KR102540141B1 - Arc flame extinguishing device for gas insulated switcher - Google Patents

Abstract

An invention for an arc flame extinguishing device for a gas insulated switchgear is disclosed. The disclosed arc flame extinguishing device for a gas insulated switchgear includes a first pipe for guiding the arc flame generated in the first arc flame generating part of the gas insulated switchgear upward, and a second arc flame generating part of the gas insulated switchgear. A second pipe for guiding the generated arc flame upward, and the first pipe and the second pipe are connected to both sides, respectively, to guide the arc flame generated in the first and second arc flame generators to the center and extinguish it, It is characterized in that it comprises an arcing chlorination unit that is moved to and extinguished again.

Description

Arc flame extinguishing device for gas insulated switchgear {ARC FLAME EXTINGUISHING DEVICE FOR GAS INSULATED SWITCHER}

The present invention relates to an arc flame extinguishing device for a gas insulated switchgear, and more particularly, to an arc flame generated in the first and second arc flame generators of the gas insulated switchgear to be directed upward through the first and second pipes. First extinguishing through the deceleration bulkhead, which gradually increases in angle from both sides to the center, and then extinguishing again through the discharge hole of the flame reduction cylinder, completely extinguishing the flame through multiple layers of flame removal units and discharging only smoke, increasing space utilization The present invention relates to an arc flame extinguishing device for a gas insulated switchgear that can prevent a fire caused by a flame ejection while preventing fire in advance.

In general, gas insulated switchgear is an electric device filled with gas such as SF6 with excellent insulation and arc extinguishing characteristics by embedding a busbar, disconnector, grounding switchgear, circuit breaker, current transformer, etc. in a grounded metal tank. It protects the power system by safely opening and closing lines from abnormal conditions such as short circuits.

A conventional gas insulated switchgear includes a first busbar, a second busbar, a first disconnector, a second disconnector, a circuit breaker, and a pressure relief valve in an enclosure.

The first disconnector is provided on the first bus bar, and the second disconnector is provided on the second bus bar. When either one of the first and second busses fails, it is designed to supply power using the other bus among the first and second buses.

In particular, the first and second disconnectors of the gas insulated switchgear are installed on the high-voltage bus bar and are used to simply open and close the charged line under the rated voltage.

Unlike a circuit breaker among gas insulated switchgears for the purpose of opening and closing load current or fault current, the first and second disconnectors do not have a load current blocking function.

The circuit breaker is provided with a fixed electrode (not shown) and a movable electrode (not shown) therein, and the movable electrode is detached from the fixed electrode by a power source to selectively cut off the power system.

The conventional gas insulated switchgear constructed as described above has a structure in which protective covers are installed on the left, right and rear sides of the gas insulated switchgear, and an arc canopy is installed on the upper side to induce and discharge arc flames to the upper side.

However, the gas insulated switchgear protects only the flame ejected when an arc is generated, and additional damage may occur because it cannot completely remove the arc. Since it surrounds the entire switchgear, inspection and maintenance are difficult.

Therefore, there is a need to improve this.

As a related background art, there is Korean Patent Registration No. 2045896 (2019.11.12, title of invention: protective cover for gas insulated switchgear).

The present invention was created by the above necessity, and the arc flame generated in the first and second arc flame generators of the gas insulated switchgear is guided upward through the first and second pipes, so that the angle increases toward the center from both sides. First extinguishing through the gradually increasing deceleration bulkhead, extinguishing again through the discharge hole of the flame reduction tank, completely extinguishing through multiple layers of flame removal parts, and discharging only smoke. Its purpose is to provide an arc flame extinguishing device for gas insulated switchgear that can prevent

In order to achieve the above object, an arc flame extinguishing device for a gas insulated switchgear according to the present invention includes a first pipe for guiding an arc flame generated in a first arc flame generator of the gas insulated switchgear upward; A second pipe for guiding the arc flame generated in the second arc flame generator of the gas insulated switchgear upward; And an arc chlorination unit in which the first pipe and the second pipe are connected to both sides to extinguish the arc flame generated by the first and second arc flame generators by guiding them to the center and moving them to the side to extinguish them again. It is characterized by including;

The first arc flame generator includes a first bus and a first disconnector connected through the first pipe, and the second arc flame generator includes a second bus, a second disconnector, and a circuit breaker connected through the second pipe. It is characterized in that it includes.

