Automotive rotary electric machine and winding assembly manufacturing method that is used therefor

The invention claimed is: 1. An automotive rotary electric machine comprising: a metal housing that comprises a front bracket and a rear bracket; a rotor that is rotatably disposed inside said housing by being fixed to a shaft that is rotatably supported by said front bracket and said rear bracket; and a stator comprising: an annular stator core in which a plurality of slots that have an opening on an inner circumferential side are disposed at a predetermined pitch circumferentially, and that is disposed so as to surround said rotor so as to be held between said front bracket and said rear bracket; and a stator winding that is mounted into said stator core, said automotive rotary electric machine comprising: said stator winding is constituted by a plurality of wave windings that have a slot pitch that alternates between a slot pitch of (N−M) and a slot pitch of (N+M), where N is an integer that is greater than or equal to 2, and M is an integer that is greater than or equal to 1 and less than N; said plurality of wave windings are constituted by at least one winding assembly that is mounted into said stator core; and said winding assembly is produced by winding wires that are constituted by 2N continuous wires, and comprises: slot-housed portions that are housed inside each of said slots of said stator core so as to form pairs that line up in an inner layer and an outer layer relative to a slot depth direction; first return portions at a first axial end of said stator core that link end portions of said slot-housed portions that are housed in a first of said inner layer and said outer layer inside each of said slots and end portions of said slot-housed portions that are housed in a second of said inner layer and said outer layer inside said slots that are (N−M) slots away; and second return portions at a second axial end of said stator core that link end portions of said slot-housed portions that are housed in said second of said inner layer and said outer layer inside each of said slots and end portions of said slot-housed portions that are housed in said first of said inner layer and said outer layer inside said slots that are (N+M) slots away, two ends of said (N−M) wires projecting at said first axial end of said stator core, and two ends of said (N+M) wires projecting at said second axial end of said stator core. 2. The automotive rotary electric machine according to claim 1 , further comprising: a rectifying apparatus that is disposed rearward of said rotor, and that rectifies an alternating-current voltage that is generated in said stator into a direct-current voltage; and a voltage regulator that is disposed rearward of said rotor, and that adjusts magnitude of said alternating-current voltage that is generated in said stator, said winding assembly being mounted into said stator core such that said second return portions are oriented toward said rear bracket. 3. The automotive rotary electric machine according to claim 2 , wherein said rectifying apparatus and said voltage regulator are disposed axially outside said rear bracket. 4. The automotive rotary electric machine according to claim 1 , further comprising: a rectifying apparatus that is disposed rearward of said rotor, and that rectifies an alternating-current voltage that is generated in said stator into a direct-current voltage; and a voltage regulator that is disposed rearward of said rotor, and that adjusts magnitude of said alternating-current voltage that is generated in said stator, said winding assembly being mounted into said stator core such that said second return portions are oriented toward said front bracket. 5. The automotive rotary electric machine according to claim 4 , wherein said rectifying apparatus and said voltage regulator are disposed inside said rear bracket. 6. An automotive rotary electric machine winding assembly manufacturing method wherein: said winding assembly is produced by winding wires that are constituted by 2N continuous wires, where N is an integer that is greater than or equal to 2; pairs of rectilinear slot-housed portions that are disposed parallel to each other so as to line up in a thickness direction are arranged at a pitch of one slot; first return portions respectively link first longitudinal end portions of said slot-housed portions on first sides in a thickness direction of said pairs of said slot-housed portions and first longitudinal end portions of said slot-housed portions on second sides in said thickness direction of said pairs of straight slot-housed portions that are (N−M) slots away, where M is an integer that is greater than or equal to 1 and less than N; second return portions respectively link second longitudinal end portions of said slot-housed portions on said second sides in said thickness direction of said pairs of said slot-housed portions and second longitudinal end portions of said slot-housed portions on first sides in said thickness direction of said pairs of straight slot-housed portions that are (N+M) slots away; two ends of said (N−M) wires project outward near said first return portions at two ends in a direction of arrangement of said pairs of said slot-housed portions; and two ends of said (N+M) wires project outward near said second return portions at two ends in a direction of arrangement of said pairs of said slot-housed portions, said automotive rotary electric machine winding assembly manufacturing method comprising: a winding step in which a winding assemblage is produced by winding said (N−M) wires and said (N+M) wires simultaneously such that: wires that are formed into a bent shape that repeats a pattern are arranged in a direction of repetition of said pattern at a uniform pitch, said pattern being constituted by: a first bent portion; a second bent portion; a first rectilinear portion that extends obliquely from said second bent portion toward said first bent portion to link both; and a second rectilinear portion that extends obliquely from said first bent portion toward said second bent portion to link both, said two ends of said (N−M) wires respectively project outward near said first bent portions at two ends in a direction of arrangement of said wires; and said two ends of said (N+M) wires respectively project outward near said second bent portions at two ends in said direction of arrangement of said wires; and a displacing step in which each of said first rectilinear portions is gripped by a first blade and each of said second rectilinear portions is gripped by a second blade such that longitudinally central portions of regions of said first rectilinear portions that are gripped by said first blades and regions of said second rectilinear portions that are gripped by said second blades are positioned on a line segment that connects intersecting portions of said wires that are positioned at two ends in said direction of arrangement of said wires on said winding assemblage, and then said first blades and said second blades are pivoted in reverse directions to each other using said longitudinally central portions of said regions of said first rectilinear portions that are gripped by said first blades and said regions of said second rectilinear portions that are gripped by said second blades as pivoting centers to displace said gripped regions of said first rectilinear portions and said gripped regions of said second rectilinear portions so as to be parallel to each other.