DE2723488A1 - Electric cable with polyethylene type insulation - and outer conductive layer contg. release agents e.g. silicone or polyethylene glycol! cpds. - Google Patents

Abstract

An electric cable comprises an insulation of opt. cross-linked polyethylene or ethylene co- or terpolymer and an outer conductive layer co-extruded and opt. co-vulcanised with the insulating layer. The conductive layer is of polyethylene, chloroprene rubber, chlorinated polyethylene, SB and/or natural rubber contg. conductive lamp black. The improvement consists in incorporating release agents in the conductive layer comprising silicones, polyols, ethers, aldehydes, waxy aliphatic hydrocarbon and/or higher liq. aromatic hydrocarbons. Good adhesion between the layers is ensured and, therefore, good electrical rigidity, while, on the other hand, the external conductive layer can be easily removed from the insulation without damaging the latter. The silicones are pref. silicone oil, grease, resin or rubber. The polyols have mol. wt. >=500 and are pref. polyethylene-glycols. The ethers have b.pts. >=200 degrees C and are pref. dibenzylethers and/or their derivs. The aldehydes influence the peroxidic crosslinking speed and are pref. tetra hydrobenzaldehyde. The waxy aliphatic hydrocarbons are paraffin oil, wax or polyethylene wax.

Description

Electrical cable with plastic insulation and

outer conductive layer The invention relates to an electrical cable with non-crosslinked or crosslinked plastic insulation based on polyethylene, Copolymers or terpolymers of ethylene and one together with the plastic insulation extruded, uncrosslinked or together with it crosslinked (co-vulcanized) outer conductive layer based on polyethylene (PE>, copolymers of ethylene, chlorosulfonated PE, chloroprene rubber, chlorinated PE, butadiene-styrene rubber and / or natural rubber or mixtures thereof with the addition of conductive carbon black.

Elekttischa cables with plastic insulation used for transmission high voltages are provided, usually have under the insulation a conductor smoothing layer on the conductor and a conductive layer over the insulation made of weakly conductive plastic. In the interests of electrical strength ces cable is the best possible adhesion of the guide rails and the insulation to promote. As is known, this is achieved in that the conductive layers and the insulation is applied to the conductor in tandem or triple extrusion and then be networked together.

When assembling accessories on high-voltage cables with plastic insulation the outer conductive layer must be easily removed from the insulation without that there is a risk that the insulation will be damaged or that residues of the Conductive layer remain on the insulation.

The good ones to be promoted because of the electrical strength of the cable Adhesion of the layers and the easy peelability of the conductive layer are opposing demands.

Various solutions have been proposed, both of which To meet demands. So far, however, none of the solutions has proven to be proved completely satisfactory.

An attempt was made to use a special cable structure at the same time to achieve sufficient strength and peelability of the layers. According to the DT-OS 24 30 792 is to this. purpose between the insulation and the outer Conductive layer an intermediate layer is provided, the mechanical strength of which is lower is than the mechanical strength of the insulation and also smaller than that of the conductive layer. According to DT-OS 24 22 003, the outer conductive layer is groove-like on its circumference Grooves provided so that they can be pulled off the insulation in strips. Both Proposals have the disadvantage that they require an increased economic outlay and that they do not guarantee good adhesion and residue-free peelability Offer.

It has also been suggested through special manufacturing processes achieve good adhesion and peelability of the layers 2'J at the same time. So is at a known process is first extruded and crosslinked before the insulation the outer conductive layer is applied. Apart from that for the application the outer conductive layer again requires an additional operation in this process, the good adhesion of the conductive layer to the insulation is not guaranteed.

Also by using special mixtures for the outer conductive layer Attempts were made to manufacture cables in which the conductive layer adheres well to the insulation adheres and yet can be easily peeled off. So it has been suggested1 for isolation and different crosslinking agents for the conductive layer use, which have no or only no effect on the crosslinking process in the adjacent layer exert a minor influence (DT-OS 25 14 890). Another suggestion is a conductive layer made of conductive polychloroprene compound on top of the VPE insulation with additions of ethylene-propylene rubber or ethylene-propylene terpolymer rubber to apply (DT-OS 25 13 576). This known cable sheathing is together with the Conductor smoothing layer can be produced in triple extrusion. as shown in practice it can only be easily peeled when heated.

There were also a number of other additions to the conductive Mixture proposed with which an improvement in peelability at the same time good adhesion of the conductive layer on the insulation should be achieved. A perfect one However, this has not yet resulted in a satisfactory solution a need for improved compounds for the outer conductive layer of high voltage electrical cables.

