SU1107214A1 - Device for automatic compensating of capacitive single-phase fault-to-earth current - Google Patents

Abstract

1. AUTOMATIC COMPENSATION DEVICE FOR CAPACITIVE VOLTAGE SINGLE-PHASE ZASHKANIYA GROUND comprising dugogas conductive magnetizing reactor and reactor control block connected to the bias winding dugogas present ,, reactor serially connected to the transformer coupled voltage the formation of zero sequence network. command generator and operating current generator of a given frequency, the output of which is connected to the auxiliary winding of the arcing reactor, are connected in series with the first task unit, the first adder, the functional converter and the memory unit, connected in series by the controlled amplifier, the given frequency filter, the voltage converter and the second adder , the second input of which is connected to the second output of the first task unit, as well as the control unit and key switch, the first of which is connected to a transformer zero sequence, the second to the current transformer connected between the arc-suppressing reactor and ground, the third to the second output of the voltage converter, and the control inputs of the keys are connected to the corresponding outputs of the control unit, characterized in that compensation and network reliability; a blocking filter, an integrator, a smoothing filter, a third and a fourth adders, a second task block, two additional keys, two shunt resistors, a control unit are corrected. the output of the blocking filter is connected to the first input of the control amplifier, the integrator’s output is connected to the second input of the controlled amplifier, and the fourth key is connected to the output of the second adder, the smoothing filter input is connected to the third output, and the output is the second input of the first adder, two additional switches, the control inputs of which are connected to the fifth and sixth outputs of the control unit, are connected to the outputs of the second task block; two shunt resistors are connected respectively in the circuit of the additional winding and the bias winding of the arcing reactor, the first input of the health monitoring unit is connected to the output of the functional converter, the second to the third output of the first task unit, the third to the seventh output of the control unit, a. the output is connected to the input of the control unit; the input of the blocking filter is connected to the outputs of the first, second and two. additional keys, the first entry

Description

The third adder is connected to the fourth output of the first assignment unit, the second to the first shunt resistor, and the output to the operating current generator of a given frequency, the first input of the fourth adder is connected to the output of the memory unit, the second to the second shunt resistor, and the output to the control unit arc suppression reactor, the second input of the memory block under the keys to the eighth output of the control unit, and the third to the second output of the command generator.

2. The device according to claim 1, which is based on the fact that the block contacts of the section oil switch are connected to the third input of the first adder in order to increase reliability during parallel operation of the substation busbar sections.

3. The device according to claim 1, wherein the control unit comprises a square pulse generator, three flip-flops, a distributor and four logic elements AND, the first output of the square-pulse generator connected to the input of the first flip-flop, the direct input of which is connected to the first inputs of the first and third logic elements, And, to the input of the distributor and the first output of the control unit; the inverse output of the first trigger is connected to the first inputs of the second and fourth logic elements And and the second output of the control unit The second output of the generator of rectangular pulses is connected to the inputs of the second and third flip-flops and the third output of the control unit, the outputs of the AND logic gates are connected respectively to the outputs of the fourth to the seventh control unit, the outputs of the first and fourth logic gates AND are also connected respectively to the installation inputs of the second and the third trigger, the outputs of the latter are connected respectively with the eighth and ninth outputs

the control unit, the installation input of the distributor is connected to the input of the control unit, the direct output of the distributor is connected to the second inputs of the first and second logic elements AND, and its inverse output to the second inputs of the third and fourth logic elements AND and the tenth output of the control unit.

4. The device according to claim 1, wherein the health monitoring module contains five triggers, two logical AND, a logical element AND-NOT and a comparator, the first logical element And, the first, second, third triggers and logical element The NAND is connected in series, the second input of the NAND logic element is connected to the output of the first trigger, and the output is connected to the setup inputs of the fourth and fifth triggers, the setup inputs of the first three triggers are connected to the first input of the health monitoring unit, the first input of the first logical element And is connected to the second input of the health monitoring unit, the first input of the first logic element I is connected to the second input of the health monitoring unit, the first input of the comparator is connected to the third one, the second to the fourth input of the health monitoring unit, the stator input of the comparator is connected to the output of the second logical element And, and the output through the fourth and fifth triggers is connected to the first VIDEO of the block. the health control, the inverse output of the fourth trigger is connected to the second output of the health control unit, and the forward one is connected to the second input of the first logical element I, the inverse output of the fifth trigger is connected to the second input of the second logical element I, the second input of which is connected to the third input of the control unit serviceability.

