FR3134031A1 - Kit comprising at least two laminated glazings - Google Patents

Abstract

The invention relates to a kit comprising a first laminated glazing (1) and a second laminated glazing (2) intended to equip the same motor vehicle (3) and comprising at least one electrocontrollable zone (11, 12, 21, 22) with tint variable. The difference ΔTLA between the light transmission of the first laminated glazing (1) in the electrocontrollable zones (11, 12) in the light state, respectively in the dark state, and the light transmission of the second laminated glazing in the electrocontrollable zones (21 , 22) in the light state, respectively in the dark state, is less than or equal to 2 in absolute value, and the color difference in transmission ΔE between the first laminated glazing (1) in the electrocontrollable zones (11, 12) in the light state, respectively in the dark state, and the second laminated glazing (2) in the electrocontrollable zones (21, 22) in the light state, respectively in the dark state, is less than or equal to 5.0. Figure 1

Description

Kit comprising at least two laminated glazings

The invention relates to the field of motor vehicle glazing.

Glazing for motor vehicles must meet an increasing number of requirements, in terms of safety (visibility, impact resistance, resistance to burglary), comfort (visual, thermal, acoustic) or even aesthetics (curvature, appearance in reflection and transmission, from inside or outside). Various functionalities are also integrated into the glazing, such as for display, heating, etc.

The use of laminated glazing, in which two sheets of glass are adhesively bonded using a laminated interlayer, improves burglary resistance and acoustic comfort, ensures good visibility even in the event of breakage, and makes it easier to integrate different functionalities.

The different glazing used (windshield, roof, front and rear side windows, quarter windows, rear window) must meet requirements which are different depending on the type of glazing. For example, an automobile roof is generally very tinted in order to ensure good thermal comfort, while a windshield must allow good vision at least in its central area, and may require defrosting or demisting functions requiring the adding thin layers to the glass. The glass sheets used for these glazings will therefore generally be different.

It is therefore common for the different glazing used for the same vehicle to have different aspects, particularly in terms of tint and light transmission. Here we mean “hue” the colored appearance in transmission, characterized in particular by the colorimetric coordinates L*a*b*, calculated from the transmission spectrum between 380 and 780 nm taking into consideration the illuminant D65 as well as the CIE 1964 observer (10°).

This is all the more true when the glazing has electrically controllable zones with variable tint allowing you to go from a light state to a dark state and vice versa. This functionality can in particular be obtained by adding functional films within laminated glazing. By “dark” state we mean a state in which the light transmission of the glazing in the corresponding zone is lower than in the “bright” state. For example, a dark state can correspond to a light transmission less than or equal to 8%, in particular less than or equal to 5%, even less than or equal to 3%, and even less than or equal to 1%. A clear state can correspond to a light transmission greater than or equal to 10%, in particular greater than or equal to 15%. In this text, the light transmission is calculated from the transmission spectrum between 380 and 780 nm taking into account the illuminant A and the CIE 1964 reference observer (10°). This functionality makes it possible to improve the thermal and light comfort of the occupants of the passenger compartment by modulating the entry of light as desired.

The inventors were able to demonstrate that despite the use of different sheets of glass, it was nevertheless possible to ensure that the appearance of the different zones with variable tint was substantially identical, both in the clear state and in the the dark state, in particular to improve the visual comfort of the occupants of the passenger compartment and the general appearance of the vehicle.

The subject of the invention is a kit comprising a first laminated glazing and a second laminated glazing, said first and second laminated glazing being different from each other and being intended to equip the same motor vehicle, in which:
- the first laminated glazing comprises at least one electro-controllable zone with variable tint so as to go from a light state to a dark state and vice versa, and comprises two sheets of glass and at least one lamination spacer,
- the second laminated glazing comprises at least one electrically controllable zone with variable tint so as to go from a light state to a dark state and vice versa, and comprises two sheets of glass and at least one lamination spacer, at least one of glass sheets of the second laminated glazing having a different shade from that of each of the glass sheets of the first laminated glazing,
- the difference ΔTLA between the light transmission of the first laminated glazing in the electrocontrollable zones in the light state, respectively in the dark state, and the light transmission of the second laminated glazing in the electrocontrollable zones in the light state, respectively in the dark state dark state, is less than or equal to 2 in absolute value, and
- the color difference in transmission ΔE between the first laminated glazing in the electrocontrollable zones in the light state, respectively in the dark state, and the second laminated glazing in the electrocontrollable zones in the light state, respectively in the dark state dark state, is less than or equal to 5.0.

