KR101063272B1 - Moving part of breaker for gas insulated switchgear - Google Patents

Abstract

The present invention relates to a gas insulated switchgear (GIS), and more particularly, to minimize the loss of the movable chamber by the hot gas generated when the breaker is blocked, and to improve the insulation strength The movable part for a gas insulated switchgear of a form is provided.

To this end, the present invention is installed in the enclosure while the front of the movable arc contactor is coupled, the rear is connected to the insulating rod is installed, the rear side circumferential surface of the movable shaft formed through the first exhaust hole; An inner side of which the movable shaft is movably installed, a rear side portion of which is fixed to an insulating support tube through which the insulating rod penetrates, and a movable side chamber having a second exhaust hole penetrated in a circumferential surface thereof; A main shield installed to surround a circumference of the movable side chamber and the popper cylinder to block hot gas exhausted through the second exhaust hole of the movable side chamber from being directly injected into the inner wall surface of the enclosure; And an auxiliary shield provided between the movable side chamber and the insulating support cylinder to guide the hot gas exhausted backward through the second exhaust hole of the movable side chamber to flow forward. A movable part of a breaker for an insulated switchgear is provided.

Gas Insulated Switchgear, Breaker, Movable, Main Shield, Auxiliary Shield

Description

Movable part of gas insulated switchgear {Gas Insulation switchgear}

The present invention relates to a gas insulated switchgear (GIS), and more particularly, to minimize the loss of the movable chamber by hot gas generated when the breaker is blocked, and to improve the insulation strength. A new type of gas insulated switchgear is provided.

In general, Gas Insulation Switchgear (GIS) uses insulation gas (SF ₆ ) with excellent insulation performance and arc extinguishing function in a metal sealed container (tank) as an insulating medium to accommodate conductors and various protective devices. It is a water substation facility with improved circuit breakers, circuit breakers, disconnecting switches, and earthing switches.

Among the components of the gas insulated switchgear, the movable part 10 constituting the circuit breaker as shown in FIG. 1 is connected to the fixed part 20 by a selective operation and serves to conduct current.

At this time, when the connection between the movable portion 10 and the fixed portion 20 is released (when the breaking operation of the breaker is in progress), the movable arc contact 11a of the movable portion 10 and the fixed arc contact of the fixed portion An arc is generated between the 21 and the arc extinguishing gas SF ₆ compressed by the piston 15 in the popper cylinder 14 is injected along the nozzle 16 to the generating site of the arc. Thus the arc is extinguished.

In addition, in the arc extinguishing process, the extinguishing gas is converted into hot gas at a high temperature, and a part of the converted hot gas flows to the fixed part and the other part flows to the movable part 10.

At this time, the hot gas flowing into the movable part 10 passes through the hollow portion of the movable shaft 11 installed in the popper cylinder 14 and moves through the exhaust hole 11c formed at the rear side of the movable shaft 11. It is discharged to the exhaust hole 12a of (12).

However, when the movable side chamber 12 of the movable part 10 of the circuit breaker for gas insulated switchgear according to the related art as described above is made of aluminum having a low melting point, the exhaust hole of the movable shaft 11 ( In the process of directly discharging the hot gas having passed through 11c) toward the exhaust hole 12a of the movable side chamber 12, melting of the portion where the exhaust hole 12a was formed frequently occurred.

In particular, since the molten waste generated as described above is discharged through the exhaust hole 12a together with the hot gas, there is a problem that a substantial decrease in the dielectric strength is caused.

In addition, a portion of the hot gas flows into the internal space of the insulating support cylinder 17 through the communication port 12b of the movable side chamber 12 for the operation of the insulating rod 11b, thereby causing a decrease in the dielectric strength. It became.

The present invention has been made to solve the various problems of the prior art described above, the object of the present invention is to minimize the loss of the movable chamber by hot gas, and to improve the dielectric strength A movable part for a gas insulated switchgear of the type is provided.

