EP0107530A2 - Supporting neutral conductor for an electrical conductor bundle, method of manufacturing it and device for putting it into operation - Google Patents

Abstract

The method of manufacturing the conductor bundle having a metallic core (2) formed by stranded metallic conductors (3), comprises at least a final lubricant-free drawing of these metallic conductors (3), with a view to obtaining conductors devoid of traces of lubricant, to constitute the core (2) - a laying of a non-coated tape, made of a non-sticking material, onto this core (2) to constitute a separable covering (4) and a high pressure extrusion of an insulating material onto this separable covering (4) to constitute an external sheath which, together with this separable covering, penetrates into the surface contours of this core (2). The method may comprise in addition an ovalisation of the cross-section of the core (2) and/or a laying of an anti-slip element between this core (2) and the separable covering (4). <IMAGE>

Description

The present invention relates to a neutral carrier conductor for a bundle of electrical conductors, a method of manufacturing this neutral carrier conductor, and means for implementing this method.

A bundle of insulated electrical conductors from an electricity distribution network for example frequently comprises an insulated neutral conductor acting as a carrier around which are twisted insulated phase conductors or other electrical conductors of this network, for example conductors public lighting.

The neutral carrying conductor comprises a metallic core made up of metallic wires cabled in a strand or cord, and an outer insulating sheath.

The twisted beam is stretched on poles or on the facades of buildings by means of its neutral carrying conductor. As a result, this neutral carrying conductor must have good mechanical resistance to support the weight of the other conductors of the bundle, and an outer insulating sheath having good sliding resistance on its metallic core under the effect of the weight of the other conductors. This sliding can cause either a rupture of the insulating sheath of this neutral conductor, or an untimely displacement of the other conductors of the bundle. As a neutral conductor, the neutral carrying conductor must also have an insulating sheath easily detachable from its metallic core when making a branch connection for example.

Known neutral conductors have hitherto given more or less satisfactory results in their use. The present invention makes it possible to produce an inexpensive neutral conductor for a bundle of electrical conductors, which excellently meets the characteristics of opposite characters recalled below.

It relates to a process for manufacturing this neutral carrier conductor, and to means for implementing this process.

• - un tréfilage terminal sans lubrifiant des fils métalliques qui constituent l'âme métallique du conducteur en vue d'obtenir des fils dépourvus de toute trace de lubrifiant,
• - une pose en long autour de l'âme métallique formée d'un toron de fils métalliques dépourvus de lubrifiant, câblés et soumis à un compactage, d'un ruban non tendu en matériau non collant servant de revêtement séparateur non collant à ce conducteur, et
• - une extrusion sous forte pression, autour de ce revêtement séparateur non tendu, d'un matériau électriquement isolant servant de gaine isolante extérieure, en vue de faire pénétrer ce revêtement séparateur non tendu et ce matériau isolant dans les moindres inégalités de surface de cette âme métallique.

According to the invention, the method for manufacturing a neutral carrier conductor for a bundle of electrical conductors, having a metallic core made of metallic wires, a non-sticking separating coating and an outer insulating sheath, easily detachable from this core, while having good resistance to sliding on the metallic core is characterized in that it comprises at least:

• - a final drawing without lubricant of the metallic wires which constitute the metallic core of the conductor in order to obtain wires free from any trace of lubricant,
• - a long laying around the metallic core formed of a strand of metallic wires devoid of lubricant, wired and subjected to compaction, of a non-stretched ribbon of non-sticky material serving as a separating coating not sticky to this conductor, and
• - an extrusion under high pressure, around this non-tensioned separating coating, of an electrically insulating material serving as an outer insulating sheath, in order to penetrate this non-stretched separating coating and this insulating material into the least surface unevenness of this core metallic.

