FR2913777A1 - Optical cable for connecting set of feed points to distribution network, has protective enclosure surrounding main optical fiber modules, and internal optical fiber module connected to one main optical fiber module - Google Patents

Abstract

The cable (100) has a protective enclosure (2) surrounding main optical fiber modules (11-14), and an external sheath surrounding optical fibers of the modules, where the sheath has an external layer (21) made of high density polyethylene. An internal optical cable (5) is provided inside the envelope. The cable (5) has an internal optical fiber module (52) with optical fibers (53), where the module (52) is connected to one of the modules (11-14). Tubes (3) are immobilized between a central carrier element (4) i.e. fiber reinforced plastics (FRP) type reinforcement element, and the envelope. An independent claim is also included for a method for connecting a set of feed points to a distribution network using an optical cable.

Description

Optical cable for connection to a general distribution network and

  The present invention relates to an optical cable for connection to a general distribution network and to a method for connecting said cable. The invention typically, but not exclusively, applies to the field of optical cables for connecting a plurality of power points to said general distribution network.

  The supply points can for example be located in subscribers or in junction boxes for supplying a branch network. Document FR2887639 discloses a structure of an optical cable 1 as represented in FIG.

  The optical cable 1 comprises main modules 11, 12, 13, 14 of optical fibers, all of said modules being surrounded by a closed protective envelope 2a of circular section and having an inner surface 2b. Each main module 11, 12, 13, 14 comprises an outer sheath 110 and a plurality of optical fibers 111 contained in the outer sheath 110, said outer sheath 110 being formed of a material having a low coefficient of dynamic friction. The main modules of optical fibers are arranged inside the protective envelope 2a so that they have sufficient clearance to facilitate their extraction.

  The clearance is such that the area of the sum of the sections of the set of main modules of optical fibers contained in the protective envelope 2a is less than 75% of the area of the section of the inner surface 2b of the protective envelope. These features facilitate the extraction of each main module 11, 12, 13, 14 of the optical cable 1 and pushing the main module in a microconduct to the connection point over a long length.

  The typical method of connection by means of this optical cable is also described in the document FR2887639. In a first step, a first opening is made in the protective envelope 2a at a first zone using a dedicated tool. The first opening provides access to the main modules 11, 12, 13, 14 of optical fibers contained in the protective envelope 2a. One of the main modules 11 of optical fibers that is to be diverted to a feed point is selected and then cut off near the first opening.

  In a second step, a second opening is made in the protective envelope 2a at a second zone, remote from the first zone along the optical cable 1. In a third step, a portion of said main module 11 is removed. . For this purpose, the main module 11 is pulled through the second opening so as to extract the sectioned portion of main module 11. In a fourth step, the portion of the main module 11 is inserted in a microconduct by pushing, drawing or blowing in the pre-installed microconduit. The microconducting extends between the main pipe in which the optical cable 1 is placed and a feed point at the subscriber or in a junction box. However, during the third connection step described above, the arrangement of the optical fiber main modules 11, 12, 13, 14 inside the protective envelope 2a of the optical cable 1, presents the disadvantage of intermingling and jamming despite the presence of the outer sheath 110 low dynamic coefficient of friction. In addition, the slightest infiltration inside the optical cable 1, in particular by the damage of the protective envelope 2a, can cause certain damage to the extraction of said main modules.

  Indeed, the infiltration, for example of sludge, inside the optical cable 1 generally leads to the aggregation of the main modules 11, 12, 13, 14 of optical fibers thus making it difficult to extract them. Consequently, it becomes very difficult to extract a main optical fiber module over a long distance, to perform multiple extractions of different main optical fiber modules within the same optical cable and thus to easily connect them to a single fiber optic module. feeding point. In addition, the method for connecting the optical cables, said stitching method, as described in the document FR2887639, is not optimized in the number of connection operations. Also the technical problem to be solved by the object of the present invention is to propose an optical cable comprising one or more optical fiber main modules comprising at least one optical fiber, the main module (s) being surrounded by an outer sheath, and a protective envelope surrounding the at least one main module of optical fibers, said optical cable making it possible to avoid the problems of the state of the art. The solution of the technical problem lies, according to the present invention, in that said optical cable further comprises an internal optical cable inside said protective envelope, said internal optical cable comprising at least one internal module of optical fibers, and in that at least one internal optical fiber module of the internal optical cable is connected to at least one of the optical fiber main modules of the optical cable. By main module is meant any module of optical fibers that can be extracted from the optical cable over long lengths, for example up to a hundred meters, for connection to localized power points, for example in subscribers or in branch boxes for supplying a branch network. The end of the internal optical cable can thus be connected to the main optical fiber modules by connection means, thus allowing end looping to extract twice (double extraction) a different portion of the same main module during operations. connecting to power points. At one end of the cable, the optical fibers of the internal modules of the internal cable can thus be advantageously connected to the optical fibers of the main modules of the optical cable to ensure the continuity of the optical transmission in said optical cable. In other words, this is an end loop. For example, the connection means between the main and internal modules can be performed by welding or by means of a mechanical connector.

