SU909669A1 - Dc voltage stabilizer - Google Patents

Description

(54) CONSTANT VOLTAGE STABLES

one

The invention relates to electrical engineering and can be used in power supply devices for automation units, computing and measuring equipment and communication facilities.

A voltage regulator is known, which contains a regulating element on a compound transistor and a protection unit l.

However, the use of a known block, protection reduces reliability due to its complexity and the presence of contiguous devices.

The closest in technical essence to the present invention is a DC voltage regulator containing a series regulating element connected to an output bus on transistors of different conductivity types, a control circuit connected to the output of a DC amplifier, an input of the comparator unit connected to the output , the inputs of which are connected to the outputs of the output voltage divider and the source of the reference voltage, the inputs connected to the corresponding output pins, and the unit for protection with starting chain 2.

The protection unit of this stabilizer contains two transistors, which complicates the circuit of the power supply unit, as well as the transistor connected by the emitter to the output of the stabilizer, and base 10 to the emitter of the matching transistor when the protection unit responds under the maximum input voltage and volts, the acceptable base-emitting voltage of the junction should also be ten volts, but such transistors have a low speed and, therefore, the speed of the protection unit will not be

20 high, and the use of high-frequency transistors with known methods of protection of the specified transition will further complicate the circuit.

The purpose of the invention is to increase the speed of protection.

The goal is achieved by the fact that, in a DC voltage regulator, the protection unit is made on a transistor of the same conductivity as the matching transistor, the base of which is connected through a resistor to the output terminal and through the starting chain to the input terminal, the collector to the emitter of the matching transistor, and the emitter is connected to the common bus of the stabilizer through a capacitor, in parallel with which the connected current protection indicator and the protection current sensor are connected, and the base of the emitter is connected to the base TpaH3ifCTOpa Diode is on.

The protection current sensor is made in the form of a stable current source, for example, a transistor with a reference resistor in the emitter circuit and a reference voltage source in the base circuit, the transistor having a collector connected to the protection current indicator, the base to the reference source output for yarn, and the emitter is through a standard resistor to the common bus of the stabilizer. In addition, the reference resistor current sensor and the reference voltage source are connected to the common stabilizer bus through an additional voltage source. Also between the total stabilizer width and the base of the transistor of the protection block an additional capacitor is connected. FIG. Figures 1, 2, and 3 show basic voltage stabilizer circuit diagrams. FIG. 1 stabilizer contains a regulating element 1 on the power transistor 2, an emitter connected to the input, and a collector to the output of the stabilizer and a matching transistor 3, a collector connected to the base of the power transistor 2, and a base to the output of the DC amplifier 4, connected to the output of the matching unit 5, the inputs of which are connected to the outputs of the divider 6 of the output voltage and the source 7 of the reference voltage, the inputs connected to the corresponding output pins, and the protection unit 8, are made on the transistor 9, the base of which It is connected through a resistor 10 to the output of the stabilizer and through the starting i chain on resistor 11 and button 12 to the input of the stabilizer, the collector is connected to the emitter of the matching transistor 3, and the emitter is connected to the common bus of the stabilizer through a parallel capacitor 13 14 current protection and sensor

15 of the protection current across the resistor 16. In parallel with the emitter-transistor, the base of the transistor 9 is connected to a diode 17 and the base is additionally connected to the common bus of the stabilizer via a capacitor 18.

FIG. 2, the protection current sensor 15 is made on a transistor 19, the collector of which is connected to the protection current indicator 14, the base is connected to the source of the reference voltage, and the emitter is through the reference resistor 20 with a common bus, a stabilizer.

Claims (6)

