SU907522A2 - Stabilized power supply source - Google Patents

Description

(54) STABILIZED POWER SUPPLY

I

The invention relates to electrical engineering, and more specifically to compensation-type power sources, and can be used as a controlled bridge inverter in a stabilized power source.

Claims (2)

According to the main author. St. No. 754386 is a stabilized power supply comprising a master oscillator, rectifier and bridge power amplifier with an output transformer made on the first, second, third and fourth transistors of the same type, powered by an unstabilized voltage source. terminal, and the emitters of the second and fourth transistors - to the second terminal of the source of a constant unstabilized voltage, parallel to the collector emitter circuit of each transistor The diode in reverse polarity is turned on, the emitter of the third and the collector of the fourth transistor are connected to the first output of the primary winding of the output transformer, the secondary winding of which is connected to the rectifier inputs, while the stabilized power source is equipped with the first and second control circuits, capacitors and a choke, and the master oscillator is made on the specified third and fourth transistors and the second control circuit, and the collectors, bases and emitters of the third and fourth transistors are connected to the inputs A second control circuit, the output of which is connected to one input of the first control circuit, two other inputs of which are connected to the outputs, and the outputs of the first control circuit are connected to collectors, bases and emitters of the first and second transistors, the emitter of the first and the collector of the second transistor are connected through a series-connected choke and capacitor with a second output of the primary winding of the output transformer in parallel with which a capacitor is connected. In this device, four transistors form a bridge amplifier, the third and fourth transistors being simultaneously elements of a master oscillator operating in self-oscillation mode, and the first and second transistors operate as controlled switching elements, the opening time of which depends on the latitude modulated signals arriving at their inputs from the first control circuit. Thus, the time during which the third and fourth transistors are alternately opened and closed is constant and is half the operating period of the master oscillator, and the time of alternately opening and closing the first and second transistors is determined by the width of the enable pulses from the first control circuit. . The first and fourth transistors, as well as the second and third transistors form the first and second shoulders of the bridge, respectively, and the transistors of one arm open simultaneously, but since the first and fourth and second and third transistors are connected in series with the inductive load, the time , during which current flows through the load, depends on the duration of the pulses that send the first and second transistors, i.e. The duration of the control signals (i.e. the opening time of the first and second transistors) is always less than the opening time of the third and fourth transistors that make up the master oscillator and operate at a constant frequency. A diode is connected to protect the transistors against overvoltages parallel to the collector and emitter of each transistor. When one of the controlled transistors, for example, the first, is closed, the current through the inductive load is cut off, and a self-induced EMF appears at the load terminals. Since the fourth transistor, which operates in the same shoulder with the first transistor, is in the open state, then its collector — the emitter and the diode connected to the second transistor — discharges this EMF itself. When this is lost, the energy accumulated in the I1-schu1 {th load, and, in addition, the fourth transistor of the sending oscillator is additionally heated (this is especially significant when the discharge current of the self-induced EMF does not stop by the end of the master oscillator period). Similarly, when the second transistor is closed, the load current is cut off, and the self-voltage EMF in the load is applied minus to the emitter of the third transistor, and a plus through a diode connected to the first transistor to the collector of the third transistor. Since this transistor is open, through it the discharge of energy accumulated in the load occurs. Thus, the disadvantage of the device lies in the fact that the energy stored in the load inductance is not used, and the discharge current of this energy further heats the transistors of the master oscillator, which generally reduces the efficiency of the device. The purpose of the invention is to increase efficiency. The indicated goal is achieved; By the fact that two diodes and a con / depressor are inserted in the device, the emitters of the second and fourth, and the collectors of the third and first transistors are connected to each other through the anode-cathode of these diodes, and a capacitor is connected between the collector of the first and the emitter of the second transistors. The drawing shows a diagram of the proposed device. The device contains transistors 1 4, source 5 unstabilized voltage, inductive load 6, choke 7, capacitor 8, transformer winding 9, second control circuit 10, first control circuit 11, diodes 12, additional diodes 13 and 14 