KR102241438B1 - Flameless venting device having rupture disc - Google Patents

Abstract

The present invention proposes an extinguishing device capable of simultaneously catching flames and fires caused by arc explosions. The anti-salt exhaust device of the present invention is composed of a connecting pipe in which a rupture disk is installed is connected to the inside, and a plurality of holes are uniformly distributed, and a plurality of pieces installed in multiple stages on the inside of the other cylinder, It has a dish-shaped dispersing device 50 having a vent hole formed in the center and an inclined surface having a high slope from the outside to the top of the vent hole. A cylindrical anti-chlorine element 30 may be installed on the outside of the other park container.

Description

Flameless venting device having rupture disc for gas insulated switchgear for power equipment

The present invention relates to an anti-salt exhaust device used in a gas insulated switchgear for power equipment, and more particularly, an anti-flame that can prevent fire, such as a flame, from being discharged to the outside by an arc explosion occurring in a gas circuit breaker for power equipment. It relates to an exhaust system.

The anti-salt exhaust device can be said to be a device for exhausting high-pressure gas while preventing the outflow of the flame to the outside when an explosion occurs. In such an anti-salt exhaust system, an anti-chlorine element, such as a mesh made of metal, has a function of anti-salt exhaust to allow gas to pass through and flames to not pass.

When an explosion occurs in an internal space (for example, a tank of a specific volume) to which such an anti-salt exhaust system is applied, the pressure is instantaneously increased. In addition, as the disc is ruptured by the increased pressure, the internal flame and high-pressure gas are discharged to the outside. These flames and high-pressure gas pass through the anti-flame exhaust system and only the gas is discharged to the outside and the flame is not discharged, thereby preventing the problem caused by the flame.

And, for example, a gas-insulated switchgear for power equipment is used by filling an insulating gas inside for arc insulation. In such a switching device, arc explosion may occur due to an abnormal current, and such arc explosion generates fire due to arc explosion as well as flame. Therefore, it can be seen that the flame-retardant exhaust system for the switching device must completely remove not only the flame but also the fire.

In addition, the anti-salt exhaust system needs to discharge gas as quickly as possible in order to solve the problem of high pressure caused by internal explosion, which means that it is necessary to quickly lower the internal pressure. And for this, it can be said that it is advantageous to have a large volume of the anti-salt exhaust system. However, since the increase in the size of the anti-salt exhaust system comes with various disadvantages, it can be said that it is most desirable that the size of the anti-salt exhaust system is small and the ability to discharge gas can be maximized.

An object of the present invention is to provide an anti-salt exhaust device capable of sufficiently removing flames and fires generated due to an arc explosion.

Another object of the present invention can be said to be to provide an anti-salt exhaust device capable of maximizing the anti-flammation capability and the discharge capability of gas while making the size as small as possible.

The anti-salt exhaust device of the present invention is configured to include a plurality of dish-type dispersing devices installed in multiple stages on the inner side of the rupture disk, and a plurality of holes in the connecting pipe is connected to the inside and a plurality of holes are molded. . Here, the plurality of dispersing devices includes a vent hole formed in the center, and an inclined surface having a high upper slope from the outside of the vent hole. In addition, the ventilation hole of the dispersing device passes a part of the explosive gas upward, and the inclined surface of the dispersing device disperses the pressure by guiding the other part of the explosive gas to the outside passing through the other barrel. In addition, the ventilation holes of the dispersing device are molded to become smaller toward the top.

According to the present invention as described above, the high-pressure gas generated by the arc explosion is dispersed throughout the entire other keg by a dispersing device in the inside of the other keg and is discharged to the outside. At this time, the metal mesh layer installed on the outside as well as other gongs will remove the flame and allow only the gas to be exhausted.

1 is a perspective view of an anti-salt exhaust device according to the present invention.
Fig. 2 is an explanatory view showing a partial cross-section of the anti-salt exhaust system of the present invention.
Figure 3 is an exemplary view of a cylindrical flame extinguishing unit of the present invention extinguishing exhaust system.

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

As shown in Figs. 1 to 3, the anti-salt exhaust device of the present invention includes a cylindrical anti-chlorine element 30 having an anti-salt function supported by a frame 20. Here, the anti-chlorine device 30 of the present invention includes a metallic mesh layer having a function of removing a general flame, as well as a fibrous high-temperature insulating material layer capable of removing fires generated by an arc explosion.

