RU2520776C1 - Inertial propulsor of bogdanov - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: inertial propulsor includes flywheel, and the flywheel contains working medium. Possibility is provided to remove working body from flywheel in such a manner that at propulsor outlet working body would move in specified direction. The flywheel contains as working medium at least on thread, and propulsor contains system of separation thread portion from the flywheel.

EFFECT: system provides possibility of separation of thread portion from rotating flywheel due to centrifugal force action in such a manner that at propulsor outlet thread portion could separate from flywheel due to centrifugal force action, and separated thread portion having at the time of separation linear speed of rotation could separate from propulsor and create jet propulsion after separation with such speed of rectilinear translation.

35 cl, 13 dwg

Description

The invention relates to the field of jet propulsion. It can be used in aviation and astronautics to create aircraft.

Known inertial propulsion, which is an energy-powered machine that uses energy stored by the flywheel [1]. Sometimes used to drive machinery, vehicles. For example, the famous fat globe, gyro globe. Girobus, Girobus [from Italy. giro, Greek gyros — circle, revolution, and Latin omnibus — for everyone], is a type of batteryless rail transport moving due to the kinetic energy accumulated in the flywheel [11]. Since 1955, electric globes (EJs) equipped with a flywheel unit consisting of an asynchronous propulsion generator coupled to a flywheel and traction electric motors have received some practical use. The spinning of the EJ flywheel is carried out by an electric motor. The stored kinetic energy is enough to cover a distance of 4-5 km. EF efficiency no more than 50%; the material consumption of the flywheel unit is 322 kg / kWh (32 times more than modern electrochemical current sources). In terms of unit operating costs, EF is more expensive than a trolleybus by 5% and a bus by 20%. Experienced ECs were operated, for example, on intercity lines Gent-Merelbeke (Belgium). EZH is an auxiliary passenger transport for short routes, suitable for servicing explosive facilities.

The disadvantage of the inertial propulsion is that it is not intended to use it for flight in airless space.

Known inertial propulsion, which is an energy-powered machine that uses energy stored by the flywheel [2]. Inertial propulsion contains a flywheel.

The disadvantage of the inertial propulsion is that it is not intended to use it for flight in airless space.

A prototype of the invention is an inertial propulsion device [3], containing a flywheel, the flywheel comprising a working fluid, either a turbine around the flywheel, the flywheel being able to feed the working fluid to the inner working surface of the turbine, or the system contains a spiral or ring with a groove on the inner the surface facing the axis of rotation of the flywheel, while the spiral or ring is made around the flywheel, and at the exit of the spiral or ring a hole is made with the possibility of exit from the hole accelerated wow working fluid.

The disadvantage of the inertial propulsion device is the small limit ratio of the energy of the rotated working fluid to the mass of the propulsive device, since it is not intended to use the working fluid to increase the tensile strength of the flywheel under the action of centrifugal forces and the strength of the flywheel depends solely on the strength of its body in which the working fluid is located.

The challenge facing the invention is to provide the ability to increase the ultimate ratio of the energy of the rotated working fluid to the mass of the propulsion device.

This problem is solved by the fact that in an inertial propulsion device containing a flywheel, and the flywheel contains a working fluid,

in addition, the flywheel as a working medium contains at least one thread, and the propeller contains a system for separating a portion of the thread from the flywheel, and the system provides the ability to separate the portion of the thread from the rotating flywheel so that the portion of the thread moves in a predetermined direction at the outlet of the propulsion.

The separation system from the flywheel section of the thread contains a laser.

The flywheel contains a bundle of threads containing at least two threads, and the holder of the bundle of threads.

The inertial propulsion device comprises a flywheel rotation drive device, wherein the flywheel rotation drive device comprises a ring and a pipe connecting the flywheel and the ring, wherein an accelerating gap is formed at the top and bottom of the ring, formed by sections of two electrodes having a shape around the ring and facing each other hollow half-cylinders, and the electrodes are made with the possibility of connection to the generator.

A remotely controlled system with a battery is made on the ring, electrically connected to at least two conductive plates electrically isolated from each other, made on opposite sides of the ring opposite each other, while the battery of the system with the battery is configured to electrically charge at least , two conductive plates with charges of opposite signs.

The inertial propulsion system comprises a system with a generator configured to generate electrical energy by rotating the flywheel or ring connected to the flywheel.

The inertial propulsion device comprises a magnetic suspension configured to hold the flywheel on weight during rotation of the flywheel.

The inertial propulsion device comprises a magnetic suspension configured to hold the flywheel on weight during rotation of the flywheel, and wherein the magnetic suspension comprises a superconducting magnet.

A system of magnetic ball bearings is connected to the flywheel, comprising at least two ball bearings, the flywheel being freely rotatable to the ball bearing system.

The separation system from the flywheel section of the thread contains an electron accelerator.

The system of separation from the flywheel section of the thread contains a machine gun.

A cryostat is made below the flywheel, while inside the cryostat there is a structure containing at least two superconducting layers separated by a dielectric, the structure being made under the flywheel in the form of a ring.

The superconducting layer contains superconducting ceramics.

A cryostat is made at the bottom of the flywheel, while inside the cryostat there is a system of structures with superconducting layers separated by a dielectric containing at least two elements, the element containing a structure containing at least two layers of a superconductor separated by a dielectric, and the system is connected with a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric, and configured to remotely control, while the system for changing the position of elements in a system of structures with superconducting layers separated by a dielectric, it is possible to receive electric power either from a battery or from a generator configured to generate electricity when the flywheel rotates, while a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric is made with the ability to arrange elements of a system of structures with superconducting layers separated by a dielectric, so that the superconducting layers are connected into rings, located below the flywheel, and is also configured to arrange the elements so that the superconducting layers are not connected into rings.

The inertial propulsion device comprises a charger configured to charge a portion of the thread with an electric charge of a certain sign at the exit of the flywheel, while the device for changing the direction of movement of the portion of the thread after separation containing an electrode system is connected to the charger, and the electrode system contains at least two electrodes.

The inertial propulsion device is configured to connect to the aircraft, while it is possible to connect a pair of inertial propulsion devices with the flywheels to the aircraft, while it is possible to rotate the flywheels in opposite directions.

The inertial propulsion device is configured to connect to a thermal power plant containing a boiler, and it is possible to separate a portion of a thread from the flywheel so that the portion of the thread after separation collides with the boiler of the thermal power station and heats the boiler of the thermal power station.

The inertial propulsion device comprises a rocket, while it is possible to direct the portion of the thread so that the portion of the thread after separation encounters the flame of the rocket propulsion device and heats the flame of the rocket propulsion device.

The inertial propulsion device comprises a rocket propulsion device configured to accelerate the working fluid, and it is possible to direct the portion of the thread so that the portion of the thread after separation from the flywheel collides with the working fluid of the propulsor and heats the working fluid of the propulsor.

The inertial propulsion device comprises a housing with a vacuum volume equipped with vacuum pumping means, while in the housing there is a window for releasing a portion of the thread.

The thread is either made entirely of Kevlar or reinforced with Kevlar.

