire extinguisher. And in the state in which the support hinge is in contact with the rupture disk, it is expected that the rupture disk is damaged at a higher pressure, thereby promoting safety.

1 is a partially exploded perspective view of a rupture disk assembly of the present invention.
Figure 2 is a longitudinal cross-sectional view of the present invention rupture disk assembly.
3 is a cross-sectional view of the rupture disk assembly of the present invention.
4 is an exemplary view of a rupture disk assembly according to another embodiment of the present invention.

Next, based on the embodiment shown in the drawings, the present invention will be described in more detail.

1 to 3, the rupture disk assembly of the present invention includes an upper valve body 12 and a lower valve body 14 that form a single cylindrical body by screwing them together. Therefore, the valve bodies 12 and 14 in the coupled state have a cylindrical shape, and the rupture disk 18 is installed therein. The upper valve body 12 is molded in an open state to communicate with the outside, and the lower valve body 14 is a part connected to a fire extinguisher to be described below.

As the rupture disk 18 used in the present invention is ruptured with respect to a predetermined pressure, any type of rupture disk 18 can be used as long as the internal fluid can be ejected to the outside. Various types of rupture disks 18 may be used, including those in which a score line is formed or slits at regular intervals are formed. In the illustrated embodiment, as can be seen from FIG. 3 , it can be seen that the rupture disk 18 formed with a plurality of slits at regular intervals is used.

And in the illustrated embodiment, the rupture disk 18 is installed on the lower valve body 14, and the support hinge 20 is installed on the upper part. And the rupture disk 18, the support jaw 14a formed on the upper part of the lower valve body 14, and a ring shape that can be placed on the upper part of the support jaw 14 from the inside of the lower valve body 14 It is supported in a state interposed between the holders 15 of the In addition, a sealing ring may be installed between the flange portion of the rupture disk 18 and the support jaw 14 of the lower valve body 14 in order to secure an airtight state. In addition, it is natural that the rupture disk 18 may be installed directly below the support hinge 20 to be described later inside the valve body through a known structure.

And the support hinge 20 of the present invention is in contact with the upper surface of the rupture disk 18, and is installed in the radial direction of the rupture disk 18 as shown in FIG. In the illustrated embodiment, when the linearly formed support hinge 20 makes surface contact with the upper surface of the rupture disk 18, the rupture pressure of the rupture disk 18 is substantially increased relatively.

For example, when the support hinge 20 is in radial contact with the upper surface of the rupture disk 18 designed to rupture at a pressure of 15 to 20 bar, the rupture pressure of the rupture disk 18 is significantly increased, for example, It can be as high as 40-45 bar. And the support hinge 20 supported in contact with the upper surface of the rupture disk 18 is supported by the lower valve body 14 so as to be able to rotate about the hinge shaft 22 .

At an end opposite to the hinge shaft 22 of the support hinge 20, a locking protrusion 23 is formed. And the locker 32 is hooked on the upper portion of the locking jaw 23 so that the support hinge 20 can always be maintained in a closed state. Here, the rocker 32 is a component installed to linearly move between the locked state and the open state of the support hinge 20 .

For example, the rocker 32 is always elastically supported outward by a spring 34 . Here, receiving the elastic force to the outside by the spring 34 means that the rocker 32 is always receiving the elastic force of the spring 34 in the open direction (not caught with the support hinge). And as shown in FIG. 4, a locking groove 36 is formed in the middle of the rocker 32, and the plunger 42 of the solenoid actuator 40 enters into this locking groove 36 and maintains the hooked state. are doing

That is, since the plunger 42 of the solenoid actuator 40 is fastened to the locking groove 36 of the rocker 32, the rocker 32 is hooked on the upper part of the locking jaw 23 of the support hinge 20. maintaining status. In this state, the plunger 42 moves downward while the power is applied to the solenoid actuator 40 by a predetermined electrical signal (for example, a fire detection signal from a fire generating device or a manual operation signal by a user, etc.) It is separated from the locking jaw (34).

When the rocker 32 is in a free state in this way, the spring 34 pulls the rocker 32 outward, and the rocker 32 moves to the left in the drawing. This movement of the rocker 32 eliminates the locking state with the support hinge 20 . In this case, the support hinge 20 is in a state in which the hinge shaft 22 can be rotated upwardly as a supporting point.

