KR100797982B1 - Disconnecting Switch - Google Patents

Abstract

The present invention configures a separate movable arc contactor inside the main contactor to maintain the speed of the drive drive, while moving only the movable arc contactor at high speed using the coil spring to reduce the damage range of the main contactor according to the arc current generation The present invention relates to a high voltage disconnector that can reduce the overuse of copper-tungsten.

The high voltage disconnector according to the present invention is electrically connected to the fixed contactor fixed in the axial direction (A) inside the metal enclosure filled with insulating gas, while the main contact is reciprocated in the axial direction (A) by a drive drive to provide electrical connection. A high-voltage disconnector for opening and closing, comprising: a fixed arc contactor fixed to the center of the inner diameter portion of the fixed contactor in the axial direction (A) and having a first conductor connected to the outside of the metal enclosure; A second conductor drawn in from the outside of the metal enclosure is connected, and moves in the axial direction (A) with the main contact in the center of the inner diameter of the main contact to contact the end of the fixed arc contact to the second conductor A movable arc contactor connected to the one conductor; A coil spring that surrounds the movable arc contact and is compressed by a limited length as the main contact moves in the separation direction from the fixed contact, and separates the movable arc contact from the fixed arc contact at high speed by the tensile force; A stop ring for determining a compression limit according to the compression length of the coil spring is provided.

Disconnector, fixed arc contactor, movable arc contactor, arc current, coil spring

Description

High Voltage Disconnector {Disconnecting Switch}

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the structure of the conventional high voltage disconnector.

2 is a diagram showing the structure of a high voltage disconnector according to the present invention;

3A to 3F are diagrams showing the operation of the high voltage disconnector of FIG.

Explanation of symbols on the main parts of the drawings

11: pinion gear 12: rack gear

13: main contactor 14: movable arc contactor

15: fixed contact 16: fixed arc contact

17: shield 18: coil spring

19: stop ring 20: copper-tungsten

The present invention relates to a high voltage disconnector, and more particularly, to a high voltage disconnector in which a main contactor and a fixed contactor are located inside a metal enclosure filled with SF ₆ gas (Gas), and the electrical contacts are opened and closed to enable energization. will be.

In general, a gas insulated switchgear (GIS) configured to protect the power system by safely opening and closing a line in an abnormal state such as an accident or a short circuit in a facility having a circuit having high voltage current such as a substation is usually used. It is composed of breaker, disconnector, ground breaker, etc. Among them, disconnector switch (DS) is a switchgear that requires continuous and repetitive opening and closing for the operation, maintenance and repair of power system.

1 is a view illustrating the structure of a conventional high voltage disconnector, in which a main contactor 3 and a fixed contactor 4 are positioned inside a metal enclosure filled with SF ₆ gas, as shown in FIG. To open and close the connected circuit.

The main contactor of the conventional high voltage disconnector finishes the copper-tungsten 6 on the main contactor 3, the shield 5, and the fixed contactor 4 by soldering, as shown in FIG.

The reason is that the general high voltage disconnector opens and closes the connected circuit by using a low speed motor drive drive. In the opening and closing process of the disconnector, an arc current 7 is generated between the main contactor 3 and the stationary contactor 4. The main contactor 3, the shield 5 and the stationary contactor 4 are melted. At this time, the slower the speed of the motor, the greater their losses due to the arc current (7). Thus, copper-tungsten materials capable of withstanding high temperatures are used to protect the main contacts in contact with each other to prevent surface damage.

However, the conventional high voltage disconnector is the main cause of the cost increase by using the high price copper-tungsten material for the protection of the main contactor, the shield, and the fixed contactor. There is a problem that (M / H) is increased.

In order to solve the above problems, 'Alstom' of France, in the low speed drive device, installs a spring inside the main contactor to increase the moving speed of the main contactor at high speed, thereby reducing the loss range of the main contactor due to the arc current. 'High voltage disconnector with moving contact moving at high speed' has been filed through Korean Patent Application No. 26494 dated May 17, 2000.

The high voltage disconnector of 'Alstom' filed in the low speed drive device installs a spring inside the main contactor to increase the moving speed of the main contactor at high speed to move the main contactor at high speed to reduce the damage of the main contactor by the arc current. To help.

However, the high voltage disconnector of 'Alstom' can amplify the moving speed of the main contactor to reduce the damage of the main contacts by the arc current, but a large size copper-tungsten is still used to reduce the damage range to the arc current. This is a major cause of cost increase, and the number of fingers per set is also a lot of production M / H is put into a problem that the defect rate is high.

Accordingly, an object of the present invention is to configure a separate movable arc contactor inside the main contactor to maintain the speed of the drive drive main contactor by moving only the movable arc contactor at high speed by using the coil spring to the main contactor according to the arc current generation It is to provide a high voltage disconnector to reduce the damage range of the copper to prevent excessive use of copper-tungsten.