The thread is either made entirely of synthetic fiber or reinforced with synthetic fiber.

The thread is either made entirely of carbon nanotubes or reinforced with carbon nanotubes.

The thread is either made entirely of graphene or reinforced with graphene.

The thread is either completely made of quartz fibers or reinforced with quartz fibers.

The thread is either made entirely of carbon fiber or reinforced with carbon fiber.

The inertial propulsion device comprises a bundle of threads containing at least two threads fixed by a thread holder connected to a shaft coaxial with the axis of rotation of the flywheel.

The thread is either wound around the flywheel, or the inertial propulsion device comprises a thread containing a portion of the thread, adapted to rotate the flywheel in a position in which the portion is parallel to a straight line perpendicular to the axis of rotation and passing through the axis of rotation.

The inertial propulsion device comprises a housing with a vacuum volume equipped with vacuum pumping means, while in the housing there is a window for releasing a portion of the thread, made with the possibility of tightly closing and tearing off, while the flywheel contains a bundle of threads containing at least two threads fixed by the holder a bundle of threads connected to a shaft coaxial to the axis of rotation of the flywheel, while the shaft is connected to a system for bringing the flywheel into rotation, and the shaft is either suspended in the housing on a magnetic suspension or connected to the housing magnetic ball bearings, with the shaft, the holder of the bundle of threads, the bundle of threads, the system for separating the portion of the thread and the system for bringing the flywheel into rotation are made in a vacuum volume inside the housing.

The flywheel contains a bundle of threads, containing at least two threads, secured by the holder of the bundle of threads made in the center of the flywheel so that the envelope of the ends of the threads lying in the plane of rotation of the flywheel rotates around the center of mass of the holder.

The inertial propulsion device is adapted to be connected to a thermal power plant, and it is possible to separate a portion of a thread from the flywheel so that the portion of the thread after separation encounters the fuel of the thermal power station and heats the fuel of the thermal power station.

The inertial propulsion device contains at least two flywheels made with rotation on the same axis parallel to each other, while the housing has a cylindrical shell with windows for each flywheel for the release of the working fluid in the form of separate sections of threads, and at least connected to the housing two systems for separating a portion of a thread.

The system for separating a section of a thread contains a laser, while it is possible to direct a laser beam to at least two sections of a bundle of threads of a flywheel along the length of the thread in increments equal to the length of the separated section of the thread, and it is possible to direct the laser beam by pulses.

The thread has a rectangular cross section.

The flywheel contains a bundle of threads containing at least two threads secured by the thread holder, the thread being made in a rectangular cross section, with at least two parallel layers of threads perpendicular to the axis of rotation of the flywheel, the threads being bonded to each other in the layer with the other, while outside the part of the bundle, compressed by the holder, it is possible to separate part of one layer of thread from another layer.

Such a technical solution provides the opportunity to increase the ultimate ratio of the energy of the rotated working fluid to the mass of the propulsion device, since the working fluid is the thread, the entire mass of which is used to ensure the strength of the flywheel. This allows you to increase the kinetic energy of rotation of the working fluid - threads in relation to the mass of the entire flywheel, consisting of a working fluid - threads and the holder of the bundle of threads.

Also, this design makes it possible to create thrust in the airless space of outer space, since it allows the flywheel to eject the working fluid accelerated during rotation — sections of the threads in a certain direction, thereby creating reactive thrust.

This is due to the fact that the flywheel is accelerated together with the working fluid - threads, and then sections of the thread are separated by a device for separating the portion of the thread. For example, they burn out with a laser beam at a point in time when the linear speed of the thread section is directed to the window for the flight of the thread section so that after separation the rotating section of the thread continues to move in the desired direction.

Also, such a technical solution provides the opportunity to increase the specific energy content per unit weight of the inertial propulsion device more than the specific energy content in chemical fuel, due to the fact that in the working fluid - in the threads brought in rotation together with the flywheel, the stored energy increases with growth radius at a speed faster than increasing centrifugal breaking loads.

At the same time, this technical solution makes it possible to increase the velocity of the expiration of the working fluid — sections of the filaments, in comparison with chemical rocket fuel, also due to the fact that in the working fluid — in the filaments rotated together with the flywheel, the stored energy grows with speed radius increases faster than centrifugal failure loads.

Due to this, this technical solution will allow, with a radius of rotation of steel threads of a flywheel of 8 m, the velocity of the expiration of the working fluid - sections of the threads, increase to a speed of 53.38 km / s. Detailed calculations of this parameter and the following parameters are given in the published, issued patent for the invention of the author [3].

This exceeds the maximum rate of expiration of the products of combustion of chemical rocket fuel, which does not exceed 5.7 km / s [4], by 9.37 times.

However, for a significant increase in the specific energy content in the flywheels, there are additional possibilities. For this, for example, you can use new materials to make flywheel threads:

synthetic fibers and, first of all, carbon nanotubes. Kevlar and carbon fiber synthetic fibers can increase the strength of flywheel threads up to 20 times per unit of its weight compared to steel, carbon nanofibers can increase this figure hundreds of times, since carbon nanofibres are 78.7 times stronger and much lighter than steel. Information on the manufacture of twisted ropes 10 km long was published [5].

In another case, Kevlar can increase the specific strength of the flywheel per unit of its weight by 20 times compared with steel, carbon fiber in the range from 10 to 20 times, and carbon nanotubes can increase its strength by 78.7 times [6, 7, 8, 9 , 10].

Long nanotube manufacturing technologies developed at Cambridge University for the manufacture of a space elevator for NASA. They developed how to make a giant nanoconstruction with a length of 230 thousand kilometers. They developed a new material for the manufacture of nanotubes, and also found a way to repeatedly join them together to form long segments [11].

Accordingly, the velocity of the outflow from the flywheel of the working fluid — the sections of the filaments that comprise carbon nanotubes — can be increased up to 8.871 times, compared with a flywheel containing steel filaments 8 m long, amounting to 473.55 km / s.

This exceeds the maximum rate of expiration of the products of combustion of chemical rocket fuel, which does not exceed 5.7 km / s [4], by 83.07 times. Accordingly, the flight time to other planets of the solar system will also be reduced by many times, compared with the use of known rocket propellers using chemical rocket fuel.

No technical solutions were found that fulfill the task with the same technical means.

Figure 1 shows a schematic diagram of the inertial propulsion Bogdanov.

Figure 2 shows a top view of the inertial propulsion Bogdanov.

Figure 3 shows a front view of the inertial propulsion Bogdanov.

Figure 4 shows a rear view of the inertial propulsion device.

Figure 5 shows a bottom view of the inertial propulsion.

Figure 6 shows a section aa.

Figure 7 shows a section bB.

On Fig shows a section bb.

Figure 9 shows a schematic diagram of the flywheel of the inertial propulsion Bogdanov.

Figure 10 shows a front view of the flywheel of the inertial propulsion Bogdanov.

Figure 11 shows a top view of the flywheel of the inertial propulsion Bogdanov.

On Fig shows a section GG.

In Fig.13 shows the remote element 1.

