CH710655A2 - Optical fiber optics. - Google Patents

Abstract

The optical fiber cable of the invention comprises light fiber elements (4, 5), each with at least one optical fiber, and reinforcing elements (1, 2, 3). At least one reinforcing element (1) is centrally located with respect to the cross section of the optical fiber cable. This and at least two spaced apart on both sides of this central reinforcing element (1) oppositely disposed, decentralized reinforcing elements (2, 3) lie on a cross-section of the optical fiber cable intersecting cross-sectional axis (A-A), with spaced therebetween, the light fiber elements (4, 5 ) are arranged. For example, there may be two light fiber elements (4, 5) on top of each other. The decentralized reinforcing elements (2, 3) are more flexible in relation to the at least one central reinforcing element (1), which has substantially kink-resistant properties. They may have a smaller cross-section and be narrower, for example, and / or consist of a rope or yarn designed for tensile strength. The inventive optical fiber cable is relatively flexible and suitable for indoor use.

Description

The present invention relates to an optical fiber cable with light fiber elements, each having at least one optical fiber, and with reinforcing elements.

Optical fiber cables serve the transmission of optical signals. It may also simply be light. However, it is mainly about data transmission in computers and computer networks and in control devices. Information can thus be transmitted securely and with both a high transmission rate and transmission bandwidth. A fiber optic cable usually has a cable sheath. In most publications, a fiber optic cable, regardless of the nature and arrangement of the optical fibers, is referred to as cables. The term fiber optic cable is to be understood accordingly. Optic fiber can be understood as any fiber or plastic fiber. The optical fibers can be arranged individually, but also bundled and / or stranded in the optical fiber cable. They can also lie next to each other and / or be hollow. Covering the various variants, is further discussed by light fiber elements.

Fiber optic cable, commonly called fiber optic cable, were used until recently less in the interior, but in the outdoor area as public utilities. This inevitably requires a larger cross section and, in addition to the resistance to weathering and temperature influences, protection against mechanical damage. Serves this, except a cable sheath, and a reinforcing element. The latter often consists of a strand arranged centrally in the optical fiber cable, be it metallic or nonmetallic. Due to the increasing public supply via fiber-optic cable, the demand for corresponding domestic installations is increasing. For smaller, that is, for optical fiber cable with fewer light fiber elements, as would be required in access and home wiring or for use as a connection cable, the known constructions are less suitable. On the one hand, they are too bulky in comparison with copper cables and often do not fit in existing cable ducts; On the other hand, they are too expensive. It has therefore been attempted to change the construction of the optical fiber cables so that they have a smaller cross-section. For example, it has been proposed to arrange the light fiber elements in series next to one another and to provide a reinforcing element on both sides. Thus, the optical fiber cable is indeed flatter overall, but remains at least the same width and loses considerable strength, especially as regards the flexural strength in the direction of the flat, smaller diameter. Bending in the longitudinal direction of the row of optical fiber elements, however, can be problematic. Also, therefore, in this construction, the two lateral reinforcing elements must be relatively rigid. As a result, bending in the width, that is, in the direction of the larger diameter, almost impossible. This is extremely unfavorable when laying the optical fiber cable in home installations.

On the basis of these findings, the invention has the object to provide an optical fiber cable, in which the disadvantages described above are largely avoided and in particular with smaller cross-section manufacturable and relatively flexible, for example, for use in the interior.

The inventive optical fiber cable corresponds to the characterizing features of claim 1. Further advantageous embodiments of the inventive concept can be seen from the dependent claims.

Hereinafter, preferred embodiments of the invention will be described in more detail with reference to the drawing. <Tb> FIG. Fig. 1 shows a first embodiment with four light fiber elements and three gain elements; <Tb> FIG. Fig. 2 shows a layout with a plurality of optical fiber cables of Fig. 1; <Tb> FIG. 3 <SEP> shows another arrangement with a plurality of optical fiber cables.

