SU1171935A1 - Versions of device for forced switching of thyristors - Google Patents

Abstract

1. A thyristors forced switching device containing a power source, the output terminals of which are connected to the corresponding terminals of two main switching thyristors, two charge thyristors, two discharge diodes, two return diodes, a switching LC circuit connected by one output to the cathode of the switching thyristor and another conclusion is to the cathode of the first charge thyristor, a switching transformer with two in series according to the included primary and secondary windings, and the output of the primary winding the primary charge thyristor is connected to the cathode, the secondary winding pin is connected to the first return diode anode, and the common junction point is connected to the second discharge diode cathode, the cathode group of distribution thyristors connected by anodes to the corresponding outputs of the thyristor converter and cathodes to the first charge cathode a single thyristor, an anodic group of distribution thyristors connected by its cathodes to the corresponding terminals, a thyristor converter, characterized in that, in order to reduce switching losses, an eye is supplied with an additional switching thyristor connected by its anode and cathode to the corresponding anodes and cathodes of the main commutating thyristors, reverse diodes connected anti-parallel to the main and additional switching thyristors, an additional LC circuit connected by one output to the additional cathode the switching thyristor and the second output to the anode of the second charge thyristor and to the anodes of the anode group of distribution thyristors, as well as the second in pairs in series with the primary and secondary windings of the switching transformer, the free output of this primary winding at (O is connected to the second charging anode anode (L torus, the free output of the secondary winding is connected to the cathode of the return diode, and the common connection point is connected to the anode first discharge diode. 2. A thyristor forced switching device containing a power source, to the output of which there are connected the output of two main series-connected switching thyristors, two charge thyristors, two discharge diodes, two return diodes, switching the LC circuit. connected by one output to the common O5 SP of the connection point of the switching thyristors and the other output to the cathode of the first charge thyristor, the switching transformer with two primary and secondary windings connected in series, the output of the primary winding connected to the cathode of the first charge thyristor, the output of the secondary winding to the anode of the first return diode, and the common connection point is connected to the cathode of the second discharge diode, the cathode group of distribution thyristors connected by anodes to corresponding to the conclusions of the thyristor converter and

Description

over the years to the cathode of the first charge thyristor, the anodic group of distribution thyristors connected by their cathodes to the corresponding terminals of the thyristor converter, characterized in that, in order to reduce switching losses, it is equipped with two additional series-connected switching thyristors connected by their respective leads to the source buses power, four reverse diodes, connected oppositely in parallel to the main and additional switching thyristors , an additional switching IC circuit connected by one output to the common connection point of additional switching thyristors and another output to the anode of the second charge thyristor and to the anodes of the anode group of distribution thyristors, the decoupling diode connected by the cathode to the anode of the charge thyristor and anode - to the cathode of the first charge thyristor, as well as the second pair, according to the series-connected primary and secondary windings of the switching transformer, and the free output of this primary coils connected to the anode of the second charging thyristor and the free terminal of the secondary winding - a cathode of the first diode discharge.

3. A thyristor forced switching device containing a power source, to the output buses of which are connected the corresponding terminals of two main series-connected switching thyristors, two discharge diodes and two series-connected return diodes, a switching circuit LC connected by one output to a common connection point of the switching thyristors and the other the output to the cathode of the first charge thyristor, the switching transformer, one of the primary windings of which is connected by its own terminals is unpaired to the cathode of the first charge thyristor and to the cathode of the second discharge diode, and the secondary winding is connected to the common pins of the thyristor converter and cathodes to the cathode of the first charged thyristor by a single output to the common connection point of the return diodes, anode group of distribution thyristors connected by cathodes to the corresponding pins of a thyristor converter, characterized in that, in order to reduce switching losses, it provides About two additional series-connected switching thyristors connected by their respective leads to power supply buses, four reverse diodes connected anti-parallel to the main and additional switching thyristors, an additional switching LC circuit connected by one output to a common connection point of additional switching thyristors and another output - to the anode of the second charge thyristor, two series-connected decoupling diodes, connected the anode to the cathode of the first charge thyristor, and the cathode to the anode of the second charge thyristor and to the anodes of the anode group of the distribution thyristors, the second primary winding of the switching transformer connected by its leads to the anodes of the second charge thyristor and the first discharge diode, and another output said secondary winding to a common connection point of the power supply diodes.

one

The device relates to converter technology and can be used for forced switching of thyristors in adjustable rectifiers and inverters of converter units (PU), as well as in traction drives of AC electric locomotives with asynchronous motors.

