SE462007B - GAS PROTECTED OPTICAL FIBER CABLE - Google Patents

Description

462 007 10 15 20 25 30 35 2 which comprises the wavelengths used for the optical signal. Under certain conditions, the result is reversible and the saturation can also be significantly reduced if the hydrogen is able to diffuse out of the fiber (for example due to the concentration of the hydrogen outside the fiber, which is the cause of the phenomenon) has decreased). It has been possible to determine that a second cause of saturation must be chemical reactions such as between the main constituents of the fiber (eg SiO2) and / or its dopants (GeO2, PZOS, etc.) and the hydrogen present inside the fiber itself. The result of these reactions is the formation of groups containing the hydroxyl radical (OH) responsible for absorption at other wavelengths which were also used for the transfer. These latter reactions are irreversible and a corresponding deterioration of the fiber properties can be foreseen under all operating conditions.

The parameters that control these phenomena are, apart from the chemical composition of the fiber, the partial hydrogen pressure to which the fiber is exposed, the temperature and of course the time.

The fiber can come into contact with the hydrogen generated inside the cable either during the manufacture of the cable or during the operation of the cable. In fact, the hydrogen can be generated by metallic or non-metallic means in the cable, which have absorbed the gas during the manufacturing, refining or finishing processes of the constituent materials.

The hydrogen can also be generated due to possible chemical degradation by oxidation of organic materials contained in the cable or by reaction with water (either in liquid or vapor form) which may be present in the cable with the metal members forming the cable itself. Some organic materials used in the fiber coating can generate hydrogen due to chemical reactions of various kinds. It has been found that a source of hydrogen was poured from the protective coating itself and in particular from silicone rubber, for which it is assumed that the crosslinking process has an extended duration and this leads to the release of hydrogen just along the fiber surface. . The hydrogen dispersion takes place in the direction of the fiber as well as towards its outside and does not cause any remarkable phenomena of the insulated fiber because in this case it dissolves in the surrounding atmosphere. Despite this, the hydrogen concentration, when the fiber is included in a closed cable and when there is a lack of sufficient free space, can assume relatively high values which cause noticeable diffusion even in the direction of the fiber itself, which is supported by the fact that the coating emanates, is very close to the fiber.

Hydrogen diffusion via various materials occurs at an increased rate and goes from the metals to the polymers, to the liquids and to the gases. Depending on the type of cable and the environment in which it is used, consequently several velocities for the emission of the hydrogen are obtained as a result of the substances contained in the cable and thus also of the absorption rates on the parts of the cable for the hydrogen which may be generated outside the cable. and which permeates the operating environment. The value of the partial hydrogen pressure inside the cable depends on these different speeds, which value is a function of the time for the greater the pressure and the longer the time the greater the risks will be for the fibers.

With a given service life of a fiber optic cable under foreseeable temperature conditions, the rate of diffusion of hydrogen through the metals is so small that metal shells of normal thickness can be considered practically impermeable to hydrogen.

The cables enclosed in the metal casings, especially if they have a small internal space, are those which in a short time and at high levels are subjected to increasing saturation due to the hydrogen released from substances inside the casing.

Disclosure of the Invention The object of the present invention is to realize an optical fiber which is protected against absorption of gaseous hydrogen, which may be present in the fiber containing the cable. This protection is achieved in accordance with the invention by arranging around the outermost glass layer of the fiber one or more coatings which contain metals which can absorb hydrogen and thus form a barrier corresponding to the coating.

The optical fiber according to the invention, which has at least one protective coating, is characterized in that at least one of the protective coatings comprises one or more metals from groups III, IV, V and VIII in the periodic table as protection against absorption of gaseous hydrogen in parts of the fiber. .

Among the metals which proved to be particularly suitable are the following: Lantanides from group III, titanium, zirconium and hafnium from group IV, vanadium, niobium and tantalum from group V and palladium from group VIII in the form of pure metals, their alloys or intermetallic mixtures. In the presence of hydrogen, the specified substances tend to form solid intermediate solutions which are absorbable as hydrides with good stability and this allows the partial hydrogen pressure in the cable to be reduced to values which balance with the hydrogen solubility in the substances themselves. Preferably, the above-mentioned substances are subjected to thermal treatment under vacuum at temperatures of a few hundred degrees Celsius before they are used in the cable production for the removal of hydrogen which might have been absorbed and / or associated oxygen.

Preferred Embodiments The invention will now be described with reference to certain preferred but non-limiting embodiments, which are illustrated in the accompanying drawing, in which Fig. 1 schematically shows a cross section through a provided 2 shows provided 3 shows optical fiber with a primary metal coating, Figs. a cross section through an optical fiber with a primary coating, Fig. schematically a cross section through an optical fiber provided with a primary and a secondary coating, Fig. 4 schematically shows a cross section through an optical fiber provided with a primary and a secondary coating , between which a buffer layer is inserted and Fig. 5 schematically shows a cross section through a loose type optical fiber, i.e. loosely housed inside a narrow tube.

