DE29602165U1 - Flat optical cable - Google Patents

Description

Description

The invention relates to a flat optical cable with a plurality of optical fibers and a sheath.

Known optical cables that are laid underground have plastic sheaths with optical fibers running through them. In order to protect the optical fibers from moisture and from being bitten by rodents, such cables require a complex multi-layer sheath. For example, EP 0 373 846 A2 describes an optical cable in which the optical fibers run in a plastic tube. The plastic tube is enclosed by a band made of a water-absorbing material that overlaps at its band edges. A plastic sheath is provided on top of this, in which a number of strand-shaped, tensile elements are embedded for strain relief.

DE 39 37 804 A1 relates to a flat optical cable, in which several optical fibers are combined to form a tensile-resistant optical element. These optical elements are covered by the cable sheath. With the help of webs formed in the sheath, the flat cable can be split into individual segments.

Based on this state of the art, the invention is based on the problem of an optical cable

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which ensures good protection of the optical fibres against moisture and rodents and which can also be manufactured in a simple manner and with little effort.

This problem is solved according to claim 1 in that the optical cable has at least two tubes made of steel, each having several optical waveguides, which run parallel to one another in a plane and are enclosed by the common sheath.

The advantages that can be achieved through the invention are in particular that the use of steel tubes ensures effective protection against rodents as well as good transverse watertightness and an effective water vapor barrier in a simple manner. The optical cable according to the invention also has high tensile strength and a simple structure and can be manufactured in a simple manner with little effort and a few manufacturing steps. The arrangement of the optical fibers in tubes that run parallel to one another in one plane is particularly advantageous in local networks with a large number of branches.

The features listed in the dependent claims enable advantageous further developments and improvements of the invention.

In order to further increase the tensile strength of the optical cable according to the invention, it is advantageous if at least one of the tubes is coated on its circumference with an adhesion promoter, so that a good mechanical connection of the tube with the sheath enclosing it is established.

For the same reason, it is also advantageous if at least one tensile element is arranged in the radial direction between the circumference of at least one tube and the circumference of the sheath. This tensile element can also act as a tear thread to facilitate the removal of the sheath of the optical cable.

For the simple manufacture of an optical cable with increased tensile strength, it is advantageous if at least one tensile-resistant element is arranged in the radial direction between the bonding agent and the circumference of the sheath. The bonding agent can ensure that the tensile-resistant element is securely held to the circumference of the respective tube after the application of the tensile-resistant element, which can also be used as a tear thread to facilitate the removal of the sheath, until the sheath is extruded.

In order to easily divide the optical flat cable according to the invention into individual wires, it is advantageous if a separation point is formed between two adjacent tubes in the jacket, extending in the longitudinal direction of the cable parallel to the tubes. For the same reason, it is advantageous if the separation point is designed in the form of a thin-walled web.

In order to effectively protect the optical fibers from excessive tensile stresses when the cable is subjected to tensile stress, it is advantageous if the optical fibers are longer than the tubes surrounding them.

It is advantageous if the optical fibers run in the form of optical fiber ribbons in the respective tube. Optical fiber ribbons enable a high packing density of the optical fibers and a

simple connection technology.

An embodiment of the invention is shown in simplified form in the drawing and explained in more detail in the following description.

The flat optical cable 1 shown as an example in the figure, which can be used as an underground cable, has, for example, four tubes 3 which run parallel to one another at a distance in a common plane and are enclosed by a common sheath 17 and which are made of steel, for example stainless steel for corrosion protection reasons. Four optical fibers 9 run in each of these tubes 3, for example. It is also possible that instead of four individual optical fibers in each tube, optical fiber ribbons combined together to form an optical fiber ribbon stack run. The sheath 17 can be made of, for example, polyethylene, HDPE, nylon or polyurethane.

The optical waveguides 9 are, for example, embedded in the respective tube 3 in a filling compound 11, which, for example, prevents water from migrating in the tube 3 in the longitudinal direction of the optical cable if the optical cable is damaged. Between two adjacent tubes 3, a separation point 19 is formed in the jacket 17, which extends in the longitudinal direction of the optical cable 1 parallel to the tubes 3, for example in the form of a longitudinally running thin-walled web. The optical waveguides 9 have an excess length of at least 1%o, for example 5%o, compared to the tube 3 surrounding them. This excess length of the optical waveguides 9 serves as an expansion reserve and protects the optical waveguides from inadmissibly high tensile stresses even if the tube 3 in question is subjected to tensile stress.

For example, two diametrically opposed, elongated and longitudinally extending tensile elements 15 are provided directly on the circumference of each tube 3, which are used as tear threads to facilitate the removal of the overlying sheath 17 and to increase the tensile strength of the optical cable 1. The tensile elements 15 are partially enclosed by the sheath 17 and, for example, lie directly on the circumference of the respective tube 3 to make it easier to remove the sheath 17.

It is also possible to coat the tubes 3 around their circumference with an adhesion promoter 13, e.g. in the form of a hot melt adhesive, before applying the jacket 17. For example, two elongated, tensile-resistant elements 15, diametrically opposed to one another, are applied to the layer formed by the adhesion promoter 13 and initially held to the circumference of the tube 3 by the adhesion promoter. As tear threads, they facilitate the removal of the jacket 17 extruded over the adhesion promoter 13 and serve to increase the tensile strength of the optical cable 1. The tensile-resistant elements 15 are partially enclosed by the jacket 17 and are located on the inside of the jacket 17 to make it easier to remove the jacket 17. The adhesion promoter 13 ensures a force-fit connection between the steel tube 3 and the sheath 17 and thus also serves to increase the tensile strength of the optical cable 1 .

Electrical message transmission elements can also be integrated into the optical cable 1 shown, for example in the form of a so-called Cu quad, thus forming a hybrid flat cable.

Claims (9)

• · · ♦ Protection claims 1. Flat optical cable with a plurality of optical waveguides and a sheath, characterized in that the optical cable (1) has at least two tubes (3) consisting of a steel, each having a plurality of optical waveguides (9), which run parallel to one another in a plane and are enclosed by the common sheath (17). 2. Cable according to protection claim 1, characterized in that at least one of the tubes (3) is coated on its circumference with an adhesion promoter (13). 3. Cable according to protection claim 1 or 2, characterized in that at least one tensile element (15) is arranged in the radial direction between the circumference of at least one tube (3) and the circumference of the sheath (17). 4. Cable according to protection claim 2, characterized in that at least one tensile element (15) is arranged in the radial direction between the adhesion promoter (13) and the circumference of the sheath (17). 5. Cable according to protection claim 3 or 4, characterized in that the tube (3) has two diametrically opposed tensile elements (15) assigned. 6. Cable according to one of the protection claims 1 to 5, characterized in that between two adjacent tubes (3) in the jacket (17) there is formed a separation point (19) extending in the longitudinal direction of the cable (1) parallel to the tubes (3). 7. Cable according to protection claim 6, characterized in that the separation point (19) is designed in the form of a longitudinal thin-walled web. 8. Cable according to one of the protection claims 1 to 7, characterized in that the optical waveguides (9) have an excess length compared to the tube (3) surrounding them. 9. Cable according to one of the protection claims 1 to 8, characterized in that the optical waveguides (9) run in the form of optical waveguide ribbons (7) in the respective tube (3).