DE2942925A1 - HUMIDITY PROTECTED ELECTRIC CABLE - Google Patents

Description

Cable and metal works Gutehoffnungshütte Aktiengesellschaft

ι 1706

Oct 22, 1979

Moisture protected electrical cable

The present invention relates to a moisture-proof electric plastic-insulated cable, in particular for transmission higher voltages, with a conductor or conductor cable made up of continuous individual elements.

Numerous investigations have recently been carried out in the art was carried out with the aim of apparently caused by accumulations of water ("water trees") damage in explain the insulation of electrical plastic cables and take measures to avoid this cable damage. Corresponding The number of publications describing the growth of water trees and suggestions is also high make how such phenomena which lower the life expectancy of a cable can be avoided.

All previous investigations assume that moisture gets into the insulation first. Moisture diffusion can take place once during production, for example in the process of networking through action

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from water vapor with continuous put chi through a chain line (CV system), or in the wire, for example when a metal jacket is damaged or by water vapor diffusion through the undamaged plastic jacket. Under the influence of the electric field strengths prevailing during operation, the well-known water trees are formed, the constant growth of which can ultimately lead to electrical breakdowns and ultimately to the destruction of the cable in general . Destruction in the cable can also occur because moisture, such as water, entering the cable conductor during operation leads to corrosion phenomena due to the formation of elements between conductor material and conductor smoothing, ie inner conductive layer. Aluminum ducts surrounded by soot-containing ducts are particularly susceptible here.

There have already been numerous proposals to solve the problem of preventing moisture from penetrating from the outside into the insulation. Thus metallic shields in the form of laid around the cable core Metal1 are bands also known (US-PS k, 1 ^ 5,567) such as insulation with inside-out directed diffusion gradient (DOS 27 5 ^ 4 33n) or water-absorbing layers above the insulation (DOS 27 37 108). Like one or the other solution is actually a water diffusion prevent or at least mitigate strong, · disregarded in here, however, that moisture from the inside, d. H. get into the insulation via the conductor itself and cause the damage mentioned there.

On the other hand, one has thought that electric particular individual wires built conductors cables serve as "water pipes" can be made that is responsible for the transport of moisture over the entire cable length. In order to remedy this situation that is restricting the transport of water, one has resorted to from the judge after kabeltechnik known Abstopfmethoden and these tailored tragungskabeln the sections Abstopfung of energy transfer.

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In this context, reference is made to a known method (IJAS 21 5'l 7V)), in which the stranded conductor Inner conductor of a high-voltage cable at regular intervals with a closed cross-section made of metallic "Material is provided. Line other well-known foreclosure of the Conductor provides (DOS 28 08 ^ 38), at intervals in the conductor rope To arrange plugs made of a cross-linked rubber-elastic material, wherein the axial length is small compared to the axial distance between the plugs following one another over the length. These Measures practically make a heavy hike & lengthways of the cable impossible, production-related in the conductor Moisture, including condensation, for example, is falling as before the possibility of between the tamping points in the inner Conductive layer and finally the insulation, with the high field strengths in the vicinity of the conductor being particularly preferred Weak points in the insulation and the conductive layer prevent the growth of saplings to meet.

The invention is therefore primarily based on the object to find a way to further reduce the risk of water trees forming. At the same time should be for it That can be ensured by different material combinations Possible element formations in the cable structure are avoided.

This object is achieved according to the invention in that the Conductor or the conductor rope of a closed seal

2 ^ metallic shell made of a longitudinally welded metal band, if necessary, pulled down onto the top layer of the individual elements of the conductor or conductor cable. This sheath, which at the same time the basket of the individual wires z. D. prevents a conductor in the manufacturing process, ensures that moisture from the conductor can no longer penetrate into the insulation or the inner conductive layer. The conductor is sealed over its entire length; additional work, such as removing stuffing means at the connection or connection points, no longer needs to be carried out during assembly. The sheath is advantageously pulled down onto the conductor cable, so that the conductor acts like a support for a pipe.

