SU1001298A1 - Self-checking dc voltage supply system - Google Patents

Description

 The invention relates to electrical engineering and is intended for operation in the composition of the secondary power supply means of electronic equipment, in which automatic re-activation is performed after the protection has been activated.

A device for protection and automatic re-activation is known, which is characterized by increased uninterrupted power supply to the consumer by eliminating the non-selective effect of protection if it is damaged, which allows the user to continue the power supply at the cost of rejecting protection that has failed due to malfunction and threatening to interrupt the work of the customer 1.

However, in building responsible power supply systems that focus on the quality of electrical energy, i.e. the strict correspondence of the voltage level to the specified tolerance field may arise the inverse problem: to strictly forbid the operation of the power supply system if the protection device is defective. This raises, for example, the question of supplying test equipment to enterprises — manufacturers of electronic systems. A certain delay in the implementation of their power supply during the break-down of the power supply system does not entail such severe consequences as possible if it was allowed to feed the object: power supply of unregulated voltage levels.

When creating such power supply systems, preference is given to the development of protection devices, their automatic self-control and automatic restart, but only when the power supply system is fully operational.

Closest to the proposed is CC1, the monitored DC power supply system, consisting of a power supply unit, the input of which is connected to the network buses, a protection sensor with an output optocoupler, an automatic control unit with a ready relay, with a relay control unit, connected with the protection sensor in the signal circuit of its operability, and the readiness relay is connected to the network buses via the thyristor of the relay control unit optocoupler; ready, with a protection signal exchange optocoupler, the thyristor and the LED of which some of its outputs are connected in parallel to the first bus line and connected to the first bus of the network, and the others are connected respectively to the control input of the power source and the resistor 1 with the second teTH bus, with a node for generating a fault signal, the input connected to the protection sensor, and via the power supply circuit connected to the network buses a second group of parallel-connected opening and closing contacts The ready relay and from the output stage with the transistor included in the emitter follower circuit, the base of this transistor is connected to the common point of the resistor and the thyristor of the protection sensor, and the collector is connected to the network bus from the relay, winding which is connected to the emistor of the transistor, and the closing contacts are connected between the output of the block and the output terminals of the system, as well as from the display element 21. The disadvantage of this device is that it can only be switched on again manually, for example, by turning off and then turning on the power toggle switch again). In addition, the winding of its ready relay for the entire time of operation (after self-control) is energized. Compact relays have a limited working life (in terms of total operating time. Coils), which does not exceed 200 hours. A powerful relay can be used (a contact, such as installed in the output stage, but this will impair the weight and size characteristics of the automatic control unit and the entire device in general. Along the way, the question arises about the thyristor mode of the optocoupler of the ready relay control, the maximum permissible current of which is usually small and less than the current of the power relay coil. Switching to a powerful thyristor optotron also leads deterioration in weight and size characteristics. Worsening and efficiency of the device, since the power required for the contactor is high. 1 Purpose; the invention is to provide repeated automatic switching on with the required number of cycles and at the same time increase the service life by eliminating long current through the readiness relay coil. It is also advisable to provide electronic on-off of the power supply system, without resorting to switching the power supply buses, to offer a specific power supply. a chemotechnical solution for the most common frequency of automatic reclosing of one (i.e. when the power supply system is switched on again only once), and to provide an indication of the system on restarting, which would indicate that the power supply system was already turned off at this cycle of operation and now works after automatic restarting, which is now will not happen again. Putting it to the target is achieved in that in a self-monitoring DC power supply system containing a power supply unit whose input is connected to the terminals for connecting the network, a protection sensor with an optocoupler thyristor at the output, an automatic control unit that includes a ready relay, a control unit a relay connected to the protection sensor on the signal circuit of its operability, the readiness relay winding being connected to the leads for connecting the network through the thyristor of the ready relay control unit, the exchange optocoupler nalom protection thyristor and the LED is one of its terminals through the parallel-connected NC and NO contacts of the first contact group readiness relay connected to the first terminal for connecting the network and the other communication terminals. are connected respectively to the control input of the power supply unit and the thyristor of the opto-sensor of the protection sensor, a node for generating a fault signal, an input connected to the protection sensor, and a power supply circuit connected to the terminals for connecting the network via the second contact group of parallel-disconnecting and closing relays of the ready relay, and an output stage including a transistor connected in accordance with the emitter follower circuit, the base of this transistor being connected to a common point of the base resistor and the opistron thyristor the protection, and the collector through the closing contacts of the ready relay - to the output for connecting the network, the relay, the winding of which is connected to the emitter circuit of the transistor, the fault indication element connected to the output of the node for generating a fault signal, four resistors, four capacitors, two diodes, a relay relay, a reclosing cycle counting unit and a first diode assembly on two diodes, and a remote switch, the first winding of which is shunted by the first cond. Sensor, one pin connected, to the first pin to connect