The movable part for the gas insulated switchgear of the present invention for achieving the above object is formed as an empty pipe while being installed in the enclosure, the movable arc contactor is coupled to the front side, and the insulating rod is connected to the rear side, and the rear side is installed. A movable shaft having a first exhaust hole through the circumferential surface thereof; The inside has an exhaust space of the hot gas discharged to the first exhaust hole while the movable shaft is installed to be movable, the rear side portion is fixed to the insulating support cylinder through which the insulating rod penetrates and the second exhaust hole on the circumferential surface A movable side chamber formed therethrough; A main shield installed to surround a circumference of the movable side chamber and the popper cylinder to block hot gas exhausted through the second exhaust hole of the movable side chamber from being directly injected into the inner wall surface of the enclosure; And an auxiliary shield provided between the movable side chamber and the insulating support cylinder to guide the hot gas exhausted backward through the second exhaust hole of the movable side chamber to the front.

Here, the auxiliary shield is formed between the fixed end fixed between the movable side chamber and the insulated support cylinder while forming the inner peripheral portion, and the hot gas exhausted backward through the second exhaust hole of the movable side chamber forming the outer peripheral portion It characterized in that it comprises a guide for guiding to flow forward.

At this time, the guide end of the auxiliary shield is characterized in that it is formed to be bent round to the front again after protruding further to the rear than the contact portion between the movable side chamber and the insulating support cylinder.

In addition, the rear portion of the hot gas discharge portion of each portion of the main shield is characterized in that the conduit is formed so as to be located in the inner central portion of the space formed by the guide end of the auxiliary shield.

In addition, the end of the guide end constituting the auxiliary shield is characterized in that it is bent rounded toward the outer peripheral surface of the main shield.

As described above, the movable part of the breaker for a gas insulated switchgear according to the present invention is prevented from directly exhausting the hot gas generated by the extinguishing action during the open operation of the breaker toward the enclosure by the main shield and the auxiliary shield, thereby insulating performance. It has the effect that the fall of can be reduced.

In particular, the auxiliary shield is configured to increase the flow distance of the hot gas and then toward the outer circumferential surface of the main shield, thereby reducing the temperature and flow rate of the hot gas, thereby minimizing the degradation of the insulation performance. .

In addition, the movable portion of the circuit breaker for gas insulated switchgear according to the present invention is formed by rounding the end portion of the auxiliary shield inwardly to prevent melting of the portion and to prevent the occurrence of sparks due to the corner portion. Has an effect.

Hereinafter, specific embodiments for the implementation of the present invention will be described with reference to FIGS. 2 and 3.

First, as shown in FIGS. 2 and 3, the movable part 100 of the circuit breaker for gas insulated switchgear according to the preferred embodiment of the present invention is installed to be opposed to the stator in the enclosure 1. ), A movable side chamber 120, a main shield 130, and an auxiliary shield 150.

This will be described in more detail below for each configuration.

First, the movable shaft 110 will be described.

The movable shaft 110 supports the popper cylinder 140 in the movable part 100 constituting the circuit breaker for the gas insulated switchgear, and discharges the hot gas generated during the breaking operation of the circuit breaker.

As described above, the movable shaft 110 is formed of an empty pipe, and a movable arc contact 111 is coupled to the front surface thereof, and an insulating rod 112 is connected to the rear thereof, and a plurality of agents are provided on the rear circumferential surface thereof. The first exhaust hole 113 is formed through.

In addition, a circumference of the movable shaft 110 is provided with a popper cylinder 140 forming a compression space in which the arc extinguishing gas SF ₆ is compressed. At this time, the front portion of the popper cylinder 140 is fixed around the front side of the movable shaft 110, the rear portion of the popper cylinder 140 is formed to be open.

Next, the movable side chamber 120 has an exhaust space through which the hot gas passing through the first exhaust hole 113 of the movable shaft 110 is exhausted. The second exhaust hole 121 is formed through.

At this time, the front side of the movable side chamber 120 is provided with a piston 123 for compressing the arc extinguishing gas (SF ₆ ) in the compression space between the paper cylinder 140 and the movable shaft 110. The compressed extinguishing gas is injected toward the arc by the nozzle 160 mounted in front of the popper cylinder 140.

In addition, an insulating support cylinder 170 is coupled to the rear side of the movable side chamber 120, and a through hole 122 through which the insulating rod 112 penetrates a rear portion of the movable side chamber 120. Is formed.

Next, the main shield 130 is a series of configurations to block the hot gas exhausted through the second exhaust hole 121 of the movable side chamber 120 is injected directly to the inner wall surface of the enclosure 1, It is installed to surround the circumference of the movable side chamber 120 and the popper cylinder 140.

In this case, a third exhaust hole 131 is formed in the rear side portion of the main shield 130 to exhaust the hot gas passing through the second exhaust hole 121 into the space inside the enclosure.