The aim of the invention is to reduce switching losses.

FIG. 1 shows a schematic diagram of the device in the first embodiment; in fig. 2 shows the control diagram and the shape of the output switching current.

for the device in the first embodiment; in fig. 3 is a schematic diagram of the device according to the second embodiment; in fig. 4 shows the control diagram and the shape of the output switching current for the device according to the second embodiment; in fig. 5 is a schematic diagram of the device according to the third embodiment; in fig. 4 - diagrams explaining the operation of the device; in fig. 6 (a, b) is one of the options for implementing the control switching device control system for all variants.

The forced switching device in the first embodiment is connected to the common

busbars connecting thyristor converter 1 to power supply 2, and contains main switching thyristors 3 and 4, additional switching thyristor 5, charge thyristors 6 and 7, return diodes 8 and 9, discharge diodes 10 and 11, reverse diodes 12- 14, isolation diode 15, LC circuits 16, 17 and 18, 19, a switching transformer with primary windings 20 and 21 and secondary windings 22 and 23, an anodic group of distribution thyristors 24 and a cathode group of distribution thyristors 25.

The anodes of the thyristors 3 and b and the cathodes of the diodes 1 I and 9 are connected to the positive bus of the power supply 2. The cathodes of thyristors 4 and 7 and the anodes of the diodes 8 and 10 are connected to the negative side of the power supply. One ends of the LC circuits 16, 17 and 18, 19 are connected to common points of the connection of the cathode of thyristor 3 with the anode of additional commuting thyristor 5, and the cathode of thyristor 5 with the anode of thyristor 4, and the other ends of LC circuits are connected to common points of connection of the cathode of thyristor 6 with the anode of the separation diode 15 and the cathode of the diode 15 with the anode of the thyristor 7. To the common connection point of the thyristor 6 and diode 15 the beginning of the primary winding 21 of the switching transformer is connected, the end is connected to the common connection point of the cathode of the diode 8 with the beginning of the secondary winding wiping transformatora.K common junction of the cathode of the diode 15 and the anode of thyristor 7 is connected beginning of the primary winding 20 of the switching transformer, the end connected to the common point of the anode of the diode 11 with a compound of the beginning of the secondary winding 22 of the switching transformer.

The ends of the secondary windings 22 and 23 of the switching transformer are connected to the cathode of diode 10 and to the anode of diode 9, parallel to the opposite side of thyristors 3-5, reverse diodes 12-14 are connected. The common anode connection point of the distribution thyristor group 24 is connected to the common connection point of diode 15 and thyristor 7. The common cathode connection point of the distribution thyristor group 25 is connected to the common connection point of thyristor 6 with diode 15. The thyristor cathode 24 and thyristor anode 25 are connected to converter 1.

The thyristors forced switching device according to the second variant (Fig. 3) is connected to common buses connecting thyristor converter 1 with power supply 2, and contains two LC circuits 16, 17 and 18, 19 connected by one output to common points of switching thyristors 3, 4 and 5, 26, which are shunted in the opposite direction by diodes 12, 14 and 13, 27. Other conclusions

A chain 16 and 17 is connected to the common connection point of the charge thyristor cathode-6 with the anode of the separation diode 15 and the cathode group of distribution thyristors 25 and with the start of the primary winding 21 of the four-winding switching transformer. LC circuits 18 and 19 are connected to the common connection point of the charge thyristor anode 7 with the cathode of the separation diode 15 and the anode group of distribution thyristors 24 and with the start of the second primary winding 20 of the switching transformer. The ends of the primary windings 20 and 21 are connected to the beginnings of the secondary windings 22, 23, and respectively to the cathode and anode of the discharge diodes 8 and 11.

The anode and cathode groups of the distribution thyristors 24 and 25 are connected by corresponding anodes and cathodes to the terminals of the thyristor converter 1.

