A number of illustrative variations may include a rotor core for an electric motor comprising permanent magnets wherein the rotor core comprises lobes of the core material that magnets may be attached to.

The invention relates to an electric machine (1) comprising a stator (10) and a rotor (20) separated from the stator (10) by way of an air gap, wherein the rotor (20) has a plurality of shell-like magnet segments (30) secured to a rotor body (22), and wherein the magnet segments (30) have in the circumferential direction in each case a plurality of sections (32, 33, 34) with different magnetic polarizations, which each form a magnetic pole of the rotor (20), and wherein transition zones (36) are formed between the sections (32, 33, 34) of the magnet segments (30) with different magnetic polarizations, wherein recesses (40) are provided in the magnet segments on the side facing the stator (10). It is proposed that the transition zones (36) are formed so as to run obliquely in the axial direction of the rotor (20) and that the transition zones (36) are formed in the region of the recesses (40).

The invention relates to an electric machine (1) comprising a stator (10) and a rotor (20) separated from the stator (10) by way of an air gap, wherein the rotor (20) has a plurality of shell-like magnet segments (30) secured to a rotor body (22), and wherein the magnet segments (30) have in the circumferential direction in each case a plurality of sections (32, 33, 34) with different magnetic polarizations, which each form a magnetic pole of the rotor (20), and wherein transition zones (36) are formed between the sections (32, 33, 34) of the magnet segments (30) with different magnetic polarizations, wherein recesses (40) are provided in the magnet segments on the side facing the stator (10). It is proposed that the transition zones (36) are formed so as to run obliquely in the axial direction of the rotor (20) and that the transition zones (36) are formed in the region of the recesses (40).

A method for positioning magnets on a rotor of an electric motor includes positioning adjacent magnets in a gap-free circle, and then simultaneously radially moving the magnets until a uniform reference gap is created between them. A device includes a plurality of ring segments capable of forming an adjustable annular ring, being simultaneously moveable in radial direction and being capable of moving the magnets from a gap-free circle radially until a uniform reference gap is created between them. A kitchen appliance is also provided.

A magnet unit includes a plurality of arc-shaped magnets arranged in a circumferential direction and a magnet holder to which the magnets are secured. Each of the magnets has arc-shaped easy axes of magnetization which extend more parallel to the d-axis in a region close to the d-axis than those in a region close to the q-axis. The easy axes of magnetization define arc-shaped magnetic paths extending therealong. The magnets are arranged to be separate from each other across the d-axis or the q-axis. Each of the magnets has a q-axis end surface facing in the circumferential direction and placed in surface-to-surface contact with that of the circumferentially adjacent magnet. Each of the magnets has an armature-remote peripheral surface which faces away from the armature. Each of the armature-remote peripheral surfaces facing an attachment surface of the magnet holder through a clearance which is filled with a resin adhesive.

A magnet unit includes a plurality of arc-shaped magnets arranged in a circumferential direction and a magnet holder to which the magnets are secured. Each of the magnets has arc-shaped easy axes of magnetization which extend more parallel to the d-axis in a region close to the d-axis than those in a region close to the q-axis. The easy axes of magnetization define arc-shaped magnetic paths extending therealong. The magnets are arranged to be separate from each other across the d-axis or the q-axis. Each of the magnets has a q-axis end surface facing in the circumferential direction and placed in surface-to-surface contact with that of the circumferentially adjacent magnet. Each of the magnets has an armature-remote peripheral surface which faces away from the armature. Each of the armature-remote peripheral surfaces facing an attachment surface of the magnet holder through a clearance which is filled with a resin adhesive.

A rotor for a permanent magnet electrical machine that includes a rotor house having a rotor house yoke, the rotor house yoke including for each of plural permanent magnet units, a magnet unit contact face and at least one through hole, at least one permanent magnet unit having a rotor house contact face, a fixing material portion between the magnet unit contact face of the rotor house yoke and the rotor house contact face of the magnet unit for fixing the magnet unit to the rotor house.

The present disclosure relates to a method for assembling a large-diameter electric motor, the method includes: a preparing step: providing two or more stator segments for forming a stator and two or more rotor support segments for forming a rotor support; a splicing step: splicing the two or more stator segments and the two or more rotor support segments in a predetermined manner to form the stator and the rotor support that are coaxially assembled, respectively, and maintaining a predetermined gap between the stator and the rotor support in a radial direction; and an assembling step: inserting a plurality of magnetic pole modules into the predetermined gap, and assembling the plurality of magnetic pole modules to a mounting surface of the rotor support. The method can avoid the influence of a magnetic pulling force at an air gap between the stator and a rotor on an assembling process, and can improve the convenience of assembling the large-diameter electric motor on site.

A motor includes: a central shaft; a stator extending in an axial direction around the central shaft; a rotor facing an outer side in a radial direction of the stator and configured to rotate around the central shaft; a substrate located on one side in the axial direction with respect to the rotor and on which a rotation position detection circuit detecting a rotation position of the rotor is mounted; and a case located on one side in the axial direction with respect to the substrate and supporting the stator. The stator includes a restricting portion restricting a position in a circumferential direction of the substrate. The case includes a fixing portion fixing the substrate. The substrate includes a restricted portion whose position in the circumferential direction is restricted by the restricting portion, and a fixed portion fixed to the fixing portion.

A manufacturing apparatus includes a magnetizing yoke in which a magnet section to be magnetized is installed. The magnetizing yoke includes a core having slots formed at predetermined intervals in a circumferential direction, and a coil received in the slots. When installed with respect to the magnetizing yoke, the magnet section is arranged to face, at locations closer to a d-axis, magnetization surfaces of the core and face, at locations closer to a q-axis, the slots of the core. The magnetization surfaces of the core are formed between the slots adjacent to one another in the circumferential direction. The coil is fixed by a nonmagnetic and elastic fixing material in the slots. On a facing surface of the magnet section which faces the magnetizing yoke, there are radially-recessed grooves formed respectively in q-axis-side portions of the magnet section.