The invention relates to a winding piece (1), in particular in the shape of a hairpin, which is provided to be inserted into the grooves (7) of an electrical machine, comprising two limbs (2) and a curved transition region (3), which connects the two limbs (2) to each other. According to the invention, the limbs (2) each have a first portion (4) having a profile, which is adjusted to the cross-section of the groove (7), and an end portion (5), which has a round profile, wherein the winding piece (1) is formed as a hollow conductor, which has a penetrating channel (9), through which a coolant can be led.

Provided is a rotor for an asynchronous rotary electrical machine with non-through shaft that includes a cylindrical magnetic mass gripped between two mounting flanges of two half-shafts, a cooling means capable of cooling the rotor and conductive bars housed within the magnetic mass and distributed substantially uniformly over a diameter of the magnetic mass. The cooling means includes, for each conductive bar, at least one cooling channel, opening onto the conductive bar according to an axial direction and located within the magnetic mass and at least one through hole arranged within each conductive bar in such a way that the cooling channel communicates with at least one hole arranged on the outer periphery of the magnetic mass.

A turbogenerator includes a stator core defining a first end and a second end, a plurality of stator bars disposed within the stator core, each stator bar including a coolant flow path, and a parallel ring having a first segment and a second segment separate from the first segment. The parallel ring is coupled to the first end of the stator core and is arranged to electrically connect the plurality of stator bars and to fluidly connect the coolant flow paths of the plurality of stator bars. A tang includes a main chamber, a first coolant opening, a second coolant opening, and a distribution channel that fluidly interconnects the main chamber, the first coolant opening, and the second coolant opening. A first lead tube has a first lead end connected to the first coolant opening and a second lead end connected to the first segment, and a second lead tube separate from the first lead tube has a first lead end connected to the second coolant opening and a second lead end connected to the second segment. The plurality of stator bars, the parallel ring, the tang, the first lead tube, and the second lead tube cooperate to define a portion of a circuit and a portion of a cooling path.

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.

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.

A rotary electric machine includes a stator core having a plurality of teeth arranged in a row along a circumferential direction of the stator core, and a stator coil composed of a winding wire wound around the teeth. The stator coil includes coil end portions extending, outside the stator core in an axial direction thereof, along a substantially circumferential direction of the stator core, and straight portions extending along the axial direction, the straight portions being at least partially housed in a slot which is a void defined by two adjacent teeth of the plurality of teeth. In the rotary electric machine, a cooling groove is formed at least in the straight portion, the cooling groove functioning as a cooling channel through which a cooling fluid flows, and each straight portion includes only one cooling channel.

A rotary electric machine includes a stator core having a plurality of teeth arranged in a row along a circumferential direction of the stator core, and a stator coil composed of a winding wire wound around the teeth. The stator coil includes coil end portions extending, outside the stator core in an axial direction thereof, along a substantially circumferential direction of the stator core, and straight portions extending along the axial direction, the straight portions being at least partially housed in a slot which is a void defined by two adjacent teeth of the plurality of teeth. In the rotary electric machine, a cooling groove is formed at least in the straight portion, the cooling groove functioning as a cooling channel through which a cooling fluid flows, and each straight portion includes only one cooling channel.

An electric machine having an electrically insulative manifold is disclosed. In one example aspect, an electric machine includes a non-electrically conductive manifold. The manifold defines a chamber operable to receive a cooling fluid. The electric machine includes a prime winding in fluid communication with the chamber and one or more secondary windings in electrical communication with the prime winding and in fluid communication with the chamber. Further, the electric machine includes an electric machine terminal extending through the non-electrically conductive manifold and coupled with the prime winding. The electric machine terminal can provide or collect cooling fluid from the chamber of the manifold and can act as the electrical connection point for directing electrical power to or from the windings of the electric machine. The non-electrically conductive manifold electrically decouples the windings of the electric machine despite each winding receiving cooling fluid provided or collected at the manifold.

A rotating electrical machine includes a magnetic field generator that includes a magnet unit that has magnetic polarities. The magnet polarities alternate in a circumferential direction of the rotating electrical machine. The rotating electrical machine includes an armature that comprises multi-phase armature windings. One of the magnetic field generator and the armature serves as a rotor. Each of the multi-phase armature windings includes conductor members arranged at regular intervals in the circumferential direction to face the magnet unit. Each of the multi-phase armature windings includes a heat dissipation passage defined in each of the conductor members for dissipation of heat from the corresponding one of the conductor members.

A rotating electrical machine includes a magnetic field generator that includes a magnet unit that has magnetic polarities. The magnet polarities alternate in a circumferential direction of the rotating electrical machine. The rotating electrical machine includes an armature that comprises multi-phase armature windings. One of the magnetic field generator and the armature serves as a rotor. Each of the multi-phase armature windings includes conductor members arranged at regular intervals in the circumferential direction to face the magnet unit. Each of the multi-phase armature windings includes a heat dissipation passage defined in each of the conductor members for dissipation of heat from the corresponding one of the conductor members.