The inertial mover of Bogdanov, hereinafter simply the inertial mover or just the mover, consists of the following elements.

Flywheel 1 of the inertial propulsion device as part of the working fluid (as the working fluid) contains a bundle of 12 threads containing threads 2, 3, and a holder 4 of a bundle of threads. The holder 4 of the bundle of threads holds the bundle of 12 threads, compresses it in the Central part of the bundle and fixes the position of the threads.

The holder of the bundle of threads can be made, for example, in the form of a strong frame made of extra strong material. For example, it may contain reinforcement made of threads bonded with filler or pressed and bonded by heating.

For example, it may contain reinforcement made of graphene strands pressed and bonded by heating.

The holder 4 of the bundle of threads is connected to the shaft 5, coaxial to the axis of rotation of the flywheel, while the shaft 5 is connected to the ring 6 of the device for bringing the flywheel into rotation.

The shaft 5 is connected to the housing 7 by magnetic ball bearings 8, 9. The housing 7 is made with a vacuum volume and equipped with vacuum pumping means. In the housing, a window 10 is made for the departure of a section of the thread, made with the ability to close in dense layers of the atmosphere and to come off in airless space. With the housing 7 is connected to the system 11 separation of the section of thread. For example, a laser. At the same time, it is possible to direct the laser beam to different sections of the beam 12 of the flywheel threads along the length of the thread with a step equal to the length of the detachable section of the thread. It is possible to direct the laser beam with short powerful pulses. The thread is made in rectangular cross section. For example, a square section. In this case, the threads in the bundle of threads are made in layers perpendicular to the axis of rotation of the flywheel, and the threads in the layer are bonded to each other and not bonded to the threads of other layers outside the bundle portion compressed by the holder. For this, for example, the threads of adjacent layers are made of materials that do not wet each other if one of them is molten and the other is in a solid state. In this case, outside the part of the beam compressed by the holder, it is possible to separate one layer from another layer. Moreover, the depth of penetration of the laser beam into the layer does not exceed the thickness of the layer, and the power of the laser pulse is sufficient to melt the junction of the section of the thread with the rest of the thread.

The system 10 is made over the flywheel 1, namely over a bundle of 12 flywheel threads.

It is possible to introduce the elements of the flywheel driving device into rotation through the window 10 into the evacuated volume of the housing 10 and, after accelerating the flywheel 1 with a bundle of 12 threads, to bring these introduced elements of the flywheel driving device into rotation back from the inertial propulsion device. For example, using automation or telemetry. A detailed description of the elements of the device for bringing the flywheel into rotation is given in the published, issued patent for the invention of the author [3].

Inertial propulsion Bogdanov works as follows.

In the composition (as) of the working fluid of the flywheel 1 of the inertial propulsion device, a bundle of threads 12 rotates, as a part of which the threads 2, 3, fixed by the holder 4 of the bundle of threads rotate. The holder 4 of the bundle of threads holds the bundle of 12 threads, compresses it in the Central part of the bundle and fixes the position of the threads.

The holder 4 of the bundle of threads rotates together with the shaft 5 around the axis of rotation of the flywheel, while the shaft 5 drives the ring 6 of the device for bringing the flywheel into rotation, and the shaft 5 is connected to the housing 7 by magnetic ball bearings 8, 9 during rotation.

Magnetic ball bearings 8, 9 reduce to zero the braking and heating by friction of the shaft 5 about the housing 7 during rotation. In the housing 7, a vacuum is created inside the evacuated volume by means of vacuum pumping. A vacuum is needed to reduce to zero the heating from friction against air of the components of the flywheel of the thread bundle and the holder of the thread bundle during rotation, by reducing friction to air to zero during rotation to zero.

Window 10 for the departure of the section of thread opens in the evacuated hall of the power plant. Then, for example, using automation or telemetry, the stationary elements of the device for bringing the flywheel into rotation are inserted inside the evacuated volume of the housing 7 and the ring 6 of the device for bringing the flywheel into rotation is rotated with their help. And together with the ring 6, the shaft 5 and the flywheel are rotated in the form of a bundle 1 with threads fixed by the holder 4.

Detailed descriptions of the operation of the ring 6 of the device for bringing the flywheel into rotation and of the entire device are given in the published, issued patent for the invention of the author [3]. After the flywheel is brought into rotation in the form of a bundle 1 with threads fixed by the holder 4, all elements of the flywheel driving device, except ring 6, are removed from the evacuated volume of the housing 7, and the window 10 for releasing a portion of the thread is closed.

Somehow, for example, on a rocket, an inertial engine from the surface of the Earth is delivered to airless space.

Window 10 for the departure of the section of the thread in the dense layers of the atmosphere is closed and comes off in airless space. The system 11 separating the section of the thread, such as a laser, disconnects the plot of the rotating thread from the bundle 12 of threads of the flywheel 1 at a time when the linear speed of rotation of the thread is directed toward the open window 10.

To do this, the junction of the section of the thread with another part of the thread heats the laser beam, the joint is heated, the tensile strength is significantly reduced in it, and the section of the thread is disconnected due to the action of centrifugal force, flies in the right direction and creates a jet thrust.

The separated section of the thread, which at the time of separation is linear in rotation speed, after separation has the same linear linear speed and moves at that speed toward the open window 10, exits through it and creates a jet thrust.

The laser directs the laser beam to different parts of the beam 12 of the flywheel threads along the length of the thread in increments equal to the length of the detachable portion of the thread. The laser directs the laser beam with short, powerful pulses. The filaments in the layer are made of rectangular cross-section, for example, square cross-section, so that the laser radiation does not pass between the filaments. In this case, the laser separates the sections of the threads by parts of the layers perpendicular to the axis of rotation of the flywheel, and the threads in the layer are bonded to each other and not bonded to the threads of other layers outside the beam portion compressed by the holder. For this, for example, the threads of adjacent layers are made of materials that do not wet each other if one of them is molten and the other is in a solid state. Moreover, the laser beam penetrates into the layer to a depth not exceeding the thickness of the layer, and the laser pulse power is sufficient to melt the junction of the section of the thread with the rest of the thread.

Various options and additions.

The inertial propulsion device may comprise a flywheel rotation drive device, wherein the flywheel rotation drive device comprises a ring and a pipe connecting the flywheel and the ring, wherein an accelerating gap is formed at the top and bottom of the ring, formed by slices of two electrodes located around the ring and facing each other, having the shape of the hollow half-cylinders, the electrodes being configured to be connected to a generator.

A remotely controlled system with a battery can be made on the ring, electrically connected to at least two conductive plates electrically isolated from each other, made on opposite sides of the ring opposite each other, while the battery of the system with the battery is configured to electrically charge, at least two conductive plates with charges of opposite signs.

Detailed descriptions of this element and the operation of this element are given in the published, issued patent for the invention of the author [3].

The device for bringing the rotation of the flywheel works as follows. First comes the process of energy storage in the device.

The flywheel 1 in the form of a bundle of 12 threads fixed in the holder 4 of the bundle of threads, cause the rotation of the elements of the device to bring the flywheel into rotation. This device is made by analogy with the charged particle accelerator cyclotron and works by analogy with it.

