EP0035968A1 - Apparatus for forming, on a glass-sheet raised to a high temperature, a plurality of resistive tracks - Google Patents

Apparatus for forming, on a glass-sheet raised to a high temperature, a plurality of resistive tracks Download PDF

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Publication number
EP0035968A1
EP0035968A1 EP81810069A EP81810069A EP0035968A1 EP 0035968 A1 EP0035968 A1 EP 0035968A1 EP 81810069 A EP81810069 A EP 81810069A EP 81810069 A EP81810069 A EP 81810069A EP 0035968 A1 EP0035968 A1 EP 0035968A1
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EP
European Patent Office
Prior art keywords
conductive
glazing
plate
gases
zones
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Granted
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EP81810069A
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German (de)
French (fr)
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EP0035968B1 (en
Inventor
Reinhard Kalbskopf
Otto Baumberger
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Societa Italiana Vetro SIV SpA
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Societa Italiana Vetro SIV SpA
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B3/00Ohmic-resistance heating
    • H05B3/84Heating arrangements specially adapted for transparent or reflecting areas, e.g. for demisting or de-icing windows, mirrors or vehicle windshields
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B2203/00Aspects relating to Ohmic resistive heating covered by group H05B3/00
    • H05B2203/017Manufacturing methods or apparatus for heaters

Definitions

  • the present invention relates to a glazing heating by Joule effect, a method for its manufacture and a device for the implementation thereof.
  • Such glazing the heating of which is ensured by the passage of an electric current through a conductor, makes it possible to remedy the lack of visibility caused by icing and fogging of the windows of vehicles traveling in cold weather. It can however be used in other fields, in particular in the building industry. It comprises on at least one of its faces a succession of areas (B) non-conductive of electricity alternating with areas (A), made conductive by the deposition by CVD (chemical vapor deposition) of a layer of Sn0 2 , in contact with a heating current source, the areas (A) and (B) being, under normal conditions, both transparent.
  • CVD chemical vapor deposition
  • the usual heating glazings in particular those used for the rear window of automobiles, comprise a network of electrically conductive wires or ribbons incorporated into the glass or applied to the surface thereof, this network releasing sufficient heat, when it is connected to the terminals of the vehicle battery, to melt the frost covering said window and thus restore to it, after a certain time, its normal transparency.
  • this defrosting action manifests itself, firstly in the immediate vicinity of the conductive zone, the intermediate zones remaining still opaque for a certain time after the application of the current.
  • these conductive zones are themselves generally opaque (this is particularly the case when they are made up of ribbons of metallic paint), such partial defrosting is insufficient, in a first tenps, to ensure a suitable overall vision through the glazing; in fact, the glazing will not offer a sufficient general vision until the defrosted areas have extended significantly on either side of the conductive strips.
  • glazing with a homogeneous conductive layer is uniformly defrosted, it only becomes sufficiently transparent for effective vision after a relatively long period of tensioning.
  • a standard type of glazing heating subjected to the same conditions provides, by comparison, more quickly alternation ("zebra" appearance) of defrosted areas co-cidant with the conductive areas and of areas still frozen; however, as we have already said, in order to be able to see clearly through this type of glazing during defrosting, it is necessary to wait until the defrosted areas have spread enough and overflow on either side of the heating tape .
  • patent FR No. 2,075,352 describes a heated glazing comprising three transparent electroconductive areas alternating with non-conductive areas (see page 2, lines 22-30 and fig. 1). Although it is not specifically indicated in this reference that the transparency of the conductive areas alone gives sufficient vision through the glazing, this seems fairly obvious from the arrangement of these areas in FIG. 1 of the drawing.
  • Patent FR No. 1,116,234 describes the deposition, by spraying, of a layer of SnO 2 on a heated glass sheet so as to constitute thereon a transparent film which conducts electricity (see pl, col. 2 lines 20-26).
  • This application illustrated on p.4, col.l, second paragraph and in fig. 3 is done by means of guns projecting horizontally a spraying solution against the glass sheet oriented vertically and perpendicularly to the sprayed jets and moving laterally in the projection area of these, the operation repeating, by back and forth comes, until the desired thickness is obtained.
  • a third reference, USP Patent No. 2,833,902 relates to the deposition of layers of SnO 2 on glass plates by spraying with solution of organic tin compounds. This process is illustrated in fig. 4 where we see a set of four spray nozzles projecting a solution of tin compound on a heated substrate moving opposite these nozzles.
  • the traces of projection of the two superposed rows of nozzles overlap each other (this is obviously necessary for obtaining a homogeneous layer over the entire surface of the plate) which cannot in no way suitable for depositing conductive strips as desired to do in the invention.
  • a fourth reference, patent FR No. 1,165,645, concerns the deposition of transparent conductive layers the transmission of which does not exceed 72% (see p.4, Example 4). These layers are obtained by depositing transparent metallic films on transparent supports, these films possibly comprising gold, silver, copper, iron, nickel or other metals.
  • USP Patent No. 3,475,588 relates to de-icing glazing comprising a succession of contiguous heating zones, each of these zones being able to be heated according to an independent program. It is therefore not a case of glazing comprising alternating conductive and non-conductive areas as in the invention.
  • Patent FR 1,531,506 describes conductive glazing which can either include opaque resistances or include independent transparent conductive zones covering almost the entire surface of the glazing (see p.3, col. 2 above and fig. 5 ). This arrangement is not advantageous because it is too close to the solution where all the glazing is heated, solution whose drawbacks have been described above.
  • the glazing of the invention also constitutes an interesting new solution to the problem posed above.
  • This glazing is characterized in that the overall ratio of the total of the surfaces (A) / (B) is less than 1/2 and, in particular, between 1/8 and 1/2.
  • the conductive pads (A) are, as in the prior art, in contact with a source of heating current, that is to say that one end of these is connected to one of the terminals of said source and the other end is connected to the other of these terminals.
  • the areas (A) and (B) are both transparent and, therefore, when it comes to thawing the glazing, overall surface ratio (A) / (B) is chosen in such a way that the lightening of the areas (A) alone allows sufficient general vision through the glazing.
  • sufficient general vision we mean a vision such that the motorist can unambiguously detect the edges of the road and possible obstacles when he reverses or, in traffic, the presence of other vehicles behind him .
  • the transparency (light transmission) of the areas (A) will not be less than 70-80% of the transparency of the areas (B).
  • the arrangement and the relative area of the zones (A) and (B) as a function of one another are chosen according to the needs and functional requirements to which the glazing of the invention will submitted.
  • the zones (A) will consist of transparent conductive strips of constant width or not arranged parallel to one another on one or both sides of the glazing.
  • the strips of one of the faces may be perpendicular to the strips of the other face, the assembly then constituting a heating grid.
  • all kinds of other variants are possible, including that where a set of conductive strips is superimposed, on the same face, on another set, these being electrically separated from one another by a transparent insulating layer.
  • the surface ratio (A) / (B) will not exceed, around 1/2 if you really want to ensure rapid demisting or defrosting of the zones (A) without consuming too much current.
  • the shape of the pads (A) / (B) can be arbitrary provided that the assembly complies with the above requirements.
  • the material of the conductive strips must therefore be both transparent and sufficiently conductive.
  • tin oxide deposited by vapor phase reaction (CVD) is used.
  • the conductivity of the latter, particularly when deposited by CVD is particularly suitable because it has a specific resistivity ((-) of the order of 1 ( 3- 10 -4 ⁇ .cm approximately, this resistivity further decreases when the material heats up with the passage of an electric current.
  • a heated glazing unit comprising horizontal strips of Sn0 2 whose total surface constituted a quarter of the useful surface of the glazing and whose thickness was of the order of 2 to 5 ⁇ m.
  • Such glazing dissipated an electrical power of the order of 50 to 100 W and, after icing, the areas covered with SnO 2 regained their clarity much more quickly than the uniform witness glazing mentioned above.
  • the areas covered with SnO 2 had excellent transparency and in no way hampered visibility through the glazing because they were hardly noticeable.
  • the ratio (A) / (B) cannot be reduced indefinitely because, then, the overall visibility effect provided by the thawed "zebra" obtained becomes insufficient (transparent patterns too fine in relation to the whole) and, moreover, if the layers of SnO 2 are too thick, they lose their transparency which harms the general optical effect of the glazing under normal conditions.
  • the fundamental element of the coating device is a nozzle with concentric nozzles disposed in the immediate vicinity of the glass plate and projecting thereon, hot, gas streams of the reactants (diluted in a carrier gas) , the union of these reagents giving rise to the formation of SnO which is deposited on said plate.
  • the deposit takes the form of a transparent ribbon adhering perfectly to the glass and of width determined by the dimensions of the nozzle and more particularly, by those of the suction enclosure. reacted gases surrounding said nozzle, the radius of dispersion on the glass plate of gases from this nozzle and, therefore, the width of said conductive pads produced by the reaction being precisely determined by the operation of this suction.
  • the operating parameters speed of flow of gas flows, concentration of reagents, etc.
  • this CVD method hardly allows to exceed, in a single pass, a thickness of 0.8 to 1 ⁇ mm.
  • the zones of the glass plate intended to become conductive can be subjected to several successive passes of depositing the transparent conductive coating, the number of passes being essentially a function of the desired final thickness.
  • the method for manufacturing the glazing of the invention according to which is made to arrive simultaneously on the plate, by means of a projection device, streams of reactive gases whose union generates the formation of a transparent conductive deposit is characterized by the fact that, as soon as they are mixed in contact with the plate and formation of the transparent deposit thereon, the reacted gases are eliminated by sucking them up in a region immediately close to said projection device so that these gases do not spread uncontrollably on the plate and so as to keep the boundary between zones (A) and (B) clear and frank.
  • FIG. 1 schematically represents a coating device by CVD ccm- taking a set of nozzles arranged so as to allow the production of a glazing according to the invention.
  • Fig. 2 schematically represents, partially in perspective, a glass plate provided with conductive zones (A).
  • the device shown comprises three nozzles 1, 2 and 3 (there could be more than three, of course), each of these comprising two concentric nozzles designated respectively by the letters a and b.
  • the set of central nozzles marked a is connected by a general distribution piping 4 to a bubbler container 5 containing one of the reagents 6 allowing the formation of the transparent conductive layer; in this case it is SnCl 4 ,
  • the nozzles b are connected by a distribution circuit 7 to a container 8 containing another reagent 9, in this case aqueous methanol.
  • the device also comprises supply lines for carrier gas, respectively 10 and 11, immersed in the reactive liquids, this gas being intended to vaporize part of these, and evacuation chambers, respectively 12, 13 and 14, these enclosures (or pipes) collecting the by-products of the coating reaction, in this case HCl, and directing them towards an evacuation chimney 15.
  • the present device is placed in the immediate vicinity of a glass plate 16 to be coated with SnO 2 , this plate being supported by rollers 17 so as to ensure its movement perpendicular to the flow of the gas flows.
  • the enclosures 12, 13 and 14 closely surround the nozzles 1, 2 and 3, respectively, and their size, as well as the suction depression which prevails therein, determine the field of dispersion on the plate 16 of gases from said nozzles and, thereby, the width of said conductive areas.
  • the present device operates as follows:
  • the glass sheet 16 is heated to a predetermined temperature, for example 500 at 600 ° C by means of an oven not shown in the drawing, and progressively conveyed, by the rollers 17, opposite the outlet of the nozzles 1, 2 and 3.
  • a predetermined flow is introduced , a carrier gas, for example an H 2 / N 2 mixture, so that, by bubbling, it entrains, in the form of vapors, the reactants 6 and 9, these simultaneously opening out orifices a and b of each of the nozzles .
  • Fig. 2 shows the glass plate 16 covered with 3 conductive strips (A) with clean edges of transparent conductive material 18 obtained according to the invention, these strips alternating with non-conductive areas (B).
  • the thickness of this material in practice a few ⁇ m, is greatly exaggerated in the drawing for obvious illustration reasons.
  • the glazing of the invention can also be produced from a glass plate covered, for example by the method described in application CH 1412/79, with a homogeneous layer of conductive SnO 2 , a part of this layer then being eliminated, so as to provide an alternation of conductive and non-conductive areas.
  • the usual means can be used, in particular a felt polishing disc or roller provided with an abrasive paste, for example a diamond paste.

