FR2509480A1 - Underwater fibre optic cable - has optical fibre lying along sinusoidal path within oblong section tube, allowing relative movement between tube and fibre - Google Patents

Abstract

The fibre optic cable includes an oblong tube (1) which houses an optical fibre. Four insulated electrical conductors (17,18,19,20) lie two on each side of the tube. The assembly is protected by two layers of high strength steel wires (21,22) twisted around the cable in opposite directions. The optical fibre lies in the tube along a sinusoidal path, touching the two sides of the tube alternately. This fibre is thus longer than the tube, and is able to flex to accommodate variations in the length of the tube. The 'wavelength' of the sine wave is sufficiently long to ensure that the fibre only flexes within acceptable limits. The cable may be used underwater, and is able to withstand temperature variations, or the tension applied as the cable is laid down.

Description

Fiber optic cable capable of supporting large lengths
The present invention relates to a fiber optic cable capable of supporting large elongations, such a cable comprising one or more optical fibers only, or comprising both optical fibers and conductors, as is known.

 Optical fibers are optical light guides of which there are different types, made of glass or any other transparent material. Such fibers are fragile and do not support a tensile force, or only support a very low tensile force, which is not likely to break the fibers.

 I1 are different solutions to allow cables with optical fibers to withstand tensile forces, therefore to withstand elongations under the effect of these tensile forces. A known solution consists in winding the fibers according to a very large pitch helix; this solution is obviously only possible if the optical fibers are not placed in the center, or approximately in the center of the cable, but around a central core constituted by one or more insulated metallic electrical conductors.

 Another known solution consists in loosely inserting one or more optical fibers into tubes of circular cross section, said tubes generally being filled with a preferably water-repellent material.

 The optical fiber (s) loosely inserted into a tube therefore have a greater length than that of the tube by the fact that they have in this tube a more or less sinusoidal profile, the amplitude of the "sinusoid" being equal to the tube radius; on the other hand the period of the "sinusoid" is necessarily large on the one hand because the optical fiber has a certain rigidity and that it cannot therefore have a small radius of curvature, and on the other hand because the diameter of the tube is only of the order of a few diameters of the optical fiber; of course this is not a fixed length period since the profile is not really sinusoidal. For all these reasons the length of the optical fiber, or optical fibers, inserted in a tube is not enough large so that there is no risk of them breaking when the cable is subjected to tensile forces which would lengthen it considerably.

This solution allows, however, a certain elongation of the cable which is not the case when the fiber has the same length as the tube, or even when the tube, with the optical fiber or fibers, is located in the center of the cable, this provision not allowing a helical winding of the tube.

 The object of the invention is to allow a cable comprising optical fibers to withstand greater elongations than those of known cables.

 The subject of the invention is a fiber optic cable capable of supporting large elongations and comprising at least one tube having at least one non-stretched optical fiber and in which said optical fiber has a more or less sinusoidal profile, characterized in that the tube has an oblong cross-section having a large dimension according to which the optical fiber is arranged, along the tube, according to a profile of sinusoidal shape.

The invention is described in more detail with the aid of exemplary embodiments illustrated by the appended figures in which
FIG. 1 represents an oblong tube of the invention,
FIG. 2 represents in section an assembly of oblong tubes of FIG. 1 with a variant of the oblong tube of FIG. 1,
FIG. 3 represents in section a cable using an oblong tube of the invention,
FIG. 4 represents in section a variant of a cable using an oblong tube of FIG. 1,
- Figure 5 shows in section a cable using a variant of the oblong tube of Figure 1.

 FIG. 1 represents an oblong tube 1 of the invention in which an optical fiber 2 is arranged, the position of which, inside the oblong tube, is shown in broken lines.

In this figure the position of the optical fiber in the oblong tube has a sinusoidal shape, but it is understood that the optical fiber is arranged very loosely inside the tube and that therefore it naturally adopts a certain profile between the opposite ends 3 and 4 of the section of the oblong tube, these ends being situated along the largest dimension of the section of the oblong tube. The profile adopted by the optical fiber is therefore more or less sinusoidal, the term sinusoidal being used only to recall that the fiber is alternately in contact with the ends 3 and 4 of the internal wall of the oblong tube 1.

 In the figure there is shown a period of the "sinusoid" formed by the optical fiber in the oblong tube 1, this only for illustration, because in this figure the radius of curvature of said optical fiber in the vicinity of the ends 3 and 4 of the oblong tube is greatly exaggerated and is not compatible with the rigidity of the optical fiber; practically therefore the "period" of the sinusoid is much greater than that shown in FIG. 1.