The invention relates to electrical engineering, in particular to the field of electrical networks, and can be used to automatically compensate for capacitive currents during single-phase earth faults in electrical networks.  It is known devices for automatically adjusting an arc-suppressing coil containing selective amplifiers, voltage converters, a functional converter, a memory block, a differential amplifier, a driver unit, and a C13 generator.  The disadvantage of the device lies in the fact that in this case the constant voltage voltage stabilization circuit includes an armature coil, which degrades the quality of regulation.  A device for automatically adjusting an arc-suppressing coil, comprising an operational current generator, filters, voltage converters, a summing amplifier, a blocking circuit, a nonlinear potentiometer, and a coil control unit 2, is known.  A disadvantage of this device is the power of the implementation of a non-linear potentiometer.  Closest to the invention, a device for tuning an arcing quenching reactor comprising a series-interlocking circuit and an operational current generator, serially connected, a first switch, controlled amplifier, through filter, voltage converter, second switch, summing unit, functional converter, first memory block, control unit r. A power supply and an arc-suppressing reactor, a second storage unit connected in series, a comparison unit and an amplifier, as well as reference voltage setting and control units. The disadvantages of the known device are the lack of stabilization of the operating current of the generator, the bias current and device, which leads to a decrease in the exact setting of compensation.  In addition, the device cannot regulate the compensation setting when combining substation busbars.  The purpose of the invention is to improve the accuracy of setting the compensation and network reliability.  The goal is achieved by the fact that a device for compensating the capacitive current of a single-phase earth fault containing an arcing suppressor with biasing and a reactor control unit connected to the bias winding of the extinguishing reactor are connected in series.  connected to the voltage transformer of the zero sequence of the network, the command driver and the operating current generator of a given frequency, the output of which is connected to the additional winding of the arcing reactor, are connected in series the first task unit, the first adder, the function converter and the memory unit, sequentially connected controlled amplifier, filter a given frequency, a voltage converter and a second adder, the second input of which is connected to the second output of the first task block, as well as Four keys are connected to the control, the first of which is connected to the zero-sequence voltage transformer, the second to the current transformer connected between the arcing reactor and ground, the third to the second output of the voltage converter, and the control inputs of the keys are connected to the corresponding outputs of the unit controls, a blocking filter, an integrator, a smoothing filter, a third and fourth adders, a second task block, two additional keys, two shunt resistors, a health monitoring unit, and a load output Each filter is connected to the nepBbiM input of the controlled amplifier, the integrator output is connected to the second input of the controlled amplifier, and the input through the fourth key is connected to the output of the second adder, the input of the smoothing filter is connected to the output of the third key, and the output to the second input of the first adder, to Two additional switches are connected to the outputs of the second task block, the control inputs of which are connected to the fifth and sixth outputs of the control unit, two shunt resistors are included in the auxiliary winding circuit and the circuit, respectively The magnetizing arcing reactor, the first input, the health monitoring unit is connected to the output of the functional converter, the second to the third output of the first task unit, the third to the seventh output of the control unit, and the output to the input of the control unit, the input of the blocking filter is connected to the outputs of the first , the second and two additional keys, the first input of the third adder is connected to the fourth output of the first block of the task.  the second to the first shunt resistor, and the output to the operating current generator of a given frequency, the first input of the fourth adder is connected to the output of the memory unit, the second to the second shunt resistor, and the output to the control unit of the arc reactor, the second input of the memory unit connected to the eighth output of the control unit, and the third to the second output of the driver. teams.  In order to increase reliability in parallel operation of substation busbar sections, the block contacts of the section oil switch are connected to the third input of the first adder.  The control unit contains a generator of rectangular pulses, three flip-flops, a distributor and four logic elements AND, the first output of the generator of rectangular pulses connected to the input of the first trigger, the direct output of which is connected to the first inputs of the first and third logic elements And, to the input of the distributor and the first output of the control unit, the inverse of the first trigger is connected to the first inputs of Bfoporo and the fourth. the logic elements And the second output of the control unit, the second output of the generator of rectangular pulses is connected to the inputs of the second and third flip-flops and the third output of the control unit, the outputs of the logic elements And are connected respectively to the outputs of the control unit from the fourth to the seventh, the outputs of the first and fourth logical elements And they are also connected respectively to the installation inputs of the second and third triggers, the outputs of the latter are connected respectively to the eighth and ninth outputs of the control unit, the installation one in od distribution divider is connected to the input of the control unit can, straight distributor output connected to second inputs pervog and second AND gates and the inverse of its output - to the second inputs of the third and fourth AND gate and a tenth output control unit.  Moreover, the health monitoring unit contains five triggers, two logical AND elements, a logical NAND element and a comparator, the first logical element I, the first, second, third triggers and the logical NAND element are connected in series, the second input of the logical element NON connected to the output of the first trigger. and the output is with the installation inputs of the fourth and fifth triggers, the installation inputs of the first three triggers are connected to the first input of the health monitoring unit, the first input of the first logic element I is connected to the second input of the health monitoring unit, the first input of the comparator is connected to the third, second to the fourth to the inputs of the health monitoring unit, the gate input of the comparator is connected to the output of the second logic element I, and the output through the fourth and fifth triggers is connected to the first output of the health monitoring unit Inverse output of the fourth flip-flop coupled to the second output of serviceability of the control unit 3 forward - to a second input of the first AND gate, inverted output of the fifth flip-flop coupled to a second input of the second AND gate, the second input of which is connected to the third input of serviceability of the control unit.  