An induction heating device includes: a rotor having a rotation shaft; a heating part disposed to be opposed to the rotor at a distance; a magnetic flux generating part provided at the rotor to generate magnetic flux for the heating part; a magnetic flux guide part provided on an opposed surface side of the heating part that is opposed to the magnetic flux generating part to guide the magnetic flux from the magnetic flux generating part to the heating part; and a flow passage provided in the heating part to allow a heating medium to circulate. The magnetic flux guide part includes magnetic substance parts. The magnetic flux guide part has a structure in which the magnetic substance parts and the insulator parts extend along a direction from the magnetic flux generating part to the heating part and are alternately layered along a circumferential direction of the heating part.

The disclosed heat generating apparatus includes: a rotary shaft, a heat generator, a plurality of permanent magnets, a magnet holder, and a heat recovery system. The rotary shaft is rotatably supported by a non-rotative body. The heat generator is fixed to the body. The magnets are arrayed to face the heat generator with a gap such that magnetic pole arrangements of adjacent ones of the magnets are opposite to each other. The magnet holder holds the magnets and is fixed to the rotary shaft. The heat recovery system collects heat generated in the heat generator. A non-magnetic partition wall is provided in the gap between the heat generator and the magnets.

The invention relates to a rotary induction heater with direct-current excitation for heating solid or liquid or gaseous substances. The alternating magnetic field required for induction or for generating inductive heat is generated with a direct-current coil having a constant magnetic field. The constant magnetic field is converted into an alternating magnetic field by way of a rotating mechanical component.

An induction heating device (1) comprising an electromagnetic coil (2) connectable to a power supply (3). The electromagnetic coil (2) comprises a coil protection insert (4). The coil protection insert (4) protrudes from a first side (5) of the coil (2) towards a surface (6) of a work piece (7) to be heated by the induction heating device (1) when the induction heating device (1) is used for heating the work piece (7). The coil protection insert (4) preventing contact between the coil (2) and the surface (6) of the work piece (7).

An apparatus for heating and impelling a fluid may comprise a housing, and an air heating impeller assembly positioned in the housing and configured to impel and heat the fluid moving through the housing. The air heating impeller assembly may comprise a support shaft, and a plurality of disks on the support shaft and spaced from each other to form fluid flow gaps therebetween. A disk may comprise a hub portion, an annular portion located radially outward from the hub portion, and a plurality of spoke portions connecting the annular and hub portions. The hub, annular and spoke portions of a disk may be formed of an integral part. A magnetic assembly may be configured to apply a magnetic field of adjustable intensity to the disks.

The disclosed heat generating apparatus includes: a rotary shaft, a heat generator, a plurality of permanent magnets, a magnet holder, and a heat recovery system. The rotary shaft is rotatably supported by a non-rotative body. The heat generator is fixed to the rotary shaft. The magnets are arrayed to face the heat generator with a gap such that magnetic pole arrangements of adjacent ones of the magnets are opposite to each other. The magnet holder holds the magnets and is fixed to the body. The heat recovery system collects heat generated in the heat generator.

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. A motor or input drive rotates the conductive components relative to the magnetic/electromagnetic plates, creating high frequency oscillating magnetic fields and thermally conditioning the fluid flow as it is communicated in succession through the first and second blower subassemblies and through the housing outlet.

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. The magnetic/electromagnetic plates include radially telescoping stem and seat portions for displacing the plates between extended positions which radially overlap with the conductive plates during a thermally conditioning mode thermal in which high frequency oscillating magnetic fields are conducted to the rotating component for outputting as a thermally conditioning fluid flow and inwardly retracted positions relative to the conductive plates during a non-thermally conditioning blower mode.

An anti-ice arrangement for a gas turbine engine may comprise an engine static structure, a fan blade housed for rotation within the engine static structure, and a magnetic field source mounted in close proximity to the fan blade and configured for inducing eddy currents in the fan blade to increase a surface temperature of the fan blade.

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.