Cooling apparatus with discrete cold plates disposed between a module enclosure and electronics components to be cooled
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H05K-007/20
F28F-007/00
출원번호
US-0054944
(2008-03-25)
등록번호
US-7486514
(2009-02-03)
발명자
/ 주소
Campbell,Levi A.
Chu,Richard C.
Ellsworth, Jr.,Michael J.
Iyengar,Madhusudan K.
Schmidt,Roger R.
Simons,Robert E.
출원인 / 주소
International Business Machines Corporation
대리인 / 주소
Neff, Esq.,Lily
인용정보
피인용 횟수 :
22인용 특허 :
28
초록▼
Cooling apparatuses and methods are provided for cooling an assembly including a substrate supporting multiple electronics components. The cooling apparatus includes: multiple discrete cold plates, each having a coolant inlet, a coolant outlet and at least one coolant chamber disposed therebetween;
Cooling apparatuses and methods are provided for cooling an assembly including a substrate supporting multiple electronics components. The cooling apparatus includes: multiple discrete cold plates, each having a coolant inlet, a coolant outlet and at least one coolant chamber disposed therebetween; and multiple coolant-carrying tubes, each tube extending from a respective cold plate and being in fluid communication with the coolant inlet or outlet of the cold plate. An enclosure is provided having a perimeter region which engages the substrate to form a cavity with the electronics components and cold plates being disposed within the cavity. The enclosure is configured with multiple bores, each bore being sized and located to receive a respective coolant-carrying tube of the tubes extending from the cold plates. Further, the enclosure is configured with a manifold in fluid communication with the tubes for distributing coolant in parallel to the cold plates.
대표청구항▼
What is claimed is: 1. A cooling apparatus for an electronics assembly comprising a substrate supporting multiple heat generating electronics components, the cooling apparatus comprising: multiple discrete cold plates, each cold plate having a first surface configured to couple to a respective elec
What is claimed is: 1. A cooling apparatus for an electronics assembly comprising a substrate supporting multiple heat generating electronics components, the cooling apparatus comprising: multiple discrete cold plates, each cold plate having a first surface configured to couple to a respective electronics component of the multiple electronics components, and each cold plate being a coolant-cooled cold plate including a coolant inlet and a coolant outlet with at least one coolant chamber disposed between the coolant inlet and the coolant outlet; a plurality of coolant-carrying tubes, each cold plate having at least two coolant-carrying tubes of the plurality of coolant-carrying tubes extending from a second surface thereof, each coolant-carrying tube being in fluid communication with one of the coolant inlet and the coolant outlet of the cold plate from which the coolant-carrying tube extends; an enclosure having a perimeter region for engaging the substrate to form an at least partially enclosed cavity with the multiple heat generating electronics components and the multiple cold plates being disposed within the cavity defined by the substrate and the enclosure, and wherein the enclosure is configured with a plurality of bores, each bore being sized and located to at least partially receive a respective coolant-carrying tube of the plurality of coolant-carrying tubes extending from the cold plates, the enclosure further being configured with a manifold in fluid communication with the plurality of bores and the plurality of coolant-carrying tubes disposed therein for distributing coolant in parallel to at least some cold plates of the multiple cold plates via a first set of coolant-carrying tubes of the plurality of coolant-carrying tubes in fluid communication with the coolant inlets of the multiple cold plates, and for receiving coolant from at least some cold plates of the multiple cold plates via a second set of coolant-carrying tubes of the plurality of coolant-carrying tubes in fluid communication with the coolant outlets of the multiple cold plates; and wherein the manifold further comprises a coolant inlet plenum and a coolant outlet plenum, the first set of coolant-carrying tubes being in fluid communication with the coolant inlet plenum and coupling in parallel the coolant inlets of the cold plates to the coolant inlet plenum, and the second set of coolant-carrying tubes being in fluid communication with the coolant outlet plenum and coupling in parallel the coolant outlets of the cold plates to the coolant outlet plenum, and the coolant inlet plenum and the coolant outlet plenum each comprising a plurality of coolant distribution fingers which extend over the at least some cold plates of the multiple cold plates for facilitating distribution of coolant in parallel to the at least some cold plates. 2. The cooling apparatus of claim 1, wherein the enclosure further comprises a cap, the cap being configured with the plurality of bores sized and located to at least partially receive the coolant-carrying tubes extending from the cold plates, and being disposed between the manifold and the cold plates, and wherein the plurality of coolant distribution fingers of the coolant inlet plenum are interdigitated with the plurality of coolant distribution fingers of the coolant outlet plenum. 3. The cooling apparatus of claim 2, wherein the manifold is configured with a single inlet opening in fluid communication with the coolant inlet plenum and a single outlet opening in fluid communication with the coolant outlet plenum, the single inlet opening allowing coolant to be fed to the coolant inlet plenum, and the single outlet opening allowing coolant to be exhausted from the coolant outlet plenum. 4. The cooling apparatus of claim 2, wherein the enclosure further comprises an orifice plate disposed between the cap and the manifold, the orifice plate being configured with a plurality of orifices, and wherein each coolant-carrying tube is axially aligned with an orifice of the plurality of orifices of the orifice plate, and coolant flows through each aligned orifice and coolant-carrying tube when passing between the enclosure and the multiple cold plates. 5. The cooling apparatus of claim 4, wherein at least some orifices of the plurality of orifices in the orifice plate are differently sized resulting in different amounts of coolant flow through the multiple cold plates, and wherein the different sizes of the at least some orifices are tailored so that coolant flow through the multiple cold plates results in a desired operating temperature for each electronics component, and wherein at least some electronics components of the multiple electronics components generate different amounts of heat when in operation. 