EP0605265A1 - Arresters on varistor basis, in particular for high voltages - Google Patents

Abstract

The present invention relates to a method of manufacturing a lightening arrester, comprising the steps which consist in producing, on a stack of varistors (100), a first at least semi-rigid casing (300), having a constant external cross-section over its length, particularly compensating for the surface inequalities in the stack of varistors due to alignment offsets and to dimensional dispersions of the varistors, extruding an external casing (400) of substantially constant thickness over the first casing (300), then attaching annular fins onto the extruded outer casing. <IMAGE>

Description

The present invention relates to the field of surge arresters.

It applies in particular to surge arresters for high voltage, typically to electrical networks of nominal voltage greater than lkV effective between phases.

Surge arresters are devices designed to be connected between an electrical line, in particular medium or high voltage, and ground, to limit the amplitude and duration of the overvoltages appearing on the line.

These overvoltages can be due for example to atmospheric phenomena, such as lightning, or inductions in the conductors.

These overvoltages can also be due to operations on the live line.

Surge arresters are generally formed by stacking different varistors, most often nowadays by stacking several discs based on zinc oxide, whose electrical resistivity is highly non-linear depending on the applied voltage.

More precisely, these varistors do not let practically any current pass as long as the voltage at their terminals is less than a starting threshold and on the other hand, let pass a very strong current, which can reach several tens of kA, when the voltage applied to their terminals exceeds the aforementioned priming threshold.

The number of varistors used in the arrester is such that the nominal service voltage on the power line is less than the ignition threshold at the terminals of the varistors stack.

Thus, the arrester can permanently withstand the nominal operating voltage, without current leakage, and on the other hand makes it possible to drain the discharge currents of very high intensity which may appear temporarily on the line in the event of accidental overvoltage.

Many types of surge arresters have already been proposed.

The field of surge arresters has given rise to a very abundant literature.

• un empilement de varistances,
• deux pièces de contact en matériau électriquement conducteur placées respectivement sur les extrémités de l'empilement de varistances, et
• une enveloppe en matériau électriquement isolant entourant l'empilement de varistances.

Surge arresters known today generally include:

• a stack of varistors,
• two contact pieces of electrically conductive material placed respectively on the ends of the stack of varistors, and
• an envelope of electrically insulating material surrounding the stack of varistors.

The envelope of electrically insulating material mentioned above itself is the subject of a very abundant literature.

Document GB-A-2 073 965 has proposed, for example, to produce this envelope using a heat-shrinkable material.

Documents US-A-4,298,900, DE-A-3,001,943, DE-A-3,002,014 have proposed to place an external porcelain casing on the heat-shrinkable envelope.

Documents US-A 4,092,694 and US-A-4,100,588 have proposed to place each varistor in a silicone-based ring and to place the stack of varistors thus surrounded in a porcelain case.

Document US Pat. No. 2,050,334 has proposed placing a stack of varistors in a porcelain case and filling the space formed between the porcelain case and the stack of varistors with a filling material. formed for example of a halogenated wax-based compound.

Documents EP-A-0 008 181, EP-A-0 274 674, EP-A-0 281 245 and US-A-4 456 942 have proposed to produce the envelope surrounding the varistors using a elastomeric material, formed in particular by overmolding.

More specifically, the document EP-A-0 274 674 proposed to overmold an envelope made of a composite material based on elastomer, EPDM, silicone, or other resin, loaded or not, on a stack of varistors.

Document US-A-4,161,012 also proposed to have an elastomer envelope on the varistors. This document proposes to produce this envelope by depositing the elastomer on the external surface of the varistors, or by molding the envelope on the varistors, or else by preforming the elastomer envelope, then inserting the varistors therein. .

Document US-A-3,018,406 proposed, as early as 1958, to produce the envelope in the form of two complementary preformed shells and an external envelope of plastic material injection molded on the varistors.

