DE742383C - Extinguishing chamber switch - Google Patents

Description

Fire chamber switch Fire chamber switches are known where the arc insulation takes place through its liquid flow, which creates the arc drives against transverse insulating partitions to the arc axis in outlet channels. In this case, the arc roots get stuck on the isolating contacts and cause there burn-off and high thermal loads. The arc continues considerably longer until it finally enters the isolation channels and goes out. As a result of the arc elongation, the arc voltage increases and so does the switching work to high values.

The invention avoids these disadvantages. To this end are in the case of an extinguishing chamber switch with interruption points in series, in which the flow of liquid generated by the arc at one point of interruption the arc of the second interruption point against Bine perpendicular to the arc axis lying insulating partition wall of two outlet channels drives, according to the invention to both Sides of the insulating partition, at a distance from its edge, with the switch contacts related metal coverings arranged as fire-fighting poles on which the to be extinguished Part of the arc caused by the liquid flow generated in the quenching chamber itself driven and there, in a kinked shape, burning around the edge of the insulating wall, to extinction is brought.

In the case of compressed gas switches, an arrangement of the marked Type for external gas purging in proposal broached. So, first of all, step too with the new extinguishing chamber switch, the advantages of the pressure gas switch can be achieved with the special arrangement of the extinguishing poles. So it is achieved that at least the contact pin is freed from the arc as quickly as possible and before it burns up is protected. The arc burns steadily between the two Ld: schpo: len Long, so that the Lüschstr5-nmung acting counter pressure modgliclhst low est. The position of the arc to be ignited is also located in extremely favorable with regard to the flow of the extinguishing agent. After the The conductive gas column remaining in the current zero passage is through the flow of the extinguishing agent is driven against the edge of the insulating partition wall, there formally cut, and there are all charge carriers of the arc path to two sides displaced in the direction of the arc roots. In addition, when the new one occurs Switch all the benefits of a liquid flow switch to an increased extent in appearance. The medium, which is much more dense than a gas flow, penetrates in the current zero passage redht energetically into the residual gas column of the arc path, which runs over the edge of the partition wall in a bent position, cuts up so faster the residual gas column and pushes all charge carriers in the direction of the two outflow spaces away. This shortens the time until the final deletion.

Is used in the Ldsclhkamener to generate a differential pump piston built into the fluid flow, one has the guarantee that the pressure in the Extinguishing liquid many times higher than the arc gas pressure. Accordingly The strength of the light-arched column pressed against the wall can also be felt small, so that the separation of the Liehtbogenpfades in Stromnnuilldurchgang in still further shortened time before sicle gent. The maximum permissible limit for the This increases the current intensity considerably. In this case it is also possible the two outlet channels enclosing the insulating partition wall to the one from the larger one Piston area limited pressure space to fii, so that the light arc extinguishing Liquid flow only runs in the practically closed fire chamber.

From the illustrations shown in the drawing are for explanation. In Fig. I, two in a row are burning in one fire chamber when it is switched off Arcs between contacts 2, 3 and d, 5. Close to the separation point 4, 5 two chamber outlets 6, 7 are provided, the Bine insulating partition 8 between to fall asleep. Both channels contain extinguishing poles 9 and Io on which the arc is triggered is driven by the exiting liquid flow. The arc burns in the bent position tan the partition edge 8 around. Be on this partition edge 8 finm current zero passage all charge carriers of the arc path in opposite directions Riclhtting displaced to the two sides of the partition, so that the cleaned one The surface of the partition wall between the Ldschpolen g and Io prevents backfire.

Fig. 2 shows an extinguishing chamber divided into two rooms, of which the bine space iI has the fixed contact l2 and the second space 13 the two the insulating partition i- ;. including - # - uslal) oil tube provided with Ljpol 15 and 16 enti hâft. Between the two fire chambers there is a separation wall 1; through which the contact pin 18 and thus also the arc is drawn. Both the perforation of the wall 1; as well as those of the lid - «- and 19 des Rauines 13 are rait a conductive metal covering cerselien, which is associated with it and Ljpol located in the outflow cannulas 15, 16. Will the Contact pin i8 moves into the switch-off position, so browns in pressure chamber 11 tin particlitbogen, which the pressure increase necessary for the Lcisclistrmung in this room. The quenching current drives the one burning in room 13 Part of the arc on the fire poles in R3 urns 15 and 16, so that the arc again in the kinked position, which is most favorable for the 1-jungle, on the front edge the partition 14 is on fire.

The I_Qschkammereinteilung in Fig. 3 is the same as in the Fig 2. It is only, deviating from Fig. 2, still in the pressure chamber a differential pumping piston 20 installed in a manner known per se. This press - #: t the liquid located in space 21 over the arc part burning in space 13. Here, the i-ôschwirl #: ung is significantly increased, since the flushing of the light arc at increased speed and with a gas-free liquid. The AusfluPil @ arâle of space 13 open both to the fire chamber according to Fig. 2 and to the chamber According to Fig. 3 in the socket outside the fire hammer.

The release agent coating of the arc can, however, also occur Fig. 4 will. In this case, the two outflow channels 15 and 16 must be connected to the zone grMereti piston area limited space i i connected.

Claims (3)

PATENT CLAIMS: i. Fire chimney switch with interruption points in series, bel to the by the arc of one Un. interruption point of broken fluid stream 5mung the arc of the second interruption point against Bine perpendicular to the arc axis horizontal insulating partition between two outlet ducts, characterized by the fact that on both sides of the insulating partition wall at a distance from its edge with d'en Switch contacts in connection with metal coverings arranged as fire poles, to which the part of the arc to be extinguished is generated in the extinguishing chamber itself Liquid flow driven and there, in a kinked shape around the edge of the insulating wall burning, is brought to see. 2. Ldschlcammerschalter according to claim I, characterized. that a differential pump piston (2o) for generating the fluid flow is built into the fire chamber. 3. Extinguishing chamber switch according to claim I and 2, characterized in that the two outlet ducts (I5, 16) which include the insulating partition wall lead to the pressure chamber (II) which is limited by the larger mechanism of the differential piston. To distinguish the subject matter of the application from the state of the art, the following publication was taken into account in the grant procedure: British patent specification ..... No. 413 75 I.