Abstract

Vitrage chauffant dégivrant comportant une alternance de plages conductrices et non conductrices de l'électricité. Les plages conductrices sont transparentes à chaud et agencées de manière que, lors du dégivrage, elles fournissent, à elles-seules, une visibilité globale suffisante à travers le vitrage, les zones non conductirices étant encore opaques. Le rapport de surface global entre les surfaces conductrices et les surfaces non conductrices est de 1/8 à 1/2.Heating and defrosting glazing comprising alternating conductive and non-conductive areas of electricity. The conductive pads are transparent when hot and arranged so that, during defrosting, they alone provide sufficient overall visibility through the glazing, the nonconductive zones being still opaque. The overall surface ratio between the conductive surfaces and the non-conductive surfaces is from 1/8 to 1/2.

Description

Domaine technique de l'inventionTechnical field of the invention

La présente invention concerne un vitrage chauffant par effet joule, un procédé pour sa fabrication et un dispositif pour la mise en oeuvre de celui-ci. Un tel vitrage, dont le chauffage est assuré par le passage d'un courant électrique dans un conducteur, permet de remédier au défaut de visibilité provoqué par le givrage et l'embuage des fenêtres de véhicules circulant par temps froid. Il est cependant utilisable dans d'autres domaines, notamment dans le bâtiment. Il conporte sur au moins une de ses faces une succession de plages (B) non conductrices de l'électricité alternant avec des plages (A), rendues conductrices par le dépôt par CVD (dépôt chimique en phase vapeur) d'une couche de Sn02, en contact avec une source de courant de chauffage, les plages (A) et (B) étant, dans les conditions normales, toutes deux transparentes.The present invention relates to a glazing heating by Joule effect, a method for its manufacture and a device for the implementation thereof. Such glazing, the heating of which is ensured by the passage of an electric current through a conductor, makes it possible to remedy the lack of visibility caused by icing and fogging of the windows of vehicles traveling in cold weather. It can however be used in other fields, in particular in the building industry. It comprises on at least one of its faces a succession of areas (B) non-conductive of electricity alternating with areas (A), made conductive by the deposition by CVD (chemical vapor deposition) of a layer of Sn0 2 , in contact with a heating current source, the areas (A) and (B) being, under normal conditions, both transparent.

