SU1116516A1 - Versions of device for adjusting double feed machine with polyphase-wound rotor and stator - Google Patents

Abstract

B A device for controlling a dual power machine with a multiphase rotor and a stator, containing a direct frequency converter with a power source, the outputs of which are connected to the rotor winding of a dual power machine, control units for starting and normal operation with driver inputs, the information inputs of which are connected to the corresponding parameter sensors the mode and the angular position of the rotor, the first outputs of the starting and normal operation control units are connected via a mode setting unit with control inputs A direct frequency converter through a pulsed-phase control system block, differing in that in order to increase reliability, by reducing dynamic overloads during start-up, the mode setting unit is equipped with switching elements, the start-up control unit is equipped with the second, third and fourth outputs, with This direct frequency converter contains two anti-parallel thyristor groups for each phase of the rotor winding, the control unit for normal operation is provided with outputs for h The phase of the rotor winding, the pulsed-phase control system unit includes the reference voltage units by the number of phases of the rotor winding and four thyristor group control units, the inputs of the reference voltage units are connected to the first information input of the start control unit, and their outputs are connected to the reference inputs three thyristor group control units, the three-phase outputs of the first thyristor groups of the rotor winding phases are provided with leads for connection to the power source, and the three-phase outputs; UPR of thyristors, phases of the rotor winding are connected to the stator circuit of the dual power supply machine, while the control inputs 9) TL of four thyristor group control units are connected to; control outputs of the control unit of normal E): operation through the corresponding co-causing elements of the mode setting unit, the reference input of the fourth thyristor group control unit. connected to the output of the reference voltage unit via the switching element, the first, second h third outputs of the launch control unit are connected through the switching elements respectively, with the control input of the first control unit of the thyristor group.

Description

with the reference and control inputs of the fourth control unit of the group of thyristors, 3 the fourth output through the switching element is connected to the control input of the first control unit of the group of thyristors. 2. A device for controlling a dual power machine with a multiphase rotor and a stator, containing a direct frequency converter with a power source, to the outputs of which the rotor winding of the dual power machine, control units for starting and normal operation with driver inputs, whose information inputs are connected to the corresponding to the sensors of the parameters of the mode and the angular position of the rotor, the first inputs of the starting control and normal operation units are connected via the mode setting unit to the control inputs the middle frequency converter through the pulsed-phase control system unit, which differs from the fact that, in order to increase reliability by reducing dynamic overloads during start-up, the mode setting unit is equipped with switching elements, the start-up control unit is equipped with the second and third outputs, the direct frequency converter contains two thyristor clusters connected in parallel to each phase for each phase of the rotor winding; the control unit for normal operation is provided with outlets according to the number of phases of the winding rotor a, the pulse phase control system unit includes reference voltage units; according to the number of phases, the rotor winding and four thyristor group control units, the inputs of the reference voltage units are connected to the information input of the start control unit, and their outputs are connected respectively to the reference inputs of two thyristor group control units, the three-phase outputs of the first groups of the rotor winding phase phases are equipped with connection to the power source, and the three-phase terminals of the second groups of thyristors of the phases of the rotor winding are connected to the stator winding of the dual-feed machine, while the control inputs of four The ex thyristor group control units are connected to their control outputs of the normal operation control unit through the corresponding switching elements of the mode setting unit, the reference inputs of the third and fourth thyristor group control units are connected to the outputs of the reference voltage units through the switching elements, and the first and third start control unit outputs connected via switching elements with control inputs of the first and second, third and fourth control units respectively thyristors and the second vkod connected through switching elements to the reference inputs of grated and fourth groups of control units of the thyristors.

I.

The invention relates to electrical engineering and can be used to control and start up powerful electric machine units, for example, hydro-accumulators of power plants,

