SU1119137A1 - Pulse d.c.voltage converter - Google Patents

Abstract

1. PULSE CONSTANT VOLTAGE CONVERTER containing a power thyristor connected between the input terminal and a load circuit, a circuit of series-connected thrusters, a charge thyristor and a capacitor connected between the input terminals, and a switching thyristor connected between the connection point of the charge thyristor and a capacitor the point of connection of the power thyristor with a load circuit, characterized in that, in order to expand the range of regulation, the choke is made with intermediate taps connected to with similarly named power electrodes of additionally introduced thyristors, the other power electrodes of which are connected to the junction point of the charge thyristor and capacitor. 2. The converter according to claim 1, characterized in that the control electrodes of the additionally inserted thyristors are connected to the control electrode of the charge thyristor through the normally closed contacts of the additionally introduced reed switches, the control windings of which are connected in series to the load circuit.

Description

The invention relates to a converter technique and can be used to control the voltage on a load when powered from a DC source. Devices for capacitor switching of thyristors are known, which contain a switching capacitor, a charging circuit and a switching circuit 1. A disadvantage of the known device is the dependence of the control range on the current value. Closest to the present invention is a DC voltage pulse converter containing a power thyristor connected between an input terminal and a load circuit, a circuit of series-connected droplets, a charge thyristor and a capacitor connected between the input terminals, and a switching thyristor connected between charge thyristor with a capacitor and the connection point of the power thyristor with the load circuit 2. The disadvantage of this device lies in the limited range of output control voltage. The purpose of the invention is to extend the adjustment range. The goal is achieved by the fact that in a pulse voltage converter containing a power thyristor connected between an input terminal and a load circuit, a circuit of series-connected droplets, a charge thyristor and a capacitor connected between the input terminals, and a switching thyristor connected between the point the connection of the charge thyristor with the capacitor and the point of connection of the power thyristor with the load circuit, the choke is made with intermediate taps connected to the same power electrodes There are additionally introduced thyristors, the other power electrodes of which are connected to the junction point of the charge thyristor and capacitor. In addition, the control electrodes of the additionally inserted thyristors are connected to the control electrode of the charge thyristor via normally closed contacts of the additionally introduced reed switches. control windings of which are connected in series to the load circuit. The drawing shows the scheme of the proposed Converter. The device consists of charge thyristor 1, capacitor 2, drossel 3 with intermediate taps and switching thyristor 4. The additionally inserted thyristors 5 are connected to the taps of drossel 3, the control electrodes of which are connected to the control electrode of the thyristor 1 through normally closed contacts 6 of the reed switches. The windings 7 of the reed switch controls are connected in series with the load circuit. Power thyristor 8 is connected between the input terminal of the converter and the load circuit. The device works as follows. At the maximum load current, the contacts of all reed switches are open and the control signal goes only to thyristor 1, so that the entire inductor 3 is turned on in the charge circuit of the capacitor 2 and the voltage on the capacitor at the end of the charge cycle is maximum. To lock a previously open thyristor 8, a control signal is applied to the control electrode of the thyristor 4. The capacitor 2 is discharged to the load and the thyristor 8 is applied to the opposite voltage, equal to the difference of the voltages on the capacitor 2 and the power source. When the load current decreases, contact 6 of the left, according to the diagram, reed switch occurs (reed switches have different thresholds). When the next control pulse is applied to the charge thyristor, the left, according to the circuit, the additional thyristor 5 and the charge circuit of the capacitor 2 are turned on, part of the chokes 3 is turned on, which leads to a decrease in the voltage on the capacitor 2 at the end of the charge cycle. With a further decrease in the load current, other additional thyristors alternately come into operation. Thus, when the load current changes, the parameters of the charge circuit of the capacitor 2 change and, consequently, the voltage across this capacitor, which expands the range of output voltage control.

Claims (2)

1. A DC PULSE CONVERTER comprising a power thyristor connected between an input terminal and a load circuit, a circuit of series connected chokes, a charging thyristor and a capacitor connected between input terminals, and a switching thyristor connected between the connection point of the charging thyristor with the capacitor and the connection point a thyristor with a load circuit, characterized in that, in order to expand the regulation range, the inductor is made with intermediate taps connected to one mennymi power input electrodes further thyristors, other power electrodes which are connected to the connection point of the charging thyristor and condenser. 2. The converter according to π. 1, characterized in that the control electrodes of the additionally introduced thyristors are connected to the control electrode of the charging thyristor through normally closed contacts of the additionally introduced reed switches, the control windings of which are connected in series to the load circuit.