FR2678076A1 - Module for storing a transmission support reserve on a link, especially a fibre-optic link, and storage device including a set of such modules - Google Patents

Abstract

This module (6) for storing a transmission support reserve on a link, especially a fibre-optic link, includes at least two storage reels (10, 11) enabling a certain length of transmission support to be stored with at least one passage of the said support from one reel to the other, and means for adjusting the relative position of the centre of these reels, as a function of the reserve length to be stored, in order to obtain a sufficient tension in the said support within this storage module.

Description

Module for storing a reserve of transmission medium on a link, in particular with optical fiber and storage device comprising a set of such modules
The present invention relates to the storage of reserves of transmission media on a link, in particular to optical fiber, in which case we will most frequently consider the following.

 Such storage modules can in particular be used at the interface between fiber optic connection cables and signal processing equipment carried by these fibers, for example to build up reserves usable in the event of repair having to be carried out on these fibers in this equipment, or even to build up reserves from which one can come to draw in more or less quantity, depending on whether the processing equipment for which these fibers are intended are more or less distant from the common (fixed) points of arrival of these fibers .

 This is for example the case of telecommunications equipment, comprising processing cards generally grouped in assemblies called chassis, themselves grouped in assemblies called frames, generally with one chassis per frame assigned to a set of such storage modules. , each of these modules being in turn assigned to a fiber leading to one of the processing cards of this frame, according to a modifiable distribution scheme, according to the desired operating scheme for this equipment.

 To make such a storage module, a reel is generally used on which a certain length of fiber is wound, corresponding to the desired reserve.

 When there is only one fixed access point to this coil, a problem arises if the length corresponding to the desired reserve, and constituting a variable portion, depending on the destination card, of a maximum length corresponding at the greatest distance to be covered, is not an integer multiple of the length of the circumference of this spool, since the length of excess fiber can no longer be properly stored and maintained; it is placed in an anarchic fashion around the coil, its minimum radius of curvature is no longer automatically respected and it can ultimately exceed outside the frame, which must be absolutely avoided.

 The present invention aims to solve this problem and allow, by a simple means to implement, not only the constitution of usable reserves as seen above, but also the absorption of possible lengths of excess fiber, when these have a length less than or greater than an integer multiple of the storage length presented by the spool.

 The subject of the present invention is a module for storing a reserve of transmission medium on a link, in particular with optical fiber, essentially characterized in that it comprises at least two storage coils making it possible to store a certain length of medium for transmission with at least one passage of said support from one reel to another, and means for adjusting the relative position of the center of these reels, as a function of the length of reserve to be stored, to obtain sufficient tension of said support to inside this storage module.

 The present invention also relates to a storage device comprising a set of such modules.

 Other objects and characteristics of the present invention will appear on reading the following description of exemplary embodiments, made in relation to the appended drawings in which - Figure 1 illustrates the use of storage modules according to the invention in a frame of telecommunications equipment, - Figure 2 shows on a larger scale, part of the frame of Figure 1, containing said storage modules, - Figure 3 shows, on a larger scale, one of these storage modules, according to a first embodiment of the invention, this module also being shown on the one hand during assembly on an axis of rotation around which it is articulated, and on the other hand once mounted on this axis, - Figures 4A, 4B, 4C, 4D are block diagrams intended to make the principle implemented in the present invention understood, according to the first embodiment thereof, - Figure 5 represents a mod ule of storage, according to a second embodiment of the invention, - Figures 6A, 6B, 6C, 6D are block diagrams intended to explain the principle implemented in the present invention, according to this second embodiment , - Figure 7 is a perspective view of a coil viewed from below and equipped, according to an exemplary embodiment of the invention, with a guide and holding device to allow movement of its center along d 'a slot made on a plate supporting it, - Figures 8 and 9 are views, respectively from above and in cross section along the axis IX-IX of Figure 8, of said coil mounted on said plate with its device guiding and holding, - Figure 10 is a detail of the axis of rotation (visible in Figure 3) partially in section, - Figure li is a view, simplified and very schematic, in cross section, of a set trays equipped to receive extra e electrical connection elements interposed on the path of the transmission support between two coils.

 In FIG. 1 is shown a frame of telecommunications equipment, generally referenced 1, in this case containing four chassis such as 2 in turn containing cards such as 3 for the processing of signals carried by optical fibers such as 4 , routed at the level of each of the cards by appropriate storage, guiding and distribution means, and a chassis 5 containing modules such as 6 for storing the optical fiber reserves of the different fibers such as 4.

 These storage modules are in this case divided into two groups, and are in each of these groups arranged horizontally and one above the other, with a possibility of access to each of them individually as illustrated in the drawing for the module referenced 6, by rotating it around an axis 7 on which all the modules of a group are articulated.

