EP1469484A1 - Composite cable comprising an optical fiber element - Google Patents

Abstract

Composite cable comprising a core (1) surrounded by a metal screen (2), an extruded electrically insulating polymer sheath (5) surrounding the screen, and a fiber optic element (6) comprising at least one optical fiber in a metal tube (61) between the screen and sheath, has a sheath-compatible polymer covering (62) around the metal tube and a layer of adhesive (3) covering the outer surface of the screen.

Description

The present invention relates to a composite cable comprising a fiber optic element.

There are already cables that carry both energy and optical information.

Document EP 0 825 465 thus discloses an energy and telecommunications, called composite cable, comprising a conductor electrical and a fiber optic element in the form of a metal tube comprising at least one optical fiber as an extension in the tube.

The steel tube is inscribed substantially in a plane. This tube as well as the optical fibers have sinusoidal ripples substantially parallel to this plane. If the cable is twisted, the tube supports thanks to the undulations of the elongations without breaking and the fibers are released from mechanical constraints.

The fiber optic element is arranged parallel to the axis longitudinal of the cable between a metallic screen, for example made of lead covering the electrical conductor and a layer of electrical insulation, extruded polymer. This layer is a multifunctional sheath: it also serves mechanical protection corrosion protection and ensures the cohesion of the whole.

At the time of extrusion of this sheath, the polymer does not come fill the spaces between the steel tube and the screen. This lack of material creates spaces extending along the longitudinal axis of the cable. In case of penetration of water, by rupture of the sheath for example, these spaces are preferential paths for the water which will flow along the axis longitudinal.

The flow promotes corrosion of the steel tube and ultimately that of the metal screen.

The object of the invention is to overcome the aforementioned problems by providing a composite cable protected against corrosion.

• un coeur entouré par un écran métallique,
• une gaine entourant l'écran, en un matériau polymérique isolant électrique et extrudé,
• un élément à fibre optique comprenant un tube métallique contenant au moins une fibre optique et disposé entre l'écran et la gaine,

   caractérisé en ce que l'élément à fibre optique comprend une enveloppe entourant le tube métallique et en un matériau polymérique compatible avec le matériau et en ce que le matériau polymérique de l'enveloppe est sensiblement identique audit matériau polymérique de la gaine.The present invention proposes for this purpose a composite cable comprising:

• a heart surrounded by a metallic screen,
• a sheath surrounding the screen, made of an electrically insulating and extruded polymeric material,
• an optical fiber element comprising a metal tube containing at least one optical fiber and disposed between the screen and the sheath,

characterized in that the optical fiber element comprises an envelope surrounding the metal tube and in a polymeric material compatible with the material and in that the polymeric material of the envelope is substantially identical to said polymeric material of the sheath.

The tube envelope provides better protection against corrosion. In addition, thanks to the compatibility between the materials of envelope and sheath, the polymeric material of the sheath will lodge more easily in small angles and thus significantly reduce voids of material, further strengthening the fight against corrosion of the tube and the screen.

Furthermore, to form the sheath by extrusion, the temperature of use of the polymeric material is high, for example between 150 ° C and 200 ° C. The tube according to the invention being placed in the head of extruder, the polymeric material of its envelope is heated which makes it adherent with the polymeric material of the sheath.

The envelope of the tube can also be produced by extrusion.

The cable also comprises a layer of adhesive covering the outer surface of the screen in order to reinforce the attachment between the sheath and the screen and to decrease the attack time by injections in particular and therefore the extent of corrosion at the screen. When the optical element is placed directly on the screen, this layer of adhesive ensures the connection between the screen and the polymeric envelope of the sheath.

Advantageously, the polymeric material of the envelope of the tube may be substantially identical to the polymeric material of the sheath, for optimized material compatibility.

In a preferred embodiment, the screen is metal-based chosen from aluminum and copper and polymeric materials from the envelope and the sheath are made of polyethylene and preferably of high density polyethylene (HDPE).

In another preferred embodiment, the cable may include in addition an anticorrosion layer covering the adhesive layer and in a extruded polymeric material substantially identical to the material polymer extruded from the sheath.

The tube and said at least one optical fiber according to the invention can have undulations along said cable substantially parallel to the axis longitudinal of the cable, to obtain the technical advantages already described.

The corrugations can be made after the manufacture of the envelope of the tube.

• la figure 1 représente schématiquement une vue en coupe transversale d'un câble composite dans un mode de réalisation préféré de l'invention,
• la figure 2 représente schématiquement une vue en coupe transversale de l'élément à fibre optique inséré dans le câble composite de la figure 1,
• la figure 3 représente schématiquement une vue partielle longitudinale et en élévation du câble composite de la figure 1.

The features and advantages of the invention will become clear on reading the description which follows, given by way of an illustrative and nonlimiting example and made with reference to the appended figures among which:

• FIG. 1 schematically represents a cross-sectional view of a composite cable in a preferred embodiment of the invention,
• FIG. 2 schematically represents a cross-sectional view of the optical fiber element inserted in the composite cable of FIG. 1,
• FIG. 3 schematically represents a partial longitudinal view and in elevation of the composite cable of FIG. 1.

The views in Figures 1 to 3 are not to scale.

We see in Figure 1, the cross section of a composite cable 10 in a preferred embodiment of the invention, cable, for example buried, telecommunications and energy, for example high voltage.

