Laminated core manufacturing method

The invention claimed is: 1. A laminated core manufacturing method of manufacturing a laminated core by linearly arranging and punching out a plurality of separate core pieces each formed of a back yoke portion and a magnetic-pole teeth portion protruding from the back yoke portion followed by stacking and die-cut caulking, the manufacturing method comprising: a first step of punching out a first region located on an opposite side to the magnetic-pole teeth portion between adjacent ends of the back yoke portions of the core pieces; a second step of punching out a second region located on a side of the magnetic-pole teeth portion between the adjacent ends of the back yoke portions of the core pieces, the second region having a shape of an area defined by edges of adjacent magnetic-pole teeth portions, to form the magnetic-pole teeth portion; and a third step of punching out a third region and a fourth region that bring the first region punched out in the first step and the second region punched out in the second step into communication, the third region and the fourth region being curved regions that curve in opposite directions from each other. 2. The laminated core manufacturing method according to claim 1 , wherein: the adjacent ends of the back yoke portions of the plurality of core pieces are provided with substantially convex portions at one ends and substantially concave portions at the other ends, which are formed in such a manner that the substantially convex portions at one ends of the core pieces and the substantially concave portions at the other ends of the core pieces abut against each other. 3. The laminated core manufacturing method according to claim 2 , wherein: the laminated core is manufactured by alternately stacking a first core member formed by sequentially arranging the core pieces provided with the back yoke portions having the substantially convex portions at one ends and the substantially concave portions at the other ends, and a second core member formed by sequentially arranging the core pieces provided with the back yoke portions having the substantially concave portions at positions corresponding to positions at which the core pieces of the first core member have the substantially convex portions and the substantially convex portions at positions corresponding to positions at which the core pieces of the first core member have the substantially concave portions. 4. The laminated core manufacturing method according to claim 3 , wherein: the substantially convex portions are provided with connection means for connecting edge portions of the respective core pieces that lie adjacent to each other in a stacking direction. 5. The laminated core manufacturing method according to claim 4 , wherein: a shape of the first region punched out in the first step is symmetrical with respect to a straight line parallel to a protruding direction of the magnetic-pole teeth portion and passing a rotation center of the connection means. 6. The laminated core manufacturing method according to claim 4 , wherein: a rotation center of the connection means is provided so as to be located on a more outer peripheral side than a rotation center of the substantially convex portions. 7. The laminated core manufacturing method according to claim 3 , wherein: in the step of punching out the third region and the fourth region that bring the first region and the second region into communication, a punching width is at least equal to a plate thickness of the core pieces. 8. The laminated core manufacturing method according to claim 2 , wherein: the substantially convex portions are provided with connection means for connecting edge portions of the respective core pieces that lie adjacent to each other in a stacking direction. 9. The laminated core manufacturing method according to claim 8 , wherein: a shape of the first region punched out in the first step is symmetrical with respect to a straight line parallel to a protruding direction of the magnetic-pole teeth portion and passing a rotation center of the connection means. 10. The laminated core manufacturing method according to claim 8 , wherein: a rotation center of the connection means is provided so as to be located on a more outer peripheral side than a rotation center of the substantially convex portions. 11. The laminated core manufacturing method according to claim 2 , wherein: in the step of punching out the third region and the fourth region that bring the first region and the second region into communication, a punching width is at least equal to a plate thickness of the core pieces. 12. The laminated core manufacturing method according to claim 2 , wherein: a shape of the back yoke portions is such that no step is produced on an outer peripheral side where the ends of the back yoke portions abut against each other in a state in which a plurality of the core pieces are sequentially arranged in an annular shape or an arc shape. 13. The laminated core manufacturing method according to claim 1 , wherein: in the step of punching out the third region and the fourth region that bring the first region and the second region into communication, a punching width is at least equal to a plate thickness of the core pieces. 14. The laminated core manufacturing method according to claim 1 , wherein: the first step of punching out the first region is performed with the third step of punching out the third region and the fourth region that bring the first region and the second region into communication. 15. The laminated core manufacturing method according to claim 1 , wherein: the second step of punching out the second region is performed with a punch that punches out the third region and the fourth region that bring the first region and the second region into communication. 16. The laminated core manufacturing method according to claim 1 , wherein: the first step of punching out the first region is performed with a step of punching out and stacking the core pieces. 17. The laminated core manufacturing method according to claim 1 , wherein the first region is an outer peripheral side notch portion; the third region and the fourth region form a convex portion and a concave portion at the adjacent ends of the back yoke portions of the core pieces; and the method includes a fourth step of forming a rotation shaft portion in the convex portion, wherein the outer peripheral side notch portion is of a symmetrical shape with respect to a straight line that passes the rotation shaft portion and that is parallel to the magnetic-pole teeth.