The disclosure provides a system, for designing and developing immersion cooling in data centers. The system includes multiple aisles that perform different functions. One of the aisles includes space for housing immersion tanks in which components of the data center may be positioned to be cooled. A second aisle allows the immersion tanks to be placed in the other aisle and for backside access. A third aisle transfers vapor from the aisle housing the immersion tanks to a vapor return unit to condense the vapor. A distribution unit distributes the coolant to cool the components of the data center is designed at the second aisle. The aisles and other units can be modularized to allow for deployment to meet different types of data center requirements.

A fluid deployment unit includes an expandable container containing mixed fluids in a gaseous region and a liquid region, where the expandable container includes a gas-out port, a liquid-out port, a gas-in port, and a liquid-in port. The fluid deployment unit includes a first three-way valve having a first port coupled to the liquid-out port, a second port coupled to the gas-out port, and a third port matable to an inlet of an electronic rack. The fluid deployment unit includes a second three-way valve having a first port matable to an input port of a liquid-to-liquid exchange unit of a testing assistant unit, a second port coupled to the gas-in port, and a third port matable to an outlet of the electronic rack, where the liquid-in port of the expandable container is matable to an output port of the liquid-to-liquid exchange unit.

Embodiments include apparatuses, systems and methods for a computer device with a casing and a substance in the casing substantially surrounding a computer component in the casing. In embodiments, the computer device may be a command and control computer, such as for example, an autonomous or semi-autonomous vehicle. In embodiments, the substance may be an electrically isolative and shear-thickening fluid to provide thermo-mechanical protection to a computer component. In the described embodiments, the substance may dampen mechanical shock or vibrational impact on the processor and the memory. The shear-thickening gel may further be thermally conductive in embodiments. In the embodiments, the casing may be substantially filled with the substance and the substance is to conduct heat away from the processor and the memory toward an outer edge of the casing. Other embodiments may also be described and claimed.

Systems and methods for cooling a datacenter are disclosed. In at least one embodiment, one or more flow controllers is associated with a cold plate and with a thermosyphon condenser that is elevated with respect to a cold plate so that two-phase fluid is enabled for gravity-assisted downflow in a liquid phase to a cold plate for absorption of heat and is enabled for buoyancy-driven upflow through a riser tube into a thermosyphon condenser for dissipation of heat of at least one computing device.

A cooling system for a data center includes an evaporative condenser, a pump cabinet and a heat exchange terminal. The pump cabinet has a first branch and a second branch, the first branch including a liquid storage tank and a fluorine pump. An input end of the liquid storage tank is connected to an output end of the evaporative condenser, an output end of the liquid storage tank is connected to an input end of the fluorine pump, and an output end of the fluorine pump is connected to an input end of the heat exchange terminal. The second branch includes a compressor with an input end connected to an output end of the heat exchange terminal and an output end connected to an input end of the evaporative condenser.

A cooling device includes: a container in which a refrigerant is sealed; an evaporation circuit that evaporates the refrigerant in a liquid phase inside the container by heat reception; a condensation circuit that condenses the refrigerant in a gas phase inside the container by heat radiation; a transport circuit that transports the refrigerant in the liquid phase inside the container to the evaporation circuit by a capillary phenomenon; a heat radiation member that includes fins, and includes a narrow portion that has a width in a direction orthogonal to a flow direction of cooling air that is narrow on a downstream side in the flow direction, and a wide portion that has the width that is wide on an upstream side in the flow direction; and an air guide member that is provided on the downstream side of the wide portion and on the upstream side of the narrow portion.

A temperature controlling method of a liquid cooling device includes a providing step, a disposing step and a processing and controlling step. In the providing step: a microprocessor and multiple flexible micro sensors are provided. In the disposing step: the microprocessor is disposed on the liquid cooling device (including an evaporator, a condenser, a cold water tube, a hot water tube, a pumping motor and a cooling fan motor), and the micro sensors are separately disposed in the cold water tube and the hot water tube to directly contact with the liquid. In the processing and controlling step: the microprocessor receives data sensed in the cold water tube and the hot water tube by the micro sensors to calculate, and controls the pumping motor and the cooling fan motor to modulate an operating performance according to a calculated result.

According to one embodiment, a cooling system includes a primary condenser, a primary supply line and a primary return line that couples the primary condenser to a cold plate that is arranged to be used for electronics cooling to create a primary heat-transfer loop in which the condenser supplies liquid coolant to the cold plate and receives vapor produced by the cold plate, a secondary condenser, a secondary supply line that couples the secondary condenser to the primary supply line, a secondary return line that couples the secondary condenser to the primary return line, and a primary valve that is coupled to the secondary return line, where, in response to vapor pressure exceeding a pressure threshold, the valve at least partially opens to create a secondary heat-transfer loop in which the secondary condenser condense vapor back into liquid coolant that is supplied to the primary supply line.

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 device for and method of hot swapping one or more electronic devices from an immersion cooling tank having a first opening, the device including a condensing unit removably locatable in first opening of the immersion cooling tank, the condensing device having a condensing coil forming a second opening through which the electronic device(s) is removable. A retractable cover sheet assembly, under computer control, is positioned to form a sized opening, which may include a containment structure, prior to opening the tank lid to minimize dielectric fluid loss.