A device may include a coupled inductor structure comprising a first winding portion, a second winding portion, and a magnetic core structure. The magnetic core structure may include a first and second core piece that are at least partially cross-sectionally U-shaped. A first connecting core piece may be attached to a first portion of the first core piece to a first portion of the second core piece, and a second connecting core piece may attach a second portion of the first core piece to a second portion of the second core piece.

A packaged module and a metal plate. The packaged module may include a bearing structure, at least one metal strip, a circuit element, and a magnetic material. Further, a first surface of the bearing structure may bear the circuit element; two ends of each of the at least one metal strip may be coupled to the bearing structure, and a part of each metal strip other than the two ends is spaced apart from the bearing structure; and the magnetic material may cover a surface of a winding functional region of the at least one metal strip, where the winding functional region may be a part or all of the metal strip to which the winding functional region belongs. The foregoing solution helps simplify a packaging process and reduce losses and manufacturing costs of the packaged module.

A coil component including a first conductive plate part formed with a first coil pattern having a first opening, and a second conductive plate part formed with a second coil pattern having a second opening and disposed at a predetermined interval in the laminating direction with respect to the first conductive plate part. The first conductive plate part and the second conductive plate part are made of the same single plate and are integrally formed by a bent joining segment.

A winding body and method to avoid short-circuiting due to contact between conductors, and to suppress occurrence of structural defects such as cracks. A continuous thin band is folded at a folding site and wound helically. The folding site has a cutout portion, and folding at the folding site so that a conductor portion overlap another conductor portion causes the cutout portion to be formed into a recessed portion having a larger space than a gap between the conductor portions. A part of the conductor inside the folding site can be stowed in the recessed portion. The continuous thin band has a thickness desirably equal to or less than twice a skin depth with respect to a driving frequency of a coil component.

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 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 structure includes a first winding portion and a second winding portion disposed so as to overlap each other with winding axes substantially parallel to each other. The first winding portion and the second winding portion have regions overlapping each other when viewed from a winding axis direction. The second winding portion has a rising portion extending in a cross section perpendicular to a direction of a current flowing through a conductor constituting the winding portion with a directional component away from the first winding portion included.

A coil module includes a first coil set and a second coil set. The first coil set has an isolation frame. The second coil set has an open first winding body. The first winding body has two ends which are out of contact with each other. One of the two ends has a first conductive portion projecting from the first winding body. The other one of the two ends has a connecting end from which an open second winding body is integratedly outward extended. A terminal of the second winding body has a second conductive portion which is outward protrudent. The connecting end comprises a bent portion which makes the second winding body and the first winding body arranged in the same direction so that the second winding body and the first winding body are attached on two opposite sides of the isolation frame.

A laminated coil and manufacturing method therefor are disclosed. The laminated coil comprises multiple lamination units formed after a base body is folded. The lamination unit comprises an opening, a first common edge, and a second common edge; opening directions of two adjacent lamination units are opposite; the lamination unit is separately jointed with two adjacent lamination units by means of the first common edge and the second common edge, so that the base body in a laminated state forms a spiral power-on path. The base body is sequentially folded to form multiple lamination units, so that the base body in the laminated state forms the spiral power-on path to improve energy efficiency of a rectangular coil. In addition, on the basis of the laminated coil structure, the manufacturing method provided is adopted, and high precision of laminated coil can be highly efficiently manufactured.

A coupled inductor structure includes a first three-dimensional inductor structure and a second three-dimensional folded inductor structure. At least a portion of the first three-dimensional folded inductor structure is located within a volume bounded by the second three-dimensional folded inductor structure. By nesting the first three-dimensional folded inductor structure within the second three-dimensional folded inductor structure, a variety of coupling factors can be achieved while minimizing the size of the coupled inductor structure.