KR200377715Y1 - A Connecting Device Between Cubicle Type SF6 Gas Insulated Switchgear And Vacuum Interupter - Google Patents

Abstract

The present invention relates to a connection device of a cubicle type SF6 gas switchgear breaker and a vacuum interrupter, and a conventional connection device of the breaker of a gas switchgear and a vacuum breaker using a shunt. In order to operate by using multi-band, the gas distribution panel can be miniaturized, and the Wipe Spring is directly configured on the movable part of the vacuum circuit breaker to reduce the link point, and also the important function related to the blocking function. The connection structure of the vacuum circuit breaker is simplified and the safety can be improved.

Description

A connecting device between cubicle type sf6 gas insulated switchgear and vacuum interupter

The present invention relates to a vacuum interrupter (Vacuum interrupter) of the cubicle type SF6 gas switchgear breaker, and more particularly, the breaker was configured by arranging a vacuum breaker using a shunt (shunt) in the breaker of the conventional gas switchgear, It is configured to be driven using multi band, so that the gas switchboard can be miniaturized, and the wipe spring is directly configured on the movable part to reduce the link point, and also the vacuum breaker which is importantly related to the blocking function. This invention relates to a vacuum circuit breaker of a gas insulated switch gear breaker that simplifies the connection structure and improves safety.

FIG. 1 shows a structure of a conventional gas switchboard breaker, which is composed of a vacuum breaker 1, a breaker mechanism 2, an opening / closing shaft 3, a wipe spring, and a flexible shunt 5. .

FIG. 2 illustrates a link connection portion of a conventional gas switchboard blocker, and FIG. 3 is a detailed view of the link connection portion of FIG. 2.

FIG. 4 shows a vacuum circuit breaker of the gas switchboard breaker and includes a movable part 16 and a fixed part 16.

5 shows a connection structure of a conventional vacuum circuit breaker, in which a wipe spring 6 is assembled to a link connected to an opening / closing shaft 3 and an opening / closing shaft lever 14 welded to the opening / closing shaft 3. The lever 14 to the driving part of the vacuum circuit breaker 1 are connected by two shafts 9 and 12 and links 7, 8, 10 and 11, which are links 7, 8, 10 and 11. Using the ratio of the length and the lever ratio, the movable part of the contact of the vacuum circuit breaker 1 moves up and down to perform an on / off function as a circuit breaker.

6 is a detailed view showing a link connection structure when the conventional vacuum circuit breaker is opened. The opening / closing shaft lever 14, the wipe spring 6, and the link lever 1 (7) move downward and are centered on the shaft A (9). When the link lever 2 (8) pulls the link link 10, the triangular lever part 11 moves upwardly about the axis B 12, which rotates the inner straight groove of the lower holder 15. Therefore, the sliding pin 18 is switched to the linear motion to move the movable portion of the vacuum circuit breaker 1 to the input position.

These series of motions transfer the kinetic energy generated from the shutoff driving mechanism in an instant and operate with the vacuum circuit breaker input. The movement from the vacuum breaker input state to the open state proceeds in the reverse direction.

  As such, the breaker of the conventional gas switchgear has a complicated connection distance from the wipe spring to the vacuum circuit breaker, which leads to a cost increase because the size of the product cannot be miniaturized, and the pressing force of the wipe spring delivered to the vacuum circuit breaker is connected to the link. It had the disadvantage of being connected and relatively inconsistent.

In addition, the flexible shunt is connected to the movable part of the vacuum breaker and the fixed busbar on the load side, and the moving distance when the vacuum breaker is opened and closed is absorbed as the flexible shunt is bent. It can be bent or moved by, and it is not stable due to the risk of breaking due to intensive stress applied to the bent part due to the continuous opening / closing action, and the space required to secure the insulation distance increases, resulting in the overall switch gear There was a problem that the size is increased.

Therefore, the present invention, for the connection structure of the vacuum interrupter of the cubicle type SF6 gas insulated switchgear breaker, by using a multi-band according to the present invention in place of the existing shunt among the breaker components, The purpose of the present invention is to provide a pressurizing force of the spring directly to the vacuum circuit breaker so that a stable pressing force can be given and a complicated link configuration can be eliminated to reduce the size of the breaking part.

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

      Figure 5 shows the connection structure of the vacuum circuit breaker according to the present invention as a blocking mechanism, the energy of the vacuum circuit breaker 20, the blocking drive mechanism and the operation unit 21, the vacuum circuit breaker contact on and off from the blocking drive mechanism It is composed of a driving opening and closing shaft 22, a wipe spring 23 that can directly apply pressure to the upper part of the vacuum circuit breaker moving part, and a multi-band 24 used as a substitute for the shunt. .

 Multi band 24 is an abbreviation of LA-CU Multilam Contact Band and is also a product name of Multi-Contact AG of Germany. The multi-band is a connection of a plurality of copper contact plates between two elongated strips of stainless material, as shown in Figures 17 and 18, used as an electrical transmission material, high electrical conductivity and high It has the features of wear resistance, heat resistance, etc., and it is a part that is used as an industrial electrical transmission material to transfer current by contact and separation.