and capacitor 15. Bridge inverter contains the first 1, second 2, third 3 and fourth 4 transistors, with the collector of the third transistor 3 connected to one input, the other connecting terminal emitter of the fourth transistor 4, and the emitter of the first 1 and the collector of the second 2 transistors connected The first output terminal of inductive load 6 is in the form of serially connected chokes 7, capacitor 8 and transformer winding 9, and the second output load 6 is connected to the emitter of the third 3 and collector of the fourth 4 transistors, the master oscillator is made on the third 3 and fourth 4 transistors and the second circuit 10 control, inputs 5 of which are connected to the leads of transistors 3 and 4, and the output is connected to the input of the first control circuit 11, whose outputs are connected to the leads of transistors 1 and 2, and connect the collector and emitter of transistors 1-4 to diodes 12, and the emitter of transistor 2 is connected to the anode of the first additional diode 13, the cathode of which is connected to the emitter of the fourth transistor 4, and the collector of the third transistor 3 is connected to the anode of the second additional diode 14, whose cathode is connected to the collector of the first transistor 1, and between the collector the first 1 and the emitter of the second 2 transistors connected capacitor 15 The device works as follows. A pair of 1 and 4 and another pair of 2 and 3 transistors form, respectively, the two diagonals of the bridge circuit, and the transistors 3 and 4 are also elements of the master oscillator operating in auto-oscillatory mode. The transistors 1 and 2 are controllable switching elements, the opening time of which is determined by the control signals from the first control circuit 11. When a voltage appears at the output of the source 5 of unstabilized voltage, the master oscillator formed by transistors 3 and 4 and the control circuit 1O starts up, and transistors 3 and 4 start to open and close in antiphase with a constant frequency. From the output of the control circuit 1O, the scattering pulses are fed to the input of the first control circuit 11, which generates control signals for alternately opening and closing transistors 1 and 2. Since transistors 1 and 4, as well as transistors 2 and 3 are connected in series with the load 6, the flow time of the alternating current through the load 6 depends on the duration of the pulses that enable transistors 1 and 2. To reduce the dynamic sweat when the transistors are turned on, the load 6 is implemented in the form of series-connected smoothing throttle 7, separation capacitor 8 and the primary winding 9 of the output transformer. When this load 6 in the range of operating frequencies is inductive in nature. When one of the controlled transistors, for example, transistor 1, 226, is turned off, the current through the load 6 is abruptly interrupted at the terminals of the pagra; 6, a self-induced EMF appears, plus which is applied to the collector of transistor 4, and the minus through an open diode 12 connected in parallel to transistor 2 is connected to the anode of the first additional diode 13. Although transistor 4 is open (as an element of the master oscillator), the discharge current of the EMF self-induction does not flow through it, since diode 13 turns on in the opposite direction. The energy stored in the inductance of the load 6 is supplied to the charge of the capacitor 15 through the diode 12 connected in parallel to the transistor 3 and the diode 14. Similarly, when the second transistor 2 closes, the EMF of self-induction of the load 6 becomes the applied minus to the emitter of the open transistor 3, and the plus through the diode 12 connected to the transistor 1 is connected to the cathode of the second additional diode 14, which in this case is connected in the opposite direction, therefore the EMF discharge through the transistor 3 does not occur. The voltage of the self-induced emf is via a diode 12 connected to transistor 1 to one output of a capacitor 15, and to another output through a diode 12 connected to transistor 4, and a diode 13 receives a minus of this voltage. In both cases, the energy accumulated in the load 6 is supplied to the charge of the capacitor 15 and is used as an additional voltage source upon the subsequent opening of the diagonal of the bridge, which ensures the achievement of the goal. In comparison with the known device, in the proposed source, energy stored in the inductive load 6 is recovered, which increases the efficiency of the device. In addition, the device eliminates the additional heating of the transistors of the master oscillator due to the discharge of energy through their open transitions. This allows to increase the reliability of the circuit and reduce the overall dimensions of the radiators of power transistors. Claims of the invention Stabilized power source according to aut. St. No. 754386, characterized in that, in order to increase the FP, two diodes and a capacitor are introduced into it, the emitters of the second and the fourth and collectors of the third and first transistors are connected to each 79075228 a friend through the anode katol of the mentioned sources of information, diodes, and the collector first-received into account during the examination and amitter of the second transistors under-1. Copyright svedetepistvo USSR the capacitor is turned on. No. 754386, cl. O05F 1/56, 1978.