RU2474031C2 - Method and device for electrical energy transmission (versions) - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: method for electrical energy transmission consists in development of resonant oscillations from a frequency converter in a circuit comprising two resonant circuits, two high-frequency transformers and a single-wire line between them, and transmission of resonant oscillations from a resonant circuit of the first high-frequency transformer to the resonant circuit of the second high-frequency transformer along a single-wire electric line insulated from ground, conversion of high frequency current into DC and then in an inverter into AC of industrial frequency. Electrical energy is transmitted symmetrically along a single-wire line in both directions by development of resonant oscillations from a converter-inverter at each side of the line, conversion of high-frequency current into DC and then into AC of industrial currency in a converter-inverter at each side of the single-wire line. The frequency converter is used as an inverter when receiving electrical energy, and the inverter is used as a frequency converter when transferring electrical energy.EFFECT: higher efficiency of energy transmission, increased length of transmission lines and possibility to transfer power along a single-wire line in two directions between two power systems, which reduces losses in process of electrical energy transfer to stationary and mobile loads and electrical vehicles, and provides for the possibility of energy recuperation and its return into a grid when braking an electrical vehicle.12 cl, 7 dwg

Description

The invention relates to the field of electrical engineering, in particular to a method and apparatus for transmitting electrical energy.

A known method and device for transmitting electricity in a closed circuit, consisting of two or more wires, transformer substations and power lines (Power transmission of alternating and direct current. Electrical reference book. - Energoatomizdat. 1988. S.337-352).

The disadvantage of this method and device is the transmission of electrical energy in one direction from the generator to the energy consumer.

A reversible voltage converter is known for transferring electric energy between AC and DC networks, comprising three rectifier inverters with automatic control of the operation of a second inverter rectifier in the mode of transferring electricity from the AC network to the DC network of an automatic normal or accelerated battery charge of a DC voltage network current, automatic coordinated control of the third and first inverter-rectifier energy from the DC voltage mains with the battery to the AC voltage network (in the energy recovery mode, when the battery of the DC voltage network is discharged), automatic transition to the energy recovery mode after an emergency shutdown of the AC voltage source, automatic return, when restoration of voltage in the AC network, to the mode of transmission of electricity from the AC voltage network to the DC voltage network (Pat. RF №2343615, bull. No. 1, January 10, 2009).

A disadvantage of the known device and method is the loss in the lines, comprising from 5 to 20%, depending on the length of the power lines, and the high cost of equipment per 1 km of power line.

A known method and device for powering electrical devices using an alternating voltage generator connected to a consumer, characterized in that the voltage of the generator is supplied to the low voltage winding of the high-frequency transformer converter, and one of the terminals of the high-voltage winding is connected to one of the input terminals of the electrical device, while changing the frequency generators achieve the establishment of resonant oscillations in the formed electrical circuit.

A device that implements this method is an AC voltage source with an adjustable frequency, a high-frequency transformer, one output of the high-voltage section of which is isolated, and the second is designed to supply energy to the consumer (RF patent No. 2108649, 1998, S. Avramenko, Method for supplying electrical devices and device for its implementation).

A device for converting and transmitting electric energy through a single-wire line over a long distance, developed by N. Tesla in 1897, is known. According to the invention of N. Tesla, the device consists of two transformers, one to increase and the other to reduce the current potential, these transformers have a winding terminal with a long wire connected to the line, and another terminal of this winding adjacent to the winding from a shorter wire length, electrically connected to it and to the ground.

The step-up transformer has a primary winding connected to an increased frequency electric generator. The primary winding is wound on a secondary high-voltage winding, the wire length of which is much greater than the length of the primary winding and approximately equal to a quarter of the wavelength of the electromagnetic field in the line. In this case, the potential of one internal output of the high voltage winding is zero, and the potential of the other external output will be maximum. The inner end of the high voltage secondary winding is connected to the electric power transmission line, and the outer end of the secondary winding and the adjacent output of the primary winding are connected to earth for electrical safety purposes. The step-down transformer is made similarly. The findings of the low-voltage winding are connected to an electric load in the form of incandescent lamps and electric motors. A single-wire power line has long insulators on poles to reduce current leakage losses (N. Tesla. Electric transformer. US Pat. No. 593138 of November 2, 1897).

