FR2800171A1 - Element of composite optical cable, has optical element(s) containing optical fiber(s) and arranged longitudinally on contact support that eventually includes reinforcing elements - Google Patents

Abstract

An element of a composite optical cable has optical element(s) containing optical fiber(s) and arranged longitudinally on a contact support that eventually includes reinforcing elements. Each optical element can be placed in any position in the cable. Independent claims are included for the following: (a) a protective sheath for a cable as above has an open U-shape between two lips. It is sufficiently stiff to remain closed but sufficiently flexible that it can be opened easily; (b) a cable including the above element and the above sheath; (c) manufacturing the above cable element by extruding the optical elements, encapsulating them with a colored coating and then with an adhesive material. The coated elements are assembled together with a ribbon like support and reinforcement is adhered between the elements; (d) use of the above cable in a cable duct.

Description

 ELEMENT <B> <U> DE </ U> </ B> CABLE <B> <U> AND </ U> </ B> CABLE <B> <U> OPTICS </ U> </ B> DERIVABLE COMPOSITES The present invention relates to a composite optical cable particularly adapted to indoor wiring, and more particularly to a type of composite optical cable. Composite optical cable allowing a bypass at any point of the cable, without intermediary burst junction box.

Many types of optical or copper cables are known for connecting offices to a broadband network capable of exchanging voice, data and images (multimedia networks).

In the case of copper, it can be considered that a cable feeds a plug, which leads to installations multiplying the cables in the parts dedicated to this function, for example false ceiling false floor. This results in congested cable trays, expensive interventions or reoperations.

In the case of optical cabling, most solutions advocate distributed type cabling that consists, from a communication center, of laying high capacity cables to sub-distribution sets, and then again to ask cables with a capacity of a few fibers up to junction boxes, and finally to put new cables to the terminal part of office. In current applications, these types of cables can be divided into two broad categories.

In the first place, we find the cables forming the central part (backbone) of a corporate network, where the search for compactness leads to cable solutions of the ribbon or compact tube type rather close to the telecommunication cables series, using multimode fibers or, more and more often, single-mode fibers. These cables are assembled from groups of fibers embedded in a resin generally polymerizable with U.V .. They try to answer in priority to the requirements of density, then to requirements of connection of mass, for example welding of the ribbons. Incidentally, they meet a breakable function allowing for example to separate two groups of ribbons (2x4, 2x8, or 3x4 fibers).

Secondly, there are the cables forming the part of the horizontal wiring, where the cables are most often made up of sheathed multi-mode fibers, that is to say coated with an extruded sheath of about 900 μm in diameter, for example. then conventionally assembled, in strands or plies, and coated with an envelope whose characteristics meet the specifications of such installations in terms of resistance to external stresses (mechanical resistance, thermal resistance and fire resistance).

Thus, patent FR 2,747,201 describes a cable comprising a plurality of optical modules and an assembly system based on a binder that surrounds each module. The separation of the modules is done by breaking the assembly system, in order to separate a group of modules from the other modules in a controlled manner. This separation also causes the breaking of the cable structure. It is only possible at the end of the cable.

In general, the cables of the prior art have interesting qualities for dense sections such as the central part (backbone) of a corporate network. However, they do not respond to an installation where the derivation function takes precedence, for example for fiber-to-desk type equipment, the cable must meet certain specific constraints. Indeed, these structures of the prior art are used by bursting at the end. Networks are then very often based on distributed-type architectures that lead to multiplying the junction points of the junction boxes and connectors, thereby burdening the overall cost of equipment and installation of optical fiber networks in buildings.

In addition to the fact that these different structures are relatively expensive, they do not allow to easily adopt economic laying techniques by separating conductors and centralized distribution of the cable network. Indeed, it is not possible to easily separate a fiber from the rest of the strand or the sheet, this separation implying the disappearance of the structure of the cable as it exists upstream of the separation. It is therefore essential to use intermediate connectors and junction boxes. The installation is then done in jerks, resulting in significant installation costs (difficult ceilings ceilings, ...) and high costs related to the large number of connection points and the cost of implementation connectors and branch boxes on the ground.

It is also known laying techniques by elementary tubes and blowing fibers or cables into these tubes as and when demand, but these techniques are ultimately quite expensive because they require the installation of tubes in a group or successive and also many junction boxes.

There is therefore a need for an optical cable permitting a bypass at any point of the cable, and not only at the end so as to feed a room or area from a central point which may consist of the main distributor-switch. without the need for a junction box or intermediate burst, which makes installation much more economical and easier.

