KR20160080022A - gas insulating bus and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a gas-insulated bus in a new shape and to a manufacturing method thereof. The gas-insulated bus comprises: an insulating post formed of an insulating material and consisting of a body terminal placed in the middle of conductors and a combination terminal protruding from the circumference surface of the body terminal toward the conductors; a combination part for combining and fixating the conductors to the combination terminal of the insulating post; and an insulating spacer placed at the end of at least one among the conductors and consisting of an insulating body constituting a body part, a combining protrusion part, which protrudes from the circumference of the insulating body and constitutes a part combining with an outer box, and multiple electricity-conducting conductors, which are installed to penetrate the insulating body in an axial direction and conduct electricity to and from the conductors. Accordingly, operation time can be reduced and conductors can be combined stably as the conductors, the insulating post and the insulating space can be combined with the outer box by being inserted into the outer box after being combined in advance outside the outer box.

Description

Gas insulated bus and manufacturing method thereof < RTI ID = 0.0 >

The present invention relates to a gas insulated busbar, and more particularly, to a gas insulated busbar, which can be easily assembled by improving a coupling structure between a three-conductor and an enclosure, And more particularly, to a gas-insulated busbar according to a new type and a method of manufacturing the same.

Generally, a gas insulated bus used in a gas insulated switchgear (GIS) is a device that receives power from a bushing that is supplied from a three-phase high voltage power source and transmits the power to the gas insulated breaker.

The gas insulated busbars are installed in such a manner that three conductors for transferring a three-phase high-voltage power supply are provided in the enclosure filled with the inert gas (SF6 gas).

At this time, the conductor is fixedly installed in an insulated state in the enclosure by an insulator, thereby preventing a current flowing along each conductor from flowing to the enclosure. In this regard, as disclosed in Japanese Patent Application Laid-Open Nos. 10-2012-105742, 10-2010-77746, 10-1999-023397, 10-1999-045064, etc. .

However, since the gas insulated busbars according to the above-described conventional techniques are configured to connect the respective conductors to the enclosures using insulators in the enclosures after inserting the three conductors into the enclosures, the operability thereof is extremely low There was a problem.

Particularly, when the length of the enclosure is long, it is extremely difficult for an operator to join the insulator in the enclosure. Therefore, the insulator must be connected to the end of each enclosure, There is a problem that the distance between the conductors can not be kept constant due to the occurrence of sagging at the portion located at the central side portion of the inner conductor.

In addition, since the gas insulated busbars according to the above-described conventional techniques are made to provide insulation separately for each conductor, an increase in the assembly time due to an increase in the number of components has yet to be caused. Of course, in the case of U.S. Patent No. 4,404,423, the insulator is formed as a single body to reduce the number of parts, but this is also difficult to assemble because it is configured to be combined in the enclosure .

SUMMARY OF THE INVENTION The present invention has been made in order to solve various problems of the prior art described above, and it is an object of the present invention to provide an improved method for assembling a three- And to provide a gas insulated bus line according to a new type in which the coupling of each conductor can be stably performed, and a method of manufacturing the same.

In order to accomplish the above object, according to the present invention, there is provided a gas insulated bus, comprising: an enclosure made of an inert gas filled with an inert gas; A plurality of conductors spaced apart from each other in the enclosure and extending along the axial direction of the enclosure; An insulating post made of an insulating material and having a body end positioned at a center between the conductors and a joint end protruding from the peripheral surface of the body end toward the respective conductors; A coupling part for coupling and fixing the respective conductors to the respective coupling ends of the insulation posts; A coupling protrusion formed on at least one end of each of the conductors and forming a body portion, a coupling protrusion protruding from the periphery of the insulation body and forming an engagement portion with the casing, And an insulating spacer formed of a plurality of conductive conductors electrically connected to the respective conductors while being installed.

Here, the coupling portion may include an outer plate having a planar structure in which one surface is laid on the end surface of the coupling end forming the insulation post, and the other surface is formed in a round structure so that the surface of the conductor is laid over the coupling plate. An inner plate having an outer surface formed in a round structure so as to be in close contact with an inner circumferential surface of the conductor while being positioned inside the conductor; And at least one fixing bolt for fixing the outer plate, the inner plate, and the conductor to the coupling end while being coupled with each other.

