FR3140982A1 - METHOD FOR MANUFACTURING A HYDROPHILIC ELECTRICAL CONDUCTOR AND CORRESPONDING ELECTRICAL CONDUCTOR - Google Patents

Abstract

To manufacture an electrical conductor (20) comprising an outer layer (200) of wires and at least one inner layer (202) of wires, a processing step is carried out applied to at least part of the outer layer (200) and to at least part of the at least one inner layer (202). This treatment is adapted to make the outer layer (200) and the at least one inner layer (202) hydrophilic. Figure for abstract: Fig. 2

Description

METHOD FOR MANUFACTURING A HYDROPHILIC ELECTRICAL CONDUCTOR AND CORRESPONDING ELECTRICAL CONDUCTOR

The present invention relates to a method of manufacturing a hydrophilic electrical conductor and to a corresponding conductor.

The invention belongs to the field of electrical cables intended for the transport of energy and/or the transmission of data. It is particularly applicable in the field of aerial conductors.

The noise from high-voltage overhead power lines is linked to the phenomenon of ionization of the air around them. This causes sparking accompanied by an electrical crackling noise, called the corona effect.

In rainy or humid weather, the noise generated by this sparking increases, due to the fact that the water drops create a point, that is to say a thickness, on the surface of the conductor. At the end of this point, the electrical potential is higher than at the surface of the electrical conductor. This phenomenon intensifies the noise, because the sparking is more frequent and stronger on these tips.

To mitigate this phenomenon, it is known to use hydrophilic surface technologies, in order to flatten the water drops on the surface of the conductor.

However, although these surfaces are hydrophilic, there is still noise, especially when it rains, on overhead lines. Indeed, a large number of water drops are formed on the surface of the conductor by gravity, during the flow of water towards the lowest point of the conductor, which is suspended for example between two pylons.

The present invention aims to remedy the aforementioned drawbacks of the prior art.

For this purpose, the present invention proposes a method of manufacturing an electrical conductor comprising an outer layer of wires and at least one inner layer of wires, remarkable in that it comprises a processing step applied to at least part of the outer layer and on at least part of the at least one inner layer, this treatment being adapted to make the outer layer and the at least one inner layer hydrophilic.

Because the treatment is applied not only to the outer layer of wires, but also to all inner layers of conductor wires, all layers of conductor wires are made hydrophilic, allowing water to penetrate into the conductor and flowing through the interior of the conductor, instead of sliding over the exterior surface of the conductor and aggregating as droplets under the conductor. This significantly reduces the overall quantity of water drops that form on the surface of the conductor. Thus, the number of spikes is significantly reduced in the event of humidity or rain, which consequently reduces the crackling noise described above.

In a particular embodiment, the treatment step is a sandblasting step.

In a particular embodiment, the treatment step is an anodizing step.

In a particular embodiment, the treatment step is a hydrophilic product projection step.

Alternatively, the treatment step consists of applying a hydrophilic powder between the outer layer and the at least one inner layer.

All these techniques make it possible to obtain a uniform roughness on the surface of the yarns thus treated. The hydrophilicity is therefore distributed evenly over all the treated surface parts of the yarns.

In a particular embodiment, the treatment step is applied to the entire outer layer.

This improves the hydrophilicity of the outer layer.

In a particular embodiment, the treatment step is applied to the entirety of at least one interior layer.

This improves the hydrophilicity of the inner layers.

For the same purpose as that indicated above, the present invention also proposes an electrical conductor comprising an outer layer of wires and at least one inner layer of wires, remarkable in that at least part of the outer layer and at least one part of the at least one interior layer have a surface roughness obtained by a process as briefly described above.

In a particular embodiment, the conductor belongs to a high voltage overhead electrical line.

Since the special characteristics and advantages of the conductor are similar to those of the process, they are not repeated here.

Other aspects and advantages of the invention will appear on reading the detailed description below of particular embodiments, given by way of non-limiting examples, with reference to the appended drawings, in which:

is a schematic representation of a section of a hydrophilic electrical conductor of the prior art.

is a schematic representation of a section of an electrical conductor according to the present invention, in a particular embodiment.