It is known that the cyclotron periodically delivers a high-frequency alternating electric field to the accelerating gap formed by slices of two electrodes located around the flywheel and facing each other, having the form of hollow half-cylinders - duants [12]. Duants are connected to the poles of a high-frequency generator through transmission lines. For example, perhaps through quarter-wave lines.

In more detail, the flywheel rotation drive device operates as follows.

An external power source, such as a nuclear or thermonuclear power plant, periodically supplies a high-frequency alternating electric field to an accelerating gap formed by slices of two electrodes located around ring 6 and facing each other, partially imitating the shape of hollow half cylinders - dunts [12]. The electrodes are two half rings electrically connected by the inner perimeters of the half conductive pipe. The electrodes are connected to the poles of the high-frequency generator of an external power source through transmission lines. For example, perhaps through quarter-wave lines. It is advisable to use a nuclear power plant with fast neutron reactors as an external power source, the development of which has become a priority for Rosatom, since it allows you to get 100 times more energy per unit of nuclear fuel and allows you to use junk uranium 238, which is very much in dumps. In addition, it is advisable to use a hybrid fusion reactor - a hybrid - as an external energy source. Demonstration thermonuclear reactors with an energy output of 1-2 have already been created. The energy yield in such a reactor can be increased by using waste uranium 238 or thorium 233 to produce additional energy, which in the fusion reactor will produce new fissile materials for a nuclear power plant.

The device for driving the rotation of the flywheel rotates the flywheel 1 in the form of a bundle of 12 threads and the holder 4 of the bundle of threads using the ring 6. Ring 6 rotate the electrodes of the device for bringing the rotation of the flywheel as follows.

On the ring 6 is made a remotely controlled system with a battery connected to the conductive plates. A system battery with a battery electrically charges conductive plates electrically isolated from each other by charges of opposite signs. Conductive plates with different signs are periodically alternated with each other.

For example, conductive plates with different signs of electric charges are made on opposite sides of ring 6. In this case, plates with one sign of electric charge and plates with opposite signs of electric charge in the gap by an electric field are accelerated in opposite directions, increasing the torque of the ring or flywheel.

The conductive plates are made on the angular segments of the ring 6 with the same periods of alternation with each other, which correlates with the frequency of the alternating voltage supplied to the electrodes. With an increase in the rotational speed of the ring 6, the frequency of the alternating voltage supplied to the electrodes of the flywheel driving device synchronously increases.

The conductive plates are located in the accelerating gap, to which an alternating electric field is applied, which accelerates the plates together with the ring 6 and the shaft 5 and makes them rotate with acceleration. An alternating electric field is changed synchronously with a change in rotational speed.

The rotation speed is increased to a certain critical value, limited from above by the strength of the material of the ring, the shaft of the threads and the holder of the bundle of threads.

Together with systems with a battery, systems with electric generators can be made that generate electrical energy when the rings or flywheels rotate.

The next addition.

Ring 6, shaft 5, flywheel 1 can hold the weight of the elements of the magnetic suspension.

For example, containing superconducting magnets, ring rails and electrodes.

Magnetic suspension elements can use not only magnetic fields, but also electric fields to keep flywheel 1, shaft 5 and ring 6 weighted. These elements can also use a feedback system that controls the position of ring 6, shaft 5, flywheel 1 and gives signals to the magnetic suspension adjustment system. They can also use in their work the well-known effect of freezing of a superconductor on a magnet - the so-called “Coffin of Magomed" effect.

It is necessary to use a magnetic suspension above and below the electrodes of the flywheel driving device for the reason that alternating electric and magnetic fields heat the superconducting magnets of the magnetic suspension until the destruction of superconductivity. Therefore, the electrodes of the flywheel driving device must be made outside of the magnetic suspensions. And the best arrangement of the electrodes of the flywheel driving device and, accordingly, the ring 6 is the location between the elements of the magnetic suspension at a distance from them.

The elements of the magnetic suspension are made above and below the electrodes of the flywheel driving device with the ability to shield the elements from alternating electric and magnetic fields created by the electrodes. For example, around the electrodes can be made massive open copper casing, made with the possibility of shielding alternating electric and magnetic fields, made by analogy with a similar casing used for similar purposes in tokamaks. In elements containing ring rails, a current is introduced along the ring rails and the flywheel is suspended by the repulsive force between currents of opposite directions. In the elements containing the electrodes, electric fields are created between the electrodes so that the emerging electric force of repulsion or attraction maintains the necessary gap between the elements of the magnetic suspension.

Since the cyclotron is capable of accelerating charged particles to relativistic speeds, the speeds to which the proposed flywheel drive device can accelerate the flywheel are limited from above only by the strength of the materials of the flywheel and rings.

The inertial propulsion device may comprise a magnetic suspension configured to hold the flywheel on weight during rotation of the flywheel, and the magnetic suspension may comprise a superconducting magnet.

Detailed descriptions of this element and the operation of this element are given in the published, issued patent for the invention of the author [3].

The inertial propulsion device may include a system with a generator configured to generate electrical energy by rotating the flywheel or ring connected to the flywheel.

In this case, the generator generates electrical energy, which can be used to create plate charges. As well as providing energy to other elements of the inertial engine. For example, systems for separating a portion of a thread. For example, a laser, an electron accelerator or a machine gun. Or to provide energy for a window opening and closing system 10.

The separation system from the flywheel portion of the thread may contain an electron accelerator.

In this case, the junction of the filament section with another part of the filament heats the electron flow, the junction heats up, the tensile strength is significantly reduced in it, and the filament section disconnects, flies in the right direction and creates a jet thrust.

The system of separation from the flywheel section of the thread may contain a machine gun.

In this case, the machine gun sends bullets to the side of the bundle 12 of the flywheel 1, which either interrupt the thread and thereby disconnect the portion of the thread that flies in the desired direction and creates a jet thrust.

Either the thread collides with the bullet, and as a result of the collision, the junction of the thread section with the other part of the thread heats up, the tensile strength is significantly reduced in it, and the thread section disconnects due to centrifugal force, flies in the right direction and creates a jet thrust.

A cryostat can be made below the flywheel, while inside the cryostat there is a structure containing at least two superconducting layers separated by a dielectric, the structure being made under the flywheel in the form of a ring.

The superconducting layer contains superconducting ceramics. For example, high-temperature superconducting ceramics.

At the bottom of the flywheel, a cryostat can be made, while inside the cryostat there is a system of structures with superconducting layers separated by a dielectric containing at least two elements, the element containing a structure containing at least two layers of a superconductor separated by a dielectric, the system is connected to a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric, and is configured for remote control, while the system for changing I elements of a system of structures with superconducting layers separated by a dielectric, is configured to receive electrical power either from a battery or from a generator configured to generate electricity when the flywheel rotates, while the system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric is made with the ability to arrange elements of a system of structures with superconducting layers separated by a dielectric, so that superconducting layers connect ring I disposed below the flywheel and is arranged to locate the elements such that the superconducting layers are connected in a ring.

