KR20150134206A - Gas circuit breaker for gas insulated switchgear - Google Patents

Abstract

The present invention relates to a gas circuit breaker of a gas insulated switchgear. In the present invention, the inner space 14 of the fixed-side conductor body 12 provided inside the stationary-side arc electrode 20 is communicated with the outside through the exhaust hole 40. The position of the exhaust hole 40 is the opposite end of the end portion of the inner space 14 through which the nozzle 30 enters and exits. This is to allow the gas from the nozzle 30 to go straight to the exhaust hole 40. A partition wall 38 communicating with the communication hole 39 is formed adjacent to the exhaust hole 40 while defining the internal space 14. The partition wall 38 allows the gas flowing at a relatively high speed to be delayed in the interior of the internal space 14 at the time of blocking the large current so that the temperature of the gas can be sufficiently adjusted. The partition wall 38 is formed integrally with the fixed-side conductor body 12 so as to reduce the number of parts as a whole and to control the flow of gas to improve the operation characteristics of the gas circuit breaker.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a gas insulated switchgear

The present invention relates to a gas circuit breaker of a gas insulated switchgear, and more particularly, to a gas circuit breaker of a gas insulated switchgear configured to smoothly transfer gas heated by heat of an arc to the outside of a fixed side conductor.

Gas Insulated Switchgear (GIS) is a power transformer facility that improves the reliability by inserting conductors and various protective devices by using insulated gas, which is excellent in insulation performance and SOHO function, in an airtight container made of metal, , A disconnector, a ground switch, and the like.

In the event of a fault in the power system, the fault current must be cut off quickly and safely to protect the system and various power devices. The device that breaks the fault current is called a breaker, which is classified as a vacuum breaker, an oil breaker, or a gas breaker depending on the SOHO and insulation medium. The breaker interrupts the fault current means that the arc arising between the two contacts at the time of the breakdown of the fault current is extinguished. According to the method of extinguishing the arc, the gas circuit breaker is a puffer type, . As an ultra high-voltage circuit breaker of 72.5kV class or higher, a gas circuit breaker of the Pafferhofer method using an insulating gas (SF ₆ ) as a soot and insulating medium is mainly used.

The breaker performs the breaking of the fault current. When a high voltage flows through the converter, an arc is generated when the electrode is disconnected. In the breaker, a separate fixed arc electrode and a movable arc electrode are provided so that an arc is generated only in the fixed arc electrode and the movable arc electrode. That is, the arc can be concentrated in one place so that it can be easily called out.

When an arc is generated between the movable arc electrode and the stationary arc electrode in the gas insulated switchgear, the gas in the nozzle is heated by the heat of the arc, and the heated gas enters the inside of the heat paraffin. In order to extinguish the arc, the gas of the heat paraffin is discharged through the nozzle. The discharged gas flows inside the fixed-side conductor on the fixed side and is discharged to the outside of the fixed-side conductor. When the density of the discharged gas is high, the electric field strength is increased and the grounding can be prevented from occurring.

However, the gas insulated switchgear has a problem in that the gas velocity is different when the current is cut off when the current is cut off and when the current is cut off, and the gas is not smoothly discharged to the outside when the current is cut off. That is, the path through which the gas flows is formed by the cylindrical flow path guide inside the fixed side conductor on the fixed side. Therefore, the gas flowing through the inside of the flow guide inside the fixed side conductor flows to the opposite side of the fixed side conductor through the flow path formed between the outer surface of the flow guide and the inner surface of the fixed side conductor. Such a structure is suitable for gas flowing at a high speed in the case of high current interruption, but is not suitable for gas flowing at a low speed in case of low current interruption. That is, the gas flowing at a low speed in the case of the low current interruption can not escape from the fixed side conductor, thereby affecting the inter-pole breaking performance.

Korean Patent No. 10-0584870

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems of the prior art, and it is an object of the present invention to allow a gas for arc extinguishing in a gas circuit breaker of a gas insulated switchgear to smoothly escape to the outside of a fixed- .

Another object of the present invention is to minimize the number of parts for the construction of the fixed side in the gas circuit breaker of the gas insulated switchgear.