- network, another output through the first resistor, the opistron thyristor of the ready relay control unit and the opening contacts of the second ready relay group - to the second output for connecting the network, the second winding of the remote switch is connected to the first output for connecting the network through the connected in parallel second resistor and the second capacitor and to the second terminal for connecting the network through the first closing contact of the relay relay, one winding terminal connected to the first terminal for connecting the network, and the other terminal through disconnecting contacts of the output stage are connected to the second output for connecting the network, the base resistor is connected to the second output for connecting the network through the disconnecting contacts of the third contact group of the remote switch, in parallel with which are connected the serially connected second closing contact of the output stage relay and the first diode the third capacitor by the first output connected to the first output of the network connection, and the second output through the closing contacts of the third contact group of the remote the switch to the common point of the first diode and the base resistor; the output of the node for generating a fault signal through the opening contacts of the contact group of the coupling relay is connected to the first output of the third capacitor via serially connected fourth capacitor and the third resistor, which in turn through the contact of the contact relay group are connected to the input of the reclosing cycle counting node, which has a thyristor optocoupler at the output, the thyristor of which is connected via a second diode to the second point of the second contact of the output stage relay and the first diode, and through the fourth resistor to the common point of the second capacitor, second resistor and second winding of the remote nepe switch, the common point of the two diodes of the diode assembly is connected to the thyristor of the ready relay control unit, the first output The output of this assembly is connected to the input of the malfunction signaling node, and the second output to the second output of the third capacitor.

In addition, the first transistor, the first terminating resistor and the second diode assembly on three diodes are inserted into the self-controlling DC voltage system, and between the break contacts of the output stage relay and the second output of the winding relay,

The collector-emitter junction of the first transistor connected by the emitter follower circuit is connected, parallel to the collector-base junction of this transistor, the first matching resistor is connected, the common point of the three diodes of the diode assembly is connected to the electronic control input, and the free terminals are respectively to the control input of the power supply unit, to the base of the first transistor and to the common point of the second capacitor, the second resistor and the second winding of the remote switch.

When the automatic reclosing frequency is equal to one, the switching cycle counting node is made on a resistor, a toggle switch and two thyristor optocouplers, the LED of the first of which is connected to the input of the node, and the thyristor is connected to the terminals for connecting the network through a resistor and LED of the second optocoupler, The thyristor of the second optocoupler, in parallel with which are connected the closing contacts of the reclosing switch of the reclosing system, is connected to the output of the counting cycle activation node.

The indication of the operation of the power supply system on re-activation is ensured by the introduction of a second transistor of the conduction type opposite to the first transistor connected according to the emitter follower circuit, the indication lamp, the second terminating resistor and the fifth resistor, the indication lamp being connected between the first output for connecting the network and the emitter of the specified transistor, the collector of which is connected to the second output of the network and through the second matching resistor to the base of the same transistor connected through the fifth cut Torr with the output node of the thyristor of the first optocoupler cycles incorporation accounts.

The drawing shows a functional diagram of a self-controlling DC power supply system.

Claims (4)