The present invention is therefore based on the object of networked or uncrosslinked a cable with art; storage protection based on PE, copolymers or to indicate terpolymers of ethylene and an outer conductive layer that is so composed is that they are provided along with the insulation and the inner conductive layer, if any such is present, can be applied and vulcanized so that on the one hand Good adhesion is created between the layers and thus the desired electrical Strength of the cable is guaranteed, but on the other hand the outer conductive layer Can be easily removed from the insulation without leaving any residue and without damaging the insulation is.

This object is achieved according to the invention in that the outer Conductive layer release agent. based on silicones, polyols, ethers, aldehydes, waxy aliphatic hydrocarbons and / or liquid highly aromatic hydrocarbons or mixtures thereof.

The silicones added as release agents to the outer conductive layer are primarily silicone oil, silicone grease, silicone resin or silicone rubber. The the Polyols added to the conductive layer as a release agent preferably have a molecular weight of 500 or above. A preferred polyol is polyethylene glycol.

If an ether is used as a separating agent, its boiling point should be be at 2000 C or above. The ethers are used as release agents in particular Dibenzyl ether and / or its derivatives in question. According to the invention as a release agent preferred aldehydes are those that reduce the rate of peroxidic crosslinking affect how the tetrahydrobenzaldehyde derivatives.

According to the invention, waxy aliphatic hydrocarbons are used Paraffin oil, paraffin wax, polyethylene wax and the like are possible. According to the invention can be the outer conductive layer Liquid, highly aromatic as a release agent Kohien'-jrserstofffl and their mixtures such as tetrahydronaphthalene and / or semi-mixtures based on naphthalene-anthracene-phenantrene.

An advantageous method for producing a cable with << r outer conductive layer according to the invention consists in dai3 on de: conductor, as far as required an inner conductive layer, the plastic insulation and the outer one Conductive layer applied simultaneously in the known triple extrusion process and, if the insulation is to be crosslinked, crosslinked (covulcanized) at the same time will.

The mixture according to the invention for the production of the outer conductive layer thus consists of a larger proportion of P ~, copolymers of ethylene, chlorosulfonated PE, chloroprene rubber, chlorinated PE, butadiene-styrene rubber and / or natural rubber or their mixtures as the base material. According to the invention, this contains in quantities from approx. 15 - 50% conductive carbon black and in amounts of 0.1 - 30 percent by weight release agent based on silicones, polyols, ethers, Aledhyden, waxy aliphatic Hydrocarbons or their mixtures. The mixture preferably contains the Release agent additive in amounts of 0.5-20 percent by weight. The release agent additives can be compounded into the base material before extrusion or superficially are mixed in. This superficial admixture is carried out, for example, by Drum up. But you can also place the base material in the extruder during the extrusion are added.

Ethylene copolymers which can be used for the base material of the mixture are e.g. ethylene-vinyl acetate copolymers and / or ethylene-ethyl acrylate copolymers. Commercially available conductive carbon blacks or special carbon blacks such as Ketjenblack are used as conductive carbon black EC application.

The cable according to the invention has an outer conductive layer which adheres well to the insulation of the cable and is nevertheless easy to peel. The outer Conductive layer can without losing the advantage of good adhesion and easy peelability extruded together with the insulation and a possibly existing inner conductive layer and be networked. Peroxidic co-vulcanization is also possible. For the Production of a cable of the type according to the invention are additional measures for It is not necessary to produce a better peelability. A particular advantage the invention consists in the fact that the force with which the outer conductive layer can be peeled off is adjustable through targeted dosing of the release agent additive. With addition Using silicone as a release agent increases the hydrophobicity of the conductive layer. That has result in the ingress of steam or water into the insulation through the the outer conductive layer is additionally hindered, making the formation of watertrees more difficult will.

Some mixing examples are given in the table. You let clearly recognize the advantages of the invention. The basic substance of the mixture examples ethylene-vinyl acetate copolymer is used for the outer conductive layer in all cases Addition of approx.

30 - 40 percent by weight conductive carbon black. This basic substance were the release agent additives are added in the specified amounts (percent by weight). The admixture was done by compounding or superficial mixing, e.g. by reeling on a drum, before extrusion or during extrusion in the extruder.

The peel force was measured for the crosslinked samples (numbers 1 - 10 under A) Determined on sandwich panels 24 hours after co-vulcanization with VPE. In the event of of the non-crosslinked, thermoplastic layers (numbers 11 and 12 under B) it measured 24 hours after its creation. It is given in Newtons / cm.

