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INVENTION
Russian Federation Patent RU2200875
BOGDANOVA electromagnetic motors for propulsion
On new physical principles

Searle drive, engine technology invention patent magnetic motor, electromagnetic motor, the motor based on new physical principles of operation, the engine Bogdanova

INVENTION. BOGDANOVA electromagnetic motors for propulsion on new physical principles. Russian Federation Patent RU2200875

Name of applicant: Bogdanov Igor Glebovich
name of the inventor: Igor Bogdanov Glebovich
The name of the patentee: Bogdanov Igor Glebovich
Address for correspondence: 111402, Moscow, ul. Old Guy, 6, building 1, kv.151, IG Bogdanov

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The invention relates to engines for propulsion on new physical principles for aircraft. It can be used to create traction systems in aviation and astronautics. The engine for propulsion on new physical principles contains a power supply system system of induction coils, the apparatus rotation, consisting of a stator and rotor, comprising a ring with a rotatable substance providing electromagnetic radiation conductive shield for shielding electromagnetic radiation with at least one window, while next to the window cover is made conductive and the movement of the cap device. The invention allows to increase engine thrust.

DESCRIPTION OF THE INVENTION

Known engine to produce thrust on new physical principles to effect movement of the object, comprising a magnetic field source made in the form of toroidal current coil, and the magnetic vector potential field winding current is directed at an angle of 90-270 degrees towards the cosmological vector potential, resulting in the inner region of the toroid are constant region and a region of low vector potential [1]. The region with reduced total vector potential is moved material bodies (w) mounted on the output from the internal cavity of the toroid and is rigidly fastened to the body of the object rods arranged uniformly over the toroid surface, and provided with a drive of their extension-cleaning along radial directions forming circumferential torus surface. Based on the area of ​​physical vacuum, in which there is a reduction of the cosmological vector potential due to the vector potential of the magnetic field source, insertion into this region the material body, rigidly connected, for example, a solenoid, entice him away. Thus, the source of the magnetic field creates a region of space in which there is a new force, and the magnet system with the body moving in space due to the energy of the physical vacuum.

The disadvantage is the low thrust engine. For example, for experiments in the magnetic field coils 17 to 150 kG and weighs 191 kg thrust model did not exceed 4 g [28].

In other experiments in fields from 130 to 140 kgf and the weight load of 26 to 30 g Rod was about 2.7 dyne / g [29].

To increase the traction engine is necessary to increase the volume of the region occupied by the magnetic field, to bring in a large area of ​​a large mass of material body. Increasing the area occupied by the magnetic field energy corresponds to an increase of the magnetic field coil is stored in the coil. Meanwhile, it is known that with increasing magnetic field energy in the superconducting solenoid growing radial stresses, tending to destroy it, what prevents to increase the volume of the region occupied by the magnetic field, and it is known that with the growth of a superconducting solenoid size decreases the current density flowing through its windings due occurrence of eddy currents during the washing.

These two factors make it difficult to increase the traction due to the increase of the stored in a superconducting solenoid, magnetic energy.

Known engine for propulsion on new physical principles Searle disk (Searle, Tsarlya, Charles) [2, 3], comprising a rotor comprising a rotatable material configured as a magnetized ring mounted on rollers arranged to rotate about an axis. Rotor before takeoff placed inside the stator. The engine is provided with a rotation device configured to rotate the rotor made as a ring magnetized. rotation device disperses electromagnetic forces magnetized ring mounted on rollers, to a large number of turns and rotates at high speed. Ring, starting from a certain rotational speed is accelerated, losing weight and then takes off. Controlled flight apparatus from London was made to the peninsula of Cornwall and back, a total of 600 km.