According to an aspect of the present invention for achieving the above object, the present invention provides an electrical connection between a fixed side conductor and a movable side conductor by a movable side main electrode and a fixed side main electrode, Side arc electrode and the fixed-side arc electrode in the fixed-side conductor are separated later than the movable-side main electrode and the fixed-side main electrode, and are generated between the movable side arc electrode and the fixed side arc electrode through the gas injected from the nozzle A gas circuit breaker of a gas insulated switchgear for extinguishing an arc, characterized in that in the internal space formed inside the fixed side conductor body forming the framework of the fixed side conductor, the nozzle is passed through the one end of the fixed side conductor body, And an exhaust hole through which the gas is discharged to the outside is formed in the inner space at the opposite end to which the gas is input / A plurality of holes are formed around the outer circumferential surface of the fixed-side conductor body.

A partition wall is formed to surround the inner surface of the inner space so as to be positioned beside the exhaust hole. The partition wall is formed in a ring shape by surrounding the inner surface of the inner space, and is formed to protrude from the inner surface of the inner space by a predetermined height.

The partition wall protrudes from the inner surface of the inner space by a predetermined height to form a communication hole. The communication hole communicates both sides of the inner space defined by the partition.

The nozzle and the fixed side arc electrode are connected to each other through a plurality of links so that the movable side arc electrode on the nozzle side and the fixed side arc electrode are coupled and separated.

One end of the link 1 is connected to the connection end of the fixed-side arc electrode so that one end of the link 1 is relatively rotated. The other end of the link 1 is connected to one end of the link 2 One end of the link 3 is connected to the other end of the link 2 and the other end of the link 3 is connected to the nozzle so as to be rotatable relative to the other end.

The following effects can be obtained in the gas circuit breaker of the gas insulated switchgear according to the present invention.

In the present invention, since the gas discharged through the nozzle in the gas circuit breaker is linearly moved from one end side of the fixed side conductor to the other end side to be discharged to the outside, not only high-speed gas but also low- It is possible to improve the inter-pole breaking performance and inter-site insulation performance of the gas circuit breaker.

In the present invention, since the partition walls are integrally formed in the fixed-side conductor, the number of components constituting the fixed side of the gas circuit breaker is relatively reduced, the degree of freedom of use of the inner space of the fixed-side conductor is increased, have.

In addition, the partition wall functions to control the flow of gas in the internal space, so that the high-temperature gas at the time of interrupting a large current is allowed to stay in the internal space for a longer time, Thereby improving the insulation performance between the ground and the ground.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic sectional view showing a configuration of a preferred embodiment of a gas circuit breaker of a gas insulated switchgear according to the present invention; FIG.
2 is a cross-sectional view showing the configuration of a fixed-side conductor body constituting the embodiment shown in Fig.
3 is a schematic cross-sectional view showing an open state in the embodiment of the present invention.
FIG. 4 is an operating state view showing the flow of gas when the gas circuit breaker of the embodiment of the present invention is opened. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a gas circuit breaker of a gas insulated switchgear according to the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, the structure of the gas circuit breaker will be described with reference to FIGS. 1 and 2. Since the entire structure of the gas circuit breaker is not disclosed in these drawings, the entire structure will be briefly described first.

The gas circuit breaker has a movable side conductor (not shown) which is installed on a fixed body (not shown) and moves to the inside and the outside of the fixed body. The nozzle 30 is provided integrally with the movable side conductor, Gas is discharged. The movable conductor extends through one end of the fixed body and is moved by the operation of the connected operation rod.

On the other hand, a fixed side conductor 10 electrically connected to and separated from the movable side conductor is shown in Fig. The fixed side conductor 10 is fixed to a spacer, which is a kind of insulation, by a coupling hole 44, which will be described below. The fixed side conductor body (12) forms a skeleton and an outer side of the fixed side conductor (10). The fixed-side conductor body 12 is formed into a cylindrical shape as shown in FIG. 2, and an internal space 14 is formed therein. The inner space 14 is provided with components such as the fixed-side arc electrode 20 to be described below.

The inner space 14 of the fixed-side conductor body 12 is open at both ends. The nozzle 30, which will be described later, enters and exits through one end, and the coupling hole 44 is provided at the other end, do.

One end of the fixed-side conductor body 12 forms the fixed-side main electrode 18. The fixed-side main electrode 18 is physically coupled with the movable-side main electrode to allow a current to flow.

A fixed-side arc electrode (20) is provided in the inner space (14) of the fixed-side conductor body (12). The fixed-side arc electrode 20 is physically engaged with and separated from the movable-side arc electrode provided in the nozzle 30 of the movable-side conductor so as to be generated between the arc electrodes 20 even if an arc is generated. The fixed-side arc electrode 20 has a cylindrical shape in this embodiment.

