SU1727179A1 - Method of reclamation of weakly sulfated storage battery and system for its implementation - Google Patents

Abstract

The invention relates to electrical engineering and can be used for the regeneration of electroplating: cells and the desulfation of battery plates when they are charged. The purpose of the invention is to reduce the recovery time of lightly sulphated batteries. The device contains a power source, a regulating unit, a battery, a switching device, a discharge device, a control device, a protection device. The device allows both charging batteries and producing training cycles in battery discharge mode up to Umin 12.9-13.5 V and in series to Umax 14.7-15.3 V. 2 sec. and 1 z.p. f-ly, 2 ill. Yo

Description

The invention relates to a converter technique, in particular to devices for charging and discharging power sources, and can be used for regenerating galvanic cells and desulfating batteries during charging.

Methods are known for restoring the capacity of weakly sulfated batteries: long-term charge with a small current; charge of batteries in distilled water; a full charge of the batteries, followed by a full discharge of currents of a tenth of the capacity; charge by various currents, etc. At the same time, the end of charge is determined by the density of the electrolyte and the rate of its increase, the intensity of the boiling electrolyte,

the voltage across the terminals is 2.4-2.7 volts per bank. The battery is completely depleted and counts at a voltage of 1.5-1.8 V per battery.

There is a known method of conducting a training and recovery cycle of a lead battery using asymmetric currents in the process of charge and discharge.

A known method of restoring weakly sulphated batteries is by cyclic charge and discharge of batteries, with charge maintained for 150 ± 45 with a normal charge current followed by discharge for 300 ± 90 with a discharge current of 0.01 in battery capacity.

The disadvantages of the method are a large recovery time, increased for

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the expense of inefficient charge at the end of each charge and over-discharge cycle at the end of each discharge cycle, as well as large power losses.

A known system for charging and discharging a battery used to cycle sulfated batteries. This system implements such a charging method in which the charge and discharge cycles are set when the battery reaches the minimum and maximum threshold voltage for lead batteries.

The closest to the present invention is the Electron-6 charging device, which contains an alternating current source, a regulating unit, a switching device made in the form of a time relay, a discharge device, a control device, and a protection device.

The operation of the device in the mode Zar d. Klyus SA is open. When the device is connected to the mains, a rectified full-wave voltage arriving at the input of the regulating unit and the switching device appears at the output of the power source. The control unit generates at its output the full-wave voltage pulses with the cut-off front part. The degree of clipping is regulated by the same block. Cut-off pulses arrive at the battery terminals, charging it.

Operation of the device in the Cyclic mode. The SA key is open, 2-3 min. The charge lasts, after which the switching device operates, leading to the disconnection of the regulating unit from the battery and the connection of a discharge device to it. The battery on the battery begins to discharge within 4-6 minutes. After this time has elapsed, the switching device is triggered, the discharge device is automatically disconnected from the battery, and the control unit is simultaneously connected to it. The following cycle of charge and discharge of the battery occurs.

The control device is designed to control the charge and discharge current of the battery.

The protection device serves to protect the device from short-circuiting the leads for connecting the battery.

The charge current is generated from the power source after full-wave rectification by two thyristors, which cut off the half-wave parts of the supply voltage.

The thyristors are controlled by a phase-shifting RC circuit from a separate winding of the power source through switching transistors. The firing angle of the thyristors is controlled by the position of the slider of the variable resistor of the phase-shifting RC circuit. In cyclic charge-discharge mode, a time relay built on an asymmetrical multivibrator is activated, the dwell time of which is determined by RC circuits. The output from the multivibrator controls a transistor switch, in the collector circuit of which there is an electromagnetic relay. Contacts

this relay turns on or off the thyristor control circuit and turns off and on, respectively, the battery discharge circuit to the 24 ohm resistor. The multivibrator and the key are powered from a separate winding with full-wave rectification. The charging current is monitored by a voltage drop across a reference resistance connected in series to the charging circuit. The same resistance is used to protect against short-circuits at the battery terminals. The voltage on the resistance during a short circuit rises sharply, the transistor switch is activated, which controls the thyristor, and the latter, in turn, short-circuits the control signal with the power thyristors to the common bus. And the thyristor closes after the end of the half wave.

The disadvantages of the known device are the relatively long recovery time of low-sulfated batteries, the direct loss of electrical energy associated with it.

The purpose of the invention is to reduce the recovery time of low-sulfated batteries and enhance functionality.

