A system for cooling a plurality of electrical equipment components inside a mobile platform may include at least one manifold and a plurality of flexible tubing ducts. The manifold may have an outlet, and a plurality of inlet tubing connections in fluid communication with the outlet. The outlet may be coupled to an interface of a cooling system of the platform by exhaust tubing. Each of the flexible tubing ducts may have a proximal end and a distal end. Each proximal end may be selectively connectable to the inlet tubing connections. Each distal end may have an air intake port that is alternatively positionable in two or more thermal dissipation zones of the electrical equipment components for permitting an exhaust profile inside the platform to the interface to be reconfigured based at least in part on respective positions of the electrical equipment components.

An optical communication system includes a co-packaged optical module and a heatsink mounted to the co-packaged optical module. The co-packaged optical module includes a processor disposed on a substrate and a plurality of light engines disposed at different locations around the processor on the substrate. The processor and the light engines generating different amounts of heat during operation. The heatsink includes a plurality of heat pipes non-uniformly distributed throughout the heatsink to remove the different amounts of heat generated at a location of the processor and respective locations of the different ones of the light engines.

A data rack system includes a data center rack frame, a shelf positioned within the data center rack frame; and a modular battery unit disposed on the shelf. The modular battery unit further includes a housing having an outer surface, a plurality of strips of phase change material (“PCM”) attached to the outer surface and spaced apart from one another; and air flow channels. The air flow channels are formed in spaces between two adjacent strips of the plurality of strips and defined by a shape and size of the spaces between the two adjacent strips.

Exemplary embodiments are directed to equipment cabinets for customized improved cable management and airflow management. The equipment cabinets include a frame structure. The frame structure includes a top frame assembly and a bottom frame assembly. In some embodiments, the equipment cabinets include a chimney assembly. In some embodiments, the equipment cabinets include a slidable vertical rail. In some embodiments, the equipment cabinets include a rotatable top panel. In some embodiments, the equipment cabinets include a condition monitoring assembly. In some embodiments, the equipment cabinets include a reinforced corner construction. In some embodiments, the equipment cabinets include divider panels capable of being split. Embodiments are also directed to methods of equipment cabinet assembly.

A modular networking hardware platform utilizes a combination of different types of units that are pluggable into cassette endpoints. The present disclosure enables the construction of an extremely large system, e.g., 500 Tb/s+, as well as small, standalone systems using the same hardware units. This provides flexibility to build different systems with different slot pitches. The hardware platform includes various numbers of stackable units that mate with a cost-effective, hybrid Printed Circuit Board (PCB)/Twinax backplane, that is orthogonally oriented relative to the stackable units. In an embodiment, the hardware platform supports a range of 14.4 Tb/s-800 Tb/s+ in one or more 19″ racks, providing full features Layer 3 to Layer 0 support, i.e., protocol support for both a transit core router and full feature edge router including Layer 2/Layer 3 Virtual Private Networks (VPNs), Dense Wave Division Multiplexed (DWDM) optics, and the like.

A plenum for processing one or more byproducts output from a generator, and systems and methods thereof, can have the plenum in the form of a hollow elongate rectangular box having a first end and a second end opposite the first end. The plenum can have a frame and a sidewall fixed to the frame, and can be adapted to be oriented vertically when operatively coupled to receive the one or more byproducts from the generator. The sidewall can include an opening adapted to receive heated air from the generator as one of the byproducts from the generator.

A system for storing data includes a rack, one or more data storage modules coupled to the rack, and one or more data control modules coupled to the rack. The data storage modules may include a chassis, two or more backplanes coupled to the chassis, and one or more mass storage devices (for example, hard disk drives) coupled to the backplanes. The data control modules may access the mass storage devices in the data storage modules.

An assembly includes a lower sub-assembly containing a first fan, a middle sub-assembly supported above the lower sub-assembly, a bottom air flow control plane supported in the middle sub-assembly and having openings sized to fit multiple computers having vertical cooling air paths, and a top air flow control plane supported in the middle sub-assembly above the bottom air flow control plane and having openings sized to fit the multiple computers such that air is forced through the vertical cooling air paths.

A computing system includes a cabinet, an inlet temperature sensor, a cooling device, an environmental sensor, and at least one processor. The cabinet houses at least one computing device. The inlet temperature sensor is configured to detect inlet temperature data for the at least one computing device. The inlet temperature data represents internal temperature within the cabinet. The cooling device is coupled to the cabinet for maintaining temperature within the cabinet. The environmental sensor is configured to detect environmental temperature data external to the cabinet. The environmental temperature data represents external temperature outside the cabinet. The at least one processor is configured to: (a) determine if one or more of the inlet temperature data and the environmental temperature data exceeds a temperature range; and (b) in response to the temperature range being exceeded, generate a first warning signal indicating a temperature problem.

A system includes a cabinet having a first wall, a second wall opposite the first wall, and a back wall extending from the first wall to the second wall. The system also includes a flow plate disposed at least partially within the cabinet and partitioning the inner space into a first portion and a second portion. The system also includes a shelf disposed at least partially within the first portion of the inner space, and a flow device fluidly connected to the cabinet. The flow device is configured to remove air from the first portion of the inner space, and the flow plate is configured to substantially prohibit removal of air by the flow device from the second portion, via the first portion, when the cabinet is in a closed condition.