SU1138874A1 - Device for protecting against earth leakage in isolated neutral system - Google Patents

Abstract

1. DEVICE FOR PROTECTION AGAINST CURRENT TO ZEMSSH IN A NETWORK WITH INSULATED NEUTRAL, containing zero sequence current transformers at each connection, current measuring elements made in the form of an RC circuit with a disconnecting key connected in parallel with a capacitor, and a DC amplifier connected to the executive relay, connected to the corresponding zero-sequence current transformer via a rectifier and an intermediate transformer, the voltage source is a zero-sequence However, to the output of which a voltage relay with a time delay is connected, as well as interlocking elements, characterized in that, in order to increase the selectivity and ensure the operation of intermittent arc closures, a diode-resistor unit consisting of series-connected resistor and two anti-parallel diodes and connected in parallel to the output of each zero-sequence current transformer, a blocking elements made in the form of blocking and intermediate a relay at each connection and a voltage relay with a time latch, with the intermediate relay winding connected to the measuring current output, one of the closing contacts of which is connected in series with the parallel locking and executive relay windings, one of the closing contacts of the latter is switched in parallel with the intermediate relay closing contacts , a disconnection w key is made in the form of an intermediate relay contact, the winding of which, respectively, for each connection connections at a second terminal zamykak CIM intermediate relay and through the newly introduced decoupling diode connected consecutively opening the tionary; yuschimi interlock relay contacts with all connections and zamykak CIM with 00 vy00 Derzhko time relay contact voltage. 2. The device according to claim 1, Ht; Due to the fact that, in order to ensure uninterrupted monitoring of the insulation resistance of the connections, operational amplifiers, each connected to the output of an intermediate transformer, and signaling elements connected to the corresponding outputs of operational amplifiers are introduced according to the number of connections.