A connection port 22 is connected to an end portion of the fixed side arc electrode 20 which is located on the side of the internal space 14 of the fixed side conductor body 12 and a link 1 24, (26) and a link 3 (28) are connected in order. The link 2 (26) is installed on one side of the fixed-side conductor body (12) so as to rotate about the center pin (27). The link 1 (24) and the link 2 (26), and the link 2 (26) and the link 3 (28) are connected by pins to allow relative motion. The link 3 28 is connected to the nozzle 30 side to be described below so as to produce the movement of the fixed-side arc electrode 20 in accordance with the movement of the nozzle 30.

On the other hand, the nozzle 30 is provided on the movable side conductor corresponding to the fixed side conductor 10. The nozzle 30 can move to the inside and outside of the movable side conductor which is fixedly installed. A gas for extinguishing an arc generated between the fixed-side arc electrode 20 and the movable-side arc electrode is discharged through the nozzle 30. The gas is provided in a funnel (not shown) or the like formed inside the movable conductor.

The nozzle hole 32 of the nozzle 30 is almost closed by the fixed side arc electrode 20 in the closed state as shown in FIG. The gas discharged from the paraffin and the heat wave paraff can be discharged to extinguish an arc generated between the fixed side arc electrode 20 and the movable side arc electrode. An attachment 34 is attached to the tip of the nozzle 30. The link 3 (28) is connected to the attachment 34 so as to be relatively rotatable. That is, the link 3 28 is connected to the attachment 34 by using a structure like a pin not shown, so that the link 3 28 is moved together with the movement of the nozzle 30 to rotate the link 2 26 . Reference numeral 36 denotes a shield for electric field relaxation.

Meanwhile, a partition wall 38 is formed in the inner space 14 of the fixed-side conductor body 12. The partition wall 38 is formed so as to surround the inner surface on the side opposite to the end where the nozzle 30 enters and exits. The partition wall 38 is formed in a ring shape by surrounding the inner surface of the inner space 14 and is formed to protrude from the inner surface of the inner space 14 by a predetermined height. The communication hole 39 is formed in the inner space 14 defined by the partition wall 38. The communication hole 39 is formed in the inner space 14 by a predetermined height from the inner surface of the inner space 14. [ It serves to communicate both sides.

The position of the partition wall 38 is adjacent to the exhaust hole 40 as the almost end portion of the fixed-side conductor body 12 in the internal space 14. The exhaust hole 40 is formed around the outer circumferential surface of the fixed side conductor body 12 corresponding to the end opposite to the end of the fixed side conductor body 12 through which the nozzle 30 enters and leaves. A plurality of exhaust holes (40) are formed around the outer surface of the fixed-side conductor body (12). This is well illustrated in FIG. The exhaust hole 40 allows the gas that has passed through the communication hole 39 to be discharged to the outside of the inner space 14.

Particularly, since the position of the exhaust hole 40 is formed at the opposite end of the nozzle 30, the gas injected from the nozzle 30 flows from one end to the other end of the internal space 14 It can flow in a straight line. When the gas flows as described above, the low-speed gas at the time of low-current interruption can also flow smoothly from the inner space 14 to the exhaust hole 40 while flowing straight.

A coupling hole (42) is formed in the fixed-side conductor body (12) at an end portion where the exhaust hole (40) is formed. A threaded portion is formed on the inner surface of the coupling hole 42 so that the coupling hole 44 is fastened. The coupling hole 44 is for fixing the fixed side conductor body 12.

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

When the operation signal is supplied by the overload in the gas insulated switchgear, the operating rod is driven by the driving source so that the moving side conductor including the nozzle 30 moves to the left side in the drawing. The movement of the movable side conductor causes the separation of the movable side main electrode of the movable side conductor and the fixed side main electrode 18 of the fixed side conductor 10. However, if the movable arc electrode and the fixed arc electrode 20 are not separated, an arc is not generated.

When the movable side main electrode and the fixed side main electrode 18 are separated by the movement of the movable side conductor and the movable side arc electrode and the fixed side arc electrode 20 are separated from each other, A) occurs. The arc (A) is formed to connect between the movable side arc electrode and the fixed side arc electrode (20).

