JPH0743986B2 - Puffer type gas circuit breaker - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Object of the Invention (Field of Industrial Application) The present invention relates to a puffer type gas circuit breaker used in a substation or a switching station of a power system.

(Prior Art) With the recent increase in capacity of power transmission systems, the breaking capacity of circuit breakers used in substations and switchyards has increased, and high reliability is required. In order to improve the reliability of such a circuit breaker, it is important to reduce the number of parts and simplify the structure. Therefore, the number of circuit breakers has been reduced. That is, it is desired to increase the breaking capacity per point of the breaker.

Thus, in order to improve the breaking performance in the conventional general puffer type gas circuit breaker, it is necessary to increase the gas pressure in the puffer chamber. For example, in the current 550KV system, a breaking current of 63KA has been put into practical use. This 550KV-63KA
Although the class circuit breaker is composed of four points, it is important to reduce the number of circuit breaks and the number of parts in order to improve the reliability of the circuit breaker.

In order to achieve such an improvement in breaking capacity, conventional 168KV
What has been used in the above transmission voltage system is a so-called puffer type gas circuit breaker in which an insulating gas is blown to extinguish the arc. This has a simple structure of the breaker and has excellent insulation and arc extinguishing performance due to the enclosed SF ₆ gas. Also, in a closed gas-insulated switchgear that insulates the entire equipment of the substation with SF ₆ gas, the insulating gas used can emphasize the insulation between the circuit breaker and other equipment, and the efficiency of the equipment arrangement is high. It's good and is especially well used.

FIG. 4 and FIG. 5 show the structure of a puffer type gas circuit breaker which has been conventionally used.

That is, as shown in FIG. 4, the fixed electrode 2 and the movable electrode 3 are provided in the gas tank 1 so as to face each other, and the insulating cylinder 4 is provided so as to surround the outside of both electrodes. Further, conductors 5 and 6 are respectively connected to the fixed electrode 2 and the movable electrode 3, and a drive device 7 for driving the movable electrode is further connected to the movable electrode 3. The movable electrode 3 is attached to the gas tank 1 via a supporting insulating cylinder 10.

The arc-extinguishing chamber of the puffer type gas circuit breaker as described above is constructed as shown in FIG. That is, the fixed electrode 2
Is composed of a fixed arc electrode 8 provided in the center thereof and a cylindrical fixed current-carrying electrode 9 provided outside thereof. On the other hand, the movable electrode 3 is composed of a puffer cylinder 12 fixed to a hollow operation rod 13, a movable arc electrode 14 and an insulating nozzle 15 surrounding the movable arc electrode 14. A puffer piston 11 fixed to a fixing portion (not shown) is arranged in the puffer cylinder 12, and a puffer chamber 17 is formed by the puffer cylinder 12 and the puffer piston 11.
Are formed.

In the conventional puffer-type gas circuit breaker configured in this way, when the operating rod 13 reciprocates left and right in the figure by the drive device 7, the movable electrode 3 opens and closes with the fixed electrode 2 facing it, Cut off the current. Here, FIG. 5 shows a state during the breaking operation, and in this state, an arc 16 is generated between the fixed arc electrode 8 and the movable arc electrode 14. And the puffer cylinder 12
Moves to the right in the figure, and when the arc-extinguishing gas is compressed in the puffer chamber 17 formed by the puffer cylinder 12 and the puffer piston 11, this arc-extinguishing gas flow causes the insulating nozzle 15
Guided by and blown onto the arc 16, it extinguishes it.

By the way, in the puffer type gas circuit breaker having the above-mentioned structure, it is necessary to increase the opening speed in order to improve the arc extinguishing performance while the voltage per breaking point is increasing. For that purpose, the driving force of the driving device 7 must be increased, and the size of the entire device is increased, resulting in a high cost.

