A coil component according to one aspect is provided with a core containing a plurality of soft magnetic metal particles, a winding wire wound on the core, and a sheathing body provided on the core so as to cover at least part of the winding wire and having a relative magnetic permeability smaller than that of the core.

Described examples include a system in package (SIP) device, including: a first leadframe having a first surface and a second surface opposite the first surface; an integrated circuit die including solder bumps on a first surface and having a second opposite surface, the solder bumps mounted to the second surface of the first leadframe; a second leadframe having a first surface including a die pad portion, and a second opposite surface, the die pad portion attached to the second surface of the integrated circuit die; and an inductor mounted to the first surface of the first leadframe, the inductor having terminals with exterior portions electrically connected and mechanically connected to the first surface of the first leadframe, the inductor terminals spaced from one another by a portion of an inductor body, the portion of the inductor body between the inductor terminals spaced from the first surface of the first leadframe by a gap of at least 100 ms.

A coil component includes: a body portion; and a coil portion disposed in the body portion, wherein the coil portion includes a support member and a first coil layer disposed on a first surface of the support member, the first coil layer including a first electrode portion led out to a first end surface of the body portion, the support member includes first and second insulators and a metal core disposed between the first and second insulators, and a first end portion of the metal core is led out to the first end surface of the body portion to which the first electrode portion of the first coil layer is led.

A coil component includes: a body portion; and a coil portion disposed in the body portion, wherein the coil portion includes a support member and a first coil layer disposed on a first surface of the support member, the first coil layer including a first electrode portion led out to a first end surface of the body portion, the support member includes first and second insulators and a metal core disposed between the first and second insulators, and a first end portion of the metal core is led out to the first end surface of the body portion to which the first electrode portion of the first coil layer is led.

A coil and an energy conversion device are provided. The coil includes an enameled wire wound, and wherein the enameled wire includes a conductor portion, the conductor portion is made of materials including a base material and at least one of graphene and carbon nanotubes. A percentage of the base material in the materials is in a range of 70% to 99.8%, a percentage of the graphene in the materials is in a range of 0.2% to 30%, and a percentage of the carbon nanotubes in the materials is in a range of 0.2% to 30%. In this way, it is possible to simultaneously improve the conductivity and fatigue resistance characteristics of the enameled wire.

Magnetic nanowire components may be used in passive radio-frequency device allowing for smaller size devices, lower power consumption, and on-chip packaging potential across a wide range of technologies. A method for fabricating magnetic nanowire component electronic devices include depositing a conductive device pattern and transmission lines onto a substrate, aligning and securing a magnetic nanowire component to the device pattern, packaging the device with an insulation layer. Alternatively, the conductive device pattern and transmission lines may be deposited on the magnetic nanowire component, and the magnetic nanowire component may then be attached to a substrate.

A wireless power receiving apparatus which wirelessly charges power according to one embodiment of the present invention includes a substrate, a soft magnetic layer which is laminated on the substrate and is formed with a plurality of patterns including at least 3 lines radiated from predetermined points, and a coil which is laminated on the soft magnetic layer and receives electromagnetic energy radiated from a wireless power transmitting apparatus.

A wireless power receiving apparatus which wirelessly charges power according to one embodiment of the present invention includes a substrate, a soft magnetic layer which is laminated on the substrate and is formed with a plurality of patterns including at least 3 lines radiated from predetermined points, and a coil which is laminated on the soft magnetic layer and receives electromagnetic energy radiated from a wireless power transmitting apparatus.

A coil component includes a body including a coil including lead portions at both ends thereof and a magnetic material sealing the coil and external electrodes disposed on outer surfaces of the body and connected to the lead portions, respectively. An outer surface of the coil including at least one of an upper surface, a lower surface, and a side surface of the coil includes a surface area increasing portion.

A coil component includes a body including a coil including lead portions at both ends thereof and a magnetic material sealing the coil and external electrodes disposed on outer surfaces of the body and connected to the lead portions, respectively. An outer surface of the coil including at least one of an upper surface, a lower surface, and a side surface of the coil includes a surface area increasing portion.