When the arc A is generated, the gas in the nozzle 30 is heated by the heat of the arc A. The gas thus heated flows backward through the nozzle flow path by the force generated by the arc A, Quot; When the high temperature gas enters the heat paraffin, the cold gas in the heat paraffin is mixed while stirring. When this gas is mixed in the heat parcels, the pressure of the parcels is increased. Is discharged out of the nozzle hole (32) through the nozzle (30) by the pressure.

In this operation, the gas extinguishes the arc (A). The gas is injected through the nozzle 30 to extinguish the arc A and flow in the internal space 14 is indicated by an arrow in FIG.

When the nozzle 30 moves to the left with reference to the drawing, the link 3 28 moves to the left together with the nozzle 30. The movement of the link 3 28 is transmitted to the link 2 26) in the clockwise direction. The clockwise rotation of the link 2 (26) causes the fixed-side arc electrode 20 to move to the right while moving the link 1 (24) to the right with reference to the drawing. In this operation, the fixed arc electrode 20 and the movable arc electrode are separated more quickly by the movement of the nozzle 30.

The gas injected through the nozzle hole 32 of the nozzle 30 is moved along the inner space 14. When the high current is cut off, the gas moves at a high speed. When the current is cut off, The gas is moved. The direction of the flow in the internal space 14 is maintained constant even when the gas moves at a relatively slow rate in the case of the low current interruption so that it can be easily transmitted to the exhaust hole 40 through the communication hole 39 . Most of the gas injected at the relatively slow velocity in the nozzle hole 32 does not flow to the inner surface of the inner space 14 but moves along the center of the inner space 14, Through the exhaust hole (40) through the exhaust hole (39).

However, when the large current is cut off, the temperature of the gas becomes higher than that at the time of low current interruption and is discharged from the nozzle hole 32 at a high speed. When the gas is injected from the nozzle 30, A large amount is also sprayed toward. The gas injected toward the inner surface of the inner space 14 moves along the inner surface of the inner space 14 and is blocked by the partition wall 38 so that the flow is slightly delayed and passes through the communication hole 39, 40, respectively.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: fixed side conductor 12: fixed side conductor body
14: inner space 18: fixed-side main electrode
20: stationary-side arc electrode 22:
24: Link 1 26: Link 2
27: center pin 28: link 3
30: nozzle 32; Nozzle ball
34: Attachment 36: Shield
38: partition wall 39: communication hole
40: exhaust hole 42: engaging hole
44: Coupling A: Arc

Claims (5)

A movable side main electrode and a fixed side main electrode perform electrical connection between the fixed side conductor and the movable side conductor, and a movable side arc electrode in the movable side conductor and a fixed side arc electrode in the fixed side conductor are electrically connected to the movable side main A gas circuit breaker of a gas insulated switchgear apparatus which recovers an arc generated between a movable side arc electrode and a fixed side arc electrode through a gas ejected from a nozzle while being later disconnected from an electrode and a fixed side main electrode,
Wherein the fixed side conductor body has an inner space formed in a fixed side conductor body forming a skeleton of the fixed side conductor, the nozzle being inserted into and out of one end of the fixed side conductor body, Wherein a plurality of exhaust holes are formed around the outer circumferential surface of the fixed-side conductor body.
The exhaust gas purifier of claim 1, further comprising a partition wall surrounding the inner surface of the inner space so as to be positioned adjacent to the exhaust hole, wherein the partition wall is formed in a ring shape by surrounding the inner surface of the inner space, Wherein the gas-insulated switchgear is formed so as to protrude as much as possible.
The gas insulated switchgear according to claim 2, wherein the partition wall protrudes from the inner surface of the inner space by a predetermined height to form a communication hole, wherein the communication hole communicates both sides of the inner space defined by the partition, Of gas breakers.
The method as claimed in any one of claims 1 to 3, wherein the nozzle and the fixed-side arc electrode are connected to each other through a plurality of links so that the movable-side arc electrode on the nozzle side and the fixed- Gas interrupter of this interlocked gas insulated switchgear.
[5] The apparatus according to claim 4, wherein the fixed-side arc electrode is provided with a connector, one end of the link is connected to the connection port in a relatively rotatable manner, and the other end of the link is rotatable about the center pin in the fixed- Wherein one end of the installed link is relatively rotatably connected and one end of the link is connected to the other end of the link and the other end of the link is connected to the nozzle so as to be rotatable relative to the nozzle.

Images