A power distribution unit includes a housing, a plurality of power outlets disposed within the housing, and a dynamic illumination element operable in a user selected one of a plurality of distinct colors. Systems and methods of color coding input power paths to power distribution units are also described. The power distribution units are universally used in different color coded combinations with increased manufacturing and supply chain efficiencies, and simplified customer order processing.

A constrainer includes a base and two arms mechanically coupled to the base. The base and two arms receive a device while the constrainer is in a first state and, while the constrainer is transitioning from the first state to a second state and while the device is disposed in the constrainer, place the device in a predetermined orientation.

Techniques for managing data center electronic devices in a data center include operating data center server devices that define a particular amount of computing power of a data center, the devices supported in server racks positioned in a frame assembly that includes bays defined along a lengthwise dimension of the frame assembly, the bays arranged in stacked layers that include at least a first layer of bays and a second layer of bays positioned vertically above the first layer of bays, the server racks positioned in at least one of the bays of the first or second layers of bays; determining that at least one of the server devices requires a maintenance operation; based on the determination, operating an automated service machine to move to a location in the data center that is adjacent to the data center server device; and performing the maintenance operation on the at least one data center server device with the automated service machine.

A configurable modular computer enclosure includes a plurality of outer enclosures (1, 2, 3), the outer enclosures being connected together in a depth stacked formation producing a single composite outer enclosure with a single internal volume and a depth equalling the combined depths of the outer enclosures. The composite outer enclosure houses multiple sets of configurable inner enclosures (4, 5, 6, 7, 8), each inner enclosure set being formed into a composite inner enclosure by connecting together the inner enclosures in the set, allowing unlimited configurations of composite inner enclosures. Each composite inner enclosure is inserted into the composite outer enclosure and aligned via guides or runners (9) integrated into the outer enclosures.

A configurable modular computer enclosure includes a plurality of outer enclosures (1, 2, 3), the outer enclosures being connected together in a depth stacked formation producing a single composite outer enclosure with a single internal volume and a depth equaling the combined depths of the outer enclosures. The composite outer enclosure houses multiple sets of configurable inner enclosures (4, 5, 6, 7, 8), each inner enclosure set being formed into a composite inner enclosure by connecting together the inner enclosures in the set, allowing unlimited configurations of composite inner enclosures. Each composite inner enclosure is inserted into the composite outer enclosure and aligned via guides or runners (9) integrated into the outer enclosures.

A server node is provided that includes a processor and a network interface controller mounted in a chassis configured to be inserted into a server node slot of a server node grid. The chassis includes a blind-mate connector system on a back side that includes a blind-mate power connector and a blind-mate network connector configured to blind-mate with a corresponding blind-mate power connector and a corresponding blind-mate network connector of the server node slot of the server node grid. As the server node is inserted into the server node slot, the blind-mate power connector is configured to blind-mate with the corresponding blind-mate power connector of the server node slot before the blind-mate network connector blind-mates with the corresponding blind-mate network connector of the server node slot, such that the blind-mate power connector provides alignment guidance for the blind-mate network connector.

A server rack according to one embodiment includes a sidewall defining an interior, an aperture in the sidewall, and a retractable terminal horizontally positionable between a retracted position and an extended position. The retractable terminal is positioned in the interior when in the retracted position. The retractable terminal is configured to extend through the aperture of the sidewall. The retractable terminal includes a base frame and a pivoting frame pivotally coupled to the base frame. The pivoting frame is configured to receive at least a display. The pivoting frame is positionable between an undeployed position and a deployed position relative to the base frame when the retractable terminal is in the extended position. The pivoting frame is about parallel to the base frame when in the undeployed position. The pivoting frame is oriented at least 30 degrees from the base frame when in the deployed position.

Systems and methods for monitoring the presence of rack mounted equipment are described herein. In certain embodiments, a system includes one or more racks, each rack in the one or more racks configured to hold rack mounted equipment at one or more positions within the rack. The system also includes one or more sensor bars associated with each position in the one or more positions, wherein each sensor bar in the one or more sensor bars produces a signal that indicates whether the rack mounted equipment is located at the position associated with a respective sensor bar. Further, the system includes an analyzer configured to receive the signal produced by the sensor bar, wherein the analyzer provides an indication that rack mounted equipment is located at the position to an infrastructure management system.

An apparatus provides an extendable rail assembly including a track for securing to a rack, a first rail slidably coupled to the track, and a second rail slidably coupled to the first rail. The first rail is movable relative to the track between retracted and extended positions, wherein the first rail includes first and second rail sections coupled together by a pivot joint. The second rail is movable relative to the first rail between retracted and extended positions. Furthermore, with the first rail in the extended position and the second rail in the extended position, the pivot joint allows the second rail and the second rail section of the first rail to pivot relative to the track and the first rail section of the first rail. A pair of rail assemblies may be secured to a rack to support a member, such as a server.

Described herein is an infrastructure management device. In accordance with one aspect, the infrastructure management device includes at least one communication interface to connect to and provide power to at least one information technology (IT) device, and communicate with at least one other infrastructure management device. The infrastructure management device may further include one or more processors and one or more non-transitory machine-readable media comprising instructions configured to cause at least one of the one or more processors to perform operations to manage the IT device.