Abstract: An electromagnetic induction heating or cooling system including a housing having a fluid air inlet, a sleeve shaped support extending within the housing and including a plurality of spaced apart and radially extending magnetic or electromagnetic plates communicated with the inlet. An elongated conductive component is rotatably supported about the sleeve support and includes linearly spaced apart and radially projecting conductive plates which alternate with the spacing established by the magnetic or electromagnetic plates. A motor rotates the conductive component which, upon rotation of the conductive plates, generates magnetic fields to condition the fluid according to either of induction heating or cooling. The rotating plates of the conductive component are further individually configured so that they simultaneously redirect the conditioned fluid flow through a warm air outlet of the housing.

Abstract: A multi-stage fluid conditioning system having a housing with a fluid inlet and outlet. A shaft extends within the housing and supports a first fan unit with a first magnet/electromagnet plate on an inlet side of said housing and a second fan unit with a second magnet/electromagnet supporting plate on an outlet side of the housing. Each of the first and second magnet/electromagnet supporting plates include at least one vane configured to direct fluid flow. The shaft rotates the plates in order to draw a fluid flow through the inlet and successively across the inlet and outlet sides for thermal conditioning resulting from creation of high frequency oscillating magnetic fields according to a succeeding conditioning operations before being outputted the conditioned fluid from the housing through the fluid outlet.

Abstract: A magnet/electromagnet thermal conditioning blower system including a housing having a fluid inlet. A sleeve shaped support extends within the housing, a plurality of spaced apart magnetic/electromagnetic plates being communicated with the inlet, such that the plates extend radially from said sleeve support. A conductive component is rotatably supported about the sleeve support, the conductive component incorporating a plurality of linearly spaced apart and radially projecting conductive plates which alternate with the axially spaced and radially supported magnetic plates.

Abstract: A magnet blower thermal conditioning system having a housing, a first blower subassembly in communication with a housing inlet for receiving an inlet fluid flow and a second blower subassembly in communication with the first blower subassembly as well as a housing outlet. Each of the blower subassemblies includes a sleeve shaped support, a plurality of spaced apart magnetic or electromagnetic plates extending radially from the sleeve supports. Conductive components are rotatably supported about the sleeve shaped supports, each incorporating a plurality of linearly spaced and radially projecting conductive plates which alternate with the pluralities of spaced and radially supported magnetic or electromagnetic plates.

Abstract: A fluid thermal conditioning (heating/cooling) system including a housing containing a fluid holding tank and having an inlet pipe and an outlet pipe. A drive shaft rotatably supports either of a conductive plate or a plurality of spaced apart magnetic or electromagnetic plates positioned within the housing. The conductive plate can be reconfigured as an elongated conductive component supported within the housing and including a plurality of individual plates which alternate in arrangement with axially spaced and radially supported magnetic/electromagnetic plates. Upon rotation of the shaft, an oscillating magnetic field is generated for thermally conditioning the fluid.

Abstract: A fluid conditioning assembly having a body constructed of an insulating material. An inner housing is configured within the body defining a spiral passageway in communication with an inlet for redirecting a fluid flow through an outlet. A shaft extends within the body and rotatably supports a conductive and fluid redirecting plate or like component positioned within the inner housing. At least one magnet or electromagnet is positioned within the inner housing in proximity to the rotating component, causing thermal conditioning of the fluid flow resulting from creation of high frequency oscillating magnetic fields at a given frequency range, the thermally conditioned fluid flow being redirected through the outlet. Additional features include the ability to generate electricity in a cogeneration application of the assembly. Conventional elements can also be incorporated into the assembly for operating simultaneously or being deactivated/turned off after an initial startup period.

Abstract: An electromagnetic induction system for providing either heating or cooling. A sleeve shaped component extends within the housing and supports a plurality of spaced apart and radially extending electro-magnetic plates. An elongated conductive component is rotatably supported about the sleeve support and incorporates a plurality of linearly spaced apart and radially projecting conductive plates which alternate with the electro-magnetic plates. A motor rotates the conductive component such that rotation of the conductive plates results in the creation of an oscillating magnetic field for conditioning of the fluid by either heating or cooling of the fluid. A controller adjusts an intensity of the magnetic fields to adjust a level of conditioning of the fluid flow which is communicated via the conductive component through an outlet of the housing.

Abstract: An electromagnetic induction heating or cooling system including a housing having a fluid air inlet, a sleeve shaped support extending within the housing and including a plurality of spaced apart and radially extending magnetic or electromagnetic plates communicated with the inlet. An elongated conductive component is rotatably supported about the sleeve support and includes linearly spaced apart and radially projecting conductive plates which alternate with the spacing established by the magnetic or electromagnetic plates. A motor rotates the conductive component which, upon rotation of the conductive plates, generates magnetic fields to condition the fluid according to either of induction heating or cooling. The rotating plates of the conductive component are further individually configured so that they simultaneously redirect the conditioned fluid flow through a warm air outlet of the housing.