RU183849U1 - DEVICE FOR AUTOMATIC SWITCHING OF THE BACK-STARTED ELECTRIC TRANSMISSION BREAKER SWITCH - Google Patents

Abstract

The invention relates to a device for automatically turning on a backup power supply and equipment (ATS) and can be used to automatically turn on a backup power line circuit breaker when using a network ATS. The essence of a utility model is that a device for automatically turning on a backup power line circuit breaker is double-sided a line status selection key is used that sets the mode of its action, depending on which of the two lines at a given time is It is working, and which backup. Thanks to this, the device always acts to turn on the circuit breaker of the line that is in standby when the working line is turned off for any reason. The technical result achieved by the implementation of the utility model is to reduce the load current flow time along the lines, which increases the life of the lines power transmission due to their uniform wear due to the periodic change in the functions performed by the lines, that is, the alternate change in their status from working to standby and using a double-acting automatic transfer switch device, which automatically switches on the circuit breaker of the one that currently performs the backup function when the working line is disconnected for any reason. 2 of FIG.

Description

The utility model relates to devices for automatically turning on the backup power and equipment (ATS) and is intended to automatically turn on the switch of the backup power lines when using network ATS.

Known devices for automatically turning on switches of the backup power lines, ensuring their automatic switching on when disconnecting the switches of the working power line for any reason [Alekseev OP, Kazansky V.E., Kozis V.L. and others. Automation of electric power systems. M .: Energoatomizdat, 1981, p. 89, fig. 3.2; Electrical reference book: In 3 vols. T. 3, Prince. 1. Production, transmission and distribution of electrical energy / Under total. ed. professors MPEI V.G. Gerasimova, P.G. Grudinsky, L.A. Zhukova et al. 6th ed. corrected and add. M .: Energoizdat, 1982, p. 421, fig. 38-30].

Such devices provide a one-time inclusion of a backup power line circuit breaker by using a special single-acting relay or an ON position relay of a line circuit breaker, which uses intermediate relays with a delay when returning.

Closest to the claimed device is a device for automatically turning on the switch of the backup power line when using network ABP according to the patent for utility model No. 176677 [Device for automatically turning on the switch of the backup power line. Posted on 01/25/2018, Bull. No. 3], containing two starting voltage elements, each of which has two minimum voltage relays, which use NC contacts, and one maximum voltage relay, which use NO contacts connected to two voltage transformers installed on the power line and on prefabricated substation buses, two time relays with a contact that closes with a time delay, an intermediate relay that uses two make contacts, a two-position relay with two windings and with an open m and closing the contacts NO and NC relay contacts position "On" switch backup power lines, which switch acts on the device in question.

The single action of such a device is ensured by a two-position relay, and to automatically return it to a state of readiness for a new action, a circuit is used from a redundant switch of the “On” position relay of a backup line switch, a second make contact of the first maximum voltage relay and a make contact of a two-position switch relay.

However, this device assumes the constant use of the same power lines as a working and reserve one and ensures automatic switching of the circuit breaker of one of them that constantly performs the backup function. Such an ABP power line device is a single-acting device, therefore, when it is used, accelerated wear of the working power line and shortening of its service life occurs.

The technical problem that the utility model is aimed at is expanding the functional capabilities of the ATS device for power lines by automatically turning on the circuit breaker of the one that currently performs the backup function when the work line is disconnected for any reason.

The technical result achieved by the implementation of the utility model is to reduce the time the load current flows along the lines, as a result of which the life of the power lines increases due to their uniform wear due to a periodic change in the functions performed by the lines, that is, a change in their status from working to standby and the use of a double-acting automatic transfer switch device, which automatically switches on the circuit breaker of the one that is currently performing fu ktsii backup, if you disable the working line for any reason.

