FR2938932A1 - Subscriber's cord connecting device for telecommunication network, has path with outlet zones arranged symmetrically at specific degrees such that fiber passes via appropriate zone, while having curvature radius greater than preset radius - Google Patents

Abstract

The device (1) has a connector removably connected to a plate (4) by tabs (49) and connecting a cord to an optical fiber. An optical fiber winding and storing path (51) has four outlet zones arranged symmetrically at 90 degrees with respect to each other such that the fiber passes via an appropriate outlet zone among the four zones, an opening and an inlet zone of another optical fiber winding and storing path (58), while having, in all points, a curvature radius greater than a preset minimal curvature radius, in one of four different assembling positions of the plate. The tabs carry studs allowing the placement of the plate in the four different assembling positions with respect to a base.

Description

The present invention relates to a connection device between an optical fiber of a network and a cord of a subscriber. Telecommunication networks, which previously generally used copper cables, are increasingly equipped with fiber optic cables. This improves the quality and the rate of transmission of information. However, the transition from copper to optical fiber leads to the emergence of specific problems that did not arise before. The network cable, which contains the optical fiber placed in a protective sheath, is brought to a connection device which can for example be fixed on a wall inside a building or in a telecommunications box. In known manner, such a connection device comprises: a rectangular contour box, comprising on the one hand a base and on the other hand a cover removably assembled to the base, the housing having at least one inlet for said optical fiber and an output port for connecting the cord to the optical fiber; - A plate assembled to the base, for example pivotally, and housed in the housing. In practice, the optical fiber of the network is connected, inside the connection device, to a second optical fiber. The free end of this second optical fiber is equipped with a tip which is introduced into the first receiving cavity of a connector placed at least partly in the housing. The connector also comprises a second receiving cavity of a tip equipping the cord of the subscriber, this second cavity being accessible via the outlet orifice formed on the housing. Thus, the connection is waiting for reception of the subscriber's cord to make the connection with the optical fiber of the network, via the second optical fiber. Two important constraints must be respected in order to guarantee a good quality of data transmission.

First, the junction, called splicing, between the two optical fibers, must be performed with great precision. In particular, the surfaces in contact must be carefully prepared and as little as possible in contact with the dust. If, after checking, it turns out that the junction has not been made with the required quality, the fibers are cut and the operator performs a new joining operation. It is therefore necessary to have, within the connection device, a reserve of the first optical fiber (network) and the second optical fiber. In addition, it is necessary to comply with a low threshold of radius of curvature, predetermined depending in particular on the nature of the fiber. Beyond this minimum radius of curvature, there is a risk of too much attenuation of the transmitted signal, or even rupture of the fiber. Because of the two aforementioned constraints, the fibers are housed in the connection device in a first and a second winding and storage paths, respectively formed on the base and on the plate. These paths are designed to prevent excessive curvature of the fibers, and to allow the storage of a sufficient supply of fibers, in a necessarily reduced space. In addition, a passage zone of the optical fiber is provided between the first and second paths, that is to say between the base and the plate. Of course, in this passage zone, the fiber must also not be too curved. This is why connection devices, and more particularly these paths, generally have a great complexity of form, carefully studied. The connection devices must be able to adapt to all the configurations desired by the user or imposed by the places. Thus, the input of the fiber optic cable must be able to be on any side of the housing. Similarly, the output for the connection of the subscriber's cord must be provided on any side of the housing, with respect to the input. In the case where the connecting devices are placed next to each other on a fixing rail of a telecommunications box, it is understood that neither the input nor the output of the devices placed in the middle of the rail, and therefore surrounded by other devices, can not be located on the side faces. To meet these requirements, the known connection devices are generally provided with several inputs for the optical fiber cable of the network, located on different sides of the rectangular housing. This has several disadvantages. First of all, this makes it even more complex to design the first path on the base, because it must be ensured that the optical fiber is not too curved regardless of its point of entry into the base. Moreover, in order to guarantee the quality of data transmission, it is necessary to equip each of the potential inlet ports with means of sealing with water and dust. These means are expensive to implement, while a single inlet port is used for a given application. The present invention aims to overcome the disadvantages mentioned above.

