Wedge for stator having overmolded insulation

What is claimed is: 1. A stator for use in an electric motor, said stator comprising: a circumferentially continuous annular core including a plurality of arcuately spaced apart teeth, each of said teeth including a generally radial leg and a head projecting from the leg to present a pair of arcuately spaced apart head ends, with a slot opening being defined between the opposed head ends of each adjacent pair of teeth; a plurality of stator wedges, each of said wedges including first and second locking plates that cooperatively present wedge surfaces facing generally radially opposite directions; and an electrically insulative overmolding molded over at least a portion of the core, said overmolding defining a plurality of wedge-retaining structures, each being at least in part fixed relative to the core and cooperating with a respective one of the wedges to compressibly retain the respective wedge between the head ends defining the corresponding slot opening, each of said wedge-retaining structures including a pair of walls, each of said walls projecting into the corresponding slot opening from a respective one of the head ends, said walls being spaced apart from one another to define an axially extending gap therebetween, each of said wedges being axially received within a corresponding one of the gaps, with the wedge cooperating with the corresponding wedge-retaining structure to prevent radial and axial movement of the wedge relative to the core, said walls presenting radially opposite inner and outer faces, each of which engages a respective one of the wedge surfaces of the corresponding wedge to restrict relative radial movement between the wedge-retaining structure and the corresponding wedge. 2. The stator as claimed in claim 1 , said overmolding defining the wedges. 3. The stator as claimed in claim 1 , said walls presenting axially oppositely facing shoulders along the gap, each of said wedges including projections configured to engage respective ones of the shoulders to restrict relative axial movement between the wedge-retaining structure and the respective wedge. 4. The stator as claimed in claim 3 , said walls defining a constricted region of the gap opening, said shoulders being defined at opposite ends of the constricted region, said projections having a circumferential dimension greater than that of the constricted region of the gap. 5. The stator as claimed in claim 1 , each of said walls presenting a first wall end and an axially opposite second wall end, each of said wedges including a catch adjacent a first axial wedge end thereof, said catch being configured to latchingly engage at least one of the first wall ends. 6. The stator as claimed in claim 5 , said catch including a pair of tabs each engaging a respective one of the first wall ends. 7. The stator as claimed in claim 5 , each of said wedges including an end plate adjacent a second wedge end thereof, said end plate being configured to engage at least one of the second wall ends. 8. The stator as claimed in claim 5 , said end plate being at least substantially perpendicular to the locking plates. 9. The stator as claimed in claim 1 , said core being formed from a helically wound stator lamination. 10. The stator as claimed in claim 1 , said inner and outer faces being defined on each of the walls, such that each of the wedge surfaces engages both of the walls.