An assembly for use with an oil-filled cable termination includes a cable gland, a cable received in the cable gland, and a stress cone received around the cable and spaced apart from the cable gland. The cable includes a central conductor and a polymeric insulation layer surrounding the central conductor. A lug is spaced apart from the stress cone and includes a barrel portion with the central conductor of the cable received in the barrel portion. An oil barrier system including an oil barrier layer surrounds the polymeric insulation layer of the cable between the stress cone and the lug.

A telecommunications enclosure is provided with reliable sealing around cables entering therein. The enclosure includes one or more cable ports with cable seals made from a material that includes an oil-bleed silicone rubber. The cable ports may also have a convoluted or serrated inner surface configured to engage and support the cable seals.

A hand-held apparatus for repairing a defect in an outer jacket of an elongated wire or cable includes a portable die and a source of a settable material. The die has a first portion connected by a hinge to a second portion. They cooperatively define a channel in a closed configuration. The source is connected to the channel through an opening between the inlet and outlet. A heating element is adapted to heat the settable material into a flowable condition and a control circuit is adapted to vary the supply of heat. The die is juxtaposed around the jacket near the defect. As the settable material is introduced into the channel, the wire or cable is moved along the channel relative to the die in the closed configuration such that a coating is formed over the defect. When the die is removed, the settable material sets into a solid condition.

A cable water stop structure for a cable that includes plural insulated wires and a sheath covering the plural insulated wires includes a heat shrinkable tube that is shrunk to wrap around an end of the sheath and the plurality of insulated wires extending from the end, and a cover that is attached to sandwich the end of the sheath, the plurality of insulated wires extending from the end and the heat shrinkable tube. The cover includes a gripping portion gripping the heat shrinkable tube to restrict the heat shrinkable tube from moving along a cable longitudinal direction.

Provided is a wire harness in which waterproofness of an exposed conductor portion can be ensured, and even when at least one of insulated wires is exposed to a high temperature, a rubber stopper of a waterproofing terminal can be kept from coming off. An outer peripheral surface of an exposed conductor portion where partially exposed conductors of a plurality of insulated wires are joined together, and outer peripheral surfaces of coating material end portions adjacent to the exposed conductor portion, is continuously covered with a waterproofing agent. A gap between adjacent insulated wires is sealed with the waterproofing agent at the coating material end portions adjacent to the exposed conductor portion. At least one insulated wire of the plurality of insulated wires has a flow path through which gas flows, the flow path being created in gaps between strands that constitute a conductor of the insulated wire.

A connection assembly connects at least two subsea cables to a dual output subsea sensor An embodiment includes an adapter piece mounted to a rear part of the subsea sensor; a sensor port in the adapter piece, through which at least a first sensor connection and a second sensor connection are led to the subsea sensor; a first and second port for respectively providing a connection to a first and second subsea cable; a first penetrator providing a liquid tight seal between an interior space of the adapter piece and a duct connected to the first port; and a second penetrator providing a liquid tight seal between the interior space of the adapter piece and a duct connected to the second port. The sealing provided by the first and second penetrator preventing fluid communication between the respective duct connected to the first and second port, through the adapter piece.

A joint (300) for joining a first electric cable (100) and a second electric cable (200), each cable (100; 200) having an electric conductor, an insulation system surrounding the electric conductor, and a water barrier (130;230) surrounding the insulation system. The insulation system has an inner semiconducting layer, an insulating layer and an outer semiconducting layer, where the joint has an electrical conductor joint electrically connecting end sections of the two electrical conductors. An insulation system joint has an inner layer made of a first polymeric semiconducting material surrounding the electric conductor joint, an intermediate insulating layer made of a polymeric insulating material, covering an external surface of the inner semiconducting layer, an outer layer made of a second polymeric semiconducting material, covering an external surface of the insulating layer; and a water barrier layer surrounding the insulation system joint, wherein the water barrier layer is made of pre-formed water barrier elements (140a; 140b; 240a; 240b).

A sealed structure (e.g., sealing module, sealing projection, etc.) transitions the direction of one or more cables passing through the structure. Sealant (e.g., a gel block) is disposed within the structure to seal one or more cables extending along a transition path within the sealed structure. Ducts and/or cables may be anchored to the sealed structure. The sealed structure may be mechanically secured to a closure at a selected rotational orientation.

A system including a sump having an inner volume and a junction box coupled to the sump. The junction box has a body defining an inner volume, and also has a first inlet and a second inlet, wherein each inlet is in fluid communication with the inner volume of the body. The junction box further has a first outlet and a second outlet, wherein each outlet is in fluid communication with the inner volume of the body such that a first wire is positionable in the first inlet and the first outlet and a second wire is positioned in the second inlet and the second outlet.

A method for making joints in an electrical cable is disclosed. A first cable having polymeric insulation and a first bare conductor end and a second cable having polymeric insulation and a second bare conductor end are provided and joined create a conductor joint. A curable reaction mixture is applied over the conductor joint and cured to form a polymeric insulating sheath over the conductor joint and bonded to the polymeric insulation of each of the first and second cables. The reaction mixture includes a carbon-Michael acceptor compound, a carbon-Michael donor compound and a carbon-Michael reaction catalyst.