For this purpose, the invention relates to a connection device between an optical fiber of a network and a cord of a subscriber, the device being generally parallelepipedic and comprising: a base including at least one inlet for said fiber optical, the base having a bottom wall from which protrude walls defining between them a first winding and storage path of the optical fiber, the first path having at least one input zone and an output zone of said fiber, - a plate comprising a plate from which protruding walls defining between them a second winding and storage path of the optical fiber, this second path having at least one input zone and an output zone of said fiber , the plate being provided with means allowing its reversible assembly on the base, superimposed on the base, a passage zone of the optical fiber being provided between the first 20 r and second paths. According to a general definition of the invention, the connection device also has the following characteristics: the plate comprises means for removably attaching at least one connector making it possible to connect the subscriber's cord to the optical fiber leaving the second way; - The reversible assembly means of the plate on the base are arranged to allow to place the plate in four different assembly positions relative to the base, corresponding to successive rotations of 90 °; The first path comprises four output zones arranged symmetrically at 90 ° to each other, arranged so that, in any one of the four assembly positions of the plate with respect to the base, the fiber wound in said first path may pass through an appropriate exit zone among the four exit zones, through said passage zone and then through an entrance zone of the second path, having at all points a radius of curvature greater than a radius of curvature predetermined minimum. Thus, thanks to the invention, it is possible to provide on the one hand a single input for the optical fiber cable of the network, on a given side of the base, and on the other hand an output for the connection of the subscriber's cord. (the fitting) on one side of the plate. By placing the stage in the proper assembly position relative to the base, the outlet can be placed in any position relative to the inlet. In this way, one can provide a single connection device that can be implemented in different places, with different positioning constraints of the input and output. In particular, the fixing on a rail of a telecommunications box can be done without any problem. This adaptation to all possible configurations is not to the detriment of good data transmission, since the first and second paths and the passage zone are designed to ensure that the fiber, on its entire path, is never curved below the minimum radius of curvature, regardless of the mounting position of the plate on the base. In addition, there is only one input to equip sealing means, which significantly reduces the cost of the connection device. It should be noted that the terms input and output are used for purposes of simplification in a fictitious sense from the network cable to the subscriber's cable. As indicated above, preferably, the base comprises four peripheral walls and only one of these four peripheral walls has an inlet for said optical fiber. In addition to the aforementioned advantages, it should be noted that, thanks to this characteristic, it is necessary to provide only one entry zone in the first path between the partitions, hence a simplified design and a gain of place inside the case. An additional inlet can also be provided in the bottom wall of the base, for some applications. It is also possible, advantageously, that the plate comprises means for removably attaching a single connector, or alternatively two connectors, which are then located at the same side of the plate.

According to a particularly advantageous embodiment, the base has a square contour and the plate has a square contour of slightly lower side. Thus, the plate is superimposed on the base and can be housed in a closed housing consisting of the base and a cover, the assembly having a square and non-rectangular contour as is the case in the prior art. Therefore, the connection device is symmetrical, and can be implemented in one direction or the other, indifferently, which makes it perfectly adaptable to all configurations. In addition, the connection device according to the invention is much more compact than the known devices, insofar as the dimension of its side may be equal to the width (small side) rectangular boxes of the prior art. According to one possible embodiment, the reversible assembly means of the plate on the base are arranged to allow pivoting of the plate relative to the base, about an axis substantially parallel to one side of the base, between a folded position in which the plate is superimposed on the base and an unfolded position allowing access to the base. It is thus possible for an operator to work on the optical fiber housed in the first path, on the base, without having to completely remove the plate.

