RU2409883C1 - Electric energy transmission method and device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: positive result is achieved due to available metal tubes used as guide channel for energy flow instead of electric conductors. The above tubes are installed for other purposes, e.g. for pumping of liquids or gases. Electric power is transferred by means of excitation of resonant oscillations of magnetic flow in the tube wall. At that, magnetic flow at resonant frequencies within (0.3÷300) kHz is excited in two opposite directions azimuth-oriented relative to tube axis. Excitation is performed with system of inductance coils of transmitting device powered from electric power generator at resonant frequency of the system. Around opposite directed magnetic flows the eddy electric field appears inside and outside the tube. Available variable magnetic and electric fields of the described spatial configuration creates energy flow along the tube. Design of receiving system is identical to transmitting one, due to which, when being in energy flow, it generates e.m.f. at outputs of terminals, which can be used for power supply to electric receivers or for obtaining mechanical or heat energy.

EFFECT: increasing transfer efficiency of electric energy and saving of materials of electric conductors.

15 cl, 7 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 from a substance in a liquid, solid or gaseous phase is formed between an electric energy source and a receiver. In the conductive channel, electromagnetic oscillations of the electric field between the substance in the insulating sheath and the substance surrounding the sheath are generated, while due to resonant vibrations they create voltage antinodes in the channel, and the channel electric field energy is converted into active energy for the consumer (RF Patent No. 2172546, 2000. Ogrebkov D.S., Avramenko S.V. Method and device for the transmission of electrical energy).

The disadvantage of this method is the necessity of forming a conductive channel isolated from the environment, as well as the use of an electrically high-strength material to create an electrically insulating shell of the conductive channel, because the intensity of electric power transmission is directly proportional to the square of the voltage in the antinode of the voltage excited in the conductive channel.

Known methods and devices for providing remote transmission of telemetric data during drilling operations, using electric and magnetic fields in the environment, formed by cylindrical or toroidal coils located on the columns (US Pat. US 6,445,307 B1, 09/03/2002. Drill string telemetry; Pat. U.S. 4,725,837, 02.16.1988. Toroidal coupled telemetry apparatus). The power of the information transferring fields is sufficient for high-quality information transfer in a conductive medium (EP 0699822 A2, 03/06/1996. A well data telemetry system).

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

The objective of the invention is to provide a method and device for transmitting electric energy using non-insulated pipelines as metal conductors, reducing the cost of electric power transmission by eliminating such power line elements as wires, insulators, cables, as well as increasing the efficiency of electric power transmission.

A positive result is achieved by the fact that in the transmission method between the source and the receiver of electric energy, an electrically conductive channel is created in the steel or cast-iron pipe by placing the transmitting and receiving resonant electromagnetic systems on it, using the transmitting resonant system, they are excited in the pipe wall in the range of 0.3 ÷ 300 kHz resonant oscillations of the magnetic flux, in two opposite directions, orthogonally oriented with respect to the pipe axis, induce vortex e in the pipe wall and on its surface an electric field, they transmit electromagnetic energy along the pipe, receive it in a receiving resonant electromagnetic system and receive an emf, which is used to power electric consumers, or is converted into mechanical or thermal energy by any known method.

In an embodiment of the method for transmitting electric energy, an electrically conductive channel is created in a steel or cast iron insulated or rotating pipe, while the transmitting and receiving coils of the resonant electromagnetic system are installed on the insulation layer or at a distance from the pipe, ensuring its rotation and passage along the pipe wall of the electromagnetic energy flow necessary to transmit a given power.

In another embodiment of the method of transmitting electrical energy, an electrically conductive channel is created in a steel or cast iron insulated or rotating pipe, while the transmitting and receiving coils of the resonant electromagnetic system are installed inside the pipe or in the grooves of the coupling between the two sections of the pipe together with the electric receiver when installing the next section of the drill string to be mounted casing or pipe string.

A device for transmitting electrical energy contains an electrically conductive steel or cast-iron pipe with transmitting and receiving resonant electromagnetic systems placed on it, while the transmitting electromagnetic system is connected to a source of electric energy through a high-frequency current generator in the range of (0.3 ÷ 300) kHz, and the receiving energy of a vortex electric field, a resonant electromagnetic system is connected through a current inverter to a receiver of electrical energy.

In an embodiment of electric energy transmission, the device comprises an electrically conductive metal pipe with transmitting and receiving resonant electromagnetic systems located inside the pipe.

In another embodiment, the device comprises an electrically conductive metal pipe with transmitting and receiving resonant electromagnetic systems placed on the surface and inside the pipe.

The invention is illustrated in Fig.1-7.

