SU726640A1 - Self-sustained inverter - Google Patents

Description

(54) AUTONOMOUS INVERTER,

I

The device relates to power converter technology, in particular to static frequency converters.

A number of autonomous inverter circuits are known, comprising controlled thyristor gates, a switching capacitor, a choke, and an output transformer 1 and 2.

In these circuits, an inductance of significant magnitude is provided at the input, whereby the input current and the current through the valves acquire a rectangular shape. When switching thyristors, the capacitor is recharged through the power supply and the choke. The time allowed for the thyristor, the previously conductive current, to restore the locking properties is determined by the discharge time of the capacitor to zero. Further, the capacitor continues to recharge, the voltage across the capacitor changes sign as well as the inductance. Moreover, this switching of the switching capacitor is performed at the same speed, since the time constant of the circuit remains unchanged. This limits the range of the output frequency of the inverter.

The purpose of the invention is to expand the frequency range.

This is achieved by the fact that in an autonomous inverter containing power thyristors connected to the primary windings of an output transformer having a midpoint connected through a choke with a tap to one of the power supply terminals, a switching capacitor connected in parallel to the primary winding of the transformer is connected to a common Two additional thyristors are connected to the points of connection of the switching capacitor with the main thyristors in the conducting direction, the opposite power terminals of which are connected to soldering input throttle.

The drawing is a schematic diagram of an autonomous inverter.

It contains a choke 1 with an average output connected to the inverter power supply circuit, a switching capacitor 2 connected between the anodes of the power thyristors. 3 and 4, auxiliary thyristors 5 and 6, connected by anodes to the average output of the choke switches 1, and cathodes to the opposite-facing plates of the switching capacitor 2. The load is connected through the output transformer 7.

Autonomous inverter works as follows.

We assume that the thyristor 3 is open and the capacitor 2 is charged with the polarity indicated in the drawing. In this case, a positive half-wave current flows in the load. In order to switch the current from thyristor 3 to thyristor 4, a trigger pulse is applied to thyristor 4. Capacitor 2 turns off thyristor 3 during the switching time, and then recharging continues through the power supply and choke 1. At the same time, a voltage is applied to choke 1 such a polarity, in which the thyristor 3 restores its locking properties. At the moment when the voltage on the capacitor 2 becomes zero, an unlocking pulse is applied to the additional thyristor 6, which turns on and changes the charge circuit of the capacitor, i.e., the charging current starts to flow from the plus of the power supply to the throttle section 1, left capacitor plate, thyristor 4, "minus power supply. In this way, an accelerated charge of the switching capacitor is ensured and the time after the switching cycle is reduced accordingly.

Similarly, the circuit works when switching current from thyristor 4 to thyristor 3. In this case, auxiliary thyristor 5 is unlocked.

Additional thyristors 5 and 6 must be switched on by control pulses that are delayed by an angle greater than or equal to

- | -, regarding the control pulses of the main thyristors. At the moment of switching on the additional thyristor, the constant of the charge circuit of the switching capacitor decreases abruptly and the total time of the switching cycle decreases, which makes it possible to increase the switching frequency of the thyristors.

Claims (2)

1.Ryvkin G. A. Conversion devices, M., Energii; 1970, p. 201 2. USSR author's certificate number 359875, cl. H 02 M 5/42, 20.11.67.  0-. + -n Vj v sr