A permanent magnet generator consisting of a stator including a pendulating master permanent magnet and a push button. The master permanent magnet is restricted in its oscillation. The master permanent magnet is oriented with a predetermined polarity towards a rotor. The rotor including a plurality of oscillating slave permanent magnets and an axel. The slave permanent magnets are equivalently spaced around an outer edge of said rotor. The slave permanent magnets are restricted in their oscillations and the slave permanent magnets are oriented with the predetermined polarity the outer edge of the rotor. When the push button is engaged, the master permanent magnet and a first of the plurality of the slave permanent magnet's magnetic fields come into contact and repel each other, driving a circular rotation of the rotor. When the circular rotation of the rotor aligns the master permanent magnet and the plurality of the slave permanent magnet's magnetic fields in sequence.

A permanent magnet generator consisting of a stator including a pendulating master permanent magnet and a push button. The master permanent magnet is restricted in its oscillation. The master permanent magnet is oriented with a predetermined polarity towards a rotor. The rotor including a plurality of oscillating slave permanent magnets and an axel. The slave permanent magnets are equivalently spaced around an outer edge of said rotor. The slave permanent magnets are restricted in their oscillations and the slave permanent magnets are oriented with the predetermined polarity the outer edge of the rotor. When the push button is engaged, the master permanent magnet and a first of the plurality of the slave permanent magnet's magnetic fields come into contact and repel each other, driving a circular rotation of the rotor. When the circular rotation of the rotor aligns the master permanent magnet and the plurality of the slave permanent magnet's magnetic fields in sequence.

An assembly for generating electricity includes a circular track configured to rotate about a first axis of rotation, the circular track comprising a first magnet having a face that is at an angle with respect to the first axis of rotation, a second magnet positioned at a center of the circular track, wherein a face of the second magnet is an opposite polarity to the face of the first magnet such that the second magnet repels the first magnet to rotate the circular track, and a device for converting rotational motion from the circular track into electricity.

An assembly for generating electricity includes a circular track configured to rotate about a first axis of rotation, the circular track comprising a first magnet having a face that is at an angle with respect to the first axis of rotation, a second magnet positioned at a center of the circular track, wherein a face of the second magnet is an opposite polarity to the face of the first magnet such that the second magnet repels the first magnet to rotate the circular track, and a device for converting rotational motion from the circular track into electricity.

A regenerative energy system comprises a power source driving a motor that rotates a drive gear about an axis, the drive gear rotating a driven gear about an axis. The drive and driven gears each comprise radially extending teeth projecting from respective gear peripheries, the teeth meshing when the drive gear drives the 5 driven gear. Permanent magnets are disposed in at least some of the drive and driven gear teeth such that the magnetic poles of the drive gear teeth repel the poles of the driven gear teeth. When magnetic repulsive forces between the drive and driven gear teeth are overcome, the drive gear and driven gear teeth can engage one another. A coil is located in proximity to the permanent magnets. The 0 coil can form part of a solenoid. Electrical current is generated in the coil by a movement of the permanent magnets relative to the coil.

A regenerative energy system comprises a power source driving a motor that rotates a drive gear about an axis, the drive gear rotating a driven gear about an axis. The drive and driven gears each comprise radially extending teeth projecting from respective gear peripheries, the teeth meshing when the drive gear drives the 5 driven gear. Permanent magnets are disposed in at least some of the drive and driven gear teeth such that the magnetic poles of the drive gear teeth repel the poles of the driven gear teeth. When magnetic repulsive forces between the drive and driven gear teeth are overcome, the drive gear and driven gear teeth can engage one another. A coil is located in proximity to the permanent magnets. The 0 coil can form part of a solenoid. Electrical current is generated in the coil by a movement of the permanent magnets relative to the coil.

A system and method for generating rotation of a body includes a rotating body configured to rotate about a rotation axis, at least one permanent flanking magnet and a bias object (or material non-uniformity) both arranged at least partially on or within the rotating body, and a drive or ring element. An axial gap between the ring element and the rotating body exists in an axial direction parallel to the rotation axis. The ring element may be a ferrous body, permanent magnet or electromagnet, and the bias object may be made from one or more materials of magnetic states, such as magnetic, ferromagnetic, paramagnetic, and diamagnetic or be a change in material properties of the rotating body. In some embodiments, a center of the ring element is not aligned with the rotation axis. Also, in some embodiments, the speed of, or rotational forces on, the rotating body may be adjusted by adjusting the axial gap or the magnetic field strength of the drive element and/or the flanking magnet(s) or by applying radial forces on the drive element. The rotating body may be connected to a shaft and drive an alternator to generate clean energy.

A system for providing dynamic force comprises a solar cell, an engine, a transmission module, two motors, two one-way fly wheels, and an electrical energy storage device. The solar cell is configured to drive the two motors. The transmission module comprises an input terminal and two output terminals. The input terminal of the transmission module is driven by the engine, and the output terminals of the transmission module are configured to drive the two motors respectively. The electrical energy storage device is configured to store electrical energy generated by the solar cell and drive the two motors. The two one-way fly wheels are driven by the two motors respectively.

A magnetic motor apparatus includes a motor housing, rotor element, rotatable urging elements and locking mechanism. The rotor element has an inner and outer rotor element, both including a plurality of permanent arc magnets arranged concentrically. The inner and outer rotor element are rotatable around an axis of rotation. The rotor element includes a plurality of shielding elements arranged in a third circle concentrically around the outer rotor element. An output shaft, rotatable with the rotor element, extends along the central axis of rotation and partly out the housing. The urging elements are arranged in a fourth circle concentrically around the rotor element. Each rotatable urging element includes a permanent magnet having poles, and is rotatable around a peripheral axis, such that each pole of the rotatable urging element in-use alternatingly faces the rotor element to impart an urging force. The locking mechanism controls rotation of the urging elements.

A device for generating power from an input power supply, wherein a net power is generated. The device includes multiple electromagnets arranged in a series to form a row. The row of electromagnets is encased in a tubular coil. Each of the electromagnets is electrically coupled to the controller such that the controller can power the electromagnets one by one in a predefined order at a predetermined switching frequency. A common magnetic field is generated from consecutive powering of the electromagnets based on the switching frequency, wherein changing common magnetic field causes inductance currents in the coil.