KR102558813B1 - High Voltage Circuit Breaker having Closing Resistor - Google Patents

Abstract

The present invention relates to an extra-high voltage circuit breaker having a closing resistance, and more particularly, to an ultra-high voltage circuit breaker having a closing resistance enabling stable recovery of the closing resistance within a timely period.
An extra-high voltage circuit breaker having a closing resistance according to an embodiment of the present invention includes a fixing unit having a fixed contact point; A movable unit having a movable contact contacting the fixed contact when inputting; a closing resistor connected to the fixing part; a closing resistance fixing unit provided on one side of the fixing unit and connected to the closing resistance; and a closing resistance movable unit provided on one side of the movable unit and contacting the input resistance fixing unit when inputting, wherein the input resistance fixing unit includes: a housing having a hollow part; a closing resistance fixed contact movably installed in the hollow part; and an elastic member elastically supporting the closing resistance fixed contact within the housing, wherein a first gas hole is formed in the housing to smoothly return the closing resistance fixed contact.

Description

High Voltage Circuit Breaker having Closing Resistor}

The present invention relates to an extra-high voltage circuit breaker having a closing resistance, and more particularly, to an ultra-high voltage circuit breaker having a closing resistance enabling stable recovery of the closing resistance within a timely period.

In general, gas insulated switchgear is installed on the circuit between the power side and the load side of the electrical system, and when the circuit is artificially opened or closed in a normal current state, or when an abnormal current such as a ground fault or short circuit occurs on the circuit, the current is safely cut off to protect the power system and load equipment. It is mainly used for extra-high voltage equipment.

Among these ultra-high voltage devices, various additional devices are installed when the rated voltage is high. For example, a capacitor or a closing resistor installed to reduce steep waves generated during closing is the case.

The Closing Resistor (CR) is installed in the extra-high voltage circuit breaker of 362kV class or higher. It is a device that protects the system by contacting the main contact in advance and allowing the current to flow sequentially in order to prevent excessive current from flowing into the system by instantaneous energization during closing and re-closing.

Referring to FIGS. 1 and 2, an ultra-high voltage circuit breaker having a closing resistance according to the prior art will be described as follows.

The main circuit breaker of the high-voltage device (gas insulated switchgear) is largely divided into a movable part (1) and a fixed part (2), and each part is assembled separately and fixed inside the tank (not shown) of the high-voltage device. A movable contact 8 is provided in the movable part 1, and a fixed contact (not shown) is provided in the fixed part 2.

A closing resistor (3) is installed at the rear of the fixing part (2). The closing resistor 3 is a device that protects the system by absorbing current prior to contacting the main contact in order to prevent excessive current from flowing in the main circuit by instantaneous energization during closing and re-closing.

One side of the movable unit 1 is provided with a closing resistance movable unit 4, and one side of the fixing unit 2 is provided with a closing resistance fixing unit 5. The closing resistance movable contact 7 is provided in the closing resistance movable part 4, and the closing resistance fixed contact 6 is provided in the closing resistance fixing part 5.

When switching from the blocking state (Off state, open state) as shown in FIG. 1 to the closed state (On state) as shown in FIG. 2, the movable contactor 8 contacts the fixed contactor and the main circuit is energized. At this time, the closing resistance movable contact 7 contacts the closing resistance fixed contact 6 before the main contact to absorb the initial overcurrent.

Here, the closing resistance fixed contact 6 is installed to be elastically movable a predetermined distance in order to provide contact pressure. That is, the closing resistance movable contact 7 pushes the closing resistance fixed contact 6 a predetermined distance, and the holding force received by the closing resistance fixed contact 6 acts as a contact pressure between the closing resistance movable contact 7 and the closing resistance movable contact 7.

At this time, the time from the preceding contact of the closing contacts 6 and 7 to the contact of the main contact is referred to as the preceding closing time.

The closing resistance (3) and the pre-closing time are determined according to the rated voltage. In the case of 362kV, the closing resistance is 400~600Ω and the pre-closing time is 6~12ms.

