RU2009113270A - METHOD (OPTIONS) AND DEVICES (OPTIONS) OF ELECTROMECHANICAL TRANSFORMATION OF FERROMAGNETIC ENERGY - Google Patents

Abstract

 1. The method (option) of the electromechanical conversion of ferromagnetic energy, which consists in the fact that when the rotor-inductor rotates, the ferromagnetic cores with windings located next to the rotor-inductor (through the air gap) are periodically magnetized and demagnetized; in this case, the energy is removed only in the demagnetization phase (during magnetization, the current does not go through the windings, it is blocked by diodes, thyristors, etc.), and almost all (except losses) is converted to the ferromagnetic energy of the stator cores, and the braking torque to the rotor inductor creates only an insignificant part of the stator ferromagnetic cores, since most of their field is closed outside the inductor rotor and does not affect the rotor creating a pulsating magnetizing field (or with a constant component) in the stator windings Damping currents blocked by diodes, etc.! 2. The method (option) of the electromechanical conversion of ferromagnetic energy, which consists in the fact that when the rotor rotates, the magnetic circuit is periodically closed, the magnetic circuit is opened (as in inductor or commutator generators), and the stator ferromagnetic cores are magnetized or demagnetized (part of the magnetic circuit) ), while the energy is removed only in the phase of demagnetization (without demagnetizing currents), and the braking moment creates only part of the ferromagnetic field of the stator cores, and in the useful electric energy converted nearly all (excluding losses) the energy of the ferromagnetic cores and the excitation system (permanent magnets or electromagnets) may be located on the stator-anchoring, and thus will rotate only

Claims (12)

1. The method (option) of the electromechanical conversion of ferromagnetic energy, which consists in the fact that when the rotor-inductor rotates, the ferromagnetic cores with windings located next to the rotor-inductor (through the air gap) are periodically magnetized and demagnetized; in this case, the energy is removed only in the demagnetization phase (during magnetization, the current does not go through the windings, it is blocked by diodes, thyristors, etc.), and almost all (except losses) is converted to the ferromagnetic energy of the stator cores, and the braking torque to the rotor inductor creates only an insignificant part of the stator ferromagnetic cores, since most of their field is closed outside the inductor rotor and does not affect the rotor creating a pulsating magnetizing field (or with a constant component) in the stator windings the currents are blocked by diodes, etc. 2. The method (option) of the electromechanical conversion of ferromagnetic energy, which consists in the fact that when the rotor rotates, the magnetic circuit is periodically closed, the magnetic circuit is opened (as in inductor or commutator generators), and the stator ferromagnetic cores are magnetized or demagnetized (part of the magnetic circuit) ), while the energy is removed only in the phase of demagnetization (without demagnetizing currents), and the braking moment creates only part of the ferromagnetic field of the stator cores, and in the useful electric energy It converted nearly all (excluding losses) the energy of the ferromagnetic cores and the excitation system (permanent magnets or electromagnets) may be located on the stator-anchoring, and thus will rotate only ferromagnetic soft magnetic insert, periodically closing the magnetic circuit. 3. The device (option) of the electromechanical conversion of ferromagnetic energy consists of a radially magnetized rotor-inductor (type “asterisk”) and radially arranged ferromagnetic stator cores around the rotor, in which a pulsating field (or with a constant component) is created when the rotor-inductor rotates, the ends of the ferromagnetic cores facing the rotor-inductor are either hidden or closed through ferromagnetic shunts, forming a magnetic circuit with a stator and rotor, the ferromagnetic cores They are separated from the rotor-inductor by sufficiently large air gaps for scattering the magnetic field of the stator cores and outside the rotor-inductor. 4. The device (option) of the electromechanical conversion of ferromagnetic energy consists of a disk rotor inductor with end excitation and an end arrangement of stator cores in the form of straight rods or U-shaped cores covering the rotor with the topology of the magnetic field system as in end generators, while the rotor the inductor may have a polarity parallel to the axis of the disk rotor-inductor or have a different polarity along the radius of the disk. 5. The device (option) of the electromechanical conversion of ferromagnetic energy consists of a disk rotor-inductor and ferromagnetic rods located parallel to the axis of the rotor and closed (through air gaps) with the ends opposite from the rotor-inductor to the shunt that closes the magnetic flux to the rotor. 6. The device (option) of the electromechanical conversion of ferromagnetic energy has axial excitation (the excitation winding is stationary) and consists of a double gear rotor-inductor and two coaxial rotors on a common shaft and stator cores located either between the rotors-inductors or adjacent to them, at This stator cores can be either straight or U-shaped. 7. The device (option) of the electromechanical conversion of ferromagnetic energy consists of a double rotor inductor with axial excitation (as in two-pack inductor generators) and a double gear stator or stator from separate rod ferromagnetic cores (or U-shaped cores). 8. The device (option) of the electromechanical conversion of ferromagnetic energy consists of a double rotor inductor with an axial axis from the permanent magnets and ferromagnetic core cores of the stator (or U-shaped cores) located around the axis of the rotor and adjacent to the rotor-inductor. 9. The device (option) of the electromechanical conversion of ferromagnetic energy consists of two U-shaped magnetic circuits, one of which is an inductor (fixed, with an excitation winding), and the other is an armature with a working winding, while the gear rotor-switch rotates between two П -shaped magnetic cores. 10. A device (option) for electromechanical conversion of ferromagnetic energy consists of two rotor inductors (on a common shaft) and a two-pack stator (as in two-pack inductor machines), in which, in order to increase the magnetic flux of scattering, the groove depth and the height of the teeth on the magnetic circuit are increased stator, as well as increased air gaps, while the stator can be composed of individual rods or U-shaped cores with windings. 11. The device (option) of the electromechanical conversion of ferromagnetic energy consists of a stationary inductor with axial excitation, in which a gear rotor-inductor, a magnetic circuit commutator (as in commutator-type inductor generators) rotate between the inductor and the gear two-package stator. 12. The device (option) of the electromechanical conversion of ferromagnetic energy, in which the inductor moves linearly, reciprocating relative to the ferromagnetic stator cores located at the ends of the inductor (through the air gaps).