The phenomenal increase in bandwidth in a few years and the promise of multimedia-type intranet networks, combining videoconferencing, cooperative work with various information processing and dissemination techniques, suggest that systems that would be able to offer such an economic solution will meet with great success.

Moreover, any cables they may be fragile. In addition, several cables may be necessary to power a specific area. In this case, the laying can be more complex, possibly involving heavy operations in false floor or false ceiling. On the other hand, installers can be particularly hampered by the need to place these cables in the middle of existing systems either for telecommunications or for energy, thus increasing the risks for the life of the wiring.

There are known techniques of placing optical cables in corrugated metal guards to protect them, but they are not suitable for differentiable cables at any point in their length, which is impossible in the presence of such protection. ringed.

The Applicant has developed an optical cable element and a newly designed optical cable, which can be extracted or drift very easily, at any point of the cable or the cable element, an optical element protecting one or more optical fibers, intended to feed a room or an area without junction box or intermediate burst. In addition, the cable or the cable element according to the invention is capable of guaranteeing the protection of the optical fiber or fibers included in each optical element, to guarantee the thermal and mechanical properties suitable for use in buildings or residences. in particular to have fire resistance characteristics adapted to the regulations in force, and to be very easy to install with possibly a marking of the optical elements by coloring.

The cable developed by the Applicant comprises at least one cable element and a special protective sheath adapted to this or these cable elements, that is to say protecting the cable element or elements while ensuring installation conditions. very simple, a security for the life of the cable, as well as a structural autonomy that allows all installation fields along a wall, along a rail, in a rail, in false floor or false ceiling, hollow partition, chutes ... This autonomy extends to the end point of connection, thus giving the cable efficiency and simplicity significantly reducing the overall cost and improving their reliability and flexibility, both in terms of installation only possible repairs or reinterventions.

A cable element can be used either as a component of a cable or as an independent cable element.

The invention therefore relates to a differentiable optical cable comprising a protective sheath surrounding one or more cable elements longitudinally assembled. Each cable element comprises at least one optical element containing at least one optical fiber, or the optical elements being arranged on a connection support. The optical elements are arranged longitudinally, that is to say substantially parallel to each other and relative to the support, preferably exactly parallel, to form each cable element. Each optical element can be derived at any point of the cable element and thus cable.

Another subject of the invention is a composite optical cable element, which comprises at least one optical element containing at least one optical fiber, the optical element or elements being arranged on a connection support longitudinally, that is to say substantially parallel to one another. to others and relative to the support, preferably exactly parallel. Each optical element can be derived at any point from the cable element.

cable as the cable element according to the invention can be of any length, for example up to several hundred meters long. Each cable element preferably includes a plurality of optical elements. For example, a cable element may comprise 12 optical elements.

The optical elements have a usual thickness, for example about 1 mm or any other suitable thickness that can be chosen by those skilled in the art. They usually have a circular or substantially circular section. They contain one or more optical fibers, which can be of any type used or usable in the field. In particular, it may be monomode optical fibers or multimode optical fibers; silica optical fibers or plastic optical fibers called FOPs (plastic optical fibers). An optical element may be a tube made of a suitable material surrounding one or more optical fibers, or a tight-sheathed optical fiber, that is to say an optical fiber covered with one or more extruded layers, with a total diameter of 900 tm for example. The optical elements, whether they are tubes surrounding fibers or tight sheathed fibers, are made in such a way that they leave functional freedom for the optical fibers and guarantee for each individual optical element appropriate mechanical and thermal properties, that is to say, that is to say a good quality of transmission of or fibers, a correct resistance to shocks and crushing, a suitable tensile strength, possibility of curvature and a good thermal behavior, that is to say a thermal behavior which causes no disturbance of the optical fibers in the temperature range adapted to the use of the cable.

The tube surrounding the optical fiber (s) of the optical elements may be made of a material selected from materials having a high tensile modulus (1500 to 10000 MPa), such as polyamides, polyesters (such as polybutylene terephthalate or polyethylene terephthalate). ), polyesters-ethers, styrenic derivatives (such as acrylonitrile butadiene styrene, polystyrene, polyphenylene ether alloy and styrene / butadiene). It may also be multilayer composite materials comprising a reinforcing layer based on a polymer alloy (s, liquid crystal and a thermoplastic polyester type for improving the Young's modulus of the composite optical element thus constituted and to reduce its coefficient of expansion.

