A field-replaceable unit (FRU) identification circuit includes a reference voltage source, a reference resistor, a plurality of comparators, and a plurality of comparator input voltage sources. The reference voltage source provides a reference voltage. A first end of the reference resistor is electrically connected to the reference voltage source. Each comparator has two inputs and an output. A first input of each comparator is electrically connected to a second end of the reference resistor. The comparator input voltage sources each provide a comparator input voltage to the second input of one of the comparators. When an FRU is electrically connected to a circuit board where the FRU identification circuit is located, the outputs of the comparators are set to a distinct combination of logical values that uniquely identifies the FRU.

A two-phase immersion cooling system for cooling electronics. The electronics are immersed in immersion tank filled with phase change liquid. As liquid evaporates due to heat generated by the electronics, it enters a vapor passageway that leads the vapor to a condenser situated remotely from the immersion tank. Upon condensing at the condenser, the condensed liquid is directed to a resupply tank, wherein the condensed liquid cools. When the level of the two phase liquid in the immersion tank drops below a set threshold, a pump is activated to deliver the condensed liquid from the resupply tank to the immersion tank. The immersion tank, vapor passageway and condenser are position inside a containment passageway. The containment passageway captures any vapor not entering the vapor passageway and direct such vapor to the condenser. An air mover generates pressure differential within the containment passageway to direct the vapor towards the condenser.

A method includes measuring a plurality of temperatures corresponding to a plurality of servers located in a data center, determining a subset of the plurality of servers as high-temperature servers based on the plurality of temperatures, and reassigning tasks from at least a portion of the subset of the plurality of servers to one or more other servers of the plurality of servers.

The cooling system for a data center includes an information technology (IT) container, secondary condensing system, and a coolant distribution unit. In particular, an IT container includes a liquid region to store cooling liquid, a vapor region to receive vapor evaporated from the cooling liquid, and a primary condenser disposed within the vapor region to condense the vapor. For example, the external cooling air or cooling liquid is controlled to be delivered to condensers. Further, a secondary condenser is coupled to the IT container via a vapor line to receive at least a portion of the vapor from the vapor region of the IT container and to condense the portion of the vapor. Furthermore, a coolant distribution unit is coupled to the IT container and the secondary condenser to store and to distribute the cooling liquid to the IT container.

A fixing assembly and an electronic device including same are disclosed. The fixing assembly includes a supporting member, a locking member, and a latching member. The supporting member includes a first supporting portion and a second supporting portion connected with each other, and the second supporting portion defines a sliding slot. The locking member includes a locking portion and a connecting portion connected with each other, the connecting portion includes a protrusion and a latching hole. The protrusion is slidably arranged in the sliding slot. When the protrusion slides along the sliding slot, the locking member slides and then rotates relative to the supporting member. The latching member is arranged on the second supporting portion and is adapted to be inserted into the latching hole. When the latching member is inserted into the latching hole, the fan is sandwiched and held between the first supporting portion and the locking portion.

Several transportable datacenters are described. The transportable datacenters include transport systems allowing them to be transported between an assembly location and an operating location. The transportable datacenters also include a ventilation system for cooling processors positioned in racks in the datacenters. The ventilation system draws cold air from the environment, through processor bays containing the processors and then exhausts the air back to the environment.

An information handling system may include a chassis configured to house components of the information handling system and a modular power supply module configured to be readily removable from the chassis. The modular power supply module may include an enclosure, power supply components housed within the enclosure, an air mover configured to drive airflow to cool one or more components of the information handling system, and a mechanical assembly configured to mechanically couple the air mover to the enclosure that enables a user to remove the air mover from the enclosure while still coupled to the enclosure via the mechanical assembly, rotate the air mover 180 degrees relative to the enclosure while still coupled to the enclosure via the mechanical assembly, and reinsert the air mover into the enclosure, in order to modify a direction of airflow driven by the air mover.

A two-phase immersion cooling system for cooling electronics. The electronics are immersed in immersion tank filled with phase change liquid. As liquid evaporates due to heat generated by the electronics, it enters a vapor passageway that leads the vapor to a condenser situated remotely from the immersion tank. Upon condensing at the condenser, the condensed liquid is directed to a resupply tank, wherein the condensed liquid cools. When the level of the two phase liquid in the immersion tank drops below a set threshold, a pump is activated to deliver the condensed liquid from the resupply tank to the immersion tank. The immersion tank, vapor passageway and condenser are position inside a containment passageway. The containment passageway captures any vapor not entering the vapor passageway and direct such vapor to the condenser. An air mover generates pressure differential within the containment passageway to direct the vapor towards the condenser.

Self-contained server assemblies for housing servers or server blades and associated computing facilities are disclosed herein. In one embodiment, a server assembly includes an enclosure having an interior space housing a server blade, a dielectric coolant submerging heat producing components of the server blade, and a condenser assembly having a condenser coil in fluid communication with a vapor gap in the interior space. The condenser coil is configured to receive a coolant that removes heat from a vapor of the dielectric coolant in the vapor gap, thereby condensing the vapor into a liquid form to be returned to the server blade.

Data center mechanical infrastructure is incrementally deployed and commissioned to support incremental changes in computing capacity in a data center while mitigating interaction between infrastructure being commissioned and installed computer systems. Incremental mechanical infrastructure commissioning can be concurrent with incremental electrical infrastructure commissioning and includes operating mechanical infrastructure to remove heat generated as a result of operating electrical infrastructure to support simulated electrical loads as part of electrical infrastructure commissioning. Incremental mechanical infrastructure deployment can be based on the power support capacity provided by incrementally deployed electrical infrastructure. Incremental infrastructure deployment can include partitioning a space in which incremental mechanical infrastructure is configured to provide cooling, so that heat generation and removal in the space, based on commissioning the incremental mechanical infrastructure, is isolated electrical and cooling support provided to electrical loads located in a remainder of the data center.