The invention also relates to a motor vehicle comprising the first laminated glazing and the second laminated glazing of the kit according to the invention.

The difference ΔTLA and the color difference in transmission ΔE are therefore small, both in the light state and in the dark state.

In the dark state, the light transmission of the laminated glazing in the electrocontrollable zones is preferably less than or equal to 8%, in particular less than or equal to 5%, or even less than or equal to 3% and even less than or equal to 1%. The dark state can therefore be opaque or almost opaque. In the clear state, the light transmission of the glazing in the electrocontrollable zones is preferably greater than or equal to 8%, in particular greater than or equal to 10%, for example between 10 and 30%.

The difference ΔTLA is preferably less than or equal to 1, in particular less than or equal to 0.5, in absolute value, in the light state and/or in the dark state.

The difference ΔTLA is determined according to the following formula:

TLA ₁ and TLA ₂ corresponding respectively to the light transmission of the first laminated glazing and the second laminated glazing (in the areas with variable tint). The light transmission is calculated from the transmission spectrum between 380 and 780 nm taking into account the illuminant A and the CIE 1964 reference observer (10°) and expressed in percent. Thus, if TLA ₁ is worth 20% and TLA ₂ is worth 18%, the difference ΔTLA is worth 2.

The color difference in transmission ΔE is preferably less than or equal to 4.0, in particular less than or equal to 3.0 or even less than or equal to 2.0, in the light state and/or in the dark state. According to the usual convention, the color deviation is determined according to the following formula:

The colorimetric coordinates L*a*b* of the first and second glass sheets (respectively indexed 1 and 2) are calculated from the transmission spectrum between 380 and 780 nm taking into consideration the illuminant D65 as well as the CIE 1964 observer (10°).

The kit or vehicle may include other laminated glazing, in particular a third laminated glazing, a fourth laminated glazing, etc. In this case, the conditions relating to the difference in transmission and the color difference may also apply to these additional laminated glazing, either in its entirety, or in possible electro-controllable areas with variable tint, and in the latter case, both in the light state and in the dark state.

The vehicle or kit may also include monolithic glazing, generally mechanically reinforced (tempered or hardened). In this case, the glass of these glazings can be chosen so that the aforementioned conditions relating to the difference in transmission and the color difference apply to these additional monolithic glazings, in the clear state or in the dark state.

Laminated glazing is generally curved, particularly in one or two directions, in order to integrate perfectly with the vehicle body. We then distinguish the interior face of the glazing, intended to be located on the interior side of the vehicle, which is the concave face, and the exterior face of the glazing, intended to be located on the exterior side of the vehicle, which is the convex face. Bending can in particular be carried out by gravity (the glass deforming under its own weight) or by pressing, at temperatures typically ranging from 550 to 650°C. According to a first embodiment, the two sheets of glass of the laminated glazing are curved separately. According to a second embodiment, the glass sheets are curved together.

Preferably, laminated glazing comprises only two sheets of glass.

The first and second laminated glazing (or even the third or fourth laminated glazing) are preferably chosen from the windshield, the roof, the side windows (front or rear), the quarter panels and the rear window. The side windows can for example include an electrically controllable zone occupying the entire surface of the window (particularly in the case of rear side windows), or only a part, for example in the form of a horizontal strip located in the upper part of the glazing ( particularly in the case of front side windows).

The first and/or second laminated glazing may comprise one or more electro-controllable zones. This or these zones can occupy all or part of the surface of the glazing. Depending on the case, the total surface occupied by the electrocontrollable zone(s) represents at least 60%, in particular at least 70%, or even at least 80% or at least 90% of the surface of the laminated glazing, or on the contrary occupies for example between 5 and 80%, in particular between 10 and 50% of the surface of the laminated glazing.

