An electric motor including a motor portion, a cooling portion and a plurality of heat pipes is provided. The motor portion includes a stator and a rotor that when energized with electric current causes the rotor to rotate. The motor portion comprises a motor frame that encloses the rotor and stator
An electric motor including a motor portion, a cooling portion and a plurality of heat pipes is provided. The motor portion includes a stator and a rotor that when energized with electric current causes the rotor to rotate. The motor portion comprises a motor frame that encloses the rotor and stator from exterior elements. The cooling portion is adjacent the motor portion and exterior of the motor portion. In various embodiments it defines a fluid chamber containing a quantity of fluid that is prevented from contacting interior of the motor portion. The plurality of heat pipes within the motor portion extend from the motor portion to the cooling portion such that the fluid contacts the heat pipe within the cooling portion in order to remove heat from the heat pipe.
대표청구항▼
We claim: 1. An electric motor comprising: a motor portion comprising a stator and a rotor that when energized with electric current, the rotor is caused to rotate by a resulting magnetic field, wherein the motor portion comprises a motor frame that encloses the rotor and stator from exterior eleme
We claim: 1. An electric motor comprising: a motor portion comprising a stator and a rotor that when energized with electric current, the rotor is caused to rotate by a resulting magnetic field, wherein the motor portion comprises a motor frame that encloses the rotor and stator from exterior elements; a cooling portion adjacent the motor portion and separated from the motor portion by a structural interface, the cooling portion comprising: a cooling chamber filled with a quantity of motor cooling fluid that is prevented by the structural interface from entering an interior of the motor portion; and a mounting plate structured to provide a sidewall of the cooling chamber such that the motor cooling fluid within the cooling chamber of the motor contacts the mounting plate, the mounting plate structured to have a pumping device, driven by the motor, mounted thereto such that a pump medium pumped by the pumping device thermally contacts and cools the mounting plate such that the mounting plate provides an infinite cold plate operable to cool the motor cooling fluid within the cooling chamber of the motor; and a plurality of heat pipes disposed within the motor portion and extending from the motor portion into the cooling chamber such that the motor cooling fluid, cooled by the mounting plate that is cooled by the pump medium, contacts the portion of heat pipes extending within the cooling chamber in order to remove heat from the heat pipes. 2. The electric motor of claim 1 wherein the stator defines a plurality of slots, the slots open at an end thereof and the plurality of heat pipes inserted in the plurality of slots and extending through the open end into the cooling chamber. 3. The electric motor of claim 2 wherein a second plurality of heat pipes contact the rotor and extend from within the rotor. 4. The electric motor of claim 3 wherein the rotor defines a plurality of rotor slots with two rotor bar portions inserted into each rotor slot with a heat pipe disposed between each of the rotor bar portions. 5. The electric motor of claim 3 wherein the rotor defines a plurality of rotor slots with a rotor bar portion inserted into each rotor slot with a heat pipe disposed adjacent to the rotor bar portion. 6. The electric motor of claim 3 wherein the rotor defines a plurality of rotor slots with a rotor winding inserted into each rotor slot with a heat pipe disposed adjacent to the rotor winding. 7. The electric motor of claim 1 wherein the rotor defines a plurality of bores in the rotor, the bores having heat pipes disposed therein. 8. The electric motor of claim 1 wherein the heat pipes contact a motor frame along a portion thereof and extend into the cooling chamber at an end thereof. 9. The electric motor of claim 1 wherein the heat pipes contact a back iron ring along a portion thereof and extend into the cooling chamber at an end thereof. 10. The electric motor of claim 1 wherein the heat pipes contact a stator core through bores formed in the stator core along a portion of the heat pipe and an end of the heat pipe extends into the cooling chamber. 11. The electric motor of claim 1 wherein the motor cooling fluid is air and further comprising a fan for forcing the air from an air inlet over the heat pipes and through an air outlet. 12. The electric motor of claim 1 wherein the motor cooling fluid is a liquid coolant. 13. The electric motor of claim 12 wherein the motor cooling fluid is delivered through a coolant inlet and exits through a coolant outlet. 14. The electric motor of claim 12 wherein the motor cooling fluid is water based coolant. 15. The electric motor of claim 14 wherein the motor cooling fluid is delivered through a coolant inlet and exits through a coolant outlet. 16. The electric motor of claim 14 wherein the motor cooling fluid is an oil-based coolant. 17. The electric motor of claim 12 wherein the motor cooling fluid is prevented from exiting the cooling chamber. 18. The electric motor of claim 2 wherein the heat pipes are disposed at a base of the slot and copper windings are placed within the slot over the heat pipe. 19. The electric motor of claim 1 wherein the heat pipes are sealed within the structural interface between the motor portion and the cooling portion to prevent the fluid from the cooling portion from entering the motor portion. 