SU1410002A1 - D.c. voltage stabilizer - Google Patents

Abstract

The invention relates to electrical engineering and can be used in power supply devices for automation units, computing equipment and communication facilities. The purpose of the invention is to increase reliability. The goal is achieved by eliminating false positives of protection in the event of short-term decreases in input voltage, reduced short-circuit current and increased stability. When the input voltage drops, the capacitor 12 is discharged through the diode 9 to the load and by the time the input voltage recovers has time to discharge, the protection transistor 5 does not open. During a short circuit at the output, the switch-over process is eliminated, since the capacitor is 12 times drawn through diode 9, and through the emitter-base junction of the protection transistor 5, the short-circuit current of the control transistor 1 decreases in this case. with S (L

Description

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The invention relates to an electrical equipment and can be used in power supply units of computers, computers and communication equipment,

I The purpose of the invention is to increase the reliability of the stabilizer.

The drawing shows a schematic diagram of a constant voltage regulator.

The stabilizer consists of a sequence (a switched on regulating transistor, a feedback amplifier 2, a matching transistor 3, the base of which is connected through the load 4 of the feedback amplifier to the input terminal, as well as to the collector t) of the protection anzistor 5 and to the output of the amplifier 2 feedback, the collector with the input terminal, and the emitter through the sh resistor 6 - with the base of the regulator (transistor 1 and through the second resistor 7 - with the output of the third emitter 8 and with the base of the transistor 5) kdemma semi-pro Vodnikovogo diode 9, the output of which is connected to the output terminal.At the same time, the other output of the resistor 8 through the fourth resistor K) and the zener diode 11 is connected to the common one, and the connection point of the third S and fourth resistor 10 is connected to the B1 INPUT terminal and capacitor 1: - with a common bus, the Emitter-base transition of the regulating transistor 1 and the first resistor 6 form an overcurrent sensor,

The stabilizer works as follows (time).

I When turned on: and the stabilizer opens the control transistor 1, C (|) speak transistor 3, through a cut; | 1stores 6-8 capacitor G2 is charged. A voltage drop across the resistors 6 and 7 is applied to the emitter-base - 5 P1 to the transistor of the transistor 5 in the blocking circuit, the board 9, the transistor 5 is closed and does not interfere with the operation of the stabilizer. The feedback amplifier 2 (with a load of 4, controls the pa ™ b (|) of the matching transistor 3 and p | of the transient transistor.

During normal operation, the stabilizer (no overload) transis- t (|) p 5 is closed, since the fall of the voltage on resistor 7 is more than on the overload sensor, and not

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five

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affects the performance of the stabilizer during

When the stabilizer is overloaded, when the load current becomes greater than the nominal value, the collector current increases, and hence the base of transistor 1. This increases the voltage removed from the overcurrent sensor, transistor 5 opens slightly and begins to shunt the emitter-base transitions of transistors and 3. The latter begin to close, and the output voltage decreases. As soon as the output voltage becomes equal to or less than the stabilization voltage of Zener diode 11, the current through the resistors 7 and 8 ceases. At the same time, the voltage drop across the resistor 7 (blocking voltage for transistor 5) becomes equal to zero, effectively shunts the emitter-base transitions of transistors I and 4, so that the overload current through transistor 1 decreases.

When the input voltage decreases, i.e., as soon as the output voltage becomes less than the voltage on the capacitor 12, the latter discharges through the semiconductor diode 9 to the load and therefore has time to discharge, thereby recovering the input voltage False actuation of protection is eliminated, thereby increasing the reliability of the stabilizer.

With repeated switching on and off of the stabilizer with a short time interval, a similar process occurs.

When the transistor 5 is opened, the stabilizer is not energized. In this case, the residual short circuit current through the regulating transistor decreases and the stabilizer stabilizes.

In case of a short circuit on the load, the capacitor 12 is discharged to a short-circuited load through the semiconductor diode 9, and not through the e.g. pc-base junction of the transistor 5 (as it happens in the prototype stabilizer), therefore the reliability of the stabilizer increases.

The proposed stabilizer provides increased reliability by eliminating false protection trips with short-term drops in the input voltage and eliminating protection transistor overloads, reducing the residual short circuit current through the regulating transistor, and also increasing stability by eliminating the excitation of the stabilizer during an overload and short circuit.

Claims (1)

Claims A constant voltage regulator containing a series regulating transistor connected to the terminals of the collector and emitter between the input and output terminals, and the base through the first resistor to the output of the second resistor and to the emitter of the matching transistor whose collector is connected to the input terminal, and base  to the output of the feedback amplifier, whose inputs are connected to the output terminal and to the common bus, the protection transistor, the emitter of which is connected to the output terminal, the collector to the base of the matching transistor and the base to the combined terminals of the second and third resistors, the zener diode, the first. The cable of which is connected to the common bus and to the first capacitor terminal, which is due to the fact that, in order to maintain reliability, a diode and a fourth resistor are inserted into it, and the diode is pushed to the second terminal and to the second terminal the capacitor lead to the free terminal of the third resistor and the first lead of the fourth resistor, the second pin p; is costly connected to the second lead of the zener diode.