Abstract:
A self-powered generator disclosed here includes a stator member, a rotor member, a direct current motor, and an alternating current motor. The rotor member is configured to rotate within the stator member, and the direct current motor is coupled to a rotor shaft of the rotor member, where the direct current motor is configured to rotate the rotor member within the stator member via the rotor shaft to generate electricity. However, the direct current motor is shut off when a predetermined amount of electricity is generated, where a portion of the electricity generated is fed to an alternating current motor coupled to the rotor shaft, where the alternating current motor continuously drives the rotor member within the stator member in a closed loop arrangement to generate a continuous supply of electricity.
Abstract:
The electric rotating machine includes a rotatable rotor including first magnetic field parts and second magnetic field parts formed in front and rear surfaces, respectively, by arranging permanent magnets in a circumferential direction; a first stator equipped with coils opposing the first magnetic field parts disposed, the coils forming first stator magnetic fields; a second stator equipped with coils opposing the second magnetic field parts disposed, the coils forming second stator magnetic fields; and a power feeder for driving the rotor to rotate by supplying power to the coils, and a power collector for extracting an induced current generated in the coils of the other stator resulting from rotation of the rotor. At least the coils disposed on the power supply side are formed by a superconducting material, a current supplied to the superconducting coils being made larger than an induced current generated in the other coils.
Abstract:
The arrangement of an electric machine, a connecting system and a converter, includes the connecting system connected between the electric machine and the converter. The connecting system has an enclosure that houses non-shielded conductors each non-shielded conductor is connected between a phase of the electric machine and the inner side of the converter. The non-shielded conductors of the connecting system that are connected to an operating phase of the electric machine are adjacent to conductors of the connecting system that are not connected to operating phases of the electric machine.
Abstract:
Aspects and embodiments disclosed herein include a highly efficient electric motor which can be embodied in several configurations, including a standard motor, a hub motor, a linear motor, or other motor configuration. In one example, there is provided a motor comprising a rotor including a plurality of magnets and a stator including at least one coil module, the at least one coil module including a plurality of coils of conductive material, the plurality of coils arranged horizontally displaced to from one another and retained in a matrix material of the at least one coil module.
Abstract:
The present invention relates to an electrical generator (40) and an electricity generation system (10 or 11 or 12) incorporating the generator. The generator comprises a stationary part (42) and a movable part (43), one of which (43) is deployed with magnetising means and the other (42) with coil means, such that movement of the movable part relative to the stationary part induces electrical current flow in the coil, the stationary part and the movable part metamagnetically interact to increase the electrical current flow.
Abstract:
Two rotors (3,4) and one stator (2) are arranged coaxially. The stator (2) comprises a coil unit (6) which produces, by the supply of a first alternating current, the same number of rotating magnetic fields as the number of magnetic poles of said first rotor (3), and, by the supply of a second alternating current, the same number of rotating magnetic fields as the number of magnetic poles of said second rotor (4). A composite current of said first and second alternating currents is supplied to said coil unit (6), and a circuit (15) is provided for compensating torque fluctuation due to non-uniformity of the magnetic field accompanying the relative rotation of the two said rotors (3, 4).
Abstract:
In a power supply for use with electronic equipment, the power supply includes a dynamic transformer having a single rotary element with permanent magnets attached, magnetic bearings to support the rotary element during operation, primary and secondary windings linking the flux of the magnets, circuit means to drive the primary windings, and means of using the secondary AC output to provide DC power at the point of use.
Abstract:
A device for feeding electricity into a Faraday cage comprises an electrical generator (8), a generator drive motor (3), and a linkage (12, 24) for mechanically coupling the generator and the motor. The device is characterized in that it includes linkages (2, 12, 24) for electrically isolating the motor and the generator from each other, together with an electromagnetic screening element (7, 15; 20) surrounding the generator and connected to the Faraday cage, the screening element including at least one waveguide passage (14, 25) through which the mechanical coupler extends.
Abstract:
Disclosed is a frequency converter system for altering the frequency of a-c power supplied from a distribution network to a load, the system including a pair of mechanically coupled rotating alternating current machines, the alteration of the rate and direction of rotation of the prime mover altering the frequency of the power. A variable impedance network comprising saturable core reactors and connected in the rotor circuit of the prime mover is utilized to effect the change of rate and direction of prime mover rotation.