Axial Gap Polyphase Motor, Stator for Use Therein, and Method for Producing Stator

1 . An axial gap polyphase motor comprising: a stator; and a rotor arranged on the same axis as the stator across a gap, the stator including: a layered stator core having a plurality of core portions arranged at equal spacing in the circumferential direction and protruding in the axial direction, and a plurality of supporting portions connecting and supporting the adjacent core portions; coils wound onto the core portions; and fastening members made of conductive material, wherein only the core portions onto which are wound the coils for flow of electric current of a single phase from among the multiple phases or the supporting portions connecting and supporting the core portions and the next core portions onto which are wound the coils for flow of electric current of the next phase have first apertures in the radial direction, wherein the fastening members are inserted into the first apertures. 2 . The axial gap polyphase motor according to claim 1 , wherein the supporting portions and the first apertures are arranged on a plane perpendicular to the axis of the stator. 3 . The axial gap polyphase motor according to claim 2 , wherein the supporting portions and the first apertures are arranged on the plane passing through the centers in the axial direction of the core portions. 4 . The axial gap polyphase motor according to claim 2 , wherein the stator has an annular portion arranged on the outer circumference of the layered stator core, wherein the annular portion has second apertures communicating with the first apertures, wherein the fastening members are inserted into the first apertures and the second apertures communicating with the first apertures. 5 . The axial gap polyphase motor according to claim 4 , wherein the layered stator core is integrally formed with the annular portion by punching and taking up a magnetic thin plate. 6 . A stator for use in an axial gap polyphase motor comprising: a layered stator core having a plurality of core portions arranged at equal spacing in the circumferential direction and protruding in the axial direction, and a plurality of supporting portions connecting and supporting the adjacent core portions; coils wound onto the core portions; and fastening members made of conductive material, wherein only the core portions onto which are wound the coils for flow of electric current of a single phase from among the multiple phases or the supporting portions connecting and supporting the core portions and the next core portions onto which are wound the coils for flow of electric current of the next phase have first apertures in the radial direction, wherein the fastening members are inserted into the first apertures. 7 . A method for producing a stator comprising: feeding a magnetic thin plate extending in a belt shape, in the longer side direction; forming cutouts at both ends of the magnetic thin plate in the shorter side direction and at predetermined spacing in the longer side direction, core portions between the cutouts adjacent in the longer side direction, and supporting portions between the cutouts adjacent in the shorter side direction; forming first apertures only in the core portions onto which are wound coils for flow of electric current of a single phase from among the multiple phases or the supporting portions connecting and supporting the core portions and the next core portions onto which are wound the coils for flow of electric current of the next phase; taking up the magnetic thin plate so as to penetrate the first apertures therethrough in the radial direction; inserting fastening members into the first apertures in the radial direction while the magnetic thin plate is taken up; and winding the coils for flow of electric current of the respective phases onto the core portions. 8 . The method according to claim 7 , further comprising forming a belt-shaped portion by controlling the feeding amount of the magnetic thin plate so that the feeding amount of the magnetic thin plate is smaller than width τp of the cutouts.