A) networked together Release agent additive No peeling force N / cm Type of dosage in % 1 - o not removable 2 tetrahydronaphthalene 2 Paraffin oil 2 Silicone paste '2 5 Tetrahydrobenzaldehyde 1 derivative 2 3 polyethylene glycol 1 Silicone oil 1 5 14 Oil on anthracene Phenanthrene base 5 4 oil on anthracene Phenanthrene base lo 15 5 silicone grease 4 Tetrahydronaphthalene 4 18 6 tetrahydronaphthalene 1.25 Paraffin oil 1.25 Silicone grease 1.25 20 Tetrahydrobenzaldehyde derivative 1.25 7 paraffin oil 2.5 Silicone oil 2, o 23 Diphenyl oxide 2.5 8 oil on anthracene 5 25 Phenanthrene-based 9 polyethylene glycol 9 25 10 tetrahydronaphthalene 4 Paraffin oil 4 27 B) uncrosslinked, thermoplastic 11-0 65 12 tetrdronaphthalene 2 Paraffin oil 2 Silicone paste 2 7 Tertabydrobenzaldehyde derivative 2 The table shows by means of examples how the peel force according to the invention can be adjusted in an advantageous manner through the choice of additives and their quantitative dosage. The outer conductive layer, which cannot be removed without the additives, cf.

Examples 1 and 11, according to the choice of release agent and its dosage can be deducted as required.

10 pages of description 16 claims

Claims (16)

Claims Electrical cable with networked or non-networked Kur.ststoffisolierung based on polyethylene, copolymers oler terpolymers of the Ethylene and a non-crosslinked extruded together with the plastic insulation or together with it cross-linked (co-vulcanized) outer conductive layer on the basis of polyethylene, chloroprene rubber, chlorinated polyethylene, butadiene-styrene rubber and / or natural rubber or mixtures thereof with additions of conductive carbon black, thereby characterized in that the outer conductive layer release agent based on silicone polyols, Ethers, aldehydes, wax-like aliphatic hydrocarbons and / or liquids contains highly aromatic hydrocarbons or mixtures thereof. 2. Cable according to claim 1, characterized in that the outer conductive layer as a release agent additive, silicones such as silicone oil, silicone grease, silicone resins or silicone rubber contains. 3. Cable according to claim 1, characterized in that the outer conductive layer contains polyols with a molecular weight> 500 as a release agent additive. 4. Cable according to claim 1 or 3, characterized in that the outer Conductive layer contains polyethylene glycol as a separating agent additive. 5. Cable according to claim 1, characterized in that the outer conductive layer contains ether as a separating agent additive with a boiling point of 2000 C or above. 6. Cable according to claim 1 or 5, characterized in that the outer Contains conductive layer as a release agent dibenzyl ether and / or its derivatives. 7. Cable according to claim 1, characterized. dan the outer conductive layer contains aldehydes as a separating agent, the affect the rate of peroxidic crosslinking. 8. Cable according to claim 1 or 7, characterized in that the da.3 outer conductive layer contains tetrahydrobelzaldehyde derivatives as a separating agent. 9. Cable according to claim 1, characterized cxekennzeich-.et that the outer Conductive layer as a separating agent, waxy 1-phatic hydrocarbons such as paraffin oil, Contains paraffin wax, polyethylene wax. 10. Cable according to claim 1, characterized. then the outer conductive layer acts as a separating agent, liquid, highly aromatic Hydrocarbons and their mixtures such as tetrahydronaphthalene and / or mixtures contains on a naphthalene / anthracene / phenantrene basis. 11. A method for producing a cable according to any one of the claims 1 to 10, characterized in that an inner conductive layer on the conductor, the Plastic insulation and the outer conductive layer with known triple extrusion are applied simultaneously. 12. The method according to claim 11, characterized1 that on the Conductor an inner conductive layer, the plastic insulation and the outer conductive layer simultaneously applied and crosslinked (co-vulcanized will. 13. Mixture for the production of the outer conductive layer electrical Cable with plastic insulation according to one of Claims 1 to 10, characterized. that they have a larger proportion of polyethylene, copolymers of ethylene, chlorosulfonated polyethylene, butadiene-styrene rubber and / or natural rubber or mixtures thereof, in amounts of 15 - 50 X conductive carbon black and in amounts of 0.1 - 30 percent by weight release agent based on silicones, polyols, ethers, Contains aldehydes, waxy aliphatic hydrocarbons or mixtures thereof. 14. Mixture according to claim 13, characterized. that they add the release agent in amounts of 0.5-20 percent by weight contains. 15. Mixture according to claim 13 or 14, characterized * that the release agent additives are compounded into the base material prior to extrusion or are superficially admixed. 16. Mixture according to claim 13 or 14, characterized in that the release agent additives are metered into the extruder during the extrusion.