A pressure relief valve for inducing an arc flame is provided at the outlet side of the first busbar, the first disconnector connected to the first pipe, the first busbar connected to the second pipe, the second disconnector, and the circuit breaker. to be

The arcing chlorination unit may include a first support cover connected to the first pipe and having a first outer support portion formed thereon; a second support cover connected to the second pipe and having a second outer support portion; a flame reduction cylinder connected to the inside of the first support cover and the second support cover and having a plurality of discharge holes; a deceleration bulkhead which is installed in multiple stages inside the flame reducing cylinder and blocks arc flame introduced through the first pipe and arc flame introduced through the second pipe, respectively; And a flame eliminator installed on both sides of the first outer support and the second outer support to remove some of the flame discharged through the discharge hole of the flame reducing cylinder and discharge smoke to the outside. .

The discharge hole is formed to gradually narrow from the entry side to the discharge side so that the outer diameter (b) is smaller than the inner diameter (a), so that the discharged arc flame hits the inner slope and is gradually reduced. .

A passage hole is formed in the center of the reduction bulkhead to allow some arc flames to explode, and the remaining arc flames collide with the inclined surface of the reduction bulkhead and are guided to the side to the discharge hole of the flame reducing cylinder and the flame removal unit. The passage hole is characterized in that it is formed to become narrower as it goes from the reduction partition at the entry side to the reduction partition at the upper center of the plurality of reduction partitions in the first and second pipes.

The deceleration bulkhead increases the reducing power of the arc flame by gradually increasing the first inclination angle (α), which is an acute angle with respect to the flame reducing pipe, from the first pipe to the center, and the deceleration bulkhead is in the second pipe The second inclination angle β, which is an acute angle with respect to the flame reducing cylinder, gradually increases toward the center to increase the reducing power of the arc flame, and the first inclination angle α and the second inclination angle β are It is characterized in that it is formed inclined in the opposite direction.

An auxiliary flame reducing unit connected to the inner surfaces of the first and second support covers is further provided around the flame reducing cylinder to change and block the path of the arc flame discharged from the discharge hole to reduce it. .

The auxiliary flame reducing unit is installed on the inner surface of the first and second support covers, and is formed in an elliptical or cylindrical shape equal to the shape of the flame reducing tube; And it is provided in the auxiliary flame reducing cylinder, is formed at a position that is offset from each other with respect to the discharge hole, and the arc flame discharged from the discharge hole is reduced while colliding with the inner wall surface of the auxiliary flame reducing cylinder, and then converts the path to the flame It is characterized in that it comprises a; secondary discharge hole to be discharged to the removal unit.

The deceleration bulkhead may be provided with a reflection movement blocker to reduce the reflection of the arc flame that hits the inclined surface of the deceleration bulkhead and move to the flame reducing chamber.

The reflection movement blocking unit may include installation members installed in multiple stages on the inclined surface of the deceleration bulkhead; And the installation member is bent and formed at a set reflection angle (θ) with respect to the inclined surface of the reduction bulkhead, and the arc flame reflected by hitting the reduction bulkhead is reflected again to return to the reduction bulkhead. Arc flame by repeating the process It is characterized in that it comprises a; blocking member for extinguishing.

The flame removal unit may include a first mesh network in which a mesh is formed; a second mesh network having a denser mesh than the first mesh network; and a third mesh network having a denser mesh than the second mesh network.

