NL9201447A - Single or multi-core electrically conductive cable, more particularly for signal transmission. - Google Patents

Description

Short designation: Single or multi-core electrically conductive cable, more particularly for signal transmission.

The invention relates to a single or multi-core electrically conductive cable, more particularly for signal transmission, wherein the conductors are embedded in a cranant section based on plastic.

According to the state of the art, the transmission of electrical signals generally uses cables with conductors of an electrically conductive metal, such as, for example, copper.

Generally, such conductors are considered a homogeneous transfer medium and the electron flow therein is understood as that of a liquid.

It is known that the quality of music reproduced by high-quality equipment is influenced or significantly affected. eventually decreases due to the type of cable connecting the various parts of the music-reproducing equipment. For example, it is known in particular that external chemical influences can seriously affect the quality of the cable as a signal-transmitting medium. A proven remedy against such damage is the electrolytic coating of the conductor with a protective layer of, for example, tin or silver.

As a criterion for expressing differences between different conductors of electrical cables, hitherto the specific resistance (chnytm3), therefore the electrical co-existence, has been used as a measure. However, in practice, additional cables in sound equipment experience differences in sound effect, which cannot be explained by differences in the conductor material used or by differences in electrical penetration.

The invention now aims at improving the hitherto conventional conductors in transmission cables, in particular to improve the transmission properties at the lower signal levels.

The aim of improvement is based on the insight that the usual metal conductor can in no way be regarded as a homogeneous medium and that much more significance should be attributed to the fact that a metal conductor is factual from a mainly mechanical way to established non-reproducible grouping of metal crystals with contaminants and boundary areas between them, which form barriers for optimal transfer at low signal levels. Even protective layers of, for example, tin or silver will not be able to prevent the impurity of the conductor (in the long term) from increasing, inter alia, through gas absorption and oxidation, and thereby also increase the barriers against an optimum signal transmission, so that the quality of the conductor becomes increasingly less.

It should be borne in mind here that the usual method of manufacture (by drawing) of the known metal conductors is pre-eminently conducive to the occurrence of dislocations with a similar barrier effect. Also during the electrolytic plating process, as well as during normal use, where the conductor is subject to deformations, such as bending, such dislocations and an associated deterioration of design transfer can occur.

Metal conductor tests and measurements, at low signal levels, where the number of higher harmonics in the output signal were found to have increased significantly, supporting this insight. Against this background, the observed decline in transmission of the lower signal levels in the known metal conductors could be described as the result of a phenomenon which can be termed "cross-crystal distortion" and is comparable to the well-known phenomenon of "cross-over distortion" with lesser quality amplifiers.

The improvement contemplated by the invention is now obtained in that at least one of the cores contains a conductor of a carbon fiber obtained by dehydrogenation of a cyclic hydrocarbon C 1 Hy.

It should be noted that the production of carbon fibers by extrusion of a carbon black product obtained by dehydrogenation of a hydrocarbon is generally known per se. However, this generally concerns carbon fibers that serve as reinforcement in plastics.

A carbon fiber is also known to be very flexible, chemically inert, strong and in principle has good electrical conductivity. The electrical conductivity, however, depends to a great extent on the degree of order of the carbon atoms. However, it is precisely this degree of orderliness which is a very uncertain factor in the carbon black product (obtained by dehydrogenation of a hydrocarbon) used as the starting material for the carbon fiber.

It has now surprisingly been found in the invention that when carbon fiber production is based on a carbon black product obtained by dehydrogenation of a cyclic hydrocarbon, the cyclic molecular structure apparently has a strong ordering effect on the reorientation of the carbon atoms during extrusion or spinning of the fiber.

It may be assumed that the carbon fiber thus obtained maintains initially a cyclic structure and that the fiber has a linear structure of partially overlapping "loops" of carbon atoms, the double bonds and the purity of the carbon fiber providing an unimpeded electron transport in ensure the longitudinal direction of the fiber. In particular, it was surprising that measurements of X-ray pedantance on a large number of individual fiber extrusion and spin techniques known per se, respectively, from a carbon fiber having a thickness of 7 microns produced by dehydrogenation of benzene as well as a large number of conductors made according to the invention. diameter of 1 mm and composed of around 12000 carbon filaments with a thickness of 7 microns led to surprisingly low and hardly fluctuating values of around 400 Kbhm / men 35 dhm / m respectively.

It has further been found that, according to a further feature of the invention, the ordering effect of the cyclic starting structure can be enhanced by the application of an electric field when extruding or spinning the fibers, and that as a result of the values just mentioned and the fluctuations between them can be further reduced .