The first and second laminated glazing preferably comprise sheets of clear glass, tinted glass and/or over-tinted glass, in any possible combination.

The light transmission and tint of each sheet of glass are adjusted using the chemical composition of the glass and the thickness of the glass sheet. The thickness of the glass sheets is preferably between 0.7 and 4.0 mm, in particular between 1.4 and 3.0 mm. The chemical composition of the glass includes a colorless base, preferably silico-soda-lime (but other glasses can be used, in particular borosilicate or aluminosilicate glasses), as well as a coloring part. The coloring part comprises in particular one or more dyes chosen from transition metal oxides – in particular iron oxides (ferrous and ferric), cobalt oxide, chromium oxide, nickel oxide, oxides of rare earths, notably erbium oxide, and selenium.

A sheet of clear glass is a sheet having, for example, a light transmission of at least 85%, or even at least 90%. It generally does not include any coloring part with the exception of inevitable impurities, in particular iron oxides, in a total content of between 0.005 and 0.200% by weight, in particular between 0.010 and 0.150% by weight, or even between 0.030 and 0.200% by weight. 0.120% by weight.

A sheet of tinted glass is a sheet of glass having, for example, a light transmission between 50 and 80%, in particular between 60 and 75%. It comprises a coloring part, for example consisting of iron oxides, in a total content of between 0.4 and 1.2% by weight, in particular between 0.6 and 1.1% by weight. The glasses obtained are then green, possibly yellowish or green-blue depending on the proportion of ferrous iron. According to other examples, cobalt oxide, selenium and/or erbium oxide are added in order to impart a tint, for example blue or gray.

A sheet of overtinted glass is a sheet of glass having, for example, a light transmission between 5 and 50%, in particular between 8 and 40%. It comprises a coloring part for example consisting of iron oxides, in a total content of between 1.0 and 2.3 by weight, in particular between 1.1 and 2.0% by weight, as well as cobalt oxides and chromium and/or selenium. The coloring part comprises for example the following dyes, in the weight contents defined below: Fe ₂ O ₃ (total iron) from 1.2 to 2.3%, in particular from 1.5 to 2.2%, CoO from 50 to 400 ppm, in particular from 200 to 350 ppm, Se from 0 to 35 ppm, in particular from 10 to 30 ppm. The redox is preferably between 0.1 and 0.4, in particular between 0.2 and 0.3. By redox we mean the weight ratio between the ferrous iron content (expressed as FeO) and the total iron content (expressed as Fe ₂ O ₃ ). The glasses obtained are notably green or gray.

At least one of the glass sheets of the second laminated glazing has a tint, and preferably also a light transmission, different from that of each of the glass sheets of the first laminated glazing. For example, the second laminated glazing may comprise a sheet of tinted glass (possibly with a sheet of clear glass or a sheet of tinted glass), while the first laminated glazing comprises two sheets of tinted glass or a sheet of tinted glass and one clear glass sheet.

These differences in color, or even light transmission, can also be characterized by the parameters ΔTLA and ΔE previously defined, except that the light transmissions and L*a*b* coordinates are those of the glass sheets to be compared, and not of the complete laminated glazing. Preferably, at least one of the glass sheets of the second laminated glazing has a difference ΔTLA of at least 10, in particular at least 15, or even at least 20 or at least 30, even at least 30. least 40 or at least 50, with at least one, and even with each of the glass sheets of the first laminated glazing. Preferably, at least one of the glass sheets of the second laminated glazing has a color difference ΔE of at least 5, in particular at least 6, or even at least 7, with at least one, or even with each of the glass sheets of the first laminated glazing.

According to a preferred embodiment, the first laminated glazing is a windshield and the second laminated glazing is a roof. The windshield may in particular be a panoramic windshield, which extends towards the rear of the vehicle above the driver and the front passenger. The roof can occupy all or part of the roof of the vehicle. It can be separated from the windshield by a part of the bodywork or, on the contrary, be a direct extension of the windshield.

