A cooling system includes a heat exchanger having one or more rows of multiple flat tubes, louvered fins disposed between pairs of flat tubes, and special header tube connections to form a counter flow heat exchanger. Heat exchangers having multiple rows may be placed near or close to the server racks and may be in fluid communication with an outdoor heat exchanger having one or more rows. A single-phase fluid is pumped through a fluid circuit or loop, which includes the heat exchangers at the server racks and the outdoor heat exchanger. The single-phase fluid circuit including the heat exchangers at the IT racks may alternatively be in thermal communication with a water circuit that includes an outdoor fluid cooler. The flat tubes can be formed tubes with one or more channels, or extruded tubes with multiple channels. The heat exchangers include header tubes/connections, which facilitate easy fabrication and connection between rows and inlet/outlet, and lower the pressure drop.

Systems and methods for cooling a datacenter are disclosed. In at least one embodiment, an in-row cooling unit is located within a row of racks and between a racks so that it can use an interchangeable heat exchanger (IHE) to receive primary coolant and can use one or more flow controllers to provide a first part of a primary coolant to cool secondary coolant that is to be distributed to at least one cold plate and to provide a second part of a primary coolant to cool air to be circulated through at least one server tray or rack.

A holder for an electronic rack includes a pivot point and a first end of the holder having a first blind-mate connector to be coupled to a second blind-mate connector at a first engagement interface. The first blind-mate connector and the second blind-mate connector are coupled in response to the holder moving to the second position in response to contact with the electronic rack. The holder additionally includes a second end of the holder having a third blind-mate connector to be coupled to a fourth blind-mate connector at a second engagement interface. The third blind-mate connector and the fourth blind-mate connector are coupled in response to the holder moving to the second position in response to contact with the electronic rack.

In a phase-change cooling apparatus including an indoor unit and an outdoor unit, a configuration to prevent dew condensation in the indoor unit causes the cooling performance to decrease; therefore, a refrigerant circulating apparatus according to an exemplary aspect of the present invention includes refrigerant-liquid thermal equilibrium means for mixing a first refrigerant liquid with a second refrigerant liquid and sending a reflux refrigerant liquid composed of the first refrigerant liquid and the second refrigerant liquid, the first refrigerant liquid being a liquid-phase refrigerant included in a gas-liquid two-phase refrigerant flowing in from heat receiving means, the second refrigerant liquid arising due to the gas-liquid two-phase refrigerant cooled by heat radiating means; a refrigerant passage configured for the gas-liquid two-phase refrigerant and the reflux refrigerant liquid to circulate between the heat receiving means and the refrigerant-liquid thermal equilibrium means; refrigerant-liquid reflux means for refluxing the reflux refrigerant liquid to the heat receiving means through the refrigerant passage; and refrigerant-liquid flow control means for controlling a flow rate of the reflux refrigerant liquid.

Systems and methods for cooling a datacenter are disclosed. In at least one embodiment, multiple parallel refrigerant paths are associated with one or more flow controllers to cool multiple computing devices associated therewith, so that one or more flow controllers can distribute equal measures of a liquid phase of refrigerant, relative to a vapor phase of a refrigerant, to such parallel refrigerant paths based in part on a cooling requirement from at least one of such multiple computing devices.

The disclosed systems and method for evaluating the integrity of media pads within an adiabatic cooling system includes at least one media compartment containing at least one media coupon that is representative of at least one of the media pads. The system is adapted to be fluidly coupled to a source of representative process water and to provide such water to the at least one media compartment. A source of airflow fluidly is also coupled to the at least one media compartment. The flow of representative process water and airflow to the media coupon within the media compartment simulates the operation of the adiabatic cooling system. The at least one media coupon may then be analyzed as representative of media pads within the adiabatic cooling system.

A cooling assembly for cooling server racks includes a server rack enclosure sub-assembly that includes at least one panel member defining a volume for receiving one or more server racks having a front portion and a rear portion, at least one of the panel members is a rear panel member; at least one frame member defines an opening for receiving the rear portion of the server racks to form a hot space between the rear panel member and the combination of the frame member and the rear portion of the server racks; a cooling sub-assembly disposed in thermal communication with the hot space to cool at least one server supported in the server rack and including a chassis receiving at least one heat exchange member for exchanging heat between a refrigerant fluid flowing through the heat exchange member and fluid flowing through the hot space heated by the server.

A device may monitor an intake temperature of an air flow through an air intake of a building that includes a ventilation system for temperature control of a first region of the building, a liquid cooling system for temperature control of equipment that is within a second region of the building, and a heat exchanger that is thermally coupled to the ventilation system and the liquid cooling system. The device may determine that the intake temperature is below a threshold temperature. The device may control the ventilation system to cause the air flow to cool a water flow of the liquid cooling system via the heat exchanger to produce a cooled water flow. The device may control the liquid cooling system to cause the cooled water flow of the liquid cooling system to bypass a chiller system of the liquid cooling system to reduce power consumption by the chiller system.

A module modular containment system for isolating and cooling racks of information handling systems in a facility comprises a plurality of vertical panels coupled to a top panel to isolate the rack from room air and a heat exchanger coupled to a facility water feed that supplies water at a water temperature greater than the room air temperature. Heated air exiting the rack passes through the heat exchanger to transfer heat to the water such that the air is cooled to the first air temperature. An air conditioning system and the modular containment system can operate independently to cool the room air to a lower air temperature for the comfort of people in the facility and to cool information handling systems based on operating parameters of the information handling systems.

Example heating and cooling systems for edge data centers are disclosed herein. A system disclosed herein includes a subterranean vault to be disposed at least partially below ground level an of environment, an edge data center in the subterranean vault, and a geothermal heat pump system to regulate a temperature of ambient air in the subterranean vault.