Abstract: An apparatus and method for measuring the physical quantities of a data center during operation and method for servicing large-scale computing systems is disclosed. The apparatus includes a cart that supports a plurality of sensors. The cart is moveable within the data center. The sensors capture temperature or other physical parameters within the room. The sensor readings, along with position and orientation information pertaining to the cart are transmitted to a computer system where the data is analyzed to select the optimum temperature or other system environmental parameters for the data center.

Abstract: Apparatus and method are 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 cooling apparatus and method of fabrication are provided for facilitating removal of heat from a heat generating electronic device. The cooling apparatus includes a plurality of thermally conductive fins coupled to and projecting away from a surface to be cooled. The fins facilitate transfer of heat from the surface to be cooled. The apparatus further includes an integrated manifold having a plurality of inlet orifices for injecting coolant onto the surface to be cooled, and a plurality of outlet openings for exhausting coolant after impinging on the surface to be cooled. The inlet orifices and the outlet openings are interspersed in a common surface of the integrated manifold. Further, the integrated manifold and the surface to be cooled are disposed with the common surface of the manifold and the surface to be cooled in spaced, opposing relation, and with the plurality of thermally conductive fins disposed therebetween.

Abstract: A cooling apparatus and method of fabrication are provided for facilitating removal of heat from a heat generating electronic device. The cooling apparatus includes an integrated coolant inlet and outlet manifold having a plurality of inlet orifices for injecting coolant onto a surface to be cooled, and a plurality of outlet openings for exhausting coolant after impinging on the surface to be cooled. The inlet orifices and the outlet openings are interspersed in a common surface of the integrated manifold. A plurality of exit openings are also provided on at least one edge surface of the manifold. These exit openings are in fluid communication through the manifold with the outlet openings to facilitate exhausting of coolant through the outlet openings and minimize pressure drop through the manifold. At least one surface plane projection of the at least one edge surface intersects a surface plane projection of the common surface.

Abstract: Apparatus and method are provided for facilitating cooling of an electronics rack employing a closed loop heat exchange system. The closed loop heat exchange system includes a first heat exchanger, a second heat exchanger, and a coolant distribution loop connecting the first heat exchanger and the second heat exchanger. When operational, the coolant distribution loop allows coolant to circulate between the first heat exchanger and the second heat exchanger. The closed loop heat exchange system couples to the electronics rack with the first heat exchanger disposed at an air inlet side of the electronics rack, and the first heat exchanger and the second heat exchanger disposed in different inlet-to-outlet air flow paths through the electronics rack to reduce an imbalance in air flow temperature of the different inlet-to-outlet air flow paths through the electronics rack.

Abstract: A coolant flow drive apparatus is provided for facilitating removal of heat from a cooling structure coupled to a heat generating electronics component. The coolant flow drive apparatus includes a turbine in fluid communication with a primary coolant flowing within a primary coolant flow loop, and a pump in fluid communication with a secondary coolant within a secondary coolant flow path. The secondary fluid flow path is separate from the primary coolant flow path. The flow drive apparatus further includes a magnetic coupling between the turbine and the pump, wherein the turbine drives the pump through the magnetic coupling to pump secondary coolant through the secondary coolant flow path.

Abstract: A cooling apparatus and method of fabrication are provided for facilitating removal of heat from a heat generating electronic device. The cooling apparatus includes a thermally conductive base having a substantially planar main surface, and a plurality of thermally conductive pin fins wire-bonded to the main surface of the thermally conductive base and disposed to facilitate the transfer of heat from the thermally conductive base. The thermally conductive base can be a portion of the electronic device to be cooled or a separate structure coupled to the electronic device to be cooled. If a separate structure, the thermally conductive base has a coefficient of thermal expansion within a defined range of a coefficient of thermal expansion of the electronic device. In one implementation, the wire-bonded pin fins are discrete, looped pin fins separately wire-bonded to the main surface and spaced less than 300 micrometers apart in an array.

