RU2022131216A - A method for generating electrical energy, an electrical energy generator, a torque generator and an orientation system for implementing the method - Google Patents

Claims (64)

1. A method for generating electrical energy, including the generation of electrical energy by changing the magnetic field over time in conducting circuits with a torque, characterized in that material objects made in the form of an electrical energy generator, a torque generator, an orientation system are combined into a group of objects, mechanically and functionally connected with each other, localized in a finite region of space, containing stationary and moving material bodies, with a common axis of symmetry coinciding with the axis of rotation, while simultaneously rotating the moving material bodies relative to the stationary material bodies with a source of external energy, spinning up sources of constant magnetic fields that form an alternating-polar magnetic field in a closed local zone of space, while changing the magnetic field in time in stationary conductive coils closed to the load and generating electrical energy in the form of variable pulsating electrical power, proportional to the product of torque and angular velocity minus the loss power, they simultaneously convert the received electrical power into potential energy of electrical voltage and send it to a torque generator, in which they convert constant electrical energy into pulsed magnetic energy, while passing an electric current through sources of a pulsed magnetic field for a limited time and magnetizing stationary material bodies made of soft magnetic materials, under the influence of which they form in the outer local zones a magnetic field that is variable by induction, increasing in time and surrounding space, in which material bodies made of soft magnetic materials are placed in the indicated zones at given distances , and rotate moving material bodies during magnetization under the influence of emerging forces of attraction, forming a cycle of the occurrence of torque, with its values increasing as the distance between the magnetizing and magnetized material bodies decreases, converting magnetic energy into rotational mechanical energy until the magnetic flux closes and the magnetization pulse ceases to operate , with subsequent demagnetization of material bodies made of soft magnetic materials, under the influence of thermal vibrations of atoms in the structure of soft magnetic materials, while imparting a pulse of rotational mechanical energy to moving material bodies, then sequentially forming in the above manner with an advance angle for switching on subsequent sources of pulsed magnetic fields, successive cycles of the occurrence of torque and form at least one continuous sequence of cycles of the occurrence of torque in one revolution of moving material bodies, while forming an average, continuous, enhanced torque, under the influence of which they increase the electrical power generated by the electrical energy generator and, accordingly, reproducing electrical power directed to generate torque to a level at which electrical power is generated in an amount exceeding the starting electrical power, power losses in the electrical energy generator for heating wires and electromechanical power losses are reduced at the first start as the generated electrical power increases external impact until complete shutdown, then the moving material bodies are spun under the influence of the generated electrical power, from which an averaged, continuous, enhanced torque is generated, increasing the angular speed of the moving material bodies, spinning up the electrical energy generator to a level at which electrical power is generated in an amount exceeding the electrical power spent on the reproduction of the torque and, in the limit, achieve equality between the power losses in the system and the electrical power spent on the reproduction of the average, continuous, amplified torque, which decreases with increasing angular speed, while retaining excess electrical energy in the form of potential energy of electrical voltage, after which a useful electrical load is connected to the electrical energy generator, while the angular speed is reduced, power losses in the system are reduced, but the generating electrical power is increased, from which an averaged, continuous, enhanced torque is generated, bringing moving material bodies into a stable mode of obtaining useful electrical power. energy according to the approximate equation: , where i ₃ ⋅U ₃ is the average value of useful electrical power at the payload (W); i ₃ - average value of useful electric current (a); U ₃ - average value of useful electrical voltage (V); i⋅U - average value of starting electrical power (W); i is the average value of the starting electric current (a); U is the average value of the starting electrical voltage (V); i ₁ ⋅U ₁ - average value of the generating electrical power generated by the generator (W); i ₁ - average value of the reproducing electric current (a); U ₁ - average value of the reproducing