FR2505057A1 - Non-metallic fibre=optic cable - has fibre cable forming core helically surrounded by optical fibres inside outer sheath - Google Patents

Abstract

The cable has its core (10) made using a number of strong fibres - for example glass or carbon fibre held together in resin. The 'wire' formed in this way may be put together with six wrapped in a helix around a central wire. The core is then wrapped with a band of material under tension, ensuring that the core itself remains in compression. Optical fibres (11) may then be carried in hollow tubes (12), six such tubes being arranged around the core. An outer sheath (14) encases the whole cable. The fibres are loose in their tubes, preventing sharp bends in the fibres when the cable is bent. The dia. of each wire is 0.5 mm.

Description

NON-METAL CARRIER ELEMENT FOR CABLE
AND CABLE COMPRISING SUCH A CARRIER
The present invention relates to a non-metallic carrier element for cable and a cable, in particular to optical fibers, comprising such a carrier.

 It is known that the plastic materials usually used to protect optical fibers are generally reinforced by carrier elements having good tensile strength and a low coefficient of thermal expansion, if possible identical to that of optical fibers.

 We already know, especially for fiber optic cables, carrier elements made of metal son. In certain applications, however, it is advantageous, even essential, to have optical transmission cables free of metallic mass, for example for making connections in substations or very high voltage devices, or else for making connections that are difficult to detect. , etc ...

 The adoption of a non-metallic carrier also leads, in most cases, to a reduction in the weight of the cable.

 Non-metallic elements are thus used either individually or in the form of a strand. A carrier element is constituted by a wire or a strand of wires, where a wire is constituted by fibers embedded in a resin.

 However, these elements are not satisfactory since, when they are subjected to compressive forces, either by curvature of the cable, or by exposure of the latter to low temperatures, the wires become fragile at the level of the external layers. , and, in the case of a strand, the different threads also tend to move apart from one another.

 The present invention relates to a non-metallic support element for cable, which does not have these drawbacks.

 The element according to the invention comprises at least one non-metallic wire and is covered with a covering with high tension. The invention also relates to a cable, in particular to optical fibers, comprising such an element.

The invention will be better understood in the description which follows given by way of nonlimiting example and where:
FIG. 1 represents in perspective a carrier element comprising a wire formed of fibers embedded in a resin,
FIG. 2 represents in section a carrier element in the form of a strand,
FIG. 3 is a perspective view of a load-bearing element during wrapping, according to the invention,
FIG. 4 shows a perspective view of a wrapped carrier element according to the invention,
FIG. 5 represents in section an element of FIG. 4 provided with a protective sheath or varnish,
FIG. 6 represents an example of cable using a carrier element from FIG. 5.

 FIG. 1 represents a carrier element designated by the general reference 1 and which comprises a wire formed from resistant fibers 2 embedded in a resin. The fibers can be for example glass fibers, aramid fibers or carbon fibers.

 FIG. 2 represents a carrier element constituted by wires 3, here 6 in number, each of which is formed of fibers embedded in a resin, for example epoxy, and which are wired in a helix, for example around a central element 4 which may or may not be of identical structure to the wires 3.

 FIG. 3 represents a carrier element which, according to the invention, is subjected to a covering operation under high tension. This operation is preferably carried out using a wick of resistant fibers, for example aramid fibers. It has the effect of achieving compaction keeping the outside of the carrier element under compression.

 The covering has the effect of preventing the breaking of the fibers constituting the external layers of the wire or wires when the element is subjected to compression, as well as the extension of this phenomenon step by step to the other fibers of each wire. The tension of the covering fibers depends in all cases on the hardness of the resin used.

 Indeed, the rupture of the fibers constituting the external layers of the son occurs because locally the compressive force, in particular during a curvature, becomes greater than the resistance of the material constituting the wire. There is then local disintegration of the material and breaking of the fibers by shearing. The covering according to the invention makes it possible, by superimposition of a radial prestressing force, to compensate for the shearing forces and to locally maintain the cohesion of the wires. The clamping force will then have to be stronger the harder the resin because it will be all the more fragile. The clamping force will be determined by calculation or experimentally depending on the conditions of use of the cable and will be higher the more severe they will be (use at low temperature, small radii of curvature). carrier of given structure and gimped according to a given pitch with a given clamping force, intrinsically has a resistance to compressive forces greater than that of the same non-gimped element. Its resistance can be expressed in the form of a minimum radius of curvature of winding and / or a minimum temperature of use. This allows a given carrier element to be used directly for a cable of given characteristics.

