RU2533060C2 - Method and device for transmission of electric power - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to electric engineering, in particular to methods and devices for electric power transmission. In the method of electric energy transmission between the power source and the consumer using as a pipeline with liquid substance as a conductive channel by forming in the eclectic insulating jacket of the pipeline an electroconductive channel of the substance in liquid phase and by creating high-frequency resonant oscillations in the circuit consisting of a high-frequency converter, a step-up resonant Tesla transformer, an electroconductive channel made of an electrically insulated pipeline with liquid substance, a step-down resonant Tesla transformer, transmission of electric energy along the conductive channel to the step-down resonant Tesla transformer, reduction of high-voltage oscillations potential and transmission of the energy through an inverter to the load; electric energy is transmitted through the pipeline installed in aquatic environment, the eclectic insulating jacket of the pipeline with in-built inner shield is filled with water having high salt concentration, the pipeline is lowered to the aquatic environment and only the beginning and the end of the conductive channel is connected by insulated cables with high-voltage outputs of the step-up and step-down Tesla transformers. The invention also describes the device for electric energy transmission.

EFFECT: invention provides reduction of costs for electric energy transmission due to exclusion of supports, wires, insulators, cables and improvement of the efficiency factor for electric energy transmission.

20 cl, 4 dwg

Description

The invention relates to the field of electrical engineering, in particular to methods and devices 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 (AC and DC power transmission. Electrical reference book. - M .: Energoatomizdat, 1988, p.337-352).

The disadvantages of this method are losses in the lines, comprising from 5% to 20%, depending on the length of the power lines, and the high cost of the equipment. In this case, the circuit connecting the energy source and the load must necessarily be a closed loop.

A known method of powering electrical devices using an alternating voltage generator connected to a consumer, in which the voltage of the generator is supplied to the low-voltage winding of a high-frequency transformer, and one of the terminals of the high-voltage winding is connected to one of the input terminals of the electrical device, in this case, resonant oscillations are established by changing the frequency of the generator in the formed electric 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 disadvantage of the known method is the need to use lines for transmission of electricity from poles, insulators, wires or cable, which increases the cost of electricity transmission.

Another disadvantage is the inability to directly use this method and device for the direct power supply of moving electric vehicles: cars, tractors.

A known method of transmitting electrical energy by creating high-frequency resonant oscillations in a circuit consisting of a high-frequency generator and two step-down and step-up high-frequency Tesla transformers, transmission of high-voltage potential and electric energy through a single-wire line to a step-down Tesla transformer, lowering the potential of its high-voltage output and transmission energy load (RF patent №2255406, 2003, Strebkov D.S., Avramenko S.V., Nekrasov A.I. Method and device for transmitting electric energy s).

The disadvantage of this method is the need for energy transfer of the Tesla transmitting high-frequency transformer to two electrically different energy carriers (a single-conductor line and ground), or to one, electrically isolated from the ground and under a high electric potential of a single-conductor line, which requires the use of supports, insulators , wires.

A known method and device for transmitting electrical energy without metal wires using transport pipelines with liquid or gaseous substances moving along them as a conductive channel. In this case, an electrically conductive channel is formed from the substance in the liquid, solid or gaseous phase between the source and the receiver of electrical energy. In the conductive channel, electromagnetic oscillations of the electric field are generated, while due to resonant oscillations they create antinodes of voltage in the channel, and the energy of the channel’s electric field is converted into active energy for the consumer (RF Patent No. 2172546, 2000. Strebkov D.S., Avramenko SV. Method and a device for transmitting electrical energy).

The disadvantage of all known methods and devices is the impossibility of their use for the transmission of electrical energy in the aquatic environment.

The disadvantages of the known methods for transmitting electrical energy are also a small amount of transmitted power, large losses and low efficiency of transmission of electrical energy.

The objective of the invention is to provide a method and device for transmitting electrical energy in an aqueous environment using insulated pipelines, reducing the cost of electric power transmission by eliminating supports, wires, insulators, cables, as well as increasing the efficiency of electric power transmission.

The technical result is achieved by the fact that in the method of transferring electric energy between a source and a consumer of energy using a pipeline with a liquid substance as a conductive channel by forming an electrically conductive channel from a substance in the liquid phase in an electrical insulating sheath of a pipeline and creating high-frequency resonant oscillations in a circuit consisting of high-frequency converter, Tesla resonance transformer, an electrically conductive channel from an electrically insulated pipe water with a liquid substance that lowers the Tesla resonant transformer, transfers electric energy along the conductive channel to the Tesla lower resonance transformer, lowers the potential of high-voltage oscillations and transfers energy through the inverter to the load, electric energy is transmitted through a pipeline installed in an aqueous medium, an insulated pipe shell with an internal the built-in screen is filled with water with a high salt content, the pipeline is lowered into the aqueous medium and the beginning and end of ovodyaschego channel insulated high voltage cables with a pin up-and-down transformer Tesla.

