WO2014031028A1

WO2014031028A1 - Electric power supply method and device for carrying out said method

Info

Publication number: WO2014031028A1
Application number: PCT/RU2013/000465
Authority: WO
Inventors: Александр Владимирович АККУРАТОВ; Кирилл Сергеевич БАЛУЕВ; Сергей Михайлович ЛОКТЕВ
Original assignee: Akkuratov Alexander Vladimirovich; Baluev Kirill Sergeevich; Loktev Sergei Mikhailovich
Priority date: 2012-08-20
Filing date: 2013-05-30
Publication date: 2014-02-27
Also published as: RU2012136401A; RU2531806C2

Abstract

The method and the device are intended for ensuring an electric power supply for consumers from an electrical supply network, from renewable energy sources and from combinations thereof. The method and device can be used in the production both of personal and of industrial electric power supply systems. The problems addressed by the inventions consist in increasing the quality and efficiency of continuously supplying electric power supply to consumers. The technical results include increasing the operating life of accumulators, ensuring an electric power supply for a consumer at a constant voltage exceeding the voltage of sources, galvanic separation between the sources and the consumers, and use of low-voltage accumulators with small capacities. In the electric power supply method, in which the direct-current voltage of a source is stabilized with the aid of stabilizers with galvanic separation up to a voltage level for charging an accumulator, parallel charging of consecutively connected accumulators is carried out with the aid of stabilizers, and the electric power supply input is fed to a consumer from terminals formed by the consecutively connected accumulators.

Description

The method of power supply and a device for its implementation The method and device are designed to provide power to consumers from the mains, from renewable energy sources and their combinations. The method and device can be used to create both personal and industrial power supply systems.

Due to the relevance of issues of power supply to consumers with capacities in excess of the maximum allowable network capacity, systems have appeared that provide energy storage and energy supply from the drive at the time of increasing energy consumption.

Known analogues are the method of accumulation and distribution of electricity and the system of accumulation and distribution of electricity (RF Patent N ° 2298867, publ. 10.05.2007). A method of accumulation and distribution of electricity for domestic and industrial consumers, which includes the following operations: using an alternating current electric power source; the use of at least one capacitor having a high storage capacity, which is connected to the specified source and to the network for the use of electricity by consumers; converting electricity from a source into direct current energy and transferring it to said at least one capacitor to charge it during a period of low power consumption from said source; transferring at least a portion of said electric energy stored in the capacitor after it is converted into alternating current energy to a load connected to the indicated energy use network by the consumer during a period of high electricity consumption; and repeating charging and discharging said capacitor during periods of low and high power consumption, respectively.

The system of accumulation and distribution of electricity for household and industrial consumers, which includes: an alternating current electric power source; at least one capacitor having a high storage power connected to said source and to at least one consumer energy network via an electric power distribution system; the transmission path of part of the electricity from the specified source to the specified capacitor for energy storage in the period of low consumption; a device for converting AC electricity from the specified source into DC electricity for storage in a capacitor; a transmission path for at least a portion of said electric energy stored by the capacitor to the electric power distribution system during a period of high power consumption; a device for converting direct current electric power stored in a capacitor into alternating current electric power for supplying to an electric power distribution system; and instrumentation to ensure that the capacitor is automatically connected to a power source and to a power distribution system.

Common features with the claimed invention are: the use of a drive, the conversion of electricity from a source into direct current energy, charging a drive, transferring energy to a load, using inverters.

The indicated method and system imply increased requirements for energy sources at the input (the capacitor must be charged with a powerful pulse of the input current), require the use of complex, expensive capacitors.

