EP1325374A1

EP1325374A1 - Telecommunication cable with optical fibre modules

Info

Publication number: EP1325374A1
Application number: EP01972187A
Authority: EP
Inventors: Patrick Jamet; Nathalie Lecourttier; Daniel Bernier
Original assignee: Sagem SA
Current assignee: Silec Cable SAS
Priority date: 2000-10-09
Filing date: 2001-09-21
Publication date: 2003-07-09
Also published as: US20030168243A1; US6937802B2; JP2004519706A; KR100487248B1; CA2418286A1; WO2002031568A1; AU2001291976A1; FR2815141A1; BR0113386A; FR2815141B1; KR20030051621A

Abstract

The invention concerns a telecommunication cable comprising a very high number of modules (MO) each with a retaining cladding (3) of slight thickness enclosing optical fibres (1-2). So as to facilitate the flaring and locating of said modules, retaining sheaths (4) contain each several respective modules and are mechanically coupled to the cladding modules (3) of the respective modules so as to form super-modules (SM) in contact with an external jacket (6-7). The retaining cladding (4) of a super-module (SM) comprises at least an identification colour or thread to distinguish the super-module from the other super-modules.

Description

Telecommunication cable with fiber optic modules

The present invention relates to a telecommunications cable comprising fiber optic modules. For example, the cable is a unimodal fiber cable for transmitting high speed telephone and / or data processing signals, in particular in a local network or between telephone exchanges or other switching or routing devices.

European patent EP 0 468 878 discloses a telecommunications cable consisting of a series of optical fibers arranged in an envelope and divided into modules each enveloped in a retaining sheath of small thickness, easily tearable. The retaining sheaths ensure cohesion of the modules and are in contact with the optical fibers to grip them without uncoupling the optical fibers. The envelope, which may contain an internal layer, preferably extruded, and a second external layer ensuring the final presentation of the cable, is in contact with the sheaths for holding the modules to form a compact assembly. The number of optical fibers in such a cable can be very large and exceed a few hundred or even a few thousand. This high number of fibers poses practical problems, in particular during operations for connecting the ends of the optical fibers of the cable to the ends of the optical fibers of one or more other cables. The different colors assigned to the module holding sheaths are typically limited to a dozen. Consequently, when the cable comprises a very large number of optical fibers which are distributed at the rate of three to a dozen fibers per module for example, several modules of the same color are present in the cable. This slight disparity in the colors of the retaining sheaths makes it difficult to identify the modules and their development and assembly into sub-assemblies respectively to be connected to other cables, and can cause connection errors.

The present invention aims to solve the practical problems mentioned above and in particular to facilitate the development of optical fibers and their identification in a telecommunication cable containing a very large number of sheathed modules of optical fibers.

To this end, a telecommunication cable with several modules, each comprising a thin holding sheath enclosing optical fibers, and an envelope surrounding the modules, is characterized in that it comprises holding sheaths which each contain several modules. and which are each mechanically coupled to the retaining sheaths of the respective modules so as to form super-modules in contact with the envelope, and the retaining sheath of a super-module comprises an identification means for distinguishing the super- module of the other super-modules in the cable.

By bringing the modules together into super-modules identified by different supermodule holding sheaths from one another, the groups of modules respectively contained in the super modules can be expanded separately. The number of super-modules in the cable, for example of the order of a dozen being significantly lower than that of the modules, the means of identification of the super-modules are different from each other. This avoids confusion between modules holding sheaths with the same color respectively included in super-modules.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description of several preferred embodiments of the invention with reference to the corresponding appended drawings in which: FIG. 1 is a very enlarged schematic perspective view of a super-module according to the invention, containing six fiber optic modules;

- Figure 2 is a greatly enlarged section of a cable containing four super-modules according to the invention.

