NL8005670A - MOISTURIZED ELECTRIC CABLE. - Google Patents

Description

tf y * - 4 J- N.O. 29,488 -1-

Electric cable protected against moisture.

The present invention relates to a moisture-protected electrical plastic insulated cable, in particular for the transmission of high voltages, provided with a conductor or conductor strand constructed from continuous individual elements.

Numerous technical studies have recently been carried out with the aim of explaining apparently damage caused by water build-up (water trees) in the insulation of electrical plastic cables and to take measures to avoid such cable damage . Likewise, the number of publications describing the growth of the water trees and suggesting how to avoid such phenomena that reduce the life of a cable, is likewise high.

All research carried out so far assumes that moisture will first enter the insulation. A moisture diffusion can already occur during manufacture, for example during the cross-linking by the action of water vapor during the continuous passing of a chain line (central heating installation) or during operation, for example if a metal jacket is damaged or by diffusion of water vapor through the undamaged plastic jacket. Under the influence of the electric field strengths in operation, the known water trees can then be formed, which grow continuously and ultimately lead to an electrical breakdown and, in the end, to complete destruction of the cable. However, destruction of the cable can also occur if moisture, for example water, which is present in the cable guide or penetrates into the cable guide during operation, leads to corrosion due to an element formation between the conductor material and the conductor compensation, ie the internal conductor layer.

Aluminum conductors, which are surrounded by soot-containing conductor layers, are particularly vulnerable here.

Numerous proposals have already been made to solve the problem of preventing the penetration of moisture from outside to inside the insulation. For example, metal shields in the form of metal bands placed around the cable core are equally known (see U.S. Patent 4,15-5,567) as insulation with diffusion traps directed from the inside out (see German Patent Application 2,754,336 laid open to public inspection. ) or water-absorbent layers on top of the insulation (see German Patent Application Laid-Open No. 2,737,108). Although one or the other solution will actually prevent a water diffusion or at least contain it strongly, it must be taken into account that moisture can also penetrate from the inside, namely 8005870 -2- through the conductor itself and there can lead to the stated damage.

On the other hand, it has already been thought that conductor strands of electrical cables 5 built up from individual wires can serve as "water conductors", that is to say they can be responsible for the transport of moisture over the entire length of the cable. In order to remedy this, that is to say to limit the water transport, use is made of the termination methods known in the telecommunication cable technology and used for the sector-wise sealing of energy transmission cables.

In this connection reference is made to the method known from German published patent application 2.154.74 * 9, wherein the inner conductor of a high-voltage cable, which is constructed as a conductor of conductors, is provided at regular intervals with a closed cross-section consisting of metallic material. In another known conductor sealing method (see German Patent Application Laid-Open No. 2,808,438) it is proposed to provide plugs of a cross-linked rubber elastic material in the conductor string at certain distances, keeping the axial length small relative to the axial distance of the consecutive plugs or seals along the length. These measures make it practically impossible to transport moisture along the cable, but moisture already present in the conductor which has entered it during manufacture, for example condensate water, still has the possibility to pass between the sealing points in the internal conductor layer and finally the insulation. the high field strength, preferably in weak places in the vicinity of the conductor in the insulation and the conductor layer, promotes the growth of the trees.

The present invention, on the other hand, is primarily based on the search for a possibility whereby the danger of the formation of water trees is further reduced. At the same time, it must then be ensured that any element formation is avoided by different material combinations in the cable construction.

According to the invention, this is solved in such a way that the conductor or the conductor strand is surrounded by a closed dense metal casing 35 of a longitudinal seam welded and optionally drawn over the top layer of the individual elements of the conductor or the conductor strand. This sheath, which at the same time prevents deviations in the position of the individual wires of, for example, a conductor strand during the manufacturing process, ensures that moisture can no longer flow from the conductor into the insulation or the internal conductive layer 800 -5870 W 4-3. intruder ». The conductor is sealed over its entire length and no additional work needs to be carried out during the mounting, such as the removal of blocking means at the connection points or connection points. The sheath is preferably pulled over the conductor string 5 so that the conductor acts as a support for a tube.

Although it is known per se, see German patent application p53697D of September 2, 1949, the conductor of a compressed gas cable to be manufactured from a core of twisted aluminum wires with a seamless bushing of aluminum, but this for the purpose of the electric field. in order to avoid corona phenomena on the surfaces as well as corrosion phenomena on the core strand. Essentially serving the same purpose is a further method known from British Patent 757,745, in which overhead lines consist of a closed envelope made of welded metal strip.

The invention, on the other hand, relates to energy transmission cables, which are provided above the conductor with extruded layers to equalize the electric field (conductive layers) with respect to the insulation, * which according to the latest discoveries are sensitive to the action of moisture and therefore, especially when using high operating voltages, in order to maintain expected operational safety, must be protected.

In the present invention, it has been found to be advantageous if the material of the closed enclosure is equal or at least approximately equal to the material of the conductor or conductor strand in position in the chemical stress series. For example, the material chosen will preferably be copper, or a suitable copper alloy, if the individual elements, i.e. the individual wires of a conductor strand, are copper. On the other hand, aluminum will be chosen if the conductor strand consists of aluminum or of an aluminum alloy.

Of course, also suitable are plated wires or sheaths, for instance of aluminum and copper, if there is a special need for this, for example to save material or in connection with the weight.

Particular advantages, also with regard to the stability of the conductor cross-section and the like, are however obtained when, according to a further development of the inventive idea, the casing itself is pressed or pressed very close to the multi-strand conductor strand. This eliminates the kinking risk of the closed enclosure during manufacture of the cable and the associated winding processes. This is especially true if the sheath itself forms part of the conductor or conductor strand. The closed envelope simultaneously produces an equalization of the electric field. In this context, it is of particular use if the sheath replaces at least the top layers of the conductors or the conductor strand. A compact and mechanically stable conductor strand with good bending properties and mounting properties is hereby obtained, which permits longitudinal water transport but excludes damage to the insulation.