  In a particularly preferred embodiment, the optical cable further comprises n main modules of optical fibers, n being an integer such as 1 n 3, disposed inside a tube of their own, said n main modules being free inside said tube, and a carrier member within said protective envelope, each of said tubes being immobilized between said carrier member and said protective envelope. Advantageously, the n main modules of each tube are isolated from n other main modules of optical fibers, which significantly limits the risk of entanglement of the main modules when they are connected to the power points.

  The tubes also protect the n main modules from any aggregation that may be caused by infiltration of sludge inside the optical cable and thus ensure optimized extraction of said n main modules. In addition, each main module can slide inside the tube and be easily extracted from said tube since the n main modules are arranged in the tube cavity with sufficient clearance. In addition, the carrier member arranges the arrangement of the tubes around said element to have easy and quick access to said tubes when connecting the main modules.

  Finally, the immobilization of the tubes has the advantage of facilitating the extraction of the n main modules inside each tube. The connection of the main optical fiber modules to different power points is thus facilitated.

  Advantageously, n is equal to 1, or in other words, each of the main optical fiber modules is disposed inside a tube of its own. Thus, each main fiber optic module is totally isolated from the other main optical fiber modules, which prevents them from becoming entangled during their connection. The extraction of the main modules of optical fibers is then optimized significantly. In a particular embodiment, the section area of the main module (s) is less than 80% of the cross-sectional area of the inner surface of the tube. The n main modules can thus be easily extracted from their tube, in particular by a blowing process. In another particular embodiment, the tube or tubes are stranded around the carrier element. Any type of configuration, or in other words any type of stranding, well known to those skilled in the art can be used, in particular a so-called helical configuration of S or Z type or a so-called inverted oscillation SZ type configuration. . The configuration of the tube or tubes around the carrier element type S-Z 25 is particularly preferred since it allows easier and faster access to the various tubes around the carrier element. According to a characteristic of the present invention, the carrier element is a reinforcing element making it possible to have good mechanical strength of the optical cable. For example, the reinforcing element is of the composite rods (FRP for Fiber reinforced plastics) or metal rods, sheathed or not. 6

  According to one variant, the carrier element may also itself be said internal optical cable, and the main modules of optical fibers are in particular the modules inserted between the internal optical cable and the protective envelope of the optical cable.

  According to another variant, the carrier element may also be either an optical fiber or a main or internal module, or a tube containing or not containing at least one optical fiber or a module, these different types of carrier element being as described in the present invention. In a preferred embodiment, all the main modules surrounding said carrier element of the optical fiber, module or tube type can be held by composite rods (FRP) or metal, to strengthen the structure of the optical cable. In another preferred embodiment, the tube is composed of a polybutylene terephthalate (PBT) and a polycarbonate (PC).

  However, the material of said tube is not limited to this type of polymer and may be composed of other thermally stable thermoplastic polymers. In addition, the tube may advantageously be composed of a coloring agent and / or inscriptions on its outer surface to facilitate the selection of the tubes visually when connecting the main modules. Thus, the coloring agent, as said inscriptions, does not alter the integrity of the main modules of optical fibers. In another particular embodiment, the outer sheath of the main module is made of a charged polymeric material so that it can be easily removed. The polymer may be, for example, a polyolefin, especially an ethylene polymer and / or copolymer, or a polyester. In another embodiment, the protective envelope comprises at least one layer of a material of the polyolefin, polyester or polyamide type. According to a variant, the protective envelope comprises an outer layer and an inner layer.