An arc flame extinguishing device for a gas insulated switchgear according to the present invention induces arc flames generated in the first and second arc flame generators of the gas insulated switchgear upward through the first and second pipes to move them from both sides to the center. First extinguishing through the deceleration bulkhead, which gradually increases in angle, and extinguishing again through the discharge hole of the flame reduction cylinder, completely extinguishing through multiple layers of flame removal parts and discharging only smoke, thereby increasing space utilization and fire by flame ejection can be prevented in advance.

In addition, the present invention further provides an auxiliary flame reducing pipe on the outside of the flame reducing pipe to form a pipe that gradually narrows from the inside to the outside and a auxiliary pipe that gradually narrows from the inside to the outside to offset each other, thereby reducing the arc flame. has the effect of significantly reducing its power by changing the path of

In addition, the present invention has an effect of extinguishing a large amount of arc flame by repeating the process of returning and reflecting the arc flame reflected from the deceleration bulkhead to the deceleration bulkhead by providing a reflection movement blocker in the deceleration bulkhead.

1 is a block diagram of the entire system of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention.
2 is a cross-sectional view of an arc chlorination unit of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention.
3 is a cross-sectional view of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention.
4 is an external perspective view of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention.
5 is a vertical cross-sectional view showing a state in which an auxiliary flame reducing unit is further provided in an arc chlorination unit of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention.
Figure 6 is an enlarged cross-sectional view of a flame reduction tube and an auxiliary flame reduction unit in an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention.
7 is a cross-sectional view showing a state in which a reflection movement blocking part is further provided in an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention.
8 is an exploded perspective view of the bottom of FIG. 7 .
9 is an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention, while the arc flame moves to the outside of the decelerating bulkhead, sequentially reduced by a flame reduction tube, an auxiliary flame reduction unit, and a reflex movement blocking unit. and a cross-sectional view showing a removed state.

Hereinafter, an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

1 is an overall system configuration diagram of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention, and FIG. 2 is an arc flame extinguishing device for an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention. 3 is a cross-sectional view of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention. 5 is a vertical cross-sectional view showing a state in which an auxiliary flame reducing unit is further provided in an arc chlorination unit of an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention, and FIG. 6 is an external perspective view of the present invention. In an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the, an enlarged cross-sectional view of a flame reducing pipe and an auxiliary flame reducing portion, FIG. 7 is an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention, 8 is an exploded perspective view of the bottom of FIG. 7, and FIG. 9 is an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention, an arc flame It is a cross-sectional view showing a state in which the flame reduction tube, the auxiliary flame reduction unit, and the reflex movement blocking unit are sequentially reduced and removed while moving to the outside of the deceleration bulkhead.

1 to 9, an arc flame extinguishing device for a gas insulated switchgear according to an embodiment of the present invention according to an embodiment of the present invention includes a first pipe 100, a second pipe 200, and It includes an arc chlorination unit 300.

The first pipe 100 is configured to guide the arc flame generated in the first arc flame generator 10 of the gas insulated switchgear upward. The first arc flame generator 10 includes a first bus 12 and a first disconnector 14 connected through a first pipe 100 .

The second pipe 200 is configured to guide the arc flame generated in the second arc flame generator 20 of the gas insulated switchgear upward. The second arc flame generator 20 includes a second bus 22 connected through a second pipe 200, a second disconnector 24, and a circuit breaker 26.

The first bus 12, the first disconnector 14 connected to the first pipe 100, the second bus 22 connected to the second pipe 200, the second disconnector 24 and the circuit breaker 26 A pressure relief valve 30 for inducing an arc flame may be provided at the outlet side.

The pressure relief valve 30 is configured to induce arc flames toward the first and second pipes 100 and 200.

The arc flame chlorination unit 300 is connected to both sides of the first pipe 100 and the second pipe 200, respectively, so that the arc flame generated in the first and second arc flame generators 10 and 20 is directed to the center. It is configured to induce anti-inflammation and to move to the side to anti-inflammatory again.

