FR2498022A1 - Dry insulation jointing technique for high tension cables - uses silicone and polymer insulating materials to seal and electrically insulated cable joints using conventional conductor jointing - Google Patents

Abstract

The ends of the cables are stripped back to the conductor strands which are jointed by soldering or a similar technique. The base conductor is covered by a two-piece aluminium or copper cylinder having an outer dia. slightly larger than that of the cable insulation. A preformed sleeve is then wrapped over the cylinder, overlapping onto the cable insulation. The sleeve is mfd. from a carbon impregnated silicone or rubber material which is electrically conductive. Silicone insulators taper away from the joint providing end sealing, and field deflecting end caps are installed over the ends of the tapered insulators. A polymer material is moulded around the space over the joint between the end insulators. The cable jointing procedure provides a reliable joint for high and extra high tension power cables. The insulation of the joint uses dry insulating materials for greater reliability at high and extra high voltages.

Description

 The present invention relates to improvements to the junctions of insulated electrical conductors and, more particularly, to a method of making junctions of dry insulated electric cables for high and very high voltage energy networks.

 The joining of dry insulated power cables for high voltages poses essentially problems with regard to the reconstitution of the insulator at the junction of the two cores or strands of junctioned cable. The techniques currently used resort to the reconstitution of the insulation by injection molding, by rubSgJ6e or by assembly of prefabricated elements. The reconstruction of the insulation by injection molding has drawbacks due to the complexity of implementation involving a specially qualified workforce, to the need to have and use material important in volume and investment, and also in the long duration of realization. The reconstitution of the insulation by taping is faster than the previous one but also presents its own drawbacks holding, in particular, the preparation of the cable heads, the uncertainty of reliability and reproducibility due to the fact that the electrical quality of the rod tion depends for large measures on the regularity of the necessary constant of the mechanical tension exerted manually by the meter on the tape, and, economically, the difficulties of supplying electrical tapes whose dimensional characteristics and physical properties and Like the other technique mentioned above, the taping process also requires the use of skilled labor. On the other hand, the electrical under-voltage resistance characteristics, although good, are notably lower than the reconstruction of the insulation by molding and injection. Finally, in the case of joining cables with cross-linked insulation, the material of the tapes used must generally be itself cross-linked, either original or by means of a crosslinking operation by heating under pressure after the insulation has been reconstituted, this operation also requiring the use of a significant material in terms of volume and investment. The reconstruction of the insulation by assembling prefabricated components offers, compared to the techniques mentioned above, the advantage of being faster and allowing factory control of the prefabricated elements. .But this technique also has drawbacks relating, in particular, to the number and the complexity of the prefabricated elements of the existing assembly devices in the embodiment of the entralné junction by the need to ensure perfect positioning and maintenance in contact. in the prefabricated element, without the presence of gaseous veil, in order to obtain satisfactory electrical voltage withstand characteristics.

 The object of the present invention is precisely to obviate the drawbacks of the above techniques by proposing a method of producing cable junctions offering excellent electrical characteristics, very stable in service, of rapid realization, and according to a procedure no longer presenting no complexity, implying no means or implementation of significant equipment, to allow execution in very good conditions of reliability without the presence of harmful gaseous veil.

 To do this, the method for producing a junction of electrical conductors with dry insulation according to the present invention comprises the step of fitting, by fitting, at least one elastic insulating tubular element preformed at the junction of the conductors and finishing the insulating envelope reconstituted by casting and cold forming of a composition of synthetic material normally in the fluid state and polymerizing or crosslinking under ambient conditions.

 According to another characteristic of the present invention, the reconstruction of insulation is carried out, advantageously, by the use of a series of pre-formed constituents including, in addition to the tubular insulating element unitary or in two separate parts , field deflecting elements, and a sleeve of elastic, electrically conductive material, which, associated with the use of a synthetic material normally in the fluid flowable state and polymerizable or crosslinkable cold and atmospheric pressure, allow the very rapid realization of an insulated junction with perfect electrical characteristics and without infrastructure or specific equipment in situ.

Other characteristics and advantages of the present invention will emerge from the following description of embodiments, given by way of illustration but in no way limiting, made in relation to the appended drawings, in which
FIG. 1 represents, diagrammatically, a junction produced according to the method of the invention using two pre-formed insulating blocks; and
FIG. 2 represents an alternative embodiment of the junction produced according to the method of the invention, using a single elongated tubular insulating element.