As shown in FIG. 1, a super-module SM included in a telecommunication cable according to the invention comprises several fiber optic modules MO, for example six in number, and more generally at least two fiber optic modules MO. The relatively small number of MO modules in the super-module SM makes it possible to clearly distinguish the modules from one another. For example, the sheaths 3 for holding the modules in each super-module have different colors from one another. In a manner known by patent EP 0 468 878, each MO module comprises several optical fibers 1-2 each having a silica core 1 coated with a colored identification layer 2, and a retaining sheath 3 of small thickness, easily tearable , holding fibers 1-2 together. The 2 layers of the fibers in the MO module have different colors from each other. The retaining sheath 3, called "microgaine" (μGaine (registered trademark)), is in contact with the optical fibers and is mechanically coupled with the optical fibers to enclose the latter. The preceding coupling means that a tensile force exerted on the retaining sheath 3 translates the optical fibers 1-2 integrally in the sheath, and conversely a tensile force exerted on the fibers translates the retaining sheath integrally. The coupling ensures cohesion of the retaining sheath and of the fibers that it contains and thus a high compactness of the module thus formed. For example according to FIG. 1, an MO module comprises 3 to 12 optical fibers. The holding sheaths 3 of the MO modules are adapted to the characteristics of the materials constituting the optical fibers in order to enclose the latter with coupling so that the expansion and

^'Shrinkage caused by temperature changes are much lower than the stresses that damage the optical fibers. The small thickness of the holding sheaths 3 avoids subjecting the fibers 1 to elongation and compression stresses during thermal cycles.

The super-module SM also includes a retaining sheath 4 surrounding all of the respective modules MO contained in the super-module so as to group them together and hold them together. The sheath 4 is in contact with the retaining sheaths 3 of the MO modules and is mechanically coupled with the retaining sheaths 3 of the modules to grip them. The thickness of the sheath 4 is at most of the order of a few tenths of a millimeter, typically 0.1 to 0.5 mm.

Like the material constituting the retaining sheaths 3 of the MO modules, the material of the sheaths 4 of the super-module SM is an amorphous thermoplastic material, for example polyvinyl chloride PVC, or an elastomer; or else a thermoplastic material, for example a polyethylene, a polypropylene, or a polyolefin such as ethylene / vinyl acetate EVA, which may contain at least one of the following mineral fillers: chalk, kaolin, silica, talc, calcium carbonate , alumina or magnesium hydrate, titanium oxide. The material of the retaining sheath 4 of the super-module SM is preferably put in place by extrusion around all of the respective modules MO simultaneously at the drawing and at the assembly of the modules MO and at the same time at the drawing and at the assembly 1-2 optical fibers in the MO modules, the assemblies preferably imparting twists in alternating directions periodically.

A filling material 5 fills the interior of the retaining sheath 3 of each module MO, between the optical fibers 1-2 contained in the module. The filling material 5 is a sealant, such as gel or oil or silicone or synthetic grease, with which the optical fibers are coated prior to their passage through an extrusion die of the retaining sheath 3 of the module. In order to further complete the seal along the inside of the cable, the filling material 5 fills the entire space between the MO modules and the retaining sheath 4 of the SM super-module, the MO modules being coated with the material 5 when they pass through a sheath extrusion die 4. According to other variants, the filling material 5 is produced by "dry process" by combining swelling powder and / or swelling strings and / or swelling tapes in the presence of water so as to form a plug which prevents the propagation of the water on the one hand between the optical fibers 1-2 inside the holding sheath 3 of each MO module, on the other hand between the MO modules inside the holding sheath 4 of the super-module SM.

Referring now to FIG. 2, a telecommunication cable CA according to the invention comprises at least two super-modules SM, and more generally several super-modules SM in number equal to four according to the example illustrated.

The SM super-modules are grouped in an outer casing 6-7 of the cable in contact with the holding sheaths 4 of the super-modules to form a compact assembly. The outer envelope 6-7 is preferably constituted by one or more extruded layers, at least one of which preferably includes ribbons and / or embedded or extruded mechanical reinforcements. According to the example illustrated in FIG. 2, the external envelope 6-7 comprises an internal layer 6 in contact with the retaining sheaths 4 of the SM supermodules, and an external layer 7 which is thicker than the internal layer 6.

As inside the super-modules SM and MO modules, the filling material 5 preferably fills the entire space between the super-modules SM inside the cable casing 6-7 so as to improve cable tightness. The holding sheath 4 of each super-module SM comprises a respective identification means for identifying the super-module in order to identify it and distinguish it from the other super-modules contained in the cable CA, particularly during a flourishing operation. super-modules SM and modules MO in order to connect the ends of the fibers 1-2.

According to a first variant, the retaining sheath 4, as an identification means, comprises a colored external identification film coating varying from a few thousandths of a millimeter to a few tenths of a millimeter, like the retaining sheaths 3 of the optical fibers 1 -2. As a variant, the colored external film coating is replaced by coloring in the mass of the sheath 4. At least the external faces of the sheaths 4 of the super-modules then have different colors from one another.