electrical voltage (V); i ₂ ⋅U ₂ - average value of the reproducing electrical power supplied to the torque generator (W); i ₂ - average value of the reproducing electric current supplied to the torque generator (a); U ₂ - average value of the reproducing electrical voltage supplied to the torque generator (v); i ₄ ⋅U ₄ - constant electrical power consumed by magnetic field sources generating alternating - magnetic field polar in induction, for example, by direct current electromagnets (i ₄ ⋅U ₄ =0, in the formation of an alternating-polar magnetic field in induction by magnetic field sources made in the form of permanent magnets) (W); i ₄ - direct electric current consumed by magnetic field sources that form an alternating-polar magnetic field by induction, for example, direct current electromagnets (i ₄ =0, when generating an alternating-polar magnetic field by induction by magnetic field sources made in the form of permanent magnets ) (A); U ₄ - constant electrical voltage supplied to the magnetic field sources, forming an alternating-polar magnetic field (c); , where K is the torque amplification factor (m); W is the number of turns of the magnetizing coil; r ₁ - radius of the circle of placement of the axes of the magnetizing coils (m); b ₁ - radial width of the magnetizing coil core (m); δ ₁ - the size of the gap between the core of the magnetizing coil and the inner side walls of the bracket-shaped magnetic circuit (m); where Ζ is the electromechanical power gain (real, dimensionless number); m is the number of cycles of torque occurrence in one angular sector; q is the number of angular sectors in the bushing; N is the number of sequences simultaneously forming cycles of torque occurrence; R is the resistance of the magnetizing coil (ohm); ω _о - nominal angular velocity (1/s); I ₁ ² ⋅r _in - power loss for heating wires when generating reproducing electrical power (W); r _in - internal resistance of the conductive turns of the electrical energy generator, generating reproducing electrical power (ohm); i ₃ ² ⋅r' _in - power loss for heating wires when generating useful electrical power (W); r' _in - internal resistance of the conductive turns of the electrical energy generator generating useful electrical power (ohms); Mpot - moment of electromechanical losses (n⋅m); (electrical power losses due to hysteresis, eddy currents, leakage currents, etc.; losses due to friction and air resistance); where j=1, 2, 3, 4; i is the current value of the electric current in the magnetizing coil during the magnetization pulse time (a); U is the voltage value on the magnetizing coil during the magnetization pulse time (v), (U=U, when connecting the magnetizing coil to a source of external energy, U=U ₂ , when connecting the magnetizing coil to a source of reproducing electrical voltage); L is the inductance of the magnetizing coil (g); , where α is the magnetization angle (rad); Δα - angle of advance of switching on the subsequent magnetization pulse (rad.); in accordance with which, in a combined group of material objects, system parameters are changed according to equations (1), (2), (3), (4), (5) to increase the generated useful electrical power in a static state, with subsequent output to a dynamic mode obtaining useful electrical energy or in a dynamic state, for example, by increasing the number of sequences of cycles of torque generation. 2. The method according to claim 1, characterized in that a source of mechanical energy is used as a source of external energy for spinning moving material bodies. 3. The method according to claim 1, characterized in that an autonomous source of electrical energy, for example, a battery, is used as a source of external energy for spinning moving material bodies. 4. The method according to claim 1, characterized in that during repeated starts of the system, the system is spun up from an external energy source to the known values of the generated reproducing electrical power identified during the first start, followed by shutdown. 5. An electrical energy generator containing a magnetic system and material bodies made of soft magnetic materials with conductive turns, characterized in that the magnetic system is made in the form of at least one alternating-polar magnetic field, formed by the imposition of magnetic fields of an even number less than two physically similar sources of a constant magnetic field with axial magnetization parallel to the axis of rotation, with alternating polarity of poles, equal end surfaces of the poles, not larger than the pole area of a fixed radial magnetic circuit, and equal masses, through equal angles, radially symmetrically placed on a circle of the same radius , at equal distances equal to at least twice the length of the center line of the pole arc of the radial fixed magnetic core, in a supporting material body of rotation made of non-magnetic, dielectric material in the form of a separator containing lateral, reinforcing the rigidity of the surface of rotation, with neutral sections of sources of constant magnetic field , located in the middle plane of the separator, perpendicular to