Cable with joints for the connection of cable armour non-metallic elements

What is claimed is: 1. A cable comprising: a cable core; and an armor comprising a plurality of consecutive sections of non-metallic tensile elements wound around the cable core, each section of the plurality of consecutive sections of non-metallic tensile elements including a first non-metallic tensile element connected to a second non-metallic tensile element by a joint, the joint comprising: a first socket and a second socket, each of the first and second sockets comprising a flat body extending longitudinally along a longitudinal axis between a proximal end and a distal end and comprising an inner through bore between a proximal aperture at the proximal end and a distal aperture at the distal end, the first and second non-metallic tensile elements having an end portion being housed in the inner through bore of respectively the first and second socket by the proximal aperture and secured therein by a bonding material, and each inner through bore being shaped to translationally and rotationally lock the bonding material, and an interconnecting device translationally and rotationally locked in the distal apertures of the first and the second sockets and allowing the sockets to relatively rotate exclusively around at least one rotation axis perpendicular to a plane where the socket body longitudinal axes of the first and the second sockets lie. 2. The cable of claim 1 , wherein the non-metallic tensile elements connected by the joint have a round or flat cross-section. 3. The cable of claim 1 , wherein the inner through bore is shaped such that in response to an application of a traction force along the socket body longitudinal axis in a direction from the distal end towards the proximal end, the bonding material securing the non-metallic tensile element end portion is compressed inside the inner through bore. 4. The cable of claim 1 , wherein at least one portion of the inner through bore is tapered towards the proximal end. 5. The cable of claim 1 , wherein the inner through bore has a rectangular cross section transversal to the socket body longitudinal axis. 6. The cable of claim 5 , wherein at least one portion of the inner through bore is tapered towards the proximal end, and wherein the length of the longer sides of the inner through bore cross section is fixed and the length of the shorter sides of the inner through bore cross section decreases along the socket body longitudinal axis towards the proximal end. 7. The cable of claim 1 , wherein the bonding material securing the end portion of the non-metallic tensile element is a thermoset material or a two-part resin. 8. A cable comprising: a cable core; and an armor comprising a plurality of consecutive sections of non-metallic tensile elements wound around the cable core, each section of the plurality of consecutive sections of non-metallic tensile elements including a first non-metallic tensile element connected to a second non-metallic tensile element by a joint, the joint comprising: a first socket and a second socket, each of the first and second sockets comprising a flat body extending longitudinally along a longitudinal axis between a proximal end and a distal end and comprising an inner through bore between a proximal aperture at the proximal end and a distal aperture at the distal end, the first and second non-metallic tensile elements having an end portion being housed in the inner through bore of respectively the first and second socket by the proximal aperture and secured therein by a bonding material, and each inner through bore being shaped to translationally and rotationally lock the bonding material, and an interconnecting device translationally and rotationally locked in the distal apertures of the first and the second sockets and allowing the sockets to relatively rotate exclusively around at least one rotation axis perpendicular to a plane where the socket body longitudinal axes of the first and the second sockets lie, wherein the interconnecting device comprises a first block and a second block, extending along the longitudinal axis, and a pivot joining them and allowing relative rotational movements of the first block and the second block around a rotation axis perpendicular to a plane where the longitudinal axes lie, wherein the blocks are locked at a first portion in the respective socket body distal apertures, and are pivotally interconnected at a second portion opposite to the first portion. 9. The cable of claim 8 , wherein the first and second blocks cross section transversal to their longitudinal axes at their first portions and the respective socket body distal aperture have matching shapes. 10. The cable of claim 8 , wherein at their first portions the first and second blocks comprise a through hole extending perpendicular to their longitudinal axes, and the respective socket body comprises two opposite ridges protruding along the longitudinal axis from the distal end, each having a through hole extending perpendicular to the socket body longitudinal axis and aligned to the block through hole, wherein the interconnecting device further comprises a pin or bolt inserted into the aligned block and socket through holes. 11. The cable of claim 8 , wherein at their second portions the first and second blocks comprise one or more ridges protruding along their longitudinal axes and parallel thereto, each having a through hole perpendicular to the block longitudinal axis, wherein a pin or bolt is inserted. 12. The cable of claim 8 , wherein at their first portions the first and second blocks comprise a plug portion for closing and sealing the distal aperture of the respective socket body. 13. A cable comprising: a cable core; and an armor comprising a plurality of consecutive sections of non-metallic tensile elements wound around the cable core, each section of the plurality of consecutive sections of non-metallic tensile elements including a first non-metallic tensile element connected to a second non-metallic tensile element by a joint, the joint comprising: a first socket and a second socket, each of the first and second sockets comprising a flat body extending longitudinally along a longitudinal axis between a proximal end and a distal end and comprising an inner through bore between a proximal aperture at the proximal end and a distal aperture at the distal end, the first and second non-metallic tensile elements having an end portion being secured within the inner through bore of respectively the first and second socket by the proximal aperture, and an interconnecting device translationally and rotationally locked in the distal apertures of the first and the second sockets and allowing the sockets to relatively rotate around at least one rotation axis perpendicular to a plane where the socket body longitudinal axes of the first and the second sockets lie, wherein the inner through bore has a rectangular cross section transversal to the socket body longitudinal axis. 14. The cable of claim 13 , wherein the non-metallic tensile elements connected by the joint have a round or flat cross-section. 15. The cable of claim 13 , wherein the inner through bore is shaped such that in response to an application of a traction force along the socket body longitudinal axis in a direction from the distal end towards the proximal end. 16. The cable of claim 13 , wherein at least one portion of the inner through bore is tapered towards the proximal end. 17. The cable of claim 13 , wherein at least one portion of the inner through bore is tapered towards the proximal end, and wherein the length of the longer sid