Rotary electric machine and method for manufacturing an armature that is used in the rotary electric machine

The invention claimed is: 1. A rotary electric machine comprising an armature that is formed by mounting an armature winding to an annular armature core, wherein: a first winding body and a second winding body are each configured so as to have a helical shape in which end portions of rectilinear portions are linked by coil ends, by winding a jointless, continuous conductor wire that is coated with insulation for m turns, where m is a natural number that is greater than or equal to two; a two-lane winding body is configured by assembling said first winding body and said second winding body such that orbiting portions that are constituted by said rectilinear portions and said coil ends of said first winding body overlap entirely in a radial direction with corresponding orbiting portions that are constituted by said rectilinear portions and said coil ends of said second winding body; said armature winding is configured by mounting said two-lane winding bodies into respective pairs of slots of said armature core that are separated by a predetermined number of slots; said coil ends include a top portion that displaces by a predetermined amount in a radial direction at an approximately central portion between said linked rectilinear portions; and said radial displacement at said top portion is approximately a×d, where a is a natural number that is greater than or equal to 2 and less than or equal to 2×(m−1), and d is a radial thickness of said rectilinear portions that are housed inside said slots, 4×m of said rectilinear portions of two of said two-lane winding bodies being housed inside said slots so as to line up in single columns in a radial direction. 2. The rotary electric machine according to claim 1 , wherein a plurality of terminals that constitute an electric power supplying portion and a neutral point of said armature winding each protrude at a first axial end of said armature winding from a radially outer side or a radially inner side and are arranged in a single row circumferentially. 3. A method for manufacturing an armature for the rotary electric machine according to claim 2 , wherein said two-lane winding body is produced by bending and forming two of said conductor wires simultaneously so as to be stacked together to assemble said first winding body and said second winding body. 4. A method for manufacturing an armature for the rotary electric machine according to claim 2 , wherein said method for manufacturing an armature comprises steps of: producing said first winding body and said second winding body separately; and mounting said second winding body inside said first winding body by inserting an orbiting portion of said second winding body that is positioned at a first end in a direction of arrangement of said rectilinear portions between two orbiting portions of said first winding body that are positioned at a second end in said direction of arrangement of said rectilinear portions, and then rotating said second winding body. 5. The rotary electric machine according to claim 1 , wherein: winding ends of said first winding bodies each extend circumferentially inward relative to said first winding bodies after emerging from said slots at a first axial end, and winding ends of said second winding bodies are configured so as to extend circumferentially outward relative to said second winding bodies after emerging from said slots at said first axial end; and end portions of said winding ends of said second winding bodies of said two-lane winding bodies are configured so as to be stacked radially together with end portions of said winding ends of said first winding bodies of other two-lane winding bodies that are positioned in a direction of extension of said winding ends. 6. The rotary electric machine according to claim 5 , wherein a plurality of terminals that constitute an electric power supplying portion and a neutral point of said armature winding each protrude at a first axial end of said armature winding from a radially outer side or a radially inner side and are arranged in a single row circumferentially. 7. A method for manufacturing an armature for the rotary electric machine according to claim 6 , wherein said two-lane winding body is produced by bending and forming two of said conductor wires simultaneously so as to be stacked together to assemble said first winding body and said second winding body. 8. A method for manufacturing an armature for the rotary electric machine according to claim 6 , wherein said method for manufacturing an armature comprises steps of: producing said first winding body and said second winding body separately; and mounting said second winding body inside said first winding body by inserting an orbiting portion of said second winding body that is positioned at a first end in a direction of arrangement of said rectilinear portions between two orbiting portions of said first winding body that are positioned at a second end in said direction of arrangement of said rectilinear portions, and then rotating said second winding body. 9. The rotary electric machine according to claim 5 , wherein connection of winding ends of said first winding bodies and said second winding bodies is completed on a radially outer side and a radially inner side of said armature winding. 10. The rotary electric machine according to claim 9 , wherein a plurality of terminals that constitute an electric power supplying portion and a neutral point of said armature winding each protrude at a first axial end of said armature winding from a radially outer side or a radially inner side and are arranged in a single row circumferentially. 11. A method for manufacturing an armature for the rotary electric machine according to claim 10 , wherein said two-lane winding body is produced by bending and forming two of said conductor wires simultaneously so as to be stacked together to assemble said first winding body and said second winding body. 12. A method for manufacturing an armature for the rotary electric machine according to claim 10 , wherein said method for manufacturing an armature comprises steps of: producing said first winding body and said second winding body separately; and mounting said second winding body inside said first winding body by inserting an orbiting portion of said second winding body that is positioned at a first end in a direction of arrangement of said rectilinear portions between two orbiting portions of said first winding body that are positioned at a second end in said direction of arrangement of said rectilinear portions, and then rotating said second winding body. 13. A method for manufacturing an armature for the rotary electric machine according to claim 9 , wherein said two-lane winding body is produced by bending and forming two of said conductor wires simultaneously so as to be stacked together to assemble said first winding body and said second winding body. 14. A method for manufacturing an armature for the rotary electric machine according to claim 9 , wherein said method for manufacturing an armature comprises steps of: producing said first winding body and said second winding body separately; and mounting said second winding body inside said first winding body by inserting an orbiting portion of said second winding body that is positioned at a first end in a direction of arrangement of said rectilinear portions between two orbiting portions of said first winding body that are positioned at a second end in said direction of arrangement of said rectilinear portions, and then rotating said second winding body. 15. A method for manufacturing an armature for the r