A rack arrangement for a data center includes an assembly frame including vertical beams, lateral beams connected to the vertical beams, and transverse beams connected to the vertical beams. The transverse beams extend at least partly in a depth direction of the assembly frame. A rack-supporting platform is connected between two of the lateral beams and extends horizontally between four of the vertical beams. Each rack of a plurality of racks is configured to support computer equipment or cooling equipment for servicing the data center. A first rack is supported at least in part by two of the lateral beams. A second rack is disposed above the first rack and disposed atop the rack-supporting platform. The rack-supporting platform is supported in part by a top portion of the first rack such that a load of the second rack is partly applied on the first rack through the rack-supporting platform.

A method for implementing power capping in a velocity cooled (VC) mobile data center (MDC). A management information handling system (IHS) applies a power cap for all power consuming components of the VC MDC based, in part, on the detected velocity of the VC MDC. The detected velocity is compared to an outside air cooling threshold velocity. In response to the detected velocity being below the outside air cooling threshold velocity, a first power cap is selected, based on the detected velocity being below the outside air cooling threshold velocity. In response to the detected velocity being at or above the outside air cooling threshold velocity, a second, higher, power cap is selected, based in part on the detected velocity being at or above the outside air cooling threshold velocity. Power capping is implemented to conserve available onboard power for IT equipment processing, based on availability of ram air cooling.

A design for the electrical infrastructure of a data center enables two different configurations to be utilized, including a distributed, redundant configuration that provides higher reliability and a non-redundant configuration that provides higher capacity. In the distributed, redundant configuration, each server in the data center draws power from at least two different power supply systems. This enables load shifting when a power supply system becomes unavailable, which can have the effect of increasing server reliability. In the non-redundant configuration, each server in the data center draws power from only one power supply system. Load shifting is not utilized in the non-redundant configuration, which eliminates the need to maintain reserve capacity and thereby increases capacity. Advantageously, it is possible to switch between these two configurations without making any internal changes to the data center other than modifying connections between sets of server racks and power buses.

Disclosed is a containerized heating, ventilation, and air-conditioning (HVAC) system comprising an HVAC unit and one or more ducts from the HVAC unit to an equipment rack. The ducts prevent mixing between the fresh and exhaust airflow, thus improving efficiency. Sensors located at sources of heat generating equipment within the racks may be used by controllers to monitor temperatures of the components at the source of heat generation, typically at the highest temperatures. The temperatures may be aggregated to determine the temperatures of devices, modules, racks, and the container interior cavity. Dampers on the ducts, at the rack inlets, at the module inlets, at the devices inlets, and such may assist in regulating airflow preferentially to the hottest components, devices, modules, or racks.

A data center regulates supply air provided to multiple compartments including an information technology (IT) compartment having a cold aisle and a hot aisle and an operation technology (OT) compartment. An environmental subsystem of the data center includes an air handling system that provides supply air to the cold aisle and that draws return air from the hot aisle to moderate or cool a temperature of IT component(s) that may be installed within the IT compartment. Airflow regulation device(s) are positioned in at least one of (i) a supply air passage that guides a portion of the supply air in the cold aisle of the IT compartment into the OT compartment to moderate or cool a temperature of OT component(s) that may be installed within the OT compartment and/or (ii) a return air passage that guides air from the OT compartment(s) to the hot aisle of the IT compartment.

Disclosed is a prefabricating and stacking combined data center. The data center is formed block structures in a multi-dimensional stacking manner. The block structures are disposed to be a fire protection layer, an air return layer, a bridge architecture wiring layer, a top-cabinet wiring layer, a cabinet device layer, and an air supply layer from up to down, which are independent from each other. Provided is a prefabricating and stacking combined data center. Operation difficulty of site construction is greatly reduced by prefabricating block structures by a factory, forming the data center by multi-dimensional stacking, and connecting the block structures with each other by splicing on site. In addition, according to different requirements of customers, corresponding ancillary facilities may be designed based on volume of an IT device, and the device and a computer room may be reasonably and effectively arranged according to the corresponding national standards and specifications.

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.

Systems include one or more critical datacenter connected to behind-the-meter flexible datacenters. The critical datacenter is powered by grid power and not necessarily collocated with the flexboxes, which are powered “behind the meter.” When a computational operation to be performed at the critical datacenter is identified and determined that it can be performed art a lower cost at a flexible datacenter, the computational operation is instead routed to the flexible datacenters for performance. The critical datacenter and flexible datacenters preferably shared a dedicated communication pathway to enable high-bandwidth, low-latency, secure data transmissions.

A data center, a rack information handling system (RIHS) delivery kit, and a method provide for removing an RIHS from and delivering an RIHS to a data center. The data center includes an enclosure having a raised floor and a lateral opening. The lateral opening has a bottom edge that is aligned with the raised floor in order to transfer a rack information handling system (RIHS) through the lateral opening for a selected one of: (i) removing the RIHSs from the raised floor; and (ii) delivering the RIHS to the raised floor. The data center includes a pallet interface coupled to or integrated into an exterior edge of the raised floor and vertically presented to abut and engage a lateral edge of a roll-off rack shock pallet that supports the RIHS during transport.

A modular data center (MDC) has an air handling system that air cools a volumetric container and heat-generating equipment contained in externally attached equipment panels. Heat-generating information technology (IT) component(s) are positioned within the volumetric container with a cold aisle defined on one side and a hot aisle defined on another side of the IT component(s). The IT component(s) has air-cooling air passages that fluidly communicate between the cold and the hot aisles. A cooling unit pressurizes the cold aisle with supply air and draws return air from the hot aisle. The equipment panel(s) are externally attached to an exterior wall of the volumetric container. A supply air conduit directs supply air from the cold aisle into the equipment panel(s). A return air conduit directs air warmed by the heat-generating equipment inside the equipment panel into the hot aisle from the equipment panel(s) that receives the supply air.