KR200461062Y1 - Gas insulated switchgear - Google Patents

Abstract

The present invention relates to a gas insulated switchgear which can ensure the insulation performance between the poles to prevent the breakdown of the poles after the current interruption, and has a cylindrical shape in which a cylinder rod having a movable arc contactor at one end is disposed therein. A movable contact body; A support insulator made of a hollow shape and in communication with the movable contact body; And a fastening body formed at an end of the movable contact body and fastened to an end of the support insulator so as to surround an end of the support insulator.

Description

Gas Insulated Switchgear {GAS INSULATED SWITCHGEAR}

The present invention relates to a gas insulated switchgear, and more particularly to a gas insulated switchgear that can ensure the insulation performance between the poles to prevent the breakdown of the poles after the current interruption.

In general, a gas insulated switchgear is a device for protecting power devices and power systems by safely extinguishing a breaking current generated in an accident and maintaining insulation performance even when a transient recovery voltage is generated between poles.

1 shows a coupling state between a movable contact and a support insulator in a conventional gas insulated switchgear.

The movable contact has a hollow movable contact body 10. The cylinder rod 11 is installed inside the movable contact body 10.

An end portion of the movable contact body 10 is connected to the support insulator 20 having a hollow shape. The end of the support insulator 20 is screwed by a plurality of fastening bolts (B) in close contact with the end of the movable contact body (10). In addition, an insulating rod (not shown) connected to an end of the cylinder rod 11 is installed inside the support insulator 20. The insulating rod is connected to a manipulator (not shown).

Although not shown in the drawings, the movable contact body 10 is divided into two spaces, and a compression cylinder is installed in one space. The cylinder rod 11 penetrates the compression cylinder. A movable arc contactor is installed at an end of the cylinder rod 11 and a sub nozzle is installed at an outer circumference thereof. Here, the movable arc contact and the auxiliary nozzle are surrounded by a compression cylinder. In addition, a main nozzle surrounding the auxiliary nozzle is provided at an end of the compression cylinder, and a space between the auxiliary nozzle and the main nozzle is in communication with the expansion chamber in the compression cylinder. And a movable contact is provided in the outer periphery of the main nozzle.

The movable contact is also arranged to face the fixed contact. The fixed contact is provided with a fixed arc contact coupled with the movable arc contact body, and a fixed contact capable of engaging with the movable contact.

In the gas insulated switchgear configured as described above, when a trip signal is generated, the movable arc contactor and the fixed arc contactor are separated from each other and generate an arc. At this time, as the compression cylinder is moved backwards, the insulating gas present in the compression chamber other than the compression cylinder is introduced into the expansion chamber is injected to the outside through the space between the main nozzle and the auxiliary nozzle.

After the arc is generated as above, when the current is cut off, a transient recovery voltage is applied between the movable arc contact and the fixed arc contact.

At this time, as shown in Figure 4a, the formed electric field is concentrated to the edge of the outer periphery protruding portion of the support insulator 20 coupled so that the outer periphery is exposed to the end of the movable contact body 10, the ground frequently occurs As a result, there is a problem that insulation breakdown occurs in the support insulator 20.

That is, in the conventional coupling structure between the support insulator 20 and the movable contact body 10, the end outer circumference of the support insulator 20 is exposed to the outside as it is concentrated on the outer edge portion of the end of the support insulator 20. As a result, there is a problem that the frequency of dielectric breakdown in the support insulator 20 is increased.

The present invention was created to solve the above problems, and an object of the present invention is to fasten the end of the support insulator so as to surround the end of the movable contact, so that the transient recovery voltage after extinguishing the arc generated when the current is interrupted The present invention provides a gas insulated switchgear that can prevent an electric field from concentrating on a contact portion with a support insulator fastened to an end of the movable contact portion when applied to the movable contact portion.

In a preferred aspect, the present invention is to provide a gas insulated switchgear.

The gas insulated switchgear includes: a cylindrical movable contact body having a cylindrical rod having one end of the movable arc contactor disposed therein; A support insulator made of a hollow shape and in communication with the movable contact body; And a fastening body formed at an end of the movable contact body and fastened to an end of the support insulator so as to surround an end of the support insulator.

Here, the fastening body, the neck body extending a predetermined length from the end of the movable contact portion body, the first hole is formed and the second hole communicating with the first hole is formed and is formed at the end of the neck body It is preferable to have a fitting body in which a fitting groove into which an end of the supporting insulator is formed, and a fastening member for fastening the fitting body and the end of the supporting insulator to each other.

