RU2544834C1 - Device for recovery of voltage in broken phase of cable - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device relates to electrical engineering and can be used to ensure uninterrupted electrical power supply to consumers of self-contained objects at breakage of a cable phase. The device includes cable terminals, three voltage control relays, each of which is provided with one opening and two closing contacts, three thyristor keys, three phase-recovering capacitors, three phase-correcting throttles, three shunting thyristor keys and three output terminals. The voltage control relays are connected between the corresponding cable terminals for line voltage as well as in-series connected phase-recovering capacitor and thyristor key; phase-correcting throttles are connected between cable terminals and output terminals and shunted with thyristor keys, all thyristor keys are identical and each of them includes three parallel chains: the first and the third chains are formed with thyristors of direct and reverse connection, and the second chain is formed with an in-series connected diode of direct connection, a contact group, a resistor and a diode of reverse connection; with that, the contact group of thyristor keys includes in-series connected closing contact of a lagging phase and an opening contact of a proper phase, the contact group of the second chain of shunting thyristor keys is formed with the closing contact of the lagging phase. The above contacts of all the relays control operation of thyristors in the above said keys.

EFFECT: increasing quick action.

1 dwg

Description

The invention relates to the field of electrical engineering and can be used to ensure uninterrupted power supply to consumers of autonomous objects when the cable phase is broken.

A device is known for recovering voltage in a dangling phase of a cable, comprising three undervoltage relays with make and break contacts, compensating capacitors, phase-shifting reactors and terminals for connecting a three-phase load, while these relays are connected between the corresponding phases of the cable, compensating capacitors are connected between adjacent phases in series with NC contacts of the lagging relay, phase-shifting chokes are connected between the phases of the cable and the terminals of the same name three-phase load connections and are shunted by the closing contacts of the lagging relay [1]. This device provides voltage recovery in the event of a break in any one phase of the cable, is characterized by the simplicity of the circuit solution, relatively high reliability and low cost. However, it also has drawbacks, among which the main ones are: limited device power and a significant voltage recovery time.

The technical result of the invention is to increase the speed of the device when restoring the voltage of the dangling phase of the cable.

The technical result is achieved by the fact that in the device for voltage recovery in the broken phase of the cable containing the cable terminals A, B, C, the first, second and third voltage monitoring relays, each of which contains a first contact, a second contact and a third contact, the first the contact is made opening, the second and third contacts are made closing, the first, second and third phase-recovery capacitors, the first, second and third phase-correcting chokes and the output first, second and third terminals, while the first The second voltage monitoring relay is connected between cable terminals A and B, the second voltage monitoring relay is connected between cable terminals B and C, the third voltage monitoring relay is connected between cable terminals C and A, the first phase correction choke is connected between cable terminal A and the first output terminal, and the second a phase-correcting inductor is connected between cable terminal B and the second output terminal, a third phase-correcting inductor is connected between cable terminal C and the third output terminal, the first, second and third thyristor switches are inserted, made identical circuits, each of which contains three parallel circuits, the first of which is formed by a direct-connected thyristor, the second circuit is formed by series-connected direct-connected diodes, the second lag phase relay contact, the first own-phase relay contact, resistor, reverse-circuit diode, the third circuit formed by a thyristor reverse circuit, and the control electrode of the thyristor of the first circuit is connected to the cathode of the reverse circuit diode of the second circuit, and the control electrode of the thyristor of the third circuit connected to the cathode of the direct connection diode of the second circuit, with the first thyristor switch connected in series with the first phase-recovery capacitor between cable terminals A and B, the second thyristor switch connected in series with the second phase-recovery capacitor between cable terminals B and C, the third thyristor switch connected in series with the third a phase-recovery capacitor between the cable terminals C and A; in addition, the first, second and third shunt thyristor switches are introduced, each of which is connected in parallel with the corresponding phase-correcting inductor, while each of the shunt thyristor keys contains a pair of counter-parallel connected thyristors, the control transition of each of the thyristors of the pair is shunted in the opposite direction by a corresponding diode, and between the control electrodes of the thyristors of each pair a circuit is connected from a series-connected resistor and a make contact of the lag phase relay.

The drawing shows a circuit diagram of a device.

