Systems and methods for operating a datacenter are disclosed. In at least one embodiment, hybrid cooling unit is disclosed wherein an evaporative cooler is to provide a source of cooled air and a liquid heat exchanger is to provide a source of cooled liquid for cooling one or more electronic components, the hybrid cooling unit further including an air inlet to direct a flow of external air to remove heat from the evaporative cooler and the liquid heat exchanger.

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.

In an airflow control system in a machine room where a plurality of ICT device groups (3a to 3f) is supplied with cold air blown out from a plurality of air conditioners (2a to 2c) an is cooled via an underfloor space, the airflow control system includes a partition that is openable and closable (4a to 4f) provided for each air conditioner in the underfloor space, and a controller that opens, when occurrence of an abnormality is detected in an air conditioner of the plurality of air conditioners, the partition between the air conditioner with the occurrence of the abnormality detected and another air conditioner adjacent to the air conditioner.

In an open-loop heat removal system for a building such as a data center or a home, cool air is supplied to the building by a chilling unit and hot air is expelled from the building without recycling, recirculating, or re-cooling the hot air. For fire suppression, the system receives temperature reading(s) from temperature sensor(s) and determines whether any temperature reading reaches or exceeds a temperature that indicates presence of a fire. If so, a louver positioned over an inlet module is automatically or programmatically closed, shutting off air supply to the building. The system determines whether the building is under a negative pressure internally. If not, an exhaust fan at the outlet of the building is turned on to create a negative pressure internally. The system determines whether an oxygen level of the building indicates that the fire has been contained. If not, a sprinkler system is activated.

A power distribution center includes a housing comprising multiple walls and multiple openings, one or more UPS modules and battery racks, and at least one exhaust air duct disposed above the one or more UPS modules and battery racks. The at least one exhaust air duct has an outlet aligned with at least one first opening. The power distribution center is configured to receive cooling air from outside the power distribution center and convey the cooling air to the one or more UPS modules and battery racks. The one or more UPS modules and battery racks are configured to transfer thermal energy to the cooling air, thereby creating heated exhaust air. The at least one exhaust air duct is configured to receive and convey the heated exhaust air to the at least one first opening to expel the heated exhaust air to an exterior space.

Cooling systems of one or more electronic racks in a cluster or point of deliver (PoD) are disclosed. A data center system includes an array of electronic racks. Each electronic rack contains a number of server chassis. The system further includes a number of rear cooling doors respectively connected to the electronic racks. Each rear cooling door cools warm/hot air exhaust from a corresponding electronic rack. The system further includes a number of airflow distributors. Each airflow distributor attaches to a side of an electronic rack to supply and distribute a cool/cold airflow to the electronic rack. The distributor either assembled in the PoD or pre-attached with the racks. The system further includes a containment to direct the cooled air towards the airflow distributors.

A computer-implemented method, a system, and a computer program product for detecting objects are disclosed. The method can include receiving, by a computer communicatively connected to a plurality of anemometers positioned throughout the space, first sensor data from the plurality of anemometers, creating a baseline profile of airflow in the space based on the first sensor data, and receiving second sensor data from the plurality of anemometers at a different time than the first sensor data. The method can include comparing the second sensor data with the first sensor data to determine first different data, rendering, in response to determining that the second sensor data is different from the first sensor data, a representation of the object using the first different data and first location data related to the first different data, and calculating a vector associated with the object using the first different data and the first location data.

A thermal management system for cooling a computing device includes a cold aisle, a hot aisle, a radiator, and a plurality of source heat sinks thermally conductively connected to the radiator. The radiator connects the cold aisle to the hot aisle and flows a cooling fluid through an interior volume of the radiator. Each source heat sink is configured to connect to a heat-generating electronic component to thermally conductively connect the heat-generating component to a surface of the radiator.

A system, an article of manufacture, and a method are disclosed. The system includes a set of components in an enclosure. The set of components includes electronic devices and airflow moving components configured to maintain airflow across the electronic devices from a front plenum of the enclosure to a rear plenum of the enclosure and direct air from the rear plenum through the first heat exchanger. The set of components also includes a first heat exchanger configured to circulate a cooling liquid and a second heat exchanger configured to maintain a constant temperature of the cooling liquid, wherein the constant temperature is a temperature of the cooling liquid within a threshold distance from a selected temperature.

A system including a data center rack enclosure, a first aisle emulator, and a second aisle emulator. The data center rack enclosure is configured to retain a data center rack, which has a first side and a second side. The first aisle emulator is coupled with the data center rack enclosure and provides a first controlled test environment with first temperature and a first gas flow to the first side of the data center rack. The second aisle emulator is coupled with the data center rack enclosure and provides a second controlled test environment for the second side of the data center rack.