The specified technical result is achieved by the fact that the device for automatically turning on the switch of the redundant power line of double-sided operation, containing the first, second, third and fourth minimum voltage relays, and the winding of the first minimum voltage relay is connected to the terminals of the secondary windings of phases A and B of the first voltage transformer connected the primary winding to the first power line, the winding of the second minimum voltage relay is connected to the terminals of the secondary windings of phases B and C of the same voltage transformer, the winding of the third minimum voltage relay is connected to the terminals of the secondary windings of phases A and B of the second voltage transformer connected by the primary winding to the substation buses, and the winding of the fourth minimum voltage relay is connected to the terminals of the secondary windings of phases B and C of the same voltage transformer, the first and second maximum voltage relays, and the winding of the first maximum voltage relay is connected to the terminals of the secondary windings of phases A and C of the first voltage transformer, and the coil of the second maximum voltage relay is connected to the terminals of the secondary windings of phases A and C of the second voltage transformer, the first time relay, the first output of the winding of which is connected through the series-connected disconnecting contacts of the first and second minimum voltage relays and the closing contact of the second maximum voltage relay is connected to the first pole operating current source, and its second output is connected to the second pole of the operating current source, the second time relay, the first winding of which through The normally open interconnecting contacts of the third and fourth minimum voltage relays and the first making contact of the first maximum voltage relay are connected to the first pole of the operating current source, and its second output is connected to the second pole of the operating current source, the first intermediate relay, the first winding of which through parallel interconnected contacts of the first and second time relays that are interlocked with a time delay and a normally open contact connected to them of the second on-off relay is connected to the first pole of the operating current source, and the first make contact of this relay through the winding of the first indicator relay connects the first pole of the operating current source to the switch circuit of the first power line circuit breaker, the first terminal of the first winding of the first on-off relay is connected through the make contact the “on” position relay of the first line switch and the second make contact of the first intermediate relay are connected to the first pole of the source operating current, the second pole of which is connected to each other by the second terminals of the first and second windings of the first on-off relay, the first terminal of the second winding of which is connected through a series-disconnecting contact of the ON position relay of the first line switch, the second making contact of the first maximum voltage relay and the make contact of the first on-off relay is connected to the first pole of the operating current source, characterized in that the fifth and sixth minimum voltage relay, and the winding of the fifth minimum voltage relay is connected to the terminals of the secondary windings of phases A and B of the third voltage transformer connected by the primary winding to the second power line, the winding of the sixth minimum voltage relay is connected to the terminals of the secondary windings of phases B and C of the same voltage transformer, and interconnected disconnecting contacts of the fifth and sixth minimum voltage relays are connected in parallel circuits of interconnected interconnecting their contacts of the first and second minimum voltage relays, the third maximum voltage relay, the winding of which is connected to the terminals of the secondary windings of phases A and C of the third voltage transformer, and the first make contact of this relay is connected in parallel with the first make contact of the first maximum voltage relay, the second intermediate relay, the second on-off relay, closing and opening contacts of the “On” position relay of the second line switch, the second indicator relay, as well as a line status selection key with two make contacts, the first of which connects the second pole of the operating current source to the second terminal of the winding of the first intermediate relay, and the second contact of this key connects the second pole of the operating current source to the second terminal of the winding of the second intermediate relay, the first output of which is connected to the disconnecting contact of the second on-off relay to the connection point of the make contacts of the first and second time relays and the make contact of the first on / off relay, the first make contact of the second industrial the daily relay through the winding of the second indicator relay connects the first pole of the operating current source to the circuit of the second power line circuit breaker, the first output of the first winding of the second on-off relay through the second-line switch of the “On” position relay of the second line and the second make contact of the second intermediate relay connected to the first pole of the operating current source, the second pole of which is connected with interconnected second terminals of the first and the second winding of the second on-off relay, the first output of the second winding of which is connected through a disconnecting contact of the ON position relay of the second line switch, the second making contact of the third maximum voltage relay and the making contact of the second on-off relay is connected to the first pole of the operating current source.

The essence of the utility model is illustrated in FIG. 1, which shows a diagram of an electrical network, and FIG. 2, which shows a diagram of the operational circuits of a device for automatically turning on a double-acting backup power line circuit breaker.

A utility model can be implemented as follows.

The circuit of the electric network has two-way power from the first 1 and second 2 sources connected to the buses of substations 3 and 4, respectively. The first line 5, connecting the buses of substations 3 and 6, is connected to the buses of the substation 3 through the switch 7, and to the buses of the substation 6 through the switch 8. The second line 9, connecting the buses of the substations 4 and 6, is connected to the buses of the substation 4 through the second switch 10, and to the buses substation 6 through switch 11.

