IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0607615
(2003-06-27)
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발명자
/ 주소 |
- Goodson,Kenneth E.
- Chen,Chuan Hua
- Huber,David E.
- Jiang,Linan
- Kenny,Thomas W.
- Koo,Jae Mo
- Laser,Daniel J.
- Mikkelsen,James C.
- Santiago,Juan G.
- Wang,Evelyn Ning Yi
- Zeng,Shulin
- Zhang,Lian
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출원인 / 주소 |
- The Board of Trustees of the Leland Stanford Junior University
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대리인 / 주소 |
Womble Carlyle Sandridge &
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인용정보 |
피인용 횟수 :
28 인용 특허 :
161 |
초록
▼
Apparatus and methods according to the present invention preferably utilize electroosmotic pumps that are capable of generating high pressure and flow without moving mechanical parts and the associated generation of unacceptable electrical and acoustic noise, as well as the associated reduction in r
Apparatus and methods according to the present invention preferably utilize electroosmotic pumps that are capable of generating high pressure and flow without moving mechanical parts and the associated generation of unacceptable electrical and acoustic noise, as well as the associated reduction in reliability. These electroosmotic pumps are preferably fabricated with materials and structures that improve performance, efficiency, and reduce weight and manufacturing cost relative to presently available micropumps. These electroosmotic pumps also preferably allow for recapture of evolved gases and deposited materials, which may provide for long-term closed-loop operation. Apparatus and methods according to the present invention also allow active regulation of the temperature of the device through electrical control of the flow through the pump and can utilize multiple cooling loops to allow independent regulation of the special and temporal characteristics of the device temperature profiles. Novel microchannel structures are also described.
대표청구항
▼
What is claimed is: 1. A cooling system for a hear emitting device, the cooling system operating using a fluid having a liquid phase, the cooling system comprising: a substrate including at least a portion of microchannel disposed therein, the substrate adapted to physically connect to the heat emi
What is claimed is: 1. A cooling system for a hear emitting device, the cooling system operating using a fluid having a liquid phase, the cooling system comprising: a substrate including at least a portion of microchannel disposed therein, the substrate adapted to physically connect to the heat emitting device, thereby providing for the transfer of thermal energy from the heat emitting device to the substrate, and the further transfer of thermal energy from the to the fluid disposed within the microchannel, the microchannel configured to provide flow of the fluid therethrough; a heat exchanger configured to provide flow of the fluid therethrough and the transfer of thermal energy out of the fluid, a high flow rate electroosmotic pump the electroosmotic pump creating the flow of the fluid and managing a plurality of generated gases; and wherein the substrate, the heat exchanger, and the electroosmotic pump are configured to operate together to create a closed loop fluid flow. 2. A hear exchanger connected the a heat-generating device including a plurality of regions of having heat densities in a cooling system wherein the heat exchanger operates using a fluid having a liquid phase, comprising: a substrate fabricated from a material selected for its thermal conduction capability and adapted to connect to the heat-generating device; and a microchannel disposed in the substrate for transfer of thermal energy to the fluid as the fluid is pumped through the heat exchanger wherein the arrangement of the microchannel is selected to minimize the temperature differences across the heat-generating device. 3. The heat exchanger connected to a beat-generating device of claim 2 wherein the substrate material is selected based on an approximate matching of a thermal expansion coefficient of the heat-generating device to which the heat exchanger is connected. 4. The neat exchanger connected to a heat-generating device of claim 2 wherein the substrate material is selected from a plurality of thin metal sheets, or a silicon layer and a glass layer, or a ceramic, or a carbon-fiber composite. 5. The heat exchanger connected to a heat-generating device of claim 2 wherein the substrate comprises a plurality of layers. 6. The heat exchanger connected to a heat-generating device of claim 5 wherein the plurality of layers comprise different materials. 7. The heat exchanger connected to a heat-generating device of claim 2 wherein the substrate is connected to a surface of the heat-generating device by a thermal attach material. 8. The heat exchanger connected to a heat-generating device of claim 7 wherein the thermal attach material is a silver-filled epoxy or solder. 9. The heat exchanger connected to a heat-generating device of claim 2 wherein the substrate and the heat-generating device are fabricated from silicon. 10. The heat exchanger connected to a heat-generating device of claim 2 wherein the heat-generating device is fabricated from silicon and the substrate is fabricated from a metal. 11. The heat exchanger connected to a heat-generating device of claim 2 wherein the substrate further comprises a thermometer integrated into the heat exchanger for providing a feedback signal to a controller in response to a local change in temperature to enable dynamic temperature control within the substrate. 12. The heat exchanger connected to a heat-generating device of claim 2 wherein the substrate comprises at least two layers and the microchannel is confined to a single layer. 