KR19980042682A - Gas Insulated Switchgear - Google Patents

Abstract

The present invention aims to standardize and share the T-branch busbar and to make the gas insulated opening device or the insulation spacer compact, which enables cross-branching, and to support and fix the three-phase conductor with the compact insulation spacer. Arrangement arrangement of the first three-phase conductors in the busbar vessel and the second three-phase conductors in the branch vessel branched from the busbar vessel to obtain a compact and inexpensive gas insulated switchgear that simplifies assembly work, simplifies the structure of the vessel, and facilitates common use. It is an improvement. Specifically, the first three-phase conductors are arranged in parallel in a straight line, and the second three-phase conductors are perpendicular to the plane on which the first three-phase conductors are arranged and in a plane substantially horizontal to the vertical axis of the plane. The arrangement, or symmetry, was arranged symmetrically with respect to the central axis perpendicular to the plane in which the first three-phase conductors were arranged.

Description

Gas Insulated Switchgear

The present invention relates to the arrangement of the three-phase conductor of the gas insulated switchgear, particularly the gas insulated switchgear in which the three-phase conductor is housed in one ground metal container.

In the conventional gas insulated switchgear, as described in Japanese Patent Laid-Open No. 56-132107 and Japanese Patent Laid-Open No. 55-139010, three-phase conductors are arranged in a triangular shape in a cylindrical ground metal container to form a busbar. . In the former gas insulated switchgear, the three-phase conductor in the container branched at right angles from the ground metal container is arranged in a triangular shape and connected to the three-phase conductor of the bus bar. The latter gas insulated switchgear is configured to connect the container-side conductor separated from the ground metal container and the three-phase conductor of the bus bar for each phase.

In the conventional gas insulated switchgear, as described in Japanese Patent Laid-Open No. 2-114813 and Japanese Patent Laid-Open No. 5-244710, a three-phase conductor having a triangular shape arrangement is supported by an insulating support for each phase, or As described in Japanese Patent Application Laid-Open No. 60-2013, three-phase conductors were collectively supported and fixed with a disk-shaped insulating spacer.

However, in the conventional gas insulated switchgear which supports and fixed each of the three-phase conductors of a triangular configuration with an insulating support, the parallelism of each of the three-phase conductors and the wick extraction with the neighboring conductors are adjusted by the height adjustment of the insulation support. In the case where there are parts such as branching of the bus bar, much effort is required for this assembly adjustment. Moreover, since the installation seat for supporting and fixing the said insulating support in the container was needed, the container structure was complicated. In addition, since the three-phase conductors of the bus bar were arranged in a triangular configuration, when the bus bar was branched in the T-shape, only one direction could be pulled out due to the restriction in the drawing direction, and cross-branching could not be performed at the same location.

In the conventional gas insulated switchgear in which three-phase conductors are collectively supported and fixed by a disk-shaped insulating spacer, since the insulating spacer and the container have the same diameter, strength against mechanical stress such as gas pressure, or epoxy own void There existed a possibility that problems, such as intensity | strength with respect to the electrical stress by a material defect, such as (evaporation), may arise.

In addition, a conventional gas insulated switchgear includes a gas insulated opening device in which three-phase conductors are arranged in a vertical direction of a container, as described in Japanese Patent Laid-Open No. 58-63016 and Japanese Patent Laid-Open No. 58-63017; As described in Japanese Patent Application Laid-Open No. 59-165907, Japanese Patent Application Laid-Open No. 60-9314, Japanese Patent Application Laid-Open No. 60-9315, there is also a gas insulated switchgear in which three-phase conductors are collectively supported and fixed by an elliptic insulating spacer. These have not considered any of the above problems. As described in Japanese Patent Application Laid-Open No. 60-59717, there is also a gas insulated switchgear having a linear arrangement of three-phase conductors of a mother bus and three-phase conductors branched from the three-phase conductors. Is arranged in an inclined straight line with respect to the laying direction of the three-phase conductor of the bus bar, and the operation mechanism of the disconnecting device is reciprocated, so that the same rotary operation mechanism cannot be installed and the gas insulated switchgear can be made compact. none.