A known method and device for transmitting electrical energy by creating high-frequency resonant oscillations in a circuit consisting of a high-frequency generator and two high-frequency and Tesla high-frequency transformers, transmission of high-voltage potential and electric energy through a single-wire line to a Tesla step-down transformer, rectification of current and transmission of electric power load, the resonant oscillations of electromagnetic energy of wavelength λ = 2L _AB / n, where n - an integer, L _AB - length isolated from s A single-wire electric line transmits from a Tesla step-up high-frequency transformer a resonant circuit of a low-voltage winding of a Tesla step-up transformer to a resonance circuit of a low-voltage winding of a Tesla step-down transformer through a single-wire electrical circuit isolated from earth, convert the reactive current in a single-wire electric line isolated from earth to high-voltage alternating current frequency containing the vector sum of the active and reactive currents, which then in form a constant current that is converted into alternating current of industrial frequency (Pat. RF №2555406. Bull. No. 18, June 27, 2004)

The specified method and device have small losses in a single-wire line and the ability to transmit electrical energy over a long distance.

A disadvantage of the known methods and devices is the inability to transmit electrical energy in two directions along a single-wire line.

The objective of the invention is to increase the efficiency of energy transfer, increasing the length of transmission lines and the ability to transfer electricity through a single-wire line in two directions between two power systems.

As a result of the use of the present invention, the efficiency is increased and losses during the transmission of electric energy to stationary and mobile consumers and electric vehicles are reduced, and it becomes possible to recover energy and return energy to the network when braking an electric vehicle.

This result is achieved in that in a method for transmitting electrical energy by creating resonant vibrations from a frequency converter in a circuit consisting of two resonant circuits, two high-frequency transformers and a single-wire line between them, and transmitting resonant vibrations of electromagnetic energy from the resonant circuit of the first high-frequency transformer to the resonant the circuit of the second high-frequency transformer through a single-wire electrical line isolated from the earth, converting current into high-frequency into direct current and then in the inverter into alternating current of industrial frequency, the electric energy is transferred symmetrically along a single-wire line in both directions by creating resonant oscillations from the inverter-converter on each side of the line, converting the high-frequency current to direct current and then to alternating current industrial frequency current in the inverter-converter on each side of the single-wire line, while the frequency converter is used as an inverter when receiving electric th power, and an inverter is used as the frequency converter with power transmission.

In an embodiment of a method for transmitting electrical energy, electrical energy is transmitted along n-single-wire lines in both directions along each single-wire line, with all single-wire lines having intersection points with each other with the electrical contact.

In an embodiment of a method for transmitting electric energy, electric energy is transferred between two segments of a single-wire line symmetrically in both directions through an air condenser, one capacitor plate and a first segment of a single-wire line are stationary, and a second capacitor plate and a second segment of a single-wire line, a second high-frequency transformer, a second resonant circuit and the inverter-converter is mounted on a mobile electric vehicle.

In a method for transmitting electric energy by creating resonant oscillations from a frequency converter in a circuit consisting of two resonant circuits and a single-wire line between them, converting a high frequency current into direct current and then in an inverter into industrial frequency alternating current, electric energy is transferred between the middle terminal of the first resonant circuit and the middle terminal of the second resonant circuit symmetrically along a single-wire isolated from the earth electrical line in both directions by creating resonant oscillations from the inverter-converter on each side of the single-wire line, converting the high-frequency current to direct current and then into alternating current of industrial frequency in the inverter-converter on each side of the single-wire line, the frequency converter is used as an inverter when receiving electric energy and the inverter is used as a frequency converter when transmitting electrical energy.

