Abstract: Methods, systems, and devices for managing the operation of data processing systems are disclosed. A data processing system may include a computing device that may provide computer-implemented services. To provide the computer-implemented services, hardware components of the data processing system may need to operate within certain thermal dissipation requirements. To regulate the temperature of the hardware components, a fan may circulate air through the data processing system when the temperatures fall outside the thermal dissipation requirements. To regulate the temperature of the hardware components more efficiently, higher air flow rates may be desired. To increase air flow rates, a three-dimensional ventilation port may be implemented to de-constrict air flow when air enters or exits the data processing system.

Abstract: A cold plate assembly has a cold plate that is resistant to corrosion and particulate fouling, allowing direct use of facility-grade cooling liquid and omission of a secondary coolant loop that uses a purified liquid coolant. The cold plate has a surface configured with an array of extended fins coated with at least one of a hydrophobic, non-conductive, and/or anti-corrosive surface treatment. The coated extended fins provide heat transfer directly to the cooling liquid without requiring a secondary coolant loop and without causing corrosion or clogging due to facility liquid chemical contaminants or particulates. An encapsulating lid of the cold plate assembly attaches to a perimeter of the surface encompassing the array of extended fins to form a liquid cooling cavity. The encapsulating lid has input and output ports sealably connectable by an open-loop liquid distribution system, respectively, to a facility liquid supply and return.

Abstract: A liquid cooled information handling system (LC_IHS) includes a first liquid cooled node coupled to a first chassis. The LC_IHS further includes a supply conduit in fluid communication with the first chassis to cool a first liquid cooled node. The supply conduit includes a plurality of fluid paths configured such that when a first fluid path of the plurality of fluid paths is interrupted, cooling of the first liquid cooled node continues.

Abstract: A method of manufacturing a chassis that cools thermal energy generating components of an information handling system (IHS) includes: forming an enclosure with a chassis that has a base wall for provisioning a thermal energy generating component; forming one or more stiffeners each having one or more air channels formed transversely through for directing air proximate to the base wall; attaching the one or more stiffeners laterally across the base wall; and attaching a planar member that is horizontally on top of the one or more stiffeners for engaging one or more forward compute components on top of the planar member that substantially block air flow above the planar member to the thermal energy generating component. The one or more air channels eliminate thermal shadowing caused by thermal energy generating components provisioned in a rear area of the chassis.

Abstract: A method of assembling a direct-contact, liquid-cooled (DL) Rack Information Handling System (RIHS) includes inserting a leak containment barrier in a node enclosure provisioned with heat-generating functional components. The method also includes attaching a system of conduits supplying cooling liquid through the node enclosure and including a supply conduit extending from a node inlet coupling and a return conduit terminating in a node outlet coupling. A trough of the leak containment barrier underlays a portion of the system of conduits of an LC node and forms a drain path to a drain port of the node enclosure. The method further includes mounting the LC node insertably received in one node-receiving slot having a rear section configured for blind mating of the node inlet and outlet ports to a node-receiving liquid inlet port and a node-receiving liquid outlet port positioned to be inwardly facing to the couplings of the LC node.

Abstract: A liquid cooled information handling system (LC_IHS) incudes a first liquid cooled node coupled to a first chassis. The LC_IHS further includes a supply conduit in fluid communication with the first chassis to cool a first liquid cooled node. The supply conduit includes a plurality of fluid paths configured such that when a first fluid path of the plurality of fluid paths is interrupted, cooling of the first liquid cooled node continues.

Abstract: A direct-interface liquid-cooled (DL) Rack Information Handling System (RIHS) includes liquid cooled (LC) nodes each comprising a chassis received in a respective chassis-receiving bay of a rack and containing heat-generating functional components. Each LC node is configured with a system of conduits to receive direct injection of cooling liquid to regulate the ambient temperature of the node and provide cooling to the functional components inside the node by removing heat generated by the heat-generating functional components. A cooling subsystem has a liquid rail formed by more than one node-to-node, Modular Liquid Distribution (MLD) conduits, each including first and second terminal connections attached on opposite ends of a central conduit that can be rack-unit dimensioned. The MLD conduits seal to and enable fluid transfer between a port of a selected LC node and a port of an adjacent LC node.

