RU2366058C1 - Electric power transmission method and device - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention can be used in electrical engineering. Generation of high-voltage high-frequency electromagnetic oscillations, modulation and transmission of electrical energy in form of radio signals takes place in voltage resonance mode. High-frequency electromagnetic oscillations at carrier frequency are generated through effect of magnetic field of permanent magnets on an isolated capacitor in form an insulated conducting body. The isolated capacitor is connected to a current collecting electrode. The high-frequency electromagnetic oscillations are amplified on voltage and current in a helical waveguide through transmission of the electromagnetic oscillations to the input of the helical waveguide from the current collecting electrode through an air gap to the receiving electrode of the outer arm of the helical waveguide and through effect of magnetic field of permanent magnets on the helical waveguide. The inner arm of the helical waveguide is connected to an electronic modulator and the modulated electrical energy is transmitted in form of a radio signal from the transfer electrode through space surrounding the electrode to the receiver of the user. A device which implements this method is also proposed.

EFFECT: simplification of the generating circuit, increased efficiency and reduced power consumption.

4 cl, 1 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 of electric power transmission, including the generation of high-frequency electromagnetic waves and their subsequent emission in the form of electromagnetic waves in such a way that high-frequency electromagnetic waves generated in a transmitter with a carrier frequency, are modulated in the radio frequency range in accordance with the transmitted message. The radio signal from the transmitter enters the transmitting antenna, through which modulated electromagnetic waves are excited in the space surrounding the antenna. Propagating, they reach the receiving antenna and excite harmonic electrical vibrations in it, which then enter the receiver.

A known device for transmitting electrical energy in the form of a radio signal contains a source of electrical energy, a self-excited electric oscillation generator that converts electric current energy to electrical vibration energy, a power amplifier of these oscillations, a modulator, an antenna (Ref .: Radio transmitting devices, edited by O.A. Chelnokova, M., 1982).

The disadvantage of this method and device is the inability to obtain sufficiently powerful electrical oscillations with high frequency stability.

Another disadvantage of the known method and device is the need to use long-range beam antennas to transmit long-wave electric vibrations.

The task of the invention is to simplify the generating circuit, increase efficiency and reduce energy costs for generating electromagnetic waves, as well as increase the transmitted power of the radio signal.

The above result is achieved in that in a method for transmitting electricity, including generating high-frequency electromagnetic waves in a transmitter with a carrier frequency in the frequency range 1 kHz-100 MHz, modulating and transmitting a radio signal to a transmitting antenna, transmitting a radio signal in the form of radio waves to a receiving antenna, and excitation in harmonic electric oscillations and transferring them to the consumer receiver, generating high-voltage high-frequency electromagnetic waves, modulating and transmitting electrically energies in the form of radio signals are produced in the voltage resonance mode, high-frequency electromagnetic oscillations of the carrier frequency are created by applying the magnetic field of permanent magnets to a solitary capacitance in the form of an insulated conductive body and attach a solitary capacitance to a current collector electrode, amplify high-frequency electromagnetic oscillations in a spiral waveguide by voltage and current by supply to the input of the spiral waveguide of electromagnetic oscillations from the collector electrode through the air gap to p To the receiving electrode of the external branch of the spiral waveguide and the magnetic field of the permanent magnets acting on the spiral waveguide, the internal branch of the spiral waveguide is connected to the electronic modulator and the modulated electrical energy is transmitted as a radio signal from the transmitting electrode through the space surrounding the electrode to the consumer receiver.

The technical result is also achieved by the fact that in the proposed device for transmitting electrical energy in the frequency range 1 kHz-100 MHz, containing a source of electrical energy, a self-excited electric oscillation generator that converts electric current energy into electrical energy, an amplifier of these vibrations, a modulator and the antenna, the generator of electrical vibrations is made in the form of a shaft rotation mechanism, on which a secluded capacitor is mounted on an insulator, a secluded capacitor is located in in the luminous space of a permanent magnet source of magnetic field, in a plane perpendicular to the magnetic induction vector, a current-collecting transmitting electrode is connected to the center of rotation of the solitary capacitance, directed through the air gap to the receiving electrode of the external branch of the spiral waveguide, the spiral waveguide is installed in the interpolar space of the magnetic field sources of permanent magnets, an electronic modulator is connected to the internal branch of the spiral waveguide, which transfers the modulated electrical energy to a radio signal through an antenna in the form of a transmitting tubular electrode with an active element to the antenna of the consumer radio signal receiver.

