A coil attachable to a tooth extending to one radial side of the tooth from an annular core back surrounding a central axis of a motor includes a first winding body including a first wound flat wire, and a second winding body including a second wound flat wire, that is located on a radial side of the first winding body, and that is connected to the first winding body. When N is a freely-selected integer of 1 or more, and M is a freely-selected integer larger than N, the first winding body is an N-layer winding body aligned and wound in two rows aligned in a radial direction, and the second winding body is an M-layer winding body aligned and wound in two rows aligned in the radial direction.

In a method for mounting a prefabricated form-wound coil or tooth-wound coil on a layered laminated core to form a stator segment or stator, the form-wound coil or tooth-wound coil is insulated with insulation. Laminates are punched and stacked to form partial laminated cores and/or a laminated core, with the partial laminated cores being spaced apart from one another by spacers and forming substantially axially extending open slots of the laminated core. The form-wound coil or tooth-wound coil are radially inserted into the slots such as to embrace a tooth of the laminated core, and a removable auxiliary element is placed at an axial end face of the laminated core to protect the insulation of the form-wound coil or tooth-wound coil as the form-wound coil or tooth-wound coil is radially inserted into the slots. The auxiliary element is radially removed and repositioned on a further tooth of the laminated core.

Provided is a coil including first and second lead parts, and a winding part. The winding part includes first to n-th turns. The winding part includes first and second coil ends. The first lead part extends from the first turn to the n-th turn along an upper surface of the first coil end. The second lead part extends from the n-th turn. The first and second lead parts include respective ends that are equal in height from the upper surface of the first coil end when viewed from a radial direction, and are equidistant from the n-th turn when viewed from an axial direction.

The invention relates to an electrotechnical coil, to a method for producing same, and to an electromagnet or an electric machine comprising at least one such coil. The aim of the invention is to produce and use an electrotechnical coil for achieving an increased slot fill factor reliably and easily in a reproducible and economical manner. This is achieved in that the method according to the invention has the steps: step A: casting an electrotechnical coil with at least one winding which runs about a coil axis; and step B: shaping the coil, thereby changing the cross-section Q, Q′ of the at least one winding, such that the centroid FS, FS′ of the cross-section Q, Q′ of the at least one winding is displaced at least partly in the radial direction R relative to the coil axis A.

A wiring machine includes a chassis, a shifting mechanism, a carrying mechanism and a wire leading mechanism. The chassis has a guide rail. The shifting mechanism is disposed on the guide rail and movable along the guide rail. The carrying mechanism is disposed under the guide rail and includes a tray movable along a direction perpendicular to the guide rail. The wire leading mechanism is connected to the shifting mechanism and movable in a direction perpendicular to the shifting mechanism. The wire leading mechanism includes a body, a wire conveying assembly disposed in the body and a wire leading head connected to the body. A wire is conveyed by the wire conveying assembly to be output by the wire leading head. Therefore, the wire may be rapidly and stably laid into different types and shapes depending on different requirements.

A method of forming a diamond coil wound stator winding including introducing a plurality of diamond coils into a plurality of slots of a linear magazine forming a diamond coil wound stator winding, transferring the diamond coil wound stator winding into a circular cassette, and shifting the diamond coil wound stator winding from the circular cassette into a plurality of slots arranged in an inner annular surface of a stator core in a single operation.

A wiring machine includes a chassis, a shifting mechanism, a carrying mechanism and a wire leading mechanism. The chassis has a guide rail. The shifting mechanism is disposed on the guide rail and movable along the guide rail. The carrying mechanism is disposed under the guide rail and includes a tray movable along a direction perpendicular to the guide rail. The wire leading mechanism is connected to the shifting mechanism and movable in a direction perpendicular to the shifting mechanism. The wire leading mechanism includes a body, a wire conveying assembly disposed in the body and a wire leading head connected to the body. A wire is conveyed by the wire conveying assembly to be output by the wire leading head. Therefore, the wire may be rapidly and stably laid into different types and shapes depending on different requirements.

A method used for producing rotors and stators of electric motors, including the production of connection wires, and comprises the following steps: Winding the coil windings (12), which comprise a plurality of individual wires (14), on a wire winder (28) to which the individual wires (14) are fed from a wire supply unit (16) via a wire guide 18, 20, 22), Depositing the coil windings (12) in a draw-in tool (36), Drawing the coil windings (12) into grooves of a stator (84) or rotor body, Combining the individual wires (14) in phases by means of slide-on tubes (52) to produce the connection wires of the stator or rotor in question. In order to be able to automate the production of the connection ends, which was previously carried out manually, it is proposed that the individual wires (14) of each coil winding (12) are fastened to each other in the region of the wire guide (18, 20, 22) in order to form winding ends (46) and winding beginnings (32), after the winding and before or during the depositing, the winding ends (46) and winding beginnings (32) of each coil winding (12) are fastened in first position holders (42, 44) arranged in certain positions with respect to the draw-in tool, and during the drawing of the coil windings (12) into the stator or rotor, the winding ends (46) and winding beginnings (32) are transferred from the first position holders (42, 44) into second position holders (90, 92) arranged in certain positions with respect to the stator body (84) or rotor body. The present invention also relates to a device for carrying out the aforesaid method.

A stator structure of a vehicle motor includes a stator core assembly and a plurality of coil assemblies composed of flat wires. The stator core assembly includes an annular portion and a plurality of tooth portions. The tooth portions extend from the annular portion in a radial direction toward a center of the stator core assembly. Each coil assembly is configured around a corresponding tooth portion. Each coil assembly includes a first flat wire and a plurality of second flat wires that are electrically connected in parallel. The first flat wire is radially stacked and wound around the corresponding tooth portion. The second flat wires are arranged radially adjacent to the first flat wire and are electrically connected in series to the first flat wire. The second flat wires are alternately stacked and radially wound around the corresponding tooth portion.

The invention relates to a stator (8) for an electric rotating machine (2), which stator has a laminated stator core (16) having coil bars (20) and has at least one stator winding head board (24) having an insulating main body (28). In order to reduce the axial length of the stator (8), according to the invention, conducting tracks (26) are integrated into the insulating main body (28), wherein the at least one stator winding head board (24) lies on an end face (23) of the laminated stator core (16) and wherein the conducting tracks (26) are integrally bonded to the coil bars (20).