In the present invention, the frame 20 includes a frame upper portion 22 and a frame lower portion 26 for supporting the cylindrical anti-chlorine element 30 from the upper and lower portions, respectively. And the frame upper part 22 and the frame lower part 26 each have a ring shape and are connected to each other by a plurality of frame connection parts 24, and they are made of a metal material having strength to withstand explosion. In addition, as shown in Fig. 2, in order to support the upper portion of the anti-chlorine element 30, an outer wall 22a and an inner wall 22b having a predetermined interval are provided on the lower surface of the frame upper portion 22.

Further, an outer wall 26a and an inner wall 26b for supporting the lower portion of the anti-chlorine element 30 are formed on the upper surface of the frame lower portion 26 as well. Therefore, it can be seen that the cylindrical anti-chlorine element 30 is supported by the upper frame 22 and the lower frame 26 as described above. And, the outer surface of the anti-chlorine element 30 is also supported by the frame connection part 24.

The upper cover 12 made of a metal material having sufficient strength is fixed to the upper part of the frame 10, and is configured to withstand the impact caused by an explosion. The upper cover 12 blocks the upper portion of the frame 20 so that the explosive gas exits radially, and passes through the anti-chlorine element 30 to be described later.

And it can be seen that a plurality of reinforcing members 14 are arranged in the radial direction on the upper part of the upper cover 12. This reinforcement structure, when explosion occurs from the bottom, the largest pressure is applied to the central portion of the upper cover 12, it is to reinforce this. The upper cover 12 is connected to the frame 10 by means of bolts, etc. In the illustrated embodiment, the upper cover 12 is connected to the frame connection part 24.

The cylindrical anti-chlorine element 30 is supported by the frames 20:22, 24, 26 made of such a metal material. In addition, inside of the anti-chlorine element 30, a plurality of holes 42 are formed, and another keg barrel 40 is installed. The other keg barrel 40 is formed of a metal material having a sufficient thickness, and the hole 42 is uniformly formed as a whole.

The other kegtong 40 may be supported by the frame 20 as described above. A plurality of dispersing devices 50 are installed in the other park container 40 so as to have a constant interval up and down. In this dispersing device 50, a vent hole 54 is formed in the center, and the periphery of the vent hole 54 is made in a dish shape having an inclined surface 52 having a high top. The dispersing device 50 has a function of dividing the explosive gas and guiding a part of the explosive gas divided in each stage to the outside (in the direction of the radial anti-chlorine element).

And in FIG. 2, the connection pipe 17 is connected to the inside of the gas insulated switchgear for power equipment, and is connected to the switchgear through a flange 18. Looking at the anti-chlorine device 30 of the present invention, as shown in Figure 3, the innermost support portion 32 is provided with a cylindrical shape. This inner support part 32 is for supporting a plurality of constituent elements disposed on the outer surface thereof, for example, it may be composed of a cylinder in which a number of air holes are molded, or may be composed of a cylinder made using a mesh having sufficient strength. have.

On the outside of the inner support part 32, a fibrous high-temperature heat insulating material layer 34 having a cylindrical shape for preventing the fire from escaping to the outside is provided. This fibrous high-temperature insulation layer 34 is installed to catch particulate arc fire, and itself can be said to be an element currently being used. A metal mesh layer 36 is installed outside the fibrous high-temperature insulation layer 34. The metal mesh layer 36 may be composed of one or more layers regardless of the size of the mesh.

For example, the mesh layer 36 may be composed of multiple layers of a large mesh network or a medium-sized mesh network, but it is preferable that a large mesh network is installed further inside. That is, it may be composed of a first mesh having the largest air permeability, a second mesh having a relatively small air permeability, and a third mesh having the smallest air permeability. That is, it can be seen that at least one of the mesh layer 36 of the present invention is made of a metal mesh.

Therefore, it is expected that the flame can be sufficiently removed while the flame passes through the plurality of meshes. And, the outermost mesh layer 36a having the smallest mesh is included on the outermost side of the mesh layer 36. Since the outer mesh layer 36a has the smallest mesh, it may not be easy for air to pass through. Therefore, in the present invention, the outer mesh layer 36a is made to have a large surface area so that the gas due to the explosion can be exhausted to the outside as quickly as possible. For example, even with the same air permeability, it is true that if the area is large, the absolute amount of air passing through is large.

