FR2583528A1 - Multi-conductor cable, especially an optical cable, and its manufacturing process - Google Patents

Abstract

a) Multi-conductor cable. b) The cable is characterised in that the cavities 9 of the fibre-carrying rod 7 are straight and parallel to the axis of the fibre-carrying rod (before winding it) and receive conductor elements 9 in order to form an elementary assembly, this assembly being wound longitudinally with untwisting about the support rod 10 or the axis of the cable. c) The invention relates especially to fibre-optic cables.

Description

"Multicore cable, in particular optical cable, and its manufacturing process".

 The present invention relates to a multiconductor cable, in particular an optical cable and to a method for manufacturing such a cable.

 Various methods are already known for producing multiconductor cables and, in particular, optical fiber cables. It is thus known to make multiconductor cables composed, based on an elementary assembly, of a rod whose periphery is provided with helical grooves (also called cells), of determined pitch. These cells receive the conductive elements, generally optical fibers. It is thus known to produce rods having, for example, each Up to ten cells for receiving ten optical fibers.

 Although there are cables formed by a single rod provided with an appropriate number of helical cells, it is also known, generally in cable manufacturing, to combine several such elementary assemblies to produce a multiconductor cable having a higher number conductors, for example to combine seven elementary assemblies of each ten conductive elements to result in a cable of 70 conductive elements. These elementary assemblies are wound in a long pitch around a central core, placed in the axis of the cable to be produced and which optionally transmits the mechanical tensile forces applied to the cable.

Generally, in the description,
will use the term "conductive element" throughout
generality. A conductive element is generally a
conductor of electric current, of an acoustic wave or
any other physical phenomenon suitable for transmission
like light, etc. This driver is himself protected
by one or more envelopes.

According to the different techniques of art
prior art, it is known to make cables with several
elementary assemblies by arranging the assemblies
elementary around the central friend, in successive layers
and in each layer the elementary assemblies have either
a regular helical line, ie a line according to the so-called "ZS" technique, that is to say with a
step right and step left, this pattern repeating along
of the cable. The repeat interval for this pattern will also be
called "cable pitch" by analogy with a pitch of a path
helical.

Generally, in assemblies
elementary, the pitch is of the order of 50 to 500 mm and in
the general assemblies, the steps often remain lower
at 1000 mm.

As indicated above, the assemblies
elementary and general are carried out according to different
techniques, such as the twist, twist technique,
over-distortion, etc. In general, according to the prior art,
we prefer the twist method which best preserves
the integrity and balance of the materials constituting the
elementary assemblies.

Accumulated experience proves that to ensure
good transmission quality, it is necessary to
define and control the regularity of the curvature of
conductors because any excessive change in curvature
of a driver is detrimental to the quality of the
transmission. While this is important for
electrical conductors, this regularity is decisive in the case of optical fibers. Indeed, in a coaxial pair, an excessive curvature causes a local variation of the characteristic impedance on which the
TOS of the cable and can make it prohibitive if this defect resulting from excessive bending is periodic.

 In the case of an optical fiber, the loss of light is all the more important the abrupt change in curvature and the greater the curvature. If the fiber no longer has any degree of freedom, under the effect of a tensile stress, it will be subjected over the entire length to deformations of the same nature, which can lead to the degradation of this fiber for the transmission of the light.

 The object of the present invention is to create a multiconductor cable and a method of manufacturing such a cable, making it possible to precisely control the curvature of the conductive elements, by simple means, of an easy and reliable implementation.

 To this end, in particular in the case of the optical cable, the invention relates to a cable characterized in that, in the elementary assembly, the conductive elements are parallel to the axis of the elementary assembly, this elementary assembly being wound at twist longitudinally around the axis of the cable to form the general assembly.

 The straight cells of each rod considerably facilitate the manufacture of such a rod, either by extrusion or by machining, since it is no longer necessary to have a relative rotation between an extrusion and machining tool and the rush. This also makes it possible to produce more precise cells and extremely simple deposition of the conductive elements in the cells. As the general assembly, that is to say the cable, is obtained in particular by winding one or more elementary assemblies around the axis of the cable, the radius of curvature of the elementary assemblies thus wound around the axis of the cable only depends on the winding around the cable since the cells are parallel to the axis of the cable. This allows to precisely adjust the curvature and especially to avoid exceeding the limit curvature detrimental to the operation of the cable.

 According to a particular characteristic, the elementary assembly is wound in a constant pitch around the axis of the general assembly.

 In this case, all the conductors included in the same layer of the general assembly have the same curvature, constant and defined by the geometric parameters of the assembly.

 Such a cable is of a particularly simple embodiment since the elementary assembly or assemblies are wound at constant pitch around the axis of the cable.

 According to another characteristic, the general assembly comprises a core and at least one elementary assembly wound around this core.

 According to another characteristic, the cells have a U-shaped or V-shaped rounded section.

According to another characteristic, the conductive elements are optical fibers
The invention also relates to the means for producing a multi-conductor cable as defined above and, in particular, a method for producing a multi-conductor cable and, in particular, an optical cable.

 In this case, the method is characterized in that at least one elementary assembly is formed by making a rod ring with cells parallel to the axis of the rod and by depositing a conductive element in at least certain cells and the elementary assemblies are wound up. around the axis of the cable.

 The implementation of this method of producing a cable according to the invention is particularly simple since it minimizes the rotating elements of the fiber deposition machine.

