Abstract: A rotational kinetic energy conversion system includes a magnetic piston with an associated winding and an actuating magnet. Relative motion between the actuating magnet and the magnetic piston causes the magnetic piston to induce a current and voltage in the winding creating electrical energy. The amount of electrical energy induced in the winding is varied by adjusting a spacing between the magnetic piston and the actuating magnet. The spacing may be based on a relative speed between the magnetic piston and the actuating magnet. Maximum energy output may be increased by including additional sets of magnetic pistons and actuating magnets. The spacing between each individual set of magnetic pistons and actuating magnets may be changed to control the energy output.

Abstract: A rotational kinetic energy conversion system includes a magnetic piston with an associated winding and an actuating magnet. Relative motion between the actuating magnet and the magnetic piston causes the magnetic piston to induce a current and voltage in the winding creating electrical energy. The amount of electrical energy induced in the winding is varied by adjusting a spacing between the magnetic piston and the actuating magnet. The spacing may be based on a relative speed between the magnetic piston and the actuating magnet. Maximum energy output may be increased by including additional sets of magnetic pistons and actuating magnets. The spacing between each individual set of magnetic pistons and actuating magnets may be changed to control the energy output.

Abstract: An energy conversion system for converting between one form of input energy selected from a mechanical energy and electrical energy, and an output energy selected from a mechanical energy and electrical energy using a linearly displaced magnetic component interacting with an orbitally displaced magnetic component.