A magnetizing yoke prevents coils from being damaged and/or broken when an object to be magnetized is magnetized, more securely as compared with any conventional arts. The magnetizing yoke includes a slot member made of thermosetting resin and formed with slots for inserting and fixing windings of an iron core, wherein the slot member is inserted into and fixed to the iron core. The magnetizing yoke is manufactured using a simple step of mounting the slot members made of resin on the iron core.

A power tool includes a motor having a stator assembly and a rotor pivotably arranged inside the stator. The stator assembly includes a lamination stack defining a plurality of poles; a plurality of field windings each arranged at at least two opposite poles of said plurality of poles and connected together around the stator assembly; and a plurality of conductive terminals longitudinally arranged along an outer surface of the lamination stack and electrically coupled to the plurality of field windings and a power source.

A stator of an electric motor includes a multilayer body including annular core sheets stacked in layers. A first annular core sheet includes linking portions, each of which defines a link between tips of two adjacent teeth and includes a seam. A first linking portion provides a link between teeth associated with a U phase. A second linking portion provides a link between teeth associated with a V phase. A third linking portion provides a link between teeth associated with a W phase.

A stator for a rotating electrical machine includes a stator coil and a stator iron core having slots into which the stator coil is mounted, wherein a coil end of the stator coil is elliptical in shape around a center axis of the stator iron core.

A cooling arrangement (1) for cooling a stator (2) for an electric machine (23). The cooling arrangement (1) comprising a stator (2) fixedly mounted relative to a rotational axis (Rot). The stator (2) comprises a stator yoke (3) and stator grooves (4). Windings are provided in the stator grooves (4), which form first and second winding heads (5, 6). First and second fluid rings (8, 14) are provided at opposite ends on the stator yoke (3). The first fluid ring (8) has a fluid inflow opening from a stator housing (7). The stator yoke (3) has a plurality of axial stator ducts (15, 18, 22) extending in the axial direction (A), which enable the inflowing fluid to flow through from the first fluid ring (8) to the second fluid ring (14), and the second fluid ring (14) redirects some of the fluid. Furthermore, the invention relates to an electric machine.

A device for rotary or linear position sensing includes a stator with a plurality of teeth, an excitation winding wrapped around at least some of the plurality of teeth, and multiple sense windings for detecting changes in voltage output. The windings are in two sets in which each set can independently determine the change in voltage output. A control circuit generates a first output signal representing a relative position of the stator based on excitation of the first sense winding set by the excitation winding and a second output signal representing a relative position of the stator based on excitation of the second sense winding set by the excitation winding.

A stator includes a stator core, a first coil and a second coil inserted into slots, and an insulating sheet arranged between the first and second coils. The first coil has a first portion accommodated in a first slot, and the second coil has a second portion accommodated in the first slot. The insulating sheet includes a sheet-like insulating parts projecting from respective end surfaces of the stator core, and leg parts. Each of the sheet-like insulating parts is arranged between a first coil end of the first coil extending from the first portion to the outside of each of the end surfaces and a second coil end of the second coil extending from the second portion to the outside of each of the end surfaces, and the leg parts include a first leg part inserted into the first slot and arranged between the first and second portions.

A stator assembly for a brushless DC motor includes a stator core including stator poles and an outer surface, at least one magnet wire wound on the poles forming stator windings, and a bus bar including a non-conductive mount and conductive terminals. Each conductive terminal includes: a main portion and a tang portion extending from a first longitudinal end of the main portion. At least a contact portion of the at least one magnet wire is wrapped around the tang portion and fused to make an electric connection to the conductive terminal. The tang portion has a smaller lateral width than the main portion and is folded over the main portion to capture the contact portion of the at least one magnet wire. A power wire supply electric power to the motor is coupled to the conductive terminal proximate the second longitudinal end of the main portion.

A structure for assembling a temperature sensor of an annular terminal unit for a drive motor. The structure includes a terminal holder having an annular shape, a temperature sensor fixed to the terminal holder, a plurality of cores radially arranged on a lower surface of the terminal holder, a bobbin inserted into each of the plurality of cores, and a stator coil wound around each of the bobbins. The temperature sensor passes through the terminal holder in a vertical direction of the terminal holder and is inserted between the bobbins around which the stator coils are wound.

An armature winding of multiple phases has a phase winding that is made of a plurality of partial windings for each phase. The partial winding includes a pair of intermediate conductor portions and crossover portions that connect the pair of intermediate conductor portions in an annular shape, and is configured by a conductor material being wound in multiple layers in the pair of intermediate conductor portions and the crossover portions. The intermediate conductor portions of the phases are arrayed in a predetermined order in the circumferential direction by one of the intermediate conductor portions of the pair of intermediate conductor portions of the partial winding of another phase being arranged between the pair of intermediate conductor portions of the partial winding. A sheet-shaped insulation covering body is provided in the intermediate conductor portion in a portion that opposes the intermediate conductor portion of the partial winding of another phase.