According to FIG. 1, the optical fiber cable has a central reinforcing element 1 as well as a decentralized reinforcing element 2 and 3 on both sides thereof. The reinforcing elements 1, 2 and 3 lie, viewed in cross-section of the optical fiber cable, in a common cross-sectional axis A-A. In between light fiber elements 4 and 5 are arranged. In this case, two light fiber elements 4 each on the one and two light fiber elements 5 on the opposite side of the central reinforcing element 1 are present. As usual with optical fiber cables, the aforementioned components are protected by a cable sheath 6 surrounded. The cable sheath 6 consists for example of a thermoplastic material, such as PVC, LDPE, MDPE, LSZH or FRNC. In the illustrated embodiment, the otherwise circular in cross-section cable sheath 6 at the top and bottom flats 7 and 8. These are approximately parallel to the said cross-sectional axis A-A.

This construction is already unusual in itself. But it is even more interesting by a special arrangement of the individual components and by the nature of the reinforcing elements 1, 2 and 3.

First, the light fiber elements 4 and 5. Overall, here are four available, which is fully sufficient for home installations in most cases. These four light fiber elements 4 and 5 are arranged one above the other in pairs and at a distance. On top of each other is approximately in an axis 9 and 10, which is parallel to a first cross-sectional axis A-A approximately perpendicularly intersecting, the second cross-sectional axis B-B. In the preferred embodiment, the light fiber elements 4 and 5 each have a smaller cross-section than the central reinforcing element 1. In the present embodiment, they are also smaller than the decentralized reinforcing elements 2 and 3. The light-fiber elements 4 and 5 are also spaced apart from the reinforcing elements 1, 2 and 3.

The cable sheath 6 can closely surround the light fiber elements 4 and 5. It makes most sense, however, if in the longitudinal direction of the cable sheath 6, as shown in Fig. 1, at least one tubular cavity 11 for receiving the light fiber elements 4 and 5 is present. An additional shell or a corresponding hose is therefore no longer necessary in this embodiment, but depending on the application can not be excluded. This construction also facilitates stripping during assembly of a plug, because the light fiber elements 4 and 5 can be made easily accessible by mounting or cutting the cable sheath 6. In the event that the optical fiber cable is desired longitudinally watertight, a corresponding sealing means and / or a water-absorbing agent can be given into the cavity 11. For example, this may be a corresponding gel.

Now to the reinforcing elements. The two decentralized reinforcing elements 2 and 3 in the preferred embodiment have a smaller cross section than the central reinforcing element 1. This can, as can be seen in the example of FIG. 1, be realized in that these decentralized reinforcing elements 2 and 3 have more height than width. The latter is to be understood as meaning that this height lies in an axis 12 which runs parallel to the second cross-sectional axis B-B, which cuts approximately perpendicularly to the first cross-sectional axis A-A. This may also have an advantageous effect on the bending properties of the optical fiber cable in the width. That is, in the direction of the larger diameter according to the cross-sectional axis A-A. Not excluded is also a smaller cross-section of other geometry. Not least, the decentralized reinforcing elements 2 and 3 could have a hollow cross-section.

The central reinforcing element 1 is designed essentially for buckling resistance. So it has kink-resistant properties. It can for example consist of metal or non-metallic material, such as fiberglass or fiberglass reinforced plastic. Depending on the selected material, training as a solid profile is possible. The advantage of GFRP is on the one hand in the high mechanical strength, but on the other hand in a low coefficient of expansion with temperature fluctuations. The latter decisively determines the temperature resistance of the optical fiber cable by the relatively large stretching and shrinkage of the cable sheath 6 being absorbed by the reinforcing element 1 during temperature fluctuations. The fiber-optic cable can thus also be used outdoors at temperatures between -40 ° C to 85 ° C. It is also conceivable, for example, the use in wind turbines.

