A coil component includes a non-conductive bobbin and a coil that winds around the bobbin. The coil includes first and second coil members with joining portions in which joining holes are formed. The bobbin includes first and second bobbin members. The first bobbin member includes: first and second positioning portions that position the first and second coil members, respectively, when the first and second coil members are moved onto the first bobbin member; and a support that supports lower portions of the first and second joining portions. The second bobbin member includes a first insulator disposed between the first and second coil members. The first and second coil members and the second bobbin member are attached to the first bobbin member by being moved in a single direction without a further step of rotating.

A coil includes a resin substrate, a first coil structure formed on a first surface of the resin substrate, a second coil structure formed on a second surface of the resin substrate on the opposite side with respect to the first surface such that the second coil structure is formed at a position corresponding to the first coil structure, a third coil structure formed on the second surface such that the third coil structure is positioned adjacent to the second coil structure, and a fourth coil structure formed on the first surface such that the fourth coil structure is formed at a position corresponding to the third coil structure. The resin substrate is folded such that the second coil structure and the third coil structure oppose each other.

A coil assembly of a stator of a planar multi-dimensional drive includes at least one coil. The at least one coil includes a winding. The winding is electrically conductive and has a winding material. The winding is a structure of the winding material, which is folded at folding points and which has one or more windings.

A coil has multiple coil sections connected to each other and each coil section includes a body portion and at least one direct or protrusive connecting portion disposed at one end of the body portion. Coil sections form at least one spiral path around the central axis of the coil, and on the projection of the coil along the central axis. The protrusive connecting portions protrude out of the path location of the direct connecting portions. Two connected coil sections form only one overlapped surface at the coupled parts of the direct or protrusive connecting portions. Regarding to the body portions in the same spiral path, a first end of one body portion is indirectly connected and disposed adjacent to a second end of another body portion. The second end has one surface with a virtual extension reaching the first end.

A method of forming a coil for an inductive component includes bending a conductor into a figure 8 configuration. The figure 8 configuration has opposite first and second ends, a first substantially rounded portion, and a second substantially rounded portion. Each of the first and second substantially rounded portions terminates at one of the first and second ends. The method further includes folding the figure 8 configuration so the first substantially rounded portion overlies the second substantially rounded portion. Other example methods of forming coils for inductive components and other example coils are also disclosed.

A transformer includes: a first coil section formed by coiling a conductor pattern in a planar state around an insertion hole provided on a circuit board; a second coil section that includes a first ring composed of a coil formed by coiling a conductor plate, the coil being covered with an electric-insulating resin, a second ring composed of a coil formed by coiling a conductor plate, the coil covered with the electric-insulating resin, and a coupled part formed by covering a coupled position between the first ring and the second ring with the electric-insulating resin; and core sections forming a closed magnetic circuit that magnetically couples the first coil section and the second coil section.

A current conductor structure with a frequency-dependent resistance. The current conductor structure comprises a first current conductor and a second current conductor connected in parallel. The first and second current conductor are configured such that the second current conductor has a higher resistance and a lower inductance than the first conductor so that, above a set frequency limit, the resistance component of a total impedance of the current conductor structure is larger than the resistance component of the impedance of the first conductor current.

An integrated copper bar for a secondary power circuit of a power electronic converter, including a transformer primary winding copper bar, a transformer secondary winding copper bar, an inductor winding copper bar, a copper bar for connecting a detection resistor, a copper bar for connecting a drive circuit and a copper bar for connecting an output terminal; wherein, said transformer primary winding copper bar, said transformer secondary winding copper bar, said inductor winding copper bar, said copper bar for connecting a detection resistor, said copper bar for connecting a drive circuit and said copper bar for connecting an output ground terminal are fixed together via injection molding.

A power converter for a power system includes an input ceramic layer, an output ceramic layer, an input stage coupled to the input ceramic layer, an output stage coupled to the output ceramic layer, and a planar transformer coupled between said input stage and said output stage. The input receives a power input and the output stage generates a power output at least partially as a function of the power input. The planar transformer includes an input winding coupled to the input stage and an output winding coupled to the output stage. The input winding has a plurality of input turns and the output winding has a plurality of output turns. The input turns interleave the output turns.

A coil has multiple coil sections connected to each other and each coil section includes a body portion and at least one direct or protrusive connecting portion disposed at one end of the body portion. Coil sections form at least one spiral path around the central axis of the coil, and on the projection of the coil along the central axis. The protrusive connecting portions protrude out of the path location of the direct connecting portions. Two connected coil sections form only one overlapped surface at the coupled parts of the direct or protrusive connecting portions. Regarding to the body portions in the same spiral path, a first end of one body portion is indirectly connected and disposed adjacent to a second end of another body portion. The second end has one surface with a virtual extension reaching the first end.