It should not be forgotten that the application of the invention is not limited to concentrically constructed conductor strands, but that molded conductors can also be encircled with closed metal envelopes. It is advantageous, for example, to use larger-cross-section aluminum sectors with the metal casing, which are wrapped around each other.

In a further development of the invention it is advantageous if the diameter of the conductor according to the invention is smaller than that of a conductor with equal resistance and consisting of a strand of several wires. This ensures that the layer structure specific to the respective cable: conductive layers, insulation, screen, sheath, can be retained and the cable diameter is smaller.

Decisive for the construction of the conductors according to the invention is the ratio of the diameter d of the core strand to the wall thickness s of the pipe welded over it. The greater the ratio d: s, the more the sheath (tube) tends to kink when bending the conductor over diameters, which are common in the individual manufacturing processes and when laying the cable and mounting. On the other hand, because the sheath, for example also in connection with corrosion, consists of the same material as the conductor core strand, the above-mentioned conductor strand structure is advantageous, namely if:

Fgef = F1 + Fh where F f is the required cross-sectional area of the conductor 30, is the cross-sectional area of the core, and F ^ is the cross-sectional area of the sheath.

For the copper conductor material, a particularly suitable conductor strand is obtained if d: s = 25. The wall thickness is then calculated according to the present invention with the formula V

If not copper but aluminum is used as conductor material, 8005670 -5- d: s = 18 and for the wall thickness s

For cables with higher voltages with conventional conductor structure, an electrically conductive layer, for example by extrusion or in the form of tapes, is generally applied to equalize the electric field on the surface of the conductor. The invention offers the possibility to completely abandon such a conductive layer in special cases, so that certain manufacturing steps and material can be saved.

However, for those cases where either an extruded conductor layer 10 is to be applied over the enclosure, or the insulation is extruded directly onto the enclosure, it may be advantageous to apply unevenness to the enclosure, for example, in the form of elevations, so that the adhesive ability is enlarged.

The invention will now be further elucidated with reference to the drawing, of which figures 1 and 2 show exemplary embodiments.

In the case of a single-core high-voltage cable according to Fig. 1, the conductor strand 1 consists of the core 2 of twisted individual wires, for example made of copper, and also of the sheath consisting of copper 3. The for transporting a certain amount of energy. necessary cross-section is formed from the core 2 and the casing 3 together, the casing 3 being formed from a longitudinally extending and tubular formed and edged at the edges by a longitudinally seamed copper tape, which after molding until pipe is pulled close to core 2.

The inner conductive layer 4, which is covered with the insulation 5, is applied to the enclosure. The moisture-proof conductor therefore protects the layers 4 and 5 against moisture from the inside. 6 denotes the external conductor layer and 7 denotes the usual shielding, which is only shown schematically here, while 8 denotes the jacket, which provides an outward mechanical protection, which jacket may for instance consist of polyvinyl chloride-based material. or rubber, while other flame-retardant materials can also be used.

Fig. 2 shows a special cost-saving solution for, for example, 35 sector-shaped aluminum conductor cross sections. The solid aluminum conductors, pressed in desired shape, indicated by 9, which have been used as conductors for low-voltage cables for many years without problems, have been wrapped around each other. The closed metal casing 10 is arranged over these twisted conductors, which can also be built up as individual strands twisted around each other. The further cable components necessary for the desired application are then fitted over this conductor construction.

The form guides themselves can also be guided around a so-called support tube or a support coil, if current displacement is to be taken into account for larger cross-sections and the core of the guide does not contribute to energy transport.

The closed envelope proposed according to the invention, for example, when using folded segment conductors, which are inexpensive to obtain, has the additional advantage that the pressing of the conductive layer into the grooves between the conductor elements is avoided, for example, when extruding crosslinkable polyethylene as an insulating material.

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Claims (8)

1. Moisture-protected electrical plastic-insulated cable, in particular for transmitting high voltages, provided with a conductor or conductor strand constructed from continuous individual elements, characterized in that the conductor or conductor strand is surrounded by a closed solid metal casing, which consists of a longitudinally welded metal strip and, optionally, drawn on the top layer of the individual elements of the conductor or conductor strand. 2. Cable according to claim 1, characterized in that the material of the sheath is equal or at least approximately equal to the material of the conductor or the conductor strand in position in the chemical voltage series. Cable according to claims 1 or 2, characterized in that the sheath itself forms part of the conductor or conductor strand. 15 4 ·. Cable according to claim 3, characterized in that the sheath replaces at least the top layer of the conductor or the conductor strand. Cable according to any one of the preceding claims, provided with a sheath and conductor elements of copper, characterized in that the wall thickness of the sheath satisfies the formula s = 2, where s is the wall thickness of the sheath in mm and F _ is the required cross-sectional area of the conductor in mnr. 6. Cable according to any one of the preceding claims, provided with an aluminum sheath and conductor elements, characterized in that the wall thickness of the sheath complies with the formula s-è ν / ^ Γ Cable according to any one of the preceding claims, characterized in that the metal sheath takes over the function of internal conductive layer. Cable according to any one of the preceding claims, characterized in that the casing is provided on its surface with unevenness to increase the adhesive capacity with the extruded conductive or insulating polymer materials. Cable according to any one of the preceding claims, characterized in that the conductor strand 8005370 -8- contained within the metal casing consists of three to six twisted metal forming strands. 8005870