CA1048827A - Composite optical fiber element for telecommunication cables - Google Patents

Abstract

COMPOSITE OPTICAL FIBER ELEMENT
FOR TELECOMMUNICATION CABLES

ABSTRACT OF THE DISCLOSURE: A composite optical fiber element for telecommunication cables comprising an optical fiber with at least three metal filaments parallel thereto, spaced therefrom and disposed therearound in planes inter-secting the fiber and at substantially equal angles to each other. The optical fiber and the filaments are surrounded by and embedded in a synthetic thermoplastic resin material.
Filaments of the same diameter are equally spaced from the optical fiber. Individual elements, or groups of such elements in a sheath, may be helically wound around a supporting core to form a telecommunication cable.

Description

104882~ ~
This invention relates to the subject matter of my co-pending Canadian application Serial No. 201,346 filed May 31, 1974, and entitled "OPTICAL FIBER CABLE AND
MANUFACTURE THEREOF".
The present invention concerns a composite, uni-tary element for the transmission of modulated light signals, e.g., in telecommunication cables, and which comprises an optical fiber.
As is known, optical fibers are fibers made of glass or of plastic synthetic material, of a very small dia-meter, of the order of 0.1 - 0.01 mm., and are constituted by a tubular core and by a sleeve or coating whose refractive index is smaller than that of the core, for example, a re-fractive index of 1.50 - 1.52 for the sleeve and 1.56 - 1.64 for the core.
Because of the differences between the refractive indexes of the materials respectively constituting the core and the sleeve, light entering from one end of the fiber ~s totally reflected inside the fiber itself and may be trans-mitted along the axis of the latter, even if it is curvi-linear, as far as the other end of the fiber. By adopting particular types of highly transparent glass, it has been found that the initial impulse is transmitted to the terminal end of the fiber with relatively little attenuation.
Optical fibers of this type can be of interest also for use as elements intended for the transmission of signals in telecommunication cables. The use of such fibers involves, however, some problems deriving mainly from the typical physical and mechanical characteristics of the fibers themselves.
In fact, it is to be taken into account that said

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1~88Z7 fibers, which are extremely thin, can satisfactorily with-stand tension stresses, but such fibers have a low ultimate elongation and are, therefore, brittle. It follows that, for the employment of such fibers in telecommunication cables, in which they are to be stranded together in a unit, it is first of all necessary to solve the problems of arranging the fibers in an orderly manner and of reducing the deformations and stresses which may act on the fibers themselves.
It is evident that the optical fiber can be in-corporated, with an appropriate support, in the cable according to several methods, such as, for example, by means of a stranded or lapped winding. During the winding pro-cess, the fiber is subjected to stresses, not easily fore-seen, along different planes.
Moreover, even when the cable is finished, further stresses, also acting on planes which cannot be predicted with certainty, can take place during the operations employed in laying or transporting the cable itself.
It is therefore understandable that the use of an optical fiber involves the problem of providing a protection ~ for the same against the various stresses acting along ; different planes.
The present invention has, as one object, the pro-vision of a composite, unitary element comprising an opti-cal fiber, intended for the transmission of signals in telecommunication cables, and having a structure which over-comes the problems mentioned hereinbefore.
Accordingly, the principal object of the present invention is a composite, unitary element for the trans-mission of signals in telecommunication cables which com-.