On sait que les vitrages chauffant habituels, notamment ceux utilisés pour la vitre arrière des automobiles, comportent un réseau de fils ou rubans conducteurs de l'électricité incorporés au verre ou appliqués à la surface de celui-ci, ce réseau dégageant une chaleur suffisante, lorsqu'il est relié aux bornes de la batterie du véhicule, pour faire fondre le givre recouvrant ladite vitre et lui rendre ainsi, après un certain temps, sa transparence normale. Bien entendu, cette action de dégivrage se manifeste, en premier lieu au voisinage immédiat de la zone conductrice, les zones intermédaires restant encore opaques un certain temps après l'application du courant. Comme ces zones conductrices sont elles-mêmes généralement opaques (c'est notamment le cas lorsqu'elles sont constituées de rubans de peinture métallisée), un tel dégivrage partiel est insuffisant, dans un premier tenps, pour assurer une vision globale convenable à travers le vitrage; en fait, le vitrage n'offrira une vision générale suffisante qu'au moment où les zones dégivrées se seront notablement étendues de part et d'autre des bandes conductrices.It is known that the usual heating glazings, in particular those used for the rear window of automobiles, comprise a network of electrically conductive wires or ribbons incorporated into the glass or applied to the surface thereof, this network releasing sufficient heat, when it is connected to the terminals of the vehicle battery, to melt the frost covering said window and thus restore to it, after a certain time, its normal transparency. Of course, this defrosting action manifests itself, firstly in the immediate vicinity of the conductive zone, the intermediate zones remaining still opaque for a certain time after the application of the current. As these conductive zones are themselves generally opaque (this is particularly the case when they are made up of ribbons of metallic paint), such partial defrosting is insufficient, in a first tenps, to ensure a suitable overall vision through the glazing; in fact, the glazing will not offer a sufficient general vision until the defrosted areas have extended significantly on either side of the conductive strips.

Technique antérieurePrior art

On a cherché à remédier à cet inconvénient, soit en amincissant considérablement et en rapprochant fortement les unes des autres les zones conductrices (cas d'un réseau très serré, noyé dans le verre, de fils conducteurs d'une épaisseur de l'ordre du m), soit en appliquant sur le verre une couche conductrice uniforme transparente (cas du dépôt, par exemple, d'une pellicule conductrice d'oxyde d'étain de quelques m d'épaisseur), ces solutions procurant alors un chauffage pratiquement homogène du vitrage et un désembuage ou dégivrage uniforme de celui-ci. Cependant, un tel renède présente un défaut grave lié au fait que, à puissances égales, la montée globale en température d'un vitrage à couche conductrice uniforme se fait beaucoup plus lentement que celle des zones privilégiées situées au voisinage immédiat des bandes conductrices d'un vitrage chauffant classique. Il en résulte que, bien qu'un vitrage à couche conductrice homogène se dégivre uniformément, il ne devient suffisamment transparent pour une vision efficace qu'après une période de mise sous tension relativement longue. Ceci étant, un vitrage chauffant de type courant soumis aux mêmes conditions fournit, par comparaison, plus rapidement une alternance (aspect "zébré") de plages dégivrées coin- cidant avec les zones conductrices et de plages encore gelées; cependant, comme on l'a déjà dit, pour qu'on puisse bien voir à travers ce type de vitrage en cours de dégivrage, il faut attendre que les plages dégivrées se soient suffisamment étalées et débordent de part et d'autre du ruban chauffant.We have sought to remedy this drawback, either by considerably thinning and bringing the conductive zones very close to each other (case of a very tight network, embedded in the glass, of conductive wires with a thickness of the order of m), or by applying a transparent uniform conductive layer on the glass (case of the deposit, for example, of a conductive film of tin oxide a few m thick), these solutions then providing a practically homogeneous heating of the glazing and a uniform demisting or defrosting thereof. However, such a renede presents a serious defect linked to the fact that, at equal powers, the global rise in temperature of a glazing with uniform conductive layer takes place much more slowly than that of the privileged zones located in the immediate vicinity of the conductive strips. conventional heated glazing. As a result, although glazing with a homogeneous conductive layer is uniformly defrosted, it only becomes sufficiently transparent for effective vision after a relatively long period of tensioning. This being so, a standard type of glazing heating subjected to the same conditions provides, by comparison, more quickly alternation ("zebra" appearance) of defrosted areas co-cidant with the conductive areas and of areas still frozen; however, as we have already said, in order to be able to see clearly through this type of glazing during defrosting, it is necessary to wait until the defrosted areas have spread enough and overflow on either side of the heating tape .

Compte tenu du fait qu'il n'est guère possible, dans le danai- ne de l'automobile, d'augmenter considérablement la puissance électrique consommée et, par cela, la vitesse de dégivrage (les puissances admises pour le dégivrage d'une lunette arrière sont de l'ordre de 50 à 250 W), il a été imaginé pour pallier les inconvénients précités de faire se concentrer le chauffage sur certaines portions, transparentes, du vitrage anti-buée, ces portions, une fois clarifiées, fournissant une pluralité de motifs transparents dont l'ensemble assure une visibilité utile suffisante à travers ce vitrage partiellement dégivré.In view of the fact that it is hardly possible, in the automobile sector, to considerably increase the electrical power consumed and, by that, the speed of defrosting (the powers allowed for defrosting a rear window are of the order of 50 to 250 W), it has been imagined to overcome the aforementioned drawbacks of concentrating the heating on certain portions, transparent, of the anti-fog glazing, these portions, once clarified, providing a plurality of transparent patterns, the assembly of which provides sufficient useful visibility through this partially defrosted glazing.

Ainsi, le brevet FR No 2.075.352 décrit un vitrage chauffant conprenant trois plages transparentes électroconductrices alternant avec des plages non conductrices (voir page 2, lignes 22-30 et fig. 1). Quoiqu'il ne soit pas spécifiquement indiqué dans cette référence que la transparence des zones conductrices seules donne une vision suffisante à travers le vitrage, cela paraît assez évident de par la disposition de ces zones à la fig. 1 du dessin.Thus, patent FR No. 2,075,352 describes a heated glazing comprising three transparent electroconductive areas alternating with non-conductive areas (see page 2, lines 22-30 and fig. 1). Although it is not specifically indicated in this reference that the transparency of the conductive areas alone gives sufficient vision through the glazing, this seems fairly obvious from the arrangement of these areas in FIG. 1 of the drawing.

En ce qui concerne la fabrication des plages conductrices transparentes, la référence ci-dessus mentionne la technique de dépôt de l'oxyde de bismuth recouvert d'or par évaporation sous vide.With regard to the manufacture of transparent conductive pads, the above reference mentions the technique of depositing bismuth oxide coated with gold by evaporation under vacuum.

Le brevet FR No 1.116.234 décrit le dépôt, par pulvérisation, d'une couche de SnO2 sur une feuille de verre chauffée de manière à constituer sur celle-ci une pellicule transparente conductrice de l'électricité (voir p.l, col.2, lignes 20-26). Cette application, illustrée à la p.4, col.l, second paragraphe et à la fig. 3 se fait au moyen de pistolets projetant horizontalement une solution de pulvérisation contre la feuille de verre orientée verticalement et perpendiculairement aux jets pulvérisés et se déplaçant latéralement dans le chanp de projection de ceux-ci, l'opération se répétant, par va-et-vient, jusqu'à obtention de l'épaisseur désirée.Patent FR No. 1,116,234 describes the deposition, by spraying, of a layer of SnO 2 on a heated glass sheet so as to constitute thereon a transparent film which conducts electricity (see pl, col. 2 lines 20-26). This application, illustrated on p.4, col.l, second paragraph and in fig. 3 is done by means of guns projecting horizontally a spraying solution against the glass sheet oriented vertically and perpendicularly to the sprayed jets and moving laterally in the projection area of these, the operation repeating, by back and forth comes, until the desired thickness is obtained.

De plus, il est indiqué p.5, col.l, lignes 16-24, que les extrémités du pare-brise (constituées par la feuille de verre) ne comportent pas de dépôt celui-ci ayant été enlevé partiellement par "ef- façage".In addition, it is indicated on p.5, col.l, lines 16-24, that the ends of the windshield (formed by the glass sheet) do not have any deposit, this having been partially removed by "ef- facade ".