Detailed descriptions of this element and the operation of this element are given in the published, issued patent for the invention of the author [3].

In addition, a description of the structures is in another published, issued patent for the invention of the author [13].

At the bottom of the flywheel is a double cryostat, which consists of two parts. The inner part contains a cryostat with liquid helium, placed in the outer part containing a cryostat with liquid nitrogen. Inside the cryostat, a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric with a high electrical resistivity has been made.

In this case, the system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric with high electrical resistivity is configured to be remotely controlled, for example, by radio, and electrically powered either by a battery connected to it or a generator connected to it and generating electricity when rotating the flywheel.

In this case, the system of changing the position of the elements of the system of structures with superconducting layers separated by a dielectric with high electrical resistivity, has the elements of the system of structures with superconducting layers separated by a dielectric with high electrical resistivity, so that the superconducting layers in one position are connected into rings located below flywheel, and in another position, the elements are disconnected and no rings are formed. For example, this system is made with the ability to stack the elements of the system - the structure in the form of an accordion or install them in the form of a stack one above the other.

In this case, the disk or ring contains a structure containing 50 layers of a superconductor separated by a dielectric with high electrical resistivity (electrical insulator), or more than 50 layers of a superconductor separated by a dielectric with high electrical resistivity.

Such a system of structures with superconducting layers can be taken as an element from Bogdanov’s electromagnetic motor to create traction on new physical principles, for which a patent has been obtained [13], which contains either a disk or a ring and a disk or ring rotation system configured to rotate the disk or rings, while the ring or disk is made inside the cryostat, and the cryostat is made with the ability to rotate with the ring.

In addition, a description of the structures is in another published, issued patent for the invention of the author [3].

At the bottom of the flywheel is a double cryostat, which consists of two parts. The inner part contains a cryostat with liquid helium, placed in the outer part containing a cryostat with liquid nitrogen. Inside the cryostat, a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric with a high electrical resistivity (electrical insulator) was made.

In this case, the system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric with high electrical resistivity is remotely controlled, for example, by radio, and is electrically powered either by a battery connected to it or a generator connected to it and generating electricity when the flywheel rotates .

In this case, a system of changing the position of elements of a system of structures with superconducting layers separated by a dielectric with high electrical resistivity, when taking off and flying near the surface of a celestial body, has elements of a system of structures with superconducting layers so that the superconducting layers are connected into rings located below the flywheel.

This add-on works as follows.

A disk or ring rotates a structure containing 50 layers of a superconductor separated by a dielectric with high electrical resistivity (electrical insulator), or more than 50 layers of a superconductor separated by a dielectric with high electrical resistivity.

During rotation of a disk or ring containing 50 layers of a superconductor separated by an insulator, or more than 50 layers of a superconductor separated by an insulator, a weight reduction of 2 percent is observed over each layer of the superconductor. This phenomenon has been experimentally confirmed [14, 15, 16]. In this case, a decrease in weight by 4 percent is observed over two layers of a rotating superconductor, which also found experimental confirmation [14, 15, 16].

Thus, over all 50 layers of a rotating superconductor, a complete decrease in weight is observed, which makes it possible to reduce energy costs when launching a payload located above rotating structures with superconductor layers into orbit (or when flying to another celestial body).

This effect of reducing weight over a rotating structure with superconducting layers separated by a dielectric with high electrical resistance is an additional effect in the operation of an inertial propulsion device, which can be used in its work, but may not be used in its work.

Such a system of structures with superconducting layers can be taken as an element from Bogdanov’s electromagnetic motor to create traction on new physical principles, for which a patent has been obtained [13], which contains either a disk or a ring and a disk or ring rotation system configured to rotate the disk or rings, while the ring or disk is made inside the cryostat, and the cryostat is made with the ability to rotate with the ring.

In addition, a description of the structures and a description of their work is in another published, issued patent for the invention of the author [3].

When planting, on the contrary, a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric with high electrical resistivity changes the position of the elements so that rings from the connected superconducting layers of structures are not formed. For example, it adds up the elements of the system - the structure in the form of an accordion or sets them in the form of a stack one above the other. In this case, the effect of weight reduction over a rotating structure with superconducting layers separated by a dielectric with high electrical resistance is not formed, and landing is carried out without counteracting this effect.

This eliminates the above drawback of the Bogdanov electromagnetic motor for creating traction on new physical principles [13], which is the fact that there is no effective mechanism that removes the effect of reducing gravity over a rotating superconductor without removing it from the superconducting state or without removing it from rotation. Elimination of the drawback allows landing without counteracting this effect during landing of an aircraft with a propulsion bearing such a rotating structure.

This eliminates the other drawback of the Bogdanov electromagnetic motor for creating traction on new physical principles, which is the fact that there is no effective mechanism for quickly removing and restoring the decrease in gravity over a rotating superconductor without removing it from the superconducting state or without removing it from rotation with a new creating a situation where a superconductor rotates in a superconducting state. Elimination of the deficiency allows multiple repetition of combinations of takeoff and landing of an aircraft with such a mover.

The next addition.

The inertial propulsion device may include a charger configured to exit the flywheel, for example at the exit from window 10, to charge a section of the thread with an electric charge of a certain sign, while a device for changing the direction of movement of the section of the thread after separation containing a system of electrodes is connected to the charger this electrode system contains at least two electrodes.

With the possibility of changing the direction of departure of the separated portion of the thread, devices of electronic, ionic and plasma optics can be made.

Also, instead of electrodes, magnetic coils and a starter can be used along one or two disconnected sections of the electric current filament. Coils can be superconducting.

Also, at the exit from the window 10, a plasma-optical system with crossed electric and magnetic fields can be made.

The operation of all elements is coordinated and controlled by the on-board computer.

This add-on works as follows.

To change the flight direction of the inertial propulsion, the departure direction of the separated section of the thread is changed. For this, methods from electronic and ion optics are used. In this case, the change in the flow direction of the accelerated working fluid in the form of a separated section of the thread is as follows.

In this case, the charger at the exit of the flywheel, for example at the exit of the window 10, charges the accelerated working fluid in the form of a separated portion of the filament with an electric charge of a certain sign. Then, the accelerated working fluid is sent to the gap between the two electrodes of the device for changing the direction of flow of the accelerated working fluid, the voltage is applied to the electrodes, and the accelerated working fluid having a certain electric charge is rejected in the desired direction. In this case, a pair of flywheels is used, the accelerated working body of which is electrically charged with electric charges of different signs. They create two approximately parallel jets of the accelerated working fluid, which are charged with electric charges of opposite signs, are attracted to each other after exiting the propulsion device, collide with each other and are electrically neutralized. In this method, a pulsed mode of operation is needed, since when current flows, electric current will flow and the charges are neutralized.

In another method, instead of electrodes, magnetic coils may be used. In this case, a conductive separated portion of the thread is used as the accelerated working fluid, for example, the thread is made of graphene.

Along two streams of the accelerated working fluid, an electric current is released, which is deflected by the magnetic field of the coils, letting the flows in the desired direction. Coils can be superconducting.