The closest analogues to the claimed invention (prototypes) are: A method of uninterrupted power supply to consumers of an electric power system operating on renewable energy sources and an electric power system (RF Patent j \ b 2153752, publ. 27.07.2000). The method includes converting the energy of a primary renewable source into alternating current electric energy using an electric generator, converting alternating current electric energy into direct current electric energy by a rectifier, storing this energy in a battery charged from a rectifier, converting direct current electric energy into electric energy using an inverter alternating current and its delivery to the consumer load, while the amount of accumulated energy in the accumulator e determined capacity which are calculated from the daily consumption of the consumer load. The electric power system contains sources of electricity - generators based on renewable energy sources, rectifiers, stabilizers, interconnected and with a common drive, the drive is connected to the inverter. Common features with the claimed invention are: conversion by means of a rectifier of electric energy of alternating current into direct current electric energy, accumulation of this energy in a battery charged from a rectifier, conversion by means of an inverter of electric current of direct current into electric energy of alternating current and its delivery to a consumer load, use of battery, stabilizers, rectifiers, inverters.

The method and system selected by the prototypes do not allow the generation of voltage at the system output above the input voltage. They require that the voltage level at the output of renewable sources constantly exceed or be equal to the minimum necessary level to ensure a given voltage at the outputs of the drive, they do not allow to limit the amount of base power consumed. The battery operates in a mode incapable of its longevity.

The objective of the invention is to improve the quality and efficiency of uninterrupted power supply to consumers.

Technical results are including:

- an increase in the service life of the batteries due to the constant flow of current through them, which is the difference between the discharge current and the charge current;

- reduction of requirements for the level of voltage sources;

- minimization of the capacity of drives (batteries);

- increase maintainability, including by providing the ability to replace batteries without shutting down the system;

- increase in power given to the consumer by removing from the "upper" groups of batteries;

- limitation of power (current) consumption;

- minimization of the basic (installed) power consumption, based on the daily consumption of electricity by consumers;

- increased reliability, durability.

In addition, other technical results are achieved, including providing the ability to:

- power supply to the consumer with both alternating and direct voltage exceeding the voltage of the sources; - filing a number of different voltages for the consumer;

- supplying the consumer with capacities exceeding the base capacities of the sources;

- use of a step-by-step inverter, if necessary, supplying an alternating current to the consumer;

battery replacement during system operation (maintainability);

- galvanic isolation between sources and consumers;

- the use of low-voltage batteries with small capacities;

- for the consumer - to receive the maximum necessary power during the period of consumption (days);

- the use of several energy sources with different voltage values and kinds of currents;

- minimization of the basic capacities of the network source;

- use of low-voltage elemental base.

The method of power supply, in which the DC voltage of the source is stabilized using stabilizers with galvanic isolation to the level of the battery charge voltage, with the help of stabilizers, parallel connected batteries are charged, the consumer is supplied with power from the poles formed by the batteries connected in series.

When implementing the proposed method, current will constantly flow through the batteries, which is the difference between the discharge current and the charge current, which will provide a significant increase in battery life.

When implementing the proposed method for charging each battery from a source, a voltage equal to the charge voltage (out) of the battery will be required. The series connection of the batteries allows the consumer to give an output constant voltage (s) greater than the voltage of the source by summing the output voltages (s) of the series-connected batteries. It is possible to form a number of stresses.

Since in the implementation of the method series-connected batteries are used, their capacity is minimized. If it is necessary to replace the battery, it can be removed during system operation, as at the poles to which the withdrawn battery was connected, the stabilized voltage will continue to flow and the series connection of the batteries will not be disturbed. Distribution of the source energy on a number of batteries allows the use of low-voltage low-cost batteries and at the same time ensures sufficient storage capacity.

In the method, batteries can be used, the capacity of each of which can be selected not less than the value calculated by the formula:

Ca = WcyT./ Ch. Cons., where

Ca - battery capacity, A * h;

Wcyr. - daily consumption of electricity by the consumer, Wh * h;

activities. consumer - the effective voltage required by the consumer, V.

During the day, the power required by the consumer can vary greatly. Having received from the consumer information about the daily consumption (Wcyr.) Of electricity, it is possible to use a battery with a minimum capacity that provides the consumer with the opportunity to receive the necessary power during the consumption period (days).