Une troisième référence, le brevet USP No 2,833,902, concerne le dépôt de couches de SnO2 sur des plaques de verre par pulvérisation de solution de conposés organiques d'étain. Ce procédé est illustré par la fig. 4 où on voit un jeu de quatre buses de pulvérisation projetant une solution de conposé d'étain sur un substrat chauffé se déplaçant en regard de ces buses. Cependant, il faut relever que, d'après le dessin de la fig. 3 de ce même brevet, les traces de projection des deux rangs superposés de buses se recoupent l'une l'autre (cela est évidemment nécessaire pour l'obtention d'une couche homogène sur la surface entière de la plaque) ce qu5 ne peut en aucune façon convenir pour déposer des bandes conductrices comme on désire le faire dans l'invention.A third reference, USP Patent No. 2,833,902, relates to the deposition of layers of SnO 2 on glass plates by spraying with solution of organic tin compounds. This process is illustrated in fig. 4 where we see a set of four spray nozzles projecting a solution of tin compound on a heated substrate moving opposite these nozzles. However, it should be noted that, according to the drawing in FIG. 3 of this same patent, the traces of projection of the two superposed rows of nozzles overlap each other (this is obviously necessary for obtaining a homogeneous layer over the entire surface of the plate) which cannot in no way suitable for depositing conductive strips as desired to do in the invention.

Une quatrième référence, le brevet FR No 1.165.645, concerne le dépôt de couches conductrices transparentes dont la transmission ne dépasse pas 72% (voir p.4, Exemple 4). Ces couches sont obtenues par le dépôt de pellicules métalliques transparentes sur des supports transparents, ces pellicules pouvant conprendre de l'or, de l'argent, du cuivre, du fer, du nickel ou d'autres métaux.A fourth reference, patent FR No. 1,165,645, concerns the deposition of transparent conductive layers the transmission of which does not exceed 72% (see p.4, Example 4). These layers are obtained by depositing transparent metallic films on transparent supports, these films possibly comprising gold, silver, copper, iron, nickel or other metals.

Le brevet USP No 3,475,588 concerne des vitrages dégivrants comprenant une succession de plages chauffantes jointives, chacune de ces zones pouvant être chauffées selon un programme indépendant. Il ne s'agit donc pas là d'un vitrage comprenant une alternance de plages conductrices et non conductrices comme dans l'invention.USP Patent No. 3,475,588 relates to de-icing glazing comprising a succession of contiguous heating zones, each of these zones being able to be heated according to an independent program. It is therefore not a case of glazing comprising alternating conductive and non-conductive areas as in the invention.

Le brevet FR 1.531.506 décrit des vitrages conducteurs qui peuvent, soit comporter des résistances opaques, soit comporter des zones conductrices transparentes indépendantes recouvrant la quasi totalité de la surface du vitrage (voir p.3, col.2 en haut et fig. 5). Cette disposition n'est pas avantageuse car elle se rapproche par trop de la solution où tout le vitrage est chauffant, solution dont les inconvénients ont été décrits plus haut.Patent FR 1,531,506 describes conductive glazing which can either include opaque resistances or include independent transparent conductive zones covering almost the entire surface of the glazing (see p.3, col. 2 above and fig. 5 ). This arrangement is not advantageous because it is too close to the solution where all the glazing is heated, solution whose drawbacks have been described above.

Une septième référence, le brevet USP No 2,564,677, décrit la préparation de films conducteurs iridescents d'oxydes sur des substrats par atanisation de solution de sels. Il ne semble pas que cette dernière référence contienne des données applicables à la fabrication de vitrages du type de celui de l'invention en raison du manque de transparence de tels dépôts iridescents.A seventh reference, US Pat. No. 2,564,677, describes the preparation of iridescent oxide conductive films on substrates by atanization of salt solution. It does not seem that this last reference contains data applicable to the manufacture of glazing of the type of that of the invention because of the lack of transparency of such iridescent deposits.

Description de l'inventionDescription of the invention

Le vitrage de l'invention constitue également une solution nouvelle intéressante au problème posé ci-dessus. Ce vitrage est caractérisé par le fait que le rapport global du total des surfaces (A)/(B) est inférieur à 1/2 et, notamment, conpris entre 1/8 et 1/2. Bien entendu, les plages conductrices (A) sont, comme dans l'art antérieur, en contact avec une source de courant de chauffage, c'est-à-dire qu'une extrémité de celles-ci est relié à l'une des bornes de ladite source et l'autre extrémité est reliée à l'autre de ces bornes. A la tenpérature anbiante, les plages (A) et (B) sont toutes deux transparentes et, ainsi lorsqu'il s'agit de dégeler le vitrage le rapport superficiel global (A) /(B) est choisi de manière telle que l'éclaircissement des zones (A) seules permette une vision générale suffisante à travers le vitrage. Par vision générale suffisante, on veut dire une vision telle que l'automobiliste puisse déceler sans ambiguité les bords de la route et des obstacles éventuels lorsqu'il fait de la marche arrière ou, dans le trafic, la présence d'autres véhicules derrière lui.The glazing of the invention also constitutes an interesting new solution to the problem posed above. This glazing is characterized in that the overall ratio of the total of the surfaces (A) / (B) is less than 1/2 and, in particular, between 1/8 and 1/2. Of course, the conductive pads (A) are, as in the prior art, in contact with a source of heating current, that is to say that one end of these is connected to one of the terminals of said source and the other end is connected to the other of these terminals. At the ambient temperature, the areas (A) and (B) are both transparent and, therefore, when it comes to thawing the glazing, overall surface ratio (A) / (B) is chosen in such a way that the lightening of the areas (A) alone allows sufficient general vision through the glazing. By sufficient general vision, we mean a vision such that the motorist can unambiguously detect the edges of the road and possible obstacles when he reverses or, in traffic, the presence of other vehicles behind him .

Caractéristiques préférées de l'inventionPreferred features of the invention

De préférence, la transparence (transmission de la lumière) des plages (A) ne sera pas inférieure aux 70-80 % de la transparence des plages (B).Preferably, the transparency (light transmission) of the areas (A) will not be less than 70-80% of the transparency of the areas (B).