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It is known per se (application p53 (iO7D of 2. ^c ). 19 * t9) to manufacture the conductor of a compressed gas cable from a stranded core of aluminum wires with a seamless aluminum sheath, but this is done with the aim of equalizing the electrical load to avoid corona appearances on the surface and signs of corrosion on the stranded core. Another known procedure (GB-PS 757.7 ^) serves essentially the same purpose, in which a closed shell made of a welded metal band is obtained.

In contrast, the invention relates to those Knergi eü liert protruding bare, which have extruded layers above the conductor to compare the electrical field (conductor layers) with respect to the insulation, which, according to more recent findings, are sensitive to the action of moisture and therefore, special to ^r> when increased operating voltages are pending, /, for ensuring the expected operational safety are protected SEN mii.

In carrying out the invention, it has proven to be advantageous if the material of the closed envelope corresponds to the material of the letter or conductor cable according to position in the chemical Voltage series is the same or at least approximately the same. So one becomes useful for the l'mhii llung as a material copper choose or a suitable copper alloy if the individual elements, z. H. Individual wires of a conductor, made of copper

2 * 5 stand. On the other hand, one will look for a shell Decide if the conductor is made of aluminum or aluminum an aluminum alloy is made. Of course, they are suitable also plated wires or sheaths, for example made of aluminum and copper, if special requirements for fins, for example Material savings or weight.

Special advantages, especially with regard to the However, there are stability of the conductive cross-section and the like then, if in continuation of the inventive concept the Sheath itself pressed very tightly onto the stranded conductor cable is. This increases the risk of kinking the closed

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ORIGINAL INSPECTED

Sheath during cable production and the associated winding processes locked out. This is especially true when the Sheath itself is part of the conductor or conductor itself. The closed one At the same time, the envelope leads to an equalization of the electric field. In this context it is particularly useful if the cover replaces at least the top layer of the conductor or conductor cable. This results in a compact, mechanically stable conductor cable with good hanging and assembly properties that allow water to be transported in the longitudinal direction allows, but excludes damage to the insulation.

It should not go unmentioned that the application of the invention is not limited to concentrically structured conductor cables, but that shaped conductors stranded with one another can also be surrounded by the closed metallic shell. It is advantageous, for example, to use Λ ¹ i: minium sectors stranded with one another with larger cross-sections with the metallic shell.

It is also advantageous in a further development of the invention that the diameter of the conductor according to the invention is smaller than that of a conductor with the same resistance in multi-wire stranding. This ensures that the Cable-specific layer structure: conductive layers, insulation » Shield, sheath can be retained and the cable diameter is smaller.

Is decisive for the structure of the conductor according to the invention the ratio of the diameter d of the stranded core to the wall thickness s of the tube welded over it. The bigger that d: s ratio, the more the casing (tube) tends to buckle In the case of bends in the conductor over such diameters, those in the individual production processes as well as in the laying of cables and assembly are common. On the other hand, the shell, for example also for reasons of corrosion, made of the same material as the stranded conductor core, is the one already mentioned above Conductor structure advantageous, namely that the following applies:

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where F “is the required total across: sehni 1 i s f lahe before the head, gef

F is the cross-sectional area of the core

and F is the cross-sectional area of the envelope.

A conductor cable that is particularly suitable for copper as a conductor material is obtained when d: s = 2 ^r >. The wall thickness is then calculated in accordance with the formula when the invention is carried out

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If not copper, but aluminum is used as the conductive material, then d: s = lH and the hand thickness s accordingly

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found

For cables with higher voltages with the usual conductor structure, in the cone to equalize the electric field at the Lei teroberi'läche a conductive layer, z. B. extruded or applied in the form of ribbons. The invention makes it possible to completely dispense with such a conductive layer in special cases, so that work steps and material can be saved.