 In the embodiment considered here, the access point of a fiber to a storage module is located near the axis 7, as illustrated more clearly in FIG. 2 where the reference 8 designates the optical fiber d 'arrival at this module and reference 8' the starting optical fiber of this module. This arrangement avoids variations in fiber length and therefore the stresses on this fiber during the rotation of the module considered.

 As illustrated more clearly in FIG. 3, each of these modules comprises a plate 9, in this case of shape substantially in a quarter circle, centered on the axis 7 and whose edges 32, 33 equal to the radius of this quarter of circle were raised at right angles and in the same direction over most of their length from the outer arc of the circle, and supporting two coils such as 10 and 11. These coils, consisting of a hollow cylinder 34 thin and with a flange 35, make it possible to maintain and store a certain length of optical fiber, with at least one passage of this fiber from one reel to the other, and have a variable positioning with respect to to the other, in order to absorb possible lengths of excess fiber, as will be described in more detail below.

 According to a first embodiment, which corresponds to the case illustrated in FIG. 3, the centers Bi, B2 of the coils 10 and li are therefore movable along two lines, in this case non-parallel. These lines, advantageously arranged in directions facilitating access to these coils from the access point to this module, are here materialized by two slots 14 and 15 formed in the plate 9.

 In FIGS. 4A to 4D corresponding to this embodiment, four different relative positions are thus shown by way of example for the points Bl and B2, going in the direction of an increasing distance of these points from one figure to the next. .

 To understand the mode of coiling the fiber inside this storage module, in one or other of the embodiments given here by way of example, it is specified that in the example considered, the points of arrival at these coils and departure of these coils constitute the same point, marked A, of the circumference of one of these coils, for example that of center Bi.

 In this case, the winding directions on these two coils must be opposite, at least over part of the path of the fiber inside this storage module.

Thus in FIG. 4A, which corresponds in this case to a reserve of minimum length, the arrival fiber, marked Al, is wound, in this case about three-quarters of a turn, in a direction corresponding to the direction of rotation clockwise on the center coil B2, then, in this case about a half turn and in the opposite direction of clockwise rotation, on the center coil B1 to thereby provide the fiber for spotted departure
A2.

 In the following figures 4B to 4D, which each correspond to the case of a reserve of greater length, the fiber is in this case wound around the assembly formed by the two spools, in this case following a single turn on the Figure 4B, following two turns in Figure 4C and following three turns in Figure 4D plus the complementary windings as seen in Figure 4A which allow the arrival and departure on these coils by point A.

 Other positions of the points B1 and B2 than those shown in FIGS. 4A to 4D would of course be possible, as would other modes of coiling or passing from one reel to the other, or as well as other combinations of positions and modes of coiling or passing from one reel to another.

For example, in the case considered here, of an arrival and a departure at the same point on the circumference of one of the coils, and starting from the case corresponding to FIG. 4A, one or more turns in the same winding direction as on the coil B2 could be carried out on the coil Bl before switching to the coil
B2, just as one or more windings could be carried out on the coil B2 before going back to the coil Bi, on which could then also be carried out one or more windings (then in the opposite direction to that of the coil B2), instead of making one or more windings around the assembly formed by the two coils.

 In the embodiment illustrated in FIGS. 6A to 6D which represent cases similar to those of FIGS. 4A to 4D, the centers B1 and B2 of the two coils are movable along a line joining these centers, this line being materialized by a slot 16 made in the plate 8, as illustrated in FIG. 5.

 In this embodiment, the edges of the two coils are advantageously truncated on their part facing each other as illustrated at 28, 29 in FIG. 5, so as to allow them to be brought closer together.

 It will be noted that the relative arrangement of the slots in the first mode, or the length of the slot in the second mode, advantageously make it possible to obtain a relative position of the points B1 and B2, corresponding in the example described to that illustrated in the figure 4D, or in FIG. 6D, allowing an overtaking length equal to or slightly less than the length of the circumference of a coil.

 Whatever the embodiment, it could also be envisaged to make one of the two coils displaceable, the other being fixed.

 It could also be envisaged to access the storage module at two different points on two different reels, in which case the winding directions would not necessarily be opposite from one reel to the other.

 Figures 7, 8 and 9 illustrate an exemplary embodiment of a means for making the center of a coil movable along a line materialized by a slot, that this slot is one of the slots 14 and 15 of the first embodiment, or the slot 16 of the second embodiment.

 This means consists on the one hand in providing the coil, for example that marked 10, seen in perspective and from below in FIG. 7, in its center, with a so-called guiding and holding device referenced 17, having on its thickness two grooves, 30, 31, allowing it to be guided along the edges of this slot, and on the other hand to produce the plate in a material such as a light alloy or a plastic material allowing said plate to be clamped inside the grooves of said guide and holding device by simple friction, and to provide on said slot a flared part, as indicated in 18 in FIG. 8, allowing an introduction of said guide and holding device into this slot after having subjected it to a rotation at 900 with respect to its position after introduction, illustrated in FIGS. 8 and 9.

