RU2008110607A - METHOD FOR CREATING AN EXCELLENT QUASI-SUPERCONDUCTING CURRENT AND METHOD FOR USING ENERGY IN TECHNOLOGY - Google Patents

Abstract

1. A method of creating a super-strong open quasi-superconducting current, characterized by the possibility of using a device of the "Tesla resonant transformer" type to create (generate) current, characterized in that a diode bridge (valve or diode) can be used. ! 2. The method according to claim 1, characterized in that a device is used that contains an oscillating circuit formed from an inductor (reactive coil) with a closed (almost closed) (slotted, split or dissected) core (for example, a ferromagnetic magnetic circuit) and a capacitor ( capacitance), connected in series to an electric circuit with an alternating current source (voltage generator), and a secondary resonant coil, which, together with a stray capacitance (and with a load), is part of the resonant LC circuit, at than the voltage generator is included in the circuit and operates at the resonant frequency of the LC circuit of the secondary coil. ! 3. The method according to claim 1, characterized in that the operating frequencies from the range from 0 Hz to 500 MHz are used. ! 4. The method according to claim 1, characterized in that the closed (almost closed) core (magnetic core) is made in the form of at least one curved fragment connected (connected) by the ends of the butt, and between adjacent parts of the ends of the fragments in the material of the core (magnetic core) ) along the plane perpendicular to its axis, a gap is created - a gap filled with non-magnetic material. ! 5. The method according to claim 1, characterized in that a dielectric gasket is introduced into the working gap. ! 6. The method according to claim 1, characterized in that the circuit breaker introduced a current chopper

Claims (24)