In an embodiment of a device for transmitting electrical energy, the active element is made in the form of a solid-state laser.

In another embodiment of the device for transmitting electrical energy, the active element is in the form of a microwave generator.

The essence of the proposed method and device for transmitting electric energy in the form of a radio signal in the frequency range 1 kHz-100 MHz is illustrated in the drawing, which shows a general diagram of a method and device for transmitting electric energy using a master generator of a carrier frequency in the form of an isolated solitary capacitance from a conductive material and a spiral waveguide to enhance the potential and the formation of the conductive channel, as well as magnetic field sources of permanent magnets to excite high-frequency electrons magnetic oscillations on the surface of a solitary capacitance and amplification of potential in a spiral waveguide.

In the drawing, the carrier oscillator 1 is made in the form of a rotation mechanism 2 with an insulator 4 fixed to the shaft 3. A secluded capacitor 5 is attached to the insulator 4. The surface of the secluded capacitor 5 is located in the pole space of the permanent magnet source 6. At the point of the center of rotation of the secluded capacitance 5, a collector transmitting electrode 8 is attached, which passes through the cavity 7 of the magnetic field source 6. The collector transmitting electrode 8 is directed through the air gap 9 towards the receive electrode 10 of the outer branch 12 of the spiral waveguide 14 using an electric bus 11. Spiral the waveguide 14 is installed in the interpolar space of the sources of the magnetic field of the permanent magnets 13, 16. The Central branch 15 of the spiral waveguide 14 using a conductor 18 passing through the cavity 17 of the source magnetic field 16, is connected to the input 19 of the electronic modulator 20, the output 21 of which is connected via an electric bus 22 to the junction 23 of the contact sleeve 24 of the transmitting tubular electrode 25. The transmitting tubular electrode 25 is connected through an electrical insulator 26 to a shielding box 28 containing the active element 29 and the hole 27. Electromagnetic waves diverge into space from the transmitting tubular electrode 25 through a conductive channel 30.

The method of electric power transmission is implemented as follows. When a magnetic field of a permanent magnet 6 acts on a secluded capacitance 5, secluded capacitance 5 generates high-frequency electromagnetic waves with voltage amplitudes that are directly proportional to the sectorial velocity V _{s of the} geometric points of the surface of rotation of the secluded capacitance (V _s = uR, where u is the orbital velocity of the point, R - radius of rotation of the point), which creates a concentric voltage gradient, capacitive reactive currents and bias currents in the space surrounding the surface of a secluded tank 5, which increase from price ra rotation to the edge surface of a solitary container. Changing the distance of the air gap 9 between the collector electrode 8 passing through the cavity 7 of the permanent magnet 6, and the receiving electrode 10 of the outer branch 12 of the spiral waveguide 14, select the frequency of the resonance voltage in the spiral waveguide 14. The transmission of electricity from the Central branch 15 of the spiral waveguide 14 using a conductor 18 through the cavity 17 of the permanent magnet 16 to the input 19 of the electronic modulator 20 and from the output 21 of the electronic modulator 20 using the bus 22 to the connection point 23 of the contact sleeve 24 transmitting its tubular electrode 25 of the active element 29, enclosed in a shielding jacket 28 containing the hole 27, is carried out using capacitive reactive currents and bias currents in the space surrounding the electrode 25, from the conductive channel 30 formed by the active element 29, in the mode of voltage resonance, at matching the frequencies of a secluded capacitance 5 with the resonant frequencies of the spiral waveguide 14, changing the air gap 9.

An example of the method and device for transmitting electricity.