 In the figures, analogous or identical elements bear the same reference numbers, possibly indicated for reasons of clarification and distinction.

 In the figures, there are shown two butted ends of insulated electrical cables with dry insulation, the cores or strands of which are recognizable, the insulating casing 2, the end portions of which have been removed to strip the strands 1 and allow their connection, and the non-metallic conductive screen 3 surrounding the insulating envelope 2 of the cables. Connection A of the strands 1 is conventionally carried out by a process involving heat, such as by welding, or, under the conditions and ambient temperatures by a mechanical process such as by punching or by shrinking. The stripping of the ends to be joined of the strands 1 is carried out by straight sectioning of the insulating jacket 2, perpendicular to the strands. an insulating surround must be reconstructed to the right of this junction to restore the continuity of insulation between the insulating envelopes 2.

 Around the junctioned ends A of the strands 1 is firstly arranged a cylindrical metallic electrode 4, consisting of a part machined in two parts made of aluminum, copper or other alloy which is a good conductor of electricity and heat, on which is tightly fitted a pre-formed sleeve 5, of electrically conductive material having an elasticity for example of silicone rubber made conductive by adding fillers of carbon black, the sleeve 5 optionally comprising end beads 50 for a better application overflows on the end tabs opposite the insulating sheets 2.

 The insulation of the junction zone is axially delimited, in accordance with the invention, by two field deflectors 6, made of elastic electrically conductive material, for example rubber having charges of carbon black, extending each overlapped on the corresponding end of the non-metallic conductive screen of the cables. These field deflectors can, for example, be made by taping of conductive tapes or, advantageously, in the form of pre-shaped constituents with a frustoconical configuration or even by ccmbinai- sound of these two techniques.

 In the embodiment of FIG. 1, two insulating blocks of elastic material 7, having the configuration shown in the figure and having a converging frustoconical surface 8, are fitted onto the cable tapes, before their connection. made of silicone rubber, EPDM or any insulating plastic or elastomeric material compatible with the flowable finishing material, as will be seen below. In this embodiment, the field deflectors 6 can be pre formed by molding at the same time as the insulating blocks 7, thus closely adhering to them to form a unitary assembly. Similarly, while the pre-formed sleeve of elastic conductive material 5 can be produced in the form of an independent component, it can be beech in the form of two pre-formed parts at the same time as the insulating blocks 7, thus also being made integral with these. According to the invention, in the space in the form of a crown with anvil transverse profile left between the converging opposite ends 8 of the insulating blocks 7 around the conductive sleeve 5, is cast and molded, for example between two shells, a composition of synthetic material 9 polymerizing or crosslinking at room temperature and at atmospheric pressure, such as for example, an epoxy resin, a polyurethane or a polyester or, preferably, a two-component silicone elastomer. under ambient conditions, at the time of casting, a low viscosity allowing rapid, homogeneous and complete filling of the volume to be filled. The polymerization or crosslinking results either from the mixture of two or more components, or from incorporation in the base polymer of a curing agent or a catalyst, these operations being carried out immediately before the casting of the material composition. After hardening, the resulting material offers mechanical and dielectric qualities required for the perfect reconstruction of the insulation of the high voltage cable. This material adheres perfectly to the pre-formed constituents previously put in place, thus making it possible to obtain a perfectly homogeneous insulation reconstitution and without the presence of gaseous haze. To facilitate the mounting of the various preformed elements, a lubricant can also be used liquid or viscous dielectric, which also sorxes any risk of the presence of gaseous haze in the junction thus produced.

 In the embodiment of FIG. 2, a tubular element or elongated insulating sleeve 7 ′ made of elastic material identical to that of the insulating blocks 7 is placed on one of the cable heads, before their connection, the sleeve 7 ′ being brought back in final position around the elastic conductive sleeve 5 and extending well over the insulating envelopes 2 of the junctioned cables, after connection of the strands 1 and installation of the electrode 4 and of the conductive sleeve 5. Here again, the field deflectors 6 can advantageously be produced in the form of preformed constituents, by casting and crosslinking or polymerization in place under ambient conditions, by taping or by a combination of these methods. In the volume delimited by the periphery of the insulating sleeve 7 ′ and the opposite ends field deflectors 6 is cast and molded the composite of synthetic material 9 polymerizing or crosslinking under ambient conditions 8, as in the example e above.

