KR101622445B1 - switchergear having pressure relief route structure - Google Patents

Abstract

A two-stage power distribution board comprising: a plurality of upper shielding chambers which are installed laterally coupled to each other with partition walls disposed on an upper end thereof; A plurality of lower blocking chambers provided at the lower ends corresponding to the plurality of upper blocking chambers and coupled laterally with partition walls therebetween; A plurality of LV seals installed in a partial upper region of the lower interrupter chamber; And a pressure-proof passage structure formed between the lower breaker chamber and the upper breaker chamber at the rear of the plurality of LV chambers, the pressure-blocking passage structure being formed by passing through the switchboard laterally; The pressure-proof passage structure is provided with a pressure-blocking passage structure having a pressure-blocking passage structure that allows gas generated in the lower blocking chamber to be discharged through a pressure-tight hole formed on the upper surface of the upper blocking chamber through the pressure-

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a switchgear having a pressure relief route structure,

The present invention relates to an electrical switchboard having a pressure-proof passage structure, more particularly, to an electrical switchboard having a pressure-proof passage structure capable of discharging energy to an upper part of the switchboard, .

The switchgear is a facility to safely supply industrial power to the user by housing the breaker and protective relay in the steel enclosure to safely use the electricity in the faucet and power distribution system.

Closed switchboard means a switchboard in which the components for performing the function of the switchboard are closed and assembled with a grounded metal body. A metal-clad switchgear is a closed switchboard with compartments with metallic bulkheads with components grounded.

When an arc short circuit fault occurs in a closed switchboard, for example, a three phase full arc short circuit, the switchboard explodes and becomes a serious accident that causes damage to the nearby people.

In the conventional two-stage closed switchboard, an ACR VENT is formed in the upper part of the upper cut-off chamber so that the gas is discharged through the pressure port in case of arc explosion in the upper cut-off chamber. Meanwhile, in the case of the lower interrupter chamber, it is structured to be connected to the pressure port formed on the upper portion of the upper interrupter chamber by using the empty space of the left and right side frames. However, the empty space of the left and right side frames has a very narrow structure.

Accordingly, it is necessary to improve the high-temperature and high-pressure gas generated in the lower cutoff chamber to be discharged to the outside.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an electrical switchboard having a pressure-proof passage structure having a structure that allows energy to be smoothly discharged upward in a three-phase short-circuited case inside a two-level switchboard located at upper and lower portions of the circuit breaker.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description will be.

According to an aspect of the present invention, there is provided a two-stage power distribution board comprising: a plurality of upper cut-off gas chambers which are installed laterally with partition walls at the upper ends thereof; A plurality of lower blocking chambers provided at the lower ends corresponding to the plurality of upper blocking chambers and coupled laterally with partition walls therebetween; A plurality of LV seals installed in a partial upper region of the lower interrupter chamber; And a pressure-proof passage structure formed between the lower breaker chamber and the upper breaker chamber at the rear of the plurality of LV chambers, the pressure-blocking passage structure being formed by passing through the switchboard laterally; The pressure-proof passage structure is provided with a pressure-blocking passage structure having a pressure-blocking passage structure that allows gas generated in the lower blocking chamber to be discharged through a pressure-tight hole formed on the upper surface of the upper blocking chamber through the pressure-

The pressure-proof passage structure includes a pressure-tight passage frame formed on the rear side of the plurality of LV chambers between the lower breaker chamber and the upper block chamber; And a lower partition wall formed as a part of the partition wall of the lower interrupter chamber and coupled to the bottom of the pressure-tight passage frame so as to be pivotally opened by the gas generated in the lower interrupter chamber.

The pressure-tight passage frame may be one of a rectangular, a triangular, a circular, and an elliptical cross-section.

The distribution board may further include a lower BUS chamber provided with a partition wall at the rear of the lower cutoff chamber, and the pressure-proof passage structure forms a part of the side partition wall of the lower BUS chamber so as to be opened and rotated by the gas generated in the lower BUS chamber. And a side partition wall provided to be coupled to a side surface of the pressure-proof passage frame.

