SU675561A1 - Self-sustained voltage inverter - Google Patents

Description

(54) AUTONOMOUS VOLTAGE INVERTER

The invention relates to a conversion technique, namely to autonomous voltage inverters, and can be used, for example, in converters of direct voltage to alternating voltage. A standalone voltage inverter is known, containing a bridge of power thyristors shunted by reverse and das, and a device for forced co-mutation of thyristors 1. Another well-known autonomous voltage inverter is made on two competitive thyristors, locked by control electrode 2J. The closest to the technical essence of this invention is an autonomous voltage inverter, which is blended according to a bridge circuit on two-operation thyristors, shunted by reverse diodes. The two-step thyristors are locked by signals supplied to the thyristor control transitions from the shock system; they are inverter 13. However, the effect of localizing the anode current in the two-step thyristor when it is turned off along the control circuit significantly reduces the switching capacity. The purpose of the invention is to increase the power of the inverter. For this, a voltage transformer containing a bridge of dual-operation thyristors shunted by reverse diodes and a thyristor control system was introduced with an additional transformer, the initial winding of which is p6ds6edynen and a docked electrical key to an auxiliary source. voltages, and secondary ones, according to the number of thyristors, are connected in series with each of the thyristor-diode pairs, - in the drawing, the electrical circuit of the voltage inverter described is given. . It contains Dual-operation thyristors 1-4, reverse diodes 5-8, main power supply 9, load 10, additional transformer 11 with secondary 12-15 and: primary 16 windings, additional switch 17 and auxiliary power supply 18. The inverter works as follows. Let thyristors 1 and 4 conduct current. To lock thyristor 1 simultaneously, a negative impulse is applied to the control of the thyristor 1, and the impulse unlocking the additional key 17.

The ratio of the turns of the primary and each secondary windings is chosen so that on the windings 12-15 an emf is induced, the emf is directed towards the main source 9 of the power supply and is smaller in size. In connection with this, the thyristor 4 continues to conduct current, and the thyristor 1, to which a negative control pulse is applied, locks up at a reduced voltage in the anode circuit, which leads to an increase in the maximum lockable anodic current, and therefore the power of the whole thyristor circuit increases devices.

After the thyristor 1 is locked, the additional key 17 along the control circuit is transferred to the locked state. The load current after the switching stage flows along the circuit: load 10 - about “DTKa 15-thyristor 4-reverse diode 6- winding 12-load 10 ,. Depending on the given algorithm, the following switching stages can be further provided; .

1) repeated repeated unlocking and locking of the thyristor I in order to regulate the output voltage by the methods of pulse regulation

2) locking the thyristor 4 and unlocking the thyristors 2 and 3 to change

Load voltage polarities.

g P CLKJ .S C

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A short-term decrease in the anode voltage on the thyristor lock-up interval significantly (2-5 times). Increases the limiting locked current. Meanwhile, the power of the inverter is significantly increased.

Claims (3)

1.Chizhenko I.M. and other Fundamentals of converting equipment M., Higher School, 1974, p.226, fig.8 2. Chizhenko I.M. et al. Fundamentals of converting equipment, M., Higher School, 1974, p.229, ris.8.5 a. 3. Bfektor, 1976 I 10 (10-66) BiU G, BilJ 2.