SU1014104A1 - Stabilized dc voltage converter - Google Patents

Description

The invention relates to electrical engineering and can be used in power supplies of electronic equipment. A stabilized DC voltage converter is known, the inverter power transistors of which are regulating elements f 13. The closest to the technical essence of the invention is a DC constant voltage converter containing an inverter with an output transformer, the secondary winding of which through you drives connected to the output filter and feedback unit, control transistors, whose bases are connected to the feedback unit via a matching element, and the power outputs are They are connected to the bases of the power transistors of the inverter, a source of control pulses with direct and “reverse outputs 2. However, the known converter has large control losses and, as a result, low efficiency. The purpose of the invention is to increase efficiency by reducing control losses. This goal is achieved in that in a stabilized DC voltage converter containing an inverter with an output transformer, the secondary winding of which is connected to an output filter and feedback unit and controls the transistors , the bases of which are connected to the feedback unit through a matching element, and the power outputs are connected to the bases of the power transistors of the inverter, the source of control, pulses with direct and inverse outputs, The matching element is made of two two-gate field-effect transistors, one pair of like gates of which are connected and connected to the output of the unit of the communication link, the second gates are connected respectively to the direct and inverted outputs of the source of control pulses, the sources to the bases of the corresponding control the transistors, the drains are connected and connected to the common connection point of the power clamp and the power inputs of the control transistors. The drawing shows a circuit diagram of a stabilized constant voltage converter. It includes a master oscillator t, a source of control pulses containing an auto-oscillator 2 (for example, a multivibrator) connected to trigger 3, direct and inverse outputs connected, respectively, to the first gates of the first i and second 5 two-gate field-effect transistors, the drains of which are connected to the power supply terminal + E., and the sources - to the bases of the first 6 and second 7 control trans, resistors connected, respectively, through the terminating resistors 8 and 9 with the bases of the power trazistor 10 and 11 of the inverter, to whose collectors the primary is connected the output transformer winding 12 of the inverter, the midpoint of which is connected to the power supply terminal + Ey, and one of the secondary windings of the transformer 12 via a rectifier diodes 13 and H is connected to the input of the feedback unit 15 consisting of a measuring element assembled along a bridge circuit from series-connected Zener diode 16 and resistor 17, the common point of which is connected; to the emitter of the feedback amplifier. transistor 18 and variable resistor 15), to the middle output of which the base of transistor 18 of the feedback amplifier is connected, between the base and collector of which the accelerating capacitor 20 is installed, and the collector is additionally connected to the second gates of the first 4 and second 5 two-gate field-effect transistors and with a resistor 21 connected by a second output to the zener diode 22 and a resistor 23 connected via diodes 2k and 25 to the para-primary winding of the transformer 12. The secondary winding of the transformer 12 through the second rectifier on diodes 26, 27 podkl Chen to output filter capacitor 28, which is made for connecting the outlet of the external load. The drawing shows for example another secondary winding of a transformer 12. The number of secondary windings is not limited, they can be with or without their own rectifiers. The stabilized DC voltage converter works as follows. In the on state, the master oscillator 1 is due to the auto-oscillator.

 and trigger 3 generates strictly symmetric opposite-polarized rectangular pulses at its outputs. These pulses, arriving at the first gates of the first 4 and second or 5 two-gate field-effect transistors, alternately at equal intervals of time open and close these transistors, changing their internal resistance and, accordingly, through these transistors, which depends on the voltage value on the first shutters, and on the magnitude of the voltage on the second shutters. Since through two gate field-effect transistors k and 5 to the power supply + Ey. the bases of control transistors 6 and 7 are connected, respectively, then the current is modulated through the latter, which through resistors 8 and 9 goes to the bases of power transistors 10 and 11, operating in linear mode, and controls the internal resistance of these transistors. Due to the current through the primary winding of a transformer 12 connected to a power source + EUJ and transistors 10, 11, rectangular pulses are formed on the primary and secondary windings of transformer 12, the amplitude of which depends on the value of the internal resistance of the transistors 10 and 11 and on the value of the supply voltage + E. From the secondary winding of the transformer 12 through a rectifier on diodes 13 and I, the voltage is fed to the input of the feedback block 15. Moving the slider of the resistor 19 establishes a predetermined voltage at the outputs of the secondary winding of the transformer 12 by setting the voltage between the base and the emitter of the transistor 18, a feedback amplifier, which O1 transmits the magnitude of the voltage across the collector of this transistor and, respectively, on the second gates of the first and second 5 two-gate field-effect transistors. This voltage ultimately determines the current through the two gate field effect transistors and 5 in the open state. If during operation the voltage on the secondary winding changes, for example, by changing the supply voltage + E, this will lead to a change in voltage in the diagonal of the bridge of the measuring element, i.e. between the base and the emitter of the transistor 18, which will lead to a reverse voltage change on its collector, which, in turn, will result from a change in resistance of two-gate field-effect transistors and 5 to a change in the resistance of terminal transistors 10 and 11. As a result, the voltage on the secondary winding will remain at a given level. Connecting the power supply terminal of the feedback amplifier on transistor 18 to Zener diode 22 and through resistor 23 and diodes 2A, 25 to the output ends of the primary winding of transformer 12 allowed creating a double stabilization of the power supply of this amplifier and thereby increasing the stabilization factor of the entire converter.

Thus, the use and inclusion of two-gate field-terminating resistors in a certain way allows using, as a source of control pulses, micropower generators, easily implemented on integrated circuits, and micropower feedback units, since two-gate transistors do not consume current. input circuits. In this case, in the proposed converter, unlike the known energy, for control of the power transistors of the inverter is consumed directly from the power source without additional about conversion. All this reduced control losses, as a result of which the overall efficiency of the converter increased. ABOUT

Claims (1)

A STABILIZED DC / DC converter containing an inverter with an output transformer, the secondary winding of which is connected through rectifiers to an output filter, and a feedback unit, control transistors, the bases of which are connected through a matching element to the feedback unit, and the power outputs are connected to the bases of power transistors inverter, a source of control pulses with direct and inverse outputs, I distinguish! and with that in order to increase efficiency by reducing losses by. control, the matching element is made on two double-gate field-effect transistors, one pair of the same name gates of which are combined: and connected to the output of the feedback block, the second gates are connected respectively to the direct and inverted outputs of the source of control pulses, the sources are connected to the bases of the corresponding control transistors, and The drains are combined and connected to a common connection point between the power clamp and the power inputs of the control transistors. . . 1 10