 FIG. 3 also shows a particularly advantageous method of fixing the plate 9 supporting said storage coils, to the axis of rotation 7 around which it is able to pivot so as to be released from the other plates.

 This axis is for this formed, as illustrated in Figure 10, of a part which has been machined to be in the form of a succession of cylinder portions which are alternately of large and small section, the portions of large section such as 71 having a thickness equal to or very slightly greater than the height of a storage module, and the portions of small section such as 72 having a thickness equal to or very slightly greater than the thickness of the tray.

 The plate further comprises, at its end allowing it to be fixed to this axis, an opening 22 of substantially circular shape having a diameter adapted to the largest of these sections, and extending in the direction of said end, by an opening 23 oblong, having a width adapted to the smallest of these sections.

 This plate can thus be mounted on this axis by the largest of these openings, then blocked, at the desired location along the axis, by simply pulling it forward at the location of the portion of small section. corresponding to this location.

 This embodiment has the particular advantage, when accessing a tray, of avoiding entraining the adjacent trays in the same rotational movement around the axis.

 FIG. 11 shows a particularly advantageous use of the plate supporting the storage coils, in which this plate also supports electrical connection elements 27 allowing a change of type of transmission medium inside this reserve.

 As the dimensions of these electrical connection elements are generally such that it exceeds the space available between two plates along the axis of rotation 7, each plate advantageously comprises two orifices such as 25 and 26, also visible in the figures 3 and 5, which are placed on the path taken by the fiber to pass from one reel to the other, and which have a shape adapted to maintain these connection elements, in a position in which a part of these elements occupies the free space between the plate in question and the upper plate, and another part the free space between the plate in question and the lower plate, these connection elements being also arranged alternately in one or the other of these orifices, from one tray to another, which eliminates all risks of seeing them collide when pivoting in one direction or another of the adjacent storage modules.

 The description which has just been made of this module and of this storage device has been given by way of example, but other embodiments of the plate, of the coils, of their guiding and holding device, may be considered while remaining within the scope of the invention.

 It is also possible to remain within the scope of the invention by providing a number of slots and coils greater than two.

Claims (12)

1 / Module for storing a reserve of transmission medium on a link, in particular with optical fiber, characterized in that it comprises at least two storage coils (10, 11) making it possible to store a certain length of transmission medium with at least one passage of said support from one reel to another, and means for adjusting the relative position of the center of these reels, as a function of the length of reserve to be stored, to obtain sufficient tension of said support at the inside this storage module. 2 / Module according to claim 1, characterized in that the points of arrival and departure of said module being located on the same reel, the winding directions are opposite from one reel to the other on at least part of said reservation. 3 / Module according to one of claims 1 and 2, characterized in that said adjusting means comprise means for allowing the displacement of the center of at least one of the coils along a line passing through the center of this coil . 4 / Module according to one of claims 1 and 2, characterized in that said adjusting means comprise means for allowing the displacement of the center of at least one of the coils along a line joining the center of these coils. 5 / Module according to claims 1 and 2, characterized in that said adjusting means comprise means for allowing the displacement of the center of the two coils, respectively along two lines passing through the center of these coils. 6 / Module according to one of claims 1 to 5, characterized in that said coils are supported by a plate (9). 7 / Module according to one of claims 3 to 5, characterized in that a line is materialized by a slot (14, 15, 16) formed in a plate (9) supporting said coils, and in that the coil of which the center is intended to move along this line is provided at its center with a part (17) for guiding along this slot and for holding inside this slot. 8 / module according to claim 6, characterized in that said plate is provided with at least one orifice for housing at least one electrical connection element (27) allowing a change of type of transmission medium inside of the said reservation. 9 / A device for storing reserves of transmission supports on a link, characterized in that it comprises a set of storage modules (6) according to one of claims 1 to 8, mounted movably around an axis of rotation common (7). 10 / Device according to claim 9, characterized in that the access points to these modules are located near said axis. 11 / Device according to one of claims 9 and 10, combined with claim 8, characterized in that, said plates being each provided with two orifices (25, 26) for housing said electrical connection elements (27), these the latter are housed alternately in one or the other of said orifices, from one module to another inside this storage device. 12 / Device according to one of claims 9 and 10, combined with claim 6, characterized in that said axis of rotation (7) is in the form of a succession of cylinder portions (71, 72) which are alternately of large and small section, and in that said plates have at the place of their articulation around said axis, an opening (22) of a shape adapted to the largest (71) of these sections allowing mounting of said modules on said axis, and extending through an opening (23) of a shape adapted to the smallest (72) of these sections, allowing said modules to be maintained once mounted on said axis.