Mis a part les critères ci-dessus, la disposition et la surface relative des zones (A) et (B) en fonction l'une de l'autre seont choisies suivant les besoins et les exigences fonctionnelles auxquels le vitrage de l'invention sera soumis. Le plus souvent, les zones (A) seront constituées de bandes conductrices transparentes de largeur constante ou non disposées parallèlement les unes aux autres sur l'une ou les deux faces du vitrage. Dans ce dernier cas, les bandes de l'une des faces peuvent être perpendiculaires aux bandes de l'autre face, l'ensemble constituant alors une grille chauffante. Cependant, toutes sortes d'autres variantes sont possibles, y compris celle où un jeu de bandes conductrices est superposé, sur une même face, à un autre jeu, ceux-ci étant électr.quement séparés l'un de l'autre par une couche transparente isolante. De façon générale, le rapport superficiel (A)/(B) ne dépassera pas, environ 1/2 si on veut réellement assurer un désembuage ou dégivrage rapide des zones (A) sans consommer trop de courant. De même, la forme des plages (A)/(B) peut être quelconque pourvu que l'ensemble soit conforme aux exigences ci-dessus. La matière des bandes conductrices doit donc être à la fois transparente et suffisamment conductrice. Comme telle matière, on utilise l'oxyde d'étain déposé par réaction en phase vapeur (CVD). En effet, la conductibilité de ce dernier, particulièrement lorsqu'il est déposé par CVD, convient particulièrement bien car elle possède une résistivité spécifique ( (-) de l'ordre de 1( 3- 10-4Ω.cm environ, cette résistivité diminuant encore lorsque la matière s'échauffe au passage d'un courant électrique. Ainsi, si on admet que, dans le cas d'une couche homogène de SnO2 déposée par CVD de 0,5 à 1 um d'épaisseur, on a des valeurs de R= 1 à 20Ω(ce qui est bien le cas, d'après les données de la demande de brevet suisse de la requérante No 7033/79) et que, d'autre part, une vitre arrière d'automobile est 2 fois plus large que haute, on aura, pour une telle vitre munie d'une telle couche, une consommation sous 12 volt d'environ 75 à 150 W ce qui correspond bien aux normes de puissances admises généralement. Aussi, dans une forme d'exécution de la présente invention, on a réalisé un vitrage chauffant comprenant des bandes horizontales de Sn02 dont la surface totale constituait le quart de la surface utile du vitrage et dont l'épaisseur était de l'ordre de 2 à 5 um. Un tel vitrage dissipait une puissance électrique de l'ordre de 50 à 100 W et, après givrage, les zones recou- vertes de SnO2 retrouvaient leur clarté beaucoup plus rapidement que le vitrage uniforme témoin mentionné ci-dessus. Les zones recouver- tes de SnO2 avaient une transparence excellente et ne constituaient en aucune façon une gêne à la visibilité à travers le vitrage car elles se remarquaient à peine. Il est entendu qu'on peut, si désiré, réaliser un vitrage dont le rapport superficiel zone (A)/zone (B) est de 1/8 ou même moins au lieu de 1/4 comme ci-dessus, l'épaisseur du SnO2 des zones (A) étant alors de 4 à 8µ (pour une même dissipation d'énergie). On obtient alors un vitrage dont les zones chauffées se dégivrent encore plus rapidement que dans le cas sus-mentionné. On ne peut cependant pas réduire indéfiniment le rapport (A)/(B) car, alors, l'effet de visibilité globale fourni par le "zèbre" dégelé obtenu devient insuffisant (motifs transparents trop fins par raport à l'ensemble) et, par ailleurs, si les couches de SnO2 sont trop épaisses, elles perdent leur transparence ce qui nuit à l'effet optique général du vitrage dans les conditions normales. D'autre part, on ne peut pas non plus trop augmenter le rapport (A)/(B) car, alors, on se rapproche exagérément de la limite constituée par la couche uniforme dont le dégivrage est trop lent. De façon générale, on préfère avoir des épaisseurs de SnO2 conductrices d'au moins 0,5 µm.Apart from the above criteria, the arrangement and the relative area of the zones (A) and (B) as a function of one another are chosen according to the needs and functional requirements to which the glazing of the invention will submitted. Most often, the zones (A) will consist of transparent conductive strips of constant width or not arranged parallel to one another on one or both sides of the glazing. In the latter case, the strips of one of the faces may be perpendicular to the strips of the other face, the assembly then constituting a heating grid. However, all kinds of other variants are possible, including that where a set of conductive strips is superimposed, on the same face, on another set, these being electrically separated from one another by a transparent insulating layer. In general, the surface ratio (A) / (B) will not exceed, around 1/2 if you really want to ensure rapid demisting or defrosting of the zones (A) without consuming too much current. Likewise, the shape of the pads (A) / (B) can be arbitrary provided that the assembly complies with the above requirements. The material of the conductive strips must therefore be both transparent and sufficiently conductive. As such material, tin oxide deposited by vapor phase reaction (CVD) is used. Indeed, the conductivity of the latter, particularly when deposited by CVD, is particularly suitable because it has a specific resistivity ((-) of the order of 1 ( 3- 10 -4 Ω.cm approximately, this resistivity further decreases when the material heats up with the passage of an electric current. Thus, if we admit that, in the case of a homogeneous layer of SnO 2 deposited by CVD of 0.5 to 1 μm thick, we have values of R = 1 to 20Ω (which is indeed the case , according to the data of the applicant's Swiss patent application No. 7033/79) and that, on the other hand, a rear automobile window is 2 times wider than it is high, we will have, for such a window fitted of such a layer, a consumption under 12 volts of approximately 75 to 150 W, which corresponds well to the generally accepted power standards. Also, in one embodiment of the present invention, a heated glazing unit was produced comprising horizontal strips of Sn0 2 whose total surface constituted a quarter of the useful surface of the glazing and whose thickness was of the order of 2 to 5 µm. Such glazing dissipated an electrical power of the order of 50 to 100 W and, after icing, the areas covered with SnO 2 regained their clarity much more quickly than the uniform witness glazing mentioned above. The areas covered with SnO 2 had excellent transparency and in no way hampered visibility through the glazing because they were hardly noticeable. It is understood that it is possible, if desired, to produce a glazing whose surface ratio zone (A) / zone (B) is 1/8 or even less instead of 1/4 as above, the thickness of the SnO 2 of the zones (A) then being from 4 to 8 μ (for the same energy dissipation). Glazing is then obtained, the heated zones of which defrost even more quickly than in the above-mentioned case. However, the ratio (A) / (B) cannot be reduced indefinitely because, then, the overall visibility effect provided by the thawed "zebra" obtained becomes insufficient (transparent patterns too fine in relation to the whole) and, moreover, if the layers of SnO 2 are too thick, they lose their transparency which harms the general optical effect of the glazing under normal conditions. On the other hand, we can not increase the ratio (A) / (B) too much because, then, we get too close to the limit formed by the uniform layer whose defrosting is too slow. In general, it is preferable to have thicknesses of conductive SnO 2 of at least 0.5 μm.

Comme on l'a vu plus haut, on peut réaliser le vitrage de l'invention grâce aux techniques habituelles de dépôt par CVD du SnO 2 sur le verre; on préfère cependant utiliser une technique de CVD inspirée de la méthode générale décrite en détail dans les demandes de brevet suisse Nos 1412/79 et 7033/79 de la requérante ainsi que dans la demande de brevet allemand DOS 2.123.274. Comme dans cette dernière, l'élément fondamental du dispositif de revêtement est une buse à tuyères concentriques disposée à proximité immédiate de la plaque de verre et projetant sur celle-ci, à chaud, des courants gazeux des réactifs (dilués dans un gaz porteur), la réunion de ces réactifs donnant lieu à la formation du SnO qui se dépose sur ladite plaque. Celle-ci étant mobile transversalement par rapport aux jets de gaz, le dépôt affecte la forme d'un ruban transparent adhérant parfaitement au verre et de largeur déterminée par les dimensions de la tuyère et plus particulièrement, par celles de l'enceinte d'aspiration des gaz ayant réagi entourant ladite buse, le rayon de dispersion sur la plaque de verre des gaz issus de cette buse et, partant, la largeur desdites plages conductrices produites par la réaction étant justement déterminée par le fonctionnement de cette aspiration. Bien entendu, les paramètres opératoires (vitesse d'écoulement des flux gazeux, concentration des réactifs, etc... jouent également un rôle concernant les dimensions et les propriétés des zones conductrices). Cependant, cette méthode par CVD ne permet guère de dépasser, lors d'une seule passe, une épaisseur de 0,8 à 1µmm. En conséquence, on peut soumettre les zones de la plaque de verre destinée à devenir conductrice à plusieurs passes successives de dépôt du revêtement conducteur transparent, le nombre de passes étant essentiellement fonction de l'épaisseur finale désirée. En résumé, le procédé pour fabriquer le vitrage de l'invention suivant lequel on fait arriver simultanément sur la plaque, au moyen d'un dispositif de projection, des courants de gaz réactifs dont l'union engendre la formation d'un dépôt transparent conducteur, est caractérisé par le fait que, dès après leur mélange au contact de la plaque et formation du dépôt transparent sur celle-ci, on élimine les gaz ayant réagi en les aspirant dans une région immédiatement proche dudit dispositif de projection de manière que ces gaz ne s'étalent pas sans contrôle sur la plaque et de façon à maintenir nette et franche la limite entre les zones (A) et (B).As we saw above, we can realize the glazing of the in vention using the usual CVD deposition techniques of SnO 2 on glass; however, it is preferred to use a CVD technique inspired by the general method described in detail in the Swiss patent applications Nos. 1412/79 and 7033/79 of the applicant as well as in the German patent application DOS 2,123,244. As in the latter, the fundamental element of the coating device is a nozzle with concentric nozzles disposed in the immediate vicinity of the glass plate and projecting thereon, hot, gas streams of the reactants (diluted in a carrier gas) , the union of these reagents giving rise to the formation of SnO which is deposited on said plate. As the latter is movable transversely with respect to the gas jets, the deposit takes the form of a transparent ribbon adhering perfectly to the glass and of width determined by the dimensions of the nozzle and more particularly, by those of the suction enclosure. reacted gases surrounding said nozzle, the radius of dispersion on the glass plate of gases from this nozzle and, therefore, the width of said conductive pads produced by the reaction being precisely determined by the operation of this suction. Of course, the operating parameters (speed of flow of gas flows, concentration of reagents, etc.) also play a role concerning the dimensions and properties of the conductive zones). However, this CVD method hardly allows to exceed, in a single pass, a thickness of 0.8 to 1 µmm. Consequently, the zones of the glass plate intended to become conductive can be subjected to several successive passes of depositing the transparent conductive coating, the number of passes being essentially a function of the desired final thickness. In summary, the method for manufacturing the glazing of the invention according to which is made to arrive simultaneously on the plate, by means of a projection device, streams of reactive gases whose union generates the formation of a transparent conductive deposit , is characterized by the fact that, as soon as they are mixed in contact with the plate and formation of the transparent deposit thereon, the reacted gases are eliminated by sucking them up in a region immediately close to said projection device so that these gases do not spread uncontrollably on the plate and so as to keep the boundary between zones (A) and (B) clear and frank.