The primary windings of the first voltage transformer 12 are connected to the first line 5 at the substation 6 buses, the primary windings of the second voltage transformer 13 are connected to the substation 6 buses, and the primary windings of the third voltage transformer 14 are connected to the second line 9 at the substation 6 buses.

The windings of the first 15 and second 16 minimum voltage relays are connected to the terminals of the secondary windings of phases A and B and B and C, respectively, of the first voltage transformer 12, and the winding 17 of the first maximum voltage relay is connected to the terminals of the secondary windings of phases A and C of the same voltage transformer.

The windings of the third 18 and fourth 19 minimum voltage relays are connected to the terminals of the secondary windings of phases A and B and B and C, respectively, of the second voltage transformer 13, and the winding 20 of the second maximum voltage relay is connected to the terminals of the secondary windings of phases A and C of the same voltage transformer.

The windings of the fifth 21 and sixth 22 of the minimum voltage relay are connected to the terminals of the secondary windings of phases A and B and B and C, respectively, of the third voltage transformer 14, and the winding 23 of the third maximum voltage relay is connected to the terminals of the secondary windings of phases A and C of the same voltage transformer.

The first output of the winding 24 of the first time relay through two parallel circuits, the first of which is formed by the interconnecting disconnect contacts of the first 15.1 and second 16.1 minimum voltage relays, and the second circuit is formed by the serially connected disconnect contacts of the fifth 21.1 and sixth 22.1 minimum voltage relays, and in series with these circuits a make contact 20.1 of the second maximum voltage relay is connected to the first pole 25 of the operating current source, and the second output it is connected to the second pole 26 of the operating current source.

The first output of the winding 27 of the second time relay through the interconnecting disconnect contacts of the third 18.1 and fourth 19.1 minimum voltage relays and the first make contact 17.1 of the first maximum voltage relay and the first make contact 23.1 of the third maximum voltage relay connected in parallel with the first pole 25 of the source operational current, and its second output is connected to the second pole 26 of the operating current source.

The first output of the winding 28 of the first intermediate relay through the contacts of the first 24.1 and second 27.1 time relays, which are connected in parallel and interconnected with time delay, and the disconnect contact 29.1 of the first on-off relay 29 connected in series with them, is connected to the first pole 25 of the operating current source, and its second output through the first make contact 30.1 of the state selection key 30 is connected to the second pole 26 of the operating current source.

The first output of the winding 31 of the second intermediate relay through the opening contact 32.1 of the second on-off relay 32 is connected to the connection point of the contacts of the first 24.1, the second 27.1 time relay and contact 29.1 of the first on-off relay 29, and its second output through the second making contact 30.2 of the state selection key 30 is connected to the second pole 26 of the operating current source.

The first make contact 28.1 of the first intermediate relay through the winding 33 of the first indicator relay connects the first pole 25 of the operating current source to the switch circuit 8 of the first line 5, and the first make contact 31.1 of the second intermediate relay through the winding 34 of the second indicator relay connects the first pole 25 of the operating current source with the switching circuit of the switch 11 of the second line 9.

The first output of the first winding 29.2 of the first on-off relay 29 through the make-contact position switch 8.1 of the on-line switch 8 of the first line 5 connected in series with each other and the second make contact 28.2 of the first intermediate relay 28 is connected to the first pole 25 of the operating current source, the first output of the second winding 29.3 of the first on-off relay 29 through the disconnect contact 8.2 of the “On” position relay of the switch 8 of the first line 5 connected in series with each other, the second make contact 17.2 of the first maximum the first voltage relay and the make contact 29.4 of the first on-off relay 29 is connected to the first pole 25 of the operating current source, and the second terminals of the first 29.2 and second 29.3 windings of the first on-off relay 29 connected to each other are connected to the second pole 26 of the operating current source.

The first output of the first winding 32.2 of the second on-off relay 32 through the make-contact 11.1 of the “On” position relay of the switch 11 of the second line 9 and the second make contact 31.2 of the second intermediate relay connected to the first pole 25 of the operating current source in series, the first output of the second winding 32.3 of the second two-position relay 32 through the interconnected opening contact 11.2 of the "on" position relay of the switch 11 of the second line 9, the second making contact 23.2 of the third maximum th voltage relay and a make contact 32.4 a second on-off switch 32 is connected to a first pole of the control current source 25, and the second terminals of the first 32.2 and second 32.3 winding the second on-off switch 32, interconnected, connected to the second pole of DC voltage source 26.

