SU1612286A1 - All-purpose d.c. voltage stabilizer - Google Patents

Abstract

The invention relates to electrical engineering, in particular to sources of secondary power supply. The goal is to increase the reliability of work. The device contains a transistor regulating element 1 with a regulating transistor 2, a protective transistor 3, a resistive current sensor 4, a safety zener diode 5 and a current limiting resistor 6, an error signal amplifier 7, a two-polar service power supply 8, a protection actuation unit 9, a resistive divider 11, 12 voltage; auxiliary resistors 13-15; a separation diode 16 and a source of voltage not shown. The latter, depending on the desired polarity of the output voltage, is connected between one of the control terminals 17, 18 and one of the terminals 22, 23 for connecting the load. In any case, the output voltage is controlled by varying the value of the reference voltage. Under the influence of destabilizing factors, the development of output voltage oscillations is carried out according to the classical compensation principle. In the event of overcurrent, the voltage drop across the current sensor 4 increases, the protection transistor 3 opens, and the control transistor 2 closes. 1 il.

Description

ND GO 00

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The invention relates to electrical engineering and is intended for use in the implementation of secondary power supply of instrumentation and testing equipment.

The aim of the invention is to increase the reliability of operation.

The drawing shows a circuit diagram of the described universal universal voltage regulator.

The device contains a transistor regulator 1. Made according to the emitter follower circuit, with a regulating transistor 2, a protective transistor 3, a resistive current sensor 4, a safety zener diode 5 and a current limiting resistor. 6, the error signal amplifier 7, the service two-pole power supply 8., the protection response indication node 9, the measuring element 1 O with a voltage divider on resistors 11 and 12, the first auxiliary resistor 13, the second auxiliary resistor 14, the third auxiliary resistor 15, a decoupling diode 16, control pins 17 and 18, and an unresolved reference voltage source. The diagram also shows the primary power source 19, pins 20 and 21 for its connection, and pins 22 and 23. for connecting the load. The power input of the transistor regulator 1 is connected to terminals 20 and 21 for connecting the primary power source 19, and the output to terminals 22 and 23 for connecting the load. The power inputs of the amplifier 7 of the error signal are connected to the corresponding poles of the service dual-pole power supply 8, and the output is connected to the control circuit of the transistor regulator 1. In the measuring element 10, the inputs of resistive dividers 11 and 12 are connected to the terminals 22 and 23 for connecting the load. Auxiliary resistors 15, 13 and 14 and separation diode 16 are connected in series between terminals 22 and 23 to connect the load. The common output of the service two-pole power source 8 is connected to the emitter circuit of the transistor regulator 1 (with the emitter of the regulating transistor 2), the control terminal 17 is connected

with the combined pins of the auxiliary resistors 15 and 13, and the control pin 13 with the combined

the leads of the auxiliary resistor 14 and the separation diode 16. The non-inverting input of the error signal amplifier 7 is connected to the output and resistive dividers 11 and I2

0 voltage and potential output

inverter input - with the combined terminals of the auxiliary resistors 13 and 14. The source of the reference voltage can be switched depending on the desired polarity of the output voltage between the control terminal 17 and the terminal 22 to connect the load (if it is minus and on pin 23 - a plus), . between the control terminal 18 and the terminal 23 for connecting the load (if it is minus, and at terminal 22 - plus). The positive output of the reference voltage source | is always connected to the output for connecting a load having a negative polarity and, if necessary, can be grounded or connected to the housing.

The stabilizer works as follows.

0 way.

In steady state or when the reference voltage source is disconnected, the output voltage of the stabilizer is formed by amplifying

5, the error signal present between the inputs of the error signal amplifier 7. The magnitude of the mismatch signal is inversely proportional to the amplification factor nil.

The resistance value of the resistor 11 is chosen to be obviously greater (by 5–10%) than the total resistance of the resistors 13 and 15, which ensures the error signal and the minimum, close to zero, value of the o voltage of the stabilizer when the reference voltage source is disconnected. The latter makes it possible to regulate the output voltage of the stabilizer with positive or negative polarity in both manual and automatic modes.

Equal resistances of resistors 12 and 14 should be significantly greater than the resistance of resistor 11, their ratio is chosen depending on the maximum output 5

Its voltage of the stabilizer and the tolerable common-mode voltage of the error amplifier 7.

With a positive polarity of the output voltage (plus - at pin 22, minus - pin 23), a change in the magnitude of the reference voltage, such as increasing it, leads to a negative potential at the output pin of the inverting input of the error signal 7 and an increase in the output current. afterwards. The control transistor 2, opened, increases the output voltage until the dissipation signal between the inputs of the amplifier 7 is made equal to zero. In this case, the diode 16 is closed by the reference voltage.

A change in the output voltage with its negative polarity (plus - at pin 23, minus - at pin 22) is performed with the similar operation of the device’s components, with the difference that in this case the diode is 6-open and current flows through it.

Under the influence of destabilizing factors, the development of fluctuations in the output voltage is carried out according to the classical compensatory principle.

As the stabilizer overload occurs, the voltage drop across the resistive current sensor 4 increases and when the opening threshold of the protection transistor 3 is reached, the control transistor 2 closes. The voltage at the output of the device decreases and the current is limited. This causes a sharp increase in the voltage at the output of the error signal amplifier 7 and the activation of the protection activation indicator 9.

The safety Zener diode 5 provides protection against the overvoltage of the emitter-base junction of the high-voltage transistor 3, as well as the protection of the signal amplifier 7 mismatch the excess of the common-mode voltage in the event of a sharp increase in the load current.

Improving the operational reliability of this device when changing the polarity of the output voltage is predetermined by the absence of complex switching nodes in the design.

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Claims (1)

Invention Formula A universal DC voltage regulator containing a transistor regulator made according to the emitter follower circuit, the power input of which is connected to the terminals for connecting the primary power source, and the output with the terminals for connecting the load, the error signal amplifier, the power inputs of which are connected to the poles of the service two-pole power source, and the output is connected to the control circuit of the transistor regulator, the measuring organ, which includes tive voltage divider connected to the input with the terminals for connecting the load, the first and second auxiliary resistors connected in series with each other, two control pins and a source of reference voltage, so that it is In order to increase the reliability of operation, a third auxiliary resistor and a separation diode were introduced into the measuring organ, and the third auxiliary resistor was connected to the first terminal to connect the load located in the emitter circuit of a transistor. regulator, a different output — with a free output of the first auxiliary resistor and a first control output; an isolation diode is connected in the conductive direction between the free output of the second auxiliary resistor connected to the second control output, and a second output for connecting the load; This power source is connected to the emitter circuit of the transistor regulator, the non-inverting input of the error amplifier is connected to the output of the resistive voltage source, and the potential output of the inverting input - with the combined terminals of the first and second auxiliary resistors, the source of the reference voltage is set to switch on depending on the desired polarity of the output voltage between the first control output and the first t16122868 a terminal for connecting the load; a second terminal for connecting the nag between the second control terminal and the hull.