Document US-A-3,586,934 has proposed making the envelope using a synthetic resin, for example based on epoxy or polyester, or even a silicone or polyester varnish.

The document EP-A-0 196 370 proposed to produce the envelope on a varistor body by pouring a synthetic resin formed for example of epoxy resin, polymer concrete, silicone resin, or an elastomer, or by covering the body of varistors with a shrinkable plastic tube, or by providing this stack with a layer of synthetic resin.

Furthermore, the documents, US-A-4 656 555, US-A-4 905 118, US-A-4 404 614, EP-A-0 304 690, EP-A-0 335 479, EP-A- 0 335 480, EP-A-0 397 163, EP-A-0 233 022, EP-A-0 443 286 and DE-A-0 898 603 proposed to produce the envelope surrounding the stack of varistors in materials composites composed of fibers, generally glass fibers impregnated with resin.

More specifically, document US-A-4 656 555 proposed to first form a winding of fibers based on plastic material, such as polyethylene, or glass, or even ceramic possibly impregnated with resin, for example l epoxy, then forming on the outside of this winding a housing made of weather-resistant polymer material, for example based on elastomeric polymers, synthetic rubber, thermoplastic elastomers, EPDM.

This document more specifically proposes either to preform the weather-resistant polymer housing, then to engage the stack of varistors provided with the winding of fibers in this housing, or to first form the winding of fibers on the stack of varistors, then make the housing of weather-resistant polymer material, by molding on the winding, projection of polymer on the winding or insertion of the stack of varistors provided with the winding in a polymer bath.

Document US-A-4,404,614 has proposed to successively place on a stack of varistors a first envelope based on glass fibers impregnated with resin, for example epoxy resin, then a second envelope based on glass flakes and epoxy resin, and finally an elastic outer covering based on EPDM rubber, or butyl rubber.

This document indicates that the first envelope, the second envelope and the external envelope can be placed successively on the stack of varistors, or the envelopes can be formed in reverse order.

This document also mentions the possibility of molding the external envelope on the second envelope based on glass flakes and epoxy resin.

The document EP-A-0 233 022 proposed to form on a stack of varistors a shell based on glass fibers reinforced with epoxy resin, then a heat-shrinkable envelope, or which can be released by equivalent mechanical means on said shell, elastomer base.

Alternatively, the envelope can be molded in situ based on synthetic resin or polymeric material.

The document states that the shell can be preformed. This document also proposes to use a sheet of prepreg fibers.

Document EP-A-0 304 690 proposes first of all making a filament winding of glass fibers impregnated with resin, then forming on the outside of the winding a coating of elastomeric material of EPDM type, by injection.

Document EP-A-0 355 479 proposes placing successively on the stack of varistors, first of all a barrier formed by a plastic film, for example based on propylene, then a winding of non-conductive filaments, and finally a weather-resistant elastomer housing.

The document EP-A-0 397 163 proposed to place successively on the stack of varistors a filament winding impregnated with resin, then to form on this winding a coating with fins, made of elastomer, for example EPDM, by injection.

The technique of using a composite material is very old.

Document DE-A-0 898 603 in fact proposed as early as 1946 to use glass fibers impregnated with resin to wrap varistors.

The surge arresters hitherto proposed have rendered great services.

However, the Applicant proposes to improve the existing surge arresters.

A main object of the present invention is to improve the reliability of existing surge arresters, in particular by avoiding any presence of air at the level of the interface (s) between the stack of varistors and the envelope which covers it. .

A more ancillary object of the present invention is to reduce the size, weight and cost of known surge arresters.

• i - empiler des varistances,
• ii - former une première enveloppe en matériau composite, sur l'empilement de varistances, et
• iii - placer une enveloppe externe à ailettes sur la première enveloppe en matériau composite,

caractérisée par le fait que:

• l'étape ii consiste à réaliser une première enveloppe au moins semi-rigide présentant une section externe constante, sur sa longueur, compensant en particulier les inégalités de surfaces de l'empilement de varistances dues aux écarts d'alignement et aux dispersions des dimensions de varistances,
• l'étape iii consiste:
  • a) tout d'abord à extruder une enveloppe extérieure sensiblement constante sur la première enveloppe,
  • b) puis à rapporter des ailettes annulaires sur l'enveloppe extérieure extrudée.