Therefore, in recent years, the double-motion type circuit breaker in which the relative opening speed is increased by moving the fixed electrode 2 in the direction opposite to the moving direction of the movable electrode 3 without changing the driving force of the driving device. Is used. This double motion type circuit breaker is, for example, as shown in FIG.
The second movable electrode 23, which is arranged to face the first movable electrode 3, is
The movable electrode 3 moves in a direction opposite to the moving direction. That is, on the outer circumference of the puffer cylinder 12, a plurality of insulating rods are kept at a certain distance from the puffer cylinder 12.
29 are provided. The insulating rod 29 is connected to the operating rod 13 at a drive device side end thereof via a link device 18 provided between the insulating rod 29 and the operating rod 13.
This link device 18 includes first and second connecting rods 18b and 18c and a link 1 which are rotatably connected to both ends of a link 18a.
It is composed of a link support portion 18d that supports 8a. Further, the link 18a is rotatably supported by the link support portion 18d about a fulcrum 18e of the link support portion 18d set to a predetermined link ratio. Furthermore, the first and second connecting rods
18b and 18c respectively have the operation rod 1 at one end thereof.
3, rotatably connected to the insulating rod 29. In addition,
The link support portion 18d is fixed to an insulating cylinder 19 that is fixed to a container (not shown) by insulation. On the other hand, the end of the insulating rod 29 on the side opposite to the drive unit is coaxial with the energizing cylinder 20.
The energizing cylinder 20 is configured to slide in the energizing portion 21a of the energizing conductor 21 supported and fixed on the side opposite to the driving device. A second movable arc electrode 22 is provided on the drive device side axis of the energizing cylinder 20, and a second movable electrode 23 for performing opening / closing operation is formed with the first movable electrode 3.
6 shows the puffer type gas circuit breaker in the closed state, in which the first movable electrode 3 and the second movable electrode 23 are in contact with each other.

In the conventional puffer type gas circuit breaker having the above structure, the breaking operation is performed as follows. That is, when the drive device is operated in the closed state shown in FIG. 6, the operation rod 13 is driven to the drive device side (right direction in the figure) at a predetermined speed, and the first movable member fixed to the tip thereof. Electrode 3
Moves to the right, and the blocking operation is started with the second movable electrode 23. On the other hand, with the operation of the operating rod 13,
The first connecting rod 18b connected to the operating rod 13 also moves in the same direction. Further, since a force in the same direction is also applied to one end of the link 18a, the link 18a rotates counterclockwise about the fulcrum 18e. As a result, the other end of the link 18a rotates to the left in the figure, so that the second connecting rod 18 connected to the same portion is rotated.
c moves to the left in the figure, and the insulated rod 2 connected to this
9 also moves to the left in the figure. Therefore, the second movable electrode 23 fixed to the insulating rod 29 also moves to the left in the drawing to move the first movable electrode 23 to the first movable electrode 23.
It dissociates from the movable electrode 3 and shifts to the open state as shown in FIG. That is, both the first movable electrode 3 and the second movable electrode 23 move in opposite directions (blocking directions) with the opening operation of the operating rod 13.

Further, the closing operation is similarly performed by driving the operating rod 13 in the direction opposite to the above-mentioned shut-off operation. That is, when the operation rod 13 is moved leftward in the figure at a predetermined speed in the cutoff completion state of FIG. 7, the first movable electrode 3 fixed to this is the contact direction with the second movable electrode 23. The link 18a rotates clockwise through the first connecting rod 18b while moving in the center left direction. As a result, the second connecting rod 18c moves to the right in the drawing, and the insulating rod 29 and the second movable electrode 23 move to the right in the drawing, which is the direction of contact with the first movable electrode 3, and the closing state is established. Become.

(Problems to be Solved by the Invention) By the way, in the high voltage circuit breaker for driving the second movable electrode in the direction opposite to the first movable electrode as described above, the second movable electrode is a driving device on the first movable electrode side. Driven by. Therefore, when the lengths of the plurality of insulating rods 29 that drive the second movable electrode are non-uniform or the mounting positions are displaced, the force applied to the second movable electrode becomes unbalanced. 2 Unnecessary force such as rotational force is applied to the movable electrode. Therefore, the second movable electrode cannot normally perform the opening / closing operation, and the opening / closing performance of the circuit breaker may be deteriorated.

