Electrical machine having cooling features

What is claimed is: 1. An electrical machine rotor, comprising: a rotor for electromagnetic cooperation with a stator of an electrical machine and structured to rotate about an axis of rotation, the electrical machine including a casing extending between opposite first and second end plates, the casing configured to house the stator and the rotor along with a shaft extending from the rotor and a bearing structured to radially support the shaft and the rotor, wherein the rotor extends along the axis of rotation and includes a first cooling passage extending therethrough and having a first cooling fluid inlet port disposed at a first axial location along the axis of rotation at or adjacent a first end face of the rotor, the first cooling passage also having a first cooling fluid discharge port in fluid communication with the first cooling fluid inlet port and disposed radially outward of the first cooling fluid inlet port at a second axial location at or adjacent a second end face of the rotor opposite the first end face, the second axial location being spaced apart from the first axial location in a first axial direction along the axis of rotation, wherein the first cooling passage removes heat from the rotor during rotation of the rotor, wherein the rotor includes a second cooling passage extending therethrough and having a second cooling fluid inlet port disposed at a third axial location along the axis of rotation at or adjacent the second end face of the rotor, the second cooling passage also having a second cooling fluid discharge port in fluid communication with the second cooling fluid inlet port and disposed radially outward of the second cooling fluid inlet port at a fourth axial location at or adjacent the first end face of the rotor, the fourth axial location being spaced apart from the third axial location in a second axial direction along the axis of rotation that is opposite the first axial direction, wherein the second cooling passage removes heat from the rotor during rotation of the rotor, the inlet ports at each of the first and second end faces being in communication with respective inlets through the casing with respective first and second cooling fluid supply passages in communication with respective ones of the inlet ports at respective ones of the first and second end faces, the first and second cooling fluid supply passages being defined between the rotor, the shaft, a respective one of first and second flow guides extending from the respective ones of the first and second end faces and the respective one of the first and second end plates, and the discharge ports at each of the first and second end faces being in communication with respective outlets through the casing with respective first and second cooling fluid exhaust passages in communication with respective ones of the discharge ports at respective ones of the first and second end faces, the first and second cooling fluid exhaust passages being defined outside the motor between the rotor, the stator, and the respective one of the first and second flow guides. 2. The electrical machine rotor of claim 1 , wherein the first cooling passage extends linearly between the first cooling fluid inlet port and the first cooling fluid discharge port. 3. The electrical machine rotor of claim 1 , further comprising a rotating and/or stationary guide vane disposed adjacent to the first cooling fluid inlet port, wherein the guide vane is configured to increase fluid pressure at the first cooling fluid inlet port. 4. The electrical machine rotor of claim 1 , further comprising a rotating and/or stationary guide vane disposed adjacent to the first cooling fluid discharge port wherein the guide vane is configured to decrease fluid pressure at the first cooling fluid discharge port. 5. The electrical machine rotor of claim 1 , wherein the first and fourth axial positions are substantially the same axial position, and wherein the second and third axial positions are substantially the same axial position. 6. The electrical machine rotor of claim 1 , wherein the first cooling fluid inlet port and the second cooling fluid discharge port are each disposed at the first end face; and wherein the second cooling fluid inlet port and the first cooling fluid discharge port are each disposed at the second end face. 7. The electrical machine rotor of claim 1 , wherein the first cooling fluid inlet port and the first cooling fluid discharge port are disposed at different circumferential positions; and wherein the second cooling fluid inlet port and the second cooling fluid discharge port are disposed at different circumferential positions. 8. The electrical machine rotor of claim 1 , wherein the rotor is an induction machine rotor or a synchronous machine rotor. 9. An electrical machine, comprising: a stator; a rotor in electromagnetic cooperation with the stator; a shaft extending from the rotor; a bearing structured to radially support the shaft and the rotor; a casing extending between opposite first and second end plates, the casing configured to house the stator, the rotor, the shaft, and the bearing; and wherein the shaft is structured to support the rotor and to rotate about an axis of rotation; wherein the rotor extends along the axis of rotation and includes a first cooling passage extending therethrough and having a first cooling fluid inlet port disposed at a first axial location along the axis of rotation at or adjacent a first end face of the rotor, the first cooling passage also having a first cooling fluid discharge port in fluid communication with the first cooling fluid inlet port and disposed radially outward of the first cooling fluid inlet port at a second axial location at or adjacent a second end face of the rotor opposite the first end face, the second axial location being spaced apart from the first axial location in a first axial direction along the axis of rotation, wherein the first cooling passage removes heat from the rotor during rotation of the rotor, wherein the rotor includes a second cooling passage extending therethrough and having a second cooling fluid inlet port disposed at a third axial location along the axis of rotation at or adjacent the second end face of the rotor, the second cooling passage also having a second cooling fluid discharge port in fluid communication with the second cooling fluid inlet port and disposed radially outward of the second cooling fluid inlet port at a fourth axial location at or adjacent the first end face of the rotor, the fourth axial location being spaced apart from the third axial location in a second axial direction along the axis of rotation that is opposite the first axial direction, wherein the second cooling passage removes heat from the rotor during rotation of the rotor, and further comprising first and second flow guides extending from respective ones of the first and second end faces, the inlet ports at each of the first and second end faces being in communication with respective inlets through the casing with respective first and second cooling fluid supply passages in communication with respective ones of the inlet ports at respective ones of the first and second end faces, the first and second cooing fluid supply passages being defined between the rotor, the shaft, the respective one of the first and second flow guides and the respective one of the first and second end plates, and the discharge ports at each of the first and second end faces being in communication with respective outlets through the casing with respective first and second cooling fluid exhaust passages in communication with respective ones of the discharge ports at respective ones of the first and second end faces, the first and second cooling fluid exhaus