RU2155435C1 - Mechanical energy generating device and process - Google Patents

Abstract

FIELD: power engineering and transport; miscellaneous industries. SUBSTANCE: single-row power module has stator and rotor with rollers combined by common separator. Stator and rotor are made of permanent magnets or electromagnets based on composite laminated magnetic, conducting, and insulating materials. Main shaft of device is coupled via free-wheel clutches with starting motor that brings device to automatic speed-maintaining mode of operation and device loading system which is, essentially, electrodynamic generator mechanically coupled with main shaft of device. Electromagnetic transducers are radially arranged on device periphery. Propulsion control is effected by adjusting mechanical energy taken off the device and by producing radial electric polarization on its periphery by means of annular electrodes separated from rotor rollers by air gap. Electrodes are connected to high-voltage power supply. Generating process includes electric power supply to starting gear, acceleration of rotor shaft to working speed, take-off of generated energy, and adjustment of mentioned energy and propulsion by varying rotor and stator speed through varying load of generator connected to device as well as by adjusting high voltage applied from external power supply. EFFECT: reduced energy consumption. 9 cl, 17 dwg

Description

 The invention relates to energy conversion, to stand-alone devices and methods that provide this conversion and are used in energy and transport, as well as in other industries.

 Known electric motor generator containing a rotor and a stator, the rotor is made of permanent magnets, the stator in the form of an electromagnet. The disadvantage of this device is that the device has limited use, since the method for converting mechanical energy into electromagnetic energy requires external sources of energy to ensure continuous operation [UK Patent N2,282,708B of November 6, 1996].

 Closest to the proposed invention is a device containing a magnetic system in the form of a stator and an axially located rotor, and a method comprising creating a stator with a magnetic field in the rotor region, polarizing the quantum structure of the electron shells of atoms by means of nonlinear resonant gyromagnetic effects associated with magnetic rotor rotation and magnetization stator field [A. Einstein, W. de Haas. Experimental proof of the existence of Ampere molecular currents // Sobr. scientific tr M.: Nauka, 1966. T. 3, p. 363-379, p. 382-385]. The disadvantage of this device and method is the need for continuous use of an external energy source to ensure the operation of the device when implementing this method.

 The present invention solves the technical problem of creating a highly efficient, autonomous and environmentally friendly converter of energy of a quantum level and a gravitational field into mechanical energy and organizing a method for converting energy of a quantum level and a gravitational field into mechanical energy.

 The stated technical problem is solved in that the device for generating mechanical energy contains one or more energy modules consisting of a stator and one or more rotors mounted coaxially to each other, the rotors are made in the form of rollers mounted around circles concentric with the circumference of the stator with the possibility of engagement with the stator by means of transverse magnetic inserts to ensure rotation around its own axis of the rotor relative to the stator and vice versa, as well as a system for creating an electric field ization consisting of electrodes arranged along the rotor on the periphery of the device, to which a high voltage relative to the stator, wherein the main shaft unit associated with starting the engine, outputting a self-maintenance unit in the rotation mode.

 The stated technical problem is also solved by the fact that the stator and rollers are made of permanent magnets, magnetic, and / or conductive, and / or dielectric materials and / or electromagnets, and / or composite materials, and also that the power take-off system consists of electrodynamic generator and electromagnetic transducers located along the rotor and providing guidance of the EMF entering the load, and also contains a system for creating electric polarization and a power take-off system, made mechanically associated with the rotor through overrunning clutches, moreover, the rotor elements are joined by a common separator rollers.

 The stated technical problem is also solved by the fact that in the method of generating mechanical energy, which consists in untwisting the rotor shaft or stator, which are installed with the possibility of engagement with each other by means of transverse magnetic inserts, to the speed of self-maintaining rotation and self-acceleration, which ensures the appearance of traction, the vector of which is directed along the central axis the stator and rotor, apply high voltage to the electrodes located along the rotor at the periphery of the device, regulate the device’s traction and rotational speed and a rotor in a self-sustaining mode of rotation by the load change, or coaxial rotation of the stator relative to the rotor, or by high voltage adjustment.

