FI72618C - Moisture protected electric cable. - Google Patents

Description

7261 8

Moisture shielded electrical cable

The present invention relates to a moisture-shielded, plastic-insulated cable intended for high voltages, with a conductor or phase conductor formed of discrete components passing through it.

Numerous studies have recently been carried out to determine the damage caused by the accumulation of water (so-called 'water tree', 'Wasserbäumchen', 'water trees') 10 in the plastic insulation of electric cables, so that such cable damage can be avoided by the measures in question. There are also many publications on the growth of ‘water tree’ and they propose measures to eliminate such phenomena that shorten the life of the cable.

15 All studies to date are based on the fact that moisture enters the insulation mainly. Moisture spreading to the cable can occur already during its manufacture, for example during the crosslinking process in the form of water vapor, by the cable as a continuous function through a chain line (CV-20 to). the metal sheath is damaged or water vapor can spread through the cable through its intact plastic sheath. Due to the electric field strengths used, these so-called 'water trees' are formed in the cable, the continuous growth of which can cause breakthroughs 25 and eventually render the cable unusable. However, the cable can also be disturbed by moisture in the condenser or penetrating it during use, such as water, causing corrosion between the conductor material and the inner conductive layer of the conductor. Aluminum conductors surrounded by carbon black-containing conductive layers are very sensitive.

Many proposals have also already been made to prevent moisture from penetrating into the insulation from outside the cable. In this connection, for example, metal strips placed around the core of the cable (U.S. Pat. No. 4,145,567) and insulations with a diffusion slope from the inside outwards are known (German patent 27 54 336), or 2 7261 8 water-absorbing layers on the insulation. (German Patent 27 37 108). Although po. the solutions actually prevent the spread of water into the cable or at least significantly reduce it, however, they do not take into account the fact that water can enter the insulation from the inside, i.e. along the conductor and cause the above-mentioned damage there.

On the other hand, it has already been thought that the phase conductors of an electric cable, especially those formed of separate strands, act as 'water lines', i.e. they can transfer moisture along the ko-10 ko length of the cable. To eliminate this, closure methods known from telecommunication cable technology have been applied to the closure of power transmission cables as parts. In this connection, reference is made to a known method (German Pat. No. 21,547,749), in which the inner conductor of a high-voltage nozzle cable formed as a braided conductor is provided at regular intervals with a closed metal material surface. Another known method of dividing a conductor into compartments (German Pat. . These measures make it impossible for moisture to pass along the cable, but the moisture in the conductor associated with its manufacture, e.g. condensate-25 water, still reaches the inner layer of the cable and 'weaknesses for growth.

Indeed, the present invention seeks primarily to find a way to further reduce the risk of such 'water trees' growing. At the same time, care is taken to ensure that the various combinations of raw materials used in the manufacture of the cable are able to avoid possible corrosion-causing element formations.

35 This is solved according to the invention by placing around the conductor or phase conductor a closed, tight 3 7261 8 metal sheath made of longitudinally welded metal strip drawn on the top layer of the separate elements, which is of the same material as the individual elements and which is itself part of the conductor or phase conductor and always replaces the top layer of at least 5 conductors or phase conductors. This cover, which also prevents, for example, the braiding of discrete strands of the phase conductor during manufacture, ensures that moisture can no longer enter the insulation or the inner conductive layer from the conductor. The cable is sealed along its entire length, so that no further work is required during installation, eg removing the plugs from the joints. The cover is preferably pulled over the phase conductor so that the conductor acts as a kind of put-support.

However, a method is already known (pat. Ch. P53697D / 2.9.1949) 15, according to which the conductor of a compressed gas cable is made of aluminum wires from a twisted core and is provided with a seamless aluminum shield. However, the purpose of this structure is only to smooth the electric field to prevent corona phenomena on the upper surface and to prevent corrosion of the twisted core. Approximately the same purpose is achieved by another method (patent 757 745), in which the multi-conductor conductors of overhead lines are provided with a closed shield made of welded metal strip.

However, the present invention relates to power transmission cables having layers molded on a conductor to equalize the electric field (s) relative to the insulation. According to the latest research, such cables are sensitive to the effects of moisture and must be protected, especially in the case of high operating voltages, in order to guarantee their reliability.

Copper or a suitable copper alloy is preferably chosen as the shielding material if the separate elements, e.g. the separate strands of the phase conductor, are copper. The aluminum shield is used again when the phase conductor is made of aluminum-35 or aluminum alloy. Po. of course, coated conductors or shields, e.g. aluminum and copper, can also be used for this purpose, provided that e.g. factors related to raw material savings or cable weight require this.

However, considerable advantages - in particular also with regard to the stability of the conductive surface 5, etc. - are obtained only when, by further developing the basic idea of the invention, the shield is pressed very tightly into a multi-stranded phase conductor.

This avoids the need for a closed cover. buckling during cable manufacture and in addition the related 10 winding functions. This is especially true when the shield is part of a conductor or phase conductor. A closed shield then equalizes the electric field. In this connection, it is very advantageous for the shield to replace at least the top layer of the conductor or phase conductor. This results in a compact, mechanically balanced phase conductor with good bending and installation properties, which allows water to move along the length of the cable, but still prevents damage to the insulation.

