KR20090073782A - Spacer of gas insulated switchgear - Google Patents

Abstract

A spacer coupling structure for a GIS(Gas Insulated Switchgear) is provided to prevent the damage of a spacer by inducing a local load transmitted through an embedded fitting to an inner part of the spacer. A central conductor(1) is arranged in a central part inside a sealed container(100). Two coupling flanges are formed around the sealed container. A first penetration hole is formed in each coupling flange. The central conductor is arranged to pass through the center of a spacer(200). An edge part of the spacer is interposed between two coupling flanges. An embed fitting(300) is arranged around the spacer. A second penetration hole is formed in the embedded fitting in an axial direction. A bolt(400) successively passes through the first and second penetration holes and couples two coupling flanges with the embedded fitting.

Description

Insertion spacer insert structure for gas insulated switchgear {Spacer of Gas insulated switchgear}

The present invention relates to a gas insulated switchgear, and more particularly, to an insulating spacer that insulates a conductor installed along the inside of a ground tank filled with insulating gas while supporting a distance from an inner wall of the ground tank.

In general, a gas insulated switchgear (GIS) uses a insulating gas (SF ₆ ) having excellent insulation performance and 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 reliability, and is composed of various components such as breakers, disconnectors, and ground breakers.

In particular, the gas insulated switchgear is provided with an insulating spacer, the insulating spacer is provided in the hermetic container while supporting the conductor through which the high voltage current flows so as not to contact the inner wall of the hermetic container to achieve an insulation state with each other It serves to relax the electric field around the conductor.

At this time, the shape of the insulating spacer is Japanese Patent Laid-Open No. 2000-236605, Japanese Patent Application Laid-Open No. 09-070126, Japanese Patent Application Laid-Open No. 54-157287, Japanese Patent Application Laid-Open No. 54-057184, and US Registration. It is formed in a cone type as disclosed in patent US57623813 and EP0750379 or the like, or in a disc type as disclosed in US Patent US3801725 and US3573341.

In addition, the conical spacer is divided into a buried insert insertion type and a metal ring flange type according to the material of the flange assembly.

At this time, the buried spacer insert spacer is an integral buried bracket (hereinafter referred to as "buried bracket") 30 and the epoxy molded article (spacer) 20 as shown in Figure 1 attached.

The above-described conventional metal insertion bracket insertion spacer has a bolt hole 31 assembled with the coupling flange 11 of the hermetic container 10 through the insertion bracket 30 so that the coupling flange of the hermetic container 10 ( 11) When assembling and easy to work closely, there is an advantage that the bolt tightening work to prevent leakage of the insulating gas.

However, in spite of the above-described advantages, since the outer surface of the embedment bracket 30 of the metal embedment insert spacer is configured to be in close contact with the inner surface of each coupling flange 11 of the hermetic container 10, an assembling process or operation is performed. Part of the bolt 40 due to the external force generated in the middle of the edge portion of the spacer 20 in contact with the end portion of the buckle 30 as a local force is applied to the end of the buckle 30 There is a problem that is easily broken in the.

In particular, as described above, when breakage of the edge portion of the spacer 20 occurs, moisture infiltration of the outside air is made through the corresponding portion. Therefore, in the winter when the outside air temperature is low, the moisture penetrating into the damaged part is frozen, which inevitably increases the risk of the spacer 20 being damaged, thereby causing a problem of safety risks.

The present invention has been made to solve the problems of the prior art described above, the object of the present invention is to prevent the occurrence of breakage of the spacer by the external force provided through the insertion bracket while fixing the spacer can be made stable It is an object of the present invention to provide a coupling structure of a buckle insert spacer for a gas insulated switchgear.

In accordance with the present invention, the inlet spacer insert-type spacer coupling structure for gas insulated switchgear according to the present invention has a central conductor along the axial direction at the central portion of the sealed inner space, and the two coupling flanges are respectively facing outwardly. Correspondingly formed in a protruding state, the two coupling flanges are formed in the first through-hole sealed container; A spacer having a center conductor penetrated to a center thereof, and a peripheral end of the spacer having an edge portion interposed between the two coupling flanges; The recess is installed in the rim of the spacer and is interposed between the two coupling flanges together with the rim, and a second through hole is formed along the axial direction. An inner circumferential surface of the second through hole has a corner portion of the two coupling flanges. An embedded bracket formed not to be in contact with the opposing surface; And, through the two coupling flanges and the through-holes of the buried bracket of the hermetic container sequentially and bolts to be coupled to each other: characterized in that it comprises a.