Abstract: A cooling apparatus for an electronics assembly having a substrate and one or more electronics devices includes an enclosure sealably engaging the substrate to form a cavity, with the electronics devices and a heat exchange assembly being disposed within the cavity. The heat exchange assembly defines a primary coolant flow path and a separate, secondary coolant flow path. The primary coolant flow path includes first and second chambers in fluid communication, and the secondary flow path includes a third chamber disposed between the first and second chambers. The heat exchange assembly provides a first thermal conduction path between primary coolant in the first chamber and secondary coolant in the third chamber, and a second thermal conduction path between primary coolant in the second chamber and secondary coolant in the third chamber. The heat exchange assembly further includes coolant nozzles to direct primary coolant towards the electronics devices.

Abstract: A method and apparatus for real-time thermal characterization of a fully operating cooling device (1002). A heat source (1004) is applied to one or more areas on a cooling device (1002) to produce non-uniform heating of the cooling device. Infrared (IR) temperature imaging (1006) detects and measures the thermal distribution of the heat source (1004) on the cooling device (1002) to develop a thermal characterization of the cooling device (1002).

Abstract: An isolation valve assembly, a coolant connect/disconnect assembly, a cooled multi-blade electronics center, and methods of fabrication thereof are provided employing an isolation valve and actuation mechanism. The isolation valve is disposed within at least one of a coolant supply or return line providing liquid coolant to the electronics subsystem. The actuation member is coupled to the isolation valve to automatically translate a linear motion, resulting from insertion of the electronics subsystem into the operational position within the electronics housing, into a rotational motion to open the isolation valve and allow coolant to pass. The actuation mechanism, which operates to automatically close the isolation valve when the liquid cooled electronics subsystem is withdrawn from the operational position, can be employed in combination with a compression valve coupling, with one fitting of the compression valve coupling being disposed serially in fluid communication with the isolation valve.

Abstract: A cooling approach is provided for cooling an electronics subsystem, such as an electronics rack. The cooling approach includes a coolant conditioning unit and a thermal capacitor unit. The coolant conditioning unit has a heat exchanger, a first cooling loop and a second cooling loop. The first cooling loop receives facility coolant from a facility coolant source and passes at least a portion thereof to the heat exchanger. The second cooling loop provides system coolant to the electronics subsystem, and expels heat in the heat exchanger from the electronics subsystem to the facility coolant in the first cooling loop. The thermal capacitor unit is in fluid communication with the second cooling loop to maintain temperature of the system coolant within a defined range for a period of time upon shutdown or failure of the facility coolant in the first cooling loop, thereby allowing continued operation of the electronics subsystem.

Abstract: A thermally conductive composite interface and methods of fabrication are provided for coupling a cooling assembly and at least one electronic device. The interface includes a plurality of thermally conductive contacts for mechanically coupling the cooling assembly and electronic device, and an adhesive material at least partially surrounding the thermally conductive contacts. The thermally conductive contacts are made of a first material, which has a first thermal conductivity, and the adhesive material is a second material, which has a second thermal conductivity, with the first thermal conductivity being greater than the second thermal conductivity. The adhesive material rigidly bonds the cooling assembly and the at least one electronic device together, thereby relieving strain on the plurality of thermally conductive contacts resulting from a coefficient of thermal expansion mismatch between the cooling assembly and the at least one electronic device.

Abstract: An electronic device cooling assembly and fabrication method are provided which include a manifold with an orifice for injecting a cooling liquid onto a surface to be cooled, and an elastic pin support material with an opening aligned to the orifice of the manifold. Multiple thermally conductive pins are mounted within the support material, extending therefrom, and are sized to physically contact the surface to be cooled. The support material has a thickness and compliance which facilitates thermal interfacing of the pins to the surface by allowing second ends thereof to move vertically and tilt. The second end of each pin has a planar surface which is normal to an axis of the pin, and the support material facilitates the planar surfaces of the second pin ends establishing planar contact with the surface to be cooled, notwithstanding that the surface may be other than planar.