The switchboard may include a first upper breaker, a second upper breaker, and a third upper breaker chamber arranged laterally adjacent to the plurality of upper breaker rooms, The second upper circuit breaker room has an open area formed in a part of the bottom surface to be connected to the pressure-proof passage structure on a part of the bottom surface, and the first lower circuit breaker, the second lower circuit breaker, The gas generated in the two lower interrupter chamber and the third lower interrupter chamber can pass through the pressure-proof passage structure and can be discharged through the bottom opening area of the second upper interrupter chamber through the pressure port provided on the upper surface of the upper interrupter chamber.

And the second upper circuit breaker room may be configured as a space of the spare area.

The second upper breaker room may form an open area at the bottom of the rear space through the vertical partition and the front space may comprise a spare area.

According to the present invention, the high-temperature, high-pressure gas generated in the lower interrupter chamber located at the lower portion in the case of a three-phase short-circuited fault inside the two-level switchboard located above and below the breaker can be smoothly discharged to the upper portion through the pressure- The stability of the switchboard can be improved.

FIG. 1 is a view for explaining a structure of a distribution board having a pressure-proof passage structure according to an embodiment of the present invention.
2 is a view showing a front surface of an electric distribution panel having a pressure-proof passage structure according to an embodiment of the present invention.
3 is a view for explaining an internal structure of an electric distribution board having a pressure-proof passage structure according to an embodiment of the present invention.
4 is a view for explaining the discharge of the gas in the lower cable chamber through the pressure-proof passage structure in the switchboard having the pressure-proof passage structure according to the embodiment of the present invention.
5 is a view for explaining the discharge of the gas in the lower cutoff chamber through the pressure-proof passage structure in the switchboard having the pressure-proof passage structure according to the embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It should be understood, however, that there is no intention to limit the scope of the present invention to the embodiment shown, and other embodiments which are degenerative by adding, changing or deleting other elements or other embodiments falling within the spirit of the present invention Can be proposed.

Although the term used in the present invention is a general term that is widely used at present, there are some terms selected arbitrarily by the applicant in a specific case. In this case, since the meaning is described in detail in the description of the corresponding invention, It is to be understood that the present invention should be grasped as a meaning of a non-term.

That is, in the following description, the word 'comprising' does not exclude the presence of other elements or steps than those listed.

FIG. 1 is a view for explaining a structure of a distribution board having a pressure-proof passage structure according to an embodiment of the present invention. 2 is a view showing a front surface of an electric distribution panel having a pressure-proof passage structure according to an embodiment of the present invention.

Referring to FIG. 1 (a), the switchgear 100 having the pressure-proof passage structure according to the embodiment of the present invention is provided with a door 110 on its front surface. The outer surface of which is covered with the housing 130. The outer surface of the housing 130 is covered with a plurality of pressure- Inside are components that include a breaker and a protective relay to safely use electricity in the faucet and distribution grid.

Referring to FIG. 1 (b), when the front door 110 and the side housing 130 are removed from the switchboard 100, the inside of the switchboard 100 can be seen. Here, components including a breaker and a protective relay mounted inside the switchgear for convenience are not shown.

The switchboard 100 has a two-level switchboard structure of an upper interrupter chamber 140 and a lower interrupter chamber 150. The switchboard 100 is provided with an LV chamber 160 in an upper part of the lower cutoff chamber 150. On the rear surface of the LV chamber 160, a pressure-proof passage 170 is formed. The pressure-proof passage 170 is formed to pass through the switchboard 100 transversely. The pressure-proof passage 170 has a rectangular cross section, but the present invention is not limited thereto. For example, the present invention can be fabricated such that the cross section is triangular or circular or elliptical.

The switchgear 100 may have a pair of cabinets in which one upper interrupter chamber 140 and one lower interrupter chamber 150 are arranged such that a plurality of cabinets may be laterally aligned, Respectively. The upper interrupter chamber 140 and the lower interrupter chamber 150 may be equipped with components for performing the function of the switchboard.

2 (a) and 1 (b), an upper breaker chamber 140 formed at the upper end of the switchboard 100 includes a first upper breaker chamber 141, an upper space 142, a second upper breaker chamber 142 are arranged laterally. At this time, the upper space 142 located between the first upper blocking chamber 141 and the second upper blocking chamber 143 is an empty space.

The lower interrupter chamber 150 formed at the lower end of the switchboard 100 has the first lower interrupter chamber 151, the second lower interrupter chamber 152 and the third lower interrupter chamber 153 arranged transversely.