A device for controlling a dual power machine with a multiphase rotor and a stator is known, which contains a thyristor frequency converter with a control unit, the information inputs of which are connected to the outputs of the mode parameter sensors, in particular, the rotor angle sensor, which allows control of the C13 valve motor. ; A disadvantage of the known device is to use it only for the duration of the start-up, which entails an under-utilization of the power of the electrical equipment. The closest to the invention to the technical essence and the achieved result is a device for controlling a dual power machine with a multiphase rotor and a stator, containing a direct frequency converter with a power source, to the outputs connected to the rotor winding of the dual power machine, control units for starting and normal operation with master inputs, the information inputs of which are connected to the corresponding sensors of the parameters of the mode and the angular position of the rotor, the outputs of the start control blocks and normal operation are connected through a mode specifying unit with the control inputs of the frequency converter directly through block C2l pulse-phase control system. However, this device is characterized by insufficient reliability due to the occurrence of dynamic overloads during start-up. The purpose of the invention is to increase reliability by reducing dynamic overloads during start-up. The goal is achieved by the fact that in the device for controlling a dual power machine with a multiphase rotor and stator, containing a direct frequency converter with a power source, to the outputs of which the rotor winding of the dual power machine, control units for launching and normal operation with master inputs, information inputs are connected which are connected to the corresponding sensors of the parameters of the mode and the angular position of the rotor, the first outputs of the starting and normal operation control units are connected through the unit mode with control inputs of the direct frequency converter through the pulse-phase control system unit, the mode setting unit is equipped with switching elements, the start control unit is equipped with the second, third and fourth outputs, and the direct frequency converter contains two groups of anti-parallel connected thyristors for each phase of the rotor winding, the control unit of the normal operation is provided with outputs according to the number of phases of the rotor winding, the unit of the pulse-phase control system T includes The reference voltage blocks by the number of phases of the rotor and four thyristor group control blocks, the inputs of the reference blocks are connected to the first information input of the control unit by starting the network voltage, and their outputs are connected to the reference inputs of the three control blocks groups of thyristors, three-phase. The terminals of the first groups of thyristors of the rotor winding are provided with leads for connection to a power source, and the three-phase terminals of the second groups of thyristors of the phases of the rotor winding are connected to the stator winding of a dual power machine, and the control inputs of four control units of the thyristor groups are connected to the control outputs of the normal control unit work through the appropriate commutation elements of the mode setting unit, the reference input of the fourth thyristor group control unit is connected to the output of the reference unit voltage through the switching element, the first, second and third outputs of the starting control unit are connected via switching elements respectively to the control input of the first thyristor group control unit, to the reference and control inputs of the fourth thyristor group control unit, and the fourth output through the switching element is connected to control to the input of the second or third thyristor group control unit. This goal in another embodiment is achieved by the fact that in the device for controlling the main double feed with multiphase roto. rum and a stator containing a direct frequency converter with a power source, the outputs of which are connected to the rotor winding of a double pitash machine, start-up and normal operation control units with driver inputs, the information inputs of which are connected to the corresponding sensors of the mode parameters and the angular position of the pOTopia control of start-up and normal operation are connected via a mode setting unit with control inputs and a direct frequency converter through a unit with a pulse-phase system control unit, the mode setting unit is equipped with switching elements, the start control unit is equipped with second and third outputs, the direct frequency converter contains two connected anti-parallel thyristor groups for each phase of the rotor winding 5, the normal operation control unit is equipped with outputs by the number of winding phases the rotor, the block of the system of impulse-phase control includes the blocks of the reference voltage by the number of phases of the rotor winding and four blocks of control of the thyristor groups, the inputs of the op Voltage is connected to the information input of the starting control unit, and their outputs are connected respectively to the reference inputs of two thyristor-group control units, the three-phase outputs of the first thyristor groups of the rotor windings are supplied with leads for connecting to the power source, and the three-phase outputs of the second groups Phase rotors of the rotor windings are connected to the stator winding of a dual-feed machine, and the control input 1 of the four thyristor group control units is connected to its control outputs Managed by normal operation, through the appropriate switching elements of the block for setting the mode, the reference inputs of the third and fourth thyristor group control blocks are connected to the outputs of the reference voltage blocks through switching elements, and the first and third starting control blocks are connected via control elements with the control blocks the first and second, third and fourth control units of the thyristor groups, respectively, and the second output is connected via switching elements to the reference input. rd and fourth thyristors blojftOB control groups. FIG. 1 shows a diagram of the device's blue part; 2 and 3 are diagrams of a control unit, respectively, in the first and second variants in FIG. 4; a diagram of a separate control unit of thyristor groups Hai in FIG. 5 is a diagram of the control unit start. The device for controlling the dual power supply machine 1 comprises a direct frequency converter formed by groups of 2-5 controlled gates. 