Clamp and Bending Strain Relief (BSR) system and method are disclosed. One example of a system can include a clamp coupled to a cable. The clamp is configured to couple an apparatus to the cable while allowing the cable to pass continuously through the clamp. A BSR apparatus is coupled to the clamp and the cable by a housing.

A power cable and filler device adapted to bear against a first and second power cores in a power cable, including a first arced wall which defines a portion of a first circle having a first diameter, a second and third arced wall, each defining a portion of a second circle having a second diameter which is smaller than the first diameter. A chamber is formed between the first, second and third arced walls.

A power cable and filler device adapted to bear against a first and second power cores in a power cable, including a first arced wall which defines a portion of a first circle having a first diameter, a second and third arced wall, each defining a portion of a second circle having a second diameter which is smaller than the first diameter. A chamber is formed between the first, second and third arced walls.

Novel tools and techniques are provided for implementing MediaLink Interconnection Boxes (“MIBs”). In some embodiments, a plurality of MediaLink Interconnection Boxes (“MIBs”) or media interconnection devices, which may be disposed throughout a recreational vehicle (“RV”) park or other bulk service provider application sites, or the like, may serve as demarcation units designed to each provide an accessible indoor or outdoor interface where long-term or temporary/transient customers can directly connect to land line service (e.g., POTS service), video or television service, and/or Ethernet or Internet services provided by one or more service providers. Fiber-to-Drop-Point (“FTDP”) and/or point-to-point fiber insertion within a passive optical network (“PON”) communications system may be implemented using apical conduit systems in conjunction with the MIBs. Alternatively, traditional ground-based or buried line interconnections (or a combination of the apical conduit system and such traditional interconnections) may be implemented in conjunction with the MIBs.

Novel tools and techniques are provided for implementing MediaLink Interconnection Boxes (“MIBs”). In some embodiments, a plurality of MediaLink Interconnection Boxes (“MIBs”) or media interconnection devices, which may be disposed throughout a recreational vehicle (“RV”) park or other bulk service provider application sites, or the like, may serve as demarcation units designed to each provide an accessible indoor or outdoor interface where long-term or temporary/transient customers can directly connect to land line service (e.g., POTS service), video or television service, and/or Ethernet or Internet services provided by one or more service providers. Fiber-to-Drop-Point (“FTDP”) and/or point-to-point fiber insertion within a passive optical network (“PON”) communications system may be implemented using apical conduit systems in conjunction with the MIBs. Alternatively, traditional ground-based or buried line interconnections (or a combination of the apical conduit system and such traditional interconnections) may be implemented in conjunction with the MIBs.

An enclosure for breaking out a trunk cable includes: a base having a generally flat surface adapted for mounting to a mounting surface; a shell having a front and two side walls extending from opposite sides of the front and two opposed end walls, the side walls of the shell mounted to the base to form a cavity; a plurality of connectors mounted to each of the side walls; and a trunk cable routed into the cavity through one of the end walls, the trunk cable comprising a plurality of power conductors and/or a plurality of optical fibers. The power conductors and the optical fibers are connected with respective ones of the plurality of connectors.

An enclosure for breaking out a trunk cable includes: a base having a generally flat surface adapted for mounting to a mounting surface; a shell having a front and two side walls extending from opposite sides of the front and two opposed end walls, the side walls of the shell mounted to the base to form a cavity; a plurality of connectors mounted to each of the side walls; and a trunk cable routed into the cavity through one of the end walls, the trunk cable comprising a plurality of power conductors and/or a plurality of optical fibers. The power conductors and the optical fibers are connected with respective ones of the plurality of connectors.

An in-ground electrical transformer trough, supporting a transformer pad is a non-conductive composite vault located below a transformer pad to provide for better access to a molded cavity below the transformer and pad to prevent access by animals, to enhance wire mobility to make it easier to switch or terminate insider the transformer, with the new design of the new bell designed at the bottom of the trough preventing floating, lift or rise after installation and to allow additional pipes, conduits and wires to be installed in the future, wherein the trough is installed prior to the installation of the ground pad and transformer to be set stable within the soil, with the transformer pad poured around the rim of the trough, further preventing slant or misplacement of the transformer and pad and providing a more solid mounting upon the ground surface without future sinking, tilt or slant.

An in-ground electrical transformer trough, supporting a transformer pad is a non-conductive composite vault located below a transformer pad to provide for better access to a molded cavity below the transformer and pad to prevent access by animals, to enhance wire mobility to make it easier to switch or terminate insider the transformer, with the new design of the new bell designed at the bottom of the trough preventing floating, lift or rise after installation and to allow additional pipes, conduits and wires to be installed in the future, wherein the trough is installed prior to the installation of the ground pad and transformer to be set stable within the soil, with the transformer pad poured around the rim of the trough, further preventing slant or misplacement of the transformer and pad and providing a more solid mounting upon the ground surface without future sinking, tilt or slant.

Provided is a cable hang-off arrangement configured for mounting at the level of an elevated platform of an offshore facility and includes a pipe configured to accommodate a number of protective tubes, wherein a protective tube is configured to accommodate a transmission cable of the offshore facility; a tube end flange arranged around an end portion of each protective tube; and a hang-off terminator configured for mounting at an end of the pipe, which hang-off terminator includes an end-plate with a number of apertures for the transmission cables, and a flange connection interface for connecting to the tube end flanges. An offshore facility, and a method of securing a transmission cable arrangement at the level of an elevated platform of an offshore facility are also provided.