FR3102865A1 - Fiber optic spreader device - Google Patents

Abstract

The invention relates to an optical fiber spreader device (10) comprising: - an input sheath (14) accommodating a plurality of optical fibers and having an alternation of flat portions (15) and grooves (16), - a plurality output sheaths (39) housing a respective optical fiber of the plurality of optical fibers, - a main body (20), - an inlet receptacle (21) mounted on the main body (20) and comprising a passage (30) ) through having an internal shoulder (33), - a first locking ring (35) housed in a first groove (34) and blocking the inlet sheath (14) in movement out of the passage (30) by abutting the first ring blocking (35) on the shoulder (33), - a second blocking ring (36) housed in a second groove (37) so as to block the inlet sheath (14) in movement in the direction of the passage (30) ) by abutment of the second locking ring (36) on an outer abutment surface of the inlet receptacle (21), - a receptacle outlet acle (22) mounted on the main body (20) and traversed by the plurality of outlet ducts (39). Figure to be published: 4

Description

Fiber optic fanout device

The invention relates to the field of optical fiber connection systems and, more particularly, to systems comprising spreader devices allowing the redirection of optical fibers in the context of a connection between an optical fiber arrival at the level of a building and a plurality of terminal points such as a plurality of building premises connection terminals.

Technology background

A building such as an apartment building generally comprises a plurality of separate premises so that, when said building is connected to an optical fiber input, it is necessary to provide a plurality of separate optical fibers for each of the premises of the building. To do this, a plurality of separate optical fibers are routed from the urban network to a connection point in the building. An optical fiber dedicated to each room is then deployed in the building in order to connect each of the terminal connection points, typically each of the rooms, to the building connection point.

In order to limit the installations necessary for the deployment of the various optical fibers connecting the terminal connection points to the building connection point, the optical fibers are grouped together in common ducts. Thus, a primary sheath houses, for example, all the optical fibers intended to be connected to the terminal connection points of the same floor of the building. Similarly, all of said primary ducts are housed in a riser that extends over the entire height of the building in order to reach all floors.

However, the grouping of the optical fibers for their deployment in the building is not necessarily identical to the grouping of the optical fibers at the level of the connection point of the building. In addition, it is necessary to be able to identify at the level of the connection point in a simple and rapid manner to which terminal connection point an optical fiber housed in a sheath is connected in order to guarantee the correct connection at the level of the connection point of the building. For example, a dedicated box can be provided at the connection point of the building for each network access provider so that the various optical fibers grouped together in a primary sheath and corresponding to the same floor can be separated at the level of the connection point. building connection. Therefore, it is necessary to be able to redistribute the optical fibers grouped together in the same sheath within the building in order to be able to group them and connect them according to their connection box and their destination in said box at the connection point of the building.

For this, spreaders are used at the connection point of the building. Such spreader devices make it possible to redistribute the group of optical fibers coming from the duct(s) deployed in the building without interrupting the optical fibers. Generally, a primary fanout is used to group all the optical fibers from the building to be connected to the same box and a secondary fanout is used for each group of fibers thus obtained to individualize the optical fibers thus grouped and allow their identification in view of the connection to the operator network in the connection point of the building.

However, the ducts coming from the building must be fixed reliably on these spreader devices without this fixing damaging the optical fibers that the said ducts contain. In publication FR2858066, this fixing is done by deforming an end portion of the spreader in order to block the end of the sheath on the spreader by pinching. Fixing the sheath therefore requires very special attention and some experience on the part of the operator installing the spreader. Indeed, if the operator deforms the end portion of the spreader too much, he risks damaging the optical fibers housed in the sheath. Conversely, if the operator does not sufficiently deform the end portion of the spreader, the fixing of the sheath on the spreader is not reliable and a simple pull can dislodge the sheath from the spreader.

Summary

An idea underlying the invention is to provide a spreader device allowing good attachment of the input sheath in the spreader device without damaging the optical fibers housed in said input sheath. An idea underlying the invention is to allow the fixing of the inlet sheath to the spreader device in a simple and rapid manner. An idea underlying the invention is to allow the fixing of the inlet sheath to the spreader device in a safe and controlled manner, without requiring this fixing to rely on the skill and experience of an operator fixing said inlet sheath on the spreader.