Figure 1 presents a diagram of a device for implementing the proposed method. The device contains a power source 1 connected to a high-frequency current generator 2, to which a transmitting resonant excitation system 3 is connected, consisting of two excitation coils 4 oppositely placed on the pipe 8, which, due to the excited magnetic fluxes 5, create a vortex time-varying in the walls of the pipe 8 electric field 6. As a result of the interaction of magnetic 5 and electric 6 fields, a flow of electromagnetic energy 7 occurs, which is transmitted along the pipe 8 to the receiving system 9, with coils excitation 10, where in the Converter 11 is the inverse conversion of the energy of the electric field into electricity of the required standard to power the load 12.

Figure 2 and figure 3 schematically shows the magnetic 5 and electric 6 fields in the coils and walls of the pipe of the transmitting resonant system, explaining the proposed method.

Figure 2 presents the cross section of the pipe 8 with the coils 4 of the excitation system 3 located on it, the lines of force of the magnetic flux 5 and the vortex electric field 6 and the lines of the flow of electromagnetic energy 7 that transmit energy along the pipe 8.

Figure 3 presents a longitudinal section of the pipe 8 with the coils 4 of the excitation system and the magnetic flux lines 5, the vortex electric field 6 and the electromagnetic energy flux lines 7 transmitting energy along the pipe 8 to the receiver, explaining the electromagnetic field interaction, located on this pipe section.

The method of power transmission is as follows.

Electric energy from source 1 is supplied to a high-frequency current generator 2, which provides a high-frequency current (0.3 ÷ 300) kHz with a transmitting resonant system 3, consisting of two excitation coils 4, which create an eddy-variable vortex due to counter-directed magnetic flux 5 electric field 6, receive a flow of electromagnetic energy 7, transmit it along the pipe 8, receive on another section of the pipeline 8 receiving system 9, consisting of two receiving coils 10, carry out the inverse transformation of the electromagnetic field energy into electrical energy required standard in the inverter 11 and supplied to the load 12.

внутри и снаружи трубы возникает переменное во времени вихревое электрическое поле

Наличие переменных магнитного

и ортогонального к нему электрического

полей порождает поток электромагнитной энергии

вдоль трубы. Плотность потока электромагнитной энергии определяется вектором Умова-ПойнтингаExcitation is carried out by a transmitting resonant system 3 with coils 4 fed by an electric energy generator 2 at the resonant frequency of the system. Around the magnetic flux

inside and outside the pipe there is a time-varying vortex electric field

The presence of variables magnetic

and orthogonal to it electric

fields generates a flow of electromagnetic energy

along the pipe. The flux density of electromagnetic energy is determined by the Umov-Poynting vector

The receiving resonant system is structurally identical to the transmitting system, due to which, being in the stream of electromagnetic energy, it generates an emf at the output terminals, which is converted and used to power electrical appliances, to produce mechanical or thermal energy.

Figure 4 presents the layout of the coil on the pipe 8.

Figure 5 shows a diagram of a method and device for transmitting electricity along a steel or cast-iron pipe, which can move along the axis or rotate around its axis. In this case, the coils 4 of the transmitting resonant excitation system 3 and the coils 10 of the receiving system 9 are fixed at a certain distance, which ensures the rotation of the pipe and the passage of the magnetic flux necessary for transmitting power.

The current generator of increased frequency 2, depending on the transmitted power, can be made either in the form of a low-power generator, or in the form of a powerful generator with a matching transformer, for example, in the form of a Tesla transformer.

Figure 6 shows a section of the pipeline with transmitting 4 and receiving 10 coils installed inside the pipe 8. The inverse transformer 11 performs the function of an inverter to obtain the DC or AC voltage required to power the load 12.

7 shows a section of the pipeline with transmitting 4 and receiving 10 coils mounted on the outer and inner surfaces of the pipe 8.

Electromagnetic systems for receiving transmitted energy are installed along the length of the pipe in areas with a maximum value of the amplitude of the electromagnetic wave, including a pipe having any insulation or protective coating.

The transmitted electric power of the electric energy transmission line through a steel pipe with the required number of load-receiving devices and the transmission distance depend on the power of the transmitting energy source 1, the current frequency, and the attenuation coefficient of electromagnetic waves.

As energy-conducting pipes, steel or cast-iron pipes of water, gas or oil pipelines, as well as other pipelines with or without insulation or protective coating, which, due to technological or other necessity, are located in the ground or on its surface, in ordinary or sea, can be used water or other media. Drill hollow rods connected to a rotating string-harness or casing of artesian wells can also be used as transfer pipes.

On a pipe rotating or moving in any medium, the transmitting or receiving electromagnetic system is installed in special grooves of the coupling joint with the electrical receiver - sensor or device flush with the pipe and protected from mechanical, temperature and other environmental influences.

