A coil component includes: a body including a support member including a through-hole and a via hole spaced apart from the through-hole, an internal coil supported by the support member and including a plurality of conductive units wound in one direction, and an encapsulant encapsulating the support member and the internal coil and filling the through-hole; and an external electrode disposed on an external surface of the body and connected to the internal coil.

A coil component includes: a body including a support member including a through-hole and a via hole spaced apart from the through-hole, an internal coil supported by the support member and including a plurality of conductive units wound in one direction, and an encapsulant encapsulating the support member and the internal coil and filling the through-hole; and an external electrode disposed on an external surface of the body and connected to the internal coil.

An inductive charging device for an electrically operated vehicle includes a housing, at least one induction coil and at least one magnetic conductor each arranged at least partially in the housing, and a supporting structure arranged at least partly in the housing. The housing includes a bottom and a cover. The support structure includes a first structure portion and a second structure portion. The second structure portion lies at least partly against a cover portion of the cover.

A packaged module and a metal plate. The packaged module may include a bearing structure, at least one metal strip, a circuit element, and a magnetic material. Further, a first surface of the bearing structure may bear the circuit element; two ends of each of the at least one metal strip may be coupled to the bearing structure, and a part of each metal strip other than the two ends is spaced apart from the bearing structure; and the magnetic material may cover a surface of a winding functional region of the at least one metal strip, where the winding functional region may be a part or all of the metal strip to which the winding functional region belongs. The foregoing solution helps simplify a packaging process and reduce losses and manufacturing costs of the packaged module.

A power conversion device such that heat dissipation of an electromagnetic induction instrument can be increased, and inductance value durability and vibration resistance of the electromagnetic induction instrument is high, is provided. Also, a power conversion device reduced in size and weight is provided. A power conversion device includes an electromagnetic induction instrument wherein an upper core and a lower core having magnetism are electromagnetically coupled across a coil body, a frame body on which the electromagnetic induction instrument is mounted, a potting resin member with which a space between the frame body and the electromagnetic induction instrument is filled, and a fixing member, disposed above the electromagnetic induction instrument so as to cover the upper core, of which an end portion is attached to the frame body, wherein the electromagnetic induction instrument is fixed to the frame body by the fixing member.

A method of fabricating a magnetic component structure with thermal conductive filler, including steps of providing a mold with a coil mounted therein, potting the mold with a thermal conductive material to form a thermal conductive filler encapsulating at least a portion of said coil, releasing the thermal conductive filler and the coil from the mold, and combining the thermal conductive filler with magnetic cores to form a magnetic component structure.

A method of fabricating a magnetic component structure with thermal conductive filler, including steps of providing a mold with a coil mounted therein, potting the mold with a thermal conductive material to form a thermal conductive filler encapsulating at least a portion of said coil, releasing the thermal conductive filler and the coil from the mold, and combining the thermal conductive filler with magnetic cores to form a magnetic component structure.

A magnetic component having a core of a high-permittivity material with one or more apertures extending between two opposite faces of the core and filled with a thermal conductors of a non-magnetic insulator material. Preferably, the apertures extending between a flat side of the core in contact with a metallic housing and the space where the windings are laid, providing a short and direct path for heat transfer. The thermal conductors may be alumina or any suitable material.

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.

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.