A method of manufacturing a base winding assembly of a stator. The base winding assembly includes a plurality of conductor loop groups each formed of a plurality of conductor loops that are open on one side, wherein the closed ends of the conductor loops that are open on one side can be arranged at one face of the base assembly and the open ends can be arranged at the opposite face side of the base assembly, wherein the manufacturing of the base winding assembly is done by an additive manufacturing process in which a layer-by-layer application and local solidification of build-up material takes place. Furthermore, a method for manufacturing a stator for an electric machine, as well as a base winding group of a stator and a stator are proposed.

Disclosed is a method for manufacturing an MSO coil, comprising: a pressing step of forming a bent surface on a part of a unit coil layer, which has a ring shape such that both ends thereof face each other, thereby endowing both ends of the unit coil layer with a height difference; a fixing step of connecting and fixing a plurality of unit coil layers to each other, each unit coil layer having the bent surface formed thereon, such that the first end of both ends of a unit coil layer having the bent surface formed thereon contacts the second end of both ends of another unit coil layer having the bent surface formed thereon; and a bonding step of bonding connection parts defined by contact of the first and second ends of each of the plurality of unit coil layers that are connected and fixed to each other.

Embodiments involve a coil winding for a rotating electric machine that are formed from conductive materials using a three dimensional printer. The coil winding is printed as a unitary structure with interconnects connecting coils of the same phase. The rotating electric machine may be an axial flux machined with three phases.

A coil forming apparatus includes: a coil winding jig that winds the belt-shaped coil, the coil winding jig including a plurality of comb-shaped grooves on an outer periphery thereof; a coil conveying mechanism that pivotally conveys the belt-shaped coil along at least a portion of the outer periphery of the coil winding jig; and guide members guide the belt-shaped coil in an arc shape while being in contact with the side ends. The guide members guide the belt-shaped coil so as to be in an arc shape having a diameter smaller than an outer diameter of the coil winding jig in a second half portion of the belt-shaped coil upon pivot conveying, and allow the plurality of straight portions to be inserted into a respective one of the plurality of comb-shaped grooves of the coil winding jig.

The subject matter of the invention is the method of construction of a linear motor winding, consisting of phase paths, characterised in that a solid flat bar is cyclically bent at a selected binding radius R.sub.1, the active part and the end parts constitute a uniform plane of the phase path, which has got elongated end fragments: the beginning of the section and the end of the section or the phase path is cut of metal sheet, as shown in the figure and then, along the line, separating the end part from the active part, it is bent at the bending radius R.sub.2, where the bend angle α.sub.1 is within the range between 0° and 180°.

A coil substrate for a motor includes a flexible substrate, and multiple coils formed on a surface of the flexible substrate. Each of the coils has a wiring having first wiring portions and second wiring portions extending from the first wirings respectively and is formed such that the first wiring portions extend parallel with respect to each other and that the second wiring portions extend not parallel to the first wirings, and the flexible substrate is formed to be formed around a magnet of a motor such that the first wiring portions form an angle that is substantially perpendicular to a rotation direction of the motor.

A coil substrate includes a flexible substrate having a first end and a second end on the opposite side with respect to the first end, and coils formed on the flexible substrate such that the coils are positioned substantially in a row between the first end and second end of the flexible substrate. The coils are formed such that the number of coils is K and that the coils include the first coil positioned close to the first end and the K-th coil positioned to form a predetermined distance between the K-th coil and the second end, where K is an integer equal to or greater than 2.

Coil body (21) is formed by cutting a peripheral wall of cylindrical body (22) into a spiral shape. Coil body (21) is winding in six turns of first turn (A1) to sixth turn (A6). A cut face between turns of coil body (21) is inclined with respect to a plane orthogonal to the axial direction of coil body (21).

A method of making a component of an electrical machine is provided. An additive manufacturing process is used to manufacture a part, including applying beams of energy to a successive plurality of ferromagnetic material particles and fusing them together to form a ring or segment of a ring with an axis, a solid portion, and laminas that extend from the solid portion in a radial or axial direction.

A 3D printed metal coil for an electrical machine. The 3D printed coil has a plurality of turns and is configured to fit within a slot in an electrical machine. A cross-sectional shape of successive turns of the plurality of turns varies such that a portion of each turn forms a part of an external surface of the metal coil, the external surface forming an interface with a side of the slot.