Abstract: An apparatus is provided for facilitating cooling of an electronics rack employing an air delivery structure coupled to the electronics rack. The air delivery structure delivers air flow at a location external to the electronics rack and in a direction to facilitate mixing thereof with re-circulating exhausted inlet-to-outlet air flow from the air outlet side of the electronics rack to the air inlet side thereof. The delivered air flow is cooler than the re-circulating exhausted inlet-to-outlet air flow and when mixed with the re-circulating air flow facilitates lowering air inlet temperature at a portion of the air inlet side of the electronics rack, thereby enhancing cooling of the electronics rack.

Abstract: A heat exchanger, method of fabrication and cooled electronics system employing the heat exchanger are provided. The heat exchanger, which in one embodiment cools air provided to heat generating components of a computer system, is disposed at an angle with respect to a direction of airflow. The heat exchanger includes a plurality of primary fins oriented parallel, and at least one plurality of secondary fins extending from at least one of a leading edge and a trailing edge of the plurality of primary fins. Each secondary fin extends from a respective primary fin at an angle other than 0° to facilitate airflow through the heat exchanger. Additionally, the secondary fins are fixedly positioned relative to and integral with the primary fins, thereby providing an increased heat transfer surface area.

Abstract: A cooling method are provided for cooling air exiting one or more electronics racks of a data center. The cooling system includes at least one cooling station separate and freestanding from at least one respective electronics rack of the data center, and configured for disposition of an air outlet side of electronics rack adjacent thereto for cooling egressing air from the electronics rack. The cooling station includes a frame structure separate and freestanding from the respective electronics rack, and an air-to-liquid heat exchange assembly supported by the frame structure. The heat exchange assembly includes an inlet and an outlet configured to respectively couple to coolant supply and coolant return lines for facilitating passage of coolant therethrough. The air-to-liquid heat exchange assembly is sized to cool egressing air from the air outlet side of the respective electronics rack before being expelled into the data center.

Abstract: A cooling apparatus is provided for facilitating cooling of electronics drawers of an electronics rack. The apparatus includes a bi-fold door assembly configured for mounting to the electronics rack. The door assembly includes a first door and a second door, each configured for separate, hinged mounting to the electronics rack. The apparatus further includes a coolant distribution apparatus, wherein a coolant supply manifold thereof is mounted to the first door and a coolant return manifold thereof is mounted to the second door. Separate connections are coupled in fluid communication with the coolant supply and return manifolds for facilitating supply and return of coolant to and from the manifolds, and for facilitating pivotal movement of the doors relative to the electronics rack. A plurality of coolant distribution ports are provided within the supply and return manifolds, and disposed to facilitate supply and return of coolant to the electronics drawers.

Abstract: A cooling system and method are provided which include a facility cooling unit, a cooling tower, and one or more thermal capacitor units. The facility cooling unit, which includes a heat dissipation coolant loop, facilitates thermal energy extraction from a facility, such as a data center, for expelling of the energy to coolant within the heat dissipation coolant loop. The cooling tower is in fluid communication with the coolant loop, and includes a liquid-to-air heat exchanger for expelling thermal energy from coolant of the heat dissipation coolant loop to the surrounding environment. The thermal capacitor unit is in fluid communication with the heat dissipation coolant loop to facilitate efficient thermal energy transfer from coolant with in the coolant loop to the surrounding environment with variation in ambient temperature about the cooling tower.

Abstract: A thermal spreading device disposable between electronic circuitry and a heat sink includes a substrate having parallel first and second faces and conduits extending through the substrate between the faces. The substrate material has a first thermal conductivity value in a direction parallel to the faces and a second thermal conductivity value in a direction normal to the faces, with the second thermal conductivity value being less than the first thermal conductivity value. The conduit material has a thermal conductivity value associated with it, with the thermal conductivity value being greater than the second thermal conductivity value of the substrate. One method of fabricating the thermal spreading device includes disposing a molding material radially about the rods and hardening the material. Other methods include press fitting and shrink fitting the rods into a substrate material.

Abstract: A cooled electronic module and method of fabrication are provided employing a cooling apparatus for removing heat from one or more electronic devices disposed on a substrate. The cooling apparatus includes a supply manifold structure having a plurality of inlet orifices for injecting coolant onto a surface to be cooled, and a return manifold structure. The return manifold structure, which is fabricated of a thermally conductive material, has a base surface sealed to the surface to be cooled along a periphery thereof employing a thermally conductive, coolant-tight seal. The return manifold structure provides at least one return passageway for exhausting coolant after impinging on the surface to be cooled, wherein coolant exhausting through the at least one passageway cools the return manifold structure, thereby facilitating further cooling of the surface to be cooled in a region where the base surface is sealed to the surface to be cooled.

