JPH0361296B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an SF ₆ gas disconnector used as an ultra-voltage (UHV) disconnector.

UHV disconnectors of 1100KV or higher, unlike disconnectors of 550KV or lower, require a resistor between the disconnecting poles to suppress surge voltage when charging current is cut off. Also, the loop current value is 2000 to 6000A for 550KV systems, whereas 12000A is required for UHV disconnectors.

Figures 1 and 2 show an example of the disconnection section structure of the SF ₆ disconnector, which is a conventional UHV disconnector. Figure 1 shows the circuit in a closed state, and Figure 2 shows it in the middle of an open circuit. There is. The movable contact 1 is fixed to a piston 4 that moves in the axial direction inside a cylinder 3 provided on the movable conductor 2, and an operating rod 5 is attached to the piston 4 in the opposite direction to the movable contact 1. ing. A movable current collector 6 attached to the fixed conductor 2 is placed in contact with the outer periphery of the end of the movable contact 1 on the cylinder 3 side. Further, a movable shield 7 attached to the movable conductor 2 is disposed so as to cover the outside of the movable current collector 6.

An arcing contact 9 that is slidably supported by the fixed conductor 8 is arranged at a position facing the tip of the movable contact 1, and the end of the arcing contact 9 on the side opposite to the movable contact 1 is provided with a wipe spring. 10. Further, a fixed current collector 11 is arranged around the arcing contact 9, and a fixed conductor 8 is attached to cover the arcing contact 9.
A fixed shield 12 attached to the fixed conductor 8 is disposed on the outer periphery of the fixed current collector 11 so as to cover it. Note that when the disconnector is in the closed state as shown in Figure 1, the movable contact 1
comes into contact with the arcing contact 9, and the fixed side current collector 11 contacts the outer circumference of the wipe spring 1.
0 presses the arcing contact 9 toward the movable contact 1 side. Movable side shield 7 and fixed side shield 1
An intermediate shield 13 is disposed approximately in the middle of the movable contact 1 so as to surround the movable contact 1. This intermediate shield 13 is fixed to the sheath 14 via a support insulator 15. Furthermore, this intermediate shield 1
3 is connected to the stationary shield 12 through a resistor 16. The movable contact 1 has a suction hole 17 extending in the axial direction and having an opening at its tip.The suction hole 17 is bent into an L-shape in front of the piston 4 and opens on the outer peripheral surface of the movable contact 1. ing. Further, a puffer chamber 18 is formed by the cylinder 3, the piston 4, and the outer peripheral surface of the movable contact 1, and this puffer chamber 18 communicates with the suction hole 17. Furthermore,
The inside of the sheath 14 is filled with SF ₆ gas.

When the movable contact 1, the piston 4, and the operating rod 5 are driven in the direction of the arrow in the figure, the volume of the puffer chamber 18 increases and the movable contact 1 and the arcing contact 9 are separated. Then, SF ₆ gas flows into the suction hole 17 provided inside the movable contactor 1 .
At this time, as shown in FIG. 2, a loop current arc 19 generated between the movable contact 1 and the arcing contact 9 is extinguished by this SF ₆ gas flow.

With such a conventional SF ₆ gas disconnector, the current value to be cut off is relatively small, as shown in Figure 3.
When the current is 4000A or less, the separation distance L of the movable contact 1 until the arc is extinguished is short, and the path of the arc 19 is limited between the center of the movable contact 1 and the arcing contact 9. Ru. However, from 6000
When interrupting a large current such as 12000A, as shown in Fig. 4, the separation distance L of the movable contact 1 becomes long until the arc 19 is extinguished, and the path of the arc 19 is also fixed to the end of the movable contact 1. and the side shield 12. In this way, if arcing occurs at the end of the movable contact 1, where the spraying effect of SF ₆ gas is low, the breaking performance will decrease, and the shield will be damaged due to the shield arcing, resulting in a decrease in the dielectric strength between the electrodes. It was hot.

Furthermore, it is necessary to provide a support insulator 15 to support the intermediate shield 13 and the resistor 16, but it is not possible to provide the support insulator 15 from the sheath 14 near the disconnection section where SF ₆ decomposition products are generated. ,
This was not desirable from the standpoint of reliability.

SUMMARY OF THE INVENTION An object of the present invention is to provide an SF ₆ gas disconnector that eliminates the above-mentioned drawbacks and can cut off ultra-high voltage and large current with high reliability.

