KR20230127011A - Rupture Disc Assembly for Hyper-voltage Circuit Breaker - Google Patents

Abstract

The present invention relates to a pressure relief plate assembly of an ultra-high voltage circuit breaker and more specifically, relates to the pressure relief plate assembly of the ultra-high voltage circuit breaker that improves safety when releasing gas. According to the pressure relief plate assembly of the ultra-high voltage breaker according to one embodiment of the present invention, a heat gas discharged from an enclosure of a circuit device part unit does not spread in all directions by a switching part, changes a direction to an enclosure cover, and disappears while hitting the enclosure cover. The pressure relief plate assembly comprises: an enclosure cover; a pressure relief plate; and a pressure relief plate cover.

Description

Rupture Disc Assembly for Hyper-voltage Circuit Breaker}

The present invention relates to a pressure relief plate assembly of an ultra-high voltage circuit breaker, and more particularly, to a pressure relief plate assembly of an ultra-high voltage circuit breaker with improved safety during gas discharge.

In general, an extra-high voltage circuit breaker is a circuit breaker used for extra-high voltage devices, and a representative device of such an extra-high voltage circuit breaker is a gas insulated switchgear. Gas Insulated Switchgear is installed between the circuit between the power side and the load side of the electrical system and safely blocks the current when the circuit is artificially opened or closed in a normal current state or when an abnormal current such as a ground fault or short circuit occurs on the circuit. It is an electrical device that protects the power system and load equipment.

The gas insulated switchgear is configured to be charged with an insulating gas such as SF6 to extinguish an arc generated between contacts when it is cut off, or to spray an insulating gas when it is cut off, thereby electrically blocking and extinguishing the arc.

These gas insulated switches (GIS) generally include a bushing unit that receives power from a high-voltage power source, a circuit breaker (CB), a disconnector switch (DS), an earth switch (ES), a moving part, and a control unit. It is composed of a number of units.

Each unit has an enclosure and is interconnected with adjacent units. On the other hand, each unit is provided with a pressure relief plate to release heat gas and pressure generated when shutting off.

1 is a perspective view of any one unit of a gas insulated switchgear according to the prior art.

Any one unit (1) of the gas insulated switchgear has an operating unit (2) providing an operating force, an enclosure (3) containing a circuit mechanism such as a movable unit and a fixed unit that are moved by the operating force of the operating unit (2). .

A pressure relief plate assembly 5 is provided in a part of the enclosure 3.

Here, the pressure relief plate assembly 5 is coupled to the connection part cover 4 and is ruptured when hot gas is generated to form an outlet, and the pressure relief plate 6 is combined with the pressure relief plate 6 to discharge hot gas. It has a pressure relief plate cover (7) with an opening (8).

However, according to the prior art, it is formed in a structure in which the hot gas is discharged by setting the outlet in one direction. In particular, the existing hot gas emission is set in a direction toward the outside rather than toward the unit side. Thus, the safety of workers may be affected.

In the pressure relief plate assembly of the gas insulated switchgear according to the prior art, the pressure relief plate is exposed in the direction set on the pressure plate cover, so there is a risk that the pressure relief plate fragments generated as they are ruptured by the discharged hot gas and gas pressure may harm the user do.

In addition, if the direction of the pressure relief plate is set upward during outdoor installation, water pooling may occur.

The present invention has been made to solve the above problems, and its object is to provide a pressure relief plate assembly of an ultra-high pressure circuit breaker that prevents hot gas from being discharged in the direction of a worker.

A pressure relief plate assembly of an ultra-high voltage circuit breaker according to an embodiment of the present invention includes an enclosure cover of a circuit device unit; a pressure relief plate coupled to cover an open hole formed in the enclosure cover; and a pressure release plate cover coupled to the enclosure cover by bringing the pressure release plate into close contact, wherein the pressure release plate cover includes a coupling portion coupled to the enclosure cover with the pressure release plate interposed therebetween, and disposed spaced apart from the coupling portion. and an outer plate portion, and a conversion portion is formed on an inner surface of the outer plate portion to change a direction of the heat gas discharged from the opening hole.

Here, it is characterized in that a plurality of first fastening holes are formed in the periphery of the open hole in the enclosure cover.

In addition, it is characterized in that a sealing member is provided between the pressure relief plate and the enclosure cover.

In addition, the sealing member is characterized in that formed in a ring shape.