Description des dessinsDescription of the drawings

Le dessin annexé illustre le procédé de l'invention. La Fig. 1 représente schématiquement un dispositif de revêtement par CVD ccm- prenant un jeu de tuyères disposées de manière à permettre la réalisation d'un vitrage suivant l'invention.The accompanying drawing illustrates the process of the invention. Fig. 1 schematically represents a coating device by CVD ccm- taking a set of nozzles arranged so as to allow the production of a glazing according to the invention.

La Fig. 2 représente schématiquement, partiellement en perspective, une plaque de verre pourvue de zones conductrices (A).Fig. 2 schematically represents, partially in perspective, a glass plate provided with conductive zones (A).

Le dispositif représenté comprend trois buses 1, 2 et 3 (il pourrait y en voir plus de trois, bien entendu), chacune de celles-ci comprenant deux tuyères concentriques désignées respectivement par les lettres a et b. L'ensemble des tuyères centrales marquées a est relié par une tuyauterie générale 4 de distribution à un récipient barboteur 5 contenant l'un des réactifs 6 permettant la formation de la couche transparente conductrice; en l'occurence il s'agit de SnCl4, Les tuyères b sont reliées par un circuit de distribution 7 à un récipient 8 contenant un autre réactif 9, en l'occurence du méthanol aqueux. Par ailleurs, le dispositif comprend encore des conduites d'amenée de gaz porteur, respectivement 10 et 11, plongeant dans les liquides réactifs, ce gaz étant destiné à vaporiser une partie de ceux-ci, et des enceintes d'évacuation, respectivement 12, 13 et 14, ces enceintes (ou conduites) recueillant les sous-produits de la réaction de revêtement, en l'occurence du HCl, et les dirigeant vers une cheminée d'évacuation 15. Le présent dispositif est disposé à proximité immédiate d'une plaque de verre 16 à revêtir de SnO2, cette plaque étant supportée par des rouleaux 17 de manière à assurer son déplacement perpendiculairement à l'écoulement des flux de gaz. Comme on l'a indiqué au dessin, les enceintes 12, 13 et 14 entourent étroitement les buses 1, 2 et 3, respectivement, et leur dimension, de même que la dépression d'aspiration qui règne au sein de celles-ci, déterminent le champ de dispersion sur la plaque 16 des gaz issus desdites buses et, par cela, la largeur desdites plages conductrices.The device shown comprises three nozzles 1, 2 and 3 (there could be more than three, of course), each of these comprising two concentric nozzles designated respectively by the letters a and b. The set of central nozzles marked a is connected by a general distribution piping 4 to a bubbler container 5 containing one of the reagents 6 allowing the formation of the transparent conductive layer; in this case it is SnCl 4 , The nozzles b are connected by a distribution circuit 7 to a container 8 containing another reagent 9, in this case aqueous methanol. Furthermore, the device also comprises supply lines for carrier gas, respectively 10 and 11, immersed in the reactive liquids, this gas being intended to vaporize part of these, and evacuation chambers, respectively 12, 13 and 14, these enclosures (or pipes) collecting the by-products of the coating reaction, in this case HCl, and directing them towards an evacuation chimney 15. The present device is placed in the immediate vicinity of a glass plate 16 to be coated with SnO 2 , this plate being supported by rollers 17 so as to ensure its movement perpendicular to the flow of the gas flows. As indicated in the drawing, the enclosures 12, 13 and 14 closely surround the nozzles 1, 2 and 3, respectively, and their size, as well as the suction depression which prevails therein, determine the field of dispersion on the plate 16 of gases from said nozzles and, thereby, the width of said conductive areas.

Le présent dispositif fonctionne comme suit : La feuille de verre 16 est chauffée à une température prédéterminée, par exemple 500 à 600°C au moyen d'un four non représenté au dessin, et progressivement acheminée, par les rouleaux 17, en regard de la sortie des buses 1, 2 et 3. Par les conduites 10 et 11 on introduit, suivant un débit préétabli, un gaz porteur, par exemple un mélange H2/N2, de manière que, par barbotage, il entraîne, sous forme de vapeurs, les réactifs 6 et 9, ceux-ci débouchant simultanément des orifices a et b de chacune des tuyères. Ces gaz sont projetés sur la plaque et, au contact de celle-ci, ils réagissent suivant la réaction

Figure imgb0001
le SnO2 se déposant sous forme de rubans sur la plaque 16 et le HCl formé étant entrainé de manière contrôlée, en compagnie du gaz porteur et des produits n'ayant pas réagi, dans la cheminée d'évacuation 15. En raison de la position concentrique des enceintes d'évacuation autour des buses, les gaz en contact avec la plaque 16 ne peuvent s'étaler librement sur la plaque au delà des limites inpo- sées par les dimensions de l'embouchure desdites enceintes qui les capture. Il résulte de cette disposition la formation de dépôts de SnO2 dont l'empreinte est bien marquée et les bords nets et francs avec un minimum de diffusion sur les zones (B).The present device operates as follows: The glass sheet 16 is heated to a predetermined temperature, for example 500 at 600 ° C by means of an oven not shown in the drawing, and progressively conveyed, by the rollers 17, opposite the outlet of the nozzles 1, 2 and 3. Via the pipes 10 and 11, a predetermined flow is introduced , a carrier gas, for example an H 2 / N 2 mixture, so that, by bubbling, it entrains, in the form of vapors, the reactants 6 and 9, these simultaneously opening out orifices a and b of each of the nozzles . These gases are projected onto the plate and, in contact with it, they react according to the reaction
Figure imgb0001
 SnO 2 being deposited in the form of ribbons on the plate 16 and the HCl formed being entrained in a controlled manner, together with the carrier gas and the unreacted products, in the exhaust chimney 15. Due to the position concentric with the evacuation chambers around the nozzles, the gases in contact with the plate 16 cannot spread freely on the plate beyond the limits imposed by the dimensions of the mouth of the said chambers which captures them. The result of this arrangement is the formation of SnO 2 deposits, the imprint of which is well marked and the edges sharp and clean with a minimum of diffusion over the areas (B).