In the method, it is possible to supply power to the consumer from the poles formed by the series-connected batteries through an inverter or a step inverter. This will provide the consumer with alternating voltage, and in the case of a stepped inverter - with alternating voltage of high quality. When using a step inverter in the method, the consumer can be supplied with power in addition to the output of the step inverter from the poles of the batteries in series connection closer to the positive pole of the row.

Due to the fact that the discharge of batteries located closer to the positive pole of a sequential row is carried out at a slower pace than the discharge of batteries located closer to the negative pole of a sequential row, this will allow to discharge the entire row more uniformly and remove constant voltage from the drives. With this variant of the method, voltage from the upper groups of batteries can be supplied to at least one transformer inverter to provide the consumer with additional AC power. In the method of power supply to stabilization can limit the voltage of the source current in the limiter, in case of exceeding the threshold voltage value, and the conversion of the current source to constant in the rectifier. This will allow the use of renewable energy. Such a restriction will improve reliability and protect the power supply system and the consumer from overvoltages characteristic of some renewable sources of electricity, for example, wind power plants.

In the method, the summed current of several sources with different voltage values and types of currents can be used as the source current, and the voltage of each source before being fed to the adder is limited in the limiter, if the threshold value is exceeded, and converted to constant in the rectifier. When implementing this method, you can use a combination of renewable sources as energy sources.

In the method, the summed current of renewable energy sources, mains current, and diesel generator can be used as the source current, while the voltage of each renewable source is limited in the limiter before being fed to the adder, if the threshold value is exceeded, and converted into a constant current in the rectifier, and the network current the source and diesel generator are limited in the current limiter, if the threshold value is exceeded, and converted into a constant in the rectifier. When implementing this method, it is possible to use a combination of renewable sources as energy sources and supplement them with a network source and a diesel generator.

In the method before stabilization, in case the source current exceeds a threshold value, it is possible to limit the source current to a level below the threshold and rectify it. Moreover, due to the fact that the batteries remain continuously included in the energy transfer path to the consumer, the consumer load will be redistributed to the batteries, and the consumer will continue receive the power it needs, which will be the sum of the source current (up to In) and the current consumed from the batteries.

This will allow, at peak load, to provide the consumer with capacities that exceed the basic capacities of the network source and not exceed the limit on the network capacity.

In this case, the threshold current value can be selected no higher than the value calculated by the formula:

In = Wc r. * 1, 2 / (24 * Networks), where

In - threshold current value, A;

Wcyr. - daily consumption of electricity by the consumer, Wh * h;

activities. mains - the effective voltage of the power supply network.

After receiving information about the daily consumption of electricity from the consumer (Wcyr.), It will be possible to minimize the threshold current value, and therefore minimize the basic capacities of the network source. In the method, the limitation of the source current to a level below the threshold can be achieved using a capacitor divider. A capacitor divider will simultaneously reduce voltage and provide current limitation. When implementing this method, it will be possible to use electronic components designed to operate with low voltage.

The method can be implemented using a power supply device, including voltage stabilizers with galvanic isolation and batteries, a separate battery is connected to the outputs of each voltage stabilizer with galvanic isolation, the batteries are connected in series and are made to remove voltage from the poles.

The device can be implemented with the following features.

The capacity of each battery is not less than the value calculated by the formula:

Ca = Wcyr./ id. Cons., where

Ca - battery capacity, A * h;

Wcyr. - daily consumption of electricity by the consumer;

activities. consumer - current voltage required by the consumer. An inverter is connected to the battery poles.

A stepped inverter is connected to the poles of the batteries.

Batteries located in series connection closer to the positive pole of the row are configured to relieve voltage to power the consumer.

The device contains at least one transformer inverter connected to the poles of the battery located in series connection closer to the positive pole of the row.