 The oblong tube 1 can be oval or elliptical, its largest dimension being of the order of a few diameters of the optical fiber. An oblong tube of the invention allows, with respect to a tube of circular section and of equal size, that is to say having a section whose surface is equal to the section of a circular tube, to have length of tube equals a longer length of optical fiber, or "soft".

This makes it possible to absorb variations in the length of a cable having optical fibers housed in oblong tubes, variations due either to expansion or contraction of the cable under the effect of temperature, or to tensile forces exerted on the cable during its installation or its lifting, in particular in the case of an underwater cable.

 Such a tube is filled with a viscous water-repellent material.

 Due to its shape, the oblong tube will generally contain only one optical fiber, but it can contain several.

 The oblong tube 1 is either a plastic tube or a metal tube.

 In the case of a plastic tube, this is for example obtained by extrusion around the optical fiber, as is conventional.

 In the case of a metallic tube, this is obtained by any means as for electric cables, for example by winding a metallic strip in a helix around the optical fiber.

 The oblong tube 1 of FIG. 1 is used in cables which can consist only of either oblong tubes, or one or more oblong tubes and insulated electrical conductors.

 Figure 2 shows in section an assembly consisting of two oblong tubes 1 identical to the oblong tube of Figure 1, and of a honeycomb oblong tube 5 which is a variant of the oblong tube of Figure 1. The honeycomb oblong tube 5 is provided a wall 8, longitudinal, located in the middle of its largest dimension so as to form two cells 6 and 7 constituting two oblong tubes.

 At least one optical fiber 2 is housed in each of the oblong tubes 1 and in each cell 6 and 7. In the wall 8 is housed a carrier 9, metallic or made of material with high tensile strength, such as polyamide "KEVLAR" sold by Société Du Pont de Nemours. The assembly of FIG. 2 is used to constitute the central structure of a cable which is protected, in a conventional manner, by a vault formed by wires or by any other mode of protection, as shown in FIGS. 3, 4 and 5.

 Figure 3 shows in section a cable consisting of an oblong tube 1 in which is disposed at least one optical fiber 2, and five insulated conductors 10, 11, 12, 13, 14, the assembly being protected by a double armor formed of high resistance steel wires distributed in two superimposed layers 15 and 16, wound in reverse pitch.

 FIG. 4 represents in section a variant of a cable using an oblong tube of FIG. 1.

 In this figure the cable comprises an oblong tube 1 in which is disposed at least one optical fiber 2, and four insulated electrical conductors 17, 18, 19, 20, arranged on each side of the oblong tube.

 The assembly is protected by a double armor formed of high-strength steel wires distributed in two superimposed layers 21, 22 wound in reverse pitch.

 FIG. 5 represents in section a cable using a variant of the oblong tube 1 of FIG. 1.

 In FIG. 5, the oblong tube 23 comprises, like the oblong tube 5 of FIG. 2, a wall 24 in the middle of its largest dimension, a wall which delimits two cells 25 and 26, each constituting an oblong tube in which is placed at the at least one optical fiber 2. No carrier is embedded in the wall 24, since the oblong tube 23 is surrounded by four insulated electrical conductors 17, 18, 19, 20. The assembly of oblong tube and insulated conductors is protected by a double armor formed by high-strength steel wires distributed in two superimposed layers 21 and 22, wound in reverse pitch.

 Of course in Figures 2 to 5, the tube can be filled with a water-repellent material with a greasy appearance, such as petroleum jelly for example.

Claims (8)

1 / Optical fiber cable capable of supporting large elongations and comprising at least one tube having at least one non-stretched optical fiber and in which said optical fiber has a more or less sinusoidal profile, characterized in that the tube (1) has an oblong cross section having a large dimension according to which the optical fiber (2) is arranged, along the tube, according to a profile of sinusoidal shape. 2 / optical fiber cable according to claim 1, characterized in that at least one tube (5) consists of two oblong cells (6, 7) separated from each other by a wall (8) located in the middle of the large dimension. 3 / optical fiber cable according to claim 2, characterized in that a carrier (9) of tensile-resistant material is included in said wall (8). 4 / fiber optic cable according to claim 2, characterized in that it comprises a tube (5) consisting of two oblong cells (6, 7) and at least two tubes (1) of oblong section arranged around said tube with two cells. 5 / cable according to claim 2, characterized in that it comprises a tube (23) consisting of two cells (6, 7) oblong and insulated electrical conductors (17, 18, 19, 20) arranged around said tube. 6 / cable according to claim 1, characterized in that it comprises a tube (1) and insulated electrical conductors (10, 11, 12, 13, 14) arranged around said tube. 7 / Cable according to one of claims 1, 2, 3, 4 and 5, characterized in that the tube (1) has an elliptical section. 8 / Cable according to one of claims 1, 2, 3, 4 and 5, characterized in that the tube (1) has an oval section.