20. The electric motor of claim 19 wherein the heat pipes are sealed within the structural interface between the motor portion and the cooling portion with seals. 21. The electric motor of claim 20 wherein seals are inserted in counterbores in the structural interface to seal the heat within the structural interface. 22. The electric motor of claim 21 further comprising a heat pipe clamp plate that is adapted to maintain the seals in a sealing arrangement with both the structural interface and the heat pipes to prevent the fluid from exiting the cooling chamber. 23. The electric motor of claim 19 wherein the heat pipes are sealed within the structural interface between the motor portion and the cooling portion through mechanical contact of the structural interface. 24. The electric motor of claim 23 wherein the mechanical connection is made by one of the group consisting solder, epoxy or braze filler. 25. A totally enclosed electric motor comprising: a motor portion comprising a stator and a rotor that when energized with electric current, the rotor is caused to rotate by a resulting magnetic field, wherein the motor portion comprises a motor frame that encloses the rotor and stator from exterior elements; a cooling portion adjacent the motor portion and separated from the motor portion by a structural interface, the cooling portion comprising: a cooling chamber filled with a quantity of motor cooling fluid that is prevented by the structural interface from entering an interior of the motor portion; and a mounting plate structured to provide a sidewall of the cooling chamber such that the motor cooling fluid within the cooling chamber of the motor contacts the mounting plate, the mounting plate structured to have a pumping device, driven by the motor, mounted thereto such that a pump medium pumped by the pumping device thermally contacts and cools the mounting plate such that the mounting plate provides an infinite cold plate operable to cool the motor cooling fluid within the cooling chamber of the motor; a plurality of heat pipes disposed within the motor portion and extending from the motor portion into the cooling chamber such that the motor cooling fluid, cooled by the mounting plate that is cooled by the pump medium, contacts the portion of the heat pipes extending within the cooling chamber in order to remove heat from the heat pipes; and a plurality of seals disposed between the heat pipes and the structural interface to prevent the motor cooling fluid from entering the interior of the motor portion. 26. The electric motor of claim 25 wherein the stator defines a plurality of slots, the slots open at an end thereof and the plurality of heat pipes inserted in the plurality of slots and extending through the open end into the cooling chamber. 27. The electric motor of claim 26 wherein a second plurality of heat pipes contact the rotor and extend from within the rotor within the motor chamber. 28. The electric motor of claim 27 wherein the rotor defines a plurality of rotor slots with two rotor bar portions inserted into each rotor slot with a heat pipe disposed between each of the rotor bar portions. 29. The electric motor of claim 27 wherein the rotor defines a plurality of rotor slots a rotor bar portion inserted into each rotor slot with a heat pipe disposed adjacent to the rotor bar portions. 30. The electric motor of claim 27 wherein the rotor defines a plurality of rotor slots with a rotor winding inserted into each rotor slot with a heat pipe disposed adjacent to the rotor winding. 31. The electric motor of claim 26 wherein the rotor defines a plurality of bores in the rotor, the bores having heat pipes disposed therein. 32. The electric motor of claim 25 wherein the heat pipes contact a motor frame along a portion thereof and extend into the cooling chamber at an end thereof. 33. The electric motor of claim 25 wherein the heat pipes contact a back iron ring along a portion thereof and extend into the cooling chamber at an end thereof. 34. The electric motor of claim 25 wherein the heat pipes contact a stator core through bores formed in the stator core along a portion of the heat pipe and an end of the heat pipe extends into the cooling chamber. 35. The electric motor of claim 25 wherein the motor cooling fluid is a liquid coolant. 36. The electric motor of claim 34 wherein the motor cooling fluid is an oil-based coolant. 37. The electric motor of claim 25 wherein the seals are inserted in counterbores in the structural interface to seal the heat pipes to the structural interface. 38. The electric motor of claim 25 further comprising a heat pipe clamp plate that is adapted to maintain the seals in a sealing arrangement with both the heat pipes and the structural interface to prevent the fluid from exiting the cooling chamber. 