 This embodiment of the invention allows to convert the energy of the quantum level of the substance of the magnetic elements of the stator and rotor due to the fact that each element of the working body of the device, whether it is the elements of the rotor - rollers or stator, with the possibility of both independent and joint rotation, already represent complete a device that interacts with the quantum level of matter organization and transforms the gravitational field. The main conditions for this interaction are the observance of fractal similarities at the micro and macro levels and the limitation or regulation of the degrees of freedom of the created macro object, the analogue of which is in the microworld.

 The principle of operation of the patented device is that a nonlinear resonant coupling is created between geometrically similar objects at the micro and macro levels. The effects of interaction with the microlevel and the transformation of the gravitational field can be significantly enhanced by choosing various options for spatial layouts described in the device, which consider the joint work of all elements of the working fluid as a single resonant structure.

 The direct Burnett effect (1909) is well known, which consists in magnetizing bodies by rotating them in the absence of an external magnetic field. The inverse Barnett effect, often referred to as the Einstein de Haas effect (1911), is also well known. [Burke G.Yu. Reference manual on magnetic phenomena. M. Energoatomizdat, 1991], which consists in the fact that during the magnetization of a cylindrical sample of a ferromagnet there is a torque. Similar effects were later discovered based on the paramagnetic and nuclear resonance techniques in other material media [Richard R. Ernst. Principles of Nuclear Magnetic Resonance in One and Two Dimensions. University Press, Oxford, England 1987]. In the above-described gyromagnetic effects, only preliminary weak structural polarization occurs. But even at this preliminary level, quantum processes give rise to a macroeffect, which can be greatly enhanced by resonant coupling with external fields.

 In the inventive device for creating a resonant coupling, specific parameters of an elementary quantum oscillator are selected, which is an energetically autonomous atomic structure of the crystal lattice of the working fluid of the device. These parameters include: natural oscillation frequency, magnetic and spin moments of the oscillator. Based on the specific parameters of an elementary quantum oscillator, a mechanical macromodel is created, which fractally repeats the properties of its quantum analog in a static version. Since the atomic structure is initially depolarized, energy exchange with the surrounding quantum space occurs spherically symmetrically. In the process of polarization, spherical symmetry is broken and a flat, ecliptic symmetry is created, thereby providing directional energy release. The claimed device, as a macroanalog of a quantum oscillator, is pre-polarized, organizing an external field. During operation of the device, a nonlinear resonant interaction between these mutually similar objects is ensured by means of external fields. As a result of this, the quantum and the external macroscillator are mutually tuned and interlocked, like two nonlinear oscillatory circuits, providing stable energy exchange, and the quantum depolarized structure is polarized with the release of energy.

 The principal analogue of this process can be the nuclear chain reaction in the working fluid of an atomic explosive device, where the nuclear charge itself in the form of a plutonium sphere and an implosive detonation system is the same macro object, which is a scaled resemblance to the unstable nucleus of the Pu239 atom [Petrosyants AM The creation of the first Soviet atomic bomb. M. Energoatomizdat, 1995].

 The condition for observing the similarity and resonant interaction with the quantum level implies the existence of a stable vortex, hierarchical structure, in general terms similar to vortices formed in continuous media. In this case, the energy of the force field is concentrated in the so-called current tubes (fields) that border the body of the vortex. In turn, each of the field tubes is a reduced model of the observed vortex system and so on, penetrating deep into matter. The characteristics of the medium and the type of incoming energy determine the degree of energy concentration in the tubes of an ordinary vortex, which is limited by the viscosity of the medium, which is not able to endlessly reproduce the structure of current tubes. Thus, in fluids below a certain threshold size, the vortex structure ceases to reproduce, and the ratio of the minimum diameter of the current tubes to the outer diameter of the vortex, which serves as an indicator of the degree of energy concentration, is finite. A qualitatively different picture is observed in the case of a vortex system at the quantum level.