In addition, in the case of using a renewable source, the device itself, as well as devices with the features mentioned above, can be supplemented with the following. The device contains a series-connected voltage limiter and a rectifier, the output of which is connected to the inputs of stabilizers with galvanic isolation.

The device contains at least two circuits of series-connected voltage limiter and rectifier, a current adder, the output of which is connected to stabilizers, and the inputs are connected to the outputs of circuits of series-connected voltage limiters and rectifiers.

The power supply device contains circuits of series-connected voltage limiter and rectifier, circuits of series-connected current limiter and rectifier, current adder, the output of which is connected to stabilizers, and inputs are connected to outputs of circuits of series-connected voltage limiters and rectifiers, current limiters and rectifiers.

Circuits of series-connected voltage limiter and rectifier, current limiters and rectifiers and current adder are structurally combined into a matching unit.

In the case of using a network power source, the device itself, as well as devices with the features indicated above, can be supplemented with the following.

The device contains a series-connected current limiter and a rectifier, the output of which is connected to the inputs of the stabilizers.

The device contains a current limiter, the threshold current (In) of which is a value not exceeding the value calculated by the formula:

1n = \ Host. * 1,2 / (24 * Local networks), where In - threshold current value, A;

Wcyr. - daily consumption of electricity by the consumer, Wh * h;

activities. mains - the effective voltage of the power supply network.

The power supply device contains circuits of series-connected capacitor dividers and rectifiers, structurally combined into a matching unit, the output of the capacitor dividers is connected to the inputs

isolation stabilizers.

The method and device are illustrated by the following figures.

FIG. 1 is a diagram of a power supply device.

FIG. 2 is a diagram of a power supply device in the case of a renewable energy source.

FIG. 3 is a diagram of a power supply device in the case of a combination of renewable energy sources and a network.

FIG. 4 - matching unit for a combination of renewable energy sources.

FIG. 5 - matching unit for a network power source.

FIG. 6 - matching unit on capacitor dividers for a network power source.

The method can be implemented using the device of figure 1, which can be used to power the consumer with direct current, using a constant current source.

A power supply device including voltage stabilizers 1 with galvanic isolation and batteries 2, a separate battery 2 is connected to the outputs of each voltage stabilizer 1 with galvanic isolation, batteries 2 are connected in series and are made to remove voltage from the poles. Thus, battery-stabilizer pairs are formed.

Low voltage batteries can be used, which will require a minimum voltage level from the source. For example, when using 12 V batteries with a charge voltage of 13 V from the source, it will be necessary to maintain a voltage of at least 13 V, while the consumer will be able to receive a number of voltages from the poles, including 12, 24, 36, 48 ... 380 V. The capacity (Ca) of each battery 2 can be selected not less than the value calculated by the formula:

Ca = WcyT./ id. consumer where

Wcyr. - daily consumption of electricity by the consumer;

activities. consumer - current voltage required by the consumer.

For example,

WcyT. = 10 kWh;

activities. Consumption = 220 V;

Ca = 10000/220 = 45 A * h.

Such a capacity will guarantee the supply of 10 kWh per day to the consumer, while during peak loads the device can give off power significantly exceeding the maximum source power.

At the input of the device, direct current can be supplied from a source such as solar panels.

The source current is distributed between the stabilizers 1 with galvanic isolation. Stabilizers 1 maintain the voltage value within the specified permissible limits, ensuring the charge of the batteries 2 and excluding overvoltage and ripple at the inputs of the latter. When you turn on the system for the first time without load at a stabilized voltage from stabilizers 1, the batteries 2 are charged by current from sources. When the load is connected, the batteries 2 are charged with a current equal to the difference between the current supplied from the stabilizer 1 and the consumer load current, and in the case when the stabilizer current is less than the consumer load current, the batteries are discharged.

Current from poles formed by series connection of batteries

2, enters the load to the DC consumer.

The accumulators 2 are constantly under voltage of the stabilizers, while a current equal to the current consumption of the load flows through the accumulators 2.