To this end, the present invention provides a method of manufacturing lightning arresters of the type comprising the steps which consist in:

• i - stack varistors,
• ii - forming a first envelope of composite material, on the stack of varistors, and
• iii - place an outer envelope with fins on the first envelope made of composite material,

characterized by the fact that:

• step ii consists in producing a first at least semi-rigid envelope having a constant external section, over its length, compensating in particular for the unevenness of the surfaces of the stack of varistors due to alignment deviations and to the dispersions of the dimensions of varistors,
• step iii consists of:
  • a) firstly to extrude a substantially constant outer envelope on the first envelope,
  • b) then to attach annular fins to the extruded outer envelope.

As will be understood later, the production of the outer envelope by extrusion makes it possible to expel any air at the interface between the first envelope of composite material and the outer envelope.

The present invention also relates to the product obtained by the implementation of this process.

• un empilement de varistances,
• une première enveloppe en matériau composite formée sur l'empilement de varistances, et
• une enveloppe externe à ailettes formée sur l'enveloppe en matériau composite.

According to the invention, the arrester obtained comprises:

• a stack of varistors,
• a first envelope of composite material formed on the stack of varistors, and
• an outer envelope with fins formed on the envelope of composite material.

• la première enveloppe formée sur l'empilement de varistances est au moins semi-rigide et présente une section externe constante sur sa longueur, afin de compenser en particulier les inégalités de surfaces de l'empilement de varistances dues aux écarts d'alignement et aux dispersions de dimensions des varistances, et
• l'enveloppe externe à ailettes comprend d'une part une enveloppe extérieure d'épaisseur sensiblement constante formée par extrusion sur la première enveloppe et des ailettes annulaires rapportées ultérieurement sur l'enveloppe extérieure extrudée.

More specifically, this arrester is characterized according to the present invention by the fact that:

• the first envelope formed on the stack of varistors is at least semi-rigid and has a constant external section along its length, in order to compensate in particular for the unevenness of the surfaces of the stack of varistors due to alignment deviations and dispersions dimensions of the varistors, and
• the outer envelope with fins comprises on the one hand an outer envelope of substantially constant thickness formed by extrusion on the first envelope and annular fins subsequently reported on the extruded outer envelope.

• les figures 1 à 6 annexées représentent schématiquement, et selon des vues en coupes axiales longitudinales du parafoudre, les diverses étapes successives de réalisation d'un parafoudre conforme à une variante de réalisation de la présente invention,
• la figure 7 représente une vue schématique de deux ébauches de parafoudre reliées entre elles par une entretoise pour faciliter l'étape d'extrusion,
• la figure 8 représente schématiquement une variante de réalisation d'un parafoudre conforme à la présente invention, plus précisément la demi vue gauche de la figure 8 représente le parafoudre en vue exérieure, tandis que la demi vue droite de la figure 8 représente le même parafoudre en coupe axiale longitudinale,
• la figure 9 représente une vue schématique en coupe axiale longitudinale d'une pièce de contact conforme à la présente invention, selon le plan de coupe référencé IX-IX sur la figure 10, et
• la figure 10 représente une vue en coupe transversale de la même pièce de contact selon le plan de coupe référencé X-X sur la figure 9.

