Disclosed is a TMS for an optical fiber remote control submersible, including an upper cylinder equipped with a counterweight and a lower cylinder equipped with a buoy; the upper cylinder and the lower cylinder are sleeved with each other, and matched electromagnets and iron plates are respectively installed in the two parts; the upper cylinder is connected with a mother ship through a light armoured optical power cable, and the light armoured optical power cable may provide electric power for the electromagnets, and the lower cylinder is connected with a submersible through a light load-bearing optical fiber cable; and an end of the light armoured optical power cable inside the upper cylinder is optically connected with an end of the light load-bearing optical fiber cable inside the lower cylinder.

An end closure for a cable having a core, at least two electrical cable wires and at least one optical transmission element, the core is surrounded by a metal wire reinforcement. On the end of the electrical cable wires an electrically suitable connection set is mounted, which at least partially protrudes out of a pipe. A connection unit is mounted on the end of the optical transmission element, which also partially protrudes from the pipe. The connection unit has a pot shaped tension element mounted tension proof on the free end of the pipe and surrounds, moisture tight and pressure tight, the part of the connection set and the connection unit that protrudes out of the pipe.

The present invention discloses a logging encapsulated optical-fiber duct cable and a manufacturing method thereof. The encapsulated optical-fiber duct cable mainly comprises an external encapsulation layer. At least one armor tube is arranged in the encapsulation layer. An optical fiber protective tube is arranged in each armor tube. A filling layer is arranged in a space between the optical fiber protective tube and the armor tube. An optical fiber is arranged in the optical fiber protective tube. The manufacturing method mainly comprises four steps: pavement of the optical fiber and formation of the protective tube, formation of the filling layer, formation of the armor tube and formation of the encapsulation layer. The optical-fiber duct cable of the present invention has the advantages of large length, high strength, good temperature tolerance, small signal transmission loss, high transmission speed and synchronous transmission of multiple signals.

A submarine device includes a main tail cable connected to a submarine cable, a first branch tail cable including a first group of optical fibers among a plurality of optical fibers included in the main tail cable, a second branch tail cable including a second group of optical fibers among the plurality of optical fibers, a branch member that couples the main tail cable to the first and second branch tail cables and including therein a through hole for branching the plurality of optical fibers included in the main tail cable into the first group and the second group, and a device main body including a first introduction part for introducing the first branch tail cable into the device main body and a second introduction part for introducing the second branch tail cable into the device main body. The branch member is fixed to the device main body.

An automated system for coiling a large (e.g., >1000 km) length of cable in a cable tank. In an example embodiment, the system comprises a gantry positioned above the cable tank and a swarm of robots deployed on the floor of the tank. The gantry operates to controllably move a touchdown point of the cable, which is being fed into the tank by a cable engine. Each of the robots is equipped with a rake that can be used to push or pull downed sections of the cable on the floor of the tank. An electronic controller operates to control the speed of the cable engine and movements of the gantry and individual robots to coil the cable in the tank in spirally wound, vertically stacked layers. Different embodiments of the system may be used for cable coiling at the cable factory and on the deck of a cable-laying ship.

The present invention provides an epoxy-less optical fiber termination. More specifically, the present invention provides an epoxy-less optical fiber termination comprising a waveguide termination having an optical fiber spliced to a stub protruding from the waveguide termination and having a strain relief disposed about the stub and the optical fiber. Additionally, the strain relief may be filled with an epoxy fill to provide additional support to the optical fiber. The present invention may be used to terminate an optical fiber joining devices in an optical communications network.

Systems and methods are provided for applying a protective graphene barrier to waveguides and using the protected waveguides in wellbore applications. A well monitoring system may comprise a waveguide comprising a graphene barrier, wherein the graphene barrier comprises at least one material selected from the group consisting of graphene, graphene oxide, and any combination thereof; a signal generator capable of generating a signal that travels through the waveguide; and a signal detector capable of detecting a signal that travels through the waveguide.

Tubing encapsulated cable consists of one or more electrical conductors and possibly one or more fiber optic cables sheathed in a corrosion resistant metallic alloy. However, pumping during the installation of tubing encapsulated cable is required to overcome the capstan effect of the tubing encapsulate cable inside the coil tubing as the tubing encapsulated cable travels through the coiled up wraps of coil tubing. In an embodiment of the invention the tubing encapsulated cable consists of one or more electrical conductors and possibly one or more fiber optic cables sheathed in a fiber reinforced composite sheath. Because there is little drag between the fiber encapsulated cable and the coil tubing, conventional pumping operations used to install braided wireline into coil tubing may not be required when installing fiber encapsulated cable into coil tubing. Additionally, the smooth outside surface and relatively small diameter of the fiber encapsulated cable are desirable attributes for well intervention work because the smooth surface is more resistant to chemical attack than braided wire while the smooth surface and relatively small diameter provide little viscous drag while fluids are pumped through the coil tubing in the course of intervention operations.

A cable (10) includes a cable body (11) that is formed from a plurality of wires (14) that are integrally bundled; and a pair of sockets (12) to which both end portions of the cable body (11) is separately affixed; at least one of the plurality of wires (14) being a fiber-containing wire (16), which is formed by an optical fiber (17) that extends in a cable length direction (D) and that is protected by a protective tube (18); wherein the optical fiber (17) protrudes from the protective tube (18), in the cable length direction, further outside than the socket (12); and each of the pair of sockets (12) is provided with a spool (30) that removably holds the optical fiber (17) and imparts an initial tensile strain to the optical fiber (17).

A terminal connector or two-part connector comprising male and female parts having respective contact pins and contact receivers (10,15) of a construction generally known in the art. In the body (1) of the or at least one part, closely juxtaposed a terminal block (9), there is provided a conductor management device (8) adapted to receive conductors (12) as they are unbundled from the connected cable or reel and support the unbundled or individual conductors through the transitional region of the connector part to where they are secured at the terminal block (9). The conductor management device (8) has through body apertures defining each conductor path (14) to align each conductor with its respective receiver (13). In a different configuration, the conductor management device provides strain relief to the conductors, provides support and conductor rigidity, provides a locking means and is a bore modifier.