At peak load currents exceeding the source current, the discharge of the batteries 2 into the common consumer load circuit begins for the equation of currents in the consumer load circuit and the electric energy source circuit, i.e. The source current and the battery discharge current are summed. In emergency situations, in the circuits of the electric energy source and the connection of the consumer load, the discharge of the batteries 2 also begins with the supply of the discharge current to the consumer load circuit. In this case, the maximum emergency time will be equal to the maximum discharge time of the batteries 2.

The method can be implemented using the device of figure 2, which allows you to work with a renewable energy source.

The device may further include series-connected voltage limiter 3 and a rectifier 4, the output of which is connected to the inputs of stabilizers 1 with galvanic isolation.

The method can be implemented using the device of FIGS. 3, 4, which allows working with a combination of renewable energy sources and a network.

The device may additionally include (Fig. 4) circuits of series-connected voltage limiter 3 and rectifier 4, series-connected current limiter 5 and rectifier 4, current adder 6, the output of which is connected to stabilizers 1, and the inputs are connected to the outputs of circuits of series-connected voltage limiters 3 and rectifiers 4.

Circuits of series-connected voltage limiter 3 and rectifier 4, series-connected current limiter 5 and rectifier 4, and current adder 6 are structurally combined into a matching unit 7.

In the device to the poles of the batteries 2 is connected to a step inverter 8.

The device comprises a transformer inverter 9 connected to the poles of one of the batteries 2 located in series connection closer to the positive pole of the row. A load of 10 is connected to the device outputs from a step-by-step inverter, and a load of 1 1 is connected from a transformer inverter.

Renewable energy sources (solar panels, a wind turbine, a hydraulic unit,), a diesel generator and a network supply electric energy with any voltage and type of current (alternating, constant, pulsed) to the matching unit 7.

In matching block 7, the voltage of renewable sources, if it is exceeded, can be limited by voltage limiters 3. Then the current is rectified in rectifiers 4. The current of the diesel generator and network, if it is exceeded, is limited by current limiters 5. The currents of all sources are summed in the current adder 6. The resulting current is distributed between the stabilizers 1 with galvanic isolation. Stabilizers 1 maintain the voltage value within the specified permissible limits, ensuring the charge of the batteries 2 and eliminating overvoltage and ripple at the inputs of the latter, as well as the inputs of the step-by-step inverter 8. When the system is switched on for the first time without load, the stabilized voltage from stabilizers 1 carries out current charging from sources. When the load is connected, charging of each battery 2 is carried out by a current equal to the difference between the current coming from the stabilizer 1 and the consumer load current, and in the case when the stabilizer current is less than the consumer load current, the batteries are discharged.

Rectified (direct current) is converted by a step inverter 7 into an alternating one with the formation of a pseudo-sinusoid and fed to the load 9 of the consumer.

From transformer inverters 8, the current enters the additional load of the consumer 16.

The batteries 2 are constantly energized by the stabilizers 1, while a current equal to the current consumption of the load flows through the batteries 2.

At peak load currents exceeding the total total current of all sources of electric energy, the discharge of the batteries 2 into the general consumer load circuit begins to equate the currents in the consumer load circuit and the electric energy source circuit, i.e. The source current and the battery discharge current are summed.

In emergency situations in the circuits of electric energy sources and connecting the total load of the consumer, the discharge of the batteries 2 also begins with the supply of the discharge current of the latter to the consumer's load circuit to balance the load current. In this case, the maximum emergency time will be equal to the maximum discharge time of the batteries 2. Failure of all sources is unlikely, and with an output of 1-3 sources, the rest will make up for the lack of power. In the case of using a network source or a diesel generator, the implementation of the method is possible by means of a device with a matching unit of FIG. 5 or 6.

