KR101400589B1 - Gas insulated switchgear - Google Patents

Abstract

The present invention relates to a gas insulation switch. The gas insulation switch, which disconnects a fixture arc member of a fixture part from a moving arc member of a moving part when a breaker including the fixture part and the moving part performs a breaking operation, includes a spray nozzle for spraying hybrid type gas stored in a hybrid gas storage unit in order to cancel arc occurring as the fixture arc member is separated from the moving arc member; a hot gas moving tube through which hot gas, which is generated when the arc is canceled due to the hybrid type gas sprayed from the spray nozzle, passes; a disk formed at one end of the hot gas moving tube to prevent the hot gas from being introduced through the hot gas moving tube to control the flow of the hot gas; a vibration tube used to supply cooling gas to the hybrid gas storage unit; and a plurality of inflow holes for allowing the cooling gas to inflow in order to cool the hot gas. According to the gas insulation switch, the cooling gas is introduced into the moving part to prevent restriking resulting from the degradation of an insulation recovery characteristic, and to block fault current, so that the breaking performance of the breaker can be improved.

Description

[0001] GAS INSULATED SWITCHGEAR [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas insulated switchgear, and more particularly, to a gas insulated switchgear for introducing a cold gas to improve the breaking performance of a circuit breaker used in a gas insulated switchgear.

In general, the gas insulated switchgear is used to connect or disconnect the system circuit of the transmission line and the substation line, and can completely limit the fault current at the time of abnormal voltage generation, ground fault and line short, It plays a very important role in restraining the accident of a car and a third. Most of the gas insulated switchgear is the Puffer soho system. In some of the switching devices, a vacuum soffing method is also used, but this is mainly applied to a small capacity class. In recent years, a composite soffring method in which a thermal expansion method and a purging method are mixed has been applied, and most of the conventional high voltage gas insulating large capacity gas insulating switching devices Is a purging method that blows heat gas to extinguish an arc.

Korean Patent Laid-Open Publication No. 10-2006-0116567 discloses a vacuum insulated switchgear for discharging hot gas through a separate outlet to simultaneously maintain the insulation characteristic of insulating gas during shutoff operation and at the same time, Side fixed contact (3) is formed at the distal end of the fixed-conductor-side conductor (1), and the movable-portion-side fixed conductor (20) is formed so as to face the fixed contact- In a high voltage arc extinguishing system in which a fixed portion side arc contact 2 is formed inside a center portion of a movable contact main contact 15 and a movable portion arc contact 10 is formed at an end portion of a movable rod 13 formed at a central portion of the movable portion main contact 15 , And a heat gas discharge / interruption part (4) for preventing discharge and re-inflow of heat gas caused by an arc generated between the stationary-side arc contact (2) and the movable arc contact (10) And the heat gas discharge / cut-off portion 4 is provided with a heat gas discharge port 6. The heat gas discharge / According to the disclosed technology, a high-voltage arc extinguisher having a suction ash part prevents recollection due to deterioration of the insulation recovery property and secures the breaking performance.

However, when the gas insulated switchgear is shut off, it is required to perform two shutdowns within 0.3 seconds. In the first cutoff of the circuit breaker, the gas insulated switchgear is shut off with the presence of the cold gas, The inside of the gas insulated switchgear is in a state of high temperature and high pressure by the generated heat gas. At this time, if the second interrupter of the circuit breaker is interrupted, the interrupting performance of the gas insulated switchgear suddenly drops, making it difficult to interrupt the fault current.

Korean Patent Publication No. 10-2006-0116567

An embodiment of the present invention is to provide a gas insulated switchgear for introducing a cold gas into a movable part to lower the temperature of a generated heat gas generated by an arc generated in a circuit breaker.