Lors d'une passe unique telle que décrite ci-dessus, il se forme des rubans de SnO2 d'environ 0,5 à 0,8 ,um d'épaisseur. Pour réaliser le vitrage suivant l'invention, on effectuera plusieurs passes, par exenple en faisant repasser la plaque, en arrière, puis de nouveau en avant, le nonbre de fois nécessaire pour que les bandes conductrices acquièrent l'épaisseur et la conductibilité choisies.In a single pass as described above, ribbons of SnO 2 about 0.5 to 0.8 µm thick are formed. To produce the glazing according to the invention, several passes will be made, for example by ironing the plate, backward, then again forward, the number of times necessary for the conductive strips to acquire the thickness and conductivity chosen.

Bien entendu, en variante, on peut travailler en continu à condition de disposer de plusieurs ranpes de buses placées, l'une après l'autre, dans le sens de déplacement de la plaque à revêtir. Un tel agencement, quoique non représenté au dessin, est facilement carpris, en imaginant deux ou plusieurs ensembles de disp sitifs tels que celui du dessin placés côte à côte de manière que le dépôt de chacune des buses successives se superpose au dépôt fourni par la buse qui la précède. Ou, en d'autre termes, on parvient à un résultat équivalant en faissant passer la plaque quatre fois en regard du dispositif du dessin ou en la faisant passer une fois en regard d'une batterie de quatre unités semblables, celle-ci étant disposées de manière que la trace de chaque unité se superpose à celle des autres.Of course, as a variant, it is possible to work continuously provided that there are several ranps of nozzles placed, one after the other, in the direction of movement of the plate to be coated. Such an arrangement, although not shown in the drawing, is easily confused, imagining two or more sets of devices such as that of the drawing placed side by side so that the deposit of each of the successive nozzles is superimposed on the deposit provided by the nozzle which precedes it. Or, in other words, an equivalent result is obtained by passing the plate four times opposite the drawing device or by passing it once opposite a battery of four similar units, the latter being arranged so that the trace of each unit is superimposed on that of the others.

La Fig. 2 représente la plaque de verre 16 recouverte de 3 bandes conductrices (A) aux bords nets de matière conductrice transparente 18 obtenue suivant l'invention, ces bandes alternant avec des zones non conductrices (B). L'épaisseur de cette matière, dans la pratique de quelques µm, est fortement exagérée au dessin pour des raisons d'illustration évidentes.Fig. 2 shows the glass plate 16 covered with 3 conductive strips (A) with clean edges of transparent conductive material 18 obtained according to the invention, these strips alternating with non-conductive areas (B). The thickness of this material, in practice a few µm, is greatly exaggerated in the drawing for obvious illustration reasons.

Possibilité d'application industriellePossibility of industrial application

L'exenple qui suit illustre l'invention de façon détaillée :

  • On a construit un appareil similaire à celui représenté au dessin mais ccnportant 8 buses espacées de 5 cm par rangée et 5 rangée successives de buses. Les orifices des buses, toutes placées dans le même plan, avaient un diamètre de 5 mm, la tuyère intérieure (a) ayant 2 mm. Chacune des buses était entourée d'une conduite (ou enceinte) cylindrique d'aspiration coaxiale avec la buse et d'un diamètre de 12 mm. Ces conduites, dont l'embouchure inférieure dépassait l'orifice des buses d'environ 1 mm., aboutissaient, par leur extrémité opposée, à la cheminée d'évacuation laquelle était équipée de turbines d'aspiration conventionnelles (non représentées au dessin). L'alimentation des buses a été effectuée, également comme représenté schématiquement au dessin, au moyen des réactifs suivants :
    • a) SnC14 (tuyères intérieures (a); gaz porteur N2/H2 (60:40) au débit de 200 1/h; débit de SnCl4 2 ml/min.
    • b) solution aqueuse à 1 % de HF (tuyères extérieures b); gaz porteur N2/H2 (60:40), débit 300 1/h; débit du réactif 1 ml/min. les différents débits étaient réglés par des vannes placées sur les conduites d'amenées des gaz porteurs.
  • On a procédé au dépôt du Sn02 sur une plaque de verre de 4 cm d'épaisseur, chauffée à 600°C et se déplaçant à 8,5 m/min. en regard et parallèlement au plane d'ouverture des buses. Les conditions de dépôt étaient les suivantes température des buses : 130°C; vitesse d'aspiration du HCl formé : 500 1/h.
  • On a obtenu les résultats suivante : largeur des plages rectilignes 15 mm; épaisseur dépôt 2,5 µm, résistivité = 10-3Ω.cm; résistance globale du vitrage R p = 0.4 Ω.
  • On a ainsi obtenu un vitrage d'environ 30 cm de hauteur présentant 5 bandes conductrices de surface globale représentant environ 1/4 de la surface totale du verre.
The following example illustrates the invention in detail:
  • An apparatus similar to that shown in the drawing was constructed, but comprising 8 nozzles spaced 5 cm apart per row and 5 successive rows of nozzles. The nozzle orifices, all placed in the same plane, had a diameter of 5 mm, the internal nozzle (a) having 2 mm. Each of the nozzles was surrounded by a cylindrical suction pipe (or enclosure) coaxial with the nozzle and with a diameter of 12 mm. These pipes, whose lower mouth protruded from the orifice of the nozzles by about 1 mm., Terminated, at their opposite end, at the evacuation chimney which was equipped with conventional suction turbines (not shown in the drawing). The nozzles were supplied, also as shown diagrammatically in the drawing, with the following reagents:
    • a) SnC14 (internal nozzles (a); carrier gas N 2 / H 2 (60:40) at the flow rate of 200 1 / h; flow rate of SnCl 4 2 ml / min.
    • b) 1% HF aqueous solution (external nozzles b); carrier gas N 2 / H 2 (60:40), flow rate 300 1 / h; reagent flow rate 1 ml / min. the different flow rates were regulated by valves placed on the supply gas supply pipes.
  • We proceeded to deposit Sn0 2 on a glass plate 4 cm thick, heated to 600 ° C and moving at 8.5 m / min. opposite and parallel to the nozzle opening plane. The deposition conditions were as follows: nozzle temperature: 130 ° C .; suction speed of the HCl formed: 500 l / h.
  • The following results were obtained: width of the rectilinear areas 15 mm; deposit thickness 2.5 µm, resistivity = 10 -3 Ω.cm; overall resistance of the glazing R p = 0.4 Ω.
  • There was thus obtained a glazing of approximately 30 cm in height having 5 conductive strips of overall surface representing approximately 1/4 of the total surface of the glass.

Après avoir appliqué sur ses extrémités latérales une bande de peinture conductrice, on a soumis une plaque de ce vitrage (60X30) à un test de givrage et dégivrage standard de la manière suivante :

  • A -15°C, on a pulvérisé de l'eau sur la plaque, de manière à la recouvrir d'une couche de givre épaisse et absolument opaque. Puis on a relié les bandes de peinture conductrice latérales aux bornes d'une source de courant continu de 12 V et on a constaté qu'à -15°, les zones conductrices devenaient claires en approximativement 1 min, ce qui permettait d'avoir une vision générale suffisante à travers le vitrage.
After having applied a strip of conductive paint to its lateral ends, a plate of this glazing (60 × 30) was subjected to a standard icing and defrosting test as follows:
  • At -15 ° C, water was sprayed onto the plate, so as to cover it with a layer of thick and absolutely opaque frost. Then we connected the lateral conductive paint strips to the terminals of a 12 V direct current source and we found that at -15 °, the conductive areas became clear in approximately 1 min, which allowed to have a sufficient general vision through the glazing.