In addition, a plurality of second fastening holes communicating with the plurality of first fastening holes are formed along the circumferential direction at the outer portion of the pressure relief plate.

In addition, the outer plate portion is characterized in that it is composed of a cover plate formed of a flat plate parallel to the coupling portion, and a side plate inclined at a predetermined angle from the circumferential surface of the cover plate.

In addition, the coupling portion is characterized in that formed in a plate-shaped ring shape.

In addition, a gas discharge hole is formed in the central portion of the coupling part, and the diameter of the gas discharge hole is equal to or larger than that of the open hole.

In addition, a plurality of third fastening holes communicating with the plurality of second fastening holes are formed in the circumferential direction in the coupling part.

In addition, a plurality of fourth fastening holes for coupling to the enclosure cover are formed in the cover plate.

In addition, a spacer is provided between the cover plate and the coupling part, one end of the spacer is connected to the coupling part, and the other end of the spacer is connected to the cover plate.

In addition, a through hole is formed along the longitudinal direction in the spaced portion, one end of the through hole is connected to the third fastening hole, and the other end of the through hole is connected to the fourth fastening hole.

In addition, an angle between the inner surface of the cover plate and the inner surface of the side plate is characterized in that it forms an obtuse angle.

In addition, among the spacing between the coupling portion and the side plate, the first interval in a direction parallel to the surface of the coupling portion is characterized in that formed smaller than the second interval in a direction perpendicular to the surface of the coupling portion.

In addition, it is characterized in that the inside of the pressure relief plate cover is provided with a zone plate formed of a plane connected to the spacer, the cover plate and the side plate.

In addition, the zone plate is characterized in that an inclined surface connecting the outer surface of the coupling part and the end of the side plate is formed.

In addition, the outer plate portion is characterized in that it has a switching portion composed of the first inner surface portion of the cover plate and the second inner surface portion of the side plate.

Further, the first inner surface portion is characterized in that the convex portion of the central portion and the first concave portion of the outer portion are formed, and the second inner surface portion is formed with a second concave portion connected to the first concave portion.

According to the pressure relief plate assembly of the extra-high voltage circuit breaker according to an embodiment of the present invention, the heat gas discharged from the enclosure of the circuit device unit does not spread in all directions by the switching unit, but changes its direction to the enclosure cover and disappears while colliding with the enclosure cover. .

Therefore, the thermal gas does not cause damage to peripheral devices or operators.

In addition, fragments of the pressure relief piece are prevented from splashing out to the outside by the pressure relief plate cover.

In addition, the discharge direction can be adjusted according to the user by adjusting the inclination of the side plate of the pressure relief plate cover.

In addition, since the side plate of the pressure relief plate cover forms an obtuse slope with the cover plate, water or foreign substances do not accumulate therein.

In addition, the distance formed by the side part of the coupling part of the pressure relief plate cover is set to be larger in the direction perpendicular to the coupling part than in the direction parallel to the coupling part, so that the direction change and discharge of the hot gas are facilitated.

Meanwhile, a convex portion is formed in the center and a concave portion is formed in the outer portion of the switching portion of the pressure relief plate cover, which is advantageous in inducing the direction of the hot gas.

1 is a perspective view of a gas insulated switchgear according to the prior art.
2 is a perspective view of a pressure relief plate assembly part applied to the gas insulated switchgear in FIG. 1;
3 is a perspective view of any one unit of a gas insulated switchgear according to an embodiment of the present invention.
4 and 5 are a perspective view and a front view of a pressure relief plate assembly part applied to the gas insulated switchgear in FIG. 3 .
6 is an exploded perspective view of an enclosure cover and a pressure relief plate assembly part.
7 and 8 are perspective and longitudinal sectional views of the pressure relief plate cover.
9 is a longitudinal sectional view of a pressure relief plate cover according to another embodiment.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, this is to explain in detail enough for those skilled in the art to easily practice the invention, which means that the technical spirit and scope of the present invention are limited by these drawings. It is not.

The term "member" or "part" used to refer to a component in the present invention is not used for any limiting purpose, and may be omitted.

