Synchronous reluctance motor having radial-direction widths slit configuration on a q-axis for improved power factor

The invention claimed is: 1. A synchronous reluctance motor, comprising: a rotor configured by fixing a rotor core to a shaft, and with a stator having winding, said rotor and said stator being disposed rotatably relative to each other across a magnetic gap, wherein said rotor core has as many flux barriers in a circumferential direction as a number of poles, said flux barriers being formed through alternate juxtaposition of one or more slits and core layers in a radial direction; rotation of said synchronous reluctance motor is controlled through energization of said winding with current of a phase having a lead angle from a d-axis being set to a current carrying phase β; when a ratio k is set to a ratio between a total sum of radial-direction widths of said slits on a q-axis and a magnetic gap length, among said core layers, a radial-direction width, on the q-axis, of the core layer that lies at a position closest in the circumferential direction to a point P at which there intersects an outer periphery of said rotor and a straight line passing through a rotor center and drawn at an angle ψ=arctan(tan β/1+0.2k)) from the d-axis, is larger than radial-direction widths of the other core layers on the q-axis; and said ratio k is set to a value higher than 34 and lower than 67. 2. The synchronous reluctance motor of claim 1 , wherein said current carrying phase β is set to lie in a range from 66° to 75°. 3. The synchronous reluctance motor of claim 1 , wherein said current carrying phase β inset to a value larger than 0° and smaller than 90°. 4. The synchronous reluctance motor of claim 1 , wherein said current carrying phase β is set to lie in a range from 56° to 85°. 5. The synchronous reluctance motor of claim 1 , wherein said current carrying phase β is set to lie in a range from arctan(1±0.2k)−5 (°) to arctan(1±0.2k)±5 (°). 6. The synchronous reluctance motor of claim 1 , wherein said rotor core is formed through stacking of thin steel sheets in an axial direction of said shaft. 7. The synchronous reluctance motor of claim 6 , wherein said rotor core is formed using a plurality of rotor core assemblies, each formed through stacking of rotor core sheets in which rolling directions of said thin steel sheets are aligned, said rotor core assemblies being stacked rotating the rolling directions of respective rotor core assemblies by identical angles. 8. The synchronous reluctance motor of claim 7 , wherein a number of said rotor core assemblies is a natural number multiple of a factor of a number of poles of said rotor core. 9. The synchronous reluctance motor of claim 7 , wherein a number of said rotor core assemblies is a natural number multiple of a number of poles of said rotor core. 10. The synchronous reluctance motor of claim 7 , wherein at least one crimp formed per pole is formed in the core layer lying at a position that is closest, in the circumferential direction, to said point P at which there intersect the outer periphery of said rotor and the straight line passing through the rotor center and drawn at said angle ψ from the d-axis. 11. The synchronous reluctance motor of claim 6 , wherein a radial direction width of a bridge that is formed between said slits and the outer periphery of said rotor core is equal to or smaller than twice a sheet thickness of said thin steel sheets. 12. The synchronous reluctance motor of claim 1 , wherein said angle ψ is set to a value higher than 15 and lower than 20.