SU951266A1 - Two-stage dc voltage stabilizer - Google Patents

Description

The invention relates to electrical engineering and can be used in power supply devices for electronic equipment.

. A voltage regulator is known, comprising two first and second stage control transistors connected in series to the output bus, a second stage controlling transistor connected to the output of the control element connected to the output of the stabilizer, a capacitor connected between the common bus and the connection point of the control transistors til

However, this circuit has a low efficiency, since the first-order control transistor operates in the active mode.

The closest to the technical essence of the invention is a two-stage DC voltage regulator, containing two regulating elements connected in series to the output bus, the first regulating element controlling input is connected to the output of the reference node, the first input of which is connected to the point elements, a capacitor connected between the common bus and the specified point

connection, the second regulating element, made on the transistor, the control input of which is connected to the output of the control element connected to the output terminals C2.

A disadvantage of the stabilizer is an output voltage ripple at low current currents. In addition, the voltage on the capacitor is stabilized by changing the opening angle of the first regulating element (thyristor), and this leads to a further increase in the phase angle between the voltage and the lagging current of the first harmonic in the network, always due to the inductance of the transformer windings therefore, to increased losses. Thyristor use

20 makes it difficult to make the stabilizer in the form of an integrated circuit, since at the present time the thyristors cannot be performed in an integrated design.

25

The purpose of the invention is to increase the efficiency and decrease the output voltage ripple.