3 is a perspective view of any one unit of a gas insulated switchgear according to an embodiment of the present invention, and FIGS. 4 and 5 are a perspective view and a front view of a pressure relief plate assembly applied to the gas insulated switchgear in FIG. 3 . 6 is an exploded perspective view of an enclosure cover and a pressure relief plate assembly portion, and FIGS. 7 and 8 are perspective views and longitudinal cross-sectional views of the pressure relief plate cover. The pressure relief plate assembly of the ultra-high voltage circuit breaker according to each embodiment of the present invention will be described in detail with reference to the drawings.

The pressure relief plate assembly of the ultra-high voltage circuit breaker according to an embodiment of the present invention includes an enclosure cover 150 of a circuit device unit; a pressure relief plate 220 coupled to cover the open hole 152 formed in the enclosure cover 150; and a pressure relief plate cover 230 coupled to the enclosure cover 150 by bringing the pressure relief plate 220 into close contact with the pressure relief plate 230, with the pressure relief plate 220 interposed therebetween. It includes a coupling portion 232 coupled to the cover 150 and an outer plate portion 240 spaced apart from the coupling portion 232. It is characterized in that the conversion unit 250 is formed to change the direction of the discharged hot gas.

The extra-high voltage circuit breaker according to an embodiment of the present invention is provided with a unit constituting each circuit device unit 100 . This circuit device unit or circuit device unit 100 may be any one of a circuit breaker, disconnector, and grounding switch.

The circuit device unit 100 , that is, each power appliance unit has an enclosure 110 . An operation unit 120 is connected to the enclosure 110 to open and close the circuit device.

Inside the enclosure 110, a power device (circuit device section) is incorporated. Here, a conductor constituting a circuit connected to a main circuit regardless of a circuit breaker, disconnector, or grounding switch is provided. Usually, since industrial external circuits are composed of three phases, these circuits are composed of three-phase circuits and conductors are also provided as three-phase conductors. Each conductor has a connecting portion to be connected to a circuit of an adjacent device portion. The connecting portion may be provided in the form of a bus bar 112 or may be provided in the form of a socket 114 .

A spacer 130 may be provided at a portion where the enclosure 110 and an adjacent enclosure (not shown) are connected. The spacer 130 serves as a barrier between enclosures and has insulating properties. A three-phase conductor such as a socket 114 or a bus bar 112 extends through the spacer 130 .

A flange portion 140 is formed on the enclosure 110 of the circuit device unit, a portion of which protrudes. An opening is provided in the flange portion 140 so that internal gas can enter and exit.

An enclosure cover 150 covering the flange portion 140 is provided. The enclosure cover 150 covers the opening of the enclosure 110 . The enclosure cover 150 is formed larger than the opening and is firmly coupled to the outer wall 140 by bolts or the like.

An open hole 152 is formed in the center of the enclosure cover 150 so that hot gas can enter and exit.

A plurality of first fastening holes 155 are formed around the open hole 152 .

An enclosure fastening hole 157 is formed at an outer portion of the enclosure cover 150 to be coupled to the outer wall 140 .

The pressure relief plate assembly 200 provided in the circuit device unit 100 of the ultra-high voltage circuit breaker will be described.

A pressure relief plate assembly 200 coupled to the enclosure cover 150 is provided.

First, a pressure relief plate 220 coupled to the enclosure cover 150 is provided. The pressure relief plate 220 is provided to properly respond to the pressure inside the enclosure 110 . Normally, the pressure relief plate 220 contracts or expands (or bends) according to the change in the internal pressure of any one unit enclosure, such as a circuit breaker enclosure, a disconnector enclosure, or a grounding switch enclosure, so that the internal pressure can be maintained constant. On the other hand, when strong pressure is generated inside any one unit enclosure 110 due to an arc, etc., the pressure relief plate 220 is ruptured so that internal gas is discharged to the outside.

The pressure relief plate 220 may be formed in a disk shape. Pressure relief plate 220 may be formed of a metal material such as aluminum or other materials. The pressure relief plate 220 is immediately ruptured (within several milliseconds (ms)) when a pressure higher than the set pressure is generated, thereby contributing to an internal pressure drop.

The central portion 222 of the pressure relief plate 220 may be convexly bent. For example, the central portion 222 may be formed in a partial spherical shape. A radial tear scratch 224 may be formed in the central portion 222 . Accordingly, when internal pressure is generated in the enclosure 110, the pressure relief plate 220 is easily ruptured along the flaw 224. This prevents the pressure relief plate 220 from bursting into irregular fragments and maintains consistent characteristics even when bursting.