In one embodiment, these optical elements are covered with a film of a suitable material to enhance the adhesion between the optical elements and the support and thus facilitate the cable assembly, while avoiding excessive adhesion and therefore leaving detachable elements easily without trace of glue. such material may be chosen from pressure-sensitive adhesives, ie adhesive by simple pressure (having a good tack), such as elastomers of the isoprene or polyacrylate type, and polar materials taken from the range of ethylene-based copolymers. such as ethylene vinyl acetate, ethylene methyl acetate, ethylene butyl acetate, and copolymers functionalized with very polar groups such as maleic anhydride or acrylic acid. These components may optionally be associated with loads to ensure the fireproofing of the material.

The optical elements can be colored to allow visual recognition of the elements, and further facilitate the use of the cable. staining can be obtained for example by using a colored material in the mass. The coloration can also be obtained by using a colored film to coat and thus color each optical element separately.

The connection support has the form of a ribbon or sheet, flexible resistant, its length being that of the cable. Its thickness may be chosen by those skilled in the art depending on the use (the strength of the cable increasing with the thickness); it will be for example about 1 mm. width, therefore the width of the independent cable element or cable, also depends on the use of said independent cable element or said cable, and in particular the number of optical elements necessary for this use. As an illustrative example, a cable element comprising 12 optical elements of thickness (or diameter) approximately 1 mm each will require a connection support of at least 12 mm, and probably about 16 mm, wide considering spaces between the optical elements.

The bonding support may be made of a coated or synthetic textile material, such as polyester nonwoven ribbon or extruded polypropylene ribbon.

The connection support may comprise any form of reinforcing elements, for example flat or cylindrical, depending on the mechanical and thermal characteristics imposed by the intended use. Such elements are commonly used in this field, and their position, shape and nature may be determined by those skilled in the art depending on the use of the cable or the independent cable member.

In some embodiments, the connection support further comprises, on its face in contact with the optical elements, a film of a suitable material to enhance the adhesion and thus facilitate the assembly of the cable, while avoiding adhesion too strong. Thus, this film allows the optical elements to take off relatively easily from the connection support without leses traces of glue harmful easy manipulation of these optical elements, while keeping a coherence of the cable element, preferable for use and the laying of such an independent cable element or a cable.

Such a material suitable for reinforcing the adhesion may be chosen from pressure-sensitive adhesives that is to say adhering by simple pressure (having a good tack), such as elastomers of the isoprene or polyacrylate type, and the polar materials taken. in the range of ethylene-based copolymers such as ethylene vinyl acetate, ethylene methyl acetate, ethylene butyl acetate and descopolymers functionalized with very polar groups such as maleic anhydride or acrylic acid. These components may optionally be associated with loads to ensure the fireproofing of the material.

The surface of the support in contact with the optical elements may advantageously have protuberances between which are placed the optical elements, protuberances introducing a small amount of material on given thickness between the optical elements. These protuberances can be formed in the profile of the support before positioning of the optical elements, or during the cable assembly. In a preferred embodiment, the protrusion height is such that it slightly exceeds the median axis optical elements. These protuberances thus create an envelope effect which, combined with the adhesion effect, ensures the cohesion of the cable element while allowing the bypass function, in particular by not causing any discomfort of the type of adhesive traces on the part 1. optical element extracted from the cable.

Preferably, the connecting support is colored or marked in any known manner, in order to facilitate identification of the cable and identification of the optical elements, themselves possibly colored.

staining may be the result of the use of colored material in the mass, or the use of a colored film surrounding the support.

optical elements thus adhere to the support in such a way that, on the one hand, the cable element or cable thus formed has sufficient coherence to be wound on a coil and to be installed by unwinding and laying in cable trays, and that, on the other hand, each optical element can be picked up or derived from its connecting support very easily at any point of the cable element or cable, without affecting the scheduling of the other components forming the cable. cable element or cable.

The link support thus provides several functions at a time. I1 provides a function of bonding or adhesion optical elements to give overall coherence composite cable or composite cable element thus formed, this connection being somehow temporary since each optical element can be easily derived and detached from the support at any location. It also provides a longitudinal and transverse mechanical strength function that contributes to the strength of the independent cable element and the cable, thus avoiding unnecessarily reinforcing each optical element. Furthermore, it can provide a function of marking the cable elements and optical elements by coloring or marking the various components of a cable or a cable element.

As detailed above, a cable according to the invention comprises at least one cable element surrounded by a protective sheath. Said protective sheath has a generally flat shape. It is sometimes referred to as the U-shaped profile. This sheath or profile is open on one of the sides, preferably one of the short sides. The constituent material is such that it stiff enough to remain closed, without necessarily that the lips on both sides of the opening touch, while maintaining sufficient flexibility so that the installer can very easily open the sheath to the level opening, spreading the lips. One of the lips preferably has a protrusion towards the other lip, possibly but not necessarily in contact with said other lip, partially closing the opening and giving the sheath the appearance of a closed sheath. Advantageously, the edges of the lips project slightly over the protuberance on one of the lips, thus facilitating the opening of the sheath at the chosen location, without the need for special tools. The sheath thus makes it easy to extract an optical element from the cable element and then from the cable.

