A method for connecting a cable to a connector (1001), and a cable connected to the connector (1001), for use in improving an anti-interference capability at a position where the cable is connected to the connector (1001) and between cable core conductors (1002), thereby improving a transmission rate and transmission power of a cable having a connector. The method of embodiments comprises: baring a preset length of a cable core conductor (1002) in a cable; connecting the cable core conductor (1002) to a connector (1002); cladding the connected bare cable core conductor (1002) using an electromagnetic shielding film (1003) to effectively reduce signal crosstalk between cable cores, the electromagnetic shielding film (1003) at least comprising a first metal layer (A), a conductive layer (B), and a protective film (C), wherein the first metal layer (A) is used for shielding electromagnetic interference, the conductive layer (B) is provided on the first metal layer (A) to shield electromagnetic interference, and the protective film (C) is provided on the conductive layer (B) to provide protection to the electromagnetic shielding film (1003).

A method for connecting a cable to a connector (1001), and a cable connected to the connector (1001), for use in improving an anti-interference capability at a position where the cable is connected to the connector (1001) and between cable core conductors (1002), thereby improving a transmission rate and transmission power of a cable having a connector. The method of embodiments comprises: baring a preset length of a cable core conductor (1002) in a cable; connecting the cable core conductor (1002) to a connector (1002); cladding the connected bare cable core conductor (1002) using an electromagnetic shielding film (1003) to effectively reduce signal crosstalk between cable cores, the electromagnetic shielding film (1003) at least comprising a first metal layer (A), a conductive layer (B), and a protective film (C), wherein the first metal layer (A) is used for shielding electromagnetic interference, the conductive layer (B) is provided on the first metal layer (A) to shield electromagnetic interference, and the protective film (C) is provided on the conductive layer (B) to provide protection to the electromagnetic shielding film (1003).

Cable foil tape having random or pseudo-random patterns or long pattern lengths of discontinuous metallic shapes and a method for manufacturing such patterned foil tape are provided. In some embodiments, a laser ablation system is used to selectively remove regions or paths in a metallic layer of a foil tape to produce random distributions of randomized shapes, or pseudo-random patterns or long pattern lengths of discontinuous shapes in the metal layer. In some embodiments, the foil tape is double-sided, having a metallic layer on each side of the foil tape, and the laser ablation system is capable of ablating nonconductive pathways into the metallic layer on both sides of the foil tape.

Cable foil tape having random or pseudo-random patterns or long pattern lengths of discontinuous metallic shapes and a method for manufacturing such patterned foil tape are provided. In some embodiments, a laser ablation system is used to selectively remove regions or paths in a metallic layer of a foil tape to produce random distributions of randomized shapes, or pseudo-random patterns or long pattern lengths of discontinuous shapes in the metal layer. In some embodiments, the foil tape is double-sided, having a metallic layer on each side of the foil tape, and the laser ablation system is capable of ablating nonconductive pathways into the metallic layer on both sides of the foil tape.

There is described an electrical isolator comprising a first fluid-carrying member and a second fluid-carrying member spaced apart from said first fluid-carrying member, a resistive, semi-conductive or non-conductive component located between and sealed against said first and second fluid-carrying member, wherein said resistive, semi-conductive or non-conductive component is adapted to convey fluid flowing from said first fluid-carrying member to said second fluid-carrying member, a reinforcing composite encircling said first fluid-carrying member, said second fluid-carrying member and said resistive, semi-conductive or non-conductive component, wherein said reinforcing composite is continuous and provides a conductive path between said first fluid-carrying member and said second fluid-carrying member, wherein said reinforcing composite comprises fibre and a resin mixture, and said resin mixture comprises resin and a conductive additive.

There is described an electrical isolator comprising a first fluid-carrying member and a second fluid-carrying member spaced apart from said first fluid-carrying member, a resistive, semi-conductive or non-conductive component located between and sealed against said first and second fluid-carrying member, wherein said resistive, semi-conductive or non-conductive component is adapted to convey fluid flowing from said first fluid-carrying member to said second fluid-carrying member, a reinforcing composite encircling said first fluid-carrying member, said second fluid-carrying member and said resistive, semi-conductive or non-conductive component, wherein said reinforcing composite is continuous and provides a conductive path between said first fluid-carrying member and said second fluid-carrying member, wherein said reinforcing composite comprises fibre and a resin mixture, and said resin mixture comprises resin and a conductive additive.

The present invention relates to a method for manufacturing a cable comprising at least one elongate electrically conductive element, at least one composite layer surrounding the elongate electrically conductive element, the composite layer comprising a non-woven fibrous material impregnated by a geopolymer material, and at least one polymer sleeve surrounding the composite layer, the method using a tube of plastic material to facilitate the extrusion of the polymer sleeve around the composite layer.

The present invention relates to a method for manufacturing a cable comprising at least one elongate electrically conductive element, at least one composite layer surrounding the elongate electrically conductive element, the composite layer comprising a non-woven fibrous material impregnated by a geopolymer material, and at least one polymer sleeve surrounding the composite layer, the method using a tube of plastic material to facilitate the extrusion of the polymer sleeve around the composite layer.

A polymer-sheathed multi-filamentary strand for use in braided covers for wiring harnesses intended for use in challenging embodiments comprises a core of glass filaments wrapped in an aramid yarn, and sheathed in a siloxane-modified polyetherimide polymer. Shielding against electromagnetic interference may also be provided.

A polymer-sheathed multi-filamentary strand for use in braided covers for wiring harnesses intended for use in challenging embodiments comprises a core of glass filaments wrapped in an aramid yarn, and sheathed in a siloxane-modified polyetherimide polymer. Shielding against electromagnetic interference may also be provided.