DE3608508A1 - Tension-proof optical conductor - Google Patents

Abstract

A tension-proof optical conductor is described in which there are arranged around at least one optical fibre (1) a slip layer (2), a separating layer (3), a tension-proof band (4) and a plastic jacket (5). The diameter of the conductor is 1.3-1.4 mm. By combining a plurality of conductors to form basic and/or main fibre groups (units), it is possible to construct multi-conductor cables of high packing density. <IMAGE>

Description

The invention relates to a tensile, optical Core according to claim 1.

A fixed wire is known from DE-OS 32 14 732. You be stands out of an optical fiber on which a layer is made tensile, not spun plastic threads, one above Insulating layer made of glass silk for thermal insulation and above a plastic cover is applied. With this vein is the optical fiber is not different from the other construction elements mechanically decoupled. External forces therefore also affect the optical fiber.

The invention has for its object a tensile, to indicate optical core that is insensitive to Tensile, compressive and transverse pressure loads.

This task is characterized by a according to the main claim designed wire loosened. Advantageous further developments are included in the subclaims.  

The wire according to the invention has high tensile strength only a small diameter. Your further processing tion can therefore be easily used on conventional stranding machines respectively. There are also high take-off speeds possible. Due to the stable core structure, high packing densities and thus small cable diameters aim.

The invention is illustrated below in one Example shown embodiment of a wire explained.

Furthermore, versions of cables are described that the like veins included.

According to the figure, the wire has an optical waveguide 1 , which is surrounded by a sliding layer 2 . Be there is a separation layer 3 , around the tubular, butt after butt a tensile tape 4 is placed. There is a plastic sleeve 5 with which the band 4 is positively connected.

Monomode, gradient or other fibers which are provided with a primary coating are used as the optical waveguide 1 . The sliding layer 2 consists of a structurally viscous filling compound, for example Macromelt TPX 20-162 from Henkel, which makes the core longitudinally watertight. To improve the mechanical decoupling between the optical waveguide 1 and the separating layer 3 , the filling mass of the sliding layer 2 can contain hollow microspheres. The separating layer 3 consists of an extrudable thermoplastic hotmelt adhesive which is impermeable to the filling compound, for example Macromelt TPX 20-030 or TPX 20-146 from Henkel.

The tensile band 4 consists of tensile, longitudinal threads made of glass or aramid and weft threads made of plastic, for example polyester or polyamide. It typically has a thickness of less than 0.2 mm and is insensitive to moisture due to a special locking. The plastic sleeve 5 is extruded over the band 4 . It holds the band 4 together and forms with it a tensile wire sheath which, depending on the material used for the band 4 (glass or aramid), has a modulus of elasticity between 60,000 and 100,000 N / mm ² .

The diameter of the wire is, for example 1.3-1.4 mm. Optical fibers account for this 0.25 mm, the sliding layer 0.25-0.35 mm and the separator layer and the plastic cover each 0.2 mm.

The wire represents an intermediate type between the wires commonly known as "fixed wire" or "hollow wire". Depending on the nature of the filling compound of the sliding layer 2 , the wire is more appropriately described by one term than by the other. If the wire contains several instead of just one optical fiber, it is similar to a loose tube.

For the production of multi-core cables, several for example, five veins combined to form a basic bundle summarizes that further construction elements, such as as a central element to improve the longitudinal watertightness of the basic bundle or tensile elements may contain. The individual veins within the reason bundles are advantageously differently colored mar kiert. Depending on the number of wires required are off several basic bundles are formed.  

The cable core thus contains a practically any type number of basic and / or main bundles in known Way can be stranded using basket stranding machines. A central Ele be made of glass fiber reinforced plastic. All known cones are basically used as cable sheath structures, such as a layer jacket, me tall free coats, etc. suitable. It can be further tensile Elements included.

Claims (7)

1. Tension-resistant optical wire with at least one optical waveguide ( 1 ), a strain relief layer and other layers, including a plastic sheath ( 5 ), in which the strain relief layer is formed by a tensile band ( 4 ), which over a separating layer ( 3 ) and is arranged under the plastic cover ( 5 ). 2. Tensile optical core according to claim 1, characterized in that the separating layer ( 3 ) is arranged loosely around the light waveguide ( 1 ). 3. Tensile optical core according to claim 2, characterized in that the space between the light waveguide ( 1 ) and the separating layer ( 3 ) is filled with a filling compound, and that the separating layer is impermeable to the filling compound. 4. Tension-resistant optical wire according to one of the preceding claims, characterized in that the band ( 4 ) is formed butt to butt into a tube and at least with the plastic sleeve ( 5 ) is positively connected. 5. Tensile optical core according to one of the preceding claims, characterized in that the band ( 4 ) is longitudinally watertight in itself. 6. Cable characterized in that there is at least one tensile optical core according to one of the contains the preceding claims. 7. Cable according to claim 6, characterized in that it at least one longitudinally watertight, contain several wires basic bundle.