A regenerative power supply system and method comprises a dynamo-electric generator, an electric drive motor coupled to the generator, a transmission device coupling the generator to the electric drive motor, and an energy storage device configured to provide a backup power supply to the regenerative power supply system. An electronic control device is configured to control a flow of electricity to the electric drive motor. An energy storage management device is configured to control a flow of electricity between the electronic control device and the energy storage device.

An electrically powered generator includes an electric motor as a power source having an output rotational speed of 5000 rpm, and a transmission mechanism driven by the electric motor to operate and having rotors and stators connected to a rear end thereof for producing and outputting induced electric energy. The rotors have a rotational speed ranged between 290 and 300 rpm. The transmission mechanism includes a drive shaft driven by the electric motor to rotate and in turn bringing a transmission shaft, an auxiliary power shaft and first and second power output shafts to rotate through power transmission. First and second flywheels are mounted on the drive shaft and the auxiliary power shaft, respectively, to store potential energy. At the time the electric motor stops rotating, the flywheels, due to the rotational inertia thereof, convert the stored potential energy into kinetic energy for the transmission mechanism to operate continuously.

An electrically powered generator includes an electric motor as a power source having an output rotational speed of 5000 rpm, and a transmission mechanism driven by the electric motor to operate and having rotors and stators connected to a rear end thereof for producing and outputting induced electric energy. The rotors have a rotational speed ranged between 290 and 300 rpm. The transmission mechanism includes a drive shaft driven by the electric motor to rotate and in turn bringing a transmission shaft, an auxiliary power shaft and first and second power output shafts to rotate through power transmission. First and second flywheels are mounted on the drive shaft and the auxiliary power shaft, respectively, to store potential energy. At the time the electric motor stops rotating, the flywheels, due to the rotational inertia thereof, convert the stored potential energy into kinetic energy for the transmission mechanism to operate continuously.

Disclosed are various embodiments for a new and improved electrical motor/generator, specifically a motor/generator comprising: a plurality of coils radially positioned about a coil assembly, a plurality of magnetic tunnels forming a relative rotational path for the coil assembly, wherein the all of plurality of magnets forming each magnetic tunnel have like poles facing inward toward the interior of the magnetic tunnel or facing outward away from the interior of the magnetic tunnel such that each magnetic field of any magnetic tunnel is of an opposite polarity to the magnetic field of an adjacent magnetic tunnel.

A magnetic power generator (10) includes at least one rotor assembly (12) that is positionable at selected angles relative to the horizontal. The rotor assembly includes a plurality of spokes (20) emanating from a central rotational axis (26), with high-performance magnetic coils (22) mounted on the outer end portions of the spokes. The rotor assembly (12) is drivingly connected to AC/DC generator (32), the output of which is routed to a power transfer switching unit (40) which outputs electricity as either AC or DC and at various desired voltages. A programmable system controller (24) controls the polarity of the magnetic coils (22) mounted on the ends of the spokes (20), as well as the operation of the generator (32) so as to power and constantly change the polarity of the magnetic coils as the rotor assembly rotates, thereby to cause the rotor assembly to rotate by virtue of interaction with the Earth's magnetic field.

A power control system includes a control unit, a motor, an electricity storing unit, and a generator set. The control unit includes a charging/driving controller and a load controller electrically connected to a load. The motor can be driven by electricity of the electricity storing unit. The generator set includes a revolving wheel which is driven by the motor for driving a driving power generator and an energy storage generator. The driving power generator provides electricity to the load. Electrical energy generated by the energy storage generator is used for charging the electricity storing unit. When the generator set breaks down, the electricity of the electricity storing unit is provided to the load through a control of the charging/driving controller. The power control system supplies sufficient electrical energy to the load under low energy consumption condition and has advantages of environment protection and fault alarm.

A power control system includes a control unit, a motor, an electricity storing unit, and a generator set. The control unit includes a charging/driving controller and a load controller electrically connected to a load. The motor can be driven by electricity of the electricity storing unit. The generator set includes a revolving wheel which is driven by the motor for driving a driving power generator and an energy storage generator. The driving power generator provides electricity to the load. Electrical energy generated by the energy storage generator is used for charging the electricity storing unit. When the generator set breaks down, the electricity of the electricity storing unit is provided to the load through a control of the charging/driving controller. The power control system supplies sufficient electrical energy to the load under low energy consumption condition and has advantages of environment protection and fault alarm.

Methods and systems for using the Earth's magnetic field to power a machine having a motor, the system including a computer, a plurality of wires, a plurality of energy storing devices, all in controlled electrical communication with each other, wherein the plurality of wires can collect electrical energy from the Earth's magnetic field while the machine is put in motion by a power source powering the motor, wherein the collected electrical energy is stored in the plurality of energy storing devices or used to power the motor.

A magnet assembly can include a base assembly and a cover assembly. The base assembly can extend along a longitudinal axis and include a base, a shaft, a first cylinder, and a first plurality of magnets. The cover assembly can extend along the longitudinal axis and include a cover, a second cylinder, and a second plurality of magnets. The base assembly and the cover assembly can be selectively engageable. The first plurality of magnets and the second plurality of magnets can be arranged such that the shaft is driven in rotation by magnetic repulsion of the first plurality of magnets relative to the second plurality of magnets when the base assembly and the cover assembly are engaged with one another. The second cylinder can be fixedly engaged with the cover.

A regenerative power supply system and method comprises a dynamo-electric generator, an electric drive motor coupled to the generator, a transmission device coupling the generator to the electric drive motor, and an energy storage device configured to provide a backup power supply to the regenerative power supply system. An electronic control device is configured to control a flow of electricity to the electric drive motor. An energy storage management device is configured to control a flow of electricity between the electronic control device and the energy storage device.