DE2730106C2 - Tensile cable - Google Patents

Description

- That each thread of the network is embedded in a plastic strand and

r> - that the kunsisioffsträngc equipped with the threads to form the network at the crumbling points caused by their undulating course are welded or glued together.

By the arrangement implemented according to the invention of the tensile threads in the form of a network results in a certain total for the tensile threads elastic extensibility wedge, which is in the order of magnitude of the extensibility of the rest of the jacket, so that the

4 ^r > required flexibility of the cable is ensured. When the net with the tensile strength threads is subjected to tensile stress, these threads are first stretched, the net somewhat reducing its diameter and correspondingly more firmly attached to the cable cele or the

^r > o subjacent layers. In this stretched position, the tensile strength of the tensile threads is fully effective. After the network is relieved of pressure, it springs back into its starting position.
By embedding the tensile threads in the

v, plastic strands, which are connected to one another to form the network, it has been possible to use the known advantages of a network with regard to tensile strength wedge and flexibility even for mechanically sensitive / ugl'esie threads. The sensitive threads are there

W) individually, d. H. each for himself, in a Kiinsisioffsirang embedded and the network is built up through the mediation of four plastic strands. This results in terms of of the network in no way whatsoever. because the Kunslsloff sirange is easy to mix with one another

b5 craps or can be glued. Such a net /, can also be done in the same process as the other layers of the maniel on the cable core be extruded on. Have the tensioned threads with you

their desired irregular course, however not directly involved in the formation of the network itself.

An embodiment of the subject matter of the invention is shown in the drawings

F i g. 1 a schematic representation of a section a cable according to the invention with partially removed layers of the cable structure,

F i g. 2 shows a cross section through FIG. 1 along line 11-11.

I "i g. 3 and 4 parts of the cable in an enlarged Malislab, wherein Fig. 4 is a section through Fig. 3 along the Line IV-IV is.

1 with the soul of any cable is referred to, which is accordingly an electrical cable or can be designed as an optical cable. Above the See-Ie 1 lie! a coat 2 of different layers, of which at least one layer consists of a suitable plastic. One of the layers of the jacket 2 is formed by a network 3, which rests directly on the Sc: lc 1 in the exemplary embodiment shown. The jacket 2 is then attached over the net 3. It However, it is just as possible to arrange the net 3 in a different layer of the jacket 2. So can it The net 3 also rest on the outside of the jacket 2.

The network 3 consists of plastic strands 4, which at their points of contact 5 by welding or gluing are connected to each other. A manufacturing method or a device for manufacturing such a Network is described in DE-PS 17 79 330. The network 3 can accordingly continuously with a jo Extrusion are produced, the deflection of the plastic length 4 to form the network 3 and for welding to one another is carried out by compressed air. The network 3 can therefore be used in the production of the Cable can be applied directly to the cable cele 1 or the jacket 2 in one operation.

When producing the network 3 or when extruding the Kunsisioffstränge 4 zuglesie are in the same Threads 6 mi ι embedded, which then participate in the course of the Kunslstoffsträngc 4. Overall it results accordingly a network 3 made of high tensile strength threads which are encased by the plastic strands 4. As a material for the tensile threads 6, in principle, any tensile material that can be extruded is suitable the DE-PS 17 79 330 can process, d. H. that is, the deflection of the plastic strands caused by the compressed air 4 participate. The threads 6 can accordingly be made of glass fibers, which are also processed into yarns can be, and it is also possible to use carbon fibers for the same. In principle The threads 6 could also be made from a suitable ztigfesien Made of metal. It is always important that the threads 6 are embedded in the plastic strands 4 through which the network3 is formed.

A particular advantage of the invention arises for v, communication cable, whose core is filled with a sealing compound, to produce in this manner a longitudinally watertight cable. If the net 3 is attached directly to the core I as shown in the drawings, the same results in an additional lnbyrimhai'ligc seal for the gap between the core 1 and the jacket 2, so that this gap is also perfectly protected against the penetration of Water is sealed. Attaching the network 3 directly to the core I has the further advantage that the otherwise customary core plating can be dispensed with, since the network provides the distance between core 1 and jacket 2 required for the required dielectric strength.

For the sake of completeness, it should be noted that the invention is not only applicable to electrical and optical Cables, but can also be used with so-called district heating cables with the same success. District heating cables consist of two concentric, gcweliten Tubes and, like the cables mentioned above, can be wound on drums.

1 sheet of drawings

Claims (2)

Patent claims: . 1. Tensile cable, the core of which is surrounded by a sheath consisting of different layers is, in which in the longitudinal direction of the cable undulating, tensile strength threads in the form a network surrounding the cable core are attached, characterized in that - That each thread (6) of the network (3) is embedded in a plastic strand (4) and - That the plastic strands (4) equipped with the threads (6) to form the network (3) the contact points (5) caused by their undulating course are welded together or are glued. 2. Cable according to claim 1, characterized in that when it is designed as a longitudinally watertight, communication cable filled with a sealing compound the network (3) directly on the core (1) is arranged The invention relates to a tensile cable, the core of which consists of one of different layers existing sheath is surrounded, in which in the longitudinal direction of the cable undulating tensile strength Threads are attached in the form of a network surrounding the Kabelscele all around. "Cable" within the meaning of the invention should include all electrical cables, such as power cables and telecommunications cables, but, for example, communication cables with optical fibers can also be understood. Such cables will be produced in great lengths and wound on drums from which they are unwound again for laying can be. Both for the Auflroinmeln as well as for the laying of the cables .mit considerable Forces are drawn both by the cable core and by the jacket surrounding the same must be endured. The tensile strength required for this is from the Kabe'seelc with electrical Cables are usually given because they contain metallic conductors. The sheath of this cable is made made of different layers, at least one layer of which is plastic while others Layers consist, for example, of wound tapes or thin metallic foils. Such a The jacket itself does not have the tensile strength required to pull such long cables is required. In DE-OS 16 40 929 a tensile strength cable is specified, as described at the beginning. This known cable is an aerial cable with a plastic jacket in which glass fibers running lengthways are embedded all around. If this fiber optic run in a straight line, then such a jacket is tensile strength but difficult to bend because of the glass fibers have a significantly lower elongation compared to plastic. The Galsfibres are in the jacket material embedded, so they are almost at the outer diameter with respect to the cable. When the Cable and also when laying the same, the cable must be bent around relatively small radii. Cable core and the plastic sheath of conventional cables easily withstand such bends. Through the storage The bending is severely hindered by rectilinear glass fibers in the plastic jacket, since the optical fibers, especially in the case of cables with a larger diameter, are not the ones required for this bend Have extensibility. As a result, cables of this type have to be used on much larger drums with very much large core diameter are wound, which are difficult to transport and beyond only ίο can accommodate short lengths. In this publication it is also mentioned that the glass fibers are housed in the form of a network in the plastic jacket could be. They would then have an undulating course. Information on how such a network of glass fiber I ¹ I sern can be implemented in practice, however, cannot be found in the publication. In fact, can be made very easily breaking Glasscidlcfädcn no net produce, dßnn a Verknotiing is nk-hi possible. A possible binding of the glass lasers at the nodes of a network divide! for economic reasons, too, since such a measure requires too much effort. The invention is based on the object of specifying a tensile strength cable in which sufficient tensile strength and flexibility are ensured so that it can be wound onto conventional drums and laid with conventional mechanisms, and in which the arrangement of the tensile threads is implemented as a network.
This object is achieved with a tensile cable of the type described in accordance with the invention in that