FIG. 1 shows a functional diagram of the device; in fig. g - functional diagrams of the control unit and the health control unit; in fig. 3 and 4 are timing diagrams of operation of the keys, the memory unit, the control unit and the health monitoring unit.  To the neutral of the three-phase power transformer 1 connected to the electrical network, the arcing reactor 2 is connected with a sub-magnetisation.  A current transformer 3 is connected in series with it, the second output of which is connected to ground.  A transformer 4 of a zero-sequence network is connected to the network.  A shaper 5 of the commands and a generator 6 of the operational current of a given frequency are connected in series with it, which through the shunt resistor 7 is connected to the additional winding of the arcing reactor 2.  A voltage switch connected to the voltage transformer is also connected in series with the first switch 8, the barrier filter 9, the controlled amplifier 10, the selector filter (filter of a given frequency) 11, the voltage converter 12.  To the input of the blocking filter 9 is also connected to the output of the second key 13, the input of which is connected to the secondary winding of the current transformer 3.  The first output of the voltage converter 12 is connected to the third key 14 serially connected, the smoothing filter 15, the first adder 16.  The second output of the voltage converter 12 is connected to the series-connected second adder 17, the fourth key 18, the integrator 19 and the control input of the controlled amplifier 10.  The output of the adder 16 is connected to serially connected functional converter 20, memory unit 21, adder 22, reactor control unit 23, which is connected via a shunt resistor 24 to the bias winding of the reactor 2.  Shunt resistor 24 is connected to the second input of the adder 22.  The device also contains two task units 25 and 26, two additional keys 27 and 28, a control unit 29, a health control unit 30.  The first task block 25 is connected to the adders 16, 17 and 31 and the health control block 30.  The second task block 26 is connected via keys 27 and 28 to the barrier filter 9.  The second input of the adder 31 is connected to the shunt resistor 7.  The third input of the adder 16 is connected to the breaker switch 32.  The control unit 29 is connected to the control inputs of the key 8, 13, 14, 18, 27 and 28, to the memory unit 21, the health control unit 30 A separate input of the health control unit 30 is connected to the output of the function converter 20.  The second output of the driver 5 commands under the key to the third input of the block 21 of the memory.  Control unit 29 (FIG. 2) consists of a generator of 33 low-frequency rectangular pulses, triggers 34–36, cells I 37–40, start-stop distributor 41.  The health control unit 30 (FIG. 2) consists of a logical element And 42, comparator 43, trigger 44 and 45, element And 46, triggers 47 - 49 and element AND-NO 50.  The device operates in two modes: in working relmme and automatic control mode.  The operation of the device is controlled by the control unit 29, which controls the position of the keys 8, 13, 14, 18, 27 and 28, the memory unit 21 and the correctness control unit 30.  in each mode, the device operates cyclically.  A cycle consists of a stabilization period and a measurement period, successively following each other.  Work mode.  The keys 27 and 28 are open, the health control unit 30 is blocked by a logical zero coming from the control unit 29.  In normal mode, the network generator 6 operating current. provides the introduction into the electrical network of the operating current of a given frequency y, the value of which is determined by the reference signal supplied to the adder 31 from the reference unit 25.  Potentiometers connected to a source of stabilized voltage can be used as task unit 25.  With the help of the feedback signal removed from the shunt resistor 7, the current of the operating frequency generator 6 is stabilized.  In air networks, in which the natural asymmetry is large enough, the frequency of the operating current is not equal to industrial, and in cable networks, in which the natural asymmetry is small, the indicated frequency can be. l is equal to that of  As a generator 6, a two-half-wave thyristor rectifier can be used, and then the operating current frequency is 100 Hz.  Stabilization period.  Keys 8 and 18 are closed and keys 13 and 14 are open.  The voltage from the transformer 4 voltage is sequentially supplied to the load. Each filter 9, a controlled amplifier 10, a selection filter 11, a voltage converter 12, an adder 17, an integrating amplifier 19 and an rfa control input of a controlled amplifier 10.  The baffle filter 9 suppresses all harmonics other than the operating current frequency.  Such a filter may consist of a double T-shaped bridge, which suppresses the voltage of the industrial frequency, and an active high-pass filter of the second type, which suppresses the voltage of the frequencies above the operating current frequency.  The gain of the controllable amplifier 10 can vary widely and depends on the magnitude of the signal at the control input.  Such a simulator can be implemented on the base of modulator 140MA1, operating in the multiplication mode of two signals from filter 9 and integrator 19, the selection filter 11 amplifies only the signal of the operating current frequency and can be implemented on two active filters of high second order.  These filters have frequency characteristics of an oscillatory dynamic link with resonant frequencies shifted relative to the operating current frequency by O, IU) Q.  Voltage converter 12 converts an AC signal.  A full-wave rectifier is used as a voltage transformer.  In adder 17 (summing amplifier), the DC signal is algebraically added (compared) with the task signal from block 25 and their difference is given to integrator 19.  As an integrator 19, an operational amplifier covered by a capacitive feedback can be used.  The integrator changes its output signal and the gain of the controlled amplifier 10 so that the output signal of the converter 12 is always (in the steady state) equal to the driver U. During this period, the smoothing filter 15 plays the role of a short-term memory and stores the output signal corresponding to previous measurement period.  An active low-pass filter of the second order can be used as a smoothing filter.  This filter has the ability to briefly memorize the output signal when the input signal is broken. .  