• - la figure 1 représente une vue schématique en perspective d'un tronçon d'un conducteur neutre porteur selon un premier exemple de réalisation de l'invention,
• - la figure 2 représente à une autre échelle, une vue schématique d'une partie d'une installation de fabrication du conducteur de la figure 1, montrant des moyens qui, participant à la mise en oeuvre du procédé de fabrication de l'invention, assurent un compactage et une ovalisation de la section transversale de l'âme métallique de ce conducteur,
• - la figure 3 représente, à une autre échelle, une vue partielle schématique en coupe partielle d'une paire de galets à axes horizontaux d'un appareil à laminer faisant partie des moyens de compactage et d'ovalisation de la figure 2,
• - la figure 4 représente une vue partielle schématique en coupe d'une paire de galets à axes verticaux de l'appareil à laminer faisant partie des moyens de compactage et d'ovalisation de la figure 2,
• - la figure 5 représente une vue schématique en perspective d'un tronçon d'un conducteur neutre porteur selon un deuxième exemple de réalisation de l'invention.

To better understand the invention, an exemplary embodiment is described below, illustrated by the appended drawings, of which:

• FIG. 1 represents a schematic perspective view of a section of a neutral carrying conductor according to a first embodiment of the invention,
• - Figure 2 shows on another scale, a schematic view of part of a manufacturing installation of the conductor of the FIG. 1, showing means which, participating in the implementation of the manufacturing process of the invention, ensure compaction and ovalization of the cross section of the metallic core of this conductor,
• FIG. 3 represents, on another scale, a schematic partial view in partial section of a pair of rollers with horizontal axes of a rolling machine forming part of the compacting and ovalization means of FIG. 2,
• FIG. 4 represents a schematic partial sectional view of a pair of rollers with vertical axes of the rolling machine forming part of the compacting and ovalization means of FIG. 2,
• - Figure 5 shows a schematic perspective view of a section of a neutral carrier conductor according to a second embodiment of the invention.

The neutral carrying conductor 1 illustrated in FIGS. 1 and 2 comprises a metallic core 2 constituted by metallic wires 3 wired in strand or cord, a non-sticky separating coating 4, constituted by a layer of paper, and an insulating outer sheath 5.

The metal wires 3 of the core 2 consist of metal or metal alloy wires whose mechanical strength and electrical conductivity correspond to the installation and operating requirements requested. According to a first exemplary embodiment illustrated in FIG. 1, the metal core 2 comprises a compact non-circular cross section, preferably oval, formed of wires 3 individually having a bare metal surface condition, devoid of any trace of lubricant.

According to an important characteristic, the non-sticky separating coating 4 intimately follows the reliefs and the hollows of the twisted profile of the metallic core 2 and the outer insulating sheath 5 tightening the separating coating 4 against this metallic core 2, penetrates into the crevices of the inequalities surface of this core 2.

The outer insulating sheath 5 is made of a known insulating material whose mechanical and electrical characteristics correspond to the desired characteristics.

In the first exemplary embodiment illustrated, the neutral carrying conductor 1, intended to produce a twisted bundle of aluminum electrical conductors, comprises a metallic core 2 consisting of seven wires made of an aluminum alloy marketed under the designation AGS, a coating separator 4 consisting of a paper tape and an outer insulating sheath 5 in crosslinked polyethylene.

The adhesion of the outer insulating sheath 5 on the metallic core 2 of the neutral carrying conductor 1 can be measured according to French standard NFC 33209 according to which a length of sheath 5 is maintained on the metallic core 2 of a section of neutral carrying conductor 1 stripped at both ends.

This conductor section is mounted in a known manner in a known type of traction machine, so that on one side one end of its metallic core 2 is firmly held by a first jaw of this machine, and on the opposite side the length of sheath is slid over this core 2 by means of a rotary assembly pulled by a second jaw of this machine. The effort developed by the second jaw of this machine to move the length of sheath 5 over a determined distance from this metallic core 2, measures the coefficient of adhesion of this sheath 5.

In the neutral carrying conductor 1, the surface condition of the bare metal devoid of any trace of lubricant from the cabled wires 3 of the metallic core 2, the penetration of the non-sticky separating coating 4 and of the outer sheath 5 into the crevices of the inequalities surface area of the twisted profile of the metal core 2 and / or the oval shape of the cross section of this core, these factors make it possible, either individually or in cooperation with each other, to obtain a high resistance to sliding of this insulating sheath 5 on this metallic core 2 and also easy detachment of this sheath 5 outside of this metallic core 2 during a connection of a bypass on this neutral conductor 1 for example. The insulating material constituting the sheath 5 being separated by the separating coating 4 does not stick to the wires of the metallic core 2 like that in certain known neutral carrying conductors and therefore does not interfere with the electrical conductivity of this branch connection.

