KR102127631B1 - Gas Insulated load Break switches with Bushing Replacement Structure - Google Patents

Abstract

The present invention relates to a gas insulated load switch having a structure capable of especially replacing a bushing (1) without operation of disassembling a bolt inside a tank. The gas insulated load switch comprises: a tank (13); a switch unit (4) embedded in the tank (13); an operation unit (5) connected to the switch unit (4); a bushing (1) installed to pass through the tank (13); and a busbar (3) applying an electric current to the bushing (1) and the switch unit (4). A bushing (1) side terminal formed on a bushing (1) side and a busbar (3) side terminal formed on the busbar (3) are coupled by allowing one to be inserted to the other in a sliding manner, and mutually apply a current in a form which the side of the terminal to be inserted is tightened to have no need to disassemble the tank which corresponds to an entire case of the gas insulated switch when the bushing is replaced so as to perform replacement of the bushing (1) on-site, thereby significantly reducing time, effort, and cost required for a maintenance process including the bushing replacement.

Description

Gas Insulated load Break switches with Bushing Replacement Structure

The present invention relates to a gas-insulated load switch, and more particularly to a gas-insulated load switch having a structure in which the bushing can be replaced without dismantling the bolts inside the tank.

Generally, a gas-insulated load switch is a device that is installed in a distribution system to open or close a line under load or to ground it in an open state, to divide a fault section or to divide a line and divide the line.

In particular, the gas insulated load switch has a form in which the opening/closing part is disposed in a tank-type case filled with SF6 gas, which is a tasteless, odorless, and non-toxic inert insulating gas having excellent insulating properties. The gas-insulated load switch can be opened and closed manually by a manual operation or remotely opened and closed by a control box or FRTU installed outside the case, and the load current is opened and closed under normal use conditions to distinguish the line. And a branch.

Electricity generated at a voltage of about 20,000V in a power plant is boosted to a very high voltage suitable for transmission and transmitted to a primary substation. In the primary substation, the supplied power is dropped to 22.9 KV and supplied to the secondary substation or each consumer. Electricity supplied from the primary substation is supplied to the power receiving facilities of each consumer through a distribution system consisting of overhead power distribution lines and underground distribution lines, and is also supplied to low voltage customers through special high voltage consumers, high pressure consumers, and various outdoor installation transformers.

At this time, a multi-circuit gas insulated load switch is used for line division and branching of the underground distribution line. Among the multi-circuit gas insulated load switch, a gas insulated load switch that uses SF6 gas as an insulating material, particularly as shown in FIG. It is widely used.

As shown in the photographs of FIGS. 1 and 2, the combination of the bushing 1 and the busbar 3 is a state in which the bushing busbar fastening bolt 10 is firmly coupled. The coupling between the bushing (1) and the busbar (3) requires stable transmission of high-voltage current, and also minimizes resistance at the contact point. Therefore, the bushing (1) and the busbar (3) are usually tightly coupled with a bolt (10) for fastening the busbar (3).

The bushing 1 is a member that protrudes to the outside and is expected to be replaced because deterioration of the contact may progress over time. However, as shown in FIG. 1, in a situation where the bushing 1 and the busbar 3 are combined with a bolt 10 for fastening the busbar 3, the tank of the gas insulated load switchgear is required to replace the bushing 1 (11) It is necessary to open the work.

However, since the tank 11 is filled with SF6 gas inside, it is usually welded or tightly sealed for the gas to be sealed, so it is impossible for the operation of opening the tank to be performed at the site where the gas insulated load switch is installed. to be.

In spite of the parts that are expected to be replaced, if the replacement work is carried out after the entire gas-insulated load switch is lifted and returned to the factory for each replacement, the work process itself for replacing one bushing (1) will take considerable time, effort, and cost. As it is required, there is an urgent need to develop a process for maintenance and replacement of the bushing 1 or a technology capable of easily replacing the bushing 1.

Patent Registration Publication No. 10-1100706 (Announcement date: December 30, 2011)

Accordingly, the present invention does not need to disassemble the welding joint of the tank corresponding to the entire case of the gas-insulated load switchgear when replacing the bushing in the gas-insulated switchgear, so that the replacement of the bushing can be made in the field, including bushing replacement. It is intended to provide a gas insulated load switchgear having a bushing replacement structure that can significantly reduce the time, effort and cost required for the maintenance process.

