DE19928078A1 - High-voltage (HV) circuit-breaker with diffusor channel - Google Patents

Abstract

A high-voltage (HV) circuit-breaker has first and second arc contact tips (2,3) placed opposite one another between which an arc is drawn in an arcing space (10) filled with an insulating gas. The first arcing contact tip (2) is drivable by a switch drive and includes a diffusor channel (11) with its inflow aperture (30) formed by a tulip contact and with the insulating gas free to flow out from the arcing space (10). At least a first (16), a second (15) and a third (17) zone are arranged one behind the other, in the direction of flow, between the inflow aperture (30) and an outflow aperture (20) of the diffusion channel (11). The second zone (15) has a greater specific flow resistance than the first and third zones.

Description

The invention relates to high voltage power switches with a first and a second against each other protruding arcing contact piece, between those in the out Switching case if necessary in an arc filled with insulating gas arc is drawn, the first arc contact piece can be driven by means of a switch drive and has an outflow channel, the inflow opening through a tulip contact is formed and by the insulating gas from Arc room can flow out.

Such a high-voltage circuit breaker is an example as known from GB 20 81 020 A. With such a High-voltage circuit breaker has an interrupter unit usually two arcing contact pieces on the one Switching state are connected to each other and in the off switching case by means of a switch drive from each other be separated. In addition, there is often additional continuous current Clock pieces provided, the continuous current when switched on wear and before the arc when switching off contact pieces are separated from each other.

The breaker unit of a high voltage circuit breaker is usually within one with an insulating gas, at for example, encapsulation case filled with sulfur hexafluoride arranged.

In the event of a switch-off, the arcing contact pieces are separated the separated, an arc is between them if necessary ge pulled through which the surrounding extinguishing gas is heated and expan  is dated. The extinguishing gas heated and ionized in this way should switch off as quickly as possible during the switch-off process Arc room to be moved away from the inflow from far rem, cool extinguishing gas to enable reignition of the arc after its extinction in a zero current passage of an alternating current to be prevented that should.

For this reason, an insulating nozzle is provided, which in the one switching case surrounding the arcing contact pieces and their narrow switch on one of the arcing contact pieces stand is enforced. This bottleneck is at the latest during of the switch-off process released in order to discharge to enable hot extinguishing gas.

The hot extinguishing gas flows through at least one outflow channel away from the arc room and, if necessary, in a cooling device device, for example, from a metal mesh or a Perforated sheet can exist, cooled or deionized to one the contamination of parts of the interrupter unit with the aggressive ionized extinguishing gas and on the other hand, as soon as possible after the switching process cooled extinguishing gas for another switching operation for ver to provide.

It was found that by designing an Abströmka nals affects the outflow of the extinguishing gas in a way can be that a specific backflow behavior is generated is, which has a reaction on the extinguishing gas pressure in the Arc room and the effect of the extinguishing gas on the Arc optimized.  

The present invention is based on the object a high-voltage circuit breaker of the type mentioned Way to optimally design the outflow channel.

The object is achieved in that between the inflow opening and an outflow opening of the outflow nals at least a first, a second and a third Be rich in the direction of flow of the insulating gas one behind the other are arranged, of which the second area opposite the first and third areas a larger specific Has flow resistance.

Characterized in that the second region with a greater specific flow resistance is provided, he there is a certain backlog of the extinguishing gas on back the arc space by means of a back pressure wave works. The effect on the arc can be approved by the Choice of the distance between the arc space and the second area and the flow resistance of the second Range can be optimized. The second area can be at for example as a conical narrowing or as a flow obstacle, for example in the form of a plate be formed with a passage opening.

An advantageous embodiment of the invention provides that a further area before or after the three areas net, which is a greater specific flow resistance has than the area immediately adjacent to it.

This makes two areas independent of each other created a greater specific flow resistance, that deal with areas of lower specific current alternating resistance.  

As a result, the extinguishing gas flows alternately when it flows out Areas with greater and lesser specific, flow resisted, so that different pressure waves when switched off Walk back to the arc room one after the other. There you can with an optimized time profile of the extinguishing gas pressure be fathered.

A further advantageous embodiment of the invention provides before that at least the second or the further area as a nozzle constriction provided in the outflow channel is formed det.

In addition, the invention can advantageously be designed in this way that at least the second or the further area is designed as a check valve.

This will cause the contaminated quenching gas to flow back prevented by the outflow channel, so that the reaction on the arc chamber only in back pressure waves and does not consist of extinguishing gas flowing back.

The invention can also be designed in that at least the second or the wider area as a die Extinguishing gas flow braking perforated plate or metal braid is trained.

With this configuration, on the one hand, a backflow of the Extinguishing gas generated in the outflow channel, on the other hand it will Extinguishing gas flowing through effectively cooled.  

In the following, the invention is illustrated by means of an embodiment shown in a drawing and described below ben.

It shows

Fig. 1 shows a part of an interrupter unit with a due senengstelle in the drive-side outflow passage,

Fig. 2 shows a part of an interrupter unit with a check valve and a metal braid in the drive-side outflow channel.

