SU1399868A1 - Device for controlling thyristors of converter - Google Patents

Abstract

The invention relates to electrical engineering and can be used to control converters comprising two sets of valve equipment. The aim of the invention is to enhance the functionality by allowing the control of the second valve set of the converter. Frequency and phase information

Description

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No network enters the control channels 1 through single-phase transformers 10 synchronization blocks 2 with a mutual phase shift of 120 degrees. In phase shifting unit 3, trapezoidal negative polarity voltage pulses are used to charge capacitors 16, 18 and set the switching sequence of switching transistors 20 for generators 14, 15, which alternate from cut-off mode of collector current to saturation mode. As a result, the capacitors 16, 18 are connected to the current-drive current transistors 22, 36, which are in the conducting state. The sawtooth voltage obtained as a result of the discharge of the shaping capacitor 16 is compared with the DC voltage on the reference capacitor 18, and their difference is applied to the diode 17 and through the light emitter of the optocoupler 24 and the resistor 25 enters the emitter of the single junction transistor 30. When the difference between these voltages reaches the switching threshold of the single-transistor 30, the capacitor 18 is discharged, and a light pulse is formed on the light-emitting element of the optocoupler 24, including the photoreceiver of the optocoupler 4. 2 hp f-ly, 2 ill.

one

The invention relates to electrical engineering and can be used to control converters comprising two sets of valve equipment, in particular, a direct frequency converter or a reversing converter.

The aim of the invention is to enhance the functionality by allowing the control of the second valve set of the converter.

FIG. 1 is a schematic diagram of a direct drive frequency converter dL device; in fig. 2 is a diagram of a control pulse distributor; in fig. 3 is a schematic diagram of an apparatus for controlling a reversible LEM.

The device for controlling the thyristors of the converter contains three phase control channels 1, each of which consists of a synchronization unit 2, the input of which is connected to the corresponding phase direction, and the outputs are connected to the clock inputs of phase-shifting 3 and additional 4 phase-shifting units, controlling the inputs of which are connected via the isolating resistor 5 to the output of the voltage source 6, control, and the opposite outputs through elements 7 and 8 of the galvanic isolation are connected to the inputs of the zero organ 9.

Synchronization unit 2 is made on a single-phase transformer 10, the primary winding of which is the input of unit 2, and the secondary winding is connected to the ends of the chain of the series-connected limiting resistor 11, double-ended Zener diode 12 and additional double-sided Zener diode 12. The connection point of the resistor 11 and Zener diode 12 is one, and the connection point of the secondary winding of the transformer 10 and the zener diode 13 - to the other outputs of block 2. The connection point of the zener diodes 12 and 13 is connected to the common bus of the device, nennoy with nulevik wire network.

The phase shifting unit 3 is provided on two generators 14 and 15 of the sawtooth voltage. Each generator 14 and 15 is made on a shaping capacitor 16, clamped by a chain of series-connected reference diode 17 and a reference capacitor 18 and connected between the common bus and the connection point of the anode of the discharge diode 19 and the collector of the switching transistor 20, the base of which is connected through the input resistor 21 to the cathode of diode 19, another generator 14 or 15, which is the synchronizing input of unit 3. Between the common bus and the connection point of the emitters of the transistors 20 of the l4 and 15 generators, the discharge transistor 22 is turned on, the bases and which is the control input of the unit 3. Between the base and the emitter of the transistors 20 of the generators 14 and 15 opposite to the direction of the base-emitter junction are included matching diodes 23.

The additional phase-shifting unit 4 is made identical to unit 3 on transistors of a different conductivity type and with the switching direction of the diodes 17, 19. and 23 reversed.

Elements 7 of galvanic isolation 20 of which are connected to one of

Each is mounted on the optocoupler 24, the light-emitting element of which is shunted by resistor 25 and connected between the corresponding output of block 3 and one input of the zero-body 9, and the photodetector is connected via a parallel RC chain 26 between the source 27 of the distributor 28 control pulses executed on summing diodes 29 connected to the primary windings of isolation transformers (not shown) connected to a six-phase star with a grounded neutral, Connected to the control transitions of the converter valves.