Abstract: A cooling apparatus is provided for facilitating cooling of electronics drawers of an electronics rack. The apparatus includes a bi-fold door assembly configured for mounting to the electronics rack. The door assembly includes a first door and a second door, each configured for separate, hinged mounting to the electronics rack. The apparatus further includes a coolant distribution apparatus, wherein a coolant supply manifold thereof is mounted to the first door and a coolant return manifold thereof is mounted to the second door. Separate swivel connections are coupled in fluid communication with the coolant supply and return manifolds for facilitating supply and return of coolant to and from the manifolds, and for facilitating pivotal movement of the doors relative to the electronics rack. A plurality of coolant distribution ports are provided within the supply and return manifolds, and disposed to facilitate supply and return of coolant to the electronics drawers.

Abstract: A system for cooling an electronics system is provided. The cooling system includes a monolithic structure preconfigured for cooling multiple electronic components of the electronics system when coupled thereto. The monolithic structure includes multiple liquid-cooled cold plates configured and disposed in spaced relation to couple to respective electronic components; a plurality of coolant-carrying tubes metallurgically bonded in fluid communication with the multiple liquid-cooled cold plates, and a liquid-coolant header subassembly metallurgically bonded in fluid communication with multiple coolant-carrying tubes. The header subassembly includes a coolant supply header metallurgically bonded to coolant supply tubes and a coolant return header metallurgically bonded to coolant return tubes.

Abstract: A cooling system and method are provided for cooling air exiting one or more electronics racks of a data center. The cooling system includes at least one cooling station separate and freestanding from at least one respective electronics rack of the data center, and configured for disposition of an air outlet side of electronics rack adjacent thereto for cooling egressing air from the electronics rack. The cooling station includes a frame structure separate and freestanding from the respective electronics rack, and an air-to-liquid heat exchange assembly supported by the frame structure. The heat exchange assembly includes an inlet and an outlet configured to respectively couple to coolant supply and coolant return lines for facilitating passage of coolant therethrough. The air-to-liquid heat exchange assembly is sized to cool egressing air from the air outlet side of the respective electronics rack before being expelled into the data center.

Abstract: A cooling apparatus and method of fabrication are provided for facilitating removal of heat from an electronic device. The cooling apparatus includes a manifold structure having a plurality of inlet and outlet passageways for injecting coolant onto, and exhausting coolant after impinging on, a surface to be cooled. The coolant inlet and outlet passageways are interleaved in the manifold structure, and coolant is injected and exhausted through a common edge of the manifold. The manifold structure further includes coolant inlet and outlet plenums, with coolant passing through the inlet passageways from the inlet plenum in a first direction and coolant passing through the outlet passageways to the outlet plenum in a second direction, the first and second directions being perpendicular to the surface to be cooled and being opposite directions, and wherein the manifold structure is contained within a rectangular volume defined by a projection of the common edge.

Abstract: A conductive heat transport cooling system and method are provided for cooling primary and secondary heat generating components of an electronics system. The cooling system includes a liquid-based cooling subsystem including at least one liquid-cooled cold plate physically coupled to at least one primary heat generating component of the electronics system, and a thermally conductive coolant-carrying tube coupled to and in fluid communication with the at least one liquid-cooled cold plate. A thermally conductive auxiliary structure is coupled to the coolant-carrying tube and to at least one secondary heat generating component of the electronics system. When in use, the thermally conductive auxiliary structure provides conductive heat transport from the at least one secondary heat generating component to the at least one thermally conductive coolant-carrying tube coupled thereto, and hence via convection to liquid coolant passing therethrough.

Abstract: Cooling apparatuses and methods are provided for cooling an assembly including a planar support structure supporting multiple electronics components. The cooling apparatus includes: multiple discrete cold plates, each having a coolant inlet, coolant outlet and at least one coolant carrying channel disposed therebetween; and a manifold for distributing coolant to and exhausting coolant from the cold plates. The cooling apparatus also includes multiple flexible hoses connecting the coolant inlets of the cold plates to the manifold, as well as the coolant outlets to the manifold, with each hose segment being disposed between a respective cold plate and the manifold. A biasing mechanism biases the cold plates away from the manifold and towards the electronics components, and at least one fastener secures the manifold to the support structure, compressing the biasing mechanism, and thereby forcing the parallel coupled cold plates towards their respective electronics components to ensure good thermal interface.