the axis of rotation, and located in the annular region of space formed by the side walls of the rings, perpendicular to the axis of rotation, consisting of poles without gaps, fixed radial magnetic circuits, closed at the periphery, located radially symmetrically relative to the axis of symmetry at least than twice the number of sources of a constant magnetic field, and containing stationary conductive turns, with equal force attraction of the “north” and “south” poles of each source of a constant magnetic field, in suspension, to the walls of the rings, with the possibility of rotation of the sources of a constant magnetic field and a synchronous change in the magnetic field induction over time in the poles and, accordingly, in stationary radial magnetic circuits, simultaneously located in the area of action of magnetic fields of constant magnetic field sources, in the absence of a change in the magnetic field in the adjacent stationary magnetic circuits, induction of EMF in conducting turns with a time-varying magnetic field, and the conducting turns in which an EMF of one polarity and one phase is generated are connected in series and counter-current when an EMF of reverse polarity of the same phase is induced in them, with the generation of electrical energy in them in the form of variable pulsating electrical power with simultaneous rectification on a full-wave rectifier and by averaging, for example, on a capacitor, with the conversion of variable pulsating electrical power into potential energy of electrical voltage, directed to reproduce torque, after which the change in the magnetic field over time when rotating sources of a constant magnetic field is carried out in adjacent stationary radial magnetic circuits, in the conducting turns of which they generate EMF and select useful electrical power in the form of phase-shifted alternating pulsating electrical power from the conducting turns connected in the above manner and directed to the payload through an independent electrical circuit, while, when an alternating-polar magnetic field is formed by magnetic field sources made in the form of electromagnets direct current, select the required amount of electrical power from the generated variable pulsating electrical power, for example, from the circuit of useful electrical power, convert it into direct electrical power in the above manner and pass the electric current through the electromagnets of the alternating-polar magnetic field, while the average arc length of the stationary radial pole magnetic core, equal to the width of the side wall of the ring in the radial direction, and equal to the product of the pulse duration in the phase of the generated EMF in the conducting turns of the stationary radial magnetic circuit and the linear speed of movement of the constant magnetic field sources relative to the poles of the radial stationary magnetic cores. 6. The generator according to claim 5, characterized in that the poles of the fixed radial magnetic circuits are made of sheets of soft magnetic material lying in planes perpendicular to the radii of the circles where the magnetization axes of the magnetic field sources are located. 7. The generator according to claim 5, characterized in that the sources of constant magnetic field are made in the form of permanent cylindrical magnets with axial magnetization. 8. The generator according to claim 5, characterized in that the sources of constant magnetic field are made in the form of permanent magnets, made in the form of regular polygonal, for example, with equilateral hexagonal bases, prisms with axial magnetization. 9. Generator according to claims. 5, 7 and 8, characterized in that the sources of constant magnetic field, made in the form of permanent magnets, are equipped with anti-shear protrusions or grooves in the area of neutral sections on the outer side surface. 10. The generator according to claim 5, characterized in that the sources of constant magnetic field are made in the form of direct current electromagnets containing cores and a magnetizing coil. 11. Generator according to claims. 5, 10, characterized in that the cores of direct current electromagnets are made of sheets of soft magnetic material and are placed in planes perpendicular to the radius of the circumference of the magnetization axes with the possibility of eliminating axial shift. 12. Generator according to claims. 5, 10, characterized in that direct electric current is supplied to sources of alternating-polar magnetic field induction, made in the form of direct current electromagnets, through sliding contacts. 