Electric machine with helical cooling path

What is claimed is: 1. An electric machine comprising: a stator core including a plurality of stacked laminations, the laminations being arranged in sets that each define four circumferentially extending slots through a thickness of the set, wherein each of the slots is diametrically opposite another one of the slots, and all of the slots have a same arc length, wherein the sets are circumferentially rotated relative to each other in sequence such that each of the slots only partially overlaps with one or more adjacent ones of the slots to form a continuous helical cooling path around the stator core, wherein an amount of circumferential rotation between adjacent ones of the laminations is greater than the arc length divided by two and less than the arc length; and windings supported on the stator core. 2. The electric machine of claim 1 , wherein the circumferential rotation of the sets is less than arc lengths of the slots so that the slots partially overlap. 3. The electric machine of claim 1 , wherein the circumferential rotation is in a forward direction of the helical cooling path. 4. The electric machine of claim 1 , wherein each of the sets includes one or more laminations. 5. The electric machine of claim 4 , wherein each of the sets includes at least two laminations. 6. The electric machine of claim 1 , wherein each of the sets defines another circumferentially extending slot through the thickness of the set, wherein the sets are circumferentially rotated relative to each other in sequence such that each of the another slots only partially overlaps with adjacent ones of the another slots to form a second continuous helical cooling path around the stator core. 7. The electric machine of claim 1 , wherein the slots are notches located on an outer diameter of the stator core. 8. The electric machine of claim 7 further comprising a housing defining an inner circumferential surface, wherein the stator core is disposed within the housing such that the notches cooperate with the inner circumferential surface of the housing to define the helical cooling path. 9. The electric machine of claim 1 , wherein each of the sets are circumferentially rotated by a same amount. 10. The electric machine of claim 1 further comprising a rotor supported for rotation within the stator. 11. An electric machine comprising: a stator core including a plurality of lamination sets each having at least two circumferentially extending notches though a thickness of the lamination set, wherein the lamination sets are circumferentially rotated relative to each other in a continuous, forward sequence such that each of the notches partially overlaps with one or more adjacent ones of the notches to form two continuous helical cooling paths around the stator core, wherein, for each lamination set, a pair of the at least two notches are diametrically opposite each other, wherein each of the lamination sets is circumferentially rotated relative to adjacent ones of the lamination sets so that the notches are circumferentially staggered by an angle that is less than an arc length of the notches and greater than the arc length divided by two. 12. The electric machine of claim 11 , wherein each of the lamination sets includes one or more laminations. 13. The electric machine of claim 11 , wherein an amount of circumferential rotation between adjacent ones of the lamination sets is less than the arc length of the notches. 14. The electric machine of claim 11 further comprising a housing defining an inner circumferential surface, wherein the stator core is disposed within the housing such that the notches cooperate with the inner circumferential surface of the housing to define the helical cooling paths. 15. The electric machine of claim 11 , wherein the stator core defines axially extending slots, and further comprising windings disposed in the axially extending slots. 16. The electric machine of claim 11 , wherein the at least two notches are four notches. 17. An electric machine comprising: a stator core including a plurality of lamination sets each having at least two circumferentially extending notches though a thickness of the lamination set, wherein the lamination sets are circumferentially rotated relative to each other in a continuous, forward sequence such that each of the notches partially overlaps with one or more adjacent ones of the notches to form two continuous helical cooling paths around the stator core, wherein, for each lamination set, a pair of the at least two notches are diametrically opposite each other, wherein the circumferential rotation of the lamination sets is less than arc lengths of the notches so that the slots partially overlap, wherein the circumferential rotation of the lamination sets is the same for all lamination sets, the arc lengths all have a same value, and the circumferential rotation of the lamination sets is greater than the arc length divided by two. 18. A method of assembling a stator core comprising: forming laminations each having at least two circumferentially extending slots through a thickness of the lamination, wherein the slots are diametrically opposing; stacking the laminations such that each lamination is circumferentially rotated relative to neighboring ones of the laminations so that the slots are circumferentially staggered by an angle that is less than an arc length of the slots and greater than the arc length divided by two such that the slots partially overlap to define a pair of helical cooling paths; and joining the laminations to form the stator core. 19. The method of claim 18 , wherein the slots are notches located on outer diameters of the laminations.