CS217575B1 - Combined feedback transistor inverter wiring - Google Patents

Abstract

In the field of transistor inverters, the invention solves the problem of limiting the overvoltage on the transistor being switched off. Its essence is the parallel connection of a first capacitor in series with a first resistor to whose common node a first diode is connected and a second capacitor in series with a second resistor to whose common node a second diode is connected between the collector of the second transistor and the base of the first transistor, while a third resistor connected in a star with the first diode and the second diode is connected to the node of the first resistor and the second resistor. The use of the invention is considered in inverters with a requirement for high efficiency in a wide load range with high utilization of the parameters of the transistors used.

Description

The invention relates to the connection of a transistor inverter with combined feedback which solves the overvoltage limitation on the switched-off transistor.

Current known inverter with current feedback solves in isolation the improvement of the output waveform by adding voltage feedback and reducing overvoltage by commutation protection, while the switched-on transistor is additionally stressed by the sum of the voltage feedback current and the current of the commutating capacitors discharged.

The above-mentioned drawbacks do not have the connection of the transistor inverter according to the invention whose essence is the parallel connection of the first capacitors in series with the first resistor to whose node the first diode is connected and the second capacitors in series with the second resistor. transistor, wherein a star resistor with a first diode and a second diode is connected to the node of the first resistor and the second resistor.

The separation of the first and second capacitors by diodes makes it possible to utilize a high capacitance low capacitance for feedback and to reduce the voltage stress of the tripped transistor, and a high capacitance electrolytic capacitor to reduce transient overvoltages. A suitable selection of the time constants for the discharge of the consoles can achieve a small current through the switched-on transistor and sufficient excitation even with lightened outputs,

The diagram shows the wiring of a transistor inverter with combined feedback, where the primary winding of the output transformer 19 is connected by the middle outlet to the terminal input to the collectors of the first transistor 15 and the second transistor 16 through the primary winding of the current transformer 18. to the output. The secondary winding of the current transformer 18 is connected via a central terminal through the fifth diode 17 to the emitters and the outer terminals with the bases of the first transistor 15 and the second transistor 16. Between the collector of the second transistor 16 and the base of the first transistor 15 to whose node the first diode 5 and the second capacitor 2 are connected in series with the second resistor 11 to whose node the second diode 6 is connected, the third resistor 10 connected to the first diode star 10 is connected to the node of the first resistor 9 and the second resistor 75 Sas second diode

6. Between the collector of the first transistor 15 and the base of the second transistor 16 is connected in parallel a third capacitor 3 in series with a fourth resistor 12 to whose node a third diode 7 is connected and a fourth capacitor 4 in series with a fifth resistor 14 to whose node is connected a fourth diode 8 wherein a star-connected sixth resistor 13 with a third diode 7 and a fourth diode 8 is connected to the node of the fourth resistor 12 and the fifth resistor 14.

At steady state during the shutdown of the second transistor 16, the first transistor 15 is energized through the first capacitor 1, the first diode 5 and the third resistor 10, the capacitance of the first capacitor 1 being small to discharge over the first resistor 9 over a half period. are limited to the large capacitance of the second capacitor 2 by opening the second diode 6 via the third resistor 10 into the base of the first transistor 15. Discharging the second capacitor 2 via the second high resistance resistor 11 is slow so that losses are small. Charging currents of the first capacitor 1 and the second capacitor 2 limited by the third resistor 10 and the secondary current of the current transformer 18 with the magnitude determined by its transmission and the output load flow into the base of the switched-on first transistor 15. The collector current of the first transistor 15 is the sum of the charging currents of the first capacitor 1 and the second capacitor 2, the discharge currents of the third capacitor 3 and the fourth capacitor 4 limited by the fourth resistor 12 and the fifth resistor 14, and the transformed output current. When switching off the first transistor 15, the function of the first transistor 15 with the second transistor 16, the first capacitor 1 with the third capacitor 3, the second capacitor 2 with the fourth capacitor 4, the first diodes 5 with the third diode 7, the second diodes 6 with the fourth diode 8, a first resistor 9 with a fourth resistor 12, a second resistor 11 with a fifth resistor 14, and a third resistor 10 with a fifth resistor 14.

The fifth diode 17 improves the closing of the transistors and the inverter oscillations. Its function is accentuated by parallel connection of capacitor, eventually parallel connection of resistors to first capacitor lacquer to third capacitor 3.

Claims (1)

Subject Combined feedback transistor inverter circuit, characterized in that a first capacitor (1) in series with a first resistor (9) is connected in parallel between the collector of the second transistor (16) and the base of the first transistor (15), to whose node a first diode ( 5) and a second capacitor OF THE INVENTION (2) in series with a second resistor (11) to which a second diode (6) is connected to a node, wherein a third resistor (10) connected to the star with the first diode (10) is connected to the node of the first resistor (9J). 5J and with a second diode (6).