Here, the width of the buried bracket in the axial direction of the bolt is formed smaller than the gap between the two coupling flanges so that the edge portion of the buried bracket does not abut the opposing surfaces of the two coupling flanges. do.

In addition, the edge portion of the second through-hole formed in the buried bracket is formed to be stepped so that the edge portion of the buried bracket does not contact the opposing surfaces of the two coupling flanges.

In addition, the edge portion of the second through-hole formed in the buried bracket is formed to be inclined so that the width of the inner circumferential surface of the second through-hole smaller than the width of the outer circumferential surface of the second through-hole so that the edge portion of the buried bracket is the two coupling flanges It is characterized in that the contact with the opposite surface of the.

As described above, the insert fitting spacer insert structure for the gas insulated switchgear according to the present invention has a gap between the two coupling flanges that join each divided portion of the sealed container during the process of joining the spacers or during the operation of the gas insulated switchgear. Therefore, even if the bolt is inclined in either direction, the breakage of the spacer can be prevented because the local load from the buckle that is pressed by the bolt can be provided as a relatively strong portion rather than the most vulnerable edge portion of the spacer. Has the effect.

Prior to the description of the embodiment of the present invention, the buried slot insert spacer structure proposed in the present invention is applicable to both a gas insulated switch (GIB) as well as a gas insulated switch (GIB). In addition, the term gas insulated switchgear provided in the present invention is premised on the concept including the gas insulated bus as well as a general gas insulated switchgear.

Hereinafter, with reference to Figures 2 to 4 attached to the preferred embodiment of the coupling structure of the above-described embedding spacer insert for spacer gas insulation switchgear of the present invention.

The gas insulated switchgear according to the preferred embodiment of the present invention includes a sealed container 100, a spacer 200, a buried bracket 300, and a bolt 400.

This will be described in more detail for each component as follows.

First, the airtight container 100 will be described.

The hermetically sealed container 100 is a body forming an external appearance of a gas insulated switchgear, and has an inner space formed in the shape of a hermetically sealed tube, and an insulating gas SF ₆ is filled in the hermetically sealed space.

The airtight container 100 is divided into at least two or more parts, and each part is manufactured to be combined with each other.

In this case, coupling flanges 110 and 120 corresponding to each other are formed at coupling portions between the respective portions of the airtight container 100, and the first through holes 111 and 121 penetrating each other are formed in the coupling flanges 110 and 120, respectively. It is formed through.

In particular, the center portion 1 of the inner space of the hermetic container 100 is provided with a central conductor 1 through which a high voltage current flows along its axial direction.

Next, the spacer 200 will be described.

The spacer 200 supports the center conductor 1 so as not to come into contact with the inner wall of the airtight container 100 so as to insulate each other and to relax an electric field around the center conductor 1. It is an insulator.

The spacer 200 may be formed in a conical shape or a disk shape, and the embodiment of the present invention suggests that the spacer 200 is formed so as to form a conical shape in which a proximal portion thereof is protruded.

In addition, the spacer 200 is entirely formed of an epoxy molding, and the center portion 210 through which the center conductor 1 is largely installed, the curved portion 220 and the curved portion 220 extending from the central portion 210. Being outwardly bent from the end of the periphery) is composed of a rim 230 which is interposed in the inner portion between the two coupling flanges (110, 120) formed in the sealed container.

Next, the embedding bracket 300 will be described.

The buried bracket 300 is a part interposed between the two coupling flanges 110 and 120 of the hermetic container 100, and a series of components to secure and secure the spacer 200 to the hermetic container 100. to be.

In this case, the insertion bracket 300 is recessed in the rim 230 of the spacer 200, is interposed between the two coupling flanges (110, 120) together with the spacer 200, the axial direction A second through hole 310 corresponding to the first through holes 111 and 121 of the two coupling flanges 110 and 120 is formed therethrough.

Here, the bolt 400 passes through the first through holes 111 and 121 of the two coupling flanges 110 and 120 and the second through hole 310 of the buried bracket 300, and the end of the bolt 400 is As the nut 410 is tightened, the coupling between the two coupling flanges 110 and 120 and the buckle 300 is made.