Therefore, in the present invention, the outer mesh layer 36a is processed to have a wave shape when viewed in a plan view. In this way, when the outer mesh layer 36a is formed to have a wave shape, the surface area becomes remarkably wider than that of a substantially planar shape. In addition, the increase in the surface area of the outer mesh layer 36a means that the amount of the explosive gas that can pass through substantially the same air permeability is large.

In addition, when the outer mesh layer 36a is formed to have a wave shape, the area in contact with the external support portion 38 installed outside the outer mesh layer 36a is significantly reduced. It is considered that the reduction in the contact area in this way can also substantially reduce the direct thermal conductivity between the meshes. In addition, when an explosion occurs, noise is generated inside, and this noise is expected to be advantageous in terms of noise reduction because more reflection occurs inside the wave-shaped outer mesh layer 36a.

As described above, the large amount of air discharged from the outer mesh layer 36a means that the high-pressure gas generated by the internal explosion can be discharged to the outside most quickly. And this point has the same meaning as that the internal pressure can be quickly reduced through rapid discharge without increasing the overall size of the anti-salt exhaust system. That is, by applying the present invention, it is possible to expect sufficient efficiency while using a small-sized anti-salt exhaust device.

Outside of the outer mesh layer 36a, an outer support portion 38 is provided to firmly support the wave-shaped outer mesh layer 36a. Such an external support 38 may be configured with, for example, a medium-sized mesh network, which can be said to be for efficient passage of air.

Next, the operation of the anti-inflammatory device of the present invention will be briefly described. As described above, when an arc explosion occurs due to an internal cause of the gas insulated switchgear for power equipment, this explosive force causes the gas to damage the rupture disk installed inside the flange 18 and the connection pipe 17 It is introduced into the interior of the other park barrel 40 through.

Here, in the inside of the other park container 40, a part of the explosive gas rises upward through the ventilation hole 54 formed in the center of the plurality of dispersing devices 50 installed inside the other park container 40, and the inclined surface ( The explosive gas hitting 52) is guided to the outer casing 40. The other keg barrel 40 can sufficiently withstand high temperatures, suppresses the flame from going to the outside as much as possible, and at least partially suppresses the outflow of the outside even with respect to the fire.

And since a plurality of the dispersing device 50 is installed over the top and bottom, and each ventilation hole becomes smaller as it goes upward, while substantially dispersing the explosive gas coming into the inside of the other park container 40 as a whole, the outside other park container ( You will understand that it will have the action of passing through 40). Here, since the upper cover 12 is installed on the upper part of the other park container 40, eventually all explosive gases, etc., pass through the external cylindrical anti-chlorine element 30 through the other park container 40.

According to the present invention, the cylindrical anti-chlorine element 30 includes a fibrous high-temperature heat insulating material layer 34 that prevents the outflow of the fire, so it is designed so that the fire generated by the arc explosion is not ultimately leaked to the outside. . And the metal mesh layer 36 installed on the outside suppresses the outflow of the flame to the outside, and moreover, when the outer mesh layer 36a is formed in a wave shape, as described above, the explosive gas is rapidly exhausted and Advantages such as suppression of heat conduction can also be expected.

As described above, the present invention can be variously modified for those skilled in the art within the scope of the basic technical idea, as well as the scope of protection of the present invention to be interpreted based on what is described in the claims. It can be said that it is natural for the purpose of the provisions of the Patent Law.

12 ......Top cover
22 ..... upper frame
24 ..... frame connection
26 ..... lower frame
30 ..... Cylindrical anti-chlorine element
32 ..... Internal support
34 ..... Fibrous high-temperature insulation layer
36 ..... Metal mesh layer
36a ..... outer mesh layer
40 ..... other park version
50 ..... Distributor
52 ..... slope
54 ..... vent hole

Claims (1)

Consisting of a plurality of dish-shaped dispersing devices 50 installed in multiple stages on the inner side of the rupture disk, the connecting pipe in which the rupture disk is installed is connected to the inside and a plurality of holes are molded Become;
Each of the plurality of dispersing devices 50 includes a ventilation hole 54 formed in the center, and an inclined surface 52 having a high upper inclination outside the ventilation hole 54;
The ventilation hole 54 of the dispersing device 50 passes a part of the explosive gas upward, and the inclined surface 52 of the dispersing device 50 guides the other part of the explosive gas to the outside passing through the other park container 40 And;
An anti-salt exhaust device used in a gas insulated switchgear for power equipment, characterized in that the ventilation hole 54 of the dispersing device 50 is formed to become smaller as it goes upward.

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