SU1552319A1 - Self-excited series inverter - Google Patents

Abstract

The invention relates to converter technology and can be used as a power source for various process plants. The aim of the invention is to expand the range of stable operation and improve the spectral composition of the output current when changing the parameters of the circuit elements and the load. The device contains N cells, each of which consists of an input double-winding throttle 3 and a thyristor 4, shunted by a counter diode 5. The switching capacitor 6 is connected in series with the primary winding 7 of the output terminal 8, which acts as the switching inductive element of the cell. By incorporating the primary windings of transformer 8 into each cell, a symmetrical flow of electromagnetic processes in all cells is ensured. 1 il.

Description

The invention relates to a conversion technique and may be used. used as a power source for various technological installations.

The purpose of the invention is to expand the range of stable operation and improve the spectral composition of the output current when changing the parameters of the circuit elements and the load.

The drawing shows a diagram of an autonomous serial inverter.

An autonomous serial Indo-converter contains positive 1 and negative 2 input terminals, N converter cells, consisting of an input choke 3, thyristor 4 • And a counter diode 5, switching 20 capacitor 6, connected in series with primary winding 7 of transformer 8, to the secondary winding whose load is connected 9.

The input inductor 3 of each cell 25 is double-wound, with the first winding of each inductor connected between the positive input terminal 1 and the connection point of the thyristor 4 anode, and the second winding of the input inductor of each cell, except the last one, is connected between the negative input terminal 2 and the connection point of the winding 7 of the same cell with the cathode of the thyristor 4 of the subsequent cell, 35 and the second winding of the input inductor 3 of the last cell and the winding 7 of the last cell are connected to the cathode of the thyristor of the first cell.

When control signals 40 are applied to the circuits 4 of all cells, the commuting capacitors 6, charged at the initial time with the indicated polarity, begin to discharge, through the primary windings 7 of transformer 45 of the transformer 8, the load 9 uniformly introduced into the switching circuits of all cells through the secondary winding of the transformer 8, and the opened thyristors 4, As the capacitors gg 6 are recharged, the current through the thyristors reaches its maximum value and drops to zero. After that, the reverse diodes 5 are turned on, during which the thyristors 4 restore their controllability, and the switching capacitors 6 are recharged through the windings 7 of the transformer 8, the load 9 uniformly introduced into the switching circuits of all cells through the secondary winding of the transformer 8 and the reverse diodes 5, which provides the flow of the second half-wave current in the load of '9. After the end of the vibrational overcharge, the reverse diodes 5 are turned off and during a pause, a current flows through the switching capacitors 6 and windings 7, due to the large inductance of the output inductor 3. When the next control pulses are applied to the thyristors 4, the processes in the inverter are repeated.

Thus, the use of this technical solution makes it possible to ensure a symmetrical flow of electromagnetic processes in all cells, which makes it possible to expand the range of stable operation and improve the spectral composition of the output current when changing the parameters of the circuit elements and load.

Claims (1)

Claim An autonomous serial inverter containing N cells, each of which consists of an input two-winding inductor, the first winding of which is connected between the positive input terminal and the connection point of the thyristor anode, shunted by a counter diode, with a switching capacitor connected in series with a switching inductive element connected, except for the element the last cell, to the cathode of the thyristor of the next cell and through the second winding of the input two-winding inductor connected to the negative input m output, as well as the load circuit, are distinguished by the fact that, in order to expand the range of stable operation and improve the spectral composition of the output current when changing the parameters of the circuit elements and the load, it is equipped with an output transformer, N primary windings of which are used as inductive elements moreover, the winding of the last cell is connected to the cathode of the thyristor first, and the load circuit is connected to one secondary winding of the output transformer.