After the opening operation, the closing resistance fixed contact 6 returns to its original position (the position shown in FIG. 1). However, if the closing resistance fixed contact 6 does not return to the original position within the set time (for example, 300 ms, which is the set time for the open-re-closing time interval), the distance from the closing resistance movable contact 7 increases, making it impossible to secure sufficient prior closing time. That is, a defect in which the contact of the input contact is not made within the pre-insertion time may occur.

Factors that determine the return of the closing resistance fixed contact 6 include the pressure resistance generated when the closing resistance fixed contact 6 returns in the closing resistance fixing part 5, the force of the return spring that provides restoring force to the closing resistance fixed contact 6, and the load due to friction.

Among them, the part that can be practically and effectively controlled is the pressure resistance, and the return of the closing resistance fixed contact 6 is delayed due to the pressure resistance generated inside the closing resistance fixing part, so that the prior insertion failure does not occur during re-insertion. It is necessary to prevent.
As a prior art document, Japanese Unexamined Patent Publication No. 2013-134864 (2013.07.08.) can be referred.

The present invention has been made to solve the above-mentioned problems, and its object is to reduce the pressure resistance generated inside the closing resistance fixing part in the ultra-high voltage circuit breaker having a closing resistance to prevent the preliminary closing failure of the closing contact. It is to provide an ultra-high voltage circuit breaker with a closing resistance.

An extra-high voltage circuit breaker having a closing resistance according to an embodiment of the present invention includes a fixing unit having a fixed contact point; A movable unit having a movable contact contacting the fixed contact when inputting; a closing resistor connected to the fixing part; a closing resistance fixing unit provided on one side of the fixing unit and connected to the closing resistance; and a closing resistance movable unit provided on one side of the movable unit and contacting the input resistance fixing unit when inputting, wherein the input resistance fixing unit includes: a housing having a hollow part; a closing resistance fixed contact movably installed in the hollow part; and an elastic member elastically supporting the closing resistance fixed contact within the housing, wherein a first gas hole is formed in the housing to smoothly return the closing resistance fixed contact.

Here, the first gas hole is characterized in that it is formed in the pressure action groove formed on the inner circumferential surface of the housing.

In addition, the pressure action groove is characterized in that formed extending from the middle part to the rear end of the housing.

In addition, the first gas hole is characterized in that formed in plurality along the circumferential surface of the housing.

In addition, the first gas hole is characterized in that formed at the front end of the pressure action groove.

In addition, a contact portion protruding annularly from an outer circumferential surface and contacting the pressure action groove is formed at the lower end of the closing resistance fixed contact.

Further, a support for supporting the housing to the fixing portion may be further included, and a plurality of second gas holes communicating with the hollow portion may be formed on the support along a circumferential surface thereof.

In addition, the space formed by the inside of the closing resistance fixed contact and the pressure action groove is referred to as a first pressure space (A), and the space formed between the outer circumferential surface of the closing resistance fixed contact and the pressure action groove is referred to as a second pressure space (B).

In addition, the first gas hole is characterized in that the second pressure space (B) and the outside of the input resistance fixing unit communicate.

And, the second gas hole is characterized in that the communication between the first pressure space (A) and the outside of the input resistance fixing unit.

According to the ultra-high voltage circuit breaker having a closing resistor according to an embodiment of the present invention, the pressure resistance inside the closing resistance fixing part is reduced so that the closing resistance fixed contact is stably returned to the original position within a timely period. Accordingly, the failure of the prior insertion of the closing resistance is prevented.

1 and 2 are front views of an extra-high voltage circuit breaker having a closing resistor according to the prior art, wherein FIG. 1 shows an open state and FIG. 2 shows a closed state.
3 and 4 are front views of an extra-high voltage circuit breaker having a closing resistor according to an embodiment of the present invention. FIG. 3 shows an open state and FIG. 4 shows a closed state.
5 and 6 are cross-sectional views of the input resistance fixture in FIGS. 3 and 4, respectively.
7 is a perspective view of a housing applied to the input resistance fixing unit in FIG. 3;

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings, which is intended to be described in detail to the extent that those skilled in the art can easily practice the invention, which does not mean that the technical spirit and scope of the present invention are limited.

