An improved deepwater optical fiber cable with abrasion protection and techniques for manufacturing the same are provided. For example, the abrasion protected deepwater cable may be a modification or enhancement of an existing special application (SPA) optical fiber cable. One or more additional layers of metallic tape and jackets may be added to the outermost layer of the SPA cable. The tape and jacket layers may have different thicknesses and may be made from different materials to optimize protection against man-made objects or otherwise naturally occurring materials in deep water environments, such as fish aggregation devices (FADs).

A fiber optic connector includes a ferrule, a ferrule adapter configured to be coupled with the ferrule, and a retention body configured to be coupled with a multi-fiber cable. The ferrule is configured to terminate a plurality of fibers of a multi-fiber cable and is configured with a cross-sectional profile smaller than a ferrule of a multi-fiber push on (MPO) connector such that the ferrule is configured to be pushed through a duct having an inside diameter smaller than a cross-sectional profile of the ferrule of the MPO connector. The ferrule adapter and the ferrule cooperate to define a ferrule interface configured to mate with ferrule of the MPO connector. The ferrule is configured to include external channels at opposing laterals sides of the ferrule. The ferrule adapter is configured to include channels that oppose the external channels of the ferrule. The channels of the ferrule adapter and the external channels of the ferrule are configured to cooperate to define a pair of bores configured to receive a pair of external pins. The bores are configured to receive a pair of pins from the mating MPO connector.

A system that may be used for deploying optical cables, the system may include a track having an outer edge and a surface, the track having a track gear disposed proximate the outer edge and a plurality of track grooves disposed on the surface of the track. The system may also include a spool having a first outer edge and a second outer edge. The spool may include a first wheel disposed on the first outer edge, a second wheel disposed on the second outer edge, a spool gear disposed on the first wheel and interfacing with the track gear, plurality of spool grooves, and a plurality of guides interfacing with the track to align the track grooves with the spool grooves.

A wall-mounted enclosure having a standard forward-facing opening but also having an expanded enclosure behind the opening. The opening allows the use of conventional prior art components (such as cover plates). The expanded enclosure allows a more generous bend radius for the creation of a service loop in a fiber optic cable or similar component.

Devices, systems and methods to prevent damage to power and communication conductors located in cold occurring regions, with an elongated cylindrical tubular assembly of closed cell foam within a braided/woven layer that can be sealed to provide longitudinal strength and a snag resistant durable and flexible outer coating. The assembly along with communication and power lines is pulled through new power and communication ducts and conduits and in retrofitting existing power and communication ducts, so that the assembly reduces the volume spacing in the ducts/conduits that can be damaged by water intrusion which expands during freeze conditions.

Embodiments of an optical fiber cable configured for installation in a roadbed are provided. The optical fiber cable includes an optical fiber, a cable jacket surrounding the optical fiber, and an upjacket surrounding the cable jacket. The upjacket does not leach a chemical or chemicals into the roadbed that soften the roadbed. Also provided are embodiments of a method of producing an optical fiber cable configured for installation in a roadbed. Further, embodiments of a method of deploying an optical fiber cable into a roadbed are provided. The method involves the steps of forming a channel in the roadbed, inserting an optical fiber cable into the channel, and closing the channel so as to bury the optical fiber cable in the roadbed.

Embodiments of an optical fiber cable configured for installation in a roadbed are provided. The optical fiber cable includes an optical fiber, a cable jacket surrounding the optical fiber, and an upjacket surrounding the cable jacket. The upjacket does not leach a chemical or chemicals into the roadbed that soften the roadbed. Also provided are embodiments of a method of producing an optical fiber cable configured for installation in a roadbed. Further, embodiments of a method of deploying an optical fiber cable into a roadbed are provided. The method involves the steps of forming a channel in the roadbed, inserting an optical fiber cable into the channel, and closing the channel so as to bury the optical fiber cable in the roadbed.

Tools and associated methods for facilitating feeding of optical fibers into a tube. In particular, the tools and associated methods are adapted to remove overlaps and tangles in the fibers as they are being fed into the tube. In this way, the number of fibers that can be fed into a tube of given transverse cross-sectional area can be maximized.

A method of cutting a microtrench in which the buried utility is exposed by opening an access hole in a roadway above the buried utility using a roadway access hole drill that is controlled by a computer system connected to an under-roadway detection unit that detects a buried utility and stops movement of the drill to avoid damaging the buried utility. Also provided is a method of drilling a substantially horizontal hole under a roadway using a horizontal drill that is controlled by a computer system connected to an under-roadway detection unit that detects a buried utility and stops movement or changes direction of the drill to avoid damaging the buried utility.

The present disclosure relates to a connector device for optical fiber configured to allow the transmission of an optical signal at a terminal end of the fiber in a cabling condition. The device comprises a portion of optical fiber having a ferrule at at least one terminal end, a ferrule holder element and a protective element for the optical fiber. The overall configuration is such that the connector device has small radial and longitudinal dimensions which, in an operating condition, allow rapid movement within wiring cables or tubular ducts, for example cable ducts, pipes, conduits etc., which due to their sizes, hinder the passage of standard connectors of known type.