Superconducting generator driven by a wind turbine

The invention claimed is: 1. A superconducting generator comprising: an annular armature connectable to rotate with a rotating component of a wind turbine; a stationary annular field winding coaxial to the armature and separated by a gap from the armature, wherein the field winding includes superconducting coils; a non-rotating support for the field winding, the non-rotating support comprising a torque tube, the torque tube comprised of: a plurality of segmented sections joined together; a flange located on at least one axial end of the torque tube; and wherein the torque tube is connected to a thermal shield casing or a field winding housing by a plurality of members separate from the flange and spaced apart circumferentially around the torque tube. 2. The superconducting generator of claim 1 , wherein the torque tube comprises a generally cylindrical shaped member. 3. The superconducting generator of claim 1 , wherein the torque tube comprises a frustoconical shaped member. 4. The superconducting generator of claim 1 , wherein the segmented sections are formed of a composite material, and the composite material is mixtures of or one of: a fiber reinforced plastic; an epoxy fiberglass laminate; a phenolic fiberglass laminate; a phenolic fiberglass with wound filaments; a polyester fiberglass laminate; a polyester fiberglass laminate with wound filaments; a polymide fiberglass laminate; a carbon epoxy; or a fiberglass epoxy laminate. 5. The superconducting generator of claim 4 , wherein the composite material has a hoop oriented fiber pattern with angles oriented at about 65 degrees to about 85 degrees. 6. The superconducting generator of claim 4 , wherein the composite material has a hoop oriented fiber pattern with angles oriented at about 75 degrees. 7. The superconducting generator of claim 1 , wherein the segmented sections each comprises a flat plate. 8. The superconducting generator of claim 1 , wherein the segmented sections each comprises an arcuate plate. 9. The superconducting generator of claim 1 , wherein the plurality of members separate from the flange and spaced apart circumferentially around the torque tube each comprises a straps. 10. The superconducting generator of claim 1 , wherein the plurality of members separate from the flange and spaced apart circumferentially around the torque tube comprises a space frame or a strut assembly. 11. A wind turbine comprising: a tower; a nacelle mounted on top of the tower; a hub connected to the nacelle and supported by the tower; a plurality of blades connected to the hub; a superconducting generator housed within the nacelle, the superconducting generator comprising: an annular armature connectable to rotate with the hub; a stationary annular field winding coaxial to the armature and separated by a gap from the armature, wherein the field winding includes superconducting coils; a non-rotating support for the field winding, the non-rotating support comprising a torque tube, the torque tube comprised of: a plurality of segmented sections joined together; a flange located on at least one axial end of the torque tube; and wherein the torque tube is connected to a thermal shield casing or a field winding housing by a plurality of members separate from the flange and spaced apart circumferentially around the torque tube. 12. The wind turbine of claim 11 , wherein the torque tube comprises a generally cylindrical shaped member. 13. The wind turbine of claim 11 , wherein the torque tube comprises a frustoconical shaped member. 14. The wind turbine of claim 11 , wherein the segmented sections are formed of a composite material, and the composite material is mixtures of or one of: a fiber reinforced plastic; an epoxy fiberglass laminate; a phenolic fiberglass laminate; a phenolic fiberglass with wound filaments; a polyester fiberglass laminate; a polyester fiberglass laminate with wound filaments; a polymide fiberglass laminate; a carbon epoxy; or a fiberglass epoxy laminate. 15. The wind turbine of claim 14 , wherein the composite material has a hoop oriented fiber pattern with angles oriented at about 65 degrees to about 85 degrees. 16. The wind turbine of claim 14 , wherein the composite material has a hoop oriented fiber pattern with angles oriented at about 75 degrees. 17. The wind turbine of claim 11 , wherein the segmented sections each comprises a flat plate. 18. The wind turbine of claim 11 , wherein the segmented sections each comprises an arcuate plate. 19. The wind turbine of claim 11 , wherein the plurality of members separate from the flange and spaced apart circumferentially around the torque tube comprises a straps. 20. The wind turbine of claim 11 , wherein the plurality of members separate from the flange and spaced apart circumferentially around the torque tube comprises a space frame or a strut assembly.