  Preferably, the outer layer is composed of a high density polyethylene and the inner layer is composed of holding strands, said retaining strands being of the polyester or aramid type. In addition, an intermediate layer of weave type, for example corrugated steel, can be interposed between the outer layer and the inner layer. Typically, the various layers constituting the protective envelope must be easily cut in order to access the tubes. Another object of the present invention is a method of connection by means of an optical cable according to the present invention, comprising the following steps: selecting a tube of the optical cable and sectioning it at a first zone of said cable, and then sectioning a main module of said tube at the first zone, sectioning said tube at a second zone of the cable, the second zone being distant from the first zone, extracting, at the level of the second zone, the sectioned portion of the module blowing the tube, and connecting a feed point to the optical cable through the extracted main module portion. In a particularly advantageous embodiment, the extraction of said main module from the tube which is its own is carried out by injecting an air flow from the first section section of the tube. In a particular embodiment, the connection method comprises a step of opening in the protective envelope at the first and / or second zone. Other features and advantages of the present invention will emerge in the light of the description of non-limiting examples of an optical cable according to the present invention with reference to the annotated figures, in which FIG. 1 schematically represents a structure of an optical cable in cross section according to the prior art; Figure 2 schematically shows a structure of an optical cable in cross-section according to the present invention; Figure 3 schematically shows another structure of an optical cable in cross-section according to the present invention; Figure 4 schematically shows another structure of an optical cable in cross-section according to the present invention; FIG. 5 schematically represents the principle of extraction of the main optical fiber modules from the optical cable of FIG. 3 or FIG. 4. FIG. 1 has already been described previously, and to facilitate understanding, the common elements between the present invention and the prior art bear the same references. Figure 2 shows the sectional view of an optical cable 10 according to a particular embodiment of the present invention. This cable 10 comprises 9 main modules 11, 12, 13, 14 of optical fibers 20 and a protective envelope 2 surrounding said main modules of optical fibers. Each main module comprises an outer sheath 110 surrounding optical fibers 111. The term "main optical fiber module" means one or more optical fibers, preferably between 1 to 16, surrounded by a polymeric outer sheath not necessarily tight around the optical fibers for be easily removed. The optical fibers typically have a diameter of 250 phi. Each main module extends inside a tube 3 which is its own, said main module being free inside said tube. 9

  For example, the diameter of the main module 11 is about 1.1 mm and the internal diameter of the tube 3 is about 1.7 mm, the section area of said main module thus being less than 80% of the area of the section of the inner surface of said tube.

  The cable further comprises a central support member 4 of the type of reinforcing element made of plastic fibers (FRP) extending inside the protective envelope 2. This central position improves the compactness of the optical cable and facilitates the organization main modules around said carrier element.

  In another embodiment not shown, the carrier element is not necessarily in the center of the optical cable. Thus, several entities comprising optical fiber main modules associated with a carrier member may extend within the optical cable shield of the present invention.

  The essential function of the carrier element 4 is to organize at its periphery the various main modules of optical fibers. As shown in FIG. 2, each tube 3 is in contact with the external surface of the carrier element 4 and is held by the protective layer 2.

  Of course, not all the tubes are in contact with the carrier element and with the protective envelope 2, in particular its internal surface. They may indeed be in contact with the carrier element 4 or in contact with the inner surface of the protective envelope 2.

  It is only essential that the tubes 3 are interposed between the protective layer 2 and the carrier element 4 in order to immobilize them. The winding of the tubes around the carrier element is preferably S-Z type stranding, which makes it possible to have easy access for each tube during the extraction of the main modules of optical fibers.

  This type of winding is carried out alternately by sections of tubes of successive lengths, with a stranding on the left (stranding S) and a stranding on the right (stranding Z). Fig. 3 shows the sectional view of an optical cable 100 according to another particular embodiment of the present invention. In particular, it presents a possible variant of the protective envelope as well as the carrier element, the other constituent elements of the optical cable 100 remaining identical to those described in FIG. 2. As shown in FIG. 2 of said optical cable 100 consists of an outer layer 21 and an inner layer 22. The outer layer 21 is for example of high density polyethylene and the inner layer 22 is a set of polyester holding wicks for example . An intermediate layer 23 of corrugated steel armor type is interposed between the outer layer 21 and the inner layer 22. The carrier element is itself an internal optical cable 5. Said internal optical cable 5 is not necessarily used for the distribution of information at feed points, or in other words is not necessarily used to be extracted over long lengths for connection to said points. The various tubes 3 are held between the outer layer 51 of protection of said internal optical cable 5 and the inner layer 22 of the protective envelope 2. This internal optical cable 5 further comprises several internal modules 25 52 of optical fibers, each module internal optical cable 5 also comprises a rigid central element 54 extending inside said internal optical cable 5. The outer layer 51 surrounds the set of internal modules 52 and 30 central rigid element 54 and can be made of a material of the same type as that used for the protective envelope 2.