In an embodiment of the method for transmitting electrical energy, an electrically conductive channel between the Tesla step-up and step-down resonant transformers is created by immersing an electrically insulated pipeline in an aqueous medium while filling the pipeline with water with a high salt content.

In an embodiment of the method for transmitting electrical energy, the shell of the conduit channel is made of electrically insulated material with zero buoyancy and with a density equal to the density of the aqueous medium.

In an embodiment of the method for transmitting electric energy, the seas and oceans of the Earth are used as the water medium, and sea water of the water medium is used as water with a high salt content.

In an embodiment of the method for transmitting electric energy, freshwater rivers and water bodies of the Earth are used as the water medium.

In an embodiment of a method for transmitting electrical energy, a frequency converter and a Tesla boost resonance transformer are installed on the shore, and a Tesla resonance step-down transformer with electric load is installed at the bottom of the aquatic environment.

In another embodiment of the method of transmitting electrical energy, a frequency converter and a Tesla resonance step-up transformer and a Tesla step-down resonance transformer with electric load are installed on various water (underwater) stationary or fixed devices.

In another embodiment of the method of transmitting electrical energy, a frequency converter with a Tesla boost resonant transformer and a Tesla step-down resonant transformer with electric load are placed on opposite sides of the aquatic environment.

In an embodiment of the method for transmitting electrical energy, a frequency converter with a Tesla step-up resonant transformer and a Tesla step-down resonant transformer with electric load are placed at a distance from each other on one side of the aquatic environment.

In an embodiment of a method for transmitting electrical energy, a frequency converter with a resonant step-up transformer is placed on the shore of an aqueous medium, and a resonant step-down transformer with electric load on a natural or artificial island in the specified water environment.

In a device for transmitting electrical energy containing sources and receivers of electrical energy with conductive channels between them in the form of pipelines filled with a substance in the liquid phase, each source of electrical energy is connected to the conductive channel through a Tesla high-frequency resonant transformer, and each receiver on the opposite side of the conductive the channel is connected to it via a Tesla step-down high-frequency resonant transformer, electrically insulated pipelines with an internal the screen is installed in an aqueous medium, filled with water with a high salt content and connected by insulated cables to the high-voltage leads of the Tesla step-up and step-down transformers.

In an embodiment of a device for transmitting electrical energy, the electrically conductive channel between the Tesla step-up and step-down resonant transformers is made of a part of the aqueous medium into which the insulated pipelines with integrated screen are immersed.

In an embodiment of the device for transmitting electrical energy, the shell of the conduit channel is made of electrically insulated material with zero buoyancy and with a density equal to the density of the aqueous medium.

In another embodiment of the device for transmitting electrical energy, the seas and oceans of the Earth are used as the water medium, and the sea water of the water medium is used as the water of the conducting channel with a high salt content.

In another embodiment of the device for transmitting electrical energy, freshwater rivers and bodies of water of the Earth are used as the water medium, and fresh water with a high salt content is used as the water of the conducting channel.

In an embodiment of a device for transmitting electrical energy, a frequency converter and a Tesla step-up resonant transformer are installed on the shore, and a Tesla step-down resonant transformer with electric load is located at the bottom of the aquatic environment.

In an embodiment of a device for transmitting electrical energy, a frequency converter and a Tesla resonance step-up transformer and a Tesla step-down resonance transformer with electric load are installed on various water (underwater) stationary or fixed devices.

In an embodiment of a device for transmitting electrical energy, a frequency converter with a Tesla step-up resonant transformer and a Tesla step-down resonant transformer with electric load are installed on opposite sides of the aquatic environment.

In an embodiment of a device for transmitting electrical energy, a frequency converter with a Tesla step-up resonant transformer and a Tesla step-down resonant transformer with electric load are located at a distance from each other on the same side of the aquatic environment.

In an embodiment of a device for transmitting electrical energy, a frequency converter with a resonant step-up transformer is installed on the shore of the aquatic environment, and a resonant step-down transformer with electric load on a natural or artificial island in the specified water environment.