13. A torque generator made in the form of a material object containing magnetic systems and material bodies, characterized in that the material object is made in the form of a torque generation system and a pulse generation system, while the torque generation system is made in the form of a set of no less than two groups of stationary, radially symmetrical with respect to the axis of symmetry sources of a pulsed magnetic field, made in the form of at least two rectangular magnetizing coils in a group containing radially oriented cores made of soft magnetic materials with magnetization axes parallel to the axis of symmetry, outside, symmetrically with respect to the axis symmetry located in the cavity formed by the internal side walls of a material body of rotation, made in the form of a bushing made of non-magnetic, dielectric material, containing in the side walls and body of the bushing an even number of at least two slots, symmetrical in pairs relative to the axis of rotation, parallel to the planes passing through axis of rotation, forming in the plane of a circle perpendicular to the axis of rotation, equal angular sectors in which material bodies made of soft magnetic materials are fixed in the form of a sheet, rectangular, one-sided bracket, with the possibility of covering the cores of magnetizing coils during rotation with the formation of closed magnetically conducting circuits with two equal successive gaps, with each bracket-shaped magnetic circuit functionally connected to the position of at least one of the group of angular path sensors of the pulse generation system containing material bodies of rotation, made in the form of tori of rectangular cross-section from a non-magnetic, dielectric material, with fixed in the middle axis rotation of the part, in recesses on the outer side surface, by a group of at least one angular path sensor, made in the form of a constant cylindrical or in the form of a regular polygonal prism, magnet with axial magnetization lying in a plane perpendicular to the axis of rotation, perpendicular to the radius passing through the center a permanent magnet, and the bodies of rotation are combined into a set of bodies of rotation and separated from each other along the axis of rotation by shielding, separating the areas of placement of fixed magnetically controlled contacts, with the possibility of excluding unauthorized operations from the magnetic field of the side angular path sensors, by magnetic cores made in the form of rings made of sheet magnetic soft material, while the angular path sensors are placed in recesses on the outer surfaces of bodies of rotation through angular distances that are multiples of the angular sector and in a set of bodies of rotation are placed in projection onto a plane perpendicular to the axis of rotation, in groups with an angular distance between the groups equal to the value of the angular sector, with the possibility during rotation of a sequential, periodic, with a period equal to the value of the angular sector, closure by permanent magnets functionally connected to each angular path sensor of one of the group of fixed magnetically controlled contacts on an angular path equal to the magnetization angle and approximately equal to the length of the angular path sensor, with the possibility of formation within one angular sector of at least two consecutive cycles of the occurrence of torque and the subsequent sequential formation of cycles of the occurrence of torque within the next angular sector, etc., while each angular path sensor, closing the magnetically controlled contact corresponding to this sensor, forms the region of its inclusion, with In this case, an electric current is supplied to the magnetizing coil corresponding to this contact, while simultaneously placing a functionally connected bracket-shaped magnetic core at a distance of the magnetization angle from the core of the magnetizing coil, and under the influence of an electric current, the core is magnetized, forming an external magnetic field, magnetized in which under the influence of emerging forces magnetization, the staple-shaped magnetic core generates a torque that increases with decreasing distance between the core and the staple-shaped magnetic core, until the magnetically controlled contact opens after completing the cycle of torque generation when the magnetic flux is closed in the nodes of the antinodes of the magnetic fields of the advancing edges of the core of the magnetizing coil and the staple-shaped magnetic core, and before turning off switched on magnetizing coil, with acceleration by the advance angle, the next magnetically controlled contact is closed to the following angular path sensors, supplying electric current to the next magnetizing coil of the next cycle of torque occurrence, etc., ensuring the continuity of the formation of cycles of torque occurrence and the formation of at least one sequence cycles of torque occurrence in one revolution of the system, with the possibility of increasing the number of sequences in one revolution of the system with an increase in the number of groups of magnetizing coils controlled from one magnetically controlled contact, as well as an increase in the number of rotating bodies containing bracket-shaped magnetic circuits to increase their number and, accordingly, increase number of groups of magnetizing coils, while the staple-shaped magnetic circuits are made with a nominal lateral surface area, the values of which are determined experimentally, and also the magnetizing coils in one group and magnetically controlled contacts in their group are placed in projection onto a plane perpendicular to the axis of rotation, at angular distances equal to angular sector minus the value of the angular sector divided by the number of cycles of torque occurrence within one angular sector. 