Il est encore à noter que le vitrage de l'invention peut également être réalisé à partir d'une plaque de verre recouverte, par exenple par la méthode décrite dans la demande CH 1412/79, d'une couche homogène de SnO2 conductrice, une partie de cette couche étant ensuite éliminée, de manière à ménager une alternance de zones conductrices et non conductrices. Pour éliminer partiellement la couche de SnO2, on peut utiliser les moyens habituels, notamment un disque ou un rouleau à polir en feutre muni d'une pâte abrasive, par exemple une pâte diamantée.It should also be noted that the glazing of the invention can also be produced from a glass plate covered, for example by the method described in application CH 1412/79, with a homogeneous layer of conductive SnO 2 , a part of this layer then being eliminated, so as to provide an alternation of conductive and non-conductive areas. To partially eliminate the layer of SnO 2 , the usual means can be used, in particular a felt polishing disc or roller provided with an abrasive paste, for example a diamond paste.

Claims (8)

1. Vitrage chauffant par effet joule comportant sur au moins une de ses faces une succession de plages (B) non conductrices de l'électricité alternant avec des plages (A) rendues conductrices, par le dépôt, par CVD, d'une couche de SnO2 en contact avec une source de courant de chauffage, les plages (A) et (B) étant, dans les conditions normales, toutes deux transparentes, caractérisé par le fait que le rapport de surfaces global (A)/(B) est conpris entre 1/8 et 1/2.1. Heating glass by Joule effect comprising on at least one of its faces a succession of areas (B) non-conductive of electricity alternating with areas (A) made conductive, by depositing, by CVD, a layer of SnO 2 in contact with a heating current source, the areas (A) and (B) being, under normal conditions, both transparent, characterized in that the overall surface ratio (A) / (B) is between 1/8 and 1/2. 2. Vitrage suivant la revendication 1, caractérisé par le fait que la transparence des zones (A) n'est pas inférieure à 70% de celles des zones (B).2. Glazing according to claim 1, characterized in that the transparency of the zones (A) is not less than 70% of those of the zones (B). 3. Vitrage suivant la revendication 4, caractérisé par le fait que les zones (A) sont des bandes parallèles horizontales ou verticales.3. Glazing according to claim 4, characterized in that the zones (A) are parallel horizontal or vertical strips. 4. Vitrage suivant la revendications 1, caractérisé par le fait que le SnO2 des zones (A) présente une résistivité de 10-3 à 10-4Ω. cm et une épaisseur de 0,5 à 5u.4. Glazing according to claim 1, characterized in that the SnO 2 of the zones (A) has a resistivity of 10- 3 to 10 -4 Ω. cm and a thickness of 0.5 to 5u. 5. Procédé pour fabriquer le vitrage suivant la revendication 1, suivant lequel on fait arriver simultanément sur la plaque, au moyen d'un dispositif de projection, des courants de gaz réactifs dont l'union engendre la formation d'un dépôt transparent conducteur, caractérisé par le fait que, dès après leur mélange au contact de la plaque et formation du dépôt transparent sur celle-ci, on élimine les gaz ayant réagi en les aspirant dans une région immédiatement proche dudit dispositif de projection de manière que ces gaz ne s'étalent pas sans contrôle sur la plaque et de façon à maintenir nette et franche la limite entre les zones (A) et (B).5. Method for manufacturing the glazing according to claim 1, according to which streams of reactive gases are made to arrive simultaneously on the plate, by means of a projection device, the union of which generates the formation of a transparent conductive deposit, characterized in that, as soon as they have been mixed in contact with the plate and formation of the transparent deposit thereon, the reacted gases are eliminated by sucking them into a region immediately close to said projection device so that these gases do not '' do not spread without control on the plate and so as to keep the boundary between zones (A) and (B) clear and frank. 6. Procédé suivant la revendication 5, caractérisé par le fait qu'on effectue des dépôts successifs superposés en faisant repasser le vitrage plusieurs fois en regard du dispositif de projection desdits gaz.6. Method according to claim 5, characterized by the fact that successive superimposed deposits are made by ironing the glazing several times opposite the device for projecting said gases. 7. Procédé suivant a revendication 5, caractérisé par le fait qu'on fait passer la plaque en regard de plusieurs dispositifs de projection desdits gaz, ces dispositifs étant agencés successivement, par rapport au sens de déplacement de la plaque, de manière que les traces des dépôts successifs fournis par ces dispositifs se superposent.7. The method as claimed in claim 5, characterized in that the plate is passed opposite several devices for projecting said gases, these devices being arranged successively, relative to the direction of movement of the plate, so that the traces of successive deposits provided by these devices overlap. 8. Dispostifs pour mettre en oeuvre le procédé suivant la revendication 5, conprenant, disposés côte-à-côte, un jeu de buses de projection par chacune desquelles on fait arriver simultanément sur la plaque des courants de gaz réactifs dont l'union engendre la formation dudit dépôt transparent conducteur, caractérisé par le fait qu'il comporte, entourant chacunes des buses et à proximité immédiates de celle-ci, des enceintes d'aspiration des gaz ayant réagi, les dimensions de ces enceintes déterminant le rayon de dispersion sur la plaque des gaz issus desdites buses et, par cela, la largeur desdites plages conductrices.8. Devices for implementing the method according to claim 5, including, arranged side by side, a set of projection nozzles by each of which are made to arrive simultaneously on the plate of reactive gas streams whose union generates the formation of said transparent conductive deposit, characterized in that it comprises, surrounding each of the nozzles and in the immediate vicinity thereof, suction chambers for the reacted gases, the dimensions of these chambers determining the radius of dispersion over the plate of gases from said nozzles and, thereby, the width of said conductive pads.
EP81810069A 1980-03-03 1981-03-02 Apparatus for forming, on a glass-sheet raised to a high temperature, a plurality of resistive tracks Expired EP0035968B1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
CH165880 1980-03-03
CH1658/80 1980-03-03

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EP0035968A1 true EP0035968A1 (en) 1981-09-16
EP0035968B1 EP0035968B1 (en) 1984-08-22

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EP (1) EP0035968B1 (en)
DE (1) DE3165621D1 (en)
ES (1) ES500017A0 (en)

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US5698262A (en) * 1996-05-06 1997-12-16 Libbey-Owens-Ford Co. Method for forming tin oxide coating on glass
DE10026454C1 (en) * 2000-05-27 2001-12-20 Daimler Chrysler Ag Radome for a distance warning radar (AWR)
JP2005212745A (en) * 2004-02-02 2005-08-11 Toyota Motor Corp Molded product for use in radar device beam passage
CN102687586B (en) * 2009-12-29 2016-09-21 Lg化学株式会社 Heating element heater and manufacture method thereof
KR102004065B1 (en) * 2015-01-26 2019-07-25 쌩-고벵 글래스 프랑스 Heatable Laminated Side Plate Glass

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EP0023471A1 (en) * 1979-07-31 1981-02-04 SOCIETA ITALIANA VETRO - SIV SpA Process for coating a glass substrate with an adherent coating of tin oxide

Also Published As

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EP0035968B1 (en) 1984-08-22
DE3165621D1 (en) 1984-09-27
ES8301407A1 (en) 1982-11-16
ES500017A0 (en) 1982-11-16
US4419570A (en) 1983-12-06

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