SU758471A1 - Method of control of thyristorized self-sustained voltage inverter - Google Patents

Description

'' The invention relates to power conversion technology and can be used in circuits of a thyristor voltage inverter with a single-phase and three-phase load.

A known method of controlling a thyristor ⁵ autonomous inverter is that the reverse anode voltage pulses are supplied to the working thyristors M И AND · 'However, this method does not ensure reliable operation of the inverter with a limited time of application of the reverse voltage.

The closest in technical sutts- NOSTA and achieved result is a method for controlling autonomous thyristor inverter with a common switching unit, which consists in the fact that the return pulses fed anode voltage, with a shape _χ ble common switching unit, operating simultaneously on all of the inverter thyristors in each switching interval and.

The method does not ensure the reliability of the inverter with a limited time of application of the reverse voltage.

The purpose of the invention is to increase the reliability of the inverter.

This goal is achieved by supplying a negative control pulse to the working thyristor, which must be locked, and the application time of the negative polarity of the anode voltage from the common switching unit is chosen so that, after removing the negative anode voltage, the thyristors to which the control pulse of negative polarity was not applied, stayed on.

In FIG. 1 shows a schematic diagram of a three-phase bridge inverter with a common switching unit; in FIG. 2 timing diagrams for two consecutive switching intervals.

s 758471

An inverter with operating thyristors 1–6 and reverse diodes 7–12 operates on a three-phase load 13 and contains a common switching unit, consisting of a capacitor 14, thyristors 15–18, double winding reactors 19, 20, the primary windings 21, .22 of which are designed to limit switching current, and the secondary windings 23, 24 together with the diodes 25, 26 are used to divert the excess energy accumulated in the switching unit to the power source.

'The control method of the inverter is as follows. fifteen

Let the main thyristors 1, 2 and 6 be open until time t ₁ , and the capacitor 14 is charged with a positive potential on the right-hand side and at this moment in accordance with 20 given the switching algorithm, you need to lock the working thyristor 1, and leave thyristors 2 and 6 in a conducting state.

At the moment, the switching 25 thyristors 15 and 18 are unlocked by applying positive control current pulses to them. In this case, the charged capacitor 14 immediately generates a reverse anode voltage pulse 30 on all the main thyristors of the inverter, which remains until the time moment f _g , until the voltage across the capacitor 14 changes polarity when it is recharged along the circuit 14-18 -'22 - source 35 inverter power supply - 21 - 15 - 14.

Simultaneously with the switching of the thyristors 15 and 18, at a time t, a pulse of negative 40 control current is applied to the working thyristor 1, thereby providing its combined shutdown, i.e., shutdown when the pulses of the reverse anode voltage and the negative current are combined management. And the working thyristors 2 and 6, which conducted the current before the start of switching and to which the negative control current pulses were not supplied, are switched back on 50 without control pulses with a corresponding decrease in the duration of the reverse anode voltage pulses — the negative control current pulse, but at the same time sufficient for reliable locking of the thyristor with simultaneous exposure to a pulse of negative control current.

In the same way, in the following switching cycles, other main thyristors of the inverter are locked, and at the same time, several (from one to three.) Working thyristors can be locked, giving, together with a shortened and common for all working thyristors, reverse anode voltage pulse · negative control current pulses to those thyristors that need to be locked at a given switching interval. In FIG. 2 shows how, at the switching stage, starting at the time point f _g , two thyristors 2 and 6 are locked,

The pulse duration of the negative control current i y should be sufficient for reliable combined shutdown of the thyristor.

The application of the proposed method improves the reliability of the inverter, reduces the power of the common switching unit, reduces the turn-off time of the working thyristors, which extends the operating frequency of the inverter.

