JPH0828929B2 - Insulation spacer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Object of the Invention (Field of Industrial Application) The present invention relates to an insulating spacer having a shield grounded via a resistor.

(Prior Art) Generally, in gas-insulated switchgear and gas-insulated busbar,
Insulating spacers are used to insulatively support the high voltage conductors within the grounded enclosure.

Here, a general insulating spacer will be described with reference to FIG. The insulating spacer 10 is made of a thermosetting resin such as epoxy resin, and has a disk-shaped insulating spacer body 11 with a protruding central portion.
And a connecting conductor 12 embedded in the central portion of the insulating spacer body 11, and a metal flange 13 arranged on the outer periphery of the insulating spacer body 11.

On the metal flange 13 side of the insulating spacer body 11, a ring-shaped shield 14 for easing an electric field is embedded.

The insulating spacer 10 is hermetically sandwiched between the two ground containers 2 in which the high voltage conductors 1 are inserted. Also,
The two ground containers 2 are electrically connected by sandwiching a metal flange 13 between the respective flanges. On the other hand, the two high-voltage conductors 1 are fitted and electrically connected to the connecting conductors 12, respectively. As a result, the high voltage conductor 1 is connected to the ground container
Insulated and supported inside.

Further, the conventional shield 14 is usually grounded at multiple points. And, the shield 14 is the third at least at one place.
It is grounded in the configuration shown. That is, one end of the metal fitting 15 embedded in the insulating spacer body 11 is connected to the shield 14. The other end of the metal fitting 15 is led out of the insulating spacer body 11 and is a lid 16 detachably attached to the metal flange 13.
It is connected to the. As a result, the shield 14 has the metal fittings 15,
It is grounded to the metal flange 13 via the lid 16.

Further, the shield 14 is grounded at least at one location in the configuration shown in FIG. That is, one end of the metal fitting 17 embedded in the insulating spacer body 11 is connected to the shield 14. The other end of the metal fitting 17 is led out to the outside of the insulating spacer body 11, and is connected to a lid 19 to which a resistor 18 is fixed at the tip and which is detachably attached to the metal flange 13. As a result, the shield 14 is attached to the metal flange via the metal fitting 17, the resistor 18, and the lid 19.
Grounded at 13.

Then, when measuring the voltage induced in the shield 14, the lid 16 on the side not grounded is removed via the resistor 18, the capacitor is connected to the metal fitting 15 instead, and the terminal voltage of this capacitor is measured with a measuring instrument. To be done.

However, when an impulse or a surge wave enters the high-voltage conductor 1 when measuring the voltage of the shield 14, the shield 14 becomes high potential and the metal fitting 17 connected to this shield 14 also becomes high voltage. Therefore, discharge occurs in the resistor 18 provided between the high-potential metal fitting 17 and the zero-potential lid 19, and the antibody 18 is damaged.

(Problems to be Solved by the Invention) As described above, in the conventional insulating spacer, the resistor may be damaged by a surge wave or the like.

The present invention has been made to eliminate the above problems, and an object of the present invention is to provide a highly reliable insulating spacer that does not damage a resistor even when an impulse or a surge wave invades.

[Structure of Invention]

(Means for Solving the Problems) In order to achieve the above object, in the present invention, a conductor that forms a minute gap between the resistor and the metal fitting flange is connected to the body side of the insulating spacer.

(Function) With this configuration, even if the potential of the shield rises due to intrusion of surge waves, etc., when the insulation strength of the resistor is reached, discharge occurs in the minute gap, preventing damage to the resistor. To be done.

(Example) Hereinafter, an example of the present invention will be described with reference to FIG. It should be noted that the same reference numerals will be given to the conventional insulating spacers and the same parts for explanation.

To the shield 14, one end of the metal fitting 20 embedded in the insulating spacer body 11 is connected. The other end of the metal 20 is led out to a space formed between the insulating spacer body 11 and the metal flange 13. Then, on the outer peripheral surface of the insulating spacer body 11, a cylindrical insulator 21 surrounding the drawn out metal fitting 20 is arranged. A conductor 22 is supported on the insulator 21. The conductor 22 is a disk-shaped base portion 22a that abuts against the anti-insulation spacer body 11 side of the insulator 21, and is inserted into the insulator 21 at the center of the base portion 22a and the tip is connected to the metal fitting 20. And a protruding portion 22b that is formed. And
The side surface of the base portion 22a of the conductor is separated from the metal flange 13 with a minute gap. Also, the insulator 21 and the conductor 22 are housed in the metal flange 13 so as to be insulated from the outside and the insulating spacer body 11.
A removable lid (23) for sealing a hole (13a) communicating with and is attached. Further, a resistor 24 is connected between the conductor 22 and the lid 23.

As a result, the shield 14 includes the metal fitting 20, the conductor 22, and the resistor 24.
And, it is grounded to the metal flange 13 via the lid 23.

The configuration on the side not grounded via the resistor is similar to that of the conventional insulating spacer shown in FIG.

When measuring the voltage induced in the shield 14, an impulse or a surge wave may enter the high voltage conductor 1. As a result, the shield 14 becomes high potential and the metal fitting 20 and the conductor 22 connected to the shield 14
Also becomes a high potential. However, conductor 22 is a metal flange
Since it is arranged with 13 and a minute gap, resistor 24
When the insulation strength is higher than, the electric discharge occurs between the conductor 22 and the metal flange 13.

Therefore, the resistor 24 is not damaged and a highly reliable insulating spacer can be provided.

〔The invention's effect〕

As described above, in the present invention, since the conductor forming the minute gap between the resistor and the metal spacer is connected to the insulating spacer body side of the resistor, the minute gap is generated even if the potential rise exceeds the insulation strength of the resistor. It is possible to provide a highly reliable insulating spacer which can be discharged by the method and which does not damage the resistor.

[Brief description of drawings]

FIG. 1 is a partial sectional view of an insulating spacer showing an embodiment of the present invention, FIG. 2 is a partial sectional view showing a general insulating spacer, and FIG. 3 shows a direct grounding of a shield of a general insulating spacer. FIG. 4 is a partial sectional view showing a resistor grounding of a shield of a conventional insulating spacer. 1 ... High-voltage conductor, 2 ... Grounding container, 10 ... Insulating spacer, 11 ... Insulating spacer body, 12 ... Connecting conductor, 13 ... Metal flange, 13a ... Hole, 14 ... Shield, 15 ... … Metal fitting, 16 …… Lid, 17 …… Metal fitting, 18 …… Resistor, 19 …… Lid, 20 …… Metal fitting, 21 …… Insulator, 22 …… Conductor, 22a …… Base, 22b… Projection , 23 ... Lid, 24 ... Resistor.

Continuation of the front page (56) Reference JP 58-222714 (JP, A) JP 61-66517 (JP, A) JP 61-231819 (JP, A) JP 63-56112 (JP , A) Actual opening Sho 49-54762 (JP, U) Actual opening Sho 57-7828 (JP, U) Actual opening Sho 57-36713 (JP, U) Actual opening Sho 58-28523 (JP, U) Actual opening Sho 58-139825 (JP, U) Actual opening Sho-58-179817 (JP, U) Actual opening Sho-59-85022 (JP, U)

Claims (1)

[Claims] 1. An insulating spacer in which a metal flange is arranged on the outer periphery of an insulating spacer body, a shield is embedded in the insulating spacer body on the side of the metal flange, and the shield is grounded to the metal flange via a resistor. An insulating spacer, wherein a conductor forming a minute gap between the resistor and the metal flange is connected to the insulating spacer body side of the resistor.