Abstract: An external chassis wall liquid cooling system includes a chassis defining a chassis housing. A chassis wall is located on the chassis and includes a first surface that is located adjacent the chassis housing and a second surface that is located opposite the chassis wall from the first surface and that provides an outer surface of the chassis. A liquid cooling channel is defined by the chassis wall and extends through the chassis wall between the first surface and the second surface. A liquid is located in the liquid cooling channel, and a pump is coupled to the liquid cooling channel and configured to move the liquid through the liquid cooling channel. A fan system in the chassis housing may move air past heat producing components to transfer heat produced by those heat producing components, and the liquid may further dissipate that heat out of the chassis.

Abstract: A method for cooling components of an information handling system (IHS) includes detecting, via a thermal control system, at least one pressure reading, at least one temperature reading and at least one current cooling device setting of the IHS. At least one new cooling device setting is calculated based on the pressure reading and the temperature reading. The new cooling device setting is compared to the current cooling device setting associated with one or more cooling devices of the IHS. In response to the new cooling device setting being different from the current cooling device setting, one or more of the corresponding cooling devices are triggered to adjust its/their current cooling device setting to the new cooling device setting corresponding to the respective cooling device.

Abstract: An assembly for cooling a heat dissipating device reducing the thermal contact/interface resistance between a heatsink and a heat dissipating device includes: a heat dissipating device having a heat releasing surface; a heatsink having a heat absorbing surface; a gasket extending between the heat releasing surface and the heat absorbing surface to provide a sealed interstitial cavity; and a working fluid provided within the cavity. The working fluid has specific thermal properties that cause the fluid to (i) absorb latent heat and evaporate from a liquid to a vapor at the liquid surface in contact with the heat releasing surface during operation of the heat dissipating device and (ii) condense from the vapor back to the liquid when the vapor contacts the heat absorbing surface of the heatsink, thus releasing the latent heat from the vapor to the heatsink.

Abstract: A computer-implemented method controls liquid cooling of a direct injection liquid-cooled (DL) rack information handling system (RIHS). The method includes receiving, at a liquid cooling control subsystem, an incoming cooling liquid supply flow rate corresponding to an incoming cooling liquid supply being supplied to the DL RIHS. A maximum flow rate cap is calculated for each of the LC nodes. The maximum flow rate cap is transmitted to a controller for each of the LC nodes. The controller triggers each of the LC nodes to adjust the associated flow rate for that LC node to correspond to the received maximum flow rate cap for that node.

Abstract: A method of assembling a direct-contact, liquid-cooled (DL) Rack Information Handling System (RIHS) includes inserting a leak containment barrier in a node enclosure provisioned with heat-generating functional components. The method also includes attaching a system of conduits supplying cooling liquid through the node enclosure and including a supply conduit extending from a node inlet coupling and a return conduit terminating in a node outlet coupling. A trough of the leak containment barrier underlays a portion of the system of conduits of an LC node and forms a drain path to a drain port of the node enclosure. The method further includes mounting the LC node insertably received in one node-receiving slot having a rear section configured for blind mating of the node inlet and outlet ports to a node-receiving liquid inlet port and a node-receiving liquid outlet port positioned to be inwardly facing to the couplings of the LC node.

Abstract: A Rack Information Handling System (RIHS) has more than one liquid cooled (LC) node containing heat-generating functional components, each LC node configured with a system of conduits to receive cooling liquid to regulate the ambient temperature of the node and provide cooling to the functional components inside the node by removing heat generated by the heat-generating functional components. A liquid control subsystem includes electrically-actuated control valves that selectively distribute cooling liquid to LC nodes each comprising a chassis received in a respective chassis-receiving bay of a rack. Liquid sensors detect a parameter of the liquid control subsystem. A liquid controller communicatively coupled to the electrically-actuated control valves and the liquid sensors detect a rack-level liquid event based at least in part on the parameter and communicates to any LC node that is affected by the rack-level liquid event.