This goal is achieved by the fact that charge and discharge cycles are set upon reaching the specified maximum and minimum threshold voltage at the battery terminals, respectively. With

this charge of the battery is produced until the voltage at its terminals rises to a value of Umax 14.7-15.3 V. A further charge, as shown by the experiment, comes from literature sources,

It is impractical because accumulation of battery charge practically does not occur and vigorous gas evolution and heating of the electrolyte begins.

For different copies. same type of battery depending on

degrees of sulfation possible variations in the voltage indicated.

To increase the charge efficiency, it is necessary to reduce the voltage at the battery terminals: either stop the charge or discharge the battery with a current of 0.01 capacity.

In the first case, the time of the voltage drop is rather long and the battery desulfation is weak. In the second case, the voltage drop time is reduced and at the same time the process of desulfation of the plates occurs.

By reducing the voltage to a value of Umin 12.9-13.5 V, the battery is charged again, etc. The process is repeated cyclically.

The degree of charge of a battery is judged by the density of the electrolyte,

Depending on the degree of sulphation of the battery, the charge and discharge cycles are determined by the state of the battery itself. If the battery is non-sulfated, such cycles appear only at the end of the charge, which can additionally serve as information about the end of the charge. Thus, the charge and training of the battery is carried out optimally with cyclic accumulation of charge, which allows to reduce the charge time and more economical use of electrical energy,

In a system for restoring a weakly sulphated battery, implementing the proposed method, containing a power source on a two-pole rectifier, a control unit, output terminals, a switching device with an electromagnetic output relay, a discharge device and a protection device, the control unit being the first the input is connected to the first output of the power source, the second input to the output of the protection device, the third input to the first output of the switching device, the output of the regulating unit of the n with the output terminals and the first input of the discharge device, the second input of which is connected to the second output of the switching device, which is powered from the second output of the power source, the switching device is designed as a two-threshold device connected to the output terminals, the first output of which is connected to the regulating unit, the second output - with a discharge device; the regulating unit contains a resistor and a zener diode connected in series, connected in the forward direction to the positive At the exit, a resistor - to the negative output

power supply, the transistor, the base output of which through a resistor is connected to the point of series connection of the resistor and the Zener diode, and the emitter

the output through an adjustable resistor is connected to the positive output of the power source, a capacitor connected by one output to the base terminal of the transistor, and the other to the positive output of the power source, a resistor connected to the collector terminal of the transistor and the anode of the photo thyristor of the protection device optocoupler, the cathode of the photo thyristor is connected with the opening contact of the first switching contact group of the relay of the switching device, and its fixed contact is connected to the control electrode of the unidirectional thyristor key, the power electrodes of which are included in the battery charge circuit, while the thyristor key is connected through a reference resistor in the forward direction to the positive output terminal and to the minus output of the power source, transistor,

5 the basic output of which is connected via a resistor to the serial connection point of the resistor and Zener diode, and the emitter output through an adjustable resistor to the positive, power supply output, a capacitor connected by one output to the basic output of the transistor, and a resistor connected to the collector output of the transistor and to the anode of the photo thyristor of the thyristor optocoupler of the protection device, the cathode of the photo thyristor is connected to the break contact of the first switching contact second group switching relay device and its contact nepod0 VISION coupled to the control electrode of the unidirectional thyristor switch, power electrodes which are included in the charging circuit and the battery, wherein the thyristor is connected via a switch

5 reference resistor in the direct direction to the positive output terminal and to the closing contact of the first switching contact group of the relay of the switching device, parallel to the thyristor

0 the key is connected in series with a resistor and a diode, while the diode with its cathode is connected to the cathode of a unidirectional thyristor switch, and the anode through a resistor to the anode of the emitting diode of the protection device, the cathode of the latter is connected to: the minus output of the power source, the discharge device contains a resistor, the anode terminal of which is connected through a reference resistor. to the positive output terminal, and the cathode is connected via a discharge lamp to the negative output of the power source and through the open The contact terminal of the switching device relay is connected to the diode and capacitor serial connection points, the second capacitor lead is connected to the control electrode of the thyristor, and the diode is connected via an anode through a resistor to the positive output of the power source, the negative output terminal is connected to the negative output of the power source the switching device contains a common wire connected to the cathode of the first diode, which is connected by its anode to the positive output terminal and is connected in series resistor and second diode / while the diode is connected in the forward direction to the minus output of the power source, and the resistor to the common wire, the transistor, the emitter terminal of which is connected to the serial connection point of the resistor and the second diode, and the collector output through the winding of the relay to common wire, parallel to the winding of the relay are connected a parallel-connected capacitor and a third diode, while the third diode is connected by its anode to the collector output of the transistor, connected in series by an adjustable resistor and a resistor shunted by the closing contact of the third contact group of the relay, while the shunt resistor is connected to the common wire by another output, the adjustable resistor to the negative output of the power source, and its slider to the basic output of the transistor and capacitor, one output of which is connected to the common wire, and the other to the negative output of the power source.

