FI68477B - HOEGSPAENNINGSKABEL MED SYNTETISK ISOLERING OCH HALVLEDANDE SKKT - Google Patents

Description

TRI Ml KUULUTUSJULKAISU 68477 l J 'PUBLICATION C C MSI f'atenttl oyonnctty 10 09 1985 Patent subdivided ^^ (\) 51 Quarterly * / lnt.CI. * tenttlh * chemus - Patent search 750213 (22) Hakemispäivä - Application day 2δ 01 75 (H) (23) Alkupäivä - Validity day 28,01 .75 (41) Tullut julkiseksi - White public Q1 gg

Patentti- ja rekisterihallitus / 44) Nähtäväkslpanon ja kuuLjulkaisun pvm. -,. ης ος

The Patent and Registration Board 'Application filed and the extradition published ^. up.op (32) (33) (31) Pyydetty etuoikeus — Begird Priority 31 * 01. 74

Ruotsi-Sweden (SE) 7 * 01244-4 (71) 0 / Y L M Ericsson A / B, 02420 Jorvas, Suomi-Fin 1 and (FI) (72) Mats Gunnar 01 sson, Stockholm, Carl Ove Tollerz, Stockholm,

Sven Gunnar Wretemark, Stockholm, Ruotsi-Sweden (SE) (74) Oy Kolster Ab (54) High voltage cable with synthetic insulation and semiconducting layers -

The present invention relates to a high voltage cable with synthetic insulation and with an external pd this semiconductor layer is applied. More specifically, a high voltage cable is referred to in which this so-called outer semiconducting layer is given a definite conductivity. In a typical high voltage cable, an inner semiconductor band or layer is wound or wound around the metal conductor, and an insulating layer is sprayed over this inner layer. A word shielding element is applied concentrically thereon over the insulation, which element usually consists of a semiconducting layer and a metal conductive shield, whereby a uniform equipotential surface around the insulation has been formed. Further study of the current conditions in the layers shows that the outer semiconducting layer a capacitive current across the layer in radial direction from the conductor to the surrounding screen; waveguides in such a resistive current, so equalize voltages which due to any uneven field distribution occur in the peripheral direction Pd the metallic shield adjacent half the surface may be adjacent to the surface. the surrounding cable sheath be applied.

For synthetic cables, ie cables with any form of extruded plastic or rubber insulation are usually applied to the inner semiconductor in the same operation as the insulation. It has been found to be advantageous to also place the outer semiconductor in the same operation, whereby triplet extrusion is mentioned. Semiconductor layers and insulating materials adhere well together to provide a mechanically and electrically reliable product. Triple extrusion has mainly come into use at the highest voltages and otherwise where specially trained installation personnel are used. One problem with high voltage cables of the prior art is that it is possible to prepare the cable for assembly, work. The preparation involves removing parts of the cable man, the shielded layers and the insulation to be able to connect the conductor. In known cable designs, in order to facilitate the preparation of the cable, the outer semiconductor has been manufactured as strip directly laid on the insulation or as a layer painted or sprayed outside the insulation, as well as conductive strips outside the painted layer. It is also known to spray a hose of e.g. semiconducting rubber, which infects To the insulation. The disadvantage of these known measures is mainly that gliding can occur in the air gaps formed by the overlap of the conductive strips. Releases can occur between loosely applied, selective layers and the insulation of mechanical and thermal stresses. The semi-conductive paint can be difficult to remove, especially if it is burnt to the substrate in connection with overheating. At the ends of the cable, where the semiconductor must be removed at a certain distance from the connection point, according to the methods used, the high edge strength of the screen edge, which arises, is known to be reduced. which layers extend a distance from the screen edge to the conductor. Hereby, part of the cable's capacitive ground closure current flows through the resistive layer and provides a widespread potential flow, which lowers the field strength and prevents gliding in the air. Other field strength designed methods are also known. Methods used require special material or special accessories, professional skill of the installer and time-consuming work. Particularly troublesome is the removal of all residues of the semiconducting layer, especially as this more or less adheres to the insulating surface. Therefore, the endeavor has been to produce semi-conductive layers which can be easily separated from the insulating surface without leaving any residue. However, the easier the scalable semiconductor is, the greater the risk of injury in case of stress.

The object of the present invention is to provide a cable, attended by one or several conductor cable assemblies, each comprising an outer semiconducting layer of good electrical and mechanical stability, which also eliminates the present disadvantages of connection. of the cable. The invention is characterized in this way as it is stated by the features of the following claims.

The invention and its advantages will be described in more detail with reference to the accompanying drawing, in which Figure 1 shows the appearance of a cable according to the present invention. Figure 2 shows in diagram the voltage gradient at the termination of a cable according to the invention. The description of the invention in the following relates to single conductor cables but is essentially applicable to individual parties in multi conductor cables.