For this, the invention provides an optical fiber fanout device comprising:
- an input sheath housing a plurality of optical fibers, the input sheath having alternating planar portions and grooves,
- a plurality of output sheaths, each output sheath housing a respective optical fiber of the plurality of optical fibers and being terminated by a connector,
- a hollow cylindrical main body,
- an input receptacle mounted on an input end of the main body, said input receptacle comprising a through passage, said passage having an internal shoulder delimiting an external portion of the passage and an internal portion of said passage, the external portion presenting a diameter greater than the outer diameter of the inlet sheath, the inner portion having a diameter greater than the diameter of the outer portion, the inlet sheath being received in the passage so that a first groove of the inlet sheath is housed in the internal portion of the passage and that a second groove is housed outside the passage,
- a first blocking ring housed in the first groove and having an external diameter greater than the diameter of the external portion of the passage so as to block the inlet sheath in displacement out of the passage by abutment of the first blocking ring on a surface of internal abutment carried by the inlet receptacle, the first groove being housed in the internal portion of the passage and the shoulder forming the internal abutment surface,
- a second blocking ring housed in the second groove of the inlet sheath and having an external diameter greater than the diameter of the external portion of the passage so as to block the inlet sheath in movement in the direction of the passage by abutment of the second locking ring on an outer abutment surface of the input receptacle,
- an outlet receptacle mounted on an outlet end of the main body and through which the plurality of outlet sheaths pass, one end of the outlet sheaths being fixed to the outlet receptacle.

Thanks to these characteristics, the inlet duct is fixed to the main body in a simple and quick way. In particular, the mounting of the locking rings in the grooves of the inlet sheath locks said locking rings in the grooves so that the locking rings have a fixed position on the inlet sheath. Thus, the locking in position of the inlet sheath on the inlet receptacle is ensured by the abutment of the locking rings on the inlet receptacle.

In addition, the use of such locking rings in the grooves does not deform the sheath so that the device does not present any risk of degradation of the fibers housed in the inlet sheath by crushing or other. Thus, fixing the inlet sheath to the inlet receptacle does not require any special skill by the operator, who can safely mount the locking rings on the inlet sheath in order to fix said inlet sheath to the input receptacle.

According to embodiments, such a spreader device may comprise one or more of the following characteristics.

According to one embodiment, the spreader device further comprises a protective envelope enveloping the main body, the input receptacle and the output receptacle so as to hold the main body, the input receptacle and the output receptacle together.

Thanks to these characteristics, the attachment between the input receptacle, the main body and the output receptacle is simple and quick since it suffices to cover all of these elements with a protective envelope.

According to one embodiment, the protective envelope is a fusible sheath. Such a heat-sealed protective envelope is simple to install and reliably secures the various elements of the spreader device.

According to one embodiment, the second groove is adjacent to the external abutment surface and the first groove is adjacent to the internal abutment surface, the distance between the internal abutment surface and the external abutment surface being greater than or equal to the distance between the first groove and the second groove. Thanks to these characteristics, the inlet sheath is locked in position on the inlet receptacle in a reliable manner and has a limited mounting clearance.

According to one embodiment, the distance between the internal abutment surface and the external abutment surface is equal to the distance between the first groove and the second groove. Thus, the inlet sheath is firmly and reliably mounted on the inlet receptacle.

According to one embodiment, the distance between the internal abutment surface and the external abutment surface is greater than the distance between the first groove and the second groove. Thus, the mounting of the locking rings in the grooves is simplified due to the slight clearance between the grooves in which the locking rings are mounted and the abutment surfaces.

According to one embodiment, the first groove is an end groove of the inlet sheath, a planar end portion of the inlet sheath being housed in the internal portion of the inlet receptacle so that the sheath inlet opens into the inner portion of the passage of the inlet receptacle. Thus, only a small portion of the inlet sheath is housed in the inlet receptacle, the inlet sheath not encumbering the main body of the spreader device.

According to one embodiment, the grooves and the flat portions of the inlet sheath are alternated according to a regular spacing, the distance between the second groove and the first groove being greater than the distance between the internal abutment surface and the surface of external stop of the input receptacle.

According to one embodiment, the difference between on the one hand the distance between the first groove and the second groove and, on the other hand, the distance between the external abutment surface and the internal abutment surface is less than the space separating two successive grooves of the inlet sheath. Thus, the play between the abutment surfaces and the locking rings is minimal and the inlet sheath is reliably locked in the inlet receptacle.