Other characteristics, aims and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings, given by way of nonlimiting examples and in which:

• FIGS. 1 to 6 annexed schematically represent, and according to views in longitudinal axial sections of the arrester, the various successive stages in the production of a arrester according to an alternative embodiment of the present invention,
• FIG. 7 represents a schematic view of two surge arrester blanks connected together by a spacer to facilitate the extrusion step,
• FIG. 8 schematically represents an alternative embodiment of a surge arrester according to the present invention, more precisely the left half view of FIG. 8 represents the arrester in external view, while the right half view of FIG. 8 represents the same arrester in longitudinal axial section,
• FIG. 9 represents a schematic view in longitudinal axial section of a contact piece in accordance with the present invention, according to the section plane referenced IX-IX in FIG. 10, and
• FIG. 10 represents a cross-sectional view of the same contact piece according to the cutting plane referenced XX in FIG. 9.

The arrester according to the present invention shown in Figure 6 attached and obtained using the intermediate steps shown in Figures 1 to 5 which will be described later, comprises a stack of varistors 100, two contact parts 200, a first casing 300 of composite material, an extruded outer casing 400, attached fins 500 and additional sealing means 600.

Preferably, the arrester further comprises, as shown in FIG. 8, two end caps 700 made of electrically conductive material.

Varistors 100 are formed from discs of constant diameter formed on the basis of zinc oxide.

Varistors based on zinc oxide are well known to those skilled in the art.

Their production process and their composition will therefore not be described below.

As shown in Figure 1 attached, the varistors 100 are first stacked along their axis 102, to be perfectly coaxial.

Where appropriate, although this is not shown in the appended FIG. 1, spacers made of electrically conductive material, for example in the form of discs, or even if necessary comprising an elastic member, may be interposed between at least some of the pairs of 100 adjacent varistors.

As shown in FIG. 2, once this stack has been produced, the two contact pieces 200 are preferably placed respectively on the ends of the varistor stacks.

However, as a variant, it is possible to envisage placing the contact pieces 200 on the ends of the arrester, only after the first envelope 300 has been produced, or even even after the external envelope 400 has been produced.

The geometry of a particular and nonlimiting embodiment of the contact parts 200 will be described in more detail below with reference to FIGS. 9 and 10.

For the moment, it will simply be noted that the contact pieces 200 preferably comprise an annular groove 210.

As shown diagrammatically in FIG. 3, the subsequent step of the method according to the present invention consists in producing a first envelope 300 of composite material, on the stack of varistors 100 thus formed.

For this, preferably, a fabric of fibers 300, very preferably of glass fibers, is wound around the stack of varistors 100 and on the base of the two contact pieces 200.

Two links 350 are tightened on the envelope 300, opposite the grooves 210 mentioned above.

The casing 300 thus ensures a firm connection between the two contact parts 200 and maintains, by axial stress, good electrical contact between the main faces 104, transverse to the axis 102, of each pair of adjacent varistors on the one hand , and between the main external faces 104 of the varistors 100 placed at the ends of the stack, and respectively the contact parts 200, on the other hand.

According to a very preferred embodiment of the present invention, but not limiting, the envelope 300 is formed, as indicated above, of a fabric of fibers.

It is preferably glass fibers.

These fibers are oriented essentially parallel to the axis 102 of the stack of varistors.

Furthermore, the fibers advantageously extend over the entire length of the stack.

Thus, when a force is applied transversely to the axis 102 on one of the ends of the arrester, the fibers of the casing 300 work for some in elongation, for the others for compression.

Glass fibers have excellent resistance properties, both in elongation and in compression.

They therefore make it possible to ensure good mechanical resistance of the arrester to bending.

More precisely still, the fiber fabric used is advantageously an open mesh fabric. This provision allows free degassing of the stack of varistors.

The fiber fabric can be impregnated with any resin known to specialists in the field of composite materials.

The link 350 can be formed of numerous variants, for example of a ribbon, or of separate fibers, such as fibers impregnated with resin.

The establishment of links 350 enables the casing 300 to be immobilized firmly in translation on each contact piece 200 and thus to ensure good immobilization in relative translation of the contact pieces 200.

The envelope 300 can be formed from different layers of superimposed fibers.