The first laminated glazing is advantageously a windshield which comprises at least one electro-controllable zone with variable tint located in the upper part of the windshield in the assembled state, in particular in zone C, for example in the form of a horizontal strip. Alternatively or cumulatively, an electrically controllable zone can be located in the lower part of the windshield, for example for the purpose of displaying information. In the case of a panoramic windshield, one or more electrically controllable zones can be located in the part intended to be located above the driver or front passenger. For example, two independently electrically controllable zones can be located one above the driver, the other above the front passenger, which allows each occupant to adapt their thermal and light comfort independently of the others. .

Taking into account current safety requirements, the light transmission of the windshield in the central part, called zone A, and in the electro-controllable zones in the bright state, is preferably greater than or equal to 70%. To do this, you can laminate a sheet of clear glass with a sheet of tinted glass. The clear glass sheet is preferably located on the exterior side of the vehicle.

When the second laminated glazing is a roof, it may in particular comprise a single electro-controllable zone, which can occupy all or part of the surface of the roof, for example between 50 and 100%, in particular between 70 and 95% of the surface of the roof. Alternatively, the roof may include several independently electrically controllable zones (in particular two, three or four), which may in total occupy all or part of the surface of the roof.

The light transmission of the roof (and generally of the first and second laminated glazing) in the electrocontrollable zone(s) in the clear state is preferably between 5 and 50%, in particular between 8 and 30%. , in order to ensure good thermal comfort. To do this, it is possible, for example, to laminate two sheets of tinted glass, or to laminate a sheet of tinted glass with a sheet of clear glass, or to laminate a sheet of tinted glass with a sheet of tinted glass, or even to leaf through two sheets of tinted glass.

The first or second laminated glazing may also comprise a thin layer or a stack of thin layers deposited on one of the glass sheets. It may in particular be a low-emissivity coating, in particular whose normal emissivity is preferably less than 0.50, in particular 0.30 and even 0.20 or even 0.10. It is preferably a stack of thin layers comprising at least one (in particular two, three or four) layers of silver or a layer of a transparent conductive oxide, in particular chosen from tin and tin oxides. indium, zinc oxides doped with aluminum or gallium or tin oxides doped with fluorine or antimony. These functional layers are generally interposed between dielectric layers based on oxides, nitrides and/or oxide nitrides.

Due to their low emissivity, these layers improve thermal comfort, by reducing the entry of solar heat in summer and reducing heat loss in winter. When electrical current inputs are provided, these layers, due to their low electrical resistivity, can also dissipate heat by the Joule effect, making it possible, particularly in the case of a windshield, to defrost or demist the glazing.

In the case of a windshield, these layers or stacks are preferably arranged on face 2 or 3 of the glazing, that is to say facing a lamination interlayer. In the case of a roof, it may also be advantageous to place such a stack, comprising a layer of transparent conductive oxide, on face 4 of the glazing, that is to say the face located in contact with the interior of the vehicle. The thermal comfort of the occupants is further improved by the presence of such a stack.

The presence of these thin layers or stacks of thin layers can also contribute to modifying the tint and light transmission of the laminated glazing, and can therefore be taken into account when it comes to matching them.

Preferably, the electrocontrollable zones with variable tint of the first and second laminated glazing comprise films interposed between two lamination interlayers and chosen independently from electrochromic films, films for suspended particle devices (technology sometimes called “SPD”) and liquid crystal films.

These films, which we will call “active films”, are generally films comprising several layers, some of which may be liquid. The functional layers are generally encapsulated between two polymer sheets, for example polyethylene terephthalate (PET) or polycarbonate (PC).

Electrochromic films preferably comprise two transparent electrodes separated by an ion storage layer, a polymer electrolyte layer and an electrochromic layer. The reversible chemical reaction between the ions and the electrochromic layer causes a variation in color.

Films for suspended particle devices comprise particles suspended in a liquid (in particular contained in the pores of a polymer matrix), said particles having the capacity to align themselves under the effect of an electric field, modifying the tint of the film (changing from dark to light).

In the case of liquid crystal films, the variation in color (from the dark state to the light state) is caused by the alignment of liquid crystals under the effect of an electric field.