Next, the auxiliary shield 150 is provided between the movable side chamber 120 and the insulating support cylinder 170, and the second exhaust hole 121 and the main of the movable side chamber 120 are provided. While passing sequentially through the third exhaust hole 131 of the shield 130 serves to block the hot gas discharged directly into the enclosure (1) flows directly toward the enclosure (1).

In particular, the auxiliary shield 150 according to the embodiment of the present invention suggests that the insulation strength can be further improved by directing the flow of the hot gas to the front.

The auxiliary shield 150 according to an embodiment of the present invention for this purpose is configured to include a fixed end 151 and a guide end 152.

Here, the fixed end 151 is configured to form an inner circumferential portion of the auxiliary shield 150 and is fixedly installed between the movable side chamber 120 and the insulating support cylinder 170.

In addition, the guide end 152 constitutes an outer circumferential portion of the auxiliary shield 150 so that the hot gas exhausted backward through the second exhaust hole 121 of the movable side chamber 120 flows forward. It serves to guide so as to, and protrudes more rearward than the contact between the movable side chamber 120 and the insulating support cylinder 170 is formed to be bent round to face forward again.

The structure of the guide end 152 is that the end portion of the guide end 152 is deteriorated under direct influence of the hot gas, so that the insulation strength can be lowered, so that the end portion of the guide end 152 is the hot gas. In order to minimize the fall of insulation strength by not being located in the position opposite to the discharge direction, the temperature and flow rate of the hot gas are decreased by increasing the length of the flow path, thereby increasing the density of the hot gas and reducing the degradation of the insulation performance. It is to be done.

Particularly, in the rear side portion in which the third exhaust hole 131 through which the hot gas is discharged is formed among the respective portions of the main shield 130, the inner central portion of the space formed by the guide end 152 of the auxiliary shield 150 is formed. A shaft pipe portion 132 is formed to be reduced in the conduit to be located in.

The shaft tube 132 is a configuration for minimizing the height of the protrusion of the guide end 152 constituting the auxiliary shield 150 to prevent the breakdown of the insulation with the enclosure, while allowing a smooth flow of hot gas. . That is, the larger the radius of curvature of the guide end 152 is advantageous for the smooth flow guidance of hot gas, but in this case there is a risk of insulation breakdown as the distance between the enclosure 1 and the guide end 152 is closer. Through the configuration of the shaft tube 132, the radius of curvature of the guide end 152 while minimizing the radius of curvature of the hot gas flowing toward the guide end 152 and the guide end 152 of the enclosure ( 1) The flow of hot gas discharged to the inside can be separated from each other so that the flow of hot gas can be made smoothly.

In addition, the end of the guide end 152 constituting the auxiliary shield 150 is bent roundly toward the outer circumferential surface of the main shield 130, so that the end portion of the guide end 152 acts as a lightning rod, In addition to preventing problems that may occur, hot gas flows along the outer circumferential surface of the main shield 130 to prevent direct injection into the enclosure 1.

Hereinafter, the operation of the movable part 100 of the circuit breaker for gas insulated switchgear according to the embodiment of the present invention configured as described above will be described.

First, when the circuit breaker performs an open operation as shown in FIG. 3 attached to the circuit breaker constituting a gas insulated switchgear as shown in FIG. As the movable part 100 is retracted by the retracting operation, the movable arc contact 111 of the movable part 100 is separated from the fixed arc contact 211 of the fixed part 200.

When this open operation is performed, an arc is generated between the movable arc contact 111 and the fixed arc contact 211, and the extinguishing arc extinguishing gas, ie, SF ₆ gas, is compressed into the breaker. It is operated to extinguish the arc while spraying through 160.

The SF ₆ gas is changed into hot gas of high temperature and high pressure while meeting the arc, and the hot gas is moved through the opened front surface of the movable arc contact 111 constituting the movable part 100. After passing through the inside of the contact 111 is introduced into the movable shaft (110).

Then, the hot gas flowing in the internal space of the movable shaft 110 as described above is inside the movable side chamber 120 through each of the first exhaust holes 113 formed in the rear circumferential surface in the movable shaft 110. In addition to being discharged into the space is discharged to the outside through each of the second exhaust holes 121 formed in the rear peripheral surface of the movable side chamber 120.