In order to achieve the above object, the high voltage disconnector according to the present invention, the main contact is reciprocated in the axial direction (A) by the drive drive to the fixed contactor fixed in the axial direction (A) inside the metal enclosure filled with insulating gas A high voltage disconnector for electrically opening and closing the electrical contact while moving, the fixed arc contactor is fixed to the center of the inner diameter of the fixed contact in the axial direction (A) and connected to the first conductor drawn from outside the metal enclosure ; A second conductor drawn in from the outside of the metal enclosure is connected, and moves in the axial direction (A) with the main contact in the center of the inner diameter of the main contact to contact the end of the fixed arc contact to the second conductor A movable arc contactor connected to the one conductor; A coil spring that surrounds the movable arc contact and is compressed by a limited length as the main contact moves in the separation direction from the fixed contact, and separates the movable arc contact from the fixed arc contact at high speed by the tensile force; A stop ring for determining a compression limit according to the compression length of the coil spring is provided.

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

2 is a diagram showing the structure of a high voltage disconnector according to the present invention.

Referring to FIG. 2, the high voltage disconnector according to the present invention includes a metal enclosure (not shown) filled with an insulating gas, such as SF _6, and a fixed contactor fixed in the axial direction A within the metal enclosure. (15) and the shield 17 surrounding the fixed contact 15 to attenuate the potential difference of the electric field generated by the fixed contact 15 to form an equipotential surface, and an axial direction by a drive drive (not shown). It consists of a main contactor 13 which makes an electrical connection to the fixed contactor 15 while reciprocating to A) and performs opening / closing of electricity.

The metal enclosure is a sealed metal container whose ground is grounded, and is filled with an insulating gas such as SF ₆ having insulation and extinguishing functions to form a sealed insulating space.

The fixed contact 15 is a structure that is fixed in the axial direction (A) inside the metal enclosure, the fixed arc contact 16 is fixed in the axial direction (A) in the center of the inner diameter.

The fixed arc contact 16 is a connection terminal to which a first conductor (not shown) drawn in from the outside of the metal enclosure is connected, and the end of the fixed arc contact 16 is energized by contacting an end of the movable arc contact 14 described later. Copper tungsten 20 for absorbing the arc current generated between the movable arc contactor 14 and the fixed arc contactor 16 in the opening and closing process of the disconnector at the end of the fixed arc contactor 16 as shown in FIG. It is attached by soldering.

The drive drive issues an opening / closing command to the pinion gear 11 in the opening and closing process of the disconnector, and the pinion gear 11 rotates to rotate the rack gear 12 when the opening and closing command is received from the drive drive. When the pinion gear 11 and the rack gear 12 are operated by the command signal of the drive drive, the main contact 13 coupled to the rack gear 12 reciprocates in the axial direction A inside the metal enclosure. do.                     

The main contactor 13 is a structure coupled to the rack gear 12 and connected to the fixed contactor 15 while reciprocating in the axial direction (A) according to the opening and closing command of the drive drive. A movable arc contact 14 is provided.

The movable arc contactor 14 is a connection terminal to which a second conductor (not shown) drawn out of the metal enclosure is connected. The movable arc contactor 14 moves in the axial direction A together with the main contactor 13. By contacting the end of the fixed arc contact 16, the second conductor is connected to the first conductor and energized. Copper tungsten 20 for absorbing the arc current generated between the movable arc contactor 14 and the fixed arc contactor 16 in the opening and closing process of the disconnector at the end of the movable arc contactor 14 as shown in FIG. It is attached by soldering.

The movable arc contactor 14 is surrounded by a coil spring 18 that is compressed by a defined length as the main contactor 13 moves in a direction separated from the fixed contactor 15.

The movable arc contactor 14 moves in the axial direction A together with the main contactor 13 when the movable arc contactor 14 moves in the connection direction to the fixed contactor 15 by the command of the drive drive. The fixed arc contactor of the fixed contactor 15 is in contact with the fixed arc contactor 16 and separates from the main contactor 13 by the tension force of the coil spring 18 when moving in the separation direction from the fixed contactor 15. Separated from (16).

The coil spring 18 is returned to the original position of the inner diameter of the main contactor 13 instantaneously while the compressed force is changed to the tensile force when the compression limit point is reached, the movable arc contactor 14 is fixed by the tensile arc contactor ( 16) at high speed.                     

One end of the coil spring 18 surrounding the movable arc contact 14 is provided with a stop ring 19 coupled to the main contact 13 to determine a compression limit according to the compression length of the coil spring 18.

An operation process of the high voltage disconnector having the above configuration will be described with reference to the accompanying drawings.