According to the invention, a method for producing the neutral carrying conductor 1 comprises at least one wire drawing without lubricating metallic wires 3 with a view to obtaining wires free from any trace of lubricant, laying lengthwise around the metallic core 2 formed of a strand of metal wires 3, devoid of lubricant, wired and subjected to compaction, of a non-stretched ribbon of non-sticky material chosen to constitute a separating coating 4 and an extrusion under high pressure of an insulating material serving of insulating sheath 5, on this separating coating 4 with a view to making this non-stretched separating coating and this insulating material penetrate into the least surface unevenness of this metallic core 2.

A drawing without lubricant for obtaining son 3 devoid of traces of lubricant for the constitution of the core metal 2 of the holder neutral conductor 1 is achieved by means of material in channels having a hardness greater than 9 _'wide hardness of minerals known as the Mohs scale. According to this Mohs scale, the hardened steel has a hardness equal to 6.5 and the diamond has a hardness equal to 10. In this conductor 1 an absence of trace of lubricant on the core 2 indeed greatly increases the slip resistance of the sheath 5. In addition in the conductor 1 of the first example, an oval cross section of the metallic core 2 greatly impedes the rotation and the sliding of the sheath 5 on this twisted metallic core 2 and thus increases the sliding resistance of the sheath 5 on this soul 2.

When the paper tape constituting the separating coating 4 is laid lengthwise, not stretched over the metal core 2, this tape can easily penetrate without tearing in the crevices of the surface unevenness of this core 2 under the thrust and the subsequent penetration of the insulating material constituting the sheath 5 extruded under high pressure, that is to say under pressure greater than the usual extrusion pressure in the insulation of electrical conductors .

An implantation of the material of the sheath 5 in the crevices of the surface unevenness of the metallic core 2 contributes to impeding the sliding of the sheath 5 on this core 2. When the coating 4 is not torn during extrusion under high pressure of the sheath 5, the material constituting the sheath 5 does not stick directly to the metal core 2 and the sheath 5 is easily detachable from the latter.

In known manufacturing methods, the separating coating 4 is usually placed taut on the metal core 2 and the sheath 5 is extruded under a pressure usually applied in the insulation of the electrical conductors. In this case the stretched separating coating 4 cannot match the surface unevenness of the metal core 2 and the material constituting the sheath 5 cannot penetrate into the crevices of these surface unevenness of the core 2. The sheath 5 known neutral conductors does not therefore have sufficient resistance to its sliding on the metallic core of the latter.

Extrusion under high pressure of the sheath 5 can advantageously be followed by a heat treatment under pressure which maintains, until the final stage of its production, the tightening of the sheath 5 on the metallic core 2.

An installation for the chain production of a neutral conductor carrier 1 of the first example, implementing the method of the invention mainly comprises a known type of stranding machine, a laminating device of the type with double pair of rollers, a setting device a separating coating tape, an insulation machine such as an extruder of the matrix type and punch adjustable in position, a known assembly with a tube for heat treatment of the insulating sheath 5 by pressurized steam or possible LEMENT by any other crosslinking system and a storage winder of known type. In this installation, the metal wires 3 devoid of lubricant are unwound and formed continuously in a strand or cord twisted in the stranding machine. The strand or twisted cord of wire which constitutes the metal core 2, passes through the roller laminator to receive a compaction and according to the first embodiment, an ovalization of the cross section. The twisted, compact cord with an oval cross-section passes through the separating coating installation device 4 which is in the example illustrated a paper tape, and leaves it covered with a layer of non-stretched separating paper, laid lengthwise. The cord provided with its separating coating enters the extruder to receive under pressure an insulating sheath 5. The neutral carrying conductor thus produced then crosses the tubular heat treatment assembly before being wound up at the end of the chain in the winding machine. storage.

A part of this installation is schematically illustrated in FIG. 2 showing a strand or cord 6 formed from metallic wires 3 wired and assembled by passing through a die 7 of a stranding machine 8 partially shown. The strand or cord 6 then passes through a laminating device 9 to be transformed, after compaction and ovalization of its cross section, a twisted metal core 2, of the neutral carrying conductor 1.

