KR20020076019A - Bidirectional operation type gas circuit breaker - Google Patents

Abstract

PURPOSE: A bidirectional driven gas circuit breaker is provided to improve the performance of fault current breaking and insulating recovery by moving a fixed arc contact in a direction opposite to that of a movable arc contact with a same speed. CONSTITUTION: A circuit breaker(301) blocks the flowing of normal current and a fault current. A manipulator(302) operates the circuit breaker(301). The circuit breaker(301) is comprised of a fixed main contact(303), a second movable arc contact(304), a movable main contact(305), a movable arc contact(306), a puffer cylinder(307), a nozzle(308), and a piston(309). A second movable arc contact moving unit is provided for moving the second movable arc contact(304) and fixed on one end of a supporting member that supports the movable main contact(305). The second movable arc contact moving unit is comprised of a plurality of first and second link members, and a plurality of supporting members.

Description

Bidirectional operation type gas circuit breaker

The present invention relates to a bidirectional driven gas circuit breaker employed to block fault current of the power system, and in particular, by using a link structure to move the fixed arc contact in the opposite direction to the movable arc contact to increase the opening speed and the distance between the poles. Ultimately, the present invention relates to a bidirectional driven gas circuit breaker that can further improve fault current blocking and insulation recovery.

In general, in the event of a fault in the power system, the fault current must be cut off to protect the system and various power equipment. A device that blocks such a fault current is called a breaker, and according to the SOHO / insulation medium, a vacuum breaker (VCB), an oil circuit breaker (OCB), and a gas circuit breaker (GCB) are used. Are classified. Breaking the fault current means that the breaker extinguishes the arc between the two contacts when the fault current is interrupted.The gas breaker is again in the popper type according to the arc extinguishing method. ), Rotary arc type, thermal expansion type, hybrid extinction type and the like. Currently, as a high voltage breaker (72.5 kV or more) circuit breaker circuit breaker of SF ₆ gas as the arc / insulation medium is mainly used.

As illustrated in FIG. 1, the paper extinguishing type gas circuit breaker is largely composed of a breaker 101 for blocking a fault current and a manipulator 109 for operating the breaker 101. In addition, the blocking part 101 is a fixed arc contact part 102, a movable arc contact part 103, a popper cylinder 104, a nozzle 105, a piston 106, and wraps and protects them as a whole. _It consists of a cylindrical metal container 107 filled with _six gases. Reference numeral 108 denotes a manipulator rod that connects the breaker 101 and the manipulator 109.

In the popper extinguishing type gas circuit breaker having the above-described configuration, in the normal state, the breaker 101 flows a normal current while maintaining the closed state as shown in FIG. 2A. However, once an abnormality occurs in the power system and a fault current of several times the normal current flows (for example, about 10 times), the drive coil of the manipulator is excited by the fault current, and the switch of the manipulator is caused by the electromagnetic force generated in the coil. (Not shown) is operated to pull (moving from the right side to the left side in the drawing) the movable portions (such as a paper cylinder, nozzle, movable arc contact portion, etc.) of the blocking portion 101 as shown in Fig. 2B. Then, the SF ₆ gas inside the popper cylinder 104 is compressed by the piston 106, and the movable arc contact portion 103 and the fixed arc contact portion 102 are separated from each other as the movable portion moves. As a result, an arc is generated between the movable arc contact portion 103 and the fixed arc contact portion 102. At this time, the generated arc is extinguished by blowing with SF ₆ gas compressed in the popper cylinder 104 as shown in FIG. 2C, and the breaker finally succeeds in breaking the fault current (actually, thermal recovery and insulation between the poles even after arc extinguishing). Only if the recovery was successful, the block was successful).

On the other hand, in order for the breaker as described above to interrupt the fault current and quickly recover the insulation between the poles, the breaker must be operated at a high speed and the distance between the poles sufficiently separated. At this time, if the inter-pole distance is increased to increase the insulation recovery between the poles, the stroke distance inevitably becomes long. If the stroke length becomes longer, the volume of the popper cylinder 104 also increases, and when the breaker is operated by the same operating force, the pressure rise in the popper cylinder 104 decreases, resulting in a failure current breaking performance.

On the other hand, in order to prevent a drop in pressure rise, the opening speed should be increased, but in order to increase the opening speed, there is a problem that the operating force of the manipulator must be greatly increased. However, in general, there is a limit in increasing the operating force of the manipulator. For example, the increase in operating force in a single manipulator is performed within 30%. Therefore, as the breaking capacity is increased, not only the breaking portion but also the manipulator may be larger.

The present invention was created in view of the above problems, and the bidirectional drive type gas circuit breaker capable of increasing the opening speed without changing the operating force or the external size of the manipulator and increasing the distance between the stroke and the pole without increasing the size of the breaker. The purpose is to provide.

1 is a schematic configuration diagram of a conventional paper extinguishing gas circuit breaker.

