Cable-routing systems can be provided for a tray configured for movement between an extended position and a stowed position. The cable-routing system can include a biasing mechanism and a pivot. The pivot can receive a bend of a cable about the pivot. The pivot can be coupled with the biasing mechanism. Movement of the tray toward the extended position can pull the cable away from a stored state against a biasing force of the biasing mechanism. The cable can be biased into the stored state by the biasing force of the biasing mechanism when the tray is in or moved toward the stowed position.

An air mover assembly may include an air mover comprising a body and a cable extending from the body and one or more air mover holders mechanically coupled to the body. The one or more air mover holders may comprise a plurality of cable maintenance features and a keying feature. The plurality of cable maintenance features may include a first cable maintenance feature configured to maintain the cable in a first configuration of the air mover in a first airflow direction and a second cable maintenance feature configured to maintain the cable in a second configuration of the air mover in a second airflow direction. The keying feature may be configured to mechanically interface with an interfering feature of a chassis when an attempt is made to improperly insert the air mover into the chassis in accordance with a proper airflow direction configuration of the chassis, in order to prevent improper insertion of the air mover into the chassis in accordance with the proper airflow direction configuration of the chassis.

The disclosure is directed at a rack unit that provides an improved system and method for users to identify the ports within the rack unit. The rack unit includes a designation plate pivots between a lowered position where the user can identify the ports within the rack unit and a raised position where the user has more space to insert a cable into an identified port.

Embodiments may be generally direct to apparatuses, systems, method, and techniques to determine a configuration for a plurality of connectors, the configuration to associate a first interconnect protocol with a first subset of the plurality of connectors and a second interconnect protocol with a second subset of the plurality of connectors, the first interconnect protocol and the second interconnect protocol are different interconnect protocols and each comprising one of a serial link protocol, a coherent link protocol, and an accelerator link protocol, cause processing of data for communication via the first subset of the plurality of connectors in accordance with the first interconnect protocol, and cause processing of data for communication via the second subset of the plurality of connector in accordance with the second interconnect protocol.

System for distributing cabling. In an embodiment, a unit comprises two levels. Each level comprises openings, on two opposing surfaces, arranged in a row parallel to a first axis, with each opening opposite to one opening on the opposing surface. Each level comprises parallel main conduits between the surfaces. Each main conduit is angled relative to a second axis, intersecting the surfaces and orthogonal to the first axis, such that each main conduit connects an opening on one surface to an opening on the other surface that is offset by one opening from its opposing opening on the other surface. A divergent conduit connects openings on one of the two surfaces to an opening on a third surface, and an articulated conduit, angled relative to a third axis that is orthogonal to the first and second axes, connects an opening on one level to an opening on the other level.

A rack door is disclosed for mounting one or more power distribution units (PDUs) to the front of a server rack. An embodiment allows access to power cables when the rack door is open or closed. An embodiment provides power cable routing that allows power cables from one PDU to be connected or disconnected independently from other cables on that same PDU or on another PDU mounted to the rack door.

A cable management device includes a first arm and a first connection element. The first arm has a first end portion and a second end portion. The first connection element is pivotally connected to the second end portion of the first arm. One of the first arm and the first connection element is arranged with an engaging feature, and the other one of the first arm and the first connection element is arranged with a corresponding feature. When the first arm pivots relative to the first connection element from a first position to a second position by a predetermined angle, the first arm is capable of being kept at the second position relative to the first connection element by cooperation between the engaging feature and the corresponding feature.

A server cable management structure includes a first arm member and a second arm member respectively pivotally coupled to the outer and inner sliding rails of a sliding rail assembly which is connected to a drawer of a server. An intermediate arm member is pivotally coupled between the first and second arm members, and a sliding bar is slidably coupled to the first arm member, with at least one spring member connected between the first arm member and the sliding bar, and a connection frame connected to the sliding bar and pivotally connected to the outer sliding rail. The inner sliding rail is movable outward a first distance when the first arm member is fully extended outward relative to the second arm member, and outward a further distance while stretching the at least one spring member when the sliding bar is fully extended outward relative to the first arm member.

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.

A modular data machine room includes a data cabinet subsystem, a cooling subsystem and a power distribution subsystem. The data cabinet subsystem includes two columns of data cabinet groups, and each column of data cabinet group includes at least one data cabinet. The cooling subsystem includes at least one cooling unit, and the cooling unit is arranged in the two columns of data cabinet groups. Each data cabinet and cooling unit is connected with the power distribution subsystem through an interface. The machine room further includes a sealing subsystem, which seals a cold/hot channel between the two columns of data cabinet groups. The machine room has a short construction period and a high cooling efficiency.