1. A method of creating a super-strong open quasi-superconducting current, characterized by the possibility of using a device of the "Tesla resonant transformer" type to create (generate) current, characterized in that a diode bridge (valve or diode) can be used. 2. The method according to claim 1, characterized in that the device is used, containing an oscillating circuit formed from an inductor (reactive coil) with a closed (almost closed) (slotted, split or dissected) core (for example, a ferromagnetic magnetic circuit) and a capacitor ( capacitance), connected in series to an electric circuit with an alternating current source (voltage generator), and a secondary resonant coil, which, together with a stray capacitance (and with a load), is part of the resonant LC circuit, at than the voltage generator is included in the circuit and operates at the resonant frequency of the LC circuit of the secondary coil. 3. The method according to claim 1, characterized in that the operating frequencies from the range from 0 Hz to 500 MHz are used. 4. The method according to claim 1, characterized in that the closed (almost closed) core (magnetic core) is made in the form of at least one curved fragment connected (buttressed) by the ends of the butt, and between adjacent parts of the ends of the fragments in the material of the core (magnetic core) ) along the plane perpendicular to its axis, a gap is created - a gap filled with non-magnetic material. 5. The method according to claim 1, characterized in that a dielectric gasket is introduced into the working gap. 6. The method according to claim 1, characterized in that a current chopper (electronic key) is introduced into the circuit of the oscillating circuit, with the help of which a voltage resonance with periodic or quasiperiodic cyclicity is periodically created (excited) in the oscillatory circuit, that is, the circuit operates in the mode of sequentially alternating periodically repeating input-output-input-output ... from the voltage resonance mode so that the circuit periodically enters the resonance state (is in an unstable state gos resonance (voltage resonance). 7. The method according to claim 1, characterized in that the core (magnetic circuit) is made of two horseshoe-shaped or U-shaped oscillating halves fixed in the middle, and the core (magnetic circuit) is made of a toroidal shape, for example, the core (magnetic circuit) is made of round or quasi-rectangular O- shaped or rectangular section. 8. The method according to claim 1, characterized in that the working gap is 0.05 ... 0.20 mm 9. The method according to claim 1, characterized in that the inductance coil and the secondary resonant coil are placed on the core (magnetic circuit) in such a way that the plane of one working gap passes through the inductance coil, and the other working gap passes through the secondary resonant coil, each of which coils covers the gap. 10. The method according to claim 1, characterized in that the inductor is structurally performed in the form of a multilayer cylindrical spiral of a Licentrate with external insulation, wound round to round on the surface of the frame with a core (magnetic circuit). 11. The method according to claim 1, characterized in that the secondary coil is a multilayer package consisting of one or more separated by a dielectric layer from each other, distributed throughout the core (magnetic circuit) from alternating layers of dielectric and connected in series volumetric turns applied ( wound, for example, wound with a tape) in layers in the form of a toroidal or cylindrical container with external insulation, coaxially inserted one into another, covering the magnetic circuit with the output of the inner edge to spikes in the form of a series of end or radial plates symmetrical with respect to the common axis through cuts that cut the surface of the inner turn of the container along current lines (current distribution lines) and the plates are rigidly attached to the pipe and the outer edge of the coil to a ring, and the leads of the secondary coil to one of which an open (open at the end) load circuit is connected, made coaxial. 12. The method according to claim 1, characterized in that the inductance coil is partitioned (in the form of separate sections). 13. The method according to claim 1, characterized in that the volumetric turns are made in the form of conductive coatings. 14. The method according to claim 1, characterized in that the inductor and the secondary coil are made of diamagnetic material (for example, pure copper, silver). 15. The method according to claim 1, characterized in that the core (magnetic circuit) is adjusted, the oscillatory circuit is tuned to the main resonant frequency by changing the thickness of the gaskets in the air working gap, followed by tightening the magnetic circuit with a tie pin. 16. The method according to claim 1, characterized in that the technical solution is used in the form of a "throttle" with a parasitic capacitance (for example, on an almost closed U-shaped slotted core (magnetic core) with a gap) or a resonator with distributed parameters (for example, in the form a cylindrical single-layer spiral winding on a rod (frame) of dielectric material, such that at a resonant frequency, taking into account the deceleration and the value of the capacitance, a quarter of the wavelength fit along the axis of the rod) or (and) capacitance (spherical or toroidal Or others. Condenser) for energy storage, which comprise a diode bridge before (or unit of two anti-parallel diodes are included, or valve, or a rectifier or diode), or after the diode bridge. 17. The method according to claim 1, characterized in that a spherical capacitor is used, made in the form of two isolated, separated by a layer of a substance (medium) having semiconducting (conductive) properties or a dielectric (ie, a substance having a certain band gap) parallel conductive plates in the form of concentric truncated spherical surfaces (the inner surface of the outer shell is equidistant to the outer surface of the inner shell), and the charges are of the same sign (for example, negative) applied (or induced, or induced, arise) from the inside, at operating temperature, on the concave inner surface of the inner spherical electrically conductive lining of a spherical capacitor, for example, by creating a corona discharge, and the outer lining is connected to a common point of the device (“ground”), and during the charging process (or after the end of the process), the spherical condenser is cooled to a temperature at which the leakage current (self-discharge) corresponds to a certain value, or the capacitor is cooled below the temperature urs phase transformations polarized medium spherical capacitor. 18. The method according to claim 1, characterized in that the conductive surfaces of the plates of the spherical capacitor are made smooth, and made of diamagnetic material (for example, copper). 19. The method according to claim 1, characterized in that the current carriers are quenched on the surface of the cooled quenching chamber (or in the quenching medium) at a given temperature, for example, a Dewar vessel with liquid nitrogen. 20. The method of using energy in technology, characterized in that they use a superstrong open quasi-superconducting current, which is a distribution process (a set (corresponding to the concept of a set) of processes (phenomena) caused (created, excited or (and) formed, excited) by distribution ) (occurrence, transfer, “overflow”, “passage”) of an ordered set (ordered structures of current carriers) of free charges (excitation quanta) of only one sign (negate positive or positive) along an open galvanic circuit (part of the circuit) that directs the distribution, characterized by a greater strength (magnetic field strength) of the current and a higher current density (higher effective current density) (higher magnetic intensity and (or) greater magnitude of the flux of electric induction) and significantly lower voltage (significantly lower electric field strength). 21. The method according to claim 20, characterized in that the distribution process is carried out under an unsteady resonance mode (conditions when a resonance mode with periodic or quasiperiodic cyclicity is created and violated (or excited)) or under transient conditions of an unsteady (unsteady) resonance. 22. The method according to claim 20, characterized in the form of application for a specific purpose to create a rotating field, a field of varying localization (traveling wave) or a wave field of beats. 23. The method according to claim 20, characterized in that a laser beam (a channel of a beam or a beam of rays or beams of rays), for example, a beam of the so-called free-electron laser, is used as a conducting (directing) current of the medium. 24. The method according to claim 20, characterized in the form of application for a specific purpose for the implementation of the ponderomotive effect (the ponderomotive interaction effect that does not satisfy Newton’s third law of mechanics (with the possibility of violating the equality of action and reaction) and (or) violation of the second law of thermodynamics) or energy production or for ponderomotive (mechanical) work (ponderomotive “effort”).