The disadvantage of the motor drive Searle is a small thrust during the flight. During flight thrust is small since Searle disk, according to the author, inefficiently uses the energy produced when the rotation of the magnetized disk of electromagnetic radiation, the nature of which will be described below. This radiation, according to the author, in the case of a disk drive Searle after takeoff to a height greater than the diameter of the disc, just heats the atmosphere (air) around the disc, and the disc just Searle rises in updrafts of hot air. This method of propulsion makes it impossible to use Searle drive in a vacuum because the vacuum will be streams of rising air. Regarding the use of disk Searle photon thrust from occurring during the rotation of the electromagnetic radiation of the disk, then the photon thrust, in fact, is not used, since the radiation is uniformly distributed up and down on the disc, Searl and the strength of the scattering of radiation acting on the top and bottom of the disc from the radiation, mutually compensated. Therefore, the resulting traction drive Searl during flight is low, as it does not increase photon thrust arising from the disc rotating Searle electromagnetic radiation, which is described below nature.

The task facing the invention is to increase thrust during the flight.

This object is achieved in that the engine for producing thrust, comprising a power supply system, the induction coil system, the rotation device consisting of a stator and rotor, comprising a ring with a rotatable substance providing electromagnetic radiation comprises a conductive shield for shielding electromagnetic radiation, at least one window, while near a window made conductive cap covers and transfer apparatus.

This object is achieved by the fact that the screen is designed as a figure of revolution, with the chamber formed with a cavity inside the screen.

This problem is solved in that the screen and camera are mounted within the frame cavity, made in the form of a polyhedron.

This object is achieved by the fact that around the rotation axis of the device is made of at least one system of rollers connected to the rotation device.

This object is achieved by the fact that one of the induction coils formed around the rotor, with the plane parallel to the coil windings of the rotor axis.

This object is achieved by the fact that the rotor ring comprises at least one coil winding wound around the ring, while the coil is electrically insulated from the ring and the corner segment occupies not more than half of the ring surface of the ring and the coil axis lies in the plane of the ring.

This object is achieved by the fact that the winding comprises a superconductor.

This object is achieved by the fact that the substance comprises a rotatable two-dimensional conductor.

This object is achieved by the fact that the two-dimensional plane of maximum conductivity of the conductor perpendicular to the axis of the ring.

This object is achieved by the fact that two-dimensional conductor is designed as a conductive film.

This object is achieved by the fact that inside the ring formed cryostat.

This object is achieved by the fact that the motor comprises a magnetic coil, formed inside the cryostat, which has at least one pair of superconducting windings, made along each other and energized by currents of opposite directions.

This object is achieved by the fact that the substance contains rotatable layered crystal plane with a maximum conductivity layered crystal axis perpendicular to the ring.

This object is achieved by the fact that the engine comprises at least one reflector is configured as a mirror, comprising at least one conductive layer with the ability to reflect electromagnetic radiation, wherein the reflector is formed around the window.

This object is achieved by the fact that the engine comprises at least one device moving reflector coupled to the rotation device.

This object is achieved by the fact that the engine comprises at least one reflector rotation device coupled to the rotation device.

This object is achieved by the fact that the reflector comprises a multilayer structure with two-dimensional conductors.

This object is achieved by the fact that the inner facing the rotating screen device surface is a multi-layer structure with two-dimensional conductors.

This object is achieved by the fact that the Fermi energy of the two-dimensional conductor material layer with increasing distance from the rotor surface in any two adjacent layers does not change or increases.

This object is achieved by the fact that the engine includes a hanger coupled to the screen, with the rotation device and the rotor, providing the possibility of free rotation unit rotating with the angle of inclination of the screen.

This problem is solved by the fact that the suspension is in the form of a gimbal.

This object is achieved by the fact that the engine comprises at least one additional longitudinal magnetic field coil adapted to create a material in a rotating magnetic field along the axis of rotation of substance.

This object is achieved by the fact that the additional longitudinal magnetic field coil provided around the rotor axis.

This object is achieved by the fact that the engine comprises at least one electron accelerator with an electron source, wherein an electron source is formed around the rotor and comprises at least one emissive cathode.

This object is achieved by the fact that the engine comprises more than two telescopic legs adapted to change its length, being sucked into the engine, or pressed against the motor.