A device for recovering voltage in a dangling phase of a cable contains cable terminals A, B, C, first 1, second 2 and third 3 voltage monitoring relays, each of which contains a first NC contact: relay 1 - contact 1-1, relay 2 - contact 2 -1, relay 3 - contact 3-1, the second and third contacts make: relay 1 - contacts 1-2 and 1-3, relay 2 - contacts 2-2 and 2-3, relay 3 - contacts 3-2 and 3 -3, first 7, second 8 and third 9 phase-recovery capacitors, first 10, second 11 and third 12 phase-correcting chokes, first 16, second 17 and third 18 output terminals; the first 4, second 5 and third 6 thyristor switches made according to identical circuits, the first 13, second 14 and third 15 shunt thyristor switches made according to identical circuits, the first voltage monitoring relay 1 connected between the terminals of cable A and B, the second monitoring relay voltage 2 is connected between cable terminals B and C, a third voltage monitoring relay 3 is connected between cable terminals C and A, the first thyristor switch 4 is connected in series with the first phase-recovery capacitor 7 between the cable terminals A and B, the second thyristor switch 5 is on it is connected in series with the second phase-recovery capacitor 8 between the terminals of cable B and C, the third thyristor switch 6 is connected in series with the third phase-recovery capacitor 9 between the terminals of cable C and A; the first phase-correcting inductor 10 is connected between the cable terminal A and the first output terminal 16, the second phase-correcting inductor 11 is connected between the cable terminal B and the second output terminal 17, the third phase-correcting inductor 12 is connected between the cable terminal C and the third output terminal 18; the first shunt thyristor switch 13 is connected in parallel with the first phase-correcting inductor 10, the second shunt thyristor key 14 is connected in parallel with the second phase-correcting inductor 11, the third shunt thyristor switch 15 is connected in parallel with the third phase-correcting inductor 12; each of thyristor switches 4 ... 6 contains three parallel circuits, the first of which is formed by a direct-connected thyristor, the second circuit is formed by series-connected direct-connected diodes, the second lag phase relay contact, the first own-phase relay contact, a resistor, reverse-circuit diode, the third circuit is formed thyristor reverse connection, as applied to the key 4: the first circuit is the input of the key 4-1, the thyristor is a direct connection 4-2, the output of the key 4-7; the second circuit is the input of the key 4-1, the diode of the direct connection 4-3, the make contact 2-2, the make contact 1-1, the resistor 4-4, the diode of the reverse connection 4-5, the output of the switch 4-7, the third circuit is the input the key 4-1, the thyristor reverse switching 4-6, the output of the key 4-7, and the control electrode of the thyristor 4-2 is connected to the cathode of the diode 4-5, and the control electrode of the thyristor 4-6 is connected to the cathode of the diode 4-3; each of the shunt keys 13 ... 15 contains a pair of counter-parallel connected thyristors, the control transition of each of the thyristors of the pair is shunted in the opposite direction by a corresponding diode, and a circuit from the series-connected resistor and the closing contact of the lagging relay is connected between the control electrodes of the thyristors of each pair for the first shunt thyristor switch 13: a pair of counter-parallel connected thyristors: thyristor 13-2 and thyristor 13-6, the control electrode of the thyristor direct included I am 13-2 bypassed by a diode 13-5, the control electrode of the reverse thyristor 13-6 is bypassed by a diode 13-3, and between the control electrodes of the thyristors 13-6 and 13-2 a circuit is connected from the resistor 13-4 and the make contact 2-3 of the relay lagging phase, while the key input is 13-1, and the output is 13-7; opening contact 1-1 of the voltage monitoring relay 1 controls the operation of the thyristor switch 4 thyristors, opening contact 2-1 of the voltage monitoring relay 2 controls the operation of the thyristor switch 5, opening contact 3-1 of the voltage monitoring relay 3 controls the operation of the thyristor switch 6; the first make contact 1-2 voltage control relay 1 controls the thyristor of the thyristor switch 6, the first make contact 2-2 voltage control relay 2 controls the thyristor of the thyristor switch 4, the first make contact 3-2 voltage control relay 3 controls the thyristor of the key 5 ; the second make contact 1-3 voltage control relay 1 controls the thyristors of the shunt thyristor switch 14, the second make contact 2-3 voltage control relay 2 controls the thyristors of the shunt thyristor switch 13, the second make contact 3-3 voltage control relay 3 controls the work of the shunt thyristors thyristor key 15.

All elements of the device are serially produced by the domestic industry.

