A re-enterable enclosure has a cover arrangement removably disposed within the interior between a rear wall and an access opening to separate the interior into a restricted access region and an unrestricted access region. The cover arrangement extends over the restricted access region to inhibit access to the restricted access region from the access opening. First and second entrances to the restricted access region are provided from the unrestricted access region. The second entrance is different from the first entrance. In some implementations, a termination field is provided at a first side of the restricted access region and a splice tray is provided at a second side of the restricted access region.

Fiber optic terminals having one or more connector ports configured for receiving fiber optic connector having a latching trigger used as a connector securing/release mechanism connectors are disclosed. The fiber optic terminals comprise an actuator along with a flexible tab that are associated with the respective connector port of the shell of the fiber optic terminal. The actuator may translate to engage the flexible tab for engaging with the latching trigger of the fiber optic connector for allowing the release of the fiber optic connector from the connector port. An example of a fiber optic connector having a latching trigger used as a connector securing/release mechanism are LC connectors, but the terminal concepts may be used with other suitable connectors such as SC connectors having a latching trigger.

A sealing unit (210) for cables extending into an enclosure comprising telecommunications equipment. The sealing unit (210) comprising a gasket (101) having an elongate section (110) of resilient material comprising a plurality of apertures (120), wherein each aperture is arranged to receive a cable (300). The elongate section (110) comprises slots (130) connecting the apertures to a lateral edge (150) of the elongate section. The apertures (120) are arranged in a two-dimensional array.

Fiber optic connectors, cable assemblies and methods for making the same are disclosed. In one embodiment, the optical connector comprises a housing and a ferrule. The housing comprises a longitudinal passageway between a rear end and a front end, and, a part of the rear portion of the housing comprises a round cross-section and a part of the front portion of the housing comprises a non-round cross-section with a transition region disposed between the rear portion and the front portion.

An optical fiber feed-through connector for optically coupling an end portion of an optical fiber cable with a non-feed-through optical fiber connector includes a feed-through duct engaging portion having a body member and a compression fitting portion configured to radially compress a portion of the body member around the free end portion of the duct and a feed-through housing portion configured to be operatively coupled to the feed-through duct engaging portion so as to allow the end portion of the optical fiber cable to be slidingly fed through the feed-through housing portion. The feed-through engaging portion is configured to permit the end portion of the optical fiber cable to be slidingly fed through both the duct and the feed-through duct engaging portion, and the feed-through duct engaging portion and the feed-through housing portion are configured to permit the optical fiber cable to be pushed or pulled through the duct and the feed-through housing portion after the feed-through duct engaging portion is operatively coupled to the feed-through housing portion.

A fiber distribution hub comprises a housing, a first side panel and a second side panel comprising one or more ports, and at least one cover disposed between the first side panel and the second side panel and forming an interior compartment. The interior compartment may include cable managers. A mounting structure aerially strand mounts the fiber distribution hub. Fiber distribution hubs comprising a first fiber distribution hub, a second fiber distribution hub configured to couple to the first fiber distribution hub, and a mounting structure configured to aerially strand mount the fiber distribution hub are also disclosed.

A fiber management tray (10) is disclosed. The fiber management tray (10) can have a body (12) including a bottom wall (14) with side walls (16) extending outwardly from the bottom wall (14). The fiber management tray (10) can include a termination region (18) that has a first side (24) and a second side (26). The termination region (18) includes a termination panel (13) that holds connectors (20). The fiber management tray (10) can include a hinge area (56) for mounting said tray (10) to a tray tower (58) and a storage basket (32) located between the termination region (18) and the hinge area (56). The storage basket (32) can include a first pocket (44) that communicates with the second side (26) of the termination region (18) and an opposite second pocket (48) that communicates with the first side (24) of the termination region (18). The fiber management tray (10) can define at least one fiber routing path on each of the first and second pockets (44, 48) of the storage basket (32). The fiber management tray (10) can define a fiber transition opening (54) for transitioning optical fibers between the second pocket (48) of the storage basket (32) and first side (24) of the termination region (18). The fiber transition opening (54) can have an access structure for allowing optical fibers to be inserted into the fiber transition opening (54).

A tool system for threading an optical fiber through a hole formed in a wall at customer premises, and for protecting the fiber inside the wall. A tool body has forwardly projecting fingers for capturing a connector at an end of the fiber from a direction approaching a front face of the connector. A back end of the tool body is arranged to engage a rod handle of such length that its free end can be threaded through the hole and out the opposite side of the wall. Using the handle, the tool body is pulled through the hole along with a captured connector and associated fiber. A hole plug has a hollow cylindrical body and an access slit for passing the fiber inside the body for protection. The plug body has teeth for engaging the premises wall and retaining the plug at a desired angular position in the wall.

A module for optical fiber installation and storage at customer premises has a base, and a fiber supply spool mounted for rotation on the base. An elongated adapter plate has a front end portion for mounting a connector adapter. A rear end portion of the adapter plate has first hinge parts at one side of the plate, and the fiber supply spool has second hinge parts for engaging the first hinge parts of the plate to define a hinge axis. The adapter plate can swivel about the hinge axis between a position where the plate lies flush on the supply spool and the spool can turn as fiber unwinds, and a position where a port of a connector adapter mounted on the plate is accessible for connection to an outside device when the module is closed, and the plate engages the module base to restrain the spool from rotation.

It is provided an apparatus, comprising a box configured to conduct an optical fiber from an exterior to an interior of the box; at least one of a mounting means adapted to mount a connecting means to which the optical fiber may be connected and a guiding means adapted to guide the optical fiber, wherein the at least one of the mounting means and the guiding means is arranged in the interior of the box; a detecting means arranged in the interior of the box adapted to detect a first signal from the interior of the box, wherein the first signal is at least one of a light and a smoke; wherein the interior of the box is substantially shielded from a second signal from an exterior of the box, and the detecting means is suitable to detect the second signal in a same manner as the first signal.