In addition, the fitting body is preferably formed of a close contact with the end of the support insulator, and a pair of partition walls protruding a predetermined length from the outer periphery of the close contact body and the inner circumference of the second hole to form the fitting groove. .

In addition, it is preferable that the outer circumference of the pair of partition walls has a predetermined curvature that is convex outward.

The outer circumferential side partition wall of the contact body may protrude a predetermined length along the opposite side of the fitting groove, and further form a fastening groove in which the fastening member is positioned.

In addition, the position of the fitting groove and the fastening groove may be arranged to be offset from each other.

In addition, the inner wall of the fitting groove and the inner circumference of the support insulator preferably form a gap that gradually widens with each other.

The present invention is fastened so that the end of the support insulator can surround the end of the movable contact, so that when the transient recovery voltage is applied to the movable contact after extinguishing the arc generated during the current interruption, the support is fastened to the end of the movable contact There is an effect that can prevent the electric field is concentrated in the contact portion with the insulator.

In addition, the present invention encloses the creepage of the fastening portion of the support insulator from the outside, it is possible to significantly reduce the occurrence rate of the dielectric breakdown due to the dust caught in this portion.

1 is a cross-sectional view showing a coupling state of a conventional movable contact and the support insulator.
2 is a cross-sectional view showing a gas insulated switchgear of the present invention.
3 is a cross-sectional view showing a state in which the movable contact body and the support insulator according to the present invention are fastened.
4A is a diagram showing electric field formation in a conventional movable contact body and a support insulator fastening portion.
Figure 4b is a view showing the electric field relaxation results in the fastening portion of the movable contact body and the support insulator of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described the gas insulated switchgear of the present invention.

Figure 2 shows a gas insulated switchgear of the present invention.

Fixed contact portion 100 in the present invention may be applied to the following configuration example.

The fixed contact portion 100 has a predetermined space therein and has a fixed length of the fixed contact portion body 101 and a fixed length, the fixed contact portion body 101 is disposed to be movable in the interior of the movable contact portion 200 of the following The first movable part 110 coupled to the outer circumference of the main nozzle 230 and the fixed contactor disposed on the outer circumferential side of the first movable part 110 to be movable in the interior of the fixed contact part body 101 ( 111, a second movable part 120 having a fixed arc contact 121 protruding a predetermined length from the center side of the first movable part 110, and a center thereof at a rear end of the first and second movable parts 110 and 120; A rotary link 133 installed to rotate, a second straight link 132 having one end linked with the second movable part 120 and the other end linked with one end of the rotary link 133, and one end thereof The other end of the rotary link 133 is connected to the first movable part 110 and the other end thereof. It consists of a first straight links 131 that connect link.

Therefore, the first and second linear links 131 and 132 are connected to both ends of the rotary link 133, and the linear reciprocating motion is performed while crossing each other in parallel with each other according to the rotation operation of the rotary link 133. As a result, the first and second movable parts 110 and 120 may alternately protrude to one side of the fixed contact body 101.

Next, to describe the movable contact portion 200 according to the present invention disposed to face the fixed contact portion 100 adopted as described above.

The movable contact portion 200 is formed of a cylindrical movable contact body 201 having a cylindrical rod 210 having one end of the movable arc contact 211 installed therein and a hollow shape, and the movable contact body 201. And a fastening body 20 formed in communication with the support insulator 20 and an end of the movable contact body 201 and fastened to an end of the support insulator 20 so as to surround an end of the support insulator 20. 300).

The interior space of the movable contact body 201 is partitioned into two spaces by a wall. A movable arc contact 211 is installed at one end of the cylinder rod 210. The cylinder rod 210 and the movable arc contact 211 penetrate the wall. In addition, a compression cylinder 220 is disposed in an outer space of the movable contact body 201, and a main nozzle protruding outward to surround the movable arc contact 211 at an end of the compression cylinder 200. 230 is installed. An auxiliary nozzle 231 is disposed at one end of the movable arc contact 211 inside the main nozzle 230. Therefore, the inner space of the compression cylinder 220 and the inner space of the main nozzle 230 may communicate with each other. Therefore, the inner space of the compression cylinder 220 may be formed as an expansion chamber, and the space between the wall and the compression cylinder 220 may be formed as the compression chamber. In addition, a movable contact 221 may be installed at one outer circumference of the compression cylinder 220 to surround the main nozzle 230.