Advantageously, the base comprises, at each of its corners, a connecting member intended to cooperate on the one hand with the reversible assembly means provided on the plate to allow the pivoting of the plate and, on the other hand, with means for holding the plate in the folded position, formed on the plate. In this way, a single connecting member performs two functions, namely pivoting and holding, according to the assembly position of the plate relative to the base. For example, the connecting members are substantially identical and each comprise an L-shaped tab, each branch of which is substantially parallel to one side of the base adjacent to the corresponding corner, each branch having an opening in which a connection means can be engaged. reversible platen or means for holding the platen in the folded position. In addition, it can be provided that the plate comprises, on the one hand, in each of two adjacent corners, an outward facing lateral pin, designed to cooperate with a connecting member to allow the pivoting of the plate relative to the base and secondly, in each of the other two corners, a lug adapted to cooperate with a connecting member to allow the maintenance of the plate in the folded position. The passage zone of the optical fiber between the first and second paths may be formed by a light formed in the plate of the plate. This passage zone is for example a single entry in the plate for the fiber coming from the base, which is also located near a single input zone of the second path. Advantageously, this light can be located near a corner of the plate. Thus, when the plate is pivotally mounted on the base, the pivoting of the plate does not cause a tension of the fiber which could deteriorate. According to one possible embodiment, the first path comprises a substantially circular main portion and tangential to the peripheral walls of the base, the four exit zones being located each between: a zone of tangency between the main portion of the first path and a peripheral wall of the base and the adjacent corner of the base located downstream of said zone of tangency in the winding direction of the fiber. Here again, the term "downstream" is used for purposes of simplification in a fictitious sense ranging from the network cable to the subscriber's cord. Finally, the connection device may further comprise: a cover removably assembled to the base and forming a housing therewith, the housing having at least one input port for said optical fiber and an output port for connecting the cord to the optical fiber; - And a shutter member mounted on the housing movably between a closed position, wherein the closure member closes the outlet port, and an open position, wherein said outlet port is clear. Thus, the shutter member is mounted on the housing itself, and not on the connector. Therefore, the device according to the invention can receive standard connectors, not equipped with valves, while ensuring the safety of people by protecting them from the light beam transmitted by the optical fiber. In addition, the shutter member being mounted on the housing, with a possibility of displacement, it is captive, unlike a removable cap 35.

A possible embodiment of the invention will now be described, by way of nonlimiting example, with reference to the appended figures: FIG. 1 is a perspective view of a connection device according to the invention; Figure 2 is an exploded perspective view of the connection device of Figure 1; Figure 3 is a top view of a base belonging to the connection device; Fig. 4 is a perspective view of a plate belonging to the connection device, further showing a connector; and Figures 5 to 8 are perspective views of the connecting device, in which the plate occupies four different assembly positions with respect to the base. Figures 1 and 2 show a connection device 1 which essentially comprises a base 2, a cover 3 and a plate 4. These are for example made by molding a plastic material. The base 2 comprises a square bottom wall 5, that is to say the four sides of which have the same length, and four peripheral walls, namely a first and a second lateral wall 6, 7, a front wall 8 and a rear wall 9. It should be noted that the positioning terms, such as front and rear in particular, are used to simplify the description but do not define a precise and fixed orientation of the connection device, which can be placed in different positions in the space. In the first side wall 6 of the base 2 is provided an inlet port 10 adapted to receive a seal 11 provided with a central passage 12 closed by flexible webs. Also found on the base 2 are side tongues 13 each provided with a latching hook 14. In addition, at each corner of the base 2, an L-shaped tab 15 protrudes in the opposite direction from the bottom wall 5. Each lug 15 thus comprises two branches perpendicular to each other and each parallel to a peripheral wall of the base 2, each branch having an opening 16. The base 2 also comprises sockets 17 intended to receive screws or other fastening members of the connection device. 1 to a support 35 (wall, cabinet). In the bottom wall 5 may further be provided an additional inlet 18, for a fiber optic cable (see Figure 3).

