An electric motor is provided. The electric motor can include a first submotor that includes a first stator component and a first rotor component, one of the first stator component and the first rotor component including a plurality of first magnets, and the other of the first stator component and the first rotor component including a plurality of conductive first windings. The electric motor can include a second submotor that includes a second stator component and a second rotor component, one of the second stator component and the second rotor component including a plurality of second magnets, and the other of the second stator component and the second rotor component including a plurality of conductive second windings. At least one of the first windings can be electrically connected in series to at least one of the second windings.

A recharging electric generator system which generates electrical energy and recharges itself, and methods thereof. A recharging electric generator system comprises at least one inverting apparatus; at least one power source/storage device to start the system and store electrical energy; at least one switching device; at least one transformer unit to adjust the voltage of the electrical energy, at least one rectifying unit to convert a portion of the electrical energy from alternating current to direct current and to transfer electrical energy to recharge the at least one power source/storage device; and at least one power outlet/output terminal to distribute electrical energy for further use. A recharging electric generator system seeks to provide of renewable source of energy which could be applied to different sectors and is conducive to conditions in both developed and developing countries.

Device for handling a strip-shaped metal material in metal working, wherein the device comprises: at least one roller element, preferably a roller, a roll or a winch, which is provided for changing the cross-section, for transporting, storing, tension build-up and/or tension release in the strip-shaped metal material, and a drive, which has an electric motor, preferably a torque motor or a synchronous motor, with a stator and a rotor, wherein the device further has a frame, the rotor is connected to the roller element, by which the rotation of the rotor is transmitted to the roller element, and the stator is mounted directly on the frame and/or the rotor is connected directly to the roller element or a shaft of the roller element.

An electromagnetic rotary motor is an apparatus used to convert electrical energy into mechanical energy. The apparatus is also configured to utilize minimal electrical power input due to the arrangement of components and the cycle for energy conversion. The apparatus includes a drive shaft, an input terminal, an annular housing, a plurality of brushes, and a plurality of electromagnetic (EM) mechanisms. The drive shaft is a cylindrical extrusion that rotates about its axis. The input terminal is a connector which provides electrical potential to the plurality of brushes through the drive shaft. The annular housing is a ring-shaped enclosure that protects the components of the apparatus. The plurality of EM mechanisms is a set of electrical components that react to the influence of the plurality of brushes.

An electromagnetic rotary motor is an apparatus used to convert electrical energy into mechanical energy. The apparatus is also configured to utilize minimal electrical power input due to the arrangement of components and the cycle for energy conversion. The apparatus includes a drive shaft, an input terminal, an annular housing, a plurality of brushes, and a plurality of electromagnetic (EM) mechanisms. The drive shaft is a cylindrical extrusion that rotates about its axis. The input terminal is a connector which provides electrical potential to the plurality of brushes through the drive shaft. The annular housing is a ring-shaped enclosure that protects the components of the apparatus. The plurality of EM mechanisms is a set of electrical components that react to the influence of the plurality of brushes.

An electromagnetic rotary motor is an apparatus used to convert electrical energy into mechanical energy. The apparatus is also configured to utilize minimal electrical power input due to the arrangement of components and the cycle for energy conversion. The apparatus includes a drive shaft, an input terminal, an annular housing, a plurality of brushes, and a plurality of electromagnetic (EM) mechanisms. The drive shaft is a cylindrical extrusion that rotates about its axis. The input terminal is a connector which provides electrical potential to the plurality of brushes through the drive shaft. The annular housing is a ring-shaped enclosure that protects the components of the apparatus. The plurality of EM mechanisms is a set of electrical components that react to the influence of the plurality of brushes. The general configuration of the aforementioned components allows the apparatus to efficiently and effectively convert electrical energy into mechanical energy.

A low-energy-consumption and high-efficiency circulating electric motor that a fan and a circular cylinder-body are disposed on a rotating-shaft and a permanent magnet is disposed on at least one blade of the fan, and at least a permanent magnet is disposed in a frame; wherein the outer diameter surface of the circular cylinder-body is set with a continuous circumferential conductive portion, and a plurality of axial conductive portions are lined in interval and connected with the circumferential conductive portion; wherein a DC generator is connected with the rotating-shaft and a storage battery is electrically connected with a control unit, the DC generator, the circumferential conductive portion, and the DC electromagnet; at the same time, the DC electromagnet intermittently generates a magnetic force by orderly contacting and not contacting the axial conductive portions; and the fan is continuously rotated by the intermittent magnetic force interacting with the permanent magnet.

A magnetic kinetic propulsion motor apparatus and method includes a shaft with a first two ended rotational blade attached at a midpoint of the two ended rotational blade to the shaft. A proximity magnetic sensor is connected at both ends of the two ended rotational blade. A stationary housing surrounds the shaft and the first two ended rotational blade. Several self-aligning repulsion electro-magnets are connected to the stationary housing and a proximity switch is connected with each of the self-aligning repulsion electro-magnets. An electronic ignition distributor is connected to each proximity switch connected with the self-aligning repulsion electro-magnets and a battery is connected to the electronic ignition distributor. A generator is connected to the shaft, the electronic ignition distributor and the battery where in response to the proximity magnetic sensor on the ends of the first two ended rotational blade detecting a proximity switch connected with a self-aligning repulsion electro-magnet the electronic ignition distributer sends power to the self-aligning repulsion electro-magnet which generates repulsive magnetic force on the proximity magnetic sensor at the ends of the first two ended rotational blade.

The Electromagnetic Rotary Motor uses the pulling or pushing force created by electromagnets to rotate a shaft and create mechanical energy. There are two main components, the spindle and the track. The spindle is comprised of the main shaft, arms, and heads. The track is a ring with electromagnets and power transfer pads positioned along it. The spindle sits inside the track and rotates. When the heads of the spindle pass by the power transfer blocks, the electromagnet will turn on and pull the heads towards it. Then the electromagnet will turn off, allowing the head to stay on its path. This action happens every time a head aligns with an electromagnet, causing the spindle to rotate creating mechanical energy.

An electric motor apparatus that includes a disk with an increased mechanical advantage to the attached axle, with donut-shaped permanent magnets, windings, a fulcrum (A.K.A. axle), bearings, a commutator, and a single bearing conductor that replaces the brushes. The center axis consists of the windings and spools with the axis of the windings placed coradial in orbit around the fulcrum of a disk. The donut-shaped permanent magnets are cut with a slot to allow passage of the disk, spools, and windings. When windings of magnet wire are inserted with windings around the spools such that the center points of the faces of the spools are concentric to the same radius of the disk and pass through the center of a donut-shaped permanent magnet, and the windings are electrified with the correct polarity, the windings are repulsed magnetically in the direction of rotation of the orbit around the fulcrum (A.K.A. axle) causing the disk and axle to rotate. Upon completion of the fractional rotation, the original set of windings is deenergized and another set of windings is energized further rotating the disk and axle.