According to a second variant shown in FIG. 1, which can be combined with the first variant, the means for identifying the super-module comprises one or more threads, or bands, 8 having predetermined colors different from each other and with respect to the sheath 4. More generally, the colors of the threads 8 of each super-module are different from the colors of the threads on the sheaths 4 of the other super-modules SM in the cable CA. The colored threads 8 extend longitudinally or helically on the sheath 4, and are either extruded simultaneously with the extruded sheath 4, or printed for example with one or more inks or indelible paints on the sheath 4. The threads 8 have a small width and can be substantially in relief on the external surface of the sheath 4. According to a third variant also shown in FIG. 1, the means for identifying the supermodule SM comprises a mark or sign composed of alphanumeric characters such as SMX, in which X is for example the number of the super-module, which is marked on the sheath 4 preferably periodically and longitudinally and / or helically on the sheath. The SMX mark, like the thread (s) 8, is preferably fluorescent so that it is more visible in low light.

In a similar way to the optical fibers 1-2 in the MO modules, and the MO modules in the sheaths 4 of the super-modules SM, the holding sheaths 4 are produced simultaneously with a drawing and an assembly of the MO modules twisted in SZ . The supermodules SM are preferably extruded in an extrusion line called SZ and thus twisted together in opposite and alternating twist directions, that is to say alternately having a section with direct helix pitch and then a section with retrograde propeller steps.

Claims

1 - Telecommunication cable with several modules (MO) which each comprise a thin sheath (3) enclosing optical fibers (1-2), and an envelope (6-7) surrounding the modules (MO), characterized in that it comprises holding sheaths (4) which each contain several respective modules (MO) and which are each mechanically coupled to the holding sheaths (3) of the respective modules so as to form super-modules (SM) in contact with the casing (6-7), and the holding sheath (4) of a super-module (SM) comprises an identification means (8, SMX) to distinguish the super-module from the other super-modules in the cable (CA).

2 - Cable according to claim 1, wherein the retaining sheath (4) of each super-module (SM) is put in place by extrusion around the respective modules (MO) that the supermodule contains.

3 - Cable according to claim 1 or 2, wherein the holding sheaths (4) of the supermodules (SM) are produced simultaneously with a draw and an assembly of the modules (MO).

4 - Cable according to any one of claims 1 to 3, in which the super-modules

(SM) are twisted in opposite and alternating directions of twist.

5 - Cable according to any one of claims 1 to 4, wherein the sheath holding (4) of each super-module (SM) has a thickness at most of the order of a few tenths of a millimeter.

6 - Cable according to any one of claims 1 to 5, wherein the holding sheaths (4) of the super-modules (SM) are made of the same material as the holding sheaths (3) of the modules

(MO).

7 - Cable according to any one of claims 1 to 6, wherein the material of the holding sheaths (3) of the super-modules (SM) is an amorphous material, or an elastomer, or a thermoplastic material, which may contain mineral fillers.

8 - Cable according to any one of claims 1 to 7, wherein the identification means of the super-modules consist of colors of the holding sheaths (4) of the super-modules different from each other.

9 - Cable according to any one of claims 1 to 8, wherein the identification means of the super-modules (SM) consist of different colors from each other at least for the external faces of the holding sheaths (4 ) super-modules.

10 - Cable according to any one of claims 1 to 9, wherein the means for identifying the retaining sheath (4) of each super-module (SM) comprises one or more colored threads (8) having colors different the from each other and relative to the sheath (4) and / or different from the colors of the threads on the retaining sheaths of the other super-modules.

11 - Cable according to any one of claims 1 to 10, wherein the identification means of a super-module (SM) comprises a mark (SMX), preferably periodically marked on the retaining sheath (4) .

12 - Cable according to any one of claims 1 to 11, wherein the holding sheaths (3) of the modules (MO) in each super module (SM) have colors different from each other.

13 - Cable according to any one of claims 1 to 11, wherein the envelope (6-7) comprises at least one extruded layer, preferably including ribbons and / or mechanical reinforcements embedded or extruded.

14 - Cable according to any one of claims 1 to 11, comprising a sealant (5) filling at least the space between the super-modules (SM) inside the envelope (6-7 ).