14. The torque generator according to claim 13, characterized in that the leading edges of the cores of the magnetizing coils and bracket-shaped magnetic circuits are made pointed with an angle of no more than 90°. 15. The torque generator according to claim 13, characterized in that in the cores of the magnetizing coils, when two or multiples of two sequences of cycles of torque occurrence per one revolution of the system are formed, with the simultaneous activation of two or multiples of two magnetizing coils, a magnetic field is created in them that is mutually reverse in polarity field. 16. The torque generator according to claim 13, characterized in that the magnetizing coils are connected in series or parallel connection to a source of electrical energy. 17. The torque generator according to claim 13, characterized in that when spinning the moving elements of the system from an external source of electrical energy, for example, a battery, the pulse generation system contains an additional starting group of magnetically controlled contacts, similar to the working group, shifted by 180° in the areas placement of magnetically controlled contacts, with the possibility of simultaneous formation of cycles of torque generation through independent electrical circuits. 18. An orientation system containing moving and stationary elements of an electrical energy generator, a torque generator, bearing supports, characterized in that the moving elements of the electrical energy generator and torque generator, when the rotation axis is oriented perpendicular to gravity, are placed on the outer surface of the rotor, containing at the ends orienting material bodies of rotation containing surfaces of rotation parallel and perpendicular to the axis of rotation, made with the possibility of contact with bearing supports at least three points on each surface of rotation, and the axes of bearing supports contain axes of rotation and symmetry located outside the axis of rotation of the rotor, while the axes of bearing supports of radial orientation are placed parallel to the axis of rotation of the rotor on the cylindrical surface of placement of the axes of bearing supports of radial orientation in projection onto a plane perpendicular to the axis of rotation of the rotor at equal angular distances from each other, and the axes of bearing supports of axial orientation are placed in the radial direction at equal angular distances from each other from each other on the circle of placement of the centers of the bearing supports in a plane perpendicular to the axis of rotation of the rotor, with the possibility of forming a system of rotation of the moving elements of the electrical energy generator and the torque generator with oscillations during rotation relative to the stationary elements of the electrical energy generator and the torque generator in the axial direction within the limits of error manufacturing bearing supports, while when the rotor rotation axis is oriented, coinciding with the axis of symmetry of the system, parallel to the force of gravity, the rotor ends are equipped with sources of annular cone-like constant magnetic fields, designed to form, together with the stationary sources, annular cone-like constant magnetic fields in planes perpendicular to the axis of rotation rotor on both end sides of the rotor, the imposition of unipolar induction, counter-directed magnetic fields, forming magnetic cushions in a local area of space, with the ability to compensate for the weight of moving elements of the system, reducing energy losses due to friction, with precise orientation of the moving elements of the system in bearing supports relative to the stationary ones elements in the above manner. 19. The orientation system according to claim 18, characterized in that the axial orientation bearing supports are equipped with toroidal outer rings. 20. The orientation system according to claim 18, characterized in that the magnetic cushions are formed from unipolar induction, counter-directed magnetic fields of a finite set of constant magnetic field sources, made in the form of regular polygonal prisms, with axial magnetization, for example, with equilateral hexagonal bases, side surfaces adjacent to each other and poles of the same name through gaps, the nominal values of which are determined experimentally, and placed in the form of cellular honeycomb structures in beehives on load-bearing surfaces in the form of truncated straight cones of external moving and internal fixed supports made of magnetically soft materials, with magnetization axes of constant magnetic field sources perpendicular to the placement surfaces, with the possibility of rigidly fixing the position of the same poles of constant magnetic field sources on the surface of supports under the influence of magnetization forces and mechanical fastening forces.