In one embodiment, a high speed induction machine includes: a stator formed of a first plurality of laminations having a thickness of less than approximately 0.01 inch and a winding comprising a coil formed of Litz wire adapted about the stator; and a rotor adapted within the stator. The rotor may include: a rotor core formed of a second plurality of laminations having a second thickness of greater than approximately 0.10 inch and formed of high strength steel and sandwiched between a first end region including at least one first peripheral second lamination and a second end region including at least one second peripheral second lamination, the first end region having a first end ring retained by a first retaining ring adapted there around, the second end region having a second end ring retained by a second retaining ring adapted there around.

An electrodynamic assembly for propelling a spacecraft in orbit around a celestial body having a magnetic field is disclosed. The assembly includes a plurality of coaxial cables for an electrodynamic assembly for propelling a spacecraft in orbit around a celestial body having a magnetic field. Each coaxial cable includes an electrically conductive core surrounded by a first electrically insulating sheath, and an electrically conductive current return circuit mounted outside the first electrically insulating sheath. The current return circuit includes a first end electrically connected to a first end of the core of the coaxial cable.

The efficiency of inserting a coil conductor into a slot of a stator core is improved in the present invention. Included are a rotor and a stator. The stator includes a stator core formed with a plurality of slots formed at a predetermined depth in a radial direction and arranged while spaced apart from each other in a circumferential direction and stator winding having a coil conductor inserted in each of the slots. A plurality of protrusions are formed in each of the slots of the stator core toward a space into which the coil conductor is inserted.

Stators (2) having teeth (4) and electrical windings (5) provided on the teeth (4), wherein the electrical windings (5) comprise graphene and/or carbon nanotubes, are already known. The electrical winding (5) of the stator (2) is produced in a winding process. The electrical winding (5) in the component of an electric machine according to the invention can be produced more easily, in particular further electrical phases can be built into the electrical winding (5) in a simpler and reproducible manner. According to the invention, the electrical windings (5) are each formed as a tubular fabric which encloses the tooth (4) to which it is assigned.

An assembly for an electric motor includes a stator including a plurality of stator poles, each stator pole including a base end and a rotor end opposite the base end, and an electromagnetic coil around each stator pole. The coil around each stator pole includes at least two electrically conductive wires wound into multiple wire turns around the stator pole that extend from the base end of the stator pole to the rotor end of the stator pole. Wire turns of the coil closer to the rotor end of the stator pole are twisted and wire turns of the coil closer to the base end of the stator pole are not twisted.

According to one embodiment, in a stator, bridge parts of seventh coil segments extend in a direction departing from one end surface while being inclined at a predetermined inclination angle from an axial direction of a stator core to the outside of a radial direction. Regarding the bridge parts of the seventh coil segments adjacent to each other in the radial direction of the stator core, when the same cross-sections defined by the radial direction and the axial direction is viewed from a circumferential direction of the stator core, a first inclination angle of the bridge part positioned relatively in an inner side of the radial direction is smaller than a second inclination angle of the bridge part positioned relatively in an outer side of the radial direction.

Axial flux electric machines and associated methods are disclosed herein. One disclosed axial flux electric machine includes a stator having a plurality of pole pieces, a rotor spaced apart from the stator in an axial direction of the axial flux electric machine, and a coiled ribbon of conductive material forming at least part of a pole piece in the plurality of pole pieces. An axial direction of the coiled ribbon of conductive material is substantially parallel to the axial direction of the axial flux electric machine. In some embodiments of the disclosed axial flux electric machine a coiled ribbon of soft magnetic material is coiled with a coiled ribbon of conductive material into an interleaved composite material coil which forms at least part of a pole piece for an axial flux electric machine.

The present invention relates to a wind turbine with an electrical machine wherein said electrical machine comprises a stator (702) with one or more electrical winding(s) (704), said electrical winding(s) being arranged to be connected to an electrical grid (760) by at least one cable (740) with at least one phase conductor (746), the at least one cable (740) comprises at least one return path (744) to conduct leakage currents, and at least one electrical shield (745), the stator being electrically isolated from a stator housing (701). The invention also relates to a method for minimizing stray currents in an electrical machine in a wind turbine.

An example turbocharger includes a turbine impeller, a rotation shaft fixed to the turbine impeller, a motor having a rotor located on the rotation shaft, and a stator located around the rotor. The stator includes a stator core, an insulator located around the stator core. The insulator includes an element pocket, a coil wound around the insulator. The coil includes a first coil end and a second coil end, and a temperature sensing device configured to detect a temperature of the coil. The temperature sensing device is located in the element pocket and hold by the element pocket.

A motor includes a rotor and a stator, a substrate electrically connected to the stator, a sheet-metal cover accommodating the stator and the substrate, and a wiring electrically connected to the substrate. The cover includes a through-hole open to a wall of the cover and communicating an outside and an inside of the cover. The wiring includes cables extending from the inside to the outside of the cover through the through-hole, and a bush with a tubular shape into which the cables are inserted, the bush being attached to the through-hole and elastically deformable. The cover includes a first cup body accommodating the stator and a second cup body accommodating the substrate. The bush is located radially between the second cup body and the substrate.