A plurality of second fastening holes 226 for coupling to the enclosure cover 150 are formed along the circumference of the outer portion of the pressure relief plate 220 . Here, the plurality of second fastening holes 226 may be equally spaced on the same circumferential surface in the same number as the plurality of first fastening holes 155 formed in the enclosure cover 150 . Accordingly, the fastening member may be fastened through the first fastening hole 155 and the second fastening hole 226 .

A sealing member 210 is provided between the pressure relief plate 220 and the enclosure cover 150 . The sealing member 210 may be formed in a ring shape. Alternatively, the sealing member 210 may be configured as an "O-ring".

A pressure relief plate cover 230 coupled with the pressure relief plate 220 is provided.

The pressure relief plate cover 230 has a coupling part 232 and an outer plate part 240 as main parts.

The coupling part 232 is provided to fix the pressure relief plate 220 to the enclosure cover 150 . The coupling part 232 may be formed in a plate-shaped ring shape. The coupling part 232 is formed to have sufficient thickness and rigidity to support the pressure relief plate 220 .

A gas discharge hole 234 is formed in the center of the coupling part 232 . The gas discharge hole 234 may have a diameter equal to or greater than that of the open hole 152 of the enclosure cover 150 . The hot gas emitted from the inside of the enclosure 110 is discharged through the gas discharge hole 234 . The arc heat gas generated when blocking is ejected through the open hole 152 of the enclosure cover 150, ruptures the pressure relief plate 220, and is discharged through the gas discharge hole 234 of the coupling part 232.

A plurality of third fastening holes 236 for coupling the coupling portion 232 to the enclosure cover 150 are formed in the coupling portion 232 along the circumferential direction. Here, the plurality of third fastening holes 236 may be equally spaced on the same circumferential surface in the same number as the plurality of first fastening holes 155 formed in the enclosure cover 150 . Accordingly, the fastening member may be fastened through the first fastening hole 155 , the second fastening hole 226 , and the third fastening hole 236 .

The coupling portion 232 is coupled to the enclosure cover 150 together with the pressure release plate 220 by fastening screws (not shown) penetrating the coupling portion 232, the pressure relief plate 220, and the enclosure cover 150. The pressure relief plate 220 is compressed between the coupling portion 232 and the enclosure cover 150 to maintain a stable coupling state.

An outer plate portion 240 is provided. The outer plate portion 240 is provided to protect arc gas coming out through the gas discharge hole 234 and to protect users. The outer plate part 240 may be composed of a cover plate 241 formed as a flat plate parallel to the coupling part 232 and a side plate 242 inclined at a predetermined angle from the circumferential surface of the cover plate 241 .

The cover plate 241 is spaced apart from the coupling part 232 . A plurality of fourth fastening holes 245 for coupling the cover plate 241 to the enclosure cover 150 are formed in the cover plate 241 . Here, the fourth fastening hole 245 may communicate with the third fastening hole 236 .

A spaced portion 235 is provided to separate the cover plate 241 from the coupling portion 232 . The spacer 235 may be formed of a linear member. It is connected to the coupling part 232 of the spaced part 235, and the other end of the spaced part 235 is connected to the cover plate 241.

A through hole 235a is formed in the spaced portion 235 along the longitudinal direction. Here, one end of the through hole 235a of the spacer 235 is connected to the third fastening hole 236 of the coupling part 232, and the other end of the spacer 235 is the fourth fastening of the cover plate 241. It is connected to hole 245. Accordingly, the fastening member is connected to the pressure relief plate assembly 200 through the fourth fastening hole 245, the through hole 235a, the third fastening hole 236, the second fastening hole 226, and the first fastening hole 155. ) can be coupled to the enclosure cover 150.

The cover plate 241 is installed at a predetermined distance from the coupling part 232 by the spacer 235 . Alternatively, the cover plate 241 and the coupling part 232 , which are spaced apart from each other, are connected by a spaced part 235 .

A side plate 242 is formed along the outer circumferential surface of the cover plate 241 . The side plate 242 is formed to have a predetermined angle with the cover plate 241 . An angle formed between the inner surface of the cover plate 241 and the inner surface of the side plate 242 is preferably an obtuse angle. More specifically, the angle formed between the inner surface of the cover plate 241 and the inner surface of the side plate 242 is preferably formed within a range of 90 degrees to 135 degrees. Accordingly, the heat gas discharged through the gas discharge hole 234 may appropriately change direction and return toward the surface of the enclosure cover 150 . When the angle formed between the inner surface of the cover plate 241 and the inner surface of the side plate 242 is within a range of 90 degrees, there is a risk of reverse circulation to the gas discharge hole 234, and the inner surface of the cover plate 241 If the angle formed by the inner surface of the side plate 242 is greater than or equal to 135 degrees, the thermal gas may spread to the surrounding area, compromising the safety of workers or damaging peripheral devices.