The output signal of the filter 15 is fed to one of the inputs of the adder 16, and the second input of this adder receives a signal corresponding to the basic inductive conductivity of the reactor from the task unit 25.  The difference of these signals through the functional converter 20 enters the memory unit 21.  Control unit 29 gives short-term permission for operation of memory block 21 and the signal from functional converter 20 is copied to memory block 21.  The signal from the memory unit 21 is fed to the reactor bias current control system, which contains the adder 22, the reactor control unit 23 and current feedback (pe1 4 resistor 24), which provides a stable bias current when the parameters of the reactor and the supply voltage is changed.  Since the dependence of the current through the compensating winding of the reactor on the bias current is nonlinear, functional converter 20 plays the role of a nonlinear element, whereby the dependence of the current through the compensating winding of the reactor on a signal proportional to capacitive current is linear.  The functional converter can be implemented on an operational amplifier using diodes and reference power sources.  The memory unit 21 operates in two modes: in the scale amplifier mode and in the long-term memory mode.  The first mode occurs when a logical unit signal is received from the control unit 29 enabling the operation of the memory unit, and the second mode is received when the logical zero signal from the control unit 29 prohibits the operation of the memory unit.  The storage unit can be implemented as a digital-analogue tracking device, in which the anapogue1 signal is converted into a digital binary code, and then back to analog.  Such a block construction scheme allows for a long time (several hours) to store the information stored in it with great reliability.  When the switch 32 of section 11 is connected to the mains, the adder 16 receives a signal proportional to the equivalent inductive conductivity of arc-suppressed reactors connected to the TT section.  Due to this, a resonant compensation setting is maintained in the network.  Measurement period  Keys 13 and 14 are closed, keys 8 and 18 are open, and the health control unit is locked.  The integrator 19 plays the role of a short-term memory device and the gain of the controlled amplifier 10 corresponds to the stabilization period.  The signal from the current transformer 3 is successively supplied to the barrier filter 9, the controlled amplifier 10, the surge filter 11, the voltage converter 12, the smoothing filter 15.  The output signal of the smoothing filter 15 is proportional to the capacitive conductance of the network (capacitive current).  By using a controlled amplifier and switches, the accuracy of measuring the capacitive conductance of the network is increased by reducing the effect of changing the parameters of the blocks 9-12.  Health monitoring mode.  The keys 8 and 13 are open, the memory block is blocked by a logical zero coming from the control block 29.  The compensation setting is kept equal to the previous control mode,.  Stabilization period.  Keys 18 and 27 are closed and 14 and 28 are open.  The input of the barrier filter 9 receives the normalized signal of the operating current of a given frequency from the task block 26.  As a task block 26, a quartz generator can be used, whose frequency is equal to the generator frequency 6.  The generator 6, for example, can be made in the form of a full-wave rectifier, and then the task block 26 can be implemented in the form of a full-wave rectifier dividers assembled on resistors.  During the stabilization period, the device operates similarly to the stabilization period of the operating mode.  Measurement period  Keys 14 and 28 are closed and keys 18 and 27 are open.  The input of the blocking filter 9 receives the normalized signal from task block 26 and, at the output of functional converter 20, there is a signal of a certain size, which is fed to one of the inputs of control block 30.  The second input of control unit 30 receives a normalized signal from task block 25.  In this period, a signal is received from control unit 29, allowing to compare the signals of the functional converter 20 and the normalized signal of task block 25.  If these signals are equal, then blocks 9–12, 15–17, 19, and 20 are intact and the control unit puts the device into operating mode.  If these signals are not equal, then one of the listed blocks is faulty.  In order to avoid false triggering of the control unit 30 from interference, the device is provided with a repeatability control mode, which is carried out by feeding the corresponding signal from the control unit 30 to the control unit 20.  If, however, when repeating the 14-12 control mode, a malfunction of one of the listed blocks is confirmed, then a device failure signal appears.  The generator 33 has two outputs, and the frequency at output A is two times less than at output B.  The distributor 41 operates in the mode of counting the number of pulses of the trigger 34 when, at its permitting input C, a signal of a logical unit is applied.  At the same time, at (non-inverse output there is a signal of a logical unit, and at the inverse output there is a signal of logical zero.  After filling the distributor with the following counting pulse, at the outputs of the distributor, the following signals are given in TC: on a non-inverse - a logical zero, and on an inverse - a logical one.  The duration of these signals is equal to the period of the counting pulses.  Thus, the distributor determines the adherence to the health check mode.  When applying to the enable input C of the logical zero signal distributor, the counting of the number of pulses by the distributor is prohibited, and the signals that precede the moment of receipt of the ban are stored on its codes.  Triggers 44, 45, 47 - 49 operate in the counting mode when the R input signal of a logical unit is applied to their setup inputs R.  When the trigger inputs R of these triggers of logical zero signals are applied to the inverse outputs of flip-flops, there are logical zero signals regardless of the pulses coming to the counting inputs C, Logic elements 46 and 50, and triggers 47-49 perform the function of a pulse counter up to five with the prohibition upon receipt of a logical zero signal from the output of the trigger 44.  The comparator 43 is a threshold device with a small dead band and is designed to compare the output signals of blocks 20 and 25.  When the relative difference between the signals of blocks 20 and 25 is less than 2%, a logical zero signal is output from the comparator.  If this difference is more than 2%, then the output of the comparator is a signal of a logical unit.  The comparator 43 has a gating (control) input, due to which the comparison of the signals of the blocks 20–25 occurs when a signal of a logical unit is applied to this input.  When the lean input of the comparator 43 of the logical zero signal is supplied to the strobe, its output always has a logical zero signal regardless of the signal difference of the blocks 20 and 25,