Figure 9 shows the connection structure when opening the vacuum circuit breaker incorporating the multi-band according to the present invention and Figure 10 shows the connection structure when the vacuum circuit breaker input.

11 and 12 are detailed views of the connection structure of the vacuum circuit breaker according to the present invention, in which the rotational movement of the cam rod 28 and the actuating rod 29 for driving the cam link 28 to the main shaft 1 are linear. A guide pin 30 for converting to a movement is connected, and a sliding multi-band that fixes a vacuum circuit breaker to it, a bolt guide 31 for helping linear movement, and a multi-band fixing and sliding upon opening and closing the vacuum circuit breaker. It consists of 32, the fixed multiband 33 which connects a movable part and a movable shaft bus bar, and the electrically conductive material 34. As shown in FIG.

On the other hand, since the description of the contact driving device or the contact pressing structure and the various mechanisms of the blocking driving mechanism is already known, the description thereof will be omitted. Here, as shown in FIGS. 11 and 12, when the blocking mechanism is driven on and off. It is assumed that the main shaft 27 produces a 45 degree rotational movement.

 When the main shaft 27 is rotated while the circuit breaker is turned on by operating the cutoff driving mechanism, the operation rod 29 makes a linear motion to the right, and the cam link 28 moves in the same direction as the main shaft 27. It will rotate.

The rotational movement of the guide pin 30 pushes the wipe spring downward along the guide of the cam link 28, in which the sliding multi-band 32 makes a linear movement along the sliding surface of the fixed multi-band 33. Thus, the vacuum circuit breaker movable part 25 is moved to the injection position.

These series of motions transfer the kinetic energy generated from the shut-off driving mechanism in an instant and operate with the vacuum circuit breaker input. Movement from the vacuum breaker input state to the open state proceeds in the reverse direction.

  FIG. 13 shows the state of the multi band when the vacuum circuit breaker is opened, and FIG. 14 shows the state of the multi band when the vacuum circuit breaker is opened.

FIG. 15 shows the state when the vacuum circuit breaker is inserted and FIG. 16 shows the state when the vacuum circuit breaker is opened.

 In the case of the cue type SF6 gas insulated switchgear using the device of the present invention, the SF6 gas insulated medium is used, which has the advantage of superior insulation and stability and reduced installation area compared to the general air switchgear. By eliminating the shunt from the existing vacuum circuit breaker connection structure, the device simplifies the connection structure, and is stable to external influences such as electromagnetic force, gravity, or vibration generated during a short circuit, and further reduces the size.

In addition, it is possible to apply the pressing force to the wipe spring directly and vertically without connecting the link, which not only provides a stable pressing force to the vacuum breaker, but also reduces the material requirements and minimizes the installation area. Make great expectations.

1 is a view showing the structure of a conventional SF6 gas switchboard blocker

2 is a view showing a link connection of a conventional device

3 is a detailed view of FIG.

4 shows the structure of a vacuum circuit breaker;

5 is a view showing a connection structure of a conventional vacuum circuit breaker

6 is a detailed view showing a link connection structure when a conventional vacuum circuit breaker is opened;

7 is a detailed view showing a link connection structure when a conventional vacuum circuit breaker is inserted;

8 is a view showing the structure of the SF6 gas switchboard block of the subject innovation

9 is a view showing a connection structure when opening the vacuum circuit breaker of the present invention

10 is a view showing a connection structure when the vacuum circuit breaker of the present invention

11 is a view showing a vacuum circuit breaker connection structure of the present invention

12 is a detailed view of FIG.

13 is a view showing a vacuum breaker opening time using a multi-band according to the present invention

14 is a view showing a vacuum circuit breaker using the multi-band according to the present invention

15 is a detailed view when the vacuum circuit breaker according to the present invention

16 is a detailed view when opening the vacuum circuit breaker according to the present invention

17 is a view showing a multi-band of the present invention

18 is a view showing the assembled state of the multi-band of the present invention

Explanation of symbols on the main parts of the drawings

1,20: Vacuum circuit breaker 2,21: Mechanism part of switchboard breaker

3,22: opening and closing shaft 4,6,23: wipe spring

5: shunt 7: link lever 1

8: link lever 2 9: axis A

10: connecting link 11: triangular lever parts

12: shaft B 14: open and close shaft lever

15: low side holder 16, 25: vacuum breaker moving part

17, 26: vacuum circuit breaker fixing portion 18: sliding pin

24: Multiband 27: Spindle

28: cam link 29: operating rod

30: guide pin 31: bolt guide

32: sliding multiband 33: fixed multiband

34: Challenger

Claims (2)

In the connecting device of the cubicle type SF6 gas switchgear breaker and the vacuum breaker including a breaker mechanism, an opening / closing shaft and a wipe spring, Cubicle type SF6 gas switchgear breaker and vacuum, characterized by using a sliding multiband, a fixed multiband and a multiband consisting of a conductive material instead of the conventional shunt connecting the wipe spring of the opening / closing shaft and the driving part of the vacuum circuit breaker. Breaker connections. 2. The connecting device of a cubicle type SF6 gas switchgear breaker and a vacuum breaker according to claim 1, wherein the sliding multiband slides up and down to directly apply a pressing force of the wipe spring to the movable part of the vacuum breaker.