The galvanic isolation elements 8 are made identical to the elements 7 with the difference that their light-emitting elements are connected to another input of the zero-body 9, made on the unijunction transistor 30, the emitter of which is one input of the zero-body 9, the first base through the adjustable resistor 31 is connected to source 27, and the second base is connected via series-connected resistor 32 and decoupling diodes 33 and 34 are connected to the emitter of transistor 30. The connection point of diodes 33 and 34 is connected to the common bus, and the connection point of diode 33 s m 32 is the other input of the zero-organ 9.

To control the direct frequency converter, the control voltage source 6 is made in the form of a modulating signal generator 35, and blocks 3 and A are equipped with an additional transistor 36 of the appropriate conductivity type connected to the discharge transistor 22 according to the current mirror circuit (Fig. 1).

To control the reversing converter, the control voltage source 6 is made in the form of a two-pole voltage source consisting of two series-connected capacitors 37 and 38, the first of which is bridged by a resistor 39 and connected to the free end

to a common bus and the other to a controlled resistor 40, the middle pin of which is the output of source 6. and two series-connected diodes 41 and 42, the point of the connection terminals of block 2 of one of the control channels 1 (Fig. 2).

The device (4ig. 1), designed to control the frequency converter, made on the bridge three-phase-single-phase scheme, works as follows.

The information on the frequency, amplitude and form of the single-phase voltage at the output of the converter is carried by the modulating signal coming from the generator 35 of the modulating voltage. Modulating voltage sets the order

the entry into operation of valve converter kits and the periodic change in the switching angles of the power thyristors. As a modulating voltage, a sinusoidal low frequency voltage is used. Depending on the polarity of the modulating voltage, phase-shifting units 3 and 4 come into operation, which carry out separate control of the corresponding valve set. Switching valve kits occurs when the modulating voltage passes through zero and maximum switching angles of the thyristors of the converter. Periodic change of the switching angles of the power thyristors of the converter is carried out by changing the discharge time of the forming capacitor 16 by changing the magnitude of the collector current of the current mirror transistor 22 proportional to the voltage level of the generator 35. The range of the switching angles of the thyristors when forming

The output voltage is close to 180 el.

Since the resistance of the emitter junction of the transistor 22 and 36 of the current mirror is small compared with the resistance of the resistor 5, the input circuit is characterized by a linear V – Amperon dependence. In this case, the base and collector currents of the transistors 22 and 36 of the current mirror, respectively, are equal, since the transistors have mutually agreed characteristics. The magnitude of the base current compared

with collector is negligible. The voltage across the supporting capacitor therefore the equality of the input and collector currents of the transistors, i.e. In the case of IK, Considering that a voltage-current input volt-ampere characteristic, as well as equality of input and collector currents, takes place, it is obvious that the control characteristic is linear. Since the magnitude of the current discharge, and, consequently.

discharging time of the forming condensate - 25to-emitting element of the optocoupler 24

torus 16 depends only on the magnitude of the input current, various destabilizing factors, such as temperature changes of parameters, aging of transistors, instability of the network voltage, etc., do not have a significant effect on the discharge time, which improves the phase stability of the output pulses and accuracy maintaining the output voltage of the converter.

Information about the frequency and phase of the mains voltage enters the control channels 1 through single-phase transformers 10 of the synchronization units 2 with a mutual phase shift of 120 e. hail. The incoming sinusoidal voltage is limited to a maximum by bilateral zener diodes 12 and 13 and is converted into alternating trapezoidal pulses. In the phase shifter 3, negative polarity pulses are used to charge capacitors 16 and 18 and set the sequence of switching transistors 20 to the 1D and 15 generators in accordance with the sequence of the phases of the network voltage. The capacitors 16 and 18 are charged by the current flowing through the diodes 17 and 19. The switching transistors 20 of the generators 14 and 15 are controlled by antiphase pulses.