According to one embodiment, the second blocking ring partially surrounds the inlet sheath. Such a locking ring is easily deformed and can be inserted simply and quickly into a groove in the inlet duct.

According to one embodiment, the outlet receptacle has a plurality of through outlet passages, each outlet sheath of the plurality of outlet sheaths being housed in a respective one of the plurality of through outlet passages. Thus, the outlet sheaths are reliably held in position by the outlet receptacle.

According to one embodiment, an exit sheath is glued to the exit receptacle. Thus, the outlet sheaths are reliably attached to the outlet receptacle.

According to one embodiment, an outlet sheath has a beveled end opening into the main body. Such an outlet sheath has a large inlet orifice compared to an outlet sheath, the end of which has a section perpendicular to the longitudinal direction of said outlet sheath. Such a large entry hole facilitates the insertion of the optical fiber into the exit duct and therefore the installation of the fanout device.

According to one embodiment, the input receptacle comprises a circular cylindrical body, an outer face of said cylindrical body having a rib delimiting an inner portion and an outer portion of said outer face, said inner portion being housed in the hollow main body and the hollow main body having an inner diameter smaller than the diameter of the rib. Such an input receptacle is simple to mount on the main body and does not risk being inserted too deeply into the main body.

According to one embodiment, the output receptacle comprises a circular cylindrical body, an outer face of said cylindrical body having a rib delimiting an inner portion and an outer portion of said outer face, said inner portion being housed in the hollow main body and the hollow main body having an internal diameter smaller than the diameter of the rib. Such an output receptacle is simple to mount on the main body and does not risk being inserted too deeply into the main body.

According to one embodiment, the output ducts have individual marking.

According to one embodiment, the invention also provides a spreader system comprising:
- a primary cable housing a plurality of optical fibers coated with individual envelopes, the optical fibers having a first marking and the individual envelopes having a second marking,
- a primary spreader device, one end of the primary cable being connected to a first end of the primary spreader device so that the optical fibers of the primary cable are distributed in the primary spreader device according to the first marking,
- a plurality of secondary spreader devices, said secondary spreader devices being spreader devices as described above, the inlet sheath of each of said secondary spreader devices having an end opposite the main body of said secondary spreader device connected to a second end of the primary spreader device, each input sheath housing a set of optical fibers having an identical first marking.

Such a spreader system makes it possible in a simple and reliable manner to redistribute optical fibers coming from a plurality of primary sheaths housed in a primary cable, for example the optical fiber deployment riser of a building, via a primary spreader and to individualize these optical fibers via the secondary fanout.

According to one embodiment, the output sheaths of each secondary spreader include a marking identical to the second marking of the individual envelopes of the optical fibers in the primary cable. Thus, it is possible to individually identify and match each fiber housed in a sheath coming out of a secondary fan out to a corresponding optical fiber housed in a primary sheath of the primary cable.

Brief description of figures

. The invention will be better understood, and other aims, details, characteristics and advantages thereof will appear more clearly during the following description of several particular embodiments of the invention, given solely by way of illustration and not limitation. , with reference to the accompanying drawings.

Figure 1 is a schematic representation of a building connected to a fiber optic supply;

Figure 2 is a schematic representation of a spreader system comprising a primary spreader and a secondary spreader;

Figure 3 is an exploded view of the secondary spreader of Figure 2;

Figure 4 is a sectional view of the secondary spreader of Figure 2;

Figure 5 is a sectional view of the inlet end of the secondary spreader of Figure 2;

Figure 6 is a sectional view of the output end of the secondary spreader of Figure 2;

Figure 1 illustrates a building 1 connected to an optical fiber arrival 2 constituting a link to the access network of one or more operators. In Figure 1, the building 1 comprises, purely by way of illustration, three floors each comprising a room 3, such a building 1 possibly comprising a different number of floors and rooms 3 per floor. In order to be able to connect each room 3 to a chosen access network by means of one or more optical fibers dedicated to this room 3, a building connection point 4 is connected to the optical fiber arrival 2.

A room 3 includes a connection terminal 5, for example in the form of an Optical Interior Termination Device or an Optical Termination Point. This connection terminal 5 constitutes the connection point of the room 3. For this, the connection terminal 5 is connected to the arrival of optical fiber 2 of the building 1 via one or more optical fibers dedicated to this room 3 and which extend between the room 3 and the building connection point 4. Typically, an optical fiber dedicated to the room 3 is deployed between the connection terminal 5 and the building connection point 4. The connection point d building 4 contains a patch panel comprising a multitude of optical connection ports, each being intended to be connected to an optical fiber of building 1.