1[)488;Z7 prises, in a synthetic, thermoplastic resin material, an optical fiber and at least three metallic filaments, each lying at equal distance from said fiber and in a plane of its own passing through the optical fiber, each plane being inclined at substantially equal angles with respect to the next adjacent planes.
In accordance with this invention here is provided a composite optical fiber element comprising a light-transmitting optical fiber and at least three continuous, reenforcing filaments embedded in and surrounded by a synthetic thermoplastic resin, said filaments being made of a material having a modulus of elasticity at least equal to the modulus of elasticity of said fiber, being spaced from and around said fiber, being substantially parallel to said fiber and respectively lying substantially in planes parallel to and intersecting said fiber and inclined with respect to each other at substantially equal angles, said filaments stiffening said element and absorbing the greatest part of the stresses when said element is subjected to bending whereby said filaments substantially reduce the stress which would otherwise be applied to said optical fiber with bending of said element.
In the preferred embodiments, the composite, unitary element comprises three metallic filaments arranged around the optical fiber at the same distance from it, said filaments being in three separate planes which intersect the fiber and which are inclined at 120 with respect to one another or comprises four metallic elements at the same distance from the optical fiber and which lie in two separate planes which interest the fiber and which are orthogonal with respect to each other.
Said preferred embodiments are particularly advantageous for maintain-ing the integrity of the optical fiber. In fact, the fiber, for its whole length and therearound, is protected by the filaments which, along with the fiber, are contained in a synthetic thermoplastic material.
The efficiency of said protection is comparable with that which would be obtained, for example, by providing a continuous jacket around the fiber which is able to absorb the stresses acting in all possible planes. In fact, in ~ - 4 -: , ..
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- ~488;:7 practice, the symmetrical arrangement of the three metallic filaments at planes arranged at 120 to each other or of the four metallic filaments in orthogonal planes, provides, in any stress plane, at least one filament resistant to tension and two filaments resistant to compression, or two resistant to tension and one to compression, such filaments having physical characteristics which enable them to oppose - 4a -1~4~8'~7 the stresses and prevent deformation of the optical fiber.
For these reasons, the composite, unitary element having the hereinbefore described structure is particularly suitable to be used as an element for the transmission of signals in a telecommunication cable. Accordingly, a further object of the present invention is a telecommunica-tion cable comprising at least one composite, unitary element as described hereinbefore.
The present invention will be better understood from the following detailed description of preferred embodi-ments thereof, which description should be considered in con-junction with the accompanying drawings, in which:
Fig. 1 is an enlarged, cross-sectional view of a preferred embodiment of a composite element of the invention;
Fig. 2 is an enlarged, cross-sectional view of a further embodiment of a composite element of the invention;
Fig. 3 is a cross-sectional view of several composite elements of the invention grouped to-; gether; and Fig. 4 is a perspective view of a telecommunication cable comprising the composite element.
The composite element 11 illustrated in Figs. 1 and 2 constitutes an element for transmitting modulated light signals which form part of telecommunication cables according to the present invention.
The element 11 comprises a support 1 formed by a synthetic thermoplastic material containing, interiorly thereof, a glass fiber 2 disposed at the center of the support 1, and at least three metallic filaments 3, 4 and 5 1~)488'~7 disposed around the fiber 2 to protect it. The physical characteristics of the filaments 3-5 are selected in a manner obvious to those skilled in the art so as to prevent bending of the element 11 by an amount which will break the fiber 2. In other words, the filaments 3-5 stiffen the element 11 and absorb the greatest part of the stresses, and the stresses on the fiber 2 are practically negligible.
Preferably, the modulus of elasticity of the filaments 3-5, when they are made of metal, is about 21,000 kilograms per square millimeter, or about three times the modulus of elasticity of the optical fiber 2. Preferably, also, the filamen~s 3-5 can be bent around a smaller radius of curva-ture than the optical fiber 2 without breaking. Said fila-ments 3-5 also have a coefficient of thermal expansion sub-stantially equal to that of the fiber 2 in order to avoid subjecting the fiber 2 to objectionable deformation because of the thermal expansion and contraction of the filaments