Since the arc chlorination unit 300 is mainly installed on the ceiling of the gas insulated switchgear, the space utilization is high, and the exposure of the arc flame to the outside can be minimized to prevent safety accidents in advance.

Since the arc flame chlorination unit 300 is disposed so that the first pipe 100 and the second pipe 200 face each other, the arc flame from the first arc flame generator 10 and the second arc flame generator 20 Although the on-arc flame may meet at the center, there are not many cases in which the arc flame generated from the first arc flame generating unit 10 and the arc flame generated from the first arc flame generating unit 10 are generated at the same time.

The arcing chlorination unit 300 is connected to the first pipe 100 and is connected to the first support cover 310 in which the first outer support 312 is formed and the second pipe 200, and the second The second support cover 320 on which the outer support 322 is formed, and the flame reduction cylinder connected to the inside of the first support cover 310 and the second support cover 320 and having a plurality of discharge holes 332 formed therein. 330 and a deceleration bulkhead installed in multiple stages inside the flame reducing vessel 330 to block the arc flame introduced through the first pipe 100 and the arc flame introduced through the second pipe 200, respectively ( 340), the first outer support part 312 and the second outer support part 322 are hooked on both sides to remove some of the flame discharged through the discharge hole 332 of the flame reducing cylinder 330 and smoke to the outside. It includes a flame removal unit 350 for discharging.

Referring to FIG. 4 , the first support cover 310 and the second support cover 320 are connected and fixed by the support cover connection part 360 for connecting and supporting the flame eliminator 350 to have an air passage.

The support cover connection part 360 is formed in a rectangular plate shape, extends from the first outer support part 312 of the first support cover 310, and connects a plurality to the second outer support part 322 of the second support cover 320. It is installed to have an air passage part in the flame removal part 350.

2 and 5, the discharge hole 332 of the flame reducing pipe 330 is formed gradually narrower from the entry side to the discharge side so that the outer diameter (b) is smaller than the inner diameter (a) The discharged arc flame may be formed to gradually decrease by hitting the inner slope.

A passage hole 342 is formed in the center of the reduction bulkhead 340, and some arc flames that explode pass through, and the remaining partial arc flame hits the inclined surface of the reduction bulkhead 340 and is guided to the side of the flame reducing vessel 330. It is guided to the discharge hole 332 and the flame removal unit 350.

The passage hole 342 is formed to become narrower as it goes from the entry-side reduction partition 340 to the upper center reduction partition 340 among the plurality of reduction partition walls 340 in the first and second pipes 100 and 200. to be characterized

The reduction bulkhead 340 is the number of reduction bulkheads 340 introduced from the first arc flame generating unit 10 through the first pipe 100 from the second arc flame generating unit 20 to the second pipe 200. The number of deceleration bulkheads 340 introduced through is configured to be larger. The reason is that the second arc flame generating unit 20 further includes the circuit breaker 26, so that the amount of arc generation increases.

The arc flame flowing from the first arc flame generating unit 10 through the first pipe 100 and the arc flame flowing from the second arc flame generating unit 20 through the second pipe 200 are strong in any direction. When the arc flame is introduced, it is possible to reduce the arc flame by utilizing not only the deceleration bulkhead 340 that blocks the corresponding arc flame but also the opposing deceleration bulkhead 340, so that the flame reduction efficiency can be further improved.

The deceleration bulkhead 340 increases the arc flame reducing power by gradually increasing the first inclination angle α, which is an acute angle, with respect to the flame reducing pipe 330 toward the center from the first pipe 100.

In addition, the reduction bulkhead 340 increases the arc flame reducing power by gradually increasing the second inclination angle β, which is an acute angle with respect to the flame reducing pipe 330, toward the center from the second pipe 200. The first inclination angle α and the second inclination angle β are inclined in opposite directions.