Description

The invention relates to protection devices against single-phase earth faults in three-phase electrical networks with insulated neutral, mainly in distribution networks with a voltage of 6-35 kV. A device for protection against earth faults in networks with insulated neutral is known, containing at each connection the measuring organs in the form of a KS circuit, the capacitor of which is charged from a zero-sequence current with a time inversely proportional to this current. Since in the damaged connection the zero sequence current is the largest, the capacitor of the measuring device of the device installed at this connection is charged to the trigger level (setpoint), which must be disconnected before charging the RC circuit capacitors to the intact connections. A13 However, this device can selectively work only with sufficiently large differences between the values of the currents of the connections, which takes place with a large number (3-4 or more protected devices network connections, as the RC capacitance charging time on an intact connection must always be longer than the disconnection time of the damaged connection. Moreover, it cannot provide selectivity for intermittent arc closures and for inrush current zero moments of a metal ground fault. It is also known to have a ground fault protection device containing, at each connection, current measuring organs, implemented in the form of a charge with a disconnecting key connected in parallel of rum with capacitors for controlling the operation of RC-circuit for the purpose of detuning from inrush current at the initial moment of closing and blocking (barring) engage the safety nonselective tyvani executive bodies on intact devices when x Connections. This enlarges the area of selective operation of devices on this principle C 23. A disadvantage of the known device is the possibility of non-selective triggers with a minimum difference of the amplitude of the connection currents compared due to the imperfection of the operation algorithm and the circuit for generating the trigger switch, signal for blocking ( prohibition of charge capacitance of connections is formed only after the currents of all connections have reached their amplitude values and the signal arrives at the actuator. The imposition of such a ban (blocking) may be delayed relative to the time of formation. no false signal on intact attachment, i.e. the moment when the charge voltage of its RC circuit reaches its amplitude value. In this case, selective operation with arc intermittent ground-to-earth closures is impossible due to the fact that it is not possible to maintain the dependence of the amplitude of the signals from the current transformer on the primary currents of the intermittent closures, and the different amplitude spectrum and frequencies. The purpose of the invention is to increase the selectivity in ground locking and ensuring operation during intermittent arc ground locking. This goal is achieved by the fact that a device for protection against earth fault in a network with insulated neutral, containing zero-sequence current transformers at each connection, current measuring units, executed in the form of a charging RC circuit with a switch key connected in parallel with the capacitor, and a DC amplifier connected to an executive relay, connected to the corresponding H5 current sequence current transformer via a rectifier and an “intermediate transformer, source A zero-voltage voltage circuit, to the output of which a time delay relay is connected, as well as blocking elements, are inserted for each connection a diode-resistor unit consisting of series-connected resistors and two anti-parallel diodes and connected in parallel to the output of each current transformer zero sequence, and the blocking elements are in the form of a blocking and intermediate (I relay at each connection and a voltage relay with a time delay, and to the output The current tester is connected to the winding of the intermediate relay, one of the closing contacts of which is connected in series with the parallel winding of the blocking and actuating relays, one of the closing contacts of the latter is connected parallel to the closing contact of the intermediate relay, and the disconnecting key is made as an intermediate contact, winding of which for each connection, respectively. is connected to the second closing contact of the intermediate relay and through the newly introduced isolating diode with The sequence connected break contacts locking relay all connections and closes with you Derzhko time relay contact voltage. At the same time, in order to ensure continuous monitoring of the insulation resistance of the connections, operational amplifiers, each of which is connected to the output of the intermediate transformer, and signaling elements connected to the corresponding outputs of the operational amplifiers are introduced according to the number of connections. Fig. 1 is a schematic diagram of an earth fault protection device (for two connections); n figure 2 is a connection diagram of intermediate zero sequence turnips (for two connections, a dash is shown for the 5th connection; in figure 3, the dependences 1 (ct) and I (b) on the active insulation resistance (Rji) of the phases monitored power supply networks for isolation control and protective disconnection zones; The device at each connection contains a zero-sequence current transformer 1 (TYPE), measuring unit 2, made in the form of an RC circuit, and a DC liter with an intermediate relay 3 pa output connected to the transformer a current matrix 1 through the detector 4, an intermediate transformer 5 and a diode-resistor unit 6, a blocking 7 and an executive 8 relay, an intermediate relay 9 (figure 2), an alarm element 10 (a LED indicator consisting of a series of LEDs, tuned to the ignition, respectively, for a series of zero-sequence increasing current levels within the isolation control zone, for example, 0.05, 0.1, ..., 0.3 AJ, connected to the output of current transformer 1 through operational amplifier 11, as well as the voltage source 12 common to all connections - zero sequence and alarm and relay 14 connected to the output of the last relay 13 with time delay. In addition, the device has a high resistor 15 connected between the network neutral (for example, the zero point of the high voltage winding of the transformer own needs of the substation) and ground, generates an additional, active ground fault current, equal in value to 50-60% of the capacitive short circuit current in the network. The device works as follows. In normal mode, if there is no one or two phase reduction of the isolation level relative to the ground below the allowable (Fig. 3) or no single phase closure of the relay 13 of the signaling TS1-W and voltage relay 14 does not work, there is no signal on the transformer TYPE 1 sufficient to open the comparison element 10 (light indicator). Contacts 13.1 and 14.1 of relay 13 and 14 are in the open state, respectively, the contact 9.1 of the intermediate relay 9 is closed, the capacitor RC is discharged, the contacts 3.1 of the intermediate relay 3 and the contacts 8.1 of the operating relay 8 are open and the J.1 of the blocking relay 7 is closed . With a one or two phase reduction of the insulation resistance of the phases relative to the earth or a single phase earth fault through a large resistance (for example, the fall of the overhead wire on poorly conducting soils, leakage to the ground through the body of reinforced concrete support with agglomerated soil at the base, the fall of the wire on the crossbeam wooden supports and other damages) on one of the connections within the isolation control zone (Fig. 3), a neutral bias voltage of 2-3 V appears on the voltage source 12, and a current on the transformer 1 All monitored connections of the zo are the secondary currents of the NP, which, after amplification, arrive at the inputs of the signaling elements 10 (for example, light 1; indicators). In this case, the relay 13 is triggered and a warning signal is nonselective, and the current transformer of the damaged connection receives a current, the secondary value of which is higher than the control setpoint (for example, 0.05A, within 0.05-0.3 A), which, after amplification, turns out to be sufficient according to the dL level of opening and ignition of the corresponding LEDs of the LED indicator row at this connection Since the secondary NP current values, which are damaged during the connection, have the highest value, the largest number of lamps is ignited on its LED when compared to the other (intact) connections of the LEDs. This gives I the ability of the operating personnel of the sub-station or the dispatcher to simply and reliably determine the connection with degraded isolation and developing damage. When a single-phase short to earth through the resistors lying in the zone of protective tripping (Fig. 3), the voltage relay 14 operates and its contact 14.1 (Fig. 2) closes with a certain time delay (about 5-10 ms). In this case, relays 9 (9.9j9 with n outgoing lines) are triggered and their contacts 9.1 (9ij. 159e,% .. .9 1) are expanded. According to the charging circuits of the NP, which are the same for all connections, they start charging compress capacitors. The settings of the operation of the relay 3 (3, p., 3 ") at the output of the amplifiers are the same on all lines, but the capacitor of the damaged line, i.e., is charged first to the level of the transistor opening of the amplifier. where current NP is the highest in value. The relay trips 3 faulty lines, its contacts 3.1 and 3.2 close the relay coil circuit 7.8 and 9. Then contact 7..1 (relay 7) opens the power circuit of the relay coils 9, 9, ...,. 9 (relay circuit 9 is closed by contact 3.2) Relays 9, 9, ..., 9 return to their original state and instantly block the inputs of amplifiers of intact lines again with their contacts (contacts 9.1, 9. 1, ..., 9.1 are closed). Contact 9.1 of relay 9 remains open. Relay 8i triggers, self-blocking, closes its contact 8.2 in the circuit breaker disconnecting circuit of the damaged line .. .. When intermittent ground faults on the secondary windings of current transformers 1 due to surges in the primary current, reaching 100-200 A, there are Serial voltages that are limited by anti-parallel-connected diodes of block 6 to protect the input circuits. But due to the presence of a resistor connected in series with the diodes (resistance of about 0.1 ohms), due to the voltage drop across it, the voltage at the input of the intermediate transformer 5 is preserved from the primary current in the connections at any amplitudes. If the primary currents to ground do not exceed 15-20 A, then the voltage at the input of the transformer 5 does not exceed the voltage values of the opening of the diodes in the forward direction (0.3-0.5 V), i.e. due to the fact that they also do not flow through the diode-resistor circuit, the voltage supplied to the input of the transformer 5 is limited only by the resistor connected in parallel with the block 6. Consequently, the proposed device provides selective operation even with intermittent arc closures aeMlue The response time of the device is V V4 + 4 t8 where & t is the delay in the operation of the voltage relay 14 (on the order of 5-10 ms); - the time of operation .tj, tj tg of the corresponding relays 14, 9, 3, 7 and 8. For the selective operation of the relay, the conditions At + ti + 4 + H - H t + t44-t3 | f | - 1 ts-- time to charge the capacitance (less current) on intact connections. Therefore, in order to fulfill conditions (1) and (2), relays 14, 9, 3 and 7 must be fast-acting, for example, reed switches (such as RES-55A, etc.). have a response time of 1-2 ms, and relay 8 must be electromagnetic with a response time of 20-30 ms. Consequently, when grounding through the resistance in the protective disconnect zone, a selective signal is generated after 40-50 ms to disconnect the damaged connection,. Experimental studies in quarry distribution networks x 6 kV showed that the proposed device compares favorably with the known high selectivity with different types of single-phase closures (deaf, through transient resistance and intermittent arc) regardless of the number of protected connections and 15 networks. 113 8. as well as the possibility of selectively determining a site with degraded insulation for timely warning of developing accidents in networks and electrical equipment. The use of this device, for example, in distribution networks with a voltage of 6-10 kV. mines and mines provide a significant economic effect by reducing the downtime of powerful mining equipment due to non-selective network shutdowns and sudden damage to the insulation of electrical equipment

