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).

According to one embodiment, a stator includes a stator core with slots, and multi-phase segment coils each including coil segments each including a first linear part and a second linear part arranged in different slots and a bridge part, the coil segment formed of a rectangular conductor. An innermost coil segment in the slot is structured with divided segments adhered together. Each divided segment includes a first linear part and a second linear part, and a bridge part, and is formed of a rectangular conductor cross-sectional area of which is smaller than the rectangular conductor of other coil segments. The bridge parts of the divided segments are arranged to cross each other in the radial direction.

A motor-driven compressor with a housing and an electric motor includes a stator that includes a stator core including a yoke and teeth, an insulator including an insulator base in contact with an end face of the yoke, and three-phase windings, each being wound around the corresponding teeth in a concentrated manner so as to form coils. The winding of each phase forms connection wires locked on an outer circumferential surface of the insulator base. Each connection wire connects adjacent coils of the corresponding phase. The outer circumferential surface includes a locking surface including accommodation grooves, each accommodating the corresponding connection wire, and a non-locking surface that does not lock the connection wires. The stator core includes an engagement recess that engages with part of a jig. The engagement recess is located radially outward from the insulator base on the end face and located radially outward from the non-locking surface.

Disclosed herein are a stator and a method for manufacturing the same. The stator according to embodiments of the present disclosure includes an insulating part and a plurality of stator coils each having two ends electrically connected to form one joint portion. The insulating part is configured to cover at least respective parts of the joint portions, and to provide a distance between neighboring joint portions. Accordingly, a partial discharge caused by a surge between the joint portions of the stator coils may be prevented, allowing operational reliability of the stator to be increased.

The invention relates to a method for producing a lamination stack for a rotor and/or a stator of an electric machine, wherein the lamination stack is produced of a stack of disk- or ring-shaped sheet metal laminations which are assembled of sub-segments that each have a radial outer edge, a radial inner edge and two lateral edges, wherein the sub-segments are stamped out of a sheet metal strip having a strip longitudinal direction that corresponds to a rolling direction of the sheet metal strip. In accordance with the invention provision is made in that for the purpose of stamping-out of the sheet metal strip first sub-segments are arranged in a first row and second sub-segments are arranged in a second row and stamped out, wherein the first row and the second row run in the strip longitudinal direction of the sheet metal strip and lie next to each other, in that the first sub-segments in the first row are aligned identically with respect to each other, wherein the radial outer edge and/or the radial inner edge run transversely to the longitudinal direction of the strip, and in that the second sub-segments in the second row are arranged identically with respect to each other, with radial outer edges and/or radial inner edges running transversely to the longitudinal direction of the strip, but diametrically opposed to the first sub-segments in the first row on the sheet metal strip.

An electric machine includes a stator core having a plurality of stacked laminations that are arranged in sets that each define a circumferentially extending slot through a thickness of the set. The sets are circumferentially rotated relative to each other in sequence such that each slot only partially overlaps with one or more adjacent slots to form a continuous helical cooling path around the stator core. Windings are supported on the stator core.

A method for manufacturing a rotor core includes detecting a height of a projecting portion formed on a lower die by a height detecting unit, and placing onto the lower die a core body in which a magnet insertion hole is formed such that the projecting portion is positioned in the magnet insertion hole when the height detecting unit has determined that the height of the projecting portion is within a set range. Additionally, the method includes bringing a permanent magnet in the magnet insertion hole into contact with an upper end of the projecting portion, and placing onto the core body a holding member after bringing the permanent magnet into contact with the upper end of the projecting portion. Melted resin is injected into the magnet insertion hole in which the permanent magnet has been inserted after placing the holding member onto the core body.

Systems and methods for manufacturing stators for electric submersible pumps, where a stator core having an inner portion and an outer portion is formed. The inner portion has a plurality of teeth and outward-facing slots. Magnet wire coils are formed on the inner portion by holding the inner portion in a stationary position and using a linearly movable robotic arm to position the magnet wire in each slot while preventing the wire from sliding axially with respect to the stator and adjacent turns of the coil. After forming the magnet wire coils on the inner portion of the stator core, the outer portion of the stator core is press-fit onto the inner portion to close the slots. The magnet wire can thereby be positioned to maximize the fill factor of each slot and increase power density for a given temperature rise.

A rotor core for an electric machine of an automobile includes a core stack including a plurality of lamination plates, each lamination plate including a plurality of apertures formed therein, the apertures of each of the lamination plates axially aligned to define a plurality of magnet slots extending axially through the core stack, a plurality of magnets stacked axially within each of the plurality of magnet slots along a length of the core stack, at least one of the plurality of magnet slots including a cavity extending axially along the length of the core stack, and a wedge inserted within the cavity adapted to apply a lateral force onto the plurality of magnets within the at least one magnet slot to secure the plurality of magnets within the at least one magnet slot.

A stator for a rotary electric machine includes a stator core and a stator coil. The stator core includes plate groups circumferentially shifted from and stacked on one another. The stator core has slots. The stator coil includes segment conductors inserted in the slots respectively. The stator coil is assembled with the stator core. The plate groups each have, as grooves that form the slots, first grooves, and second grooves wider than the first grooves. At least one of the slots is configured with one or more of the first grooves and one or more of the second grooves.