An object of the present invention is to provide a gas insulated switchgear capable of standardizing and sharing a T-shaped branch busbar and enabling cross-shaped branching. In addition, the compact and inexpensive gas insulated switchgear which compacts the insulating spacer and supports and fixes the three-phase conductor with the compacted insulating spacer, simplifies busbar assembly workability, simplifies the structure of the container, and makes it common. It is for the purpose of providing.

In the gas insulated switchgear according to the present invention, the first three-phase conductor is arranged in parallel in a busbar container in a straight state, and the second three-phase conductor is branched from the first three-phase conductor in a branch container branched from the busbar container. The second three-phase conductor is disposed in a plane that is perpendicular to the plane on which the first three-phase conductor is arranged and is substantially horizontal to the central axis that is perpendicular to the plane. Alternatively, the first three-phase conductors are arranged in parallel in a busbar container in a straight state, and the second three-phase conductors are branched from the first three-phase conductors in the branching vessel branched from the bus container, and the second three-phase conductors It arrange | positions symmetrically and parallel with respect to the perpendicular center axis of the plane which arrange | positioned the 1st three-phase conductor.

The first and second three-phase conductors arranged as described above are divided into the busbar container, the branch container branched from the busbar container, the flanges provided at the end portions of the busbar container and the branch container, and the respective flanges. It is installed in the chamber and housed in an airtight container formed by an insulating spacer for supporting and fixing the first and second three-phase conductors. SF ₆ gas is enclosed in this airtight container.

The second three-phase conductor includes a connecting line branched from the first three-phase conductor and a blade provided in the middle of the connecting line, and the operating mechanism for operating the blade is also housed in the sealed container.

An elliptic insulating spacer is used for the insulating spacer for holding and fixing the first and second three-phase conductors, and a T-shaped or cross-shaped branching container is used for the branching container.

1 is a longitudinal sectional view of a bus bar portion having a T branch of a gas insulated switchgear in which a three-phase conductor according to an embodiment of the present invention is housed in one ground metal container;

2 is an arrow A-A cross-sectional view of the bus bar of the gas insulated switchgear of FIG.

3 is an arrow B-B cross-sectional view of the bus bar of the gas insulated switchgear of FIG.

4 is a right side view of the bus bar of the gas insulated switchgear of FIG.

The bus bar portion having the T branch of the gas insulated switchgear is connected to a busbar container 1 (or a ground metal container) formed in a cylindrical, elliptic or rectangular cross-sectional structure, and one end of the T branch container 4. Doing. The other end of the T branch container 4 is provided with a flange 21 by fixing means such as a bolt. The insulating spacer 8 is provided in the substantially center part of this flange 21 by fixing means, such as a bolt. An end flange 22 is provided at one end of the busbar container 1 by means of fixing means such as a bolt, and an insulating spacer 12 is provided at an approximately center of the end face flange 22 by means of fixing means such as a bolt. I install it. On the other hand, the other end has the same structure as one end, and the end face flange 23 and the insulating spacer 10 are provided by fixing means such as a bolt at a position facing the one end. SF ₆ gas is enclosed in the sealed container formed in this way.

In the busbar container 1, the three-phase bus conductors 2 are arranged in parallel in the vertical direction in a straight line, and one end thereof is supported and fixed by the insulating spacer 10. In addition, the other end is electrically connected to the conductor supported by the insulating spacer 12 via the tulip contact 11. In other words, when the other end of the three-phase bus conductor 2 is connected between the busbar containers 1, the other end of the three-phase bus conductor 2 has a structure in which the insulating spacer of the neighboring bus bar is automatically connected to the tulip contact, and in the tulip contact 11. The tulip-shaped contact 11 side of the three-phase bus conductor 2 is supported and fixed by the guide rod provided.