Finally, the base 2 comprises partitions 19 projecting from the bottom wall 5, defining between them a first path 51 of winding and storage of the optical fiber, open at its upper part. As seen in FIG. 3, this first path 51 comprises a main portion 52 that is substantially circular and tangential to the peripheral walls 6, 7, 8, 9 of the base 2, in which the fiber 41 of the network is wound, and a second fiber 43, as will be seen later. Tabs 53 parallel to the bottom wall 5 and extending from the upper edge of the partitions 19 above the path 51 prevent the fibers 41, 43 from coming out of the main portion 52 of the first path 51 of unwanted way. These tabs 53 are here provided substantially at each corner of the base 2. The first path 51 also comprises an annex portion 54, located in the middle of the main portion 52, wherein the fiber 41 can be derived from the main portion 52 to be connected to the second fiber 43. The first path 51 has only an inlet zone 55 opposite the inlet orifice 10 and, if appropriate, an inlet zone 56 in the extension of the inlet orifice 18 In addition, the first path 51 comprises only four exit zones 57a, 57b, 57c, 57d, which are each located between: a zone of tangency between the main portion 52 of the first path 51 and a peripheral wall 6, 7, 8, 9 of the base 2; and the adjacent corner of the base 2 located downstream from said zone of tangency in the winding direction of the fiber 41, 43. More specifically, the exit zones are here each located immediately upstream of a tongue 53. Thus, the four exit zones 57a, 57b, 57c, 57d are arranged symmetrically at 90 ° to each other, that is to say to the vertices of a square. The first output zone 57a is defined as the closest (downstream) of the input port 10, as shown in FIG. 3. The optical fiber 41, 43 can not leave the path 51, to the top, only by one of these four output zones 57a, 57b, 57c, 57d. Of course, the first path 51 is designed so that the fibers 41, 43 which are wound therein are not curved beyond the minimum radius of curvature, whatever the path they take, and in particular: inlet port 10 to the inlet zone 55, from the inlet port 18 to the inlet zone 56, in the main portion 52 and in the auxiliary portion 53, from the main portion 52 to the portion 53 and vice versa, the main portion 52 to any of the four exit zones 57a, 57b, 57c, 57d. The cover 3 has a generally square top wall 20, that is to say whose four sides have the same length, and four peripheral walls, namely a first and a second side wall 21, 22, a front wall 23 and a rear wall 24. The front wall 23 is curved, and the upper wall 20 has an advance 25, beyond its square outline. The side walls 21, 22 comprise, on the inside, notches (not shown) intended to each receive a hook 14 of a tongue 13 of the base 2, for the assembly of the cover 3 to the base 2, by snap-fastening, removable.

In the assembled position, the hood 3 and the base 2 form a substantially parallelepipedal housing, of square outline. As can be seen in FIG. 1, in this position, the cover 3 has a portion protruding beyond the front wall 8 of the base 2, formed in particular by the projection 25 of the upper wall 20 and by the wall before 23 bulging.

In the advance 25 and the front wall 23 are provided two outlet orifices 26 through which cords can be introduced, as will be seen later. At each of the outlet orifices 26, the cover 3 comprises an axis 27 substantially orthogonal to the side walls 21, 22. The two axes 27, which are preferably aligned, are here at a distance from the upper wall 20 of the cover 3 , that is to say in the lower portion of the outlet ports 26, the side of the base 2 in the assembled position of the housing. Two closure members 28 are provided to be mounted on the cover 3, each at an outlet port 26. A closure member 28 comprises four substantially planar side walls 29 and a curved front wall 30. In addition, the closure member 28 has two latching lugs 31 intended to cooperate with the axis 27, so that the closure member 28 can pivot about the axis 27. In the open position ( right part of Figure 1), the closure member 28 releases access to the outlet port 26. In the closed position (left part of Figure 1), the closure member 28 closes the orifice In this position, the walls 29, 30 of the closure member 28 form a housing 32 substantially parallelepipedic and open towards the inside of the housing. In addition, when in the closed position, the closure member 28 is located substantially in the extension of the upper face 20 and the front face 23 of the cover 3. Elastic return means 33, formed here of a bent wire, are arranged to bias the closure member 28 to its closed position. The plate 4 is in the form of a generally square plate 34, that is to say whose four sides have the same length, from which protrude the partitions 35 defining between them a second winding path 58 and storage of the optical fiber. On the plate 34 are also found wells 36 for the passage of screws or other fasteners, these wells 36 being arranged to be placed in alignment with the wells 17 provided on the base 2, in the mounted position of the connection device 1 .