Referring to FIG. 1, a first arcing contact piece 2 and a this opposite second arcing contact piece 3 are arranged in a capsule housing 1. The first arcing contact 2 is driven by a switch actuator not shown in the direction of arrow 4 in the course of an opening movement.

The first arcing contact piece 2 is connected to a first permanent contact piece 5 and to an insulating nozzle 6 .

The second arcing contact piece 3 is arranged in a stationary manner and is concentrically surrounded by a likewise permanent second contact piece 7 .

However, the second arcing contact piece 3 can also be drivable in a direction opposite to the direction of movement of the first arcing contact piece 2 .

In the switched-on state, the second arcing contact piece 3 passes through the constriction 8 of the insulating nozzle 6 .

If the drivable arcing contact piece 2 is accelerated in the direction of arrow 4 together with the insulating nozzle and the first continuous current contact piece 5 , an arc 9 is drawn in an arcing space 10 between the arcing contact pieces 2 , 3 . The arc heats the quenching gas sulfur hexafluoride located in the interrupter unit in the arc space 10 and this flows out at least partially through an inflow opening of an outflow channel 11 within the first arcing contact piece. Part of the heated quenching gas flows through a heating channel 12 into a heating room 13 , where it is stored until the next current zero crossing of the current to be switched and from where it then flows back through the heating channel 12 to the arc chamber 10 to blow the arc 9 .

The extinguishing gas flows, according to which the second arcing contact 3, the constriction 8 of the insulating nozzle has released 6, partly also from along the second arcing contact piece. 3

An insert 14 is provided within the outflow channel 11 , by means of which a nozzle constriction 15 is created in the outflow channel 11 . This nozzle constriction 15 forms a second area of the outflow channel 11 , which is arranged downstream of a first cylindrical or slightly conically widening area 16 of the outflow channel 11 in the course of the extinguishing gas flow.

The second area 15 is followed by a third area 17 of the outflow channel 11 , which is cylindrical or slightly conical in the sense of the extinguishing gas flow and into which the extinguishing gas can expand behind the nozzle constriction.

The third area 17 is followed by a further area 18 in the form of a plate which has one or more flow openings for the extinguishing gas and through which a greater specific flow resistance is generated than in the third area 17 .

Behind the further area 18 , a last area 19 is provided with a cylindrical cross-section, which has radial outflow openings 20 for the extinguishing gas, through which the extinguishing gas can flow out into the expansion space 21 surrounded by the encapsulation housing 1 .

The sequence of regions shown with greater specific flow resistance and lower specific flow resistance achieves a targeted backflow behavior of the extinguishing gas in the outflow channel 11 , which has a positive effect on the temporal course of the extinguishing gas pressure in the arc chamber 10 .

In this context, the specific flow resistance is understood to mean the flow resistance based on the Längenein unit in the outflow channel 11 .

In Fig. 2, an interrupter unit is shown, which corresponds exactly to that shown in Fig. 1 except the design of the flow channel. The outflow channel 22 has a first area 23 with a low specific flow resistance and subsequently a second area 24 with a greater specific flow resistance in the form of a plate with a flow opening 25 which can be closed by a spring-loaded closure flap 26 .

If the quenching gas flows from the arc chamber 10 through the outflow channel 22 , the closure flap 26 is lifted off and the quenching gas can flow through the second region 24 . Any backflow of the extinguishing gas is prevented by the check valve thus formed.

The second area 24 is followed by a third area 27 , which is cylindrical and has a lower specific flow resistance.

The third area is followed by a further area 28 , which is formed by a permeable metal mesh (mesh cooler).

This area could also be one or more metallic Perforated sheets are formed.

Claims (5)

1. High-voltage power switch having a first and a second opposing arcing contact piece (2, 3) is drawn between those in Ausschaltfall optionally in a container filled with insulating gas arc chamber (10) an arc (9), the first arcing contact piece (2) by means of a switch drive can be driven and has an outflow channel ( 11 ), the inflow opening ( 30 ) of which is formed by a tulip contact and can flow through the insulating gas from the arc chamber ( 10 ), characterized in that between the inflow opening ( 30 ) and an outflow opening ( 20 ) of the outflow channel, at least a first ( 16 ), a second ter ( 15 ) and a third region ( 17 ) are arranged one behind the other in the direction of flow of the insulating gas, of which the second region ( 15 ) is more specific than the first and third regions Flow resistance has. 2. High-voltage circuit breaker according to claim 1, characterized in that the three areas ( 15 , 16 , 17 ) upstream or downstream of a further area ( 18 ), which has a larger specific current resistance than the area immediately adjacent to it. 3. High-voltage circuit breaker according to claim 1 or 2, characterized in that at least the second ( 15 ) or the further region ( 18 ) is formed as a nozzle constriction provided in the outflow channel ( 11 ). 4. High-voltage circuit breaker according to one of claims 1 or 2, characterized in that at least the second ( 15 ) or the further region ( 18 ) is designed as a check valve. 5. High-voltage circuit breaker according to claim 1 or 2, characterized in that at least the second ( 15 ) or the further region ( 18 ) is designed as a perforated plate or metal braiding which brakes the extinguishing gas flow.