The device operates as follows.

When you select as the working second line 9, the state selection key 30 is set to "Slave. 9". In this case, its contact 30.1 will be closed, and contact 30.2 open. The switches 10 and 11 of line 9 must be turned on, the switch 7 of line 5 is turned on, and the switch 8 is turned off. Consumers of substation 6 receive power on line 9 from power source 2.

The contacts of the first 15.1, second 16.1, third 18.1, fourth 19.1, fifth 21.1 and sixth 22.1 of the minimum voltage relay are open, and the contacts of the first 17.1, second 20.1 and third 23.1 of the maximum voltage relay are closed. The current from the operating current source does not flow through the windings of the first 24 and second 27 timers; their contacts 24.1 and 27.1 are open.

Contact 29.1 of the first on-off relay 29 is closed, but current does not flow through the winding 28 of the first intermediate relay, its contacts 28.1 in the switching circuit of switch 8 and 28.2 in the circuit of the first winding 29.2 of the first on-off relay 29 are open.

Contact 32.1 of the second on-off relay 32 is closed, but current does not flow through the winding 31 of the second intermediate relay, its contacts 31.1 in the switching circuit of switch 11 and 31.2 in the circuit of the first winding 32.2 of the second on-off relay 32 are open.

The closing contact 8.1 of the ON position switch of switch 8 of the first line 5 is open, and the closing contact 8.2 of the same relay is closed. Second contact 17.2 of the first maximum voltage relay is closed, and contact 29.4 of the first on-off relay 29 in the circuit of its second winding

29.2 open. Currents through the windings 29.2 and 29.3 of the first on-off relay 29 do not flow.

The closing contact 11.1 of the “On” position relay of the switch 11 of the second line 9 is closed, and the opening contact 11.2 of this relay is open. The second contact 23.2 of the third maximum voltage relay is closed, and the contact 32.4 of the second on-off relay 32 in the circuit of its second winding

32.3 open. Currents through the windings 32.2 and 32.3 of the second on-off relay 32 do not flow.

When the voltage disappears on the buses of substation 3 and in line 5, the first and second minimum voltage relays operate and close their contacts 15.1 and 16.1, and contact 17.1 of the first maximum voltage relay opens.

Through the series-connected contacts 15.1, 16.1, 20.1 and the winding 24 of the first time relay, current flows. The first time relay trips and closes its contact 24.1. Since the contacts 29.1 of the first on-off relay 29 and 30.1 of the state selection switch 30 are closed, the current flows through the winding 28 of the first intermediate relay, which, having tripped, closes its contacts 28.1 in the switching circuit of switch 8 and 28.2 in the circuit of the first winding 29.2 of the first on-off relay 29 .

The switch 8 is turned on, as a result of which the voltage on the tires of the substation 3 is restored, the consumers of which receive power from source 2.

After turning on the switch 8, the “On” position relay of this switch is activated, its contact 8.1 closes, and contact 8.2 opens. Through closed in series-connected contacts 8.1 and 28.2, the first winding 29.2 of the first on-off relay 29 receives power from the operating current source. The first on-off relay 29 switches, its contact 29.1 opens, and contact 29.4 closes.

As a result of the restoration of voltage in line 5, the first and second minimum voltage relays open their contacts 15.1 and 16.1 and open their contacts 24.1 of the first time relay, and their contact 24.1 opens in the circuit of the winding 28 of the first intermediate relay. The first intermediate relay returns to an idle state and opens its contacts 28.1 and 28.2.

If the loss of voltage in line 5 is caused by the circuit breaker 7 being turned off by the relay protection installed on the side of the substation 3 buses, as a result of a short circuit at point K1 on line 5 and this short circuit is stable, then after turning on the circuit breaker 8, it will be turned off by the relay protection, installed on line 5 from the bus side of substation 6.

The first and second minimum voltage relays will operate and their contacts 15.1 and 16.1 will be closed in the winding circuit 24 of the first time relay. As a result of the flow of current from the operating current source through the winding 24 of the first time relay, it will trip and close its contact 24.1 in the circuit of the winding 28 of the first intermediate relay. But the current through the winding of this relay will not flow, since its power supply circuit from the operating current source will be opened by the opening contact 29.1 of the first on-off relay 29. This ensures a single operation of the device.

