DE29509015U1 - High-voltage circuit breakers with a fixed heating volume - Google Patents

Description

956AO83

Description

High-voltage circuit breaker with a fixed heating volume
5

The invention relates to a high-voltage circuit breaker with a pair of opposing arcing contact pieces that delimit an isolating distance in the off state and a pair of continuous current contact pieces arranged coaxially to the arcing contact pieces, of which at least one of the contact pieces can be driven from a drive side, and with a compression device that can be actuated during the switching movement and has a compression piston and a drivable compression cylinder and a heating volume arranged on the drive side of the compression piston and is fixed during the switching movement.

Such a high-voltage circuit breaker is already known from DE-OS 41 03 119. In the known switch, two arc contacts are coaxially surrounded by permanent current contacts and a fixed heating volume is provided in which the extinguishing gas heated by an arc during the switching process can be stored and made available for subsequent blowing of the arc. In addition, a mechanical compression device for the extinguishing gas is provided, which on the one hand provides sufficiently high extinguishing gas pressure at low current intensities when the heating of the extinguishing gas by the arc is not sufficient and on the other hand supports the blowing of the arc at medium current intensities.

A significant advantage of the known circuit breaker described over other known designs is that the heating volume and the components that limit it do not need to be accelerated during the switching movement.

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This reduces drive energy and therefore the effort required for the switch drive.

This advantage is to be retained in the design underlying the invention, whereby the components to be accelerated are to be reduced even further.

This object is achieved according to the invention in that the compression cylinder carries the drivable continuous current contact on its outside, that the compression piston is arranged on the side of the circuit breaker facing the drive in such a way that the compression cylinder with the continuous current contact can be moved out of the isolating gap and that the continuous current contacts are separated from the arc contacts in a gas-tight manner by an insulating body that coaxially surrounds them.

Because the compression cylinder is structurally connected to the permanent current contact, the switch is structurally simplified overall and the masses to be accelerated are reduced. This means that the compression cylinder, which now carries electrically conductive elements, must be withdrawn from the isolating gap in the switched-off state.

This is made possible by moving the heating chamber to the drive side of the switch. The heating volume stores the heated extinguishing gas and makes it available for subsequent blowing of the arc. The insulating body prevents contamination of the permanent current contacts with hot extinguishing gas.

An advantageous embodiment of the invention provides that the compression piston is penetrated by a check valve that only allows gas to flow in the direction from the compression chamber to the heating volume.

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The extinguishing gas compressed in the compression chamber can thus pass through the check valve into the heating chamber, while an overflow of pressurized extinguishing gas from the heating chamber into the compression chamber is not possible. This prevents the extinguishing gas pressure in the compression chamber from increasing so much that it hinders or slows down the switching-off movement.

A further advantageous embodiment of the invention provides that the permanent current contact carried by the compression cylinder in the off state forms a field electrode for equalizing the electric field in the area of the isolating gap.

Since the compression cylinder already carries the permanent current contact, it is advisable to design this in the form of a field electrode or to connect it to a field electrode. This ensures that the field is evened out in the area between the contacts when the compression cylinder is retracted, i.e. when the circuit breaker is switched off.

The fixed counter-contact to the movable permanent current contact can also be designed as a field electrode. It is also conceivable to arrange a known, retractable field electrode on the side opposite the drive side of the switch, which is subjected to a spring force in the axial direction of the switch, can be pushed back by the compression cylinder when the switch is switched on, and follows the compression cylinder up to a stop when it is switched off and remains there as a field electrode.

In the following, the invention is shown using an embodiment in a drawing and then described.

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The figure shows schematically a part of an interrupter unit of a circuit breaker without the housing, in the upper half in the off state and in the lower half in the on state.

In the high-voltage circuit breaker shown, two arcing contacts 1, 2 are coaxially opposite each other in the off state in the upper half of the figure. In the on state, ie in the lower part of the figure, the drivable arcing contact 1 is retracted into the fixed counter-contact 2. At the same time, in the on state, the drivable permanent current contact 3 is also brought into contact with the fixed permanent current contact 4. The drivable permanent current contact 3 consists of an electrically conductive, metallic coating on the outside of the compression cylinder 5, which forms the drivable part of a mechanical compression device for the extinguishing gas.