From the theory of electroweak interactions, it follows that, on a scale smaller than 10 ^-18 m, the electromagnetic field and weak interaction manifest themselves in some unified manner [Salam A. Elementary Particle Theory, Ed. N. Swartholm-Almguist and Wiksell, 1968.-p. 367]. Due to such continuity and mutual transformation, the destruction of power tubes not only does not occur, but, on the contrary, as follows from quantum electrodynamics, their phenomenal properties to concentrate the energy of an external source are greatly enhanced due to the inclusion of quantum processes. In the case of macroscopic scales, within which the dominant role belongs to electromagnetic interactions, the energy concentration mechanism can be described as a continuous decrease in the wavelength in the internal power tubes. With the transition of the weak interaction threshold and the inclusion of quantum mechanisms of energy exchange, thinner force fields induce quantum resonance phenomena of energy interaction, in which light-carrying particles of the lepton cloud are involved.

As a result of resonance phenomena, energy concentration occurs with a further reduction in scale and a shift in the effective distance of interacting particles to a subnuclear level. The scalability of the structure of a quantum vortex system (CVS) leads to the interconnectedness of the electroweak and strong interactions on a scale of 10 ^-22 - 10 ^-30 m [Okun LB Leptons and quarks, M. Nauka, 1990.]. Thus, at the subnuclear level, force tubes locally organize spontaneous fluctuations in the energy of space - time, manifesting itself as a vortex of "virtual" particles.

 When approaching Planck energy, the scale of manifestation of strong interaction gradually aligns with the scale of gravitational [Mulvey J.H. (ed). The Nature of Matter.-Oxford: Clarendon Press, 1981], and the level of energy concentration necessary for proton decay (X-particle formation) is reached in a force vortex long before the Planck radius. As is known from classical theory, the decay of a proton occurs with the formation of a positron and a neutral pion, which in turn decays into two photons that generate two pairs of electron-positron [Okun LB Leptons and quarks, M. Nauka, 1990]. Once in the electromagnetic field of the FAC, an electron with a positron moves in opposite directions, increasing in turn the intensity of the electromagnetic field that generates the main vortex system. Thus, the resonance effect manifests itself already at the macro level and leads to intensive self-induction of the vortex by the principle of positive feedback. In this case, as the density of the positrons formed increases, some of them do not have time to break out of the FAC and annihilate when they collide with electrons. The elimination of free electrons and the release of excess energy feed the resonant phenomena and lead to a self-developing process in the patented device.

 Elements of the working fluid of the device have the ability to self-center relative to each other. This possibility is achieved by the presence of the internal structure of the working fluid, described in the formula of the device. Due to this internal structure, the features of mutual magnetization and the joint rotational movements of structural elements, there is mutual capture and mutual centering, leading to the emergence and self-maintenance of the process of resonant energy conversion of the quantum level. Through the declared internal structure of the elements of the working fluid, they make joint rotational movements in space. A feature of this movement is that the rotor elements - rollers, in addition to collective movement around the stator, also rotate about their own axis. In one embodiment of the structural solution of the device arrangement, the rotor elements are combined by a common separator, and the device is started by an accelerating engine through a power take-off shaft connected to the rotor separator. The stator in this embodiment is stationary mounted on the device casing and the rotor rotates relative to it.

 The starting engine gradually increases the rotor speed of the device to the moment of self-developing (critical) mode. The reasons for this process are described above and they lead to the fact that the rotor of the device begins to spontaneously increase speed. This phenomenon is essentially analogous to chain nuclear reactions, only occurs without nuclear fission and the transformation or destruction of the working fluid. The critical mode of the patented device is characterized by two main aspects. Firstly, this is a spontaneous increase in the rotor speed of the device and, secondly, this is the transformation of the gravitational field associated with the structural polarization of the elements of the working fluid of the device, which is accompanied by directed coherent gravitational radiation.

The mechanism for creating directional coherent gravitational radiation in the inventive device is as follows. The proton holds the electron "dancing" around it, interacting with it through exchange photons γ (Fig. 1a). A photon or elementary particle (EC) generates a displacement D in a physical vacuum environment, which is the body of a graviton (Fig.1 b). The physical essence of the mechanism of graviton emission is that there is an identity of the electric displacement with the mechanical displacement of the vortex sponge D (Fig. 1 c), the latter due to the bending of the vortex tube, as well as the displacement in the medium of physical vacuum and has two propagation velocities. Along the vortex tube, the rotating bend advances at the speed of light C, and in the plane perpendicular to the axis of the vortex tube, displacements concentrically propagate at infinite speed with a density ρ of _total empty space equal to zero. It should be recalled that the physical vacuum medium has the full set of properties of a Bernoulli vortex sponge [Kelly E. "American Journal of Physics", 1963, 31, No. 10, pp. 785 -791].