6. The cooling apparatus of claim 2, further comprising a sealant disposed between each coolant-carrying tube and an inner wall of the cap defining the associated bore at least partially receiving the coolant-carrying tube, and wherein the sealant comprises at least one of solder or at least one O-ring seal. 7. The cooling apparatus of claim 6, further comprising an interface material disposed between the first surface of each cold plate and its respective electronics component, the interface material comprising at least one of an adhesive or a metallurgical bond. 8. The cooling apparatus of claim 6, further comprising multiple spring biasing mechanisms, each spring biasing mechanism being coupled to a respective cold plate and being disposed between the cap and the respective cold plate, each biasing mechanism biasing the respective cold plate away from the cap, and towards the associated heat generating electronics component when the cooling apparatus is in use. 9. The cooling apparatus of claim 6, wherein the sealant comprises two O-ring seals, and wherein each coolant-carrying tube has two circumferential grooves in an outer surface portion thereof disposed within the associated bore, each circumferential groove partially receiving and positioning one O-ring seal of the two O-ring seals. 10. The cooling apparatus of claim 1, wherein the plurality of coolant-carrying tubes are similarly configured and sized, and wherein the bores in the enclosure are sufficiently sized to accommodate at least one of height and angular orientation variation of at least some electronics components relative to the substrate. 11. A cooled electronics module comprising: an electronics assembly including a substrate and multiple heat generating electronics components; and a cooling apparatus for facilitating cooling of the multiple heat generating electronics components, the cooling apparatus comprising: multiple discrete cold plates, each cold plate having a first surface configured to couple to a respective electronics component of the multiple electronics components, and each cold plate being a coolant-cooled cold plate configured with a coolant inlet and a coolant outlet with at least one coolant chamber disposed between the coolant inlet and the coolant outlet; a plurality of coolant-carrying tubes, each cold plate having at least two coolant-carrying tubes of the plurality of coolant-carrying tubes extending from a second surface thereof, each coolant-carrying tube being in fluid communication with one of the coolant inlet and the coolant outlet of the cold plate from which the coolant-carrying tube extends; and an enclosure having a perimeter region engaging the substrate to form an at least partially enclosed cavity with the multiple heat generating electronics components and the multiple cold plates being disposed within the cavity defined by the substrate and the enclosure, and wherein the enclosure is configured with a plurality of bores, each bore being sized and located to at least partially receive a respective coolant-carrying tube of the plurality of coolant-carrying tubes extending from the cold plates, the enclosure further being configured with a manifold in fluid communication with the plurality of bores and the plurality of coolant-carrying tubes disposed therein for distributing coolant in parallel to at least some cold plates of the multiple cold plates via a first set of coolant-carrying tubes of the plurality of coolant-carrying tubes in fluid communication with the coolant inlets of the multiple cold plates, and for receiving coolant from at least some cold plates of the multiple cold plates via a second set of coolant-carrying tubes of the plurality of coolant-carrying tubes in fluid communication with the coolant outlets of the multiple cold plates. 12. The cooled electronics module of claim 11, wherein the enclosure further comprises a cap, the cap being configured with the plurality of bores sized and located to at least partially receive the coolant-carrying tubes extending from the cold plates, and being disposed between the manifold and the cold plates, and wherein the plurality of coolant distribution fingers of the coolant inlet plenum are interdigitated with the plurality of coolant distribution fingers of the coolant outlet plenum. 13. The cooled electronics module of claim 12, wherein the enclosure further comprises an orifice plate disposed between the cap and the manifold, the orifice plate being configured with a plurality of orifices, and wherein each coolant-carrying tube is axially aligned with an orifice of the plurality of orifices of the orifice plate, and coolant flows through each aligned orifice and coolant-carrying tube when passing between the enclosure and the multiple cold plates. 14. The cooled electronics module of claim 13, wherein at least some orifices of the plurality of orifices in the orifice plate are differently sized resulting in different amounts of coolant flow through the multiple cold plates, and wherein the different sizes of the at least some orifices are tailored so that coolant flow through the multiple cold plates results in a desired operating temperature for each electronics component, and wherein at least some electronics components of the multiple electronics components generate different amounts of heat when in operation. 15. The cooled electronics module of claim 12, further comprising a sealant disposed between each coolant-carrying tube and an inner wall of the cap defining the associated bore at least partially receiving the coolant-carrying tube, and wherein the sealant comprises at least one of solder or at least one O-ring seal, and further comprising an interface material disposed between the first surface of each cold plate and its respective electronics component, the interface material comprising at least one of an adhesive or a metallurgical bond. 16. The cooled electronics module of claim 15, wherein the sealant comprises two O-ring seals, and wherein each coolant-carrying tube as two circumferential grooves in an outer surface portion thereof disposed within the associated bore, each circumferential groove partially receiving and positioning one O-ring seal of the two O-ring seals. 17. The cooled electronics module of claim 11, wherein the plurality of coolant-carrying tubes are similarly configured and sized, and wherein the bores in the enclosure are sufficiently sized to accommodate at least one of height and angular orientation variation of at least some electronics components relative to the substrate.
