An assembly includes: first and second fiber optic cables, each of the first and second fiber optic cables including an exposed portion of an optical fiber and an overlying jacket, wherein the optical fiber of the first fiber optic cable is fusion spliced to the optical fiber of the second fiber optic cable to form a splice area; a splice protector that surrounds the splice area of the first and second fiber optic cables; a flexible tube that encircles the splice protector, the exposed portions of the first and second fiber optic cables, and end portions of the jackets of the first and second fiber optic cables, wherein the splice protector, the exposed portions of optical fibers of the first and second fiber optic cables reside in a lumen of the flexible tube; first and second adhesive barriers positioned between an inner surface of the flexible tube and the end portions of the first and second fiber optic cables, respectively; and an outer sleeve that circumferentially overlies the flexible tube and portions of the jackets of the first and second fiber optic cables.

A reinforcement sleeve is a member for reinforcing a connection part of an optical fiber tape core wire, and comprises a heat-shrinkable tube, a heat-meltable member, a tension member, and the like. The heat-shrinkable tube is a cylindrical member. The tension member is a rod-shaped member. The tension member and the heat-meltable member are inserted in the heat-shrinkable tube. The heat-meltable member is disposed above the tension member. The tension member is approximately circular or approximately elliptical in a cross section perpendicular to the longitudinal direction of the reinforcement sleeve. More specifically, the surface on the heat-meltable member side of the tension member is formed to have an arc-shaped convex curved surface in a cross section perpendicular to the longitudinal direction of the tension member.

The present disclosure relates to a fiber optic cable that includes a plurality of internal optical fibers and a fiber optic cable portion. The fiber optic cable portion includes an outer jacket and an inner conduit, the inner conduit containing the plurality of optical fibers disposed therein. The fiber optic cable further includes a flexible conduit portion, wherein the flexible conduit portion has a proximal end and a distal end. The proximal end is secured to the fiber optic cable portion and the distal end has a terminating device. The terminating device at least partially encases the flexible conduit portion, and the plurality of optical fibers passes through the flexible conduit portion and the terminating device.

Embodiments of a furcated optical fiber cable are provided. A main distribution cable has optical fibers surrounded by a cable jacket. The optical fibers are divided into at least two furcation legs. A furcation plug is located at a transition point between the main distribution cable and the at least two furcation legs. The furcation plug surrounds at least a portion of the main distribution cable and each of the at least two furcation legs. Optical connectors are provided for each of the at least two furcation legs, and each connector includes optical fibers that are spliced at a splice location to the optical fibers of the connector's respective furcation leg. The splice location is closer to the connector than to the furcation plug. A method of furcating an optical fiber cable and a pulling configuration for the furcated optical fiber cable are also provided.

Embodiments of a furcated optical fiber cable are provided. A main distribution cable has optical fibers surrounded by a cable jacket. The optical fibers are divided into at least two furcation legs. A furcation plug is located at a transition point between the main distribution cable and the at least two furcation legs. The furcation plug surrounds at least a portion of the main distribution cable and each of the at least two furcation legs. Optical connectors are provided for each of the at least two furcation legs, and each connector includes optical fibers that are spliced at a splice location to the optical fibers of the connector's respective furcation leg. The splice location is closer to the connector than to the furcation plug. A method of furcating an optical fiber cable and a pulling configuration for the furcated optical fiber cable are also provided.

A main fanout includes a plurality of intermediate fanout devices that are connected to one another. Each intermediate fanout device can be assembled separately and then connected together to form the main fanout. Each intermediate fanout device is connected to an intermediate cable of a main cable and a plurality of optical fibers of each intermediate cable is positioned within at least one furcation tube. The plurality of optical fibers and at least one furcation tube are secured to a main body of each intermediate fanout device. Each intermediate fanout device includes a mating feature to connect to adjacent intermediate fanout devices with a like mating feature. The mating feature reduces relative movement between adjacent intermediate fanout devices.

The present disclosure relates to a hardened fiber optic fan-out arrangement including a fan-out housing. A plurality of fiber optic pigtails projects outwardly from the fan-out housing. The fiber optic pigtails have free ends including hardened de-mateable fiber optic connection interfaces. A fiber optic feeder cable also projects outwardly from the fan-out housing. The fiber optic feeder cable is optically coupled to the fiber optic pigtails.

Embodiments of a furcated optical fiber cable are provided. A main distribution cable has optical fibers surrounded by a cable jacket. The optical fibers are divided into at least two furcation legs. A furcation plug is located at a transition point between the main distribution cable and the at least two furcation legs. The furcation plug surrounds at least a portion of the main distribution cable and each of the at least two furcation legs. Optical connectors are provided for each of the at least two furcation legs, and each connector includes optical fibers that are spliced at a splice location to the optical fibers of the connector's respective furcation leg. The splice location is closer to the connector than to the furcation plug. A method of furcating an optical fiber cable and a pulling configuration for the furcated optical fiber cable are also provided.

The present disclosure relates to a hardened fiber optic fan-out arrangement including a fan-out housing. A plurality of fiber optic pigtails projects outwardly from the fan-out housing. The fiber optic pigtails have free ends including hardened de-mateable fiber optic connection interfaces. A fiber optic feeder cable also projects outwardly from the fan-out housing. The fiber optic feeder cable is optically coupled to the fiber optic pigtails.

Anchoring an input cable (190) at an input port (123, 223) of an enclosure (110) includes inserting the input cable (190) through an anchor member (151, 251) so that a cable jacket (191) terminates within the anchor member (151, 251) and at least one optical fiber (195) extends outwardly from the anchor member (151, 251). The anchor member (151, 251) is secured to the cable jacket (191) using the sheath (175). A cover (162, 260) is mounted to the anchor member (151, 251) to form a pass-through assembly (150, 250) defining an enclosed region. Material is injected into the enclosed region to fix strength members (197) and/or optical fibers (195) of the input cable (190) to the pass-through assembly (150, 250). The ruggedized pass-through assembly (150, 250) is disposed at a base (120, 220) of the enclosure (110).