The device returns to the state of readiness for a new action automatically after the voltage in line 5 is restored from the power source 1 and the circuit breaker 8 is turned off via the remote control circuit, that is, after the initial operation of the electric network is restored.

When the switch 8 is turned off, the contact 8.1 opens and the contact 8.2 of the "on" position relay of switch 8 closes. If in this case voltage is supplied to line 5 from the power source 1, then the second make contact 17.2 of the first maximum voltage relay will be closed. the contacts 8.2, 17.2 and 29.4 receive power from the operating current source, the second winding 29.3 of the first on-off relay 29. The first on-off relay 29 switches to its initial state, its contact 29.1 closes, and contact 29.4 opens. As a result of the closure of contact 29.1 of the on-off relay 29, the device is put into operation.

When the voltage disappears on the buses of substation 4, in line 9 and on the buses of substation 6, the third, fourth, fifth and sixth minimum voltage relays operate and close their contacts 18.1, 19.1, 21.1 and 22.1, and contact 20.1 of the second maximum voltage relay opens. As a result of this, the current does not flow through the winding 24 of the first time relay and its contact 24.1 remains open, and current flows through the contacts 18.1, 19.1, 17.1 and the winding 27 of the second time relay in series. The second time relay trips and closes its contact 27.1.

Since the contacts 29.1 of the first on-off relay 29 and 30.1 of the state selection switch 30 are closed, the current flows through the winding 28 of the first intermediate relay, which, having tripped, closes its contacts 28.1 in the switching circuit of switch 8 and 28.2 in the circuit of the first winding 29.2 of the first on-off relay 29 .

The circuit breaker 8 is turned on, as a result of which the voltage on the buses of substations 6 and 4 is restored, the consumers of which receive power from source 1.

After turning on the switch 8, the “On” position relay of this switch is activated, its contact 8.1 closes, and contact 8.2 opens. Through closed in series-connected contacts 8.1 and 28.2, the first winding 29.2 of the first on-off relay 29 receives power from the operating current source. The first on-off relay 29 switches, its contact 29.1 opens, and contact 29.4 closes.

As a result of the restoration of voltage in the line 9 and on the buses of the substation 6, the third, fourth, fifth and sixth minimum voltage relays open their contacts 18.1, 19.1, 21.1 and 22.1, the winding 27 of the second time relay loses power and its contact 27.1 opens in the winding circuit 28 of the first intermediate relay. The first intermediate relay returns to an idle state and opens its contacts 28.1 and 28.2.

If the disappearance of voltage in the line 9 and on the buses of the substation 6 is caused by the disconnection of the circuit breaker 10 by the relay protection of the line 9 installed on the side of the buses of the substation 4 as a result of a short circuit at point K2 on line 9 and this short circuit is stable, then after turning on the switch 8 the switch 11 will be disconnected by the relay protection of the line 9 installed on the bus side of the substation 6.

Since in this case there will be no voltage in line 9, the fifth and sixth minimum voltage relays will trip and their contacts 21.1 and 22.1 will be closed in the winding circuit 24 of the first time relay, and as a result of the voltage on the substation 6 buses, contact 20.1 of the second maximum will be closed voltage relay. A current will flow from the operating current source through the winding 24 of the first time relay, this relay will trip and close its contact 24.1 in the circuit of the winding 28 of the first intermediate relay. But the power circuit of the winding of the first intermediate relay from the operating current source will be opened by the opening contact 29.1 of the first on-off relay 29, as a result of which it does not work. The device for automatically turning on the switch does not work. Consumers of substation 6 receive power on line 5 from source 1.

The device is returned to the state of readiness for a new action automatically after the voltage is restored in the line 9 and on the substation 6 buses from the power supply 2 and the switch 8 is turned off via the remote control circuit, that is, after the initial operation of the electric network is restored.

When the switch 8 is turned off, the contact 8.1 opens and the contact 8.2 of the "on" position relay of switch 8 closes. If in this case voltage is supplied to line 5 from the power source 1, then the second make contact 17.2 of the first maximum voltage relay will be closed. the contacts 8.2, 17.2 and 29.4 receive power from the operating current source, the second winding 29.3 of the first on-off relay 29. The first on-off relay 29 switches to its initial state, its contact 29.1 closes, and contact 29.4 opens. As a result of the closure of contact 29.1 of the on-off relay 29, the device is put into operation.