2.3 groups of controls. The valves are connected counter-parallel to each other and connected via the switch 6 to the winding of the rotor 7 of the double-supply machine I. Groups 4 and 5 of the controlled gates are connected 16-counter-parallel with each other and connected via the switch 8 to the winding of the 9-rotor, machines of the double supply 1 The three-phase outputs of groups 2 and 4 of controlled valves are connected via buses to the secondary winding of a matching transformer 10. The three-phase outputs of groups 3 and 5 of controlled valves are connected in parallel with each other, and connected via a three-phase switch 11 to y tires and through a three-phase switch 12 to the stator winding of the dual-power machine 1. Parallel to the three-phase switch 12 are connected after; ovatively connected three-phase switch 13 and the second matching transformer 14. The stator of the dual-power machine 1 is connected to the network or the power grid and to the terminals the primary winding of the transformer 10, as well as with the stator current sensor 16 and the stator voltage sensor 17, the outputs of which are connected, as well as the network current sensor 18, of the voltage sensor 19 network, rotor winding current sensor 20, rotor angular position sensor 21, through information signal conversion unit 22 with corresponding informational inputs of control unit 23, which contains (FIG. 2.3) normal operation control unit 24, whose information inputs form the corresponding information inputs of the block 23. The normal operation control unit 25 has two outputs, but can be made with a separate output for each of the four groups of controlled frequency converter gates. The inputs of the reference voltage blocks 26 and 27 are connected to the first information input of the block 23, and their outputs are connected respectively to the reference inputs of the thyristor groups controlling blocks 28 and 29, 30 and 31, which form the impulses. The control inputs of blocks 28-31 are combined in pairs and connected to the corresponding outputs of block 25. The blocks 28 to 31 are connected to the outputs through corresponding controlled key elements 32 to 35 to the inputs of the corresponding groups 2 to 5 of the controlled frequency converters. The control inputs of the units 28-31 are connected to the outputs of the normal operation control unit 25 71, respectively, through the switching elements 36-39 of the mode setting unit 40. The reference input of the block 29 is connected to the output of the block 26 of the reference voltage via the switching element 41. The start-up control unit 24 is made with four outputs, the first, second and third of which are connected via the switching elements 42 - 44 respectively to the control input of the block 28, the reference and the control input of the block 29, and the fourth output of the block 24 through the switching element 45 is connected to the control input of the block 30. The control inputs of the controlled key elements 32, 33 and 34, 35 are connected to the corresponding outputs of the blocks 46 and 47 of the separate control Yeni valve groups. The first control input of the separate control unit 46 is connected to the control input of the unit 28. The control input of the separate control unit 47 of the valve group is connected to the control input of the unit 30. The output of the mode setting unit 40 is connected to the second input of the separate control unit 46 The mode setting unit 40 may be rectified, for example, as a switch with two positions. In the first position, its switching elements 36-39 and 41 are turned on, and 42-45 are turned off, this position corresponds to the normal operating mode of the dual-feed machine. In the second position, on the contrary, the switching elements 36–39 and 41 are turned off, and the switching elements 42–45 are turned on, this position corresponds to the start mode. FIG. 2 and 3 shows the states of the block 40 in the start mode. In the start mode, the switches 6,11,13,15 are open, and the switches 8,12 hr. Whips. According to the second variant, in block 23 (FIG. 3) the block 40 contains an additional but three switching elements 48-50, wherein the switching elements 42 and 45 are combined on the one hand and connected to the first output of the block 24 the switching elements 43 and 49 are interconnected on the one hand and connected to the second output of the block 24, the switching elements 44 and 48 combined on the one hand and connected to the third output of the block 24; Switching element 48 and 49 on the other hand are connected to the control and reference outputs of the block 31, the reference 68 input of which is connected to the output of the block 27 via the switching element 50. The block for the separate control of thyristor groups, for example 46 (figure 4), contains an output current logic sensor 51 a direct frequency converter that receives information from the rotor current sensor 20, element 52 OR-NOT, elements 53-56 AND, triggers 57 and 58, elements 59 and 60 at the same time, elements 61 and 62 OR, the first inputs of which are connected to the output of block 40 mode settings, their second inputs are are connected respectively with the outputs of the elements 35 and 56, and the outputs with the control inputs of the controlled key elements 32 and 33. The start control block 24 (FIG. 5) contains the block 63 for calculating the speed and block 64 for calculating the EMF, the speed regulator 65 and current torus 66, the output of which is connected to commuting element 42, threshold element 67 with adjustable trigger threshold, controllable switching elements 68 and 69, combined on one side and connected to commutator element 43. Array switching control module 70 One input is connected to the output of the threshold element 67, the other input is connected to the output of the rotor 21 angular position sensor, and the input is connected to the correcting input of the comparison element at the input of the current regulator 66. The inverter opening angle unit 71 is connected to the output of the switching element 44, and The block 72 for setting the excitation current in the rotor windings is connected to the output of the switching element 45. Information and settings of the inputs of the comparison element 73 at the input of the current regulator 66 are connected respectively to the outputs of the current sensor 18 and the regulator speed 65, at the input of which the comparison element 74 is connected by a driver input to the acceleration intensity adjuster, and the information input is connected to the output of the block 63, the input of which is connected to the output of the rotor angular position sensor, as well as to the 5T1 switching element 68 that is fed from the threshold element 67, from which also the switching element 69 is connected to the output of the block 64, the input of which is connected to the stator voltage sensor 17.