Thus, the residual oscillations between the ring currents of an electron e (-) and a positron e (+) (Fig. 1a), appearing during the commutation of a resting elementary particle or occurring in a vortex tube when it is straightened (for a moving EC or photon), are the body of the graviton g (Fig.1 b), this is the physical nature of the particle-carrier of gravitational interaction, propagating at a speed significantly exceeding the speed of light. These residual vibrations are nothing but secondary microbends of the vortex tube (Fig. 1 c), therefore, everything regarding the process of photon propagation is applicable to them. In particular, they almost instantly fill the entire space of the quantum medium with themselves, since they have two propagation velocities: light along the vortex tube (V _CR = C) and infinite in directions perpendicular to its instantaneous orientation (V _pop = ∞ at ρ _total = 0). Actually, the presence of matter in the Universe (ρ _total ≠ 0) reduces V _pop to final values, but it still remains much higher than C. The presence of two propagation velocities determines the presence of two wavelengths in a graviton. Along the vortex tube, it is equal to λ _c ; across the vortex tube, the wavelength will be longer due to the much higher shear propagation velocity in these directions (V _pop >> C). The born graviton instantly “spreads out” to the whole Universe. We note once again that extremely large values of V _pop (V _pop >> C) and λ _gr contribute to this. However, the graviton body is still a concentrated formation. It moves along the vortex tube at the speed of light C, and when it encounters another elementary particle in the virtual positron that is in its path, it is absorbed by it. When forming a complete picture of the gravitational interaction, it is also necessary to take into account the "reradiation" of gravitons.

 Gravitational vibrations of the electron-positron pairs of the Universe are coherent and in total represent one self-consistent oscillation of the medium of a physical vacuum. Gravitational interaction has many features in common with electromagnetic. It has two propagation velocities: finite, equal to C, and infinite in the "empty" space. The presence of the second component of the velocity ensures the stability of gravitational and electromagnetic orbital systems. Due to the precession of the electron orbit, in an unpolarized atom (Fig. 1 g), the radiation of gravitons is spherically symmetrical in nature and completely compensated for the "momentum".

 To create a thrust impulse, or in other words, to create directed coherent gravitational radiation, it is necessary to get rid of the precession of electronic orbits and, accordingly, spherically-symmetric radiation of gravitons.

 In the inventive device for this purpose, conditions are created for the maximum polarization of the atomic structure relative to the applied external force. This effect puts electronic orbitals in the plane of the ecliptic. In this case, the emission of gravitons occurs coherently and unidirectionally (Fig. 1 e, f). This allows you to create a system in which the oscillations of the displacement D will be coherent, that is, the gravitons g emitted by the exchange photons γ will have the same direction and one phase. The direction of graviton emission is determined by the direction of rotation of the working fluid of the device.

 The critical mode of operation of the device is recorded through the mains supply of the starting engine when the current and voltage drop to the idle value. At this moment, the starting engine is switched off and the installation becomes completely energy autonomous. At this moment, the draft of the device is already fixed, the vector of which is directed along the central axis of the working fluid along the Z axis (Fig. 1 d, f). After a few seconds, the rotor reaches operating speed. At this stage, the electromagnetic clutch and the generator, which is not yet connected to the load, are turned on. This is done in order to smoothly generate the inertia of the rotor of the generator, without affecting the critical mode of the device. After the generator has set the nominal speed, the workload is connected.

 Full stabilization of the rotor speed is carried out by retractable electromagnetic transducers operating on additional or main load. In the event of an emergency failure of the electromagnetic converter, an additional electric generator and a friction block of the heat generator are included in the heat exchange circuit.

 In an embodiment of the patented device, as a device for creating traction, a coaxial arrangement of the rotor and stator is provided, ensuring their relative rotation. This achieves the control of the coherence and direction of the emission of gravitons and, accordingly, the thrust vector. Since the converted energy in the patented device has a quantum character and is associated with the process of emitting gravitons, the draft of the device is determined by the degree of structural polarization of the working fluid and depends on the mechanical energy removed from the device.