The method and device can be primarily used to power the electrochemical protection devices of gas pipelines, drill string sensors and other devices for monitoring and transmitting telemetry and other information in pipeline systems.

Claims (15)

1. A method of transmitting electrical energy, comprising transmitting electrical energy from an electric energy source to an electric energy receiver, characterized in that an electrically conductive channel is created between the source and the electric energy receiver in a steel or cast-iron pipe by placing transmitting and receiving resonant electromagnetic systems on it, Using a transmitting resonant system, resonant oscillations of the magnetic flux are excited in the pipe wall in the range 0.3–300 kHz, in two opposing, orthogonally oriented in relation to the axis of the pipe, they induce a vortex electric field in the pipe wall and on its surface, transmit electromagnetic energy along the pipe, receive it in the receiving resonant electromagnetic system and obtain the emf, which is used to power electric consumers, or transform into mechanical or thermal energy in any known manner. 2. The method of transmitting electrical energy according to claim 1, characterized in that the conductive channel is created in a steel or cast iron insulated or rotating pipe, while the transmitting and receiving coils of the resonant electromagnetic system are installed on the insulation layer or at a distance from the pipe, ensuring its rotation and the passage along the pipe wall of the flow of electromagnetic energy necessary to transmit a given power. 3. The method of transmitting electrical energy according to claim 1, characterized in that the electrically conductive channel is created through a steel or cast iron insulated or rotating pipe, while the transmitting and receiving coils of the resonant electromagnetic system are installed inside the pipe or in the grooves of the coupling between the two pipe sections in conjunction with the electrical receiver when installing the next section of the drill string, casing or pipe string. 4. The method of transmitting electrical energy according to claim 1, characterized in that the electrically conductive channel is created in a steel, or cast-iron insulated, or rotating pipe, while the transmitting and receiving windings of the resonant electromagnetic system are performed in two sections and orthogonally set the first section inside and the second section outside the pipe. 5. The method of transmitting electrical energy according to claim 1, characterized in that between the source and the receiver of electrical energy create an electrically conductive channel in a steel or cast-iron rotating pipe, placing on it the transmitting and receiving energy of the electromagnetic field electromagnetic resonance systems. 6. The method of transmitting electrical energy according to claim 1, characterized in that between the source and the receiver of electrical energy create an electrically conductive channel in a steel or cast-iron pipe, placing electromagnetic systems transmitting and receiving energy inside the pipe. 7. The method of transmitting electric energy according to claim 2, characterized in that between the source and the receiver of electric energy create an electrically conductive channel in a steel or cast-iron rotating pipe, placing electromagnetic systems transmitting and receiving energy of the vortex electric field inside the pipe. 8. The method of transmitting electrical energy according to claim 1, characterized in that between the source and the receiver of electrical energy create an electrically conductive channel in a steel or cast-iron pipe, placing electromagnetic systems transmitting and receiving energy of the vortex electric field on the surface and inside the pipe. 9. The method of transmitting electric energy according to claim 2, characterized in that an electrically conductive channel is created between the source and the receiver of electric energy in a steel or cast-iron rotating pipe by placing electromagnetic systems on the surface and inside the pipe that transmit and receive energy of the vortex electric field. 10. A device for transmitting electrical energy, containing a source and a receiver of electrical energy with a power line, characterized in that the device comprises an electrically conductive steel or cast iron pipe with transmitting and receiving resonant electromagnetic systems, the transmitting electromagnetic system is connected to a source of electrical energy through a current generator of increased frequency in the range (0.3 ÷ 300) kHz, and a resonant electromagnet receiving energy of a vortex electric field itnaya system is connected via a current inverter with electric power receiver. 11. The device for transmitting electrical energy according to claim 10, characterized in that the device comprises an electrically conductive metal pipe with transmitting and receiving resonant electromagnetic systems inside the pipe. 12. The device for transmitting electrical energy according to claim 10, characterized in that the device comprises an electrically conductive metal pipe with resonant electromagnetic systems transmitting and receiving on the surface and inside the pipe. 13. The device for transmitting electrical energy according to claim 10, characterized in that the device comprises an electrically conductive metal pipe with a rotation device with transmitting and receiving resonant electromagnetic systems located on its surface. 14. The device for transmitting electrical energy according to claim 10, characterized in that the device comprises a rotating electrically conductive metal pipe with a rotation device with transmitting and receiving resonant electromagnetic systems located inside the pipe. 15. The device for transmitting electrical energy according to claim 10, characterized in that the device comprises a rotating electrically conductive pipe with a rotation device with transmitting and receiving resonant electromagnetic systems located outside and inside the pipe.

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