13. The heat exchanger connected to a heat-generating device of claim 2 wherein the substrate comprises at least two layers and the microchannel is formed in more than one layer. 14. The heat exchanger connected to a heat-generating device of claim 12 wherein the at least two layers are fabricated from silicon and glass and are bonded by any one of the following bonding processes: anodic, fusion, eutectic and adhesive. 15. The heat exchanger connected to a heat-generating device of claim 12 wherein the at least two layers are fabricated from metal and are bonded by any one of the following: welding, soldering, eutectic bonding and adhesive bonding. 16. The heat exchanger connected to a heat-generating device of claim 2 further comprising a high flow rate electroosmotic pump integrated into the substrate for pumping fluid through the heat exchanger. 17. The heat exchanger connected to a heat-generating device of claim 16 further comprising a microcontroller integrated into the substrate for monitoring a plurality of temperature, pressure and flow rate sensors disposed in the heat exchanger and providing a driving voltage to a power supply associated with the high flow rate electroosmotic pump. 18. The heat exchanger connected to a heat-generating device of claim 5 wherein the microchannel is disposed in the layer of the substrate that is in direct contact with the heat-generating device. 19. The heat exchanger connected to a heat-generating device of claim 5 wherein the plurality of layers comprise a bottom layer, at least one middle layer and a top layer, and each of the bottom, middle and top layers may be fabricated from a different material. 20. The heat exchanger connected to a heat-generating device of claim 19 wherein the bottom layer is fabricated from a metal, or silicon, or glass, or a ceramic, or a plastic. 21. The heat exchanger connected to a heat-generating device of claim 20 wherein the bottom layer is fabricated from copper. 22. The heat exchanger connected to a heat-generating device of claim 20 wherein the bottom layer is fabricated from Kovar. 23. The heat exchanger connected to a heat-generating device of claim 19 wherein the at least one middle layer is fabricated from silicon. 24. The heat exchanger connected to a heat-generating device of claim 19 wherein the at least one middle layer is fabricated from a metal. 25. The heat exchanger connected to a heat-generating device of claim 19 wherein the lop layer is fabricated from a glass or a plastic. 26. A heat exchanger connected to a heat-generating device in a cooling system wherein the heat exchanger operates using a fluid having a liquid phase, comprising: a substrate fabricated from a material selected for its thermal conduction capability and adapted to connect to the heat-generating device; a high flow rate electroosmotic pump integrated into the substrate for pumping fluid through the heat exchanger and managing a plurality of generated gases; and a microchannel disposed in the substrate for transfer of thermal energy to the fluid as the fluid is pumped through the heat exchanger wherein at least one inlet and at least one outlet are positioned on a side of the heat exchanger. 27. The heat exchanger connected to a heat-generating device of claim 26 wherein the substrate material is selected based on an approximate matching of a thermal expansion coefficient of the heat-generating device to which the heat exchanger is connected. 28. The heat exchanger connected to a heat-generating device of claim 26 wherein the substrate material is selected from a plurality of thin metal sheets, or a silicon layer and a glass layer, or a ceramic, or a carbon-fiber composite. 29. The heat exchanger connected to a heat-generating device of claim 26 wherein the substrate comprises a plurality of layers. 30. The heat exchanger connected to a heat-generating device of claim 29 wherein the plurality of layers comprise different materials. 31. The neat exchanger connected to a neat-generating device of claim 26 wherein the substrate is connected to a surface of the heat-generating device by a thermal attach material. 32. The heat exchanger connected to a heat-generating device of claim 31 wherein the thermal attach material is a silver-filled epoxy or solder. 33. The heat exchanger connected to a heat-generating device of claim 26 wherein the substrate and the heat-generating device are fabricated from silicon. 34. The heat exchanger connected to a heat-generating device of claim 26 wherein the heat-generating device is fabricated from silicon and the substrate is fabricated from a metal. 35. The heat exchanger connected to a heat-generating device of claim 26 wherein the substrate further comprises a thermometer integrated into the heat exchanger for providing a feedback signal to a controller in response to a local change in temperature to enable dynamic temperature control within the substrate. 36. The heat exchanger connected to a heat-generating device of claim 26 wherein the substrate comprises at least two layers and the microchannel is confined to a single layer. 37. The heat exchanger connected to a heat-generating device of claim 36 wherein the substrate comprises at least two layers and the microchannel is formed in more than one layer. 38. The heat exchanger connected to a heat-generating device of claim 36 wherein the at least two layers are fabricated from silicon and glass and are bonded by any one of the following bonding processes: anodic, fusion, eutectic and adhesive. 39. The heat exchanger connected to a heat-generating device of claim 36 wherein the at least two layers are fabricated from metal and are bonded by any one of the following; welding, soldering, eutectic bonding and adhesive bonding. 