In this case, the power supply device may include (similarly to the device of FIG. 3) a matching unit 7, stabilizers 1 with galvanic isolation, batteries 2, a step inverter 8 with the possibility of forming a pseudo-sinusoid, transformer inverters 9, the matching unit 7 contains a current limiter 5, a rectifier 4 , the current limiter 5 is connected to the rectifier 4, which is connected to the stabilizers 1, each stabilizer 1 with galvanic isolation is connected to a single battery 2, the batteries 2 are interconnected consequently and made with the possibility of stress relief from the poles. The transformer inverter 9 is connected to the pole of the battery located in series connection closer to the positive pole of the row. The input of the matching unit 7 is connected to a 220 V network or a diesel generator.

At the output of the device, loads 10 and 1 1 of the consumer are connected.

The capacity of each battery 2 can be selected as described above.

The threshold current of the current limiter 5 can be set to a value not exceeding the value calculated from the formula:

1n = \ ^ days. * 1, 2 / (24 * Networks), where

Wcyr. - daily consumption of electricity by the consumer, Wh * h;

activities. Networks - the current voltage of the power network, V.

For example,

Wcyr. = 10 kWh;

activities. Consumption = 220 V;

1n = 10000 * 1.2 / (24 * 220) = 2.27 A.

When choosing such a threshold current, the power consumed from the network will be limited to 499.4 W, providing the consumer at the device output with the required power that exceeds the network capacity limits.

The network power source supplies electrical energy with a voltage of 220 V to the matching unit 7. In matching block 7, the current of the network source, if it is exceeded above the threshold, can be limited by the current limiter 5 to a value below the threshold. Then the current is rectified in the rectifier 4. The resulting direct current is distributed between the stabilizers 1 with galvanic isolation. The stabilizers 1 maintain the voltage value within the specified permissible limits, ensuring the charge of the batteries 2 and eliminating overvoltage and ripple at the inputs of the last and step inverters 8. Further operation of the device is similar to the operation of the device of FIG. 3 described above.

In the case of using capacitor dividers 12 (in FIG. 6), they simultaneously serve as a current limiter and a matching element, which allows lowering the voltage to the battery charge voltage, which makes it possible to use a low-voltage element base.

Claims

Formula

1. The method of power supply, in which the DC voltage of the source is stabilized using stabilizers with galvanic isolation to the level of the battery charge voltage, with the help of stabilizers, parallel-connected batteries are charged in parallel, power is supplied to the consumer from the poles formed by the batteries connected in series.

2. The method of power supply according to claim 1, characterized in that the batteries are selected, each of which has a capacity of not less than the value of Ca, calculated by the formula:

Ca = WcyT./ Ass. Cons., where

Ca - battery capacity, A * h;

Wcyr. - daily consumption of electricity by the consumer, Wh * h;

activities. consumer - the effective voltage required by the consumer, V.

3. The method of power supply according to claim 1, characterized in that the consumer is supplied with power from the poles formed by the batteries connected in series through the inverter.

4. The method of power supply according to claim 1, characterized in that the consumer is supplied with power from the poles formed by the batteries connected in series through a step-by-step inverter.

5. The method of power supply according to claim 4, characterized in that the power supply to the consumer, in addition to the output of the stepwise inverter, is also supplied from the poles of the batteries in series connection closer to the positive pole of the row.

6. The method of power supply according to claim 4, characterized in that the power supply to the consumer, in addition to the output of the stepwise inverter, is also supplied from the poles of the batteries in series connection closer to the positive pole of the row through transformer inverters.

7. The method of power supply according to any one of claims 1 to 6, characterized in that prior to stabilization, the voltage of the source in the limiter is limited, if the threshold voltage is exceeded, and the source current is converted to constant in the rectifier.

8. The method of power supply according to claims 1 to 6, characterized in that the summed current of several sources with different voltage values and types of currents is used as the source current, while the voltage of each source is limited in the limiter before being fed to the adder, if the threshold is exceeded values, and convert to constant in the rectifier.