In the third method, the flow of the working fluid is rejected by crossed electric and magnetic fields.

The operation of all elements is coordinated and controlled by the on-board computer.

The inertial propulsion device is configured to connect to an aircraft. In this case, the propulsion accelerates the aircraft.

The use of the inertial propulsion Bogdanov in the energy system of the country.

The inertial propulsion device may be configured to connect to a thermal power station containing a boiler, and it is possible to separate a portion of a thread from the flywheel so that the portion of the thread after separation collides with the boiler of the thermal power station and heats the boiler of the thermal power station.

The inertial propulsion device can be configured to connect to a thermal power plant, and it is possible to separate a portion of a thread from the flywheel so that the portion of the thread after separation encounters the fuel of the thermal power station and heats the fuel of the thermal power station.

In these cases, the portion of the thread is separated from the flywheel in such a way that after departure it would collide with either the boiler or the fuel. And collision would heat either the boiler of a thermal power plant or the fuel of a thermal power plant.

In these cases, the inertial propulsion is charged with energy by bringing the flywheel into rotation near an energy source that is far from the energy consumer. For example, near a geothermal power station, built near a volcano, nuclear power plant, hydroelectric power station and so on.

The mover can be used to transfer energy accumulated in the rotating flywheels from power plants made near energy sources, or from the energy sources themselves to power plants made near energy consumers, or to the energy consumers themselves. Sources of energy can be deposits of gas, oil, coal, geothermal sources. As well as volcanoes.

In this case, the flywheels of the propulsion device can be energized from power plants made near energy sources, or from the energy sources themselves.

For example, they build power plants where there are deposits of gas, oil, coal, geothermal springs or volcanoes.

In another embodiment, power plants can transport aircraft with the inertial propulsion Bogdanov. For this, in the simplest version, the power plant contains a boiler with a generator mounted on top. The boiler is mounted on a tripod, the height of which is slightly higher than the height of the pipe on which the associated gas is burned. A tripod with a boiler is installed over a pipe in which associated gas is burned. Burning gas heats the boiler, water boils, rotates the generator turbine, and the power plant generates electricity. Water is sent to the boiler by a pump through a hose from the nearest body of water.

In another embodiment, a boiler with a generator mounted on top is lowered into the mouth of a volcano. The volcano heats the boiler, the water boils, rotates the generator turbine, and the power plant generates electricity. Water is also sent to the boiler by a pump through a heat-resistant hose made of fire-resistant materials from the nearest body of water. Moreover, if the level of lava is lower than the level of water in the nearest body of water, then the water is first sent by the pump, and then flows into the boiler itself according to the law of communicating vessels.

They generate cheap electrical energy. This flywheel is powered by the flywheels of the inertial propulsion Bogdanov and transferred by the aircraft with this propulsion the stored energy to the energy consumers. There, the stored energy is redistributed. For example, water, air or natural gas can be passed through the inertial propulsion device of Bogdanov through a power plant installed in a power plant and heated with a working fluid that leaves the flywheel at high speed.

Water heats up, boils, steam forms, steam rotates the turbine of the power plant, the power plant generates electricity. In another case, heated air or natural gas increases the combustion temperature of the fuel and provides additional heat to generate electricity. In addition, heated water can be used in steam or water heating systems in cities.

Other inertial propulsors of Bogdanov can be powered by the resulting electricity to repeat the process.

Such a method of energy transfer for Russia will give a significant profit due to the following factors.

1. It will save energy due to the absence of transport energy losses during its transmission by wire over a considerable distance.

2. Accelerate energy transfer due to the fact that you do not need to build a long power line for a long time, but you can quickly transfer a significant amount of energy to aircraft with Bogdanov’s inertial propulsion device.

In addition, if we consider the entire set of technical and economic parameters of such a method of energy transfer and distribution based on the inertial propulsion Bogdanov, then we can say the following.

On its basis, a grandiose project to change the entire energy system of the country can be created, which will bring benefits and will have advantages in the following respects.

1. The country - a huge profit from the development of remote oil and gas fields. Including arctic. Agree, the development of the Arctic shelf is already a priority state task. So - this is another reason to give carte blanche to this Project !!!

2. The solution to the problem of associated gas at all oil fields - if it cannot be transported, it can simply be burned in the furnaces of gas power plants.

3. The solution to the problem of deterioration of power lines. Energy is not transferred through them, but in flywheels reinforced with carbon nanotubes.

4. The obvious benefit and direct benefit is that, firstly, there are no energy losses in power lines. Secondly, it is not necessary to make clearings in the dense taiga, it is not necessary to drain swamps in Siberia and the tundra on the path of power lines, and it is not necessary to pull power lines through wide rivers and taiga mountain ranges.

5. There is no alienation of the territory under power lines in the case when they pass through fields and cities - through territories that are somehow involved in the national economy.

6. It is possible to dismantle worn-out power lines, and build elite villages on their territory. Land from worn out power lines can be sold and made a profit.

7. There is an opportunity to get additional profit from unprofitable deposits today. For example, from offshore. And to make them at the expense of this cost-effective.

8. In the context of the global crisis, the Project will provide Russia with the creation of new jobs and will not allow the development of mass unemployment.

9. It is known that in flywheels the specific density of accumulated energy increases with increasing size. This means that with an increase in the size of the system, the specific energy density will be several orders of magnitude higher than the specific energy density in both oil and liquefied gas. Even by many orders of magnitude !!! And this is a direct benefit in transporting energy.

The next addition.

The inertial propulsion device may contain a rocket, while it is possible to direct a portion of the thread so that the portion of the thread after separation collides with the flame of the rocket engine and heats the flame of the rocket engine.

In this case, the propulsion device simply heats the flame of the rocket. And thereby increases the speed of departure of the working fluid of the rocket. Thereby increasing traction.

The next addition.

The inertial propulsion device may comprise a rocket propulsion device capable of accelerating the working fluid, while it is possible to direct the portion of the thread so that the portion of the thread after separation from the flywheel collides with the working fluid of the propulsor and heats the working fluid of the propulsor.

In this case, the inertial propulsion device simply heats the working fluid of the rocket propulsion device. And thereby increases the speed of departure of the working fluid of the rocket propulsion device. Thereby increasing traction.

The following additions.

The thread can either be made entirely of Kevlar or reinforced with Kevlar. This increases the strength of the thread.

The thread can either be made entirely of synthetic fiber or reinforced with synthetic fiber. This increases the strength of the thread.

The thread can either be made entirely of carbon nanotubes or reinforced with carbon nanotubes. This increases the strength of the thread.

The thread can either be made entirely of graphene or reinforced with graphene. This increases the strength of the thread.

The thread can either be made entirely of quartz fibers or reinforced with quartz fibers. This increases the strength of the thread.

The thread can either be made entirely of carbon fiber or reinforced with carbon fiber. This increases the strength of the thread.

The thread can either be wound around the flywheel, or the inertial propulsion device contains a thread containing a section of thread, configured to rotate the flywheel in a position in which the section is parallel to a straight line perpendicular to the axis of rotation and passing through the axis of rotation.