2a to 2c are views showing the arc extinguishing process of the paper extinguishing gas circuit breaker.

3 is a schematic diagram of a bidirectional driven gas circuit breaker according to the present invention;

Figure 4 (A) to (C) is a view showing the interaction relationship between the first, second link member and the second movable arc contact portion associated with the fault current blocking of the bi-directionally driven gas circuit breaker according to the present invention.

<Explanation of symbols for the main parts of the drawings>

101,301 ... cut-off 102 ... fixed arc contact

103,306 ... Movable arc contact 104,307 ... Popper cylinder

105,308 ... Nozzle 106,309 ... Piston

302.Operator 303.Fixed main contact

304 ... 2nd movable arc contact part 305 ... movable main contact part

310 ... first link member 311 ... second link member

312.Support member 313 ... Guide member

In order to achieve the above object, the bidirectional drive type gas circuit breaker according to the present invention includes a fixed main contact portion, a fixed arc contact portion, a movable main contact portion, a movable arc contact portion, and a papper for the conduction of normal current and the interruption of fault current. In the gas circuit breaker which has a block part which has a cylinder, a nozzle, and a piston, and the manipulator for operating the said block part,

Fixed arc contact portion moving means is provided between the movable main contact portion and the fixed arc contact portion to move the fixed arc contact portion in a direction opposite to the moving direction of the movable portion by using the moving force when the movable portion moves. There is a characteristic.

Here, the fixed arc contact portion moving means is a one end of the body is fixed to one side of the support member for supporting the movable main contact portion, a plurality of first link members for linear movement together in accordance with the movement of the movable portion; One end of the body is respectively connected to the plurality of first link members, and the other end of the body is respectively connected to the fixed arc contact portion, so that the linear kinetic force of the first link member is opposite to the direction of movement of the first link member. A plurality of second link members delivered to the fixed arc contact portion; And seesaw the second link member so that the linear kinetic force of the first link member can be transmitted to the fixed arc contact portion in a direction opposite to the movement direction of the first link member by the plurality of second link members. It is configured to include a plurality of support members for supporting the second link member to enable movement.

Preferably, the apparatus further includes a guide member stably guiding the movement of the fixed arc contact portion when the fixed arc contact portion is moved by the movement of the first and second link members.

According to the present invention as described above, by moving the fixed arc contact portion in the opposite direction at the same speed as the movable arc contact portion in accordance with the stroke of the cylinder rod of the blocking portion, it is possible to increase the opening speed and the inter-pole distance relative to the conventional breaker. .

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

3 is a schematic diagram of a bidirectional driven gas circuit breaker according to the present invention.

Referring to FIG. 3, the bidirectional-driven gas circuit breaker according to the present invention, like a general gas circuit breaker, includes a breaker 301 for blocking conduction and fault current of a normal current, and a manipulator for operating the breaker 301 ( 302).

The blocking part 301 has been described as a 'fixed arc contact part' in order to explain that the fixed main contact part 303 and the fixed arc contact part 304 (the components of the conventional blocking part are intact. In the present invention, since the conventional fixed arc contact portion is not fixed as in the related art, the movable arc contact portion is operated, which will be described later.), The movable main contact portion 305, and the movable portion. The arc contact portion 306, the popper cylinder 307, the nozzle 308 and the piston 309 are basically provided.

In addition, between the movable main contact portion 305 and the second movable arc contact portion 304, the second movable arc contact portion 304 is moved in a direction opposite to the moving direction of the movable portion by using the moving force when the movable portion moves. A second movable arc contact portion moving means is provided for moving in the.

Here, the second movable arc contact portion moving means is fixed to one side of the support member for supporting the movable main contact portion 305, one end of the body, a plurality of first links that linearly move together in accordance with the movement of the movable portion Member 310; One end of the body is connected to each of the plurality of first link members 310, and the other end of the body is connected to the second movable arc contact portion 304, respectively, to provide linear motion force of the first link member 310. A plurality of second link members 311 transmitting to the second movable arc contact portion 304 in a direction opposite to the movement direction of the first link member 310; And a linear momentum force of the first link member 310 by the plurality of second link members 311 to the second movable arc contact portion 304 in a direction opposite to the direction of movement of the first link member 310. It is configured to include a plurality of support members 312 for supporting the second link member 311 to enable the seesaw movement of the second link member 311 so as to be transmitted.

Preferably, when the second movable arc contact portion 304 moves by the movement of the first and second link members 310 and 311, the second movable arc contact portion 304 stably guides the movement of the second movable arc contact portion 304. It further comprises a guide member 313.

Only the movable part is moved to the plurality of first link members 310 until the movable part is moved by a predetermined distance, and after the predetermined distance is moved, the second movable arc contact part 304 is also simultaneously moved in the opposite direction to the movable part. Long holes 310h are formed to allow each, and one end of the second link member 311 is connected to the long hole 310h portion.