40. The heat exchanger connected to a heat-generating device of claim 26 further comprising a microcontroller integrated into the substrate for monitoring a plurality of temperature, pressure and flow rate sensors disposed in the heat exchanger and providing a having voltage to a power supply associated with the high flow rate electroosmotic pump. 41. The heat exchanger connected to a heat-generating device of claim 29 wherein the microchannel is disposed in the layer of the substrate that is in direct contact with the heat-generating device. 42. The heat exchanger connected to a heat-generating device of claim 29 wherein the plurality of layers comprise a bottom layer, at least one middle layer and a top layer, and each of the bottom, middle and top layers may be fabricated from a different material. 43. The heat exchanger connected to a heat-generating device of claim 42 wherein the bottom layer is fabricated from a metal, or silicon, or glass, or a ceramic, or a plastic. 44. The heat exchanger connected to a heat-generating device of claim 43 wherein the bottom layer fabricated from copper. 45. The heat exchanger connected to a heat-generating device of claim 43 wherein the bottom layer is fabricated from Kovar. 46. The heat exchanger connected to a heat-generating device of claim 42 wherein the at least one middle layer is fabricated from silicon. 47. The heat exchanger connected to a heat-generating device of claim 42 wherein the at least one middle layer is fabricated from a metal. 48. The heat exchanger connected to a heat-generating device of claim 42 wherein the top layer is fabricated from a glass or a plastic. 49. A heat exchanger for the transfer of heat from a heat-generating device including a plurality of regions of varying heat densities in a cooling system wherein to heat exchanger operates using a fluid having a liquid phase, comprising: a multi-layer substrate fabricated from a plurality of materials that are bonded together and attached to the heat-generating device; and a microchannel disposed in at least one layer of the substrate for transfer of thermal energy to the fluid as the fluid is pumped through the heat exchanger wherein the arrangement of the microchannel is selected to minimize to temperature differences across the heat-generating device. 50. A heat exchanger for the transfer of heat from a heat-generating device including a plurality of regions of varying heat densities in a cooling system wherein the heat exchanger operates using a fluid having a liquid phase, comprising: a multi-layer substrate fabricated from a plurality of materials that are bonded together and attached to the heat-generating device; and a microchannel disposed in at least one layer of the substrate for transfer of thermal energy to the fluid as the fluid is pumped through the heat exchanger by a high flow rate fluid pump and wherein at least one inlet and at least one outlet are positioned on a side of the heat exchanger. 51. A cooling system for a heat emitting device including a plurality of regions of varying heat densities, the cooling system operating using a fluid having a liquid phase, the cooling system comprising: a substrate including at least a portion of a microchannel disposed therein, the substrate adapted to physically comment to the heat emitting device, thereby providing for the transfer of thermal energy from the heat emitting device to the substrate, and the further transfer of thermal energy from the substrate to the fluid disposed within the microchannel, the microchannel configured to provide flow of the fluid therethrough and wherein the arrangement of the microchannel is selected to minimize the temperature differences across the heat emitting device; a heat exchanger configured to provide flow of the fluid therethrough and the transfer of thermal energy out of the fluid; a high flow rate fluid pump for creating the flow of the fluid; and wherein the substrate, the heat exchanger, and the fluid pump are configured to operate together to create a closed loop fluid flow. 52. The cooling system according to claim 51 wherein the fluid pump is disposed between the heat exchanger and the substrate such that the fluid is formed into the microchannel of the substrate from the fluid pump. 53. The cooling system according to claim 51 wherein the microchannel includes a plurality of parallel subchannels, each of the parallel subchannels sharing a common inlet portion and a common outlet portion. 54. The cooling system according to claim 53 further including a temperature sensor disposed in proximity to the plurality of parallel subchannels. 55. The cooling system according to claim 54 further including a temperature control circuit that receives as inputs signals from the temperature sensor. 56. The cooling system according to claim 51 wherein the substrate is comprised of a plurality of layers, and wherein at least a portion of the microchannels is formed within both a first and a second layer. 57. The cooling system according to claim 51 wherein the substrate is comprised of a first layer and a second layer, the first layer being physically connected to the heat emitting device, and wherein at least a portion of the microchannel is formed within only the first layer. 58. The cooling system according to claim 51 wherein the neat emitting device is comprised of a plurality of integrated circuits and the substrate is disposed between the plurality of integrated circuits. 59. The cooling system according to claim 51 wherein the heat emitting device includes a plurality of regions with several regions having a higher heat density than other regions. 60. The cooling system according to claim 51 wherein the substrate further includes a plurality of vertical electrical interconnects. 61. The cooling system according to claim 60 wherein the microchannel further includes vertical and horizontal fluid channels. 