The invention is illustrated by the General diagram of the device shown in FIG. 2 as well as FIG. 3-19, which show the following:
FIG. 3 is a schematic diagram of a single-row device;
FIG. 4 - N-row device;
FIG. 5 - modular device;
FIG. 6 - modular-block device, the relative position and internal structure of the stator and rotor elements;
FIG. 7 is a block diagram of a single-row device with a coaxial mechanism and a power frame;
FIG. 8 is a diagram of an induction power take-off of a device;
FIG. 9 is a connection diagram of a high voltage polarization system;
FIG. 10 is a diagram of a ratio of stator diameters and rotor elements;
FIG. 11 - the relative position and internal structure of the stator and rotor elements;
FIG. 12 - the internal structure of the stator, magnetization options;
FIG. 13 - the internal structure of the rotor element and the structure of the transverse inserts;
FIG. 14 - internal structure of the stator and rotor with polymer filler, magnetization and electric polarization options;
FIG. 15 - the internal structure of the stator in a macroblock version;
FIG. 16 - the internal structure of the rotor element in a macroblock version;
FIG. 17 - the internal structure of the stator or rotor in a micropackage version.

 The single-row energy module shown in FIG. 2 contains a stator 1, a rotor consisting of magnetic rollers 2 connected by a common separator 3, through which torque is transmitted from the main shaft 4 of the device. The main shaft 4 of the device by means of overrunning clutches 5 is connected to the starting engine 6, which displays the device in the mode of self-rotation, and the load system of the device in the form of an electrodynamic generator 7, mechanically connected to the main shaft of the device. Along the rotor are electromagnetic transducers 8 with open magnetic circuits 9. Elements of the rotor 2 are magnetic rollers, crossing the magnetic circuits and closing the magnetic flux through electromagnetic transducers 8, induce an EMF in them, which goes directly to the load 10. Electromagnetic transducers 8 are located radially at the periphery of the device in single-row version and cover it in the longitudinal direction in a multi-row device. Electromagnetic transducers 8 are equipped with an electric drive 11 and have the ability to smoothly move along the rails 12. For radial electrical polarization at the periphery of the device between the electromagnetic transducers 8 are installed cellular electrodes 13 having an air gap with the rollers 2 of the rotor. The electrodes are connected to a high voltage voltage source 14.

 In the variant of the thermal energy generator, the device’s ability to directly reduce the entropy of the installation and the environment is used. As a result, any object (body, gas, etc.) placed in the field of action of the device lowers its temperature by several degrees Celsius, thereby ensuring the difference in thermal potentials in any energy cycle. It is also possible to drive any conventional thermal generators 15, for example, friction oil, water cavitation, etc., via the power take-off shaft 4.

Figure 2-7 shows structural embodiments of a device for converting the energy of the quantum level and the gravitational field into mechanical energy. Depending on the functional purpose of the device, several main design options can be distinguished:
1. The single-row device shown in figure 2 and figure 3, consists of one ring of the stator 1 and several rollers of the rotor 2 located axially around the stator, having the ability to rotate about the common axis of the device, and also having the ability to rotate around its own axis. The stator 1 can also rotate relative to the rollers of the rotor 2. In figure 3, position b shows a metal cylinder covering the rotor element - roller 2, which can be used in all variants of the device.

2. The N-row device shown in FIG. 4 consists of 3N, where N is the integer number of rows of single-row stator-rotor modules of FIG. 3. The movement and interaction of this system are similar to the single-row version. Weight ratios of modules A, B, C, etc. are reflected in the identity G _A = G _B = G _C.

 3. The modular device shown in FIG. 5, consists of single-row (Fig. 3) and / or N-row (Fig. 4) stator-rotor modules located coaxially. The dynamics and interaction of a single module are similar to those described above. The parameters of the system as a whole are selected constructively, based on the functional purpose of the device.

4. The modular-block device (Fig.6), respectively, consists of modular devices (Fig.3) located in space relative to each other. The parameters of the system as a whole are selected constructively, based on the functional purpose of the device, and have the ability to be located in space at any structurally necessary angle α, from 0 ^o to 360 ^o .

