DE29700912U1 - Fiber optic cable network - Google Patents

Description

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Fiber optic cable network

The invention relates to a fiber optic cable network according to the preamble of claim 1.
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Fiber optic cable networks are superior to conventional copper-based communication networks, particularly in terms of transmission rate and transmission quality. Efforts are therefore being made to further expand the fiber optic infrastructure for local, regional and long-distance connections. The gradual integration of fiber optic cables into existing copper telecommunications networks and the supply of broadband cable networks for cable television services are also being sought. Furthermore, a much broader supply and thus future-oriented upgrading of broadband cable networks to provide additional, new services as well as the integration of energy supply networks used for communications technology into communication networks in a cost-effective manner is desirable.

To expand the fiber optic cable network, streets, sidewalks and other areas are currently being dug up in order to lay the cables either directly or in so-called cable ducts. However, this type of laying is very time-consuming and expensive and is only possible when the ground is frost-free.

0 In order to avoid excavation work, so-called aerial cables can also be laid. This technology is used in particular for power supply in long-distance areas. In local and regional networks to supply the

However, aerial cables are rarely used anymore due to various disadvantages.

DE-A-42 03 718 proposes laying the fiber optic cables in accessible water channels, especially rainwater channels, and providing transitions to other cable network components on the channel ceilings or on the walls of gullies or manholes. Excavation work is required for connection to other networks.

Recently, a cable laying method has also been tested in which a groove is milled into the street or sidewalk, the fiber optic cable is then inserted and the opening is filled with a filling compound. The mechanical damage to the street or sidewalk is considerably less than when laying cables by digging, but there is still a permanent impairment or reduction in the value of the traffic routes.

The invention is therefore based on the object of specifying a fiber optic cable network according to the preamble of claim 1, whereby the fiber optic infrastructure can be expanded into the buildings in a simple, fast and cost-effective manner in a very flexible and reliable manner at any time of year.

This object is achieved by the characterizing feature of claim 1.

A further aim of the invention is that the optical fiber cable network according to the preamble of claim 15 for pipes which are usually otherwise

used, is pipe-optimized and can be handled very flexibly. This task is solved by the characterizing feature of claim 16.

Further embodiments of the invention are the subject of the subclaims.

By using existing, non-accessible sewer or pipe systems, such as the sewage system or gas pipe systems, the fiber optic cables can be easily laid into the individual buildings.

According to the invention, the fiber optic cables are also attached to the walls of non-accessible duct or pipe systems. The installation is carried out using a remote-controlled duct robot, which inserts the cables into the duct and pipe systems and attaches them to the walls.

A particularly flexible fiber optic cable network is created when the individual fiber optic cable has an external metal protective tube in which the fiber optic fibers are contained, with a large number of such fiber optic cables being attached next to one another and flat to the walls of the duct or pipe system. The cable system must be designed in such a way that it is not damaged by rodents, cleaning and inspection work or by waste water containing alkalis or acids.

Further embodiments of the invention are described in more detail using some embodiments and the drawing.

Show in the drawing

Fig.l is a schematic cross-sectional view with a first fastening element,

Fig.2 a schematic longitudinal section of the

Fastening element according to Fig.l,

Fig. 3 is a schematic cross-sectional view with

a second fastening element, 15

Fig. 4 is a schematic cross-sectional view with a third fastening element,

Fig. 5 is a schematic cross-sectional view with a fourth fastening element,

Fig.6 a schematic representation of a sewer robot,

Fig.7 a schematic representation of a ribbon cable,

Fig. 8 is a schematic cross-sectional view of a ribbon cable attached with a special hose,

Fig. 9 a schematic representation of a 90° optical fiber installation

Fig. 10 is a schematic representation of the optical fiber in the area where it exits the duct or pipe system.

Fig.l shows a cross-section of a pipe 1, which is used, for example, as a wastewater pipe in a sewer or pipe system. A fiber optic cable 2 is held on a wall la of this pipe 1 by means of a fastening element 3.

