An inductor includes a core containing magnetic powder and a conductor embedded in the core. The core includes a mounting surface facing a mounting substrate side at the time of mounting, a pair of end surfaces orthogonal to the mounting surface, a pair of side surfaces orthogonal to the mounting surface and the pair of end surfaces. The conductor has a plate shape and includes a conductive wire portion extending inside the core over the end surfaces and a pair of electrode portions provided at both end portions of the conductive wire portion and extending from the end surface of the core to the mounting surface. The conductive wire portion includes a belt-shaped flat plate portion. One surface of the electrode portion facing the core is embedded in the core, and the other surface of the electrode portion facing the one surface is exposed from the core.

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.

A coil device includes a first conductor, a second conductor, and a core. The second conductor is disposed inside the first conductor and at least partly extending along the first conductor. The core internally arranges the first conductor and the second conductor. An insulating layer is formed at least between the first conductor and the second conductor.

A transformer structure comprising a winding stand, a first coil, two second coils, and an iron core set. The first coil winds on the winding portion of the winding stand, and the first coil connects to the first pins electrically. The second coils are two metal sheets having electrical conductivity, the two second coils are provided with a ring body and two second pins respectively, the two second coils being arranged on the side edge of the winding portion of the winding stand. The iron core set is arranged on the winding stand, and the iron core set passes internally through the first coil and the two second coils. As a result, the DC resistance is decreased and the power consumption is reduced accordingly, improving the temperature rising problem.

An electro-magnetic device is provided, including a first winding set of nested windings, and a second winding set of nested windings positioned adjacent to the first winding set. A method of making an electro-magnetic device including a first winding set of nested windings, and a second winding set of nested windings positioned adjacent to the first winding set is also provided.

An electromagnetic component includes a magnetic core and a dual-winding arrangement inside the magnetic core structure. The dual-winding arrangement includes a first winding fabricated from an elongated conductor having a first thickness and defining a first inverted U-shaped main winding portion including out of plane axial bends, and a second winding fabricated from a conductor having a second thickness and being formed into a second inverted U-shaped main winding portion with perpendicular sections extending co-planar to one another without any out of plane axial bends.

An electrical component includes a ferromagnetic core with a first and a second leg; a primary winding with a first primary winding portion arranged around the first leg of the ferromagnetic core and a second primary winding portion arranged around the second leg of the ferromagnetic core; wherein the first primary winding portion and the second primary winding portion each include parallel connectable conductors arranged around the ferromagnetic core in a cross section with the conductors being radially displaced with respect to each other at radial row positions, wherein the number of conductors of the first primary winding portion is equal the number of conductors of the second primary winding portion.

An inductor includes a magnetic core, a first winding, a first electrically conductive standoff, and a second electrically conductive standoff. The magnetic core includes opposing first and second outer surfaces separated from each other in a first direction. The first winding has first and second ends, and the first winding is wound around at least a portion of the magnetic core. The first electrically conductive standoff is connected to the first end of the first winding, and the first electrically conductive standoff extends along the magnetic core in the first direction from the first outer surface to the second outer surface. The second electrically conductive standoff is connected to the second end of the first winding, and the second electrically conductive standoff extends along the magnetic core in the first direction from the first outer surface to the second outer surface.

The power conversion device in which a transformer, a first rectifier element, a second rectifier element, a smoothing coil, and a smoothing capacitor are placed on a base, the transformer including a secondary winding including a first secondary winding and a second secondary winding, and an intermediate terminal at which to connect the secondary winding and the base, the smoothing coil including a smoothing coil first terminal and a smoothing coil second terminal, the smoothing capacitor being connected to the smoothing coil second terminal and the intermediate terminal, another end side of the first secondary winding and another end side of the second secondary winding being connected to each other at a connection portion, the connection portion being located between the first terminal and the second terminal, and the first terminal or the second terminal being located between the intermediate terminal and the connection portion.

An inductance element includes a magnetic core and a coil having a portion embedded in the magnetic core. This portion includes a wound portion formed by winging a wire-shaped coil material including a wire-shaped conductive material and an insulating coating. The insulating coating includes a thin-walled portion reduced in thickness. A biting ratio R is defined by formula: R=ds/B, which is from 0.4 to 0.85 inclusive, where B is the average thickness of inter-coil insulating coatings, and ds is an upper biting limit obtained by measuring a biting depth, approximating a frequency distribution of the results by a normal distribution, and computing, as the upper biting limit, the sum of the mean da of the normal distribution and the product of 3.99 and the standard deviation σ. The biting depth is obtained by subtracting, from the average thickness B, the thickness of the thin-walled portion.