In the present invention, an insulating nozzle is provided between the fixed side shield and the intermediate shield, and the insulating nozzle confines the arc generated between the movable contact and the arcing contact at the time of opening within the nozzle, thereby improving the breaking performance. The intermediate shield and the interrupting resistor are fixedly supported by the insulating nozzle.

Hereinafter, an embodiment of the SF ₆ gas disconnector of the present invention will be described with reference to FIG. 5, using the same reference numerals for the same parts as those of the conventional example.

FIG. 5 shows the structure of the SF ₆ gas disconnector of this embodiment in a closed state. The tip of the movable contact 1 fixed to a piston 4 movable within a cylinder 3 provided on the movable conductor 2 contacts the arcing contact 9, and the fixed current collector 11 contacts the outer circumference of the movable contact 1. is in contact with. A fixed-side shield 12 attached to the fixed-side conductor 8 is arranged so as to surround the outside of the fixed-side current collector 11. An insulating nozzle 20 located on the outer periphery of the movable contact 1 with a predetermined gap is fixed to the front part of the fixed shield 12, and an intermediate shield 13 is attached to the tip of the insulating nozzle 20. . Further, a resistor 16 connecting the intermediate shield 13 and the stationary shield 12 is also supported by the insulating nozzle 20. The insulating nozzle 20 has a cylindrical shape with a widening taper toward the movable conductor 2 formed on the inner surface of the opening thereof.

When the movable contact 1, piston 4 and operating rod 5 move to the left side in FIG.
The SF ₆ gas whose volume has been increased is sucked through the suction hole 17 of the movable contact 1 to create a gas flow between the arcing contact 9 and the movable contact 1 .

According to the disconnector of this embodiment, the movable contact 1 until the arc is extinguished when a large current is interrupted.
Even if the separation distance becomes longer, the arcing contact 9
Since the space between and the movable contact 1 is surrounded by the insulating nozzle 20, the arc path is
Since there is no migration between the tip end and the fixed shield 12, the arc blowing effect by the gas flow is not inhibited, and there is an effect that large current can be reliably interrupted. In addition, since there is no arcing between the fixed side shield 12 and the fixed side shield 12,
This has the effect of increasing the reliability of the disconnector by preventing the dielectric strength between the electrodes from decreasing.

As described above, the SF ₆ gas disconnector of the present invention has the effect of being able to interrupt ultra-high voltage and large current with high reliability.

[Brief explanation of drawings]

Figures 1 and 2 are explanatory diagrams showing the structure of a conventional SF ₆ gas disconnector, Figure 3 is an explanatory diagram showing the state of the arc that occurs when the conventional SF ₆ gas disconnector interrupts the normal current, and Figure 4 is an explanatory diagram showing the structure of a conventional SF 6 gas disconnector. The figure is an explanatory diagram showing the state of an arc that occurs when a conventional SF ₆ gas disconnector interrupts a large current, and FIG. 5 is an explanatory diagram showing the structure of an embodiment of the SF ₆ gas disconnector of the present invention. 1...Movable contact, 2...Movable side conductor, 3...
Cylinder, 4... Piston, 7... Movable side shield, 8... Fixed side conductor, 9... Arcing contact, 12... Fixed side shield, 13... Intermediate shield, 16... Resistor, 17... Suction hole, 18...
... Patshua chamber, 20... Insulated nozzle.

Claims (1)

[Claims] 1. A fixed-side conductor equipped with a fixed-side current collector and a fixed-side shield and a movable-side conductor equipped with a movable-side current collector and a movable-side shield, which are arranged facing each other, and are provided on the fixed-side and movable-side conductors respectively to open and close. A fixed contact and a movable contact are arranged approximately in the middle between the fixed side shield and the movable side shield, and
The movable contact has an intermediate shield connected to the fixed side shield via a resistor, and the movable contact has an opening at the tip and an axial suction hole so that the movable contact is filled with water when the contact is opened. In this device, the arc is extinguished by the gas flow generated near the tip of the movable contact by inhaling SF ₆ gas, and the inner surface of the opening to the fixed side shield is formed with a widening taper toward the movable side conductor. An SF ₆ gas disconnector, characterized in that a cylindrical insulating nozzle is attached, and the intermediate shield and the resistor are supported and fixed by the insulating nozzle.