Liquid crystal films are for example liquid crystal films dispersed in a polymer (technology called PDLC) or liquid crystal films of the guest/host type (also called “Guest-Host” or GH-LCD). In the latter case, dichroic coloring molecules are dissolved in a liquid crystal, the two components aligning under the effect of an electric field so as to go from the dark state to the light state. Guest/host type liquid crystal films are preferred because they feature very fast switching time, high contrast between light and dark states, low blur, and neutral tint.

According to a preferred embodiment, the active films of the first and second laminated glazing are of the same nature. It is thus easier to obtain similar shades and light transmissions.

An alternative mode, in which the active films of the first and second laminated glazing are of different natures, is however possible. It is for example possible to use a first laminated glazing comprising an SPD film and a second laminated glazing comprising a PDLC film or a GH-LCD film.

The active films are normally encapsulated between the two sheets of glass using lamination interlayers. The laminated glazing then comprises, in the electrically controllable zones, the succession of the following elements: first sheet of glass / first lamination interlayer / active film / second lamination interlayer / second glass sheet. In the case where laminated glazing also includes non-electro-controllable zones, the succession of elements in these zones is as follows: first sheet of glass / first lamination spacer / second lamination spacer / second glass sheet. In this area, the first and second interlayers become one after lamination.

The lamination interlayers are preferably made of a material chosen from poly(vinyl acetal) (in particular poly(vinyl butyral) or PVB), copolymers of ethylene and vinyl acetate (EVA), polyurethane ( PU), polyethylene terephthalate, polycarbonate, acrylic resins or even transparent adhesive materials (also called OCA for “optical clear adhesives”). Lamination interlayers can be in the form of self-supporting films, but some OCAs are deposited in liquid form before being crosslinked, for example using ultraviolet radiation.

In the case of self-supported films, the lamination step can be carried out by autoclave treatment, for example at temperatures of 110 to 160°C and under a pressure ranging from 10 to 15 bars. Prior to autoclave treatment, the air trapped between the glass sheets and the lamination interlayer can be eliminated by calendering or vacuum. Particularly in the case of self-supported OCA, lamination can alternatively be carried out by calendering or using a vacuum press, followed by autoclave treatment, to eliminate residual air bubbles and optimize adhesion. .

The agreement of the shades and transmissions between the first and the second laminated glazing can be done in several ways, in particular by playing on the optical properties of one of the elements of the glazing (in particular the lamination interlayer or the active film) or by adding an additional colorful element such as a layer.

According to a preferred embodiment, at least one lamination spacer of the first laminated glazing has a color different from that of the or each lamination spacer of the second laminated glazing. This embodiment is particularly advantageous, on the one hand because there are on the market a large number of lamination interlayers having very varied shades and light transmissions, and on the other hand because it does not require modifying the process manufacturing of glazing. For example, only one of the lamination inserts of the first or second laminated glazing can be tinted, the others being clear. According to another example, at least two, for example two or three, of the lamination interlayers of the first or second laminated glazing are tinted (in particular have different shades), the others being clear.

According to another embodiment, the active film of the first laminated glazing has a different shade from that of the active film of the second laminated glazing. For example, it is possible to color the polymer layers (typically PET or PC) of at least one of the active films.

According to another embodiment, at least one of the first and second laminated glazings also comprises an additional colored layer. The term “additional colored layer” means an additional layer in relation to the elements of the glazing which are the glass sheets, the interlayer and the active film.

Such an additional colored layer can in particular be deposited on one of the glass sheets of at least one of the glazings. It can be a mineral or organic layer.