The circuit consists of a power supply unit 1, an input connected to the terminals for connecting the network, an output stage 2 with a transistor 3, and a relay 4 having closing contacts 4. 1 through which the output of the power supply unit 1 is in communication with the output 4. 2 systems and opening contacts 4. 3, and the winding of this relay is connected between the emitter of the transistor and the first output for connecting the network, protection sensor 5 with an optocoupler thyristor 6 at the output, automatic control unit 7 containing a remote switch. 5 with two windings 8. 1 and 8. 2 with contact; groups of 8. 3 and 8. 4 parallel-connected opening and closing contacts, the latter being used as a group of opening contacts, for which it is separated from the closing contacts by a diode 9.1 of the diode assembly assembled on two diodes 9. 1 and 9. 2 having a common point with closing contacts 8. 5 and the opening and closing contacts of the contact group 8. 6, a relay control unit 10 having a thyristor optocoupler 11 and connected to a protection sensor 5 along a signal circuit for its operability, a protection signal exchange optocoupler 12, one of the thyristor terminals and an LED of which are connected together and parallel connected disconnecting and closing contacts contact group 8. 3 are connected to the first terminal for connecting the network, and the second in the thyristor is connected to the control input of power supply unit 1, node 13 for generating a malfunction signal connected to the protection sensor by the input circuit, to power contacts of contact group 8.  4, and through diode 9. 1 - to disconnecting and also having a thyristor optocoupler 14 at the output, the first resistor 15, installed in series in the circuit of the first 8. 1 winding of the remote switching of the bodies and the thyristor of the optocoupler 11 of the node 1 of the ready relay control, which includes the opening contacts of the contact group 8. four,.  the first capacitor 16 connected in parallel with the first winding of the remote switch, connected in parallel the second capacitor 17 and the second resistor 18, through which the first terminal for connecting the network is connected to one of the terminals of the second winding 8. 2 remote switches, relay 19 relays with closing contacts, through which the second terminal of the second winding of the remote switch is connected to the second terminal for CONNECTING the network, and a group of opening and closing contacts of the contact group, the first transistor 20, which emitter through the winding the drive relay is connected to the first output for connecting the network, a terminating resistor 21 connected between the base and the collector of the first transistor 20 connected through the break contacts 4. 3 with a second terminal for connecting the network to which via the contacts8. 5 is connected to the collector of the transistor 3 of the output stage 2, the base resistor 22 connected through the break contacts of the contact group 8. b between the second output for connecting the network and the base of the transistor 3, also connected to the thyristor of the optocoupler b (in the sensor 5 are protected, you), the second output of which is connected to the free output of the LED of the optocoupler 12, the first diode 23, connected together in series with The closing contacts of the relay 4 in parallel with the opening contacts of the contact group 8. 6, the third capacitor 24, one plate of which is connected to the first terminal for connecting the network, and the second through diode 9. 2 diode assemblies and breaker contacts 8. 4 to a second terminal for connecting the network and via make 8 contacts. 6 - to the common point of the base resistor 22 and the first diode 23, diode assembly with diodes 25. 1, 25. 2 and 25. 3, the common point of which is connected to the electronic switching input, and the free terminals are connected respectively to the base of the first transistor 20, the common point of the second capacitor 17, the second resistor 18 and the winding 8. 2 and the output of the thyristor of the optocoupler 12 connected to the control input of the power supply unit 1, the fourth capacitor 26 and the third resistor 27 connected in series with each other and connected via the disconnecting contacts of the relay 19 to the output of the node 13 to form a fault signal to which the element is also connected 28 of the fault indication (electric light; from the turn-on cycle counting unit 29, which includes the thyristor optocouplers 30 and 31, the LED of the first of which is connected to the input of the node connected in the automatic control unit 7 through the closing contacts of the contact group 19 with the fourth capacitor 26 and the third resistor 27, resistor 32, on-loop counting node, connected between the LED of the second optocoupler and the first thyristor, opposite terminals connected respectively to the first and second terminals to connect the network, and a toggle switch 33 connected parallel to the thyristor 31 of the optocoupler, connected to the output of the switching cycle counting node 29, from the second diode 34 and the fourth resistor 35 ,.  through which both output pins of the switching cycle counting node are connected respectively to the common contact point of the closing contacts of the relay 4 with the first diode 23 and the common point of the second capacitor 17, the second resistor 18 and the winding 8. 2 of the second transistor 36, the collector of which is connected to the first output for connecting the network, from the display element 37 (electric light) connected between the emitter of the transistor and the second output for connecting the network, and from two resistors: the second matching 38 and the fifth 39, the first of which is connected between the collector and the base of the second transistor 36, and the second between the base of this Transistor and the common point of the thyristor of the optocoupler - 30 with a resistor 32 in the node 29 of the count of switching cycles.  The electronic control input can be connected, as shown in the drawing, to the first bus of the network through the switching element-toggle switch 40.  