In the illustrated embodiment, the rocker 32 is supported by a rocker support portion 38 formed to extend outwardly from the lower valve body 14, and can be linearly moved in one direction by the rocker support portion 38. It can be seen that it is supported. And the outer end of the rocker 32 is receiving elastic force to the outside by the spring 34, and the support block 39 on which the inner end of the spring 34 is caught while supporting this portion is also from the outside of the rocker support portion 38. It is integrated by screwing.

In the illustrated embodiment, it can be seen that the rocker 32 is configured to be changed to a state engaged with the support hinge 20 or a state spaced from the support hinge 20 by the operation of the solenoid actuator 40. can That is, it can be seen that the plunger 42 of the solenoid actuator 40 is driven between the locking state with the rocker 32 and the releasing state with the rocker 32 .

However, if the force of the solenoid actuator can be secured, it will be possible to configure the solenoid plunger instead of the rocker 32 . That is, the plunger 42 of the solenoid actuator 40, instead of the above-described rocker 32, it is also possible to have a function of being caught or released directly on the upper portion of the locking jaw 23 of the support hinge 20. can do.

And the lower valve body 14 is connected to the fire extinguisher, so it is actually in a state where the liquid fire extinguishing liquid is full, and this liquid fire extinguishing liquid has a predetermined filling pressure. The filling pressure of this liquid extinguishing liquid is a pressure (for example, 30 bar) higher than the bursting standard pressure (15 to 20 bar) of the bursting disk 18 itself. In addition, since the bursting pressure of the rupture disk 18 is increased by the support hinge 20, the rupture disk 18 does not rupture even with the filling pressure of the extinguishing liquid (30 bar) and maintains the state of FIG. 2 .

In this state, as described above, when the plunger 42 is separated from the locking groove 36 of the support hinge 20 by an electric signal applied to the solenoid actuator 40, the rocker 32 is moved to the support hinge ( 20) will be released. Therefore, the support hinge 20 is in a state in which it can rotate about the hinge shaft 22. At this time, since the rupture disk 18 is in a state in which the reinforcement force of the support hinge 20 is released, the pressure of the extinguishing liquid (30 bar) ) is ruptured by As such, when the rupture disk 18 is ruptured by the pressure of the digestive fluid, the digestive fluid is ejected to the outside to perform the extinguishing action.

However, as described above, in a state in which the support hinge 20 is in contact with the upper surface of the rupture disk 18, the rupture disk 18 can withstand a higher pressure (eg, 40 to 45 bar). Here, in the state where there is no electrical signal for fire extinguishing (the state in which the plunger 42 is caught in the locking groove 36), the pressure inside the fire extinguisher rises abnormally and exceeds 40 to 45 bar, it is ruptured by this internal pressure Disc 18 ruptures.

Here, when the pressure inside the fire extinguisher becomes high pressure (40 to 45 bar) and the rupture disk 18 ruptures, since the support hinge 20 is in contact with the upper surface of the rupture disk 18, the support hinge ( 20), the rupture disks 18 on both sides are ruptured, respectively. And when the rupture disk 18 is ruptured after the support hinge 20 is in a free state by the signal of the solenoid actuator 40, the rupture disk 18 is centered around the connection support 19 in FIG. Because of the rupture, the rupture pattern of the rupture disk in the two cases is substantially different.

In the embodiment described above, the bottom surface of the support hinge 20 has a flat shape. And the rupture disk 18 also has a flat shape at first, but after the rupture disk 18 is installed like the support hinge 20, the extinguishing liquid inside the fire extinguisher connected to the lower valve body 14 is released at a predetermined pressure (eg, For example, when filling up to 30 bar), both sides of the rupture disk 18 corresponding to both sides of the support hinge 20 swell by this filling pressure. The rupture disk 18 in FIG. 2 is shown in a state in which the rupture disk 18 is inflated upward in this way.

Next, the embodiment shown in FIG. 4 will be described. In this embodiment, the rupture disk 28 uses a different type. In the following description, a detailed description of common parts will be omitted, and only substantially different parts will be described.

