Abstract: A chassis of an information handling system (IHS) includes a lateral segment that spans across a directional path of air travelling from an air intake side to an air exhaust side and including receiving affordances for insertion of a lateral support for a directional air mover. A user can select one of a first lateral support and a second lateral support that is insertable into the lateral segment and securable to the receiving affordances. The first lateral support has apertures of a first size to receive respective first fan modules and the second lateral support has apertures of a second size to receive respective second fan modules. An inserted one of the first and second lateral supports is selected based on a cooling air requirement corresponding to user selected compute components placed within the chassis to operate within the IHS.

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: 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: 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 Rack Information Handling System (RIHS) has a liquid cooling subsystem that provides cooling liquid to liquid cooled (LC) nodes received in chassis-receiving bays of a rack. Leak collection structures are positioned to receive cooling liquid that leaks from the liquid cooling subsystem. Liquid sensors detect a presence of leaked cooling liquid in the leak collection structures. A leak detection subsystem responds to a detected presence of liquid by providing a leak indication. In one or more embodiments, the liquid cooling subsystem has a liquid rail formed by more than one rack interconnections vertically aligned in a rear section of the rack that are connected by modular rail conduits for node-to-node fluid transfer. The leak collection structures include a pipe cover received over at least one modular rail conduit. A liquid cavity of each pipe cover spills over into another lower pipe cover at a rate that can be correlated to severity of the leak.

Abstract: A method provides a service mode within a direct-injection liquid-cooled (DL) Rack Information Handling System (RIHS) having at least one liquid-cooled (LC) node. The method includes: in response to detecting selection of the service mode trigger, transmitting a first control signal to cause a proportional valve to move to an open position for enhanced cooling of the node; monitoring a temperature being sensed in the node; and in response to the temperature reaching a pre-established service mode temperature: forwarding a second control signal, to cause the proportional valve to move to a fully closed position; and generating a notification of an entry of the RIHS into a service mode during which an LC node can be re-engaged with the supply and return port, without affecting an operational on-state of the RIHS and without incurring significant hydraulic pressure when re-engaging the LC node with the liquid cooling system.

Abstract: A liquid handling (LH) block of an Information Handling System (IHS) having a first transfer conduit having node-receiving intake port/s sealably engaged for fluid transfer to node intake port/s of Liquid Cooled (LC) node/s and having supply connection/s. A second transfer conduit has node-receiving outlet port/s sealably engaged for fluid transfer to LC node output port/s of the LC node/s and having return connection/s. A radiator includes a portion of the second transfer conduit. A cooling liquid distribution subsystem has a user selectable first and second sets of liquid conduits connectable to the module in one of an open-loop configuration utilizing facility supplied cooling liquid and a closed-loop configuration to recirculate cooling liquid between the block radiator and the node-level system of conduits.

Abstract: An Information Handling System (IHS) includes at least one node provisioned with heat-generating components and an air passage that enables air to pass through the node and exit the node as exhaust air. An air-to-liquid heat exchanger (ATLHE) block is placed in a path of the exhaust air. The ATLHE block has an air directing structure, one or more air movers to move the exhaust air through the air directing structure, and an ATLHE. The ATLHE includes a liquid transfer conduit having at least one liquid supply port extending into a heat transfer section, which terminates into at least one liquid return port, the liquid transfer conduit enabling cooling liquid transfer through the ATLHE. A liquid cooling subsystem includes supply and return conduits. The supply conduit is sealably mated to the at least one supply port and the return conduit is sealably mated to the at least one return port.

Abstract: A method for designing and assembling a modular IT rack includes a manufacturer designing and constructing lightweight, modular corrugated cardboard modules/segments and corresponding banding and corner components that can be used to assemble the modular IT rack. A user/assembler of the modular IT rack assembles modular tray grouping and enclosure (MTGE) casing units using a first set of cardboard modules. The user constructs trays using a second set of cardboard modules. The user affixes cable support components to the sides of sub-groups of the constructed trays. The user encloses sub-groups of trays having the affixed cable support components within the assembled MTGE casing units to create MTGE blocks. The user vertically stacks the MTGE blocks having the tray sub-groups and the affixed cable support components enclosed within. The user aligns and secures the vertically stacked MTGE blocks in a fixed position using banding and corner components.

Abstract: Systems and methods for a dry power supply for immersion-cooled Information Handling Systems (IHSs) are described. In some embodiments, an IHS may include: a chassis configured to be at least partially disposed under a surface of a dielectric liquid coolant, where the chassis includes one or more components configured to be cooled by the dielectric liquid coolant during operation of the IHS; and a power supply coupled to the chassis and configured to provide power to the one or more components via an adaptor configured to maintain the power supply above the surface of the dielectric liquid coolant during operation of the IHS, where the power supply comprises a fan configured to blow air.

