A method is provided for preparing an uncovered insulation layer surface of an end section of a cable using optical profilometry, the uncovered insulation layer surface having an advantageous low roughness, a method for jointing two cables. A method is also provided for preparing a termination assembly on a cable, a cable end, a joint and a termination assembly.

A method is provided for preparing an uncovered insulation layer surface of an end section of a cable using optical profilometry, the uncovered insulation layer surface having an advantageous low roughness, a method for jointing two cables. A method is also provided for preparing a termination assembly on a cable, a cable end, a joint and a termination assembly.

A method is provided for preparing an uncovered insulation layer surface of an end section of a cable. The uncovered insulation layer surface has an advantageous low roughness. A method is also provided for jointing two cables, and for preparing a termination assembly on a cable, a cable end, a joint, and a termination assembly.

A method is provided for preparing an uncovered insulation layer surface of an end section of a cable. The uncovered insulation layer surface has an advantageous low roughness. A method is also provided for jointing two cables, and for preparing a termination assembly on a cable, a cable end, a joint, and a termination assembly.

An electrical conductor comprising a flat conductor formed of a solid metallic material, the flat conductor having at least two opposite broad sides, two opposite narrow sides and two opposite end sides and having an at least quadrangular cross-sectional profile, and a flexible conductor formed of a plurality of strands, the strands of the flexible conductor being at least partially joined to one another in a materially bonded manner in the region of at least one end of the flexible conductor, characterized in that the flexible conductor, at its end with the joined strands, is joined in a materially bonded manner with its end face to an end face, a narrow side or broad side of the flat conductor.

A wire processing system includes a tray having at least one tray surface configured to sequentially receive a first wire and a second wire from a wire feed system of a wire processing machine. The tray surface has a surface feature configured to provide a wire-to-surface coefficient of friction between the tray surface and the first wire higher than a wire-to-wire coefficient of friction between the first wire and the second wire laying on top of the first wire. The wire-to-surface coefficient of friction reduces movement of at least a portion of the first wire relative to the tray surface during movement of the second wire relative to the first wire.

A high-voltage cable sealing end (100) has a primary volume (102) and a secondary volume (104) fluidically connected thereto, which are filled with an insulating fluid. The primary volume (102) and the secondary volume (104) are sealed with respect to the atmosphere surrounding the high-voltage cable sealing end (100). The secondary volume (104) can be disconnected from the primary volume (102) via a separable connection (106) which can be cut off in a fluid-tight manner. A drying agent, which draws moisture out of the insulating fluid, is introduced into the secondary volume (104).

A high-voltage cable sealing end (100) has a primary volume (102) and a secondary volume (104) fluidically connected thereto, which are filled with an insulating fluid. The primary volume (102) and the secondary volume (104) are sealed with respect to the atmosphere surrounding the high-voltage cable sealing end (100). The secondary volume (104) can be disconnected from the primary volume (102) via a separable connection (106) which can be cut off in a fluid-tight manner. A drying agent, which draws moisture out of the insulating fluid, is introduced into the secondary volume (104).

A technique facilitates forming couplings along a power cable used, for example, to supply power to an electric submersible pumping system. In coupling the power cable to the electric submersible pumping system, a pothead may be provided with individual pothead bodies connected to individual conductors of the power cable. The pothead bodies are held with respect to each other by a plate structure which may be readily secured to a submersible motor of the electric submersible pumping system. If splices are formed along the power cable, individual potheads may be secured to conductor ends of the sections of power cable. The conductor ends are then inserted into corresponding individual adapters in a manner forming a secure and sealed connection.

The present disclosure relates to the technical field of cable processing, and discloses a method for processing a reaction force cone of a cable main insulating layer. The method includes: two ends of a cable are clamped through a clamping device, and the cable is enabled to pass through a cutting device; a cutting depth of the cutting device in a radial direction and a cutting position of the cutting device in an axial direction are adjusted; the cutting device is started, and the cable is cut by the cutting device to form the reaction force cone.