For the cases where / however either an extruded conductive layer If it is intended to be provided over the casing or if the insulation is to be extruded directly onto the casing, it can be expedient there may be bumps on the shell, for example in the form of elevations and to provide depressions so that the adhesiveness is increased will ·

The invention will be explained in more detail with reference to the embodiments shown in Figs. 1 and 2:

In a single-core high-voltage cable according to FIG. 1, the conductor 1 consists of the core 2 of stranded individual wires, made of copper, for example, and the shell, which is also made of copper 3

1 ? 0 0 1 9/0 2 1 1

demanded Gessmtqiifirsctmi t ι thus consists of the core 2 and the envelope "3 together, the envelope 3 from a longitudinal inlet formed into a pipe and longitudinally welded at the edges There is copper tape that is drawn down tightly onto the core 2 after the tube has been formed.

The inner conductive layer * t is provided above the sheath and is covered by the insulation 5. The moisture-proof conductor thus reliably protects the layers k and 5 against moisture from the inside. The outer conductive layer is denoted by 6. 7 is the usual screen, only indicated schematically here, and 8 is the dumbbell which ensures mechanical protection to the outside, for example made of a material based on polyvinyl chloride or rubber, also in flame-resistant form.

1S Tn of FIG. 2 is: a particularly cost-effective solution for, for example Sector-shaped aluminum conductor cross-sections shown. The solid molded aluminum sector ladder marked 9, di <> as a conductor in low voltage cables since that can be used without problems for many years are stranded together. About the stranded conductors, which are also made from stranded Single wires can be built up, the closed metallic one Shell 10 arranged. l'above this ladder structure then becomes the the intended use: appropriate cable structure made.

The form conductor itself can also be a so-called. Support tube or a support spiral must be roped around if current displacement must be expected with large conductor cross-sections and the core of the conductor does not contribute to the energy transport.

The closed sheath proposed according to the invention brings, for example, when using stranded segment conductors that • 30 can be obtained inexpensively, still have the advantage of that an impression of the conductive layer in the gusset between the Head elements is avoided if, for. B. crosslinkable polyethylene is extruded on as an insulating material.

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L e r s e i t e

Claims (1)

Cable and metal works Gutehο ffnungshütte Aktiengesellschaft ι 1706 Oct. 22, 1979 Pat en t to language Moisture-protected electrical plastic-insulated cable, in particular for transferring higher voltages, with a conductor or conductor cable made up of continuous individual elements, characterized in that the conductor or conductor cable is made up of a closed, dense metallic sheath consisting of a longitudinally seam-welded and possibly on the top layer of the individual elements of the conductor or conductor cable is surrounded by pulled down metal tape. 2. Cable according to claim 1, characterized in that the material of the sheath is the same or at least approximately the same as the material of the conductor or conductor cable according to position in the chemical series. 3. Cable according to claim 1 or 2, characterized in that the sheath itself is part of the conductor or conductor cable. k. Cable according to Claim 3i, characterized in that the sheath replaces at least the top layer of the conductor or conductor cable. 1 30019/021 1 . Cable according to Claim 1 or one of the following with a sheath and conductor elements made of copper, characterized in that the wall thickness of the sheath roughly corresponds to the formula is sufficient, where s is the wall thickness of the shell in mm and F _ the required overall cross-sectional area of the conductor in mm is. 6. Cable according to claim 1 or one of the following with a sheath and conductor elements made of aluminum, characterized in that the wall thickness of the sheath is approximately of the formula enough. 7. Cable according to claim 1 or one of the following, characterized in that the metallic sheath simultaneously takes on the function of the inner conductive layer. 8. A cable according to claim 1 or one of the following, characterized in that the sheath superficial unevenness for increasing the adhesion to extruded-conductive or insulating polymer materials having. 9. Cable according to one or more of claims 1 to 8, characterized in that the conductor cable located in the metallic sheath consists of three to six metallic strands stranded together. 130019/0211