Abstract: A multi-layer heat-shrinkable tubular sleeve (100) comprises an outer layer (110) and an inner layer (120). The outer layer (110) is arranged around the inner layer (120). The outer layer (110) comprises a partially crystalline thermoplastic material with a major part of partially crystalline thermoplastic material with a crystallinity of more than 60%. The inner layer (120) comprises a partially crystalline thermoplastic material or an elastomeric material.

Abstract: A multi-layer heat-shrinkable tubular sleeve (100) comprises an outer layer (110) and an inner layer (120). The outer layer (110) is arranged around the inner layer (120). The outer layer (110) comprises a partially crystalline thermoplastic material with a major part of partially crystalline thermoplastic material with a crystallinity of more than 60%. The inner layer (120) comprises a partially crystalline thermoplastic material or an elastomeric material.

Abstract: A heat-shrink tube for an electrical power cable comprises a sleeve having an insulating inner layer, a conductive outer layer and a thermoplastic mid-layer located between the inner and outer layers. The mid-layer is recovered by the application of heat thereto. The insulating inner layer is preferably comprised of an elastomeric material and the thermoplastic mid-layer is rigid and acts to retain the inner layer in a radially expanded state prior to its recovery.

Abstract: A sheet-like electrical stress control article includes at least one void-filling layer of elastomeric void-filling material having some electrical stress control functionality (for example, containing 20 to 70% by weight of electrically conductive or semi-conductive fillers) and at least one support layer of elastomeric material selected and/or formulated (for example, with 45 to 65% by weight fillers) to require increasing applied stress to produce therein a given unit of strain as it approaches its break point The thickness and composition of the respective layers are selected so that the article is stretchable during application thereof to parts of a cable and the increasing stress required to stretch the support layer resists over-elongation of the void-filling layer.

Abstract: An electrical insulation material which is suitable for high voltage applications, the material including (a) a polymeric material, and (b) an additive incorporated into the polymeric material, the additive including a compound of the formula: Rf—O2C(CH2)xCO—R′f where Rf and R′f are fluorine-substituted aliphatic chains, and x is an integer in the range 9 to 18.