A conduit is formed in a cable (10) having a plurality of wire bundles (12) by removing one or more of the centrally located bundles (12). A bundle (12) is removed by penetrating a wedge (14) into the bundle (12) and then pulling the pierced bundle (12) out of the cable (10). The bundle (12) is then engaged by wheels (18) of a device (17) and pulled out of the cable (10) thereby forming the conduit. The process is repeated dependent on the size of the cable (16) and the desired size of the conduit.

A continuous processing system and method for the continuous processing of an electrical conductor cable having aluminum strands encasing a steel core directly from a puller or from a puller and reel, simultaneously or on-the-fly during substantially the entirety of a reconductoring or re-stringing of the cable, wherein such cables are used for power lines or for static wires. The system is adapted to cooperate with a pulling machine. The pulling machine may be formed integrally within the system or may be a conventional pulling machine which cooperates with the system. The processing system runs continuously, substantially without interruption, during the pull of all of the cable from the pull zone of the reconductoring or restringing.

A connector assembly (10) is disclosed in which a connector part (12) and a cable manager part (20) are provided. The cable manager part (20) can be provided with a separable lacing fixture (24) that functions to retain the severed portions (6a) of the wires (6) that result from the termination process, rather than allowing the severed wire portions (6a) to fall to the floor in an uncollected state. In one aspect, the cable manager part (20) has a main body (22) to which the separable lacing fixture (24) is attached via a plurality of breakaway portions (34). During installation, the connector part (12) is inserted onto the cable manager part (20) and is placed in a wire termination tool (7) which fully inserts the connector part (12) onto the cable manager part (20). This action causes the connector part (12) to cut the wires (6) and to sever or break the breakaway portions (34) such that the separable lacing fixture (24) is separated from the fully formed connector (10).

A stripping apparatus and a stripping station capable of reducing cycle time for steps of stripping an insulation coating from a conducting wire material are provided. A stripping apparatus configured to strip an insulation coating WL from a conducting wire material W, including the insulation coating WL and cross-section of which orthogonal to a longitudinal direction has a rectangular shape, the stripping apparatus includes: an upper mold 150 provided with a stripping blade configured to strip the insulation coating WL; a lower mold 110 configured to support the conducting wire material W from a lower side thereof; a pressing member 130 configured to prevent displacement of the conducting wire material W; and a rotation mechanism configured to rotate the conducting wire material W around a rotational axis C1 that is parallel to a axial center of the conducting wire material W.

A peeling apparatus 1 includes a first peeling die and a second peeling die respectively including a pair of cutting blades 251 that peels the insulating film by being moved in a direction perpendicular to an axial direction of the conductive wire material 2 to cut the insulating film, and a support die 253 that supports a side surface of the conductive wire material 2 from a downstream side in a moving direction of the cutting blades 251 at the time of cutting by the cutting blades 251, the support die 253 of the first peeling die including a convex portion 2533 protruding toward the conductive wire material 2.

An improved bacterial oil treatment composition or pool for handling a decommissioned oil cable, which may be laid in particular as part of a power grid in the ground. The invention further relates to a bacteria growth culture medium containing the bacterial oil treatment composition for refurbishing an oil cable and a corresponding use.

A pneumatic stripping tool is provided. A top end of a main base is connected with an upper plate through screws; a middle part of a top end of the upper plate is connected with a handle through screws; one end of the upper plate is connected with a pneumatic-wrench fixing seat collar through screws; a pneumatic wrench is connected between the handle and the pneumatic-wrench fixing seat collar; the outer side of one end of the pneumatic wrench is connected with a power wrench sleeve; mounting holes are formed in portions of the main base which are corresponding to the power wrench sleeve; the inner side of one end of the power wrench sleeve is connected with a bottom wheel; and the bottom wheel extends into an inside of the mounting hole.

A continuous processing system and method for the continuous processing of an electrical conductor cable having aluminum strands encasing a steel core directly from a puller or from a puller and reel, simultaneously or on-the-fly during substantially the entirety of a reconductoring or re-stringing of the cable, wherein such cables are used for power lines or for static wires. The system is adapted to cooperate with a pulling machine. The pulling machine may be formed integrally within the system or may be a conventional pulling machine which cooperates with the system. The processing system runs continuously, substantially without interruption, during the pull of all of the cable from the pull zone of the reconductoring or restringing.

A connector assembly (10) is disclosed in which a connector part (12) and a cable manager part (20) are provided. The cable manager part (20) can be provided with a separable lacing fixture (24) that functions to retain the severed portions (6a) of the wires (6) that result from the termination process, rather than allowing the severed wire portions (6a) to fall to the floor in an uncollected state. In one aspect, the cable manager part (20) has a main body (22) to which the separable lacing fixture (24) is attached via a plurality of breakaway portions (34). During installation, the connector part (12) is inserted onto the cable manager part (20) and is placed in a wire termination tool (7) which fully inserts the connector part (12) onto the cable manager part (20). This action causes the connector part (12) to cut the wires (6) and to sever or break the breakaway portions (34) such that the separable lacing fixture (24) is separated from the fully formed connector (10).

A peeling apparatus 1 includes a first peeling die and a second peeling die respectively including a pair of cutting blades 251 that peels the insulating film by being moved in a direction perpendicular to an axial direction of the conductive wire material 2 to cut the insulating film, and a support die 253 that supports a side surface of the conductive wire material 2 from a downstream side in a moving direction of the cutting blades 251 at the time of cutting by the cutting blades 251, the support die 253 of the first peeling die including a convex portion 2533 protruding toward the conductive wire material 2.