The material used for the manufacture of the sheath is preferably inexpensive, and allows to obtain small radii of curvature and effective shock protection of the cable or cables.

A suitable material may be selected from natural rubber elastomers, styrene butylene styrene and styrene ethylene butylene styrene copolymers; flexible formulations of the range of elastomers, composed of polymers such as copolymers of ethylene and methyl acrylate, ethyl acrylate, butyl acrylate, and copolymers of ethylene and vinyl acetate, these polymers optionally being associated with flame retardant fillers and antioxidant additives, the polyester-ether type copolymers such as Arnitel copolymers manufactured by the company DSM Hytrel R manufactured by Dupont de Nemours, will preferably be one or more flame-retarded polyolefins without halogen, of the type commonly used in the cladding of cables installed in buildings.

The outer surface of the sheath may be annealed. The dimensions of the sheath will be easily adapted by those skilled in the art to the dimensions of the cable element or elements surrounded by the sheath. By way of example, these dimensions may be from 15 to 30 mm in width and from 10 to 25 mm in thickness.

The sheath containing the cable element or elements is very easy to install, makes it possible to make sharp turns while keeping sufficient resistance to pull the optical cable through risers, false ceilings, false floors, ......, which is sometimes necessary in a centralized cabling system.

The sheath or U-shaped profile advantageously comprises indentations on one of the sides. These indentations have a shape may be U, V, or half-cylindrical, or any other suitable form chosen by the skilled person. They are advantageously regularly spaced, and they make it possible to derive an optical element without risk of pinching or too tight a radius of curvature likely to deteriorate this optical element at the place of derivation and therefore of the outlet of the sheath. In addition, preferably regular notches also have a role in the flexibility-resistance compromise sought for the sheath and explained above.

thus, the sheath is a flexible and resistant protective envelope, easy to open at the chosen location for a bypass and easy to install, including in case of fairly severe curves, whose size remains modest, but which presents a great autonomy of installation and attachment in all the configurations encountered on the installation sites. Its U shape makes it possible to extract very easily, taking into account the clearance between the cable element (s) and the sheath, one or more cable elements from which one or more optical elements can be derived, before replacing the element (s). of cable in the sheath.

The overall mechanical and thermal behavior of an independent cable element or cable according to the invention is the result of the composite assembly formed of the sheath and the cable element or elements (for the cable), and the optical elements and the connecting support optionally comprising reinforcing elements for imparting greater tensile strength and, if necessary, a reduced coefficient of expansion. Moreover, each optical element has a good thermal and mechanical behavior, that is to say a behavior of the optical element taken individually over a short length which ensures good protection of the optical fiber or fibers for the desired manipulation. I1 is therefore a self-sufficient optical element when it is derived from the cable or the cable element. The cable element according to the invention can be manufactured by several different methods. These manufacturing processes in particular make it possible to ensure a form of adhesion of the components forming the cable element sufficient for the cable or cable element to be installed without risk of delamination-like disturbances but remaining extremely easy to remove by the installer to the desired length to have at a given point the optical element ready to be connected economically to the cable fitted to the part to be connected and which, preferably, is a fully prepared cable and factory equipped.

A particularly economical manufacturing method is to manufacture optical elements using a high speed extrusion process. The optical element obtained may have a single layer or several layers, for example a layer of colored material in the mass, or a layer made from a liquid crystal polymer. The extrusion can be followed by coating the optical elements obtained with a colored film. The optical elements may also be covered with a film of a suitable material to enhance adhesion.

The optical elements are then assembled in a shaping system to form a sheet of optical elements. The conformation system produced, for example, by means of series of precision rollers capable of rotating at very high speed arranged in two orthogonal planes to form a sheet with n optical elements. This sheet is then directly inserted into the die intended to produce the ribbon-shaped connection support, into which mechanical reinforcing elements may be introduced. This thus makes it possible to achieve adhesion to the composite assembly thus produced, while ensuring easy separation of optical elements on the site.

In another manufacturing method, the connecting support is extruded separately in such a way that protuberances are accurately formed in the profile of the support, the optical elements being then inserted slightly by force, and this, in particular thanks to the elasticity of the material. constituting the link medium. This method of manufacture has the advantage of not requiring to wear the optical elements at high temperatures as occurs at the extrusion heads. Furthermore, the support can then be colored or marked in a known manner, for example by coating with a thin colored film, independently of the optical elements.

