The present disclosure discloses a combined air-cooling and liquid-cooling refrigeration system and a data center, where the combined air-cooling and liquid-cooling refrigeration system includes a closed area, a combined device group, and a circulating liquid-cooling system. The combined device group and the circulating liquid-cooling system are installed in the closed area. The combined device group includes a first device group and a second device group, and a closed thermal channel is formed between the first device group and the second device group. The first device group and the second device group each include a plurality of air cooling devices and a plurality of heating devices. The circulating liquid-cooling system is connected to primary heating sources of the plurality of heating devices, and the plurality of air cooling devices refrigerate hot air discharged from the closed thermal channel.

Provided is a rack, comprising: a plurality of rack units; and a plurality of lockers each housing a different respective subset of the rack units, wherein respective lockers among the plurality comprise: a first respective barrier disposed between a respective pair of the rack units; a second respective barrier disposed between another respective pair of the rack units; a third respective barrier that is orthogonal to the first barrier and the second barrier, the third respective barrier being moveably or removeably coupled to the rack; a respective volume configured to receive one or more computing devices; and a respective lock configured to secure the third respective barrier to the rack in the closed position when in a locked state.

Disclosed is a storage-type modular data center. The storage-type modular data center includes a box, a dust removing module, an evaporative cooling module, and an air supply module. The box is provided with an air inlet and an air outlet. A server is disposed between the air inlet and the air outlet. The dust removing module is disposed between the server and the air inlet. The evaporative cooling module is disposed between the server and the air inlet, and includes an evaporative media and a water sprinkling tray module. One end of the evaporative media is immersed in liquid contained in the water sprinkling tray module. The air supply module is operative to drive air to flow between the air inlet and the air outlet.

An apparatus is provided herein. The apparatus includes a sensor module and a control module. The sensor module to receive a measured environmental condition. The control module to use the measured environmental condition to determine a fluid temperature to cool a first set of components and determine an air temperature to cool a second set of components.

A portable blockchain mining system is disclosed comprising: a portable building; a plurality of blockchain mining processors mounted within, or a plurality of blockchain mining processor mounts located within, an interior of the portable building; an air inlet defined in the portable building; an air outlet defined in the portable building above the air inlet and oriented to direct exhaust air out of the portable building; and a cooling fan connected to convey air through the air inlet, across the plurality of blockchain mining processors and out the air outlet.

A modular enclosure for housing various computing devices is provided. The modular enclosure includes a platform and a housing module mounted on the base module. The housing module has lateral sides, a front side, a rear side and a roof defining an interior volume for receiving the various computing devices and fan cassettes. Each fan cassette is provided with its own controller which is configured to adjust the rotational speed of the fan based on the power consumption of the one or more computing devices. When connected in a cluster, the fan cassettes provide a N+1 redundancy, wherein each cassette as an adjacent fan cassette configured as an active backup. The fan cassettes of a cluster communicate via a communication bus. The fan cassettes may include dampers to redirect air drawn from the computing devices back toward them in cold whether conditions, or toward the outdoors, in hot weather conditions.

A data center includes various sets of infrastructure modules which each provide a particular type of infrastructure support to support computing operations in the data center. Separate sets of infrastructure modules can be installed incrementally based on incrementally changing support capacity for the corresponding type of infrastructure support in the data center. Such incrementally changing support capacity can be based upon support requirements of electrical loads, including rack computer systems, which are inbound to the data center. Where support capacity for a particular type of infrastructure support drops below a threshold, a quantity of additional infrastructure modules which provide the particular type of infrastructure support can be selected and installed to increase the support capacity. Separate sets of infrastructure modules can be selected and installed independently of each other, to independently adjust support capacity for separate types of infrastructure support, which can minimize excess support capacity at any given time.

A modular datacenter facility and a method thereof is provided in accordance with some embodiments. The module datacenter facility can be constructed with an initial set of building modules of different types of functionality. A first building module can be a data-floor building module. A first set of sidewall-connected heating, ventilation, and air conditioning (“HVAC”) units can connect to a sidewall of the modular datacenter facility and use electrical power provided by a first electrical power distribution building module to supply conditioned air into an air-supply plenum of the sidewall to cool computing systems housed in the data-floor building module. The first set of the sidewall-connected HVAC units allow for fewer penetrations in a roof of the data-floor building module, thereby minimizing an amount of leaks potentially occurring in the roof of the ceiling, and thereby minimizing risk of any damage to the computing systems.

A cold energy recovery apparatus for a self-powered data centre is disclosed. The apparatus comprises a fluid storage tank having at least a pair of inlet and outlet, the inlet configured to receive a coolant; and a heat exchanger arranged in the tank, the heat exchanger having a pair of inlet and outlet, the inlet configured to receive liquefied natural gas. The apparatus is operable to permit the coolant to flow from the inlet to the outlet of the tank causing the coolant to be in fluid contact with the heat exchanger, in which the coolant is progressively cooled to a lower temperature by heat transfer to the liquefied natural gas via fluid contact with the heat exchanger. The liquefied natural gas is vaporized into natural gas due to the heat transfer and is directed out from the outlet of the heat exchanger.

A method of cooling a data centre, and a data centre, is disclosed. Optionally, the data centre comprises: a cooling air source (201); at least one rack room (202) having a floor and rack storage areas (203a-203d) on the floor, each rack storage area accommodating racks in which items of electronic equipment having at least one fan (204) are housed; one or more cold aisles (205) in the rack room, each cold aisle being adjacent to a rack storage area; one or more hot aisles (206) in the rack room, each hot aisle being adjacent to a rack storage area; and an air supply corridor (207) for transporting cooling air, above the floor, from the cooling air source to the one or more cold aisles. The method optionally comprises transporting cooling air from the cooling air source (201) to the one or more cold aisles (205) substantially under the control of the fans (204) of the items of electronic equipment.