Abstract: A conductive water blocking material and an optical fiber cable and method of constructing an optical fiber cable including the same. The cable includes at least one optical fiber and strength members disposed around the fiber. A conductor is disposed around the strength members. The conductive water blocking material includes a carrier material and conductive metallic particles and is provided in strength member interstices defined by the strength members.

Abstract: A conductive water blocking material and an optical fiber cable and method of constructing an optical fiber cable including the same. The cable includes at least one optical fiber and strength members disposed around the fiber. A conductor is disposed around the strength members. The conductive water blocking material includes a carrier material and conductive metallic particles and is provided in strength member interstices defined by the strength members.

Abstract: A multiple conductor optical cable may be coupled to an undersea device, such as a cable joint, branching unit, or repeater, with one or more isolated bypass conductive paths being provided across the undersea device. At least one conductor may be terminated within a housing of the undersea device and at least one conductor may be coupled to a conductive bridge member that provides the isolated bypass conductive path across the device. Multiple conductor optical cables may be coupled to undersea devices in optical networks using independent power paths, for example, to deliver power to different powered components at different voltage potentials.

Abstract: A multiple conductor optical cable may be coupled to an undersea device, such as a cable joint, branching unit, or repeater, with one or more isolated bypass conductive paths being provided across the undersea device. At least one conductor may be terminated within a housing of the undersea device and at least one conductor may be coupled to a conductive bridge member that provides the isolated bypass conductive path across the device. Multiple conductor optical cables may be coupled to undersea devices in optical networks using independent power paths, for example, to deliver power to different powered components at different voltage potentials.

Abstract: A multiple conductor optical cable may be coupled to an undersea device, such as a cable joint, branching unit, or repeater, with one or more isolated bypass conductive paths being provided across the undersea device. At least one conductor may be terminated within a housing of the undersea device and at least one conductor may be coupled to a conductive bridge member that provides the isolated bypass conductive path across the device. Multiple conductor optical cables may be coupled to undersea devices in optical networks using independent power paths, for example, to deliver power to different powered components at different voltage potentials.

Abstract: An undersea equipment housing includes an inner housing, molded terminations secured at each end of the inner housing, and an outer strength housing. In one embodiment, the housing is used to house optical and electrical equipment, for example, in a repeater. The undersea equipment housing may also include a molded portion around an inside of the inner housing. The molded portion and the molded terminations provide voltage isolation.

Abstract: An apparatus for retaining and protecting spliced optical fibers that are part of cables that have ultra-high strength steel wires, in which the optical fibers are free to move within a sleeve inside of the wires. The apparatus includes ajoint box having opposing longitudinal cable termination ends. The high-strength steel wires of each cable are attached to a respective cable termination end. At least one optical fiber from each cable extends through its respective cable termination end and is spliced together to form a continuous optical fiber. The fiber or fibers are splinted and potted at locations longitudinally spaced from the splice to form ferrules. A central portion or shelf of the joint box includes fiber retaining devices which take the form of ferrule retainer assemblies. The ferrule retainer assemblies have a trough that contains and restrains a respective ferrule.

Abstract: An apparatus for retaining and protecting spliced optical fibers that are part of cables that have ultra-high strength steel wires, in which the optical fibers are free to move within a sleeve inside of the wires. The apparatus includes a joint box having opposing longitudinal cable termination ends. The high-strength steel wires of each cable are attached to a respective cable termination end. At least one optical fiber from each cable extends through its respective cable termination end and is spliced together to form a continuous optical fiber. The fiber or fibers are restrained at locations on the continuous optical fiber spaced from the splice by winding portions of the fibers around a friction imparting element, such as a drum, that includes a curved outer surface. Tension forces applied to the fiber or fibers are transferred to the drum.

Abstract: A cable ship is outfitted with an improved dynamometer including a multi-roller sheave which is positioned between an optical fiber cable, supply and the cable destination so that the cable rolls over the multi-roller sheave. The center axis of the cable changes direction from one side of the multi-roller sheave to the other side. When the ship is propelled and pulls the cable, tension in the cable causes the multi-roller sheave to move and consequently stress a strain gauge. A signal produced by the strain gauge accurately indicates the tension in the cable. Friction and wear between the cable and the dynamometer are eliminated for all practical purposes. Very accurate readings of tension are obtained.

Abstract: In a dynamometer, a multi-roller sheave is positioned between a cable, or other elongate element, supply and the cable destination so that the cable rolls over the multi-roller sheave. The center axis of the cable changes direction from one side of the multi-roller sheave to the other side. Tension in the cable causes the multi-roller sheave to move and consequently stress a strain gauge. A signal produced by the strain gauge is amplified into a signal that accurately indicates the tension in the cable. Friction and wear between the cable and the dynamometer are eliminated for all practical purposes. Very accurate readings of tension are obtained.