0 The thyristors forced switching device according to the third variant (Fig. 5) is connected to the common buses connecting the thyristor converter 1 with the power source 2, and contains the main series, sequentially connected switching thyristors 3 and 4, charge thyristors 6 and 7, and discharge thyristors. diodes 8 and 11, series-connected return diodes 9 and 10. Thyristor anodes 3, 5 and 6 and cathodes of diodes 9, 13 and 14 are connected to the positive

0 to the power supply source 2. The thyristor cathodes 4, 7 and 26 and the anodes of the diodes 8, 10, 12 and 27 are connected to the negative bus of the power source 2. The switching circuit 16 and 17 is connected at one end to the common connection point of switching thyristors 3 and 4, and at the other end to the cathode of charge thyristor 6, to the cathodes of distribution thyristors 25 and to the beginning of the primary winding 21 of the switching transformer. The switching LC circuit 18 and 19 is connected at one end to the common connection point of switching thyristors 5 and 26, and the other end to the cathode of charge thyristor 7 and to the beginning of the primary winding 20 of the switching transformer, and to the distribution anodes

, thyristors 24. Sequentially connected decoupling diodes 15 and 23 are connected by an anode to the cathode of charge thyristor 6 and by a cathode to the anode of charge thyristor 7. The beginning of the secondary winding 22 of the switching transformer is connected to the common connection point of the connecting diodes 15 and 23. Reverse diodes 12, 13, 14 and 27 are connected in parallel to the main and additional switching thyristors 3, 4, 5 and 26.

The device in the first embodiment (Fig. 1) works as follows.

Suppose that at the initial time, the capacitors 16 and 18 are charged with voltage, the polarity of which is indicated in FIG. 1. According to the control diagram (Fig. 2), at the time ti turn on the thyristor 3. Capacitor 16 begins to recharge across the circuit capacitor 16 - reactor 17 - diode 15 - winding 20 - diode 11 - thyristor 3 - capacitor 16. Switching winding voltage transformer 20, through one of the thyristors of group 24, is applied to the lockable thyristor of converter 1 in the opposite direction. At time t2, the thyristor 5 and the capacitor 18 are recharged across the circuit; capacitor 18 — reactor 19 — winding 20 — diode 11 — thyristor 3 — thyristor 4 — capacitor 18. In the secondary windings 22-23 of the switching transformer, a mutual inductance voltage is induced, the currents of which winding 22 - diode 11 - source 2 - diode 10 - winding 22 - winding 23 - diode 9 - source 2 - diode 8 - winding 22 are closed at the circuit. At time ts, the capacitor 16 is overcharged, but the thyristor 3 remains open, as the recharge of the capacitor 18 continues. At the moment i at the end In the process of recharging, the thyristor 7 is opened and the capacitors 16 and 18 are charged from the power source 2 along the circuits plus source 2 - thyristor 3 - capacitor 16 - reactor 17 - diode 15 - thyristor 7 - minus source 2; "Plus source 2 - thyristor 3 - thyristor 5 - capacitor 18 - reactor 19 - thyristor 7 -" minus source 2. At time ts, the dosage of capacitors 16 and 18 ends, thyristors 3 and 5 are locked with positive potentials of capacitors 16 and 18. During the switching and switching process, the capacitors 16 and 18 can be recharged above the voltage of the power source. Then, over the time interval ts-te, the excess energy of the capacitors is transferred to the power source 2 via a circuit capacitor 16 - diode 14 - source 2 - diode 8 - winding 21 - reactor 17 - capacitor 16 capacitor 18 - diode 13 - diode 14 - source 2 - diode 8 - winding 21 - diode 15 - reactor 19, capacitor 18. In the secondary winding 23, a mutual inductance voltage is induced, the current of which is closed along the circuit winding 23 - diode 9 - source 2 - diode 8, winding 23. At the moment of time te the voltage of the capacitors equals the voltage of source 2 and the process ends. At time t /, the next switching starts, but the switching sequence of switching circuits changes, thyristor 4 turns on, and capacitor 18 starts recharging through circuit capacitor 18 - thyristor 4 - diode 8 - winding 21 - diode 15 - reactor 19 - capacitor 18 The voltage of the winding 21 is applied through the distribution thyristor of group 25 to the lockable thyristor of converter 1 in the opposite direction. Further, the thyristors are turned on according to the control diagram in FIG. 2, and the switching process is similar.

The forced switching device according to the second variant (FIG. 3) operates as follows.

Suppose at the initial moment

over time, the capacitors 16 and 18 are charged with a voltage whose polarity is indicated in FIG. 3. According to the control diagram (Fig. 4), at time ti, the thyristor 3 is turned on and capacitor 18 begins to recharge across the circuit. Capacitor 16 — reactor 17 — separation diode 15 — winding 20 — diode 1 1 — thyristor 3 — capacitor 18. Voltage transformer winding 20 through one of the distribution thyristors of group 24 is applied

Q to the lockable thyristor of the converter 1 in the opposite direction and it is locked. At time t2, the thyristor 5 is switched on and the capacitor 18 is recharged across the circuit; capacitor 18 — reactor 19 — winding 20 — diode 11 — thyristor 5 — capacitor 18. In the secondary windings 20-23 of the transformer, EMF of the mutual induction of the currents is induced 22 - diode 11 - power supply 2 - diode 10 - winding 22 - winding 23 - diode 9 - source 2 - diode 8 - winding 23. At time ts, the capacitor 16 is overcharged and the thyristor 3 is locked with a positive potential of the capacitor 16 thyristor cathode 3.

