An optical cable termination unit includes a case, a first adapter panel that is disposed in the case and includes a plurality of first adapters each configured so that a corresponding one of a plurality of optical connectors is connectable thereto and disconnectable therefrom and a first surface on which the plurality of first adapters are arranged, and a second adapter panel that is disposed in the case and includes a plurality of second adapters each configured so that a corresponding one of a plurality of optical connectors is connectable thereto and disconnectable therefrom and a second surface on which the plurality of second adapters are arranged. The first and second surfaces are separated from each other. The first adapter panel is configured to be movable relative to the second adapter panel so that the first surface and the second surface are capable of becoming parallel to each other.

The present disclosure describes an optical fiber splice closure for joining two fiber optic cables. The optical fiber splice closure comprises a strain relief assembly that securely holds the two fiber optic cables being connected, and an enclosure that houses the strain relief assembly. The configuration of the strain relief assembly allows for securing the two fiber optic cables in a compact space, thus permitting a compact enclosure of the optical fiber splice closure, while also providing quick and easy installation in the field. A method of joining fiber optic cables using the optical fiber splice closure is also disclosed. The optical fiber splice closure and ease of joining also facilitates repairing damaged fiber optic cable. A method of repairing existing fiber optic cable is disclosed.

The present disclosure relates to a fiber optic assembly having a splice tray that increases spatial efficiency within the fiber optic assembly and within the splice tray. The splice tray may be inserted and/or removed from a terminal without utilization of tools. Additionally, the splice tray may be configured to enable one handed insertion or removal, which may be advantageous, such as in small terminals or confined spaces. The splice tray also provides an efficient routing pattern of optical fibers to enable larger diameter optical fibers to be routed within the splice tray and the terminal.

A fiber optic telecommunications tray is provided with features that improve accessibility and handling of fibers and/or cables in the tray. The tray may include a combination of a fiber storage device, a fiber splice device, and a fiber termination device, which are arranged in a particular order. Alternatively, the tray may include a plurality of fiber termination devices. Further, the tray may include a fiber funneling structure that make is easy to route and retain fibers in the tray.

Cable fixation assemblies for telecommunications systems. A cable support body of a cable fixation assembly defines a tie wrap passage. The tie wrap passage includes features that can improve tie wrap tightening control and/or a preferred tie wrap advancement direction when securing a cable to the cable support with the tie wrap.

A method of assembling a wavelength division multiplexing (WDM) cassette for a fiber optic network is disclosed and includes attaching a first plurality of wavelength filters to a first cassette workpiece, attaching a second plurality of wavelength filters to a second cassette workpiece, organizing the optical fibers extending from the wavelength filters, adjusting a length of the optical fibers extending from wavelength filters, and forming an optical connection between the optical fibers from the wavelength filters via a mass fusion splice. The first cassette workpiece and the second cassette workpiece are separate from each during at least one of the attaching, organizing, adjusting, and forming steps. The optical fibers may have predetermined lengths for being arranged in a helix configuration and folded to produce an organized fiber stack that fits within the confines of the cassette. A WDM cassette having an organized arrangement of optical fibers is also disclosed.

A network access point enclosure is configured to house a splice tray that is configured to pivot to provide increased access to opposite sides of the splice tray during assembly. The enclosure includes a base, a cover configured to be sealingly coupled with the base to form a housing, and a splice tray configured to be pivotally coupled with the base. The splice tray is configured to be pivoted between a first orientation relative to the base and a second orientation relative to the base. The splice tray is configured to form a larger angle relative to the base in the first orientation than in the second orientation, and the splice tray is configured to provide increased access to a front side of the splice tray and a rear side of the splice tray in the first orientation than in the second orientation.

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).

Fiber distribution systems, terminals and tap boxes that provide a reconfigurable and expandable system of hardened connections. An aerial terminal may include at least one feeder port and a plurality of distribution ports, each of the at least one feeder port and the plurality of distribution ports being sealable ports configured to receive one of a duct and a connector, where the connector is configured to interface with a drop type cable. The terminal may include an expandable module configured to receive a splitter. The terminal may be configured to receive a fiber through the feeder port and to output a plurality of fibers through the plurality of distribution ports.

A cable restraint located in a splice enclosure to restrain a cable includes a tray having a bottom side with an upward facing surface. The cable restraint also includes a restraint bridge removably attached to the tray. The restraint bridge includes a central portion having a surface configured to cooperate with the tab feature to inhibit relative motion between the restraint bridge and the tray in a direction non-perpendicular to an axis of the cable. A restraint clip is removably attached to the restraint bridge and includes a restraint post attached to the body portion configured to secure a strength member of the cable to the restraint clip. The restraint clip further includes a column attached to the body portion configured to inhibit relative motion between the restraint clip and the restraint bridge in the direction non-perpendicular to the axis of the cable.