Among the embodiments, the gas insulated switchgear is a gas insulated switchgear in which a fixed arc member of a fixed portion and a movable arc member of a movable portion are separated from each other when a circuit breaker comprising a fixed portion and a movable portion is shut off, A nozzle for spraying a SOHO gas in a SOHO gas storage unit for canceling an arc generated due to the separation of the arc members, a heat gas flow pipe for passing a heat gas generated when the arc is canceled by the SOHO gas injected from the injection nozzle, A disk formed at one end of the hot gas moving tube for guiding the flow of the hot gas flowing through the hot gas moving tube, a vacuum tube for supplying the cool gas to the small gas storage section, And a plurality of inflow holes for introducing the cold gas.

In one embodiment, the hot gas moving tube is formed at a position where the discharge hole position of the hot gas moving tube discharges thermal gas after passing through the vacuum tube to prevent mixing of the hot gas and the hot gas introduced from the inlet hole .

In one embodiment, the inlet of the inflow hole may be inclined at a certain angle so that the cold gas supplied from the cold gas tank smoothly flows into the inflow hole.

The gas insulated switchgear according to an embodiment of the present invention can prevent recollection due to deterioration of insulation recovery characteristics by introducing the cool gas into the movable portion and cut off the fault current to improve the breaking performance of the breaker.

1 is a cross-sectional view illustrating a gas insulated switchgear according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view illustrating a flow of a thermal gas when an arc is generated in the gas insulated switchgear shown in FIG. 1; FIG.
FIG. 3 is a view for explaining a state when all of the thermal gas shown in FIG. 2 has escaped. FIG.
4 is a cross-sectional view for explaining the inflow of the cold gas into the gas insulated switchgear shown in Fig.
Fig. 5 is a view for explaining an inflow hole of the gas-insulated switchgear shown in Fig. 1. Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

FIG. 1 is a cross-sectional view illustrating a gas insulated switchgear according to an embodiment of the present invention, FIG. 2 is a cross-sectional view illustrating a flow of a heat gas when an arc is generated in the gas insulated switchgear of FIG. 1, Fig. 4 is a cross-sectional view for explaining the inflow of the cool gas into the gas insulated switchgear of Fig. 1; Fig.

1, 2, 3, and 4, the gas insulated switchgear 100 includes a fixed portion 110 fixed to a circuit breaker of the gas insulated switchgear 100, The fixed arc member 111 of the fixed portion 110 and the movable arc member 121 of the movable portion 120 are separated when the breaker comprising the movable portion 120 capable of linearly moving left and right in the circuit breaker is shut off.

The gas insulated switchgear 100 includes an injection nozzle 122, a heat gas transfer pipe 123, a disk 124, and an inlet hole 125.

The injection nozzle 122 is formed at one end of the movable part 120 so as to be symmetrical with respect to the fixed arc member 111. When the movable part 120 linearly moves left and right, Gas in the soot gas reservoir 127 to cancel the arc 200 caused by the separation between the fixed arc member 111 and the movable arc member 121 when the circuit breaker is shut off, 300).

The movable arc member 111 and the movable arc member 121 are separated from each other and the SOG gas 300 in the SOG gas storage unit 127 is separated from the SOG gas storage unit 127 Through the hole 127-1 between the fixed arc member 111 and the injection nozzle 122 and through the gap 122-1 formed between the fixed arc member 111 and the injection nozzle 122, So that the SOH gas 300 can be sprayed.

The hot gas moving pipe 123 is formed as a pipe or a tube at one end of the movable arc member 121. The hot gas moving pipe 123 is formed of a hot gas generated when the arc 200 is canceled by the soot gas 300 injected from the injection nozzle 122 (400) may pass. At this time, a part of the thermal gas 400 may flow to the fixing part 110, and a part of the thermal gas 400 may flow out of the disk 124 through the thermal gas moving pipe 123.

The hot gas 400 moved through the hot gas moving pipe 123 can be discharged through the discharge port 123-1 and the disk 124 through the disk 124. [

The hot gas moving pipe 123 can prevent the cold gas 510 flowing in the inlet hole 125 and the hot gas 400 in the hot gas moving pipe 123 from being mixed with each other.