According to another aspect of the present invention, there is provided a method of manufacturing a gas insulated busbars comprising: a first step of coupling and fixing conductors to respective connecting ends of a single insulation post; A second step of joining insulating spacers to either end of each of the conductors to complete the conductor assembly; A third step of inserting the completed conductor assembly into the enclosure; And a fourth step of coupling and fixing the insulating spacer to the coupling bracket of the enclosure.

As described above, the gas insulated busbars and the method of manufacturing the same according to the present invention allow the coupling between the conductors and the enclosures to be made by the insulating posts and the insulating spacers, thereby maintaining and maintaining the spacing distance between the conductors The deflection of each conductor can be stably prevented.

That is, the central portion of each conductor is collectively coupled to a single insulation post so that the separation distance between the respective conductors by the insulation posts is kept constant, and the deflection phenomenon of each conductor can be prevented. It is possible to stably maintain the installation state by being fixedly coupled to the enclosure using an insulating spacer.

In particular, according to the gas insulated busbars of the present invention and the manufacturing method thereof, the connection between each conductor and the insulation post and the connection between the respective conductors and the insulation spacer can be performed through a separate operation process from the exterior of the enclosure, Considering that the joint between the enclosures is also at the end of the enclosure, the operation for joining the enclosure is performed outside the enclosure, so that the convenience of the operation and the operation time can be shortened.

1 is an exploded perspective view illustrating a gas insulated bus line according to an embodiment of the present invention.
2 is a cross-sectional view illustrating the internal structure of the gas insulated busbar according to the embodiment of the present invention
FIG. 3 is a perspective view illustrating a joint structure between the insulating spacer and the enclosure of the gas insulated busbar according to the embodiment of the present invention.
Fig. 4 is an enlarged view of the " A &
5 is an exploded perspective view of a key portion for explaining a coupling structure between an insulation post and a conductor by a coupling portion of a gas insulated bus according to an embodiment of the present invention.
FIG. 6 is a cross-sectional view illustrating a coupling structure between a dielectric post and a conductor by a coupling portion of a gas insulated bus according to an embodiment of the present invention.
7 is an enlarged view of " B "
8 is an enlarged view of " C "
Fig. 9 is an enlarged view of " D "
Fig. 10 is a cross-sectional view of the main part shown for explaining the connection structure between the respective enclosures of the gas insulated busbars according to the embodiment of the present invention

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a gas insulated busbar according to the present invention; FIG.

FIG. 1 is an exploded perspective view illustrating a gas insulated busbar according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view illustrating an internal structure of a gas insulated busbar according to an embodiment of the present invention.

As shown in these drawings, the gas insulated busbars according to the embodiment of the present invention mainly include an enclosure 100, a plurality of conductors 200, an insulation post 300, a coupling portion 400, and an insulation spacer The insulating posts 300 and the insulating spacers 500 may be connected to the inside of the enclosure 100 after they are preliminarily joined to the outside of the enclosure 100 and connected to the enclosure 100. [ So that it can be used as a reference.

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

First, the enclosure 100 forms an outer tubular body of the gas insulated busbars, and is formed into an empty tube while being filled with an inert gas.

At this time, the enclosure 100 is made of a single pipe and a flange 110 is formed at an end of the enclosure 100, through which the plurality of enclosures 100 are coupled while using the flanges 110.

Next, the conductor 200 is a portion for transmitting three-phase high-voltage power.

To this end, it is suggested that the conductors 200 are provided in three, spaced apart from each other with the same distance.

At this time, each of the conductors 200 is formed to have a long pipe structure along the axial direction inside the enclosure 100. Of course, the conductor 200 may be formed of a round bar or a groove, not an empty pipe structure.

Next, the insulation posts 300 are positioned between the conductors 200 in the enclosure 100 to couple the conductors 200 together, and the spacing between the conductors 200 is always It is the part that keeps constant.

