Electric motor with water jacket and oil-cooled stator and method for operation of the electric motor

The invention claimed is: 1. An electric drive unit, comprising: an electric motor including: a housing including a water jacket arranged therein; a stator including a plurality of stator laminations that are positioned within the housing; an oil inlet mounted to an outer wall of the housing via multiple fasteners; and a plurality of seals provided between the oil inlet and the housing; wherein the oil inlet extends radially outward from the outer wall; wherein the oil inlet extends through the outer wall, an inner wall of the housing, and the water jacket; wherein the plurality of stator laminations include a radial opening that is designed to: receive oil from the oil inlet; and direct oil to one or more oil ducts that axially extend through at least a portion of the plurality of stator laminations; wherein the inner wall is positioned radially inward from the water jacket and the outer wall is positioned radially outward from the water jacket; wherein a working fluid in the water jacket includes water and the working fluid in the oil inlet and the one or more oil ducts is oil; and wherein the water jacket is fluidly separated from the oil inlet and the one or more oil ducts. 2. The electric drive unit of claim 1 , wherein: the water jacket includes one or more coolant channels with an inner periphery defined by an outer surface of the inner wall; an inner surface of the inner wall is in face sharing contact with a peripheral surface of the stator; and the one or more oil ducts have a plurality of baffles. 3. The electric drive unit of claim 1 , further comprising a ring designed to receive the oil from the one or more oil ducts. 4. The electric drive unit of claim 3 , wherein the ring is a spray ring that includes an opening that directs the oil to an end winding in the stator. 5. The electric drive unit of claim 1 , wherein the electric motor does not include an external oil cooler. 6. The electric drive unit of claim 1 , wherein the one or more oil ducts include two ducts that extend from the radial opening in opposing axial directions. 7. The electric drive unit of claim 1 , further comprising a thermal interface material arranged between the plurality of stator laminations and the housing. 8. The electric drive unit of claim 1 , wherein a press-fit interface is formed between the housing and the stator. 9. The electric drive unit of claim 1 , wherein the electric motor is a traction motor in a vehicle. 10. A method for an electric motor-cooling system comprising: flowing a coolant which includes water through a water jacket in a housing that is directly coupled to a stator; flowing oil through an oil inlet that extends through the water jacket and an inner wall and an outer wall of the housing; flowing the oil from the oil inlet to one or more axially extending oil ducts that traverse at least a portion of a plurality of stator laminations; and thermally conducting heat from the oil to the water jacket through the inner wall in the housing; wherein the oil inlet extends radially outward from the outer wall; wherein the oil inlet is coupled to the outer wall via multiple fasteners; wherein the inner wall is positioned radially inward from the water jacket and the outer wall is positioned radially outward from the water jacket; wherein a working fluid in the water jacket includes water and the working fluid in the oil inlet and the one or more axially extending oil ducts is oil; wherein the water jacket is fluidly separated from the oil inlet and the one or more axially extending oil ducts; wherein a plurality of seals are provided between the oil inlet and the housing; and wherein the oil inlet extends through the outer wall, the inner wall, and the water jacket. 11. The method of claim 10 , further comprising: flowing the oil from the one or more axially extending oil ducts to a spray ring; and flowing the oil from the spray ring to an end winding through an opening in the spray ring. 12. The method of claim 11 , further comprising: collecting the oil from the end winding in an oil sump; flowing the oil from the oil sump to an oil pump; and flowing the oil directly from the oil pump to the oil inlet without passing through a heat exchanger. 13. The method of claim 10 , wherein flowing the oil from the oil inlet to the one or more axially extending oil ducts includes flowing the oil through a radial opening that extends through the housing and is positioned axially between two of the axially extending oil ducts. 14. An electric motor, comprising: a housing including a water jacket; a stator including a plurality of stator laminations with a peripheral surface that forms an interface with the housing; an oil inlet mounted to an outer wall of the housing via multiple fasteners; wherein the oil inlet extends through the outer wall, an inner wall of the housing, and the water jacket; and a plurality of seals provided between the oil inlet and the housing; wherein the plurality of stator laminations include a radial opening designed to: receive oil from the oil inlet; and direct the oil to a plurality of oil ducts axially extending through at least a portion of the plurality of stator laminations; wherein the plurality of oil ducts have a plurality of baffles; an oil sump coupled to the housing and configured to receive the oil from the plurality of oil ducts; and an oil pump including an inlet in fluidic communication with the oil sump; wherein an oil line extends directly from an outlet of the oil pump to the oil inlet; wherein the inner wall is positioned radially inward from the water jacket and the outer wall is positioned radially outward from the water jacket; wherein a working fluid in the water jacket includes water and the working fluid in the oil inlet and the plurality of oil ducts is oil; and wherein the water jacket is fluidly separated from the oil inlet and the plurality of oil ducts. 15. The electric motor of claim 14 , wherein the interface is a press-fit interface with a thermal interface material designed to reduce a thermal resistance of the interface. 16. The electric motor of claim 14 , wherein the plurality of baffles extend in radial directions.