In the cable according to figure 1, 1 is denoted by the inner conductor, consisting of, for example, twisted and packed wires. Without this, an inner semiconducting layer 2 is applied in the form of semiconductor strips or extruded semiconductor material for equalizing voltage stresses from the individual trees of the inner conductor. 3 denotes the insulation, which consists of e.g. polyethylene material and with a thickness determined by the rated voltage of the cable. Surface. the insulation 3 is an outer semiconducting layer k applied, usually by injection molding and subsequent vulcanization. In cables of known kind, the surface resistance, measured longitudinally along the outer surface of the cable part, is at this position and at most about 10 ohms / square. Hereby a field image is obtained in the cable, which exhibits smudge. stress gradients in tangential joints even at frequencies higher than the mains frequency, for example in transient processes (flashbacks and the like). However, calculations show that the surface resistivity of the layer can be significantly increased in addition to the practical values of 2 hours, 10 to 10 ohms / square with maintained operational reliability. According to the invention, a value greater than 10 µm / square is selected, for example 7 'ohm / square. Thereby, the advantages of the layer are substantially retained as filament-smoothed resistance, but some additional advantages will be obtained at the termination of the cable, as will be further described in connection with Figure 2.

The high ohmic semiconducting layer may also consist in known cable designs of, for example, a layer of polyethylene material containing additives of koi, for example carbon black, to obtain the desired resistivity. Consequently, the layer is suitably applied by extrusion and preferably triple extrusion, which provides the best electrical and mechanical stability. It is also possible to apply the outer semiconductor by continuous coating with a high-ohmic varnish layer in principle in the same way as is currently applied to low-ohmic layers. For example, the layer can be applied by spraying, dipping or by electrostatic coating. As a result, good adhesion to the insulating layer underneath 1 can be achieved. The extruded outer semiconductor according to the invention may be of the type of elastomeric, thermosetting, or crosslinked plastics (vulcanized), which, in the manufacturing process, can also be fully adhered to the insulating surface, thereby avoiding the risk of any glare. In some cases, the high ohmic semiconducting layer 3 may be supplemented by an outer layer of conductive plastic, paper * textile, synthetic fiber or similar resistivity values of conventional size. The end enamel of the invention has hereby not been fringed, since this outer material can be very easily removed during preparation in connection with the termination of the cable.

In Figure 2, the voltage distribution is shown along a cable termination to illustrate the advantage of the invention. The cable termination is shown in a longitudinal section, and, as in Figure 1, is indicated by 1 inner conductor, to which the inner semiconducting layer 2 is applied. In the insulation 3, the outer semiconducting layer h lies, and in order to divert the field currents to earth, in known manner, an earthed metallic shield 6, for example of copper wire, is applied. Below this, as mentioned, an additional semiconducting layer 5 may lie. With UQ, the potential of the conductor, for example 12 / | / 3 ~ or 24 / | / 3kV, is denoted, whereby the shield has the potential 0. At the end of the cable the grounded shield and the semiconductor are removed. the layer 5, in that an end portion length 1 of the outer semiconducting layer 3 is exposed. Further, a portion of the inner semiconducting layer and insulation have been removed so that the conductor 1 is exposed at the cable end. The outer semiconductor layer is brought into electrical contact with the conductor at the free end of the cable, for example, by plating nigra layers of semiconductor tape 8. Of interest, the voltage distribution that occurs in the outer semiconductor layer is in the distance between the shield 6 and the inner conductor 1. At too high a voltage gradient. undesirable glare arises in the voltage tests prescribed by the norms. The side gliding occurs in conventional cable designs at the screen edge, ie. the edge formed in the insulation of the cable is released from conductive surface coating, unless special itineraries are taken.

With a cable construction according to the present invention, this coating is not removed, i.e. the outer semiconducting layer k, without this being maintained and thereby fulfilling its function of equalizing the longitudinal field between the outer shield 6 and the inner conductor 1. The diagram shows that by means of a semiconducting layer whose resistivity is selected according to the inventive idea, an even voltage distribution along the exposed cable length is obtained with 1. The curves in the diagram are shown for different values p in the resistivity of the outer half conductive layer, and for a certain value <\ = 10 'ohm / square, an approximately linear voltage distribution can be obtained. Mad a layer of lower resistivity, ie around the values of 10 ^ - 10 ohms / square of acreage, too much power generation is obtained in the semiconducting layer with fire as a result. In practice, concentrated creep stream stretches and surface estimates increase due to the fact that such a semiconducting layer is not belt homogeneous.

Claims (3)

6 Patent Claims: 68477 An electrical cable comprising a conductor (1) and an insulating material (3) enclosing said synthetic material and an outer layer (4) of semiconducting material arranged on the surface of the insulation, the outer semiconducting layer being preferably synthetic. material and that the electrical surface resistivity of the layer measured along its outer surface is substantially voltage independent and exceeds the value of 10 ohms / square, characterized in that the aforementioned semiconducting layer (4) is intended to be left on the insulating layer at the junction points of the cable. (3) to prevent gleaming at the edge of the proximity of the intersection point peeled off grounded metallic shield. 2. A cable according to claim 1, characterized in that the semiconducting layer (4) is applied to the surface of the insulation (3) by continuous extrusion. Cable according to claim 1, characterized in that the semiconducting layer (4) is applied to the surface of the insulation (3) by continuous coating, for example by spraying, dipping or electrostatic peeling.