SU598169A1 - Electric network - Google Patents

Description

(54) ELECTRIC NETWORK

Claims (6)

The invention relates to the electric power industry and can be used in installations for melting ice with direct current on wires and cables of overhead power lines during smelting using earth as a return wire. Networks are known that contain transformers with a deafly grounded neutral, a device for melting ice with direct current and a grounding circuit of a substation as operational grounding for returning direct current over ground I. When melting ice with direct current using earth as a return wire and grounding circuits It is inevitable that direct current enters the AC circuit through grounded neutrals of transformers, which leads to their magnetisation, increased losses in transformer steel, and voltage distortion. These circumstances make it difficult, and often exclude, the use of substation grounding circuits as working groundings for direct current melting. An electrical network is also known, including, and transformers with grounded neutrals, a device for melting the ice with direct current and grounding loops of substations as working groundings for returning direct current by JCMJie | 2j. In this case, to avoid direct current melting on the alternating current, you can use the grounding circuit of the substation as a return wire from one end of the heated line, connect a negative rectifier to it from the opposite end of the line. grounding from the territory of the substation. The execution of remote grounding, calculated by the current of melting the current of melting of 1000 A, is complicated and expensive. In order to increase the reliability of the network during the melting of ice in the proposed electrical network, in neutrals of transformers, a low-voltage current-carrying element, surge arrester and switching device are installed in parallel. As a current limiting element can be used resistance or capacitor. In addition, a fuse is connected between the transformer neutral and the low-voltage current-limiting element. In addition, a thyristor contactor can be connected in parallel with the capacitor. and a discharge resistance is connected in series with the thyristor contactor. The presence of a current-limiting element prevents the DC branch in the neutral of transformers in normal network operation when melting on one of the lines, however, during emergency operation of the network (for example, during asymmetrical short circuits to earth or non-phase-phase modes) AC current inevitably for transformer neutrals and the presence of a current-limiting element may cause the relay network to malfunction. A possible change in the mode of operation of the network is prevented by shunting the current-limiting element, for which it is parallel to it. The detector is triggered when the voltage between the neutral and ground increases to a predetermined level. The connected n; jp; jj.ie, nbMo discharge card switching apiKipar, after switching on the discharging trigger, prevents damage to the latter and creates a dead-ground neutral grounding mode. FIG. 1 shows the scheme of the described shogi; in fig. 2 is one of the embodiments of current limiting resistance. The ground loop; 1 of the substation 1 is connected to the rectifier unit 2 for melting bare, e.aa on line 3 and the neutral of the transformer 4. The opposite end of the heating line 3 and the neutral of the transformers 6 and 7 are connected to the ground loop of the substation 5 the current can spread not only along the ground, but also across the network through the neutrals of transformers 4, 6 and 7. To limit the DC current branching into transformers 4, 6 and 7, current-limiting current circuits are installed in parallel between their neutrals and ground loops low voltage s elements 8 arrester 9 and the switching device 10. As tokoogranichivayuidego nizkovo. A resistive element as well as a capacitor can be used as a capacitive element. In addition, in order to increase the reliability of the current-limiting element, a fuse 11 is connected between it and the neutral of the transformer. FIG. 2 shows one of the variants of the current-limiting resistance 8, in which capacity a capacitor is used, in order to facilitate and increase reliability, a thyristor contactor 12 is connected in parallel with it, in series with which the discharge resistance 13 is connected. The switching device 10 must be supplied with a switching device, for example, , from the current sensor 14 installed in the arrester circuit 9. The current limiting element 8 is chosen in such a way as to sharply limit the amount of direct current, which responds when smelting in the neutral of transformers, or to prevent its flow through the neutrals completely. At the same time, for alternating current, which can occur in neutrals (for example, during asymmetrical short circuits to earth, long non-phase modes), the resistance of this element should be, as far as possible, insignificant. In the event of a sharp increase in the alternating current through the current limiting element on it, the voltage increases. The thermal stability of the current limiting element 8 is provided by a fuse 11 connected in series. When the fuse 11 is triggered, its restoring voltage is applied to the parallel-connected discharge 9, the volt-second characteristic of which is matched with the corresponding characteristics of the neutral insulation. When a glitter is triggered, a pulse is applied to turn on the shunt switching device 10 and a pulse can be given to turn off the ice melting unit. If a capacitor is used as the current-limiting element 8 (Fig. 2), then as the voltage increases on it and the pre-set level is reached, the thyristor contactor 12 is turned on, which limits the voltage on the current-limiting element 8. The cascade operation of the thyristor contactor 12, slot 9 and switching device 10 in case of accidents, during melting, provides a neutral grounding mode, similar to deaf grounding, which is necessary under the conditions of isolation and relay protection of the network. Eliminating the spreading of direct current melting through the AC network allows the use of grounding loops of substations as working earthing switches for diverting direct current to earth when melting according to the circuit using ground as a return wire. The rejection of expensive remote grounding will provide significant savings in the operation of ice melting units. 1. Electrical network comprising transformers with grounded neutrals, a device for melting direct current glaze and grounding loops of substations as working groundings for returning direct current on the ground, in order to increase reliability in neutrals The transformers are installed in parallel with the current-limiting low-voltage element, the arrester and the switching device. 2. The electrical network according to claim 1, characterized in that the resistance is used as a current-limiting low-voltage element. 3. The electrical network according to claim 1, wherein a capacitor is used as a current-limiting low-voltage element. 4. The electrical network according to claim 1, characterized in that a fuse is connected between the neutral of the transformer and the low-voltage current-limiting element. 5. The electrical network according to claim 1 and 3, characterized in that a thyristor contactor is connected in parallel with the capacitor. 6. Electrical network according to claim 1, 3 and 5, characterized in that the discharge resistance is connected in series with the thyristor contactor. Sources of information taken into account in the examination: 1.Buridorf V.V. Ice melting by direct current without disconnecting the line, “Electric stations, No. 10.1945. 2. Guidelines for melting ice on overhead power lines, M., STSTI ORGRES, 1969 ABOUT  ll / m VI -pcp one IT fb1 E