62. The cooling system according to claim 60 wherein the plurality of vertical interconnects provide a portion of an electrical connection that electrically connects a plurality of temperature sensors to a temperature control circuit. 63. The cooling system according to claim 51 wherein the substrate includes an opening through which another interaction is capable of impinging upon a portion of the heat emitting device. 64. The cooling system according to claim 63 wherein the another interaction is an electrical interaction. 65. The cooling system according to claim 63 wherein the another interaction is an electrical connection to a surface of the device to which the substrate is physically connected, and which electrical connection does not pass through any portion of the substrate. 66. The cooling system according to claim 63 wherein the another interaction is one of pressure, sound, chemical, mechanical force, and an electromagnetic field. 67. The cooling system according to claim 63 wherein the opening is created by a surface area of the substrate that contacts a corresponding surface area of the device being smaller than the corresponding surface area of the device. 68. The cooling system according to claim 51 wherein a portion of the microchannel includes: an upper chamber; a lower chamber; and a plurality of subchannels disposed between the upper chamber and the lower chamber wherein the arrangement of the subchannels is selected to minimize the temperature differences across the heat emitting device. 69. The cooling system according to claim 51 further including a pressure sensor. 70. The cooling system according to claim 51 further including a temperature sensor disposed within the substrate. 71. The cooling system according to claim 70 further including a temperature control circuit that receives as inputs signals from the temperature sensor. 72. The cooling system according to claim 51 further including a temperature sensor disposed in the loop at a location other than within the substrate. 73. The cooling system according to claim 51 wherein the microchannel includes a portion containing a partial blocking structure to increase surface area contacting the fluid. 74. The cooling system according to claim 73 wherein the partial blocking structure is comprised of a roughened portion of a microchannel wall. 75. The cooling system according to claim 73 wherein the partial blocking structure is disposed within the microchannel. 76. The cooling system according to claim 51 wherein the heat emitting device includes a plurality of regions with several regions having a higher heat density than other regions. 77. A cooling system for a heat emitting device including a plurality of regions of varying heat densities, the cooling system operating using a fluid having a liquid phase, the cooling system comprising: a substrate including at least a portion of a microchannel disposed therein, the substrate adapted to physically connect to the heat emitting device, thereby providing for the transfer of thermal energy from the heat emitting device to the substrate, and the further transfer of thermal energy from the substrate to the fluid disposed within the microchannel, the microchannel configured to provide flow of the fluid therethrough; a heat exchanger configured to provide for (i) the flow of the fluid therethrough, wherein at least one inlet and at least one outlet are positioned on a side of the heat exchanger, and (ii) the transfer of thermal energy out of the fluid; a high flow rate fluid pump for creating the flow of the fluid; and wherein the substrate, the heat exchanger, and the fluid pump are configured to operate together to create a closed loop fluid flow. 78. The cooling system according to claim 77 wherein the high flow rate fluid pump is disposed between the heat exchanger and the substrate much that the fluid is pumped into the microchannel of the substrate from the fluid pump. 79. The cooling system according to claim 72 wherein the microchannel includes a plurality of parallel subchannels, each of the parallel subchannels sharing a common inlet portion and a common outlet portion. 80. The cooling system according to claim 79 further including a temperature sensor disposed in proximity to the plurality of parallel subchannels. 81. The cooling system according to claim 80 further including a temperature control circuit that receives as inputs signals from the temperature sensor. 82. The cooling system according to claim 77 wherein the substrate is comprised of a plurality of layers, and wherein at least a portion of the microchannel is formed within both a first and a second layer. 83. The cooling system according to claim 77 wherein the substrate is comprised of a first layer and a second layer, the first layer being physically connected to the heat emitting device, and wherein at least a portion of the microchannel is formed within only the first layer. 84. The cooling system according to claim 77 wherein the heat emitting device is comprised of a plurality of integrated circuits and the substrate is disposed between the plurality of integrated circuits. 85. The cooling system according to claim 77 wherein the substrate further includes a plurality of vertical electrical interconnects. 86. The cooling system according to claim 85 wherein the microchannel further includes vertical and horizontal fluid channels. 87. The cooling system according to claim 85 wherein the plurality of vertical interconnects provide a portion of an electrical connection that electrically connects a plurality of temperature sensors to a temperature control circuit. 88. The cooling system according to claim 77 wherein the substrate includes an opening through which another interaction is capable of impinging upon a portion of the heat emitting device. 89. The cooling system of claim 88 wherein the another interaction is an electrical interaction. 