The plate 4 further includes tabs 37 located at the four corners of the plate 34. Two tabs 37 adjacent carry lateral pins 38 facing outwards, each engaging in an opening 16 of a tab 15 of the base 2 Thus, the plate 4 can pivot relative to the base 2, around the common axis of the pins 38, between a folded position where the plate 34 is substantially parallel to the bottom wall 5 of the base 2, the plate 4 can then be housed in the closed housing, and an unfolded position allowing access to the base 2. The two other legs 37 of the plate 4 have lugs 39 which snap into the openings 16 of the other legs 15 of the base 2, way to keep the plate 4 in the folded position. In the plate 34 is also practiced a light 59, at a corner adjacent to one of the two pins 38. The second path 58 occupies about half of the surface of the plate 34, the side of the nipples 38. comprises a main portion of generally oval shape, adjoining three sides of the plate 34, in which is wound the second fiber 43. Tongues 60 parallel to the plate 34 and extending from the upper edge of the partitions 35 above the path 58 prevent the fiber 43 from leaving the second path 58 undesirably. The second path 58 also comprises an auxiliary portion, substantially circular and located in the middle of the main portion, around which is wound the fiber 43 towards an exit zone of the second path 58. The second path 58 has a a single input zone 61, adjacent to the light 59, and two output zones 62a, 62b formed in the partition 35 located in the middle of the plate 34. Of course, the second path 58 is designed so that the fiber 43 which is wound therein is not curved beyond the minimum radius of curvature, and this over its entire path, namely in particular: from the light 59 to the entry zone 61, and from the main portion to the any of the two output areas 62a, 62b. In practice, a cable 40 of a telecommunications network, comprising at least one sheath 42 in which is housed an optical fiber 41, is introduced through the inlet port 10 of the base 2 (via the central passage 12 of the seal sealing 11). The optical fiber 41 is wound in the first path 51 formed between the partitions 19 of the base 2, and is connected to a second optical fiber 43, on the base 2. The second optical fiber 43 leaves the first path 51 by the one of the four output areas 57a, 57b, 57c, 57d which is located substantially under the light 59 formed in the plate 4. This second optical fiber 43 then rises towards the corner of the plate 4, initially initially following the curvature of the first path 51 , passes into the light 59, then enters the second path 58 formed between the partitions 35 of the plate 4 by the input zone 61, and is wound in the second path 58 to one of the two exit zones 62a, 62b. The free end of the optical fiber 43 is provided with a tip 44 (see FIG. 4). This tip 44 is itself introduced into a connector 45 which may be standard. The connector 45 comprises a first receiving cavity of the nozzle 44, open towards the inside of the housing, and a second receiving cavity of a nozzle 46 fitted to a cord 47 of a subscriber, this second cavity opening to the outside of the housing, at one of the outlets 26 (see Figure 1), and therefore being accessible to the subscriber. Advantageously, the connector 45 comprises wings 48 which are inserted between tabs 49 provided on the plate 34 of the plate 4, for the removable attachment of this connection 45 to the plate 4. The connector 45 may further comprise a plug 50 removable from closing the second cavity when no subscriber line 47 is inserted, but this is not essential. The base 2 is fixed to a support, for example on a wall inside a room of a building, the end piece 44 of the optical fiber 43 is inserted in the connection 45 mounted on the plate 4, and the second cavity of this connector 45 is waiting for the receipt of the tip 46 of a cord 47 of the subscriber. In this position, as illustrated on the left-hand part of FIG. 1, the shut-off member 28, biased by the elastic return means 33, is in the closed position, and the connection 45 is partly housed in the housing 32. When the subscriber wishes to connect his cord 47 (provided with the tip 46), he pivots the closure member 28 with the fingers, thus releasing the outlet orifice 26, and can then insert the tip 46 into the connector 45. As shown in Figures 5 to 8, the connection device according to the invention is designed to be able to adapt to all configurations. Indeed, on the one hand, because of its square and non-rectangular outline, the base 2 can be fixed in four different positions (corresponding to successive rotations of 90 °) without the overall size is changed. Thus, it is possible to place the single inlet port 10 in the desired position relative to the environment. On the other hand, the plate 4 also square is assembled on the base in any one of four possible assembly positions (corresponding to successive rotations of 90 °). This is made possible in particular by the structure of the lugs 15, nipples 38 and lugs 39. Thus, the connectors 45 open into any peripheral wall of the connection device 1. In other words, the operator can choose the position relative between entry and exit. Thus, in FIG. 5, the axis of pivoting of the plate 4 relative to the base 2 runs along the rear wall 9 of the base 2, and the lugs 39 snap into the lugs 15 situated on the side of the front wall 8 In this configuration, the connectors 45 open into the front wall 8, near the inlet port 10. The second optical fiber 43 leaves the first path 51 of the base 2 by the exit zone which is then substantially under the light 59 of the plate 4, namely the second output zone 57b.