The schemes of the control unit and the health monitoring unit (Fig. 2) allow the operation mode, the health monitoring mode, false information about the malfunction from the actual malfunction of the units covered by the control. The time diagrams (Fig. 3) of the operation of the elements of the control unit, the health monitoring unit, the keys 8, 13, 14, 18, 27 and 28 and the memory unit 21 are shown when the blocks covered by the control are in order (the difference between the signals from the output of the blocks 20 and 25 in the control mode is less than 2%) and the time diagrams (figure 4) of the same blocks, when one | of the blocks covered by the control is faulty. As follows from the diagram, in the control mode, when a gating pulse arrives at the input of the comparator 43 from block 36, a signal of a logical unit appears at the output of the comparator through the element 42, which changes the state of the triggers 44. The logical zero signal arrives at the enable input C of the distributor 41 and with the arrival of the next pulse at the counting input of the distributor 41, the latter does not change state. Thus, a repeated control cycle is performed, at which the comparator 43 reinstates the signal of the logic unit and changes the states of the flip-flops 44 and 45. The non-inverted output of the flip-flop 45 causes the logic unit signaling the failure of one of the blocks covered by the control. From the inverse trigger output 45, the element 42 receives a logical zero signal and, thus, the gate pulse is not allowed to be passed to the control input of the comparator 43. Fault information is maintained until the trigger 45 is forced does not return to its original state. The state of the remaining elements of the control unit and the control unit after re-monitoring corresponds to the operating mode.