Due to the small thickness (on the order of 10 µm) of the (individual) carbon fibers, distortions such as bending during use, unlike with the known metal conductors, will not lead to a deterioration of the signal transmission, lower levels leading to dislocations whereas, due to the purity of the carbon fiber and its chemical inertness, the lifetime can be considered almost unlimited in all respects.

In a practical application, a conductor according to the invention will consist of a bundle of the above-described carbon filaments. As with a cable with metal conductors, these bundle carbon filaments will be embedded in a plastic sheath, for the purposes of the invention in particular, the plastics are polyethylene, polypropylene and polytetrafluoroethylene.

In order to take full advantage of the high chemical stability and purity of the carbon fiber in this case, it is advisable to coat each fiber (for example, by dipping) with an insulation layer during the manufacturing process, so that the electron transport is only in the longitudinal direction of the conductor can take place and no undesired "cross traffic" can take place.

It is practical to choose a protective layer or lacquer layer soluble in a solvent such as acetone. This offers the possibility to finish it with a connecting component (connector) of a conductor insulated from a bundle by lacquer layers of each other by dipping in acetone over a very long length from the insulating lacquer layers, so that in the conductor end there is actually effective transverse contact between the individual carbon fibers are formed, which is necessary for diverting the electron currents from all fibers to a connecting bush or bush-shaped part of the connector which can be arranged mechanically around the thus "internally stripped" conductor end.

The invention also relates to a method for manufacturing a carbon fiber suitable for use as a conductor in an electrically conductive cable, by extruding or spinning a carbon black product obtained by dehydrogenation of a hydrocarbon. A first feature of the process according to the invention consists in that an electric field is applied in the extrusion or spinning zone during the extrusion or spinning process, while a cyclic hydrocarbon is preferably used as the hydrocarbon. As noted above, the application of an electric field in the manufacture of the carbon fiber has an ordering effect on the atomic arrangement during the formation phase of the carbon fiber, while the cyclic molecular structure of a cyclic hydrocarbon also has an ordering effect on the atoam arrangement in the forming carbon fiber. goes out.

A special aspect of the invention furthermore concerns the processing of cable residues or of cables that have become unusable.

Cables with metal conductors that have become unusable are generally processed by combustion. As is known, such processing is considered to be very harmful to the environment, and there is increasing resistance to this.

In this regard, a transmission cable according to the invention, all of which conductors are made of carbon fibers, offers other processing options which do not pollute the environment.

A preferred method of processing (residues of) cables according to the invention consists in that the cable and cable residues are respectively chopped into pieces, which are then fused by heating into a coating mass suitable for reuse as electrically conductive electrical conductors. This coating material is a homogeneous carbon-mixed and thereby electrically conductive plastic, the base material of which is formed by the insulating coating of the (carbon) conductors in the cable.

The invention is applicable to all types of single and multi-core cables, including so-called coaxial cables, in which a central conductor consisting of carbon fibers according to the invention is surrounded or shielded by an outer conductor consisting of a network of carbon fibers.

In summary, the invention has opened the possibility to maximize the electrically conductive properties of carbon fibers in a reproducible manner and thus make these carbon fibers suitable for use as an electrical conductor in transmission cables, of which especially the signal transfer at the lower levels is of great importance.

Used in high-quality music-reproducing equipment, a transmission cable according to the invention, due to its excellent transmission properties at the lower levels, contributes to music distinguished for connoisseurs by an unmistakable spaciousness11.

Claims (8)

1. Single-core or multi-core electrically conductive cable, in particular for signal transmission, the conductors being embedded in a cam jacket based on plastic material, characterized in that the conductor of at least one core is obtained by dehydrogenation of a cyclic hydrocarbon C ^ Hy carbon filament. Cable according to claim 1, characterized in that the core consists of a single bundle of carbon filaments. Cable according to claim 2, characterized in that the individual filaments or fibers are covered by an insulating coating layer. Cable according to claim 3, characterized in that the coating layer has a thickness in the range of 0.5-2 microns. Cable according to claims 3-4, characterized in that the coating layer consists of a material soluble in a solvent, such as acetone. 6. Method for manufacturing a carbon fiber suitable for use as a conductor in an electrically conductive cable, by extruding or spinning a carbon black product obtained by dehydrogenation of a hydrocarbon, characterized in that during the extrusion or spinning process an electrically field is constructed in the extrusion or spinning zone. Process according to claim 6, characterized in that a cyclic hydrocarbon is used as the hydrocarbon. Method for processing cables to be regarded as waste, respectively, from cable residues according to claims 1 to 5, of which all cores consist of carbon filaments (fibers), characterized in that the cables or cable residues are chopped into pieces, which are then heated by heating fused to a coating mass suitable for reuse as conductive shielding of electrical conductors.