The two decentralized reinforcing elements 2 and 3, however, are designed essentially to tensile strength. So they have mainly tensile properties. At least they are more flexible in relation to the central reinforcing element 1, that is, less kink-resistant. For example, they may be made of a non-metallic material, such as a rope or yarn of aramid and / or glass fibers. However, other synthetic fibers or dielectric materials are also possible. An embodiment of the decentralized reinforcing elements 2 and 3 as a yarn or rope in any case facilitates stripping and exposing the optical fiber elements 4 and 5 during assembly of a plug. Obviously, these materials are not able to impart kink resistance to the fiber-optic cable, but they are very resistant to tension.

For the central reinforcing element 1 as well as for the two decentralized reinforcing elements 2 and 3, it can not necessarily be configured as a solid profile but also as a hollow profile. The reinforcing elements 1, 2 and 3 are at least partially in contact with the cable sheath 6. Thus, they form a composite with this.

In the event that the optical fiber cable is desired longitudinally watertight, in the possible hollow profile of the reinforcing elements 1, 2 and 3, a corresponding sealing means and / or a water-absorbing agent can be given. This makes sense in the reinforcing elements 2 and 3, even if they are not designed as a hollow profile, but for example rope or fiber-like. In this preferred embodiment, they would not be inherently longitudinally watertight, so that the addition of a sealant and / or a water-absorbing agent would remedy this situation. Otherwise, the possible hollow profile of the reinforcing elements 1, 2 and 3 could also be filled with another material, for example with that of the cable sheath 6.

The optical fiber optic cable according to the invention can be produced, for example, for domestic installation with a diameter between 1.4 and 4.0 mm. It is very flexible and can also be routed in cable ducts with sharp bends.

As can be seen from FIGS. 2 and 3, a plurality of optical fiber cables according to the invention can also be used in a larger optical fiber cable or be part of a cable construction of larger diameter. This optical fiber cable can thus also be considered as a basic element that can be used for a variety of purposes, possibly also in the outdoor area. It is also conceivable according to FIG. 3, the combination with other cable types, for example with a conventional copper cable.

Of course, it is within the scope of the invention according to claim 1, the optical fiber cable in detail to construct differently than shown in the drawings. It has already been mentioned in the introduction that the light fiber elements 4 and 5 can contain both individual and a plurality of bundled and / or stranded optical fibers.

It would also correspond to the idea of the invention, if instead of two light fiber elements 4 and 5 at the same location a group of three, four or more light fiber elements would be arranged. This group of light fiber elements should preferably be grouped around a center lying on the cross section axis A-A intersecting the cross section of the optical fiber cable. As this also ultimately corresponds to the present Fig. 1 with two light fiber elements 4 and 5, considered as a pair, with a cross-section of the cross-sectional axis A-A and the axis 9 or 10 corresponding center on this cross-sectional axis A-A.

The central reinforcing element 1 may also have another, different from the circular cross-section. It would also be conceivable to divide this into two or more central reinforcing elements 1, which are grouped around the longitudinal axis of the optical fiber cable. The optical fiber cable could also differ in size and shape from the drawings. The cross section does not necessarily have to be a truncated round, but may for example also be elliptical or have a different geometry. It makes sense, of course, if the cross section is flattened. That is, the first cross-sectional axis A-A is larger than the second, from the first angled cross-sectional axis B-B.

Claims (23)