When you select as the working first line 5, the state selection key 30 is set to "Slave. 5". In this case, its contact 30.1 will be open, and contact 30.2 is closed. The switches 7 and 8 of line 5 must be turned on, the switch 10 of line 9 is turned on, and the switch 11 is turned off. Consumers of substation 6 receive power on line 5 from power source 1.

The contacts of the first 15.1, second 16.1, third 18.1, fourth 19.1, fifth 21.1 and sixth 22.1 of the minimum voltage relay are open, and the contacts of the first 17.1, second 20.1 and third 23.1 of the maximum voltage relay are closed. The current from the operating current source does not flow through the windings of the first 24 and second 27 timers; their contacts 24.1 and 27.1 are open.

Contact 29.1 of the first on-off relay 29 is closed, but current does not flow through the winding 28 of the first intermediate relay, its contacts 28.1 in the switching circuit of switch 8 and 28.2 in the circuit of the first winding 29.2 of the first on-off relay 29 are open.

Contact 32.1 of the second on-off relay 32 is closed, but current does not flow through the winding 31 of the second intermediate relay, its contacts 31.1 in the switching circuit of switch 11 and 31.2 in the circuit of the first winding 32.2 of the second on-off relay 32 are open.

Closing contact 8.1 of the ON position switch of switch 8 of the first line 5 is closed, and NC 8.2 of this relay is open. Second contact 17.2 of the first maximum voltage relay is closed, and contact 29.4 of the first on-off relay 29 in the circuit of its second winding 29.2 is open. Currents through the windings 29.2 and 29.3 of the first on-off relay 29 do not leak.

The closing contact 11.1 of the "On" position relay of the second line switch 11 is open, and the opening contact 11.2 of this relay is closed. The second contact 23.2 of the third maximum voltage relay is closed, and the contact 32.4 of the second on-off relay 32 in the circuit of its second winding 32.3 is open. Currents through windings 32.2 and 32.3 of the second on-off relay 32 do not leak.

When the voltage disappears on the buses of the substation 4 and in line 9, the fifth and sixth minimum voltage relays contact 21.1 and 22.1 operate and close their contacts, and the contact 23.1 of the third maximum voltage relay opens.

Through the closed serially connected contacts 21.1, 22.1, 20.1 and the winding 24 of the first time relay, current flows. The first time relay trips and closes its contact 24.1. Since the contacts 32.1 of the second on-off relay 31 and 30.2 of the state selection switch 30 are closed, the current flows through the winding 31 of the second intermediate relay, which, having tripped, closes its contacts 31.1 in the switching circuit of the switch 11 and 31.2 in the circuit of the first winding 32.2 of the second on-off relay 32 .

The switch 11 is turned on, as a result of which the voltage on the tires of the substation 4 is restored, the consumers of which receive power from source 1.

After turning on the switch 11, the “On” position relay of this switch is activated, its contact 11.1 closes, and contact 11.2 opens. Through closed in series-connected contacts 11.1 and 31.2, the first winding 32.2 of the second on-off relay 32 is supplied with power from the operating current source. The second on-off relay 32 is switched on, its contact 32.1 opens, and the contact 32.4 closes.

As a result of voltage recovery in line 9, they return to their initial state and open their contacts 21.1 and 22.1 of the fifth and sixth minimum voltage relays, lose the power to the coil 24 of the first time relay and open its contact 24.1 in the winding circuit 31 of the second intermediate relay. The second intermediate relay returns to an idle state and opens its contacts 31.1 and 31.2.

If the disappearance of voltage in line 9 is caused by the disconnection of the circuit breaker 10 by the relay protection installed on the bus side of the substation 4, as a result of a short circuit at point K2 on line 9 and this short circuit is stable, then after the circuit breaker 11 is turned on, it will be disabled by the relay protection, installed on line 9 from the bus side of substation 6.

The fifth and sixth minimum voltage relays will operate and their contacts 21.1 and 22.1 will be closed in the winding circuit 24 of the first time relay. As a result of the flow of current from the operating current source through the winding 24 of the first time relay, it will trip and close its contact 24.1 in the circuit of the winding 31 of the second intermediate relay. But the current through the winding of this relay will not flow, since the circuit of its power supply from the operating current source will be opened by the opening contact 32.1 of the second on-off relay 31. This ensures a single operation of the device.