The laminating device 9 is a device of known type comprising two pairs of rollers tightening in their grooves the strand or cord 6: a horizontal pair of rollers 10 (Figures 2 and 4) and a vertical pair of rollers 11 (Figures 2 and 3).

In a laminating device equipping known installations for manufacturing electric cables, the grooves of the two pairs of rollers successively form circular passages for the metal core or cable subjected to compaction. As a result, the metal core or cable exiting from this rolling machine is provided with a circular cross section.

In the manufacturing installation schematically illustrated in FIG. 2, to implement the method of the invention which comprises compacting and ovalization of the cross section of the strand or cord 6 forming the metal core 2, the apparatus to laminator 9 is provided with a first pair of rollers 10, the central zone of the bottom of the grooves having the same radius of curvature 13 is connected to the lateral zones of these grooves which have radii of curvature 14 larger than these radii of curvature 13 so that the grooves of this pair of rollers 10 form an oval passage for the strand or cord 6 and of a second pair of rollers 11 whose grooves have the same radius of curvature 12 so that these grooves form a circular passage for the strand or cord 6. As a result, according to the method of the invention, the cord or strand 6 by passing through the laminator 9 of FIG. 2 is first subjected to a first compaction and a simultaneous ovalization of the section transverse under the action of the rollers of the first pair 10 then a second compacting further reducing the dimensions or diameters of the cross section while retaining ovalization, under the action of the rollers of the second pair 11.

According to an important characteristic, in the first pair of rollers 10, the difference between the spokes 13 of the central zone of the bottom of the grooves of these rollers and the larger spokes 14 of the lateral zones of these grooves is greater than or equal to 0.125 millimeter . In other words, in an example of a neutral carrying conductor 1 having an oval cross section whose small dimension or minor axis is for example 9.20 millimeters, the large dimension or major axis of this oval cross section is greater than or equal to 9, 45 millimeters.

In the extruder which forms the insulating sheath 5 on the metallic core 2 of the neutral carrying conductor 1, this metallic core 2 provided with its separating coating 4 passes first through a wire guide or punch then through a die or which are axially aligned and spaced from each other. In the extruder the insulating material is pushed through the space separating these wire guide and die to wrap the metallic core 2 which runs there.

The die gives its cylindrical reach a uniform external dimension to the insulating sheath 5 while the suitable wire guide maintains a constant concentricity of the metal core 2 and the die, therefore, a constant concentricity of the metal core 2 in the insulating sheath 5.

In the implementation of the method of the invention, a high pressure of the extrusion of the sheath 5 is obtained by an increase in the extruder of the axial spacing between the wire guide and the die and an increase in the length of the cylindrical surface of the die with respect to the usual corresponding values thereof for a usual extrusion of known cable sheaths. This dimensional increase allows easy entry of the insulating material onto the metal core 2 without disturbing the operation of the extruder.

It follows that in an example of extrusion of an insulating sheath 5 having an outside diameter of 10 to 15 millimeters, on a metallic core 2 provided with an oval cross section having a major axis of 8 to 12 millimeters the spacing between the wire guide and the extruder die is 12 to 16 millimeters and the length of the cylindrical surface of the latter's die is 13 to 17 millimeters. On the other hand, in a usual manufacture of insulated conductor, an extrusion of an insulating sheath, operated in the same extruder, the spacing between the wire guide and the die thereof is of the order of only a few millimeters and the length of the cylindrical surface of the die of this extruder is about 5 millimeters.

The neutral carrying conductor 1 produced according to the method of the invention comprises an insulating sheath 5 having excellent resistance to sliding on its metallic core 2 making it capable of correctly playing the role of a good carrying conductor for a bundle of electrical conductors, this insulating sheath 5 being easily detachable from this metallic core 2 for a bypass connection for example.

Good sliding resistance of the insulating sheath 5 on the metallic core 2 of the neutral carrying conductor 1 is corroborated by the following results of measurements carried out according to the French standard NFC 33209 mentioned in a previous paragraph.

