A motor includes a rotor and a stator. The stator is formed by laminating a plurality of magnetic thin strips each having a plurality of teeth parts. The magnetic thin strip includes an elliptical-shaped inner diameter part formed along tip end portions of the plural teeth parts. At least one magnetic thin strip in the laminated magnetic thin strips is shifted by a given angle with respect to other magnetic thin strips in a horizontal direction, and positions of all teeth parts of the laminated magnetic thin strips correspond to one another to reduce cogging torque.

An electric motor suitable for use in a laundry machine comprises an improved stator and/or rotor design.

A rotary electric machine includes: a rotary shaft member; first and second rotor including first and second rotor core, respectively, including first and second permanent magnets having first and second polarity, first and second magnet-based magnetic pole portions having the first and the second polarities and being formed by the first and the second permanent magnets, and first and second iron core portions having the second and the first polarities and being formed by iron pole portions of the first and the second rotor core, are alternately arranged in a circumferential direction of the first rotor core; a stator; and a field yoke. Further, the first magnet-based magnetic pole portion and the second iron pole portion face each other and the first iron pole portion and the second magnet-based magnetic pole portion face each other in the axial direction.

A method for manufacturing a stator for an electric machine comprises manufacturing a slot cooling fin to extend into a slot defined between a first tooth, a second tooth, and a stator yoke, and disposing a coil in the slot, wherein the slot cooling fin extends into the first coil.

A permanent magnet brushless motor, robot joint, a servo actuator, and a robot are provided. The motor is of fractional-slot and inrunner type, including a stator (1) and a rotor (2). The stator (1) includes a stator iron core (10) and a stator winding, the stator winding is a concentrated winding, and the stator iron core (10) has an integral structure. The stator iron core includes a stator yoke and stator teeth, the stator teeth include a plurality of stator teeth (102) protruding from the stator yoke, and the surfaces of the stator teeth (102) are provided with insulating layers. The stator winding comprises a plurality of preset winding coils (11) formed by machine, and each stator tooth is inserted into x winding coils, wherein x is greater than or equal to 1.

A brushless direct current motor includes a rotor made up of at least one permanent magnet and a stator having at least three partitions radially extending from a circular based cylindrical main body, the partitions together defining at least two volumes for receiving at least three coils generating a magnetic field, wherein each volume is closed by a wall connecting the partitions, and in that the wall comprises, on the face thereof oriented toward the rotor, at least one magnetic restriction zone. A sleeve surrounds the stator and the rotor and has at least one deformation zone formed by cutouts adapted to maintain the external geometrical configuration of the sleeve when mounting the constituent elements of the motor. A method for manufacturing such a motor.

The rotary electric machine includes: a rotor core configured having electromagnetic steel sheets; a stator core having electromagnetic steel sheets; a magnet inserted in each of a plurality of through holes; and a magnetic end plate in contact with one or each of an end surface on one side in the axial direction of the rotor core and an end surface on another side in the axial direction of the rotor core, and having a single magnetic sheet or a plurality of magnetic sheets stacked in the axial direction, wherein heat generated from the magnetic end plate owing to eddy current that is generated in the magnetic end plate by magnetic flux from the stator core is equal to or lower than heat generated from the rotor core owing to eddy current that is generated in the rotor core by magnetic flux from the stator core.

An electric machine that increases structural freedom to increase output of the electric machine while satisfying requirements of an outer shape. An armature portion includes armature cores (H1, H2) and a plurality of coils (CL) attached to the armature core (H1). A magnetic field portion (Fs) is relatively rotatable to the armature portion and includes a plurality of magnets (Mg) and a plurality of magnetic field cores (22N, 22S). In the magnetic field portion (Fs), the magnets (Mg) are disposed between two magnetic field cores (22N, 22S) adjacent in a rotation direction. Each of the armature cores (H1, H2) includes magnetic pole groups (G1, G2). The magnetic pole group (G1) included in the armature core (H1) and the magnetic pole group (G2) included in the armature core (H2) constitute a magnetic pole group pair (P) that forms a magnetic path through the magnetic field portion (Fs).

Provided is an axial gap-type rotary electric machine in which a first stator, a second stator, and a rotor are arranged in a direction of a rotary shaft of the rotor. The first stator includes a first coil and a first core. The second stator includes a second coil and a second core. The first core includes an annular first yoke, a plurality of first teeth, and a first mark indicating a reference position in a circumferential direction of the first yoke. The second core includes an annular second yoke, a plurality of second teeth, and a second mark indicating a reference position in a circumferential direction of the second yoke. When viewed in the direction of the rotary shaft, the first mark and the second mark are symmetrically positioned with respect to the rotary shaft.

An electric motor includes a stator including four split cores, and a rotor having four magnetic poles. Each of the split cores includes a yoke and a tooth. An angle θ1 [degree] formed by a side surface of the tooth and a side surface of the yoke on an inner side in a radial direction of the stator satisfies 90 degrees ≤θ1<180 degrees.