In order to facilitate the deployment in the building 1 of the optical fibers dedicated to each of the premises 3, the various dedicated optical fibers are grouped together according to their location in the building 1. Typically, the optical fibers connected to the various connection terminals 5 of all the premises 3 of the same floor are connected to an optical connection point 6 dedicated to said floor. At the optical branch point, the various optical fibers connected to said optical branch point 6 come from a riser 8.

The riser 8 develops along the building 1. This riser 8 makes it possible to accommodate all the optical fibers of the building 1 up to the connection point of the building 4. In the riser 8, each optical fiber is individually coated with an envelope.

However, at the building 4 connection point, the different optical fibers must be identified in order to connect each optical fiber to the correct connection port in the building 4 connection point.

In order to identify the different optical fibers at the connection point of building 4, a marking system is implemented.

A first marking can be made by many means to identify the different optical fibers. In the remainder of the description, this first marking is produced by the use of different colors for the material of which the optical fibers are made, for example four colors, yellow, red, green and blue.

In order to identify the envelopes of the optical fibers, a second marking is also used. This second marking can be achieved by means of the different colors of the envelopes.

In order to redistribute the optical fibers at the level of the connection point of building 4, a spreader system is used at the level of the connection point of the building. Such a spreader system is illustrated in Figure 2 and comprises a primary spreader 9 and a plurality of secondary spreaders 10.

The primary spreader 9 is connected to the riser 8 of the building and therefore receives all the optical fibers deployed in the building. One end 11 of the riser 8 is fixed to a first end 12 of the primary fanout 9. The individual envelopes of the optical fibers are interrupted in the primary fanout 9 so that all of the optical fibers pass through the primary fanout 9 and come out without an individual envelope.

At the output of the primary spreader 9, the various optical fibers are grouped together according to the first marking. Typically, all the optical fibers having the same color are grouped together at a second end 13 of the primary fanout 9. The second end 13 of the primary fanout 9 is connected to a plurality of intermediate sheaths 14. Each group of optical fibers grouped together according to the first marking is housed in a dedicated intermediate sheath 14 at the level of the second end 13 of the primary spreader 9.

As illustrated in this figure 3, the intermediate sheath 14 is a corrugated sheath. The intermediate sheath comprises an alternation of planar cylindrical portions 15 and grooves 16. In the embodiment illustrated in the figures, the grooves 16 have a regular spacing along the intermediate sheath 14, the different planar cylindrical portions 15 thus having a same length.

One end of each intermediate sheath 14 opposite the primary spreader 9 is associated with a first end 17 of a respective secondary spreader 10. A second end 18 of each secondary fanout 10 is also connected to a plurality of output sheaths 39, each output sheath 39 housing a respective optical fiber coming from the intermediate sheath 14 connected to the first end 17 of said secondary fanout 10.

Each output sheath 39 connected to a secondary spreader 10 has a third distinct marking. This third marking is identical to the first marking and therefore determined according to the color of the optical fibers.

By way of example, an optical fiber having a first green color marking is housed in an intermediate sheath 14 housing all of the optical fibers having a first green color marking coming from the riser 8.

Figures 3 to 6 illustrate different views of the secondary spreader 10 of Figure 2.

The secondary spreader 10 comprises a main body 20, an input receptacle 21 and an output receptacle 22.

The main body 20 is a cylinder of revolution and hollow. This main body 20 forms a central housing 23 through.

The input receptacle 21 has a hollow cylindrical shape.

An outer face 24 of the inlet receptacle 21 has a diameter slightly smaller than the inner diameter of the central housing 23 of the main body 20. The inlet receptacle 21 has a rib 25 projecting radially from the outer face 24. This rib 25 has a diameter greater than the internal diameter of the central housing 23 of the main body 20.

The input receptacle 21 is mounted on the main body 20 by insertion into the central housing 23 until the rib 25 is brought into abutment against a first end 26 of the main body 21.

The outlet receptacle 22 has, similarly to the inlet receptacle 21, a hollow cylindrical shape, one outer face 27 of which has a diameter slightly smaller than the diameter of the central housing 23 so as to be housed in the central housing 23 at the level of a second end 28 of said main body 20, a rib 29 in abutment against said second end 28 limiting the insertion of the outlet receptacle 22 into the central housing 23.