In this case, the system for separating the section by them disconnects the section of the thread in the same way as in the main embodiment.

The flywheel may contain a bundle of threads containing at least two threads secured by the holder of the bundle of threads made in the center of the flywheel so that the envelope of the ends of the threads lying in the plane of rotation of the flywheel rotates around the center of mass of the holder.

In this case, the thread section separation system disconnects the thread section in the same way as in the main embodiment.

The next addition.

In flywheel drive devices, conductive plates can charge a high voltage generator using corona electrodes. Using a high-voltage generator, an electric discharge is applied to the corona electrodes, and electronic emission begins with them. A positive charge on the conductive plate is created if the corona electrodes are made on the conductive plate, and the voltage is applied such that electrons are emitted from the corona electrodes and the plate is charged with the same positive charge. A negative charge on the plate is created if the corona electrodes are made outside the conductive plate opposite it on the other side of the interelectrode gap. A potential difference is applied to the gap, electron emission is from the corona electrodes, electrons fly out from the corona electrodes and enter the conductive plate. And thereby they charge the plate with a negative charge.

A high-voltage generator can also supply high voltage to the electrodes of the flywheel driving device with a high frequency due to a modulator containing a rotatable disk with alternating conductive plates electrically isolated from each other, on some of which there are corona electrodes, and on the others. In this case, the rotatable disk is rotated between two fixed disks also with conductive plates electrically isolated from each other, on some of which there are corona electrodes, and on the other not. High voltage is applied to the conductive plates of the fixed disks, electronic emission is caused, and electric charges are created on the plates of the rotatable disk, which are supplied from it to the conductive plates, and with their help the ring 6 is rotated, connected to the flywheel 1, as described above.

The next option.

In the flywheel drive devices, the conductive plates can charge a high voltage generator inside the ring. For example, the Van der Graf generator. This generator rotates the tape between two conductive plates. At the same time, the tape removes a negative charge from one plate and thereby creates an excess positive charge on it. On the other hand, the tape, on the contrary, applies a negative charge to and creates an excess negative charge on it.

The energy for moving the tape and for the operation of other elements of the high-voltage generator is provided either by a system with a battery, or by a system with a generator that generates electricity when the flywheel or the ring is connected to the flywheel.

The next option.

The ring 6 and the shaft 5 connected to the flywheel 1 are made entirely of synthetic fibers or reinforced with synthetic fibers.

The ring and shaft connected to the flywheel are made entirely of carbon nanotubes or reinforced with carbon nanotubes.

This strengthens the elements of the mover.

The next option.

The inertial propulsion Bogdanov may contain more than one flywheel, made with one axis of rotation parallel to each other. In this case, the housing has a cylindrical shell with windows for each flywheel for the departure of the working fluid in the form of separated sections of threads. Moreover, more than one thread section separation system is connected to the body.

This option works in the same way as the first option with the difference that it is possible to simultaneously separate all sections of the threads by all the flywheels. The threads can be separated in one direction to create traction and in different directions to rotate the engine.

An aircraft with such an inertial propulsion device of Bogdanov, made in the form of a large cylinder, can transfer other smaller aircraft, made in the form of aircraft with the propulsion device of Bogdanov according to the first embodiment of the invention, when flying to other celestial bodies in its hangar. Thus, an aircraft with an inertial propulsion Bogdanov in the form of a cylinder becomes a womb for smaller aircraft with a propulsion Bogdanov according to the first embodiment of the invention.

The Bogdanov inertial propulsion device, made in the form of a large cylinder, can create the greatest thrust of all options, since the largest number of flywheels per unit surface of the aircraft can be placed along the side surface of the cylinder.

Thus, the Bogdanov inertial propulsion device, made in the form of a large cylinder, becomes an ideal version of the uterine ship propulsion device, adapted for transferring smaller aircraft with the Bogdanov propulsion device to other celestial bodies, made according to the first embodiment of the invention.

The next option.

In aircraft, it is advisable to use Bogdanov’s inertial propulsors in pairs, so that pairs of flywheels of different propulsors rotating in opposite directions extinguish the arising moment of rotation. You can use either one pair of flywheels or several pairs of flywheels.

Information sources

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3. Bogdanov I.G. Inertial engine Bogdanov. Patent No. 2449170. Registered in the state register of inventions of the Russian Federation on April 27, 2012. Application No. 201034520. Priority of the invention August 19, 2010

4. Space movers: state and prospects. Edited by Cavney L. Moscow, Mir, 1988, p. 415.

5. Popular mechanics No. 2, 2010, p. 42.

6. Bogdanov K. Yu. How can one calculate the strength of a carbon nanotube, March 20, 2009.

http://www.nanometer.ru/2009/03/19/nanotubes_145296.html

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10. Nanotubes for a space elevator, RBC daily, Monday January 26, 2009, No. 11 (574), p. 11.

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http://slovari.yandex.ru/dict/bse/article/00026/42300.htm

12. Physical Encyclopedia, 1998, vol. 5, p. 249.

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Priority 05.17.2000.

14. An article on the topic "Scientific research". Russian scientists discovered antigravity. © 2008 ScienceArt.Ru

http://scienceart.ru/researches/rossiyskie_uchenie_otkrili_antigravitaeiyu.html

15. Ventura Tim. The secret of antigravity. New Energy No. 3 (1 8), 2004, p. 88.

16. Frolov A. V. Modern antigravity research. New Energy No. 4 (19), 2004, p. 71.

Claims (35)

