Multi-gap rotary machine with dual stator and one rotor with dual permanent magnets and salient poles with dimensions and ratios for torque maximization

What is claimed is: 1. A multi-gap type rotary electric machine, comprising: a shaft supported rotatably by a bearing secured to a housing; an annular rotor secured to the shaft and configured 5 to rotate together with the shaft; and a stator secured to the housing and configured to have a gap between the stator and the rotor, wherein the rotor comprises an annular rotor core made of soft magnetic material and configured to have a radial direction and a circumferential direction, a plurality of inner magnets, each composed of a permanent magnet, embedded in radially inner portions of the rotor core at equal pitches in the circumferential direction, and a plurality of outer magnets, each composed of a permanent magnet, embedded in radially outer portions of the rotor core at equal pitches in the circumferential direction; the rotor core comprises a plurality of inner salient poles each formed between mutually adjacent two of the inner magnets in the circumferential direction, and a plurality of outer salient poles each formed between mutually adjacent two of the outer magnets in the circumferential direction, the inner and outer salient poles being made of soft magnetic material; the stator comprises at least an inner stator located on a radially inner side of the rotor with a gap left between the inner stator and the rotor, and an outer stator located on a radially outer side of the rotor with a gap left between the outer stator and the rotor, wherein the inner stator comprises an inner stator core provided with a plurality of inner slots formed on an radially outer circumference of the inner stator at equal intervals in the circumference direction and a plurality of inner teeth formed on the radially outer circumference at equal intervals in the circumferential direction, the inner slots and the 5 inner teeth being aligned alternately in the circumferential direction; and an inner stator winding full-pitch wound at the inner stator core through the inner slots, the outer stator comprises an outer stator core provided with a plurality of outer slots formed on an radially inner circumference of the outer stator at equal intervals in the circumference direction and a plurality of outer teeth formed on the radially inner circumference at equal intervals in the circumferential direction, the outer slots and the outer teeth being aligned alternately in the circumferential direction; and an outer stator winding full-pitch wound at the outer stator core through the outer slots, wherein relationships of: 3. 5 <P 13/ P 6  (1) and P 7/ P 6 >0.5  (2) are met, where P 6 denotes a circumferential width of each of the outer salient poles, P 7 denotes a circumferential width of each of the inner salient poles, and P 13 denotes a circumferential width of each of the outer magnets. 2. The rotary electric machine of claim 1 , wherein the rotor core includes a rotor yoke which provides a magnetic path in common for both an outer magnetic circuit and an inner magnetic circuit through which magnetic fluxes from the outer stator and the inner stator pass, and a relationship of P 14/( P 6+ P 7) >0.8  (3) is met, where P 14 denotes a radial width of the rotor yoke at a pole center between each of the inner magnets and each of the outer magnets. 3. The rotary electric machine of claim 2 , wherein when the outer stator has an outer diameter of P 1 , a diameter between bottoms of two of the outer slots, which passes through a radial center of the outer stator, is P 2 , P 3 denotes a circumferential length obtained by multiplying a circumferential width of one of the outer teeth by the number of outer teeth contained in one magnetic pole of the outer stator, the rotor has an outer diameter of P 4 , each of the outer magnets has a radial thickness of P 5 , each of the inner magnets has a radial thickness of P 8 , the rotor has an inner diameter of P 9 , a diameter between bottoms of two of the inner slots, which passes through the radial center of the outer stator, is P 10 , P 11 denotes a circumferential length obtained by multiplying a circumferential width of one of the inner teeth by the number of inner teeth contained in one magnetic pole of the inner stator, and the inner stator has an inner diameter of P 12 , the dimensions P 1 to P 13 except for the dimensions P 6 , P 7 , and P 13 are set to meet dimensional ratios listed in a group H 2 of the following table 1, the dimensions P 6 and P 13 are set to meet both the dimensional ratios listed in the group H 2 of the table 1 and the relationships of 3.5 <P 13 /P 6 , and the dimensions of P 6 and P 7 are set to meet both the dimensional ratios listed in the group H 2 of the table 1 and the relationships of P 7 /P 6 <0.5: TABLE 1 Superior Torque characteristics Group H1 Group H2 P1: Outer-stator outer 1 diameter P2: Outer-stator inter-slot 0.936-0.966 0.928-0.974 diameter P3: Outer-stator-tooth width 0.0632-0.1016 0.0564-0.1128 (per pole) P4: Rotor outer diameter 0.846-0.884 0.835-0.895 P5: Outer-magnet thickness 0.0112-0.0207 0.0112-0.0226 P6: Outer-salient-pole 0.0112-0.0339 0.0075-0.0376 width P7: Inner-salient-pole width 0.0150-0.0489 0.0132-0.0489 P8: Inner-magnet thickness 0.0093-0.0207 0.0056-0.0207 P9: Rotor inner diameter 0.688-0.726 0.680-0.726 P10: Inner-stator inter-slot 0.579-0.636 0.575-0.636 diameter P11: Inner-stator-tooth 0.0316-0.0734 0.0278-0.0734 width (per pole) P