The disk 124 is formed with two bars (for example, conical or plate shape) at one end of the hot gas moving tube 123 so as to be symmetrical with respect to the hot gas moving tube 123, It is possible to guide the flow of the thermal gas 400 that has entered through. At this time, the thermal gas 400 may be collected inside the disk 124 through the discharge hole 123-1 formed between the thermal gas moving pipe 123 and the disk 124. [

Compared with the conventional method in which the thermal gas 400 introduced through the thermal gas transfer pipe 123 fills the vacuum tube 128 and the thermal gas 400 flows into the SOG gas storage unit 127, 124 prevent the introduction of the thermal gas 400 into the SOH gas storage unit 127 by guiding the thermal gas 400 and allow the cool gas 510 to flow outside the thermal gas transfer tube 123, The blocking performance can be enhanced.

The heated gas 400 whose flow is controlled by the guide of the disk 124 can be completely discharged to the discharge port 129 formed on both sides of the movable part 120.

The inlet hole 125 is formed between the disk 124 and the vacuum tube 128 and allows the cold gas 510 to flow in order to cool the thermal gas 400 in the disk 124. The inlet 126 of the inlet hole 125 is inclined at a predetermined angle so that the cold gas 510 supplied from the cold gas tank 500 can smoothly enter the inlet 125. [ .

The inlet hole 125 may be formed of a plurality of holes surrounding the movable portion 120 as shown in FIG. 4 so that the cold gas 510 can be quickly introduced into the vacuum tube 128 through the inlet hole 125. At this time, the plurality of inflow holes 125 are formed at regular intervals and may have a circular or square shape.

The gas insulated switchgear 100 may further include a vacuum tube 128.

The vacuum tube 128 is formed outside the heat gas moving tube 123 and may be formed between the disk 124 and the SOH gas storage 127. The vacuum tube 128 is expanded in a short time when the movable part 120 is closed toward the fixed part 110 after all of the thermal gas 400 has exited and becomes an instantaneous vacuum state. The cold gas 510 can be introduced into the inflow hole 125.

The cool gas 510 flowing into the inlet hole 125 and passing through the vacuum tube 128 is supplied to the arc 200 and the arc 200 generated when the stationary arc member 111 and the movable arc member 121 are separated from each other. It is possible to cool the thermal gas 400 generated due to the contact between the SOFC 300 and the SOFC 300 injected to remove the SOFC 300.

In one embodiment, the gas insulated switchgear 100 may further include a cold gas tank 500.

The cooling gas tank 500 stores the cooling gas 510 to be introduced into the inlet hole 125 and may supply the cooling gas 510 to the inlet hole 125 to cool the thermal gas 400 .

Hereinafter, the operation of the gas insulated switchgear according to an embodiment of the present invention will be described in detail.

The gas insulated switchgear 100 cuts the circuit breaker twice. When the circuit breaker is firstly cut off, the fixed arc member 111 of the fixing part 110 and the movable arc member 121 of the movable part 120 The arc 200 can be generated while being separated. At this time, in order to cancel the arc 200, the SOH gas 300 in the SOH gas storage part 127 is supplied through the hole 127-1 between the SOH gas storage part 127 and the injection nozzle 122 So that the injection nozzle 122 can inject the SOH gas 300 through the gap 122-1 formed between the fixed arc member 111 and the injection nozzle 122. [

The thermal gas 400 may be generated due to the contact between the SOG gas 300 and the arc 200 and the thermal gas 400 may move to the fixing unit 110 and the thermal gas transfer pipe 123.

The heat gas 400 collected in the fixing unit 110 can be completely removed from the discharge port 112 formed at both sides of the fixing unit 110 and can be removed by a pipe or a tube at one end of the movable arc member 121 The thermal gas 400 moved through the formed hot gas moving pipe 123 is moved between the hot gas moving pipe 123 and the disk 124 by the disk 124 formed on one side of the hot gas moving pipe 123 And may be collected inside the disc 124 through the formed discharge hole 123-1.