The goal is achieved by the fact that the second input of the comparison node

30 is connected to the output to 1emme.  In addition, the node, the comparison is performed on the K-transistor, the gate is connected to the second input of the node, the second drain to the first input of the node. comparison, and the first drain - in the course of the comparison node, the first regulating element is made on a transistor, the emitter connected to the output terminal, the collector - with the point of connection of the capacitor and watts.  a regulating element, and a resistor is connected parallel to the base – emitter junction of the transistor.  Comparison node is complete. On the A-transistor, whose gate through a resistor is connected to the second input of the comparison node parallel to the gate, the second drain of the L transistor is connected to the first zener diode and the first drain is connected to the base of the matching transistor, the collector connected to the output of the comparison node, and the emitter to the output an amplitude limiter made on a second Zener diode resistor and a transistor whose collector is connected to the output terminal, the base through a resistor to the collector and through the second stabilizer diode to the first input of the reference node, and ter - acc popping the emitter of the transistor, wherein tranzis Torr first regulating member is connected to the collector of the input Clem my emitter - with the condenser and wherein the parallel passages base - emitter voltage of the matching transistor and a transistor connected to be amplitude limiter additional re ican.  In addition, in order to protect L.  - overvoltage transistor, between the base of the transistor of the amplitude limiter and the second Zener diode a third zener diode is switched on by a capacitor, and the emitter of the input protection transistor is connected to the base of the transistor of the first transistor and its first transistor is connected to the base of the first inserted protection transistor; . - the second and third input resistors are connected to the point of connection of the second and third zener diodes and parallel to the base – emitter junction of the protection transistor and the input terminals. In order to increase the reliability of operation between the second Zener diode and the first input of the comparison node, a trigger is included, performed on two transistors of different types of conductivity and two resistors, the base of the first transistor connected to the collector of the second and the base of the second to the collector of the first and through a diode connected to the input terminal, parallel to the transitions, the base - emitter of each transistor is connected to a corresponding resistor, while the emitter of the second transistor is connected to the first input of the reference node, and the emitter of the first transistor through the entered fourth resistor is connected to the base of the inserted protection transistor, the collector of which is connected to the base of the matching transistor, and the emitter through the fifth entered resistor is connected to the connection point of the inserted diode and capacitor - connected in series and.  connected to the input terminals, where the third resistor is also connected, the emitter of the protection transistor through the input zener diode is connected to the second drain of the L transistor, besides the base-emitter junction of the transistor is shunted by the sixth resistor.  Between the base of the amplitude limiter transistor and the first input of the comparison node, a trigger is made on two transistors of different conductivity types and one resistor, with the base of the first transistor connected to the collector of the second, and the base of the second collector of the first and through a diode connected to the input terminal the emitter of the second transistor is connected to a resistor, while its emitter is connected to the first input of the comparison node, and the base of the first transistor is connected to the base of the input through the entered fourth resistor protection transistor, the collector of which is connected to the base of the matching transistor, and the emitter through the fifth entered resistor is connected to the connection point of the inserted diode and capacitor connected in series and connected to the input terminals where the third entered resistor is also connected, the emitter of the protection transistor through the input zener diode - to the second drain of the L-transistor, besides the base-emitter junction of the protection transistor is shunted by the entered sixth resistor.  In order to increase the efficiency and reduce the output voltage ripple, the second input of the comparison node is connected to the output terminal through one diagonal adjustable potentiometer of the inserted resistance bridge, to the other diagonal of which the input auxiliary voltage source is connected through the input diode.   FIG.  1-6 are schematic diagrams of a two-stage DC voltage regulator.  Stabilizer (FIG.  1) contains a regulating element 1 on a transistor 2, parallel to the base-emitter junction of which a resistor 3 is connected, the emitter is connected to the output of the stabilizer, and the base is connected to the first drain A of the transistor 4 of the comparison node 5 and the collector is connected to the capacitor b, to the collector of the regulating transistor 7 and to the second drain of the L -transistor 4, the gate of which is connected to the output of the stabilizer.  The regulating transistor 7 is connected to the output of the stabilizer by the emitter, and the base to the output of the control body 8 connected to the output of the stabilizer.  In addition, the transistor 2 (FIG.  2) the collector is connected to the input of the stabilizer, the emitter to the capacitor b, and the base to the collector of matching transistor 9 of the comparison node 5, the base of which is connected to the first drain of the L -transistor.  4, emitter - to the emitter of the transistor 10 of the amplitude limiter 11. The collector of the transistor 10 is connected to the stabilizer input and through the resistor 12 is connected to the base, which through the Zener diode 13 is connected to the capacitor 6, and in parallel to the base-emitter junction of transistor 9 and 10, respectively, resistors 14 and 15 are connected.  The gate of the L-trans torus 4 is connected to the output of the stabilizer of the torus through a resistor 16 and through a zener diode 17 with a second drain.  The base of the transistor 10 (FIG.  3) connected to the zener diode 13 through parallel connected.  