A conversion unit 250 is provided on the inner surface of the cover plate 241 . The switching unit 250 is provided to change the direction of the hot gas coming out through the gas discharge hole 234 . Since the conversion part 250 is provided on the inner surface of the cover plate 241, it is spaced apart from the coupling part 232 by a predetermined distance.

The conversion unit 250 may be referred to as the combination of the first inner surface portion 251 of the cover plate 241 and the second inner surface portion 252 of the side plate 242 . The thermal gas coming out of the gas discharge hole 234 first collides with the first inner surface portion 251 of the cover plate 241, and is directed to the side portion due to the collision in the hot gas in the center, and the second inner surface portion of the side plate 242. While colliding with 252, it flows in the reverse direction and flows toward the surface of the enclosure cover 150. Therefore, the thermal gas discharged through the gas discharge hole 234 primarily collides with the switching unit 250 to change its direction, and secondarily collides with the enclosure cover 150 to weaken and dissipate.

A zone plate 237 is provided inside the pressure relief plate cover 230 . The zone plate 237 is formed of a surface connected to the spaced portion 235, the cover plate 241, and the side plate 242. The zone plate 237 is a surface extending radially from the central axis of the pressure relief plate cover 230 through the spaced portion 235 . The zone plate 237 is formed so that the hot gas is not concentrated in one place but is divided and ejected in various directions.

The zone plate 237 has an inclined surface 237a connecting the outer surface of the coupling part 232 and the end of the side plate 242. The inclined surface 237a is formed on the zone plate 237 to prevent the hot gas from leaking out to the outside as much as possible.

A first gap G1 and a second gap G2 between the coupling part 232 and the side plate 242 are formed in the pressure relief plate cover 230 . Here, the first distance G1 means a distance in a direction parallel to the surface of the coupling part 232, and the second distance G2 means a distance in a direction perpendicular to the surface of the coupling part 232. At this time, the first gap G1 is smaller than the second gap G2. This is to increase the function of inducing the heat gas to return to the enclosure cover 150 after being changed in direction without spreading to the periphery.

Referring to FIG. 9, another embodiment of the pressure relief plate cover 230A will be described.

The same parts as the pressure relief plate cover 230 of the previous embodiment will not be explained, and the same will be applied to this embodiment.

The conversion portion 250 formed on the inner surfaces of the cover plate 241 and the side plate 242 is formed as a curved surface. The first inner surface portion 251 formed on the cover plate 241 has a convex portion 251a in the center and a first concave portion 251b in the outer portion.

The second inner surface portion 252 formed on the side plate 242 has a second concave portion 252a. Here, the first concave portion 251b and the second concave portion 252a are smoothly connected to each other.

The conversion part 250 is formed of a convex part 251a and concave parts 251b and 252a and serves to guide the flow of hot gas.

According to the pressure relief plate assembly of the extra-high voltage circuit breaker according to an embodiment of the present invention, the heat gas discharged from the enclosure of the circuit device unit does not spread in all directions by the switching unit, but changes its direction to the enclosure cover and disappears while colliding with the enclosure cover. .

Therefore, the thermal gas does not cause damage to peripheral devices or operators.

In addition, fragments of the pressure relief piece are prevented from splashing out to the outside by the pressure relief plate cover.

In addition, the discharge direction can be adjusted according to the user by adjusting the inclination of the side plate of the pressure relief plate cover.

In addition, since the side plate of the pressure relief plate cover forms an obtuse slope with the cover plate, water or foreign substances do not accumulate therein.

The distance formed by the side part of the coupling part of the pressure relief plate cover is set to be larger in the direction perpendicular to the coupling part than in the direction parallel to the coupling part, so that it is easy to change the direction and discharge the hot gas.

A convex part is formed in the center and a concave part is formed in the outer part of the switching part of the pressure plate cover, which is advantageous in inducing the direction of the hot gas.