Abstract: A direct-contact liquid-cooled (DL) Rack Information Handling System (RIHS) includes liquid cooled (LC) nodes having a chassis received in a respective chassis-receiving bay of the rack and containing heat-generating functional components. The LC node configured with a system of conduits to receive direct contact of cooling liquid to regulate the ambient temperature of the node and provide cooling to the functional components inside the node by removing heat generated by the heat-generating functional components. The chassis has a leak containment barrier configured with a trough that underlays a portion of the system of conduits of the LC node and that forms a drain path to a drain port of the chassis. In one or more embodiments, the storage drive carrier has vibration absorbing material that mitigates vibrations of a storage drive placed in the storage drive carrier.

Abstract: In accordance with embodiments of the present disclosure, a method may include based on a power consumed by at least one information handling resource and thermal resistances associated with heat-rejecting media thermally coupled to the at least one information handling resource, calculating an exhaust temperature of the heat-rejecting media proximate to an exhaust of an enclosure housing the at least one information handling resource. The method may also include based on the exhaust temperature, controlling at least one of an operating frequency of the at least one information handling resource and a flow rate of fluid proximate to the heat-rejecting media.

Abstract: A method and an information handling system for selecting or scaling system performance. The method of scaling performance of an information handling system includes a controller receiving component data that identifies a heat removal effectiveness of a cooling component, selecting a performance characteristics of the information handling system based on the received component data, and adjusting the operating parameters of the information system to achieve the selected performance characteristics and heat removal capability. The controller communicates with the cooling component through a serial signal bus. The cooling component includes a cooling device and storage.

Abstract: A direct-interface liquid-cooled (DL) Rack Information Handling System (RIHS) includes liquid cooled (LC) nodes that include a system of conduits supplying cooling liquid through the node enclosure and including a supply conduit extending from a node inlet coupling and a return conduit terminating in a node outlet coupling. The node inlet port and the node outlet port are positioned in an outward facing direction at a rear of the node enclosure and aligned to releasably seal to the respective inlet liquid port and outlet liquid port in the node-receiving slot for fluid transfer through the system of conduits. An air-spring reducer conduit is in fluid communication with the system of conduits and shaped to trap an amount of compressible fluid that compresses during sealing engagement between the node inlet coupling and node outlet coupling and the inlet liquid port and outlet liquid port, respectively.

Abstract: A Rack Information Handling System (RIHS) has a liquid-to-liquid heat exchanger (LTLHE) that is received in a rear section of a rack and includes node-receiving supply port/s and return port/s. LTLHE includes a first liquid manifold extending between the node-receiving supply port/s and the node-receiving return port/s. LTLHE includes a second liquid manifold capable of being in sealed fluid connection to a supply conduit and a return conduit of a liquid cooling supply for fluid transfer of a second cooling liquid. LTLHE includes a transfer plate formed of thermally conductive material separating the first and second liquid manifolds for transferring heat from the first cooling liquid to the second cooling liquid. RIHS includes a node-receiving chassis configured to receive inserted liquid cooled nodes that sealingly engage for fluid transfer of the first liquid to LTLHE embedded in the rack for heat absorption and transfer by the second liquid.

Abstract: Systems and methods for component population optimization are described. In some embodiments, an Information Handling System (IHS) may include a logic circuit and a memory coupled to the logic circuit, the memory having information stored thereon that, upon access by the logic circuit, enable the IHS to: identify a connector provided on a Printed Circuit Board (PCB), wherein the connector is configured to receive a device and to couple the device to a processor; and visually indicate a status of the connector.

Abstract: A computer-implemented method regulates exhaust air temperature from direct interface liquid-cooled (DL) nodes in a rack information handling system (RIHS). The method includes receiving a first input corresponding to a desired ambient temperature of an exterior space and a second input is corresponding to an amount of heat being dissipated from functional components operating within an interior space of at least one LC node. An ambient temperature reading of the exterior space is received. A flow rate is calculated for liquid flowing through an air-to-liquid heat exchange (ATLHE) subsystem that results in an amount of heat exchange in the ATLHE subsystem, which generates exhaust air at a temperature that causes a change in the ambient temperature towards the desired ambient temperature. The flow rate is dynamically adjusted of the liquid flowing through the ATLHE subsystem to the calculated flow rate.