The device is returned to the state of readiness for a new action automatically after the voltage in line 9 is restored from the power source 2 and the circuit breaker 11 is disconnected via the remote control circuit, that is, after the initial operation of the electric network is restored.

When the circuit breaker 11 is disconnected, the contact 11.1 opens and the contact 11.2 of the ON position relay of the switch 11 closes. If in this case voltage is supplied to the power supply from line 2, then the second making contact 23.2 of the third maximum voltage relay will be closed. the contacts 11.2, 23.2 and 32.4 receive power from the operating current source, the second winding 32.3 of the second on-off relay 32. The second on-off relay 32 switches to its initial state, its contact 32.1 closes I, and contact 32.4 opens. As a result of the closure of contact 32.1 of the on-off relay 32, the device is put into operation.

When the voltage disappears on the buses of substation 3, in line 5 and on the buses of substation 6, the third and fourth minimum voltage relays trip and close their contacts 18.1 and 19.1, and contact 20.1 of the second maximum voltage relay opens.

Through the series-connected contacts 18.1, 19.1, 17.1 and the winding 27 of the second time relay, current flows. The second time relay trips and closes its contact 27.1.

Since the contacts 32.1 of the second on-off relay 32 and 30.2 of the state selection switch 30 are closed, the current flows through the winding 31 of the second intermediate relay, which, having tripped, closes its contacts 31.1 in the circuit of the switch 11 and 31.2 in the circuit of the first winding 32.2 of the second on-off relay 32 .

The circuit breaker 11 is turned on, as a result of which the voltage in line 5 is restored, on the buses of substations 6 and 3, the consumers of which receive power from source 2.

After turning on the switch 11, the “On” position relay of this switch is activated, its contact 11.1 closes, and contact 11.2 opens. Through closed in series-connected contacts 11.1 and 31.2, the first winding 32.2 of the second on-off relay 32 is supplied with power from the operating current source. The second on-off relay 32 is switched, its contact 32.1 is opened, and contact 32.4 is closed,

As a result of voltage recovery in the line 5 and on the substation 6 buses, they return to their initial state and open their contacts 15.1, 16.1, 18.1 and 19.1 the first, second, third and fourth minimum voltage relays, the winding 27 of the second time relay loses power and its contact 27.1 opens in the winding circuit 31 of the second intermediate relay. The second intermediate relay returns to the Unused state and opens its contacts 31.1 and 31.2.

If the disappearance of voltage on the buses of the substation after line 5 is caused by the disconnection of the circuit breaker 7 by the relay protection of line 5 installed on the side of the buses of the substation 3, as a result of a short circuit at point K1 on line 5 and this short circuit is stable, then after turning on the switch 11 it will be turned off switch 8 by relay protection of line 5 installed on the side of the substation 6 tires.

Since in this case there will be no voltage in line 5, the first and second minimum voltage relays will trip and their contacts 15.1 and 16.1 will be closed in the winding circuit 24 of the first time relay, and as a result of the voltage on the substation 6 buses, contact 20.1 of the second maximum will be closed voltage relay. Current will flow from the operating current source through the winding 24 of the first time relay, this relay will trip and close its contact 24.1 in the circuit of the winding 31 of the second intermediate relay. But the power circuit of the winding 31 of the second intermediate relay from the operating current source will be opened by the opening contact 32.1 of the second on-off relay 32, as a result of which it does not work. The device for automatically closing the switch does not work. Consumers of substation 6 receive power on line 9 from source 2.

The device is returned to the state of readiness for a new action automatically after the voltage is restored in the line 5 and on the substation 6 buses from the power supply 1 and the switch 11 is disconnected from the remote control key, that is, after the initial operation of the electric network is restored.

When the circuit breaker 11 is disconnected, the contact 11.1 opens and the contact 11.2 of the ON position relay of the switch 11 closes. If in this case voltage is supplied to the power supply from line 2, then the second making contact 23.2 of the third maximum voltage relay will be closed. the contacts 11.2, 23.2 and 32.4 receive power from the operating current source, the second winding 32.3 of the second on-off relay 32. The second on-off relay 32 switches to its initial state, its contact 32.1 closes I, and contact 32.4 opens. As a result of the closure of contact 32.1 of the second on-off relay 32, the device is put into operation.