3 and 4 are front views of an extra-high voltage circuit breaker having a closing resistor according to an embodiment of the present invention. FIG. 3 shows an open state and FIG. 4 shows a closed state. An extra-high voltage circuit breaker having a closing resistor according to each embodiment of the present invention will be described in detail with reference to the drawings.

An ultra-high voltage circuit breaker 10 having a closing resistance according to an embodiment of the present invention includes a fixing part 20 having a fixed contact point 23; A movable part 11 having a movable contact 15 contacting the fixed contact 23 at the time of input; An input resistor 30 connected to the fixing part 20; a input resistance fixing unit 50 provided on one side of the fixing unit 20 and connected to the input resistance 30; It is provided on one side of the movable part 11 and contacts the input resistance fixing part 50 when it is put in; includes, and the input resistance fixing part 50 includes a housing 52 having a hollow part 53; a closing resistance fixed contact 60 movably installed in the hollow part 53; An elastic member 65 for elastically supporting the input resistance fixed contact 60 within the housing 52, and the housing 52 facilitates the return of the input resistance fixed contact 60. It is characterized in that a first gas hole 54 is formed.

The gas insulated switchgear includes various power devices such as an ultra-high voltage circuit breaker 10 installed in a tank (enclosure, not shown).

The ultra-high voltage circuit breaker 10 includes a movable part 11 and a fixed part 20. The movable part 11 is in contact with or separated from the fixed part 20 . Here, the movable part 11 and the fixed part 20 are connected to the main circuit to conduct or block the main circuit. When the movable part 11 is connected to the fixed part 20, the main circuit is energized, and when the movable part 11 is separated from the fixed part 20, the main circuit is cut off.

In the movable part 11, the main nozzle 13, the auxiliary nozzle 14, the movable contact 15, and the movable arc contact 16 are provided in the movable cylinder 17 and move linearly by the movable rod 18. Since each component of the movable unit 11 is the same as in the prior art, individual descriptions thereof will be omitted.

The fixing part 20 is provided on a fixing part support 21 formed in a cylindrical shape. A fixed contact point 23 is provided at the front end of the fixing part support 21 . Inside the fixing part support 21, a fixed arc contact 25 is provided along the central axis. Since each component of the fixing unit 20 is the same as the prior art, individual descriptions thereof will be omitted.

As shown in FIG. 4, the movable contact point 15 contacts the fixed contact point 23 during input, and the main circuit is energized. At this time, the movable arc contact 16 is in contact with the fixed arc contact 25. At the time of blocking, the arc contacts 16 and 25 are separated before the main contacts 15 and 23 to induce generation and discharge of arcs.

A closing resistor 30 is provided at the rear end of the fixing part 20 . In order to prevent excessive current from flowing in the main circuit by instantaneous energization during closing or open-closing, the closing resistor 30 makes contact (preceding contact) prior to the contact of the main contacts 15 and 23 to protect the system by allowing current to flow sequentially. The input resistor 30 is composed of a large-capacity resistor.

On one side of the movable part 10, the input resistance movable part 40 is provided. The closing resistance movable unit 40 is provided with a closing resistance movable rod 41 connected to the movable rod 18 and linearly moving in the same direction as the movement direction of the movable rod 18 . The movable rod 18 and the input resistance movable rod 41 are connected mechanically and electrically. For example, the movable rod 18 and the input resistance movable rod 41 may be connected by a link 19 .

The closing resistance movable part 40 is provided with a closing resistance movable contact 43 connected to the closing resistance movable rod 41 . The closing resistance movable contact 43 is in contact with the closing resistance fixed contact 60 when closing, and is separated from the closing resistance fixed contact 60 when shutting off.

