There is configured a coil unit arrangement device that forms an array coil group by arranging in a predetermined arrangement order each relevant coil of a coil unit in which a plurality of coils corresponding to a plurality of phases is connected by a jumper wire for each phase, the coil unit arrangement device including: a holding section provided with a rotatable coil unit support that supports the coil unit; and a receiving section provided with an array coil group support that supports the array coil group, the receiving section relatively turning with respect to the holding section.

A method of making a therapy delivery element configured for at least partial insertion in a living body is disclosed. A conductor structure is coiled around a mandrel. A segment of the conductor structure is secured to the mandrel. After this, an outer tubular structure is positioned around the conductor structure. Portions of the conductor structure that are not secured are free to expand to an inside surface of the outer tubular structure. A lumen is formed by removing at least a portion of the mandrel.

Fabrication methods for a 3D multipath inductor, including forming a metal layer to form spiral turns about a center region, the spiral turns including segments that extend length-wise along the turns and having positions that vary from an innermost position and an outermost position relative to the center region; forming a lateral cross-over configured to couple portions of lateral segments in different relative positions from the center region to form lateral segment paths that have a substantially same length for all lateral segment paths in a grouping thereof; forming an additional metal layer to form spiral turns about the center region including corresponding geometry to the first metal layer; and forming a vertical cross-over configured to couple portions of segments on different metal layers to form vertical segment paths that have a substantially same length for all vertical segment paths in a grouping thereof.

Provided is in an armature coil formed by arranging a plurality of coil conductors on a lower metal die having a tapered groove that is narrower toward an inner side. The coils are pressed using an upper metal die having an end portion narrower than the width of the groove. The coils are formed in a substantially trapezoidal shape which gets narrower toward the radially inner side and the cross-sectional areas of the plurality of the coil conductors in the slot are each substantially the same and the circumferential width thereof is formed narrower as the coil conductor is arranged toward the radially inner side; and one coil conductor is formed in a convex shape and another coil conductor is formed in a concave shape along the convex shape.

A magnetic assembly includes a bobbin with two end flanges. A passageway extends longitudinally between the end flanges. An inner core extends through the passageway. The inner core has first and second end surfaces, each end surface proximate to one of the end flanges. A rectangular outer core is positioned around the bobbin with inner surfaces of the outer core close to the outer surfaces of the end flanges of the bobbin. A respective gap is formed between each end surface of the inner core and the adjacent inner surface of the outer core. A protrusion is formed on at least one inner surface of the outer core to control the cavity distance between the inner surfaces of the outer core proximate to the end surfaces of the inner core. The thickness of the protrusion is selectably reduced to increase the cavity distance to control the gaps.

A method of forming electronic substrates and assemblies is provided. The method includes depositing a material. The material is deposited as a powder or slurry. The method includes sintering the material, and retrieving an article, including a solid electronic substrate. Also provided are electronic substrates formed by additive manufacturing, and methods of deploying the same.

A method for producing a pair of electrically conductive members assembled into an electrical component assembly provided with a coil. The method includes: forming connection terminal sections provided in the pair of electrically conductive members by arranging them alternately opposite to each other and then performing press punching; and after the press punching, bending the connection terminal sections in the pair of electrically conductive members toward a side departing from the coil into a protruding form.

The disclosed stator or rotor has a distributed wave winding, in which the wires are associated in pairs lying with straight segments in the same slots. Head portions of two successive straight segments of each wire of a pair protrude from opposite ends of slots. For forming two wire groups, a plurality of coil windings are simultaneously created by winding up n parallel wires with intermediate spacing onto a striplike former that is rotatable about its longitudinal axis. From each of the parallel wires one straight segment and one end turn are doubled by being bent over with the wire length of a head portion, and then head portions are formed and the wires interlaced. Finally, the two wire groups are wound onto one another and thereby intertwined with one another, and then introduced as an entire intertwined wave winding strand into the stator or rotor slots.

A coil substrate includes insulating layers, and conductive layers laminated on the insulating layers in a plate thickness direction of the insulating layers, respectively. The conductive layers include three or more conductive layers and a set of conductive layers such that the set of conductive layers includes a first outermost conductive layer on one end side in the plate thickness direction and does not include a second outermost conductive layer on the opposite end side in the plate thickness direction and that the set of conductive layers includes coil portions each having a spiral form respectively and aligned in the plate thickness direction.

A current transformer assembly for harvesting power from a primary conductor, such as a power line, for operating electronics, where the assembly is secured to the conductor while the conductor is connected. The assembly includes a current transformer having a transformer structure with a central opening that accepts the primary conductor and a spindle member for accepting a current transformer magnetic tape operating as the core of the current transformer. The assembly also includes a tape carrier secured to the structure on which the transformer tape is wound, and a winding device operable to unwind the transformer tape from the tape carrier and wind the tape onto the spindle member.