An ultimate sheet of fibers can be wound if necessary over the whole of the preformed casing 300 as well as the links 350 in order to define a perfectly continuous cylindrical external surface before making the external casing 400.

It is indeed essential, for the extrusion step shown diagrammatically in FIG. 4, that the external surface of the internal envelope 300 have an irreproachable surface condition and be of strictly constant section over its length.

The thickness of the internal envelope 300 must be adapted, as indicated above, in particular to compensate for the unevenness of the surfaces of the stack of varistors due to deviations in alignment and to the dispersions of dimensions of varistors.

According to a very preferred implementation of the present invention, the fiber fabric making up the envelope 300 is a fabric of glass fibers crossed at a rate of 62.5% by weight of fibers in the weft direction parallel to the axis 102 and 37.5% by weight of fibers in the warp direction transverse to the axis 102.

The fabric has 3.5 x 5mm mesh.

The entangled glass fibers are heat sealed.

The length of the frame is equal to the length of the envelope 300.

The thickness of each layer of fabric is of the order of 1.60 mm and preferably two to three layers of superimposed fabric are used.

The resin used is preferably an unsaturated polyester.

According to an embodiment given by way of nonlimiting example, the link 350 is formed of glass fibers at a rate of 80% by weight in the warp direction and 20% by weight in the weft direction and has a width of 20mm.

As shown diagrammatically in FIG. 4, the subsequent step consists in engaging the stack obtained shown in FIG. 3 and comprising the internal envelope 300 in an extrusion die 800 to form the external envelope 400.

FIG. 4 schematically shows an extrusion head 300.

In practice, it is in fact possible to use any suitable conventional extruder.

The main purpose of the outer casing 400 is to protect the stack of lightning arresters 100 and the inner casing 300 of composite material, in particular with regard to humidity, and more generally with regard to inclement weather.

The outer casing 400 can be formed from any suitable material.

It is preferably formed from silicone.

The casing 400 has a substantially constant thickness over the entire length of the arrester, and over the entire periphery thereof.

The thickness of the external envelope is typically at least 3mm.

During this extrusion step, the stack comprising the varistors 100 coated with the envelope 300 of composite material can be driven and guided in translation along its axis 102 centered on the die 800 by any appropriate means.

As shown diagrammatically in FIG. 7, to ensure the guidance of the stacks, the stacks shown in FIG. 3 can be connected two by two using intermediate bars 810 of the same external diameter as the casing 300 and fixed on contact parts 200 by studs 812.

According to a variant of the representation given in FIG. 7, one can provide not an intermediate bar 810, placed between a pair of stacks of the type shown in FIG. 3, but two equivalent bars 810, fixed respectively on the contact pieces 200 from the same single stack of varistors.

In this case, the stacks are engaged successively, one by one, in the extrusion die 800, and not point successively as authorized with the aid of the interlayer 810 shown in FIG. 7.

Preferably, a bonding primer is placed on the external surface of the casing 300, before the extrusion step. However, this attachment primer is not placed on the bar (s) 810.

The product obtained at the end of the extrusion step is represented in FIG. 5.

Thereafter, as shown diagrammatically in FIG. 6, the fins 500 should be placed on the external envelope 400.

It is recalled that the fins 500 are intended to lengthen the line of flight on the outside of the arrester.

To this end, the fins 500 are preferably pre-molded, then threaded successively onto the body obtained after the extrusion step.

Their number, profile and spacing may vary depending on the requirements for resistance to pollution and of course the nominal voltage of the arrester.

Preferably, the fins 500 have a generally frustoconical shape, as shown in FIG. 6.

They are advantageously made from silicone, like the envelope 400.

The retention of the fins 500 on the outer casing 400 is preferably ensured by the addition of a synthetic component which acts as an adhesive.

It will also be noted, on examining FIG. 6, that preferably, in order to reinforce the tightness of the arrester, collars 600 are tightened on the ends of the casing 400, opposite each contact piece 200 respectively.