Description of embodiment(s)

The conductor according to the present invention is an electrical conductor intended for example for the transport of energy and/or the transmission of data. For example, it is a conductor of a high-voltage overhead power line.

There shows a section of a hydrophilic conductor 10 of the prior art.

The conductor 10 comprises an outer layer 100 of wires and an inner layer 102 of wires. Only the exterior surface of the exterior layer 100, shown in thick lines in the drawing, has undergone a treatment making it hydrophilic.

When the weather is humid or when it rains, the water remains on the surface of conductor 10 because it flows only on its hydrophilic exterior surface.

By gravity, water accumulates in the lowest region of the conductor 10 section and forms a peak there. This causes a significant crackling noise as explained in the introduction.

There shows a section of a hydrophilic conductor 20 according to the present invention, in a particular embodiment.

The conductor 20 comprises an outer layer 200 of wires and at least one inner layer 202 of wires. In the non-limiting example of conductor shown, conductor 20 comprises a single interior layer 202, but it may equally well comprise several layers, which are arranged one above the other.

The method of manufacturing the conductor 20 according to the invention comprises a treatment step applied to at least part of the outer layer 200 and to at least part of the at least one inner layer 202, this treatment being adapted to make hydrophilic the outer layer 200 and the at least one inner layer 202.

As a non-limiting example, the technique used for the treatment may be a surface treatment such as sandblasting, anodizing or spraying with a hydrophilic product. However, as a variant, any other technique making it possible to make the treated parts hydrophilic could be used, whether this technique has as its principle the abrasion of the treated surface or another principle.

For example, the treatment may consist of applying a hydrophilic substance, for example in powder form, between the outer layer 200 and the at least one inner layer 202. The term "between" means that the powder is applied to the outer layer. 200 and on the at least one inner layer 202 as well as in the interstices between the outer and inner layers.

When the weather is humid or raining, water flows both over the hydrophilic surface portion of the outer layer 200 and into the interior of the conductor 20, where it is distributed over the hydrophilic surface portions of the interior layer(s) 202.

Thus, the quantity of water which could accumulate in the lowest region of the section of conductor 20 is notably reduced and no longer forms significant peaks there. The sizzling noise is therefore very reduced.

The treatment can be applied either to only part of the outer layer 200, or to its entirety.

Likewise, the treatment can be applied either to only part of the interior layer(s) 202, or to the entire layer(s).

We thus obtain the conductor 20 according to the invention, in which at least a part of the outer layer 200 and at least a part of the at least one inner layer 2020 have a surface roughness obtained by the method described above .

The conductor 20 belongs for example, but not necessarily, to a high voltage overhead power line.

Claims (9)

Method of manufacturing an electrical conductor (20) comprising an outer layer (200) of wires and at least one inner layer (202) of wires, characterized in that it comprises a processing step applied to at least part of said outer layer (200) and on at least part of said at least one inner layer (202), said treatment being adapted to make said outer layer (200) and said at least one inner layer (202) hydrophilic. Method according to claim 1, characterized in that said treatment step is a sandblasting step. Method according to claim 1, characterized in that said treatment step is an anodizing step. Method according to claim 1, characterized in that said treatment step is a hydrophilic product projection step. Method according to claim 1, characterized in that said treatment step consists of applying a hydrophilic powder between said outer layer (200) and said at least one inner layer (202). Method according to any one of the preceding claims, characterized in that said treatment step is applied to the entirety of said outer layer (200). Method according to any one of the preceding claims, characterized in that said treatment step is applied to the entirety of said at least one interior layer (202). Electrical conductor (20) comprising an outer layer (200) of wires and at least one inner layer (202) of wires, characterized in that at least part of said outer layer (200) and at least part of said at least one at least one inner layer (202) have a surface roughness obtained by a method according to any one of the preceding claims. Conductor (20) according to claim 8, characterized in that it belongs to a high voltage overhead electrical line.