SE516721C2 - Gas and oil free power cable termination for e.g. signal boxes or high voltage networks, contains insulator body pressed against resin impregnated capacitor body by spring fitting - Google Patents

Abstract

The capacitor body (9) is impregnated with a curable resin and the termination (1) also includes an insulator body (10) pressed against the capacitor body by a spring fitting (11). A cable termination for a power cable (2) insulated with solid insulation material comprises a capacitor body surrounding the cable conductors (4), the body comprising alternate electrically insulating layers and conductive capacitor layers (14). The capacitor body is impregnated with a curable resin and the termination also includes an insulator body pressed against the capacitor body by a spring fitting. An Independent claim is also included for the method of making the cable termination.

Description

15 20 25 30 35 516 721 2 destroy the cable termination and the insulation of the power cable, as ozone chemically decomposes organic compounds.

The electric field can in principle be controlled in three ways in a power cable termination, namely resistive, geometric and capacitive. f Resistive field control is based on a resistive control layer being applied to the insulation of the cable at the cable end and that a capacitive current flows in the control layer from the cable conductor to the semiconductor layer. The capacitive current gives a resistive voltage drop in the control layer, which means that the electric field at the cable end is distributed in a way that is advantageous from a slab strength point of view. The method is mainly used for alternating current, but due to power losses in the control layer it is not usually used at voltages above 36 kV.

Geometric field control is based on an insulating body, with a dielectric number in the same order of magnitude as the dielectric number of the cable insulation, being applied to the insulation of the cable.

The insulating body has an outer semiconducting layer which is connected to the semiconducting layer of the cable. as a thickening of the cable insulation and by designing the insulating body can be seen "the insulating body in the right way, the electric field strength on the surface of the insulating body so that the air (or capacitor - electrical strength is not exceeded.

(EPDM) oil) The insulating body is usually made of ethylene propylene or silicone rubber.

To further increase the electrical strength of the cable termination, the cable end can be enclosed with an insulating gas, e.g. SFV In capacitive field control, one or more capacitor coatings in a capacitor body are concentrically arranged around the conductor of the cable or cable termination. By adjusting the number of capacitor coatings, their lengths and their location in the cable termination, the electric field can be distributed so that the electric field strength is kept down. 10 15 20 25 30 35 516 721 3 A common way today to achieve a capacitor body is to wrap paper and metal foil alternately around a mandrel.

The paper and metal foil package is then impregnated, under heat and negative pressure, with oil.

However, there are a number of disadvantages to a cable termination of the above type. Firstly, the presence of oil means that there is a risk of leakage, both at the manufacturing stage and when using the cable termination. Secondly, the manufacturing process means that it is difficult to prefabricate the cable termination as the impregnation step in most cases requires that the cable termination is built around the cable at the place where the cable termination is to be used, e.g. in a switchgear.

Thirdly, an impregnation in the field means that it is very difficult to disassemble and reassemble the cable termination if necessary.

For gas-filled cable terminations, there is also the risk of leakage. As the reduced pressure of the gas drastically reduces the electrical strength of the cable termination, gas-filled cable terminations must be equipped with density monitors that monitor the gas pressure.

DISCLOSURE OF THE INVENTION According to a first aspect, the object of the invention is to provide a gas- and oil-free cable termination which connects a power cable with fixed insulation to another electrical component, e.g. an air-insulated conductor or a transformer. Electrical contact must be obtained between the conductor of the power cable and the electrical component at the same time as feeds. the cable termination has a good electrical strength.

The cable termination must also be possible to prefabricate and allow a quick and easy installation at the installation site. 10 15 20 25 30 35 516 721 4 The cable termination must also be possible to quickly and easily disassemble and reassemble.

According to a second aspect, the object of the invention is to provide a method for manufacturing a cable termination according to the first aspect of the invention.

The above-mentioned object according to the first aspect of the invention is achieved with a cable termination comprising a capacitor body arranged around the conductor of the termination of the cable termination, which comprises alternating electrically insulating layer and conductive capacitor layer, characterized in that the capacitor body is further impregnated with a curable resin. comprises an insulating body and a spring device which presses the insulating body against the capacitor body.

When the capacitor body is impregnated with a curable resin, the capacitor body, once the resin has hardened, becomes a solid and hard body that can be easily integrated in a prefabricated cable termination which can thus be quickly and easily mounted on the assembly site. The hardened capacitor body also enables the cable termination to be quickly and easily disassembled and reassembled.

Because the capacitor body is impregnated with resin, the electrical strength required for a cable termination for power cables is obtained without the need for gas or oil. As the condenser body and the cable termination are free of oil, the environmental impact of the oil is thus avoided by eliminating the risk of oil leakage and the need for the density monitors that monitor the gas pressure in gas-filled cable terminations are also eliminated.

According to an embodiment of the invention, the cable termination comprises an insulating body according to known technology in addition to the capacitor body, which further increases the electrical strength of the cable termination. According to a further embodiment of the invention, a spring device presses the insulating body against the condenser body so that no air pockets can arise between the insulating body and the condenser body.

The present invention relates to technology for high voltage bushings previously known from PCT application SE97 / 00677 in which a method for manufacturing a resin impregnated bushing body is described. According to the method, a fabric of insulating material is wound, such as e.g. paper, around a mandrel. A mold is then formed by a flexible shell, e.g. tape, the insulating fabric wrapped around the mandrel is applied.