The inlet receptacle 21 has the function of fixing the intermediate sheath 14 on the secondary spreader 10. The inlet receptacle 21 has a through passage 30. This through passage 30 has an outer portion 31 and an inner portion 32 separated by a shoulder 33.

The outer portion 31 of the through passage 30 has a diameter slightly greater than the outer diameter of the intermediate sheath 14, that is to say slightly greater than the outer diameter of the flat cylindrical portions 15 of the intermediate sheath 14. The inner portion 32 has a diameter greater than the diameter of the outer portion 31, and therefore greater than the diameter of the intermediate sheath 14.

In order to fix the intermediate sheath 14 on the inlet receptacle 21, the intermediate sheath 14 is inserted into the through passage 30 so that a first groove 34, for example an end groove of the intermediate sheath 14, is housed in the internal portion 32 of the through passage 30.

A first locking ring 35 is mounted in a fixed position on the intermediate sheath 14. More specifically, this first locking ring 35 is housed in the first groove 34 of the intermediate sheath 14. For this, the first locking ring 35 has a internal diameter smaller than the external diameter of a flat cylindrical portion 15 of the intermediate sheath 14.

The first groove 34 being housed in the internal portion 32 of the through passage 30, the first locking ring 35 is also housed in the internal portion 32 of the through passage 30.

The first locking ring 35 has an outer diameter greater than the diameter of the outer portion 31 of the through-passage 30. In other words, the shoulder 33 of the through-passage 31 forms an internal abutment surface blocking the passage from the first locking ring 35 to the through the outer portion 31 of the through passage 30. Thus, on the one hand the first locking ring 35 being housed in the first groove 34 is integral in movement with the intermediate sheath 14 and, on the other hand, the first locking ring lock 35 is locked in movement towards the outer portion 31 of the through passage 30 by abutment on the shoulder 33 of the through passage 30. The end of the intermediate sheath 14 is therefore locked in the inner portion 32 of the through passage 30 when a traction tending to extract the intermediate sheath 14 from the through passage 30 is exerted. In addition, the first groove 34 being an end groove of the intermediate sheath 14, the intermediate sheath 14 is interrupted in the secondary spreader 10 in the internal portion 32 of the through passage 30 and does not disturb the redirection of the optical fibers in the secondary fan 10.

A second locking ring 36 is housed in a fixed manner in a second groove 37 of the intermediate sheath 14. This second locking ring 36 has an internal diameter smaller than the external diameter of the flat cylindrical portions 15 of the intermediate sheath 14 so that the second locking ring 36 is integral in movement with the intermediate sheath 14. In addition, this second locking ring 36 has an outer diameter greater than the inner diameter of the outer portion 31 of the through passage 30.

The second groove 37 is a groove located outside the through passage 30 and outside the secondary spreader 10. Preferably, and as illustrated in the figures, this second groove 37 is the groove 16 of the intermediate sheath 14 located outside the secondary spreader 10 and the closest to the inlet receptacle 21. Thus, the insertion of the intermediate sheath 14 in the through passage 30 is blocked beyond the second groove 37 due on the one hand to the fixed mounting of the second locking ring 36 in the second groove 37 and on the other hand due to the abutment of said second locking ring 36 on an external abutment surface formed by the inlet receptacle 21 at the entrance of the outer portion 31 of the passage through 30.

Mounting the first locking ring 35 in the first groove 34 and the second locking ring 36 in the second groove 37 of the intermediate sheath 14 thus makes it possible to fix the end of the intermediate sheath 14 on the inlet receptacle 21.

When mounting the locking rings 35 and 36 on the intermediate sheath 14, the end of the intermediate sheath 14 is first inserted into the through passage 30 so that the first groove 34 is received outside the through passage. 30. The first locking ring 35 is then mounted in the first groove 34. Then, the intermediate sheath 14 is pulled so as to bring the first locking ring 35 into the internal portion 32 of the through passage 30 in abutment against the shoulder 33. Finally, the second locking ring 36 is mounted on the second groove 37, that is to say on the groove 16 of the intermediate sheath 14 located outside the through passage 30 and located closest to the inlet receptacle. 21.