 In either embodiment, the various elastic pre-formed components (conductive sleeve 5, field deflectors 6, insulating blocks 7 or elongated insulating sleeve 7 ′) respectively have internal diameters slightly smaller than the external diameters of the elements on which they are arranged so as to be held in place by elastic tightening during the operation of the cables. More specifically, the conductive elastic sleeve 5 has a diameter, at rest, slightly less than the external diameter of the electrode 4, the internal diameter of the insulating blocks 7 or of the elongated insulating sleeve 7 ′ is, at rest, slightly less than the external diameter of the insulating envelope 2 of the cables, while the smallest internal diameter of the field deflectors 6 is less than the external diameter of the non-metallic conductive screen 3 of the cable.

 In the foregoing description, we have limited ourselves to the aspects relating to the connection of the strands or cores of the cables and to the reconstruction of the insulating envelope proper, the reconstruction of the screens, metallic or not, and of the protection external cables being carried out according to methods similar to those normally used in the techniques currently in force and assumed here known.

 Although the present invention has been described in relation to particular embodiments, it is not limited thereto but is on the contrary liable to modifications and variants which will appear to those skilled in the art.

Claims (10)

 1 - Method for producing a junction of electrical conductors with dry insulation, comprising the steps of stripping the ends of the conductors to be joined and of reconstituting an insulating envelope at least in line with the junction of the conductors, characterized in that it comprises the steps of placing, by fitting at the junction (A), at least one pre-formed elastic insulating element (7; 7 ') and of finishing the insulating envelope reconstituted by pouring and cold forming of a composition of insulating synthetic material (9) polymerizing or crosslinking under ambient conditions.  2 - Method according to claim I, oractérisé in this tool comprises the step of setting up, on either side of the junction (A), field deflector elements (6) of electrically conductive material, axially delimiting l 'reconstituted insulating envelope.  3 - Method according to claim 2, characterized in that it comprises the steps of fitting on the insulated conductors to join preformed field deflector elements (6) of elastic elastomeric material rendered electrically conductive.  4 - Method according to any one of claims 1 to 3, characterized in that it comprises the steps of fitting, on the insulated conductors to be joined, two insulating blocks (7) made of elastic material leaving axially between them, at the junction (A) of the electrical conductors (1), an annular space into which the composition of synthetic insulating material (9) is poured.  5 - Method according to claim 3 and claim 4, characterized in that the field deflector elements (6) are pre-assembled on the insulating blocks (7).  6 - Method according to any one of claims 1 to 3, characterized in that it comprises the steps of fitting on one of the insulated conductors to join an elongated elastic insulating tubular element (7 '), to be brought back after connection conductors (1), the middle zone of this tubular element around the junction zone (A) of the conductors, and pouring the composition of synthetic insulating material (9) around this elongated tubular element.  7 - Method according to any one of the preceding claims, characterized in that it comprises the prior step of putting in place, around the joined bare areas of the electrical conductors (1), a pre-formed sleeve means (5) of elastic electrically conductive material.  8 - Method according to claim 7, characterized in that it comprises the initial step, before the introduction of the preformed sleeve means (5), to set up a cylindrical metal electrode (4) around the bare areas of the connected electrical conductors (1), in contact with them, the preformed conductive sleeve means (5) being fitted on the electrode (4) and projecting axially therefrom.  9 - Process according to any one of the preceding claims, characterized in that the composition of cast synthetic insulating material (9) is a two-component silicone elastomer.  10 - Equipment for making a junction of electrical conductors with dry insulation according to the method of claim 8, characterized in that it comprises: a metallic cylindrical electrode means (4) of internal diameter corresponding to the external diameter of the electric conductors connected (1); a sleeve means pre-formed of electrically conductive elastic material (5) of internal diameter, at rest, slightly less than the external diameter of the electrode means (4); a pair of field deflector elements (6) of elastic material, of frustoconical shape, of minimum internal diameter slightly less than the diameter of the insulating envelope (2) of the insulated conductors; at least one elastic insulating tubular element (7; 7 ') with an internal diameter slightly smaller than the external diameter of the insulating envelopes (2) of the insulated conductors; and, a composition of synthetic insulating material (9) normally in the fluid state, flowable and polymerizable or crosslinkable under ambient conditions.