An electrical machine having a rotor component configured to rotate with respect to a stator component includes a sensing arrangement to sense electrical, magnetic, and/or mechanical machine parameters during machine operation. The electrical machine also includes a fluid sprayer coupled to a coolin
An electrical machine having a rotor component configured to rotate with respect to a stator component includes a sensing arrangement to sense electrical, magnetic, and/or mechanical machine parameters during machine operation. The electrical machine also includes a fluid sprayer coupled to a cooling controller. The cooling controller activates the fluid sprayer to spray cooling fluid on a portion of the electrical machine in response to in response to the sensed electrical, magnetic, and/or mechanical machine parameters.
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1. An electrical machine, comprising: a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;a temperature sensing arrangement coupled to a cooling controller, andwherein the temperature sensing arrangement is configured to sen
1. An electrical machine, comprising: a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;a temperature sensing arrangement coupled to a cooling controller, andwherein the temperature sensing arrangement is configured to sense transient temperature increases at one or more machine locations during machine operation, and wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed transient temperature increases and a second cooling arrangement is configured to cool machine components independent of the sensed transient temperature increases. 2. The electrical machine of claim 1, wherein the portion of machine on which the fluid sprayer sprays cooling fluid is within or internal to the stator and/or rotor component. 3. The electrical machine of claim 1, wherein the fluid sprayer is configured to spray an evaporative cooling fluid on the portion of the machine. 4. The electrical machine of claim 3, further comprising, an exhaust structure configured to vent evaporated cooling fluid. 5. The electrical machine of claim 1, further comprising, a fluid recycling structure configured to recycle the cooling fluid sprayed on the portion of the machine. 6. The electrical machine of claim 1, wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to machine operation parameters including one or more of rotation speed, acceleration, and torque. 7. The electrical machine of claim 1, wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response anticipated machine operation parameters including one or more of rotation speed, acceleration, and torque. 8. The electrical machine of claim 1, wherein the fluid sprayer is coupled to a fluid supply reservoir attached to the machine. 9. An electrical machine, comprising: a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;a temperature sensing arrangement coupled to a cooling controller, and wherein the temperature sensing arrangement is configured to sense transient temperature increases at one or more machine locations during machine operation and wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed transient temperature increases and the portion of machine on which the fluid sprayer sprays cooling fluid corresponds to an air gap between the stator and rotor components. 10. An electrical machine, comprising: a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;a temperature sensing arrangement coupled to a cooling controller, and wherein the temperature sensing arrangement is configured to sense transient temperature increases at one or more machine locations during machine operation, and wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed transient temperature increases and prediction circuitry is coupled to the cooling controller, wherein the prediction circuitry is configured to predict machine component heating under a machine operation scenario and wherein the controller is configured to activate the fluid sprayer to spray cooling fluid according to the predicted heating. 11. The electrical machine of claim 10, wherein the prediction circuitry is further configured to estimate available cooling capacity under the machine operation scenario. 12. The electrical machine of claim 11, wherein the prediction circuitry configured to estimate available cooling capacity includes a sensor configured to determine an amount of available cooling fluid. 13. The electrical machine of claim 12, wherein the prediction circuitry is further configured to provide an alternate machine operation scenario in an instance where the available cooling capacity is insufficient to counteract the projected component heating under the machine operation scenario. 14. The electrical machine of claim 13, wherein the alternate machine operation scenario includes limiting machine load and/or limiting a time of machine operation. 15. An electrical machine, comprising: a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;a cooling controller coupled to the first cooling arrangement; anda sensing arrangement coupled to the cooling controller, andwherein the sensing arrangement is configured to sense electrical, magnetic, and/or mechanical machine parameters, and wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed electrical, magnetic, and/or mechanical machine parameters and a second cooling arrangement is configured to cool machine components independent of the sensed electrical and/or mechanical machine parameters. 16. The electrical machine of claim 15, wherein the sensing arrangement is configured to sense mechanical machine parameters including one or more of air gap separation, component dimension, rotation speed, acceleration, and torque. 17. The electrical machine of claim 15, wherein the sensing arrangement is configured to sense electrical and/or magnetic parameters including one or more of voltage, current, capacitance, inductance, resistance, phase, frequency permeability, magnetic susceptibility, electrical and/or magnetic field strength. 18. The electrical machine of claim 15, wherein the sensing arrangement is configured to sense electrical and/or magnetic parameters in rotor and/or stator circuitry and/or differences therein. 19. The electrical machine of claim 15, wherein the portion of machine on which the fluid sprayer sprays cooling fluid is within or internal to the stator and/or rotor component. 20. The electrical machine of claim 15, wherein the fluid sprayer is configured to spray an evaporative cooling fluid on the portion of the machine. 21. The electrical machine of claim 20, further comprising, an exhaust structure configured to vent evaporated cooling fluid. 22. The electrical machine of claim 15, further comprising, a fluid recycling structure configured to recycle the cooling fluid sprayed on the portion of the machine. 23. The electrical machine of claim 15, wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to anticipated electrical, magnetic and/or mechanical machine parameters. 24. The electrical machine of claim 15, wherein the fluid sprayer is coupled to a fluid supply reservoir attached to the machine. 