39. An electric motor comprising: a motor portion comprising a stator and a rotor that when energized with electric current, the rotor is caused to rotate by a resulting magnetic field, wherein the motor portion comprises a motor frame that encloses the rotor and stator from exterior elements; a cooling portion adjacent the motor portion and separated from the motor portion by a structural interface, the cooling portion comprising: a cooling chamber filled with a quantity of motor cooling fluid that is prevented by the structural interface from entering an interior of the motor portion, the cooling portion receiving a supply of the motor cooling fluid from a fluid inlet and expelling the motor cooling fluid from a fluid outlet; and a mounting plate structured to provide a sidewall of the cooling chamber such that the cooling fluid within the cooling chamber of the motor contacts the mounting plate, the mounting plate structured to have a pumping device, driven by the motor, mounted thereto such that a pump medium pumped by the pumping device thermally contacts and cools the mounting plate such that the mounting plate provides an infinite cold plate operable to cool the cooling fluid within the cooling chamber of the motor; and a plurality of heat pipes disposed within a back iron ring disposed between the motor frame and the stator and extending from the motor portion to the cooling chamber such that the motor cooling fluid, cooled by the mounting plate that is cooled by the pump medium, contacts the portion of the heat pipes extending within the cooling chamber in order to remove heat from the heat pipes. 40. The electric motor of claim 39 wherein the stator defines a plurality of slots, the slots open at an end thereof and the plurality of heat pipes inserted in the plurality of slots and extending through the open end into the cooling chamber. 41. The electric motor of claim 40 wherein a second plurality of heat pipes contact the rotor and extend from within the rotor. 42. The electric motor of claim 41 wherein the rotor defines a plurality of rotor slots with two rotor bar portions inserted into each rotor slot with a heat pipe disposed between each of the rotor bar portions. 43. The electric motor of claim 41 wherein the rotor defines a plurality of rotor slots a rotor bar portion inserted into each rotor slot with a heat pipe disposed adjacent to the rotor bar portions. 44. The electric motor of claim 41 wherein the rotor defines a plurality of rotor slots with a rotor winding inserted into each rotor slot with a heat pipe disposed adjacent to the rotor winding. 45. The electric motor of claim 41 wherein the rotor defines a plurality of bores in the rotor, the bore having heat pipes disposed therein. 46. The electric motor of claim 39 wherein the heat pipes contact a motor frame along a portion thereof and extend into the cooling chamber at an end thereof. 47. The electric motor of claim 39 wherein the heat pipes contact a back iron ring along a portion thereof and extend into the cooling chamber at an end thereof. 48. The electric motor of claim 39 wherein the heat pipes contact a stator core through bores formed in the stator core along a portion of the heat pipe and an end of the heat pipe extends into the cooling chamber. 49. The electric motor of claim 39 wherein the motor cooling fluid is air and the motor further comprising a fan for forcing the air from the fluid inlet over the heat pipes and into the fluid outlet. 50. The electric motor of claim 39 wherein the motor cooling fluid is a liquid coolant. 51. The electric motor of claim 48 wherein the motor cooling fluid is water based coolant. 52. The electric motor of claim 40 wherein the heat pipes are disposed at a base of the slot and copper windings are placed within the slot over the heat pipe. 53. The electric motor of claim 39 wherein the heat pipes are sealed within the structural interface to prevent the fluid from the cooling portion from entering the motor chamber. 54. The electric motor of claim 53 wherein the heat pipes are sealed within the structural interface with seals. 55. The electric motor of claim 54 wherein the seals are inserted in counterbores in the structural interface to seal the heat pipes to the structural interface. 56. The electric motor of claim 55 further comprising a heat pipe clamp plate that is adapted to maintain the seals in a sealing arrangement with both the structural interface and the heat pipes to prevent the motor cooling fluid from exiting the cooling chamber. 57. The electric motor of claim 53 wherein the heat pipes are sealed within the structural interface through mechanical contact of the heat pipe to the structural interface. 58. The electric motor of claim 57 wherein the mechanical connection is made by one of the group consisting solder, epoxy or braze filler. 59. A method for cooling an electric motor, said method comprising: providing a motor, the motor including: a motor portion operable to drive a mechanical device operable to pump a pump medium; a cooling portion separated from the motor portion by a structural interface; and a plurality of heat pipes disposed within a back iron ring disposed between the stator and the frame, the heat pipes having evaporator ends disposed within the motor portion and condenser ends disposed within the cooling portion; and cooling the condenser ends of the heat pipes utilizing the pump medium pumped by the mechanical device driven by the motor portion.
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이 특허에 인용된 특허 (22)
McMaster Thomas M. (Bellingham WA), Cooling system for journalled rotating shaft machinery.
Glandorf Frank J. (Cincinnati OH) Wagner Paul D. (Cincinnati OH) Keuper John J. (Cold Spring KY), Heat exchange arrangement for cooling lubricant for vertical electric motor thrust bearing.
Cashmore Douglas H. (Tulsa OK) Budenholzer Robert J. (Monroeville PA) Veronesi Luciano (O\Hara Township ; Allegheny County PA), Heat pipes for cooling pole windings of salient pole machines.
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