A reactor, comprising: a support; a coil wound on an outer surface of the support and including a plurality of coil segments electrically connected in sequence; and at least one first insulating separator disposed on the outer surface of the support and separating the outer surface of the support into a plurality of regions, in which the plurality of coil segments is respectively arranged.

A circuit structure includes: a circuit substrate provided with a conductive path and through holes that are electrically connected to the conductive path; a coil apparatus that includes coils 51 including terminal portions and a core made of a magnetic material; a heat dissipation member that includes a housing cavity that houses the coil apparatus, and on which the circuit substrate is laid; and grease that comes into contact with the inner surface of the housing cavity and the coil apparatus, and the terminal portions in the coil apparatus are inserted into the through holes and are soldered thereto.

A circuit structure includes: a circuit substrate provided with a conductive path and through holes that are electrically connected to the conductive path; a coil apparatus that includes coils 51 including terminal portions and a core made of a magnetic material; a heat dissipation member that includes a housing cavity that houses the coil apparatus, and on which the circuit substrate is laid; and grease that comes into contact with the inner surface of the housing cavity and the coil apparatus, and the terminal portions in the coil apparatus are inserted into the through holes and are soldered thereto.

A method of manufacturing a wireless power reception apparatus includes: forming a lower tray that includes a thermally conductive material and accommodates and fix a coil winding; arranging a coil winding on the lower tray; forming a magnetic field shielding plate so as to accommodate and fix a plurality of magnetic tiles at predetermined intervals; forming a coupled member of a magnetic tiles-magnetic field shielding plate by arranging the plurality of magnetic tiles at the predetermined intervals on the magnetic field shielding plate; forming a thermally conductive polymer molding layer by applying a thermally conductive polymer molding solution to fill spaces between the coil winding and the coupled member of a magnetic tiles-magnetic field shielding plate and bonding the plurality of magnetic tiles and the coil winding such that the plurality of magnetic tiles are positioned over the coil winding; and curing the thermally conductive polymer molding layer.

A reactor includes: a reactor main body including a core formed of a powder magnetic core, a resin member covering the circumference of the core, and a coil wound around the outer circumference of the resin member; a casing which includes a bottom surface and a side wall standing upright therefrom, and which houses therein the reactor main body; and a filler molding portion formed of a cured filler, and fastening the reactor main body to the casing. The resin member is provided with a bottom opening provided in an end surface that faces the bottom surface of the casing and exposing the core, and a back-side opening provided in an end surface orthogonal to the winding direction of the coil and facing the side wall, and exposing the core. The back-side opening is provided with exposing portions which is not covered with the filler molding portion and is exposed.

A reactor includes: a reactor main body including a core formed of a powder magnetic core, a resin member covering the circumference of the core, and a coil wound around the outer circumference of the resin member; a casing which includes a bottom surface and a side wall standing upright therefrom, and which houses therein the reactor main body; and a filler molding portion formed of a cured filler, and fastening the reactor main body to the casing. The resin member is provided with a bottom opening provided in an end surface that faces the bottom surface of the casing and exposing the core, and a back-side opening provided in an end surface orthogonal to the winding direction of the coil and facing the side wall, and exposing the core. The back-side opening is provided with exposing portions which is not covered with the filler molding portion and is exposed.

Embodiments of the present disclosure include an apparatus having a band including a high thermally conductive material is disposed at least partially around an inductor.

An inductive core including a body including a ferromagnetic material and a magnet, the magnet forming a first path for circulating of magnetic flux lines produced by the magnet, and the ferromagnetic material at least partially forming a second path for circulating the magnetic flux lines, wherein the ferromagnetic material extends continuously between the poles of the magnet along the poles of the magnet and makes contact with at least a part of an exterior lateral wall of the magnet extending between its poles.

An inductive core including a body including a ferromagnetic material and a magnet, the magnet forming a first path for circulating of magnetic flux lines produced by the magnet, and the ferromagnetic material at least partially forming a second path for circulating the magnetic flux lines, wherein the ferromagnetic material extends continuously between the poles of the magnet along the poles of the magnet and makes contact with at least a part of an exterior lateral wall of the magnet extending between its poles.

Assemblies having multi-functionalities of any combination of heat spreading, absorption of stray radiation, signal focusing, and shielding are provided. The assemblies may include a heat spreading layer of at least one sheet of a compressed particles of exfoliated graphite, graphitized polymers and combinations thereof. The assemblies may also include at least one magnetic layer, which may provide the benefits of magnetic flux management and/or stray radiation absorption. The assemblies may include an optional plastic coating on one or both of the exterior surfaces. The assemblies may be used to enable fast wireless charging of electronic devices by efficiently focusing magnetic flux for better power transmission efficiency.