Abstract: Example fiber optic connector systems have rugged, robust designs that are environmentally sealed and that are relatively easy to install and uninstall in the field. Some connector systems can be configured in the field to be compatible with different styles of fiber optic adapters. Some connectors include a first seal (90) on a release sleeve; and a second seal (88) between the release sleeve and a connector body. Other connectors include a seal (139) and a flexible latch (136) on a connector. Other connectors include a protective structure (228, 328, 428) that mounts over the fiber optic connector. Other connectors include a protective outer shell (528, 860) and a sealing and attachment insert (570, 570A, 876). Other connectors include a protective outer shell (728) and a fastener (780).

Abstract: Cabling a terminal access cable through a residence includes optically coupling an end of a subscriber cable to a first end of a terminal access cable within a transition anchoring the terminal access cable to an anchor surface (202) formed as a flange surrounding the side walls (203) of the transition box with adhesive; storing excess length of the terminal access cable at a storage location (207) within the transition box; routing the terminal access cable from the transition box to a wall outlet box; anchoring the terminal access cable to an anchor surface of the wall outlet box with adhesive; and routing a second end of the terminal access cable into the wall outlet box and optically coupling the second end to a port of an optical adapter disposed within the wall outlet box. A jumper cable can be optically coupled to the subscriber cable by plugging a connectorized end of the jumper cable into the port.

Abstract: A fiber distribution system (10) includes a fiber distribution hub (20, 300); at least one fiber distribution terminal (30, 100); and a cable (40) wrapped around a spool (110) of the fiber distribution terminal (30, 100). The fiber distribution terminal (30, 100) includes a spool (110) and a management tray (120) that rotate together. A second connectorized end (40b) of the cable (40) is held at a fiber optic adapter (125) on the tray (120). After dispensing the first connectorized end (40a) to the hub (20), an optical splitter (70, 130, 140) can be mounted to the tray (120). The splitter (26, 70, 130, 140, 306) has output adapters at which patch cords (50) can be inserted to connect subscribers to the system. The fiber distribution hub can use the same format of splitters (26, 70, 130, 140, 306). Other distributed splitter systems are provided with splicing and/or adding of splitters as needed.

Abstract: A hybrid cable distribution system wherein a feeder cable is received by a box. The feeder cable can be a hybrid cable including optical fibers and copper wire (coax). The box may be used only for copper signal handling (such as coaxial signal handling), and then at a later date, the box may be used for receiving fiber signals. Customers can directly connect to the feeder fan out device by connecting a tail of a drop splice module that is spliced to an individual distribution cable to the feeder fan out device. This connection creates a point-to-point connection. The number of fan out devices in the system can be increased or decreased as needed. Alternatively, a splitter input can be connected to the feeder fan out device, such as through a pigtail extending from the splitter, wherein the splitter splits the signal as desired into a plurality of outputs. The outputs of the splitters can be in the form of connectors or adapters.

Abstract: Aspects and techniques of the present disclosure relate to an IP 55 rated enclosure that does not use a rubber O-ring or comparable elastomeric sealing member disposed between pieces of the enclosure to provide sealing. Another aspect of the present disclosure relates to an IP 55 compliant sealing interface that includes mating sealing profiles made of the identical materials. A further aspect of the present disclosure relates to an enclosure having jet stream redirecting structures that prevent spray from a water jet from being sprayed directly into an ingress path defined by a sealing interface. A further aspect of the present disclosure relates to a sealing interface provided by an interference-fit between two plastic profiles which create pressure on the interface keeping it closed while concurrently including angled surfaces so that greater tolerances are allowed.

Abstract: Example telecommunications wall outlets (200) include a base structure (220) and a stationary spool structure (237) extending from the base structure (220). The spool structure (237) includes a hub portion (248) extending between a first wall (238) and a second wall (250). A length of fiber optic cable (190) is coiled about the hub portion (248) between the first and second walls (238, 250). A cover (260) is also provided which covers at least a portion of the spool structure (237). The cover (260) includes a port (266) aligned over the hub portion (248) through which the length of cable can be dispensed from the spool structure (237) by unwinding the cable (190) about the spool structure (237) such that the port (266) revolves around the spool structure (237). Additional embodiments are disclosed.

