The invention relates to a stator for an electric machine, comprising a plurality of rod conductors and a plurality of interconnection pieces. The interconnection pieces each have a curved shape, in particular the shape of a C, extending in the radial direction and about the axis of rotation of the stator; in order to form respective interconnection planes along the axis of rotation, each group of interconnection pieces is arranged in the region of at least one short end of the rod conductors of the associated group of rod conductors that are to be electrically connected. The invention further relates to a connection component and an electric machine.

Each pair of the forming die and the clamping die holding a straight portion of a plane-bent intermediate coil from both sides in the circumferential direction have equal widths in the radial direction of the coil forming device, and the forming dies and the clamping dies holding a plurality of the straight portions disposed from an inner peripheral side of the coil forming device toward an outer peripheral side of the coil forming device are disposed alternately in the circumferential direction with the straight portions interposed therebetween.

A manufacturing method for a segment coil according to the invention includes forming an assembled wire by bundling a plurality of element wires, forming a stranded wire by twisting the assembled wire, forming a rectangular conductor by rolling the stranded wire, and forming a segment coil by cutting the rectangular conductor into a given length and bending the cut rectangular conductor. Before the rectangular conductor is bent, the plurality of element wires is fastened at a position where the coil end portion of the segment coil is formed.

A system for producing a winding bar for a stator winding of a stator of a rotating electric machine, in particular a turbine generator, having two machining units which can be arranged at a variable distance to each other. Each machining unit has machining device for machining an end portion of the winding bar, and each machining device is arranged on the respective machining unit in a pivotal manner about a pivot axis via at least one respective pivot arm. The pivot axis is identical to a longitudinal central axis of the rotating electric machine, and the radial distance between each machining device can be varied relative to the pivot axis.

The present disclosure relates to a method for fabrication of a conductor bar and to a use of a conductor tape with applied putty for the fabrication of a conductor bar. Described is a method for fabrication of a conductor bar including, applying a putty at one side of a conductor tape, applying a release foil at the other side of the putty opposed to the conductor tape, removing the release foil before applying the conductor tape to the narrow side of the conductor bar, providing a pressing mold with rounded edges at the inner side of the pressing mold, surrounding the conductor bar with putty and conductor tape with the pressing mold, and hot pressing the conductor bar with the pressing mold.

A rotating electric machine includes a stator, and a rotor. The stator has a rod-shaped coil which is disposed in a slot of a stator core and the rod-shaped coil includes plate conductors having slits formed in a twisted state. The rotor is disposed adjacent to a stator core and rotates. The rod-shaped coil is continuously wound on the stator core. In the rod-shaped coil, the number of slits of the plate conductor disposed on a side close to the rotor is greater than the number of slits of the plate conductor disposed on a side separated from the rotor.

The cold pressure welding apparatus includes a first holding part capable of sandwiching a first flat conductor, a second holding part disposed opposite to the first holding part and capable of sandwiching a second flat conductor, and a drive part for moving the first holding part and the second holding part. The drive part can move the first holding part and the second holding part between a first direction separated position and a close position along a first direction. The drive part can move the first holding part and the second holding part between a second direction separated position and a sandwiching position along a second direction.

A coil segment, in particular for a stator coil, wherein the coil segment has a conductor bundle, wherein the conductor bundle has a multiplicity of electrical conductors, wherein the conductor bundle has a form fit, wherein the conductor bundle has at least one cutout for feeding coolant. Furthermore, a method for manufacturing a stator coil, a stator coil having a coil segment according to the present invention, a machine having a stator coil according to the present invention, and a vehicle having a machine according to the present invention.

A method and apparatus for inserting an undulated coil assembly (90) in the hollow core (101) of a dynamoelectric machine, the coil having a planar configuration with adjacent superimposed linear portions (LI) extending parallel to each other and a plurality of turn portions (T) connecting the linear portions (LI), comprising positioning at least a first coil portion (90) of the coil assembly around a support member (200); aligning a guide assembly (302,303,304) with respect to the end faces and the slots (102) of the core (101); engaging the superimposed linear portions (LI) along guide surfaces that form a passage (301) during the feeding along the guide assembly (302,303,304); feeding the first coil portion (90) from the support member (200) along the guide assembly (302,303,304) to change orientation of adjacent superimposed linear portions (LI) being fed and to insert the adjacent superimposed linear portions being fed in the slots (102); relatively moving the core (101) with respect to the guide assembly (302,303,304) to position the slots (102) for receiving the superimposed linear portions (LI). A hollow core of a dynamoelectric machine wound with an undulated coil assembly comprising superimposed linear portions positioned at different pitch distances (PT1,PT2) in two adjacent slots (102).

The coil manufacturing apparatus includes: a bending device configured to bend each of a plurality of flat conductors; and a welding device configured to weld the plurality of flat conductors. The bending device is a unit configured to bend each of the flat conductors before being supplied to the welding device. The welding device includes a first holding portion and a second holding portion disposed facing each other, and a driving portion configured to move the first holding portion and the second holding portion. The helical structure body is formed by pressing end faces of the one flat conductor and the another flat conductor against each other along a strip longitudinal direction and joining the flat conductors through pressure welding while reducing a distance in the strip longitudinal direction. The coil manufacturing apparatus includes a removing device configured to remove an unwanted portion of the flat conductors generated by welding.