Electrical machine housing and methods of assembling the same

What is claimed is: 1. A housing for an electrical machine having a rotation axis, a rotor assembly including a rotor, and a controller assembly, the rotor assembly including at least one bearing assembly, said housing comprising: an endshield comprising an annular center section comprising a bore sized to couple to the at least one bearing assembly; and a cover coupled to said endshield and comprising: a generally axially-extending flange wall formed about a perimeter of said cover; a volute-shaped inner chamber configured to at least partially enclose the rotor coupled to the rotor assembly of the electrical machine; a cooling channel positioned radially outward from said inner chamber, said cooling channel configured to at least partially enclose the controller assembly of the electrical machine; and a volute-shaped curved wall that extends axially from an inner surface of said cover, said curved wall at least partially defining said inner chamber and said cooling channel. 2. The housing in accordance with claim 1 , wherein said cover further comprises an air outlet portion formed at an end of said cooling channel to provide open communication between said cooling channel and an environment exterior to said cover. 3. The housing in accordance with claim 2 , wherein said air outlet opening comprises at least one through-opening disposed in directional alignment with a path of airflow through said cover. 4. The housing in accordance with claim 3 , wherein said at least one through-opening comprises at least one elongate slot disposed in said flange wall. 5. The housing in accordance with claim 1 , wherein said cooling channel comprises a volute-shaped cooling channel. 6. The housing in accordance with claim 1 , wherein said cover further comprises an annular intake opening formed substantially concentric with the rotation axis of the electrical machine. 7. The housing in accordance with claim 6 , wherein said annular intake opening comprises a latticework extending across said intake opening to form an open framework of material configured to enable air to pass through. 8. The housing in accordance with claim 1 , wherein said curved wall extends circumferentially about the rotation axis of the electrical machine forming an increasing expansion angle for airflow. 9. An electrical machine comprising: a rotor assembly comprising a rotor coupled to a rotor shaft defining a rotation axis, said rotor assembly further comprising at least one bearing assembly; a stator assembly comprising a stator core and a plurality of windings; a housing comprising an endshield comprising an annular center section comprising a bore sized to couple to the at least one bearing and a cover coupled to said endshield, said cover comprising: a generally axially-extending flange wall formed about a perimeter of said cover; a volute-shaped inner chamber configured to at least partially enclose said rotor of said rotor assembly; a cooling channel positioned radially outward from said inner chamber, said cooling channel configured to at least partially enclose a controller assembly of said electrical machine; and a volute-shaped curved wall that extends axially from an inner surface of said cover, said curved wall at least partially defining said inner chamber and said cooling channel; and a controller assembly coupled to said housing, wherein said controller assembly is positioned radially outward from said rotor and located in said cooling channel. 10. The electrical machine in accordance with claim 9 , wherein said rotor is disk-shaped and has a diameter that is less than a minimum radius of said curved wall. 11. The electrical machine in accordance with claim 9 , wherein said rotor comprises a first surface substantially perpendicular to the rotation axis, and a plurality of blades formed on said first surface and extending axially from said first surface. 12. The electrical machine in accordance with claim 11 , wherein each blade of said plurality of blades is substantially straight and extends substantially radially from the rotation axis. 13. The electrical machine in accordance with claim 11 , wherein each blade of said plurality of blades comprises one of a backward inclined blade, a backward curved blade, a forward inclined blade, a forward curved blade, and an airfoil-shaped blade. 14. The electrical machine in accordance with claim 9 , wherein said cooling channel comprises a volute-shaped cooling channel. 15. The electrical machine in accordance with claim 9 , wherein said rotor comprises at least one axially-extending opening disposed adjacent a hub portion of said rotor, wherein said at least one opening is configured to enable air to pass through said rotor during operation of said electrical machine. 16. The electrical machine in accordance with claim 15 , wherein said at least one opening comprises a plurality of openings equi-spaced about the hub portion of said rotor. 17. The electrical machine in accordance with claim 15 , wherein a radially outer edge of said at least one opening generally corresponds to a radially inner edge of an opening formed in said stator assembly. 18. A method of assembling an electrical machine, said method comprising: providing an endshield including an annular center section having a bore sized to couple to at least one bearing assembly; coupling a rotor assembly to the endshield to enable rotation of the rotor assembly with respect to the endshield, the rotor assembly including the at least one bearing assembly and a rotor having a plurality of blades formed thereon; providing a cover including a generally axially-extending flange wall formed about a perimeter of the cover, a volute-shaped inner chamber configured to at least partially enclose the rotor, a cooling channel positioned radially outward from the inner chamber, and a volute-shaped curved wall that extends axially from an inner surface of the cover, the curved wall at least partially defining the inner chamber and the cooling channel; and coupling the cover to the endshield to substantially enclose the rotor therein. 19. The method in accordance with claim 18 , further comprising coupling a controller assembly to the cover, wherein the controller assembly is positioned radially outward from the rotor and is located in the cooling channel, wherein the curved wall is configured to substantially isolate the rotor from the controller assembly within the cover.