A propulsion system includes a cylindrical shaft member coupled to a motor with a motor frame; said shaft member mechanically coupled to a disc members with radius, to rotate in a dynamically and statically balanced state with said shaft when said motor rotates; the apparatus further comprising a power source to supply power to said motor to rotate said shaft member with said disc members; each said disc members comprising an annular radial array of material segments extending radially to the radius; said material segments comprising of a material that responds to electromagnetic fields to change shape radially on said disc member; such that when power is supplied to rotate the motor, the motor rotates the disc members and when each such material segment rotates to an angular location of the shaft member relative to a fixed point on the motor frame, each said material segment is supplied with said electromagnetic field; and said material responds to said electromagnetic field to change its shape radially to a new radius different from, at said angular location, and such that the mass of said material segment is redistributed radially at the radius R2 in said material segment in said angular location; and such that the difference in centripetal forces acting on said change in radial location from R1 to R2 at said angular location creates a radial force on said shaft member in the direction of the said angular location.

Apparatuses, systems, and methods of use for a magnetic coupling device is disclosed. The magnetic device may have a plurality of magnets to create a magnetic field to the devices enclosed within the device. The coupling device may have a housing that encloses and/or partially surrounds one or more rotatable shafts. The coupling device may couple an output shaft from a motor to an input shaft of a generator. The coupling device may have an electric coil that when energized may vary any applied magnetic field to the rotatable shafts. The magnetic device may have a first plurality of magnets positioned at a first radial position and a second plurality of magnets positioned at a second radial position, with the first magnets being rotatable and the second magnets being stationary. Multiple magnetic coupling devices may be coupled together in series to provide increased magnetic fields to the enclosed system.

Converting magnet repulsion/attraction force into continuous mechanical energy by simulating the meeting distance of two different magnet using a magnetic shield material. Design uses structure made up of non-magnetic material, inside the structure there is a piston made up of permanent magnet that moves up and down. Another permanent magnet is fitted on top of the structure, facing with same magnetic pole. In between the fixed magnet and moving magnet a layer is made up of magnetic shield material is used to block the magnet fields' passes between the magnets. The shield layer will open when the moving magnet about to move down using the crankshaft and very near to the fixed magnet, so that both magnets will repel each other and push the moving magnet away. When the moving magnet reaches the crankshaft repositioning position then the magnet shield layer on the top will close to block the magnetic fields, by doing this the moving magnet connected to the piston or connecting rod will moves up without facing any repulsive force and the cycle continues to produce continuous energy.

The magnetic attraction and repulsion device for driving axes in rotation is a system for producing motive force released through one or two coaxial outlets. The magnetic attraction and repulsion device includes a centrally positioned axis carrying one or various permanent magnets and at least one synchronization toothed gear to form the rotor. The system also consists of other peripheral axes around the rotor, each carrying at least one permanent magnet and at least one synchronization toothed gear. The transmission toothed gears are connected by meshing the synchronization toothed gears of the rotor and of the peripheral axes. All the axes should be in stainless steel. The continuous activity of the system is achieved by the fact that one or various magnetic poles of permanent magnets carried by the rotor axis is directed in alternation between two or four magnetic poles of permanent magnets carried by the peripheral axes.

This invention is a self-sustaining, primary source of electricity for residential use, electric vehicle (EV) integration for automated self-charging, and various mobile applications. An electric motor mechanically turns compactly arranged AC PM generator rotor shafts by the use of a belt and pulley system. The electrical output of the AC PM generators is stored in an external 48V primary battery system which, in turn, provides power to the electric motor. A programmable system controller monitors the state of charge of the 48V primary battery system and other electrical components and automatically powers or stops the electric motor according to programmed upper and lower limits. The programmable system controller monitors all functions of the generator system and performs necessary actions to perpetuate operation of the self-sustaining electricity generation system.

This invention is a self-sustaining, primary source of electricity for residential use, electric vehicle (EV) integration for automated self-charging, and various mobile applications. An electric motor mechanically turns compactly arranged AC PM generator rotor shafts by the use of a belt and pulley system. The electrical output of the AC PM generators is stored in an external 48V primary battery system which, in turn, provides power to the electric motor. A programmable system controller monitors the state of charge of the 48V primary battery system and other electrical components and automatically powers or stops the electric motor according to programmed upper and lower limits. The programmable system controller monitors all functions of the generator system and performs necessary actions to perpetuate operation of the self-sustaining electricity generation system.

Apparatuses, systems, and methods of use for a generator is disclosed. In one embodiment, the generator has a stator and a rotor and a first plurality of magnets coupled to the rotor and a second plurality of magnets coupled to the stator. An external magnetic housing may be coupled to an input shaft of the generator or surround the generator itself. A first layer of magnets produce a rotating magnetic field and a second layer of magnets create a static magnetic field, whether such magnets are in the generator itself or within an external magnetic housing. The disclosed generator increases the mechanical power inputted into the generator, which then produces an increased output of the generator.

An infinity electrical reactor system is described. Embodiments of the infinity electrical reactor system include, but are not limited to, a first electric motor, a friction motor, a second electric motor, a third electric motor, a converter, a step-up transformer, and a current multiplier. An axle can be implemented to operatively connect the first electric motor, the friction motor, the second electric motor, and the third electric motor.

An infinity electrical reactor system is described. Embodiments of the infinity electrical reactor system include, but are not limited to, a first electric motor, a friction motor, a second electric motor, a third electric motor, a converter, a step-up transformer, and a current multiplier. An axle can be implemented to operatively connect the first electric motor, the friction motor, the second electric motor, and the third electric motor.

An electrical generator is provided. The electrical generator can include a generator, an electric motor, and a battery. The generator has a rotatable shaft and stationary component and be operatively coupled via a drive belt to the motor, which provides torque to the rotatable shaft of the generator The battery is operatively coupled to the motor. The generator can be operatively coupled to a utility grid via a transformer/invertor that can import current from the utility grid to charge the battery when the utility grid is operating and export current from the generator to a grid connector when the utility grid is not operating.