SU820599A1 - Device for maximum current protection of three-phase converter - Google Patents

Abstract

A DEVICE FOR MAXIMUM CURRENT PROTECTION OF THE 1TECHPHASE CONVERTER, containing in each phase a current derivative sensor connected in parallel to the current limiting element of the converter, the output centers of the current derivative sensor are connected according to the star-zero circuit, the terminal of the terminal of the terminal. a symmetric component filter containing windings of zero-sequence, direct and reverse sequences, each of which is connected to the input to the input its forward bridging bridge, the outputs of the above mentioned bridging bridges are connected in parallel and connected to an executive unit, characterized in that, in order to increase reliability, the zero-sequence filter winding is puffed out with a transformation ratio 1.5-2 times LESS than the winding filter of direct and inverse sequences of „a Ш ^ 5В ^ У9 ^ unit

Description

The invention relates to the field of electrical engineering and can be used in protection devices for converters.

A device for overcurrent protection is known, which contains current transformers with closed magnetic cores as sensors.

The disadvantage of these sensors is the saturation of the magnetic cores,

Closest to the invention in its technical essence and the achieved effect is a device for protection of a three-phase converter, which in each phase contains a current derivative sensor connected to a parallel

In a straightforward current-limiting element of the converter and a star with zero connected according to the scheme, a transformer filter of symmetrical components connected to the inputs of two pilot power bridges, respectively, connected in parallel with the outputs and connected to the actuator.

A disadvantage of the known device is the low sensitivity, speed at asymmetrical short closures and, as a result, low reliability.

The aim of the invention is to increase reliability. The goal is achieved by the fact that, in a known device, the zero sequence filter winding is performed with a transformation ratio 1.5-2 times smaller than the forward and reverse sequence filter windings. The drawing shows a schematic diagram of the device for maximum current protection of a three-phase high-voltage power supply to the electrical system 1 through the switching device 2 and the current-limiting elements 3, .4, 5 connected in series with it A three-phase high-voltage rectifier 6 with a load of 7 o is connected. In parallel, current-derived sensors 8, 9, 10 are connected to the current-limiting elements, the output circuits of which are assembled according to the star with zero circuit and connected to the input of the transformer filter I of the symmetrical components 11, consisting from the group of single-phase three-note transformers with. The output filter of the direct and inverse sequence 12 and the output of the zero-sequence filter 13 through rectifying motors 14 and 15 connected in parallel, are connected to the protection body 16 at the output. Rectifying bridges 14 and 15 contain delay lines in the form of KS circuits 17 and 18 to the parallel driver; common bus 19 is connected to an alternating current network of 20 ". To eliminate shunting effect of rectifying bridges 14, 15, diodes 21 and 22" are connected to their output. Current sensor B, 9, 10 can be used B dependencies t class voltage circuit in which single-phase transformers manufactured measured voltage and a cascade voltage single-phase transformers are connected in parallel current-limiting elements 3, 4, 5 ,, device operates as follows. The voltage on the current-limiting elements 3 ,. 4, 5, which changes the value in proportion to the derivative of the monitored current, is fed to the common input of the transformer filter symmetric components 11 and through rectifying bridges 14, 15 - to the input of the protection actuator 16o. The sensor activation circuit (8, 9, 10) provides the supply to the input of a transformer filter 11 of a three-phase voltage system. This system simulates a real one, when the primary circuit at the terminals of current-limiting elements on the side of the rectifier forms a neutral, Tooeo's short circuit (koZ) at the poles (K-1), internal Koz rectifier (K-2) and single-phase KoZ in its three-phase power supply circuit (K-3), or when K. Zo in the network 20, feeding in parallel with the converter 6 from common buses 19c, B of established short circuits at the poles direct current (K-1) and during the breakdown of the rectifier arm (K-2) a portion of the phase voltage of the power supply is applied to each of the reactors, which is proportional to the resistance of the current-limiting elements 3, 4, 5 At the time of the inverter. L 6 cannot increase abruptly, since the KOZ circuits are predominantly inductive. Therefore, the voltage on the current-limiting elements 3, 4, 5 is ahead of the current by almost the angle 1G. , at the moment KoZO is not zero and appears instantly. If we assume that the output voltage of rectifier bridges 14 and 15 at the moment k = passed through a maximum, then the next maximum will be reached no later than 1/6 of period B steady-state single phase to about 3 o in the power supply circuit of rectifier 6 (point K-3) or with single-phase KoZo at point K-4, the voltage on the current limiting element of the damaged phase is absent Voltage on the current limiting elements of the other two phases shifted relative to each other - 21G for certain The angle (from ––––) to a three-phase bridge 14 means the difference of these time-shifted sinusoidal voltages. At the output of the bridge, a pulsating voltage is obtained, as in the single-phase full-wave circuit, since in this case the pulse of the rectified voltage the output of bridge 14 occurs at a double frequency, possibly a delay: protection in the limit by half a period. This disadvantage is eliminated by means of a BOM zero-sequence filter, the voltage from which through the ignition bridge 15 is applied to the input At the open triangles of the zero sequence filter 9 in single-phase KoZ mode, a voltage is obtained in the power supply circuit of top 6 (point K-3), or in single-phase KoZ, at point K-4, a voltage is obtained proportional to the sum of the voltages current limiting elements of the intact phases, we will result in the resulting voltage — shifted in phase relative to the difference

. ft

these voltages at an angle x and amplitude are three times greater (assuming that the transformation ratio of the filter of symmetric components is taken equal to unity)

Parallel connection of rectifying bridges 14 and 15 increases the overall sensitivity of protection by 3 times, the maxima of the pulsating voltage at the output of bridge 14 coincide with the dips of the voltage at the output of bridge 15, the total output voltage pulsation occurs with a quadruple frequency, therefore the protection lags not fundamentally exceeds 1/4 period

When connecting a high-voltage rectifier for melting on a disconnected wire (VL) operating in a non-full phase mode, induction current from the wires of the VL phase phases remaining in operation will flow through the valves of the converter 6, this actually corresponds to the mode “s” at the poles of the converter to those until the magnitude of the current peak exceeds the value of the pickup current, and

A similar mode may occur when / - switching on converter 6 on one of the two-circuit LINU1 transmission lines taken out of operation, as well as on switching on two high-voltage reversing units for melting ice, connected in series on the DC side

To increase the selectivity of device operation in these modes, delay lines in the form of RC circuits (17.18) are introduced into the rectifying bridges 14 and 15 of protection.

Claims (1)

A DEVICE FOR MAXIMUM CURRENT PROTECTION OF A THREE-PHASE CONVERTER, containing in each phase a derivative of a current derivative connected in parallel to a current-limiting device