SU667962A1 - Dc voltage stabilizer - Google Patents

Description

I

The invention relates to self-adjusting devices, in particular voltage regulators, and can be used in a power supply system of electronic equipment and measuring equipment.

A voltage regulator with a current overload and overvoltage protection circuit 6T is known, which contains a voltage amplifier, a current sensor, a current sigma amplifier {ala, a driving oscillator, an output amplifier providing protection against overvoltages and current overload ij.

However, the known circuit is characterized by complexity and low immunity due to high speed, which leads to false alarms of the protection circuit and shutdown of the stabilizer.

The closest technical solutions. In this invention, a constant voltage stabilizer comprising a series connected

To the power bus there is a regulating transistor, the base of which is connected to the input of the amplifying element and to the output of the amplifier; a current sensor connected to one of the power buses; a current signal amplifier; an output connected to the input of the feedback amplifier with a delay element; - the house is connected to the output of the feedback amplifier, and an overvoltage signal amplifier 2,

Known stabilizer 1meet insufficient noise immunity of protection while maintaining its speed.

The purpose of the invention is to increase the noise immunity of protection while maintaining speed while simplifying it.

For this purpose, in the proposed constant voltage regulator, the overvoltage signal amplifier is designed as a series-connected resistive divider and a zener diode connected between the input and output pins, and a transistor, the bases of which are

It is connected to the midpoint of the resistor divide, and the collector is connected to the input of such a signal amplifier.

In the drawing, the circuit diagram of the proposed DC voltage regulator is presented in principle.

The stabilizer contains a successively connected regulating transistor 1, a base connected to the input of the amplifying element 2 and to the output of an upper amplifier 3, a current sensor 4, the current signal amplifier 5 whose output is connected to the input of the feedback amplifier 6 with the element trailing on the capacitor 7 , an overvoltage signal amplifier 8, made by connecting a resistive splitter {resistors 9, 10), a zener diode 11 and a transistor 12.

The principle of operation of the stabilizer is as follows. When the stabilizer is switched on by the charging current of the capacitor 7, the transistor of the current signal amplifier 5 is open, its collector current is opened and the transistor of the feedback amplifier 6, which maintains the open state of the transistor of the amplifier 5. Overvoltage factors 8 and the overvoltage amplifier 8 and the output body 6 are closed .

When overcurrent drop iJanr zheyi 4 on the sensor current increases, transistor amplifier 5 pbdzapira e1 and tra nzistor output amplifier 3 of- piraetsy, vozdeystu on vhoy reguLyruyuschego oVrazom transistor 1 so that velichiva not prevshaet overcurrent set value, the controller | The value of the resistance in the base of the transistor of the amplifier 5. The transistor of the feedback amplifier 6 is amplified by increasing the locking of the transistor of the amplifier 5. One; ak6 o does not act immediately, but with a certain delay determined by the value of the capacitor 7 that shunts its Transition. Upon charge of the capacitor feedback, the transistors of the amplifiers 5 and 6 are closed, and the transistor of the amplifier 3 is saturated and shunts the input of the regulating transistor 1. The stabilizer is turned off. The protection circuit remembers the overload. To re-enable the stabilizer, it is necessary to turn off and switch on the stabilizer.

Thus, during the overload delay, the stabilizer turns on to the stabilization mode (

current, and during this time the overload is not eliminated, the stabilizer is turned off, and the protection circuit remembers the overload. .

During overvoltage at the output of the stabilizer, current through Zener diode 11 begins to flow, creating a voltage across the resistive divider. By this voltage, the transistor 12 of the amplifier 8 for the voltage is starting to open, reducing the voltage on the input of the amplifier 5. The transistor of the amplifier 5 starts to lock and the device works further, in the case of an overcurrent, the only thing that caused the amplifier 5 to lock is not an increase in the voltage on the current sensor 4, but an unlocking of the transistor 12 of the amplifier 8, while the output amplifier 3 acts on the regulating transistor 1 in such a way that the output voltage he exceeds the allowable level. Moreover, the control transistor 1 is affected without delay, since there are no special delay elements in the circuit of amplifiers 8, 5, 3, and the stabilizer is turned off with a delay determined by the value of the capacitor 7 in amplifier 6.

Consequently, a large over-voltage at the output of the stabilizer is processed without a delay, if it is long (longer than the set delay time), the stabilizer turns off. This achieves a high resistance with a speed determined only by the frequency properties of the elements.

Claims (1)

1. The patent of Germany And 2136030, iui.G 05 Pi / 58. 1972. J..ynfermtiongf lournaf of fe troftics №: 6, 33. c. 597-599. 1972.