In the case of a neutral carrier conductor 1 produced according to the first embodiment of the invention having an outer sheath 5 and a metal core 2 having an oval cross section whose major axis is equal to 9.45 millimeters and the small axis measures 9.2 millimeters, a tensile force greater than 270 Newtons is required to move this insulating sheath 5 on the metallic core 2. For a known neutral conductor having an outer sheath and a metallic core having a circular cross section, simply a pulling force of less than 130 Newtons to move this insulating sheath 5 on this metallic core 2.

According to a second exemplary embodiment, illustrated in FIG. 5, a neutral carrying conductor 1 comprises a metallic core 2 constituted by metallic wires 3 wired in strand or cord, a non-sticky separator 4 constituted by a layer of paper for example, and an insulating outer sheath 5.

The metal wires 3 of the core 2 consist of metal or metal alloy wires whose mechanical strength and electrical conductivity correspond to the installation and operating requirements requested.

The metallic core 2 comprises a circular or non-circular cross section, and the metallic wires 3 constituting it individually have a bare metal surface condition, devoid of any trace of lubricant.

In the conductor 1, the separator 4 intimately follows the reliefs and the hollows of the twisted profile of the metallic core 2 and the external insulating sheath 5 tightening the separator 4 against this metallic core 2, penetrates into the crevices of the surface unevenness of this soul 2.

As a result, this conductor 1 has good resistance to sliding of its outer insulating sheath 5 on its metallic core 2.

According to an important characteristic of this second embodiment of the invention at least one more or less flexible non-slip element 16 with a high coefficient of friction and not sticking to a metal surface is formed in the conductor 1, along the latter, between the metallic core 2 and the separator 4, with a view to further greatly increasing this sliding resistance of its outer insulating sheath 5 on this metallic core 2.

This flexible non-slip element 16 penetrates, by its internal face into the surface crevices of the metallic core 2 and by its external face into the surface unevenness of the separator 4, and clings to it so that the external insulating sheath 5, by its tightening on the separator 4 against this metallic core 2, and by its internal surface which marries the slightest surface inequalities of this separator 4 and this metallic core 2, has a high resistance to any force tending to slide it on the metallic core 2, while allowing easy detachment of these non-slip elements 16 - separator 4 - sheath 5 without leaving sticky residue on this metallic core 2 during a stripping operation of the conductor 1.

In this last example illustrated in FIG. 5, the non-slip element 16 placed non-stretched comprises a support made of natural or synthetic fibers arranged in the form of a ribbon, the faces of which are coated with a layer of a more or less flexible material. with a high coefficient of friction not sticky to a metal surface, and having a permanent deformation of its faces under the effect of the heat and the pressure of the insulating outer sheath 5 during the extrusion thereof on the core metallic 2 of the conductor 1. In addition, the material constituting the non-slip element 16 is a non-corrosive material for the metallic core 2, the separator 4 and the outer sheath 5 of the conductor 1.

Fibers constituting a support in the form of a woven or braided or non-braided ribbon of an anti-slip element 16 are for example natural or synthetic fibers such as wool, cotton, linen, silk, cellulose acetate, polyvinyl chloride, polypropylene, polyamide, polyester, polyethylene terephthalate, etc.

A material constituting a coating of the support of the non-slip element 16 in the form of a ribbon is for example a material based on or a derivative of polyvinyl alcohols, starch, animal proteins, vegetable proteins, phenoplasts, aminoplast resins, etc.

In an alternative embodiment not shown of a neutral carrying conductor, the non-slip element 16 is devoid of any support made of natural or synthetic fibers. This non-slip element 16 consists of a single layer of a more or less flexible material, identical to that described in the second example illustrated in FIG. 5, deposited between the metallic core 2 and the separator 4, along the conductor 1 The deposition of this layer of material can be carried out according to a known coating, soaking or spraying technique.

An improvement in a neutral conductor carrying a slip resistance of an insulating sheath 5 on a metal core 2 is corroborated by the results of measurements made according to the French standard NFC 33 209 on conductors with oval section, with insulating sheath outer conforming to the surface unevenness of the metallic core produced according to the first example (FIG. 1) and on conductors of equivalent dimensions with circular section, with non-slip element 16 produced according to the second example (FIG. 5).

A comparison of the measurement results recalled above shows that the conductors produced according to the second example have, compared to the conductors produced according to the first example, an increase in the sliding resistance of the sheath 5 on the metallic core 2 by a value ranging from 70 to 200 newtons.

