In general, aspects of this invention relate to electrical cables and, in particular, to a cable with electromagnetic and/or anti-ballistic shielding. According to one aspect, a cable may comprise: a conductor; a continuous metallic sheath surrounding the conductor; and a supplemental sheath layer surrounding the metallic sheath. According to another aspect, a cable may comprise: a conductor; an armor layer surrounding the conductor; a fabric layer surrounding the conductor; and a polymer layer surrounding the conductor. According to yet another aspect, a cable may comprise: a conductor; an inner synthetic strength member surrounding the conductor; a polymer compound positioned between the conductor and the inner synthetic strength member; a polymer layer surrounding the inner synthetic strength member; an armor layer surrounding the polymer layer; an outer synthetic strength member surrounding the armor layer; and a polyolefin layer surrounding the outer synthetic strength member.

It is disclosed a cable comprising an elongated tensile element having a cross section area and comprising a fibre reinforced polymer composite core having an elastic modulus of at least 70 GPa and a sheath at least partially covering the composite core, the sheath being made of metal and being at least 30% of the cross section area of the tensile element.

In accordance with embodiments of the present disclosure, a cable system for conveying well servicing equipment into a wellbore includes a core support structure extending longitudinally along an axis of the cable system. The core support structure comprises polymer reinforced with fibers, and the fibers are oriented substantially parallel to the axis of the cable system. The cable system also includes a mesh layer disposed around and bonded to the core support structure. The mesh layer includes metal wrapped around the core support structure. The cable system also includes a polymeric coating disposed around and bonded to the mesh layer. The mesh layer enables increased structural support of the cable system, particularly against forces in the radial direction relative to the axis of the cable system. In some applications, the mesh layer acts as a return conductive path for conductors embedded in the core support structure.

A deep sea lifting cable having a cable core (36) surrounded by armouring (32), wherein the armouring is surrounded by an outer jacket (33), wherein the cable core comprises at least one power cable (10) is disclosed. The armouring (32) comprises synthetic stiff ropes and interstices (35) between the stiff ropes are filed with a high viscous filler.

The present invention discloses a metal wire armored optoelectronic hybrid cable, which comprises an optoelectronic hybrid unit, a metal wire armoring and an outer protection casing. The optoelectronic hybrid unit comprises an electrical unit and an optical unit which are mixed. The metal wire armoring wraps the optoelectronic hybrid unit. The outer protection casing wraps the metal wire armoring. In the present invention, due to the use of the metal wire armoring, the bending performance is favorable, the production and processing processes are simple, and the production cost of the hybrid cable is greatly reduced.

A self-supporting electric power cable is disclosed. The electric power cable includes an outer jacket portion and a core portion. The core portion includes at least one insulated conductor and at least one supporting cord. The at least one insulated conductor includes a number of individual wires, and the at least one supporting cord includes synthetic fibers. The number of individual wires, individually or arranged in bundles, are arranged in a first lay direction. The at least one insulated conductor and the at least one supporting cord are arranged in a second lay direction. The at least one supporting cord is arranged as a separate unit in a cross sectional sector of the self-supporting electric power cable. Thus flexible and durable power cable for sea use is provided. Also an offshore arrangement is disclosed herein.

A cable has a tensile armor having a number of elongated polymeric tensile elements. At least one of the elongated polymeric tensile elements includes a bundle of high tensile fibers and a jacket tightly retaining the bundle of fibers. The elongated polymeric tensile elements are arranged with a lay loss of 1.5% at most. A method of manufacturing such a cable is also disclosed.

High bandwidth push-cables for high speed image or video data transmission between a camera head and a cable reel or camera control unit (CCU) are disclosed.

A composite optoelectronic HDMI cable having the advantages of low signal attenuation, long distance application, ease of installation and light weight is disclosed. Specifically, a fiber optic bundle unit is provided in the HDMI cable instead of the existing copper wire or alloy conductor, and the overall outer diameter is reduced by half and the weight is reduced by three quarters when compared to the copper wire or alloy conductor. It is very convenient for long-distance use or project laying.

A self-supporting electric power cable is disclosed. The electric power cable includes an outer jacket portion and a core portion. The core portion includes at least one insulated conductor and at least one supporting cord. The at least one insulated conductor includes a number of individual wires, and the at least one supporting cord includes synthetic fibres. The number of individual wires, individually or arranged in bundles, are arranged in a first lay direction. The at least one insulated conductor and the at least one supporting cord are arranged in a second lay direction. The at least one supporting cord is arranged as a separate unit in a cross sectional sector of the self-supporting electric power cable. Thus flexible and durable power cable for sea use is provided. Also an offshore arrangement is disclosed herein.