Excitation windings 2X, 2Y and a detection winding configured in a multipolar mode are disposed coaxially with a fixed body, a plurality of sets (M1, M2) of intermediate rotating windings M1 . . . configured by a pair of winding portions Mx1, My1 . . . configured by the multipolar mode and with predetermined electrical phases D made different are disposed coaxially with a rotating body, and the winding portions in the same phase (Mx1 and Mx2, My1 and My2) of the plural sets of the intermediate rotating windings M1, M2 are connected so as to form closed circuits H . . . , respectively.

A transformer that can easily cope with various input voltage specifications and that, has improved productivity is obtained. A transformer includes: a core portion for forming a magnetic circuit; and a primary-side winding and a secondary-side winding wound at the core portion. One or both of the primary-side winding and the secondary-side winding are divided into a plurality of division windings, and each of the plurality of the division windings of the at least one divided winding has a wound part wound at the core portion, and two extending members extending from both ends of the wound part. The extending members of the plurality of the division windings of the at least one divided winding are mutually connected, and a number of turns in the transformer of the at least one divided winding is set.

A reactor comprises a coil member and a core member. The coil member comprises an insulation-coated conductive wire and an insulation coating. The insulation-coated conductive wire is wound and coated, at least in part, with the insulation coating. The core member comprises a first member and a second member.

The first member has a relative permeability higher than another relative permeability of the second member. The second member includes a composite magnet, and the relative permeability of the second member is between 1 and 30 (both inclusive). The composite magnet is formed of a hardened binder and magnetic particles dispersed in the binder. The composite magnet has an elastic modulus that is one hundred times or more than another elastic modulus of the insulation coating.

A wireless charging coil is provided herein. More specifically, provided herein is a wireless charging coil comprising a first stamped coil having a first spiral trace, the first spiral trace defining a first space between windings, and a second stamped coil having a second spiral trace, the second spiral trace defining a second space between windings, the first stamped coil and second stamped coil in co-planar relation, the first stamped coil positioned within the second space of the second stamped coil, and the second stamped coil positioned within the first space of the first stamped coil, the first and second coils electronically connected and an adhesive covering and surrounding the first stamped coil and the second stamped coil to bond the coils together and to insulate the coils.

A coil structure includes a conductor band and a first insulating plate. The conductor band turns around a coil axis in such a manner that the conductor band folds at a plurality of portions which form a plurality of folded portions. The first insulating plate includes a first edge portion which abuts along at least one of the plurality of folded portions. At least part of the conductor band is wound around the first insulating plate.

A power control module and a method to create the power control module is provided. The power control module includes a plurality of transformers, wherein each transformer of the plurality of transformers includes a stack of ferrite cores comprising a plurality of ferrite cores and a continuous winding. The continuous winding has a plurality of turns through each ferrite core of the plurality of ferrite cores. The plurality of ferrite cores are oriented such that the plurality of ferrite cores are stacked together with legs of the plurality of ferrite cores oriented in opposite directions, and wherein the continuous winding comprises a folded section that extends between the plurality of ferrite cores of the stack of ferrite.

In some embodiments, the instant invention can provide an electrical system that includes: a three-phase inductor with a core, including: a first segment having a first coil arrangement; a second segment having a second coil arrangement; a third segment having a third coil arrangement; where each of the first coil arrangement, the second coil arrangement, and the third coil arrangement has at least one air duct; at least one air baffle; and where the at least one air baffle is configured to be operationally attached to at least one selected coil arrangement in a position which allows the at least one air baffle to extend from at least one surface of the at least one selected coil arrangement into a flow of a supplied air.

A server power transformer structure includes: a first iron core, a first projection being configured thereon; an axle body, in combination with the first projection, and configured with four copper foils and first spools, each copper foil, first spool being respectively put around the axle body, at least one first, second, third, fourth connection portion being extended from bottoms of the respective copper foils, and the first spool being sandwiched between each two adjacent copper foils; a second iron core, a second projection being configured thereon, a second spool being put around the second projection, and the second projection being in combination with the axle body; and a solder bar, having a combination portion, first and second through holes, the combination portion being in electric connection with a main board, the connection portions being inserted in and bonded with the respective through holes.

A coil module includes a coil conductor including a plurality of coil elements and a plurality of wire electrodes disposed on a circuit board, each of the plurality of coil elements including a pair of leg portions and a bridge portion connecting one end portions of the pair of leg portions together, the plurality of coil elements being disposed to cross a winding axis. A method for manufacturing the coil module includes an assembly forming step of integrating the plurality of coil elements with resin to form a coil element assembly, and a conductor forming step of mounting the coil element assembly on the circuit board to complete the coil conductor wound about the winding axis. In the conductor forming step, the resin is introduced into a die set in which the plurality of coil elements are arranged to form a block, to thus form the coil element assembly.

A power inductor includes a winding and a metal magnetic powder core. The metal magnetic powder core is configured to support the winding, and the winding uses a metal conductive sheet. During assembly, the metal magnetic powder core is integrated with the winding through pressing, the metal magnetic powder core wraps the winding, and the metal magnetic powder core is insulated from the winding. The winding has a first pin and a second pin, and the first pin and the second pin are exposed on different surfaces of the metal magnetic powder core. Pins are separately disposed on two different surfaces of the power inductor. In addition, the winding is formed by integrally pressing the metal conductive sheet and the metal magnetic powder core.