A magnetic motor comprising a rotating flywheel coupled to rotate a drive output shaft within a support cage. Multiple permanent magnets extend directionally from the flywheel. Pairs of positionally fixed electro-magnets extend from the cage effacing platforms for sequential selective magnetic interaction with permanent magnets rotatable driving the flywheel and the drive output shaft.

Permanent magnet motor having a drive shaft connected to a power generator. At least a first power unit and a second power unit are arranged about the drive shaft, mutually delimited within the longitudinal axis of the drive shaft by a shielding plate. Each power unit exhibits a first rotary disc and a second rotary disc, mutually inclined with respect to the longitudinal axis of the drive shaft. A stator plate is arranged between the first and second rotary disc and exhibits a pull track along its periphery, and a push track on diametral opposite side of the rotary disk. At least six permanent magnet pairs having a pull magnet and a push magnet are arranged at an equal mutual distance along respective attachment circles at the same radial distance from the drive shaft as the pull track and the push track, respectively.

Permanent magnet motor having a drive shaft connected to a power generator. At least a first power unit and a second power unit are arranged about the drive shaft, mutually delimited within the longitudinal axis of the drive shaft by a shielding plate. Each power unit exhibits a first rotary disc and a second rotary disc, mutually inclined with respect to the longitudinal axis of the drive shaft. A stator plate is arranged between the first and second rotary disc and exhibits a pull track along its periphery, and a push track on diametral opposite side of the rotary disk. At least six permanent magnet pairs having a pull magnet and a push magnet are arranged at an equal mutual distance along respective attachment circles at the same radial distance from the drive shaft as the pull track and the push track, respectively.

An electromagnetic power generator device and a method thereof for using balanced electromagnetic forces to drive one or more flywheel rotor assemblies and one or more magnetic enahcement assemblies on a fixed shaft and generating large amount of electrical power are provided. The electromagnetic power generator device includes a non-rotating shaft attached to a support frame, at least one flywheel rotor assembly, and at least one input driver plate assembly which is coupled to the flywheel rotor assembly via the non-rotating shaft penetrating through a first centered hole of a bearing of the flywheel assembly and a second centered hole of the input driver plate assembly.

An electromagnetic power generator device and a method thereof for using balanced electromagnetic forces to drive one or more flywheel rotor assemblies and one or more magnetic enahcement assemblies on a fixed shaft and generating large amount of electrical power are provided. The electromagnetic power generator device includes a non-rotating shaft attached to a support frame, at least one flywheel rotor assembly, and at least one input driver plate assembly which is coupled to the flywheel rotor assembly via the non-rotating shaft penetrating through a first centered hole of a bearing of the flywheel assembly and a second centered hole of the input driver plate assembly.

A magnets-based generator is disclosed that comprises a stagnant-magnet anchored to a chassis; a wandering-magnet that is designated to be propelled from a first position to a second position and vice versa; an E-magnet and a J-magnet disposed adjacent to one end of the wandering-magnet; and at least one pair of buffers disposed between the stagnant-magnet and another end of the wandering-magnet. The wandering-magnet moves from the first position to the second position by joining the E-magnet and the J-magnet together and splitting the pair of buffers apart, and it moves from the second position to the first position by splitting the E-magnet and the J-magnet apart and joining the pair of buffers together. The generator further comprises an energy converter adapted to generate electrical energy from movements of the wandering-magnet from the first position to the second position and vice versa.

A novel magnetic engine, multifunctional, movable, customizable, convertible, scalable; housed magnetic engine; comprising of an interior offset magnetic rings mounted at the optimal distance and angle, with facing poles for the inner and outer rings to force constant flow, creating a forceful spin onto the drive shaft holding the magnetic plates into the housing; enveloped in a magnetic shielding, a glide mechanism will be used to extract the inner rings from the housing to stop the engine when needed, offering a flexible use and adaptation for need. Novel flexibility to be used as a home generator or to power anything needing constant motion with the desire of reduction in other energy sources, limitless applications in adaptation, scalable design also increases the flexibility in the use.

A novel magnetic engine, multifunctional, movable, customizable, convertible, scalable; housed magnetic engine; comprising of an interior offset magnetic rings mounted at the optimal distance and angle, with facing poles for the inner and outer rings to force constant flow, creating a forceful spin onto the drive shaft holding the magnetic plates into the housing; enveloped in a magnetic shielding, a glide mechanism will be used to extract the inner rings from the housing to stop the engine when needed, offering a flexible use and adaptation for need. Novel flexibility to be used as a home generator or to power anything needing constant motion with the desire of reduction in other energy sources, limitless applications in adaptation, scalable design also increases the flexibility in the use.

A system in a water body uses buoyant force of gaseous Hydrogen and Oxygen to generate electrical power with one or more turbines that includes power resulting from the buoyant force while transporting the Hydrogen or Oxygen to a higher elevation, without loss of electrons, for conversion to electricity at the higher elevation. Conversion of Hydrogen and Oxygen to water through a Hydrogen Fuel Cell or by burning at the higher elevation may generate additional steam power, hydropower, or purified water. Portable submersible modules may transport the system below or above the water to and from the base of a plumbing portion of the system. The amount of gaseous fuel energy available at the higher elevation is not detrimentally impacted by the generation of electricity by the turbine.

A system in a water body uses buoyant force of gaseous Hydrogen and Oxygen to generate electrical power with one or more turbines that includes power resulting from the buoyant force while transporting the Hydrogen or Oxygen to a higher elevation, without loss of electrons, for conversion to electricity at the higher elevation. Conversion of Hydrogen and Oxygen to water through a Hydrogen Fuel Cell or by burning at the higher elevation may generate additional steam power, hydropower, or purified water. Portable submersible modules may transport the system below or above the water to and from the base of a plumbing portion of the system. The amount of gaseous fuel energy available at the higher elevation is not detrimentally impacted by the generation of electricity by the turbine.