DE1870499U - ARRANGEMENT FOR TESTING SWITCHGEAR. - Google Patents

Description

SIEMENS

SIEMENS-SCHUCKERTWERKE AKTIENGESELLSCHAFT

Berlin and Erlangen patent and license department

® BERLIN-SIEMENSSTADT

60/0092

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throw, kicked

-1·

PA 60/0092

of the tension that is lulled in the yoke styoma towards afar the course suggested st romes returns.

firing
According to WW8M $ , a three-electrode spark gap with an ignition electrode is used as the spark gap for connecting the high voltage source, the middle electrode of which is connected to one pole of the high voltage source via a resistor. Accordingly, between this center electrode and the electrode that is connected to the other pole of the high-voltage source, the voltage of the high-voltage source always prevails before the breakdown. This voltage between the two electrodes is not influenced by the voltages occurring in the hole-tri-circle, as would be the case, for example, if a Zv / eielektorfunkenspinkgap would be used. As a result, lie in the estuary before getting clear ferhältniiee, which is favorable to the spark gap for Mn Bmrehsohlag.

firing The drawing shows an embodiment of the ÄliöMIp. 1 with the m testing switch is referred to. In series with it is in a known manner an auxiliary switch 2, which receives the switch command at the same time or approximately at the same time as the switch to be tested. The two switches are connected in series to the transformer 5, to which a capacitor 9 is connected in parallel. The transformer is fed via the choke coil 4 and the switch 5 from the generator β. Parallel to the switch to be tested

PA 60/0092

lies- the lending circuit from a capacitor 13 and .einem. ohascheii iiderst & Ed 14. Parallel mm auxiliary switch is borrowed from capacitor Ii and resistor 12. Mt ■ called ext file form dtit high current circuit. Her high-voltage circuit consists of the charged capacitor 10, which can also be replaced by another high-voltage source, the broad-strip electrode fences 15, the lidar stand 20- and the inductance 21. The fulcrum strip 15 has three Ilectrodes 16, 1? uni 18. In. the Il @ ktroete 18 igl-in feekamter quietly inserted the 2ilndelectrode 19. Biese receives two-fold of the potential from supply electrode # 18, in the example shown here because a smooth element 24 electrode 18 and ignition pin 19 are provided, which are permeable to the DC voltage but impermeable to the ignition pulse. The ignition electrode receives its ignition pulse via the dry rectifier 23, which is connected to the resistor 8, which is in line with the spark gap 7 in parallel with the line circuit from switch 1 and switch 2. The dry rectifier is connected in such a way that it opposes the direct voltage of the high voltage source with a high resistance, but allows the ignition pulse to pass through. The center electrode 17 is connected to the lower pole of the circuit breaker coil 10 via a high-ohm resistor 22.

To test, switch 5 is closed and the two switches 1 and 2 receive the switch-off command. Is flows above both of the furring stream. When the switches stop

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M 60/0092

reach distance, occurs after Bull are äes current to the two switches and extinction of the arcs a recovery voltage, which is supplied from the high-current source and is distributed according to the lying parallel to the _t two switches "leitascti &ltunp" of resistance mii Konäeneator. By suitable choice of the elements of the hole circuit, a recurring voltage can be generated on the switch 1, which is a prescribed. Course corresponds. As soon as this voltage reaches a certain ififert, the spark gap 7 responds. As a result, the ignition electrode 19 receives a voltage pulse, causing a breakthrough to the slektrode 18 and then to the electrodes 17 and 16, whereby the high voltage source is now effective, which now generates a recurring voltage at the switch 1 together with the high current * source, which e.g. corresponds to the run required by regulations. For this purpose, the ignition point and the switching elements must be selected or dimensioned accordingly.

As already mentioned, a three-electrode spark gap is used intended. As mentioned, this has the advantage that the electrodes swish before the breakdown. 17 and 18 always the Späimsmg the Ioehspsiffiungstpelle Iiigt. flria man. just one Provide electrical spark gap, so the distance must of the electrodes, also be measured for this voltage. in the However, the moment of ignition by the auxiliary electrode 19, the voltage between the two main electrodes is due

the recurring voltage of the high-current circuit at the switch 1 smaller. This would adversely affect the breakdown between the main electrodes. In the exemplary embodiment it is assumed that the repetitive voltage is positive. As a result, the top terminal of the capacitor is positive, the lower terminal negative and the second pulse also positive.

If the ^ circuit of the voltage in the lülliyretifäng or before the iulläurali§ang takes place, the ferwtntai a wide-electrode fimkenstreckö also cheap, because with one EweifaöhfMnkenstrecken would go through the BriimspaimuBg dee Hochetroiakreisa influences the tension between the electrodes j so that the accuracy of the point in time of the average would be affected.

1 figure
1 claim

Claims (1)

FA 6Ö / Ö092 Protection claim: zvtr sjatlieiisctai test toe Setaltggraten with a Hoe & strom «and a locJaspasniiiigspelle, ait over a spark gap ait express electrode to the to be tested Switching device is switched on and its ignition electrode is one lilnäiiipuls in the ability of an Oven iee Bbchstrosr circle receives, daänroli gekeimzeicteit, deS as Fimkenstreckö ice. ireielektorodeiifEneiistrecke serves, whose Medium electrical power over iron resistance with one Pole of the voltage source is verijimden. -6-