In an embodiment of the method for transmitting electric energy, electric energy is transmitted along n-single-wire lines (n = 1,2,3 ...) in both directions along each single-wire line, all single-wire lines having intersection points with each other with an electrical contact.

In an embodiment of the method for transmitting electric energy, electric energy is transferred between two segments of a single-wire line symmetrically in both directions through an air condenser, one lining of which and the first segment of the single-wire line are fixed, and the second lining of the capacitor and the second segment of the single-wire line, the second resonant circuit and the inverter-converter installed on a mobile electric vehicle.

In the device for transmitting electric energy, containing at the input a rectifier of a frequency converter and a frequency converter, two resonant circuits and two high-frequency transformers connected by a single-wire line, an inverter rectifier and an inverter connected to the load, multifunctional units are installed at the input and output of the device combining the functions of the converter frequency, rectifier, inverter and control unit, while the input parallel to the rectifier of the frequency converter is additionally installed nvertor coupled via a rectifier and an inverter control unit with the inverter output frequency and the input of the first resonance circuit, and the output unit is set parallel inverter inverter rectifier coupled via the frequency converter and control unit with the output of the second resonant circuit and the input of inverter rectifier.

In an embodiment of a device for transmitting electrical energy, it contains n intersecting single-wire lines (n = 1,2,3 ...) electrically connected at the intersection points, each single-wire line contains multifunction blocks at the input and output that combine the functions of a frequency converter, a rectifier, an inverter, and control unit and which are connected to a single-wire line through resonant circuits and high-frequency transformers.

In an embodiment of a device for transmitting electrical energy, a single-wire line is made of two parts interconnected via an air condenser, one part of a single-wire line together with a multifunctional unit combining the functions of a frequency converter, a rectifier, an inverter and a control unit, as well as a first resonant circuit and a high-frequency transformer and one lining of the air condenser are installed stationary, and the second lining of the condenser and the second part of the single-wire line together with the second resonance An analog circuit, a second high-frequency transformer and a multifunctional inverter-rectifier-frequency converter and a control unit are mounted on a mobile electric vehicle.

In the device for transmitting electric energy, containing at the input a rectifier of a frequency converter and a frequency converter, a first resonant circuit, a single-wire line, a second resonant circuit, an inverter rectifier and an inverter connected to the load at the output, multi-functional units are installed at the input and output of the device combining functions a frequency converter, a rectifier, an inverter and a control unit, while a single-wire line is connected to the middle terminals of the first and second resonant circuits, on the input An additional inverter is installed in parallel to the frequency converter rectifier, which is connected through the inverter rectifier and the control unit to the output of the frequency converter and the input of the first resonant circuit, and at the device output, a frequency converter rectifier is installed in parallel with the inverter, which is connected through the frequency converter and the control unit to the input of the inverter rectifier and the output of the second resonant circuit.

In an embodiment of a device for transmitting electrical energy, it contains n single-wire lines (n = 1,2,3 ...) electrically connected by the (n + 1) -th single-wire line, each single-wire line contains multifunction blocks at the input and output that combine the functions of a frequency converter , a rectifier, an inverter and a control unit, which are connected to a single-wire line through resonant circuits.

In an embodiment of a device for transmitting electrical energy, a single-wire line is made of two parts interconnected via an air condenser, one part of a single-wire line with a functional unit combining the functions of a frequency converter, a rectifier, an inverter, and a control unit that is connected to a resonant circuit, and one lining the air condenser is installed stationary, and the second lining of the condenser and the second part of the single-wire line together with a resonant circuit with a multifunctional Torr rectifier-inverter and a control unit mounted on the mobile electric vehicle.