The invention is illustrated in figure 1, figure 2, figure 3, figure 4, where figure 1 shows a diagram of a method and device for transmitting electric energy from an energy source on the sea or ocean to a stationary underwater vehicle - energy consumer, .2 is a diagram of a method and device for transmitting electrical energy from an energy source onshore to a drilling platform, FIG. 3 is a diagram of a method and device for transmitting electric energy from an energy source on a surface ship to an underwater vehicle is an energy consumer, in FIG. 4 - spos scheme ba and devices for transmitting electrical energy from an energy source on an underwater apparatus to another surface and underwater apparatus - energy consumers.

In Fig.1, a high-frequency energy source 1 is connected through a resonant capacitance 2 to a low-voltage winding 3 of a Tesla boost resonant transformer 4. The low-potential terminal 5 of the high-voltage winding 6 is grounded. An energy source 1 with a resonant capacitance 2 and a step-up high-frequency resonant transformer Tesla 4 is placed in a container 7 on the shore of the sea 9 8. The high-potential terminal 10 of the high-voltage winding 6 of the Tesla transformer 4 is connected by an electrically insulated cable 11 with a conductive channel 12 of a pipe 13 of electrical insulation material with an internal built-in screen 14. The pipeline shell is made of two layers of fiberglass or polyethylene, between which a shielding layer of copper, aluminum or steel is embedded. The pipeline 13 is filled with sea water and installed on the bottom of the sea 8 between the energy source 1 and the underwater object 15 - a consumer of electrical energy. At the ends of the pipeline 13 installed insulated inputs 16 and 17 for the supply and removal of electrical energy. Electrical energy from the energy source 1 is supplied from the sea through a conductive channel 12 with sea water to the underwater vehicle 15. On the underwater vehicle 15 inside the housing 16 there is a Tesla high-frequency resonance step-down transformer 18. The high-potential terminal 19 of the high-voltage winding 20 is connected by an electrically insulated cable 21 with the opposite end an electrically insulated pipeline 13 filled with sea water. The low-potential terminal 22 of the high-voltage winding 20 is connected via cable 23 to the body 24 of the underwater vehicle 15. The low-voltage winding 25 of the Tesla 18 low-frequency resonant transformer is connected via a capacitor 26 and an inverter 27 with an electric load 28. The electric systems of the underwater vehicle are used as the electric load 28 and energy storage devices (not shown in FIG. 1).

In Fig.2, electric energy from the energy source 1 on the shore 9 of the sea 8 is transmitted through a conductive channel 12 with sea water to a step-down high-frequency resonant transformer 29 with a resonant capacitance 30 and an inverter 31, which is located in the container 32 on the drilling platform 33 in the sea 8. The device in figure 2 allows you to transfer electrical energy to any stationary objects in the sea: islands, ships standing on the roadstead away from the coast, etc.

In Fig. 3, a container 32 with a high-frequency source of electric energy 1, capacity 2 and a step-up transformer Tesla 4 is mounted on a surface ship 34. Electric energy from a source 1 on a surface ship 34 is transmitted through a conductive channel 35 in an electrically insulated pipeline 36 with sea water to a resonant step-down a transformer 36 with a resonant capacitance 37, an inverter 38, which is installed on the underwater vehicle 39 similarly to figure 1. The pipeline 36 is made of insulating material with zero buoyancy, and the shell of the pipeline 36 with an integrated screen 40 has a density close to the density of sea water. As a result, the mass of the pipeline 36 with the conductive channel 35 is reduced, which makes it possible to transmit electric energy to deep-sea vehicles with an immersion depth of 10 km or more. At the same time, the possibility of vertical movement of the deep-sea vehicle due to a change in the length of the pipeline 36 and, to a small extent, the horizontal movement of the deep-sea vehicle, remains.

In Fig.4, a high-frequency source of electric energy 1, increasing the Tesla high-frequency resonant transformer 4 with a resonant capacity 2 is installed on the underwater object 41. Electric energy from the energy source 1 is transmitted through a conductive channel 42 in an electrically insulated pipeline 43 with sea water to the resonant step-down high-frequency transformers 44 with a resonant capacitance 45, which are installed on the underwater vehicle 46 similarly to figure 1 and on the surface vehicle 47 similarly to figure 2.

The method and device for transmitting electrical energy are implemented as follows.

