A repulsive force conversion drive system for centrifugal force conversion to drive a load. A operational load to be driven by movement and provide external power due to movement of the operational load. A rotary repulsive force conversion drive connected to the operational load, such that the operational load moves in a first linear direction due to centrifugal force of rotating mass of the rotary repulsive force conversion drive. A linear repulsive force conversion drive connected to the operational load, the linear repulsive force conversion drive connected to the operational load such that the operational load moves is a second linear direction that is opposite the first linear direction on command from the linear repulsive force conversion drive.

An oscillating pendulum-based power generation mechanism of a power generator includes a stator device and a rotor device. The stator device has a stationary base and multiple first magnetic bars mounted on an inner annular surface of the stationary base. The rotor device has a spindle, multiple pendulum assemblies and multiple second magnetic bars. The spindle is rotatably mounted through the stationary base and is connected with a shaft of the power generator. Each pendulum assembly is connected with the spindle and includes a weight. The second magnetic bars are distributed across the weights of the multiple pendulum assemblies and are identically oblique to the weights and repel the first magnetic bars. The repellant forces between the first magnetic bars and the second magnetic bars allow the pendulum assemblies to be rotated to drive the power generator for power generation.

The present invention uses a traditional electrical motor with a rotor to generate electricity or power. By manipulating the magnetic fields within a rotor, large amounts of electricity are generated by the rotation of the rotor within an external magnetic field. Oppositely charged rare-earth magnets are placed around the rotor to create a strong magnetic field that the rotor can spin or rotate within. A battery or other power source supplies power to the rotor at positive and negative terminals (brushes) that are connected to commutator. The positive and negative terminals contact the commutator close to each other, such that only a few windings or coils are charged or magnetized, and the remaining windings or coils are free to generate electricity within the external magnetic field. The few coils that are charged in combination with the external magnetic fields create sufficient rotation, while enabling the remaining free coils to generate electric power. This power or electricity that is generated is then collected at a terminal about 150-200 degrees from the positive and negative terminals from the power source. The rotor may be offset or closer to one set of magnets, which further improves power generation.

Society today is heavily dependent on electricity for everyday life. There are many different types of electrical generators. The present invention uses the concept of a conventional swing to produce electricity. On a conventional swing, humans are the prime movers, keeping the swing in motion by body movements and pumping the legs. The present invention produces rotation in a generator by operating a prime mover that mimics these human movements on a conventional swing. In the present invention, a mechanized prime Mover, in human form, takes the place of a person's body movements to keep the swing in motion.

A motor includes a frame, a shaft rotatably mounted onto the frame, and at least one disc mounted onto the shaft. At least one permanent magnet is mounted on the disc, and at least one electromagnet and at least one coil are mounted to the frame in rotational magnetic proximity to the permanent magnet. A battery is connectable to the electromagnet and the coil for energizing the electromagnet and for receiving electrical current from the coil for charging the battery. A relay switch controls the transmission of electrical power from the battery to the electromagnet. A sensor generates a signal to the relay switch to activate electrical power to the electromagnet upon sensing that the permanent magnet is positioned with respect to the electromagnet such that a magnetic force generated by the electromagnet would be effective for inducing movement of the permanent magnet and consequent rotation of the disc.

An electric generator includes an electric generating device and a driving device. The electric generating device includes a supporting frame, and an electric generating mechanism including a transmission shaft rotatably mounted to the supporting frame, a wire tray unit disposed around the transmission shaft, and a magnetic plate unit including a magnetic plate body co-rotatably sleeved on the transmission shaft and multiple magnets mounted to the magnetic plate body. The wire tray unit generates an electric power induced by relative rotation of the wire tray unit and the magnets. The driving device is connected to the transmission shaft, and is driven by a part of the electric power to drive rotation of the transmission shaft.

A magnetic piston assembly that includes: a piston sleeve; a magnetic head adapted to engage the piston sleeve, where the magnetic head includes a first polarity; a mechanism to apply a second polarity to the magnetic head, where said mechanism to apply causes movement of the piston sleeve and magnetic head within a chamber; and an opening at the bottom of the piston sleeve, where said opening is adapted to engage a connecting rod.

A magnetic motor includes a rotor and a stator, in which there are magnets and materials of high magnetic permeability. The stator magnets are arranged with surfaces facing the rotor magnets in a staggered arrangement. The motor may be used to boost torque, for example in bicycles.

A gravity-lever-actuated rotating engine which emulates a perpetual motion machine by appearing to produce more energy than is required to power the engine. The gravity-lever-actuated rotating engine produces energy by utilizing a combination of forces, such as gravity, centrifugal force, and air pressure, causing a lever arm featuring shifting weights to rotate about an axis. Accordingly, the gravity-lever-actuated rotating engine appears to produce more energy than is required to power the engine due to the utilization of a combination of natural forces, such as gravity and centrifugal force.

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.