Abstract: A fiber distribution system (10) includes a fiber distribution hub (20, 300); at least one fiber distribution terminal (30, 100); and a cable (40) wrapped around a spool (110) of the fiber distribution terminal (30, 100). The fiber distribution terminal (30, 100) includes a spool (110) and a management tray (120) that rotate together. A second connectorized end (40b) of the cable (40) is held at a fiber optic adapter (125) on the tray (120). After dispensing the first connectorized end (40a) to the hub (20), an optical splitter (70, 130, 140) can be mounted to the tray (120). The splitter (26, 70, 130, 140, 306) has output adapters at which patch cords (50) can be inserted to connect subscribers to the system. The fiber distribution hub can use the same format of splitters (26, 70, 130, 140, 306). Other distributed splitter systems are provided with splicing and/or adding of splitters as needed.

Abstract: Example wall outlets include a base; a spool arrangement that mounts to the base; and a cable wound around the spool arrangement at the drum region. The base includes a mounting wall and a sidewall. The base defines a port and defines a first annular perimeter. The spool arrangement is rotatable relative to the base. The spool arrangement includes a drum region, a management region, and an aperture extending between the drum region and the management region. The drum region is enclosed by the sidewall of the base and the management region extends outwardly beyond the base. The cable has a first end extending through the aperture and terminated at a first fiber optic ferrule held at the management region. The cable also has a second end that extends through the port defined in the base and is terminated at a second fiber optic ferrule disposed external of the base.

Abstract: Cabling a terminal access cable through a residence includes optically coupling an end of a subscriber cable to a first end of a terminal access cable within a transition anchoring the terminal access cable to an anchor surface (202) formed as a flange surrounding the side walls (203) of the transition box with adhesive; storing excess length of the terminal access cable at a storage location (207) within the transition box; routing the terminal access cable from the transition box to a wall outlet box; anchoring the terminal access cable to an anchor surface of the wall outlet box with adhesive; and routing a second end of the terminal access cable into the wall outlet box and optically coupling the second end to a port of an optical adapter disposed within the wall outlet box. A jumper cable can be optically coupled to the subscriber cable by plugging a connectorized end of the jumper cable into the port.

Abstract: A closure (100) is configured to hold one or more termination arrangements (120) at which one or more connectorized ends of optical cables can be received. The closure (100) provides axial pull-out protection for the connectorized ends (142) of the optical cables (140). In certain implementations, the closure (100) provides axial pull-out protection for the connectorized ends (142) of optical cables (140) arranged in multiple layers within the closure (100). In certain implementations, the closure (100) provides axial pull-out protection for standard optical connectors (e.g., standard SC connectors, standard LC connectors, standard LX.5 connectors, standard MPO connectors, etc.). The axial pull-out protection can be in the form of a cover (130). Cable bend protection (136) may also be provided by the cover.

Abstract: Example fiber optic connector systems have rugged, robust designs that are environmentally sealed and that are relatively easy to install and uninstall in the field. Some connector systems can be configured in the field to be compatible with different styles of fiber optic adapters. Some connectors include a first seal (90) on a release sleeve; and a second seal (88) between the release sleeve and a connector body. Other connectors include a seal (139) and a flexible latch (136) on a connector. Other connectors include a protective structure (228, 328, 428) that mounts over the fiber optic connector. Other connectors include a protective outer shell (528, 860) and a sealing and attachment insert (570, 570A, 876). Other connectors include a protective outer shell (728) and a fastener (780).

Abstract: Example fiber optic connector systems have rugged, robust designs that are environmentally sealed and that are relatively easy to install and uninstall in the field. Some connector systems can be configured in the field to be compatible with different styles of fiber optic adapters. Some connectors include a first seal (90) on a release sleeve; and a second seal (88) between the release sleeve and a connector body. Other connectors include a seal (139) and a flexible latch (136) on a connector. Other connectors include a protective structure (228, 328, 428) that mounts over the fiber optic connector. Other connectors include a protective outer shell (528, 860) and a sealing and attachment insert (570, 570A, 876). Other connectors include a protective outer shell (728) and a fastener (780).

Abstract: A subscriber interface unit (60) can be installed by attaching a storage spool (120) to a wall using a fastener (180); deploying a pre-wound cable (50) from the storage spool (120) by turning the storage spool (120) about the fastener (180); and mounting the subscriber interface unit (60) on the storage spool (120). The storage spool (120) includes a drum portion (122) having a side wall (128) and a rear end wall (129). The rear end wall (129) defines a fastener opening (125) aligned with an axis of rotation of the spool (120). A flange portion (124) is coupled to a front end (121) of the drum portion (122). The spool (120) can define a slot (170) having a radial portion (170A) that extends though the flange portion (124) and an axial portion (170B) that extends through the side wall (128) of the drum portion (122).