There is shown in Figure 8 attached an embodiment of a surge arrester according to the present invention for 63kV network.

It will be noted on examining the appended FIG. 8 that this arrester also comprises, at each of its ends, an electrically conductive cap 700, preferably formed from metal.

Each cap 700 can for example cover the associated collar 600.

Each cap 700 can be fixed to the end of the arrester by any suitable means, for example by screwing into the contact piece 200.

Preferably, each cap 700 is provided with a central orifice coaxial with the axis 102, designed to allow the passage of a stud connected to the associated contact piece 200.

It will be noted that, according to the particular embodiment shown in FIG. 8, the contact pieces 700 which have an identical geometry have the general shape of a truncated cone tapered towards the outside of the arrester.

The larger diameter flat face of the contact pieces 700, which extends perpendicular to the axis 102, is arranged against the ends of the above-mentioned stack.

Furthermore, the largest diameter of the contact piece 700 is between the external diameter of the casing 400 and the largest diameter of the fins 500.

Even more precisely, the largest diameter of the caps 700 is preferably equal to half the sum of these two diameters.

Thus, the two circular edges 702 formed at the junction of the large flat base 704 of the caps 700 and their frustoconical surface 706 define a preferential arc striking path in the event of power faults greater than those which can be absorbed by the stack of surge arresters 100.

We will now describe in more detail the contact part 200 according to a particular embodiment of the present invention shown in FIGS. 9 and 10.

Preferably, the two contact pieces 200 placed respectively at the ends of the arrester are identical.

Each contact piece 200 is formed from a single metal block having a general symmetry of revolution about an axis 202.

In use, this axis 202 is coaxial with the axis 102 of the stack of varistors.

In FIG. 9, the main faces of the contact piece 200 are referenced 204 and 206.

These main faces 204 and 206 are planar and orthogonal to the axis 202.

The main face 204 is based on the use on the main external face 104 of a varistor 100 placed at the end of the stack.

The main face 206 is directed towards the outside of the arrester.

The contact piece 200 comprises a cylinder 220 adjacent to the main face 206 and extended in the direction of the main face 204 by a barrel 230 of smaller section.

Preferably, the section of the barrel 230 is equal to the external section of the varistors 100.

Thus, when the contact pieces 200 are placed on the stack of varistors 100, the barrel 230 extends the external surface of the stack.

The abovementioned annular groove 210 is formed in the barrel 230, substantially at the mid-length thereof.

The bottom 211 of the groove 210 preferably has a polygonal section, for example a hexagonal section, as shown in FIG. 10.

The first side 212 of the groove 210 placed on the side of the main face 204 is preferably plane and perpendicular to the axis 202.

The second flank 213 of the groove 210 placed on the side of the main face 210 is preferably conical centered on the axis 202 and with a concavity directed towards the main face 206.

In addition, helical threads 232 are formed on the outer surface of the barrel 230.

Preferably, the threads 232 extend on either side of the groove 210.

However, the threads 232 are advantageously interrupted before the main face 204.

The limit of the threads 232 on the side of the main face 204 is formed by an annular groove 234.

Finally, each contact piece 200 has a blind tapped bore 240 centered on the axis 202 and opening onto the main face 206.

This threaded bore 240 is designed to receive a connecting stud, as indicated above.

The polygonal bottom 211 of the groove 210 and the threads 232 form non-symmetrical structures of revolution around the axis 202.

These structures in engagement with the envelope 300 make it possible to prohibit any relative rotation between the contact parts 200 and the envelope 300.

Furthermore, the annular grooves 210 in which the ends of the sheet of fabric forming the envelope 300 are engaged make it possible to secure a stable translation between said envelope 300 and the contact parts 200.

In conclusion, the structure described above and shown in the appended figures makes it possible to obtain perfect rigidity of the arrester, when bending, rotating around the axis 102 of the stack and in relative translation along this axis.