1. Optical fiber cable with light fiber elements (4, 5), each having at least one optical fiber, and with reinforcing elements (1, 2, 3), characterized by at least one with respect to the cross section of the optical fiber cable centrally arranged reinforcing element (1) and at least two spaced apart on both sides of this central reinforcing element (1) arranged opposite one another, decentralized reinforcing elements (2, 3), between these and the at least one central reinforcing element (1) light fiber elements (4, 5) are arranged. 2. An optical fiber cable according to claim 1, characterized in that the at least one central reinforcing element (1), the decentralized reinforcing elements (2, 3) and the light fiber elements (4, 5), or in each case a group of light fiber elements (4, 5), approximately on a cross-section of the optical fiber cable intersecting cross-sectional axis (A-A) are arranged. 3. Optical fiber cable according to claim 1 or 2, characterized in that the light fiber elements (4, 5) and the reinforcing elements (1, 2, 3) are spaced from each other. 4. An optical fiber cable according to claim 2 or 3, characterized in that two or more light fiber elements (4, 5) are arranged one above the other in each case approximately in an axis (9, 10) parallel to one of the first cross-sectional axis (A-A) approximately perpendicularly intersecting, second cross-sectional axis (B-B) of the optical fiber cable is located. 5. An optical fiber cable according to any one of claims 1-4, characterized in that the at least one central reinforcing element (1) is designed essentially to kink resistance. 6. optical fiber cable according to claim 5, characterized in that the at least one central reinforcing element (1) consists of a non-metal, for example made of GRP. 7. An optical fiber cable according to any one of claims 1-6, characterized in that the decentralized reinforcing elements (2, 3) are designed substantially to tensile strength. 8. optical fiber cable according to claim 7, characterized in that the decentralized reinforcing elements (2, 3) in relation to at least one central reinforcing element (1) are flexible or less kink resistant. 9. Optical fiber cable according to claim 8, characterized in that the decentralized reinforcing elements (2, 3) consist of a synthetic fiber, for example an aramid or glass fiber. 10. An optical fiber cable according to claim 9, characterized in that the decentralized reinforcing elements (2, 3) are formed as a rope or yarn. 11. An optical fiber cable according to any one of claims 7-10, characterized in that the decentralized reinforcing elements (2, 3) have a smaller cross-section than the at least one central reinforcing element (1). 12. An optical fiber cable according to any one of claims 7-11, characterized in that the decentralized reinforcing elements (2, 3) have more height than width, said height being in an axis (12) parallel to the first cross-sectional axis (A -A) extends approximately at right angles intersecting, second cross-sectional axis (B-B) of the optical fiber cable. 13. An optical fiber cable according to any one of claims 1-12, characterized in that the at least one central reinforcing element (1) and the decentralized reinforcing elements (2, 3) have a larger cross section than the light fiber elements (4, 5). 14. An optical fiber cable according to any one of claims 1-13, characterized in that the at least one central reinforcing element (1) and / or the decentralized reinforcing elements (2, 3) is designed as a solid profile / are. 15. An optical fiber cable according to any one of claims 1-13, characterized in that the at least one central reinforcing element (1) and / or the decentralized reinforcing elements (2, 3) is designed as a hollow profile / are. 16. An optical fiber cable according to any one of claims 1-15, characterized in that the at least one central reinforcing element (1) and / or the decentralized reinforcing elements (2, 3) and / or the light fiber elements (4, 5) with a sealing means and / / or provided with a water-absorbing agent. 17. Optical fiber-optic cable according to claim 15 and 16, characterized in that at least one central reinforcing element (1) and / or the decentralized reinforcing elements (2, 3) have at least in the hollow profile a sealing means and / or a water-absorbing agent. 18. An optical fiber cable according to any one of claims 1-17, characterized in that a cable sheath (6) at least partially in contact with the reinforcing elements (1, 2, 3) and / or form a composite with the cable sheath (6). 19. An optical fiber cable according to claim 15 and 18, characterized in that in the hollow profile of the central reinforcing element (1) and / or the decentralized reinforcing elements (2, 3) of the same material of the cable sheath (6) is arranged. 20. An optical fiber cable according to any one of claims 1-19, characterized in that a cable sheath (6) in the longitudinal direction at least one tubular cavity (11) for receiving the light fiber elements (4, 5). 21. An optical fiber cable according to claim 20, characterized in that the at least one tubular cavity (11) is provided with a sealing means and / or with a water-absorbing agent. 22. An optical fiber cable according to any one of claims 1-21, characterized in that its cross-section, ie the cross-section of a cable sheath (6) is flattened, wherein a first cross-sectional axis (A-A) greater than a second, angled from the first cross-sectional axis ( B-B). 23. An optical fiber cable according to claim 22, characterized in that the cable sheath (6) has a deviating from the circular cross-section geometry with flats (7, 8) which are approximately parallel to a cross-sectional axis (A-A) of the optical fiber cable.