Abstract: A fiber distribution terminal (30, 130, 230) including a housing (131, 231); and a spool arrangement (136, 236) that can rotate relative to the housing about an axis of rotation. The spool arrangement includes a drum portion (142, 242) centered on the axis of rotation and a flange (144, 146, 244, 246) that rotates with the drum portion about the axis of rotation. A fiber optic cable (40) is coiled on the drum portion. A fiber optic adapter (164, 264) and a connectorized pigtail (160, 260) are carried with the flange and positioned within the housing. The spool arrangement (136, 236) rotates relative to the housing when the fiber optic cable (40) is paid out. The drum portion (142, 242) can be removed from the flange after the fiber optic cable has been paid out to provide the distribution terminal with a compact configuration.

Abstract: A cable distribution system is provided wherein a feeder cable with one or more feeder fibers is received by a distribution terminal, device, or box. The feeder fibers are spliced to a feeder fan out device. Customers can directly connect to the feeder fan out device by patching between the feeder fan out device and a distribution fan out device that is spliced to a distribution cable. This connection creates a point-to-point connection. Alternatively, a splitter input can be connected to the feeder fan out device wherein the splitter splits the signal as desired into a plurality of outputs. The outputs of the splitters can be in the form of connectors or adapters. The connectors or adapters are then connected to the distribution fan out device, and customers can receive a split signal through the distribution cable that is spliced with the distribution fan out device.

Abstract: A cable distribution system is provided wherein a feeder cable with one or more feeder fibers is received by a distribution device or box. The feeder fibers are terminated to a fiber optic connector. Customers can directly connect to the connectors of the feeder cable through an adapter and a mating connector for a point-to-point connection. Alternatively, a splitter input can be connected to one or more of the connectors of the feeder cable, such as through a pigtail extending from the splitter, wherein the splitter splits the signal as desired into a plurality of outputs. The outputs of the splitters can be in the form of connectors or adapters. Customers can connect to the splitter outputs through a mating connector (and an adapter if needed).

Abstract: A fiber optic connector (12) is mounted to a fiber optic connector holder (14). The holder (14) can be a separate piece mountable to other devices, such as trays, panels, modules, cassettes, and chassis. Alternatively, the holder (14) can be integrally formed with the device. In some implementations, multiple holders (14) can be provided as separate elements, or as an integral element. The fiber optic connector holder (14) holds the fiber optic connector (12) in position ready for connection to another fiber optic connector (50) at a desired time. The holder (14) receives a fiber optic adapter (36), and a second fiber optic connector (50). The adapter (36) aligns the two connectors (12, 50) for fiber optic signal transmission. The fiber optic connector holder (14) includes a clip (26) for clipping to the first connector (12).

Abstract: Example fiber optic connector systems have rugged, robust designs that are environmentally sealed and that are relatively easy to install and uninstall in the field. Some connector systems can be configured in the field to be compatible with different styles of fiber optic adapters. Some connectors include a first seal (90) on a release sleeve; and a second seal (88) between the release sleeve and a connector body. Other connectors include a seal (139) and a flexible latch (136) on a connector. Other connectors include a protective structure (228, 328, 428) that mounts over the fiber optic connector. Other connectors include a protective outer shell (528, 860) and a sealing and attachment insert (570, 570A, 876). Other connectors include a protective outer shell (728) and a fastener (780).

Abstract: A fiber optic connector (12) is mounted to a fiber optic connector holder (14). The holder (14) can be a separate piece mountable to other devices, such as trays, panels, modules, cassettes, and chassis. Alternatively, the holder (14) can be integrally formed with the device. In some implementations, multiple holders (14) can be provided as separate elements, or as an integral element. The fiber optic connector holder (14) holds the fiber optic connector (12) in position ready for connection to another fiber optic connector (50) at a desired time. The holder (14) receives a fiber optic adapter (36), and a second fiber optic connector (50). The adapter (36) aligns the two connectors (12, 50) for fiber optic signal transmission. The fiber optic connector holder (14) includes a clip (26) for clipping to the first connector (12).

Abstract: A fiber distribution system (10) includes a fiber distribution hub (20, 300); at least one fiber distribution terminal (30, 100); and a cable (40) wrapped around a spool (110) of the fiber distribution terminal (30, 100). The fiber distribution terminal (30, 100) includes a spool (110) and a management tray (120) that rotate together. A second connectorized end (40b) of the cable (40) is held at a fiber optic adapter (125) on the tray (120). After dispensing the first connectorized end (40a) to the hub (20), an optical splitter (70, 130, 140) can be mounted to the tray (120). The splitter (26, 70, 130, 140, 306) has output adapters at which patch cords (50) can be inserted to connect subscribers to the system. The fiber distribution hub can use the same format of splitters (26, 70, 130, 140, 306). Other distributed splitter systems are provided with splicing and/or adding of splitters as needed.