Embodiments are disclosed of an information technology (IT) rack. The IT rack includes an equipment enclosure with a front, a rear, and one or more partitions, each partition adapted to receive one or more pieces of liquid-cooled information technology (IT) equipment. One or more cooling doors are positioned on the back of the equipment enclosure, each having therein a heat exchanger, the heat exchanger that is fluidly coupled to at least one of the one or more pieces of liquid-cooled IT equipment forming liquid cooling loops. Each of the one or more cooling doors is movable between a first position where the cooling door extends across the back of at least one partition so that air from the interior of the at least one partition flows through the cooling door, and a second position where air from outside the equipment enclosure flows through the cooling door. Fans are used in the middle section of rack or between two enclosures for assisting airflow management. Dedicated space for the fans are designed on the rack.

Apparatuses and systems associated with a server rack to hold a plurality of rack components may include a cabinet having a front opening of width W, and a first mounting pole and a second mounting pole located parallel to each other at the front opening to facilitate receipt and to hold the plurality of rack components. The server rack may further include the first and second mounting poles having a spacing of x inches or centimeters from each other, with the mid-point of the spacing being offset from the mid-point of width W, that defines a first mounting space to receive a first subset of the rack components in a first orientation and a second mounting space to receive a second subset of the rack components in a second orientation that differs from the first orientation. Other embodiments may be described and/or claimed.

A branded fleet server system includes a pre-assembled third-party computer system integrated into a chassis of the branded fleet server system. The pre-assembled third-party computer system is configured to execute proprietary software that is only licensed for use on branded hardware. A baseboard management controller (BMC) included in the server chassis couples with the pre-assembled computer system via one or more cables coupled to ports of the pre-assembled computer system. The BMC enables remote control of the pre-assembled computer system, such as remote power on and power off. An electro-mechanical device, such as a solenoid, presses a power button of the pre-assembled computer system based on control signals from the BMC to change a power state of the pre-assembled computer system.

A method of installing a cable finger accessory in a cable manager includes: positioning a first semi-arcuate clamp section against a section of an extruded support member of the cable manager; positioning a second semi-arcuate clamp section, which is hingedly connected to the first semi-arcuate clamp section, against an opposite side of the section of the extruded support member such that, together, the first and second semi-arcuate generally surround the section of the extruded support member; and fastening a clamp mechanism connected to a distal end of the first semi-arcuate clamp section and adapted to secure the distal end of the first semi-arcuate clamp section against a distal end of the second semi-arcuate clamp section such that the first and second semi-arcuate clamp sections are secured against the section of the extruded support member. The cable finger extends outwardly from at least one of the first and second semi-arcuate clamp sections.

Field serviceable display assemblies are provided. Multiple side assemblies are mounted to a structural framework in a moveable manner, each including a channel located between a transparent layer and an electronic display, which is located behind the transparent layer. A fixed structure is positioned within a cavity located within the structural framework and between the side assemblies. The fixed structure remains stationary when the side assemblies are moved between a closed position where the cavity is enclosed, and an opened position where the fixed structure is exposed to facilitate direct access to electronic components located thereon.

A framework for an electronic or network cabinet, having a first profile frame and a second profile frame, as well as four depth struts. Each depth strut is directly or indirectly connected at corresponding points to the vertical profile frames. Furthermore, the depth struts are dimensioned so that they can absorb and compensate tilting forces of the vertical profile frames.

A modular mounting for a computer motherboard. An outer cabinet is designed to provide a protective enclosure for electrical components, and designed to permit throughhole drilling to facilitate mounting on a wall while avoiding disturbance of contents to be mounted within the outer cabinet. A subpanel plate is designed to detachably and securely attach a computer motherboard and cage assembly, and designed to removably mount the motherboard and cage assembly within the outer cabinet as a modular component, mounting of the motherboard and cage assembly being independent of power supply and nonvolatile storage. An inner cage is designed to protectably mount and enclose a computer motherboard and heat sink, and mount to the subpanel plate. A multipole switch may have a set of contacts for each conductor of a network cable entering the outer cabinet, one throw of the switch connecting all conductors of the cable, another throw of the switch disconnecting all contacts of the cable.

A server assembly having a housing and a tray mounted in the housing are provided. The tray had a top surface and a front surface, and an open position in which the top surface of the tray is accessible and a closed position in which the top surface of the tray is inaccessible. A first set of chip connections in the top surface can vertically removably receive at least one first storage device. The front surface of the tray can define at least one opening below the top surface configured to horizontally removably receive at least one second storage device. The first set of chip connections electronically couple the at least one first storage device with the server assembly and are inaccessible when the tray is in the closed position, and the openings are accessible regardless of whether the tray is in the open or closed position.

An electrical device including a skeleton-like frame structure and at least one electrical module is provided. The skeleton-like frame structure has a low rigidity, while the at least one electrical module provides an increased rigidity when mounted.

A chassis includes at least one slot and a plurality of guiding extensions. The at least one slot is configured for receiving a plurality of first storage devices (e.g., E1.S carriers) or a second storage device (e.g., 1×2.5 inch hard drive disk (HDD)). The at least one slot is formed by a top wall, a bottom wall, a first side wall, and a second side wall. The guiding extensions extend into the at least one slot. The guiding extensions include a first set of guiding extensions and a second set of guiding extensions. The first set of guiding extensions configured to receive and secure one of the first storage devices. The second set of guiding extensions configured to receive and secure a second one of the first storage devices.