In another method of manufacture, the sheet of optical elements constituted by the conformation system is plated on the non-reinforced tape after the latter and / or the optical elements have been coated or glued, using a film of a material suitable for reinforcing the adhesion of the optical elements and the cohesion of the composite assembly thus formed, while ensuring the easy separation of the optical elements.

Thus, the main features of the independent cable element and the cable comprising at least one cable element are united through two essential factors.

The first of these factors is the realization of a thin optical element, self-sufficient when it is derived from the cable or the cable element, that is to say ensuring the protection and thermal behavior and mechanics of the fiber ensuring by proper decoupling the correct resistance crushing and ensuring a basic tensile strength adapted to the desired use, in particular a minimum tensile strength, good bending behavior and a Minimum bending radius suitable for the desired application, after the separation function, and a cumulative tensile strength quite acceptable for the complete wiring at the time of installation.

second factor is constituted by a simple function of adhesion between the optical elements themselves, and also between the optical elements and the connection support, which ensures a sufficient cohesion during the installation, in particular by unwinding and laying on rails conventionally used in the field in corporate networks to enhance the mechanical strength of the assembly, while allowing a simple, easy, and safe way, a derivation of the optical elements one by one at any point intended to power a room or a set of parts to be connected, without traces of adhesive, the cable or cable element retaining its structure downstream of the portion derived from the optical element.

The manufacture of the optical cable according to the invention is easy, insofar as the sheath such as the cable element or elements forming the cable can be extruded packaged in great length in a very economical way; the optical cable can therefore be manufactured continuously by assembling the various elements (one or more cable elements manufactured according to one of the methods described above and a sheath) by a simple management of the number and nature of the optical elements by cable element, and the number of cable elements per sheath. Alternatively, the single cable element or the cable elements stacked on each other is inserted into the protective sheath.

When or after the installation of an independent cable element or a cable according to the invention, an optical element is extracted or derived at any given point of the cable or cable element, by section of the cable. optical element then simple separation and exit of the sheath of this optical element to a suitable length, that is to say a length sufficient to place the fiber or fibers contained in said optical element is waiting for connection near the office or from the zone to be equipped, either directly to the optoelectronic socket. This avoids the intermediate boxes and manipulations are minimized, the wiring of the office or area being done in a second time, for example from a preconnectorized set. It reduces the risks of malfunction, and the ultimate interventions and repairs for either changing the office or zone are very simple.

The portion of the optical element extracted or derived from the cable element or cable has sufficient mechanical and thermal resistance characteristics to be considered as a self-supporting optical element waiting to be wired to the part (s) ) or zone (s) concerned by this optical element.

The optical element portion which is derived from the cable member may be threaded into a micro-sheath, for example a ringed micro-sheath.

The derivation of the optical element can be ensured by simple positioning of a suitable clamp around the sheath or U-shaped profile. A bypass is thus produced which guarantees the protection of the optical cable assembly without requiring any connection and preserving all integrity of the cable elements. The qualities of a single installation of the cable or of the cable element, a range of autonomy of the whole point of installation and attachment to all the support structures encountered on the building sites, and a possibility of derivation at any point in the network by simple extraction of the optical element.

The downstream part of the optical element thus derived from the structure of the independent cable element or cable is considered lost, that is to say that the optical fibers it contains are no longer functional. However, the optical element is always present in the cable or the independent cable element. The cable or independent cable element downstream of the branch therefore retains its structure and general mechanical and thermal behavior, which is very important for the overall behavior of each fiber.

It may be thought a priori that such a technique of losing wired fiber is expensive. It is not the case, quite the opposite. The considerable reduction in the cost of fibers, especially single-mode fibers, and the high-speed extrusion techniques used to produce the optical elements make them extremely economical, and the interior wiring which is favored the composite optical cable differentiable according to the invention, that the loss of 50 to 100 m or more fiber in an optical element is significantly more economical than spending a lot of time in the installation of these networks both for installation only for taps and for mounting junction boxes and multiple field connections.

The cabling technique according to the invention thus opens the field to a very great economy on optical fiber enterprise networks in that the last part of the wiring between the workpiece and the end of the portion of the optical element derived cable can be made by a fast and economical technique. Indeed, the cable equipping the part to be connected may include a set entirely preconnectorized and therefore prepared in the factory. This assembly can be composed as an example of an optoelectronic plug or a passive plug of a portion of cable that will be connected very simply to the portion derived from the optical element by using small devices like optical dominoes well known to those skilled in the art and very economical both from the point of view of the parts constituting these connections as time on the site to make the connection. Moreover, it can be seen that at this stage of the simplicity of the wiring, the cable may contain one or more optical fibers, the very simple devices for exploding optical fibers that exist industrially, being compact and economical.

