SU1169101A1 - Device for controlling thyristors - Google Patents

Abstract

1. A TIRISTOR CONTROL DEVICE containing three control channels by the number of phases, each of which contains a single-phase synchronizing transformer, the secondary winding of which is connected via a diode to a storage capacitor connected to a primary winding of a pulse transformer through a diode, the secondary winding of which is intended to be connected to a control capacitor power thyristor, and a power source connected to a relaxation generator on a single junction transistor, the input of which is is located in the form of a phase-shifting RC circuit, and the output is connected to a thyristor control transition, and a variable resistor is connected to one of the power supply terminals, characterized in that, in order to increase the control stability, it is equipped with an additional power source synchronization, made in the form of an additional winding of a synchronizing transformer connected through the base resistor to the base-emitter junction of the transistor, and two additional windings of the pulse transf The armature, the second and third channels are each equipped with an additional thyristor, with an additional power source connected to the input of the relaxation generator of the first channel through a synchronizing node transistor, the inputs of the second and third channel relaxation generators through additional thyristors, the control transitions of which are connected to additional windings pulse transformer, and the input of the PSI power source - to the synchronizing voltage. 2. The device according to claim 1, characterized in that each control channel is provided with an additional diode, a thermistor and an indicator connected to the charging capacitor charge circuit, the series-connected thermistor and the variable resistor connected to the output O5 of the power supply, and their connection point through an additional diode connected to the second base of the unijunction transistor of the relaxation generator.

Description

The invention relates to electrical engineering, in particular, to devices for pulsed phase control of thyristors and can be used, for example, to implement a smooth start of an induction motor or to control a three-phase rectifier.

Thyristor control devices are known that contain phase-shifting R C-circuits and threshold elements for generating control pulses 1.

The disadvantage of these devices is the instability of the formation of the phase of the control angle.

The closest in technical essence to the present invention is a thyristor control device comprising three control channels in terms of the number of phases, each of which contains a single-phase synchronizing transformer, the secondary winding of which is connected via a diode to a storage capacitor connected through the thyristor to the primary winding of a pulse transformer, the secondary the winding of which is intended to be connected to the control transition of the power thyristor, and the power source connected to the relaxation a generator on a single junction transistor, the input of which is made in the form of a phase-shifting RC circuit, and the output is connected to a control transition of a power thyristor, and a power source connected to a relaxation generator on a single junction transistor, the input of which is made in the form of a phase-shifting RC circuit, and the output is connected a thyristor control transition, with a variable resistor 2 connected to one of the power supply terminals.

A disadvantage of the known device is the variation in the formation of the angle over the control channels.

The purpose of the invention is to increase the stability of control.

This goal is achieved by the fact that a device for controlling thyristors contains three control channels by the number of phases, each of which contains a synchronizing single-phase transformer, the secondary winding of which is connected via a diode to a storage capacitor connected to the primary winding of a pulse transformer whose secondary winding is intended for connection to a control transition of a power thyristor, and a power source connected to a relaxation generator on a single junction nn transistor, whose input is made in the form of a phase-shifting RC circuit, and the output is connected to a thyristor control transition, and to one of the terminals of the power supply is connected

variable resistor, equipped with an additional power source, the first control channel is equipped with a synchronization node, made in the form of an additional winding of a synchronizing transformer connected through the base resistor to the base-emitter junction of the transistor, and two additional windings of the pulse transformer, the second and third channels are provided with each additional thyristor, moreover, the additional power source is connected to the input of the relaxation generator of the first channel through the transistor; its node inputs relaxation oscillators second and third channels - through additional thyristors, control transitions guides which are connected to the secondary winding of the pulse transformer, and a power source input - to the synchronizing voltage.

In addition, each control channel is equipped with an additional diode, a thermistor and an indicator connected to the charging capacitor charge circuit, the series-connected thermistor and the variable resistor being connected to the output of the power supply, and their connection point through the additional diode is connected to the second base of the single junction relaxation transistor generator.

The drawing shows a device diagram.

The device for controlling thyristors contains three channels 1-3 of control according to the number of phases A, B, C of the network and two sources 4 and 5 of the power supply, the first of which is designed as an unstabilized rectifier whose input is connected to a synchronizing voltage of the network. Each control channel 1-3 contains a clock transformer 6 with an additional winding 7 and a secondary winding 8, connected via diode 9 to a storage capacitor 10, which is connected to the primary winding of a pulse transformer 12 with a secondary 13 and two additional 14 and through a thyristor 11 15 windings, a relaxation generator 16 on a single junction transistor 17, the input of which is formed by a phase-shifting RC circuit 18 of a capacitor and a control resistor 20. The relaxation generator 16 is connected to the power supply output ka, shunted by a series-connected thermistor 21 and a variable resistor 22, through the base resistors 23 and 24 of the single junction transistor 17. The connection point of the resistors 21 and 22 is connected via an additional diode 25 to the second base of the transistor 17, and the output of the generator 16 formed by the base resistor 24 is connected to the control electrode of the thyristor 11. An additional power supply 5 is connected to the input of the relaxation generator 16 of the first drip 1, shunted by the load resistor 26 through the transistor 27 of the node 28 of the syncro The base, whose base through the base resistor 29 is connected to the auxiliary winding 7 of the transformer 6, and to the inputs of the generators 16 channels 2 and 3 through additional thyristors 30 and 31, the control transitions of which are connected to the additional windings 14 and 15 of the pulse transformer 12, respectively. An indicator 32 is included in the charge circuit of the storage capacitor 10 of each channel.

