A low smoke, zero halogen self-regulating heating cable includes a semi-conductive heating core and two conductive wires embedded within and separated by the semi-conductive heating core. The cable also includes a primary jacket surrounding the semi-conductive core, a braid surrounding the primary jacket, and a final jacket surrounding the braid. At least one of the primary jacket and the final jacket includes a low smoke, zero halogen material.

A low smoke, zero halogen self-regulating heating cable includes a semi-conductive heating core and two conductive wires embedded within and separated by the semi-conductive heating core. The cable also includes a primary jacket surrounding the semi-conductive core, a braid surrounding the primary jacket, and a final jacket surrounding the braid. At least one of the primary jacket and the final jacket includes a low smoke, zero halogen material.

An electrical grounding assembly includes an electrically conductive metal grounding substrate that is electrically connectable to a structure to be electrically grounded. A corrosion-protective jacket is on the grounding substrate. The jacket is electrically conductive and water impermeable, and includes a polymeric matrix and a particulate carbonaceous material dispersed in the polymeric matrix.

An anti-corrosive material contains an ultraviolet curable resin including a polymerizable compound including at least one of a photopolymerizable (meth)acrylate monomer or a photopolymerizable (meth)acrylate oligomer. The anti-corrosive material has a viscosity of 18,900 mPa.Math.s or less. The anti-corrosive material has an elongation rate of 60% or greater as a result of heating at 120° C. for 4,000 hours after curing.

A technique facilitates splicing of a power cable including splicing of a protective lead barrier. According to the technique, the power cable comprises conductors which form individual phases of a multi-phase conductor assembly. The conductors may be individually spliced for each phase of the multi-phase conductor assembly. Subsequently, splicing of the protective lead barrier may be performed by utilizing a lead based tape which is wrapped, e.g. helically wrapped, around the conductors. The wrapping technique provides a gas seal with respect to each individual insulated conductor within the multi-phase conductor assembly. Depending on the specifics of a given application and environment, additional layers may be added to ensure formation of a desirable splice.

A technique facilitates splicing of a power cable including splicing of a protective lead barrier. According to the technique, the power cable comprises conductors which form individual phases of a multi-phase conductor assembly. The conductors may be individually spliced for each phase of the multi-phase conductor assembly. Subsequently, splicing of the protective lead barrier may be performed by utilizing a lead based tape which is wrapped, e.g. helically wrapped, around the conductors. The wrapping technique provides a gas seal with respect to each individual insulated conductor within the multi-phase conductor assembly. Depending on the specifics of a given application and environment, additional layers may be added to ensure formation of a desirable splice.

A conductor arrangement for an electrical connection includes a flexible multi-core internal conductor, an electromagnetic shield surrounding the flexible multi-core internal conductor, a thermoplastic hard plastic sheath surrounding a first portion of the flexible multi-core internal conductor, and a flexible corrugated tube surrounding a second portion the flexible multi-core internal conductor. A first portion of the thermoplastic hard plastic sheath includes an elongated flattened shape. A second portion of the thermoplastic hard plastic sheath includes an essentially round shape. The second portion of the thermoplastic hard plastic sheath is adjacent the first portion of the thermoplastic hard plastic sheath.

A multicore cable includes a plurality of sheathed wires, and a second cover layer covering an outer periphery of the plurality of sheathed wires, wherein the sheathed wire includes a conductor, and a first cover layer covering the conductor, the first cover layer is a crosslinked fluoroelastomer or a crosslinked fluororesin, and the second cover layer is a crosslinked fluoroelastomer.

Electrical cables and methods of forming such cables are disclosed, comprising a layer of a two dimensional material. In some embodiments, the cable is a subsea cable. In other embodiments, the cable may be an overhead power cable or a cable for forming electrical windings in a motor, generator or transformer. In some embodiments, the cable comprises a conductive core for carrying an electric current, and the layer of two dimensional material is disposed on the conductive core. In some embodiments, the subsea cable is a subsea power cable, umbilical cable or telecommunications cable. In some embodiments, the two dimensional material is configured to be superconducting or near-superconducting.

An anti-corrosive material contains an ultraviolet curable resin including a polymerizable compound including at least one of a photopolymerizable (meth)acrylate monomer or a photopolymerizable (meth)acrylate oligomer. The anti-corrosive material has a viscosity of 18,900 mPa.Math.s or less. The anti-corrosive material has an elongation rate of 60% or greater as a result of heating at 120° C. for 4,000 hours after curing.