This object is achieved by the fact that the engine includes a connecting unit configured to dock at least two engines together, and at least one computer controlling the operation of the engine, and after docking engines computers are combined into a single local area network.

This design allows the engine to create traction performance on two different physical principles in two different ways.

The first method allows you to create the photon engine thrust to the pressure on a rotating substance of the order of several hundred tons per square meter of the surface of the rotating substance. Photon thrust with pressure force radiation scattering theoretically feasible to establish due to the fact that it is possible to remove the screening with several kinds of electromagnetic fields that are naturally present in various combinations in any material, but do not go outside of the fact that the shielded movement of free electrons and turns the axes of rotation of the electron shells of atoms and nuclei.

These electromagnetic fields occur as a relativistic effect of different types of motion of charged particles forming substance. Movement of particles occur within the material. Electric fields of moving particles, depending on the speed have an angular dependence due to relativistic effects.

During the rotation of matter at high speed electron shells of atoms and nuclei of atoms under the influence of the total emission of these fields are under the influence of a pair of arm strength. Since the nucleus and electron shells still rotate under the influence of couple they make precession that prevents such rotation axes of their own moments of rotation, in which the radiation is completely shielded. These electromagnetic fields in rotation substance with high speed stop is partially screened and out of matter, creating powerful electromagnetic radiation. The intensity distribution of this radiation depending on the angle with respect to the rotational axis symmetrically about the axis of rotation and material symmetrically about a plane passing through the center of mass of the rotating axis of rotation perpendicular to the substance. Therefore, no thrust around a rotating material does not occur, even though the radiation is.

The photon thrust generated by the fact that a portion of the space next to the rotated material overlaps the conductive shield. In this screen overlaps the flux in this direction, and reflects a part of the radiation in the opposite direction, creating a draft.

To create thrust in the desired direction of the windows formed in the screen with the possibility of electromagnetic radiation passing through the window, overlap the conductive lids displacement device cover and the reflect light incident upon them. Part of the views and the radiation comes out of them through a region surrounded screen photon producing thrust in the desired direction.

and to create thrust in the desired direction of the light output from the windows on the reflectors, and reflectors are moved and rotated devices move the reflectors so that the reflected light beam is reflected in a given direction to produce thrust in the desired direction.

Most emission occurs in two cases.

In the first case a rotatable at a high speed rotation device affects substance short pulses sequentially first magnetic field parallel to the axis of rotation, and then a magnetic field perpendicular to the rotation axis. As a result, everything revolves agent starts to make precession. At the same time large areas of the rotating substance during precession synchronized tilt axis of the magnetic moments of the electron shells of atoms. The angles of inclination of a large number of magnetic moments of the electron shells of the same. At this time, the rotating electrons of the electron shells of the atoms have the same angular orientation of the electric field created by them, due to their relativism, whereby these regions emit.

In the second case a rotatable two-dimensional material includes conductor layers formed perpendicularly to the axis of rotation. In the two-dimensional conductor layers occur vibration and rotation of the electron plasmons. The electrons move predominantly plasmons in the same plane and emit. The radiation is not shielded rotated at a high velocity dielectric as to shield the magnetic moments of the electron shells of atoms of the dielectric should turn perpendicular to the axis of rotation, and to create leverage forces that cause rotation, precession occurs, the frequency of which is much smaller than the electron oscillation frequency of the plasmons.

Since the frequency of the plasmon radiation of electrons exceeds the precession frequency of the field arising in the course of the precession can not completely escape this radiation.

The second method allows the engine to create thrust through the use of electromagnetic energy. To do this, turn the substance contains paramagnetic or ferromagnetic. Rotatable substance may be configured as a magnet. The magnet is designed as a ring. When you rotate the paramagnetic material or ferromagnetic substance is rotated by magnetomechanical phenomena additionally magnetized and creates a magnetic field around itself. During a paramagnetic material or ferromagnetic rotation may further increase the magnetization by polarization paramagnetism, which does not test the trend towards saturation. As a result, the material in the rotating magnetic fields are generated with an intensity exceeding the magnetic field strength achievable in superconducting magnetic systems.