The method and apparatus for transmitting electrical energy are illustrated in the drawing, where:

figure 1 shows a block diagram of a method and device for transmitting electrical energy with two resonant transformers;

figure 2 is a block diagram of a method and apparatus for transmitting electrical energy with two resonant transformers and multifunctional blocks;

figure 3 is a block diagram of a method and apparatus for transmitting electrical energy with three intersecting single-wire lines;

figure 4 is a block diagram of a method and device for transmitting electrical energy to a mobile electric vehicle;

figure 5 shows a block diagram of a method and apparatus for transmitting electrical energy with two resonant circuits;

Fig.6 is a block diagram of a method and apparatus for transmitting electrical energy with two resonant circuits for powering a mobile electric vehicle;

Fig. 7 is a flowchart of a method and apparatus for transmitting electrical energy with three single-wire lines interconnected.

The block diagram of the method and device for transmitting electrical energy in figure 1 contains a power source 1, a rectifier 2 of the frequency converter 3, a first resonant circuit 4, a first high-frequency transformer 5, a single-wire line 6, a second high-frequency transformer 7, a second resonant circuit 8, a rectifier 9 of the inverter 10 and the electric load 11. To ensure the transmission of electric energy through a single-wire line 6 in two opposite directions at the input of the power source 1 in parallel with the rectifier 2 of the converter In stota 3, an additional inverter 12 is installed, which is connected through the rectifier 13 of the inverter 12 and the control unit 14 to the output of the frequency converter 3 and to the input of the first resonant circuit 4. At load 11, a rectifier 15 of the frequency converter 16 is installed parallel to the inverter 10 at the output of the device 10, which through the block control 17 is connected to the output of the second resonant circuit 8 and the input of the rectifier 9 of the inverter 10.

In Fig.2, at the input and output of the device for transmitting electric energy, multifunctional units 18 and 19 are installed, each of which performs the functions of a frequency converter, a rectifier, an inverter, and a control unit.

In Fig. 3, the device for transmitting electric energy contains three intersecting single-wire lines 20, 21, 22, which are electrically connected at the points of intersection 23. Each single-wire line contains multifunctional units 18 and 19 at the input and output that perform the functions of a frequency converter, rectifier, and inverter and control unit. Multifunctional units, 18 and 19 are connected to single-wire lines 20, 21 and 22 through resonant circuits 4 and 8 and high-frequency transformers 5 and 7.

4, the single-wire line 24 is made of two parts 25 and 26. One part 25 of the single-wire line 24 is fixedly installed in the form of a cable integrated in the pavement 27. The single-wire line 24 is connected to the power source 1 through the multifunction converter / inverter unit 18, the first resonant circuit 4 and the first high-frequency transformer 5, which are also stationary. Two parts 25 and 26 of the single-wire line 24 are connected to each other through an air capacitor 28, one capacitor plate 28 represents a part 25 of the single-wire cable line 24 in the road surface 27. The second capacitor plate 28 is made of a metal insulated plate 29, which is part 26 of the single-wire line 24 connected through a second high-frequency transformer 7, a second resonant circuit 8 and a multifunctional converter / inverter unit 19 with electric load 11. The second part 25 of a single-wire line 23, high-frequency transformer 7, the resonant circuit 8, multifunctional unit 19 and electrical load 11 are mounted on the mobile electric vehicle 30.

In Fig. 5, the multifunctional converter / inverter unit 18 at the input of the device is connected to the power supply 1 and the first resonant circuit 31, and the multifunctional converter / inverter unit 19 at the output of the device is connected to the second resonant circuit 32 and to the load 11. A single-wire line 6 is connected to the average conclusions 33 and 34 of the resonant circuits 31 and 32.

6, an air condenser 28 is connected to the gap of the single-wire line 24. One part 25 of the single-wire line 24 is stationary and connected to the middle terminal 33 of the first resonant circuit 31, which is connected to the stationary power source 1 through the multifunction converter / inverter 18. The second part 26 of the single-wire line 24 is connected to the lining 29 of the air condenser 28 and to the middle terminal 34 of the second resonant circuit 32. The resonant circuit 32 is connected through a multifunctional converter / inverter unit 19 with an electrical load 11. All elements of the electric circuit of the electric power transmission device connected to the second part 26 of the single-wire line 24, installed on a mobile electric vehicle 30.