  Figure 4 shows the sectional view of an optical cable 101 according to another particular embodiment of the present invention. Identical to Figures 2 and 3 described above, the optical cable 101 comprises main modules 11, 12, 13, 14 of optical fibers, all of said main modules being surrounded by a protective envelope 2 surrounding said main modules of optical fibers. Each main module comprises an outer sheath 110 surrounding optical fibers 111, each main module being as previously described in the present invention.

  Said outer sheath 110 may be formed of a material having a low coefficient of dynamic friction as described in FR2887639. The optical cable 101 further comprises an internal optical cable 5 inside said protective envelope 2, said internal optical cable 5 being as previously described in connection with FIG. 3. Said internal optical cable 5 comprises at least one internal module 52 of optical fibers 53. At least one internal optical fiber module 52 of the internal optical cable 5 is connected to at least one of the main modules 11, 12, 13, 14 of optical fibers of the optical cable 101. The main modules 11, 12, 13, 14 of optical fibers are typically arranged inside the protective envelope 2 so that they have sufficient clearance to facilitate their extraction. The clearance is such that the area of the sum of the sections of all 25 main optical fiber modules contained in the protective envelope 2 and the internal optical cable 5 is less than 80% of the area of the section. of the inner surface of the protective envelope 2. These characteristics preferably make it possible to facilitate the extraction of each main module 11, 12, 13, 14 of the optical cable 101 and the pushing of the main module in a microconduct to the point of connection over a long length. The techniques used for the extractions and connections of said main modules can be those described in the document FR2887639.

  The number of main and / or internal modules 11, 12, 13, 14, 52 and the number of optical fibers 111, 53 shown in FIGS. 2, 3 and 4 are of course in no way limiting. The preferred method of connection by means of the optical cable according to the present invention is of the type known as stitching method as described in patent document FR2887639. In a first step, a first opening is made in the protective envelope 2 at a first zone using a dedicated tool. This opening makes it possible to access the tubes 3 contained inside the protective envelope 2. One of the tubes 3 containing a main module 11 is selected, said main module being the one which one wishes to deviate towards a feeding point. The tube 3 of the main module 11 is cut off near the first opening of the optical cable 10, 100 to access said main module. In a second step, a second opening is made in the protective envelope 2 at a second zone using a dedicated tool. The tube of the main module 11 is cut off near the second zone of the optical cable in order to reach said main module 11, the second zone 25 being distant from the first zone. The distance between the first zone and the second zone along the optical cable 10, 100 is typically between a few meters and a few tens of meters, but can reach a hundred meters. In a third step, the main module 11 is pulled at the second zone so as to extract the severed portion of said main module.

  Extraction of said portion of the main module 11 at the second zone of the cable is advantageously effected by injecting a flow of air from the first sectional area of the tube 3, inside said tube. In a fourth step, a feed point is connected to the optical cable 10, 100 through the extracted main module portion. By applying the so-called stitching method to the optical cable 100 or 101 respectively shown in FIGS. 3 and 4, the internal optical cable 5 advantageously makes it possible to feed the main modules of optical fibers in order to perform two connection operations on a different portion of FIG. a same main module of optical fibers. This dual use of a main fiber optic module is feasible when, at one end of the optical cable 100, 101, the internal modules 52 of the internal optical cable 5 are connected to the main optical fiber modules of the optical cable 100, 101 by a connecting means 6 as shown in Figure 4 to form a connection loop. In other words and more generally, at least one optical fiber 53 of an internal module 52 of the internal optical cable 5 is connected to an optical fiber 111 of a main module 11, 12, 13, 14 of the optical cable 100, 101. FIG. 5 schematically represents an example of connection of different main modules 11 to 16 to N buildings 11 to 11 N. First connection operations, carried out by the stitching method as described above, make it possible to connect a portion 11 a of the main module 11 to the building 11, to connect a portion 12a of the main module 12 to the building 11, to connect a portion 13a of the main module 13 to the building 12, to connect a portion 14a of the main module 14 to the building 12, to connect a portion 15a of the main module 15 to the building 14, and connect a portion 16a of the main module 16 to the building 14. Through the looping, by the connection means 6, between the optical cable in 5 and the main modules 11 to 16 in the building N, second connection operations can also be performed by stitching on other portions of the same main modules 11 to 16.