3-5.
The arrangement and number of the filaments 3-5 in-side the support 1 may vary, provided that at least three metallic filaments are used, each filament lying at the same distance from the fiber 2 and in a plane of its own passing through the fiber 2, the angles between the planes being substantially equal. For example, the number of filaments may be greater, but for ease of manufacture and to keep costs to a minimum, the number of filaments preferably is not greater than twelve, an increase above such number not justi-fying, in improved protection, the increase in manufacturing difficulties and the expense. In fact, four such filaments, arranged as described hereinafter, are usually adequate.
By means of said arrangement of the metallic fila-1~8827 ments, such filaments are practically distributed on the surface of an imaginary cylinder around the fiber 2 and with a spacing such that they can efficiently withstand the stresses in each plane.
In particular, in the preferred embodiments, said filaments are three in number, as shown in Fig. 1, and are arranged to lie in planes forming angles of 120 with re-spect to one another, or are four in number (filaments 6, 7, 8 and 9 shown in Fig. 2) and are arranged to lie in two planes orthogonal to each other.
Considering in greater detail the parts of the composite element 11, the diameter of the optical fiber 2 is between 0.01 and 0.1 mm., and the diameter of the fila-ments 3-9 is about the same order of magnitude as that of the fibers 2. It is preferred to make the filaments 3-9 of steel or of steel alloys with a nickel percentage of 42%. -The support 1, which is made of synthetic thermo-plastic resin material, may be made, for example, of a polyester, a polyamide or a polyolefin, such materials having appropriate properties. The support 1 can have a different cross-sectional shape. For example, it may be -~square, rectangular, etc., with a maximum transverse di-mension of about 1.5 mm.
Obviously, the small dimensions of the support 1 permit, advantageously, the grouping in a limited space of a large number of composite elements 11, as potential means intended for the transmission of signals. In this case, -each support 1 for the optical fibers 2 is formed with a thermoplastic material which is preferably loaded with carbon black so as to avoid the possibility that the trans-mission of light inside one optical fiber will be influenced lQ48827 by the light coming out of contiguous fibers.
The composite elements 11 can be associated to-gether in various ways, for example, by stranding, and can be contained in a single sheath 10 made of polyethylene or of another thermoplastic material, as shown in Fig. 3.
As mentioned hereinbefore, the composite element 11 is useful as an element for the transmission of signals in telecommunication cables. Said element 11, because of its particular structure, which includes metallic filaments for protecting the optical fiber, can be joined with others so as to form a bunch of stranded fibers in a telecommunication cable and will be subjected to practically negligible stresses.
In particular, Fig. 4 shows the application of a plurality of composite elements 11 helically wound around the core 13 of a telecommunication cable, the core 13 com-prising a stranded wire rope 12 and a protective covering 14.
Instead of individual elements 11, the group of elements 11 surrounded by the sheath 10, as shown in Fig. 3, may be wound around the core 13 in the same manner as the individual elements 11.
The stranded arrangement of the element 11 about the cable core 13 is advantageous, since said stranding, having, for example, a pitch greater than 100 mm., permits the use of fibers with a developed length exceeding the cable length by only a small amount.
The metallic filaments 3-9 could be replaced by non-metallic filaments, provided that the physical character-istics of the material used and the arrangement of said non-metallic filaments are such as to increase the flexing re-sistance of the composite element 11. Examples of non-; , ~)488Z7 metallic materials useful for the filaments 3-9 are glass and plastics having a modulus of elasticity at least equal to the modulus of elasticity of the optical fiber 2 and which will not break with normal bending of the element 11.
In addition, it will be understood that the pro-tection for the optical fiber 2 can be obtained in a manner practically equivalent to that described above by using filaments 3-9 arranged on planes having inclination angles slightly different from one another, as even under such conditions it is possible for the filaments to be disposed so as to be compression-resistant and tension-resistant.
Also, a protection of the fibers equivalent to that obtained in the examples shown in Figs. 1 or 2 could be obtained by adopting filaments 3-9 having different dia-meters. In the latter case, the optical fiber 2 would not be arranged at the same distance from the filaments, but instead, would be disposed in the position of more reduced flexing stress, namely, along the neutral axis of the re-sistance section determined by the characteristics of the filaments. For example, the fiber 2 would be located farther from a smaller diameter filament than from a larger diameter filament.
Although preferred embodiments of the present invention have been described and illustrated, it will be understood by those skilled in the art that various modifi-cations may be made without departing from the principles of the invention.

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Claims (13)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A composite optical fiber element comprising a light-transmitting optical fiber and at least three contin-uous, reinforcing filaments embedded in and surrounded by a synthetic thermoplastic resin, said filaments being made of a material having a modulus of elasticity at least equal to the modulus of elasticity of said fiber, being spa-ced from and around said fiber, being substantially parallel to said fiber and respectively lying substantially in planes parallel to and intersecting said fiber and inclined with re-spect to each other at substantially equal angles, said filaments stiffening said element and absorbing the greatest part of the stresses when said element is subjected to bend-ing whereby said filaments substantially reduce the stress which would otherwise be applied to said optical fiber with bending of said element.

2. A composite optical fiber element as set forth in claim 1, wherein each of said filaments has a temperature coefficient of expansion substantially equal to the tempera-ture coefficient of expansion of said optical fiber.

3. A composite optical fiber element as set forth in claim 1, wherein said modulus of elasticity of said fila-ments is greater than the modulus of elasticity of said fiber and the radius of curvature of said filaments without rup-ture is smaller than the corresponding radius of curvature of said fiber.

4. A composite optical fiber element as set forth in claim 1, wherein said optical fiber has a diameter in the range from 0.01 to 0.1 millimeters and said fila-ments have a diameter of the same order of magnitude as the diameter of said fiber.

5. A composite optical fiber element as set forth in claim 1, wherein the maximum cross-sectional di-mension of said element is less than 1.5 millimeters.

6. A composite optical fiber element as set forth in claim 1, wherein each of said filaments has the same diameter and said filaments are equally spaced from said fiber.

7. A composite optical fiber element as set forth in claim 6, wherein each of said filaments is made of metal.

8. A composite optical fiber element as set forth in claim 7, wherein the modulus of elasticity of each filament is at least three times the modulus of elasticity of said optical fiber.

9. A composite optical fiber element as set forth in claim 7, wherein said metal is selected from the group consisting of steel and steel alloys.

10. A composite optical fiber element as set forth in claim 1, wherein there are three filaments and said planes are inclined at an angle of substantially 120 degrees with respect to each other.

11. A composite optical fiber element as set forth in claim 1, wherein there are four filaments and said planes are substantially orthogonal to each other.

12. A telecommunication cable comprising a plurality of composite optical fiber elements each con-structed as set forth in claim 1 and arranged in parallel relation.

13. A cable as set forth in claim 12, wherein said cable comprises a central core and said elements are helically wound around said core.