Here, the parallel arrangement in a straight line state is arranged nearer to a straight line as compared with the conventional triangular arrangement, and includes a three-phase bus conductor 2 arranged away from a straight line. Moreover, the same product can be applied to the insulating spacer 8, the insulating spacer 10 which supports and fixes the bus conductor 2, and the insulating spacer 12. FIG. In addition, as shown in FIG. 4, the shape of the insulating spacer 8 and the insulating spacer 10 is made elliptical, and the earth insulation distance from each phase conductor to a ground container is made equal.

In the T branch container 4, the three-phase connection line which T-branched from the three-phase bus conductor 2 was linearly arrange | positioned, and the blade 3 which is a blade-type conductor is provided in the middle of each connection line. In this embodiment, the three-phase branch conductor having the three-phase connection line branched from the three-phase bus conductor 2 and the three-phase blade 3 provided in the middle of the connection line is arranged with the three-phase bus conductor 2. It is arrange | positioned in the plane perpendicular | vertical with respect to one plane, and substantially horizontal with respect to the central axis perpendicular | vertical of the plane. The three-phase blade 3 has a rotating shaft conductor supported by the insulating spacer 8 on the insulating spacer 8 side, and a fixed side conductor on the three-phase bus conductor 2 side, and the rotation of the rotary lever 7. By operating, the rotating shaft conductor is operated. The rotary shaft side conductor is in a connected state ("mouthed" state) with the fixed side conductor at the position of ① of the rotary lever 7, and is open at the position of ② rotated 45 ° from the position of ①. And the ground terminal 5 installed in the T-branch container 4 at the position of ③ rotated 45 ° from the position of ②, and in the connected state (the "ground" state). do. In this embodiment, the disconnecting device with a grounding device is constituted as described above. Moreover, the tulip-type contact 9 is provided in the outer side of the insulation spacer 8, and it can connect with the circuit breaker which is not shown in figure.

According to this embodiment, the three-phase bus conductors 2 in the busbar container 1 are arranged in parallel in the longitudinal direction in a straight line, that is, three-phase on the center axis of the busbar container 1 or in parallel with the center axis thereof. Since the primary bus conductors 2 in parallel are arranged in a straight line in the vertical direction, the three-phase bus conductors 2 can be T-branched in any of the left and right directions. In other words, the three-phase bus conductor 2 can be branched bilaterally. In addition, when the T branch portion is constituted by a cross branch container, the three-phase bus conductor 2 can be cross branched.

Further, according to this embodiment, the three-phase bus conductors 2 are arranged in parallel in the longitudinal direction in the bus container 1 in a straight line, that is, the three-phase bus conductors 2 with respect to the central axis of the busbar container 1 are arranged. The three-phase branched conductor having three-phase connecting wires arranged in parallel in a linear state in axial symmetry, and T-branched from three-phase bus conductors 2, and three-phase blades 3 provided in the middle of the connecting wires. The three-phase branch conductors are arranged in a plane perpendicular to the plane in which the bus conductors 2 are arranged and substantially horizontal to the center axis perpendicular to the plane, that is, the three-phase branch conductors with respect to the center axis of the T branch container 4. Since it is arrange | positioned to an object, it is possible to share and standardize the components which comprise a gas insulation switchgear, such as a conductor, an insulation spacer, a blade, the operation mechanism of a blade, and a container.

In this way, the cross branch of the three-phase bus conductors 2 and the common and standardization of the components constituting the gas insulated switchgear can be made compact, so that the overall configuration of the gas insulated switchgear can be made compact, and the arrangement of all the gas insulated switchgear The same applies to.

In addition, in this embodiment, as shown in FIG. 4, the example which arrange | positioned the three-phase branch conductor in the position slightly shift | deviated with respect to the central axis of the T branch container 4 was shown, but this is the center of the T branch container 4; By placing on the shaft, flanges can be used and standardized.

In addition, according to this embodiment, since the space opposite to the T branch of the busbar container 1 becomes a surplus space, when the cross section of the busbar container 1 is elliptical with castings or the like, the entire busbar can be reduced. have.