As an example of an organic layer, we can cite polymeric layers applicable by liquid means. The polymer can be dissolved in a solvent to make liquid deposition possible. We can cite for example a polymeric layer based on poly(vinyl butyral), polyethylene, copolymer of ethylene and vinyl acetate dissolved in a solvent. Preferably, with the aim of using polymer formulations with as little solvent as possible, the colored polymeric layer is a layer obtained from a composition comprising epoxy compounds or (meth)acrylate compounds. The polymeric layer is for example obtained from a liquid composition comprising (meth)acrylate compounds chosen from monomers, oligomers, or polymers comprising at least one methacrylate function. The polymeric layer comprises a coloring agent, which preferably represents between 0.01 and 10% by mass relative to the total mass of the polymeric compounds. The coloring agent is in particular an organic compound, preferably inserted into the polymeric composition in the molecular state, that is to say that it is dissolved in the composition and does not form solid particles. For example, derivatives of the anthraquinone family can be cited as dyes (Acid Blue 25, Alizarin, Anthrapurpurin, Carminic acid, 1,4-Diamino-2,3-dihydroanthraquinone, 7,14-Dibenzpyrenequinone, Dibromoanthanthrone, 1,3- Dihydroxyanthraquinone, 1,4-Dihydroxyanthraquinone, Disperse Red 9, Disperse Red 11, Indanthrone blue, Morindone, Oil Blue 35, Oil Blue A, Parietin, Quinizarine Green SS, Remazol Brilliant Blue R, Solvent Violet 13, 1,2,4- Trihydroxyanthraquinone, Vat Orange 1, Vat Yellow 1) or products from the Neozapon®, Irgasperse®, Basantol®, Orasol® ranges, marketed by the company BASF.

As an example of a mineral layer, we can cite colored sol-gel layers, that is to say a coating obtained by a sol-gel process. A sol-gel process typically comprises the formation of a “sol”, that is to say a solution containing at least one precursor of the oxide to be deposited, the application of this solution to the surface to be coated , then the consolidation or densification of the coating by means of heat treatment. The precursor includes salts of the element whose oxide is to be deposited. These include organometallic compounds or nitrates, acetates, chlorides, etc. Examples of organometallic compounds include alkoxides, for example tetraorthosilicate (TEOS) in the case of a layer of silicon oxide. or titanium tetraisopropoxide in the case of a layer of titanium oxide. The soil may be partially watery. It preferably comprises an organic solvent, for example an alcohol, in particular chosen from ethanol, isopropanol, butanol and glycols or glycol derivatives, and their mixtures. The sol may additionally contain viscosity regulating agents, such as cellulose ethers or polyacrylates. The sol-gel layers are notably colored by adding inorganic pigments such as metal oxides or metals, generally in the form of nanometric particles.

The additional colored layer can alternatively be a colored polymeric film interposed at the time of lamination.

The different embodiments can obviously be combined with each other.

Particularly in the case of a windshield or a roof, the first and/or second glazing preferably comprises an opaque layer, generally black, such as an enamel or a silicate paint, deposited for example by screen printing or printing. digital in the form of a peripheral strip and used to conceal and protect the joints used for mounting the glazing on the bodywork window.

Examples

The examples which follow illustrate the invention in a non-limiting manner, in connection with Figures 1 to 4.

illustrates a vehicle according to the invention.

is a partial schematic sectional view of laminated glazing in an electrically controllable zone.

is a partial schematic sectional view of laminated glazing in an electrically controllable zone.

is a partial schematic sectional view of laminated glazing in an electrically controllable zone.

Vehicle 3 shown in comprises a laminated windshield 1 as well as a laminated roof 2 comprising electro-controllable zones with variable tint. The vehicle also includes side windows 4 and 5, quarter windows 6 and a rear window (not shown). In this example, these glazings do not include electrically controllable zones with variable tint. In other examples, these glazings, or some of them, could also include electrically controllable zones with variable tint.

The windshield 1 comprises in this example, in its upper part, two electro-controllable zones with variable tint 11 and 12, in the form of a horizontal strip and serving as sun visors. The two zones can be independently electrically controlled or not. When they are, this allows the driver and front passenger to adjust their level of visual comfort independently of the other. The windshield 1 also includes a black opaque peripheral strip 14, for example made of enamel, in order to conceal and protect the joints used for mounting the windshield in the bodywork and the various wiring, electrical current inlets and sensors (such as for example rain sensor, Lidar etc…).

The roof 2 includes in this example two electrically controllable zones with variable tint 21 and 22. These zones can be independently electrically controlled in order to allow the front and rear passengers to adjust their level of visual and thermal comfort independently. This configuration is obviously only given as an example, other configurations being possible, for example with a single electro-controllable zone or with three or even four electro-controllable zones. The roof 2 also includes an opaque, black peripheral strip 24, for example made of enamel.