Fig. 1 illustrates a basic optical fiber comprising a glass part 1 of some kind, i.e. with "step index", "graded index" or of another kind, and a primary coating 2 arranged thereon which has the task of protecting the fiber from the external environment.

According to a first embodiment of the invention, this protection is obtained by a metallized layer of one or more of the above-mentioned substances. This layer can constitute the primary coating 2 shown in the figure in close connection with the glass structure of the optical fiber. Thus, a fiber is obtained in which the primary coating is of the metal type and which at the same time also reveals the mechanical function as well as the function of protecting against hydrogen absorption from the atmosphere surrounding the fiber during its operation.

According to a variation (not shown), the metallization layer is arranged immediately on top of the usual primary coating made of crosslinked resin. This construction is used when it is not possible or suitable to modify the plant for fiber production where it is envisaged that a protective coating will be applied immediately after the optical fiber has been drawn to the desired dimensions.

A further variation, also not shown, foresees the application of the metallised layer around one of the other surrounding coatings.

According to the second embodiment, schematically illustrated in Fig. 2, the coating 2, which is of acrylic resin or primary other suitable material, comprises a solution of powder of one or more of the indicated metals, their alloys or intermetallic mixtures. This allows the protective only hydrogen to be included in a conventional manufacturing process. 462 10 15 20 25 30 35 007 6 A third embodiment (Fig. 3) provides for the introduction of the metal powder into the coating 3 which immediately surrounds the primary coating. This coating is typically made of silicone rubber and, as explained above, can later be a particularly dangerous source of hydrogen.

The presence of metals in this coating effectively neutralizes hydrogen generated even before it can diffuse inward into the fiber.

The optical fiber schematically illustrated in Fig. 4 constitutes a fourth embodiment according to the invention, which involves a dispersion of metal powder in the secondary coating H, which is formed by, for example, nylon or some other thermoplastic polymer. In the above embodiments, the particles contained in the powder have dimensions which are preferably less than 10 .mu.m and the quantity of powder per unit length of optical fiber is determined with the intention of reaching a concentration in the range between 0.1 - 10 phr (parts per hundred). of resin) in the resin.

It must be borne in mind that the protective function according to the invention is achieved in different ways in accordance with the coating in which the metals are included. More specifically, the very intimate presence of the protective layer on the optical fiber protects this fiber primarily against hydrogen generated in the innermost protective coatings while an outer protective coating (e.g. on top of the silicone rubber) primarily provides protection for hydrogen derived from the cable elements.

In view of what has been stated above as well as other factors, which depend on the structure and the foreseeable operating conditions of the cable, the previously described embodiments can be combined in the same optical fiber.

Finally, a further embodiment is illustrated in Fig. 5 where an optical fiber 1, which has a primary coating 2, is accommodated inside a small tube 9 of plastic, which has an inner diameter which is larger than the outer diameter of the fiber and is provided with the normal coatings to form a loose type optical fiber. For this type of fiber, which therefore requires coatings that are non-adhesive,. The protection can be realized both by means of coatings such as those described above and by means of a gel 8 containing a powder dispersion of specified metals, their alloys or intermetallic mixtures inside the small tube 9.

As an alternative, in or without combination with previously stated embodiments, the material constituting the small tube may contain a powder dispersion of the specified metals, their alloys or intermetallic mixtures. Although the invention has been illustrated by certain preferred embodiments, these should not be construed as limiting the invention because, as one skilled in the art will readily appreciate, various variations and / or modifications are conceivable without departing from the spirit of the invention.

Claims (7)

462 10 15 20 25 007 PATENT REQUIREMENTS Optical fiber comprising at least one protective coating (2 - 4) of plastic, the coating (2 - 4) of plastic contains a powder dispersion characterized in that the protection of one or more of the metals lanthanides, titanium, hafnium, tantalum or an alloy containing one or more of these metals or an intermetallic mixture of palladium, zirconium, vanadium, niobium or one or more of these metals as protection against the absorption of gaseous hydrogen in the optical fiber. Fiber according to claim 1, characterized in that the dimensions of the particles forming powder are less than 10 μ and that the powder is included in a sufficient amount to obtain concentrations of 0.1 - 10 phr in the protective coating itself (2 - 4) ¿ Fiber according to claim 1 or 2, characterized in that the powder is included in a primary coating (2) on the optical fiber in the immediate vicinity of the outermost glass layer (1) of the fiber. Fiber according to Claim 1 or 2, characterized in that the powder is included in a coating (3) which is arranged in the immediate vicinity of the primary coating (2) of the optical fiber. Fiber according to claim 4, characterized in that the coating (3) is made of silicone rubber. Fiber according to Claim 1 or 2, characterized in that the coating (3) is a secondary coating. Fiber according to claim 1, characterized in that the coating is of the loose type in the form of a plastic tube (9) in which the optical fiber or fibers are freely laid. 3 ,, 14