A movable contact portion 44 is provided at the front end of the closing resistance movable contact 43.

One side of the fixing part 20 is provided with an input resistance fixing part 50 . 5 to 7 show detailed views of the input resistance fixing unit 50 .

The closing resistance fixing part 50 includes a support 51, a cylindrical housing 52 fixed to the support 51, a closing resistance fixed contact 60 installed to be linearly movable in the housing 52, and an elastic member 65 that elastically supports the closing resistance fixed contact 60.

The support 51 is fixedly installed to the fixing part support 21 . The support 51 is fixed to the fixing part support 21 to support the housing 52 . Also, the support 51 is electrically connected to the input resistor 30 .

An elastic member support portion 51a and an elastic member guide portion 51b are formed at the front end of the support 51. Here, the elastic member support portion 51a may be formed as a stepped portion, and the elastic member guide portion 51b may be formed in a circular tubular shape.

A second gas hole 51c is formed along the circumferential surface of the support 51 . The portion where the second gas hole 51c is formed communicates with the hollow portion 53 of the housing 52 described later. Accordingly, the second gas hole 51c communicates with the first pressure space A, which will be described later.

The housing 52 is shown in cross section in FIGS. 5 and 6 and in a perspective view in FIG. 7 . The housing 52 is formed in a cylindrical shape. That is, the hollow part 53 is formed in the housing 52 along the longitudinal axis. The input resistance fixed contact 60 is slidably inserted and installed into the hollow part 53.

The rear end of the housing 52 is fixedly installed to the support 51 to receive support. The housing 52 may be fitted and coupled to the support 51 . The coupling part 56 of the housing 52 does not interfere with the second gas hole 51c.

A pressure action groove 55 is formed on an inner circumferential surface of the housing 52 . The pressure action groove 55 may be formed stepwise on the inner circumferential surface of the housing 52 . The pressure action groove 55 may extend from the middle of the housing 52 to the rear end. 5 and 6, it can be seen that the second pressure space B is formed in a ring shape by the pressure action groove 55 and the outer circumferential surface of the closing resistance fixed contact 60.

A first gas hole 54 is formed in the front end of the pressure action groove 55 in the housing 52 . A plurality of first gas holes 54 may be formed along the circumferential surface of the housing 52 . Through the first gas hole 54 , gas in the second pressure space (B) may be discharged to the outside or external gas may be introduced into the second pressure space (B).

A closing resistance fixed contact 60 is provided. The closing resistance fixed contact 60 is formed in a cylinder shape (cylindrical shape).

A fixed contact portion 61 is provided at the front end of the closing resistance fixed contact 60 . The fixed contact portion 61 of the closing resistance fixed contact 60 is disposed toward the closing resistance movable contact 43. The fixed contact portion 61 is exposed by moving to the outside of the housing 52 in the open state and is concealed by moving to the inside of the housing 52 in the closed state.

The closing resistance fixed contact 60 is slidably inserted into the hollow part 53 of the housing 52.

A contact portion 63 protruding annularly along an outer circumferential surface is formed at the rear end of the closed resistance fixed contact 60 . The contact portion 63 contacts the inner circumferential surface of the pressure action groove 55. Therefore, the input resistance fixed contact 60 can stably move linearly (sliding) while being supported in the housing 52 .

A third gas hole 64 is formed adjacent to the contact portion 63 in the closing resistance fixed contact 60 . A plurality of third gas holes 64 are formed along the circumferential surface of the closed resistance fixed contact 60 . Gas in the first pressure space (A) and gas in the second pressure space (B) may flow in and out of each other through the third gas hole 64 .

An elastic member support part 62 is provided below the contact part 61 of the closing resistance fixed contact 60.

An elastic member 65 is provided. The elastic member 65 has its front end in contact with the elastic member support portion 62 of the input resistance fixed contact 60 and its rear end in contact with the elastic member support portion 51a of the support 51 to exert an elastic force. That is, since the support 51 is fixed, the elastic member 65 acts as a force pushing the input resistance fixed contact 60 forward.