25. An electrical machine, comprising: a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;a cooling controller coupled to the first cooling arrangement; anda sensing arrangement coupled to the cooling controller, and wherein the sensing arrangement is configured to sense electrical, magnetic, and/or mechanical machine parameters, and wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed electrical, magnetic, and/or mechanical machine parameters and the portion of machine on which the fluid sprayer sprays cooling fluid corresponds to an air gap between the stator and rotor components. 26. An electrical machine, comprising: a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;a cooling controller coupled to the first cooling arrangement; anda sensing arrangement coupled to the cooling controller, and wherein the sensing arrangement is configured to sense electrical, magnetic, and/or mechanical machine parameters, and wherein the cooling controller is configured to activate the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed electrical, magnetic, and/or mechanical machine parameters and prediction circuitry is coupled to the cooling controller, wherein the prediction circuitry is configured to predict machine component heating under a machine operation scenario and wherein the controller is configured to activate the fluid sprayer to spray cooling fluid according to the predicted heating. 27. The electrical machine of claim 26, wherein the prediction circuitry is further configured to estimate available cooling capacity under the machine operation scenario. 28. The electrical machine of claim 27, wherein the prediction circuitry configured to estimate available cooling capacity includes a sensor configured to determine an amount of available cooling fluid. 29. The electrical machine of claim 28, wherein the prediction circuitry is further configured to provide an alternate machine operation scenario in an instance where the available cooling capacity is insufficient to counteract the projected component heating under the machine operation scenario. 30. The electrical machine of claim 29, wherein the alternate machine operation scenario includes limiting machine load and/or limiting the time of machine operation. 31. A method comprising: in an electrical machine having a rotor component configured to rotate with respect to a stator component and a first cooling arrangement including a fluid sprayer,sensing transient temperature increase at one or more machine locations during machine operation; andactivating the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed transient temperature increases; andpredicting machine component heating under a machine operation scenario and activating the fluid sprayer to spray cooling fluid according to the predicted heating. 32. The method of claim 31, further comprising, deploying a second cooling arrangement configured to cool machine components independent of the sensed transient temperature increases. 33. The method of claim 31, wherein the fluid sprayer is configured to spray an evaporative cooling fluid on the portion of the machine. 34. The method of claim 31, further comprising, deploying an exhaust structure configured to vent evaporated cooling fluid. 35. The method of claim 31, further comprising, recycling the cooling fluid sprayed on the portion of the machine. 36. The method of claim 31, wherein predicting machine component heating includes estimating available cooling capacity under the machine operation scenario and providing an alternate machine operation scenario in an instance where the available cooling capacity is insufficient to counteract the projected component heating under the machine operation scenario. 37. The method of claim 36, wherein the alternate machine operation scenario includes limiting machine load and/or limiting the time of machine operation. 38. A method, comprising: in an electrical machine having a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;sensing electrical, magnetic, and/or mechanical machine parameters during machine operation;activating the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed electrical, magnetic, and/or mechanical machine parameters; anddeploying a second cooling arrangement configured to cool machine components independent of the sensed electrical and/or mechanical machine parameters. 39. The method of claim 38, wherein sensing electrical, magnetic, and/or mechanical machine parameters includes sensing one or more of air gap separation, component dimension, rotation speed, acceleration, and torque. 40. The method of claim 38, wherein sensing electrical, magnetic, and/or mechanical machine parameters includes sensing one or more of voltage, current, capacitance, inductance, resistance, phase, frequency, permeability, magnetic susceptibility, electrical and/or magnetic field strength and electrical and/or magnetic parameters in rotor and/or stator circuitry and/or differences therein. 41. The method of claim 38, further comprising, deploying a second cooling arrangement configured to cool machine components independent of the sensed electrical and/or mechanical machine parameters. 42. The method of claim 38, wherein the fluid sprayer is configured to spray an evaporative cooling fluid on the portion of the machine. 43. The method of claim 42, further comprising, deploying an exhaust structure configured to vent evaporated cooling fluid. 44. A method, comprising: in an electrical machine having a rotor component configured to rotate with respect to a stator component;a first cooling arrangement including a fluid sprayer;sensing electrical, magnetic, and/or mechanical machine parameters during machine operation;activating the fluid sprayer to spray cooling fluid on a portion of the machine in response to the sensed electrical, magnetic, and/or mechanical machine parameters; andpredicting machine component heating under a machine operation scenario and activating the fluid sprayer to spray cooling fluid according to the predicted heating. 45. The method of claim 44, wherein predicting machine component heating includes estimating available cooling capacity under the machine operation scenario and providing an alternate machine operation scenario in an instance where the available cooling capacity is insufficient to counteract the projected component heating under the machine operation scenario. 46. The method of claim 45 wherein the alternate machine operation scenario includes limiting machine load and/or limiting the time of machine operation. 47. The method of claim 46, wherein activating the fluid sprayer to spray comprises spraying cooling fluid on a portion of the machine in response to anticipated electrical, magnetic, and/or mechanical machine parameters. 48. The method of claim 46, wherein activating the fluid sprayer comprises sourcing the cooling fluid from a fluid supply reservoir attached to the machine.
Ohmae, Hideki; Wada, Mitsuhiro; Tanabe, Kazunori; Aruga, Shigeru; Sakaguchi, Hirokazu; Shimose, Hisatoshi, Color wheel assembly and color sequential display device using the same, color wheel unit and color sequential display device using the same, and color sequential display device.
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