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An energy producing magnetic converter is provided that outputs both electrical and mechanical energy. The converter includes a controller assembly rotatably secured between a plurality of field coil assemblies and a plurality of magnets. During a rotation of the controller assembly between the plur

An energy producing magnetic converter is provided that outputs both electrical and mechanical energy. The converter includes a controller assembly rotatably secured between a plurality of field coil assemblies and a plurality of magnets. During a rotation of the controller assembly between the plurality of field coil assemblies and the plurality of magnets, electric current is generated in wire coils of the field coil assemblies, and counter-magnetic fields are induced around the wire coils. A pole of each counter-magnetic field is formed on the controller assembly, and counterforce present between magnetic fields of the plurality of magnets and the counter-magnetic fields cause and maintain forward rotational motion in the energy producing magnetic converter. Accordingly, because the forward rotational motion is maintained in the presence of sufficient counterforce, the magnetic converter outputs torque in addition to the electric current, thereby increasing an efficiency of the magnetic converter.

대표청구항 ▼

What is claimed is: 1. An energy producing magnetic converter, comprising: a housing; a plurality of field coil assemblies disposed on a first surface of the housing; a plurality of magnets disposed on a second surface of the housing opposite of and aligned with the plurality of field coil assembli

What is claimed is: 1. An energy producing magnetic converter, comprising: a housing; a plurality of field coil assemblies disposed on a first surface of the housing; a plurality of magnets disposed on a second surface of the housing opposite of and aligned with the plurality of field coil assemblies; and a controller assembly rotatably secured to the housing and positioned between the plurality of field coil assemblies and the plurality of magnets, wherein, upon application of an electric load to the plurality of field coil assemblies, a rotation of the controller assembly relative to the plurality of field coil assemblies and the plurality of magnets induces at least one counter-magnetic field for generating an electric current. 2. The energy producing magnetic converter of claim 1, the housing comprising: a plurality of housing brackets; a first plate secured to and supported by the plurality of housing brackets; and a second plate secured to and supported by the plurality of housing brackets, wherein, the plurality of field coil assemblies is disposed on the first plate, and the plurality of magnets is disposed on the second plate. 3. The energy producing magnetic converter of claim 1, wherein each of the plurality of magnets is a substantially horse-shoe shaped permanent magnet. 4. The energy producing magnetic converter of claim 1, wherein each magnet of the plurality of magnets is aligned with a corresponding field coil assembly of the plurality of field coil assemblies and is separated from the corresponding field coil assembly by a spacing interval. 5. The energy producing magnetic converter of claim 4, the controller assembly comprising: a controller plate; and a plurality of controllers disposed along a perimeter of the controller plate, wherein each of the plurality of controllers is arranged to pass through the spacing interval. 6. The energy producing magnetic converter of claim 5, each of the plurality of controllers comprising: a first spacer having a first surface secured to the controller plate; a first magnetic section having a first surface secured to a second surface of the first spacer; a second spacer having a first surface secured to a second surface of the first magnetic section; and a second magnetic section secured to a second surface of the second spacer. 7. The energy producing magnetic converter of claim 6, wherein upper and lower surfaces of the first and second magnetic sections are formed in a substantially trapezoidal shape. 8. The energy producing magnetic converter of claim 6, wherein the first and second magnetic sections are formed from steel. 9. The energy producing magnetic converter of claim 6, wherein the first and second spacers are formed from a non-magnetic material. 10. The energy producing magnetic converter of claim 9, wherein the first and second spacers are formed of one selected from brass, aluminum, and hard plastic. 11. The energy producing magnetic converter of claim 6, each of the plurality of field coil assemblies comprising: a wire coil; and support brackets disposed on opposing faces of the wire coil, wherein the support brackets are secured to the first surface of the housing. 12. The energy producing magnetic converter of claim 11, wherein, during the rotation of the controller assembly, each of the controllers is arranged to pass through the spacing interval between each magnet and the corresponding field coil assembly, and the first and second magnetic sections of each of the controllers are arranged to pass across respectively first and second legs of each magnet and to pass outboard a perimeter of the wire coil of the corresponding field coil assembly. 13. The energy producing magnetic converter of claim 11, wherein, during the rotation of the controller assembly, each of the controllers is arranged to pass through the spacing interval between each magnet and the corresponding field coil assembly, and the first spacer of each of the controllers is arranged to pass outboard of each magnet and the corresponding field coil assembly, and the second spacer of each of the controllers is arranged to pass across the wire coil of the corresponding field coil assembly. 14. A magnetic converter system, comprising: a plurality of field coil assemblies; a plurality of magnets, each magnet of the plurality of magnets being positioned opposite of and separated from a corresponding field coil assembly of the plurality of field coil assemblies by a spacing interval; a controller assembly having a plurality of controllers, each controller of the plurality of controllers being arranged to pass through the spacing interval between each magnet and the corresponding field coil assembly; and wherein, during a rotation of the controller assembly, a plurality of counter-magnetic fields generated substantially on the plurality of controllers as the plurality of controllers pass through the spacing interval between each magnet and the corresponding field coil assembly generates sufficient counterforce to provide and maintain forward rotational motion to the controller assembly, and wherein the maintaining of the forward rotational motion generates an output torque of the magnetic converter system. 15. The magnetic converter system of claim 14, wherein a drive shaft having a pulley is disposed along a centrally defined axis of the controller assembly, and wherein the output torque is drawn from the drive shaft using the pulley. 16. The magnetic converter system of claim 14, each of the plurality of controllers comprising: a first spacer; a second spacer; a first magnetic section secured between the first spacer and the second spacer; and a second magnetic section secured outboard of the second spacer, wherein the first spacer and the second spacer are formed from a non-magnetic material. 17. The magnetic converter system of claim 16, wherein upper and lower surfaces of the first and second magnetic sections are formed in a substantially trapezoidal shape. 18. The magnetic converter system of claim 14, wherein a number of controllers in the plurality of controllers is greater than a number of field coil assemblies included in the plurality of field coil assemblies and a number of magnets included in the plurality of magnets. 19. The magnetic converter system of claim 14, wherein, during the rotation of the controller assembly, each controller of the plurality controllers is separated from each magnet by a first separation space and from the corresponding field coil assembly by a second separation space as the controller passes through the spacing interval. 20. A method for generating usable electrical energy and usable mechanical energy of a magnetic converter, comprising: rotating a plurality of controllers secured to a controller plate of the magnetic converter between a field coil assembly and an opposing magnet of the magnetic converter; utilizing a counter-magnetic field generated on each controller of the plurality of controllers to produce sufficient counterforce to maintain forward rotational motion of the controller plate and the plurality of controllers; wherein maintaining forward rotational motion of the controller plate and the plurality of controllers generates usable mechanical energy of the magnetic converter, and wherein application of an electric load to the field coil assembly generates usable electrical energy of the magnetic converter.