5 Diode 15 is blocked by the negative potential of the capacitor 16 applied to its anode. Thus, the total voltage of the power supply 2 and the capacitor 18 is shared between the locked thyristor 3 and the locked diode 15. Therefore, the diode 15 allows to reduce the voltage applied to the switching thyristors. At time i, recharging of the capacitor 18 is terminated and the thyristor 7 is opened. Capacitors 16 and 18 are charged from the power supply 2 via the plus circuit 2 - thyristor 3 - capacitor 16 - reactor 17 - diode 15 - thyristor 7 - " minus power source 2; "Plus source 2 - thyristor 5 - capacitor 18 - reactor 19 - thyristor 7 -

0 "minus 2 power supply.

At the time ts, the discharges of the capacitors 16 and 18 are terminated and the thyristors 3 and 5 are closed by the positive potentials of the capacitors 16 and 18. During the dispensing and switching process, the switching capacitors 16 and 18 can be charged above the voltage of the power supply. Then, over the time interval ts-te, the excess energy of the capacitors is transmitted to the power source 2 via a circuit capacitor 16 — diode 14 — source 2 — diode 8 — winding 21 — reactor 17 — capacitor 18; capacitor 18 - diode 13 - source 2 - diode 9 source 2 "-" winding 21 - diode 15 - reactor 19 - capacitor 18. In the secondary winding 23 of the transformer, a mutual inductance EMF is induced, which closes along the circuit winding 23 - diode 9 - source 2 - diode 8 is a winding 23. At the time point te, the voltage of the capacitors is equal to the voltage of source 2 and the switching process ends. At the moment of time ty, the next commutation starts, but at the same time the switching order of the commutating Circuit changes; the thyristor 26 is turned on and the capacitor 18 is recharged by the capacitor 18 - thyristor 26 - diode 8 - winding 21 - diode 15 - reactor 19 - capacitor 18. The voltage of the winding 21 is applied through the distribution thyristor of group 25 to the lockable thyristor of converter 1 in the opposite direction . Further, the thyristors are turned on according to the control diagram in FIG. 4 and the switching process is similar. The forced switching device according to the third variant (FIG. 5) operates as follows. Let us suggest that at the initial time instant the capacitors 16 and 18 are charged with voltage, the polarity of which is indicated in FIG. 5. According to the control diagram (Fig. 4), at time ti, the thyristor 3 is turned on and capacitor 16 starts to recharge across the circuit capacitor 16 - reactor 17 - isolation diode 15 - separation diode 23 - winding 20 - diode 11 - thyristor 3 - capacitor 16. The voltage of the transformer winding 20 through one of the distribution thyristors of group 24 is applied to the lockable thyristor of converter 1 in the opposite direction and it is locked. At time iz, the thyristor 5 is turned on and the capacitor 18 is recharged across the circuit; capacitor 18 — reactor 19 — winding 20 — diode I — thyristor 5 — capacitor 18. A voltage of inductance induced in the secondary winding 22 of the transformer, the current of which closes along the winding 22 — diode 23 — winding 20 — diode 11 — power supply 2, diode 10 — winding 22. At time ta, the recharging of capacitor 16 ends and the thyristor 3 is locked by the positive potential of capacitor 16 applied to the thyristor cathode 3. At time t4, the capacitor recharges 18 and about they cover charge thyristor 7. Capacitors 16 and 18 are charged from power supply 2 via circuits plus source 2 - thyristor 3 - capacitor 16 - reactor 17 - diode 15 - thyristor 7 - "minus of power supply 2 -" plus source 2 - thyristor 5 - nor - "plus source 2 capacitor 18 - reactor 19 - thyristor 7 -" minus power supply 2. At the time ts, the charging of capacitors 16 and 18 is terminated and the thyristors 3 and 5 are closed by the positive potentials of the capacitors 16 and 18. In the process of switching and switching, the switching capacitors 16 and 18 can be charged above the voltage of the power supply. Then, in the time interval ts-te, the excess energy of the capacitors is transmitted to the power source 2 via a circuit capacitor 16 - diode 14 - source 2 - diode 8 - winding 21 - reactor 17 - capacitor 18 - capacitor 18 - diode 13 - source 2 - diode 8 - winding 21 - diode 15 - diode 23 - reactor 19 - capacitor 18. In the secondary winding 22 of the transformer, a mutual induction EMF is induced, which is closed along the circuit winding 22 - diode 9 - source 2 - diode 8 - winding 21 - diode 15 - winding 22. At time te, the voltage of the capacitors is equal to the voltage of source 2 and the switching process ends feels like At the moment of time t-, the next switching starts, but the switching order of switching LC circuits changes: the thyristor 26 is turned on and the capacitor 18 is recharged through the circuit capacitor 18 - thyristor 26 - diode 8 - transformer 21 - diode 15 - diode 23 - the reactor 19 is a capacitor 18. The voltage of the winding 21 is applied through the distribution thyristor of group 25 to the lockable thyristor of converter 1 in the opposite direction. Further, the thyristors are turned on according to the control diagram in FIG. 4 and the switching process is similar. The control system of the forced switching devices according to the second and third variants consists of a signal generator (FS) 28 and a pulse distributor (PS) 29. FS outputs 28 are connected to the inputs of the RS 29, and from the output of the pulse distributor, control signals V3-V7 are sent to the corresponding thyristors of the device forced commutation. The control system operates as follows. The input of the FS 28, which is used as a frequency regulator (RF) 30, receives the voltage of the frequency reference signal and /. Two signals + Ua and -Ua are input from the output of the RCSA. They are fed to the input of two channels RI 29. Each channel RI 29 contains a single vibrator 31, a pulse shaper (PI) 32, one vibrator 31, FI 34 and 35, a logical element OR-2 36.