The second movable arc contact portion 304 is configured in the form of a pipe in which one end thereof is blocked, and the guide member 313 is installed to allow relative entry and exit into and out of the body of the pipe.

Then, the operation of the bidirectional-driven gas circuit breaker according to the present invention having the above configuration will be briefly described with reference to FIGS. 3 and 4.

In the normal state (state in which normal current flows), the main contact portions 303 and 305 and the arc contact portions 304 and 306 of the blocking portion 301 are in contact with or engaged with each other, that is, a state in which the circuit is closed. Normal current flows while maintaining. At this time, the first and second link members 310 and 311 and the second movable arc contact portion 304 are maintained as shown in FIG.

In the above state, when an error occurs in the power system and a fault current that reaches several times the normal current flows, the manipulator 302 operates to operate the primary movable portion of the breaker 301, that is, the popper cylinder 307 and the nozzle. 308, the movable arc contact portion 306 is pulled (from left to right in FIG. 3). Then, the SF ₆ gas inside the popper cylinder 307 is compressed by the piston 309, and the movable arc contact portion 306 and the second movable arc contact portion 304 are separated from each other as the primary movable portion moves. . As a result, an arc is generated between the movable arc contact portion 306 and the second movable arc contact portion 304. At this time, the generated arc is extinguished by blowing SF ₆ gas compressed in the popper cylinder 307, the breaker is finally successful in blocking the fault current.

In the above series of processes, when the primary movable portion moves, the first link member 310 having one end connected to one side of the supporting member supporting the movable main contact portion 305 also moves together (from the left side). To the right). Accordingly, the second link member 311 connected to the long hole 310h portion of the other end of the first link member 310 performs a relative sliding motion by the long hole 310h until the initial predetermined time, that is, the first link member Although the linear movement force of the 310 is not received, the linear movement force of the first link member 310 is transmitted to the second link member 311 from the time when the long hole 310h ends, so that the second link member 311 is The seesaw movement is performed with the support member 312 as an axis, and then the state is as shown in FIG. 4C. At this time, when the second link member 311 performs the seesaw movement with the support member 312 as an axis, that is, the connection side of the second link member 311 with the first link member 310 moves the support member 312. When the pivoting movement in one direction on the axis, the connecting side of the second link member 311 with the second movable arc contact portion 304 is pivoting in the opposite direction. As a result, the second movable arc contact portion 304 is pulled out (from left to right in FIG. 4) so that the separation (opening) speed of the second movable arc contact portion 304 and the movable arc contact portion 306 is Compared to the conventional two times, the inter-pole distance is also increased twice.

As described above, the bidirectionally driven gas circuit breaker according to the present invention uses a movable arc by connecting a fixed arc contact portion (second movable arc contact portion) according to the stroke of the cylinder rod of the breaker when the fault current is blocked. By moving in the opposite direction at the same speed as the contact part, the opening speed and the inter-pole distance can be increased relatively to further improve fault current interruption and insulation recovery performance.

Claims (5)

Blocking part having fixed main contact part, fixed arc contact part, movable main contact part, movable arc contact part, popper cylinder, nozzle and piston for the conduction of steady current and interruption of fault current, and manipulator for operating the breaker part In the gas circuit breaker having: Fixed arc contact portion moving means is provided between the movable main contact portion and the fixed arc contact portion to move the fixed arc contact portion in a direction opposite to the moving direction of the movable portion by using a moving force when the movable portion is moved. Bidirectional driven gas circuit breaker. The method of claim 1, wherein the fixed arc contact portion moving means, A plurality of first link members having one end of the body fixed to one side of the support member for supporting the movable main contact portion and linearly moving together as the movable portion moves; One end of the body is respectively connected to the plurality of first link members, and the other end of the body is respectively connected to the fixed arc contact portion, so that the linear kinetic force of the first link member is opposite to the direction of movement of the first link member. A plurality of second link members delivered to the fixed arc contact portion; And The seesaw movement of the second link member is enabled by the plurality of second link members so that the linear kinetic force of the first link member can be transmitted to the fixed arc contact portion in a direction opposite to the movement direction of the first link member. And a plurality of support members respectively supporting the second link members. The bidirectionally driven gas circuit breaker of claim 2, further comprising a guide member stably guiding the movement of the fixed arc contact portion when the fixed arc contact portion is moved by the movement of the first and second link members. . The method of claim 2, wherein only the movable portion is moved to the plurality of first link members until the movable portion is moved by a predetermined distance, and the fixed arc contact portion is simultaneously moved in the opposite direction to the movable portion after the predetermined distance is moved. A long hole for each is formed, one end of the second link member is a bidirectional drive gas circuit breaker, characterized in that connected to the long hole. The method of claim 1, The fixed arc contact portion is configured in the form of a pipe is closed at one end, the bidirectional drive type gas circuit breaker, characterized in that the guide member is installed to allow relative entry into and out of the pipe-shaped body.