Patent ID: 7898123
Filing Date: 2011-03-01
Classification: H02K

Abstract:
1. A permanent magnet type multi-phase rotary machine having an outer rotor, comprising: a stator having four stator units coaxially stacked one on the other, each of which includes a pair of stator yokes having an even number of comb-shaped magnetic pole teeth formed at regular intervals, and a air-core coil which is sandwiched between the pair of stator yokes; and the outer rotor including a permanent magnet having a number magnetic poles which are fixed on an inner face of a cylindrical rotor yoke in a manner such that each of the magnetic poles is not divided in an axial direction, the magnetic poles respectively facing the magnetic pole teeth of the stator yokes, said rotor being rotatably supported by an output shaft, wherein each of the four stator units is assigned to either an A-phase or a B-phase, a second of the four stator units being stacked on the first stator unit, a third of the four stator units being stacked on the second stator unit, and a fourth of the four stator units being stacked on the third stator unit, the stator yokes of the four stator units respectively having the same number of magnetic pole teeth, which are formed in a rotational direction of said rotor at regular intervals, the four stator units being directly coaxially stacked, and the magnetic pole teeth being shifted with a prescribed phase difference with respect to the rotational direction of said rotor in all of the stator units, wherein three boundaries faces A, B, and C are formed between the stacked stator units, the first boundary face A being between the first and second stator units, the second boundary face B being between the second and third stator units, and the third boundary face C being between the third and fourth stator units, and wherein centers of mass of the adjacent magnetic pole teeth of the boundary face A, and the centers of mass of the adjacent magnetic pole teeth of the boundary face C are shifted with a phase difference of 90°±30°, thereby a resultant cogging torque of the cogging torques respectively generated in the magnetic circuits passing through the boundary faces A and C is reduced.