DE19624967A1 - Optical conductor wire for overhead cable - Google Patents

Abstract

The optical conductor wire (1) has at least one optical fibre (5) and an associated tension restraint element (3), contained within an outer sleeve (9) which is filled with a packing material (11). The optical fibre is secured to the tension restraint element, e.g. a number of optical fibres are secured around the outside of a central tension restraint element of glass-fibre- reinforced plastics or steel.

Description

The invention relates to an optical wire with at least an optical fiber, at least one tensile and crushproof element and one with a filler filled outer shell.

Optical wires with at least one loose in an outer Optical fiber arranged as a hollow or Loose tubes. The outer shell consists of usually from a low coefficient of friction having inner layer and an optical fiber external mechanical protection Layer. A swellable material is used as the filling material or a thixotropic gel that uses the Longitudinal water tightness guaranteed. A optionally provided excess length of the optical fiber protects against the outer shell surrounding it optical fiber against impermissibly high tensile loads and allows the core z. B. as a central element in an optical aerial cable.

In such or similar applications are also in the outer shell is resistant to tension and compression for example made of glass fiber reinforced plastic or Steel integrated, which protects the optical fibers from tensile and To protect upset stresses. In doing so however, the optical fibers through the solid outer Cover only indirectly protected and have none immediate protection against mechanical stress  on.

The invention is based on this state of the Technology based on the problem of having an optical core at least one running in an outer shell form optical fiber such that the optical Fiber as good as possible against tensile and compressive stresses is protected.

This problem is solved according to claim 1 solved that the at least one optical fiber with the at least one element that is resistant to tension and compression connected is.

The advantages that can be achieved by the invention exist especially in that the at least one optical fiber and the at least one tensile and compressible element existing unit itself tensile and is crushproof and so an effective and immediate protection of the optical fiber against impermissible high mechanical stress is guaranteed. This is particularly the case with such cable constructions Advantage where the cable is frequent or constant Is exposed to tensile loads, for example at Aerial cables. In addition, one can easily defined excess length of the optical fiber compared to the ensure the outer shell surrounding them. The optical core according to the invention is also simple and inexpensive way to manufacture.

By the features listed in the subclaims are advantageous developments and improvements of Invention possible.

For a firm and permanent connection of at least an optical fiber with the at least one tensile and compressible element, it is advantageous if the  optical fiber and the tensile and compressive element by means of the optical fiber and the pull and compressible element jointly enclosing inner Wrapping are interconnected.

It is for a high strength of the connection and a simple manufacture of the invention Optical vein an advantage if the inner cladding is made a hot melt adhesive or from one by UV radiation cured paint is formed.

It is advantageous if a central train and crushproof element a plurality of optical fibers is arranged so that at a comparatively low Outer diameter of the optical wire a large number of optical fibers safely protected in the optical core can be accommodated.

In order to withstand the bending stresses of the optical wire optical fibers as free as possible from tensile and To be able to keep compressive stresses, it is from Advantage if the optical fibers pull around the central and compressible element are stranded. In this way is also before the connection is established between the optical fibers and the tensile and crushproof element a secure hold of the optical Fibers guaranteed.

For a particularly good protection of an optical fiber before mechanical stress, it is an advantage if the optical fiber between two parallel to this running tensile and compressive elements arranged is.

Two embodiments of the invention are in the Drawing simplified and shown in the following description explained in more detail.  

In Fig. 1 a first embodiment of an optical core 1 of the invention is illustrated by way of example. To a central tensile and compressive element 3 , the z. B. is made of glass fiber reinforced plastic or steel, for example, twelve optical fibers 5 are stranded in one layer next to each other. An inner sheath 7 is applied over these optical fibers 5 , which encloses the tensile and compressive element 3 and the optical fibers 5 together and thereby firmly connects them to one another. The inner envelope 7 can, for. B. be formed by applying a molten hot melt adhesive. However, it is also possible to form the inner covering 7 from a lacquer hardened by UV radiation. The unit consisting of tensile and compressive element 3 , the optical fibers 5 and the inner sheath 7 is arranged in an outer sheath 9 , the annular space between this unit and the outer sheath 9 to ensure the longitudinal water tightness of the optical core 1 with a Filling material 11 is filled. As a filler 11 z. B. a swellable powder or a thixotropic gel can be used.

In the second exemplary embodiment of an optical wire 1 according to the invention, shown by way of example in FIG. 2, an optical fiber 5 is arranged between two tensile and compression-resistant elements 3 running parallel to the optical fiber. An inner sheath 7 formed, for example, from a hot-melt adhesive coats the two tensile and compression-proof elements 3 and the optical fiber 5 and establishes a firm connection between them. The unit formed from optical fiber 5 , tensile and compressive elements 3 and inner sheath 7 is surrounded at a distance by an annular outer sheath 9 made of plastic. The annular space formed between the unit and the outer shell 9 is filled with a filling material 11 .

Claims (7)

1. Optical core with at least one optical fiber, at least one tensile and compressive element and an outer shell filled with a filler material, characterized in that the at least one optical fiber ( 5 ) with the at least one tensile and compressive element ( 3 ) is firmly connected. 2. Optical core according to claim 1, characterized in that the optical fiber ( 5 ) and the tensile and compressive element ( 3 ) by means of an optical envelope ( 5 ) and the tensile and compressive element ( 3 ) together enclosing inner covering ( 7 ) are interconnected. 3. Optical core according to claim 1 or 2, characterized in that a plurality of optical fibers ( 5 ) is arranged over a central tensile and compression-resistant element ( 3 ). 4. Optical core according to claim 3, characterized in that the optical fibers ( 5 ) are stranded around the central tensile and compressive element ( 3 ). 5. Optical core according to claim 1 or 2, characterized in that an optical fiber ( 5 ) is arranged between two parallel to this tensile and compression resistant elements ( 3 ). 6. Optical wire according to one of claims 2 to 5, characterized in that the inner sheath ( 7 ) is formed from a hot melt adhesive. 7. Optical core according to one of claims 2 to 5, characterized in that the inner sheath ( 7 ) is formed from a lacquer hardened by UV radiation.