The novelty here is that this SRE Electromagnet stand-alone unit (does not require an external source of energy to be set in motionfor continuous operation, or for continually producing surplus energy)utilizing the property of inertiathis invention makes this possible by the displacement of resistant power. By utilizing centrifugal force of One or more weighted spin-wheelsa (Single deep grove ball barring casings on each end)a reduction gearbox, or sprockets. (Capable of charging external batteries while also adequately recharging its own internal battery's energy)without the need of an outside external source of energy or fuel. The primary object novelty of the SRE invention is (self-reliant)(self-regenerating energy) for remote areas, home lights, electric cars, boats, est.

The present invention uses a traditional electrical motor with a rotor to generate electricity or power. By manipulating the magnetic fields within a rotor, large amounts of electricity are generated by the rotation of the rotor within an external magnetic field. Oppositely charged rare-earth magnets are placed around the rotor to create a strong magnetic field that the rotor can spin or rotate within. A battery or other power source supplies power to the rotor at positive and negative terminals (brushes) that are connected to commutator. The positive and negative terminals contact the commutator close to each other, such that only a few windings or coils are charged or magnetized, and the remaining windings or coils are free to generate electricity within the external magnetic field. The few coils that are charged in combination with the external magnetic fields create sufficient rotation, while enabling the remaining free coils to generate electric power. This power or electricity that is generated is then collected at a terminal about 150-200 degrees from the positive and negative terminals from the power source. The rotor may be offset or closer to one set of magnets, which further improves power generation.

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 demagnetizing member including the demagnetizing rotating board. 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 board has demagnetizing magnet parts, having magnetic forces weaker than the magnetic poles of the top pole surfaces a and different from the polarity of the top pole surfaces and the non-magnetic force parts.

The present disclosure is directed to several embodiments or variations of a power generation system. Several of these variations use the same power generators and also include one or more prime movers that supply mechanical power to the generators. In a first embodiment of the power generation system, two single drive through-shaft generators adapted to produce electric power are configured to be driven by a common prime mover. In a second, alternative embodiment of the power generation system, a plurality of generators is arranged into first and second generator groups. Each of the first and second generator groups is operably associated with an independent motor, which allows the power output to be controlled via adjustment to the applied power of the independent motors.

A motor with self power generation includes a motor body, at least one magnetic element, a shield case, an induction element, a transfer circuit board and a working module. The motor body includes a shaft member. The at least one magnetic element, located at the shaft member, is to generate a dynamic electromagnetic induction space while the shaft member rotates. The shield case, located close to the shaft member, is to shield the shaft member. The induction element, fixed at the shield case, has a portion located inside the dynamic electromagnetic induction space to generate an induction power while the shaft member rotates. The transfer circuit board has a transfer circuit electrically coupled with the induction element to receive the induction power to further generate a working power. The working module, electrically coupled with the transfer circuit, is to receive the working power to execute a default work.

The invention describes a metal container that comprises a cathode containing an insulated anode with gases at pressures less than a fraction (0.1-0.9) of a mmHg. Metallic normal glow discharge diode and triode devices with large cold cathode area as efficient charge generator to function as a power cell. A metallic glow discharge device comprising a cylindrical cathode and a coaxial insulated anode containing gas at very low pressure utilizing radial electric field. A metallic normal glow discharge diode device containing a planar geometry, with an insulated metallic plate parallel to the broad side of the container forms the anode, while the container acts as the cathode.

Systems and methods of generating, storing and/or distributing electric power are disclosed. The system may include two or more direct current battery subsystems, a direct current motor/alternating current generator combination, an electric power distribution network, and battery recharging elements. One battery subsystem may power an alternating current generator while the other battery subsystem charges using a portion of the generated power. Excess power may service other electric loads. The roles of the battery subsystems may be switched periodically between charging and powering, repeatedly. A gear box may connect the electric motor and generator to adjust the relative rotational speeds of each for optimal performance of the system.

According to an embodiment of the present disclosure, a generator using a flexible piezoelectric device comprises a tire with a hollow tube structure, a ring-shaped inner wall formed on an inner surface of the tire, a supporting frame connecting a center of the tire with in inner surface of the tire to support the inner wall, and a flexible piezoelectric device fastened or mounted on an overall outer surface of the inner wall. The flexible piezoelectric device is pressurized to generate electricity as the tire is compressed by contact with the ground and at space between the inner wall and the inner surface of the tire is thus reduced.

A magnetic windmill generator that provide a magnetic windmill generator that is adapted to create electricity from a renewable source using magnets. The magnetic windmill generator includes an armature having an attachment device, a pair of LED lights, a magnetic powered windmill and a pair of LED casings, a magnetic system having a casing, a plurality of copper spools, one or more stator magnets formed underneath the casing and one or more brushes and terminals positioned below the one or more stator magnets and a plurality of armature extensions extend downward from the magnet system adapted to contain one or more stacked output generators.

The invention describes a metal container that comprises a cathode containing an insulated anode with gases at pressures less than a fraction (0.1-0.9) of a mmHg. Metallic normal glow discharge diode and triode devices with large cold cathode area as efficient charge generator to function as a power cell. A metallic glow discharge device comprising a cylindrical cathode and a coaxial insulated anode containing gas at very low pressure utilizing radial electric field. A metallic normal glow discharge diode device containing a planar geometry, with an insulated metallic plate parallel to the broad side of the container forms the anode, while the container acts as the cathode.