FR2551253A1 - Transmission cable, especially an optical transmission cable, comprising an elastic element. - Google Patents

Abstract

The subject of the invention is a transmission cable comprising an elastic element 30 around which one or more cable elements 31 providing the transmission are cabled. The invention is especially applicable to transmissions by optical fibres under difficult environmental conditions.

Description

TRANSMISSION CABLE, ESPECIALLY OPTICAL,
COMPRISING AN ELASTIC ELEMENT.

 The present invention relates to a transmission cable, comprising an elastic element around which are placed one or more cable elements ensuring transmission, in particular by optical fibers.

 The object which the present invention proposes to achieve is, in the event of a tensile force applied to a cable causing its longitudinal deformation, to limit the forces supported by the so-called active elements of this cable, that is to say those which ensure the transmission of signals. This aspect is particularly important for optical cables in which, as is known, the stresses applied to optical fibers have the effect in particular of considerably increasing the attenuation undergone by the signal during transmission.

 To reduce the effect of longitudinal constraints, various solutions are currently known, among which we can cite - the solution used to make a flexible telephone cord, which consists in winding the cord on a mandrel and heating the whole to a relatively high temperature, so that it retains its helical shape; this solution has the drawback of being inapplicable for certain types of cables, in particular optical cables for which the required temperature would deteriorate the optical fibers; the solution used in certain optical targets, consisting in placing the active elements in grooves arranged in a support, the active elements being in excess length relative to the support; this solution can be used when the active elements are fibers; when the active elements are cable elements comprising a plurality of fibers and already having a certain bulk, the volume required by the protective structure becomes too large.

 The present invention relates to a cable making it possible to meet the above requirements without having the drawbacks of known solutions. To this end, it includes one or more active elements arranged helically around an elastic element, longitudinally and transversely. Under the effect of the application of a longitudinal stress, this structure allows: - on the one hand, a longitudinal deformation of the core of the cable (i.e. active elements and elastic element) without immediately bringing constraints on the active elements - on the other hand, a radial deformation of the elastic element which makes it possible to decrease the diameter of the cable.

 More specifically, the transmission cable according to the invention comprises at least one cable element constituting a transmission support and in addition, an elastic element, wired with the cable element, capable of elongating and crashing under the effect of a longitudinal force applied to the cable.

Other objects, characteristics and results of the invention will emerge from the description below, given by way of nonlimiting example and illustrated by the appended drawings which represent:
- Figure la, a first embodiment of the cable according to the invention;
- Figures lb and lc, explanatory diagrams relating to Figure la;
- Figure 2, an embodiment of an optical cable element capable of being used in the cable according to the invention
- Figure 3a, another embodiment of the cable according to the invention
- Figure 3b, an explanatory diagram relating to the previous figure.

 In these different figures, the same references refer to the same elements.

 In FIG. 1a, a first embodiment of a cable core according to the invention is therefore shown in longitudinal section, in which a single active element marked 11 is wired in pair with an elastic element marked 10, that is to say that these two elements are assembled helically. By way of example, the active element and the elastic element have the same diameter D and, as shown in FIG. 1b, which represents this cable seen in cross section, the transverse axis of the cable passes through the point of tangency of the two elements 10 and 11. The cable diameter is then equal to 2D.

 The active element 11 can be an electric cable, an optical cable or even a mixed cable.

 For example, there is shown in cross section in Figure 2 an optical fiber cable element of the grooved cylindrical type, capable of constituting the element 11 of Figure la.

 The cable element of FIG. 2 comprises a support 21, for example made of flexible plastic, having at its periphery grooves 22, for example helical or with alternating pitch; each groove 22 comprises one or more optical fibers 23, placed in these grooves with a certain extra length relative to the support 21. In order to impart a certain mechanical resistance to the structure, a central core 24, metallic or not, can be added to it. The cable element thus obtained is terminated by taping and / or sheathing, not shown.

 The elastic element 10 must have both a longitudinal elasticity and a radial elasticity. For this purpose, it can be massive or cellular, made for example of a natural elastic material or of elastomer (neoprene for example), possibly reinforced by a carrier, metallic or not, limiting the elongation of the whole of the element elastic, arranged for example in the center of the element.

Illustrated in FIG. 1c, which is the same section as that of FIG. 1b but produced in the presence of longitudinal tensile forces applied to the cable, the active element 11 of diameter
D, assumed not yet deformed, and the elastic element 10. The latter, more flexible than the element 11, is crushed in the radial direction so as to have only a thickness D ', while elongating in the longitudinal direction. In this way, on the one hand the structure of the cable is slightly modified, due to both the greater elongation of the elastic element 10 and its transverse crushing, which is illustrated by the axis 12 of the cable which is no longer at the point of tangency of the two elements but now crosses the active element 11; on the other hand, the total diameter of the cable, equal to D + D ′, has decreased, due to the crushing of the elastic element.

 FIG. 3a shows another embodiment of a cable core according to the invention, seen in cross section.

 In this figure, there is shown an elastic element 30 of diameter Do around which are conventionally wired, that is to say helically, a certain number of active elements 31, optical or electrical, for example all having the same diameter D1 , which may or may not be equal to Do. In FIG. 3a, a single layer is shown, consisting of five active elements 31, but it is clear that one or more layers of elements can be arranged, each comprising one or more elements whose number is such that, depending on the diameter Do, there remains between two active elements 31 a free distance d, the role of which will be seen below. The maximum diameter of this cable is therefore DMAX = Do + 2D1.

 FIG. 3b represents the same section but when a longitudinal tensile force is applied to the cable, it being assumed that the active elements 31 retain their diameter D1. As shown in the figures, the elastic element 30 is deformed so as to allow the active elements 31 to come to be embedded in the element 30, two opposite elements 31 no longer being separated as much as possible. that by a distance D'o 4 D ,, thus allowing an overall reduction in the diameter of the cable, at the maximum now equal to D'MAX = D1 + 2D1 <DMAX Correlatively, there is a decrease in the distance d, which has become of Figure 3b. It thus appears that the reduction in the diameter of the cable is only possible if the elements 31 are not previously adjacent (d i O).

 The cable according to the invention therefore allows, under the action of a given longitudinal force, a radial and longitudinal deformation preventing the immediate application of stresses on the active elements. It should however be noted that the intensity of the force which a cable element has to bear is a function of the dimensioning of the reinforcing elements, depending lux-even in particular on considerations of size, weight and cost.

 The description given above was only given by way of nonlimiting example, and it is thus in particular that it has been shown in the various figures that a single elastic element (10 or 30) but that 'A cable according to the invention can include any number. Likewise, the elastic element has been shown to be massive, but it can be tubular, thus allowing the passage of conductors, of fluid, etc.

 The invention is particularly applicable to optical transmissions, and more particularly adapted to difficult environmental conditions.

Claims (7)

 1. Transmission cable, comprising at least one so-called active cable element, constituting a transmission support, the cable being characterized in that it also comprises an elastic element, wired with the active element, capable of lengthen and crash under the effect of a longitudinal force applied to the cable.  2. Cable according to 12 claim 1, characterized in that the elastic element and the active element are wired in pair.  3. Cable according to claim 1, characterized in that it comprises one or more active elements, wired helically around the elastic element.  4. Cable according to one of the preceding claims, characterized in that the active element comprises optical fibers.  5. Cable according to one of the preceding claims, characterized in that the elastic element comprises a naturei elastic material or elastomer.  6. Cable according to one of the preceding claims, characterized in that the elastic element is made of solid or cellular material.  7. Cable according to one of the preceding claims, characterized in that the elastic element further comprises at least one carrier limiting its elongation.