DE4217232A1 - Electrical high-voltage power switch - has compression system for quenching gas with cylinder floors made of material with good electrical conductivity - Google Patents

Abstract

The power switch includes two facing contact pieces (1,2) at a fixed distance from each other and a moveable bridging switch piece (3). A mechanical compression system for a quenching gas has an insulating material cylinder (4) which surrounds the contact pieces in the closed position. A first driveable cylinder floor (5) compresses the quenching gas during the disconnecting movement. A further cylinder floor (6) is also included in the compression system. Both cylinder floors are made of material with good electrical conductivity. ADVANTAGE - Has increased electrical stability, especially in switched-off state.

Description

The invention relates to an electrical high Voltage circuit breakers with two each other in fixed Distance coaxially opposing contact pieces, with a movable bypass switch and with one mechanical compression system for an extinguishing gas that one the contact pieces at least in the switch position surrounding insulating material cylinder and one for Compressing the extinguishing gas in the course of the switch-off movement drivable first cylinder base and another Has cylinder bottom, each one of the contact pieces in the Switch-off state surrounded concentrically.

Such a high voltage circuit breaker is already known from DE-OS 35 40 474. The one described there ben switch is a first cylinder bottom sliding in stored a fixed outer insulating cylinder. The first cylinder base is equipped with a blow grille tied, which also drives the cylinder base transmits. The further cylinder bottom is fixed by one standing compression piston formed. In the off position, the first cylinder base concentrically surrounds it fixed contact piece facing away from the drive side, while the fixed further cylinder bottom that of the An drive side facing contact piece concentrically surrounds.

The present invention is based on the object dielectric strength of a switch of the beginning ge mentioned type, especially when switched off.  

The object is achieved in that the first and the other cylinder bottom from an electric good conductive material.

The field between the fixed contact pieces equalized so that the Probability of rollovers is reduced. There by the switch can be used for higher voltages without fear of electrical flashovers are. The cylinder bottoms advantageously consist of Metal.

A particularly advantageous embodiment of the invention results from the fact that each of the cylinder bottoms in each case ver with that fixed contact piece is bound that it surrounds in the off position.

The first cylinder base is, for example, over a conductive sealing lip that abge on the drive side turned fixed contact piece slides with this conductively connected. Such a sealing lip can game made of polytretrafluoroethylene.

Each of the cylinder bottoms then has the same electrical Potential on how the corresponding fixed contact piece, so that the potential distribution in the switch is determined by the applied voltage. It can then no free potential on the cylinder bottoms form.

A further advantageous embodiment of the invention provides before that the further cylinder bottom with the first Cylinder bottom firmly connected and drivable with it and that a third, fixed cylinder base on the  the side facing away from the first cylinder bottom Cylinder base is arranged.

The space between the first cylinder bottom and the In this case, another cylinder floor is used as a boiler room used while the space between the further Cylinder bottom and the third, fixed cylinder bottom serves as a compression space. The distance between that first and the other cylinder bottom is in this case fixed unchangeable. This results in firm lying conditions for the field distribution in the room between the cylinder bottoms.

The invention can also be advantageously configured in this way be that the further cylinder base is arranged stationary is. In this case, the space between the first cylinder base and the further cylinder base a boiler room and a compression room at the same time mechanical compression of an extinguishing gas, its volume in the course of the opening movement except for one remaining Dead volume is reduced. The stationary cylinder base must then not moved and especially not mitbe be accelerated. This will make the required To drive energy of the switch reduced.

Another embodiment of the invention provides that the facing surfaces of the first and the other cylinder bottom have the same contour.

This ensures that the field structure between the Cylinder bottoms, d. H. also between the fixed ones Contact pieces is symmetrical. This will create a further homogenization of the electric field he enough.  

The invention can also advantageously be designed in this way be that the first cylinder bottom with the insulating material cylinder is firmly connected.

In this case the Insulating cylinder to achieve compression movement driven and the drive movement is by the insulating cylinder on the first cylinder bottom transfer. As a result, there is no sliding seal between the first cylinder base and the insulating material cylinder necessary. In addition, no additional device for Transfer of the drive movement to the first cylinder floor should be provided.

Another advantageous embodiment of the invention provides before that the first cylinder bottom in the insulating cylinder is slidably sealed. In this case, a separate Transfer of the drive movement to the first cylinder floor is provided and there is an additional one sliding seal between the insulating material cylinder and the first cylinder base necessary. In contrast, by the fixed arrangement of the insulating cylinder which at Shutdown process accelerated mass and reduced thereby saving drive energy.

The invention based on an embodiment example shown in a drawing and then be wrote.

It shows:

Fig. 1 shows a high-voltage circuit breaker according to the invention schematically in longitudinal section, the further cylinder base being stationary.

Fig. 2 shows a high-voltage circuit breaker schematically in longitudinal section, in which a third cylinder base is provided.