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unit 2, arriving at the base through resistors 21 from the anodes of the zener diodes 12 and 13. Under the influence of the control current, the switching transistors 20 of the generators 1A and 15 alternately switch from the cut-off mode of the collector current to the saturation mode. As a result, the capacitors 16 and 18 are connected to the transistors 22 and 36 of the current mirror, which are in the conducting state. Here, the shaping capacitors 16 are discharged by the current mirror transistor 22.

pax 18 does not change as the diode 17 prevents the flow of the discharge current. The sawtooth voltage obtained as a result of the discharge of the shaping capacitor 16 is compared with a constant voltage on the reference capacitor 18, and their difference is applied to the diode 17 and through a parallel circuit consisting of the over-resistor 25, is fed to the emitter of the unijunction transistor 30. When the difference of these voltages reaches the switching threshold of the unijunction transistor 30, the resistance of the emitter junction will decrease, the capacitor 18 will discharge And a light pulse is generated on the light emitting element of the optocoupler 24, including a photodetector of the optocoupler 4.

Phase shifting unit 4 works in the same way, except that for Zar da capacitors 16 and 18 and

Switching transistor controls 20 of oscillators 14 and 15 use pulses of positive polarity of block 2.

Variable resistor 31 is designed to balance the output pulses in phases. The need for balancing is due to the nonidentity of the parameters of single-junction transistors according to the magnitude of the switching threshold and disappears in the case of the selection of transistors by parameters.

Since the capacitor discharge processes take place in different half-cycles of the mains voltage, symmetric phase-shifted 180 e. Degrees are formed at the outputs of the phase shifter. control pulses. Since in the phase control channels the formation processes

pulses flow with a mutual phase shift of 120 electr., at the outputs of the control channels there are two three-phase control impulse systems, which are shifted between themselves by 60 el. grades, since the control system of the centrifugal set must ensure the inclusion of power thyristors of the converter with dual pulses, following through 60 el.grad. The control channels are connected via summing diodes 29 to the six-phase star with a grounded neutral primary windings of isolation transformers, the secondary windings of which are connected to the control electrodes of the power thyristors of the converter.

The device shown in figure 2, operates as described.

Separate control of the valve sets of the reversing converter is achieved by the fact that control pulses are supplied to only one valve set working at the moment. Switching the valve sets is achieved by changing the polarity of the control signal at the input of the phase shifting units 3 and A. Phase shifting devices 3 or 4, which carry out the first conductivity type transistors 20 and 22 of the same conductivity type, start working and on the transistors of the opposite type - control of the second valve sets. The input control signal is generated by a source 6 of two polar voltages, made on capacitors 37 and 38, which are charged through rectifier diodes A1 and 42, respectively, to twice the amplitude value of the voltage, limited by the zener diode 12. The voltage of the capacitors 37 and 38 is supplied adjustable 40 and constant 39 resistors. In the middle position of the slider of the resistor 40, the voltage supplied to the input of the phase-shifting b; socks 3 and 4 is zero, and in the extreme positions it is maximum positive or negative. A change in the turn-on angle of the power thyristors of the valve sets is achieved by changing the discharge time of the forming capacitors 16 by changing the size of the collector current of the bottom of the transistor 22. At the maximum control voltage level, the turn-on angle of the thyristors is close to zero, which corresponds to the maximum voltage at the output of the converter. Switching of valve sets occurs at the moment when the control voltage passes through zero at maximum switching angles. The working angles corresponding to the required output voltage are set after switching the valve set.

Thus, due to the introduction into each phase channel of the control two phase-shifting units, real. transistors of the same type of conductance control first, and on

transistors of the opposite type - control of the second valve sets; a spread of device functionality is achieved.