The power supply system operates as follows.  From the moment the supply voltage (network) is supplied to it, the protection protection self-monitoring starts, after completion of which, from the protection sensor 5, the ready-control relay node 10 receives a signal about the protection circuit's health, as a result of which the thyristor of its optocoupler 11 and the first winding 8 . 1 remote switch 8 through the break contacts of the contact group 8. 4 and the first resistor 15 will receive a current causing the operation of the remote switch while receiving the right position.  Reversible contacts 8. -3 for the switching time, briefly break the current circuit of the thyristors of the optocouplers 12 and 6 (the current of the latter passes through the opening contacts of the contact group 8. 6, the base resistor 22 and the contacts of the contact group 8. 3, which were activated during the self-monitoring process, when conditions were artificially created in the protection sensor to check the sensor despite the compliance of the output voltage of the power supply unit to the nominal value) After switching off the thyristors of the optocouplers 12 and 6 bblok power supply is on again , since the operation prohibition is removed from it, the signal of which comes from the thyristor of the optocoupler 12, and the protection sensor 5 is again ready for operation.  The first condenser 16, the inverter 16, will prolong the presence: the voltage on the winding 8.1 to the full switching of the remote switch.  Even before it was switched over, when the self-role had passed, the third capacitor 24 charged (up to the mains voltage) through contact 8. 4 and diode 9. 2  After switching the remote switch, this capacitor is disconnected from the network (contacts 8 are open. 4) through the base resistor 22 is connected to the base circuit of the transistor 3 of the output stage 2, and since the contacts 8. 5 this transistor will be communicated to the collector power supply, the relay of the 4 output stage also triggers its closure contacts 4. 1 turn on the output of the power supply unit 1 to the system output, and the opening contacts 4. 3 through the first diode 23 will be supplied to the base of the transistor 3 current: {also through the base resistor 22 already from the network, since the third capacitor 24, having split, would not support the base current of the transistor 3, and hence the relay 4 itself level and last would turn off.  On the circuit of contacts 4. 2, a first self-blocking is created from the first diode 23.  This technical solution was needed to always start the system from the left (the off position of the remote switch, and if it turns out that it is different, then the output box will not switch the output of the power supply unit to the consumer, although the collector of the transistor 3 will network, its base current will be absent.  Output to the consumer, therefore, is possible only if the remote switch is in the left position (in which the output stage is necessarily switched on due to the break by the contacts of the contact group 8. 4 collector supply circuits of transistor 37 and. self-control will succeed, due to which the remote switch will assume the right position (switched on).  Since at the end of the cycle of operation (with the primary power supply cut off or due to the protection tripping) the remote switch remains in the right position, for starting self-checking and then connecting to the consumer it is necessary to transfer it to the left position (turn off by applying current to the left winding of the remote switch  This function is performed by the circuit assembled at the break contacts 4.3 of the output stage 2 relay, the emitter follower with the first transistor 20, the terminating resistor 21 and the relay 19, which is the load of this emitter. the repeater and the drive; in the off state of the relay 4 by the current passing through its winding from the ONE bus to the other via the opening contacts 4. 3 and the first transistor 20.  Relay 19, triggered, creates a capacitive current circuit of the second capacitor 17 to the winding 8. 2, which switches the remote switch to the left.  After a successful self-control and the transition of the remote switch to the right position, the re- switches.  4, resulting in the output of the system to the consumer, and the winding current 8. 2 remote toggle The device stops because the winding of the relay 19 is de-energized.  From this moment, continuous monitoring of the output voltage level of the system begins, and if it is deviated beyond the agreed limits (thresholds of the protection sensor), further supply of this voltage is stopped by the protection, which is accompanied by the operation of the optocoupler (b), the optocoupler 12, supplying the control input of power supply unit 1 for the prohibition of the negative potential of the network bus through the thyristor of the optocoupler 12 and short-term potential removal from the base of transistor 3 (in the output stage 2), as a result of this relay 4 off It turns out that the lock itself is locked.  The thyristor 14 of node 13 for generating an indication signal, turned on when the protection sensor is triggered, gives a current to the indication element of failure 28, which, even after the self-switch of the system, will indicate a fault has occurred.  But, having turned off, relay 4 through its breaker contacts 4. 3 will again create a current circuit to the emitter circuit (transistor 20) and then to the winding of relay 19 (turning it on, and thus switching the remote switch to the left).  The cycle of self-control and output to the consumer, described above, will begin again, and in the case of preservation of unhealthiness, self-deactivation again.  At this stage in the development of circuitry, switching on and off of the system in the presence of persistent inadequacy related to the consumer (in case of overload or short circuit of the output of the power supply system, they will follow each other continuously.  The fault indication element 28 will also flash (once each time it is turned on), as well. When transferring the contacts of the contact group 8.4, the node 13 for generating a malfunction signal (and its optocoupler 14) for a short time will lose power.  