Claims (10)

1. Method for manufacturing a neutral carrier conductor for a bundle of electrical conductors, having a metallic core (2) consisting of metallic wires (3), a non-sticky separating coating (4) and an external insulating sheath (5), easily detachable from this core (2) while having good sliding resistance over the metallic core (2), characterized in that it comprises at least - a wire drawing without lubricant of the metallic wires (3) which constitute the metallic core (2) of the conductor in order to obtain wires (3) devoid of any trace of lubricant, - a long laying around the metal core (2) formed of a strand of metal wires (3) devoid of lubricant, wired and subjected to compaction, of a non-stretched ribbon of non-sticky material serving as a separating coating not sticky (4) to this conductor, and - an extrusion under high pressure, around this non-tensioned separating coating (4), of an electrically insulating material serving as an external insulating sheath (5), in order to penetrate this non-stretched separating coating and this insulating material into the least surface unevenness of this metallic core. 2. Method according to claim 1, characterized in that it comprises in the wire drawing without lubricant of the metal wires (3) which constitute the metal core (2), a wire drawing produced with a die of material having a hardness greater than 9 in the Mohs scale of mineral hardness. 3. Method according to one of claims 1 and 2, characterized in that it comprises a preliminary shaping of the metal core (2) of the conductor in a non-circular cross section before the installation of the separating coating (4) on this soul. 4. Method according to one of claims 1 and 2, characterized in that it comprises a prior ovalization of the cross section of the metal core 2) of the conductor, before the installation of the separating coating (4) on this core. 5. Method according to one of claims 1 to 4, characterized in that it comprises a fitting between the metallic core (2) and the separating coating of at least one more or less flexible non-slip element, with a large coefficient of friction, not sticky to the metallic surface of the core (2) non-corrosive to these cores (2), separator (4) and the outer insulating sheath (5), and the inner face of which penetrates into the surface crevices of the metal core (2) and the outer face are introduced into the surface unevenness of the separator (4) to remain there following their permanent deformation under the effect of heat and extrusion pressure during the laying of the outer insulating sheath (5) of the conductor. 6. Method according to claim 5, characterized in that it comprises an installation of an anti-slip element (6) consisting of a layer of a material chosen from materials based on or derivatives of polyvinilic alcohols, starch, animal proteins, vegetable proteins, phenoplasts or aminoplast resins. 7. Method according to claim 5, characterized in that it comprises an installation of an anti-slip element (6) constituted by a non-stretched ribbon having a support of fibers chosen from natural and synthetic fibers such as wool, cotton, linen , silk, cellulose acetate, polyvinyl chloride, polypropylene, polyamide, polyester, polyethylene, terephthalate ..., faces coated with a material chosen from materials based on or derivatives of polyvinyl alcohols, starch, animal proteins , vegetable proteins, phenoplasts or aminoplast resins ... 8. Means for implementing the method of one of claims 3 and 4, comprising for the shaping of the metallic core (2) of the neutral carrying conductor (1), a laminator (9) having two pairs of rollers successively tightening in their grooves the strand or cord (6) of metallic wires (3) constituting this metallic core, and for the fitting of the outer insulating sheath (3) of this neutral carrying conductor (1) an extruder comprising a axially aligned and spaced thread guide and die, characterized in that, in the laminator (9), a first pair of rollers (10) comprises grooves having an oval passage for the cord (6) and a second pair of rollers (11) comprises grooves having a circular passage for this cord (6). 9. Means according to claim 8, characterized in that, in the first pair of rollers (10) of the rolling machine, the spokes (13) of the central zone of the bottom of the grooves of the rollers and those (14) of the lateral zones of these grooves have a difference in length greater than or equal to 0.125 millimeter. 10. Means according to claim 9, for producing a neutral carrying conductor (I) having an outer insulating sheath (5) with an outside diameter of 10 to 15 millimeters, and a metallic core (2) provided with a oval cross section having a major axis of 8 to 12 millimeters, characterized in that in the extruder, the axial spacing between the wire guide and the die is 12 to 16 millimeters, and the length of the cylindrical seat of this die is from 13 to 17 millimeters.

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