Repeated inspection in the device is provided in order to prevent false information about the fault.

This information may appear due to interference in the first monitoring cycle and is remembered by trigger 44 (FIG. 3). If during a repeated monitoring cycle, information about the failure of one of the units covered by the monitoring is not confirmed (the comparator 43 does not generate a logical zero signal), then (unlike the diagram in Fig. 3) at the time the gate pulse of the comparator 43 disappears at the output of element 50 Wits signal logical zero. The latter returns the trigger 44 to the initial state, and there is a logical unit signal at the destructive input of the distributor 41. With the next pulse, arriving at the counting input of the distributor 41, the operating mode begins. At the same time, the logic inputs of the flip-flops 47-49 receive a logic zero signal from the inverse output of the distributor 41. The output of the flip-flops 47-49 has a logic zero signal, and the output of the element 50 has a logic unit signal. The state of the elements of the control unit corresponds to the operating mode (Fig. 2 and 3).

With a single-phase short circuit to earth, the voltage of the transformer 4 voltage increases sharply, the driver 5 of the commands is triggered and generates a ban on the generator 6 and the block 21 of the memory. In this case, the generator 6 is blocked, and the memory block is transferred to the mode of storing the information preceding the single-phase short to ground. The appropriate compensation setting is maintained until the single-phase ground fault is eliminated. After the elimination of the single-phase substitute to earth, the command driver returns to its initial state with a time lag and the operation of the device corresponds to the normal mode of the network.

The application of the invention improves the accuracy of compensation adjustment by increasing the accuracy of measuring the capacitive conductance of the network, which is achieved by reducing the number of single-phase earth-fault transitions in two and phase-to-phase short circuits and thereby increases the reliability of power supply to consumers.