In order to facilitate the assembly of the locking rings 35 and 36 in the grooves 34 and 37, the locking rings 35 and 36 are split. In the embodiment illustrated in the figures, the first locking ring 35 is a split ring whose slot is widened to mount said first locking ring 35 in the first groove 34. The second locking ring 36 is itself a circlip surrounding partially the intermediate sheath 14.

The input receptacle 21 of the secondary spreader 10 makes it possible to individualize the different optical fibers coming from the intermediate sheath 14. The output receptacle 22 has a plurality of output passages 38 passing through the output receptacle 22, typically a output passage 38 by optical fiber housed in the intermediate sheath 14.

A plurality of outlet sheaths 39 are fixed in the outlet receptacle 22. Each outlet sheath 39 passes through a respective outlet passage 38 of the outlet receptacle 22. The outlet sheaths 39 are fixed on the outlet receptacle 22 for example by bonding. For this, the outlet sheaths 39 are inserted into the outlet passages 38 in a through manner so that one end of the outlet sheath 39 protrudes from the outlet passage 38. Glue is then applied to the outer face of said protruding portion of the end of the outlet sheath 39. The outlet sheath 39 is then pulled towards the outside of the outlet passage 38 so as to bring back the external face of the said protruding portion of the outlet sheath 39 on which the glue is applied in the exit passage 38 so that the glue makes it possible to fix the exit sheath 39 in the exit passage 38.

The ends of the output sheaths 39 are preferably bevelled so as to increase the entry surface of said output sheaths 39, thus facilitating the insertion of the optical fiber into the output sheath 39.

Optical fibers generally in the form of optical fiber strands cannot be fitted directly with connectors given their mechanical fragility. The output sheaths 39 make it possible to dress said fiber optic strands in order to then be able to equip them with connectors 7.

Each output sheath 39 has the same second marking, namely for example the same color, as the individual envelope in which the optical fiber was housed in the riser 8. For example, an output sheath 39 intended to house a fiber optic having a second green color marking may also have a green color, thus making it simple and direct to know that the optical fiber housed in this output sheath 39 has an individual envelope of green color in the riser 8.

In order to secure the inlet 21 and outlet 22 receptacles to the main body 20, an envelope 40 is applied to the secondary spreader 10. This envelope 10 completely surrounds the main body 20 as well as the portions of the inlet receptacle 21 and of the output receptacle 22 protruding from the central housing 23 of the main body 20. This envelope 40 is for example made of fusible plastic material in order to ensure on the one hand its good fixation on the main body 20, the input receptacle 21 and the outlet receptacle 22 and, on the other hand, the good attachment and connection between them of the main body 20, of the inlet receptacle 21 and of the outlet receptacle 22. The envelope 40 is for example made in the form of an iron-on sheath.

Such an envelope 40 is simple to install and does not require complex handling while presenting no risk of degradation of the input 21 and output 22 receptacles. In addition, such an envelope 40 may have a marking corresponding to the first marking to indicate to the operator that the secondary fanout 10 that it surrounds houses all the optical fibers having this first marking.

Although the invention has been described in connection with several particular embodiments, it is obvious that it is in no way limited thereto and that it includes all the technical equivalents of the means described as well as their combinations if these fall within the scope of the invention as defined by the claims.

The use of the verb "to comprise", "to understand" or "to include" and of its conjugated forms does not exclude the presence of other elements or other steps than those set out in a claim.

In the claims, any reference sign in parentheses cannot be interpreted as a limitation of the claim.

Claims (15)

