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 rugged information and communication system closure for outdoor installation and a method for assembling the same are provided. The closure includes an outer housing, a circuit device, a splice tray, a cable stub, and an epoxy filler. The outer housing includes a plurality of mounts configured to support the circuit device and the splice tray. The circuit device is mounted in the outer housing and includes internal circuitry, a first plurality of fibers connected to the internal circuitry, and a housing enclosing the internal circuitry. The splice tray is mounted over the circuit device and supports the first plurality of fibers. The cable stub extends through the outer housing and includes a second plurality of fibers spliced to the first plurality of fibers to form a splice. The splice is positioned on the splice tray. The epoxy filler occupies any remaining space of the outer housing to protect the circuit device and fibers from outside plant conditions.

Disclosed herein are cable sealing devices having features for enhancing effective sealing, volume compensation, seal pressurization, cable size range-taking, cable installation and insert installation. Also disclosed herein is an enclosure including at least one cable sealing device.

Holders that anchor sheaths containing optical fibers. The holders include various anchoring and placement features for the sheaths held by the holders. In some examples, a labyrinthine passage is provided to secure the sheaths within the holder. In some examples, the holder includes a twist-to-anchor mechanism. In some examples, the holder includes a narrow and expandable lateral entry slot for sheaths that is in communication with a wide sheath holding volume.

A cable enclosure assembly having a receiving area configured to alternatively receive a cable retainer and a cable adapter so as to permit an opening of the cable enclosure assembly to be alternatively configured as a cable pass through and an adapter port, includes: a base; a receiving area in the base. The receiving area is configured to receive a cable retainer that comprises a first portion and a second portion connected by a pivot portion; the cable retainer comprises a first exterior surface and a second exterior surface that are configured to contact the receiving area; the receiving area is configured to receive a cable adapter; and the receiving area is configured to alternatively receive the cable retainer and the cable adapter so as to permit an opening of the cable enclosure assembly to be alternatively configured as a cable pass through and an adapter port.

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. The connectors or adapters are then connected to tails of drop splice modules that are spliced to individual distribution cables so that customers can receive a split signal. The cable distribution system allows for mixing of connection types to the customer(s) such as a direct connection (point-to-point), or a split signal connection. Further, the types of splitters can be mixed and varied as desired. Further, the types of fan out devices can be mixed and varied as desired.

A cable port seal is provided including an upper and lower elements for cables to pass and be compressed therebetween to provide a environmental barrier. The upper or lower elements include a first sealing member having a first face, an opposing second face, and a first sealing edge with a first and second ends, the first sealing edge including first cable cutouts disposed proximate to each of the first and second ends of the first sealing member, a second sealing member having a third face, an opposing fourth face, and a second sealing edge with a first and second ends, the second sealing edge including at least one second cable cutout disposed proximate to each of the first end and the second end of the second sealing member, and at least one third cable cutout disposed between each of the at least one second cable cutouts.

An enclosure for accommodating splicing between cables is disclosed. The enclosure can include a housing containing a frame (e.g., a tray) to which the cables can be affixed. The housing can have an elongate in-line configuration, a triangular configuration, or other configurations. Cable reversing configurations and moveable adapter configurations are also disclosed.

Aspects and techniques of the present disclosure relate to an enclosure including a housing, a volume of sealant that defines a port in communication with an interior of the housing, and a fiber optic connection module including a sleeve that mounts within the port with the volume of sealant forming a seal about an exterior of the sleeve. The sleeve includes an inner end adjacent the interior of the housing and an outer end outside the housing. The fiber optic connection module also includes a demateable fiber optic connection interface adjacent the outer end of the sleeve. The demateable fiber optic connection interface includes a fiber optic connector. Other aspects of the present disclosure relate to fiber optic connection modules having features that make such modules suitable to be mounted within a port defined by a volume of sealant.

A telecommunications cable fixation and sealing system (14) includes a telecommunications cable (18) including a jacket defining a jacket perimeter having a generally non-circular transverse cross-section and an adapter tube (26) slidably placed over the jacket of the telecommunications cable (18), the adapter tube (26) defining a tube perimeter (28) having a generally circular transverse cross-section and defining a throughhole (30) having a generally non-circular transverse cross-section that is configured to receive the telecommunications cable (18).