Abstract: An apparatus is provided for facilitating cooling of an electronics rack. The apparatus includes a heat exchange assembly mounted to an outlet door cover hingedly affixed to an air outlet side of the rack. The heat exchange assembly includes a support frame, an air-to-liquid heat exchanger, and first and second perforated planar surfaces covering first and second main sides, respectively, of the air-to-liquid heat exchanger. The heat exchanger is supported by the support frame and includes inlet and outlet plenums disposed adjacent to the edge of the outlet door cover hingedly mounted to the rack. Each plenum is in fluid communication with a respective connect coupling, and the heat exchanger further includes multiple horizontally-oriented heat exchange tube sections each having serpentine cooling channel with an inlet and an outlet coupled to the inlet plenum and outlet plenum, respectively. Fins extend from the heat exchange tube sections.

Abstract: A system for cooling an electronics system is provided. The cooling system includes a monolithic structure preconfigured for cooling multiple electronic components of the electronics system when coupled thereto. The monolithic structure includes multiple liquid-cooled cold plates configured and disposed in spaced relation to couple to respective electronic components; a plurality of coolant-carrying tubes metallurgically bonded in fluid communication with the multiple liquid-cooled cold plates, and a liquid-coolant header subassembly metallurgically bonded in fluid communication with multiple coolant-carrying tubes. The header subassembly includes a coolant supply header metallurgically bonded to coolant supply tubes and a coolant return header metallurgically bonded to coolant return tubes.

Abstract: A conductive heat transport cooling system and method are provided for cooling primary and secondary heat generating components of an electronics system. The cooling system includes a liquid-based cooling subsystem including at least one liquid-cooled cold plate physically coupled to at least one primary heat generating component of the electronics system, and a thermally conductive coolant-carrying tube coupled to and in fluid communication with the at least one liquid-cooled cold plate. A thermally conductive auxiliary structure is coupled to the coolant-carrying tube and to at least one secondary heat generating component of the electronics system. When in use, the thermally conductive auxiliary structure provides conductive heat transport from the at least one secondary heat generating component to the at least one thermally conductive coolant-carrying tube coupled thereto, and hence via convection to liquid coolant passing therethrough.

Abstract: A hybrid cooling system and method of fabrication are provided for a multi-component electronics system. The cooling system includes an air moving device for establishing air flow across at least one primary and at least one secondary heat generating component to be cooled; and a liquid-based cooling subsystem including at least one cold plate, physically coupled to the at least one primary heat generating component, and a thermally conductive coolant-carrying tube in fluid communication with the at least one cold plate. A thermally conductive auxiliary structure is coupled to the coolant-carrying tube and includes a plurality of thermally conductive fins extending from a surface thereof. The plurality of thermally conductive fins are disposed at least partially over the at least one secondary heat generating component to be cooled, and provide supplemental cooling of at least a portion of the air flow established across the multiple components of the electronics system.

Abstract: A hybrid cooling system and method of fabrication are provided for a multi-component electronics system. The cooling system includes an air moving device for establishing air flow across at least one primary and at least one secondary heat generating component to be cooled; and a liquid-based cooling subsystem including at least one cold plate, physically coupled to the at least one primary heat generating component, and a thermally conductive coolant-carrying tube in fluid communication with the at least one cold plate. A thermally conductive auxiliary structure is coupled to the coolant-carrying tube and includes a plurality of thermally conductive fins extending from a surface thereof. The plurality of thermally conductive fins are disposed at least partially over the at least one secondary heat generating component to be cooled, and provide supplemental cooling of at least a portion of the air flow established across the multiple components of the electronics system.

Abstract: 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.

Abstract: Cooling apparatuses and methods are provided for cooling an assembly including a planar support structure supporting multiple electronics components. The cooling apparatus includes: multiple discrete cold plates, each having a coolant inlet, coolant outlet and at least one coolant carrying channel disposed therebetween; and a manifold for distributing coolant to and exhausting coolant from the cold plates. The cooling apparatus also includes multiple flexible hoses connecting the coolant inlets of the cold plates to the manifold, as well as the coolant outlets to the manifold, with each hose segment being disposed between a respective cold plate and the manifold. A biasing mechanism biases the cold plates away from the manifold and towards the electronics components, and at least one fastener secures the manifold to the support structure, compressing the biasing mechanism, and thereby forcing the parallel coupled cold plates towards their respective electronics components to ensure good thermal interface.