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이 특허에 인용된 특허 (28)
Mathias Joseph S. (Riverton NJ) Mittal Faquir C. (Audubon PA), Apparatus for cooling integrated circuit chips.
Young Steven P. (LaGrangeville NY) Acocella John (Hopewell Junction NY) Fahey Albert J. (Pleasant Valley NY) Messina Gaetano P. (Hopewell Junction NY) Song Seaho (Highland NY), Apparatus for indirect impingement cooling of integrated circuit chips.
Campbell,Levi A.; Chu,Richard C.; Ellsworth, Jr.,Michael J.; Iyengar,Madhusudan K.; Schmidt,Roger R.; Simons,Robert E., Cooling apparatus, cooled electronic module and methods of fabrication thereof employing an integrated manifold and a plurality of thermally conductive fins.
Campbell,Levi A.; Chu,Richard C.; Ellsworth, Jr.,Michael J.; Iyengar,Madhusudan K.; Schmidt,Roger R.; Simons,Robert E., Cooling apparatuses and methods employing discrete cold plates compliantly coupled between a common manifold and electronics components of an assembly to be cooled.
Campbell, Levi A.; Chu, Richard C.; Ellsworth, Jr., Michael J.; Iyengar, Madhusudan K.; Schmidt, Roger R.; Simons, Robert E., Cooling system and method employing a closed loop coolant path and micro-scaled cooling structure within an electronics subsystem of an electronics rack.
Tanzer Herbert J. (Topanga CA) Goodarzi Gholam A. (Torrance CA) Olaveson Richard J. (Inglewood CA), Integral extended surface cooling of power modules.
Goodson,Kenneth; Kenny,Thomas; Zhou,Peng; Upadhya,Girish; Munch,Mark; McMaster,Mark; Horn,James, Method and apparatus for achieving temperature uniformity and hot spot cooling in a heat producing device.
Kenny,Thomas W.; Munch,Mark; Zhou,Peng; Shook,James Gill; Upadhya,Girish; Goodson,Kenneth; Corbin,David, Method and apparatus for flexible fluid delivery for cooling desired hot spots in a heat producing device.
Campbell, Levi A.; David, Milnes P.; Demetriou, Dustin W.; Ellsworth, Jr., Michael J.; Schmidt, Roger R.; Simons, Robert E., Composite heat sink structures.
Campbell, Levi A.; David, Milnes P.; Demetriou, Dustin W.; Ellsworth, Jr., Michael J.; Schmidt, Roger R.; Simons, Robert E., Composite heat sink structures.
Campbell, Levi A.; David, Milnes P.; Demetriou, Dustin W.; Ellsworth, Jr., Michael J.; Schmidt, Roger R.; Simons, Robert E., Composite heat sink structures.
Campbell, Levi A.; Chu, Richard C.; Ellsworth, Jr., Michael J.; Iyengar, Madhusudan K.; Schmidt, Roger R.; Simons, Robert E., Cooling apparatuses with discrete cold plates compliantly coupled between a common manifold and electronics components of an assembly to be cooled.
Campbell, Levi A.; David, Milnes P.; Demetriou, Dustin W.; Ellsworth, Jr., Michael J.; Schmidt, Roger R.; Simons, Robert E., Liquid-cooled heat sink assemblies.
Campbell, Levi A.; David, Milnes P.; Demetriou, Dustin W.; Ellsworth, Jr., Michael J.; Schmidt, Roger R.; Simons, Robert E., Liquid-cooled heat sink assemblies.
Chen, Richard T.; Tan, Will J., Micro heat transfer arrays, micro cold plates, and thermal management systems for cooling semiconductor devices, and methods for using and making such arrays, plates, and systems.
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