According to the control signal diagram of FIG. 66 at time i, on the falling edge of the signal + Ua, FI 35 generates a control pulse + K, arriving through the OR element on the thyristor V3.

At the same time, the -f K signal is applied to the inputs of the single vibrators 31 and 33. The single vibrator 31 generates a pulse with a duration equal to the time interval ti-12 (Fig. 4). On the falling edge of this pulse, the PH 33 generates a pulse coming from the output of the RI 29 to the thyristor V5 (Fig. 3).

The single-oscillator 33 generates a pulse with a duration equal to the time interval ti-14 (Fig. 4), on the falling edge of which FI 34 generates a pulse arriving at turning on the thyristor and simultaneously through the OR-2 logic element 36 at the output of RI 29 to re-enable the V3 thyristor. The second channel RI works in a similar way. On the trailing edge of the pulse - UB in FI 35, a pulse K is formed, which arrives through the element OR-2 36 at the output of the RI 29 to turn on the V6 thyristor. At the same time, the impulse -K is applied to one-shot 31 and 33. With a time delay equal to the interval t | -t by the value of the length of the pulse of the one-shot 31, FI 32, it generates a pulse coming from the RI 29 to the V4 thyristor (Fig. 3). And with a time delay equal to the interval (Fig. 4) by the magnitude of the pulse duration of the one-shot 33, a pulse is generated in FI 34 to turn on the thyristor V9 and simultaneously through the OR-2 36 element to the output of the RI 29 to turn on the thyristor V6 again. By adjusting the duration of the pulses of one-shot 31 and 33, you can adjust the time interval between switching on the first and second oscillating circuits, as well as the time when the control pulses are applied to turn on charge thyristors.

The frequency controller, adjustable delay elements, pulse drivers are performed according to well-known principles. The proposed forced switching devices in the first and second versions can be used in various power ranges, since the total switching currents of both LC circuits and the switching thyristors in it are twice as high in the circuit with the additional thyristor in the first variant. in terms of heat losses than in the scheme according to the second variant with two additional commutation thyristors. but

the use of the first variant of the circuit reduces the number of commuting thyristors. Therefore, it is advisable to use the first variant in the power range, where the switching thyristors are not loaded for heat loss. In the circuit

0 with two additional switching thyristors according to the second variant, only one LC circuit flows through the switching thyristor circuit, therefore, the second option is rational to use the circuit in converter installations with a power higher than 1000 kW when the switching thyristors are selected according to the maximum allowable amplitude of the operating current and extremely dormant heat loss m. In the scheme according to the second option

The independent operation of the LC circuits is ensured only by the introduction of an isolation diode, and in the first embodiment, the independent operation of the LC circuits is ensured by the introduction of an additional thyristor and the isolation diode.