0 During the switching-off movement, the drivable compression cylinder 5 is pulled over a fixed compression piston 6 and the compression volume 7 formed between them is compressed.

In addition, the arcing contacts 1, 2 and the continuous current contacts 3, 4 are separated from each other, whereby an arc is drawn between the arcing contacts 1, 2.

Due to the influence of this arc, the extinguishing gas present in the arc chamber 8 is heated and flows through the gas channel 9 within the nozzle-shaped insulating body 10 into a heating chamber 11.

This heating chamber 11 is fixed and does not move when the switch is operated. In the heating chamber, expanded extinguishing gas is provided by the heat of the arc,

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which flows back through the gas channel 9 to the arc chamber 8 to extinguish the arc at zero current crossing.

Between the heating chamber 11 and the compression chamber 7, a check valve 12 is provided in the compression piston 6, which is formed by part of the insulating body 10 and part of the wall delimiting the heating chamber 11, which prevents hot extinguishing gas from overflowing from the heating chamber 11 into the compression chamber 7. Such an overflow of hot, pressurized extinguishing gas into the compression chamber 7 would namely slow down the switch drive, which causes the compression cylinder 5 on the one hand and the arc contact 1 and the continuous current contact 3 on the other hand to move to the left in the figure towards the drive side.

On the other hand, if the arc does not heat the extinguishing gas sufficiently at low switching currents, mechanically compressed extinguishing gas can flow from the compression chamber 7 via the check valve 12 into the heating chamber 11 in order to support the blowing of the arc.

Since the permanent current contact 3 consists only of a conductive coating, for example in the form of a sheet on the compression cylinder 5, and no individually load-bearing construction is necessary for the permanent current contact, the total masses to be accelerated during the switching movement are reduced. The compression cylinder 5 is connected to the drivable arc contact piece 1 via a rod 13 and is driven by it. The compression cylinder can also consist entirely of metal, for example aluminum.

The heating chamber 11 is shifted so far away from the arc chamber 8 towards the drive side that the compression cylinder 5 during the switching-off movement reaches the fixed compression

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on piston 6 can be moved towards and away from the isolating gap. The electrically conductive coating 3 of the compression cylinder 5 is pulled over the front surface of the compression cylinder 5 and, in the off state, forms a field electrode for equalizing the electrical field between the arc contacts or the continuous current contacts.

The insulating nozzle 10, which has the gas flow channel 9, is arranged in a fixed position in the area of the isolating gap and separates the area of the arc chamber 8 from the outside area of the interrupter unit, which in turn is enclosed, for example, by a porcelain housing (not shown). Only hot extinguishing gas is fed into the heating volume 11 via the gas flow channel 9.

This also prevents hot extinguishing gas, which is contaminated by decomposition products of the extinguishing gas on the one hand and by vaporized materials on the other, from reaching the inner wall of the switch housing, where it can permanently impair the insulation strength.

Claims (3)

1. High-voltage circuit breaker with a pair of opposing arcing contact pieces (1, 2) which delimit an isolating gap in the off state, and a pair of continuous current contact pieces (3, 4) arranged coaxially to the arcing contact pieces, of which at least one of the contact pieces can be driven from a drive side, and with a compression device which can be actuated during the switching movement and has a compression piston (6) and a drivable compression cylinder (5), and a heating volume (11) arranged on the side of the compression piston (6) facing the drive and which is fixed during the switching movement, characterized in that the compression cylinder (5) carries the drivable permanent current contact (3) on its outside, that the compression piston (6) is arranged on the drive side of the circuit breaker in such a way that the compression cylinder (3) with the permanent current contact can be moved out of the isolating gap and that the permanent current contacts are separated from the arc contacts in a gas-tight manner by an insulating body which coaxially surrounds them. 2. High-voltage circuit breaker according to claim 2, characterized in that the compression piston (6) is penetrated by a check valve (12) which only allows gas to flow in the direction from the compression chamber (7) to the heating volume (11). 3. High-voltage circuit breaker according to claim 1 or a of the following, characterized in that the permanent current contact (3) carried by the compression cylinder (5) in the off state has a field electrode for 95 G 40 8 3 uniformity of the electric field in the area of the isolating gap.