That is, considering that the length of each conductor 200 used for the gas insulated busbars is long, a portion located at the center of the inside of the enclosure 100 among the respective portions of the conductor 200 may be sagged So that the insulation posts 300 can be used to maintain the constant spacing between the conductors 200.

The insulation posts 300 include a body 310 positioned at a center between the conductors 200 and a coupling terminal 320 protruding from the peripheral surface of the body 310 toward the respective conductors 200. [ And at least a part of the conductor 200 is formed of an insulating material so that the conductors 200 are not energized with each other despite the coupling with the conductor 200.

Of course, there has been a structure of an insulator such that the spacing between the conductors 200 is always spaced by a constant distance as in the case of the insulation post 300 according to the embodiment of the present invention.

However, since the above-described conventional insulation is separately formed and fixed to the enclosure 100, the operation for coupling with the respective conductors 200 is performed simultaneously inside the enclosure 100 and outside the enclosure 100 It has a problem that it has been inevitable.

The insulation posts 300 according to an embodiment of the present invention may be formed as a single body and may be connected to the enclosures 100 in a state where the respective conductors 200 are coupled to the respective conductors 200 from the outside of the enclosure 100, 1 and 2, which are not located only on the edge side of the enclosure 100 because they are located inside the enclosure 100 by the operation of inserting the enclosure 100 into the enclosure 100, The central portion of the conductor), so that deflection of each conductor 200 can be prevented more stably.

Next, the coupling portion 400 is a portion for coupling and fixing the respective conductors 200 to the coupling ends 320 of the insulation post 300.

As shown in FIGS. 5 to 7, the coupling unit 400 includes an outer plate 410, an inner plate 420, and a fixing bolt 430.

The outer plate 410 is interposed between the outer surface of the conductor 200 and the coupling end 320 of the insulation post 300 while the conductor 200 is connected to the coupling end 320 6 and 7, one of the surfaces is formed in a planar structure that is placed on the end surface of the coupling end 320 constituting the insulation post 300, In addition, the other surface is formed in a rounded structure so that the surface of the conductor 200 is laid.

The inner plate 420 is fastened to the inner surface of the conductor 200 and is fastened by the outer plate 410 and a fixing bolt 430 to be fixed to the conductor 200, Is located inside the conductor (200).

5 and 6, the inner surface of the inner plate 420 has a curvature equal to that of the inner circumferential surface of the conductor 200 so as to be in close contact with the inner circumferential surface of the conductor 200, As shown in FIG.

The outer plate 410 and the inner plate 420 described above are preferably formed of a metal material for stable coupling of the conductor 200, but are not limited thereto.

The fixing bolt 430 is configured to fasten the outer plate 410, the inner plate 420, and the coupling end 320 of the insulation post 300 to each other.

The fixing bolt 430 sequentially passes through the inner plate 420 and the outer plate 410 and is fastened to the end surface of the coupling end 320 forming the insulation post 300 while the outer plate 410 The inner plate 420 and the conductor 200 are fixed to the coupling end 320. [

At this time, the height of the fixing bolt 430 is determined so as to be positioned inside the conductor 200 so as not to protrude from the outer circumferential surface of the conductor 200. That is, considering that the fixing bolt 430 is formed of a metal material, if the fixing bolt 430 is positioned so as to protrude from the outer circumferential surface of the conductor 200, The fixing bolt 430 may be positioned only inside the conductor 200 because there is a possibility that the insulation bolt 430 may cause insulation breakdown from the enclosure 100. [

A through hole 210 is formed in the outer circumferential surface of the conductor 200. The penetration of the fixing bolt 430 through the through hole 210 and the penetration of the inner plate 420 into the conductor 200 As shown in Fig.

Next, the insulating spacer 500 is a portion for fixing the end side portion of each of the conductors 200 to the end side portion in the enclosure 100.