9 . II

A device for controlling a dual-feed machine with a multi-phase rotor and a stator in the first embodiment operates as follows.

In the normal operating mode, the machine with dual power supply K operates in generalized synchronous or asynchronous modes. At the time of the start-up, the power part of the direct frequency converter, made up of bridge groups 2-5 controlled by gates, is resetted into controlled variable inverter unit and two rectifiers. Accordingly, the device and operation of the pulsed-phase control system units is tuned to the start time.

In the first embodiment, the valve group 2 is used as a controllable rectifier, and the screw group 3 is used as an inverter for the duration of the start. The valve group 4 together with the winding 9 of the rotor is osu-. excites MDP as a synchronous machine also at the time of launch. These modes of valve groups are provided by start control unit 24. In this case, group 5 of controlled valves and winding 7 of the rotor are not used during start-up in the first embodiment, switch 6 is open, and switch 8 is closed.

The first output of the block 24 through the commutation element 42 allows the corresponding control signals to be transmitted, the block 28 for generating control pulses, providing the rectifying mode of the valve group 2. The signals from the third output are passed through the switching element 44 to the shaping unit 29 control pulses, providing inverse mode of the valve group 3, the second input of the block 29 dp forming control pulses through the switching element 43 from the second output of the control unit 24 is given as The reference voltage is harmonic signals from the output of the sensor. 21 The rotor's angular position or from the network. The control signals from the fourth output of the starting control unit 24 through the switching element 45 enter the pulse shaping unit 30 and provide a rectifying mode of the valve group 4 which allows the machine to double the power to excite using the winding 9 of the rotor as a synchronous machine. In re-1

651610

press start signal from block 40 mode, transmitted through block 46 separate control valve Q groups, controlled key (chevy elements 32 and 33 are closed. On

The control inputs of the block 30 and the block 47 from the fourth output of the start control block 24 are supplied through the switching element 45

0 impact, therefore, block 47 of separate control of valve groups in the start-up mode enables operation of valve group 4 in the emergency mode and prohibits operation of the valve

5 groups 5.

The acceleration process is carried out in two stages. The first (initial) stage of acceleration in the frequency range of rotation. rotor (0-0,1) u) ohm is characterized

0 low value of EMF induced in the stator winding. At this stage, such switching of the thyristors of the rectifier 2 is necessary in order to ensure the artificial de-energization of the intermediate DC circuit for the time required for restoring the thyristor properties of the Inventor 3, the current in the intermediate / DC circuit is discontinued at this stage, the Inverter 3 thyristors are unlocked in accordance with the position of the rotor of the dual power machine according to the signals of the sensor 21 of the angular position of the rotor. The second stage of acceleration (0.1-1) UJ ko / l implies the presence of EMF in the stator windings

5 is sufficient for switching the thyristors of group 3 operating in the dependent Inventor mode, and the dual power machine operates in the mode of a valve motor. When this occurs, the current is switched in the thyristors of the group (rectifier) at the expense of the EMF of the network, and in the thyristors of group 3 (Inventor) at the expense of the EMF induced in the stator winding of the machine. After overclocking is complete

 the switch 12 is opened, the switches 6 and 11 turn on, the switch 40 of the unit 40 is switched, including the switching elements 36-39 and 41, turning off 4245, i.e. power circuit returns

0 to the original circuit of the direct frequency converter. Block 23 is prepared for normal operation. After closing the switch 15, the machine is functioning

5 in the generalized synchronous or asynchronous modes.