Figure 1 shows the structural diagram of the proposed device; FIG. 2 is his circuit diagram in principle.

The system contains a power source 1 with a full-wave rectifier, a regulating unit 2, a battery 3, a switching device 4, made according to the two-threshold device scheme, a discharge device 5, a control device 6, a protection device 7.

The regulating unit 2 is connected to the first input of the first output of the power supply 1, the second input to the output of the protection device, the third input to the first output of the switching device 4. The output of the regulating unit is connected to the battery 3, the control device 6, the first input of the discharge device 5 whose second input is connected to the second

the output of the switching device, which is supplied with power from the battery output, and the output of the control device is connected to the input of the protection device 7.

In this case, the power source is made on a matching transformer 8, the primary winding 9 of which is connected to the first output through parallel-connected interlock normally open contact 10 of the relay 11 and button 12 to the input terminal 13, and the other output to the input terminal 14. The full-wave rectifier is assembled on diodes 15, 16 and is powered by the secondary winding 17 of the matching transformer. In this case, the first output of the secondary winding is connected to the anode of the diode 15, the cathode of which is connected to the cathode of the diode 16 with a key, and is a common positive output of the full-wave rectifier. The anode of the diode 16 is connected to the second terminal of the secondary winding of the matching transformer, the middle terminal of which is the common negative output of the full-wave rectifier.

A diode 18 and an electromagnetic relay 11 are connected in series between the positive and negative outputs of the full-wave rectifier, while the diode 18 is connected in the forward direction to the negative one, and the electromagnetic relay is connected to the positive output of the full-wave rectifier, the capacitor 19 is connected

parallel to the electromagnetic relay 11.

The regulator is powered from a full-wave rectifier and contains a resistor 20 and

Zener diode 21, while the zener diode is connected in the forward direction to the positive output, and the resistor to the negative output of the full-wave rectifier. Base terminal of transistor 22 through resistor

23 is connected to the serial connection point of a resistor and a zener diode, and the emitter output of the transistor through an adjustable resistor 24 is connected to the positive output of a full-wave rectifier,

the capacitor 25 is connected by one output to the positive output of the full-wave rectifier, and the other to the basic output of the transistor. Resistor 26 is connected to the collector output of the transistor and the anode

photo thyristor thyristor optocoupler 27, the cathode of which is connected to the closed contact 28 of the first switching contact group of the relay 29. The switching contact 30 is connected to the control

The electrode of the unidirectional thyristor switch 31, the power electrodes are connected to the battery charge circuit, while the unidirectional thyristor switch is connected through the reference resistor 32 in the forward direction to the positive terminal 33 for connecting the battery and to the open contact group 34 of the relay 29.

In parallel with a unidirectional thyristor key, a series-connected resistor 35 and a diode 36 are connected, while the diode is connected to the cathode of the unidirectional thyristor key by its cathode, and the anode through the resistor 37 to the anode of the emitting diode of the thyristor optocoupler 27, the cathode of the latter is connected to the minus output of the dual-period diode to the minus output of the dual-period diode of the thyristor optocoupler 27, the cathode of the latter is connected to the minus output of the two-period diode to the minus output of the dual-period diode of the thyristor optocoupler 27, the cathode of the latter is connected to the minus output of the two-period diode to the minus output of the dual-period diode of the thyristor optocoupler 27; ...-.

The discharge device 5 is made on the thyristor 38, the anode terminal of which is connected via the reference resistor 32 to the positive terminal 33 for connecting the battery 3, and the cathode is connected via the discharge lamp 39 to the negative output of the full-wave rectifier and - through the normally closed contact 40 The second contact group of the relay 29 is connected to the serial connection point of the diode 41 and the capacitor 42, the second terminal of which is connected to the control electrode of the thyristor 38, and the diode is connected via its anode through the resistor 43 to the positive output do a full-wave rectifier, the minus terminal 44 for connecting the accumulator is connected to the negative output of the full-wave rectifier.