The embodiments described above are examples of the best practice for implementing the present invention, and those skilled in the art can make various modifications and modifications without departing from the essential characteristics of the present invention. transformation will be possible. Therefore, these embodiments are only intended to explain and not to limit the technical idea of the present invention. Therefore, it should be understood that the scope of the technical idea of the present invention is not limited by these embodiments. That is, the protection scope of the present invention should be construed according to the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100 circuit device unit
110 enclosure
120 control panel
130 spacer
140 Flange
150 enclosure cover
152 open hole
200 Pressure Plate Assembly
210 sealing member
220 pressure plate
230 pressure plate cover
232 joint
234 gas discharge hole
235 separation
237 regional edition
240 outer plate
241 cover plate
242 shroud
250 transition
251 first inner side portion
252 second inner side part

Claims (18)

an enclosure cover of a circuit device portion unit;
a pressure relief plate coupled to cover an open hole formed in the enclosure cover; and
A pressure relief plate cover coupled to the enclosure cover by closely contacting the pressure relief plate,
The pressure relief plate cover,
A coupling part coupled to the enclosure cover with the pressure relief plate interposed therebetween;
Including an outer plate portion disposed spaced apart from the coupling portion,
The pressure relief plate assembly of the ultra-high pressure circuit breaker, characterized in that the conversion portion is formed on the inner surface of the outer plate portion to change the direction of the hot gas discharged from the opening hole. The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 1, wherein a plurality of first fastening holes are formed around the open hole in the enclosure cover. The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 1, wherein a sealing member is provided between the pressure relief plate and the enclosure cover. [4] The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 3, wherein the sealing member is formed in a ring shape. The pressure relief plate assembly of claim 2, wherein a plurality of second fastening holes communicating with the plurality of first fastening holes are formed in a circumferential direction at an outer portion of the pressure relief plate. The method of claim 2, wherein the outer plate portion,
A cover plate formed of a flat plate parallel to the coupling part;
Pressure relief plate assembly of an ultra-high voltage circuit breaker, characterized in that composed of a side plate inclined at a predetermined angle from the circumferential surface of the cover plate. [7] The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 6, wherein the coupling part is formed in a plate-shaped ring shape. [8] The pressure relief plate assembly of an ultra-high pressure circuit breaker according to claim 7, wherein a gas discharge hole is formed at a central portion of the coupling part, and the gas discharge hole has a diameter equal to or greater than that of the open hole. [Claim 9] The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 8, wherein a plurality of third fastening holes communicating with the plurality of second fastening holes are formed in the coupling part along a circumferential direction. [Claim 10] The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 9, wherein a plurality of fourth fastening holes for coupling to the enclosure cover are formed in the cover plate. 11. The method of claim 10, wherein a spaced portion is provided between the cover plate and the coupling portion,
The pressure relief plate assembly of the ultra-high voltage circuit breaker, characterized in that one end of the spacer is connected to the coupling part, and the other end of the spacer is connected to the cover plate. 12. The method of claim 11 , wherein a through hole is formed in the spaced portion along a longitudinal direction, one end of the through hole is connected to the third fastening hole, and the other end of the through hole is connected to the fourth fastening hole. A pressure relief plate assembly of an extra-high voltage circuit breaker. The pressure relief plate assembly of claim 6, wherein an angle formed between an inner surface of the cover plate and an inner surface of the side plate forms an obtuse angle. The ultra-high pressure according to claim 6, wherein, among the distances between the coupling part and the side plate, a first distance in a direction parallel to the surface of the coupling part is smaller than a second distance in a direction perpendicular to the surface of the coupling part. The pressure relief plate assembly of the circuit breaker. [Claim 12] The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 11, wherein a region plate formed in a plane connected to the spaced portion, the cover plate, and the side plate is provided inside the pressure relief plate cover. [16] The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 15, wherein the zone plate has an inclined surface connecting an outer surface of the coupling part and an end of the side plate. [Claim 7] The pressure relief plate assembly of an ultra-high voltage circuit breaker according to claim 6, wherein the outer plate portion has a switching portion composed of a first inner surface portion of the cover plate and a second inner surface portion of the side plate. 18. The method of claim 17, wherein a convex portion of the center and a first concave portion of the outer portion are formed on the first inner surface portion, and a second concave portion connected to the first concave portion is formed on the second inner surface portion. Pressure relief plate assembly of high-voltage circuit breaker.

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