The present invention has been proposed in order to solve the above-mentioned problems of the prior art, and an object thereof is to support the second movable electrode in a stable state and perform the opening / closing operation with high accuracy. It is to provide a puffer type gas circuit breaker.

[Structure of the Invention] (Means for Solving the Problem) The present invention has first and second movable electrodes in which a first movable movable electrode and a second movable movable electrode are arranged to face each other in a container in which an arc extinguishing gas is sealed. The electrode and the puffer cylinder are fixed to one end of an operating rod connected to a drive device, and the arc extinguishing gas in the puffer cylinder is compressed by a puffer piston arranged in the puffer cylinder. In a puffer-type gas circuit breaker, which is jetted as a high-speed gas flow from an insulating nozzle fixed to and is blown to an arc generated between the opposing arc electrodes to extinguish the arc, the puffer-type gas circuit breaker is electrically connected to the second movable electrode. A flange formed on the second movable electrode side of the current-carrying conductor supported by the fixed portion has a through hole through which an insulating rod for driving the first and second movable electrodes in opposite directions slides, A ring is attached in the through hole, and a portion where the insulating rod slides with the ring is made of metal.

(Operation) According to the puffer type gas circuit breaker of the present invention, the first and second
An insulating rod that drives the movable electrodes in opposite directions is opened and closed while being inserted and supported in a through hole formed in a flange formed on the second movable electrode side of the conducting conductor supported by the fixed portion. Therefore, the opening / closing operation of the second movable electrode is stabilized. Further, since the ring is arranged in the through hole and the sliding portion of the insulating rod is also made of metal, the sliding resistance is small.

(Embodiment) An embodiment of the present invention will be specifically described below with reference to FIGS. 1 to 3. Further, the same members as those of the conventional type shown in FIGS. 4 to 7 are designated by the same reference numerals, and the description thereof will be omitted.

In this embodiment, as shown in FIG.
A current-carrying conductor 31 is coaxially arranged on the tip side of 29, and is supported by a fixed portion (not shown). This conducting conductor
A current-carrying portion 31a is provided on the driving device side (right end portion in the figure) of 31 via a flange 32, and is electrically connected to the current-carrying conductor 31. In addition, the insulating rod 29
A plurality of through holes 32a are provided at positions corresponding to, and rings 36 are provided in the through holes 32a, respectively.
On the other hand, at the end of the insulating rod 29 on the side opposite to the drive unit side,
A metal part 29a is formed. The metal portion 29a of the insulating rod 29 is slidably disposed in the ring 36 disposed in the through hole 32a. The metal part 29a is
It is configured to be longer than the moving stroke length of the second movable electrode 23.

A second movable shield 34 is coaxially supported via a flange 33 inside the end of the insulating rod 29 opposite to the drive unit, and the outer surface of the second movable shield 34 is in contact with the current-carrying portion 31a. ing. Further, the second movable arc electrode 22 is supported on the central portion of the flange 33 by a plurality of ribs 35. In the cutoff completion state shown in FIG. 2, the distance between the flange 32 of the current-carrying conductor 31 and the flange 33 that supports the second movable arc electrode 22 is determined by the insulating rod 29.
Is set longer than the total movement stroke length of.

In the puffer type gas circuit breaker of this embodiment having such a configuration, when the opening operation is started in response to the breaking command in the closing state as shown in FIG. Move to the middle right). Then, as shown in FIG. 2, when the operating rod 13 operates, the puffer cylinder 12 attached to the operating rod 13 moves in the same direction as the operating rod 13. At the same time, the puffer chamber 17 constituted by the puffer cylinder 12 and the puffer piston 11 starts to be compressed. On the other hand, as the operating rod 13 moves, the link
18a rotates, and the insulating rod 29 moves leftward in the figure.
Then, the second movable shield 34 and the second movable arc electrode 22 attached to the flange 33 fixed to the other end of the insulating rod 29 also move leftward in the figure. At this time, the insulating rod 29
As shown in FIG. 3, the metal portion 29a provided on the sliding member slides on and is supported by the ring 36 disposed on the through hole 32a formed on the flange 32, and is opened and closed.