On . Figure 1 shows a dual power machine with two phases of the excitation winding. But all of the above will be true even with the m - phase winding of the rotor. In the latter case, one phase of the rotor winding is driven. In the second variant, the starting mode is carried out using two rotor windings and all four groups of controlled gates, the switches 6 and 8 are closed, and the switches 11 and 15 are open, as in the first version. In the control unit 23 of FIG. it is enough to use the three outputs of the start-up control unit 24, increase by three the number of switching elements of the mode setting unit 40 and connect the output of the reference voltage unit 27 to the reference input of the unit 31 to generate pulses through the switching element 50 of the unit 40. The start-up process proceeds, similarly to the first variant . The units for separate control of groups of controlled valves (Fig. 4) operate as follows. The inputs of logic elements 53 and 54 I receive the information signal d-from the output of sensor 51, the other input of element 53 directly and to the other, the input of element 54 through element 52 OR OR NOT signal the polarity of control voltage, which comes from the output of blocks 24 or 25, depending on the modes, respectively, starting silt normal. Signals 1, if the load current is less than the setpoint, and the signal is sign ey 1 during the positive half-wave voltage and sign “y O during the negative half-wave. Consider the operation of the circuit in normal mode. Triggers 57 and 58 with two stable states are in the first stable state. In this case, the logical signal at the output of element 55 And is 1, and at the output of element 56 And 0. Therefore, the key 32 is open, and the key 33 is locked, and the thyristors of the valve group 2 receive control impulses. At the moment of time when the load current reaches the current sensor set point at the output of sensor 51, signal 1 appears. It becomes a fair equality of the OC sign isy 1. Therefore, at the output of element 54, signal 1 appears, which translates trigger 57 into the second stable signal. state and starts item 60 of the pppNte extract. Until the end of time, the trigger 58 switches to the right steady state, the key 33 is turned on and the valve group 3 starts working. The process of switching off the valve group 33 and turning on 32 is similar to that indicated. The condition for switching on the valve group 2 is the logical control sign Su 1 and the switch on condition valve group 3 - the reduced equation. The normal operation process of unit 47 for separate control of thyristor groups 4 and 5 of the other phase of the field winding is similar. In the start-up mode, the output of block 40 is equal to 1, therefore, from the outputs of elements 61 and 62 OR, single signals block the operation of the separate thyristor group control unit 46, and the control signals from the output of the launch control unit 24 go through the group control units. thyristors, ensuring the operation of the valve group 2 in the rectifying mode, and group 3 - in the invert mode. The block 47 in the second embodiment of the device (Fig. 2) works as in the normal mode, to the input of which one character is fed, therefore one of the valve 4,5 works in rectification mode, providing the excitation of the machine in the start mode. I Block 24 is controlled as follows. Harmonic signals from the output of the rotor angular position sensor 21 are fed to the input of the speed calculation unit 63, from the output of which a signal proportional to the speed of rotation of the shaft is fed to the information input of the comparison element 74, to the specifying input of which the signal from the speed sensor arrives. The signal from the output of the comparison element 74 via the speed controller 65 is supplied to the input of the comparison element 73, to the information input of which the voltage is supplied from the current sensor 18, and from the output of the element 73 through the current regulator 66, the control voltage is supplied to the switching element 42. Thus, the start control unit provides dual-circuit start control and contains a speed control loop to which the current control loop is subordinated. The switching of the Inverter's thyristors in the frequency zone above 0.1 WMOM is natural due to the EMF of the machine extracted by the 64-EMF sensor from the voltage signal of the stator from the sensor 17 When starting in the low-frequency zone up to 0, the Inverter thyristors are artificially switched due to quenching the rectified current by removing the control pulses from the rectified l. This is implemented using a threshold element 67, to the inputs of which signals are proportional to the speed of rotation from block 63 and the reference signal is proportional to 0.1 Uj com. If the speed signal is less than this setpoint, which corresponds to the state of the elements in Fig. 5, then the output of the threshold element 67, a control signal appears, which closes the switching element 68 and bursts the switching element 69, thereby ensuring the passage of harmonic signals from the rotor angle position sensor 21 through the switching element 43. Simultaneously The control signal from the output of the threshold element 67 and the harmonic signals from the rotary angular position sensor 21 are fed to the inputs of the artificial switching mode control unit 70, providing an intermittent current mode. When the speed is reached (J O, the control signal of the threshold element disappears and through commutating element 69, the inverter commutates via the emf signals from sensor 64. In the simplest case, the inverter opening angles, as well as the excitation current of the dual-feed machine, are not controlled during start-up, 5 shows that embodiment ispolneii shapers 71 and 72 of these signals as the control signals permanent setting devices, such as a source of calibrated voltage and an adjustable potentiometer. As a result of the application of the invention, there is no need to use starting resistors or special accelerating devices, and the overall dimensions of the device improve.

