Permanent-magnet-type rotating electric mechanism

The invention claimed is: 1. A permanent-magnet-type rotating electric mechanism comprising: a stator having stator windings wound on a plurality of tooth portions formed on a stator core; and a rotor having permanent magnets embedded between a plurality of magnetic poles formed along a circumferential direction of a rotor core, the rotor being rotatable integrally with a shaft, wherein the rotor core has a plurality of low permeability areas each having lower permeability than that of a material of the rotor core, the low permeability areas are located between an outer circumference of each magnetic pole and a side surface of each permanent magnet, the low permeability areas are formed asymmetrically with respect to a geometric center in the circumferential direction of each magnetic pole so that a magnetic center of the magnetic pole is displaced toward one side with respect to the geometric center, and the rotor core includes two rotor core parts that are placed upside down relative to each other so that a relative position in the circumferential direction of the low permeability areas of the two rotor core parts with respect to the permanent magnets differs, wherein Z is a natural number of slots of the stator, P is a natural number of magnetic poles of the rotor, m is a number of phases, and a number q of slots per pole per phase is represented as q=Z/(m×P), the magnetic center is displaced by an electric angle with respect to the geometric center of each magnetic pole, and if q satisfies (⅖)≦q<(½), the electric angle is set at 15 degrees or greater, and if q satisfies (½)≦q, the electric angle is set at 30 degrees or greater. 2. The permanent-magnet-type rotating electric mechanism according to claim 1 , wherein the permanent magnets are placed radially from a center side toward an outer circumference side of the rotor core. 3. The permanent-magnet-type rotating electric mechanism according to claim 1 , wherein the permanent magnets are provided two by two per one pole of the magnetic poles of the rotor core, and the two permanent magnets are placed so as to spread in V shape from a center side toward an outer circumference side of the rotor core. 4. The permanent-magnet-type rotating electric mechanism according to claim 2 , wherein the low permeability area is formed by a plurality of thin voids formed between the outer circumference of each magnetic pole of the rotor core and each side surface of the permanent magnets placed at both sides of the magnetic pole, and a number or a length of the voids is different between right and left with respect to the geometric center of each magnetic pole. 5. The permanent-magnet-type rotating electric mechanism according to claim 2 , wherein the low permeability area is formed by a plurality of thin voids formed between the outer circumference of each magnetic pole of the rotor core and a side surface of one of the permanent magnets placed at both sides of the magnetic pole. 6. The permanent-magnet-type rotating electric mechanism according to claim 1 , wherein, in the case where L is a depth from an outer circumference of the stator core to a surface of the shaft, the low permeability area is formed within a range of 1/2L from the outer circumference side. 7. The permanent-magnet-type rotating electric mechanism according to claim 1 , wherein, in the case where a is a distance from an outer circumferential surface of each magnetic pole of the rotor core to an end, of the low permeability area, that is close to the outer circumferential surface, and b is a distance from a side surface of each permanent magnet to an end, of the low permeability area, that is close to the side surface, a is set at 0.2 to 0.7 mm, and b is set to be longer than a but not longer than 3 mm. 8. The permanent-magnet-type rotating electric mechanism according to claim 1 , wherein the relative position in the circumferential direction of the low permeability areas is inverted depending on a position in an axial direction of the rotor, with a number of the inversions being an even number, so that the magnetic centers of the magnetic poles at one axial end side and the other axial end side of the rotor are aligned at the same position.