The rotation mechanism 2 in the drawing has a rated power of 10 kVA, the number of revolutions is 10-100 s ^-1 . The solitary container 5 is made of a copper plate with a thickness of 0.005 m in the form of a disk with a diameter of 1 m, is attached to the shaft 3 of the rotation mechanism 2. When the solitary vessel 5 is rotated in the pole space of the magnetic field source 6 with a pole surface area of Sп = 1 m ² and magnetic field induction B = 9 · 10 ^-4 T, high-frequency electromagnetic waves with a nominal frequency fн = 1 kHz-100 MHz are generated at the collector transmitting electrode 8. Energy is transferred from the collector transmitting electrode 8 through the air gap 9 to the receiving electrode 10 of the outer branch 12 of the spiral waveguide 14 in the form of a spark discharge of electric current with a power of up to 1000 A. The spiral waveguide 14 is made of a copper tape 0.001 m thick and 0.05 m wide, s isolation between turns of 0.001 m. By changing the gap between the collector electrode 8 and the receiving electrode 10, the resonance frequency of a solitary capacitance 5 and a spiral waveguide 14 is obtained with a continuous spark discharge in the air gap 9 between the transmitting electrode 8 and p receiver electrode 10.

A feature of a spiral waveguide located in the interpolar space of permanent magnets is its ability to operate in a voltage resonance mode, pumping electromagnetic energy with the subsequent release of stored energy. In fact, the generator of high-frequency high-voltage electromagnetic waves 1, made in the form of a resonant system 2-18 with an open generating circuit, is an analogue of a maser operating in the frequency range 10 kHz-100 MHz at the maximum possible power with modulation of high-frequency electromagnetic waves. The pumping of electromagnetic energy in a spiral waveguide is as follows. When electricity is supplied from the collector transmitting electrode 8 to the receiving electrode 10 of the outer branch 12 of the spiral waveguide 14 with an electromagnetic frequency from 1 kHz to 100 MHz, the spiral waveguide 14 becomes a spiral resonator in the voltage resonance mode.

Claims (4)

1. A method of transmitting electrical energy, including the generation of high-frequency electromagnetic waves in a transmitter with a carrier frequency in the frequency range 1 kHz-100 MHz, modulating and transmitting a radio signal to a transmitting antenna and in the form of radio waves to a receiving antenna and exciting harmonic electric oscillations therein, and their transmission to the consumer receiver, characterized in that the generation of high-voltage high-frequency electromagnetic waves, modulation and transmission of electrical energy in the form of radio signals production In the voltage resonance mode, high-frequency electromagnetic oscillations of the carrier frequency are created by applying a magnetic field of permanent magnets to a solitary capacitance in the form of an insulated conductive body and attach a solitary capacitance to a collector electrode, amplify high-frequency electromagnetic oscillations in a spiral waveguide by voltage and current by applying a spiral waveguide of electromagnetic oscillations from the collector electrode through the air gap to the receiving electrode of the outer spiral branch a single waveguide and acting on a spiral waveguide with a magnetic field of permanent magnets, attach the internal branch of the spiral waveguide to an electronic modulator and transmit modulated electrical energy in the form of a radio signal from the transmitting electrode through the space surrounding the electrode to the consumer receiver. 2. A device for transmitting electrical energy in the frequency range 1 kHz-100 MHz, comprising a source of electrical energy, a self-excited electric oscillation generator, converting electric current energy to electric vibration energy, a power amplifier of these oscillations, a modulator and an antenna, characterized in that the generator electrical vibrations is made in the form of a shaft rotation mechanism, on which a secluded capacitance is mounted on an insulator, a secluded capacitance is located in the pole space of a magnetic source about the field of permanent magnets, in a plane perpendicular to the vector of magnetic induction, a current-collecting transmitting electrode is connected to the center of rotation of the solitary capacitance, directed through the air gap to the receiving electrode of the outer branch of the spiral waveguide, the spiral waveguide is installed in the pole space of the sources of the magnetic field of permanent magnets, to the inner branch a spiral waveguide is connected to an electronic modulator that transmits modulated electrical energy in the form of a radio signal through an antenna in the form of Reda tubular electrode with the active antenna element to the receiver radio user. 3. A device for transmitting electrical energy according to claim 2, characterized in that the active element is made in the form of a solid-state laser. 4. A device for transmitting electrical energy according to claim 2, characterized in that the active element is made in the form of a microwave generator.