According to the invention, the fiber optic cable 2 is laid in a non-accessible channel or pipe system. The inner diameter of the pipe 1 is in particular less than 1 m.

The fiber optic cable network is laid in such pipes using a remote-controlled sewer robot, which inserts the fiber optic cable into the pipe and secures it. The sewer robot can also be used efficiently in walkable pipes.

Particularly in the case of non-accessible sewer or pipe systems, special requirements are placed on the type of fastening and its position within the pipe. The fibre optic cable is usually fastened in such a way _that the primary use of the sewer or pipe system is impaired as little as possible. In addition, the fastening must not lead to damage or long-term impairment of the system. Since it will not always be possible to avoid, for example, the waste water flowing through the pipe coming into contact with the fibre optic cable and the fastening elements,

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the fastening elements are shaped in a way that is favorable for flow, as can be seen in particular from the longitudinal section according to Fig. 2. The fastening elements 3 should in particular be designed in such a way that dirt particles carried along with the waste water cannot adhere to the fastening elements.

The fastening elements 3 consist on the one hand of means 3a for receiving at least one optical fiber cable 2 and means 3b for fastening to the wall 1a of the pipe 1. In principle, all types of fastening that can be carried out by a sewer robot are conceivable, such as dowelling, fastening by means of bolts or gluing. However, the use of dowels is not possible, especially with thin-walled pipes or pipes made of clay or plastic. Gluing also requires additional work steps in many cases to ensure sufficient adhesion.

The fastening means 3b of the fastening element 3 are formed by a spring-loaded stainless steel ring which presses against the wall la of the pipe 1. The fastening means 3b are expediently in contact with the wall over a circumferential angle range of at least 180°.

However, it would also be conceivable to design the stainless steel ring as closed, as shown in Fig.3.

The means 3a for receiving the optical fiber cable are preferably designed as snap clamps. The receiving means 3a and the fastening means 3b can

be designed either as a single piece or as separate parts. In the latter case, a suitable connection option must be provided.

In the embodiment shown, the fiber optic cable is guided in a cable duct 4, which protects the fiber optic cable from damage caused by rodents, cleaning and inspection work or by alkaline or acidic waste water. The cable duct 4 can, for example, be designed as a flexible cable pull duct in which the fiber optic cable is laid using known methods.

The laying of the fiber optic cable and its fastening is carried out using a remote-controlled channel robot 5, as shown schematically in Fig.6.

Fig.3 shows a second embodiment of a fastening element 3', whose fastening means 3'b are designed as a closed stainless steel ring, which merges into the receiving means 3'a in one piece. In the area of the receiving means 3'a, the closed stainless steel ring, which consists for example of a rust-proof spring steel strip, has a round indentation which accommodates the optical fiber cable 2, which in the minimum case, as described, consists of just one metal tube with the fibers inside. Here too, the optical fiber cable 2 is surrounded for example by a cable tube 4. Of course, the receiving means 3'a can also be combined with the open stainless steel ring 3b according to Fig.1.

The optical fiber cable 2 is fixed as shown in Fig.3 between the wall la of the pipe 1 and the fastening elements 3'.

Fig.4 shows a fastening element 2'' with means 3''a for receiving a plurality of optical fiber cables 2, wherein the fastening element is flat and the optical fiber cables lie flat next to one another on the wall la of the tube 1.

The receiving means 3''a are formed, for example, by a meandering, rust-proof steel band forming individual chambers into which the optical fibers are snapped by the sewer robot. The receiving element 3''a can be held by all possible means for fastening to the pipe wall 3b, such as an open or closed stainless steel ring, dowels, bolt fastening or gluing.

The flat design is particularly important for non-accessible channel and pipe systems in order to keep the obstacles created as small as possible.

Fig. 5 shows a variant of the multiple cable system according to Fig. 4, where again a large number of optical fibers are arranged next to each other in a first layer on the wall la. A second layer of optical fiber cables is placed offset above this first layer. The fastening means 3'''a are again formed by a meandering stainless steel strip forming chambers in a row. All fastening elements 3b can be used for this as well.