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Claims (4)

1. DEVICE FOR AUTOMATIC COMPENSATION OF A CAPACITIVE CURRENT SINGLE-PHASE CIRCUIT TO EARTH, containing an arcing reactor with magnetization and a reactor control unit connected to a magnetization winding of an arc suppression reactor, a voltage generator which is connected to the additional winding * of the extinguishing reactor, connected in series to the first task unit ^ first the first adder, a functional converter and a memory unit, a controlled amplifier, a predetermined frequency filter, a voltage converter and a second adder, the second input of which is connected to the second output of the first task unit, as well as a control unit and four keys, the first of which is connected to the voltage transformer, in series zero sequence, the second to the current transformer connected between the arcing reactor and the ground, the third to the second output of the voltage converter, and the control inputs of the keys with are integrated with the corresponding outputs of the control unit, characterized in that, in order to increase the accuracy of compensation settings and network reliability, a blocking filter, an integrator, a smoothing filter, a third and fourth adder, a second reference unit, two additional switches, two shunt resistors are introduced into it, a health monitoring unit, the output of the trap being connected to. the first input of the control amplifier, the integrator output is connected to the second input of the controlled amplifier, and the input through the fourth key is connected to the output of the second adder, the input of the smoothing filter is connected to the output of the third key, and the output is to the second input of the first adder, two are connected to the outputs of the second task unit additional switches, the control inputs of which are connected to the fifth and sixth outputs of the control unit, two shunt resistors are included respectively in the circuits of the additional winding and the magnetizing winding of the arc reactor, the first input of the health monitoring unit is connected to the output of the functional converter, the second to the third output of the first task unit, the third to the seventh output of the control unit, and. output - with the input of the control unit, the input of the blocking filter is connected to the outputs of the first, second and two additional keys, the first input SU .1107214 of the third adder is connected to the fourth output of the first task unit, the second to the first shunt resistor, and the output to the operating current generator of a given frequency, the first input of the fourth adder is connected to the output of the memory unit, the second to the second shunt resistor, and the output to the control unit of the arc suppression reactor, the second input of the memory unit is connected to the eighth output of the control unit, and the third to the second output of the command generator. 2. The device according to π. 1, I note that in order to increase reliability during parallel operation of sections of substation busbars, the block contacts of the section oil circuit breaker are connected to the third input of the first adder. 3. The device according to claim 1, characterized in that the control unit comprises a rectangular pulse generator, three triggers, a distributor and four logical elements AND, the first output of the rectangular pulse generator being connected to the input of the first trigger, the direct input of which is connected to the first inputs the first and third logical elements And, to the input of the distributor and the first output of the control unit, the inverse output of the first trigger is connected to the first inputs of the second and fourth logical elements And and the second output of the control unit , the second output of the rectangular pulse generator is connected to the inputs of the second AND third triggers and the third output of the control unit, the outputs of the logical elements AND are connected respectively to the outputs of the control unit from the fourth to the seventh, the outputs of the first and fourth logical elements And are also connected respectively to the installation inputs of the second and third triggers, the outputs of the latter are connected respectively to the eighth and ninth outputs of the control unit, the installation input of the distributor is connected to the input of the control unit, p pit distributor output connected to second inputs of first and second AND gates and the inverse of its output - to the second inputs of the third and fourth AND gates and tenth output control unit. 4. The device according to π. 1, wherein the health monitoring unit contains five triggers, two logical elements AND, a logical element AND, and a comparator, the first logical element And, the first, second, third triggers and the logical element AND NOT connected in series, the second input of the AND gate is connected to the output of the first trigger, and the output to the installation inputs of the fourth and fifth triggers, the installation inputs of the first three triggers are connected to the first input of the health monitor, the first input of the first logic gate And it is connected to the second input of the health monitoring unit, the first input of the first logical element And is connected to the second input of the health monitoring unit, the first input of the comparator is connected to the third, the second to the fourth inputs of the health monitoring unit, the gate input of the comparator is connected to the output of the second logical element And, and the output through the fourth and fifth triggers is connected to the first output of the health monitoring unit, the inverse output of the fourth trigger is connected to the second output of the health monitoring unit, and the line to the second Odom first AND gate, a fifth flip-flop inverse output coupled to a second input of the second AND gate, the second input of which is connected to the third input of serviceability of the control unit.