Usually, after the second or third self-switching, it becomes clear that the malfunction is persistent and further connection to the consumer becomes inappropriate.  Therefore, in the proposed power supply system, a switching cycle counting unit 29 is provided, which, counting out a predetermined number of cycles, will prohibit the further powering of the power supply system, t. e.  turn it off completely.  The prohibition of the charge of the second capacitor 17 through the thyristor of the output optocoupler 31 of the node 29 of the account of cycles of inclusions.  The electronic switching off of the power supply system takes place by applying a potential bus to the diode assembly of the negative bus of the network (for example, a tommer 40 or the contacts of a relay).  Diode 25. 3 will signal the signal to the control input of unit 1 power | nor, as a result, it will turn off, via diode 25. 1 will be lowered the base potential of the first transistor 2. 0 and it no longer turns on relay 19 (despite the fact that the break contacts 4. 3 will be closed, and the second capacitor 17 will be urgently discharged by diode 25.2 (so that the drive will immediately take place if the potential of the negative bus network is removed from the electronic power supply circuit).  In the proposed embodiment, the execution of the inclusion cycle counting unit 29 is a one-time repeated inclusion cycle.  Information that the power supply system has been turned off on the protection side is sensed by the LED of the optocoupler 30, through which the discharge current of the fourth capacitor 26 passes, earlier (at the moment of failure) the charge from the output contact of the contact group 45 from the output of the node 13 to generate a fault signal the discharge will pass through the third resistor 27 and the closing contacts of the contact group 19. 2).  After turning on the thyristor of the optocoupler 30, current will flow to the LED of the optocoupler 31 and therefore, when relay 4 is turned on again (repeatedly). 2 contacts will form a current circuit through the thyristor of the optocoupler 31, which includes the second diode 34 and the fourth resistor 35, and since this thyristor is already illuminated by its LED, it immediately turns on and the second capacitor 17 begins to charge.  This will occur immediately, since the fourth resistor 35 is selected to be of small value only to limit the inrush of the capacitive current of the second capacitor 17 to the level acceptable for the thyristor of the optocoupler 31.  If the power supply system is turned off by the protection for the third time, then, although the contacts 4. 3, the mains voltage is again applied to the emitter follower (collected on the transistor 20) and the relay 19 is turned on again, the current through the winding 8. 2 no longer occurs, since there will be no capacitive current of the second capacitor 17, because it will already be charged from the side of the thyristor of the optocoupler 31).  Bringing the remote switch to the left position will no longer occur and therefore the power supply system will not turn on again.  Its fault indication element 28 will now light up, indicating that a malfunction has occurred, which is not random in nature.  When operating the power supply system, it may be necessary to turn it off immediately at the first malfunction, and switching it on again would be superfluous.  For this, a toggle switch 33 is provided, which, if it is turned on, when the switch 4 is turned on, relay 4 creates conditions for charging the second capacitor 17 and turning the system back on, if the protection works in it, will become impossible.  The indication of the system operation, the power supply on re-activation is obtained by activating when the thyristor of the optocoupler 30 triggers, the voltage divider formed by resistors 38 and 39, thereby decreasing the voltage at the base of the second transistor 36, and then at the first switch-on, when the protection after the self-control did not work yet, it burned to full brightness, since the potentials of the collector and the base of the second transistor 36 were close to each other (transistor 36 also works in the emitter mode, repeat .  The reduced brightness of the normal operation indication will indicate that the system has been switched off in the past (if it was fully operational, otherwise it would not turn on again, since it would not perform self-monitoring and that the attempt to turn on again was already used.  Any next failure will lead to a final self-shutdown.  Now, to turn on the power system again, it is necessary to completely remove the mains voltage from it; then the thyristors of its optocouplers are turned off (6. 12, 14, 30) and upon subsequent supply to the primary power system, it will first begin the above process of operation and again be able to turn on again, and the lamp 37 indicating normal operation will light up to full brightness.  The proposed power supply system eliminates the disadvantage of the prototype, the limited service life — due to the rapid deterioration of the winding of the ready relay (which in the prototype is constantly under current), it is given the property of repeated, and if necessary, repeated switching on after the protection has been activated, each once pre-checked, not to re-enable in the event of an internal malfunction, an indication of the state of the power supply system is provided, indicating whether it is working for the first time before the operation shields or is already triggered, and the ability to control the electron ronnogo switching that allows to enable and disable chem mu without resorting to the switching voltage or rail network.  Claim 1.  