Conventional fiber optic cables consist of a large number of individual fiber bundles that are surrounded by a cable sheath. Such fiber optic cables are particularly suitable for regional or long-distance areas. However, if fiber optic cables are to be laid to individual households or subscribers, these conventional fiber optic cables are too large and cannot be handled flexibly enough.

According to the invention, an optical fiber cable is therefore proposed that consists of a fiber bundle surrounded by a protective sheath. The diameter of this optical fiber cable is normally less than 15 mm, preferably 3 to 5 mm. A metallic sheath is particularly suitable as a protective sheath, as it would also ensure adequate protection against rodents.

A large number of these fiber optic cables can be held next to one another in a duct or pipe system, for example, using fastening elements as shown in Fig. 4 or 5. The many small fiber optic cables ensure a very high level of application flexibility. The maximum branching options of the fiber optic network that can be achieved in this way mean that all types of cable connection can be implemented.

Stainless steel tubes or tubes made of other metals or alloys are particularly suitable as protective sheaths for these small fiber optic cables. Due to the small diameter of these fiber optic cables,

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Cables can also be laid in pipes with a diameter of just a few centimetres.

If not all clamps in the multiple cable systems are occupied by cables, the remaining cavities can be closed with plugs to protect them from contamination. The plugs are removed by the sewer robot before further cables are inserted.

Another cable design is shown in Fig.7, in which one or more of the optical fibers are integrated in a metal protective sheath and several of these are joined together to form a ribbon cable. The cable is hardly bulky due to its flat construction and enables very easy installation in the duct or pipe system.

Fig. 8 shows a possibility of fixing a ribbon cable 7 in a pipe to its wall la. The fastening element used for this is formed by a special hose which is inserted into the pipe and then inflated, whereby it presses itself and the ribbon cable previously inserted into the pipe or individual fiber optic cables against the wall la of the pipe. The cables and the hose itself are permanently fixed to the wall by subsequent hardening of the special hose. It is also particularly advantageous that the fiber optic network is protected by the hose from waste water or other impairments and there are no places where dirt particles can settle. This can be particularly advantageous

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Use this procedure if sewer rehabilitation by installing the protective hose is required anyway.

When laying the fiber optic cables, the transitions from horizontally laid pipe systems to inclined or vertically laid pipe systems are particularly problematic, as the fiber optic cables must not be kinked or bent sharply. Fig. 9 shows the conditions for a 90° laying, which is again carried out with the help of the special hose 7. The inserted* and inflated special hose 8 adheres to the wall of the pipe during the curing process, so that the inevitably created cable loop is also drawn to the pipe wall and held there. The elasticity of the special hose 7, which must be designed appropriately, in turn means that the cable does not completely adhere to the bend where the pipes meet.

The fiber optic cable is led out of the duct system, for example, on a so-called duct cleaning piece, see Fig.10. For this purpose, the duct cleaning piece is provided with a special cover 8, which provides a lead-through for the fiber optic cable, can be removed without affecting the fiber optic cable, and also allows the pipe system to be cleaned without restrictions through the inspection opening. The lead-through is expediently designed in such a way that the cable is led through at an angle and strongly inclined against the cover, so that the cable only has to be bent slightly. The area of the lead-through is additionally protected against dirt deposits by a cover 9. The lead-through point is of course water and

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designed to be airtight. Other exit points are also conceivable within the scope of the invention, for example in the area of drainpipes. If the subscriber's pipe system does not offer a suitable option for the cable to exit, the last few meters to the subscriber can also be laid outside the pipe system, whereby only minimal excavation work is required or an underground connection to or from the sewer or pipe system can be established using a conventional pressing device. The laying and assembly of the fiber optic cable network by the sewer robot is essentially carried out as follows:

The robot, which is equipped with one or more cameras, moves on wheels or chains into the pipe system (Fig. 6). The journey and the various tools can be influenced by remote control. The fiber optic cables can be attached to the robot and inserted into the pipe system during the first or subsequent travels.

