An apparatus including an alternator, wherein said alternator is configured to generate power. A shaft coupler for connecting a rotor to said alternator. At least one or more permanent magnets attached to said rotor. At least one or more electromagnets disposed in a close proximity to said at least one or more permanent magnets. A first feedback loop configured to carry said generated power to said at least one or more electromagnets. A second connection from the said feedback loop configured to carry said generated power to an external connection. A battery configured to provide startup power. And, a start power regulator configured to control said startup power supplied from said battery to said alternator and said electromagnets.

A self-powered generator disclosed here includes a stator member, a rotor member, a direct current motor, and an alternating current motor. The rotor member is configured to rotate within the stator member, and the direct current motor is coupled to a rotor shaft of the rotor member, where the direct current motor is configured to rotate the rotor member within the stator member via the rotor shaft to generate electricity. However, the direct current motor is shut off when a predetermined amount of electricity is generated, where a portion of the electricity generated is fed to an alternating current motor coupled to the rotor shaft, where the alternating current motor continuously drives the rotor member within the stator member in a closed loop arrangement to generate a continuous supply of electricity.

A wind turbine panel is configured to distribute electricity to a load. The wind turbine panel includes a frame further comprising a first slot having a first slot first end and a first slot second end. A first alternator is located in a first alternator mount on the first slot first end. A second alternator is located in a second alternator mount on the first slot second end. A wind turbine is connected to the first alternator and the second alternator via a first alternator shaft and a second alternator shaft, respectively. The first alternator and the second alternator are electrically coupled to an electrical outlet point on the frame. Wind traveling through the frame rotates the wind turbine, impels the alternator shafts to generate electricity which is then transferred to an electrical outlet point and further to an electrical panel for use in a plurality of downstream applications.

A power transmission assembly includes a base, a rotating frame rotatably coupled to the base and configured to rotate about an axis, an output shaft coupled to the rotating frame, a weight selectively repositionable relative to the rotating frame, and a weight actuator configured to reposition the weight relative to the rotating frame to move the weight from a subtraction position located at a first height to an addition position located at a second height. The second height is greater than the first height such that a gravitational force on the weight drives the rotating frame to rotate about the axis and drive the output shaft.

Provided is a power generation device using magnetic force, the power generation device comprising: a plurality of tunnel-type bodies having unilateral open passages and arranged and fixed at the same intervals on a revolutional orbit, wherein the respective tunnel-type bodies are provided with a plurality of permanent magnets between inner magnetic bodies and outer magnetic bodies, and permanent magnets and the outer magnetic bodies are attached to the outer surface of the inner magnetic bodies such that the permanent magnets facing the inner and outer magnetic bodies can have opposite polarities, thereby forming magnetic fields in inner body spaces; and magnetic border membranes having opposite magnetic poles on the inner and outer sides thereof and formed on entrance sides and exit sides of the tunnel-type bodies.

Provided is a power generation device using magnetic force, the power generation device comprising: a plurality of tunnel-type bodies having unilateral open passages and arranged and fixed at the same intervals on a revolutional orbit, wherein the respective tunnel-type bodies are provided with a plurality of permanent magnets between inner magnetic bodies and outer magnetic bodies, and permanent magnets and the outer magnetic bodies are attached to the outer surface of the inner magnetic bodies such that the permanent magnets facing the inner and outer magnetic bodies can have opposite polarities, thereby forming magnetic fields in inner body spaces; and magnetic border membranes having opposite magnetic poles on the inner and outer sides thereof and formed on entrance sides and exit sides of the tunnel-type bodies.

A self-generating power generation system is a generating system that is designed to use a portion of the incoming power to generate additional power to make the system highly efficient. The system may be used in a motor vehicle and take advantage of the available kinetic energy of the turning wheels regenerate power to multiply the efficiency. The system uses two batteries, a brushless dc motor, a generator, gearing, relays, switches, a regulator, a diode, and a controller.

An electric motor with a movable permanent magnet stator is disclosed. The electric motor includes a rotor with an armature having a plurality of windings about the armature. A plurality of stator magnets are disposed about the rotor. The plurality of stator magnets a selectively positionable between a proximal position, in close proximity to the rotor, and a distal position, away from the rotor. An actuator is coupled to the plurality of stator magnets, the actuator operable to position the plurality of stator magnets between the proximal position and the distal position. The output of the electric motor is controlled by moving the stator magnets towards and away from rotor, rather than applying varying amounts of electricity to the rotor.

An improved hybrid magnetic engine/generator apparatus and method includes a shaft. A pair of oppositely positioned ferrous metal arms is connected to the shaft where the ferrous metal arms include a first end and a second end. Wire is wrapped in non-overlapping fashion around the ferrous metal arms and the wire includes a positive power connection and a negative power connection. A power source is connected with positive power connection and the negative power connection. A stacking magnet is located at the second end of the ferrous metal arms and an opposing magnet is located opposite from and in proximity to the first end of both of the oppositely positioned ferrous metal arms. A device for selectively connecting with the power source is provided such that the wire is intermittently charged such that polarity at the first end of the ferrous metal arms is intermittently changed.

The invention relates to a magnetic generator (1) comprising at least one rotary drive means (2) having an axle associated with an actuator system, the actuator system comprising at least one induction rotor (5) associated with the axle of the rotary drive means (2), the induction rotor (5) comprising magnetic inductor structures (6), the induction rotor (5) being associated with at least one induced rotor (7) comprising induced magnetic structures (8) configured so as to cooperate with the inductive magnetic structures (6) so that the inductive magnetic structures (6) driven by the induction rotor (5) cause the induced structures (7) and the induced rotor (6) to rotate, said induced rotor (6) being associated with an electric power generation means (9).