A self-monitoring direct-voltage power supply system containing a power supply unit whose input is connected to the terminals for connecting the network, a protection sensor with an optocoupler thyristor at the output, an automatic control unit that includes a ready relay, a control unit for this relay connected to the protection circuit sensor a signal about its serviceability, the readiness relay winding being connected to the leads for connecting the network through the thyristor of the optocoupler of the readiness relay control unit, the optocoupler of the protection signal exchange, the thyristor and the LED to One of its outputs through parallel connected disconnecting and closing contacts of the first contact group of the ready relay are connected to the first terminal for connecting the network, and the other terminals are connected, respectively, to the control input of the power supply unit and the thyristor of the protection sensor optocoupler, input connected to the protection sensor, and on the power supply circuit connected to the terminals for connecting the network through the second contact group of parallel connected disconnectors and short-circuits to ready relay contacts and an output stage including a transistor connected in the emitter follower circuit, the base of this transistor is connected to the common point of the base resistor and the optron thyristor of the protection sensor, and the collector through the closing contacts of the ready relay is connected to the network, the relay winding of which is included in the emitter circuit of the transistor, a fault indication element connected to the output of the node for generating a fault signal, characterized in that Atomic switching with the required number of cycles and at the same time increasing the service life by eliminating the continuous passage of current through the winding of the ready relay, four resistors, four capacitors, two diodes, a relay relay, a reclosing cycle counting node and the first diode assembly are introduced. The ready relay has a remote switch, the first winding of which is shunted by the first capacitor, is connected to the first terminal to connect the network with one lead. another terminal through the first resistor, the opistron thyristor of the readiness relay control unit. and disconnecting contacts of the second group of readiness to the second output for connecting the network, the second winding of the remote switch is connected to the first output for connecting the network through parallel connected second resistor and the second capacitor and to the second output for connecting the network through the first closing contact of the relay H1, one output winding, connected by the first output to connect the network, and the other output - through the opening of the contacts of the output stage is connected to the second output to connect the network, b zovy resistor connected to the second terminal to the network through the break contacts of the third contact group of remote switches, in parallel which are connected in series.  connected to the second closing contact of the output stage relay and the first diode, 15 the third capacitor is connected to the first output to the first output to connect the network, and the second output through the third contact contacts of the remote switch to the common point of the first diode and the base resistor, the node output for generating a fault signal through the break contacts of the contact group of the relay relay is connected to the first terminal of the third capacitor through the fourth capacitor connected in series and the third resistor, which in turn through the closing contacts ,, j of the contact group of the casting relay: is connected to the input of the reclosing cycle counting node, which has a thyristor optocoupler at its output, whose thyristor is connected via a second diode to the common point of the second contact of the output stage relay and the first diode, and through the fourth resistor to the common point of the second capacitor, the second resistor and the second winding of the remote 40 switch, the common point of the two diodes of the diode assembly is connected to the thyristor of the optocoupler control of the ready relay, the first output of this assembly is connected to the 45th input of the malfunction signal prior to the node, and the second output to the second output of the third capacitor. 2. Pop. 1 system, differing from the fact that, in order to ensure electronic control by switching off the system, the first transistor, the first matching resistor of the second diode assembly on three diodes, and between the opening contacts of the output stage relay and the second output winding of the relay relay, the collector-emitter of the first transistor connected according to the emitter follower circuit is switched on; the first matching resistor is connected to the electronic control input in parallel to the collector-base junction of this transistor and the free outputs respectively to the control input of the power supply unit, to the base of the first transistor and to the common point of the second capacitor, second cut Stora and second winding remote switch 3. The system according to claims 1 and 2, characterized in that when the automatic re-on ratio is equal to one, the switching cycle counting node is made on a resistor, a toggle switch and two thyristor opron, the first LED of which is connected to the node input, and the thyristor through the resistor and the LED of the second optocoupler thyristor are connected to the leads for connecting the network, while the thyristor of the second optocoupler in parallel with the closing contacts of the reclosing switch of the reclosing system is connected to the output of the loop counting node Yeni. 4. The system according to paragraphs.1.2 and 3, so that in order to indicate the system is working on restarting, a second transistor of the conduction type opposite to the first one, connected according to the emitter follower circuit, the indication lamp, the second matching resistor and a fifth resistor, with the indication lamp being connected between the first output to connect the network and an emitter of the said transistor, the collector of which is connected to the second output of the network and through the second matching resistor to the base of the same transistor connected via a fifth resistor to the output of the thyristor of the first optocoupler of the turn-on counting node. Sources of information taken into account in the examination 1. USSR author's certificate number 635555, cl. H 02 H 7/10, 1975. 2. USSR author's certificate number 769514, cl. G05F 1/58, 1979.