If open stainless steel rings as shown in Fig. 1 are used as fastening means, the robot can, for example, take the prefabricated fastening means 3b from a magazine it carries with it and insert it into the pipe. The holding means 3a for the fiber optic cables can either already be attached to the fastening means 3b or can only be attached to them by the robot in a subsequent work step.

The magazine can also be designed in such a way that it contains a spring steel strip wound into a coil, from which the channel robot removes the staples in the

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can be cut to the length required for the pipe system. This has the advantage that different clamps do not have to be kept in stock and processed for different pipe diameters, which leads to cheaper assembly times and implementation costs.

In a similar way, the closed stainless steel rings can be processed according to Fig.3.

Claims (15)

· · »t ■ 14 - Protection claims: 1. Optical fibre cable network in a duct or pipe system primarily used for other purposes, whereby the optical fibre cables are attached to the walls of the duct or pipe system, characterized in that the channel or pipe system used is a non-walkable channel or pipe system. 2. Optical fiber cable network according to claim 1, characterized in that for fastening the optical fiber cables (2) aerodynamically shaped Fastening elements (3; 3'; 3 ' ' ; 3 ' ' ') are provided. 3. Optical fiber cable network according to claim 2, characterized in that the fastening elements (3, 3', 3 ", 3"') have means (3a, 3'a, 3"a, 3"'a) for receiving at least one optical fiber cable (2) and means (3b; 3'b; 3''b) for fastening to a wall (la) of the channel or pipe system. 25 4. Optical fiber cable network according to claim 1, characterized in that the optical fiber cables (2) can be fastened to a wall (la) of the channel or pipe system by fastening elements (3b, 3'b, 3''b) which are spring-loaded in such a way that they press against the wall (la). 5. Optical fiber cable network according to claim 4, characterized in that the fastening element (3b; t ♦ · * - 15 - 3'b; 3''b) rests against the wall (la) over a circumferential angle range of at least 180°. 6. Optical fiber cable network according to claim 2, characterized in that the fastening element (3b; 3'; 3''b) has means (3'a; 3"a; 3'"a) for receiving a multiplicity of optical fiber cables (2), the fastening element being designed in such a way that the optical fiber cables are arranged next to one another and flat on the wall (la) of the channel or pipe system. 7. Optical fiber cable network according to claim 3, characterized in that the means (3a, 3'a, 3''a, 3"'a) for receiving an optical fiber cable are designed as snap clamps. 8. Optical fiber cable network according to claim 1, characterized in that the optical fiber cable (2) has a metallic tube in which optical fibers optical fibers are arranged. 9. Optical fiber cable network according to claim 8, characterized in that the tube has a diameter of less than 15 mm. 10. Optical fiber cable network according to claim 1, characterized in that the optical fiber cable network is guided in a sewer and in the area of a sewer cleaning piece (8) from the sewer or pipe system is brought out. 11. Optical fiber cable network according to claim 1, characterized in that for fastening the optical fiber - 16 - conductor cable (2) an inflatable hose (7) which hardens when inflated is used. 12. Optical fiber cable network according to claim 1, characterized in that the optical fiber cable (2) is fastened in a cable pipe (4) to the wall (la) of the duct or pipe system. 13. Optical fiber cable network according to claim 1, characterized in that for fastening the optical fiber cable (2) fastening elements (3') are provided which fix the optical fiber cable (2) between the wall (la) of the duct or pipe system and the fastening element. 14. Optical fiber cable network according to claim 1, characterized in that fastening elements are provided on the walls (la) which fix several optical fiber cables (2). 15. Optical fibre cable network in a duct or pipe system used primarily for other purposes, whereby the optical fibre cables (2) are attached to walls (la) of the duct or pipe system, characterized in that the optical fiber cables (2) have an outer metal tube with good bending properties combined with good stability and a diameter of less than 15 mm, in which optical fibers are arranged, whereby a single or a plurality of these optical fiber cables are arranged next to each other and flat on the - 17 - Walls (la) of the duct or pipe system.