Described herein is an integrated data center that provides for efficient powering and cooling, as well as efficient wire routing.

Embodiments are disclosed of a module attachable to an electronics rack. The module includes a housing attachable to a rear part of the electronics rack. One or more pairs of laterally-running mounting channels are positioned within the housing and one or more service panels are positioned within the housing. Each of the one or more service panels is movably mounted to a corresponding pair of mounting channels, and each of the one or more service panels can be coupled to at least one electronic device to be mounted in the electronics rack. Implementing the modules to racks and data centers can be realized with multiple methods.

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.

The invention is directed to a portable container system comprising a container which comprises a floor, four upwardly-extending sidewalls, wherein at least one of the sidewalls is hinged to allow the at least one sidewall to open outwardly, and a top wall. The system also comprises a plurality of skids contained within the container. Each skid comprises a base and one or more upwardly extending members; and one or more cabinets mounted on the base or one or more upwardly extending members, wherein the one or more cabinets comprise: control power distribution panel cabinets, human-machine interface cabinets, programmable logic controller-redundancy cabinets, network cabinets, or remote I/O cabinets.

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 at 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.

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.

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.

An optical interconnect system for installing fiber optic cables in an equipment rack having an equipment patch panel with a plurality of coupling port locations is disclosed. The optical interconnect system includes a plurality of cable harnesses configured for installation in the equipment rack and at least one installation tray having a plurality of coupling locations. The plurality of coupling locations receives a connector from the plurality of cable harnesses. The plurality of coupling locations on the installation tray has an arrangement that corresponds to the plurality of port locations on the at least one equipment patch panel, thereby allowing a technician to visually realize that a patching error has occurred during the installation. A method of installing fiber optic cables in an equipment rack using the optical interconnect system is also disclosed.

The present invention discloses a skylight operating system of a modular data center, so as to timely respond to a firefighting requirement of the modular data center to reduce occurrence of firefighting-related accidents. The skylight operating system comprises: an electric skylight; a firefighting environment index monitoring device arranged inside the modular data center; a monitoring and interacting device arranged in a monitoring room outside the modular data center, and connected with the electric skylight and the firefighting environment index monitoring device, the monitoring and interacting device adapted for receiving monitoring information of the firefighting environment index monitoring device, and opening the electric skylight upon determination that a firefighting-related issue occurs inside the modular data center.

A method for cooling IT equipment of a velocity cooled (VC) mobile data center (MDC) includes: determining if a velocity of the VC MDC is above a minimum threshold velocity that enables ram air cooling of IT equipment within the VC MDC; and in response to the velocity not being above the minimum threshold velocity, activating a secondary cooling source to provide a flow of cooling air across the IT equipment within the VC MDC, the flow of cooling air supplementing the ram air cooling.