Abstract: In accordance with the present disclosure, a detachable power cable interface box (PCIB) for coupling AC power to a rack-level power infrastructure is described. The detachable PCIB includes a body section and a terminal disposed within the body section. The terminal may be coupled to an AC power source. A wiring block may also be disposed within the body, and the modular wiring block may be coupled to the terminal. The wiring block may arrange power input from the AC power source into a pre-determined output configuration corresponding to a detachable interface. The system may also include the detachable interface, and the detachable interface may be configured to couple with an integrated connector of the rack-level power infrastructure. The detachable interface may be common to all types of AC power sources.

Abstract: An information handling system (IHS) has a heatsink including cooling fins each having a plate structure and attached to the base in spaced parallel arrangement for receiving a first air flow that is in parallel alignment to the conductive surface. The heatsink includes a tunnel formed through the cooling fins perpendicularly to the first air flow. The IHS provides cooling air to one or more heatsinks without thermally shadowing other compute components as well as providing a second flow of cooling air to downstream component/s via the tunnel of each heatsink.

Abstract: In accordance with the present disclosure, a scalable and modular rack-level power infrastructure is described. The power infrastructure may include a power distribution unit (PDU), which receives alternating current (AC) power from an external power source. The PDU may be coupled to a busbar and output DC power to the busbar. The busbar may be coupled to a server within a rack-server system and provide DC power to the server. Additionally, the infrastructure may include a battery back-up unit (BBU) element coupled to the busbar. The BBU element may charge from and discharge to the busbar.

Abstract: In accordance with the present disclosure, a detachable power cable interface box (PCIB) for coupling AC power to a rack-level power infrastructure is described. The detachable PCIB includes a body section and a terminal disposed within the body section. The terminal may be coupled to an AC power source. A wiring block may also be disposed within the body, and the modular wiring block may be coupled to the terminal. The wiring block may arrange power input from the AC power source into a pre-determined output configuration corresponding to a detachable interface. The system may also include the detachable interface, and the detachable interface may be configured to couple with an integrated connector of the rack-level power infrastructure. The detachable interface may be common to all types of AC power sources.

Abstract: A method for structurally protecting an information handling system (IHS) for both shipment and operation includes: providing a lightweight server (LWS) chassis; providing a casing that is formed of structurally rigid material to protect the server chassis and any functional compute components inserted within the server chassis; inserting the LWS chassis into the casing; and fully enclosing the LWS chassis within the casing using sealable flaps of the casing such that the casing can be utilized as an external shipping carton in which the IHS is physically shipped to a destination.

Abstract: An Information Handling System (IHS) includes a chassis having a base panel, a selected modular cover, and a latching structure. The base panel has an upper chassis surface to receive selected compute components and infrastructure components that vary in height desired for the fully assembled IHS or rack in which the IHS will be inserted. The selected modular cover can have peripheral sides of a vertical height to complement a vertical height of the lateral guides of the base panel to create either a first height enclosure of a first height to house compute components of less than the first height or a second height enclosure of a second height to house compute components of less than the second height but greater than the first height. The latching structure is formed between the peripheral sides of the selected one of the first and second modular cover and the lateral guides of the base panel.

Abstract: An Information Handling System (IHS) includes a chassis configured with infrastructure components arranged for housing one or more compute components. The chassis includes a bottom segment having a base wall to receive the one or more compute components. One or more connecting cabling interconnects the compute components to assemble a fully functional IHS. A cover is fixedly engaged to the bottom segment to form a casing enclosing inserted IHS components. The cover has at least one access panel that can be moved from a closed position to an open position to expose one or more top loaded slots and enable insertion and/or removal of the respective compute component, after assembly of the chassis.

Abstract: An information handling system (IHS) includes user selectable compute components including a storage drive. A chassis includes a base panel having an upper chassis surface. At least one resilient component is coupled to the upper chassis surface. An upwardly presented adhesive surface on one or more of the at least one resilient component can fixedly engage and provide vibration damping for a vibration-susceptible compute component that is inserted during provisioning or later modification or repair of the IHS.

Abstract: A chassis of an information handling system (IHS) includes a lateral segment that spans across a directional path of air travelling from an air intake side to an air exhaust side and including receiving affordances for insertion of a lateral support for a directional air mover. A user can select one of a first lateral support and a second lateral support that is insertable into the lateral segment and securable to the receiving affordances. The first lateral support has apertures of a first size to receive respective first fan modules and the second lateral support has apertures of a second size to receive respective second fan modules. An inserted one of the first and second lateral supports is selected based on a cooling air requirement corresponding to user selected compute components placed within the chassis to operate within the IHS.

Abstract: An information handling system (IHS) includes a modularly-constructed chassis for receiving varying sizes of snap-in compute components for assembly of the IHS. The modularly-constructed chassis includes a base panel having a chassis surface that includes more than one engagement feature formed within the chassis surface and a selected at least one of a first tray that is sized to receive a first compute component of a first size and a second tray that is sized to receive a second compute component of a second size. The first and second trays have a bottom surface with more than one complementary engagement feature formed within the bottom surface to snap-in corresponding engagement features of the base panel. The IHS includes one or more connecting cabling interconnecting the at least two compute components.