Where appropriate, it is possible, as a variant, to envisage forming zones of weakness in the external envelope 400, during the extrusion step shown diagrammatically in FIG. 4, for example by providing longitudinal grooves in said envelope 400.

These longitudinal grooves can be obtained using complementary shapes provided on the die, or alternatively inserts placed on the outer surface of the casing 400, for example based on glass fibers, and subsequently removed.

Alternatively, the arrester according to the present invention can be equipped with a fault signaling device.

This device can be placed for example on one end of the arrester.

Such a fault signaling device is designed to visualize the passage of a line current to earth via the arrester, that is to say to visualize the passage of a leakage current through the arrester.

The applicant has already described and represented such a signaling device in his patent application in France filed on December 20, 1991 under No. 91.15915.

For this reason, this fault signaling device will not be described in detail later.

• un goujon centré sur l'axe 102 de l'empilement de varistances et relié électriquement à l'une des pièces de contact 200,
• un capteur de courant faible perte comportant un bobinage entourant le goujon,
• un circuit électronique comportant:
  • 1 - un pont redresseur dont les entrées sont reliées au bobinage et
  • 2 - un condensateur relié aux sorties du pont redresseur pour intégrer l'énergie du courant de fuite détecté,
• un ensemble de signalisation, par exemple à base de composants pyrotechniques, conçu pour être initié par l'énergie intégrée dans le condensateur.

It should however be noted that preferably such a fault signaling device comprises:

• a stud centered on the axis 102 of the stack of varistors and electrically connected to one of the contact parts 200,
• a low loss current sensor comprising a winding surrounding the stud,
• an electronic circuit comprising:
  • 1 - a rectifier bridge whose inputs are connected to the winding and
  • 2 - a capacitor connected to the outputs of the rectifier bridge to integrate the energy of the detected leakage current,
• a signaling assembly, for example based on pyrotechnic components, designed to be initiated by the energy integrated in the capacitor.

The surge arrester according to the present invention offers numerous advantages over known prior lightning arresters.

First of all, compared to a molded or overmolded envelope, the production of the outer envelope 400 by extrusion offers the great advantage of very great flexibility and makes it possible to modify the parameters of the profile obtained easily and quickly.

In addition, the present invention makes it possible to easily adapt the length of the arrester to the nominal voltage of the line to be protected.

The present invention in no way requires the adaptation of any mold.

The present invention makes it possible to avoid any layer of air at the interface between the casing 300 and the casing 400, and consequently makes it possible to avoid any surface discharge at this level.

The present invention also makes it possible to significantly reduce the weight and size of the surge arresters compared to the known prior art.

Of course, the present invention is not limited to the particular embodiment which has just been described, but extends to any variant in accordance with its spirit.

Claims (25)