The device operates as follows. If there is voltage in all phases of the cable at its terminals A, B, C, the voltage of the specified value will appear, and the minimum voltage relay 1 ... 3 will trip, which will lead to the closure of contacts 1-2, 2-2, 3-2 and contacts 1- 3, 2-3, 3-3 and the opening of contacts 1-1, 2-1 and 3-1, as a result, the thyristor switches 4 ... 6 will be turned off, since their second circuits are open, while the phase-recovery capacitors 7 ... 9 are discharged, and shunt thyristor switches 13 ... 15 are included and phase-correcting chokes 10 ... 12 are bridged with these keys, while the currents from the cable terminals A, B, C will t flow through the wires to the output terminals 16 ... 18, which provide three-phase operating mode users (not shown). If any phase of the cable is interrupted (for example, phase A), there will be no voltage at the cable terminal A, respectively, there will be no voltage at relay 1, 3, therefore only voltage monitoring relay 2 will work, while only the contacts of the second relay will change the initial state: 2-1 2-2 and 2-3. When contact 2-2 closes through an open thyristor switch 4, a phase-reducing capacitor 7 charge circuit is formed, and current in phase A flows through the circuit: cable terminal B, phase-reducing capacitor 7, output 4-7, thyristors 4-6 (4-2) , the input 4-1 of the thyristor switch 4, the wire connecting the cable terminal A to the output terminal 16 (not indicated), the shunt thyristor switch 13 and the output terminal 16, while the current does not pass through the phase correction choke 10; the current in phase B will flow through the circuit: cable terminal B, phase-correcting choke 11, output terminal 17; the current in phase C will flow through the circuit: cable terminal C, phase-correcting inductor 12, output terminal 18, and when the second circuits of the thyristor switch 4 and the bypass thyristor switch 13 are closed, the thyristors of the first and third circuits will turn on and off alternately, providing current flow from the source to the load, since the control of these thyristors is formed from the anode voltages of the thyristors. As a result, phase A of the cable is restored from phase B, forming an angle between the previous position of the phase B vector equal to 90 °. To again make the voltage system with the new phase A vector symmetrical, the previous direction of the phase vectors B and C is shifted counterclockwise by an angle of 30 ° due to the inductances of the windings of the phase-correcting reactors 11 and 12.

The mechanism of formation of a symmetrical system of stresses at the break of any other phase remains the same.

Thus, the introduction of parallel and sequential thyristor switches has significantly improved the speed of the device, since the turn-on and turn-off times of power thyristors are units of μs at any power, since the direct currents of power thyristors exceed 1000 A.

Source

[one]. Copyright certificate of the Russian Federation No. 2006135, cl. H02J 9/06, H02M 5/14, 1994.

Claims (1)

A device for recovering voltage in a dangling phase of a cable, comprising cable terminals A, B, C, a first, second and third voltage monitoring relay, each of which contains a first contact, a second contact and a third contact, the first contact being made disconnecting, the second and third contacts made closing; the first, second and third phase-recovery capacitors, the first, second and third phase-correcting chokes and the output of the first, second and third terminals, while the first voltage monitoring relay is connected between the cable terminals A and B, the second voltage monitoring relay is connected between the cable terminals B and C, a third voltage monitoring relay is connected between cable terminals C and A; the first phase-correcting inductor is connected between the cable terminal B and the first output terminal, the second phase-correcting inductor is connected between the cable terminal B and the second output terminal, the third phase-correcting inductor is connected between the cable terminal C and the third output terminal, characterized in that the first, second and third thyristor keys made according to identical schemes, each of which contains three parallel circuits, the first of which is formed by a direct connection thyristor, the second circuit is formed sequentially by a direct-connected external diode, a second lag phase relay contact, a first eigenphase relay contact, a resistor, a reverse circuit diode, the third circuit is formed by a reverse circuit thyristor, the control circuit of the thyristor of the first circuit connected to the cathode of the reverse circuit diode of the second circuit, and the control electrode of the thyristor of the third the circuit is connected to the cathode of the direct connection diode of the second circuit, while the first thyristor switch is connected in series with the first phase-recovery capacitor between the terminals to Abel A and B, the second thyristor switch is connected in series with the second phase-recovery capacitor between the terminals of cable B and C, the third thyristor switch is connected in series with the third phase-recovery capacitor between the terminals of cable C and A; in addition, the first, second and third shunt thyristor switches are introduced, each of which is connected in parallel with the corresponding phase-correcting inductor, while each of the shunt thyristor keys contains a pair of counter-parallel connected thyristors, the control transition of each of the thyristors of the pair is shunted in the opposite direction by a corresponding diode, and between the control electrodes of the thyristors of each pair a circuit is connected from a series-connected resistor and a make contact of the lag phase relay.