1. An inertial propulsion device comprising a flywheel, wherein the flywheel comprises a working fluid, and it is possible to withdraw the working fluid from the flywheel so that at the exit of the propulsion the working fluid moves in a predetermined direction, characterized in that the flywheel comprises, as a working fluid, at least one thread, and the mover contains a system for separating a portion of the thread from the flywheel, and the system provides for the possibility of separation from the rotating flywheel due to the centrifugal force of the portion of the thread so that Exit from propulsor thread portion by the centrifugal force is detached from the flywheel, and the separated thread portion having a point separating the linear speed after separation with this velocity rectilinear translational motion and separated from the propulsion jet thrust created. 2. The inertial propulsion device according to claim 1, characterized in that the system for separating a portion of the thread from the flywheel comprises a laser. 3. The inertial propulsion device according to claim 1, characterized in that the flywheel comprises a bundle of threads containing at least two threads and a holder of a bundle of threads. 4. The inertial propulsion device according to claim 1, characterized in that it comprises a flywheel rotation drive device, wherein the flywheel rotation drive device comprises a ring and a pipe connecting the flywheel and the ring, wherein an accelerating gap formed by slices of two located at the top and bottom of the ring around the ring and facing each other electrodes having the form of hollow half-cylinders, the electrodes being configured to be connected to a generator. 5. The inertial propulsion device according to claim 1 or 4, characterized in that the ring is made remotely controlled system with a battery, electrically connected to at least two conductive plates electrically isolated from each other, made on opposite sides of the ring opposite each other, wherein the battery of the system with the battery is configured to electrically charge at least two conductive plates with charges of opposite signs. 6. The inertial propulsion device according to claim 1, characterized in that it comprises a system with a generator configured to generate electrical energy by rotating the flywheel or ring connected to the flywheel. 7. The inertial propulsion device according to claim 1, characterized in that it contains a magnetic suspension configured to hold the flywheel in weight during rotation of the flywheel. 8. The inertial propulsion device according to claim 1, characterized in that it contains a magnetic suspension configured to hold the flywheel in weight during rotation of the flywheel, and the magnetic suspension contains a superconducting magnet. 9. The inertial propulsion device according to claim 1, characterized in that the system of magnetic ball bearings is connected to the flywheel, comprising at least two ball bearings, the flywheel being freely rotatable with the ball bearing system. 10. The inertial propulsion device according to claim 1, characterized in that the system for separating from the flywheel section of the thread contains an electron accelerator. 11. The inertial propulsion device according to claim 1, characterized in that the system for separating from the flywheel section of the thread contains a machine gun. 12. The inertial propulsion device according to claim 1, characterized in that a cryostat is made below the flywheel, while inside the cryostat there is a structure containing at least two superconducting layers separated by a dielectric, the structure being made under the flywheel in the form of a ring. 13. The inertial propulsion device according to claim 1 or 12, characterized in that the superconducting layer contains superconducting ceramics. 14. The inertial propulsion device according to claim 1, characterized in that a cryostat is made below the flywheel, while inside the cryostat there is a system of structures with superconducting layers separated by a dielectric, containing at least two elements, the element containing a structure containing at least at least two layers of a superconductor separated by a dielectric, the system being connected to a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric, and configured to remotely control a system for changing the position of elements of a system of structures with superconducting layers separated by a dielectric, is configured to receive electric power either from a battery or from a generator configured to generate electricity when the flywheel rotates, while the system is changing the position of elements of a system of structures with superconducting layers separated by a dielectric configured to arrange elements of a system of structures with superconducting layers separated by a dielectric , So that the superconducting layers are connected in a ring disposed below the flywheel and is arranged to locate the elements such that the superconducting layers are connected in a ring. 15. The inertial propulsion device according to claim 1, characterized in that it comprises a charger configured to charge a portion of the thread at the exit of the flywheel with an electric charge of a certain sign, while a device for changing the direction of movement of the portion of the thread after separation is connected to the charger, comprising an electrode system while the electrode system contains at least two electrodes. 16. The inertial propulsion device according to claim 1, characterized in that it is configured to connect to the aircraft, while it is possible to connect a pair of inertial propulsion engines with flywheels to the aircraft, while it is possible to rotate the flywheels in opposite directions. 17. The inertial propulsion device according to claim 1, characterized in that it is adapted to be connected to a thermal power station containing a boiler, and it is possible to separate a portion of the thread from the flywheel so that the portion of the thread after separation collides with the boiler of the thermal power station and heats the boiler of the thermal power station . 18. The inertial propulsion device according to claim 1, characterized in that it contains a rocket, while it is possible to direct the portion of the thread so that the portion of the thread after separation encounters the flame of the propellant of the rocket and heats the flame of the propellant of the rocket. 19. The inertial propulsion device according to claim 1, characterized in that it contains a rocket propulsion device configured to accelerate the working fluid, it being possible to direct the portion of the thread so that the portion of the thread after separation from the flywheel collides with the working fluid of the propulsor and heats the working fluid mover. 20. The inertial propulsion device according to claim 1, characterized in that it comprises a housing with a vacuum volume equipped with vacuum pumping means, while in the housing there is a window for releasing a portion of the thread. 21. The inertial propulsion device according to claim 1, characterized in that the thread is either completely made of Kevlar or reinforced with Kevlar. 22. The inertial propulsion device according to claim 1, characterized in that the thread is either completely made of synthetic fiber or reinforced with synthetic fiber. 23. The inertial propulsion device according to claim 1, characterized in that the thread is either completely made of carbon nanotubes or reinforced with carbon nanotubes. 24. The inertial propulsion device according to claim 1, characterized in that the thread is either completely made of graphene or reinforced with graphene. 25. The inertial propulsion device according to claim 1, characterized in that the thread is either completely made of quartz fibers or reinforced with quartz fibers. 26. The inertial propulsion device according to claim 1, characterized in that the thread is either completely made of carbon fiber or reinforced with carbon fiber. 27. The inertial propulsion device according to claim 1, characterized in that the flywheel comprises a bundle of threads containing at least two threads secured by a thread holder connected to a shaft coaxial with the axis of rotation of the flywheel. 28. The inertial propulsion device according to claim 1, characterized in that the thread is either wound on the flywheel, or the inertial propulsion device comprises a thread containing a portion of the thread, configured to rotate the flywheel in a position in which the portion is parallel to a straight line perpendicular to the axis of rotation and passing through the axis of rotation. 29. The inertial propulsion device according to claim 1, characterized in that it comprises a housing with a vacuum volume equipped with vacuum pumping means, while in the housing there is a window for releasing a portion of the thread, made with the possibility of hermetically closing and tearing off, while the flywheel contains a bundle of threads, comprising at least two threads fixed by a thread bundle holder connected to a shaft coaxial to the axis of rotation of the flywheel, the shaft being connected to a system for bringing the flywheel into rotation, the shaft being either suspended in a magnetic housing weight, or connected to the housing by magnetic ball bearings, while the shaft, the thread bundle holder, the bundle of threads, the system for separating the portion of the thread and the system for bringing the flywheel into rotation are made in a vacuum volume inside the housing. 30. The inertial propulsion device according to claim 1, characterized in that the flywheel comprises a bundle of threads containing at least two threads fixed by a thread bundle holder made in the center of the flywheel so that the envelope of the ends of the threads lying in the plane of rotation of the flywheel rotates around the center of mass of the holder. 31. The inertial propulsion device according to claim 1, characterized in that it is configured to connect to a thermal power plant, and it is possible to separate a portion of a thread from the flywheel so that the portion of the thread after separation collides with the fuel of the thermal power station and heats the fuel of the thermal power station. 32. The inertial propulsion device according to claim 1, characterized in that it contains at least two flywheels made with one axis of rotation parallel to each other, while the housing has a cylindrical shell with windows for each flywheel for the release of the working fluid in the form of separated sections threads, moreover, at least two systems for separating a section of a thread are connected to the housing. 33. The inertial propulsion device according to claim 1 or 3, characterized in that the system for separating a section of a thread contains a laser, while it is possible to direct a laser beam to at least two sections of a bundle of flywheel threads along the length of the thread with a step equal to the length of the detachable section filaments, and it is possible to direct the laser beam by pulses. 34. The inertial propulsion device according to claim 1, characterized in that the thread has a rectangular cross section. 35. The inertial propulsion device according to claim 1, characterized in that the flywheel comprises a bundle of threads containing at least two threads fixed by a thread holder, the thread being made in a rectangular cross section, with at least two parallel layers being made in the bundle threads perpendicular to the axis of rotation of the flywheel, and the threads in the layer are bonded to each other, while outside the part of the bundle, compressed by the holder, it is possible to separate part of one layer of thread from another layer.

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