Stator for electric rotary machine and fabricating method of the same

The invention claimed is: 1. A stator for an electric rotary machine, the stator including: a stator core having plural slots; segmented coils of plural phases; a pair of base plates provided at both ends of the stator core; and insulation material, wherein the segmented coils have plural substantially-straight coil bars which are respectively inserted in the slots in the stator core, and plural connection coils which are disposed on the base plates so as to connect together the coil bars of the same phase to thereby make up spanning portions of the segmented coils, wherein the base plates are made of a non-magnetic material, and include plural grooves that are formed on surfaces of the base plates facing axial end faces of the stator core, wherein the coil bars are respectively disposed in the slots in the stator core, and each of the coil bars have a radially outer coil bar and a radially inner coil bar, wherein the insulation material comprises the radially outer coil bar and the radially inner coil bar, wherein the radially outer coil bar and the radially inner coil bar are integrally covered by the insulation material, and wherein the insulation material is interposed between the radially outer coil and the radially inner coil bar, wherein the connection coils are disposed in the plural grooves formed on the surfaces of the base plates so that the connection coils of the same phase are connected together while the connection coils of the different phases are insulated from each other, wherein insulation sheets are provided between the axial end faces of the stator core and the surfaces of the base plates, wherein each of the insulation sheets define a plurality of holes which are penetrated by the coil bars, wherein the stator core and the coil bars make up a stator core assembly and the base plates and the connection coils make up base plate assemblies, so that the stator is made up of the stator core assembly and the base plate assemblies which are disposed at both ends of the stator core assembly, and wherein the radially outer coil bar and the radially inner coil bar of each of the coil bars are configured to connect the base plate assemblies disposed at both ends of the stator core assembly to the stator core assembly. 2. The stator of claim 1 , wherein the coil bars and the connection coils are connected together by being press fitted or crimped together at both end portions thereof. 3. The stator of claim 1 , wherein the coil bars and the connection coils are connected together by being press fitted and crimped together at both end portions thereof. 4. The stator of claim 3 , wherein tapered portions are formed at both end portions of each coil bar, and tapered holes adapted to be fitted on the tapered portions are formed in the connection coils, and wherein the coil bars and the connection coils are respectively joined to each other simultaneously by press fitting the tapered portions in the tapered holes and thereafter crimping distal ends of the tapered portions by crushing them to be deformed. 5. The stator of claim 1 , wherein the connection coils are disposed to at least partially in a region where the stator core is projected in an axial direction. 6. The stator of claim 1 , wherein the spanning portions are at least partially exposed to axial end faces and are formed flush with the axial end faces, and wherein a cooling plate is provided on an outer side of at least one of the base plates so as to be in surface contact with the exposed spanning portions directly or indirectly. 7. The stator of claim 6 , wherein the radially outer coil bar and the radially inner coil bar are aligned in a radial direction, wherein the connection coils each includes an inner connection coil and an outer connection coil which are disposed in different axial positions, wherein the plural grooves are formed on an outer surface and an inner surface of each of the base plates, and the plural grooves on the outer surface and on the inner surface are opposite from each other, wherein the outer connection coils are disposed in the grooves which are formed on the outer surfaces and the inner connection coils are disposed in the grooves which are formed on the inner surfaces, and wherein one of the radially outer coil bar and the radially inner coil bar is connected to the outer connection coil at one end and is connected to the inner connection coil at the other end, and the other of the radially outer coil bar and the radially inner coil bar is connected to the inner connection coil at one end and is connected to the outer connection coil at the other end. 8. The stator of claim 1 , wherein the coil bars to be respectively inserted in the slots are each made integral by the insulation material. 9. The stator of claim 1 , wherein the coil bars covered by the insulation material are press fitted in the slots, respectively. 10. The stator of claim 1 , wherein the connection coils each includes an inner connection coil and an outer connection coil which are disposed in different axial positions, wherein the grooves are formed on an outer surface and an inner surface of each base plate which are opposite from each other, and wherein the outer connection coils are disposed in the grooves formed on the outer surface, while the inner connection coils are disposed in the grooves formed on the inner surface. 11. A fabrication method of a stator for an electric rotary machine, the stator including: a stator core having plural slots; segmented coils of plural phases; a pair of base plates which are provided at both ends of the stator core; and insulation material, wherein the segmented coils have plural substantially-straight coil bars which are respectively inserted in the slots in the stator core, and plural connection coils which are disposed on the base plates so as to connect together the coil bars of the same phase to thereby make up spanning portions of the segmented coils, the fabrication method including: forming a stator core assembly by respectively inserting the coil bars in the slots in the stator core; forming base plate assemblies by disposing the connection coils on the base plates; and assembling the base plate assemblies to both axial ends of the stator core assembly, wherein the base plates are made of a non-magnetic material, and include plural grooves that are formed on surfaces of the base plates facing axial end faces of the stator core, wherein the coil bars are respectively disposed in the slots in the stator core, and each of the coil bars have a radially outer coil bar and a radially inner coil bar, wherein the insulation material comprises the radially outer coil bar and the radially inner coil bar, wherein the radially outer coil bar and the radially inner coil bar are integrally covered by the insulation material, and wherein the insulation material is interposed between the radially outer coil and the radially inner coil bar, wherein the connection coils are disposed in the plural grooves formed on the surfaces of the base plates so that the connection coils of the same phase are connected together while the connection coils of the different phases are insulated from each other, wherein insulation sheets are provided between the axial end faces of the stator core and the surfaces of the base plates, wherein each of the insulation sheets define a plurality of holes which are penetrated by the coil bars, and wherein the radially outer coil bar and the radially inner coil bar of each of the coil bars are configured to connect the base plate assemblies assembled to both axial ends of the stator core assembly to the stator core assembly.