  Thus, the second connection operations make it possible to connect another portion 11b of the main module 11 to the building I N-1, to connect another portion 12b of the main module 12 to the building I N-1, to connect a other portion 13b of the main module 13 to the building I N-2, to connect another portion 14b of the main module 14 to the building I N-2, to connect another portion 15b of the main module 15 to the building I N-4, and connect another portion 16b of the main module 16 to the building I N-4. The unused portions 11c, 12c, 13c, 14c of the main modules 11, 12, 13, 14 for the connection remain inside the optical cable 100, 101.

  This end looping makes it particularly advantageous, for a number x of connection operations, to use only x / 2 main modules of optical fibers. The total number of main optical fiber modules between the internal optical cable and the protective envelope is thus significantly limited. Typically, the end of the optical cable opposite to the loopback, that is to say the end from which the modules 11 to 16 leave the side of the building 11, is connected for example to a so-called point of presence of supply of the optical cable, not shown in FIG.

This point of presence is well known to those skilled in the art and allows the connection of said optical cable to power it oytquement. The present invention is not limited to the examples of optical cables that have just been described and generally relates to all optical cables that can be envisaged from the general indications provided in the disclosure of the invention.

Claims (17)

  An optical cable (100, 101) comprising: one or more optical fiber main modules (11, 12, 13, 14) comprising at least one optical fiber (111), the at least one main module being surrounded by an outer sheath (110) , and a protective envelope (2) surrounding the at least one optical fiber main module, characterized in that the optical cable (100, 101) further comprises an internal optical cable (5) within said protective envelope (2). ), said internal optical cable (5) comprising at least one internal optical fiber module (52) (53), and in that at least one internal fiber optic internal fiber module (52) of the internal optical cable (5) is connected to at least one of the optical fiber optic fiber main modules (11, 12, 13, 14) (100, 101).   2. Optical cable according to claim 1, characterized in that it further comprises: n main modules (11, 12, 13, 14) of optical fibers, n being an integer such as 1 n 3, arranged inside a tube (3) of their own, said n main modules being free inside said tube (3), and a carrier element (4) inside said protective envelope (2), each of said tubes (3) being immobilized between said carrier element (4) and said protective envelope (2).   3. Cable according to claim 2, characterized in that n is equal to 1.   Cable according to claim 2 or 3, characterized in that the cross-sectional area of the n main modules (11, 12, 13, 14) is less than 80% of the cross-sectional area of the inner surface of the tube. (3).   5. Cable according to any one of claims 2 to 4, characterized in that the tube or tubes (3) are stranded around the carrier member (4).   6. Cable according to claim 5, characterized in that the configuration of the tube or tubes (3) around the carrier element (4) is of type S-Z.   7. Cable according to any one of claims 2 to 6, characterized in that the carrier element (4) is a reinforcing element.   8. Cable according to any one of claims 2 to 6, characterized in that the carrier element (4) is said internal optical cable (5).   9. Cable according to any one of claims 2 to 8, characterized in that the tube (3) is composed of a polybutylene terephthalate (PBT) and a polycarbonate (PC).   10. Cable according to any one of claims 2 to 9, characterized in that the tube (3) is composed of a coloring agent.   11. Cable according to any one of the preceding claims, characterized in that the outer sheath (110) is composed of a charged polymer material.   12. Cable according to any one of the preceding claims, characterized in that the protective envelope (2) comprises an outer layer (21) and an inner layer (22).   13. Cable according to claim 12, characterized in that the outer layer (21) consists of a high density polyethylene and the inner layer (22) consists of retaining strands.   14. Cable according to claim 12 or 13, characterized in that an intermediate layer (23) of the weave type is interposed between the outer layer (21) and the inner layer (22).   15. The method of connection by means of an optical cable as defined in claims 1 to 14, comprising the steps of: selecting a tube of the optical cable and severing it at a first zone of said cable, then severing a main module of said tube at the first zone, severing said tube at a second zone of the cable, the second zone being distant from the first zone, extracting, at the level of the second zone, the severed portion of the main module of the tube which it is clean by blowing, and connect a feed point to the optical cable through the extracted main module portion.   16. The method of claim 15, characterized in that the extraction of said main module of the tube which is specific to it is performed by injecting an air flow from the first sectional area of the tube.   17. The method of claim 15 or 16, characterized in that it comprises a step of making an opening in the protective envelope at the first and / or second zone.