Spreader device (10) for optical fibers comprising:
- an input sheath (14) housing a plurality of optical fibers, the input sheath (14) having alternating planar portions (15) and grooves (16),
- a plurality of output sheaths (39), each output sheath (39) housing a respective optical fiber of the plurality of optical fibers and being terminated by a connector (7),
- a main body (20) of hollow cylindrical shape,
- an inlet receptacle (21) mounted on an inlet end (26) of the main body (20), said inlet receptacle (21) comprising a through passage (30), said passage (30) having a shoulder inner (33) delimiting an outer portion (31) of the passage (30) and an inner portion (32) of said passage (30), the outer portion (31) having a diameter greater than the outer diameter of the inlet sheath (14 ), the inner portion (32) having a diameter greater than the diameter of the outer portion (31), the inlet sheath (14) being housed in the passage (30) so that a first groove (34) of the inlet sheath (14) is housed in the internal portion (32) of the passage (30) and that a second groove (37) is housed outside the passage (30),
- a first blocking ring (35) housed in the first groove (34) and having an external diameter greater than the diameter of the external portion (31) of the passage (30) so as to block the inlet sheath (14) movement out of the passage (30) by abutment of the first locking ring (35) on an internal abutment surface carried by the inlet receptacle (21), the first groove (34) being housed in the internal portion (32) of the passage (30) and the shoulder (33) forming the internal abutment surface,
- a second blocking ring (36) housed in the second groove (37) of the inlet sheath (14) and having an external diameter greater than the diameter of the external portion (31) of the passage (30) so as to block the inlet sheath (14) moving in the direction of the passage (30) by abutment of the second locking ring (36) on an external abutment surface of the inlet receptacle (21),
- an outlet receptacle (22) mounted on an outlet end (28) of the main body (20) and crossed by the plurality of outlet sheaths (39), one end of the outlet sheaths (39) being fixed on the receptacle outlet (22). Spreader device according to claim 1, further comprising a protective casing (40) enveloping the main body (20), the input receptacle (21) and the output receptacle (22) so as to hold the main body (20) together ), the input receptacle (21) and the output receptacle (22). Spreader device according to claim 2, in which the protective envelope (40) is a heat-sealed sheath. Spreader device according to one of Claims 1 to 3, in which the second groove (37) is adjacent to the external abutment surface and the first groove (34) is adjacent to the internal abutment surface, the distance between the internal abutment and the external abutment surface being greater than or equal to the distance between the first groove (34) and the second groove (37). Spreader device according to one of Claims 1 to 4, in which the first groove (34) is an end groove of the inlet sheath (14), a planar end portion of the inlet sheath (14 ) being housed in the inner portion (32) of the inlet receptacle (21) so that the inlet sheath (14) opens into the inner portion (32) of the passage (30) of the inlet receptacle (21) . Spreader device according to one of Claims 1 to 5, in which the grooves (16) and the flat portions (15) of the inlet sheath (14) are alternated at regular spacing, the distance between the second groove (37 ) and the first groove (34) being greater than the distance between the inner abutment surface and the outer abutment surface of the inlet receptacle (21). Spreader device according to one of Claims 1 to 6, in which the second blocking ring (36) partially surrounds the inlet sheath (14). Spreader device according to one of Claims 1 to 7, in which the exit receptacle (22) comprises a plurality of through exit passages (38), each exit sheath (39) of the plurality of exit sheaths (39) being housed in a respective one of the plurality of through exit passages (38). Spreader device according to one of Claims 1 to 8, in which an outlet sheath (39) is glued to the outlet receptacle (22). Spreader device according to one of Claims 1 to 9, in which an outlet sheath (39) has a bevelled end opening into the main body (20). Spreader device according to one of Claims 1 to 10, in which the input receptacle (21) comprises a circular cylindrical body, an external face (24) of the said cylindrical body having a rib (25) delimiting an internal portion and a outer surface of said outer face (24), said inner portion being housed in the hollow main body (20) and the hollow main body having an internal diameter smaller than the diameter of the rib (25). Spreader device according to one of Claims 1 to 11, in which the output receptacle (22) comprises a circular cylindrical body, an external face (27) of the said cylindrical body having a rib (29) delimiting an internal portion and an external of said external face (27), said internal portion being housed in the hollow main body (20) and the hollow main body (20) having an internal diameter smaller than the diameter of the rib (29). Spreader device according to one of Claims 1 to 12, in which the output sheaths (39) have individual markings. Spreader system comprising
- a primary cable (8) housing a plurality of optical fibers coated with individual envelopes, the optical fibers having a first marking and the individual envelopes having a second marking,
- a primary spreader device (9), one end of the primary cable (8) being connected to a first end (12) of the primary spreader device (9) so that the optical fibers of the primary cable (8) are distributed in the device primary spreader (9) according to the first marking,
- a plurality of secondary spreader devices (10), said secondary spreader devices (10) being spreader devices according to one of claims 1 to 13, the inlet sheath (14) of each of said secondary spreader devices (10) having an end opposite the main body (20) of said secondary fanout device (10) connected to a second end (13) of the primary fanout device (9), each input sheath (14) housing a set of optical fibers having a first marking identical. Fanout system according to claim 14, in which the output sheaths (39) of each secondary fanout (10) have a marking identical to the second marking of the individual envelopes of the optical fibers in the primary cable (8).