The vector potential of the magnetic field of the rotating material at an angle 90-270 degrees toward the cosmological vector potential. The region with the magnetic field of the rotating mass of material introduced substance such material body, with a device moving the mass of substance. As a result, some substances are rotated with a constant region and a region of low vector potential. In areas with low total vector potential is moved masses of matter (material body) made inside the rings gimbals, with a device moving masses of matter. Since the gimbal and is designed as a magnet, the inside of the ring further by moving a region of low vector potential within the material body of the ring.

Based on the area of ​​physical vacuum, in which there is a reduction of the cosmological vector potential due to the vector potential of the magnetic field source, introduced into this area mass of the substance, such as a material body, rigidly connected, for example, a gimbal ring, drags him along. Thus, the source of the magnetic field creates a region of space in which there is a new force, and the magnet system with the body moving in space due to the energy of the physical vacuum.

There were no technical solutions, reaching the task similar technical means.

BOGDANOVA electromagnetic motors for propulsion on new physical principles. Russian Federation Patent RU2200875

FIG. 1 izobazhena printsipialnaya scheme of torsional engine Bogdanov in horizontal thrust to open the side windows and the closed upper and lower windows.

BOGDANOVA electromagnetic motors for propulsion on new physical principles. Russian Federation Patent RU2200875

Figure 2 shows a section A-A.

BOGDANOVA electromagnetic motors for propulsion on new physical principles. Russian Federation Patent RU2200875

Figure 3 shows a section B-B.

BOGDANOVA electromagnetic motors for propulsion on new physical principles. Russian Federation Patent RU2200875

Figure 4 shows a section of the main ring.

BOGDANOVA electromagnetic motors for propulsion on new physical principles. Russian Federation Patent RU2200875

5 shows a sectional view of a multilayer structure.

The engine includes a spinning device 1 comprising a rotor 2 with a rotating material containing the base ring 3, and the rotation device configured to rotate the rotor, and with it its constituent base ring. The rotor, and with it the main ring system is connected to the rollers or bearings 4 with the stator rotation device.

The apparatus comprises three rotating induction coils cross the magnetic field 5, 6, 7 formed around the main ring of the rotor symmetrically about the rotor axis with the possibility of generating a magnetic field transverse to the rotation axis, the magnetic field lines are perpendicular to the coil rotation axis substance. The coils are made at an equal distance from each other.

The engine 8 includes a power supply system, said power system comprising induction coils. The induction coil is made from the side of the main ring and the plane perpendicular to the plane of the ring of coils of the induction coil, wherein the coil of the induction coil is bent so as to surround part of the ring and the ring is arranged to rotate around a portion of the coil so that the coil portion surrounds the ring.

The ring comprises at least three winding coil 9, 10, 11 wound on the ring, with the winding is electrically isolated from the ring, wherein the coil axis lies in the plane of the ring, while the coil takes on not the entire surface area of ​​the ring. The windings are electrically isolated from each other. Between windings of the ring section does not contain windings. The surface area of ​​the base ring windings without exceeding the surface area of ​​the ring covered by windings. Windings arranged symmetrically with respect to the rotation axis substance.

the rotation device comprises at least one longitudinal magnetic field coil 12 configured to create a material in a rotating magnetic field along the axis of rotation of substance. Coil longitudinal magnetic field formed around the rotational axis of the substance. Coils of a transverse magnetic field are made close to each other, at the same time around the coil is made of a longitudinal magnetic field that surrounds them.

Rotating primary ring material in some areas, a two-dimensional layer comprises a conductor, or a multilayer structure of two-dimensional layers of conductors, or more multilayer structures with layers of two-dimensional conductors. 4 and 5 is shown a multilayer structure 14.

