SU568046A1 - Dc voltage stabilizer - Google Patents

Description

(54) STANDING VOLTAGE VOLTAGE

And the base through a resistor, podalyuhhhy to the collector of the specified transistor of the dates of the switch is disconnected.

The drawing shows the conventional scheme of the stabilizer of the constant tension.

The stabilizer contains a differential amplifier 1, both inputs of which are connected to the terminals for connecting the load, one through a divider on resistors 2, 3 and the other through on resistors 4, 5 with a zener diode 6, and the output is connected to the base of the transistor 7 for storing the shutdown, moreover, The stabilizer contains a datac to the current 8 with an amplifier 9, made in the form of two successively inserted transistors 10, 11, mjoiTHpoBaiH ix resistors, each with its own basic divider on the resistors 12, 13 and 14, 15. Regulating element 16 of the stabilizer, through a threshold th element of c is connected to output 17 of the differential amplifier 1, a trigger capacitor 18.

The constant voltage stabilizer operates as follows.

During normal operation of the voltage regulator on the input of the differential amplifier, there is a low voltage level and an open cocTojiHHe transistor 7 for storing the disconnection, because the output connected to the terminals for connecting the load "divider through resistors 2,3" is higher than the input connected with the terminals for connecting the load / through a resistive divider 4, 5 and stabilized paths 6; On the other hand, the transistors 10, P amplifier 9 d 1Tank 8 are also open, because the reference voltages are determined respectively by the dividers 12 , 13 and 14, 15 BMnie than the voltage drop on the current sensor 8, determined by the load current of the stabilizer. There is no signal from the output of the threshold element 17 connected to the other referendal amplifier 1 causing the control element 16 to trip.

With a current overload of the stabilizer, the voltage drop on the current sensor 8 increases, and the voltage on the emitter of the transistor 10 of the amplifier 9 turns out to be more onopiraro. The transistor 10 of the amplifier 9 is blocked up and pressed upward on the emitter of the transistor 11 of the amplifier 9, which becomes greater than the reference voltage of the transistor, as a result of which the amplifier 9 is locked.

The latter implies an increase in the level of voltage at the output of the differential amplifier 1 and the locking of the transistor 7 to prevent oscillation, which, in turn, facilitates the locking of the amplifier 9 and ensures the memory overload after its removal. From the output of the threshold element Metrra 17, a signal is triggered which triggers the regulating element 16, which disconnects the load.

Thus, the presence of basic reference dividers in the amplifier 9 and the sequence; the connection of the transistors in it allows it. 1) to reduce the voltage drop on the current sensor and, accordingly, to reduce the power loss.

When the voltage at the output of the regulating element is necessary, the voltage level at the output of the differential amplifier 1 rises. A transistor 7 for storing a trip is plugged in, locking the amplifier 9, which will even more control the level of the output voltage of the differential amplifier 1, i.e. positive feedback takes place. As soon as the con- tactmipyeMoe voltage goes below the permissible value, the output from the threshold element 17 is supplied with a signal that triggers the operation of the regulating element 16, which disconnects the load. Transistor 7 provides a trip memory after the removal of the emergency mode.

When the voltage at the output of the regulating element rises, the voltage over the input of the differential amplifier 1 connected to the divider 4, 5 becomes higher than the input voltage, connected to the divider 2, since the transfer ratio of the divider 4.5 is greater than transmission divider 2,3. Zener diode 6 provides the difference in transmission coefficients. The voltage level at the output of the differential amplifier 1 is increased. The transistor 7 is switched on to memorize a trip, and the lockout circuit 9, which further increases the level of the output voltage of the differential amplifier 1. As soon as the monitored voltage rises above the allowable value, the output of the threshold element 17 triggers a control ejection 16 that shuts off the load. The transistor 7 provides a trip failure after the removal of the overvoltage.

The stabilizer is turned on through a pinned capacitor 18 connected between the collector of transistor 7 and the common power wire, the charging current of which provides the open state of the transistors 10.11 of amplifier 9 for the duration of the turn on. Restoration of the normal mode of operation of the stabilizer is produced by the power supply.

When replacing the type of conductivity of the control transistor, the type of conductivity of the stabilizer transistors is replaced. When the current sensor is turned on to the negative bus, the conductivity type of the stabilizer transistors is replaced.

The positive effect is to increase efficiency, improve weight and size characteristics by reducing the voltage drop across the current sensor, the simplicity of the circuit solution providing simultaneous control of three parameters, as well as the possibility of unifying the device for secondary power sources, since it can be used as for linear stabilizers, as well as for key and other