According to this embodiment, since the three-phase bus conductor 2 and the branch conductor branched from the three-phase bus conductor 2 are supported and fixed by an insulating spacer provided on the flange, the three-phase bus conductor 2 and It is not necessary to provide an installation seat for supporting and fixing the branch conductor branched from the three-phase bus conductor 2 through the insulation support in the bus container 1 and the T branch container 4, and the bus container 1 ) And the T branch container 4 can be simplified.

Further, the insulating spacer is formed in an elliptical shape, and the three-phase bus conductors 2 and the branch conductors branched from the three-phase bus conductors 2 are arranged in parallel in a straight line, and the busbar container 1 and the T-branch vessel 4 are arranged in parallel. Since the earth insulation distances to the same are made the same, the volume can be made compact and the occurrence of material defects during resin casting can be minimized.

Moreover, by machining the flange provided with the said insulating spacer, the precision dimension including the squareness of the flange provided in the bus container 1 and the T branch container 4 can be measured, and the three-phase bus conductor at the time of assembly ( 2) There is no need to adjust the parallelism and wick extraction with neighboring conductors, which simplifies assembly work.

Claims (12)

The first three-phase conductors are arranged in parallel in the busbar container in a straight state, and the second three-phase conductors are branched from the first three-phase conductors in the branch vessel branched from the bus-bar vessels. A gas insulated switchgear characterized in that the three-phase conductor is arranged in a plane perpendicular to the plane on which the three-phase conductors are arranged and substantially horizontal to the center axis perpendicular to the plane. The first three-phase conductors are arranged in parallel in a busbar container in a straight state, and the second three-phase conductors are branched from the first three-phase conductors to the second three-phase conductors in the branching vessel branched from the bus container. A gas insulated switchgear characterized in that the conductors are arranged symmetrically in parallel with respect to a vertical central axis of the plane. The gas insulated switchgear according to claim 1 or 2, wherein the second three-phase conductor includes a connection line branched from the first three-phase conductor and a blade provided in the middle of the connection line. The gas insulated switchgear according to claim 1 or 2, wherein the first and second three-phase conductors are supported and fixed by an elliptic insulating spacer to a flange provided at the end portions of the busbar container and the branch container. Device. The gas insulated switchgear according to claim 1 or 2, wherein the branch container is a T-shaped or cross-shaped branch container. The busbar container, the first three-phase conductor arranged in a straight line in the flange busbar container in parallel with each other, the branching vessel branched from the busbar container, and the branching vessel from the first three-phase conductor, A second three-phase conductor disposed in a plane perpendicular to the plane in which the three-phase conductors are arranged and substantially horizontal to a vertical axis of the plane, a flange provided at the ends of the busbar container and the branch container; The first and second conductors in an airtight container formed by the busbar container, branch container, flange and insulating spacer, each having an insulating spacer installed on each flange and supporting and fixing the first and second three-phase conductors. Gas insulated switchgear characterized in that the storage. The busbar container, the first three-phase conductor arranged in a straight line in the flange busbar container in parallel with each other, the branching vessel branched from the busbar container, and the branching vessel from the first three-phase conductor, A second three-phase conductor symmetrically arranged in parallel with respect to a vertical central axis of the plane in which the three-phase conductors are arranged, a flange provided at the end portions of the busbar container and the branch container, and the first and second flanges An insulating spacer for supporting and fixing the first and second three-phase conductors, wherein the first and second conductors are housed in an airtight container formed by the bus bar, branch container, flange, and insulating spacer. Device. The gas insulated switchgear according to claim 6 or 7, wherein SF ₆ gas is enclosed in the sealed container. 8. The gas insulated switchgear according to claim 6 or 7, wherein the second three-phase conductor includes a connection line branched from the first three-phase conductor and a blade provided in the middle of the connection line. 10. The gas insulated switchgear according to claim 9, wherein the operation mechanism of the blade is accommodated in the sealed container. The gas insulated switchgear according to claim 6 or 7, wherein the insulating spacer has an ellipse shape. 8. The gas insulated switchgear according to claim 6 or 7, wherein the branch vessel is a T-shaped or cross-shaped branch vessel.