That is, the center portion of each conductor 200 is structured so as to be prevented from being sagged by being coupled to each other by the above-described insulation post 300, and the end side portion of each conductor 200 is connected to the insulation spacer 500 So that it is possible to prevent the conductor 200 from sagging all the time and maintain a constant distance from the conductor 200. In the case of the insulation post 300, The insulating spacers 400 allow each of the conductors 200 to be coupled with the enclosure 100 in consideration of the absence of any coupling structure with the enclosure 100. [

2, 3, and 8, the insulating spacer 500 is located at least at one end of each of the conductors 200, and the insulating body 510, the coupling protrusions 520, And energizing conductors 531 and 532.

The insulating body 510 is formed to be a body portion of the insulating spacer 500. The coupling protrusion 520 protrudes from the periphery of the insulating body 510 and forms a joint portion with the enclosure 100 Respectively. The insulation body 510 and the coupling protrusions 520 are formed of an insulating material so as to form a unitary body so that the conductors 200 are prevented from conducting with each other, Energization is also prevented.

In addition, the coupling protrusion 520 is a portion that is fixedly coupled to an inner peripheral surface of an end side of the enclosure 100. At this time, an engagement bracket 120 is disposed on the inner peripheral surface of the end side of the enclosure 100 so as to interpose the engagement protrusion 520 of the insulation spacer 500. The engagement protrusion 520 is engaged with the engagement bracket 120) and a bolt (not shown).

Particularly, in the embodiment of the present invention, it is further provided that a cover body 540 is further provided on the outer side of the engaging protrusion 520.

The cover body 540 serves to alleviate the electric field of the bolts for fastening between the coupling protrusions 520 and the coupling bracket 120, So that the coupling protrusions 520 can be stably installed.

In this case, the coupling bracket 120 provided in the enclosure 100 may be provided separately from the enclosure 100 and may be fixedly coupled to the enclosure 100, and may be formed integrally with the enclosure 100 .

The conduction conductors 531 and 532 forming the insulation spacer 500 serve not only as a part for coupling with the conductors 200 but also because the conductors 200 are connected to another enclosure 100, So as to be electrically connected to each of the conductors 200 placed in the housing. In this case, the another enclosure 100 may have the same shape and structure as the enclosure 100 constituting the gas insulated busbar shown in the embodiment of the present invention, so that a plurality of such enclosures are coupled to form a single gas insulated busbar .

The conduction conduc- tors 531 and 532 may be formed of electrically conductive materials so that ends of the conductors 200 positioned in the enclosure 100 are received or inserted into the ends of the conductors 200, And an outer conduction connector 532 which is formed of a conductive material and has one end electrically connected to the inner conduction conduit 531 and the other end protruding toward the outside of the outer casing 100. As a result, Is configured to be capable of energizing connection between the conductors (200) in the two extending enclosures (100). At this time, ring-shaped contact springs 533 and 534 are provided on the outer circumferential surface of each of the conduction conductors 531 and 532 so that the conduction coupling with the conductor 200 is more accurately performed.

In the following, the manufacturing process of the gas insulated busbar according to the embodiment of the present invention described above will be described in more detail.

First, a conductor 200 is mounted on each coupling end 320 of a single insulation post 300, and the coupling unit 400 is used to fix the conductor to each other.

That is, the conductor 200 is brought into contact with the outer plate 410 in a state where the outer plate 410 constituting the coupling part 400 is placed on each coupling end 320 of the insulation post 300, The inner plate 420 is inserted through the through hole 210 formed in the conductor 200 to contact the inner circumferential surface of the conductor 200 and then the fixing bolt 430 is inserted into the inner plate 420, So that the coupling between the insulation posts 300 and the conductor 200 can be performed by sequentially penetrating the plate 410 and the coupling end 320. This is as shown in FIGS. 5 to 7 attached hereto.

When the connection of each conductor 200 to each coupling end 320 of the insulation post 300 is completed through the repetition of the above process, the insulation spacer 500 ) To complete a conductor assembly (an assembly comprising a conductor and an insulating post and an insulating spacer combined).

At this time, the coupling between the insulating spacer 500 and the conductor 200 is achieved by electrically connecting the respective conductors 200 to the respective inner conduction conductors 531 constituting the insulating spacer 500.

Then, the conductor assembly thus completed is inserted into the enclosure 100.