The elastic member 65 may be composed of a coil spring.

The closing resistance fixed contact 60 is slidably installed in the hollow part 53 of the housing 52. The input resistance fixed contact 60 receives the force of the elastic member 65 and protrudes out of the hollow part 53 in an open state. The closing resistance fixed contact 60 moves inside the housing 52 by receiving the force of the closing resistance movable contact 43 during closing.

Pressure spaces A and B are formed within the housing 52 to receive internal and external gas pressure.

The first pressure space (A) is a space formed by the inside of the closing resistance fixed contact 60 and the pressure action groove 55 of the housing 52. The first pressure space (A) is formed to a maximum when opening according to the movement of the closing resistance fixed contact 60 and to a minimum when closing.

The second pressure space (B) is a space formed between the outer circumferential surface of the closing resistance fixed contact 60 and the pressure action groove 55 of the housing 52. The second pressure space (B) is formed to a minimum when opening according to the movement of the closing resistance fixed contactor 60 and to a maximum when closing.

The first pressure space (A) communicates with the outside through the second gas hole (51c), and the second pressure space (B) communicates with the outside through the first gas hole (54). In addition, the first pressure space (A) and the second pressure space (B) communicate with each other through the third gas hole (64).

The operation of the ultra-high voltage circuit breaker with closing resistance according to an embodiment of the present invention will be reviewed.

First, reference is made to the open states shown in FIGS. 3 and 5 . In the open state, the main contacts 15 and 23 and the arc contacts 16 and 25 are separated and the main circuit is in a cut off state.

In addition, the closing resistance movable contact 43 is in a separated state from the closing resistance fixed contact 60.

Refer to the input state shown in FIGS. 4 and 5 . When converted to the input state by a user's operation, the main contacts 15 and 23 and the arc contacts 16 and 25 are connected, respectively, and the main circuit is placed in a state of being energized.

At this time, the closing resistance movable contact 43 moves in the direction in which the closing resistance fixed contact 60 is disposed, and the closing resistance contact parts 44 and 61 come into contact with the main contacts 15 and 23. Accordingly, current is connected to the input resistor 30 in advance, so that overcurrent does not occur in the main circuit.

Here, the time during which the closing resistance contact parts 44 and 61 make preliminary contact with the main contacts 15 and 23 is designed to be maintained within a set time (preceding contact time t1).

At this time, the gas in the first pressure space (A) is discharged to the outside through the second gas hole (51c) or the first gas hole (54) via the second pressure space (B) through the third gas hole (64). Therefore, the insertion movement of the closing resistance fixed contactor 60 occurs smoothly while the pressure resistance decreases according to the decrease in the first pressure space A.

In this energized state, the process of opening and re-insertion due to overcurrent generated in the main circuit will be described as follows.

When blocking occurs, the main contacts 15 and 23 and the arc contacts 16 and 25 are separated, and the closing resistance movable contact 43 is separated from the closing resistance fixed contact 60. That is, the state of FIGS. 4 and 6 is converted to the state of FIGS. 3 and 5 .

The closing resistance fixed contact 60 returns to its original position by the restoring force of the elastic member 65. At this time, the first pressure space (A) is expanded. External air is sucked into the first pressure space A through the second gas hole 51c. In addition, the gas in the second pressure space (B) moves to the first pressure space (A) through the third gas hole (64).

On the other hand, the second pressure space (B) decreases. The gas in the second pressure space (B) is discharged to the outside through the first gas hole (54) or moves to the first pressure space (A) through the third gas hole (64).

According to the change in the volume of the first pressure space (A) and the second pressure space (B), outside air is introduced into the first gas hole 54 or inside air is discharged to the outside.

