A rotary power generating apparatus has the first, second piston magnet members, the crankshaft, the first, second guide members and the first, second fixed magnet members and the first, second demagnetizing belts. The first, second piston magnet members and the first, second fixed magnet members are arranged so that the top pole surfaces and fixed pole surfaces having equal polarity, oppose each other. The first, second demagnetizing belts have demagnetizing magnet parts, having magnetic forces weaker than that of the magnetic poles of the top pole surfaces and different from the polarity of the top pole surfaces, and non-magnetic force parts.

Obtaining of a secure reciprocation of piston magnets and enhance the continuity to obtain a continuous rotary power. The rotary power generating apparatus has the first, second piston magnet members, the crankshaft, the first, second guide members, and the first, second fixed magnet members and the first, second demagnetizing rotary drums respectively having the first, second demagnetizing cylindrical bodies. The first, second piston magnet members and the first, second fixed magnet members are arranged so that the top pole surfaces and fixed pole surfaces, having equal polarity, oppose each other. The first, second demagnetizing cylindrical bodies have demagnetizing magnet parts, having magnetic forces weaker than that of the magnetic poles of the top pole surfaces and different from the polarity of the top pole surfaces, and non-magnetic force parts.

An electricity generator includes a core having a pair of opposing end caps interconnected by a mid-section cooperating to define an interior chamber. In use, the core is held at a vacuum and filled with at least one inert gas. A frequency generator is attached for introducing and inputting electromagnetic waves into the interior chamber. A waveguide tube is provided to connect the frequency generator to the core, allowing for the passage of electromagnetic waves from the frequency generator into the interior chamber. In addition, a plurality of electrodes is provided which extend into the interior chamber to heat the inert gas and conduct the flow of electricity away from a lining on the interior chamber in order to produce steam. The electricity generator further includes at least one external steam generator system for converting the produced steam into energy.

A device for generating an electric charge, having: a base; at last one capacitor; at least one magnet; a cover; a splitter; a load; a conductive core; a frictionless surface; and at least one discharge point. The at least one capacitor adapted and configured to store electricity generated from the electric charge. The splitter is adapted and configured to receive a first portion of electricity from the conductive core and divert a second portion of electricity back to the at least one capacitor and further divert a third portion of electricity to the load. The load is adapted and configured to store electricity and use a fraction of the total electricity generated by the device. The at least one magnet is adapted and configured to levitate and rotate on an electromagnetic rail around said conductive core in an infinite loop, wherein said rotation causes a magnetic field.

The present invention relates to a power generation system using a vehicle. The power generation system includes: a vehicle, such as an automobile, a train, an airplane, and an escalator, for carrying people or freight; a movement route, such as a road, a railroad, and a runway, formed so that the vehicle can move thereon; and a power generation unit including a magnetic force generation portion and a magnetic force receiving portion alternatively installed in the vehicle and the movement route, and configured to generate electric energy using electromagnetic induction occurring due to relative movement between the magnetic force generation portion and the magnetic force receiving portion according to movement of the vehicle. The power generation system using a vehicle according to the present invention has a power generation device installed in the vehicle to generate power during travel of the vehicle and also has a power generation device installed on a movement route of the vehicle to generate power, so that electric energy generated by the power generation device of the vehicle can be used or stored as power required for the vehicle and electric energy generated by the power generation device installed on the movement route can be supplied to safety facilities for safe travel of vehicles on the movement route or convenient facilities near the road, or stored in additional batteries.

Methods and systems for using the Earth's magnetic field to power a machine having a motor, the system including a computer, a plurality of wires, a plurality of energy storing devices, all in controlled electrical communication with each other, wherein the plurality of wires can collect electrical energy from the Earth's magnetic field while the machine is put in motion by a power source powering the motor, wherein the collected electrical energy is stored in the plurality of energy storing devices or used to power the motor.

An electric fan-type power generating device includes a housing receiving an electric motor that is supplied electricity from a chargeable battery to drive a first fan and a second fan to rotate at high speeds to thereby generate wind power close to a third fan mounted to a first generator. The first fan uses the wind power to drive the third fan in the housing. The third fan drives the first generator to generate electricity that is supplied to the chargeable battery. The second fan uses the wind power in the housing to drive a fourth fan to rotate. The fourth fan drives the second generator to generate electricity that is supplied to the chargeable battery. The chargeable battery recycles the electricity that supports operation of the electric motor for generating wind power. Furthermore, the wind power drives the first and second generators to continue generating electricity.

Obtaining of a secure reciprocation of piston magnets and enhance the continuity to obtain a continuous rotary power. The rotary power generating apparatus has the first, second piston magnet members the first, second connecting rods the crankshaft, the first, second guide members and the first, second fixed magnet members and it has the first, second demagnetizing member including demagnetizing rotating boards respectively. The first, second piston magnet members and the first, second fixed magnet members are arranged so that the top pole surfaces and fixed pole surfaces, having the same polarity, opposes each other. The demagnetizing rotating boards has demagnetizing magnet parts, having magnetic forces weaker than the magnetic poles of the top pole surfaces and different from the polarity of the top pole surfaces and the non-magnetic force parts.

An electronic power cell memory back-up battery is disclosed. The electronic power cell memory back-up battery utilizes stored light photons to produce usable energy, and can be used to replace batteries or other power sources in electronic devices. The electronic power cell memory back-up battery disclosed includes a light source and a photovoltaic device in optical communication with the light source. The photovoltaic device creates electrical power in response to receiving light from the light source. A portion of the electrical power generated by the photovoltaic device is used to power the light source. In some embodiments power input contacts are included for use in providing initial start-up power to the light source. In some embodiments the light source comprises a light-emitting device and a photoluminescent material optically coupled to the light-emitting device, where the photoluminescent material emits light in response to receiving light from the light-emitting device.

An alternative energy generating apparatus is provided. The apparatus comprises a stationary metal coil or coils positioned by, above, below, or beside a magnet or a rotor of magnets with one or more imbedded magnets (e.g., rare earth magnets). Magnets may be imbedded along an outer part of a disc-like rotor. The one or more coils may be held in a coil plate apparatus, essentially parallel to the magnet rotor. The provided apparatus further comprises a shaft having a gear ratio for turning the rotor of magnets, such as by hand or by a motor in order to achieve a high turning velocity. The magnets generate an electromagnetic field, which when rotated against the stationary metal coils, produce an electric current.