This invention describes the use of pre-packaged air shipping containers for delivery of edge data center equipment. The containers are capable of rapid deployment and positioning at the edge data center delivery site to minimize time between the order of equipment and deployment of a functioning edge data center. The containers allow for easy access, and rapid repair/replacement of modular edge data center equipment.

A data center rack system includes a rack housing that includes side panels and a top panel coupled to the side panels, the top and side panels defining a rack volume sized to enclose a plurality of data center server rack trays, each of the data center server rack trays configured to support a plurality of heat generating electronic devices; and a rack bottom coupled to the side panels to at least partially define the rack volume, the rack bottom including a bottom panel having a top surface coupled to the side panels and a plurality of blocks coupled to a bottom surface of the bottom panel opposite the top surface, at least one pair of the plurality of blocks defining an opening between the blocks and below the bottom surface of the bottom panel and sized to receive a lifting member of a lifting machine.

A data center provides containment walls of an operation technology (OT) interior compartment, such as a meet me room, positioned between cold and hot aisles in an information technology (IT compartment. The OT interior compartment limits air flow so that IT components outside of the OT interior compartment receive sufficient supply air for moderating or cooling a temperature of the IT components. Pressure differential is measured on an exterior and interior of door(s) to the OT interior compartment. Air flow regulation device(s) are positioned in a supply air passage to the OT interior compartment and/or in a return air passage out of the OT interior compartment are controlled to limit the pressure differential between an exterior and interior of the containment wall. Limiting the pressure differential ensures that door(s) facing the cold aisle are not difficult to open and door(s) facing the hot aisle are not difficult to close.

An upper portion of an aisle containment system for a data center. The upper portion includes spaced vertical supports aligned in two parallel rows and horizontal supports that extend between and are connected to adjacent vertical supports to form the basic framework of the upper portion. The upper portion also includes (1) at least one pair of arms that extend outwardly from opposite longitudinal sides of the basic framework and are configured to support services and (2) at least one busbar casement that is attached to the vertical supports and extends substantially the length of the upper portion. Each arm of the at least one pair of arms includes a segment that is rotatable between a first position in which the segment is substantially parallel to the vertical supports and a second position in which the segment is substantially perpendicular to the vertical supports.

A data center power system includes an electrical power conductor that includes a live conductor surface and is configured to carry electrical power from a power source through a human-occupiable workspace of a data center. The live conductor surface includes a rail configured to mount to a floor of the data center. The data power system further includes a grounded conductor positioned in the human-occupiable workspace apart from the electrical power conductor; a first electrical connector configured to mount to a data center rack that supports a plurality of electronic devices and moveable to electrically contact the live conductor surface of the electrical power conductor; and a second electrical conductor positioned on the rack and configured to electrically contact the grounded conductor.

A rack system for a data center includes: a plurality of racks configured to house electronic equipment therein, at least one rack column being formed by at least some of the racks being disposed above one another, each rack having a rack depth measured in a front-to-rear direction; and at least one supporting pedestal disposed below the at least one rack column in order to support the at least one rack column, the at least one supporting pedestal being configured to be positioned on a ground surface of the data center to distribute a load of the at least one rack column on the ground surface, each of the at least one supporting pedestal having a pedestal depth measured in the front-to-rear direction, the pedestal depth being greater than the rack depth, a ratio of the pedestal depth over the rack depth being between 1.2 and 2.5 inclusively.

A modular data center has an air handling unit (AHU) that is coupled to a first panel that is engaged over a first opening in a volumetric container. The AHU directs pressurized supply air through a supply air outlet into a cold aisle causing the supply air to pass through a first side of the IT component(s) installed in an interior of the volumetric container. A chimney of a return air plenum captures return air from a second side of the IT component(s), directing the return air to a return air duct of the return air plenum that is connected to a return air inlet of the AHU. In one or more embodiments, a second AHU is coupled to a second panel that is engaged to a second opening in a second side, directing pressurized supply air via a supply air plenum to the opposing first side.

A mobile, extendable, self-contained, integrated assessment, management, and transaction facility that is completely equipped to assess, manage, and trade capital from almost anywhere in the world, in an example embodiment housed in a cabinet carried in a vehicle bed, in a trailer, heavy duty cart, or other mobile infrastructure that enables the facility to be mobile or portable. A mobile, extendable, self-contained capital assessment, management, and transaction facility and method of use of same to develop, manage, and use capital generally consists of a self-contained, integrated facility; mobile operation; and a method flow for capital that enables the inventory, procurement, assessment, valuation, monitoring, trading, leveraging, tracking and tracing, and other activities or tasks on or associated with different forms, or types, of tangible and intangible capital.

A method of making a data centre is disclosed, comprising making a data centre in an existing building (3010) having a floor, walls and a roof, an air inlet and an air outlet. The method includes: installing prefabricated data centre elements by (a) connecting to the inlet an air handling module (3001, 3002); and (b) installing cold aisle services modules (3011) each having one or more integrated blanking portions and one or more data centre services extending along its length terminating with a connection to an adjacent module (3011); and installing racks of IT equipment arranged in parallel rows; the method being so performed that the floor, racks, and cold aisle services modules (3011) together define parallel cold aisles for entraining cooling air flows to the IT equipment. Also disclosed are a data centre, a service carrying frame and a cold aisle services module for a data centre and a supporting frame for supporting prefabricated data centre elements.

Portable blockchain mining systems and methods of use are discussed here. Systems include 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; and an air outlet defined in the portable building. Air outlets may be above the air inlet and oriented to direct exhaust air in an upward direction out of the portable building. A cooling fan may be connected to convey air through the air inlet, across the plurality of blockchain mining processors and out the air outlet. The cooling fan may simultaneously cool a genset and processors 72. Compact, stackable mining modules are discussed.