Fig. 1 shows a high-voltage circuit breaker with two mutually opposite contact pieces 1 , 2 , which are hollow for the discharge of extinguishing gases. In the switched-on state (upper half section), the two contact pieces 1 , 2 are conductively connected to one another by a movable bridging switching piece 3 . The bypass switch 3 is mechanically connected to a switch drive, not shown in the figure. During the switch-off process, an arc arises between the contact pieces 1 , 2 , which is extinguished by blowing with an extinguishing gas. For this purpose, a mechanical compression device for the extinguishing gas is provided, which consists of an insulating tube 4 coaxially surrounding the contact pieces 1 , 2 , a first cylinder base 5 fixedly connected to this and a further cylinder base 6 designed as a compression piston. In the course of the switch-off movement, the insulating tube 4 is moved by the switch drive in such a way that the compression space 8 is reduced and the quenching gas therein is compressed. The quenching gas is then fed through a blow grille 9 to the arc space 10 , where it strikes the arc and extinguishes it. The first cylinder base 5 has the same contour as the further cylinder base 6 on its side facing the compression space. In the switch-off state, the separating distance between the fixed contact pieces 1 , 2 is partly covered by the blow grille 9 . The first cylinder base 5 and the further cylinder base 6 are made of metal. The first cylinder base 5 is conductively connected to the contact piece 1 via a conductive sealing lip 11 , which consists of polytetrafluroethylene, while the further cylinder base 6 is conductively connected to the fixed contact piece 2 . This results in an equalization of the field structure between the contact pieces by the geometry of the cylinder bottoms 5 , 6 acting as shielding electrodes. The compression chamber 8 has a certain dead volume, which remains even when switched off and also acts as a boiler room. That is, the quenching gas heated by the arc in the arc space 10 can evade this compression / heating space 8 and build up an increased gas pressure there, which leads to a gas reflux in the arc space 10 which weakens the arc, which supports the extinguishing of the arc .

The first cylinder base 5 is fastened to the insulating tube 4 by means of a screw connection or gluing. The further cylinder base 6 is sealed against the insulating tube 4 by means of a seal 13 .

Fig. 2 shows an electrical high-voltage power switch, with a first cylinder base 5 , a further cylinder base 6 and a third cylinder base 7th The further cylinder base 6 is firmly connected to the insulating tube 4 and thereby maintains a fixed distance from the first cylinder base 5 during the switching movement. On the side facing away from the first cylinder base 5 of the further cylinder base 6 , the third cylinder base 7 is easily seen; A compression space 14 is formed between the further cylinder base 6 and the third cylinder base 7 . A heating chamber 15 with a constant volume is formed between the first cylinder base 5 and the further cylinder base 6 .

During the switch-off movement, the further cylinder base 6 is driven together with the first cylinder base 5 via the insulating tube 4 . The extinguishing gas located in the compression space 14 is compressed. As soon as an arc is ignited, hot quenching gas flows into the boiler room 15 , whereby the quenching gas pressure is increased in this room. As long as there is a higher extinguishing gas pressure in the boiler room than in the compression room 14 , the opening 17 in the further intermediate floor 6 is closed by the rattling valve 16 , so that an optimal gas pressure build-up in the boiler room 15 is ensured. Only when the hot quenching gas flows out of the heating chamber 15 at the zero crossing of the current and consequently the quenching gas pressure drops there, can the quenching gas flow in from the compression chamber 14 and thus ensure an extended blowing of the arc.

In addition, by closing the rattling valve 17 it is ensured that the pressure increase due to the heating effect of the arc does not act against the driving force applied to the first and the further cylinder bases 5 , 6 . If the quenching gas pressure in the compression chamber 14 is greater than in the heating chamber 15, so the rattle valve 16 automatically opens and gas can flow through the recesses 18 in the further intermediate floor 6 from the compression chamber 14 into the heating 15th In addition, it is ensured by overflow valves 19 that if the extinguishing gas pressure in the compression chamber rises too strongly, this pressure can be reduced by flowing into an expansion chamber 20 .

Claims (7)

1. Electrical high-voltage circuit breaker with two mutually coaxially opposed contact pieces, with a movable bridging switch piece and with a mechanical compression system for an extinguishing gas, the one surrounding the contact pieces at least in the switch-on insulating cylinder and one for compressing the extinguishing gas in the course of the opening movement drivable first cylinder base and a further cylinder base, each concentrically surrounding one of the contact pieces in the switched-off state, characterized in that the first and the further cylinder base ( 5 , 6 ) consist of an electrically highly conductive material. 2. Electrical high-voltage circuit breaker according to claim 1, characterized in that each of the cylinder bottoms ( 5 , 6 ) is in each case conductively connected to that fixed contact piece ( 1 , 2 ) which it surrounds in the open position. 3. Electrical high-voltage circuit breaker according to claim 1 or 2, characterized in that the further cylinder base ( 6 ) with the first cylinder base ( 5 ) is firmly connected and can be driven with this, and that a third, fixed cylinder base ( 7 ) on the first cylinder base ( 5 ) facing away from the further cylinder base ( 6 ) is arranged. 4. Electrical high-voltage circuit breaker according to claim 1 or 2, characterized in that the further cylinder base ( 6 ) is arranged stationary. 5. Electrical high-voltage circuit breaker according to claim 1 or one of the following, characterized in that the mutually facing surfaces of the first and the further cylinder base ( 5 , 6 ) have the same contour. 6. Electrical high-voltage circuit breaker according to claim 1 or one of the following, characterized in that the first cylinder base ( 5 ) with the insulating cylinder ( 4 ) is fixedly connected. 7. Electrical high-voltage circuit breaker according to one of claims 1 to 5, characterized in that the first cylinder base ( 5 ) in the insulating cylinder ( 4 ) is slidably sealed.