with tablithron 18 and capacitor 19 and with the emitter of protection transistor 20, the collector of which is connected to the base of the matching transistor 9, and the base through a resistor 21 with a connection point of zener diodes 13 and 18.  The shutter L of the transistor 4 is connected to the engine potentiometer 22 of the bridge 23.  The terminals of the potentiometer 22 are connected to the output of the auxiliary voltage source 24 through diode 25 and through resistors 26 and 27 to the output of the stabilizer, and parallel to the base-emitter junction of the protection transistor 20 and the stabilizer input are connected respectively resistors 28 and 29.  In the stabilizer (FIG.  4) Zener diode 13 is connected to capacitor 6 via an emitter-ter-base junction of transistor 30, the collector of which is connected via a resistor 31 to a common stabilizer bus.  The gate of the L-transistor 4 through the resistor 16 is connected to the potentiometer 22 engine and instead of the resistor 27 uses a field-effect transistor 32, which is connected to the output of the stabilizer by the gate, the source to the emitter of the control transistor 7 and the potentiometer and parallel to the drain-to-source transition Zener diode 33- is connected, and a resistor 34 is turned on between the emitter of transistor 7 and the output of the stabilizer.  Transistor 10 (FIG.  5) an amplitude limiter 11 of the base is connected via a Zener diode 12 to the base of the first transistor 35 of the trigger 36, made on two transistors 35 and 37 connected to each other, respectively, the base with the collector, the collector with the base, and parallel to the transitions-base-emitter are connected respectively resistors 38 and 39.  The first transistor 35 is connected to the second drain of the A-transistor 4, and the base through the diode 40 to the input of the stabilizer.  The second transistor 37 is connected by an emitter through a resistor 21 to the base of the protection transistor 20, the emitter of which is connected via a Zener diode 41 to the second drain of the transistor 4 and through a resistor 42 to the connection point of the diode 43 and a capacitor 44 connected in series and connected in parallel to the stabilizer input.  Transistor 10 (FIG.  6) the limiter amplitude 11 base is connected to the emitter of the second transistor 37 of the trigger 36, the base of which through a resistor 21 is connected to the base of the protection transistor 20 ,.  .  The operation of the second stage of the stabilizer on the control transistor 7 with the control element 8 is similar to the work of the known compensatory stabilizers With a series control transistor.  This stage serves to stabilize, output the voltage and smooth the pulsations.  The regulating element 1 of the first stage on the transistor 2 with the comparison circuit 5 serves to stabilize the voltage on the regulating transistor 7 with a wide range of variation of the supply AC voltage and adjust the output DC voltage.  This is achieved by stopping the capacitor 6 charge at the time of the period of the supplying pulsating voltage from the rectifier, while its value is higher than the maximum voltage on the capacitor 6 Uca fnax. This is achieved by opening the transistor 2 of the regulating element 1 when the input voltage rises to the level of the minimum voltage condenser capacitor 6 Ucs. rnin closing when the voltage of the capacitor 6 reaches.  . .  In the stabilizer (FIG. 1), the transistor 2 opens with an increase in the input voltage of the transistor, therefore.  That the base is connected to the collector through the transition of the first drain - the second drain A.  - transistor 4, in which, at low voltages at the junction, the first drain - the second drain - the drain current increases with increasing voltage, t. e.  The base current of transistor 2 increases, and with a further increase in the input voltage, the current of transistor 2 will increase, as the current through the A transistor will increase.  Opening transistor 2 leads to charge of capacitor 6, m. e.  to the growth of the control voltage of the L-transistor 4, since its gate is connected to the output of one hundred of the transformer, t. e.  stabilized voltage.  An increase in the control voltage leads to a slowdown in the growth of the drain current of the X transistor 4, then to a decrease in its current and, finally, to a complete locking of the L transistor 4 and transistor 2.  The charge of the capacitor b reduces the growth of the input voltage of the stabilizer by increasing the voltage drop across the transformer windings and the diode of the rectifier, therefore, when the transistor 2 is closed, the charge current is reduced and this leads to an increase in the input voltage steepness that ycKop ieT the closing time determined by the speed of transistor 2 and 4.  After closing the transistor 2, the voltage from the stabilizer input through the resistor 3 enters the first drain of the L-transistor and keeps it closed until April 1 at the percussion of the first drain - the second drain is greater than the voltage at which the transistor opens, and since this voltage is determined by the parameters of the transistor and the control voltage, it is possible to choose the capacitance of the capacitor b so that when using any D-transistors of one type, the control voltage decreases so that when the voltage drops voltage of the audio -tranzistor 4 and transistor 2 substantially. did not open.  When used in the second stage of the electronic short circuit protection (short circuit) stabilizer, as the most reliable, the output voltage of the stabilizer drops to O and A transistor 4 when the load is closed because the second drain to the junction is the voltage of the capacitor 6 , and the first drain to the transition is the total input voltage, and, therefore, for reliable operation, the stabilizer circuit of FIG.  1 can be used if the amplitude value of the input voltage Ugj yriotx f is higher than the admissible HanpHKeTiHe nepexo and the first drain is the gate and (;. 5dor A-tra resistor 4.  If the voltage is d / L; 1-aop, then the stabilizer circuit of FIG. 2 is used.  In this stabilizer, in order to limit the voltage on the L-driver, 4, parametrically, the stabilizer 11 is used on the zener diode 13, the transistor 10 and the resistors 20 and 24, connected in parallel with the regulating element 1.  The transistor 10 serves to reduce the output impedance of the parametric stabilizer when open. 9G matching transistor working simultaneously with L -transistor 4 in the same way as in the stabilizer (FIG.  1) transistor 2 is working.  