Two-dimensional conductors are artificially created conductive system at the interface of two poorly conductive medium, such as a vacuum - insulator, semiconductor - insulator [20]. An example of a two-dimensional conductor - layer electrons, held above the surface of the dielectric with a negative electron affinity (eg, liquid helium) electrostatic image forces (electrons polarized dielectric and are attracted to it), but also the external constant electric field applied perpendicular to the surface of the dielectric. Similarly heterostructures (e.g., gallium arsenide) at the free surface of the semiconductor layer is formed with a two-dimensional concentration of excess charge carriers moving or inverse conductivity. The two-dimensional layer is formed due to the band bending and the application of the potential difference to the structure of the metal - insulator - semiconductor. Two-dimensional conductors, and are thin metal film. and two-dimensional conductors are in layered crystals.

Main ring contains a lot of two-dimensional conductors, such as conductive films made of a metal thickness of 0.01 to 0.1 microns, between which a film made of a dielectric. The conductive film formed parallel to each other and perpendicular to the axis of rotation of the rotor. Many two-dimensional conductors separated by a dielectric to form a multilayer structure.

Inside multilayer structure made of two-dimensional layers of conductors 18, 19, 20. In the two-dimensional conductor layers formed dielectric layers 21, 22, 23. The dielectric layers are electrically separated from each other by layers of two-dimensional conductors. The structures are made of layers. The plane of maximum conductivity of two-dimensional conductor is perpendicular to the axis of the rotor. The two-dimensional conductor is designed as a conductive film, wherein the film plane perpendicular to the rotor axis. The film thickness is chosen as small as possible, for example, on the order of several interatomic distances.

Some portions of the multilayer structure formed on the end surfaces of the main ring. We call the end portions of the multilayer structure.

The end portion of the multilayer structure of the ground ring may contain from 5 to 50 conductive films. The approximate thickness of the dielectric film of from 0.1 to 10 microns. The conductive film may be made of ferromagnetic material.

Some portions of the multilayer structure formed on the sides of the main ring. We call them the side portions of the multilayer structure.

Two-dimensional conductors may be formed as a ferromagnetic film.

The structures are made in the form of plates, in addition, an additional dielectric layers may be formed as a dielectric waveguide with the ability to pass along the dielectric layer plane electromagnetic radiation with a wavelength plasmon radiation. For this purpose, the refractive index at the center of the dielectric insulator layer must be greater than the dielectric layer near the edges of the two-dimensional conductor.

Yield dielectric waveguide is formed on the side surface of the main ring. To output from the waveguide light on the side surface of the main ring is made of a dielectric waveguide end to output end of the light propagating in the waveguide.

Vraschayuschemoe substance of the main ring, which is part of the rotor may contain a two-dimensional conductor is formed as a layered crystal [21]. The layered crystal is a crystal with a layered type of crystal packing and, consequently, a strong anisotropy of the electron motion. As the layered crystal, which may comprise a rotating substance can be offered, for example, a compound interkanalirovannoe transition metal dichalcogenide TAS 2 pyridine. For this connection there is a high conductivity anisotropy order 10 5.

If the rotatable base ring comprises a multilayer system of two-dimensional conductors, such as conductive films separated by insulators or layered crystals, perpendicular to the film plane of the axis of rotation of matter, a two-dimensional plane perpendicular to the conductor material and the plane of the axis of rotation or the direction of maximum conductivity layered crystal material perpendicular to the axis of rotation.

The surface of the base ring constituting the rotor is formed as a multilayer structure with two-dimensional conductors. The multilayer structure of the surface of the ground ring may comprise a two-dimensional conductors, made either of the same material or of different materials. In this case the Fermi energy of two-dimensional materials conductors with distance from the surface of the main ring, the rotor surface does not decrease, that is, either the Fermi energy does not change or increases in the direction from the surface deep into the core of the ring, that is, the distance from the surface of the base ring.

Inside the main ring is made cryostat 27 with the ability to cool the two-dimensional conductors with a two-dimensional conductor structures. The cryostat 28 coolant is poured as liquid helium which can be executed.

rotation device is connected to the conductive shield 29 made of a conductive material.

