SE525855C2 - Increasing conductivity of outer conductive layer of coiled insulated electric cable, by providing length direction component with high conductivity - Google Patents

Abstract

At least one length direction component (5) with a high conductivity is provided in or on the outer conductive layer (4), in order to remove capacitive current from this layer. The cable comprises at least one conductor (1) surrounded by an inner conductive layer (2), insulation (3) and an outer conductive layer. An independent claim is also included for the insulated electric cable.

Description

the conductivity of the existing materials used for conductive layers is conductivity leads to problems arising with conductivity external limited. This limited the capacitive charging currents that occur in the outer conductive layer when alternating voltage or pulsating direct voltage is applied to the cable. This leads to potential differences between parts of the outer conductive layer partly along the cable, partly between adjacent turns or layers in a coil of cable, which can lead to the layer being degraded and the cable invention can describe a breakdown. The present cable construction, which gives outer conductive layers a reinforced conductivity so that the above-mentioned problems do not arise.

Possible uses for electrical cables designed according to the invention are various forms of windings such as transformer or reactor windings, generator or motor windings or the like where several 'turns' of' one. cables are wound in external contact with each other or in the vicinity of each other and where there is difficulty in securing earth potential on the outer conductive layer.

The invention will now be described in more detail with the aid of preferred embodiments and with reference to the accompanying figure sheets.

DESCRIPTION OF THE DRAWINGS Figure 1 shows a radial cross-section of an insulated cable arranged according to the invention with reinforced conductivity by means of a metallic tree.

Figure 2 shows a radial cross-section of an insulated cable arranged according to the invention with reinforced conductivity by means of a metallic foil. lO 15 20 25 30 f 'Û' f- (\ ïfr _ - - gu u- n,. s.,, _ \ J __, x. V '1, I °.' '..' 1: »n .. 0: .. non Figure 3 shows a radial cross-section of an insulated cable arranged according to the invention with reinforced conductivity by means of two strands of extruded polymer with high conductivity.

PREFERRED EMBODIMENTS / JER Figure 1 shows a radial cross-section of an insulated electrical cable designed according to the invention. The cable has a conductor l surrounded by an inner conductive layer 2, an insulation 3 cx fl1 an outer conductive layer 4. Partially embedded in or on the surface of the outer conductive layer a metallic conductor 5 such as a metallic tree 5 is arranged and laid in. Substantially along the axial joint of the cable.

Alternatively, several metallic conductors may be provided on or in the outer conductive layer. By arranging one or more metallic conductors substantially along the axial joint of the cable on the outer layer, the electrical or conductive conductivity of the outer conductive layer can be increased.

Figure 2 shows a radial cross-section of an electric cable formed according to the invention with the four inner parts equal to the four inner parts in Figure 1, but where a metallic foil 6 has been arranged laid in or on the surface of the outer conductive layer 4 and substantially along the axial path of the cable. Alternatively, several metallic foils or strips of metal may be provided in the outer conductive layer. By arranging one or more metallic foils or bands substantially along the axial joint of the cable on or in the outer conductive layer, the electrical conductivity of the outer conductive layer can be increased.

Figure 3 shows a radial cross-section of an electric cable formed according to the invention with the four inner parts equal to the four inner parts in Figure 1, but where two extruded strands 7 of a polymeric material with high conductivity have been arranged laid in or on the surface of the outer conductive layer and laid mainly along the axial direction of the cable. Alternatively, an extruded strand of a high conductivity polymeric material may be provided on or in the outer conductive layer. By arranging one or more extruded strands of a high conductivity polymeric material substantially along the axial direction of the cable on or in the outer conductive layer, the electrical conductivity of the outer conductive layer can be increased. By adapting the conductivity to the outer layer, the voltage gradient can be phased along the axial direction of the cable. In a controlled manner, the invention is of course not limited to the embodiments described above and shown in the drawing, but may be modified within the scope of the appended claims.

Claims (1)

1. 0 15 20 25 30 r 'r ~ v' m qj i '_. V 1.. u .. v f v ..._ u 'v t, v: ._: .._ .- .u av. _03 .fl g .E .g: __ rg: s n q n o o 0 '',. uc I '' non ao oo 0 0 '2 q II' '2 z:: "° ,,' .In» o en en nu ° Method for arranging a reinforced conductivity of an outer conductive layer on a wound insulated electrical cable comprising at least one conductor enclosed by an inner conductive layer, an insulation and an outer conductive layer, characterized in that the conductivity of the outer conductive layer is increased by arranging at least one longitudinal element with high conductivity in or on the outer conductive layer to conduct capacitive currents A method according to claim 1, characterized in that the element comprises at least one metallic conductor such as a wire of a metallic material and is arranged in or on the outer conductive layer substantially along the axial joint of the cable. 1, characterized in that the element comprises at least one strip or foil of a metallic material and is arranged in or on the outer conductive layer substantially county gs cable axial joint. Method according to claim 1, characterized in that the element comprises at least one strand of extruded polymer with electrical conductivity and is arranged in or on the outer conductive layer substantially along the axial joint of the cable. Insulated electrical cable comprising at least one conductor, an inner conductive layer, an insulation and an outer conductive layer with reinforced conductivity and arranged wound up, characterized in that at least one longitudinal element (5-7) with high conductivity is arranged in or on the surface of the outer conductive layer (4). and laid substantially along the axial direction of the cable to divert capacitive currents from the outer conductive layer of the wound insulated electrical cable. Insulated electrical cable according to claim 5, characterized in that the element comprises at least one metallic conductor such as a wire (5) of a metallic material, is arranged in or on the surface of the outer conductive layer (4) and. laid in. mainly along the axial direction of the cable. Insulated electrical cable according to claim 5, characterized in that the element comprises at least one strip or foil (6) of metallic material, is arranged in or on the surface of the outer conductive layer (4) and laid substantially along the axial direction of the cable. Insulated electrical cable according to claim 5, characterized in that the element comprises at least one strand (7) of an extruded polymer with high electrical conductivity, is arranged in or on the surface of the outer conductive layer (4) and laid substantially along the axial direction of the cable.