When the transistor 9 is opened, the transistor 2 also opens, as the collector current of the transistor 9 is the base current of the transistor 2.  After the L-transistor 4 is closed, the voltage at the base of the transistor 10 and, consequently, on the first drain, the Zener diode 13 does not open, then the voltage increase stops, t. e.  The short-circuit load voltage at the junction is the first drain - the second drain is determined by the Zener diode 13, and at the transition the second drain - gate - by the Zener diode 17, regardless of the magnitude of the input and output voltages.  At high load currents in.  units of ampere to eliminate the inclusion of the L -transistor 4 and transistor 2 when the input voltage drops, a large capacitor b is required, which dramatically increases the size of the stabilizer.  In such cases, it is more expedient to use the capacity of the capacitor completely, t. e.  so that the ripple voltage on the capacitor 6 is equal to the allowable one for the chosen type of capacitor, but then the amplitude of the control voltage for g increases.  transistor 4 and the greater the load current, the greater the voltage at the junctions will be the opening of the A transistor: 4 and transistor 2, and this leads to a sharp increase in power dissipation in transistor 2 and a decrease in efficiency if the voltage drops across the internal resistance. the input voltage source is insufficient to provide a saturated operation of the transistor 2.  In such cases, to avoid overheating of the transistor 2 and reducing the efficiency, the stabilizer circuit of FIG.  3  In this scheme, after the transistor 2 is closed, the voltage at the collector-emitter junction increases and when the operating voltage of the Zener diode 13 reaches, the capacitor 19 starts charging and the transistor 20 opens, which by junction collector-emitter shunts the base of the emitter transistors 9 and 10, a further increase in the input voltage when the zener diode 18 opens, the charge of the capacitor 19 stops, and after the input voltage drops below the opening voltage of the zener diode 18 it.  It begins to discharge through the resistor 21 and the base of the transistor 20, and the transistor 20 is pushed in the open state until the input voltage drops below the capacitor 6.  After that, the Zener diode 13 and the collector junction of the transistor 10 are opened in the forward direction and the capacitor B is recharged to the direct voltage of the Zener diode 18, this closes the transistor 20, and it remains closed until the Zener 13 opens again after the transistor 2 is closed .  The stabilizer circuit of FIG.  3, due to the presence of capacitor 19, it is technologically difficult to manufacture in the form of an integral lcpx, we must therefore use a stabilizer circuit according to phi to produce a mash stabilizer in the form of a microcircuit.  5 and b.  In the stabilizer (FIG.  5) after closing the transistor 2, when the zener diode 13 opens, the transistor 35 of the trigger 36 opens, which triggers the trigger 36, current transistor 20 and 37 flows through the base current of transistor 20 and transistor 20 opens and connects the base of transistor 9 to the zener diode 41, the operating voltage of which is greater than the voltage of the Zener diode 13, and as a result the base-emitter junctions of the transistors 9 and 10 are closed by reverse voltage due to the difference in the working voltages of the Zener diodes 13 and 41, the Transistors 35 and 37 of the trigger 36 remain open and After closing the zener diode 13 when input voltage decline voltage due to positive feedback.  When the input voltage becomes fiJeHbiiie, than the voltage on the capacitor 6, the diode 40 is opened, the reverse voltage is applied to the base-emitter junction of the transistor 35 and the transistor 35 closes.  This causes the trigger 36 and the transistor 20 to close, they remain closed until the zener diode 13 is reopened. The voltage on the stitron 41 still remains constant during operation of the stabilizer due to the voltage on the capacitor 44.  FIG.  6 in the stabilizer after.  close the transistor 2, when the input voltage becomes greater than that of the bilitron 41, the transistor 37 opens, and hence the transistor t. e.  Trigger 36 triggers and transistor 20 opens.  In this case, the base-emitter transitions of transistors 9 and 10 turn out to be under reverse voltage, determined by the zener diode 41, since the voltage across the open transistors 35 and 37 can be neglected.  In this case, the transistors 35 and 37 of the flip-flop 36 are closed when the emitter current of the transistor 37 decreases when the input voltage drops, so that the transistor 35 goes out of saturation and then, due to the positive feedback, the transistors 35 and 37 close.  The emitter of the transistor 37, at which the trigger 36 closes, depends on the gain factor (E of the transistor 35.  Consequently, the magnitude of the operating current and / 3 of the transistor 35 vs can be ensured that the closing of the rigger 36 occurs when the voltage is on.  at the input of the stabilizer is not enough to open the transistor 2,. e.  less than its saturation voltage.  Thus, in the above schemas of the stabilizer (FIG.  3, 5, and 6) about the time period after closing the transistor 2, before the input voltage becomes less than that of the capacitor 6, the transistor 2 is closed and when the control voltage on the A-transist 4 decreases so much that It also opens with a falling input.  When the gate of the transistor 4 is connected to the output of the stabilizer (FIG.  1 and 2) the voltage of the pulsations on the capacitor 6 is determined by the A transistor 4 and the regulating transistor 7, namely, Sat c min. M 7 m n since.  .  rnctx output 014 Cfe m-i fl 7 1 where U0 (, ix is the output voltage of the stabilizer; the cut-off voltage A of transistor 4; cattp11P is the minimum allowable voltage. transition collector-emitter transistor 7 for work in active mode.  JBo stabilizer operation time is always ° V4 / cat7m1p Cfe and, therefore, when tuning for maximum efficiency according to the existing UoT4 and, UK3T7m1n it is necessary to choose the capacitance of the capacitor 6 so that from 4 UK3T7min - This is easy to accomplish at low load currents even taking into account that ripples on the capacitor 6 should not exceed the permissible value, but at high load currents this leads to incomplete use of the capacitor b capacity and large stabilizer dimensions, and given that the L-transistors have a technological variation, ozhet skazats that. .  0, T4 TOin CATTGO1P CEAOP oT4min K3T7nnin CbAon where UA; permissible amplitude of the pulsations on the capacitor 6)