Referring to FIGS. 5, 7, and 9, the circumference of the flame reducing cylinder 330 is connected to the inner surfaces of the first and second support covers 310 and 320, and the arc discharged from the discharge hole 332. An auxiliary flame reduction unit 400 for reducing and changing the path of the flame is further provided.

The auxiliary flame reduction unit 400 is installed on the inner surface of the first and second support covers 310 and 320, and is formed in an elliptical cylinder or a cylinder corresponding to the shape of the flame reduction cylinder 330. It is provided in the barrel 410 and the auxiliary flame reducing cylinder 410, and is formed at a position that is offset from the discharge hole 332, so that the arc flame discharged from the discharge hole 332 is discharged from the inside of the auxiliary flame reducing cylinder 410. It includes a secondary discharge hole 420 that reduces while hitting the wall and then switches the path to be discharged to the flame removal unit 350.

Like the discharge hole 332, the auxiliary discharge hole 420 is formed gradually narrower from the entry side to the discharge side so that the outer diameter (d) is smaller than the inner diameter (c), so that the arc flame discharged is formed on the inner slope. It is formed by colliding and gradually decreasing.

The inner diameter (c) of the auxiliary discharge hole 420 is smaller than the inner diameter (a) of the discharge hole 332, and the outer diameter (d) of the auxiliary discharge hole 420 is the outer diameter (b) of the discharge hole 332. ) It is advantageous to form the auxiliary discharge hole 420 smaller than the discharge hole 332 in general so as to form smaller than ). The reason is to further weaken the arc flame discharged through the auxiliary discharge hole 420 since it has already been weakened in the discharge hole 332 .

At this time, the inner diameter (c) of the auxiliary discharge hole 420 is greater than the outer diameter (b) of the discharge hole 332.

The flame reduction tube 330 and the auxiliary flame reduction tube 410 are installed on the first support cover 310 and the second support cover 320 by the installation fixing part 500 .

The installation fixing part 500 is provided on the inner surface of the first and second support covers 310 and 320, and the inner fixing member 510 supporting both ends of the flame reducing cylinder 330, respectively, and the first. The outer fixing member 520 provided on the inner surface of the second support cover 310 or 320 and supporting both ends of the auxiliary flame reduction pipe 410, respectively, and the first and second support covers 310 and 320 ) Is provided on the inner surface of, and includes a central fixing member 530 for supporting between the flame reducing pipe 330 and the auxiliary flame reducing pipe 410.

The width of the central fixing member 530 is displaced from the discharge hole 332 after the arc flame passing through the discharge hole 332 of the flame reduction vessel 330 hits the inner wall surface of the auxiliary arc flame reduction vessel 410. The auxiliary discharge hole 420 has a size (interval) that allows smooth induction and guidance.

7 to 9, the reduction bulkhead 340 is provided with a reflection movement blocking unit 600 to reduce the reflection of the arc flame that hits the inclined surface of the reduction bulkhead 340 and move to the flame reducing vessel 330. do.

The reflection movement blocking unit 600 includes an installation member 610 installed in multiple stages on the inclined surface of the deceleration bulkhead 340, and a reflection angle θ set with respect to the inclined surface of the deceleration bulkhead 340 by being bent in the installation member 610. ), and includes a blocking member 620 that extinguishes the arc flame by repeating the process of returning to the speed reduction partition wall 340 by reflecting the arc flame reflected back to the speed reduction partition wall 340.

The reflection movement blocking part 600 is formed in an elliptical or cylindrical funnel shape, but in some cases, it may be formed separately in plurality for each set section of the deceleration partition wall 340 .

A plurality of reflection movement blocking parts 600 are formed at set intervals from the passage hole 342 toward the flame reduction cylinder 330.

The reflection angle θ of the blocking member 620 gradually increases from the passage hole 342 of the speed reduction partition wall 340 toward the discharge hole 332 of the flame reducing cylinder 330. This is to gradually collect and extinguish the arc flame.