7, the device for transmitting electrical energy contains three single-wire lines 35, 36, 37, electrically connected to each other by a single-wire line 38 at points 39, 40 and 41. Each single-wire line contains at the input and output functional blocks 18 and 19 that perform functions frequency converter, rectifier, inverter and control unit. Function blocks 18 and 19 are connected to the resonant circuits 31 and 32, the middle conclusions 33 and 34 of which are connected to single-wire lines 35, 36 and 37.

The method of transmitting electrical energy is implemented as follows. In normal operation, electrical energy is transmitted from the generator 1 to the load 11 via a single-wire line 6. In this case, the control unit 14 (Fig. 1) compares the voltage at the input and output of the unit 14 and, when the voltage on the frequency converter 3 increases, connects the frequency converter 3 to the resonant circuit 4. The control unit 17 with increasing voltage on the resonant circuit 8 connects the resonant circuit 8 with the rectifier 9 of the inverter 10 and with the load 11 (figure 1). The multifunctional blocks 18 in FIGS. 2, 3, 4, 5, 6, 7, when transferring energy from the generator 1 to the load 11, operate in the frequency converter mode, and the functional blocks 19 operate in the inverter mode. When the voltage at load 11 increases due to energy recovery during braking of an electric vehicle (Figs. 4 and 6) or when the consumer turns on load 11 (Figs. 1, 2, 3, 5, 7) of an autonomous generator 39 (Fig. 7) based on a diesel generator or solar battery 3 (not shown in FIGS. 1, 2, 3, 5, 7), a control unit 14 in FIG. 1 or a converter / inverter 19 function block in FIGS. 2, 3, 4, 5, 6, 7 connects the load 11 through the rectifier 15 and the frequency converter 16 to the resonant circuit 8. Electric energy is transmitted (in Fig. 1) through a high frequency transformer 7, single-wire line 6, high-frequency transformer 5 to the resonant circuit 4. The control unit 14 compares the voltage at the input and output of the block 14 and, when the voltage is increased on the resonant circuit 4, connects the circuit 4 to the rectifier 13 of the inverter 12. The transmitted electric energy along the single-wire line 6 from the load 11 to the generator 1 is used in the load 40 of the generator 1 (Fig.7). When the voltage on the tires of the generator 1 increases, the control device 41 of the generator 1 in Fig. 7 reduces the power of the generator 1.

Examples of the method and device for transmitting electrical energy.

Example 1. The generator 1 in figure 3 has an electric power of 150 kW. As an electric vehicle, a trolley bus with a load electric drive power of 11 100 kW is used. Electric power of multifunctional units 18 and 19 converter / inverter 150 kW. The operating frequency of the generator is 1 50 Hz, the working frequency of a single-wire line is 6 25 kHz. The voltage of the generator is 1 220/380 V. The voltage in a single-wire cable line is 10 kV. The length of the stationary part 25 of a single-wire cable line is 6 10 km. The distance between the plates 25 and 21 of the air condenser is 28 0.3 m, the load voltage is 11 220/380 V, the frequency is 50 Hz. As an electric drive, an asynchronous electric motor with a frequency regulator of the speed is used. In normal mode, when transmitting electrical energy from the generator 1 to the load 11, the multifunction unit 18 operates in the frequency converter mode and the multifunction unit 19 in the inverter mode. When braking a trolley, the mechanical braking energy is converted into electrical energy, the voltage at the input of the induction motor of the load increases, and electric energy is transferred from the load 11 to the generator 1. In this case, the multifunctional unit 19 operates in the frequency converter mode, and the multifunctional unit 18 in the inverter mode. Instead of a generator 1, a power system or an electric network of several generators can be used (Fig. 6), and instead of a trolley bus, an electric scooter, an electric bike, an electric car. Moreover, the method and the device allows the use of several electric vehicles powered by a single-wire line 6 or several single-wire lines (Fig.6) with energy recovery and transmission of electric energy from several electric vehicles through one or more single-wire lines from the consumer 11 to the generator 1 and in the opposite direction, or turns off the generator 1. Functional blocks 19 in FIGS. 2, 3, 4, 5, 6, 7 when transmitting electric energy from the load 11 to the generator 1 operate in the mode a frequency converter, and the functional blocks 18 are in inverter mode.