 On the other hand, a covering according to the invention also makes it possible to improve the performance of the element in traction. It is therefore also possible to characterize an element according to the invention by a tensile strength and / or a maximum temperature of use.

 If the carrier element is made up of several cabled elements, the covering is carried out under a sufficient tension to ensure compacting of the assembly, in the form of elements 4 ′ and 3 ′ (FIG. 4) between which practically no intermediate space does not subsist.

As a variant, the elements 3 and 4 can be coated collectively with resin before the covering operation.

 The covering, to be effective, must ensure good covering of the external surface of the carrier element, that is to say it will preferably be made with contiguous turns or with covering.

For example, a carrier element was made from 7 wires in the form of fibers coated with epoxy resin, and wired together.

Each wire has a diameter of 0.5 mm. The carrier element was wrapped using a wick of aramid fibers ("Kevlar" brand), each fiber of which has a section of approximately 6 to 7 microns, and having a breaking strength of 30 Kg. This wick, sold under the reference KEVLAR 49 (1580 dtex), produces, when laid flat in the form of wrapping, a ribbon about 1 mm wide and 1 to 2 tenths of a mm thick. One thus laid such a wick under a tension of a few kilos, the tension having been obtained by braking a reel unwinding the wick, and at a pitch of about 1 mm in order to obtain a wrapping edge to edge. This tension is sufficient to ensure the desired compaction. Such a carrier element can be wound without inconvenience over a diameter of 40 mm and withstand temperatures from - 550C to + 1200C. It will be noted that the maximum temperature which the carrier element can bear also depends the quality of the resin used.

 A carrier element coated with a covering 8 according to the invention can be used in various ways.

 It can first of all be directly integrated as a supporting element in a structure of plastic material, for example a grooved cylindrical structure whose grooves contain optical fibers, or even in a reinforcement sheath extruded around a cable comprising several elements carriers for example 3.

 It can also be used as a wired carrier and for this purpose is preferably coated with an additional layer 9.

In this form, it is represented by the reference 10 in FIG. 3.

This layer 9 can be a sheath, or a varnish. Its function is to protect the fibers constituting the covering 8. The use of a sheath also makes it possible to bring the element to the diameter necessary for its use. For example, a polyamide sheath is well suited since this material, in extruded form, is relatively fluid and fills the interstices well. Likewise, any resin which can be deposited in very small thickness is particularly suitable, for example 1 "ETFE" (tetrafluoroethylene-ethylene copolymer).

 FIG. 6 illustrates a use of a carrier element designated by the general reference 10, covered and covered with an additional layer 9. It is surrounded by a plurality of tubes 12, here 6 in number, each of which contains a fiber optical. The assembly is surrounded by a sheath and / or an envelope 14. The additional layer 9, which is not essential, makes it possible to protect the wrapping against mechanical friction.

 The invention is not limited to the embodiments described above. Thus, it is possible to proceed with wrapping using a continuous ribbon provided that its tensile strength is sufficient.

It is also possible to use a covering with several layers.

Claims (11)

 1. Non-metallic support element for cable, characterized in that it comprises at least one wire (1, 3 ', 4') and in that it is covered with a covering (8) at high tension.  2. Element according to claim 1, characterized in that it comprises a plurality of wires (3 ', 4') assembled.  3. Element according to claim 2, characterized in that the wires (3 ', 4') are wired helically around a central wire.  4. Element according to one of claims 1 to 3, characterized in that a wire (3 ', 4') consists of resistant fibers (2) embedded in a resin.  5. Element according to claim 4, characterized in that the fibers (2) are chosen from aramid fibers, glass fibers and carbon fibers.  6. Element according to one of claims 4 or 5, characterized in that the resin is an epoxy resin.  7. Element according to one of the preceding claims, characterized in that the covering (8) is made from at least one strand of resistant fibers (7) laid helically edge to edge or with overlap.  8. Element according to claim 7, characterized in that the fibers constituting the wick (7) are aramid fibers.  9. Element according to one of the preceding claims, characterized in that it comprises an additional layer (9) of protection.  10. Cable characterized in that it comprises a carrier element according to one of the preceding claims.  11. Cable according to claim 10, characterized in that it comprises optical fibers.