SU888047A2 - Device for testing switches for charging current cut-out - Google Patents

Description

I

The invention relates to electrical engineering, namely to the field of testing high-voltage circuit breakers in the disconnection mode of unloaded (idle) lines.

Claims (1)

Basically auth. St. G describes a device for testing switches for switching off the charging current used in switching tests of high-voltage switches in the mode of switching off capacitive currents of unloaded lines. This device contains a capacitor bank connected in series, a switch-on element, a reactor and a shut-off element, forming an industrial-frequency oscillating circuit, an additional reactor connected in parallel with the shut-off element. Parallel to the capacitor battery, a chain is connected, consisting of a series-connected reactor reproducing the inductance of a real source, a switch being tested, and an index-discontinuous Da simulating a disconnecting line. | In parallel with a reactor reproducing the inductance of a real source, an RC-chain of regulation of the restoring voltage is turned on. For pre-charging capacitors, the device contains a DC power supply unit 13. The disadvantage of this device is that when the circuit breaker is tested, the oscillating circuit will have a capacitor bank. attenuate due to the presence of significant active losses in the oscillating circuit and on the arc of the test breaker. Therefore, after the capacitance switch under test is interrupted, the voltage recovered at the contacts of the switch may be insufficient. The use of a high-power capacitor bank in an oscillating circuit to reduce voltage attenuation is associated with large capital expenditures, since the gchondensator battery is manufactured at a high voltage where and. - the greatest operating voltage of the switch. The aim of the invention is to improve the test accuracy by reproducing the amplitude of the restoring voltage at the switch under test. The goal is achieved by the fact that the device for testing switches is equipped with a compensating capacitor and a switch-on element connected in series with the second additional reactor. Diagram of the device shown in the drawing. It contains a capacitor 1 that simulates a switchable line, a DC power supply unit 2, a test switch 3, a switch element, a capacitor battery 5, the first additional reactor 6, the reactor 7i resistor 8 and the capacitor 9, an RC chain for adjusting the form of restoring voltage network side, the second additional reactor 10, the disconnecting element 11, the compensating capacitor 12, the switch-on element 13. The capacitor battery 5, the switch-on element k, the reactor 7, the shut-down element 11 are connected in series and when turned on Lema that form an oscillating circuit incorporating a high voltage power frequency. A chain of series-connected reactor 6, test switch 3 and capacitor 1 is connected in parallel to a capacitor battery. Switch-on element 13, additional reactor 10 and compensating capacitor 12 are connected in series and shunt the disconnecting element 11. Reactor 6 reproducing inductance of the real network is shunted in series included resistor 8 and capacitor 9. The device operates as follows. Before the experience, the tested switch 3, the disconnecting element, 11 are switched on, and the switching elements 4, 13 are disconnected. From a constant voltage source 2 to the required voltage (depending on the voltage class 7 of the tested switch), the voltage of the same polarity is charged by the capacitor battery 5 and the capacitor 1. At the same time, the compensating capacitor 12 is charged from the constant voltage source (not shown) The magnitude of the charging voltage of the compensating capacitor 12 depends on the magnitude of the required voltage compensation and the ratio of the capacitors of the capacitor battery and the compensating capacitor 12. The polarity of the charging voltage the reaping capacitor 12 must be such that at the moment the capacitance current switch 3 capacitive current 5 has a polarity opposite to the polarity of the capacitor 12. At some point in time, the switch-on element is triggered and the command to turn off the test switch 3 is triggered. capacitive current. After the contacts of the test switch are opened and the discharge current of the capacitor 1 is broken, a voltage remains on the capacitor that simulates the residual charge of the disconnecting line. At the time of the zero current to be switched off, the disconnecting element 11 is triggered, the switching element 13 is triggered, and an additional reactor and charged compensating capacitor 12 are introduced into the oscillating circuit of the battery 5 and the reactor 7. The oscillatory process in the circuit 5-7, 10-12 depends on on the equivalent capacitance of the series-connected capacitor bank 5 and the compensating capacitor 12 and on the sum of the inductances of the reactor 7 and the additional reactor 10. The inductance of the reactor 10 is selected from the condition wounds in the circuit 5-7, 10-12 of the industrial frequency after the switch disconnects the capacitor 1, simulating a disconnecting line. Through the half-cycle of the industrial frequency, the capacitor battery 5 recharges and its polarity will be opposite to the polarity of the charge of the capacitor 1. After recharging, the voltage on the capacitor battery 5 and capacitor 12 is distributed in inverse proportion to the OT of the capacitor bank 5 and the compensating capacitor 12. Since the capacitance of the compensating capacitor 12 (performed at a relatively small voltage) is much greater than the capacity of the battery S, the voltage on the capacitor battery 5 is The overcharging will increase, and on the compensating capacitor 12 it will decrease. Thus, the circuit allows compensation of the voltage on the capacitor battery of the oscillating circuit and adjusts the amplitude of its own reconstructed shunt voltage on the contacts of the tested switch on the side of the oscillating circuit. To substantiate the technical and economic efficiency of the proposed device, we consider, for example, the necessary parameters of the circuit when testing two discontinuities (4-4) of the BB-500 kV switch in the off-load mode. According to GOST 12 50-73, it is necessary to reproduce the current of the unloaded phase 1, 5-500 A 750 A and the amplitude of the industrial voltage frequency 1-H.I, jL 525 -Г-25КК that is restored through the half-period. nr and -Gb 5 A capacitor that imitates a disconnecting line should have a C 26.2 microfarad capacity, Ucp 130 kV (cost 37 thousand rubles). We have, for example, a capacitor bank C 131 microfaram capacitance. When the circuit operates in the half-period of the arc through the condensate circuit 1 and the test switch 3, a charge current of 750 A flows and through the capacitor battery of the oscillating circuit tOOO A. Due to the presence of active resistances in the circuit (protective resistors of each capacitor) and energy release on the arc of the switch under test (the resistance of the arc column is significantly due to the small switchable current) the voltage on the end-line battery 5 will decrease by half. After a break in the tested switch during the recovery period, the current flows only in the oscillating circuit of the industrial frequency and the voltage of the capacitor battery 5 will decrease by another 6-8 times the initial charge voltage. The invention The device for testing switches for switching off the charging current according to aut. St. If 699 "53, characterized in that, in order to increase the test accuracy by reproducing the amplitude of the restoring voltage on the switch under test, it is equipped with a compensating capacitor and switching element, which are connected in series with the second additional reactor. Sources of information taken into account in the examination 1. USSR author's certificate, If, cl. (5 01 R 31/32, 1977. eight /