 5. Integrated options. Depending on the functional purpose of the device, various variations from the above technological options can be applied.

 For transmitting a thrust impulse from the rotor and stator of the device to the housing and further to various structures, power elements 16 are provided. One of the options is shown in FIG. 7. In all variants of the device, it is possible to place the stator and rotor in a special tank 17 with rarefied gas or evacuated. In some embodiments, the arrangement of the device provides for the coaxial arrangement of the rotor and stator (Fig. 7, position 18) to ensure their relative rotation.

 The inventive device provides a system of electromagnetic transducers 8, which are installed for direct power take-off and are open magnetic circuits 9 with induction coils. In FIG. Figure 8 shows two versions of induction power take-off using the example of a 3-row device.

 For radial electric polarization on the periphery of the device between the electromagnetic transducers 8 are installed cellular electrodes 13 having an air gap with the rotor 2 (Fig. 9). The electrodes are connected to a high voltage voltage source 14.

To ensure high efficiency and stability characteristics of the device for converting the energy of the quantum level and gravitational field into mechanical energy in the design of the device, all variants of magnetic systems can be made on the basis of the following magnetic compounds:
Magnets based on iron, cobalt, nickel and aluminum;
Magnets made of hard magnetic sintered materials based on cobalt alloys with rare-earth metals;
Magnets made of magnetically hard sintered materials based on neodymium-iron-boron alloys;
Magnets from hard magnetic deformable materials based on alloys of iron, chromium and cobalt, subjected to hot or cold plastic deformation.

 To ensure the operability of the device, the ratio of the parameters of the stator 1 and the element of the rotor 2 (Fig. 10) is chosen so that the ratio of the diameters of the stator - D and the element of the rotor - d is an integer equal to or greater than 12. This achieves a resonant mode between the elements of the working fluid of the device .

,
где N - число вставок по периметру ролика.In FIG. 11 shows the joint arrangement of the stator 1, rotor elements - rollers 2 and the principle of their mutual engagement. Between the surface of the stator and the rollers an air gap is organized - δ, having a value from 0 to half the diameter of the stator. By the principle of gear meshing and by means of transverse magnetic inserts 19 on the stator and rotor, the clutch of the rotor rollers with the stator is organized. When the rotor rotates relative to the stator or, conversely, the rollers rotate around its own axis, circling the stator. Magnetization vectors In the transverse inserts 19 of the stator and rotor, they have opposite directions, as shown by the arrows in FIG. 11. The spatial arrangement of the elements of the device is reflected in the dependencies:
t ₁ = t ₂

,
where N is the number of inserts around the perimeter of the roller.

 The distance between the rollers - k is equal to half the diameter of the roller of Fig.11.

The design of the device includes the main technological options:
1. A variant of a modular system without a polyamide filler can be made on the basis of magnetic materials (Fig. 12, 13). In FIG. 12 shows a stator 1 of a device having the form of a thick-walled cylinder, which is assembled in a slipway from pre-magnetized segments 20 and 21 or is made in one piece. The direction of the magnetization vector B _I segment 20 and the vector B _II segment 21 can be selected in accordance with the functions of the device regarding its use as a device for converting the energy of the quantum level and / or gravitational field. The internal structure 22 of stator 1 and variants of its general magnetization B _I and B _{II are} also shown in FIG. 12. Above and below the cylinder of the stator 1 are two rims of the transverse inserts 19 with the magnetization vectors B, shown by arrows. They are made of rare-earth magnets (REM) 23 (Fig. 13), molded with poly-ε-caproamide 24 or pulse-magnetized by a special device in the form of a monolithic stator.

 In FIG. 13 shows the internal structure of a rotor element - a roller 2, which has the shape of a cylinder, which is assembled in a slipway from pre-magnetized blocks 25 or is made in one piece with the vertical direction of magnetization B. Two rims of transverse inserts 19 with a magnetization vector B are located above and below the cylinder of the rotor element. are made from REM magnets 23 formed with poly-ε-caproamide 24 or are magnetically pulsed by a special device in the form of a monolithic rotor element. Element 23 can be made in the form of a cylindrical insert with a diameter J1 or a rectangular insert with side J1.