Claims (3)

 The invention relates to power converter technology and can be used in thyristor voltage inverter circuits with single-phase and three-phase loads. A known method for controlling a thyristor autonomous inverter is that impulses of reverse anode voltage supply to working thyristors. However, this method does not ensure reliable operation of the inverter with a limited time of application of reverse voltage. The closest in technical essence and the achieved result is a method of controlling a thyristor autonomous inverter with a common switching unit, which consists in sending pulses of reverse-anode voltage generated by a common switching unit, simultaneously to all working thyristors inverter on each switching interval 3j. The method does not ensure reliable operation of the inverter with a limited time for the application of the reverse voltage. The purpose of the invention is to increase the reliability of the inverter. The goal is achieved by applying a negative control pulse to the working thyristor, which must be locked, and the time of application of the negative polarity of the anode voltage from the common switching unit is chosen so that after removing the negative anode voltage, the thyristors to which no pulse was applied negative polarity control, remained in the on state. FIG. 1 is a schematic diagram of a three-phase bridge inverter with a common switching unit; in fig. 2 timing charts for two consecutive switching intervals. An inverter with working 1-6 chips and reverse diodes .2 operates on a three-phase load 13 and has a common switching unit consisting of co-capacitor 14, thyristors 15-18 and double-wound chokes 19, 2O, the primary windings 21, 22 which are intended to limit ilHOHHoro current, and the secondary windings 23, 24 together with diodes 25, 26 serve to divert to the power source the excess energy accumulated in the switching unit. The inverter control method is carried out as follows. Let the main thyristors 1, 2 and b be opened up to the time t, and the capacitor 14 is charged with positive potentials on the right side and at a given time in accordance with the given switching algorithm it is necessary to lock the working thyristor 1, and leave the thyristors 2 and 6 in the conducting state. 8, moment t, the switching thyristors 13 and 18 are unlocked by applying positive control current pulses to them. At the same time, the charged koi sensor 14 immediately generates an inverse anodic voltage pulse on all of the main inverter thyristors, which persists until time point t h. until the voltage on the capacitor 14 does not change the polarity when it is recharged along the circuit 14-18 -22 the inverter power source - 21 - 15 - 14 Simultaneously with the unlocking of the switching thyristors 15 and 18, at the time t gives a pulse of negative control current working thyristor 1, thus ensuring its combined shutdown, i. a. switching off with the joint action of impulses of reverse anode voltage and of a positive control current. And the working thyristors 2 and 6, which were conducted before the commencement of the commutation, and to which the negative control current pulses were not applied, were re-enabled without control pulses, with a corresponding decrease in the duration of the reverse anodic voltage pulse. The value of t g- is chosen so that it would not lead to the locking of the working, thyristor in the absence of 7 14 pulses of negative control current, but at the same time remained sufficient for reliable locking} and the thyristor while simultaneously affecting it by a negative current pulse management In the same way, in the following switching cycles, the other main inverter thyristors are locked, and at the same time several (from one to three.) Working thyristors can be locked, giving together with a shortened and anode current for all working thyristors, negative current pulses controls for those thyristors that need to be locked at a given switching interval. FIG. Figure 2 shows how, at the switching stage starting at time t, two thyristors 2 and 6 are locked in. The duration of the pulsed negative control current i y should be sufficient for reliable combined switching off of the thyristor. The application of the proposed method improves the reliability of the inverter, reduces the power of the common switching unit, reduces the turn-off time of the working thyristors, which expands the operating frequency of the inverter. Claims The method of controlling a thyristor autonomous voltage inverter with a common switching unit is that it generates negative polarity pulses in the common switching unit and serves them simultaneously to all the inverter thyristors at each switching interval, characterized in that increase reliability, serves a negative control pulse on the working thyristor, which must be locked, and the time of application of the negative polarity of the anode voltage from the common switching unit are chosen such that after the negative anode voltage is removed, the thyristors that are not impulsed to control the negative polarity remain in the on state. Sources of information taken into account in the examination 1. Bulatov O, G., Odin S. V. Thyristors with combined switching in the mode of large anode currents. -Electrotechn. industry. Ser.Transformation 57584716 Vat.tehnika, Informelektro, 1975, vol. resistance Electricity, 1977, Jsfe 10, 7 (78), p. 3-5 s 82-84. 2. Bulatov O. G., Otsyn S. V. and other toroidal pulse-voltage inverters High-speed instrument key regulation, M., Energne, 1977, Type - combined switchable ti-s. 34, fig. 1-2, G. ; r | i sch3 3. Zabrotsin Yu. S. Autonomous types of tiris a i cg and OB four /, / 4VG U2.2