DE2503463A1 - Telecommunications cable with core of several three-conductor strands - having sufficient tensile strength without use of conventional reinforcements - Google Patents

Abstract

Telecommunications cable comprises a core consisting of several strands each of which consists of conductors, surrounded by a sheath. In the gaps between the conductors are disposed continuous longitudinally extending expansion-resistant members, pref. twisted glass fibre yarns, or plastic threads of e.g. polyamide. These are pref. introduced into the gaps in a single proces simultaneously with stranding of the conductors.

Description

Communication Cable The present invention relates to a communication cable with a core of a large number of at least three-core stranding elements and one the coat surrounding the soul.

Every electrical cable must have a certain tensile strength, thus tensile forces that z. B. can attack the cable when laying, not damage to the cable or impairment of the electrical transmission properties of the cable.

An electrical cable can carry this required tensile strength the cable core, the cable sheath or additional equipment, which are arranged in the cable core or the cable sheath.

In the case of communication cables, the cable core is used to absorb tensile forces only suitable up to the specific copper cross-section load capacity, otherwise they can experience uncontrollable stretching when attacked by tensile forces, as a result of which the electrical transmission properties change in an unmanageable way. For this reason, the sheath with receiving organs is used in communication cables for greater tensile loads provided for the tensile forces. Such organs with tensile strength, which at Communication cables are attached, for example, steel wire armouring, such as t2und- and flat wire armatures or steel wire mesh. Sheath constructions for cables with such additional Pull organs are of course very heavy. One is therefore to a lighter construction passed over, in which the cable jacket according to the type of layered jacket or corrugated steel jacket is constructed. In the case of cables with such a sheath construction, however, the classic ones are missing Pulling organs such as steel, round or flat wires or steel wire mesh.

The present invention is based on the object of a communication cable indicate the required tensile strength without having the classic traction elements has, but is lighter with the same diameter.

This problem is solved by the fact that in a communication cable of the type specified above, in the interstices formed by the veins Stranding elements are arranged in the longitudinal direction continuous, high tensile strength organs. According to the invention, fiberglass threads are preferably provided as the organs with high tensile strength. The tensile organs can also consist of a tensile plastic. A such is, for example, polyamide.

The invention also provides a method for producing one according to the invention Cable. The method consists in that the tensile organs in one operation with the stranding of the cores to the stranding elements in the interstices of the stranding elements be brought in.

The invention takes advantage of the fact that the stranding elements of a Telecommunication cables because of the round shape of the stranded wires, both Have inside and outside gussets. These gussets mean that within the Stranding elements have a relatively high proportion of air voids. The air in the interstices between the wires is a desirable insulation medium in the cable. The invention now gives the inner gussets of the stranding elements a further one Function, namely to be a placeholder for the tensile organs.

It is known that fours from plastic-insulated cores without a heart cord a much higher stability, d. H. Dimensional stability as a foursome from paper-insulated Has veins. Experiments have shown that fours from plastic-insulated cores without a solid heart cord have better electrical coupling properties than fours who identify such a heart cord.

Surprisingly, it has now been shown that glass silk threads due to their high flexibility in the interstices of the stranding elements plastic-insulated wires can be introduced without the electrical Coupling properties are impaired. The ones in the inner gussets of the stranding elements arranged glass silk threads lead, on the contrary, to even better constancy of the Core configuration of the stranding elements.

The inventive arrangement of tensile organs in the inner gusset spaces stranding elements should not be used for stranding elements made of plastic-insulated cores limited. Rather, stranding elements made of paper-insulated cores can also be used the invention Way equipped with organs with high tensile strength are particularly suitable for equipping stranding elements according to the invention those with internal gusset formation, d. H. So three, four, five, etc.

The advantages of the invention are in particular that a communication cable is proposed in which the soul can absorb significantly greater tensile forces.

The communication cable according to the invention is of the same diameter lighter than the known communication cables with an additional one provided on the jacket Tensile reinforcement. Tensile cable terminations can be attached to the communication cable according to the invention easy to manufacture because the fiberglass threads are exposed at the ends of the cables.

The fiberglass threads are not vie z. fl. Metal or plastic foils or the jacket material connected. The manufacture of the tensile stranding elements for the communication cable according to the invention can without special Effort on the usual and known machines.

Exemplary embodiments of the invention are shown in the drawing. Figure 1 shows a cross section through a communication cable according to the invention, the Figures 2, 3 and 4 contain cross-sections through stranding elements according to the invention.

With 1 a communication cable is referred to. It consists of the soul 2, which is made up of the stranding elements 3, and the one surrounding the core Cable sheath 4. The stranding elements 3 in turn consist of the wires 5. In the The intermediate space formed by the cores 5 of each stranding element is, as shown in FIG FIGS. 2 to 4 can be seen, organs 8 with tensile strength are arranged. The stranding elements forming cores in turn each consist of the conductor 6, which is covered by an insulating sleeve 7 is surrounded. This insulating sleeve can be made of plastic or made of paper. The cable sheath 4 can consist entirely of a suitable plastic or be constructed in the manner of the known layered jacket. Then there is one concentric position of a metallic layer 9.

5 claims 1 131. -Drawings with 4 figures

Claims (5)

P a t e n t a n s p r ii c h e communication cable with a soul a large number of at least three-core stranding elements and one surrounding the core Sheath, characterized in that in the gusset spaces formed by the veins of the stranding elements are arranged in the longitudinal direction continuous tensile organs. 2. communication cable according to claim 1, characterized in that the organs with tensile strength are fiberglass threads. 3. communication cable according to claim 1, characterized in that the organs with high tensile strength are threads made of plastic. 4. communication cable according to claim 3, characterized in that the organs with high tensile strength are polyamide threads. 5. A method for producing a communication cable according to one of the Claims 1 to 4, characterized in that the tensile organs in one operation with the stranding of the cores to the stranding elements in the interstices of the stranding elements be introduced.