DE937719C - Protection arrangement for series capacitors in high and medium voltage networks - Google Patents

Description

Protection arrangement for series capacitors in high and medium voltage networks The invention relates to a protection arrangement for high and medium voltage networks provided series capacitors bridged by spark gaps, which are used for compensation the inductive voltage drop. Such arrangements are known at those for extinguishing the arc in the current zero passage with protective spark gaps Pressurized gas are blown. Since the blowing, however, during the entire time of the short-circuit current occurs, each time the arc is extinguished on the series capacitors, high levels occur Voltages on which again when the response voltage of the spark gap is reached to collapse. The consequence is a strong intermittent load on the capacitors, which can easily lead to their destruction. In the protective arrangement according to the invention these stresses on the capacitors are avoided by controlling the Blowing device for the protective spark gap in such a way that only with cancellation of the short-circuit current a brief blowout begins. It is useful to do this two of the short-circuit current controlled, with their contacts in the electric circuit of the blower Horizontal relays are provided, one of which is a relay with a delayed response and falling normally open contact and the other relay is equipped with a normally closed contact is and through which the circuit for the blower device only with the cessation of the short-circuit current is closed. The arrangement of the relays is possible in various ways, such as in connection with the in Embodiments shown in the drawing the invention is apparent.

Fig. Z shows a circuit arrangement in which the "in the power line lying capacitor C the protective spark gap SF is connected in parallel. Of the The current transformer W1 through which the short-circuit current flows is with its secondary winding connected to a relay AR with a delayed response and falling Working contact is provided. Another current transformer through which the short-circuit current flows W2 controls a break contact relay RR via its secondary winding, which is only at a certain amperage which is higher than the nominal amperage of the capacitor C, comes to the fore. The coming from a facility not shown Glass air is controlled via the relay BR. The circuit for the - blow relay BR leads via the contacts of the normally open relay and the normally closed relay.

If a short circuit occurs on the line, the current transformer W2 the normally closed contact of relay RR is open. and after ignition of the protective spark gap SF Relay AR via current transformer W1, if necessary with an adjustable delay, closed. The glass relay BR is not actuated because its circuit is open. After the short circuit has been eliminated, the break contact relay RR drops out and closes as a result the circuit for the blower relay BR. The spark gap is now briefly blown and deleted immediately. In this way, if a short-circuit continues during the electrical Dead time reaches that the spark gap is safely deionized and when switched on again of the network does not re-ignite.

In Fig. 2 there is another. Circuit arrangement shown, the particularly It is then expedient if the protective spark gap is from a safety switch is bridged. In this circuit arrangement, the normally closed contact relay.RR is the Contacts of the safety switch SiS in parallel. The normally open contact relay AR is designed as a locking relay.

The mode of operation of this arrangement is as follows: The normally closed relay is initially open. Due to the short-circuit current flowing through the protective spark gap SF the relay AR is closed. A little later the safety switch SiS closes, so that the arc voltage of the spark gap SF collapses and thus that Relay RR drops out. The blower relay BR now receives power and the protective spark gap is briefly inflated. The locking of the relay AR is activated after the Interlock BR canceled, so that the blowing also stops again.

Another possibility for brief blowing of the protective spark gap after the short-circuit current has ceased, after closing the safety switch only to release the triggering of the glass relay via a delay relay.

Claims (3)

PATENT CLAIMS: r. Protection arrangement for in high and medium voltage networks intended series capacitors bridged by protective spark gaps blown by compressed gas, which are used to compensate for the inductive voltage drop, characterized by a control of the blower in such a way that only when the short-circuit current is canceled a brief blowing of the protective spark gap (SF) begins. 2. Protection order according to claim z, characterized in that in the circuit of the blower relay (BR) the Contacts of two relays controlled by the short-circuit current are provided, of which one relay (AR) with delayed responding and falling work contact and the other relay (RR) is equipped with a normally closed contact, creating the circuit for the blower relay (BR) is only closed when the short-circuit current has ceased. 3. Protection arrangement according to claim r and 2 with the protective spark gap connected in parallel Safety switch, characterized in that the normally closed contact relay (RR) the Safety switch (SiS) is connected in parallel. q .. protection arrangement according to claim z safety switch connected in parallel with the protective spark gap; through this characterized in that the safety switch is a controlling the contacts of the blower relay Delay relay is connected in parallel.