The switching device 4, made according to the scheme of a two-threshold device, contains a common wire connected to the cathode of the diode 45, which is connected by its anode to the positive terminal 46 for connecting a battery. Diode 47 and resistor 48 are connected in series with each other, while the diode is connected in the forward direction to the minus output of the full-wave rectifier, and the resistor is connected to the common wire. The emitter output of the transistor 49 is connected to the point of the serial connection of the diode 47 and the resistor 48, and the collector output through the winding of the electromagnetic relay 29 to the common wire. Parallel to the winding of the electromagnetic relay 29 are connected a parallel-connected capacitor 50 and a diode 51, which by its anode is connected to the collector output of transistor 49. The adjustable resistor 52 and the resistor 53, shunted. Are normally open contact 54 of the third contact group of relay 29, are connected in series. At the same time, the shunted resistor 53 is connected to the common wire by another output, the adjustable resistor 52 to the negative output of the full-wave 5 rectifier, and its slider to the basic output of the above-mentioned transistor, the capacitor 55 is connected to the negative output by one output full-wave rec.

0 The control device 6 is made on a microammeter 56. One pin of which is connected to the positive terminal 33 for connecting the battery and the other to the measurement switch 57. Resistor 58

5 is connected with one pin to the contact pad 59 of the measurement switch, and the other to the cathode of the unidirectional thyristor switch 31. The resistor 60 is connected with one pin to the pin

0 pad 61 of the measurement switch, and another pin. - to the minus output of full-wave rectifier,

Relay 11 provides disconnection of the device from the supply voltage during emergency operation.

The capacitor 50 is designed to increase the response time and release the relay 29,

The capacitor 19 is designed to smooth out the pulsations of the rectified voltage supplied to the relay 11.

The capacitor 55 smoothes the ripple of the rectified voltage supplied to the switching device 4.

5 Diodes 18 and 45 are designed to separate the supply voltages of the relay 11 and the switching device 4, respectively, and the voltage received from the rectifier .....

0 A diode 47 is intended to create a positive bias at the emitter of the transistor 49 ..

Diode 51 protects the collector-emitter junction of transistor 49 from breakdown.

5 A system that implements the expansion of functionality due to the introduction of a switch of the type of work included in the circuit between the anode of the first diode of the switching device and the positive output.

0 terminal, contains a switch 46 kind of work included in the circuit between the anode of the first diode 45 of the switching device and the output plus terminal 33. The device operates as follows.

The operation of the device according to the structural diagram (figure 1) in the mode Zar.post. Switch 46 kind of work is open. When the device is connected to the mains, the output of the power source 1 appears

rectified full-wave voltage supplied to the first input of the regulating unit 2, which forms at its output the full-wave voltage pulses with the cut-off front part. The degree of clipping is regulated by the same block. The cut-off pulses arrive at the terminals for connecting the battery 3, charging it.

In the regime Pepper, (switch 46 closed) the device operates as follows ..

When the voltage at the battery terminals 3 reaches a predetermined threshold, for example, 15 V (On), the switching device 4 is made according to the two-threshold device scheme, which disconnects the regulating unit from the battery, connecting the discharge device 5 to it. Battery begins to unload. When the battery reaches a lower threshold voltage, for example 13 V, the threshold device automatically disconnects from the battery, simultaneously connecting the regulating unit to it and disconnecting the discharge device.

Control device 6 is designed to control the charge and discharge current of the battery, as well as the voltage at its terminals.

The protection device 7 serves to protect the device against short-term loss of the supply voltage, short-circuit of the output terminals and incorrect (reverse) connection of the battery to them.

The operation of the device in principle is as follows: turn the switch 46 to the open state, which corresponds to the mode Zar.post.

When the device is connected with the T2 button to the mains, at the output of the full-wave rectifier entering the power source 1, a rectified full-wave voltage appears, which through the diode 18 supplies the winding of the electromagnetic relay 11, which causes its normally open contact 10 to close and button 12 is locked, capacitor 19 is charging.

Under the influence of a straightened ex. from the output of the full-wave rectifier, an open-circuit emitting diode of the thyristor optocoupler 27 is formed; plus full-time rectifier output; resistors 35 and 37; emitting diode thyristor optocouple 27; minus output of full-wave rectifier; as a result, the photo thyristor of the thyristor optocoupler opens.

