In order to facilitate the production of coil windings in components of electrical machines a method and a device are provided for winding a wave winding mat for forming a coil winding of an electrical machine, wherein one or more wires are wound with a predefined wire spacing between wire sections, wherein the wire spacing is set differently for different regions of the wave winding mat.

A stator and a manufacturing method thereof is enabled to easily determine the quality of welding produced between conductors. The stator includes a stator core and a stator winding installed in the stator core. The stator winding is configured by including multiple flat conductor segments in which conductors 34 are coated with insulating films 35, respectively. At a leading end of each of the conductor segment, an exposed portion 33 is formed in which the conductor is exposed. At a coil end section of the stator winding, a pair of exposed portions of different conductor segments are joined together by laser welding. A collective conductor width in a joining direction in which exposed portions join with each other is smaller at a laser irradiation incidence side, which is a side of the exposed portions receiving laser irradiation than that at a side opposite to the laser irradiation incidence side.

A device and method for producing a plugged wave winding by plugging together first and second wave winding parts. A first receptacle receiving the first wave winding part includes elements for guiding first wave winding part straight wire sections. A second receptacle receives the second wave winding part and has elements for guiding second wave winding part straight wire sections. A device for bending portions of at least one of the wave winding parts is configured to displace one or more of the winding heads directed towards the other wave winding part to plug the wave winding parts together. A relative displacement device pushes and plugs the first and second wave winding parts into one another. The first and/or second guide elements are movable between a position for guiding the straight wire sections and a position for releasing the path of winding heads while plugging into one another.

A bending unit for bending a bend of a wave winding for a coil winding of an electric machine, having a first holding element for holding a first segment of a wire to be bent, a second holding element for holding a second segment of the wire to be bent and at least one bending mold for bending a transition region of the wire between the first segment and the second segment. The first and the second holding elements are in engagement with each other via at least one mechanical control cam to control a relative pivoting and a relative displacement of the first and the second holding element. Furthermore, a bending device having a plurality of such bending units, a wave winding production apparatus having a plurality of bending units which are synchronized via control cams, and a bending method and a wave winding production method are described.

A process is described, for making a continuous winding for a stator of an electric machine comprising the following steps: bending on a plane of a strip to make a strap in a single piece, which comprises first sectors to be inserted inside closed slots of a stator and connected by second bending sectors which remain outside the slots; providing a first, internal stator part comprising a plurality of longitudinal teeth, spaced by a space which makes the lower part of the slots; making the winding on the first stator part, by placing the first sectors of strap in the spaces included between the teeth; and connecting the two free ends of every strap; a continuous winding made with such process is further described.

A method to produce rotors or stators of electric machines having radial grooves into which webs of flat windings having parallel webs and winding heads connecting said webs being pulled, wherein a winding is produced on a rotating, strip-shaped flat former shorter than the winding such that windings are pulled off the former and transferred into a linear transfer device, which transports the windings to a removal position at which the windings are transferred into radial grooves of a rotor or of the transfer tool for transfer into radial grooves of a stator, wherein the former, the transfer device, and the rotor or the transfer tool being jointly rotated about an axis of rotation of the former when rotated to form windings.

A method and an apparatus for compact insertion of thick wire multiphase pseudo helical wave winding into a ferromagnetic core of an electrical machine, achieving high fill factor of the core slots, resulting in better heat transfer between the winding and the core, low mass and volume, and overall higher efficiency of electrical machine. An apparatus being fully programmable and physically adaptable to wide range of electric machine dimensions, where process is automated, simple, accurate, reliable and quick, while being suitable for mass production.

A process for making a continuous bar winding (4) for an electric machine is described, comprising: a) a step of providing a template (10) having a template axis (X) and a circular array of slots (11) extended about said template axis (X), said circular array of slots having a number of slots equal to a number of slots of the stator or of the rotor of said electric machine, each slot (11) of said circular array having a first and a second open end face (11A, 11B) which are axially spaced from one another and a third open end face (11C), said third face (11C) being a longitudinal face extended between said first and second end faces (11A, 11B) b) a step of providing a conductive bar (20); c) a step of locking a locking portion (21) of said conductive bar; d) a step of inserting the conductive bar (20) into the slots (11) of said array and shaping the conductive bar (20) so that such conductive bar (20) repeatedly passes through the slots (11) of said array from the side of the first open end faces (11A) to the side of the second open end faces (11B) and vice versa, so that said bar (20) has a plurality of bar portions (20B, 20E, 20H) received in the slots (11) of said array and a plurality of connecting portions (20C, 20D; 20F, 20G) projecting beyond said first and second open end faces (11A, 11B), each of said connecting portions joining a pair of said bar portions (20B, 20E, 20H) received in the slots (11) of said array; in which said step d) comprises: d1) an operation of inserting a first bar portion (20B) of said plurality of bar portions into a respective slot (11) of said circular array of slots (11) through said third face (11C) of such slot (11); d2) an operation of shaping a first connecting portion (20C, 20D) of said plurality of connecting portions (20C, 20D; 20F, 20G); d3) an operation of inserting a second bar portion (20E) of said plurality of bar portions (20B, 20E, 20H) into a further slot (11) of said array, different from the slot (11) into which said first bar portion (20B) has been inserted, through said third face (11C) of the further slot (11); in which said first connecting portion (20C, 20D) joins said first and second bar portions (20B, 20E) projecting beyond the second end faces (11B) of the slots (11) in which said fi

A coil element for a coil of an electric machine having at least two conductor elements extending parallel for arrangement in slots of a coil body and at least one connection portion that connects the two conductor elements to one another. The conductor elements and the connection portion are integrally formed. A bending position in a plane defined by the two conductor elements is provided only at a transition from a conductor element to the connection portion, and the connection portion extends in a straight line.

The invention relates to a method for producing a coil winding (70) for insertion into radially open slots (82) in a rotor or stator (80) of an electrical machine, wherein the coil winding (70) has a wire pack (60) consisting of a number of wires (32), wherein the wires (32) of the wire pack (60) run parallel to one another and are connected to one another in pairs at one end of the wire pack (60), and wherein the coil winding (70) is formed by a flat winding former which can be rotated about an axis of rotation (26). According to the method, the wire pack (60) is fixed on a winding former (26) and winding heads (42) are produced by displacing fixations of the wire pack (60). The winding shaft (26) can be rotated so that, after carrying out the method, a coil winding (70) is present in the form of a wave winding having wires (32) of the wire pack (60) preconnected in pairs at one end. Such a method allows a particularly space-saving coil winding (70) to be produced, which has a particularly high mechanical stability and requires the least amount of installation space in a rotor or stator (80).