3 shows a state in which the movable contact body 201 and the support insulator 20 are fastened according to the present invention.

Referring to FIG. 2, the support insulator 20 may be fastened with its outer circumference surrounded by a fastening body 300 formed at the other end of the movable contact body 201.

The configuration of the fastening body 300 is as follows.

The fastening body 300 is formed at the end of the neck body 310 and the neck body 310 protruding a predetermined length from the other end of the movable contact body 201 to surround the outer periphery of the end of the support insulator 20. It consists of a fitting body 320 is fastened to the support insulator.

Here, the neck body 320 is in communication with the inner space of the movable contact body 201, there is formed a first hole (H1) for providing a flow space of the cylinder rod (210). In particular, the outer diameter of the neck body 310 is preferably formed smaller than the outer diameter of the movable contact body (201).

The fitting body 320 is formed in a ring shape at an end of the neck body 310, and communicates with the first hole H1 therein and allows the cylinder rod 210 to flow therein. H2) is formed of a close contact body 321 and a pair of partitions formed on the inner and outer periphery of the close contact body 321.

Here, a fitting groove 321a is formed in one surface portion of the close contact body 321 to which the end portion of the support insulator 20 is fitted, and a fastening groove 321b is formed in the other surface portion.

The pair of partitions formed on the inner circumference and the outer circumference of the close contact body 321 may have an inner partition 323 protruding a predetermined length along the outer side from the inner circumference of the close contact body 321 and left and right at the outer circumference of the close contact body 321. It may be composed of an outer partition wall 322 protruding in the direction.

Therefore, the fitting groove 321a is formed by being surrounded by the inner partition 323 and the outer partition 322 on the support insulator 20 side, and the fastening groove 321b is formed on the outer circumference of the neck body 310 and the movable contact body. It is formed by surrounding the outer partition 322 on the 201 side.

In addition, the fitting groove 321a and the fastening groove 321b may be formed such that their positions are different from each other. Preferably, the fitting groove 321a is formed to be closer to the first hole H1 by a predetermined distance than the coupling groove 321b.

Accordingly, the thickness of the outer partition 322 on the support insulator 20 side may be formed to be thicker than the thickness of the outer partition 322 on the movable contact body 201. In addition, the thickness of the inner partition wall 323 may be formed thinner than the thickness of the neck body 310.

In addition, the outer periphery of the pair of partitions 322 and 323 may be formed to have a certain curvature that is convex outward, so that local concentration between equipotential lines may be eliminated when the electric field is formed.

In addition, as illustrated in FIG. 4B, an inner wall of the fitting groove 321a and an inner circumference of the support insulator 20 may form a gap that gradually widens with each other.

3 and 4B, a spaced protrusion 323a may be further formed at an inner edge portion of the fitting groove 321a to space the inner circumference of the support insulator 20 from the inner circumference of the fitting groove 321a. Can be.

In addition, the ends of the support insulator 20 are fastened to each other by the fastening member B in a state of being fitted in the fitting groove 321a, and the fastening member b is the close contact body 321 through the fastening groove 321b. And bolts for fastening the ends of the support insulator 20 to each other.

Meanwhile, the cylinder rod 210 penetrating the fastening body 321 may be connected to an insulating rod that is movable inside the support insulator 20 and connected to an external manipulator.

Next, to explain the action of ensuring the insulation performance during arc arcing between the movable contact and the fixed contact according to the present invention configured as described above.

2 and 3, according to the tripping signal of the gas insulated switchgear of the present invention, the insulating rod connected to the manipulator is pulled in the direction of the arrow, the cylinder rod 210 is connected to the insulating rod, and is connected thereto The main nozzle 230, the auxiliary nozzle 231, the movable arc contact 211 and the compression cylinder 220 are also moved in the direction of the arrow. In addition, the first movable part 110 connected to the main nozzle 230 is moved along the arrow B direction while being connected to the first linear link 131, and thus the rotary link 133 is rotated. Subsequently, the second linear link 132 linked to one end of the rotary link 133 is moved in the direction of arrow A, and accordingly, the second movable part 120 is moved in the direction of arrow A. Therefore, the insulating gas that has been compressed inside the compression chamber moves to the expansion chamber of the compression cylinder 220, and the insulating gas is injected to the outside through the space between the main nozzle 230 and the auxiliary nozzle 231. Therefore, the arc generated at the moment of separation between the fixed arc contact 121 and the movable arc contact 211 can be extinguished and at the same time the current can be interrupted.