In addition, these short-length networks absolutely do not need to aim for very high performance for fittings, thus further facilitating the economic approach of such quick couplings. It is thus possible to envisage, according to the topology of the planned network, to equip each optical element with several fibers and to make a domino allowing bursting on n office equipment cables. Mixed cables can also be envisaged combining multimode fibers with single-mode fibers, mixing silica optical fibers or FOPs, mixing optical elements containing one or two fibers. It can thus be seen that the great qualities of the cable or of the independent cable element according to the invention are to allow a simple separation or derivation, preferably thanks to an excellent color identification and by apparent separation of each optical element on the sheet, to preserve after separation or derivation all the functionalities of an optical element easy 'handle without risk for the installer, while keeping for all a cohesion of the wiring tablecloth made by the composite according to the invention made of an adhesion between the optical elements and the bonding support and a persistence of the composite structure over the entire length (except the derived parts optical elements).

It can be seen that this is therefore a differentiable cable or element of independent cable very adapted to a very economical laying technique, which gives priority to the qualities of optical fiber cables, and particularly to single-mode or multimode optical fiber cables, to the detriment of the complex and particularly expensive optical connections to be made on a site involved by the devices of the prior art.

In this type of application, the density function does not appear to be essential, since such a cable retains perfectly acceptable dimensions and in no way harmful to laying in cable trays practically generalized for computer wiring. The lightness of the optical cable thus produced, the presence of a bare minimum of relatively expensive reinforcing elements and the application of a centralized wiring method which reduces to its simplest expression the intermediary connection elements make it a particular cable. suitable for enterprise optical cabling in the terminal part of networks.

Other features and advantages of the invention will become apparent upon reading the following description of a particular non-limiting embodiment of the scope of the invention, with reference to the figures in which - FIG. sectional view of a cable according to the invention, comprising two cable elements, - Figure 2 is a perspective view of a protective sheath of a cable according to the invention, having notches, an optical element being derived from 3 is a cross-sectional view of a cable element according to one embodiment of the invention; FIG. 4 is a cross-sectional view of a connection of a cable element having protuberances according to FIG. An embodiment of the invention - Figure 5 is a cross-sectional view of a cable element according to another embodiment of the invention.

FIG. 6 is a sectional view of a cable according to the invention, the derivation of an optical element being provided by a clamp, FIG. 7 is a schematic view from above of a cable element according to an embodiment. Of the invention, one of whose optical elements has derived, - Figure 8 schematically shows general organization of a cabling irrigating several areas from a single central point.

Figure 1 shows a cable 1 according to the invention. This cable comprises two cable elements 2 stacked and surrounded by a protective sheath 9. A space e is preferably left free between the cables and one side of the sheath.

The protective sheath 9 of a cable 1 according to the invention is shown in FIG. 2. It is generally U-shaped, open on a small side between the lips 11. One of the lips 11 has a protuberance lb partially closing opening and giving it a closed sheath appearance. The edges 11a of the lips 11 project slightly over the protuberance 11b, thus facilitating the opening of the sheath at the chosen location. An optical element 4 of a cable element can be pulled out at notches 10 present in the protuberance 11b.

FIG. 3 represents a differentiable composite optical cable element 2 according to the invention. I1 comprises optical elements 4, each protecting one or more optical fibers 3, and a ribbon connection support 5 in this case comprising reinforcing elements 6. The optical elements 4 are made in such a way as to leave a functional freedom 3. The connection support 5 is an extruded support whose shape has protuberances 7 facilitating adhesion between the optical elements 4 and the connection support 5. These protuberances 7 are such that they introduce a small amount of material between the optical elements 4, and their height h is such that it slightly exceeds the median axis xx 'of the optical elements 4.

FIG. 4 shows the connection support 5 of a cable element, comprising protuberances 7, into which the optical elements 4 will be inserted.

In the embodiment shown in FIG. 5, the connection support 5, of flat or ribbon shape, covered on one side with a film of material 8 strongly adhering to the connection support 5 holding optical elements 4.

FIG. 6 shows a cable comprising two cable elements 2 surrounded by a cladding sheath 12 adapted to the sheath, at the level of the branch of an optical element 4a which is protected by a corrugated micro-sheath 13.