In particular, in the embodiment of the present invention, the inner peripheral surface edge portion of the second through hole 310 of each portion of the buried bracket 300 is characterized in that it is formed so as not to contact the opposing surfaces of the two coupling flanges (110, 120). do.

The structure of the bolt 400 according to the displacement of the two coupling flanges (110, 120) corresponding to each other of the sealed container 100 by an external force that can be generated during the fastening process of the bolt 400 or the operation of the gas insulated switchgear ( Considering that the local load due to the inclination of the bolt 400 is provided to the inner circumferential surface edge of the second through hole 310 of the buried bracket 300 when the inclined side 400 is inclined to the one side, the local load is the spacer ( This is to prevent the edge portion, which is the most vulnerable portion of 200).

That is, even if the bolt 400 is inclined to either side, the local load provided by the buckle 300 from the bolt 400 is transmitted to the spacer 200 by avoiding a corner portion of the spacer 200. By doing so, it is possible to prevent breakage of the spacer 200 with respect to the corresponding part (edge part).

As described above, the structure of forming the inner circumferential surface edge portion of the second through hole 310 so as not to contact the opposing surfaces of the two coupling flanges 110 and 120 may be various.

For example, as shown in FIG. 2, the overall width W1 of the buried bracket 300 in the axial direction of the bolt 400 may be smaller than the spacing S1 between the two coupling flanges 110 and 120. And, as shown in Figure 3 attached to the corner portion of the second through hole 310 formed in the buried bracket 300 may be formed stepwise, as shown in Figure 4 attached to the second buried bracket 300 The edge portion of the through hole 310 may be formed to be inclined so that the inner circumferential surface width W2 of the second through hole 310 is smaller than the outer circumferential surface width W3 of the second through hole 310.

As a result, the two coupling flanges 110 and 120 corresponding to each other of the hermetically sealed container 100 are displaced by the external force that may be generated during the assembly of the spacer or the operation of the gas insulated switchgear according to the above-described configuration. ) Is inclined in one direction to press the inner peripheral surface edge portion of the second through hole 310 formed in the buried bracket 300, the concentrated load transmitted through the buried bracket 300 is the edge of the spacer 200 The local stress can be alleviated because it is provided to the inner portion of the spacer 200 rather than the portion.

Accordingly, the risk of breakage of the spacer 200 may be minimized.

1 is a schematic cross-sectional view illustrating main parts of a coupling structure to a spacer insert spacer of a gas insulated switchgear according to the related art.

2 to 4 is a schematic cross-sectional view of the main portion for explaining the coupling structure for the spacer insert type spacer of the gas insulated switchgear according to an embodiment of the present invention

Claims (4)

A center container is provided at a central portion of the sealed inner space along an axial direction, and two coupling flanges are respectively formed on the circumferential surface thereof so as to protrude outwardly, and each of the two coupling flanges has a first through hole formed therein; A spacer having a center conductor penetrated to a center thereof, and a peripheral end of the spacer having an edge portion interposed between the two coupling flanges; The recess is installed in the rim of the spacer and is interposed between the two coupling flanges together with the rim, and a second through hole is formed along the axial direction. An inner circumferential surface of the second through hole has a corner portion of the two coupling flanges. An embedded bracket formed not to be in contact with the opposing surface; And, Inserting spacer insert structure for a gas insulated switchgear for gas insulated switchgear, characterized in that it comprises a: a bolt for coupling to each other while sequentially passing through the two coupling flange and the through hole of the buried bracket of the sealed container. The method of claim 1, Gas insulation, characterized in that the width of the buried bracket in the axial direction of the bolt is smaller than the gap between the two coupling flanges so that the edge portion of the buried bracket does not contact the opposing surfaces of the two coupling flanges. Insertion spacer insert structure for switchgear. The method of claim 1, The edge portion of the second through-hole formed in the buried bracket is formed to be stepped so that the edge portion of the buried bracket so as not to contact the opposing surfaces of the two coupling flanges insertion spacer insert type spacer coupling for gas insulated switchgear rescue. The method of claim 1, The corner portion of the second through hole formed in the buried bracket is formed to be inclined so that the width of the inner circumferential surface of the second through hole is smaller than the width of the outer circumferential surface of the second through hole so that the edge of the buried bracket faces the two coupling flanges. Spacer insert-type spacer coupling structure for gas insulated switchgear, characterized in that the contact with the surface.

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