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Claims (2)

1. Device for controlling a dual-power machine with a multiphase rotor and stator, comprising a direct frequency converter with a power source, the outputs of which are connected to the rotor winding of the dual-power machine, control units for starting and normal operation with master inputs, the information inputs of which are connected to the corresponding parameter sensors mode and angular position of the rotor, the first outputs of the start and normal operation control units are connected through the mode setting unit to the control inputs a direct frequency converter through a block of a pulse-phase control system, characterized in that in order to increase reliability, by reducing dynamic overloads at start-up, the mode setting unit is equipped with switching elements, the start-up control unit is equipped with a second, third and fourth outputs, the direct frequency converter contains two counter-parallel connected groups of thyristors for each phase of the rotor winding, the normal operation control unit is equipped with outputs according to the number of phases of the winding rotor ki, the pulse-phase control system unit includes reference voltage blocks according to the number of phases of the rotor winding and four control units of thyristor groups, inputs of reference voltage blocks are connected to the first information input of the start control block, and their outputs are connected respectively to the reference inputs of three corpse control blocks · * In thyristor assemblies, the three-phase outputs of the first groups of thyristors of the phases of the rotor winding are equipped with leads for connecting to a power source, and the three-phase outputs of the second groups of thyristors, phases of the rotor coils are connected to the stator winding of the dual-power machine, while the control inputs of the four control units of the thyristor groups are connected to the control outputs of the normal control unit ^: operation through the corresponding switching elements of the mode setting unit, the reference input of the fourth control unit of the thyristor group is connected to the output of the reference voltage unit through the switching element, the first, second and third outputs of the start-up control unit are connected via the switching elements to the control input of the first group conductive thyristor control unit, 16516 with the reference and control inputs of the fourth thyristor group control unit, and the fourth output is connected via a switching element to the control input of the first thyristor group control unit. 2. A device for controlling a dual-power machine with a multiphase rotor and a stator, comprising a direct frequency converter with a power source, the outputs of which are connected to the rotor winding of the dual-power machine, control units for starting and normal operation with master inputs, the information inputs of which are connected to the corresponding parameter sensors mode and angular position of the rotor, the first inputs of the start and normal operation control units are connected via the mode setting unit to the control inputs directly of the frequency converter via the pulse-phase control system unit, it is distinguished by the fact that, in order to increase reliability by reducing dynamic overloads, at start-up, the mode setting unit is equipped with switching elements, the start-up control unit is equipped with a second and third outputs, while the direct frequency converter contains two counter-parallel connected groups of thyristors for each phase of the rotor winding, the normal operation control unit is equipped with outputs for the number of phases of the rotor winding, b The lock of the pulse-phase control system includes reference voltage blocks by the number of phases of the rotor winding and four control units of thyristor groups, inputs of reference voltage blocks are connected to the information input of the start control unit, and their outputs are connected respectively to the reference inputs of two control units of thyristor groups, the three-phase outputs of the first groups of thyristors of the phases of the rotor winding are equipped with leads for connecting to a power source, and the three-phase outputs of the second groups of thyristors of the phases of the rotor winding phases are connected with the stator winding of the dual-power machine, while the control inputs of the four control units of the thyristor groups are connected to their control outputs of the normal operation control unit via the corresponding switching elements of the mode setting unit, the reference inputs of the third and fourth control units of the thyristor groups are connected to the outputs of the voltage reference blocks through the switching elements, the first and third outputs of the start-up control unit are connected through the switching elements to the control inputs of the respectively first and second, third and fourth groups of control units of the thyristors, and the second output is connected through switching elements to the reference inputs of grated and fourth groups of control units of the thyristors.