(; с - maximal and minimal values respectively

and

nor the cut-off voltage of the LT4 min L transistor, due to technological variation,

In the first case, additional power is dissipated on the transistor 7, since UoT4 tnax is greater than necessary and the second case is unacceptable, as the control transistor 7 enters the saturation mode, i.e. Both cases have their drawbacks. If an additional voltage source is introduced into the gate circuit of the L-transistor 4 so that when setting, the inequalities 1 and 2 turn into equality, i.e., &,, and. di, ..

OT4 max AL

CААОП НЭТ7m n и и ... , 4U.

OT4min Aa SVOp Katt m-in 1

where Od and MA are the voltage of the additional source, then with any technological scatter of the parameters of the transistors, any load current and any amplitude, the maximum efficiency can be obtained. For this, in the circuit in FIG. 3 an additional source of voltage 24 is connected to the output of the stabilizer and the gate of the L-transistor 4 through bridge 23 on potentiometer 22 and resistors 26 and 27. In this case, the additional voltage is removed from the diagonal of bridge 23, namely the motor 22 and can be as positive and negative, i.e. By simple adjustment, maximum efficiency can be obtained. Using an additional voltage source 24 with the bridge shown in FIG. 3, possibly in the stabilizer of FIG. 2, 5 and 6, while the resistor 16 may be absent, since it is replaced by resistors 26 and 27, and to protect the voltage source 24 from the reverse polarity voltage arising on the resistance part of potentiometer 22 P13 and short-circuit, a diode is used in the load 25, which closes if the voltage that occurs is greater than the voltage of the source 24, and protects it from the reverse voltage. When using a voltage source 24 with a bridge as shown in FIG. 3, the diode 25 is not needed in the stabilizer of FIG. 1, since the second drain-to-L-transistor 4 transition is always closed and there is no danger of a reverse voltage at the input of source 24.

The circuits of the stabilizers of FIGS. 1-3, 5, and 6 are maximum. The PDC, if the load current does not change. With changes in load current over 11 limits, dU, and since equality 01-4-HiV L C6 and, at 7 m-in does not hold at the minimum load current, i.e.

from 4- A cat cat7 tvltl.

then additional power is dissipated at the transistor, and the efficiency is reduced. In order that it does not depend on the load current, it must be changed in direct proportion to the load current, which allows to obtain the maximum efficiency with any change in load current. This is achieved by the fact that, in the pr scheme, FIG. 4 one of the resistors of the bridge 23 is a field-effect transistor 32 in the mode of a voltage-controlled resistor, in which the control voltage is the voltage taken from the load current sensor - resistor 34. Suppose that with a minimum load current the control voltage is equal to 0, the transistor 32 is open and the voltage drop across it is also equal to O, and at maximum the control voltage is greater than 5c cutoff of the transistor 32, it is closed and the voltage across the resistor 26 is rainy O, then the voltage removed from the slider potentiometer 22, neg at the minimum current and positive at the maximum, i.e. as the load current increases, the voltage taken from the diagonal of the bridge increases, as required, and the position of the slider of the potentiometer 22 could also be compensated for by the technological variation of the parameters of the transistors. Using the bridge 23 of FIG. 4 in the stabilizer circuits of FIG. 2, 3, 5, and 6 may, with a short-circuit load, the lower position of the slider 22 of the bottom potentiometer causes the voltage to be applied to the drain-source transistor 32

SIT5-1 kz bblX JAiT

Claims (3)