The device works as follows.

After supplying mains voltage, the storage capacitor 10 is charged through diode 9 to an amplitude value of the voltage on the winding 8. Negative half-wave voltage of the additional winding 7 through the resistor 29 opens the transistor 27 of the synchronization unit 28 and the voltage of the power source 5 from the load resistor 26 is supplied to the phase-shifting circuit 18. The capacitor 19 begins to charge to the response level of the single-junction transistor 17, after which the thyristor 11 is opened and the storage capacitor 10 is discharged through the primary th ob.motku i.mpulsnogo the transformer 12 in the output winding 13 which is formed by a control pulse.

At the same time, the pulses from the synchronization windings 14 and 15 are supplied to the additional thyristors 30 and 31, which are opened, and the voltage of the power supply 5 is supplied to the second (B) and third (C) channels. The processes occurring in these channels are similar to the processes in the first channel. The only difference is that in the second channel the operation of the unijunction transistor occurs through 120 e. hail, and in the third channel - through 240el. grad, relative to the first channel, which is the master. Tripping phases are set using adjustment resistors of 20 phase-shifting RC circuits in the second and third channels and do not change during operation. The power supply of the phase-shifting RC-circuits 18 and the generators 16 of the channels 2 and 3 is also carried out from the source 5, which makes the operation of the device independent of the voltage fluctuations of the supply mains.

Setting phase-shifting RC-circuits 18 of the second and third channels is fixed.

and the operation of the entire device is controlled from n () mon1c1 n1 o.uioro of variable resistor 20 () slvak) 1gr1 of value 18 first () 1h) dripped. When you get it.

symmetry currents by ((shzam.

Odpoperehodpogo Power transistor 17 from the first channel only nestabi.schzirovannogo straightening mite.ch 4, luxiK.noMCHiioid to pitayuscheG network allows stabi.shzironat output parameters (starting current induction motor, vgchodpoe voltage controlled three-phase rectifier) when the oscillation voltage x bride network. So. with decrease (decrease), voltage increases (decreases) interbase

5 the voltage of the unijunction transistor 17. This triggers its operation at a higher (men1) P1) voltage on the capacitor 19, which is equivalent to a time shift (relate the sine wave of the power supply network) of the control pulse. With a decrease (increase) in the voltage of the network, the impulse is correspondingly transferred to the patch (end) of the sine (), i.e. takes place) stabilization of the output parameters.

5Temperature resistor 21, transition 11 diode 25

and the variable resistor 22 is part of the bridge formed by the unijunction transistor 17 and the base resistor 23. At normal (+ 20 ° C) temperature, the bridge is tuned by the variable resistor 22 so that the transition diode 25 is locked with a small (about 0: 5V) voltage. With decreasing temperature, the transmission ratio of the one-way transistor 17 is increased, which leads to an increase in the output parameters. By simultaneously increasing the resistance of the thermistor 21, the transient diode 25 opens, the second potential of the second base of the single junction transistor 17 appears, which leads to its compensation

 transmission coefficient. Similarly, compensation occurs in the second and third channels.

Introduction to the charge circuit of the storage capacitor 5 of the indicator 32 of the indicator 32 makes it possible, by the nature of its luminescence (off, on fully, on, intermittently) to quickly determine the operability of the device or outdated elements, which simplifies the operation of the device. 0 Thus, the invention makes it possible to improve the operational characteristics of the device by increasing the accumulation of the formation of the iiMiiy.ibcon phase of different channels.

Claims (2)

1. A device for controlling thyristors, containing three control channels by the number of phases, each of which contains a synchronizing single-phase transformer, the secondary winding of which is connected through a diode to a storage capacitor connected via a thyristor to the primary winding of a pulse transformer, the secondary winding of which is intended to be connected to the control power thyristor transition, and a power source connected to a relaxation generator on a single-junction transistor, the input of which is made in ide phase-shifting RC circuit, and the output is connected to the control transition of the thyristor, and a variable resistor is connected to one of the terminals of the power source, characterized in that, in order to increase control stability, it is equipped with an additional power source, the first control channel is equipped with a synchronization unit, made in the form of an additional winding of a synchronizing transformer connected through a base resistor to the base-emitter junction of the transistor, and two additional windings of a pulse transformer, sec the first and third channels are each equipped with an additional thyristor, with an additional power supply connected to the input of the relaxation generator of the first channel through the transistor of the synchronizing unit, the inputs of the relaxation generators of the second and third channels through additional thyristors, the control transitions of which are connected to additional windings of the pulse transformer, and power supply input - to the synchronizing voltage. 2. The device according to π. 1, characterized in that each control channel is equipped with an additional diode, a thermistor and an indicator included in the charge capacitor charge circuit, and a thermistor and a variable resistor connected in series are connected to the output of the power source, and the point of their connection through the additional diode is connected to the second base of the single-junction transistor relaxation generator. 11 1