 The elements of the stator 20 and 21 (Fig. 12) and the elements of the rotor 25 (Fig. 13) are processed before assembly by grinding according to the 4th accuracy class without chips and burns.

Necessary properties of magnetic elements:
Maximum magnetic energy 25-30 kJ / m;
Induction coercive force ~ 80 kA / m;
Residual induction 0.9-1.2 T
2. A variant of a modular system with a polyamide filler can be made on the basis of anisotropic metal-polymer magnets FeCo, REM (Co) with a binder filler made of poly-ε-caproamide [OC (CH ₂ ) ₅ NH] _n or [HN (CH ₂ ) ₆ NHCO (CH ₂ ) ₄ CO] _n . In this case, the internal structure of the stator 1 and rotor elements 2 fully corresponds to that shown in FIG. 12 and FIG. 13. Transverse magnetic inserts are performed similarly.

In FIG. 14 shows the directional directions of the magnetization vectors B _I and B _II in the stator 1 and in the rotor element 2 relative to the direction of the electric polarization vector E of the electret (poly-ε-caproamide), and also shows the direction of the energy circulation S relative to the magnetization options B _I and B _II .

 When pressing to ensure uniform density, it is necessary to use molds with double-sided application of load. Molds must ensure a surface quality of at least 4th accuracy class. The compressive strength of fully-pressed elements must be at least 120 N / mm. The necessary properties of magnetic elements should be at the level given in the first embodiment. Tooling tolerances must be kept within the limit of +/- 0.1 mm.

3. The macropackage variant is based on metals (Ti, Fe, Nd, Cu) and polymer (OC (CH ₂ ) ₅ NH] _n or [HN (CH ₂ ) ₆ NHCO (CH ₂ ) ₄ CO] _n . The internal structure of the stator 1 and rotor elements 2 is shown in Fig. 15 and Fig. 16. Metals are denoted by the letters c, e, f, polymer d. The transverse inserts 19 have the same magnetization and are structurally performed similarly (from rare-earth magnets) to the variant described in paragraph .1 and item 2. The surface quality of the connected elements of the stator and rotor must not be lower than accuracy class 4. Moreover, the connection of the elements of the stator and rotor must be b not lower than the level of diffusion. The requirements for equipment are similar to the options according to claim 1 and claim 2. Possible technological solutions for assembling the stator are shown in dashed lines in Fig. 15.

4. The micropackage variant is also based on metals (Ti, Fe, Nd, Cu) and the polymer [OC (CH ₂ ) ₅ NH) _n or [HN (CH ₂ ) ₆ NHCO (CH ₂ ) ₄ CO] _n . The implementation of this option involves the creation of a layered structure of the elements? indicated in FIG. 17, in all embodiments depicted in FIG. 12-17. Layers of k-elements should have a thickness within 3-5 microns and be deposited by electrochemical method, plasma spraying, or in some other way on the finished substrate. Metals are marked with the letters - c, e, f, polymer - d.

 The internal structure of the stator 1 and rotor elements 2 is similar to that shown in FIG. 15 and FIG. 16. The requirements for surface quality and connection of elements are the same as in the embodiment of claim 3.

The proposed method during operation of the device is as follows:
- supply electricity to the trigger mechanism 6 (figure 2);
- untwist the rotor shaft 4 (figure 2) to a speed at which there is no need for external energy;
- the generated energy is diverted by means of mechanical power take-off with the help of traditional electric generators 7, 15 (FIG. 2), mechanisms and machines and / or systems of electromagnetic transducers 8 (FIG. 2);
- regulate the generated energy by mechanical power take-off using traditional 7.15 power generators (FIG. 2), mechanisms and machines and / or electromagnetic transducer systems 8 (FIG. 2);
- regulate the rotational speed of the rotor or rotors, stator or stators and the generated energy by increasing or decreasing the load of the electric generator and / or the system of electromagnetic converters and / or adjusting the relative rotation speed of the rotor or rotors, stator or stators, as well as by adjusting the high voltage of the external source 14 (Fig. 2).

 The critical mode of operation of the device is fixed through the mains supply of the starting engine 6 (Fig.2), when the current in the circuit drops to the idle value. Then, the starting engine is turned off using the electromagnetic clutch 5 and the device becomes completely energy autonomous. At this moment, the draft of the device is already fixed, the vector of which is directed along the central axis of the rotor and stator.