Method for manufacturing a surge arrester of the type comprising the steps which consist in: i) stacking varistors (100), ii) forming a first envelope (300) of composite material on the overlap of varistors (100), and iii) placing an outer envelope (400) with fins on the first envelope (300) made of composite material, characterized by the fact that: - Step ii) consists in making a first envelope (300) at least semi-rigid having a constant external section over its length, compensating in particular for the surface inequalities of the stack of varistors due to alignment deviations and to dimension dispersions of the varistors, and - step iii) consists of: a) first of all extrude an outer casing (400) of substantially constant thickness on the first casing (300), then b) attaching annular fins (500) to the extruded outer casing. A method according to claim 1 characterized in that it further comprises the step of disposing contact pieces (200) of electrically conductive material, on the ends of the stack of varistors (100), before the step ii). Method according to one of claims 1 or 2 characterized in that the outer envelope (400) is made from silicone material. Method according to one of claims 1 to 3 characterized in that the external envelope (400) has a thickness at least equal to 3mm. Method according to one of claims 1 to 4 characterized in that the fins (500) are fixed to the outer casing (400) using synthetic adhesive. Method according to one of claims 1 to 5 characterized in that the envelope of composite material (300) comprises a fabric of fibers oriented parallel to the axis of the stack of varistors (100) and that it is provided means (210, 232) capable of immobilizing the envelope (300) of composite material, in rotation and in translation on contact parts (200) placed at the end of the stack of varistors (100). Method according to one of claims 1 to 6 characterized in that the first envelope (300) is formed using a fabric of fibers having open meshes. Method according to one of claims 1 to 7 characterized in that collars (600) are tightened on the ends of the outer casing (400). Method according to one of Claims 1 to 8, characterized in that it also comprises the step consisting in placing a bonding primer on the external surface of the first envelope (300) before subjecting it to the 'extrusion step. Method according to one of claims 1 to 9 characterized in that it further consists in fixing a bar (810) centered on the axis (102) of the stack and of the same external section as the first envelope (300 ), on at least one of the ends of a stack of varistors (100) equipped with the first envelope (300), before subjecting this stack to the extrusion step. Method according to claims 9 and 10 taken in combination, characterized in that the bonding primer is placed only on the external surface of the first envelope (300) but is not placed on the intermediate bar (810). Surge arrester of the type comprising - a stack of varistors (100), a first envelope (300) of composite material formed on the stack of varistors (100), and - an outer envelope (400) with fins placed on the first envelope (300) of composite material,
characterized by the fact that: the first envelope (300) is at least semi-rigid and has a constant external section over its length, compensating in particular for the surface unevenness of the stack of varistors due to alignment deviations and to size variations of the varistors and - The outer envelope with fins comprises on the one hand an outer envelope (400) of substantially constant thickness formed by extrusion on the first envelope (300), and on the other hand annular fins (500) subsequently attached to the extruded outer shell. Surge arrester according to claim 12 characterized in that it further comprises contact parts (200) made of electrically conductive composite material, on the ends of the stack of varistors (100). Surge arrester according to one of claims 12 or 13 characterized in that the outer casing (400) is made from silicone material. Surge arrester according to one of claims 12 to 14 characterized in that the envelope (400) has a thickness at least equal to 3mm. Surge arrester according to one of claims 12 to 15 characterized in that the fins (500) are fixed to the outer casing (400) using synthetic adhesive. Surge arrester according to one of claims 12 to 16 characterized in that the envelope of composite material (300) comprises a fabric of fibers oriented parallel to the axis of the stack of varistors (100) and that it is provided means (210, 232) capable of immobilizing the envelope (300) of composite material, in rotation and in translation on contact parts (200) placed at the end of the stack of varistors (100). Surge arrester according to one of claims 12 to 17 characterized in that the first envelope (300) is formed using a fabric of fibers having open meshes. Surge arrester according to one of claims 12 to 18 characterized in that collars (600) are tightened on the ends of the outer casing (400). Surge arrester according to one of claims 12 to 19 characterized in that it further comprises caps (700) made of electrically conductive material on the ends of the arrester. Surge arrester according to claim 20 characterized in that the caps (700) have a larger diameter defined by an edge (702) between the outer diameter of the outer casing (400) and the larger diameter of the fins (500) . Surge arrester according to one of claims 12 to 21 characterized in that it comprises on each end a contact piece (200) comprising an annular groove (210) designed to receive one end of the envelope (300) of composite material and a link (350) clamping this envelope in the groove, and a structure (211, 232) non-symmetrical in revolution around the axis (202) of the contact piece. Surge arrester according to claim 22 characterized in that the non-symmetrical structure of revolution provided on each contact piece (200) is chosen from the group comprising helical threads (232) and an element (211) of polygonal cross section. Surge arrester according to one of claims 12 to 23 characterized in that it further comprises a fault signaling device on the end of the arrester. Surge arrester according to one of claims 12 to 24 characterized in that it comprises a primer for attachment to the external surface of the first envelope (300).

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