Around the rotation means are arranged reflectors radiation end surface 17, 30, 31, 32 and lateral radiation reflector surface 33. The reflector is designed as a plane mirror with a conductive layer, for example made of metal with the ability to reflect electromagnetic radiation. Four radiation reflector end surface opposite end portions formed structure, such end face light reflectors 17, 30, 31, 32. At least one lateral radiation reflector surface, such as the reflector 33 is formed opposite to the side surface of the main ring. radiation reflector side surface 33 is inclined to the vertical at an angle of approximately 45 degrees. Reflector emission side surface formed in a ring from which rings are cut portions at the locations of the induction coils cross the magnetic field.

The reflector can be formed as a multilayer structure with two-dimensional conductors. The multilayer reflector structure may comprise a two-dimensional conductors, made of either a single material or different, wherein the Fermi energy of two-dimensional conductors of materials as the distance from the reflecting working surface of the reflector does not decrease, that is, either it does not change or increases in the direction from the working surface reflector depth, ie the distance from the rotor. On the other hand, on the back on the trailing side of the reflector can be made optional cryostat with liquid helium cooling with reflector.

Inner facing the rotation surface of the screen device may be formed as a multilayer structure with two-dimensional conductors. The multilayer structure of the inner surface of the screen may comprise a two-dimensional conductors, made either of the same material or of different materials. In this case the Fermi energy of two-dimensional materials conductors with distance from the surface of the main ring, the rotor surface does not decrease, that is, either the Fermi energy does not change or increases in the direction from the surface into the screen, that is, the distance from the surface of the base ring.

Inside the screen can be made with the possibility of cooling the cryostat dimensional conductors in a conductor with two-dimensional structures. Inside the cryostat poured refrigerant as liquid helium which can be executed. The outer surface of the cryostat is made of a conductive material with radiation shielding ability.

The front and rear of the screen rotation axis substance relative movement direction of the traction motor system formed side windows 13, 15, 16, 24, 25, 26, 34, 35 with the possibility of free passage of electromagnetic radiation through the window. The screen is about a rotation device and surrounds the rotational device. Above the ground ring formed in the upper screen windows 36, 37, and under the ground ring formed in the lower screen windows 38, 39. With the conductive screen connected to the cover 40, 41, 42, 43 made of conductive material adjacent to the windows to open and close window. With lids connected device moving cover 50 containing the frames 44, 45, arranged to move the lid relative to the window inside the frame so that the lid opens or closes the window with the possibility to close or open the passage of electromagnetic radiation through the window. The screen formed on the inner surface of the lid moving device 50 facing the rotation device. In this part of the display screen provided on the inner surface of the chassis 45 (which is part of the device moving the lid 50) facing the rotation device. The side windows 13, 15, 16, 24, 25, 26, 34, 35, 36, the upper window 37 and lower window 38, 39 formed not only in the screen device but also to move the lid 50. In particular, these windows are made and in frames 44, 45 that make up the movement of the cap 50 of the device.

The reflector is made near the window. Reflectors are arranged to change the angle of inclination relative to the plane of the ring. Reflectors are made inside the screen.

Engine rotation device comprises a reflector 74, 75, connected with a screen adapted to rotate and move relative to the main reflector ring and a reflector to change the angle of inclination relative to the plane of the ring.

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INFORMATION SOURCES

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  9. Bogdanov IG electrorocket Bogdanova engine. 2046210. Patent Application 5064411. The priority of invention, October 5, 1992.

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  25. Physical encyclopedia. Volume 2. Moscow, 1990, p. 664.

  26. B. P.Burdakov, Yu.I.Danilov. Physical problems of space propulsion energy. 1969, p. 37.

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  28. YA Baur, B.M.Seregin, A.V.Chernikov. Experimental studies of the interaction of high-current systems with the physical vacuum and the implementation of a new principle of motion. Physical thought of Russia. 1, 1994, Aug., p. 66.

