A vertical column assembly including an intermediate distribution frame enclosure with an internal structure. The vertical column assembly also includes side panels, door assemblies, and a top cover assembly. The internal structure is hidden by the side panels, the door assemblies, and the top cover assembly. The vertical column assembly encases the network equipment installed within the internal structure.

A system for improved cable management is disclosed in several example embodiments. The disclosed embodiments describe example structures for supporting cables, for example telecommunications and fiber optic cables, within a cable storage cabinet. The disclosed embodiments also describe a door for a cable storage cabinet. The example door includes a hinge control and handle system which allows the door to be opened along either side to therefore allow the door to be opened either way from a single handle. The disclosed embodiments also describes an indicator system which informs a user when the door for the cable storage cabinet is in either a closed position or an open position. Each of these embodiments improves the utility and safety of cable management, particularly within cable storage cabinets.

In one embodiment, an autonomous carrier transports a fog computing module to an enclosure at a location determined to be in need of a particular fog computing resource, and aligns and anchors the fog computing module to the enclosure, where the aligning and anchoring is based on mating mechanical connectors on the fog computing module and enclosure. One or more electronic components of the fog computing module may then interface to the enclosure due to the anchoring, and the fog computing module activates at the location, accordingly. In one particular embodiment, the particular fog computing resource of the fog computing module is an additive resource to an existing fog computing resource module at the enclosure, and the existing fog computing resource module provides the mechanical connectors and interfaced electronic components of the enclosure.

Certain types of aggregation enclosures include cable input ports and downwardly angled cable output ports. A cover is pivotally coupled to the body so that the cover moves between an open position and a closed position. A modular component panel may be disposed within the enclosure. The component panel includes one or more distribution components (e.g., fiber distribution components or power distribution components) configured to connect at least a portion of an incoming cable to at least a portion of an outgoing cable.

A telecommunications system is disclosed herein. The telecommunications system includes a chassis defining a top end, a bottom end, and a generally pyramidal shape, wherein a transverse cross-sectional footprint of the chassis changes in outer dimension as the transverse cross-sectional footprint extends from the top end to the bottom end, the telecommunications chassis further defining at least one sidewall, the at least one sidewall extending at an angle to both the top end and the bottom end, the at least one sidewall defining ports defining connection locations for receiving telecommunications equipment.

A splice equipment assembly includes two routing paths along opposite sides of a splice region. The two routing paths do not cross. The two routing paths do not extend circumferentially around the splice region. The two routing paths provide adequate slack to allow a splice tray to be removed from the splice region and moved to a workstation outside of the splice equipment assembly. Multiple splice equipment assemblies can be mounted to the same rack (e.g., at a front and rear of the rack).

A fiber distribution hub configured to house a patch panel includes a plurality of walls forming a chamber, a first shelf attached to a first wall of the plurality of walls in the chamber, a first track supported by the first shelf, and a frame body configured to support the patch panel and to be coupled with the first shelf via the first track. The frame body is configured to shift along the first track between a stored position, a front-exposed position, and a back-exposed position.

A modular high density communications chassis including a chassis, pull-out cable management system (POCMS), and at least two or more slidable carrier modules (carrier module(s)) is provided. The carrier modules are slidably mounted to the chassis and POCMS vertically, respectively. The POCMS is assembled to the chassis. In an operational position, ends of the carrier modules of the chassis extend outward from an access mounting opening of the chassis and ends of the carrier modules of the POCMS, alternately neighboring, lie flush with a plane of the access mounting opening. A handle of the POCMS is configured to move the POCMS from the operational position to a cable management position, whereby, the ends of the carrier modules of the POCMS extend past the ends of the carrier modules of the chassis, providing staged access to the carrier modules and staged management of connector cables extending to and therefrom.

The present disclosure describes an equipment rack for a telecommunications cabinet. The equipment rack allows a telecommunications cabinet to be reconfigured such that telecommunications equipment can be vertically mounted therein. The equipment rack includes a structural rail configured to be mounted within the telecommunications cabinet, an insert plate configured to fit within a cavity of the structural rail and be secured to the structural rail, and a bracket configured to be secured to the to the insert plate and configured such that a piece of telecommunications equipment can be mounted thereto.

A slide assembly for slidably coupling a telecommunications tray to a telecommunications chassis includes a rail configured for mounting to the chassis, the rail defining a rail sliding cavity flanked by a first detent adjacent a first end and a second detent adjacent a second end of the rail, the rail further comprising first and second chassis mounting features, the first and the second chassis mounting features are oriented with respect to each other such that if two of the same rails are aligned and brought together in a juxtaposed relationship with the first and second chassis mounting features facing each other, the first and the second chassis mounting features can nest relative to each other so as to not increase the total width of the two rails. A guide configured for mounting to the telecommunications tray defines a guide sliding cavity configured to slidably receive the rail such that the rail sliding cavity and the guide sliding cavity face each other, the guide defines a pin connected thereto via a flexible cantilever arm, at least a portion of the pin extending into the rail sliding cavity when the rail and the guide are in a sliding relationship for latching by the first and second detents of the rail in providing two predetermined stop positions for the guide.