An optical fiber pedestal box comprises a pedestal having a rail and an optical fiber box configured to mount to the pedestal. The optical fiber box is restricted in movement by at least one cable and the pedestal is configured to slide relative to the optical fiber box to accommodate cables moving because of ground heaving during freezing and thawing. The optical fiber pedestal box may be configured to receive different sizes and types of optical fiber cables.

A fiber termination point arrangement (100) including an enclosure (110) and a storage member (130). The enclosure (110) holds at least one optical adapter having an external port. The storage member (130) includes a rearwardly facing cable spool (135). The fiber termination point arrangement (100) mounts over a wall outlet so that the cable spool (135) is hidden from view. The fiber termination point arrangement (100) has a rear input port that enables a cable or fiber to enter the fiber termination point arrangement (100) from the rear (e.g., at the cable spool) without extending beyond the boundaries of the fiber termination point arrangement (100) when routed from the wall outlet.

An optical termination module (50) comprises a fixed part (60) to be attached to a mounting member (108) of an electric cabinet (100) and a movable part (70) rotatably attached to the fixed part (60) to move relative to the fixed part (60) about a rotation axis (X-X) between a first position and a second position. The fixed part (60) has a bottom surface (61a) with an inlet opening (61b) configured to receive an optical drop cable (1) and the movable part (70) has a bottom surface (71a) with one or more outlet openings (71b) configured to receive respective one or more optical customer cables (5).

Grounding assemblies for cables entering telecommunications enclosures. The grounding assemblies include a cable fixation subassembly and a grounding subassembly that are electrically coupled together to ground strength members and a conductive shield of a cable. The cable fixation subassembly can fixate the cable such that the strength members lie in a plane that is at a non-zero angle relative to each of a horizontal reference plane and a vertical reference plane.

A fiber splice closure for housing an optical connection between a distribution cable and at least one drop cable of an optical network includes a base and an insert. The base includes round drop cable ports configured to receive a drop cable containing a first optical fiber. Screw holes are arranged in a radial side wall of the drop cable ports and receive a fixing device to secure the drop cable. A round port receives a distribution cable containing a second optical fiber. A clamp secures the distribution cable to the base. An insert has first and second wrap guides that house excess first optical fiber. A center section is arranged between the first and second wrap guides and includes a splitter module, splice protector holder elements that hold splice protectors, an LC adaptor that receives the second optical fiber from the distribution cable, and an LC connector module that connects the first optical fiber to the splitter, which in turn is connected to the LC adaptor, thereby providing an optical connection between the distribution cable and the drop cable.

A storage hub component for hanging optical fiber cable that includes a mounting base configured to be mounted within a cable storage housing. A hanging projection extends outwardly from the mounting base. The hanging projection is sized to receive loops of optical fiber cable thereon. A cable retaining feature includes a flexible retaining tab extending outwardly from a peripheral surface of the hanging projection. The flexible retaining tab is configured to bend upon contact with the optical fiber cable.

A fiber optic assembly for supporting optical connections in a fiber optic network employing parallel optical configurations is described. In one embodiment, the fiber optic assembly includes at least two live multi-fiber components and at least one tap multi-fiber component. Optical signals are routed from one live multi-fiber component to another in a parallel optical connection configuration, with each group of optical signals corresponding to a respective group of fiber positions on each live multi-fiber component. Each group of optical signals is also routed to one of the first and second groups of fiber positions of the at least one tap multi-fiber component in a parallel optical connection configuration. In this manner, fiber optic signals can be simultaneously provided and monitored within an active fiber optic network using a parallel optical configuration without the need for interrupting network operations.

A fiber optic splice enclosure includes a basket. The basket includes an outer shell, the outer shell including an outer sidewall defining at least a portion of a periphery of the basket. The basket further includes an insert disposed within the outer shell, the insert including a first sidewall and a second sidewall spaced apart from each other along a transverse axis and each extending along a longitudinal axis to define an inner channel therebetween. The first sidewall and the second sidewall are each further spaced apart from the outer sidewall along the longitudinal axis to define a first outer channel and a second outer channel. The fiber optic splice enclosure further includes a splice tray assembly including at least one splice tray, the splice tray assembly disposed within the inner channel.

A splice enclosure that may include a body portion, a lower portion, an adapter portion, and a splice portion. The adapter portion may be configured to pivot relative to the body portion between a first adapter portion position and a second adapter portion position. The splice portion may be configured to pivot relative to the body portion between a first splice portion position and a second splice portion position. The adapter portion may configured to be disposed between the splice portion and the lower portion when the splice portion is in the first splice portion position and the adapter portion is in the first adapter portion position such that the splice portion is configured to block access to the adapter portion The splice portion also may be configured to permit access to the adapter portion when the splice portion is pivoted to the second splice portion position such that the adapter portion is configured to be selectively pivoted to the second adapter portion position so as to provide improved access to an adapter that is configured to be coupled with the adapter portion.

An adapter panel arrangement including a chassis and a panel of adapters. The adapters defining open rearward cable connections and open forward cable connections of the panel arrangement. The adapters being arranged in arrays that slide independently of other adapter arrays to provide access to the open rearward and open forward cable connections.