Gas insulated load switchgear having a bushing (1) replacement structure according to the present invention for achieving this purpose is built in the sealed tank 13 and the tank 13, so that the load side terminal and the supply side terminal can be opened and closed. It is manufactured and any one of the terminals is formed of a movable mover (4), and connected to the opening and closing portion (4), through the operation unit 5 and the tank 13 to transmit power to the mover to operate A bushing (1) formed at the tip of the bushing (1) so that the opening (4) inside the tank (13) and the outside of the tank (13) energize each other. Consists of a bus bar (3) connecting between the side terminal and the opening and closing part, any one of the bushing (1) side terminal formed on the bushing (1) side and the bus bar (3) side terminal formed on the bus bar (3) It is characterized in that the power is made to each other in a form that is inserted and coupled to the rest of the sliding method.

Here, either the bushing (1)-side terminal or the busbar (3)-side terminal is preferably provided with a connector 110 in the form of a socket, and the other one is inserted into the connector 110 in a sliding manner and coupled to each other. .

In this case, the inner surface of the connector 110 is preferably compressed by an elastic force while surrounding the side of the terminal inserted into the connector 110 while reducing the contact resistance between the bushing (1) side terminal or the busbar (3) side terminal. A conductive elastic member for energizing is provided.

At this time, the conductive elastic member is preferably a plurality of louvers, which are curved members of a conductive material, are disposed in a circular shape corresponding to the inner surface of the connector 110, and are composed of a strip that is a rigid ring-shaped member that connects all of the plurality of louvers. The diameter of the circle having both and elasticity and formed inside the conductive elastic member is smaller than the outer diameter of the terminal on the side of the bushing (1) or the terminal on the busbar (3), and on the side of the bushing (1) or on the busbar (3) When the side terminal is inserted into the inside of the conductive elastic member, the inner circular shape of the conductive elastic member is expanded, thereby pressing the outer circumferential surfaces of the bushing (1) side or busbar (3) side terminals, thereby making the conductive elastic member and the bushing (1) side or booth The electrical resistance between the terminals on the side of the bar 3 is reduced, the surface of the conductive elastic member is formed of silver plating, the electrical conductivity is adjusted according to the number of louvers, and the conductive elastic member has two or more on the inner surface of the connector 110. It is installed step by step.

The gas insulated load switchgear having a bushing replacement structure according to the present invention does not need to disassemble the tank corresponding to the entire case of the gas insulated switchgear without changing the structure of the bushing when the bushing is replaced in the gas insulated switchgear. Since the replacement can be made in the field, there is an effect that the time, effort and cost for the maintenance process including the replacement of the bushing can be significantly reduced.

1 is a side cross-sectional view of a conventional gas insulated load switch,
Figure 2 is an internal picture of a conventional gas-insulated load switch,
Figure 3a is an external perspective view of a conventional gas insulated load switch,
Figure 3b is an external photograph of a conventional gas insulated load switch,
Figure 4 is a side cross-sectional view of the gas insulated load switch according to the present invention,
5 is an external photograph of a gas insulated load switch according to the present invention,
6a and 6b is a bushing (1) fastening structure of the gas insulated load switch according to the present invention,
7 is an enlarged view of the connector 110 in FIGS. 6A and 6B,

The specific structure or functional descriptions presented in the embodiments of the present invention are exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. Also, it should not be construed as being limited to the embodiments described herein, but should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The gas insulated load switchgear system according to the present invention includes a tank 13, an opening/closing part 4, an operation part 5, a bushing 1, and a busbar 3 as shown in FIGS. 1 and 3A. It is composed.

The tank 13 refers to the enclosure shown in FIG. 1. Since the opening and closing portion 4 is installed inside the tank 13, SF6 (sulfur hexafluoride, sulfur hexafluoride gas) is filled for insulation. And the tank 13 is welded continuously along the edge as in the manufacturing process to prevent gas leakage to the outside, and the welding line WB may be formed as shown in FIGS. 3A and 3B.

The opening/closing unit 4 performs power supply, opening or grounding in an insulated state by SF6 gas. That is, it plays a role of blocking current in case of accidents such as opening and closing of the load or grounding or short circuit in the transmission and substation system or electric circuit.