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CLAIM

  1. The engine for propulsion, comprising a power supply system, the induction coil system, the rotation device consisting of a stator and rotor, comprising a ring with a rotatable substance providing electromagnetic radiation, characterized in that it comprises a conductive shield for shielding electromagnetic radiation with at least one window, while the window is made near the conductive cover and the cover moving device.
  2. The engine for propulsion of Claim. 1, characterized in that the screen is designed as a figure of revolution, with the chamber formed with a cavity inside the screen.
  3. The engine for propulsion of claim. 2, characterized in that the screen and camera are mounted within the frame cavity, made in the form of a polyhedron.
  4. The engine for propulsion of claim. 2, characterized in that around the rotation axis of the device is made of at least one system of rollers connected to the rotation device.
  5. The engine for propulsion of claim. 2, characterized in that one of the induction coils formed around the rotor, with the plane parallel to the coil windings of the rotor axis.
  6. The engine for propulsion of claim. 5, characterized in that the rotor ring comprises at least one coil winding wound around the ring, while the coil is electrically insulated from the ring and holds the angular segment of the ring is not more than half of the ring and the coil axis It lies in the plane of the ring.
  7. The engine for propulsion of claim. 6, characterized in that the winding comprises a superconductor.
  8. The engine for propulsion of Claim. 1, characterized in that the substance comprises a rotatable two-dimensional conductor.
  9. The engine for propulsion of claim. 8, characterized in that the two-dimensional plane of maximum conductivity of the conductor perpendicular to the axis of the ring.
  10. The engine for propulsion of claim. 8, characterized in that the two-dimensional conductor is designed as a conductive film.
  11. The engine for propulsion of claim. 8, characterized in that the cryostat is made inside the ring.
  12. The engine for propulsion of claim. 11, characterized in that it comprises a magnetic coil, formed inside the cryostat, which has at least one pair of superconducting windings, made along each other and energized by currents of opposite directions.
  13. The engine for propulsion of Claim. 1, characterized in that the rotatable layered crystal material contains, in the plane of maximum conductivity layered crystal axis perpendicular to the ring.
  14. The engine for propulsion of Claim. 3, characterized in that it comprises at least one reflector is configured as a mirror, comprising at least one conductive layer with the ability to reflect electromagnetic radiation, wherein the reflector is formed around the window.
  15. The engine for propulsion of claim. 14, characterized in that it comprises at least one prism displacement device coupled to the rotation device.
  16. The engine for propulsion of claim. 15, characterized in that it comprises at least one reflector rotation device coupled to the rotation device.
  17. The engine for propulsion of claim. 16 wherein the reflector comprises a multilayer structure with two-dimensional conductors.
  18. The engine for propulsion of Claim. 3, characterized in that the inner facing the rotating screen device surface is a multi-layer structure with two-dimensional conductors.
  19. The engine for propulsion as claimed in claim. 8, 17 or 18, wherein the Fermi energy of the two-dimensional conductor material layer with increasing distance from the rotor surface in any two adjacent layers does not change or increases.
  20. The engine for propulsion of Claim. 1, characterized in that it comprises a suspension connected to the screen, with the rotation device and the rotor, providing the possibility of free rotation unit rotating with the angle of inclination of the screen.
  21. The engine for propulsion of claim. 20 wherein the suspension is designed as a gimbal.
  22. The engine for propulsion of Claim. 1, characterized in that it comprises at least one additional longitudinal magnetic field coil adapted to create a material in a rotating magnetic field along the axis of rotation of substance.
  23. The engine for propulsion of claim. 22, characterized in that additional longitudinal magnetic field coil provided around the rotor axis.
  24. The engine for propulsion of Claim. 1, characterized in that it comprises at least one electron accelerator with an electron source, wherein an electron source is formed around the rotor and comprises at least one emissive cathode.
  25. The engine for propulsion of Claim. 1, characterized in that it comprises more than two telescopic legs adapted to change its length, being sucked into the engine, or pressed against the motor.
  26. The engine for propulsion of Claim. 1, characterized in that it comprises a connecting device adapted to dock with at least two engines together, and at least one computer controlling the operation of the engine, and after docking engines computers combined into a single local area network.