A housing including a plurality of openings for receiving fiber optic connectors and protecting the polished end face of the connectors from damage while the connectors are stored within a telecommunications connection cabinet. A module with a plurality of optical fiber cables connected to a first optical fiber cable and terminated by a fiber optic connector. Each of the connectors are inserted within openings in a connector holder for storage and protection until the cables need to be connected to a customer equipment cable.

A telecommunications assembly including a housing and a plurality of modules mounted within the housing. The modules includes a rear face in which is mounted at least one fiber optic connector. Within an interior of the housing are positioned at least one fiber optic adapters. Inserting the module through a front opening of the housing at a mounting location positions the connector of the module for insertion into and mating with the adapter of the housing. The adapters within the interior of the housing are mounted to a removable holder. A method of mounting a telecommunications module within a chassis.

A novel method and apparatus are described that can be used to equalize the latency in fiber optic distribution links within data centers containing multiple pods (clusters of servers) and thereby improve the overall operation and utility of the data center for multiple customers. Specifically, the apparatus serves to add precisely measured latency (signal delays) to data transmission in certain fiber optic cable links so that there are negligible differences in signal transmission times from the central switch (core router) to each of the distributed pods within a data center. While that purposeful addition of latency may, at first, seem counterintuitive to optimizing the performance of a data center, the effect achieved is quite the opposite. That is because all pods will have equal access to received and transmitted data thereby reducing signal congestion and the unbalanced time favoritism of one pod operator over another to the access incoming data.

A cable management bracket that routes cables in a cabinet or rack. The cable management bracket includes an inner mounting rail and an outer mounting rail. The outer mounting rail is secured to the inner mounting rail by fasteners. The inner mounting rail has a top flange, first and second end flanges, a bottom flange, and a side surface. The outer mounting rail has a top flange, an end flange, a bottom flange, and a side surface. The side surfaces of the inner mounting rail and the outer mounting rail have a plurality of mounting features for securing bundling clips that receive a plurality of cables.

An example cable enclosure is provided that includes a chassis, a front cover coupled to the chassis, and first and second slide rails slidably coupled relative to the chassis. The cable enclosure includes a first release lever mounted to the chassis. The first release lever is capable of being positioned into a first position and a second position. In the first position, the first release lever engages the chassis to prevent sliding of the chassis and the front cover relative to the first and second slide rails. In the second position, the first release lever disengages the chassis to allow for sliding of the chassis and the front cover relative to the first and second slide rails.

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 telecommunications assembly including a housing and a plurality of modules mounted within the housing. The modules includes a rear face in which is mounted at least one fiber optic connector. Within an interior of the housing are positioned at least one fiber optic adapters. Inserting the module through a front opening of the housing at a mounting location positions the connector of the module for insertion into and mating with the adapter of the housing. The adapters within the interior of the housing are mounted to a removable holder. A method of mounting a telecommunications module within a chassis.

An interconnect system for a building includes a pre-terminated trunk cable assembly that has different groups of optical fibers carried by subunits and terminated by ferrules. The interconnect system also includes trays for managing interconnections with the ferrules. A plurality of adapters are disposed on each tray and arranged in a direction along a longitudinal axis of the tray. The adapters may be oriented at an angle relative to the longitudinal axis to facilitate routing of the optical fibers. At least one tray mount receiver may also be provided on each tray to cooperate with a tray mount that can secure a select subunit to the tray.

An optical distribution and splice frame system includes rack(s), enclosure(s), cable management component(s), and/or cassette(s) that have features to allow for different cable management configurations not yet available in the market. A fiber optic cassette and enclosure are designed to enable flexibility in cable management configurations for the overall system.

A structured optical fiber cabling system configured to connect first and second layers of switches in a mesh network is disclosed. The system comprises groups of fiber optic ports arranged side-by-side, with each group including a plurality of the fiber optic ports distributed in a vertical direction. A plurality of fiber optic jumper assemblies each include a horizontal segment and a plurality of legs and fiber optic connectors extending from the horizontal segment, with each fiber optic connector configured to connect to a corresponding fiber optic port of the plurality of the fiber optic ports at the same vertical location in each group of the array.