JPH0797465B2 - Puffer type gas breaker - Google Patents

Description

Description: TECHNICAL FIELD OF THE INVENTION The present invention relates to a puffer type gas circuit breaker for compressing an arc-extinguishing gas and blowing it to an arc by relative motion between a puffer piston inserted in a puffer cylinder and a movable piston. It is about.

[Technical background of the invention and its problems] A puffer piston or a movable piston in which a pair of electrodes are supported in a container in which an arc extinguishing gas such as SF ₆ gas is sealed and which are inserted into the puffer cylinder at the same time when the electrodes are opened and closed. Move
This relative motion compresses gas, blows this gas through a nozzle provided between electrodes to create a high-speed gas flow, and blows this gas to an arc to cut off the puffer-type gas circuit breaker, which is a high-voltage region. It has become the mainstream of high-voltage circuit breakers today because of its excellent circuit breaking performance, and its simpler structure and smaller size than double-pressure circuit breakers.

FIG. 3 shows the basic structure of the puffer type gas circuit breaker in the vicinity of the arc extinguishing chamber.

In the puffer type gas circuit breaker shown in the figure, the puffer cylinder is attached to the operation rod and also serves as a movable piston. In the figure, 1 is a fixed electrode, 2 is a movable electrode, and the movable electrode 2 is connected to a drive unit via an operating rod 3. The puffer cylinder 4 provided on the outer periphery of the operation rod 3 is fixed to the operation rod 3 on the fixed electrode side thereof, and forms a puffer chamber with the puffer piston 5 fixed to a container (not shown). A nozzle 6 is provided around the movable electrode 2, and the nozzle 6
Is also fixed to the operating rod. In the figure, 7 is a shield for the fixed electrode 1, and 8 is a gas flow path formed between the movable electrode 2 and the nozzle 6.

In the puffer type gas circuit breaker of such a system, the gas is compressed by the relative movement of the puffer cylinder 4 and the puffer piston 5 at the same time when the opening operation is started, and this compressed gas is generated between the movable electrode 2 and the nozzle 6. The gas is discharged via the gas passage 8. However, since a sufficient gap length is required to withstand the transient recovery voltage after interruption, the blowing gas in the initial stage of the contact opening process not only does not effectively act on interruption, but also reduces the rise in gas pressure. This is also a drawback because it leads to a reduction in arc extinguishing performance.

FIG. 4 is proposed to compensate for this drawback.
In this system, the puffer cylinder 4 is the puffer piston 5
The movable piston 9 is independently provided and fixed to the operation rod 3. Similarly, an intermediate piston 10 fixed to the operation rod 3 is inserted in the puffer cylinder 4, and the intermediate piston 10 compresses gas. The puffer cylinder 4 has a large-diameter portion on the contact side with the puffer piston 5, and when the intermediate piston 10 reaches this portion, compressed gas is generated through a gap formed between the outer periphery of the intermediate piston 10 and the puffer cylinder 4. The gas is discharged and guided to a gas flow path 8 provided between the movable electrode 2 and the nozzle 6 via a gas flow path 11 provided between the intermediate piston 10 and the movable piston 9.

In this system, compression is performed without releasing gas until the intermediate piston 10 reaches the large-diameter portion of the puffer cylinder 4, so that the compression rate is high and therefore the blocking performance is improved. However, in order that the tip of the puffer cylinder 4 has a sufficient gap length with the tip of the shield 7 on the fixed side, the movable piston 9 has a shape retracted outward from the movable electrode 2 toward the puffer piston 5 side. Therefore, the axial length can be increased. In the open state,
The intermediate piston 10 reaches the puffer piston 5, but the movable piston 9 must not reach the large diameter portion of the puffer cylinder 4, so a certain distance or more is required between the movable piston 9 and the intermediate piston 10. Therefore, the length in the axial direction is inevitably longer than that of the conventional puffer type gas circuit breaker, and therefore the distance between the terminals of the circuit breaker is increased.

[Object of the invention] The present invention has been proposed in order to solve the above-mentioned drawbacks of the prior art, and an object thereof is to make it possible to provide an intermediate piston without extending the axial distance. Accordingly, it is an object of the present invention to provide a puffer type gas circuit breaker having improved circuit breakage performance and a reduced distance between terminals of the circuit breaker.

[Summary of the Invention] In the puffer type gas circuit breaker of the present invention, an insulating cylinder covering the electrodes is provided between the puffer piston and the fixed electrode side, one end of this insulating cylinder is fixed to the puffer piston, and the other end is fixed. The insulating cylinder is fixed to a fixed electrode, and a recess that forms a gap between the insulating cylinder and the intermediate piston is formed at the end of the insulating cylinder on the puffer piston side. It is characterized in that it is configured so as to be movable from the non-formation area of the recess to the formation area of the recess.

With such a configuration, the arc extinguishing chamber can be configured with the same axial length as that of the conventional puffer type gas circuit breaker while providing the intermediate piston.

[Embodiment of the Invention] FIG. 1 shows an embodiment of the puffer type gas circuit breaker of the present invention as described above.

In the figure, an arc extinguishing gas such as SF ₆ gas is filled in a container (not shown), and the puffer piston 5 is placed in the container.
Is supported and fixed. An insulating cylinder 12 is provided on the end surface of the puffer piston 5 on the fixed electrode side, and the fixed electrode 1 is attached to the tip of the insulating cylinder 12. The movable electrode 2 is inserted into the puffer piston 5 so as to face the fixed electrode 1, and the operation rod 3 is connected to a drive unit (not shown).
It is fixed to. The puffer cylinder 4 has a through hole 4a into which the insulating cylinder 12 is inserted, and is similarly supported and fixed to the operation rod 3 together with the intermediate piston 10 having the through hole 10a.
It is externally attached to the puffer piston 5. An insulator nozzle 6 is provided on the end surface of the puffer cylinder 4, which also functions as a movable piston, on the side of the fixed electrode so as to form an outlet between the electrodes. A small diameter portion 12a that forms a recess is provided at the end of the insulating cylinder 12 on the puffer piston 5 side. When the intermediate piston 10 reaches the small diameter portion 12a, a gap is formed between the small diameter portion 12a and the intermediate piston 10. There is.