As described above, after the current is cut off, a transient recovery voltage between the movable arc contact 211 and the fixed arc contact 121 is applied, and at this time, the movable contact body 201 and the support insulator 20 in the present invention. The electric field at the fastening portion of the liver can be relaxed by these fastening shapes.

That is, referring to FIG. 4B, the end of the support insulator 20 is fitted into the fitting groove 321 a of the fastening body 300 formed at the end of the movable contact body 201, and the end outer circumference of the support insulator 20 is provided. By being enclosed so as to be enclosed, the spacing between the equipotential lines of the electric field can make a gap more than a predetermined level.

In addition, the flow of the electric field formed at the end of the support insulator 20 can be prevented from being concentrated in a part through the curvature of the outer partition 322 surrounding its outer periphery.

In addition, the gap between the inner side of the fitting groove 321a and the end of the support insulator 20 is formed by a spaced protrusion 323a in which the fitting groove is formed at the inner edge thereof, whereby a support insulator 20 is in close contact with the support insulator 20. It is possible to prevent the electric field formation around the end inner circumference of the c) from being concentrated. Here, the outer circumference of the inner partition 323 forming the inner groove 321a is formed to gradually open along the other side from the end of the support insulator 20 so as to gradually open the gap. Accordingly, the flow path of the electric field may guide the flow of the electric field to the end of the support insulator 20 along the inner partition 323 where the curvature is formed so that the space between the equipotential lines may be gradually opened.

As described above, the end of the support insulator 20 is fitted into the fitting groove 321a formed in the fastening body 300 formed at the end of the movable contact body 201 to thereby secure the end of the support insulator 20. The outer periphery is enclosed, whereby a phenomenon in which the electric field is concentrated at the end of the support insulator 20 which is a part to be fastened with the fastening body 300 can be prevented.

Therefore, after arc extinguishment, even if a constant voltage is applied to the movable contact body 201, the electric field generated at this time is supported by the fastening body 300 connecting the support insulator 20 and the movable contact body 201 to each other. Since the dispersion is not concentrated at the end of the insulator 20, the ground fault caused by the insulation problem may be suppressed.

10: fastening bolt 100: fixed contact portion
101: fixed contact body 110: first movable part
111: fixed contact 120: second movable part
121: fixed arc contact 131: first straight link
132: second straight link 133: rotating link
200: movable contact 201: movable contact body
210: cylinder rod 211: movable arc contactor
220: compression cylinder 221: movable contact
230: main nozzle 231: auxiliary nozzle
240: insulating rod 300: fastening body
310: neck body 320: fitting body
321: contact body 321a: fitting groove
322: outer partition 323: inner partition
323a: Spacing protrusion 321b: Fastening groove
H1: Hall 1 H2: Hall 2

Claims (7)

A cylindrical movable contact body having a cylinder rod having one end of the movable arc contactor disposed therein;
A support insulator made of a hollow shape and in communication with the movable contact body; And
And a fastening body formed at an end of the movable contact body and fastened to an end of the support insulator so as to surround an end of the support insulator.
The fastening body extends a predetermined length from an end of the movable contact body, a neck body having a first hole formed therein, and a second hole communicating with the first hole and formed at an end of the neck body and supported by the support body. And a fitting body having a fitting groove into which an end of the insulator is fitted, and a fastening member for coupling the end of the fitting body and the support insulator to each other. delete The method of claim 1,
The fitting body,
And a close contact body which is in close contact with an end of the support insulator, and a pair of partition walls which protrude a predetermined length from the outer circumference of the close contact body and the inner circumference of the second hole to form the fitting groove. The method of claim 3, wherein
The outer circumference of the pair of partition walls is a gas insulated switchgear, characterized in that the curvature is formed to be convex outward. The method of claim 4, wherein
The outer circumferential side partition wall of the contact body of the pair of partition walls protrude a predetermined length along the opposite side of the fitting groove, the gas insulation opening and closing device, characterized in that further forming a fastening groove is located. 6. The method of claim 5,
Gas insulated switchgear, characterized in that the position of the fitting groove and the fastening groove are arranged to be offset from each other. The method according to any one of claims 1 to 7, or 3 to 6,
And an inner wall of the fitting groove and an inner circumference of the support insulator form a gap that gradually widens with each other.

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