DE2749096B1 - Optical transmission element - Google Patents

Description

The invention is not explained on the basis of exemplary embodiments The F i g. 1 shows four enveloping, square, non-light-conducting protective fibers 1, which envelop an optical waveguide fiber 2 inserted with play The diameter of the protective fibers 1 can be, for example, 300 to 400 jun, while the diameter The utal optical fiber lies at about 100 to 1050 The Kaatentlinge of the whole The element is then about - to 800 ZnL The straight lines from 300 to 400 mm to the sufficient for local network cables; The F i g. 2 shows the arrangement of three protective fibers 1, in the interstices of which the Optical waveguide fiber 2 is arranged.

A basic bundle made from such structural elements has a relatively small diameter. If the structural elements are joined together like a ribbon, then one obtains ribbon cables with relatively small dimensions. For example you can stack ten ribbons of 20 fibers each on top of each other.

The protective fibers of the sheath of the optical transmission element are superficially prepared in such a way that they come into close contact with sufficient heating glue and a closed square resp.

Form triangular shell in which the centrally located light-guiding The fiber remains mobile. This fiber is not involved in the bonding process melting varnish, for example covered with a nitrocellulose varnish. Appropriately an adhesive and a non-adhesive varnish are used, the same Funds are resolvable. For example, the protective fibers of the shell can be coated with polyvinylidene fluoride, cover the central optical fiber with nitrocellulose varnish, for which one is considered common Solvent acetone can use.

A particularly advantageous manufacturing process consists in the five fibers of the in F i g. 1 shown embodiment to pull together, to configure and the protective fibers under rewarming and pressure with each other to weld. The centrally located optical waveguide fiber 2 and with each other Protective fibers 1 to be welded are coated with protective varnish. The glass of the Protective fibers should then have a lower melting range than the light-conducting fibers own.

The optical transmission element is advantageously also for Cables with a low number of fibers and can be used for single-fiber cables. Since the supportive Core is quite stable against compression by the outer plastic shell, requires a Single-fiber cables only have a solid plastic coating on the optical transmission element, For example polyethylene with a diameter of approx. 1 mm, a tensile reinforcement and an outer jacket.

If the protective fibers are twisted back with a lay length that is not too great stranded and not glued to one another, but only wrapped tightly together, This gives the optical transmission element a flexibility that can only be achieved through the individual protective fiber is determined. This results in permissible ones Bending radii from 150 to 200 mm. In this case, the optical fibers and the Protective fibers are coated with non-melting protective varnish before stranding. Stranding element and single-fiber cables can be produced in one operation, if an SZ method is used for stranding. Drawing, painting, SZ stranding with twistering, wrapping, reinforcing and sheathing can then be carried out in one operation are executed.

In addition to the in FIGS. 1 and 2 described arrangements with square or protective fibers arranged in a triangle shape are also optical transmission elements feasible in which more than four touching protective fibers interfere with the optical waveguide surrounded concentrically.

Claims (1)

Claims: 1. Optical transmission element for fiber optic cables, Containing an optical waveguide fiber which is loosely arranged in a sheath, characterized in that the shell consists of at least three arranged in a triangular shape, non-light-conducting protective fibers, in their common inner gusset space the optical waveguide fiber is arranged, and that the diameter of these protective fibers is so great that the optical waveguide fiber is loose and with great freedom of movement 2. Optical transmission element according to claim comes to lie in this intermediate space 1, characterized in that the protective fibers consist of glass. 3. Optical transmission element according to claim 1, characterized in that that the protective fibers are made of plastic. 4. Optical transmission element according to claim 1, characterized in that that the protective fibers are made of metal. 5. Optical transmission element according to one of the preceding claims, characterized in that several optical transmission elements are stranded together are arranged in a cable core. 6. Optical transmission element according to one of claims 1 to 4, characterized in that several optical transmission elements form a ribbon cable are summarized. 7. Optical transmission element according to claim 6, characterized in that that the upper side or the underside of the ribbon cable forming protective fibers summarized in a volume and z. B. be produced jointly by extrusion. 8. Optical transmission element according to one of the preceding claims, characterized in that the protective fibers are superficially prepared so that they stick together with sufficient heating and thus a closed one Form envelope. 9. Optical transmission element according to one of claims 1 to 8, characterized in that the optical waveguide fibers with a non-melting Varnish are covered. 10. Optical transmission element according to one of claims 8 and 9, characterized in that the applied to the surface of the protective fibers Adhesive and the lacquer coating on the optical waveguide fibers are of this type, that they are poundable by the same means. The invention relates to an optical Transmission element for optical waveguide cables, containing an optical waveguide fiber, which is loosely arranged in a sheath used for the transmission of control signals or for the transmission of messages An essential component of fiber optic cables is the ghs fiber, which is used to Guiding the Ucbtstrahles is used in the construction of optical cables must be known the mechanical properties of the glass fiber are particularly taken into account, i.e. the glasses must in particular withstand mechanical stresses such as pressure, tension and bending stresses are protected. For the protection of fiber optic cables one has therefore embedded this in a protective jacket, which has an inner diameter which is larger than the outer diameter of the fiber. The sheath is tubular designed and has an inner surface that is not on the fiber or on the fibers is liable (DE-OS 2528991). Due to the loose arrangement of the optical transmission elements in a mechanically resistant protective jacket made of plastic that is applied at a distance there is a certain mechanical decoupling between the other construction elements of the cable and the optical transmission elements achieved current cable constructions lead to relatively large cable cross-sections in multi-core fiber optic cables. For example, if you use the core of a currently known 1S fiber cable with a diameter of approx. 5 mm as a bundle element for the construction of a cable with 190 fibers, this leads to a core diameter of about 25 mm. This cable construction has a concentric layer structure. The cable diameter is then about 30 mm. The object underlying the invention is now the Cross-section of a fiber optic cable with loosely arranged in a protective cover Making Uchtwdlenleiter fibers as small as possible and thereby also aiming at a new structural element with good mechanical properties are created, which is easier to manufacture The task set is with the optical transmission element solved according to the invention in that the shell of at least three in triangular shape arranged, non-light-conducting protective fibers, in their common inner Gusset space the optical waveguide fiber is arranged, and that the diameter this protective fiber is chosen so large that the optical waveguide fiber loose and When there is sufficient freedom of movement, it is advantageous to lie in this gusset space the protective fibers can consist of Ghs, plastic or metal. Several optical transmission elements can be stranded together be arranged in a cable core. These optical transmission elements can also advantageously be used combine to form a ribbon cable. Due to the loose arrangement of the optical waveguide fibers in the crotch space of at least three protective fibers arranged in a triangle shape is a permanent, Effective protection against practically all occurring mechanical loads reached Even when mechanical pressure loads start there is damage or mechanical stress on the light waveguide fiber is hardly to be feared, because the protective fibers are solid.