In this case, considering that the main shield 130 is installed at the outer circumference of the movable side chamber 120, the hot gas discharged to the outside through each of the second exhaust holes 121 is the main shield 130. The third exhaust hole 131 formed in the rear side portion of the main shield 130 after receiving the guidance of the main shield 130 after the flow is not immediately discharged toward the enclosure 1 is blocked Through it is discharged into the space in the enclosure (1).

However, since the auxiliary shield 150 is provided at the portion where the third exhaust hole 131 is formed, the hot gas discharged through the third exhaust hole 131 guides the flow by the auxiliary shield 150. Will receive.

In particular, because the guide end 152 of the auxiliary shield 150 is formed to be bent toward the front after being protruded toward the rear more than the position of the third exhaust hole 131 due to the guide end 152 As the flow distance of the hot gas is increased by the length to be converted, the flow rate of the hot gas is lowered and the temperature is reduced by that much. As a result, the density of the hot gas is increased, thereby reducing the insulation performance.

In addition, when considering that the shaft portion 132 of the main shield 130 is located in the inner portion of the guide end 152, the flow of the hot gas due to the shaft portion 132 is the guide end 152 In addition, the hot gas flowing under the guidance of the guide end 152 and back flow into the main shield 130 is prevented.

In addition, as the end portion of the guide end 152 constituting the auxiliary shield 150 is bent roundly toward the movable side chamber 120, spark generation in the portion is prevented.

As a result, the hot gas discharged into the enclosure while being guided by the auxiliary shield 150 by the above-described series of processes is gradually reduced in temperature by a long flow, and the flow rate is also drastically reduced, thereby reducing the degradation of insulation performance. Will be.

As a result, the circuit breaker is opened by the above-described series of processes.

1 is a schematic internal state diagram illustrating an internal structure of a conventional gas insulated switchgear breaker

Figure 2 is a schematic configuration diagram showing a state of blocking of the movable part structure of the circuit breaker for a gas insulated switchgear according to an embodiment of the present invention.

3 is a schematic configuration diagram illustrating an open state of a movable part structure of a circuit breaker for a gas insulated switchgear according to an embodiment of the present invention;

Explanation of symbols for main parts of the drawings

100. Movable part 110. Movable shaft

111. Movable arc contact 112. Insulated rod

113. First exhaust hole 120. Movable side chamber

121. Second exhaust hole 122. Through hole

130. Main shield 131. Third exhaust hole

132. Shaft pipe section 140. Popper cylinder

150. Auxiliary shield 151. Fixed end

152. Guide 160. Nozzle

170. Insulated support 200. Fixed part

211. Fixed Arc Contactors

Claims (5)

It is installed inside the enclosure and is formed as an empty pipe. At the periphery, a popper cylinder is formed to form a compression space for compressing SOHO gas (SF ₆ ). A movable shaft having a first exhaust hole penetrated at a rear circumferential surface thereof; The inside has an exhaust space of the hot gas discharged to the first exhaust hole while the movable shaft is installed to be movable, the rear side portion is fixed to the insulating support cylinder through which the insulating rod penetrates and the second exhaust hole on the circumferential surface A movable side chamber formed therethrough; A main shield installed to surround a circumference of the movable side chamber and the popper cylinder to block hot gas exhausted through the second exhaust hole of the movable side chamber from being directly injected into the inner wall surface of the enclosure; And, Guide to guide the hot gas exhausted to the rear through the second exhaust hole of the movable side chamber to form a fixed end and an outer peripheral portion that is fixed between the movable side chamber and the insulating support cylinder while forming an inner peripheral portion Comprising a stage, the end of the guide end is bent round toward the outer circumferential surface of the main shield to prevent the occurrence of sparks in the corresponding portion and the hot gas can flow along the outer circumferential surface of the main shield Auxiliary shield for: Movable part of the circuit breaker for gas insulated switchgear, characterized in that it comprises a. delete The method of claim 1, The guide end of the auxiliary shield Movable part of the circuit breaker for gas insulated switchgear, characterized in that is formed to be protruded further rearward than the contact portion between the movable side chamber and the insulated support cylinder and then bent rounded forward again. The method according to claim 1 or 3, The rear portion of the main shield of the hot gas is discharged portion of the main shield is a movable portion of the breaker for gas insulated switchgear, characterized in that the conduit is formed so as to be located in the inner central portion of the space formed by the guide end of the auxiliary shield. delete

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