In FIG. 6, the axis of pivoting of the plate 4 runs along the front wall 8 of the base 2. The connectors 45 open into the rear wall 9, away from the inlet orifice 10. The second optical fiber 43 leaves the first path 51 of the base 2 by the fourth output zone 57d. In FIG. 7, the axis of pivoting of the plate 4 runs along the first lateral wall 6 of the base 2. The connectors 45 open into the second lateral wall 7, opposite the inlet orifice 10. The second optical fiber 43 leaves the first path 51 of the base 2 by the third output zone 57c. Finally, in FIG. 8, the axis of pivoting of the plate 4 runs along the second lateral wall 7 of the base 2. The connectors 45 open into the first lateral wall 6, that is to say into the wall in which is practiced the input port 10. The second optical fiber 43 leaves the first path 51 of the base 2 by the first output zone 57a. In each of these four configurations, the fibers 41, 43 over their entire path are always less curved than the minimum radius of curvature required, because of the adapted design of the paths 51, 58, their entry zones and output, and the positioning of the light 59. In addition, the fact that the light 59 is located in the vicinity of a pivoting corner of the plate 4 prevents traction being exerted on the fiber when an operator rotates the plate to its unfolded position.

Thus, the invention provides a decisive improvement to the prior art, providing a modular connection device that can adapt to all the conditions desired by the user. In addition, this connection device guarantees a high quality of data transmission by providing for the fiber a winding path and storage adapted to all these configurations. It goes without saying that the invention is not limited to the embodiment described above by way of example but that it encompasses all variants thereof.

Claims (12)

