SU1709483A1 - Transistor inverter - Google Patents

Abstract

The invention relates to electrical engineering, namely to converter equipment, and can be used in the design of transistor inverters. Whole ^ of the statement - higher reliability by; limiting the current during transient processes. The transistor inverter contains a push-pull power amplifier 1 with transistors 8 and 9 with an output transformer 2g, capacitors 4, 13 and 15, a reverse diode 5, protective diodes 10 and 11. Resistor 12 and capacitor 13 allow to generate a smoothly increasing supply voltage on master oscillator 14 which is provided by transistors 8 and 9 floating control pulses. Transistor ^ 8 and 9 ^ smoothly transitions from re-. press cut to linear mode and < at the end of the transient process to saturation mode. Changing the constant charging times of capacitors 13 and ISi, you can select the time to reach load mode 18 and the operating mode of transistors 8 and 9.2 or 1 "t

Description

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О О 4 00 СА The invention relates to electrical engineering, namely to converter equipment, and can be used in the design of transistor inverters operating at turn-on transients that are much higher than the nominal value (motor starting, charging capacitive filters). The purpose of the invention is to increase reliability by limiting the current during transient processes in the circuit, Figure 1 shows the circuit of the proposed inverter; Fig. 2 shows an oscillogram of an Oeg voltage on a master oscillator. The inverter contains a push-pull transistor power amplifier 1 with an output transformer 2, the middle terminal of the primary winding 3 of which is connected to the first terminals of the capacitor 4 and the reverse diode 5 and forms the first input terminal 6. The second power terminals of the transistors 8 and 9, the first, are connected to the second input terminal 7 the power terminals of which are connected to the extreme terminals of the primary winding 3 of the output transformer 2 and the first terminals of the protective diodes 10 and 11. The second terminals of the diodes 10 and 11 are connected to the second terminal of the capacitor 4 and through a cut Sided terminal 12c of capacitor 13 and the first supply terminal of the master generatttra 14 (MH). the second supply of which is connected to the second output of the reverse diode 5 and through the capacitor 15 with the second input terminal 7 and the output of the capacitor 13. Output CG. 14 is connected to the control terminals of power amplifier 1. The output winding 16 of the transformer 2 is connected to the rectifier 17, to which the load 18 is connected (electric motor or capacitor). On f, 2 are marked; Ui3- plus voltage VG-oscillogram of voltage on capacitor 13; Ui5-minus voltage on ZG - oscillogram of voltage on capacitor 15. The inverter starts to work when the power is connected to the input terminals 6 and 7 (Fig. 1). The constant charge time of the capacitor 13 must be 10 or more times longer than the time constant of increasing the supply voltage. By. the circuit 6 - 3 10 (11) - 12 charges the capacitor 13 and, through ZG 14, the capacitor 15. The charging time of the capacitor 13 is chosen less than that of the capacitor 15, which makes it possible to ensure a smoothly increasing voltage at the supply ports of the ZG 14. The closer the time of the capacitors 13 and 15, the slower the voltage increases to SG 14, The smooth increase in voltage on the SG 14 allows the amplitude of the variable control voltage and current of the power amplifier 1 to increase smoothly. Transistors 8 and 9 are initially switched in a linear mode and as the amplitude of the control alternating voltage increases from the output of SG 14 goes into saturation mode. The transition to the established mode ends when the capacitor 4 is charged to Upit capacitor, 13- to about 2pits (less by the amount of voltage drop on resistor 12 of ZG 14 consumption), and the capacitor 15 - to Upit plus direct voltage drop on diode 5, which captures the voltage across the capacitor 15 (Fig. 2, Uis). At the moment of switching off transistors 8 and 9, a voltage surge occurs on their collectors, which is limited by diode 10 (11) to the direct voltage, integrated by capacitor 4, and is spent on power supply of SG 14 and power amplifier 1 control, which results in increased efficiency. A smooth output to the mode ensures a smooth increase in the output voltage of the inverter and virtually eliminates the occurrence of current surges when charging the load filter 18 capacitors or starting DC motors. When a short circuit in the load decreases the voltage on the windings 16 and 3 (due to the voltage drop on the active resistance of the winding) and the capacitor 4, the voltage on SG 14 and the control voltage of the transistors 8 and 9 decrease. mode, which further reduces the voltage on the capacitor 4. The process develops as an avalanche and the inverter shuts down. In order to turn on the inverter, it is necessary to remove the power and allow all the capacitors to be discharged. The reclosing ensures a smooth output to the mode without current surges in charge of the filter capacitors (starting the DC motor, especially after successive excitation). By reducing the voltage on the 3G, its operating frequency decreases. If at a specific combination of parameters (frequency, output voltage of the SG, gain factor of transistors, induction of the transformer core) the transition of the core is possible, or have the CTa6M, ni, iJficTii frequency requirements, it is necessary to use / T with external synchronization.

Claims (1)

Claims of the invention A transistor inverter containing a push-pull power amplifier, the middle terminal of the primary winding of the output transformer of which is connected to the first input terminal, the terminals of the first capacitor and the reverse diode, the extreme terminals of the primary winding are connected to the first terminals of protective diodes, the second terminals of which are connected with the second output of the first capacitor, while the second output diode diode is connected to the second supply output of the master oscillator, the output is connected to the control inputs of the transistors of the power amplifier, the second power terminals of the transistors are connected to the second input terminal, which is characterized by the fact that, in order to increase reliability by limiting the current during transients in the circuit, a third capacitor is inserted which is connected to the second input terminal, and the second output - to the first output of the resistor and the first supply output, the master oscillator, the second output of the resistor is connected to the second terminals of the first capacitor and protections th diodes, the second) terminal of the second capacitor is connected to the second feed:) conductive terminal oscillator. % %  t FIG. 2