The operation part 5 is a mechanism in which a driving means and a power transmission means for operating the opening and closing part 4 manually or automatically are combined. 2 and 3A to 3C, manual operation is possible. Only when the operation part 5 is operated at a normal speed can the opening/closing part 4 quickly interrupt the problem current supply, so the question of whether the operation part 5 operates quickly is very important for preventing accidents. .

The bushing (1) is an insulation mechanism for power line protection installed in the tank (13) so that current flowing into or out of the tank (13) can be energized with the outside of the tank (13) while maintaining the airtight state of the tank (13). .

The busbar 3 is a member that connects one of the terminals of the opening/closing part 4 and the bushing 1 to be energized.

However, as described in the background section above, in a conventional insulated switchgear, the coupling between the bushing 1 and the busbar 3 is performed stably while high voltage current is transmitted, and the resistance at the contact point should be minimized. Therefore, as can be seen in the photographs of FIGS. 1 and 2, the bushing 1 and the busbar 3 are tightly coupled with a bolt 10 for fastening the busbar 3. Therefore, in order to dismantle the bushing (1), it is necessary to move the entire insulating switch to the factory and tear off the tank along the welding line (WB) shown in the photo in FIG.

In order to solve this problem, in the present invention, the bushing (1) side terminal formed on the bushing (1) side and the busbar (3) side terminal formed on the busbar (3), one of which is inserted in a sliding manner with respect to the other one. It is configured to be coupled, the side of the terminal on the side to be inserted is in the form of tightening the power to each other.

That is, as the bushing 1 is coupled by a sliding method, the bushing clamp fastening nut 9 for coupling the bushing 1 and the tank 13 without dismantling the tank is dismantled, as shown in FIG. 5. Since it is possible to withdraw only 1), the bushing 1 can be replaced on the spot.

More specifically, the coupling structure of the bushing 1, as shown in FIG. 4, either the bushing 1 side terminal or the busbar 3 side terminal is provided with a socket-type connector 110, and the other one It is configured to be inserted into the connector 110 in a sliding manner and coupled to each other. Here, the terminal inserted or withdrawn from the connector 110 will be referred to as a withdrawal terminal 120.

In this case, in the installation of the busbar 3, if the busbar 3 is installed closer to the bushing 1 than the position when the bushing 1 is engaged, the bushing 1 is particularly final. When the bushing clamp fastening nut (9) is fixed to the tank (13), the pushing force between the bushing (1) and the busbar (3) is applied to each other, so that strong contact between the connector (110) and the withdrawal terminal (120) is achieved. Thus, stable energization can be achieved.

When the energizing structure between the busbar 3 and the bushing 1 is formed in this form, there is no need to change the shape of the conventional bushing 1 in the present invention. In the present invention, a separate bushing suitable for this embodiment (1) There is no need to be manufactured, the conventional bushing (1) can be utilized any number, there is an effect that can be significantly reduced in terms of cost.

In addition, in the present invention, while encircling the side of the terminal inserted into the connector 110 on the inner surface of the connector 110 so that energization between the busbar 3 and the bushing 1 is made more stable and resistance at the contact point is minimized. A conductive elastic member is installed to reduce the contact resistance between the bushing (1)-side terminal or the busbar (3)-side terminal by pressing with an elastic force.

In particular, a socket spring 112 manufactured in the form of a photograph of FIG. 8 may be applied to the conductive elastic member. That is, the connector 110 may be formed of a socket 111 and a socket spring 112.

The socket spring 112 includes a plurality of louvers, which are curved members of a conductive material, arranged in a circle corresponding to the inner surface of the connector 110, and is composed of a strip, which is a rigid ring-shaped member that connects all of the plurality of louvers, so as to be conductive and elastic. Have all

And the diameter of the circle formed inside the socket spring 112 is smaller than the outer diameter of the terminal on the bushing (1) side or the busbar (3) side, and the bushing (1) side or the busbar (3) side terminal The conductive elastic member and the bushing (1) side or busbar (3) by pressing the outer circumferential surface of the terminal of the bushing (1) side or busbar (3) side by expanding the inner circle of the conductive elastic member when inserted inside the conductive elastic member ) The electrical resistance between the terminals on the side is reduced.

The surface of the socket spring 112 may be plated with silver to maximize electrical conductivity, and electrical conductivity is adjusted according to the number of louvers in the manufacturing process.

In addition, two or more of the socket springs 112 are installed stepwise on the inner surface of the connector 110 to maximize the tightening force and electrical conductivity exerted by the socket springs 112.