REVENDICATIONS1. Device for connection between an optical fiber (41) of a network and a cord (47) of a subscriber, the device (1) being generally parallelepipedic and comprising: - a base (2) comprising at least one orifice of input (10) for said optical fiber, the base (2) having a bottom wall (5) from which protruding walls (19) defining between them a first path (51) for winding and storing the optical fiber said first path having at least one input region (55, 56) and an output region (57a, 57b, 57c, 57d) of said fiber, - a platen (4) having a plate (34) of which protruding walls (35) defining between them a second path (58) for winding and storing the optical fiber, said second path having at least one input zone (61) and an output zone (62a, 62b) of said fiber, the plate (4) being provided with means allowing its reversible assembly on the base (2), in a superimposed manner at the base (2), a passage zone (59) of the optical fiber being provided between the first and second paths (51, 58), characterized in that - the plate (4) comprises removable fixing means (49). ) at least one connector (45) for connecting the cord (47) of the subscriber to the optical fiber (43) coming out of the second path (58); - The reversible assembly means (38) of the plate (4) on the base (2) are arranged to allow to place the plate (4) in four different assembly positions relative to the base (2), corresponding at successive rotations of 90 °; the first path (51) comprises four exit zones (57a, 57b, 57c, 57d) arranged symmetrically at 90 ° from each other, arranged so that, in any one of the four assembly positions of the plate (4) with respect to the base (2), the fiber wound in said first path (51) can pass through an appropriate exit zone among the four exit zones, by said passage zone (59) then by a input region (61) of the second path (58), having at all points a radius of curvature greater than a predetermined minimum radius of curvature. 2. Connection device according to claim 1, characterized in that the base (2) has four peripheral walls (6, 7, 8, 9) and in that only one of these four peripheral walls has an inlet port ( 10) for said optical fiber (41). 3. Connection device according to claim 1 or 2, characterized in that the plate (4) comprises removable fixing means (49) of a single connector (45), or two connectors (45) at the level of one side of the plate (4). 4. Connection device according to one of claims 1 to 3, characterized in that the base (2) has a square contour and in that the plate (4) has a square contour slightly lower side. 15 5. Connection device according to one of claims 1 to 4, characterized in that the reversible assembly means (38) of the plate on the base are arranged to allow pivoting of the plate (4) relative to the base (2), about an axis substantially parallel to one side of the base, between a folded position in which the plate is superimposed on the base and an unfolded position allowing access to the base. 6. Connection device according to claim 5, characterized in that the base (2) comprises at each of its corners, a connecting member (15) for cooperating on the one hand with the reversible assembly means (38). ) 25 formed on the plate (4) to allow pivoting of the plate and, secondly, with holding means (39) of the plate (4) in the folded position, formed on the plate. 7. Connection device according to claim 6, characterized in that the connecting members are substantially identical and each comprise an L-shaped lug (15) each branch of which is substantially parallel to one side of the base (2) adjacent to the corresponding corner, each leg having an opening (16) in which can be engaged a reversible assembly means (38) of the plate (4) or a holding means (39) of the plate (4) in the folded position. 10 8. Connection device according to claim 6 or 7, characterized in that the plate (4) comprises, on the one hand, in each of two adjacent corners, a lateral stud (38) facing outwards, intended to cooperate with a connecting member (15) to allow pivoting of the plate (4) relative to the base (2) and secondly, in each of the other two corners, a lug (39) adapted to cooperate with a body of link (15) to allow the holding of the plate (4) in the folded position. 9. Connection device according to one of claims 1 to 8, characterized in that the passage area of the optical fiber between the first and second paths (51, 58) is formed by a slot (59) formed in the plate (34) of the plate (4). 10. Connecting device according to claim 9, characterized in that the light (59) is located in the vicinity of a corner of the plate (4). 11. Connection device according to one of claims 4 to 10, characterized in that the first path (51) comprises a main portion (52) substantially circular and tangential to the peripheral walls (6, 20 7, 8, 9) of the base (2), the four exit zones (57a, 57b, 57c, 57d) being located each between: - a zone of tangency between the main portion (52) of the first path (51) and a peripheral wall of the base (2) ); and the adjacent corner of the base (2) situated downstream from said zone of tangency in the winding direction of the fiber. 12. Connection device according to one of claims 1 to 12, characterized in that it further comprises a cover (3) assembled to the base (2) removably, and forming with the latter a housing, the housing having at least one input port (10) for said optical fiber (41) and an output port (26) for connecting the cord (47) to the optical fiber, the connecting device (1) further comprising a shutter member (28) movably mounted on the housing between a closed position, wherein the shutter member (28) closes the outlet port (26), and an open position, wherein said orifice outlet (26) is disengaged.