A magnetic cylinder gear system includes an electric motor, a first cylindrical body, at least a first rectangular magnet, a second cylindrical body and at least a second rectangular magnet. The electric motor has a first rotatable drive shaft terminally and concentrically connected to the first cylindrical body. The first cylindrical body is positioned closely adjacent the second cylindrical body such that in an initial position a North polarity of the first rectangular magnet imparts magnetic attraction to a South polarity of the second rectangular magnet. In a rotated position, the South polarity of the first rectangular magnet imparts magnetic attraction to a North polarity of the second rectangular magnet such that a rotation of the first cylindrical body in a clockwise direction imparts a corresponding counter-clockwise rotation of the second cylindrical body, thereby driving the second cylindrical body without physical contact between the first cylindrical body and the second cylindrical body.

In some embodiments, the present invention may include, for example, systems, devices, and methods for power generation using a permanent magnet and/or an electro magnet installed on a twisted band wheel or wheels and/or installed on stationary discs and plates. Due to magnetic field forces for example between the stationary discs and the twisted band, the twisted band may be driven to move (e.g., rotate), rotation of the twisted band is optionally transferred by an axle to a generator.

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.

An engine includes an engine block with at least one cylinder bank including cylinder bores formed therein. A piston is reciprocatingly disposed in each of the cylinder bores. A crankshaft is rotatably mounted to the engine block. Connecting rods are rotatably attached to the crankshaft and are coupled to the piston. A cylinder head with intake valves and exhaust valves in fluid communication with the cylinder bores is mounted to each cylinder bank. At least one permanent magnet is disposed in a skirt of each piston. At least one electromagnet is positioned adjacent to the permanent magnet(s). A control system selectively provides an electrical current to the electromagnets to produce a desired magnetic field, wherein the magnetic field of the electromagnets cooperates with a magnetic field of the permanent magnets to affect a motion of the piston in respect of the engine block.

An engine includes an engine block with at least one cylinder bank including cylinder bores formed therein. A piston is reciprocatingly disposed in each of the cylinder bores. A crankshaft is rotatably mounted to the engine block. Connecting rods are rotatably attached to the crankshaft and are coupled to the piston. A cylinder head with intake valves and exhaust valves in fluid communication with the cylinder bores is mounted to each cylinder bank. At least one permanent magnet is disposed in a skirt of each piston. At least one electromagnet is positioned adjacent to the permanent magnet(s). A control system selectively provides an electrical current to the electromagnets to produce a desired magnetic field, wherein the magnetic field of the electromagnets cooperates with a magnetic field of the permanent magnets to affect a motion of the piston in respect of the engine block.

The present invention is directed to a power generation machine or device, comprising permanent magnets, a three-phase system, bifilar coils and a magnet arrangement disposed axially to the generator rotor; and comprising a system embedded by magnetic pulse control software for the moment of magnetic collapse or generation of electric power peaks or valleys, whereby a set of sensors detect the precise angular moment in which the coils have stored the maximum magnetic energy and then trigger their magnetic collapse or generation of electric power peaks or valleys by a switching process controlled by the signals coming from said sensors. All these elements are arranged in the rotor and circumferential stator, which generates electrical energy when moving.

An electric generator comprises a substantially flat magnet having a series of alternating north and south polarities, the magnet having an upper surface, a lower surface and opposing edges. A first metal plate formed on the upper surface of the magnet, and a second metal plate formed on the lower surface of the magnet. A pair of wires is connected to one of the first or second metal plates and an edge of the magnet, the pair of wires capturing for use energy or power produced by the electric generator.

Systems and methods for generating mechanical and/or electrical energy are presented. A system generates mechanical energy by using direct current to cause a plurality of rotors to rotate within and/or around a plurality of stators and generate electrical energy by using the rotation of the rotors within and/or around the stators to generate an electromagnetic field. Sensors provide information about the rotors and the stators to a control system which sends commands to alter various properties and conditions for the rotors and stators.

Systems and methods for generating mechanical and/or electrical energy are presented. A system generates mechanical energy by using direct current to cause a plurality of rotors to rotate within and/or around a plurality of stators and generate electrical energy by using the rotation of the rotors within and/or around the stators to generate an electromagnetic field. Sensors provide information about the rotors and the stators to a control system which sends commands to alter various properties and conditions for the rotors and stators.