There only illustrates a particular example of implementation. According to other variants, the windshield 1 can also include electrocontrollable zones in other parts, for example in its lower part, for display purposes (for example by projection of information). In the case of an autonomous vehicle, the entire windshield can be occupied by one or more electro-controllable zone(s). The other glazing of the vehicle, such as the side windows 4 and 5, the quarter panels 6 and/or the rear window can also include electrically controllable zones, which can also satisfy the conditions relating to the difference ΔTLA and the color difference in transmission ΔE .

Figures 2 and 4 represent schematic sectional views of the windshield 1 in an electro-controllable zone, according to two different (but nevertheless combinable) embodiments. There represents a schematic sectional view of the roof 2 in an electro-controllable zone.

The windshield 1 comprises two sheets of glass 102 and 104 and two lamination inserts 106 and 108 (or 109 in the case of the ), for example in PVB, sandwiching an active film 107, for example an LCD-GH type film.

Similarly, the roof 2 comprises two sheets of glass 202 and 204 and two lamination inserts 206 and 208, for example in PVB, sandwiching an active film 207, for example an LCD-GH type film. Other types of interlayers and active films are obviously possible, as described above. In the example illustrated in , the glass sheet 204 has a different shade from those of the glass sheets 102 and 104. It may for example be over-tinted glass while the other glass sheets are clear glass or tinted glass.

In the case exemplified in , the interlayer 108 has a different shade from that of the interlayers 206 and 208. In the case exemplified in , the interlayer 109 has the same color as that of the interlayers 206 and 208, but the windshield 1 includes an additional colored layer 110. In the example illustrated, the layer 110 is placed on the glass sheet 104, but d Other examples are obviously possible, the layer being able for example to be placed on the glass sheet 102 or between one of the interlayers 106 or 109 and the active film 107.

In an exemplary embodiment, conforming to the and 3:
- the windshield 1 included in the electro-controllable areas, and from outside the vehicle, a sheet of clear glass 102 2.1 mm thick coated on face 2 with a stack of thin layers comprising three layers of silver and used for defrosting the windshield, then an interlayer 106 in clear PVB 0.76 mm thick, then an active film 107 of LCD-GH type, then an interlayer 108 in gray PVB 0.85 mm d thickness, then a sheet of green tinted glass 104 1.6 mm thick. In the clear state, the glazing had a TLA of 11.3% and the following colorimetric coordinates: L* = 41.0; a* = -9.6; b* = 6.3. In the dark state, the glazing had a TLA of 0.6% and the following colorimetric coordinates: L* = 6.0; a* = -2.4; b* = 0.2.
- the roof 2 included in the electro-controllable areas, and from outside the vehicle, a sheet of clear glass 202 2.1 mm thick coated on face 2 with a stack of thin layers comprising four layers of silver, then an interlayer 206 in clear PVB 0.76 mm thick, then an active film 207 of LCD-GH type (identical to that used for windshield 1), then an interlayer 208 in clear PVB 0.38 mm thick, then a sheet of gray overtinted glass 204 1.6 mm thick. In the clear state, the glazing had a TLA of 12.0% and the following colorimetric coordinates: L* = 41.0; a* = -6.0; b* = 9.3, i.e. a ΔTLA of 0.7 and a ΔE of 4.7. In the dark state, the glazing had a TLA of 0.6% and the following colorimetric coordinates: L* = 6.0; a* = -1.2; b* = 1.0, i.e. a ΔTLA of 0.7 and a ΔE of 1.4.