Curable resin is added to the mold, after which the bushing body is cured in the mold. A cable termination according to the invention may advantageously comprise a capacitor body which is manufactured according to the method above with the addition that conductive capacitor layers are alternated with the insulating material. The steps in a suitable method for manufacturing a capacitor body included in a cable termination according to the invention are then - that an insulating fabric and a conductive foil are alternately wound on a mandrel so that insulated layers and conductive capacitor layers are formed, - that a mold is applied around them on the mandrel wound layers and - that curable resin is added to the mold, after which the capacitor body is cured in the mold.

The mold applied to the wound layers can be solid or flexible. Examples of materials in a suitable solid mold are metal or hard plastic. Suitable flexible molds can be provided by wrapping strips of tape or paper around the insulated and conductive layers. A further example of a flexible material in a suitable flexible mold is a polymer insulator. A capacitor body included in a cable termination according to the invention can of course also be manufactured according to other suitable methods.

DESCRIPTION OF THE FIGURES The invention will be explained in more detail by describing two embodiments with reference to the accompanying figures, where figure 1 shows a cable termination according to the invention as connected a power cable to an air-insulated line, and figure 2 shows a cable termination according to the invention connecting a power cable to a transformer.

DESCRIPTION OF EMBODIMENTS Figure 1 shows a partially cut-away view of a cable termination according to a first embodiment of the invention. The cable termination 1 connects a power cable 2 with fixed insulation to an overhead line 3, the conductor 4 of the power cable being in electrical contact with the overhead line 3 via a contact 5, a line pipe 6, a connecting flange 7 and a connecting slack 8.

The cable termination comprises a capacitor body 9 and an insulating body 10 which have the task of distributing the electric field in such a way that the electric field strength is maintained at such a level that the electrical strength of the cable termination 1 is not exceeded. Important in this context is that there are no air pockets between the conduit 6 and the capacitor body 9 or between the capacitor body 9 and the insulator body 10. A spring device 11 presses the insulator body 10 against the capacitor body 9 so that no air pockets can arise between the insulator body 10 and the capacitor body 9. for example porcelain or any polymeric material, is arranged around the capacitor body 9 and prevents, together with the connecting flange 7 and a cover 13, moisture from penetrating into the cable termination 1. The insulator 12 also provides the cable termination with a required electrical creep distance. between the connecting flange 7, which in normal operation is energized, and the cover 13, which has earth potential.

The capacitor body 9 comprises layers of an insulating material interspersed with capacitor layers 14, which are arranged concentrically around the conduit 6. In Figure 1, six capacitor layers 14 are visible. Said layers are impregnated with a curable resin. The insulating material is preferably paper and the capacitor layers preferably consist of some metal foil, for example aluminum foil. The curable resin is preferably some form of epoxy resin to which a hardener is added in the manufacture of the condenser body 9 so that the condenser body 9 after curing is cured and solid.

In Figure 1, the capacitor layers 14 are six in number and they are arranged offset in relation to each other. In general, the capacitor layers must be arranged in the capacitor body so that no glare occurs during any of the operating conditions for which the cable termination is dimensioned. The material in which the capacitor layers are made, the capacitor layers' location in the capacitor body, the number of capacitor layers, their mutual location and size and the geometry of the capacitor body can then vary between cable terminations designed for different voltage levels.

Figure 2 shows a partially cut-away view of a cable termination 1 according to a second embodiment of the invention. The cable termination 1 connects a power cable 2 with fixed insulation to a winding terminal of a transformer (not shown). In this case, the conductor 4 of the power cable is in electrical contact with the winding socket via a contact 5, connecting slack 8. As in Figure 1, the cable termination includes a conduit 6, a connecting flange 7 and a connection 1 a capacitor body 9 and an insulating body 10. Cable 516 721 8 the terminal 1 is attached to the tank 15 surrounding the transformer.

As in Figure 1, the capacitor body 9 comprises layers of an insulating material interspersed with electrically conductive capacitor layers 14 concentrically arranged around the conduit 6, said layers being impregnated with a curable resin.

Claims (5)

516 721 PATENT CLAIMS Cable termination (1) for a power cable (2) insulated with a solid insulating material, comprising a capacitor body (9) arranged around the conductor (4) of the power cable, which comprises alternating electrically insulating layer and conductive capacitor layer (14), characterized in that the capacitor body (1) is impregnated with a curable resin and that the cable termination (1) further comprises an insulating body (10) and a spring device (11) which presses the insulating body (10) against the capacitor body (9). Cable termination (1) according to claim 1, characterized in that the insulating layers comprise paper and that the conductive capacitor layers (14) comprise aluminum foil. Cable termination (1) according to Claim 1 or 2, characterized in that the curable resin is an epoxy resin. A method of manufacturing a cable termination (1), drawn by the magma, - that an insulating fabric and a conductive foil are alternately wound on a mandrel so that electrically insulated layers and conductive capacitor layers (14) are formed, - that a mold is applied around the layers wound on the mandrel, and - that hardenable resin is supplied to the mold, after which the capacitor body (9) is hardened in the mold. Use of a cable termination (1) according to any one of claims 1-4 or a method according to claim 5 in a switchgear or high voltage network.