A space-saving, high-density modular data pod and a method of cooling a plurality of computer racks are disclosed. The modular data pod includes an enclosure including wall members contiguously joined to one another along at least one edge of each wall member in the shape of a polygon and a data pod covering member. Computer racks arranged within the enclosure form a first volume between the inner surface of the wall members and first sides of the computer racks. A second volume is formed of second sides of the computer racks. A computer rack covering member encloses the second volume and the data pod covering member form a third volume coupling the first volume to the second volume. An air circulator continuously circulates air through the first, second, and third volumes. The method includes circulating air between the first and second volumes via the third volume and the computer racks.

This application provides a cooling system, including a heat exchanger, a cooling supplement component, a bypass vent valve, and a controller. The heat exchanger includes an air intake vent A and an air exhaust vent B that are used for outdoor fresh air entry and discharge, and an air intake vent C and an air exhaust vent D that are used for indoor return air entry and discharge. The cooling supplement component includes a condenser and an evaporator, the condenser is connected to the air exhaust vent B by using an exhaust air pipe, and the evaporator is connected to the air exhaust vent D. The bypass vent valve is disposed on the exhaust air pipe, and the bypass vent valve communicates with outdoor air. The bypass vent valve is connected to the controller, and the controller is configured to control the bypass vent valve.

Systems and methods for cooling a datacenter are disclosed. In at least one embodiment, a cold plate has microchannels and a heat pipe to support a first fluid in an active mode of operation of a cold plate that uses microchannels, and to support a second fluid in a passive mode of operation of a cold plate that uses a heat pipe.

A cooling system, including a first refrigeration medium, a first evaporator, a first condenser, and an all-condition cooling tower. The first evaporator is installed in a to-be-cooled space, the first evaporator is connected to the first condenser, an installation position of the first condenser is higher than an installation position of the first evaporator; the first condenser is connected to the all-condition cooling tower, and the all-condition cooling tower is disposed outside the to-be-cooled space, the all-condition cooling tower is used for providing the first condenser with a cold source for cooling the first refrigeration medium in a gaseous state.

A cooling system configured to remove heat from a chimney of a server cabinet. The system includes a first heat exchanger unit in the chimney of the server cabinet. The first heat exchanger has a fluid inlet for receiving a working fluid and a fluid outlet for discharging the working fluid. The first heat exchanger also has an upstream surface receiving waste heat generated by one or more servers and a downstream surface that discharges air cooled by the first heat exchanger. The upstream surface is generally perpendicular to the downstream surface.

A cooling system for a datacenter is disclosed. The datacenter cooling system includes a refrigerant cooling loop to extract heat from a secondary cooling loop that is located within the datacenter or to provide supplemental cooling to one or more components of the datacenter that are coupled to the secondary cooling loop.

A cooling system for an electronic rack of a data center, such as an IT rack or PoD, is disclosed. The system includes a coolant distribution unit (CDU) coupled to a rack manifold of the electronic rack through a fluid cooling loop. The CDU supplies cooling fluid that is distributed to the IT rack or PoD, and receives returning warm/hot fluid from the IT rack or PoD. The system further includes an enhancing cooling unit to receive a first part of a first distributed portion of the cooling fluid and to further cool the first part of the first distributed portion of the cooling fluid to a lower temperature value than the one of the supplied cooling fluid through an enhancing cooling loop. The system further includes a first external cooling unit connected to the CDU through a cooling fluid loop to supply the cooling fluid to the CDU. The system further includes an air cooling unit to receive a second distributed portion of the cooling fluid and to use the second distributed portion of the cooling fluid to cool the airflow for IT rack or PoD. The system is arranged in five portions, and fluids and cooling units are shared among the portions within distributing loops.

Conditioning systems and methods for providing cooling to a heat load can include an evaporative cooler arranged in a scavenger plenum with a recovery coil downstream of the evaporative cooler. The conditioning systems can operate in various modes, including an adiabatic mode and an evaporative mode, and a blended mode between the adiabatic mode and the evaporative mode, depending on environmental conditions. The blended mode can be enabled by a fluid transmission and retention device fluidically connected to the inlet and outlet of the evaporative cooler, the recovery coil outlet, and the heat load. The fluid transmission and retention device can variably distribute the cooling fluid exiting the recovery coil and the cooling fluid exiting the evaporative cooler to one or both of the heat load and the evaporative cooler inlet. In an example, the fluid transmission and retention device includes a manifold. In another example, the fluid transmission and retention device includes one or more tanks.

A floor system for detecting refrigerant includes one or more tiles. Each tile includes a tile body having a cavity formed therein and a grille element positioned within the cavity of the tile body. The grille element is configured to receive air from at least one of above or below the tile body. Each tile further includes a control assembly associated with the grille element. The control assembly includes a refrigerant sensing device to detect refrigerant in the received air. The control assembly is configured to output a signal indicating a detection of refrigerant.

There is disclosed a device for cooling a server rack within a server room having a first chamber and a second chamber, the device comprising: a main chilling unit; a heat exchanging unit operatively coupled to the main chilling unit; the main chilling unit including a housing for housing: an evaporator; a first airlock device to removably secure the main chilling unit to the server rack from a side of the first chamber; a first fan configured to force air from the first chamber to the second chamber; the heat exchanging unit including a housing for housing: a condenser in fluid communication with the evaporator, the condenser being configured to transmit heat from the liquid coolant to air surrounding the condenser; a second airlock device configured to removably secure the heat exchanging unit to the second chamber; a second fan configured to blow the heated air into the second chamber.