In another embodiment, a tinted interlayer (one gray and the other blue) was added for each of the glazings. More precisely :
- the windshield included in the electrically controllable areas, and from the outside of the vehicle, a sheet of green tinted glass 2.1 mm thick, then a clear anti-UV PVB interlayer 0.76 mm thick thickness, then a gray PVB interlayer 0.38 mm thick, then an active film of LCD-GH type, then a clear PVB interlayer 0.38 mm thick, then a sheet of clear glass 1 .6mm thick. In the clear state, the glazing had a TLA of 10.2% and the following colorimetric coordinates: L* = 39.0; a* = -9.1; b* = 1.0. In the dark state, the glazing had a TLA of 0.4% and the following colorimetric coordinates: L* = 4.0; a* = -0.8; b* = -1.0.
- the roof included in the electro-controllable areas, and from the outside of the vehicle, a sheet of clear glass 2.1 mm thick, then an interlayer in clear anti-UV PVB 0.76 mm thick, then a 0.76 mm blue PVB interlayer, then an LCD-GH type active film (identical to that used for the windshield), then a 0.38 mm thick clear PVB interlayer, then a sheet 2.1 mm thick gray tinted glass. In the clear state, the glazing had a TLA of 10.0% and the following colorimetric coordinates: L* = 39.0; a* = -8.2; b* = 1.8, i.e. a ΔTLA of 0.2 and a ΔE of 1.2. In the dark state, the glazing had a TLA of 0.4% and the following colorimetric coordinates: L* = 4.0; a* = -0.5; b* = -0.8, i.e. a ΔTLA of 0 and a ΔE of 0.4.

Claims (10)

Kit comprising a first laminated glazing (1) and a second laminated glazing (2), said first and second laminated glazing being different from each other and being intended to equip the same motor vehicle (3), in which:
- the first laminated glazing (1) comprises at least one electrically controllable zone (11, 12) with variable tint so as to go from a light state to a dark state and vice versa, and comprises two sheets of glass (102, 104) and at least one lamination insert (106, 108, 109),
- the second laminated glazing (2) comprises at least one electrocontrollable zone (21, 22) with variable tint so as to go from a light state to a dark state and vice versa, and comprises two sheets of glass (202, 204) and at least one lamination spacer (206, 208), at least one of the glass sheets of the second laminated glazing (202, 204) having a different shade from that of each of the glass sheets (102, 104) of the first glazing laminated,
- the difference ΔTLA between the light transmission of the first laminated glazing (1) in the electrocontrollable zones (11, 12) in the light state, respectively in the dark state, and the light transmission of the second laminated glazing in the electrocontrollable zones ( 21, 22) in the light state, respectively in the dark state, is less than or equal to 2 in absolute value, and
- the color difference in transmission ΔE between the first laminated glazing (1) in the electrocontrollable zones (11, 12) in the light state, respectively in the dark state, and the second laminated glazing (2) in the zones electrocontrollable (21, 22) in the light state, respectively in the dark state, is less than or equal to 5.0. Kit according to the preceding claim, in which the first laminated glazing (1) is a windshield and the second laminated glazing (2) is a roof. Kit according to the preceding claim, in which the first laminated glazing (1) is a windshield which comprises at least one electro-controllable zone (11, 12) with variable tint located in the upper part of the windshield in the assembled state. Kit according to one of the preceding claims, in which the electrically controllable zones (11, 12, 21, 22) with variable tint of the first and second laminated glazing comprise films interposed (107, 207) between two lamination spacers (106, 108 , 109, 206, 208) and independently selected from electrochromic films, films for suspended particle devices and liquid crystal films. Kit according to the preceding claim, in which the films (107, 207) of the first and second laminated glazing are of the same nature. Kit according to one of the preceding claims, in which the difference ΔTLA in the light state and/or in the dark state is less than or equal to 1, in particular less than or equal to 0.5, in absolute value. Kit according to one of the preceding claims, in which the color difference in transmission ΔE in the light state and/or in the dark state is less than or equal to 4.0, in particular less than or equal to 3.0, or even less than or equal to 2.0. Kit according to one of the preceding claims, in which at least one lamination spacer of the first laminated glazing (108) has a color different from that of the or each lamination spacer of the second laminated glazing (206, 208). Kit according to one of the preceding claims, in which at least one of the first and second laminated glazing (1, 2) further comprises an additional colored layer (110). Motor vehicle (3) comprising the first laminated glazing (1) and the second laminated glazing (2) of the kit according to one of the preceding claims.