Under the influence of the trapezoidal pulsating voltage, the amplitude of which is determined by the stabilization voltage of the Zener diode 21, the capacitor 25 is charged through the resistor 23. When the voltage on the capacitor 25 exceeds the voltage on the adjustable resistor 24, the transistor 22 opens in the following circuit: positive output of a full-wave rectifier tel; adjustable resistor 24; emitter - collector of transistor 22; resistor 26; open photo thyristor thyristor optocoupler 27; contact 28; switching contact 30 of relay 29, control electrode

5 - cathode unidirectional thyristor key 31; reference resistor 32; battery 3; negative output of the full-wave rectifier, unidirectional thyristor switch 31 is opened,

0, a current flows from the remaining part of the half-wave of the supply voltage through the battery.

After the end of the half-wave of the supply voltage, the unidirectional thyristor key 31 is closed, and into the next half-wave of the supply voltage, the process is repeated, which leads to a gradual charging of the battery 3, Changing the resistance value of the adjustable resistor

0 24, you can open the thyristor 31 for

the time following the half-wave feed

voltage, compartment of its front,

those. change the firing angle of the thyristor.

The operation of the device in the training mode, for which we translate the switch 46 in the closed position, which corresponds to the charge transfer ..

The battery is charged in the same way as in the Charger mode. When the voltage of a given threshold is reached, for example, 15 V (on), the transistor 49 is opened at the battery terminals: a positive terminal 33 for connecting the battery; switch 46; di5 od 45; shunted resistor 53, adjustable resistor slider 52; base-emitter of transistor 49, diode 47; minus output of full-wave rectifier. When the collector current becomes

0 is enough to trigger the electromagnetic relay 29, it is triggered, contact 54 is closed and the opening current of the transistor increases to saturation, contact 30 switches from position 28 to position 34. the control electrode of the unidirectional thyristor switch 31 is switched to its cathode, which causes closing last at the end of the half-wave supply voltage. The battery charge stops;

The contact 40 of the relay 29 is opened and a charge circuit of the capacitor 42 is formed: the positive output of the full-wave rectifier; resistor 43; diode 41; capacitor 42; the control electrode is the cathode of the thyristor 38; bottom lamp 50; the minus output of the full-wave rectifier, with a charge of charge current, the thyristor 38 opens. A battery discharge circuit 3 is formed: a positive terminal 33, a reference resistor 32, a thyristor 38, a discharge lamp 39, a negative terminal for connecting a battery.

The voltage at the battery terminals begins to decrease and when the voltage reaches a lower threshold value, for example 13 V (11 V), the opening current through the transistor 49 becomes less than the closing current flowing through the circuit: a positive terminal for connecting the battery; switch 46; diode 45; resistor 48; emitter-base transistor 49; the slider of the adjustable resistor 52, the minus output of the full-wave rectifier, the transistor 49 is closed, the relay 29 is turned off. Its contacts 30, 40 and 54 return to their original state, which, when: leads to the connection of the battery to the charging circuit, and the process is cyclically repeated. Through the closed contact 40, the capacitor 42 with its discharge current closes the thyristor 38.

With the resistance of the resistor 53, you can change the position of the upper threshold (On) of the two-threshold device.

By changing the position of the slider of the adjustable resistor 52, it is possible to move the lower threshold of operation (Tachl.) Of the two-threshold device.

In case of loss of supply voltage, i.e. at the moment when the battery is discharged to the lamp 39, the closed contact 40 closes the thyristor 38 to eliminate the uncontrolled discharge of the battery, and the relay 11, power loss, unlocks the button 12, not allowing the charger to automatically turn on again on the mains voltage.

In the short-circuit mode, the output terminals 44 and 33 are short-circuited, and a short circuit is formed which shunts the power supply circuit of the emitting diode of the thyristor optocoupler 27, which will result in locking the emitting diode and the photothyristor of the thyristor optocoupler 27, causing the unidirectional thyristor switch 31 to turn off.

In this case, the power supply circuit of the electromagnetic relay 11 will be shunted, which will lead to its de-energizing and opening of the contact 10.

In the case of incorrect (reverse) connection of the battery to the output terminals 5 and 44, a circuit is formed to pass the closing current of the thyristor optocoupler 27: the positive terminal of the battery 3, the radiating diode of the thyristor optocoupler 27; resistor 37; diode 36;

0 reference resistor 32; the minus terminal of the battery 3, thereby prohibiting the inclusion of a unidirectional thyristor switch 3.1.

The charge and discharge current is controlled by

5 voltage drop on the reference voltage: a stop 32 with a microammeter 56, which is connected across the contacts 57, 59 of the measurement switch and a limiting resistor 58 parallel to this resistor, and during voltage monitoring the microammeter 56 is connected through the contacts 57, 61 of the measurement switch, auxiliary resistor 60 parallel to the battery pack.