. Для понижающего высокочастотного резонансного трансформатора Тесла 18 на подводном объекте 15 индуктивность L₂ низковольтной обмотки 25 и емкость C₂ выбирают таким образом, что выполняется условие:When applying electric energy from a high-frequency source 1 (Fig. 1) to a low-voltage winding 3 in a series circuit consisting of a low-voltage winding 3 with an inductance L ₁ and a capacitance 2 of magnitude C ₁ , electromagnetic oscillations with a resonant frequency occur

. For the Tesla 18 high-frequency resonant step-down transformer on the underwater object 15, the inductance L _{2 of the} low-voltage winding 25 and the capacitance C ₂ are chosen in such a way that the condition:

The transmitted power and transmission range of electric energy increases with increasing diameter of the conductive channel 12 with sea water.

, где C - скорость распространения электромагнитной волны в проводящем канале 12. Понижающий высокочастотный резонансный трансформатор Тесла 18 воспринимает электромагнитные колебания с резонансной частотой f₀, усиливает их по току в контуре L₂C₂ и передает через инвертор 27 в электрическую нагрузку 28.Electromagnetic vibrations with a frequency f ₀ amplify the voltage in the Tesla resonant transformer 4 and propagate through a conductive channel 12 with sea water, forming stationary waves in a conductive channel with a wavelength

, where C is the propagation velocity of the electromagnetic wave in the conducting channel 12. The Tesla 18 low-frequency resonant transformer picks up electromagnetic waves with a resonant frequency f ₀ , amplifies them by current in the circuit L ₂ C ₂ and transfers them through the inverter 27 to the electric load 28.

When using the device and method for transmitting electrical energy in fresh water, the conductive channel 12 is formed by filling the pipe 13 with water with a high salt content at the sea level. The method and device can be used to transfer electric energy to islands, drilling platforms, ship movers in roads, deep-sea vehicles, settlements located along the sea coast and river channels, as well as to transfer energy between energy systems through water bodies.

Examples of the method and device for transmitting electrical energy.

Example 1. On the shore 9 of the sea 8 (Fig. 1), a container 7 is installed containing an energy source 1 made in the form of a diesel power station with a maximum power of 150 kW with a frequency converter 50 Hz / 1 kHz (not shown in Fig. 1), which the resonant capacitance 2 is connected to a Tesla high-frequency resonant step-up transformer 4, in which the serial resonant circuit of the low-voltage winding 3 is tuned to the resonant frequency f ₀ = 1 kHz. A Tesla 18 low-frequency resonant transformer with a resonant frequency of 1 kHz is installed on an underwater vehicle 15 at a distance of 10 km from shore 9 in a marine environment 8 at a depth of 100 m. The voltage in the conductive channel 12 is 110 kV, the diameter of the conductive channel is 20 cm. Output voltage high-frequency transformer 18,400 V, electric power at a load of 28,100 kW, which is used to charge a battery of electrical energy (not shown in FIG. 1) and to power the power plant of the underwater vehicle 15.

Example 2. A container with a high-frequency energy source 1 with a resonant frequency f ₀ = 5 kHz, a resonant capacitance 2 and a step-up high-frequency resonant transformer Tesla 4 is installed on board a surface ship 34 (Fig. 3). The maximum electric power of the energy source is 7500 kW, the resonant frequency f ₀ = 5 kHz, the voltage in the conductive channel is 35 220 kV, the diameter of the conductive channel is 0.5 m. A Tesla 36 resonant high-frequency transformer lowering with a resonant frequency of 5 kHz is installed on an underwater deep-sea vehicle 39 at a depth 5 km. The voltage at the output of the Tesla step-down transformer is 36,400 V, the electric power at a load of 400 kW.

The method and device for transmitting electric energy in the marine environment using stationary waves of current and voltage is characterized by low losses due to the absence of active current in the conductive channel and the low cost of the conductive channel from sea water compared to the cost of underwater electric cables, the price of which is 3-5 million dollars / km.

Claims (20)