Thus, in this embodiment, the insulating rod 29 is the flange of the conducting conductor 31 supported by the fixed portion during the opening / closing operation.
Since it moves in the through hole 32a provided in 32 while sliding with the ring 36 arranged inside thereof, the second movable electrode is always supported in a stable state, and the force applied to the second movable electrode is It does not become non-uniform, and unnecessary force such as rotational force is not applied to the second movable electrode. Further, since the tip of the insulating rod is made of metal, sliding resistance when sliding on the ring in the through hole is small.

[Effects of the Invention] As described above, according to the present invention, the insulating rod that drives the first and second movable electrodes in opposite directions slides on the flange of the conducting conductor supported by the fixed portion. The second movable electrode is supported in a stable state by a simple means in which a through hole is formed, a ring is attached in the through hole, and a portion where the insulating rod slides with the ring is made of metal. It is possible to provide a puffer type gas circuit breaker capable of performing the opening / closing operation with high accuracy.

[Brief description of drawings]

FIG. 1 is a sectional view showing a closed state of an embodiment of the puffer type gas circuit breaker of the present invention, FIG. 2 is a sectional view showing a breaking operation, and FIG. 3 is a sectional view taken along the line AA of FIG. FIG. 4 is an external view of a circuit breaker accommodating an arc extinguishing chamber of a conventional puffer type gas circuit breaker, FIG. 5 is a sectional view showing the arc extinguishing chamber of the puffer type gas circuit breaker, and FIG. 6 is a double motion type. FIG. 7 is a sectional view showing a closed state of the circuit breaker, and FIG. 7 is a sectional view showing a closed state of the double motion type circuit breaker. 1 ... gas tank, 2 ... fixed electrode, 3 ... movable electrode,
4 ... Insulating cylinder, 5,6 ... Conductor, 7 ... Driving device, 8 ...
Fixed arc electrode, 9 ... Fixed energizing electrode, 10 ... Supporting insulating cylinder, 11 ... Puffer piston, 12 ... Puffer cylinder, 13 ... Operating rod, 14 ... Movable arc electrode, 15 ...
Insulation nozzle, 16 …… Arc, 17 …… Puffer chamber, 18 ……
Link device, 18a ... Link, 18b ... First connecting rod, 18
c ... second connecting rod, 18d ... link support, 18e ... fulcrum, 19 ... insulating cylinder, 20 ... current-carrying cylinder, 21 ... current-carrying conductor,
21a ...... current-carrying part, 22 ... second movable arc electrode, 23 ... second movable electrode, 29 ... insulating rod, 29a ... metal part, 31 ...
… Conductive conductor, 31a… Conductive part, 32… Flange, 32a…
… Through hole, 33 …… Flange, 34 …… Second movable shield,
35 …… rib, 36 …… ring.

Claims (1)

[Claims] 1. An operating rod in which a first movable electrode and a second movable electrode which are freely contactable and separable are arranged to face each other in a container filled with an arc extinguishing gas, and the first movable electrode and a puffer cylinder are connected to a drive unit. The arc-extinguishing gas in the puffer cylinder is compressed by the puffer piston arranged in the puffer cylinder, and the compressed gas is ejected as a high-speed gas flow from the insulating nozzle fixed to the puffer cylinder. In a puffer-type gas circuit breaker for extinguishing an arc generated between the opposing electrodes by extinguishing the arc, the second movable conductor electrically connected to the second movable electrode and supported by a fixed portion. A flange formed on the electrode side is formed with a through hole in which an insulating rod for driving the first and second movable electrodes in opposite directions slides, and a ring is attached in the through hole. Puffer type gas circuit breaker, wherein an insulating rod is composed of metal parts sliding the ring.