DE605588C - Method for producing a telecommunication cable with a distributed inductive load - Google Patents

Description

It is common to use telecommunication cables]! with constantly distributed inductive load the load material, as which is usually an alloy with high initial permeability, for example Permalloy, is used in the form of thin strips on the electrical conductor to raise. So far, for manufacturing reasons, the use of tapes has been made which were still relatively thick, although made of magnetic material Reasons the use of much thinner tapes would have been sufficient. Very thin strips less than 0.05 mm thick, the would be sufficient in and of itself to achieve a sufficiently high inductance, could you do not use them, because they can also be produced by the usual method of rolling is so expensive that the advantages achieved with the thin ribbons are outweighed would. It has therefore already been suggested to move on to the ligaments because of the difficulties To completely dispense with their production and directly to the copper conductor 'one deposit a wafer-thin layer of, for example, 0.05 mm thick. The Bielasturigs layers produced in this way however, have the disadvantages that on the one hand excessive eddy current losses occur in them, since the deposited layers form a closed shell, and that they on the other hand as a result of their intimate connection with the conductor at bends of the conductor are subjected to stretching, which the magnetic Impact properties of the loading layer and thus the inductance of the conductor in an undesirable manner. One is therefore still dependent on the use of tapes and has tries to improve their manufacturing processes.

One has already tried the production of the loading bands in such a way that a layer of arbitrarily small thickness is electrolytically applied to a foreign surface knocked down and cut into ribbons that peeled off the backing and should be spun onto the copper conductor. In doing so, however, you had to because of the lower mechanical strength electrolytic layers, the layer thickness and thus the strength of the strips as well make it unnecessarily large again. Another known method is that Load material applied in fine distribution to fiber belts, what by Spraying or gluing of powder is to be effected, and this on one or both sides metallized tapes are then wound onto the conductor. This method has, inter alia, the disadvantages that as a result of the all too frequent subdivision of the load layers unnecessarily thick layers are required to achieve sufficient inductance values and also a subsequent annealing to improve the magnetic properties with regard to the destruction of the fibrous strips serving as carriers of the loading layer not possible. These disadvantages are already avoided in other known methods in which the load

material united with such meta-use will that have a high mechanical, and Have electrical resistance and diffuse into the surface of the magnetizable Body. In these procedures it is known to be the core of the stress band either from the material with high permeability or from the material with high mechanical and electrical Manufacture resistance and the outer layer of the respective different material precipitate electrolytically. However, these manufacturing processes still have major disadvantages. In the case of a tape, the outer jacket of which is made of the magnetic material consists, the core made of the resistance material only serves to increase the tensile strength of the load material and, in electrical terms, represents a more or wezo Less ineffective amount of material. In addition, there is' about half of the magnetic Material too far away from the conductor. If conversely the core of the magnetic material and the jacket is formed by the resistance material, is the magnetic material overall of that given by the electrical conductor Current path kept at too great a distance and thereby the inductance compared to the amount of the expended magnetic material is considerably reduced. The resistor material has, dated From an electrical point of view, it has negligible importance and participates in the Stx-omleitung practically not part.

With the method according to the invention the disadvantages of these known methods become all avoided. In the method according to the invention, the magnetic material is also electrolytically applied a metallic support body is deposited, but a different arrangement of the material on the support body is thereby and also used a different material for the carrier body itself. The procedure according to the invention consists in that the loading material is electrolytically only on one side of my thin conductive tape, especially made of copper, if necessary but also made of iron, then surrounds the copper conductor with this tape in such a way that that the conductive tape rests with its uncovered side on the conductor itself, and then further processed the conductor loaded in this way.

The main advantages of the method according to the invention are that the loading bands contain no dead material! as a carrier for the magnetizable Material serving conductive tape takes part in the electrical current conduction and one further the magnetizable material in any thin layer directly above the current path of the 'electrical conductor can be arranged without being forced to use the magnetizable Roll the material into strips yourself or thin it in the form of a seamless Apply layer rigidly connected to the conductor. Since one as a carrier for the magnetizable Material ie a relatively soft material, e.g. B. copper or also Iron, can use and the rolling out of these fabrics into thin strips fabrication causes no difficulties and no noteworthy costs, the Kabei significantly cheaper than the known cables. Achieved in magnetic terms one has the advantage that the magnetizable material of high permeability on the Ladder can slide and is not exposed to harmful stretching even when bent. Another advantage is that the application of the magnetizable material is on the copper conductor can be done at great speed, especially if you have the Choose a large height of rise when spinning.

Instead of the conductive material covered with the magnetizable high permeability material Winding the tape in a helical shape on the conductor, you can do it if necessary also fold lengthways around the ladder.

The figure shows an embodiment of a telecommunication cable according to FIG Invention of certain conductor. In it, 2 is the copper conductor, 3 is the one on the copper conductor wound conductive tape, on the leash layer 4 magnetizable in the desired layer thickness Material of high initial permeability is applied.

Claims (1)

Claim: Process for the production of an Eernmeldekabel with steadily four-part inductive Load, in which a magnetic, highly permeable material is electrolytically applied to a metallic one as the load material Carrier body is applied, characterized in that the loading material Applied only to one side of a thin conductive tape, in particular made of copper, then the copper conductor Surrounded with this tape in such a way that the conductive tape rests with its uncovered side on the conductor itself, and the in this way loaded ladder is further processed. 1 sheet of drawings