1. A method of transferring electrical energy between an energy source and a receiver using a pipeline with a liquid substance as a conductive channel by forming an electrically conductive channel from a substance in the liquid phase in an electrical insulating sheath of a pipeline and creating high-frequency resonant oscillations in a circuit consisting of a high-frequency converter that increases the resonant Tesla transformer, an electrically conductive channel from an electrically insulated pipeline with a liquid substance, which reduces the resonance Tesla transformer, transmitting electric energy along the conductive channel to the Tesla step-down resonant transformer, lowering the potential of high-voltage oscillations and transferring energy through the inverter to the load, characterized in that the electric energy is transmitted through a pipe installed in an aqueous medium, an insulated pipe shell with an internal built-in screen fill with water with a high salt content, lower the pipeline into the aquatic environment and connect the beginning and end of the conductive channel en pin with high voltage cables up-and-down transformer Tesla. 2. The method of transmitting electrical energy according to claim 1, characterized in that the electrically conductive channel between the step-up and step-down resonance Tesla transformers is created by immersing an electrically insulated pipeline in an aqueous medium while filling the pipeline with water with a high salt content. 3. The method of transmitting electrical energy according to claim 1, characterized in that the shell of the conduit channel is made of electrically insulated material with zero buoyancy and with a density equal to the density of the aqueous medium. 4. The method of transmitting electric energy according to claim 1, characterized in that the seas and oceans of the Earth are used as the water medium, and the sea water of the water environment is used as water with a high salt content. 5. The method of transmitting electrical energy according to claim 1, characterized
the fact that freshwater rivers and reservoirs of the Earth are used as the aquatic environment. 6. The method of transmitting electric energy according to claim 1, characterized in that the frequency converter and the Tesla resonance step-up transformer are installed on the shore, and the Tesla resonance step-down transformer with electric load is installed on the bottom of the aquatic environment. 7. The method of transmitting electric energy according to claim 1, characterized in that the frequency converter and the Tesla resonance step-up transformer and the Tesla resonance step-down transformer with electric load are installed on various water (underwater) stationary or fixed devices. 8. The method of transmitting electrical energy according to claim 1, characterized in that the frequency converter with a Tesla step-up resonant transformer and a Tesla step-down resonant transformer with electric load are placed on opposite sides of the aquatic environment. 9. The method of transmitting electric energy according to claim 1, characterized in that the frequency converter with a Tesla step-up resonant transformer and a Tesla step-down resonant transformer with electric load are placed at a distance from each other on one side of the aquatic environment. 10. The method of transmitting electrical energy according to claim 1, characterized in that the frequency converter with a resonant step-up transformer is placed on the shore of the aquatic environment, and a resonant step-down transformer with electric load on a natural or artificial island in the specified aquatic environment. 11. A device for transmitting electrical energy, containing sources and receivers of electrical energy with conductive channels between them in the form of pipelines filled with a substance in the liquid phase, each source of electrical energy is connected to the conductive channel through a Tesla high-frequency resonant transformer, and each receiver on the opposite side the conductive channel is connected to it through a step-down high-frequency resonant transformer Tesla, characterized in that the electrically insulated pipelines with Cored oil built-in screen installed in an aqueous medium, filled with water with a high salt content and are connected to high voltage insulated cables with a pin up-and down-Tesla transformer. 12. The device for transmitting electrical energy according to claim 11, characterized in that the electrically conductive channel between the step-up and step-down resonance Tesla transformers is made of a part of the aqueous medium into which the insulated pipelines with integrated screen are immersed. 13. The device for transmitting electrical energy according to claim 11, characterized in that the shell of the conduit channel is made of electrically insulated material with zero buoyancy and with a density equal to the density of the aqueous medium. 14. The device for transmitting electrical energy according to claim 11, characterized in that the seas and oceans of the Earth are used as the water medium, and the sea water of the water medium is used as the water of the conductive channel with a high salt content. 15. The device for transmitting electric energy according to claim 11, characterized in that freshwater rivers and reservoirs of the Earth are used as the water medium, and fresh water with a high salt content is used as the water of the conducting channel. 16. The device for transmitting electrical energy according to claim 11, characterized in that the frequency converter and the Tesla step-up resonant transformer are installed on the shore, and the Tesla step-down resonant transformer with electric load is located at the bottom of the aquatic environment. 17. The device for transmitting electric energy according to claim 11, characterized in that the frequency converter and the Tesla resonance step-up transformer and the Tesla resonance step-down transformer with electric load are installed on various water (underwater) stationary or fixed devices. 18. The device for transmitting electrical energy according to claim 11, characterized in that the frequency converter with a Tesla step-up resonant transformer and a Tesla step-down resonant transformer with electric load are installed on opposite sides of the aquatic environment. 19. The device for transmitting electrical energy according to claim 11, characterized in that the frequency converter with a Tesla step-up resonant transformer and a Tesla step-down resonant transformer with electric load are placed at a distance from each other on the same side of the aquatic environment. 20. The device for transmitting electrical energy according to claim 11, characterized in that the frequency converter with a resonant step-up transformer is installed on the shore of the aquatic environment, and a resonant step-down transformer with electric load on a natural or artificial island in the specified water environment.

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