An undersea connection system for connecting together at least three high voltage or very high voltage undersea electric cables comprises an outer cage defining a connection space; and a connection fitting comprising a conductive connection electrode that presents a junction node from which there extend at least three branches. Each of the at least three branches of the conductive electrode includes a male terminal portion that is connected to a respective one of the electric cables in a connection zone about which there is mounted a connection sleeve made of pre-molded insulating material that receives, via its ends, firstly the male terminal portion of one of the branches of the conductive electrode, and secondly the connection end of one of the electric cables.

A cable has a corrugated armor exterior surface, and a split bushing defines an interior surface which conforms to the corrugated exterior surface. The bushing is split radially in one place to form a gap which may be opened to allow the bushing to open, or the bushing is split radially at two or more places to form two or more parts, and is fitted about the corrugated exterior surface. The bushing defines first and second external chamfer surfaces. A connector includes a body having external threads and a chamfer which urges against the first bushing chamfer. A nut has internal threads which engage the external threads of the body, and a chamfer which urges against the second bushing chamfer. As the nut is tightened onto the body, wedge action on the first and second bushing chamfers compresses the bushing around the corrugated exterior surface to secure the connector to the cable.

An undersea connection system for connecting together at least three high voltage or very high voltage undersea electric cables comprises an outer cage defining a connection space; and a connection fitting comprising a conductive connection electrode that presents a junction node from which there extend at least three branches. Each of the at least three branches of the conductive electrode includes a male terminal portion that is connected to a respective one of the electric cables in a connection zone about which there is mounted a connection sleeve made of pre-molded insulating material that receives, via its ends, firstly the male terminal portion of one of the branches of the conductive electrode, and secondly the connection end of one of the electric cables.

An undersea connection system for connecting together at least three high voltage or very high voltage undersea electric cables comprises an outer cage defining a connection space; and a connection fitting comprising a conductive connection electrode that presents a junction node from which there extend at least three branches. Each of the at least three branches of the conductive electrode includes a male terminal portion that is connected to a respective one of the electric cables in a connection zone about which there is mounted a connection sleeve made of pre-molded insulating material that receives, via its ends, firstly the male terminal portion of one of the branches of the conductive electrode, and secondly the connection end of one of the electric cables.

A covering processing tool performs a covering process of a cable connection portion and is provided with a first tubular unit extending in an axial direction, a second tubular unit disposed so as to surround the first tubular unit on an outer peripheral side, and a third tubular unit disposed so as to surround the first tubular unit on the outer peripheral side. The second tubular unit is installed on the first tubular unit so when extracting a first diameter expansion holding member of the first tubular unit, by supporting the second tubular unit from an outer peripheral side, relative movement in an axial direction and a circumferential direction of the first tubular unit relative to the second tubular unit is suppressed.

A covering processing tool performs a covering process of a cable connection portion and is provided with a first tubular unit extending in an axial direction, a second tubular unit disposed so as to surround the first tubular unit on an outer peripheral side, and a third tubular unit disposed so as to surround the first tubular unit on the outer peripheral side. The second tubular unit is installed on the first tubular unit so when extracting a first diameter expansion holding member of the first tubular unit, by supporting the second tubular unit from an outer peripheral side, relative movement in an axial direction and a circumferential direction of the first tubular unit relative to the second tubular unit is suppressed.

A shield for spliced electrical connections includes a cover for T-tap electrical connections. In embodiments, the cover includes complementary halves designed to quickly and securely snap together when the halves are mated with each other to create a shield for a T-tap connection. Fully assembled, the shield provides sleeves that allow the cables being spliced to enter and/or exit the shield. Each of the sleeves is provided with an adhesive sealant that tightly seals the shield against contamination from the elements. Integrated with the cover are structural elements such as gussets that enhance the resistance of the shield to impact damage such as crushing. The shield may be molded from a polymer that, when cured, provides a rigid or semi-rigid cover that generally protects the t-tap connection from all types of environmental damage.

A shield for spliced electrical connections includes a cover for T-tap electrical connections. In embodiments, the cover includes complementary halves designed to quickly and securely snap together when the halves are mated with each other to create a shield for a T-tap connection. Fully assembled, the shield provides sleeves that allow the cables being spliced to enter and/or exit the shield. Each of the sleeves is provided with an adhesive sealant that tightly seals the shield against contamination from the elements. Integrated with the cover are structural elements such as gussets that enhance the resistance of the shield to impact damage such as crushing. The shield may be molded from a polymer that, when cured, provides a rigid or semi-rigid cover that generally protects the t-tap connection from all types of environmental damage.

A cable has a corrugated armor exterior surface, and a split bushing defines an interior surface which conforms to the corrugated exterior surface. The bushing is split radially in one place to form a gap which may be opened to allow the bushing to open, or the bushing is split radially at two or more places to form two or more parts, and is fitted about the corrugated exterior surface. The bushing defines first and second external chamfer surfaces. A connector includes a body having external threads and a chamfer which urges against the first bushing chamfer. A nut has internal threads which engage the external threads of the body, and a chamfer which urges against the second bushing chamfer. As the nut is tightened onto the body, wedge action on the first and second bushing chamfers compresses the bushing around the corrugated exterior surface to secure the connector to the cable.

A splice device for electromagnetically sealing a junction or bond between a plurality of cables is provided. A first and second cable each has a conductive core wire, an inner insulation, a braided sleeve, and an insulating cover. The junction or bond fixes and electrically connects the core wire of the second cable to the core wire of the first cable. A plurality of ferrules overlays the braided sleeve and the insulating cover of the first cable and the braided sleeve and the insulating cover of the second cable. A plurality of ring collars overlays the plurality of ferrules and is fixed to the plurality of ferrules. A splice cover or shield overlays the first cable, second cable, plurality of ferrules, and plurality of ring collars and electromagnetically seals the junction/bond between the core wires of the first cable and the second cable.