Each length of the blocking member 620 is formed gradually longer at the end of the installation member 610 from the passage hole 342 of the speed reduction bulkhead 340 to the discharge hole 332 side of the flame reducing cylinder 330. . This is also to collect and dissipate the arc flame gradually.

The flame removal unit 350 has a first mesh network 352 having a mesh formed thereon, and a second mesh network 354 having a denser mesh than the second mesh network 352, and the second mesh network 354. It includes a third mesh network 356 having a denser mesh compared to the above.

The first mesh network 352 is hooked and mounted on the first and second inner support parts 314 and 324 protruding from the inside of the first and second support covers 310 and 320, respectively.

In this way, the arc flame passing through the discharge hole 332 or the auxiliary discharge hole 420 is partially captured by the first mesh network 352, and the arc flame passing through the first mesh network 352 is the first mesh network 352. ), and the arc flame passing through the second mesh network 354 is almost caught in the third mesh network 356, which is more dense than the second mesh network 354. The arc flame is completely extinguished (extinguished) and finally only the smoke is discharged to the outside.

Therefore, in the arc flame extinguishing device for gas insulated switchgear according to an embodiment of the present invention, the arc flame generated in the first and second arc flame generators of the gas insulated switchgear is passed through the first and second pipes to the upper side. , first extinguishing through the deceleration bulkhead, which gradually increases in angle from both sides to the center, extinguishing again through the discharge hole of the flame reduction tank, and completely extinguishing through multiple layers of flame removal parts to discharge only smoke, thereby increasing space utilization. It is possible to prevent a fire caused by a flame eruption while raising it.

In addition, the present invention further provides an auxiliary flame reducing pipe on the outside of the flame reducing pipe to form a pipe that gradually narrows from the inside to the outside and a auxiliary pipe that gradually narrows from the inside to the outside to offset each other, thereby reducing the arc flame. has the effect of significantly reducing its power by changing the path of In addition, the present invention has an effect of extinguishing a large amount of arc flame by repeating the process of returning and reflecting the arc flame reflected from the deceleration bulkhead to the deceleration bulkhead by providing a reflection movement blocker in the deceleration bulkhead.

The present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments. will understand

Therefore, the true technical protection scope of the present invention should be determined by the claims below.

10: arc flame generating unit 20: second arc flame generating unit
30: pressure relief valve 100: first pipe
200: second pipe 300: arc chlorination unit
310: first support cover 312: first outer support
314: first inner support 320: second support cover
322: second outer support 324: second inner support
330: flame reduction tube 332: discharge hole
340: reduction bulkhead 342: through hole
350: flame removal unit 352: first mesh network
354: second mesh network 356: third mesh network
360: support cover connection part 400: auxiliary flame reduction part
410; Auxiliary flame reduction pipe 420: auxiliary discharge hole
500: installation fixing part 510: inner fixing member
520: outer fixing member 530: central fixing member
600: reflection movement blocking unit 610: installation member
620: blocking member

Claims (12)