90. The cooling system according to claim 88 wherein the another interaction is an electrical connection to a surface of the device to which the substrate is physically connected, and which electrical connection does not pass through any portion of the substrate. 91. The cooling system according to claim 88 wherein the another interaction is one of pressure, sound, chemical, mechanical force, and an electromagnetic field. 92. The cooling system according to claim 88 wherein the opening is created by a surface area of the substrate that contacts a corresponding surface area of the device being smaller than the corresponding surface area of the device. 93. A thermal transfer apparatus connected to a semiconductor heat emitting device, the thermal transfer apparatus operating using a fluid having a liquid phase comprising: a substrate adapted to physically connect to the semiconductor heat emitting device; a plurality of fluid inlets disposed in the substrate; a plurality of fluid outlets disposed in the substrate; a plurality of microchannels connected between the plurality of fluid inlets and the plurality of fluid outlets, the plurality of microchannels thereby providing a plurality of independent fluid flow paths; and wherein the arrangement of the microchannels is selected to minimize the temperature differences across the heat emitting device. 94. The apparatus according to claim 94 further including a plurality of temperature sensors respectively located in proximity to the plurality of microchannels, such that each of the temperature sensors detects thermal energy generated by the heat emitting device in proximity to said each temperature sensor. 95. The apparatus according to claim 94 further including a control circuit electrically connected to the plurality of temperature sensors, the control circuit inputting signals from the plurality of temperature sensors and providing a control signal for controlling a fluid pump. 96. The apparatus according to claim 95 further including a second fluid pump, such that the first fluid pump pumps the fluid through one microchannel and the second fluid pump pumps the fluid through another microchannel and wherein the control circuit controls the first and second fluid pumps, the control circuit being capable of independently controlling the pumping of fluid through each of the first and second fluid pumps. 97. The apparatus according to claim 93 further including: a plurality of temperature sensors disposed within the substrate, such that a first temperature sensor detects thermal energy generated by the heat emitting device in proximity to the first temperature sensor and a second temperature sensor detects thermal energy generated by the heat emitting device in proximity to the second temperature sensor; and a control circuit electrically connected to the first and second temperature sensors, the control circuit inputting signals from a first and second temperature sensors and providing a control signal for controlling the fluid pump. 98. The apparatus according to claim 97 wherein the control circuit operates to sense a predetermined condition. 99. The apparatus according to claim 98 wherein upon sensing the condition, the control circuit causes a reversal of the fluid flow for a period of time. 100. The apparatus according to claim 98 wherein the control circuit detects a change in temperature over a period of time and correspondingly adjusts the fluid flow within the fluid pump to compensate for the change in temperature. 101. The apparatus according to claim 93 further including a plurality of temperature sensors respectively located in proximity to the plurality of microchannels, such that each temperature sensor detects thermal energy generated by the heat emitting device in proximity to said each temperature sensor. 102. The apparatus according to claim 93 wherein each of the plurality of microchannels contain portions that are disposed parallel and adjacent to one another such that fluid flow in one microchannel occurs in a direction opposite die fluid flow in another microchannel. 103. The apparatus according to claim 93 wherein a first microchannel is at least partially disposed over a high thermal energy location of the heat emitting device and a second microchannel is disposed over another portion of the heat emitting device different from the high thermal energy location. 104. The cooling system according to claim 93 wherein the substrate further includes a plurality of vertical electrical interconnects. 105. The cooling system according to claim 104 wherein the plurality of vertical interconnects provide a portion of an electrical connection that electrically connects a plurality of temperature sensors to a temperature control circuit. 106. The cooling system according to claim 93 wherein the substrate includes an opening through which another interaction is capable of impinging upon a portion of the heat emitting device. 107. The cooling system according to claim 106 wherein the another interaction is an electrical interaction. 108. The cooling system according to claim 107 wherein the electrical interaction is an electrical connection to a surface of the device to which the substrate is physically connected, and which electrical connection does not pass through any portion of the substrate. 109. The cooling system according to claim 106 wherein the another interaction is one of pressure, sound, chemical, mechanical force, and an electromagnetic field. 110. The cooling system according to claim 106 wherein the opening is a vertical column having enclosed sidewalls. 111. The cooling system according to claim 93 wherein a portion of at least one of the plurality of microchannels includes: an upper chamber; a lower chamber; and a plurality of subchannels disposed between the upper chamber and the lower chamber.
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