The proposed device for automatically turning on the backup power line circuit breaker is a double-acting device, which expands its functionality, which makes it possible to increase the life of the lines by ensuring uniform wear.

Claims (1)

A device for automatically turning on a double-acting backup power line circuit breaker, comprising a first, second, third and fourth minimum voltage relay, the winding of the first minimum voltage relay being connected to the terminals of the secondary windings of phases A and B of the first voltage transformer connected by the primary winding to the first power line, the winding of the second minimum voltage relay is connected to the terminals of the secondary windings of phases B and C of the same voltage transformer, the winding of the third the voltage relay is connected to the terminals of the secondary windings of phases A and B of the second voltage transformer connected by the primary winding to the substation buses, and the winding of the fourth minimum voltage relay is connected to the terminals of the secondary windings of phases B and C of the same voltage transformer, the first and second maximum voltage relays, moreover, the winding of the first maximum voltage relay is connected to the terminals of the secondary windings of phases A and C of the first voltage transformer, and the winding of the second maximum voltage relay is connected on to the terminals of the secondary windings of phases A and C of the second voltage transformer, the first time relay, the first output of the winding of which through the interconnected disconnecting contacts of the first and second minimum voltage relays and the closing contact of the second maximum voltage relay is connected to the first pole of the operating current source, and its second output is connected to the second pole of the operating current source, the second time relay, the first output of the winding of which through disconnect the strokes of the third and fourth minimum voltage relays and the first make contact of the first maximum voltage relay is connected to the first pole of the operating current source, and its second output is connected to the second pole of the operating current source, the first intermediate relay, the first winding of which through parallel connected to each other by time delay the contacts of the first and second time relays and the NC contact of the first on-off relay connected in series with them are connected to the first pole operating current, and the first make contact of this relay through the winding of the first indicator relay connects the first pole of the operating current source to the circuit of the first power line circuit breaker, the first output of the first winding of the first on / off relay through the first contact of the first position relay “On” switch of the first line and the second make contact of the first intermediate relay is connected to the first pole of the operating current source, the second pole of which is connected with interconnected by the second terminals of the first and second windings of the first on-off relay, the first terminal of the second winding of which is connected to the first line circuit breaker, the second make contact of the first maximum voltage relay and the make contact of the first two-position relay through the disconnect contact of the first position relay pole of the operating current source, characterized in that the fifth and sixth minimum voltage relays are introduced into it, and the winding of the fifth minimum the voltage relay is connected to the terminals of the secondary windings of phases A and B of the third voltage transformer connected by the primary winding to the second power line, the winding of the sixth minimum voltage relay is connected to the terminals of the secondary windings of phases B and C of the same voltage transformer, and the disconnecting contacts connected in series of the fifth and sixth minimum voltage relays are connected in parallel to the circuit from the disconnect contacts of the first and second minimum relays connected in series voltage, the third maximum voltage relay, the winding of which is connected to the terminals of the secondary windings of phases A and C of the third voltage transformer, and the first make contact of this relay is connected in parallel with the first make contact of the first maximum voltage relay, the second intermediate relay, the second on / off relay, make and break contacts the “on” position relay of the second line switch, the second indicator relay, as well as the line status selection key with two make contacts, the first of which connects t the second pole of the operating current source with the second terminal of the winding of the first intermediate relay, and the second contact of this key connects the second pole of the operating current source with the second terminal of the winding of the second intermediate relay, the first terminal of which is connected to the connection point of the closing contacts of the first and the second time relay and the opening contact of the first on-off relay, the first closing contact of the second intermediate relay through the winding of the second indicator the relay connects the first pole of the operating current source with the second circuit of the second power line circuit breaker, the first output of the first winding of the second on-off relay through the second-position circuit breaker “On” of the second line circuit breaker and the second closing contact of the second intermediate relay connected to the first pole of the operational source current, the second pole of which is connected with interconnected second terminals of the first and second windings of the second on-off relay, the first the second terminal of the second winding of which, through the disconnected contact of the ON position relay of the second line switch, the second make contact of the third maximum voltage relay and the make contact of the second on-off relay, is connected to the first pole of the operating current source in series.

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