It should now be noted that the use of the invention is not limited to concentrically manufactured phase conductors, but that the conductors that are tensioned together can also be provided with a closed metal shield placed around them. For example, it is preferred to use interlocking aluminum sectors with a larger cross-sectional area and a metal shield.

A further advantageous feature of the invention is that the diameter of the conductor according to the invention is smaller than the diameter of a conductor of equal resistance made in a multi-strand braid, since this ensures that the layer structure required for the cable in question, i.e. conductive layers, insulation, shield and sheath, can be maintained regardless of the smaller diameter.

From the point of view of the structure of the conductor according to the invention, the ratio of the diameter d of the twisted core to the wall thickness s of the pipe welded to the core is decisive. The higher the ratio d: s the easier the cover (tube) folds when the conductor is bent to diameters when calculating the cable 5 7261 8 and when installing. Since, on the other hand, the shield is, for example, the same material as the twisted core of the conductor to prevent corrosion, it is advantageous to use the above-mentioned phase conductor structure, ninomoma, when 5 F - = F. + F., gef 1 h '. the cross-sectional area, 10 F- ^ is the cross-sectional area of the heart, and F ^ is the cross-sectional area of the cover.

When copper is used as a conductive material, a very suitable phase conductor is obtained when d: s = 25. When applying the invention, the wall strength is then calculated only s = - \ l '' gef 20 y When using aluminum instead of copper 20 as conductive material is d: s 18 and wall thickness s, respectively

IL-I

3 --A- f gef

In cables for higher voltages, which have a conventional conductor structure, a conductive layer is usually made on the upper surface of the conductor, e.g. by injection molding or in strips, to equalize the electric field. According to the invention, such a conductive layer can in some cases be dispensed with altogether, thus saving labor and material.

In cases where a conductive layer is to be injection molded onto the shield, or if the insulation is injection molded directly onto the shield, it may be advantageous to make protrusions and recesses in the surface of the shield to better adhere the injection molding material.

The invention will now be described in more detail with reference to the structural examples shown in dry sections 1 and 2.

7261 8

The single-stranded high-voltage cable shown in Fig. 1 comprises a phase conductor 1, the core 2 of which is wound from separate conductors 2 (e.g. copper wire), and also a shield 3 made of copper. The total cross-sectional area of the cable for transmitting a certain energy thus consists of a core 2 in this case, a longitudinally formed and longitudinally welded copper strip formed as a tube, which is drawn tightly on the core 2 after the tube has been shaped.

On top of the cover there is an inner conductive layer 4 and on top of it again insulation 5. Layers 4 and 5 are protected from moisture from the inside by means of a moisture barrier conductor. The outer conductive layer is denoted by reference numeral 6, and No. 7 corresponds to a conventional shield, which is now shown only as a diagram. No. 8 is a sheath that provides mechanical protection to the outside, which is, for example, made of PVC or rubber-based material, also in non-flammable form.

Figure 2 shows a very cost-effective solution for e.g. sector-shaped aluminum conductors.

20 The massive die-cast aluminum sector conductors marked 9, which have been used without difficulty as conductors for low-voltage cables for many years, are twisted together. On top of the twisted conductors, the conductors can also consist of twisted discrete wires with a closed metal-25 sleeve 10. A cable structure is then made on top of this conductor structure.

Formwork conductors can still be twisted so-called. around the support tube or spiral if, in the case of large conductor surfaces, there is a risk of current congestion on the conductor surface (the so-called 3 ° surface phenomenon) and the conductor core is not involved in energy transfer.

For example, in the case of twisted segment conductors (available preferably), the closed shield according to the invention has the further advantage that the conductive layer does not have to be pushed into the wedge part between the conductor elements when e.g. crosslinked polyethylene is injection molded as an insulating material.

Claims (6)

7261 8 Moisture-shielded, plastic-insulated electric cable, specifically for the transmission of high voltages, provided with a conductor or phase conductor (1; 9) formed of 5 through separate elements, characterized in that a closed, tight metal sheath (3; 10) is provided around the conductor or phase conductor. made of longitudinally welded metal-10 tape stretched over the top layer of the discrete elements, which is of the same material as the discrete elements and thus forms part of the conductor or phase conductor itself and replaces at least the top layer of conductor or phase conductor. A cable according to claim 1, comprising a copper sheath (3; 10) and copper conductor elements, characterized in that the wall thickness of the sheath (3; 10) corresponds approximately to the formula s = ύ f ^ st '20 wherein s is the wall thickness of the sheath in millimeters and F ^ is the total cross-section required for the conductorOta 2. .. mm: mother. Cable according to Claim 1, with an aluminum sheath (3; 10) and aluminum conductor elements, characterized in that the wall thickness of the sheath (3; 10) corresponds approximately to the formula s = JJ ^ 30 '' 1 Cable according to Claim 1 or one of the following claims, characterized in that the metal sheath (3; 10) simultaneously acts as an inner conductive layer. 8 7261 8 Cable according to Claim 1 or one of the following claims, characterized in that the surface of the sheath (3; 10) has uneven points in order to improve the adhesion between it and the injection-molded, conductive or insulating polymeric materials. Cable according to one or more of Claims 1 to 5, characterized in that the phase conductor (1; 9) in the metal sheath comprises 3 to 6 interlocking metal formwork conductors. 7261 8