At this time, the hot gas moving pipe 123 can prevent the hot gas 400 in the hot gas moving pipe 123 from being mixed with the cold gas 510 flowing in the inlet hole 125.

The heated gas 400 whose flow is controlled by the guide of the disk 124 can be completely discharged to the discharge port 129 formed on both sides of the movable part 120.

When all of the thermal gas 400 generated at the time of the first breaking of the breaker comes out, the cold gas 510 can be introduced through the inflow hole 125 in the cold gas tank 500. The inflow hole 125 is formed between the disc 124 and the vacuum tube 128 so that the cold gas 510 supplied from the cold gas tank 500 can flow smoothly into the inflow hole 125 The inlet 126 of the hole 125 may be inclined at an angle.

The inlet hole 125 may be formed of a plurality of holes surrounding the movable portion 120 to allow the cold gas 510 to be quickly introduced into the vacuum tube 128 through the inlet hole 125, (125) are formed at regular intervals, and may have a shape such as a circle or a square.

The cold gas 510 flowing through the inlet hole 125 is expanded in a short time when the movable part 120 is closed toward the fixed part 110 after the thermal gas 400 is completely exhausted, The vacuum tube 128 may be formed outside the thermal gas moving tube 123 and formed in the middle of the disk 124 and the SOH gas storage unit 127. In this case,

When the breaker is shut down for a second time, the arc 200 is generated due to the separation of the fixed arc member 111 and the movable arc member 121, The injection nozzle 122 can inject the SOH gas 300 in the injection nozzle 122. [

The thermal gas 400 is generated due to the contact between the SOG gas 300 and the arc 200 and the thermal gas 400 can move to the fixing unit 110 and the thermal gas transfer pipe 123. However, The performance of the circuit breaker can be improved by cooling the thermal gas 400 through the cold gas 510 passing through the vacuum tube 128 located outside the hot gas moving tube 123 when passing through the hot gas moving tube 123 have.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the present invention as defined by the following claims It can be understood that

100: Gas insulated switchgear
110: fixing part 111: stationary arc member
120: moving part 121: movable arc member
122: injection nozzle
123: Heat gas moving pipe 124: Disk
125: inlet hole 128: vacuum tube
200: arc
300: Soho gas
400: Thermal gas
500: Cold gas tank 510: Cold gas

Claims (3)

A gas insulated switchgear comprising a fixed arc member of a fixed portion and a movable arc member of a movable portion separated from each other when a circuit breaker comprising a fixed portion and a movable portion is cut off,
A spray nozzle for spraying SO.sub.GAS in the SO.sub.G storage to offset an arc generated by separation between the fixed arc member and the movable arc member;
A hot gas moving pipe formed at one end of the movable arc member in the shape of a pipe or a tube, through which a thermal gas generated when the arc is canceled by the SO gas flows;
A vacuum tube formed on the outside of the hot gas moving tube to supply the cool gas to the SOG storage section when the cool gas flows from the cold gas tank;
The heat gas flow pipe is symmetric with respect to the heat gas moving pipe and is formed at one end of the heat gas moving pipe to guide the flow of the heat gas to prevent the heat gas flowing through the heat gas moving pipe from flowing into the vacuum pipe. ; And
And a plurality of inflow holes through which the cooling gas for cooling the thermal gas flows.
The heat exchanger according to claim 1,
Wherein a position of the discharge hole of the hot gas moving tube is formed at a position for discharging a thermal gas after passing through the vacuum tube to prevent mixing of the hot gas and the cold gas introduced from the inlet hole.
3. The apparatus of claim 2, wherein the inlet
Wherein the inlet of the inflow hole is inclined at a predetermined angle so that the cold gas supplied from the cold gas tank can smoothly enter the inflow hole.

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