A first pipe for guiding the arc flame generated in the first arc flame generating unit of the gas insulated switchgear upward; A second pipe for guiding the arc flame generated in the second arc flame generator of the gas insulated switchgear upward; And an arc chlorination unit in which the first pipe and the second pipe are connected to both sides to extinguish the arc flame generated by the first and second arc flame generators by guiding them to the center and moving them to the side to extinguish them again. including;
The arcing chlorination unit may include a first support cover connected to the first pipe and having a first outer support portion formed thereon; a second support cover connected to the second pipe and having a second outer support portion; a flame reduction cylinder connected to the inside of the first support cover and the second support cover and having a plurality of discharge holes; a deceleration bulkhead which is installed in multiple stages inside the flame reducing cylinder and blocks arc flame introduced through the first pipe and arc flame introduced through the second pipe, respectively; And a flame eliminator installed on both sides of the first outer support and the second outer support to remove some of the flame discharged through the discharge hole of the flame reducing cylinder and discharge smoke to the outside; includes,
An arc flame extinguishing device for a gas insulated switchgear, characterized in that the reduction bulkhead is provided with a reflection movement blocking part to reduce the reflection of the arc flame striking the inclined surface of the reduction bulkhead and moving to the flame reducing chamber.
According to claim 1,
The first arc flame generator includes a first bus and a first isolator connected through the first pipe,
The second arc flame generating unit arc flame extinguishing device for a gas insulated switchgear, characterized in that it comprises a second bus, a second disconnector and a circuit breaker connected through the second pipe.
According to claim 2,
A pressure relief valve for inducing an arc flame is provided at the outlet side of the first busbar, the first disconnector connected to the first pipe, the first busbar connected to the second pipe, the second disconnector, and the circuit breaker. Arc flame extinguishing device for gas insulated switchgear.
delete According to claim 1,
The discharge hole is formed gradually narrower from the entry side to the discharge side so that the outer diameter (b) is smaller than the inner diameter (a), so that the discharged arc flame hits the inner slope and is gradually reduced. Characterized in that Arc flame extinguishing device for gas insulated switchgear.
According to claim 1,
A passage hole is formed in the center of the reduction bulkhead to allow some arc flames to explode, and the remaining arc flames collide with the inclined surface of the reduction bulkhead and are guided to the side to the discharge hole of the flame reducing cylinder and the flame removal unit. being guided,
The passage hole is arc flame extinguishing device for a gas insulated switchgear, characterized in that formed gradually narrower from the speed reduction partition on the entry side of the plurality of speed reduction partitions in the first and second pipes to the speed reduction partition on the upper center.
According to claim 1,
The reduction bulkhead increases the reducing power of the arc flame by gradually increasing a first inclination angle α, which is an acute angle with respect to the flame reducing pipe, from the first pipe to the center,
The reduction bulkhead increases the reducing power of the arc flame by gradually increasing the second inclination angle β, which is an acute angle with respect to the flame reducing pipe, toward the center from the second pipe,
The first inclination angle (α) and the second inclination angle (β) arc flame extinguishing device for gas insulated switchgear, characterized in that formed inclined in the opposite direction.
According to claim 1,
An auxiliary flame reduction unit connected to the inner surfaces of the first and second support covers around the flame reduction tube and reducing by changing and blocking the path of the arc flame discharged from the discharge hole is further provided. Arc flame extinguishing device for gas insulated switchgear.
According to claim 8,
The auxiliary flame reducing unit,
an auxiliary flame reducing tube installed on inner surfaces of the first and second support covers and formed in an elliptical or cylindrical shape equal to the shape of the flame reducing tube; and
It is provided in the auxiliary flame reducing cylinder, and is formed at a position opposite to the discharge hole, so that the arc flame discharged from the discharge hole is reduced while colliding with the inner wall of the auxiliary flame reducing cylinder, and then the path is changed to reduce the flame retardation. Auxiliary discharge hole to be discharged by rejection;
Arc flame extinguishing device for gas insulated switchgear, characterized in that it comprises.
delete According to claim 1,
The reflection movement blocking unit,
Installation members installed in multiple stages on the inclined surface of the speed reduction bulkhead; and
It is bent in the installation member and formed at a set reflection angle (θ) with respect to the inclined surface of the reduction bulkhead, and the arc flame reflected by hitting the reduction bulkhead is reflected again to return to the reduction bulkhead. By repeating the process of returning the arc flame a blocking member that extinguishes;
Arc flame extinguishing device for gas insulated switchgear, characterized in that it comprises.
According to claim 1,
The flame eliminator,
A first mesh network having a loose mesh;
a second mesh network having a denser mesh than the first mesh network; and
An arc flame extinguishing device for a gas insulated switchgear, characterized in that it comprises a third mesh network having a denser mesh than the second mesh network.

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