where) Its voltage is the junction of the drain-source of the transistor 31 at load short-circuit, the working voltage of the Zener diode 17, which may be greater than the allowable, then to protect the transistor 32, the Zener diode 33 is put, and to limit the current through Zener diodes 17 and 33 the gate of the D-transistor 4 is connected to the potentiometer motor 22 through a resistor 16. In the circuit of FIG. 1 when installing the bridge of FIG. 4 zener diode 33 and resistor 16 are optional. The purpose of the diode 25 in the circuit in FIG. 4 is the same as in FIG. 3. With a minimum load current, the charge current of the capacitor 6 passing through the circuit: resistor 12, zener diode 13 or zener diodes 18 and 13, and resistor 42, zener diode 41, can exceed the load current and then the voltage on the capacitor 6 becomes greater than U. which can disrupt the first stage of the stabilizer. To eliminate this, Zenerons 13 and 41 are connected to capacitor 6 through an emitter-base transition of transistor 30, as a result, the charge current through the circuit is reduced to, where (teo gain factor of transistor 30, while resistor 31 serves to reduce power dissipation on the transistor 30. This invention allows to increase the efficiency and reduce output voltage ripple Claim 1. A two-stage DC voltage regulator containing two control elements connected in series to the output voltage. bus, the first control element of the control input is connected to the output of the comparison node, the first input of the KO is connected to the connecting point of the regulating elements, a capacitor connected between the common bus and the specified connection point, the second regulating element made on the transistor, the control input which is connected to the output of the control unit connected to the output terminals, characterized in that, in order to increase the efficiency and reduce the output voltage ripple, the second input of the comparison node is connected to the output terminal. 2. A stabilizer according to claim 1, in accordance with the fact that the Comparison Unit is made on. D. - transistor, the gate of which is connected to the second input of the comparison node, the second stock of the first input of the comparison node, and the first drain - with the output of the comparison node, the first regulating element on the transistor, the emitter connected to the output terminal, the collector - with a capacitor junction and the second regulating element, and a resistor is connected in parallel with the base-emitter transistor connection. 3. The stabilizer according to claim 1, characterized in that the comparison node is made on an L-transistor, which through a resistor is connected to the second input of the comparison node, parallel to the junction, the second drain of the transistor, the first Zener diode is connected to the base a matching transistor, a collector connected to the output of the comparison node, and an emitter connected to the output of an amplitude limiter, made on a resistor, the second zener diode and whose transistor / collector is connected to the output terminal, the base through the collector resistor via the second zener — with the first input of the comparison node, and the emitter — with the emitter of the matching transistor, the transistor of the first regulating element being connected to the input terminal, the emitter with the capacitor, and parallel to the base-emitter transition of the matching transistor and the amplitude limit transistor additional resistors are connected 4. The stabilizer according to claim 3, characterized in that, in order to protect the L-transistor from overvoltage, between the base of the transistor of the amplitude limiter and the second stabilizer The fourth zener diode is shunted by a capacitor, the emitter of the inserted protection transistor is connected to the base of the transistor of the amplitude limiter; the collector of which is connected to the base of the matching transistor, the base through the first entered resistor is connected to the junction of the second emitter of the protection transistor and the input terminals are connected to the second and third entered resistors. 5. The stabilizer in accordance with claim 3, in which, in order to increase the reliability of operation, between the second zener diode and the first input of the comparison node is activated a trigger made on two transistors of different conduction types and two resistors, the base of the first the transistor is connected to the second collector, and the base of the second is connected to the collector of the first and is connected via a diode to the input terminal, the corresponding resistor is connected in parallel with the base-emitter transitions of each transistor, and the emitter of the second transistor is connected to the first input comparison node, and the emitter of the first. the transistor through the input fourth resistor is connected to the base of the input protection transistor, the collector of which is connected to the base of the matching transistor, and the emitter of the fifth input resistor is connected to the connection point of the inserted diode and capacitor connected in series and connected to the input terminals, where the third input resistor is also connected, the emitter of the protection transistor through the introduced zener diode - to the second drain of the transistor, besides the transition base - emitter of the protection transistor is shunted by the inserted poles resistor. 6. The stabilizer of claim 3, in order to increase the reliability of operation, between the base of the transistor of the amplitude limiter and the first input of the comparison node is enabled a trigger made on two transistors of different conductivity type and one resistor, with -i the base of the first transistor is connected to the collector of the second, and the base of the second is connected to the collector of the first and through a diode connected to the input terminal. A resistor is connected to the first emitter of the second transistor, the emitter is connected to the first input of the reference node, and the first transistor through The introduced fourth resistor is connected to the base of the inserted transistor protection, the collector of which is connected to the base of the matching transistor, and the emitter is connected through the fifth entered resistor to the junction point of the inserted diode. and a capacitor connected in series and connected to the input terminals where the third input resistor is also connected, the emitter of the protection transistor 4epeS, the input zener diode to the second drain of the L -transistor, in addition, the base-emitter transition of the protection transistor is shunted by the entered sixth resistor. 7. The stabilizer according to claim 4, characterized in that, in order to increase efficiency and reduce output voltage ripple, the second input of the comparison node is connected to the output terminal through one diagonal adjustable potentiometer of the inserted resistor bridge, the input auxiliary source connected to the other diagonal voltage through the diode entered. Sources of information taken into account in the examination 1. Authors certificate of the USSR N 513354, cl. G 05 F 1 / 5b, 197. 2. USSR author's certificate number 423112, cl. G 05 F 1 / 5b, 1973 .four-