3A to 3F are diagrams illustrating an operation process of the high voltage disconnector of FIG. 2.

First, when the connection command is issued from the drive drive of the disconnecting device, the pinion gear 11 rotates to rotate the rack gear 12. The rotation of the rack gear 12 causes the main contactor 13 and the movable arc contactor 14 to rotate. It moves in the axial direction A, is connected to the fixed contactor 15 and the fixed arc contactor 16, and is energized as shown in FIG. 3A.

In this state, when the separation command is issued from the drive drive, the pinion gear 11 rotates to rotate the rack gear 12, and the main contact 13 is rotated by the rotation of the rack gear 12, as shown in FIG. 3B. It is separated from the fixed contactor 15 by primary movement in the opposite direction at the time of input, that is, in the separation direction.

The separation process of the main contactor 13 proceeds as shown in FIG. 3C without stopping, where the main contactor 13 is separated from the fixed contactor 15, but the movable arc contactor 14 is still fixed. It is connected to the arc contact 16 and is energized.

Subsequently, the separation process of the main contactor 13 proceeds 3rd as shown in FIG. 3D, where the main contactor 13 reaches the compression limit point of the coil spring 18 surrounding the movable arc contactor 14. The retractable arc contactor 14 is connected to the fixed arc contactor 16 but is energized continuously in the separation direction.

When the main contactor 13 is separated to the compression limit point of the coil spring 18, the compressed force of the coil spring 18 is changed to the tension force and is returned to its original state instantaneously, and the movable arc contactor 14 is caused by the tension force. Is separated at high speed from the fixed arc contact 16 as shown in FIG. 3E.

At this time, an arc current is generated in the process of separating the movable arc contactor 14 and the fixed arc contactor 16, but the coil spring 18 is instantaneously shown in FIG. It returns to the original position of the inner diameter part of the main contactor 13 at high speed.

Although the movable arc contactor 14 is separated from the fixed arc contactor 16 at high speed, the generated arc current is inevitable, and the generated arc current is the end of the fixed arc contactor 16 as partially enlarged in FIG. And copper tungsten 20 attached to each end of the movable arc contactor 14 by soldering to damage the fixed arc contactor 16 and the movable arc contactor 14 against hot heat generated by the arc current. prevent.

In addition, when the disconnector is inserted again, as shown in FIG. 3A, the main contactor 13 and the movable arc contactor 14 are simultaneously introduced into the fixed contactor 15. At this time, an arc current is generated, and the generated arc current is absorbed by the copper-tungsten 20 attached to the ends of the movable arc contactor 14 and the fixed arc contactor 16 as in the case of separation.

Accordingly, the main contactor 13 is separated at a low speed in the high voltage disconnector in which the opening and closing operation is performed by the low speed drive drive according to the present invention, but the movable arc contactor 14 is compressed before the arc current is generated and then the arc current is generated. It is only necessary to absorb a very small amount of arc current in the copper-tungsten 20 attached to these ends by being separated at a high speed from the fixed arc contact 16 by the coil spring 18 which is tensioned momentarily.

What has been described above is only one embodiment of the high voltage disconnector according to the present invention, anyone skilled in the art to which the present invention belongs to the technical spirit of the present invention to the extent that various changes can be made. will be.

As described above, the high voltage disconnector according to the present invention has the following effects.

First, by attaching a small amount of copper-tungsten absorbing the arc current to the end of the movable arc contactor and the fixed arc contactor, there is an effect of reducing the production cost of the high-cost copper-tungsten.

Second, by reducing the damage range of the main contactor caused by the arc current to secure the reliability of the disconnecting device to prevent accidents of the power system, it has the advantage of reducing the maintenance cost by extending the replacement cycle of the disconnecting device.

Claims (2)

In a high-voltage disconnector for opening and closing the current through the electrical connection to the fixed contactor fixed in the axial direction (A) inside the metal enclosure filled with insulating gas in the axial direction (A) by the drive drive. , A fixed arc contactor fixed to the center of the inner diameter portion of the fixed contactor in an axial direction (A) and to which a first conductor drawn out of the metal enclosure is connected; A second conductor drawn in from the outside of the metal enclosure is connected, and moves in the axial direction (A) with the main contact in the center of the inner diameter of the main contact to contact the end of the fixed arc contact to the second conductor A movable arc contact for connecting to one conductor; A coil spring that surrounds the movable arc contact and is compressed by a limited length as the main contact moves in the separation direction from the fixed contact and separates the movable arc contact from the fixed arc contact at high speed by the tensile force; And And a stop ring for determining a compression limit according to the compression length of the coil spring. The method according to claim 1, wherein the fixed arc contactor and the movable arc contactor, A high voltage disconnector, wherein copper-tungsten is attached by soldering to ends thereof in contact with each other.

Images