In the present embodiment, the upper valve body 12, the lower valve body 14, the rocker support portion 38, and the rocker 32 and the surrounding configuration related to their operation are substantially the same as described above. The rupture disk 28 of this embodiment has a disk body 28a concave downward, a slot 28c formed along the magnetic field of the disk body 28a, and a disk body reversed by high pressure ( 28a) and a knife 28b for breaking. Such rupture discs 28 themselves are known and widely used.

In addition, the support hinge 50 in this embodiment has a lower surface convex downward so as to be in surface contact with the concave upper surface of the rupture disk 28 . That is, since the support hinge 50 of this embodiment also has to make surface contact with the upper surface of the rupture disk 28 in the radial direction, the bottom surface of the support hinge 50 is convex to correspond to the upper surface of the rupture disk 28 . it is being molded

The operation of this embodiment having such a configuration is substantially the same as that of the first embodiment described above. Briefly, when the rocker 32 is released from the fastening state with the locking protrusion 52 of the support hinge 50 by an external electrical signal, the support hinge 40 moves upward with respect to the hinge shaft 54 . By rotating to , the rupture disk 28 is exposed to the internal pressure of the fire extinguisher.

At this time, since the internal pressure of the fire extinguisher is set higher than the reference pressure of the rupture disk 28 itself, the rupture disk 28 is ruptured by the internal pressure of the fire extinguisher and the extinguishing liquid is ejected to the outside to perform a predetermined fire extinguishing operation. be able to And in the absence of an electrical signal for fire extinguishing, if the internal pressure of the fire extinguisher rises more than necessary, the rupture disk at a pressure higher than the reference pressure of the original rupture disk 28 by the above-described support hinge 50 (eg, 50 bar). (50) is ruptured.

Also in this embodiment, it can be seen that the rupture pressure of the rupture disk 28 is substantially different depending on whether the support hinge 50 is in contact with the rupture disk 28 or not. Using this point, the rupture of the rupture disk at a low pressure due to the opening of the support hinge 50 by an electrical signal and the rupture of the rupture disk at a high temperature due to the closing of the support hinge 50 are induced. can be known

In the above two embodiments, when the internal pressure of the fire extinguisher is high and the rupture disk ruptures (the rupture disk contact state of the support hinge) and the rupture disk 18 based on an electrical signal through the solenoid actuator 40 It can be seen that in the case of rupture (non-contact state of the rupture disk of the support hinge), the rupture form is different.

Of course, other various modifications are possible for those skilled in the art within the scope of the basic technical idea of the present invention as described above. And it will be natural for the purpose of the provisions of the Patent Act that the protection scope of the present invention should be interpreted based on what is described in the claims.

12 ..... Upper valve body
14 ..... Lower valve body
18 ..... ruptured disc
20 ..... support hinge
22 ...... Hinge shaft
23 ..... jamming jaw
28 ..... ruptured disc
32 ..... Locker
34 ..... spring
40 ..... solenoid actuator
42 ..... Plunger
50 ..... support hinge

Claims (3)

The upper valve body communicating with the outside air and the lower valve body connected to the inside of the fire extinguisher are connected to each other, the valve body having a tubular shape;
a rupture disk installed inside the valve body and having a rupture reference pressure;
a support hinge having one end connected to the valve body about a hinge shaft and having a locking protrusion formed at the other end;
The support hinge supports the rupture disk like the support hinge against the internal set pressure of the fire extinguisher by being caught with the locking jaw of the support hinge. A rupture disk assembly comprising a support hinge holding and releasing means for controlling the rupture disk to rupture with respect to the rupture disk.
According to claim 1, wherein the support hinge holding and releasing means,
A rocker caught on the upper surface of the locking jaw of the support hinge to keep the support hinge in surface contact with the upper surface of the rupture disk, a spring that generates elastic force to release the locking state of the locker caught on the locking jaw of the support hinge with the support hinge, and a rocker A rupture disk assembly comprising a solenoid actuator having a plunger that can be fastened to or detached from a locking groove formed in the .
According to claim 1, wherein the support hinge holding and releasing means,
Rupture consisting of a fastening member caught on the upper surface of the locking jaw of the support hinge so that the support hinge is in surface contact with the upper surface of the rupture disk, and a solenoid actuator that moves the fastening member from the upper surface of the locking jaw of the support hinge to the released state. disk assembly

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