• un écran métallique 2, par exemple en aluminium, obtenu par extrusion ou contre-collé ou soudure, et par exemple de 0,2 à 2 mm d'épaisseur,
• de préférence une couche de colle extrudée 3, recouvrant la surface extérieure de l'écran 2, par exemple de 0,5 mm environ d'épaisseur,
• de préférence une couche anticorrosion 4 recouvrant la couche de colle 3, par exemple de 0,5 mm d'épaisseur, en un matériau polymérique électriquement isolant qui est de préférence un polyéthylène haute densité et est par exemple coextrudé avec la colle 3.

The composite cable 10, of longitudinal axis Z, comprises a conventional core 1 containing for example an insulated electrical conductor (not shown), this core 1 being successively surrounded by the following concentric elements:

• a metal screen 2, for example made of aluminum, obtained by extrusion or laminated or welded, and for example 0.2 to 2 mm thick,
• preferably a layer of extruded glue 3, covering the outer surface of the screen 2, for example approximately 0.5 mm thick,
• preferably an anticorrosion layer 4 covering the adhesive layer 3, for example 0.5 mm thick, made of an electrically insulating polymeric material which is preferably a high density polyethylene and is for example coextruded with the adhesive 3.

Furthermore, a sheath 5 serving as an electrical insulation layer and mechanical protection, surrounds the anticorrosion layer 4 and is in one identical extruded polymeric material, such as high polyethylene density, for example 4 to 5 mm thick on average.

In addition, between the anticorrosion layer 4 and the sheath 5, is disposed a fiber optic element 6 which is a coated metal tube containing a plurality of optical fibers.

The metal tube 61 is for example made of stainless steel and by example about 2 mm wide.

This tube 61 is coated, for example by extrusion, with an envelope 62 protective, in a polymeric material compatible with the material polymer extruded from the sheath 5 and preferably identical, for example the high density polyethylene. The thickness of the envelope 62 is for example of the order of 0.5 mm.

The optical fiber element 6 is arranged substantially parallel to the longitudinal axis Z and preferably as close as possible to the interior of the cable 10 in order to comply with the normalization criteria for sheath thickness 5 with a minimum of material used. In addition, for the same purpose, the sheath 5 is preferably eccentric: the thickness e1 of the sheath in the part located above the fiber optic element 6 is substantially equal to the thickness e2 of the sheath in the opposite part with respect to the axis Z.

As detailed in FIG. 2, the optical fiber element 6 can contain for example four FO optical fibers.

As detailed in FIG. 3, the optical fiber element 6, and more precisely the metal tube coated by the casing 62, has corrugations 63, for example sinusoidal and parallel to the longitudinal axis Z. Inside the metal tube, each optical fiber (not shown) also has undulations (not shown) which substantially follow the corrugations of the coated tube but are less in amplitude. The mechanical stresses on the fibers are thus limited.

After the manufacture of all of the concentric elements 2, 3, 4 and in particular the extrusion of polyethylene to obtain the layer anticorrosion 4, the optical fiber element 6 is placed on this last layer 4 and placed in the extruder head. When extruding the sheath 5, the polyethylene used easily binds with the polyethylene of the casing 62 of the metal tube 61 and with the polyethylene of the layer anticorrosion 4 in particular in zones A, A 'in the vicinity of this last layer 4 (see Figure 1).

In a variant (not shown), the cable 10 does not include the anti-corrosion layer 2. Before the sheath 5 is extruded, the fiber element optics 6 is thus placed on the glue or, in the absence of glue, on the screen. In this variant, the sheath 5 also acts as a layer of anticorrosion for screen 5. This variant requires only one step polyethylene extrusion.

Of course, the above description has been given as purely illustrative. Without departing from the scope of the invention, it is possible to replace any means by equivalent means.

The composite cable according to the invention can comprise a plurality fiber optic elements according to the invention.

The composite cable can be single conductor or Multicore.

The composite cable can be a terrestrial or submarine cable.

The thickness of the sheath can be chosen according to the criteria of standardization in force.

The composite cable may include other layers above sheath.

The invention can also be applied when the screen is based on lead and polyvinyl chloride sheath. We will then adapt the material of envelope it accordingly.

Claims (6)

Composite cable (10) comprising: a heart (1) surrounded by a metallic screen (2), a sheath (5) surrounding the screen, made of an electrically insulating and extruded polymeric material, an optical fiber element (6) comprising a metal tube (61) containing at least one optical fiber (FO) and disposed between the screen and the sheath characterized in that the optical fiber element comprises a casing (62) surrounding the metal tube and a polymeric material compatible with the polymeric material of the sheath and in that it comprises a layer of adhesive (3) covering the outer surface of the screen (2). Composite cable (10) according to claim 1 characterized in that the polymeric material of the envelope (62) is substantially identical to said polymeric material of the sheath (5). Composite cable (10) according to one of claims 1 or 2 characterized in that the screen (2) is based on a metal chosen from aluminum and copper and in that the polymeric materials of the envelope (62 ) and the sheath (5) are made of polyethylene. Composite cable (10) according to one of claims 1 or 2 characterized in that the screen (2) is based on a metal chosen from aluminum and copper and in that the polymeric materials of the envelope (62 ) and the sheath (5) are made of high density polyethylene. Composite cable (10) according to one of Claims 1 to 4, characterized in that it comprises an anticorrosion layer (4) covering the adhesive layer and made of an extruded polymeric material substantially identical to the extruded polymeric material of the sheath (5) . Composite cable (10) according to one of claims 1 to 5 characterized in that , the cable having a given longitudinal axis (Z), the tube (61) and said at least optical fiber (FO) each have, along said cable, corrugations (63) substantially parallel to said longitudinal axis.

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