Claims (2)

1. DEVICE FOR PROTECTION AGAINST CIRCUIT TO EARTH ON A NETWORK WITH INSULATED NEUTRAL, containing zero-sequence current transformers at each connection, measuring current elements made in the form of a charging RC circuit with an isolating key connected in parallel with a capacitor, and a DC amplifier, the output associated with the executive relay connected to the corresponding transformer of the zero sequence current through the rectifier and the intermediate transformer, the voltage source zero sequence and, to the output of which a time delayed voltage relay is connected, as well as blocking elements, characterized in that, in order to increase the selectivity and ensure operation during intermittent arcing faults, a diode-resistor unit consisting of series-connected a resistor and two counter-parallel diodes and connected in parallel to the output of each zero-sequence current transformer, and the blocking elements are made in the form of a blocking and intermediate relay for each connection and a voltage relay with time delay, and the intermediate relay winding is connected to the output of the current measuring organ, one of the closing contacts of which is connected in series with the parallel windings of the interlocking and executive relays, one of the closing contacts of the latter is connected in parallel with the closing contact § of the intermediate relay, and the opening key is made in the form of an intermediate relay contact, the winding of which for each of the connections is connected to the second closing intermediate relay contact and through the newly introduced decoupling diode connected in series with opening the ^ - '• yuschimi interlock relay contacts and closing all connections with a time delay relay contact voltage. · 2. The device according to π.1, characterized in that, in order to provide continuous monitoring of the insulation resistance of the connections, operational amplifiers are introduced into it, according to the number of connections, each of which is connected to the output of the intermediate transformer, and alarm elements, connected to the corresponding outputs of operational amplifiers. SU „„ 1138874