Since the intermediate piston 10 is inserted in the thick main body portion of the insulating cylinder 12 in the initial stage of the opening operation by having the above-mentioned configuration, the intermediate piston 10 compresses the gas without letting it escape. . Then, when the distance between the fixed and movable electrodes is sufficiently obtained, for example, when the movable piston moves to 1/3 to 1/2 of the fully-open operating range, the intermediate piston 10 is placed in the small diameter portion 12a of the insulating cylinder 12. The compressed gas is reached and blown out through the gas flow paths 11 and 8. Therefore, a sufficiently compressed gas is released and the blocking performance is improved.

Further, in this embodiment, the small diameter portion 12a is formed at the end portion of the insulating cylinder 12 supporting the fixed side on the puffer piston 5 side, and the gas blowoff is adjusted by the intermediate piston 10 into which the insulating cylinder 12 is inserted to adjust the puffer cylinder. 4 can be connected to the operation rod 3, and it is not necessary to retract the intermediate piston in the radial direction toward the puffer piston side in order to provide a distance between the fixed side and the puffer cylinder as in the conventional case. Without increasing the axial length so much,
Moreover, it is possible to configure an arc extinguishing chamber of a puffer type gas circuit breaker provided with an intermediate piston, which is effective for shortening the distance between terminals of the circuit breaker using the arc extinguishing chamber of this system.

Another embodiment of the present invention is shown in FIG. In the embodiment shown in FIG. 2, the insulating cylinder 12 is fixed to the outer periphery of the puffer piston 5, and the large diameter portion 12b provided at the puffer piston 5 side end portion also serves as a puffer cylinder.

In this embodiment, in addition to the effects of the embodiment of FIG. 1, the structure is simplified by using the insulating cylinder 12 as a puffer cylinder.

Although no reference has been made to the energizing side contact in the above description, the same applies to the case having the energizing side contact. Further, in the above-mentioned embodiment, only the case where the volume of the gas flow passage 11 is not extremely large as described in FIG. 1 has been described, but the volume of this portion is increased and the gas pressurized by the arc is The present invention can be applied to a puffer type gas circuit breaker configured to be held in the same gas flow path.

[Effects of the Invention] As described above, according to the present invention, since the insulating cylinder is provided between the puffer piston and the fixed electrode side, the axial direction is not extended while the intermediate piston is provided. It is possible to provide a puffer type gas circuit breaker that improves the breaking performance and is effective in reducing the distance between the terminals of the circuit breaker.

[Brief description of drawings]

FIG. 1 is a sectional view showing an arc extinguishing chamber in one embodiment of the puffer type gas circuit breaker according to the present invention, FIG. 2 is a sectional view showing an arc extinguishing chamber in another embodiment of the present invention, and FIG. Sectional view showing the arc-extinguishing chamber of a basic puffer-type gas circuit breaker,
FIG. 4 is a sectional view showing an arc extinguishing chamber of a conventional puffer type gas circuit breaker of the intermediate piston type. 1 ... fixed electrode, 2 ... movable electrode, 3 ... operating rod,
4 ... Puffer cylinder, 5 ... Puffer piston, 6
...... Nozzle, 7 ...... Shield, 8 ...... Gas flow path, 9 ......
Movable piston, 10 ... Intermediate piston, 11 ... Gas flow path,
12 ... Insulating rod, 12a ... Small diameter part, 12b ... Large diameter part.

Claims (3)

[Claims] 1. A pair of electrodes, a fixed side and a movable side, are provided in a container in which an arc extinguishing gas such as SF ₆ gas is sealed, and the movable electrode side is connected to a drive unit to open and close the movable electrode. Operation rod, puffer cylinder for gas compression, puffer piston inserted in the cylinder, movable piston,
And an intermediate piston are respectively provided, the puffer piston is supported and fixed to the container, the movable piston and the intermediate piston are attached to the operation rod, and the fixed electrode side of the movable piston is a puffer type having a nozzle for blowing a high-speed gas flow to the arc. A gas circuit breaker, wherein an insulating cylinder covering the electrodes is provided between the puffer piston and the fixed electrode side, one end of this insulating cylinder is fixed to the puffer piston, and the other end is fixed to the fixed electrode. The puffer piston side end portion of the insulating cylinder is formed with a recess forming a gap between the insulation piston and the intermediate piston, and the intermediate piston is
A puffer-type gas circuit breaker, characterized in that after the opening operation is started, the insulating cylinder is configured to be movable from a region where the recess is not formed to a region where the recess is formed. 2. An insulating cylinder, one end of which is fixed to a fixed electrode side end surface of a puffer piston, and a small diameter portion is provided at the puffer piston side end portion to form the recess.
The puffer type gas circuit breaker according to claim 1, wherein the puffer cylinder is integrated with the movable piston, and the puffer cylinder and the intermediate piston each have a through hole into which an insulating cylinder is inserted. 3. An insulating cylinder, one end of which is fixed to the outer circumference of a puffer piston, and a large diameter portion is provided at the end portion on the puffer piston side to form the concave portion, and the large diameter portion is a puffer cylinder. The puffer type gas circuit breaker according to claim 1, which also serves as a gas breaker.