SU528673A1 - Inverter - Google Patents

Claims (3)

At the initial moment of time, let the switching capacitors 17 of the inverter cells 1–3 be charged with the polarity indicated in the drawing. When the thyristors 4 and 5 are turned on, the circuit 1 is connected to the circuit: winding 8 - thyristor 4 - capacitor 17 - thyristor 5 - capacitor 13 - load 14 the oscillating current of the recharge and switching capacitor 17 of this cell begins to flow. Through the load 14 flows the first half-wave of the oscillating current. The moment of transition of the recharge current through the maximum voltage on the secondary winding of the switching transformer of cell 1 changes the polarity and the valve 10 of this cell is turned on. As the current through the valve 10 increases, the current through the thyristors 4 and 5 decreases and they turn off. The energy stored in the switching transformer is transmitted through the valve 10 to the capacitor 15, and a voltage appears on it with the polarity indicated in the drawing. The magnitude of this voltage depends on the amount of energy stored in the switching transformer and the capacitance of the capacitor 15. The valve 10 turns off when all the energy transfers to the capacitor 15. Switching off the valve 10 on the windings 8 and 9 causes switching overvoltages, since after the fall of the direct current, the valve passes the reverse current due to the presence of voltage on the capacitor 15, and then abruptly cuts it off. The discharge of the capacitor 15 occurs during a pause when the current of the input throttle flows through it. The valve 11 does not allow the polarities of the voltage on the capacitor 15 to vary. Then the thyristors 4 and 5 of cell 2 are turned on and the described processes proceed similarly, and in the load 14 a second half-wave current is formed. Similar processes occur in the inverter when the thyristors 4 and 5 are turned on in cell 3. The switching capacitors 17 are charged with the polarity opposite to that indicated in the drawing, and as a result, conditions are created for switching on the next thyristors 6 and 7 in each of the cells. At the end of the conductivity of thyristors 6 and 7, cell 3 ends the full cycle of the inverter. In the inverter, the frequency of the output current is multiplied, since the cells operate alternately, and a full period of current is formed in the load during the conductivity of the thyristors of each cell and pause. During the pause during the operation of the inverter, the capacitor 15 is discharged to zero through the load 14, valve 12 and input choke 16. Returning the excess reactive energy from the switching transformer to the power supply limits the voltage on the inverter elements during operation to a oscillatory load varying within wide limits, And the low voltage, at which the process of reactive energy return begins, significantly reduces the overvoltage on the circuit elements, which makes it possible to increase the reliability of the inverter. Claims of the Inverter comprising thyristor bridges with switching capacitors in a diagonal, connected in parallel through the primary windings of switching transformers, the secondary windings of which are connected in series with the diodes and in parallel with each other, a choke with a non-return valve and an additional capacitor, characterized in that An additional capacitor is shunted by a diode and connected in parallel with the indicated secondary windings and diodes. Sources of information taken into account in the examination; 1.Yu. S. Zabrodin “Forced capacitor switching nodes of thyristors, M., Energie, 1974, p. 117. 2. Avt. St. No. 221039, cl. H 02M 5/42, 1966. 3. Avt. St. No. 367510, cl. H 02M 5/42, 1973. 75 rj n 12