Aspects of the present disclosure relate to a modular fiber optic distribution system for enhancing installation flexibility and for facilitating adding components to a terminal housing over time so as to delay cost. The system is configured to allow components (e.g., inserts, add-on modules, etc.) to be readily added to the terminal housing over time to expand capacity, provide upgrades and to provide forward and backward compatibility.

A fiber optic drop terminal assembly includes a housing, a spool and a fiber optic distribution cable. The housing has a first exterior surface and an oppositely disposed second exterior surface. A plurality of ruggedized adapters is mounted on the first exterior surface of the housing. The ruggedized adapters include a first port accessible from outside the housing and a second port accessible from inside the housing. The spool is engaged with the second exterior surface and includes a drum portion. The fiber distribution cable is coiled around the drum portion. The distribution cable includes a first end and an oppositely disposed second end. The second end is disposed inside the housing.

A fibre routing structure is disclosed for routing and terminating optical fibres within an enclosure, having a number of fibre routing trays which receive and guide a fibre across a surface of the tray from an entry point to an exit point, and at least one fibre routing tray has a mounting point for a fibre termination component. The fibre routing trays are mounted in a stacked configuration on a tray support member which routes fibres between the fibre routing trays. The fibre routing trays extend from the tray support member in cantilevered fashion and at least one fibre routing tray is hingedly mounted to the tray support member permitting it to be pivoted away from an adjacent underlying tray to reveal and provide access to the adjacent underlying tray and permitting it to be pivoted back to lie parallel to the adjacent underlying tray. The tray support member is mounted above a base and a coiled fiber storage area is provided which extends at least partly below the tray support member. This provides compact storage accommodating large number of fibre connections and terminations with ease of access to the stacked trays.

The present disclosure relates to a re-enterable enclosure for a fiber optic network. The enclosure can include features such as a low compression-force perimeter gasket, cable seals constructed to seal effectively seal triple points, multi-function port size reducer plugs and multi-function blind plugs.

An optical termination box comprising: a tubular housing (10) with an open end (10b) and a closed end (10a) provided with an input opening (11) for an optical distribution cable (100); a cover (20) securable against the open end (10b) of the housing (10) and pierced by output adapters (30); and an optical fiber accommodating tray (40), internal to the tubular housing (10) and having a first end (41) carrying a tubular bushing (50) with a base portion (51) seated against the closed end (10a) of the tubular housing (10), and a projecting body portion (52) out of the input opening (11), to cooperate with a puller (60) that holds the tubular bushing (50) hermetically pressed against the closed end (10a) of the tubular housing (10). The tubular bushing (50) hermetically receives and retains an end portion (100a) of an optical distribution cable (100) containing at least one optical fiber (FO).

The present disclosure relates to an optical termination enclosure having an enclosure housing containing a fiber management assembly. The enclosure housing can define sealed cable ports and can include cable anchor mounting locations in alignment with the cable ports. Cable anchoring and grounding units can be attached at the cable anchor mounting locations. The fiber management assembly can include a fiber break-out arrangement including a resilient grommet used to anchor a protective tube that carries optical fibers from the cable anchor mounting location to the fiber management assembly.

An optical termination box includes a housing, a module case slidably attached in a front-rear direction with respect to the housing, a front adapter fixed to a front end of the module case, an adapter holder disposed on a rear end side of the module case, a rear adapter fixed to the adapter holder, and an optical fiber that connects the front adapter to the rear adapter. The adapter holder is fixed to a rear end portion of the housing such that the rear adapter is exposed rearward of the housing.

A fiber optic cable terminal proximally terminates a stub cable carrying one or more optical fibers. The stub cable is structurally adapted to be advanced through at least a portion of a conduit by distally pushing a distal end of the stub cable from a location that is proximal to a proximal end of the conduit and without applying any pulling force at any location that is distal to the proximal end of the conduit.

Distributed optical tapping architectures include two or more optical tap terminals daisy-chained together. Each optical tap terminal includes an environmentally sealed enclosure; an optical tapping circuit positioned within an interior of the enclosure, the optical tapping circuit including an tap input, a tap pass-through output, and a tap drop output; and hardened interface locations (e.g., de-mateable fiber optic connection locations, cable-pass through glands, etc.) corresponding to the tap input, the tap pass-through output and the tap drop output.

A telecommunications terminal including a terminal housing and a fiber optic adapter secured to the terminal housing and having a first port accessible from outside the terminal housing and a second port positioned inside the terminal housing, the first port being a hardened port. A first fiber optic cable is routed into the terminal housing, the first fiber optic cable being a tether cable having a free end outside the terminal housing, the free end including a hardened fiber optic connector. A second fiber optic cable is routed into the terminal housing, the second fiber optic cable including at least one optical fiber connected to the fiber optic adapter and at least one optical fiber connected to the tether cable.