Example 2. Three generators 1 in Fig. 7 form a power system to which three single-wire lines 25, 36, 37 are connected, which are connected by an additional single-wire line 38. Electric energy is transmitted from three generators 1 to three load consumers 11, while the multi-function blocks 18 operate in the frequency converter mode, and the multifunctional units 19 in the inverter mode. The electric power of each generator is 1500 kW, voltage 220/380 V, frequency 50 Hz. Each generator 1 has an electric load 40 with an electric power of 1-500 kW, which is connected to the tires of the generator 1. Each consumer of load 11 has a backup generator 39 with an electric power of 500 kW, voltage 220/380 V, frequency 50 Hz. The electrical power of each load consumer varies from 1 to 500 kW, voltage 220/380 V, frequency 50 Hz, voltage on single-wire lines 35, 36, 37, 38 30 kV, frequency 30 kHz. When one, two or three generators 39 are turned on at the load consumer 11, the voltage at the output of the multifunctional units 18 and 19 of the converter / inverter rises, and the multifunctional units 19 are switched from the inverter mode to the frequency converter mode, and the multifunction blocks 18 are switched from the frequency converter mode to the mode inverter. Electric energy is transmitted along single-wire lines 35, 36, 37 from generators 39 on the consumer side of load 11 to loads 40 on the side of generators 1. In the partial-load mode 11 and 40, electric energy is transmitted through various single-wire lines in various, including opposite directions, for example, on a single-wire line 35 from the generator 1 to the load 11, and on a single-wire lines 36 and 37 from the generators 39 to the load 40.

Claims (12)