 The production of rods provided with cells is very simple since this can be done by extrusion without a rotating part or by machining the cells. In both cases, extremely precise cells are obtained with reduced means. The removal of the conductive elements, in particular of the optical fibers in the cells, can be done with great precision as for the extra length.

 The general assembly of the cable by winding the elementary assemblies around the axis of the cable is done in the usual way.

 Finally, according to a particular characteristic of the process, the winding of the elementary assemblies on the axis of the cable is done at constant pitch.

The present invention will be described in more detail with the aid of the accompanying drawings in which
FIG. 1 is a schematic perspective view of a rod according to the invention,
- Figures 2 and 3 are two examples of rods with different groove section,
- Figure 4 is an enlarged view of the helical arrangement of an elementary assembly according to the invention around a cable groin.

 Figure 1 shows on a very enlarged scale a rod 1 having grooves or cells 2, made in its periphery. These cells 2 are parallel to the axis X-X of the rod. The rod provided with conductive elements constitutes an elementary assembly.

 Figures 2 and 3 show sectional views of two rods with different cell shapes. For the rod 3 in Figure 2, the cells 4 have a U-shaped section while for the rod 5 in Figure 3, the cells 6 have a rounded V-shaped section.

 Figure 4 schematically shows the arrangement of a rod 7 with cells 8 in which are placed conductive elements 9. The conductive elements 9 may be optical fibers and constitute the elementary assembly.

This rod 7 is arranged in a twisting helix around a frame 10 of the cable or general assembly. Several rods 7 can be wound with the same twisting pitch around the central element 10. This central element generally consists of an element capable of withstanding tensile forces; it can also be constituted by a rod provided with conductive elements. Like the cells 8 of the rod 7 are parallel to the axis of the rod 7, when the rod 7 is arranged helically around the friend 10, the curvature of the conductive elements 9 is perfectly defined.

 Although in the diagram of FIG. 4, the cable friend 10 is materialized by a tubular element, this core can be limited to a geometric axis, not materialized, for example when several elementary assemblies in limited numbers, such as the 'assembly 7, are assembled with respect to each other, all following the same pitch.

 It should be noted that the elementary assemblies are assembled with a twist around the friend or around the geometric axis not materialized by a core. Such an arrangement is essential for the invention. To emphasize this characteristic, FIG. 4 shows a system of two axes of coordinates (ox, oy) plotted in the plane of section of the friend 10 as well as a system of two axes of coordinates (ol xl ol yl) plotted in the section of the rod 7 arranged in a helix.

According to the invention, the system (ol xl; ol yl) always remains parallel to the system (ox, oy) regardless of the point ol along the axis of the rod: this means that the joint is twisted around groin 10; there is no rolling "epicycloid of the rod around the soul.

 The cable according to the invention is produced in a particularly simple way since the rod is produced with cells.

by extrusion; these cells can also be trailed in the smooth rod before the removal of the conductive elements.

As the cells are rectilinear, with an axis parallel to the axis of the rod, the machine for extruding the rods with cells or for cutting the cells in a smooth rod, is extremely simple without a rotating part as in the devices of the art. prior. This eliminates all the problems of enslavement of the relative rotational movements of the tools in order to obtain cells with constant pitch.

 The removal of the conductive elements, in particular optical fibers in the straight cells, is a particularly simple operation, which is carried out on a machine requiring no rotating part - with the exception of the coils unwinding the rod and the conductive elements and the coil of reception receiving the cable. In particular, the subjections imposed by the untwisting of the fibers are eliminated.

 Given the very great simplicity of this manufacturing and as during the realization of the elementary assembly, the rods do not rotate on themselves but keep the same orientation, (that is to say are twisted with twist), the conductive elements can be removed from the rods alveoli at a selected point. There. has no difficulty temporarily holding the conductive elements in the cells between the point of removal of these conductive elements in the -alveoli and the point where the rod receives its first protective envelope.

 The machine performing the general assembly is advantageously a conventional twisting assembly cable machine provided with suitable means for ensuring equal tension on each of the elementary assemblies.

Claims (7)

 10) Multiconductive cabal, in particular optical cable, composed of at least one elementary assembly formed of at least one conductive element, cable characterized in that, in the elementary assembly, the conductive elements are parallel to the axis of the elementary assembly, this elementary assembly being twisted longitudinally around the axis of the cable to form the general assembly.  20) Multicore cable, according to claim 1, characterized in that the elementary assembly is formed of a rod (1, 3, 5, 7) provided with cells, at least some of which contain a conductive element, these cells (2 , 4, 6, 9) of the rod (1, 3, 5, 7) being straight, parallel to the axis of the rod.  30) Multicore cable according to claim 1, characterized in that the elementary assembly is formed of several conductors all parallel to the axis of the elementary assembly.  40) Cable according to claim 1, characterized in that the elementary assembly (7) is wound in a constant pitch around the axis of the general assembly.  50) Cable according to claim 1, characterized in that the general assembly comprises a core (10) and at least one elementary assembly (7, 9) wound around this core (10).  60) Cable according to claim 2, characterized in that the cells (4, 6) have a U-shaped or rounded V-shaped section.  70) Cable according to any one of claims 1 to 5, characterized in that the conductive elements (9) are optical fibers.  80) Method for producing a multiconductor cable, in particular an optical cable, according to any one of claims 1 to 7, characterized in that at least one elementary assembly is formed by producing a rod with cells parallel to the axis of the rod and by depositing a conductive element in at least certain cells and the elementary assemblies are wound along along the line, around the axis of the cable.  90) Method according to claim 8, characterized in that the elementary assemblies are wound in a constant pitch.