The first upper cut-off chamber 141, the second upper cut-off chamber 143, the first lower cutoff chamber 151, the second lower cutoff chamber 152, and the third lower cutoff chamber 153, except for the upper space 142, ) Are equipped with components for distribution function.

The upper space 142 has an open area 142a connected to the pressure-proof passage 170 at a part of the bottom surface. That is, the pressure-proof passage 170 formed on the rear surface of the LV chamber 160 is exposed through the open area 142a of the bottom surface of the upper space 142.

The gas generated in the second lower cutoff chamber 152 flows through the pressure receiving passage 170 and the open area 142a of the bottom surface of the upper space 142 to the pressure port 120 ). ≪ / RTI >

The upper space 142 may be exposed to the entire bottom surface of the upper space 142 with the open area 142a formed on the bottom surface thereof, An open area 142a may be formed in the front space, and the front space may be used as a preliminary space. The spare space may be equipped with components for distribution functions as required.

The gas generated in the first lower cut-off valve chamber 151 moves to the bottom surface of the upper space 142 through the pressure-blocking passage 170 formed in the upper portion of the first lower cut-off valve chamber 151, Through the open area 142a of the bottom surface of the upper space 142,

The gas generated in the third lower blocking chamber 153 moves to the bottom surface of the upper space 142 through the pressure blocking passage 170 formed in the upper portion of the third lower blocking chamber 153, Through the open area 142a of the bottom surface of the upper space 142,

3 is a view for explaining an internal structure of an electric distribution board having a pressure-proof passage structure according to an embodiment of the present invention.

Referring to FIG. 3, the switchboard 100 having the pressure-proof passage structure according to the embodiment of the present invention includes an upper cutter chamber 140 formed at an upper end thereof and a lower cutter chamber 150 formed at a lower end thereof And an LV chamber 160 is formed in a part of the upper part of the lower cutter chamber 150. A pressure-proof passage 170 is formed between the upper portion of the lower cutoff chamber 150 and the upper cutoff chamber 140. The pressure-proof passage 170 is formed on the rear surface of the LV chamber 160.

The pressure blocking passage frame 171 is in contact with the LV chamber 160 on the front side and contacts the lower BUS chamber 191 on the rear side. The upper blocking chamber 140 is in contact with the upper blocking chamber 171, (150) are formed in contact with each other.

The pressure-proof passage frame 171 constituting the pressure-proof passage 170 is provided with a side partition 172 and a lower partition 173 which are rotatable by the impact of gas.

The side partition wall 172 is provided on the side surface of the pressure-proof passage frame 171 so as to be adjacent to the lower BUS chamber 191. The side partition wall 172 is fastened to the pressure-proof passage frame 171 so as to be rotatable by the hinge 174 as shown in Fig. 4 (a). The safety pin 175 is installed so that the side partition wall 172 can be kept closed in the pressure-proof passage frame 171 before the gas is generated. When the gas explosion occurs in the lower BUS chamber 191, the side partition wall 172 rotates in the pressure-tight passage frame 171 by the impact of the gas generated in the lower BUS chamber 191 as shown in FIG. 4 (b) Can be opened.

The lower partition wall 173 is provided on the lower surface of the pressure-proof passage frame 172 so as to be adjacent to the upper portion of the lower block chamber 150. The lower partition wall 173 is installed in the pressure-proof passage frame 171 so as to be opened and rotated by the impact of the gas generated in the lower cut-off valve chamber 150.

The lower partition wall 172 is fastened to the pressure-proof passage frame 171 so as to be rotatable by a hinge as shown in FIG. 5 (a). The safety pin 176 is installed so that the lower partition wall 173 can be maintained in the closed state in the pressure-proof passage frame 171 before the gas is generated. When the gas explosion occurs in the lower blocking chamber 150, the lower blocking wall 173 rotates in the pressure blocking passage frame 171 by the impact of the gas generated in the lower blocking chamber 150, as shown in FIG. 5 (b) Can be opened.

A lower BUS chamber 191 and a lower cable chamber 192 are positioned at the lower end of the switchboard 100 on the rear surface of the lower cutoff chamber 150.

An upper BUS chamber 193 and an upper cable chamber 194 are located on the rear of the upper breaker chamber 140 at the upper end of the switchboard 100.

A first pressure port 121 is formed at an upper portion of the upper cut-off chamber 140. A second belling port 122 is formed on the upper portion of the upper BUS chamber 193. A third charging port 123 is formed on the upper portion of the upper cable chamber 194.