1. A method of transmitting electrical energy by creating resonant vibrations from a frequency converter in a circuit consisting of two resonant circuits, two high-frequency transformers and a single-wire line between them, and transmitting resonant vibrations from the resonant circuit of the first high-frequency transformer to the resonant circuit of the second high-frequency transformer through a single-wire isolated from the earth of an electric line, converting a high frequency current into direct current and then in an inverter into alternating current industrial frequency, characterized in that the transmission of electrical energy is carried out symmetrically along a single-wire line in both directions by creating resonant oscillations from the inverter-converter on each side of the line, converting high-frequency current to direct current and then into alternating current of industrial frequency in the inverter-inverter with each side of a single-wire line, while the frequency converter is used as an inverter when receiving electric energy, and the inverter is used as eobrazovatelya frequency during power transmission. 2. The method of transmitting electric energy according to claim 1, characterized in that the electric energy is transmitted along n-single-wire lines in both directions along each single-wire line, wherein all single-wire lines have intersection points with each other with an electrical contact. 3. The method of transmitting electric energy according to claim 1, characterized in that the electric energy is transferred between two segments of a single-conductor line symmetrically in both directions through an air capacitor, one capacitor plate and a first section of a single-wire line are stationary, and the second capacitor plate and a second segment of a single-wire lines, the second high-frequency transformer, the second resonant circuit and the inverter-converter are installed on a mobile electric vehicle. 4. A method of transmitting electrical energy by creating resonant oscillations from a frequency converter in a circuit consisting of two resonant circuits and a single-wire line between them, converting a high frequency current into direct current and then in an inverter into alternating current of industrial frequency, characterized in that the electric transmission energy is carried out between the middle terminal of the first resonant circuit and the middle terminal of the second resonant circuit symmetrically along a single-wire electrical line isolated from earth in both directions by creating resonant oscillations from the inverter-converter on each side of the single-wire line, converting the high-frequency current to direct current and then into alternating current of industrial frequency in the inverter-converter on each side of the single-wire line, the frequency converter being used as an inverter for receiving electric energy, and the inverter is used as a frequency converter for transmitting electric energy. 5. The method of transmitting electric energy according to claim 4, characterized in that the electric energy is transmitted along n-single-wire lines (n = 1, 2, 3, ...) in both directions along each single-wire line, and all single-wire lines have intersection points between itself with electrical contact. 6. The method of transmitting electric energy according to claim 4, characterized in that the electric energy is transferred between two segments of a single-wire line symmetrically in both directions through an air condenser, one lining of which and the first segment of the single-wire line are installed stationary, and the second lining of the capacitor and the second segment of the single-wire lines, a second resonant circuit, and an inverter-converter are mounted on a mobile electric vehicle. 7. A device for transmitting electric energy, containing at the input a rectifier and a frequency converter, two resonant circuits and two high-frequency transformers connected by a single-wire line, a rectifier and an inverter connected to a load, characterized in that multifunction blocks are installed at the input and output of the device, combining functions of the frequency converter, rectifier, inverter and control unit, while at the input of the device parallel to the rectifier of the frequency converter is additionally installed ertor coupled via a rectifier and an inverter control unit with the inverter output frequency and the input of the first resonance circuit, and the output unit is set parallel inverter inverter rectifier coupled via the frequency converter and control unit with the output of the second resonant circuit and the input of inverter rectifier. 8. The device for transmitting electrical energy according to claim 7, characterized in that it contains n intersecting single-wire lines (n = 1, 2, 3, ...) electrically connected at the intersection points, each single-wire line contains multifunction blocks at the input and output combining the functions of a frequency converter, a rectifier, an inverter and a control unit, and which are connected to a single-wire line through resonant circuits and high-frequency transformers. 9. The device for transmitting electric energy according to claim 7, characterized in that the single-wire line is made of two parts interconnected via an air condenser, one part of the single-wire line together with a multifunctional unit combining the functions of a frequency converter, rectifier, inverter and control unit as well as the first resonant circuit and the high-frequency transformer and one lining of the air condenser are installed stationary, and the second lining of the capacitor and the second part of the single-wire line together those with a second resonant circuit, the second high-frequency transformer and a multifunction unit inverter-rectifier, a frequency converter and control unit are mounted on a mobile electric vehicle. 10. A device for transmitting electrical energy, comprising a rectifier and a frequency converter, a first resonant circuit, a single-wire line, a second resonant circuit, a rectifier and an inverter connected to a load at the input, characterized in that multifunction blocks are installed at the input and output of the device, combining the functions of a frequency converter, a rectifier, an inverter and a control unit, while a single-wire line is connected to the middle terminals of the first and second resonant circuits, at the input parallel but an additional inverter is installed to the rectifier of the frequency converter, which is connected through the inverter rectifier and the control unit to the output of the frequency converter and the input of the first resonant circuit, and at the device output, a frequency converter rectifier is installed parallel to the inverter, which is connected through the frequency converter and the control unit to the input of the inverter rectifier and the output of the second resonant circuit. 11. The device for transmitting electrical energy according to claim 10, characterized in that it contains n single-wire lines (n = 1, 2, 3, ...) electrically connected by the (n + 1) th single-wire line, each single-wire line contains the input and output are multifunctional units combining the functions of a frequency converter, a rectifier, an inverter and a control unit, which are connected to a single-wire line through resonant circuits. 12. The device for transmitting electrical energy according to claim 10, characterized in that the single-wire line is made of two parts interconnected via an air condenser, one part of the single-wire line with a functional unit that combines the functions of a frequency converter, rectifier, inverter and control unit, which is connected to the resonant circuit, and one lining of the air condenser is installed stationary, and the second lining of the capacitor and the second part of the single-wire line together with a resonant circuit with multifunction cial unit inverter-rectifier-inverter and a control unit mounted on the mobile electric vehicle.

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