Claims (2)

1. A device for controlling a thyristor of a converter, comprising a source of constant voltage, source of control voltage and three phase control channels, each of which consists of a phase-shifting unit, the control input of which is connected to a source of control voltage, the synchronization input — to the outputs of the synchronization unit, the input of which is connected to the corresponding phase voltage, and anti-phase outputs of the phase-shifting unit through the elements galvanic isolation - to the input of the zero-organ, and the synchronization unit is made on a single-phase transformer, the primary winding of which is the input synchronization unit, and the secondary winding is connected at one end to one clock input of the phase-shifting unit, and the other end through a limiting resistor to to the other synchronous input of the phase-shifting unit and to one output of the double-sided Zener diode, the phase-shifting unit is made in the form of two sawtooth voltage generators, each of which is made on a shaping capacitor, connected between a common organizer bus, connected to the zero prone (DGi geti, and a junction point (co.tgkorl comm10 15 20 25 of the transistor and the anode of the discharge diode and the bridged chain of series-connected reference diode and the reference capacitor, the junction points of which are between them are the corresponding output of the phase-shifting unit, the synchronous input of which is the corresponding sawtooth generator, and the control the input is connected to the base of the common for both generators of the sawtooth voltage of the discharge transistor connected between The common bus and the junction point of the emitters of the switching transistors of both sawtooth voltage generators, the bases of which are connected through the input resistors to the cathode of the discharge diode of another sawtooth voltage generator, is zero-body on two developing diodes and a single junction transistor whose emitter is connected to one cathode A diode is a single zero-organ input, the first base is connected via a variable resistor to a constant voltage source, and the second base is connected to one output terminal. The device is characterized in that, in order to expand its functionality, it is equipped with a control pulse distributor, placed on summing diodes connected to a primary winding of isolation transformers connected to a six-phase star with grounded neutral, the secondary windings of which are intended to be connected to control transformers of thyristors In each control channel, the synchronization unit is equipped with an additional double-sided zener diode, connected between one end of the secondary The phase winding of the single-phase transformer and the other output of the main bilateral zener diode connected to the common bus, the phase-shifting unit is equipped with two matching diodes connected between the base and the emitter of the switching transistors of the sawtooth voltage generators in the direction. 1399868 between the corresponding output of the phase-shifting unit and the input of the zero-organ, and the photodetector is connected between the power source and the corresponding input of the pulse distributor through a parallel RC chain, each control channel is equipped with an additional phase-shifting unit and two additional elements of galvanic isolation, made identical to the main phase-shifting unit with replacement by transistors of a different type of conductivity and changing the direction of the diodes to the opposite and the main element there is galvanic isolation, the inputs of the additional phase-shifting unit are connected to the corresponding inputs of the main phase-shifting unit, its outputs are connected via photo detectors of additional galvanic isolation elements to the corresponding inputs of the control pulse distributor and through light-emitting elements of additional galvanic isolation elements to the connection point of another output resistor and the anode of the other decoupling diode, which is the other input of the null-30 40 Yes, it is connected to the anode of one decoupling diode of a zero-organ and to the common bus 2. The device according to claim 1, characterized in that, in order to form a sinusoidal single-phase voltage half-wave voltage close to the modulating waveform, the control voltage source is made in the form of a modulating signal generator, and the phase-shifting blocks in each control channel are equipped with each additional transistor corresponding type of conductivity, connected with a discharge transistor according to the current mirror scheme. 3, the apparatus according to claim 1, characterized in that, for the purpose of (Separate control of valve sets, the source of control voltage is made as a source the opposite direction of the base-emitter-55 dual-pole voltage, transition state, elements of galvanic two consecutive connections are made each on the optocoupler, capacitors, one of which has a light-emitting element, which is bounded by a resistor and connected with a resistor, connected to a free end to a common bus. zo Yes, it is connected to the anode of one decoupling diode of a zero-organ and to the common bus about 0 2. The device according to claim 1, characterized in that, in order to form a sinusoidal single-phase voltage half-wave voltage close to the modulating waveform, the control voltage source is made in the form of a modulating signal generator, and the phase-shifting blocks in each control channel are equipped with each additional transistor corresponding type of conductivity, connected with a discharge transistor according to the current mirror scheme. 3, the apparatus according to claim 1, characterized in that, for the purpose of (Separate control of valve sets, the source of control voltage is in the form  1399868 and the other is an adjustable resistor, connected by a diode, the junction point of which is average connected to one of the outputs by a voltage source of the control of the synchronization unit of one of the channels, and two in series (Sbij (odaM) / jv j f (ve gg7i / 1nom / fo / / ieff / 77ff u / it / ffffZ Figg control gear. K B S S FIG 3