Overall, since the gas in the first pressure space (A) and the second pressure space (B) is smoothly exchanged with the outside through the first gas hole 54, the second gas hole 51c, and the third gas hole 64, the pressure resistance that hinders the opening movement of the closing resistance fixed contact 60 is greatly reduced. In particular, the problem that the movement of the closing resistance fixed contactor 60 is hindered by the pressure resistance of the gas existing in the second pressure space B is largely solved.

Accordingly, the time for the closed resistance fixed contactor 60 to return to the original position in order to prepare for re-insertion at the time of opening is reduced so that it can be returned within the set time (closed resistance fixed contactor return time t2). That is, the closing resistance fixed contact 60 returns within the return time t2 set when opening and enters within an appropriate interval range with the closing resistance movable contact 43, so that the preceding contact of the closing resistance contact occurs within the preceding closing time t1 of the closing resistance when re-inserting.

According to the ultra-high voltage circuit breaker having a closing resistance according to an embodiment of the present invention, the pressure resistance inside the closing resistance fixing part is reduced so that the closing resistance fixed contact can be stably returned within a set time when moving. Accordingly, the failure of the prior insertion of the closing resistance is prevented.

The embodiments described above are embodiments implementing the present invention, and various modifications and variations may be made to those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. That is, the protection scope of the present invention should be construed according to the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10 High voltage circuit breaker 11 Moving part
12 Moving part support 13 Main nozzle
14 auxiliary nozzle 15 movable contact
16 Moving arc contact 17 Moving cylinder
18 movable rod 19 link
20 Fixing part 21 Fixing part support
23 fixed contact 25 fixed arc contact
30 closing resistance 40 closing resistance moving part
41 closing resistance movable rod 43 closing resistance movable contactor
44 Movable contact part 50 Closing resistance fixing part
51 support 51a second gas hole
52 housing 53 hollow part
54 first gas hole 55 pressure action groove
56 Coupling part 60 Closing resistance fixed contact
61 fixed contact part 62 elastic member support part
63 contact part 64 third gas hole

Claims (10)

A fixed part having a fixed contact point;
A movable unit having a movable contact contacting the fixed contact when inputting;
a closing resistor connected to the fixing part;
a closing resistance fixing unit provided on one side of the fixing unit and connected to the closing resistance;
A closing resistance movable unit provided on one side of the movable unit and contacting the input resistance fixing unit when inputting;
The input resistance fixing unit,
a housing having a hollow part;
a closing resistance fixed contact movably installed in the hollow part;
An elastic member elastically supporting the input resistance fixed contact within the housing;
A first gas hole is formed in the housing to smoothly return the closing resistance fixed contact,
Further comprising a support for supporting the housing to the fixing unit, and a plurality of second gas holes communicating with the hollow part are formed on the support along a circumferential surface,
The first gas hole is formed in a pressure action groove formed on an inner circumferential surface of the housing,
The space formed by the inside of the closing resistance fixed contact and the pressure action groove is referred to as a first pressure space (A),
The space formed between the outer circumferential surface of the closing resistance fixed contact and the pressure action groove is referred to as a second pressure space (B),
A third gas hole is formed at the lower end of the closing resistance fixed contact so that gas can flow in and out between the first pressure space (A) and the second pressure space (B). delete The ultra-high voltage circuit breaker according to claim 1, wherein the pressure action groove extends from the middle part to the rear end of the housing. The ultra-high voltage circuit breaker of claim 1, wherein the first gas hole is formed in plurality along a circumferential surface of the housing. [5] The ultra-high voltage circuit breaker of claim 4, wherein the first gas hole is formed at a front end of the pressure action groove. [2] The ultra-high voltage circuit breaker of claim 1, wherein a contact portion protrudes annularly from an outer circumferential surface and comes into contact with the pressure action groove at a lower end of the closing resistance fixed contact. delete delete The ultra-high voltage circuit breaker of claim 1, wherein the first gas hole communicates the second pressure space (B) with the outside of the closing resistor fixing unit. The ultra-high voltage circuit breaker of claim 1, wherein the second gas hole communicates the first pressure space (A) with the outside of the closing resistor fixing unit.

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