 After a few seconds of self-acceleration, the rotor reaches operating speed and the load is smoothly connected to the electric generator 7 (Fig. 2). After connecting the load, a steady increase in speed is observed. Full stabilization of the rotor speed is carried out by sliding electromagnetic transducers 8, operating at a load of 10 (figure 2). In the event of an emergency failure of the electromagnetic converter, an additional electric generator (not shown in the diagram) and a friction block of the heat generator 15 included in the heat exchange circuit are switched on.

 In the operating mode, the magnitude of the thrust vector is further adjusted by applying a high voltage to the electrodes 13 relative to the stator 1 (Fig.2.9). By changing the magnitude and polarity of the applied high voltage, the magnitude and direction of the thrust vector generated by the device are controlled.

It should be noted that the device in one form or another has the ability to create traction in the axial direction. The thrust vector has the ability to change its direction depending on the direction of rotation of the rotor / stator of the device. Traction control can be carried out:
power take-off from the device by means of mechanical, thermal and electromagnetic load;
synchronous rotation of the stator relative to the rotating rotor. For this, a coaxial mechanism 18 is provided (Fig. 7) for stator 1 and rotor elements 2 in the device body (in any embodiment, structural and technological design);
connecting a high voltage power supply 14 (Fig.9).

 A laboratory prototype of the operating device of the energy converter of the quantum level and gravitational field into mechanical energy was assembled. His sketch is shown in FIG. 2. The device had a rotor with rollers made of rare-earth magnets and placed in copper glasses. The total weight of the device was 120 kg. The device was placed on a stabilized platform, providing the possibility of only vertical movement and measuring the magnitude of this movement by means of induction sensors. In operating mode, an active load of 6 kW was connected to the electric generator. At the same time, the device provided stable operation for a long time. Depending on the direction of rotation of the rotor, the direction of the thrust vector changed, which was recorded by the induction displacement sensor of the platform. Changing the weight of the device at a maximum converted power of 6 kW was +/- 40% of the total weight of the installation. The change in weight could be controlled by applying a high voltage of 20 kV to the cell electrodes located around the perimeter of the rotor.

Claims (9)

 1. A device for generating mechanical energy, containing a stator and a rotor, characterized in that it contains one or more energy modules consisting of a stator and one or more rotors mounted coaxially to each other, the rotors are made in the form of rollers mounted in circles concentric the stator circumference with the possibility of engagement with the stator by means of transverse magnetic inserts to ensure rotation around the rotor’s own axis relative to the stator and vice versa, as well as a system for creating an electrical polarization, consisting of electrodes located along the rotor at the periphery of the device, to which high voltage is applied relative to the stator, moreover, the main shaft of the device is connected to the starting motor, which displays the device in a self-sustaining rotation mode.  2. The device according to claim 1, characterized in that the stator and the rollers are made of permanent magnets.  3. The device according to claim 1, characterized in that the stator and rollers are made using magnetic and / or conductive or dielectric materials.  4. The device according to claim 1, characterized in that the stator and the rollers are made of electromagnets.  5. The device according to claim 1, characterized in that the stator and rollers are made of composite materials.  6. The device according to claim 1, characterized in that the power take-off system consists of an electrodynamic generator and electromagnetic converters located along the rotor and providing guidance of the EMF entering the load, and also contains a system for creating electric polarization.  7. The device according to claim 1, characterized in that the systems for power take-off are made mechanically connected to the rotor through overrunning friction clutches.  8. The device according to claim 1, characterized in that the rotor elements of the rollers are combined by a common separator.  9. The method of generating mechanical energy, which consists in unwinding the rotor shaft or stator, which are installed with the possibility of engagement with each other by means of transverse magnetic inserts to a speed of self-maintaining rotation and self-acceleration, which ensures the appearance of traction, the vector of which is directed along the central axis of the stator and rotor, applying high voltage to electrodes located along the rotor at the periphery of the device, regulating the traction of the device and the speed of rotation of the stator and rotor in the mode of self-maintaining rotation through PTO load changes or coaxial rotation of the stator relative to the rotor, or by high voltage adjustment.

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