SU1480071A1 - Stabilized transistor voltage converter - Google Patents

Abstract

The invention relates to the field of electrical engineering and can be used as a secondary power source in electronic devices and in systems for the automatic regulation of electrical measuring equipment. The purpose of the invention is to increase the efficiency and reliability of the converter. Transistor voltage converter contains output transformer 9 with primary winding 10, windings 11 and 12, decoupling diodes 15 and 16, Zener diode 14, controlled resistive element 17. Elimination of stabilization winding allowed us to simplify the stabilization circuit and eliminate additional losses specified winding stabilization. 1il

Description

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The invention relates to electrical engineering and can be used as a secondary power source in electronic devices and in automatic control systems for electrical measuring equipment.

The aim of the invention is to increase efficiency and reliability by simplifying

The drawing shows a circuit diagram of a voltage converter.

The constant voltage source is connected to the input buses 1 and 2 of the converter. The converter contains transistors 3 and 4, connected according to a circuit with a common collector, a converter starting circuit consisting of resistors 5, 6 and 7, 8, a transformer 9, having 10, 11 and 12 primary windings and 13 output windings, a zener diode 14 that breaks diodes 15 and 16, an adjustable resistive element 17. Rectifier 18, filter 19 and load circuit 20 are connected in series to the output winding 13 of the transformer.

When connecting to the spikes 1 and 2 of the power supply of the DC voltage source, due to the appropriate connection of the windings 10-12 of the transformer 9 to the terminals of the transistors 3 and 4, the converter is self-excited. Its initial start is made by resistive starting circuits consisting of resistors 5-8, respectively.

If the voltage of the power supply exceeds the stabilization voltage of the Zener diode 14, the latter opens when the bus 1 is open to Zener diode 3 — diode 15 — resistor 6 — winding 11 of transformer 9 — transistor 3 — bus 2 runs a stabilization current. If the transistor 4 is open at the moment in question, the flow path of the stabilization current is different: bus 1 — Zener diode 14 — diode 16 — resistor 8 — winding 12 of the transformer 9 — transistor 4 — bus 2. If we take into account that the resistors are 5 and 7 is significantly more than an order of magnitude greater than the resistance of the resistors 6 and 8, the current component of the Zener diode through the resistors 5 and 7 can be excluded from consideration. Thus, resistors 6 and 8 alternately and synchronously with switching

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Torsts 3 and 4 become ballast for a parametric stabilizer at Zener diode 14. When transistor 3 is open, the voltage at its base relative to the positive power supply bus is stabilized by the mentioned parametric stabilizer and is equal to the sum of the voltage stabilized by Zener diode 14 and the voltage drop across the diode 15. So as transistors 3 and 4 in the circuit operate in the mode of emitter followers, the voltage on the emitter of transistor 3 will be stabilized and equal to the voltage on the base, reduced by a drop in voltage ernom transition, ie, almost equal to the stabilization voltage of the Zener diode 14. All of the above applies to the transistor 4 when it is open, with the only difference that it is necessary to take into account the voltage drop across the diode 16.

If the resistance of the controlled resistive element 17 is zero, then each half-life of the converter to the corresponding half of the winding 10 of the transformer 9 is applied a stabilized voltage, the amplitude of which is equal to the stabilization voltage of the Zener diode 14. The EMF arising in the secondary winding 13 of the transformer 9 will also be stabilized. If the resistance of the resistive element 17 is different from zero, then the voltage on each half of the winding 10 is reduced by the amount of voltage drop across the resistive el 17, which causes a proportional decrease in voltage in the output winding 13.

Since the resistive element 17 is not included in the current flow circuit of the Zener diode 14, changes in the resistance of the resistive element 17 over a wide range do not affect the stability of the output voltage.

Thus, the proposed converter stabilizes and adjusts the output voltage.

The stabilization effect is achieved without the use of additional windings of the transformer, which increases the reliability and efficiency of the converter as a whole, and also affects the reduction of the complexity of its manufacture, weight and size.

Claims (1)

Invention Formula A stabilized transistor voltage converter containing an output transformer with a primary winding, made according to a circuit with a middle point, feedback windings, and decoupling diodes connected by the like terminals directly to the bases of transistors, a zener diode, one of the terminals of which is connected to the bus power controlled A resistive element, one of the terminals of which is connected to the zener diode and the said power bus, is characterized in that, in order to increase efficiency and reliability by simplifying the converter, the second diode terminals are directly connected to the second zener diode terminal, and the second output of the adjustable resistive element is connected to the midpoint of the primary winding of the transformer.