It can thus be seen that the cable according to the invention is a cable whose intrinsic qualities make it possible to envisage a centralized type of wiring from easily differentiable optical elements to a determined distribution point, containing one or more fibers allowing an easy and scalable connection to an office or any other area to be wired. The low cost of optical element allows a lost part largely compensated by the fact that such a resistant light cable can be installed easily and quickly in risers and in cable trays intended for building wiring by avoiding many boxes of cables. derivation provided in distributed type wiring.

FIG. 7 shows a cable element 2 comprising eight optical elements 4 each protecting one or more optical fibers 3. An optical element 4 'has cut at the level of the section A and extracted or derived the cable element 2. The drifted part 4 4 'optical element is waiting for connection, for example clipped into a device 4 adapted to the room or the area to be equipped. The downstream part 4'b of optical element 4 'derived from the cable element 2 is considered lost, but the cable element 2 downstream of the branch retains its structure, in particular its connection support and the optical elements .

The last part of the wiring between the part or the zone to be connected and the derived end 4 'of the optical element 4' extracted from the cable element 2 can be carried out by a simple and economical technique, which in this mode of realization comprises a set 16 fully preconnectorized and therefore can be prepared in the factory. This assembly is composed of an optoelectronic plug or a passive plug 17 of a cable portion 18 which will be connected very simply to the derived portion 4'a by using small devices such as optical dominoes 15 well known to the craftsman.

Figure 8 shows schematically the general organization of a cable irrigating several areas from a single central point, through the cable or cable elements according to the invention. The central point of such a centralized system is here a splitter-switch 20. The cable 1 or cable element 2 irrigates all the areas or offices to feed 19.

 At the level of each zone, an optical element 4a, which is clipped into a suitable device 14 or into a clip 12 fitting to the sheath, is extracted or drifted so as to be placed waiting for connection at the level of the zone. or office 19, to result in boxes 17 which may be the terminal element of an optoelectronic plug or a passive plug. The derived optical element is therefore easily connected to the zone or the office in an easy and scalable manner by means of a cord advantageously preconnectorized and prepared in the factory, reducing the final cost of the installation and allowing in case of evolution , for example for the terminal plug, to modify very simply the terminal architecture of the network. It is also very easy, in some cases, to equip the desktop socket directly from the optical element derived from the cable or the cable element.

Claims (8)

