An inductor built-in substrate includes a core substrate having an opening and a first through hole, a first plating film formed in the first through hole of the core substrate, a magnetic resin body having a second through hole and including a magnetic resin filled in the opening of the core substrate, and a second plating film formed in the second through hole of the magnetic resin body such that the second plating film is formed in contact with the magnetic resin body.

Provided is an electro-magnetic compatibility (EMC) filter including a lower bobbin having a U-shaped cross-sectional shape, a lower core including a magnetic material having a U-shaped cross-sectional shape and disposed on the lower bobbin, a bus bar disposed on the lower core, an upper bobbin having a hollow inside, having a hexahedral shape with one side open, and configured to cover an upper portion of the lower bobbin, and an upper core including a magnetic material having a plate-like shape, disposed in an internal space of the upper bobbin, and disposed on the lower core (U core) to cover the bus bar with a gap maintained by the bus bar between the upper and lower cores when the lower bobbin and the upper bobbin are coupled to each other.

A ferrite core 10 includes a through hole 11 in which a wire 40 is arranged, and a holding portion 60 provided to hold the wire 40 in this through hole 11. The holding portion 60 may include a plurality of projections 61, 62 projecting from the inner peripheral surface of the through hole 11. Further, the plurality of projections 61, 62 are arranged at an interval in a length direction of the through hole 11 and at positions different in a circumferential direction of the through hole 11.

There is provided a noise filter. A noise filter according to the present disclosure includes: a non-divided type magnetic core in which a through-hole having a first opening and a second opening at respective ends of the through-hole is formed; a conductive coupling terminal including a first connection portion and a second connection portion at respective ends of the conductive coupling terminal, the first connection portion and the second connection portion being connectable to busbars, the conductive coupling terminal being disposed inside the through-hole; and a holding portion that holds the coupling terminal disposed inside the through-hole. The coupling terminal is held to the magnetic core by the holding portion in a state where the first connection portion faces the first opening from inside of the through-hole and the second connection portion faces the second opening from inside of the through-hole.

A method for manufacturing an inductor built-in substrate includes forming openings in a core substrate including a resin substrate and a metal foil laminated on the resin substrate, filling a magnetic resin in the openings formed in the substrate, forming a shield layer including a first plating film on the substrate and on a surface of the magnetic resin such that the shielding layer is formed on the metal foil and on the surface of the magnetic resin, forming first through holes in the substrate, applying a desmear treatment in the first through holes, forming second through holes in the magnetic resin after the desmear treatment, and forming a second plating film on the substrate, on the magnetic resin, and in the first and second through holes such that the second plating film is formed on the shield layer, in the first through holes, and in the second through holes.

A wire harness including: a wire; a cover that covers an outer circumference of a portion of the wire in a length direction thereof; an electromagnetic wave absorber mounted on an outer circumference of the cover; and a fixing member that fixes one end of the cover in a length direction thereof to the wire, wherein: the electromagnetic wave absorber includes a ring-shaped magnetic substance core, and a ring-shaped case in which the magnetic substance core is housed, the cover includes a first latch formed on an outer circumferential surface of the cover, and the case includes a second latch that latches to the first latch in the length direction of the cover.

An inductive device includes an insulating layer, a lower magnetic layer, and an upper magnetic layer that are formed such that the insulating layer does not separate the lower magnetic layer and the upper magnetic layer at the outer edges or wings of the inductive device. The lower magnetic layer and the upper magnetic layer form a continuous magnetic layer around the insulating layer and the conductors of the inductive device. Magnetic leakage paths are provided by forming openings through the upper magnetic layer. The openings may be formed through the upper magnetic layer by semiconductor processes that have relatively higher precision and accuracy compared to semiconductor processes for forming the insulating layer such as spin coating. This reduces magnetic leakage path variation within the inductive device and from inductive device to inductive device.

An inductor built-in substrate includes a core substrate having an opening, a magnetic resin body having a through hole and including a magnetic resin filled in the opening of the core substrate, and a plating film formed in the through hole of the magnetic resin body and including an electrolytic plating film such that the electrolytic plating film is formed in contact with the magnetic resin body.

Disclosed are designs for inductor cores for electromagnetic interference (EMI) filters. In some embodiments, an inductor core comprises a plurality of enclosed structures, where each enclosed structure of the plurality of enclosed structures includes a plurality of elongated bars and at least one connection device. In some embodiments, an enclosed structure is configured to encompass a signal bus. In some embodiments, an enclosed structure has a longitudinal axis and a triangular cross-sectional shape taken perpendicular to the longitudinal axis.

An inductive filtering device includes a magnetic core at least one electrical cable wound around the magnetic core so as to form at least one turn, the electrical cable being intended to convey an electrical signal possessing at least one undesirable AC component superposed on a fundamental frequency of the electrical signal, and an electrically conductive screen that is electrically insulated from its environment, the screen being placed between the magnetic core and the electrical cable so as to allow, in the screen, via electromagnetic induction, a current to be generated the frequency of which is higher than the fundamental frequency, the screen being configured so as not to allow a current to flow in a direction parallel to that of the one or more turns formed by the winding of the electrical cable around the magnetic core.