9. The method of power supply according to claims 1 to 6, characterized in that the summed current of renewable energy sources, mains current and diesel generator is used as the source current, while the voltage of each renewable source is limited in the limiter before being fed to the adder, if the threshold is exceeded values, and are converted to constant in the rectifier, and the current of the mains source and diesel generator is limited in the current limiter, if the threshold value is exceeded, and converted to constant in the rectifier,

10. The method of power supply according to claims 1 to 6, characterized in that before stabilization, in case the current exceeds the threshold value, the current of the source is limited to a level below the threshold and rectified.

1 1. The method of power supply according to claim 10, characterized in that the threshold current value (In) is set not higher than the value calculated by the formula:

In = WcyT. * 1, 2 / (24 * Networks), where

In - threshold current value, A;

Wcyr. - daily consumption of electricity by the consumer, Wh * h;

Tsstsev. network - the current voltage of the power network, V.

12. The method of power supply under item P, characterized in that the limitation of the source current to a level below the threshold is carried out using a capacitor divider.

13. The power supply device, including voltage stabilizers with galvanic isolation and batteries, a separate battery is connected to the outputs of each voltage stabilizer with galvanic isolation, the batteries are connected in series and are made to remove voltage from the poles.

14. The power supply device according to item 13, wherein the capacity of each battery is not less than the value of Ca, calculated by the formula: Ca = Wcyr./ id. consumer where

Ca is the battery capacity, A * h;

Wcyr. - daily electricity consumption by the consumer, W;

activities. consumer is the effective voltage required by the consumer, V.

15. The power supply device according to item 13, wherein the inverter is connected to the poles of the batteries.

16. The power supply device according to item 13, characterized in that a step inverter is connected to the poles of the batteries.

17. The power supply device according to clause 16, characterized in that the batteries located in series connection closer to the positive pole of the row are made with the possibility of relieving voltage to power the consumer.

18. The power supply device according to clause 16, characterized in that it contains at least one transformer inverter connected to the poles of the battery in series connection closer to the positive pole of the row.

19. The power supply device according to any one of paragraphs.13-18, characterized in that it contains a series-connected voltage limiter and a rectifier, the output of which is connected to the inputs of stabilizers with galvanic isolation.

20. The power supply device according to any one of paragraphs.13-18, characterized in that it contains at least two circuits of series-connected voltage limiter and rectifier, a current adder, the output of which is connected to stabilizers, and the inputs are connected to the outputs of the circuits of series-connected voltage limiters and rectifiers .

21. The power supply device according to any one of paragraphs.13-18, characterized in that it contains circuits of series-connected voltage limiter and rectifier, circuits of series-connected current limiter and rectifier, current adder, the output of which is connected to stabilizers, and the inputs are connected to the outputs of circuits in series connected voltage limiters and rectifiers, current limiters and rectifiers.

22. The power supply device according to item 21, wherein the circuit is connected in series with a voltage limiter and a rectifier, current limiters and rectifiers and a current adder are structurally combined into a matching unit.

23. The power supply device according to any one of paragraphs.13-18, characterized in that it contains a series-connected current limiter and a rectifier, the output of which is connected to the inputs of the stabilizers.

24. The power supply device according to any one of paragraphs.13-18, characterized in that it contains a current limiter, the threshold current (In) of which is a value not exceeding the value calculated by the formula:

In = WcyT. * L, 2 / (24 * UfleftcTB. Networks), where

In - threshold current value, A;

Wcyr. - daily consumption of electricity by the consumer, Wh * h;

Tsstsev. network - the current voltage of the power network, V.

25. The power supply device according to item 23, wherein the current limiter and the rectifier are structurally combined in a matching unit.

26. The power supply device according to any one of paragraphs.13-18, characterized in that it contains circuits of series-connected capacitor dividers and rectifiers, structurally combined into a matching unit, the output of the capacitor dividers is connected to the inputs of the stabilizers with galvanic isolation.