In the scheme according to the third variant, the design of the switching transformer is simplified and the number of its windings decreases, however, the losses in the decoupling diodes are doubled.

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Claims (3)

1. A thyristor forced switching device containing a power source, to the output buses of which are connected the corresponding terminals of two main switching thyristors, two charging thyristors, two discharge diodes, two return diodes, a switching GS circuit connected by one output to the switching thyristor cathode and another output - to the cathode of the first charging thyristor, a switching transformer with two in series according to the included primary and secondary windings, and the output of the primary winding pr and connected to the cathode of the first charging thyristor, the output of the secondary winding to the anode of the first return diode, and the common connection point is connected to the cathode of the second discharge diode, the cathode group of distribution thyristors connected by anodes to the corresponding terminals of the thyristor converter and cathodes to the cathode of the first charging thyristor, the anode a group of distribution thyristors, connected by its cathodes to the corresponding terminals, of a thyristor converter, characterized in that, in order to reduce the commutator losses, it is equipped with an additional switching thyristor, connected by its anode and cathode to the corresponding anodes and cathodes of the main switching thyristors, reverse diodes connected counter-parallel to the main and additional switching thyristors, an additional GS circuit connected by one output to the cathode of the additional switching thyristor and the second conclusion - to the anode of the second charging thyristor and to the anodes of the anode group of distribution thyristors, as well as the second pair series-connected primary and secondary windings of the switching transformer, the free output of this primary winding is connected to the anode of the second charging thyristor free terminal of the secondary winding - a return to the cathode of the diode and the common point of · compound connected to the anode of the first diode discharge. 2. A thyristor forced switching device containing a power source, the output buses of which are connected to the output of two main series-connected switching thyristors, two charging thyristors, two discharge diodes, two return diodes, a switching GS circuit connected by one output to a common connection point of switching thyristors and another output - to the cathode of the first charging thyristor, a switching transformer with two according to the series connected primary and secondary windings, and the output of the primary winding is connected to the cathode of the first charging thyristor, the output of the secondary winding is connected to the anode of the first return diode, and the common connection point is connected to the cathode of the second discharge diode, the cathode group of distribution thyristors connected by anodes to the corresponding terminals of the thyristor converter and cathodes - to the cathode of the first charging thyristor, the anode group of distribution thyristors, connected by its cathodes to the corresponding terminals of the thyristor converter, about characterized in that, in order to reduce switching losses, it is equipped with two additional series-connected switching thyristors, connected by their respective terminals to the buses of the power source, four reverse diodes connected in parallel to the main and additional switching thyristors, an additional switching VC-circuit, a suction ~ one terminal to the common connection point of the additional switching thyristors and another terminal to the anode of the second charging thyristor and to the anodes of the anode group of distribution thyristors, a decoupling diode connected by a cathode to the anode of the second charging thyristor and the anode to the cathode of the first charging thyristor, as well as a second pair according to the primary and secondary windings of the switching transformer connected in series, and the free terminal of this primary winding is connected to the anode of the second charging thyristor, and the free output of the secondary winding to the cathode of the first discharge diode. 3. A thyristor forced switching device containing a power source, to the output buses of which are connected the corresponding terminals of two main series-connected switching thyristors, two bit diodes and two series-connected return diodes, an LC switching circuit connected by one terminal to a common connection point of switching thyristors and the other output - to the cathode of the first charging thyristor, a switching transformer, one of the primary windings of which is connected by its terminals and to the cathode of the first charging thyristor and to the cathode of the second discharge diode, and the secondary winding with one output to the common junction point of the return diodes, the cathode group of distribution thyristors connected by anodes to the corresponding terminals of the thyristor converter and the cathodes to the cathode of the first charging thyristor, the anode group of distribution thyristors connected by cathodes to the corresponding terminals of the thyristor converter, characterized in that, in order to reduce switching losses, it is equipped with two I have additional series-connected switching thyristors, connected with their respective terminals to the buses of the power source, four reverse diodes connected counter-parallel to the main and additional switching thyristors, an additional switching AC circuit connected by one output to the common connection point of the additional switching thyristors and another output - to the anode of the second charging thyristor, two decoupling diodes connected in series the house to the cathode of the first charging thyristor, and the cathode to the anode of the second charging thyristor and to the anodes of the anode group of the distribution thyristors, and the introduced second primary winding of the switching transformer is connected by its leads to the anodes of the second charging thyristor and the first discharge diode, and the other terminal of the said secondary winding to common connection point of decoupling diodes.