The gas generated in the upper cutoff chamber 150 may be discharged through the first pressure port 121 formed in the upper portion of the upper cutoff chamber 150.

The gas generated in the lower cutter chamber 150 is separated from the lower partition chamber 150 by the lower partition wall 173 provided at the lower portion of the pressure-tight passage frame 171 constituting the pressure- And can be moved to the upper cut-off chamber 150.

The gas in the lower cutoff chamber 150 moved to the upper cutoff chamber 150 may be discharged through the first pressure port 121 formed in the upper portion of the upper cutoff chamber 150.

Similarly, the gas generated in the lower cable chamber 191 is supplied to the side partition wall 172 provided on the side portion of the pressure-proof passage frame 171 constituting the pressure-proof passage 170 formed in the side surface of the lower cable chamber 191, And can be moved to the upper cut-off chamber 150, as shown in FIG.

The gas in the lower cable chamber 191 moved to the upper cutoff chamber 150 may be discharged through the first pressure port 121 formed in the upper portion of the upper cutoff chamber 150.

The gas generated in the upper BUS chamber 193 may be discharged through the second pressure port 123 formed on the upper portion of the upper BUS chamber 193. [

The gas generated in the upper cable chamber 194 may be discharged through the third pressure port 123 formed in the upper portion of the upper cable chamber 194. [

The gas generated in the lower cable chamber 192 is formed in the upper portion of the upper cable chamber 194 while the partition wall 192a provided between the lower cable chamber 192 and the upper cable chamber 194 is pivoted by the gas impact, And may be discharged through the third pressure receiver 123.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims and the claims.

Claims (7)

A plurality of upper shielding chambers installed laterally with their respective bulkheads on top; A plurality of lower blocking chambers provided in the lower portion corresponding to the plurality of upper blocking chambers and laterally coupled to each other with partition walls therebetween; A plurality of LV seals installed in a partial upper region of the lower interrupter chamber; And a lower BUS chamber provided with a partition at the rear of the lower cutoff chamber,
And a pressure-tight passage structure formed between the lower breaker chamber and the upper cut-off chamber at the rear side of the plurality of LV chambers, the pressure-blocking passage structure being formed by passing through the switchboard laterally;
Wherein the pressure-blocking passage structure is formed such that gas generated in the lower cutter chamber or the lower BUS chamber is discharged through the pressure-blocking port formed on the upper surface of the upper cut-off chamber through the pressure-blocking passage structure,
Wherein the pressure-proof passage structure includes a pressure-tight passage frame formed on the rear side of the plurality of LV chambers between the lower breaker chamber and the upper block chamber;
A lower partition wall which is coupled to a bottom side of the pressure-proof passage frame to constitute a part of the partition wall of the lower cutoff chamber and is opened by pivoting by gas generated in the lower cutoff chamber,
And a side partition wall which is coupled to a side surface of the pressure-proof passage frame to constitute a part of a side partition wall of the lower BUS chamber and which is opened by pivoting by gas generated in the lower BUS chamber. delete The method according to claim 1,
Wherein the pressure-proof passage frame is provided with a pressure-proof passage structure having a square or triangular cross-section. delete The method according to claim 1,
Wherein the plurality of upper breaker chambers include a first upper breaker chamber, a second upper breaker chamber, and a third upper breaker chamber arranged laterally adjacent to each other,
Wherein the plurality of lower breaker rooms include a first lower breaker chamber, a second lower breaker chamber, and a third lower breaker chamber that are arranged laterally adjacent to each other,
Wherein the second upper circuit breaker chamber has an open region formed in a part of a bottom surface thereof so as to be connected to the pressure-proof passage structure,
The gas generated in the first lower cut-off chamber, the second lower cut-off chamber, and the third lower cut-off chamber passes through the pressure-blocking passage structure and flows through the bottom open region of the second upper cut- An electric distribution panel equipped with a pressure-proof passage structure discharged through a pressure port provided on the upper surface. The switchgear according to claim 5, wherein the second upper circuit breaker room is provided with a pressure-proof passage structure that is a space of a spare area. 6. The method of claim 5,
Wherein the second upper breaker room is divided through the vertical partitions to form the open area at the bottom of the rear space and the front space is provided with the pressure-proof passage structure having the spare area.

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