Provide are a stator, a rotor, and a rotating electrical machine that reduce cogging or ripple due to a gap between core divided sections. The stator comprises a plurality of core divided sections each having a cutout part extending along an. axial direction, and a plurality of pins provided for each of the core divisions adjacent to each. other and press- fit into pin press-fit holes formed by the cutout parts facing each. other. The plurality of core divided. sections are divided from each other at division surfaces each consisting of four or more constituent surfaces extending along the axial direction, the constituent surfaces including the three surfaces of a first surface closest to a magnetic gap part, a second surface second closest to the magnetic gap part after the first surface, and a farthest surface farthest from. the magnetic gap part. A pin press-fit surface that is one of the constituent surfaces other than the first surface and the second surface and provided with the cutout part has a normal direction oriented in an out-of-plane direction of the first surface or an out-of-plane direction of the second surface.

Disclosed is a motor or generator comprises a rotor and a stator, wherein the rotor has an axis of rotation and is configured to generate first magnetic flux parallel to the axis of rotation, the stator is configured to generate second magnetic flux parallel to the axis of rotation, and at least one of the rotor or the stator is configured to generate a magnetic flux profile that is non-uniformly distributed about the axis of rotation. Also disclosed is a method that involves arranging one or more magnetic flux producing windings of a stator non-uniformly about an axis of rotation of a rotor of an axial flux motor or generator.

A machined object that can prevent a coating material of a coating surface from peeling off when a machined surface that is adjacent to the coating surface is machined after coating of the coating surface. The machined object includes a main body and a coating material applied to the main body, the main body includes a machined surface that is machined, a coating surface that is arranged adjacent the machined surface via a boundary and to which a coating material is applied, and a recess formed in the main body and recessed toward an inner side of the main body from the machined surface and the coating surface at the boundary, and the recess extends along the boundary so as to separate the machined surface and the coating surface from each other.

A machined object that can prevent a coating material of a coating surface from peeling off when a machined surface that is adjacent to the coating surface is machined after coating of the coating surface. The machined object includes a main body and a coating material applied to the main body, the main body includes a machined surface that is machined, a coating surface that is arranged adjacent the machined surface via a boundary and to which a coating material is applied, and a recess formed in the main body and recessed toward an inner side of the main body from the machined surface and the coating surface at the boundary, and the recess extends along the boundary so as to separate the machined surface and the coating surface from each other.

A stator for an electric motor has a stator main body with stator teeth arranged in the form of a star and a stator yoke. The stator main body is formed with a number of axial grooves on an outer circumference. Spring elements are inserted into the axial grooves and the spring elements circumferentially protrude in the radial direction from the stator main body. The spring elements are introduced with a radial form-fit.

An electric motor with a stator and an axle (20). The stator has a laminated stator core (10) formed from a multitude of individual teeth (11). At least some of the individual teeth (11) each have a radially inner pressing portion (13) for elastic and/or plastic deformation and establishment of a press-fit connection between the laminated stator core (10) and the axle (20). The stator is fixed to the axle (20) through the deformation of the pressing portions (13) and a force acting on the axle (20). At least one securing element (30) is on at least some of the pressing portions (13) to transmit a torque between the axle (20) and the laminated stator core (10) and fix the position of the laminated stator core (10) relative to the axle (20) in the circumferential direction (U).

Provided is a motor capable of having an improved output while keeping the mechanical strength of the stator core. A motor includes: a stator including a stator core including an annular yoke having an outer part and an inner part and teeth extending inwardly from the inner part of the yoke, and a coil wound around the teeth; and a rotor rotatably disposed inside of the stator. The stator core includes the lamination of sheet members made of a soft magnetic material. Each sheet member has a binding part to bind the sheet members in the lamination at a first part corresponding to the outer part of the yoke. At least the binding part of the first part is made of an amorphous soft magnetic material. The sheet member has a second part other than the first part, and the second part is made of a nanocrystal soft magnetic material.

Provided is a motor capable of having an improved output while keeping the mechanical strength of the stator core. A motor includes: a stator including a stator core including an annular yoke having an outer part and an inner part and teeth extending inwardly from the inner part of the yoke, and a coil wound around the teeth; and a rotor rotatably disposed inside of the stator. The stator core includes the lamination of sheet members made of a soft magnetic material. Each sheet member has a binding part to bind the sheet members in the lamination at a first part corresponding to the outer part of the yoke. At least the binding part of the first part is made of an amorphous soft magnetic material. The sheet member has a second part other than the first part, and the second part is made of a nanocrystal soft magnetic material.

An axial flux machine for a drive train of a purely electric or hybrid motor vehicle having an annular stator and two rotor elements which are mounted so as to be rotatable relative to the stator about a rotational axis. A first rotor element is arranged axially adjacent to a first end face of the stator and a second rotor element is arranged axially adjacent to a second end face of the stator. The stator has a plurality of stator cores that are distributed in a circumferential direction of a circular line extending about the axis of rotation and are designed in a wedge shape in the radial direction. At least one stator core has a plurality of radially extending sheet metal segments that are stacked on top of one another in the circumferential direction and are of plate-like design. All of the sheet metal segments (are surrounded on their two circumferential sides, that face away from one another in the circumferential direction, by a covering section made of a soft-magnetic composite material.

Systems and methods relate to a vertical takeoff and landing (VTOL) platform that can include a stator and a rotor magnetically levitated by the stator. The rotor and stator can be annular, such that the rotor rotates about a rotational axis. The stator can include magnets that provide guidance, levitation, and drive forces to drive the rotor, as well as to control operation of rotor blades of the rotor that can be independently rotated to specific pitch angles to control at least one of lift, pitch, roll, or yaw of the VTOL platform. Various controllers can be used to enable independent and redundant control of components of the VTOL platform.