A composite optical cable element characterized in that it comprises at least one optical element) containing one or more optical fibers (3) and arranged longitudinally on a connecting support (5), said connection support optionally comprising reinforcing elements. (6), each optical element being derivable at any point of said cable. Cable element according to claim 1, characterized in that each optical element (4) consists of a tight sheathed optical fiber or a tube surrounding one or more optical fibers. 3. Cable element according to claim 2, characterized in that the material forming the tube is selected from materials having a high tensile modulus that is to say 1500 to 10000 MPa, such as polyamides, polyesters such as polybutylene terephthalate or polyethylene terephthalate, polyesters-ethers, styrenic derivatives such as acrylonitrile butadiene styrene, polystyrene, polyphenylene ether and styrene / butadiene ether alloy); and multilayer composite materials comprising a reinforcing layer based on an alloy of liquid crystal polymer (s) and a polyester type thermoplastic. 4. Cable element according to any one of claims 1 to 3, characterized in that at least one optical element (4) and / or the connection support (5) is colored, in particular by coloring in the mass or presence of a colored film. 5. Cable element according to any one of claims 1 to 4, characterized in that the optical element or elements (4) leave a functional freedom optical fibers and guarantee for each optical element taken individually mechanical and thermal properties. Cable element according to one of Claims 1 to 5, characterized in that the connecting support (5) is made from a coated or synthetic textile material, such as a non-woven polyester ribbon or a extruded polypropylene ribbon. Cable element according to one of Claims 1 to 6, characterized in that the connecting support (5) and / or the optical element (s) (4) is covered with a film of a material suitable for or the optical elements (4) adhere to each other and support connection while being differentiable (s) easily in any place without traces of glue. 8. Cable element according to the claim characterized in that the material is selected from pressure-sensitive adhesives that is to say single-stick adhesive such as elastomers of the isoprene polyacrylate type, and polar materials taken in the range of copolymers based on ethylene such as ethylene vinyl acetate, ethylene methyl acetate, ethylene butyl acetate, and copolymers functionalized with very polar groups such as maleic anhydride acrylic acid, all these materials possibly being be associated with charges. Cable element according to one of Claims 1 to 8, characterized in that the connecting support (5) has at its surface in contact with the optical element or elements (4) protuberances (7), height h is preferably such that it slightly exceeds the median axis xx 'of the optical element or elements. . Protective sheath (9) of a cable element according to any one of claims 1 to 9, characterized in that it has a U-shape open on one side between two lips (11), preferably on a short side, and in that it is made of a material stiff enough to remain closed but elastic enough to be easily opened. . Protective sheath according to the claim characterized in that the material is selected from natural rubber elastomeres, styrene butylene styrene and styrene ethylene butylene styrene copolymers flexible formulations of the elastomer range, composed of polymers such as copolymers of ethylene and diene. methyl acrylate, ethyl acrylate butyl acrylate, and copolymers of ethylene and vinyl acetate, these polymers being optionally combined with flame retardant fillers and antioxidant additives polyester-ether type copolymers such as Arnitel copolymers manufactured by the company DSM or Hytrel manufactured by the company Dupont Nemours; preferably one or more flame-retardant polyolefins without halogen. 12. Sheath according to claim 10 or characterized in that one of the lips (11) comprises protuberance (11b) towards the other lip, thus partially closing the opening. 13. Sheath according to any one of claims 10 to 12, characterized in that it comprises on one side of the notches (10), preferably regularly spaced. 14. Sheath according to any one of claims 10 to 13, characterized in that the edges (11a) of the lips (11) project slightly above the protuberance (11b) present on one of the lips. 15. Composite optical cable (1), characterized in that it comprises at least one cable element (2) according to any one of claims 1 to 9, surrounded by a protective sheath (9) according to one of any of claims 10 to 14. 16. A method of manufacturing a cable element (2) according to any one of claims 1 to 9, characterized in that. - the optical element (s) (4) having one or more layers by high speed extrusion is produced, - the optical element (s) are optionally coated with a colored film, - the optical element or elements of a film are optionally coated. of a suitable material for reinforcing the adhesion, - the optical element or elements are assembled in a conformation system in order to constitute a sheet of elements, said sheet of elements is introduced directly into the die forming the connecting support ( 5) in ribbon, in which is optionally introduced at least one reinforcing element (6), to create adhesion between the optical elements and the support. . A method of manufacturing a cable element (2) according to any one of claims 1 to 9, characterized in that - the optical element (s) (4) having one or more layers is produced by high-speed extrusion; the optical element (s) are optionally coated with a colored film, the optical element (s) is optionally coated with a film of a material suitable for reinforcing the adhesion, the optical element (s) is assembled in in order to form a sheet of elements, the connection support (5) is extruded separately, into which at least one reinforcing element (6) is optionally introduced, so as to form protuberances (7) in the profile of the support binding, the support is optionally coated with a colored film, - the film is optionally coated with a film of a suitable material to reinforce the adhesion, - plate of elements on the connecting support to insert the optical elements in the protuberances. 18. A method of manufacturing a cable element (2) according to any one of claims 1 to 9, characterized in that one or more optical elements (4) having one or more layers by high speed extrusion is produced, the optical element (s) are optionally coated with the colored film, - the optical element (s) are assembled in a conformation system in order to form a sheet of elements, and the connection support (5) is extruded separately. the reinforcement element (6) is preferably coated with a colored film, - the support and / or the optical elements are coated with a film of a material suitable for reinforcing the adhesion; elements on the connection support to create adhesion between the tubes and support. 19. A method of manufacturing an optical cable (1) according to claim 15, characterized in that one or more cable elements (2) manufactured by the method according to any one of claims 16 to 18 and a sheath are assembled. protector (9) extruded at high speed. 20. Use of a cable element (2) according to any one of claims 1 to 9, characterized in that the cable element (2) is placed in a cable tray, and an optical element (4) is derived at any point by section and then simply detachment of the optical element to a suitable length for connection with the cable of the workpiece to be connected, said cable of the part being preferentially preconnectorized, the part of the optical element in downstream of the branch being inactive but remaining present on the cable element. 21. Use of a cable (1) according to claim 15, characterized in that the cable (1) is placed in a cable tray, and an optical element (4) is derived at any point by section and then simple detachment and output of the sheath (9) this optical element to a suitable length, in connection with the cable of the workpiece to be connected, said cable the part being preferentially preconnectorized, the portion of the optical element downstream of the branch being inactive but remaining present the cable. Use according to claim 21, characterized in that the cable element (2) is out of the sheath (9) by spacing the lips (11) facilitated by the possible presence of the edges (11b), then an optical element (4). ) is derived from the cable element and the cable element is replaced in the sheath. 23. Use according to claim 21 or characterized in that the portion of the optical element) is derived is threaded into a possibly annealed micro-sheath. 24. Use according to any one of claims 21 to 23, characterized in that derivation of the optical element is provided by simple positioning of a clamp (12) adapted around the sheath.