At this time, the conductor assembly is inserted into the inside of the enclosure 100 from a side opposite to the side where the insulation spacer 500 is coupled, on both sides of each conductor 200. When the insertion of the conductor assembly is completed, The engaging protrusion 520 forming the spacer 500 is blocked by the engaging bracket 120 provided on the inner peripheral surface of the end portion of the enclosure 100 and is no longer inserted.

Subsequently, the cover body 540, the engaging protrusion 520 and the engaging bracket 120 are collectively assembled using a bolt while the cover body 540 is further positioned outside the engaging protrusion 520 Tighten and secure. This is illustrated in FIGS. 3 and 8 attached hereto.

Thus, the coupling between the conductor assembly and the enclosure 100 is completed.

When the plurality of enclosures 100 coupled with the conductor assembly are prepared by repeating the above-described process, the flanges 110 of each of the enclosures 100, And the outer conduction conduit 532 of the insulating spacer 500 located at one end of each of the enclosures 100 is coupled to each of the conductors 200 located at the other end of the other enclosure 100 do. This is as shown in the attached Fig.

Therefore, the gas insulated busbars according to the present invention are completed by the above-described respective processes.

The gas insulated busbars of the present invention are positioned at the central portion in the enclosure 100 by allowing the connection between the respective conductors 200 and the enclosure 100 to be made by the insulation posts 300 and the insulation spacers 500 It is possible to stably maintain the separation distance between the conductors 200 and to prevent the deflection of each conductor 200.

That is, the central portion of each of the conductors 200 is collectively coupled to the single insulation post 300 so that the separation distance between the respective conductors 200 by the insulation post 300 is kept constant, And the end of each of the conductors 200 is fixedly coupled to the enclosure 100 using the insulating spacer 500, thereby enabling stable maintenance of the installed state.

Particularly, the coupling between the conductor 200 and the insulation post 300 and the coupling between the conductor 200 and the insulation spacer 500 can be performed through a separate process outside the enclosure 100, Considering that the joint between the insulating spacer 500 and the enclosure 100 is also the end side of the enclosure 100, work for joining the enclosure 100 outside the enclosure 100 can be performed, .

100. Enclosure 110. Flange
120. Coupling bracket 200. Conductor
210. Through hole 300. Insulation post
310. Body 320. Bonding end
400. Coupling part 410. Outer plate
420. Inner plate 430. Fixing bolt
500. Insulation Spacer 510. Insulation Body
520. Coupling protrusion 531. Inner conduction connector
532. Outside conduction conductor 533, 534. Contact spring
540. Cover body

Claims (3)

An enclosure which is filled with an inert gas and whose interior is made of an empty tube;
A plurality of conductors spaced apart from each other in the enclosure and extending along the axial direction of the enclosure;
An insulating post made of an insulating material and having a body end positioned at a center between the conductors and a joint end protruding from the peripheral surface of the body end toward the respective conductors;
A coupling part for coupling and fixing the respective conductors to the respective coupling ends of the insulation posts;
A coupling protrusion formed on at least one end of each of the conductors and forming a body portion, a coupling protrusion protruding from the periphery of the insulation body and forming an engagement portion with the casing, And an insulating spacer comprising a plurality of conductive conductors electrically connected to the respective conductors while being installed. The method according to claim 1,
The coupling portion
The outer plate being formed in a planar structure in which one surface is laid on the end surface of the coupling end forming the insulation post and the other surface is formed in a round structure so that the surface of the conductor is laid,
An inner plate having an outer surface formed in a rounded shape so as to be in close contact with an inner peripheral surface of the conductor in a state of being positioned inside the conductor,
And at least one fixing bolt penetrating the inner plate and the outer plate sequentially to be fastened to the end surface of the coupling end constituting the insulation post and fixing the outer plate and the inner plate and the conductor to the coupling end. Gas insulated busbars. A first step of coupling and fixing the conductor to each of the coupling ends of the single insulation post;
A second step of joining insulating spacers to either end of each of the conductors to complete the conductor assembly;
A third step of inserting the completed conductor assembly into the enclosure;
And a fourth step of coupling and fixing the insulating spacer to the coupling bracket of the enclosure.

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