At this time, if the combination consisting of the socket spring 112 and the withdrawal terminal 120 is referred to as the connecting module 100, the connecting module 100 may be installed on the bushing side as shown in FIGS. 6A and 6B or the busbar. It can be installed on the side.

As described above, the gas insulated load switch according to the present invention is composed of a connecting module 100 composed of a connector 110 and a drawing terminal 120, so that the bushing 1 and the busbar 3 are coupled as described above. When the life of 1) is over or replaced for other reasons such as damage, only the nut 9 for fastening the bushing clamp is dismantled in the field, as shown in Fig. 5, without the need to lift the entire gas insulated switch and transport it to the factory. Since it is possible to replace the bushing 1 immediately after making it, there is an effect that the cost and time required for the maintenance work of the gas insulated load switch can be dramatically reduced.

The present invention described above is not limited by the above-described embodiments and accompanying drawings, and various substitutions, modifications, and changes are possible within the scope of the present invention without departing from the technical spirit of the present invention. It will be apparent to those who have the knowledge of.

WB: Welding line 1: Bushing
2: Bushing clamp 3: Bus bar
4: opening and closing part 5: operation part
6: Manipulator box 8: Insulator
9: Nut for fastening the bushing clamp 10: Bolt for fastening the bushing busbar
11: Main circuit input operation axis 12: Ground input operation axis
13: tank 100: connecting module
110: connector 111: socket
112: socket spring 120: withdrawal terminal

Claims (4)

A sealed tank 13;
Built in the tank 13, the load-side terminal and the supply-side terminal is made to be opened and closed, and any one of the terminals is an opening and closing part (4) formed as a movable variable;
An operation unit 5 connected to the opening/closing unit 4 to transmit power to the mover for operation;
A bushing (1) installed to penetrate the tank (13) to energize the opening (4) inside the tank (13) and the outside of the tank (13); And,
Consisting of, consisting of a bushing bar (3) connecting the bushing (1) side terminal formed on the front end of the bushing (1) and the opening and closing part so that the bushing (1) and the opening and closing part are energized,
The bushing (1) side terminal formed on the bushing (1) side and the busbar (3) side terminal formed on the busbar (3) are coupled by being inserted in a sliding manner with respect to the other one, and inserted side The terminals of the terminals are energized to each other in the form of tightening,
One of the terminals of the bushing (1) side or the busbar (3) side is provided with a socket-type connector 110, and the other is inserted into the connector 110 in a sliding manner so as to be coupled to each other so that it can be pulled out. It is formed of a drawing terminal 120 corresponding to the internal shape of the connector 110, and the drawing terminal 120 is inserted into the connector 110 in a socket form by sliding, and the surface of the drawing terminal 120 and the connector 110 The inner surfaces of each other are in close contact with each other,
Conductive elasticity is applied to the inner surface of the connector 110 while reducing the contact resistance between the bushing (1)-side terminal or the busbar (3)-side terminal by pressing with an elastic force while surrounding the side of the terminal inserted into the connector (110). The member is installed,
The conductive elastic member is a plurality of louvers, which are curved members of a conductive material, are disposed in a circular shape to correspond to the inner surface of the connector 110, and are composed of a strip that is a rigid ring-shaped member that connects all of the plurality of louvers. Take it all,
The diameter of the circle formed inside the conductive elastic member is smaller than the outer diameter of the terminal of the bushing (1) side or the busbar (3) side, and the terminal of the bushing (1) side or busbar (3) side is conductive elastic The conductive elastic member and the bushing (1) side or busbar (3) side by pressing the outer circumferential surface of the terminal on the side of the bushing (1) or busbar (3) by expanding the inner circle of the conductive elastic member when inserted inside the member The electrical resistance between terminals is reduced,
The conductive elastic member has a surface formed of silver plating, the electrical conductivity is adjusted according to the number of louvers, and the conductive elastic member has two or more stepwise installed on the inner surface of the connector 110,
A circular groove is formed on the inner surface of the connector 110 so that a portion of the outer circumference of the conductive elastic member is inserted, and the conductive elastic member is installed in a shape inserted into the circular groove,
The busbar (3) and the bushing (1) are installed in close contact with each other so that the residual force acts in a direction close to each other, so that strong contact is made between the connector 110 and the extraction terminal 120, and stable energization is achieved. Gas insulated load switch with a bushing replacement structure. delete delete delete

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