5 The degree of charge of the battery is also controlled by the discharge lamp 39.

FORUMAWLAH AND ISLANDS

Claims (3)

1. A method for restoring a weakly sulphated rechargeable battery, including cyclic charge and battery discharge, the battery being charged to a predetermined maximum Umax power at its terminals, and the discharge to 5 of the specified minimum voltage UMHH, characterized in that, in order to reduce the recovery time, the maximum charge voltage is chosen within 14.7-15.3 V, and the minimum discharge voltage is within UMHH -12.9 -13.5 V. 2. A system for recovering a weakly sulfated battery containing a power supply to 5 full-wave rectifier, regulating unit, output terminals, switching device with an electromagnetic relay at the output, a discharge device and a protection device, and regulating 0 the first input unit is connected to the first output of the power source, the second input to the output of the protection device, the third input to the first output of the switching device, the output of the regulating unit co5 is unified with the output terminals and the first input of the discharge device, the second input of which is connected to the second output switching device, the power to which comes from the second output of the power source, characterized in that In order to improve energy performance, the switching device is made according to the scheme of a two-threshold device connected to the output terminals, the first output of which is connected to the regulating unit, the second output - to a discharge device, the regulating unit contains a resistor and a zener diode connected in series direction to the pole output, and the resistor to the minus output of the power source, the transistor, the basic output of which is connected via a resistor to the serial connection point resistor and zener diode, and the emitter output through an adjustable resistor to the positive output of the power source, a capacitor connected by one output to the base terminal of the transistor, and the other to the positive output of the power source, a resistor connected to the collector output of the transistor the stator optocoupler of the protection device, the cathode of the photothyristor is connected to the opening contact of the first switching contact group of the relay of the switching device, and its fixed contact is connected to the control a unidirectional thyristor switch, the power electrodes of which are included in the battery charge circuit, while the thyristor switch is connected through the reference resistor in the forward direction to the positive output terminal and to the negative output of the power source, the transistor whose basic output is connected through a resistor to point of the series connection of the resistor and the Zener diode, and the emitter output through an adjustable resistor to the positive output of the power source, a capacitor connected by one output to the main output the transistor, and the other to the positive output of the power source, a resistor connected to the collector output of the transistor and to the anode of the phototransistor of the protection device, the cathode of the photothyristor is connected to the break contact of the first switching contact of the relay of the switching device, a. its fixed contact is connected to the control electrode of a unidirectional thyristor switch, the power electrodes of which are included in the battery charge circuit, while the thyristor switch is connected through the reference resistor in the forward direction to the positive output terminal and to the closing contact of the first switching contact of the relay devices connected in series with a thyristor switch are a series-connected resistor and diode, while the diode is connected to the cathode of the unidirectional thyristor switch by its cathode, and the anode through the resistor to the anode of the emitting diode of the thyristor optocoupler of the protection device, the cathode of the latter is connected to the minus output of the power source, the discharge device contains a resistor, the anode output of which is connected through a reference resistor to the positive output terminal, and the cathode is connected through a discharge lamp to the negative output and power supply and through the disconnecting contact of the contact group of the relay of the switching device to the point of the serial connection of the diode and capacitor, while the second output the capacitor is connected to the control electrode of the thyristor, and the diode with its anode through a resistor is connected to the positive output of the power source, the negative output terminal is connected to the negative the power supply output, the switching device contains a common wire connected to the cathode of the first diode, which is connected by its anode to the positive output terminal, a series-connected resistor and a second diode, while the diode is connected in the forward direction to the negative output of the power source, and the resistor is connected to common wire transistor, the emitter terminal of which is connected to the point of series connection of the resistor and the second diode, and the collector output through the relay winding - to the common wire, parallel to the relay winding are connected a parallel-connected capacitor and a third diode, while the third diode is connected by anode to the collector output of the transistor, connected in series by an adjustable resistor and bypass make contact the third contact group of the relay, while the shunt resistor is connected by another output to the common wire, the adjustable resistor is connected to the minus output of the power supply, and its slider is connected to the base the output of the transistor, and a capacitor, one output of which is connected to the common wire, and the other to the negative output of the power source. 3. The system according to claim 2, characterized by by the fact that, in order to expand the functionality, a type of work switch is inserted into it, connected to the circuit between the anode of the first diode of the switching device and the output positive terminal. Fy R