FIG. 3, the reference resistor 20 and the source 7 of the reference voltage are connected to the common bus of the stabilizer via an additional voltage source 21. The stabilizer works as follows. When the stabilizer turns on after applying voltage to its input, the contacts of the button 12 are closed and the voltage from the stabilizer input goes through the resistor 11 to the base of transistor 9, as a result, the capacitor charge current 13, limited by resistor 11, flows through the emitter junction, this contributes to rapid saturation the transistor 9 and the opening of the matching transistor 3, as well as its collector current is the base current of the power transistor 2, the transistor and the latter, i.e. the control element 1 opens. Thereafter, a voltage appears at the output of the stabilizer, which increases until the comparison circuit 5 and the DC amplifier 4, which reduces the control voltage at the base of the matching transistor 3, t. e. the negative feedback circuit is triggered and the output voltage rise stops. When the increasing voltage at the output becomes greater than that at the base of transistor 9, a current flows to the base of transistor 9 through a resistor 10 from the output of the stabilizer, which accelerates the charge of the capacitor 13. and keeps the transistor 9 in the saturation state. Thus, the stabilizer is turned on by the further normal operation of the transistor. 9 is in the saturation state and does not affect the quality characteristics of the stabilizer. When trans-shipment or k.z. load current of the emitter of the matching transistor 3 increases, t, e. the collector current of transistor 9 increases, this leads to an increase in the voltage drop across the resistances of the indicator 14 and the protection current sensor 15, as a result, the voltage between the emitter of the transistor 9 and the stabilizer output, i.e. base current decreases. A further increase in the emitter current of the matching transistor 3 leads to a decrease in the base current to zero, but the transistor 9 remains in saturation mode, so that the excess charge accumulated in the base region cannot change instantly. The emitter current of the matching transistor 3 increases until the voltage at the emitter of transistor 9 becomes greater than at the output of the stabilizer after this, p 1 starts to discharge capacitor 13 through the base-emitter junction of transistor 9 and resistor io on the load and the discharge current decreases, the charge accumulated in the base of the transistor 9, i.e. the discharge of capacitor 13 accelerates the dissipation of excess charge in the base and locks the transistor 9. Closing transistor 9 leads to a sharp increase in the resistance in the emitter circuit of the matching transistor 3 and, therefore, to a sharp decrease in its collector current almost to zero, therefore, the current the base of the power transistor 2 and the load current also fall to zero, i.e. the control element 1. is closed. The emitter current of the transistor 9 when the stabilizer operates is ET9 KT9 5t9 where, respectively, the current of the emitter, collector and base of the transistor 9 and then the voltage across the emitter of transistor 9 is d53 T9et9 9 where the voltage across the emitter of transistor 9 is 9, i.e. General resistance of the indicator 14 and the sensor 15 current protection. The base of the transistor 9 through the resistor 10 is connected to the output of the stabilizer and then, assuming that the voltage across the transistor 9 is zero, we get where euix is the output voltage of the stabilizer, "the resistance of the resistor 10 and then 9TeVB 6bW iO Zbtd, and since 9 starts when the ° C closure is KgtgHitTe eWV The collector current of the transistor 9 is the base current of the power transistor 2 (), so the load current will be equal to Zn 0 5t1 Chog. where 3c is the load current, ufO is the static gain of the base current of the power transistor 2. Therefore, when the resistance RjYg changes, i.e. resistance of the protection current sensor 15, the magnitude of the load current at which the protection unit 8 is triggered and the protection current S3 can be determined from equality,. By measuring the emitter current of the transistor 9 with the protection current indicator 14, it is possible to determine the trigger current. In this case, indications of indicator 14 depend on the load current, i.e. at different load currents there will be different currents of the base of transistor 9, and therefore different Va-gH, therefore, setting the current to the required value must be made at the operating load current or practically determine the dependence of the set protection current on the load current. Adjusting the output voltage of the stabilizer in the larger limits changes the protection tripping current, therefore in the stabilizer as shown in FIG. 2, the protection current sensor 15 is made in the form of a current stabilizer on the transistor 19 and the reference resis. To the torus 20, this eliminates the output voltage of the response current, protection, and also allows setting the required protection current at any load current, i.e. Vg-gH changes affect the eject current of the transistor 9. In the circuit of FIG. 2, it is not possible to decrease the output voltage of the stabilizer less than the reference voltage of the source 7, since the transistor 19 and the comparison circuit 5, i.e. The stabilizer will not work, therefore, to obtain an output voltage adjustment from zero in the circuit of FIG. 3, an additional voltage source 21 is used, the voltage of which is greater than the voltage of source 7. When the output voltage of the gate voltage exceeds the allowable reverse voltage of the base – emitter transistor 9, then when the protection unit 1k activates, an invalid reverse one will be applied voltage due to the residual voltage on the capacitor 13, therefore the transition protection circuit is used by Cyode 7. With a pulse load, when the average load current is less than the current for iiififbi and the pulse current is higher, the output voltage voltage stabilizer may be less than the voltage on the capacitor 13, which are shown to block the protection triggering 8. In this case, a capacitor 18 is connected to the base of transistor 9, which delays the operation of the protection unit for a time determined by the capacitance of the capacitor 18 and the resistance of the resistor 10, and excludes the possibility of the operation of the protection unit against impulse load current. The capacitance value of the capacitor 18 must be such that the delay time is less than the charging time of the capacitor 13 by the emitter current of the transistor 9, otherwise the voltage on the capacitor 18 will play the role of the output voltage and the protection unit will operate. The use of the proposed stabilizer circuit allows using any high-frequency transistors in the protection unit, for which the permissible switching voltage of the collector emitter is greater than the input voltage of the stabilizer, which increases the speed of the protection unit. Claim 1. Stabilizer of direct voltage containing sequentially connected to the output bus an integral control element on transistors of different conductivity type, control circuit, connected to the output of the direct current amplifier, input connected to the output of the comparing unit, the inputs of which are connected to the outputs of the divider the output voltage and the source of the reference voltage, the inputs connected to the corresponding.-output terminals, and the unit for protection with a starting chain, so that, in order to increase the protection speed, the protection unit is made on a transistor of the same conductivity as the matching transistor, the base of which is connected through 4) to the output terminal and through the starting chain to the input terminal, the collector to the matching transistor, and the emitter is connected to the common bus of the stabilizer through a capacitor, in parallel with which the connected current indicator of protection and the current sensor behind the shields are connected in parallel, and a diode is connected parallel to the emitter junction - the base of the transistor. , 2., Stabilizer according to claim 1, about t. L. Due to the fact that the protection current sensor is made on a resistor. 3. A stabilizer according to claim 1, characterized in that the protection current sensor is made in the form of a stable current source. 4. The stabilizer on the PP. 1.3, which is distinguished by the fact that a stable current source is made on a transistor with a reference resistor in the emitter circuit and a voltage source in the base circuit, the transistor being connected to the protection current indicator by the collector, the base to the output of the voltage source, and the emitter through a resistor - to the common bus. 5. The stabilizer on the PP. 1, 2, characterized in that the resistor of the protection current sensor and the reference voltage source are connected to common bus through an additional voltage source. 6. A stabilizer according to claim 1, characterized in that, in order to increase the reliability of operation at a pulse load, between the common bus and the transistor of the fs unit Shields additionally connected capacitor. Sources of information taken into account in the examination 1. USSR author's certificate number 418845, cl. G 05 H 1/58. 1972. 2. USSR author's certificate number 650068, cl. G 05 H 1/58, 1976. (rig.G (Rig.z