The fitting of a stator (13) body (14) equipped with a winding (12) in an inner support surface (250) for a skirt (155) of a bearing (15) of a rotary electrical machine, such as an alternator or an alternator-starter of a motor vehicle, characterized in that the skirt (155) is heated locally by induction before fitting of the body (14) equipped with its winding (12) in the skirt (155). The invention also relates to a rotary electrical machine comprising a fitting of this type.

A synchronous machine (100) has a frame (110), a shaft (115), a main section (120), and an exciter section (125). The main section (120) has a stator winding (130) which is mounted on the frame, and a rotor winding (135) which is mounted on the shaft. The exciter section has a transformer (140) and a rectifier (145). The transformer has a primary winding (140A) mounted on the frame and a secondary winding (140B) mounted on the shaft. The rectifier is mounted on the shaft and rectifies an output of the secondary winding to provide a rectified output to the rotor. A control unit (170) provides a high-frequency control signal to the primary winding. This signal is magnetically coupled to the secondary winding, rectified, and then applied to the rotor to control the operation of the synchronous machine.

A rotor of an asynchronous machine with a cage rotor includes a laminated core formed from a plurality of partial laminated cores. The laminated core has substantially axially extending conductors arranged in slots in the laminated core. The conductors include at least two materials of different electrical conductivities, such that a material with a higher electrical conductivity surrounds a material with a lower electrical conductivity by at least 65% in a circumferential direction.

A stator assembly method in which coils that have slot housed portions and coil ends formed from a conductive wire are mounted to an annular stator core that has a plurality of teeth that extend from a back yoke toward an inner side in a radial direction and slots formed between two of the teeth.

A wire position correction apparatus 14 corrects, in a stator 2 including an annular stator core 21 formed with a plurality of slots and a plurality of wires arranged in the slots, a tip end position of a wire leg portion 261 of the wire protruding from the slot to a reference position. The wire position correction apparatus 14 includes a wire clamper 4 that holds a tip end portion 263 of the wire leg portion 261, a turning mechanism 5 that supports the wire clamper 4 and turns the wire clamper 4 about a center axis passing through a base point P such that the tip end position moves in a direction approaching the reference position, and a movement mechanism 6 that moves the wire clamper 4 and the turning mechanism 5 along the vertical direction and circumferential and radial directions of the stator core 21.

Method for removing U-shaped winding elements for an electromagnetically excitable core of an electric rotation machine from a setting tool, wherein the U-shaped winding elements are set and are initially located in the setting tool, wherein in one step the winding elements are partially lifted out from the setting tool, so that parts of rod sections of the winding elements are freely accessible from the outside, characterized in that the winding elements are removed from the setting tool by means of a removal device, by gripping the rod sections.

A stator with closed slots with continuous winding is described, comprising a first internal stator part (25) which comprises a plurality of longitudinal teeth (26), spaced by a space (27) configured to form the lower part of the closed slots (14) of the stator, a second external annular stator part (35), comprising a plurality of seats (36) complementary to the teeth (26) of the first stator part (25) and configured to fit together with the teeth (26) so as to form the closed slots (14) and the stator (15), a continuous winding comprising at least one strap (11, 21, 31) configured to be wound on the first internal stator part (25) in the spaces (27) between the teeth (26) in which at least one slot (14) is asymmetrical; a process for manufacturing the stator (15) and an electric machine comprising the stator (15) are also described.

A joining method for inserting a coil winding into a component of an electrical machine by: providing the component with an annular arrangement of inwardly opening slots which are bounded by inwardly projecting slot boundaries, providing the coil winding wound with a coil diameter which is equal to or smaller than an inner diameter of the annular arrangement inside the annular arrangement, the coil winding having a plurality of straight conductor sections connected by winding heads, providing radially movable support fingers axially adjacent the slot boundaries, expanding the coil winding outwards while inserting the conductor sections of the coil winding into the slots, and moving the support fingers radially along with the coil winding to guide conductor sections and/or winding heads during insertion.

A stator assembly method in which coils that have slot housed portions and coil ends formed from a conductive wire are mounted to an annular stator core that has a plurality of teeth that extend from a back yoke toward an inner side in a radial direction and slots formed between two of the teeth.

A stator coil that includes a first coil portion including a pair of first slot-housed portions respectively arranged on an outer side of a first slot of the stator core in a radial direction and on an outer side of a second slot of the stator core in the radial direction; a second coil portion including a pair of second slot-housed portions respectively arranged on an inner side of the first slot in the radial direction and on an inner side of a third slot in the radial direction, the third slot being arranged across the first slot from the second slot in a circumferential direction; and a third coil portion including a pair of third slot-housed portions respectively arranged on an inner side and on an outer side in the radial direction.