A roof system including a frame, a plurality of roof panels, wherein each roof panel is connected to the frame and is rotatable with respect to the frame, and a holding mechanism for holding a first roof panel among the plurality of roof panels in a closed position, wherein each roof panel among the plurality of roof panels overlaps at least one adjacent roof panel among the plurality of roof panels, and wherein release of the holding mechanism causes each of the roof panels to rotate toward an open position in a sequential manner.

A container module includes a baseplate assembly and a plurality of columns, where the baseplate assembly includes a base frame and a baseplate fixed on the base frame, the plurality of columns are fixed on the base frame in parallel to each other, each column has an extension section extending above the baseplate assembly, and/or a lower end of each column has an extension section extending below the baseplate assembly. A container assembly includes at least two container modules that are stacked vertically and/or connected laterally. A data center includes a function device and the container module.

A rapidly deployable sensitive information facility may include a rapidly deployable a structure and preconstructed, pre-accredited panelized environment. The structure may be a tension fabric membrane shell having an extruded frame to support the tension fabric membrane. The structure may be configured to comply with one or more security accreditation requirements. The panelized environment may be positioned within the structure, and may comprise an access terminal in communication with one or more servers storing sensitive information. A user's access to the one or more servers may be conditioned on an authorization of the user with regard to the security accreditation requirement.

A data centre, a method of cooling electrical equipment in a data centre, and a services module for a data centre, are disclosed. The data centre is for accommodating a plurality of racks of IT equipment and comprises: a) a plurality of hot aisles interleaved with a plurality of cold aisles separated by IT equipment rack storage areas; b) an air handling unit configured to supply cooling air to the cold aisles; c) a services area for accommodating at least one UPS switchboard for directing electrical power to a plurality of IT equipment racks, the services area comprising hot and cold zones, a hot zone being separated from a cold zone by at least one of (i) a UPS switchboard storage area and (ii) a partition; wherein, in use, cooling air is supplied to the UPS switchboard storage area from the air handling unit via the cold zone of the services area.

A method for the construction of a data center, includes (a) providing a fresh concrete composition including a paste that includes a hydraulic binder, a mineral addition and water, the paste being present in a mixture with sand and aggregates, whereby the paste is present in the concrete composition in a volume of <320 L/m.sup.3 and/or the solid volume fraction of said paste is >50 vol.-% and (b) placing the fresh concrete composition so as to build walls, a floor and/or a ceiling of the data center, which are intended to surround the individual components of computer systems, which are housed in the data center.

The invention relates to a Data Center Operating System. An embodiment of the present invention comprises: a memory component that stores inventory data for a plurality of data centers; an interactive interface that receives one or more user inputs; an API input that receives data from one or more data center systems; and a processor configured to perform the steps comprising: receiving, via the API input, monitored data from a plurality of data centers at one or more locations; automatically generating, via the processor, an interactive data center floorplan that comprises the monitored data at a device-level for a specific data center; and displaying, via the interactive interface, the interactive data center floorplan in one or more views wherein the one or more views comprises detailed data for a particular rack in the specific data center.

A structural grid support system adapted for transferring seismic loads to the vertical structural supports of a modular structure. The system includes larger and longer high load capacity main runners with mechanically fastened cross tees, which transfer seismic forces without failing. The structural grid can provide a diaphragm using mechanically fastened connections in a single horizontal plane without requiring additional overhead support from the roof deck, or requiring fewer such supports. The main runners may include additional connecting elements disposed within the usable space beneath the runner (e.g., ventral threaded receivers) for attaching deployment-specific equipment or hardware, such as network cable trays.

A data centre, a method of cooling electrical equipment in a data centre, and a services module for a data centre, are disclosed. The data centre is for accommodating a plurality of racks of IT equipment and comprises: a) a plurality of hot aisles interleaved with a plurality of cold aisles separated by IT equipment rack storage areas; b) an air handling unit configured to supply cooling air to the cold aisles; c) a services area for accommodating at least one UPS switchboard for directing electrical power to a plurality of IT equipment racks, the services area comprising hot and cold zones, a hot zone being separated from a cold zone by at least one of (i) a UPS switchboard storage area and (ii) a partition; wherein, in use, cooling air is supplied to the UPS switchboard storage area from the air handling unit via the cold zone of the services area.

A computing center module (151), comprising: a plurality of containers (102), each container (102) having a plurality of side walls (102s) that are substantially (e.g. on 3 sides) fully openable with two fixed walls (102z) behind them on the two short ends having standardized feed interfaces (412) for all media and containing at least one entrance door (712t), thus leaving the container (102) unchanged; a computing device (104) within the container (102), the computing device (104) having a plurality of processors (104p); an improved reliability power supply infrastructure (106) within the container (102) for supplying electrical power to the computing device (104); wherein the power supply infrastructure of each container (102) of the computing center module (151) or the entire container (102) is individually pre-certified with respect to a reliability of the computing device (104).

A method according to one embodiment includes securing a first plurality of conductive sheets to a surface, applying a conductive tape to a first plurality of joints between conductive sheets of the first plurality of conductive sheets, and securing a second plurality of conductive sheets to the first plurality of conductive sheets without fully penetrating the first plurality of conductive sheets. In such an embodiment, each of a second plurality of joints between conductive sheets of the second plurality of conductive sheets is offset relative to the first plurality of joints.