BR112021006661B1 - GLASS COMPRISING A FUNCTIONAL COATING AND AN ABSORBENT COATING WITH COLORIMETRIC ADJUSTMENT - Google Patents

Abstract

GLASS COMPRISING A FUNCTIONAL COATING AND AN ABSORBENT COATING WITH COLORIMETRIC ADJUSTMENT. The invention relates to a material comprising one or more transparent substrates that have two main faces, characterized by the fact that: - one of the faces of one of the substrates is coated with a functional coating capable of acting on solar radiation and/or infrared radiation, and - a side not coated with the functional coating of one of the substrates has a colorimetrically adjustable absorbent coating comprising an absorbent layer that absorbs solar radiation in the visible part of the spectrum.

Description

[0001] The invention refers to a material comprising a transparent substrate coated with a functional coating capable of acting on solar radiation and/or infrared radiation. The invention also relates to panes containing these materials, as well as the use of such materials to manufacture thermal insulation and/or sun protection panes.

[0002] In the description below, the term “functional” qualifying “functional coating” means “capable of acting on solar radiation and/or infrared radiation”.

[0003] These panes can also be used to equip both buildings and vehicles, especially by: - reducing the air conditioning effort and/or preventing excessive overheating, the so-called “solar control” panes and/or - reducing the amount of energy dissipated to the outside, the so-called “low emission” panes.

[0004] Depending on the climate of the countries in which these panes are installed, particularly depending on the levels of insolation, the efficiencies sought in terms of light transmission and solar factor may vary. Consequently, different ranges of glazing characterized by their level of light transmission are developed.

[0005] For example, in countries where insolation levels are high, there is a strong demand for glazing that has a light transmission of around 40% and sufficiently low solar factor values. In countries where insolation levels are lower, higher light transmission is desirable.

[0006] The “S” selectivity makes it possible to evaluate the efficiency of these panes. It corresponds to the ratio between the visible light transmission TLvis of the pane and the solar factor FS of the pane (S = TLvis / FS). The solar factor “FS or g” corresponds to the ratio in % between the total energy that enters the room through the glazing and the incident solar energy.

[0007] Achieving high selectivity must not come at the expense of the aesthetic aspect, in particular the color. In general, we seek the most neutral aesthetic possible in external and internal reflection and transmission.

[0008] The traditional approach to achieving both high selectivity and excellent color neutrality is to develop increasingly sophisticated functional coatings.

[0009] Known selective glazings have transparent substrates coated with a functional coating comprising a stack of several metallic functional layers, each disposed between two dielectric coatings. Glazing of this type improves solar protection and at the same time maintains high light transmission. These functional coatings are generally obtained by a succession of depositions carried out by sputtering, possibly assisted by a magnetic field.

[0010] In a conventional way, the faces of a pane of glass are designated starting from the outside of the building and numbering the faces of the substrates from the outside to the inside of the passenger compartment or the place where it is installed. This means that incident sunlight passes through the faces in increasing order of their number.

[0011] The known selective glazing is, in general, double glazing comprising the functional coating located on face 2, that is, on the outermost substrate of the building, on its face facing the interlayer gas blade.

[0012] The adaptation of the colorimetry of these panes is obtained using the nature and thickness of the layers or coatings that constitute the functional coatings.

[0013] The invention specifically relates to highly selective glazing comprising complex silver-based functional coatings.

[0014] In fact, silver-based functional coatings are generally more efficient in terms of selectivity than other functional coatings that reflect known infrared radiation, such as coatings comprising conductive oxide-based layers.

[0015] On the other hand, silver-based functional coatings are classified as complex due to the number of layers they are made of, the nature of the materials making up these layers and the adjustment of the thickness of these layers.

[0016] The complexity of functional coatings makes it difficult for us to jointly obtain good thermal efficiency and a particular aesthetic appearance, for example, excellent color neutrality or obtaining a particular color.

[0017] This difficulty in obtaining excellent color neutrality is even more pronounced for panes with a light transmission of around 50%, as they are intrinsically more colorful than panes that have a higher or lower light transmission. . In fact, for very low or very high light transmissions, for which the clarity is close to 0 or 100, the perception of colors is less intense. The colors “converge” towards black and white.

[0018] Finally, the complexity of these functional coatings makes it similarly difficult to maintain a constant production quality for a given functional coating. In fact, multiplying the number of layers and materials making up these functional coatings, it has become increasingly difficult to adapt the deposition conditions standards in order to obtain functional coatings of identical colors coming from two batches produced at the same production site or from two batches produced in two different production sites.

[0019] The objective of the invention is, therefore, to mitigate these inconveniences by creating a pane of glass that at the same time has good thermal efficiency and ensures the desired aesthetic appearance.

[0020] The objective pursued by the invention is, therefore, to easily obtain any range of glazing that at the same time presents high selectivity and a particular aesthetic aspect, for example, excellent color neutrality or obtaining a particular color.

[0021] The applicant developed a new solution that makes it possible to adapt the colorimetry of panes containing functional coatings without making these functional coatings more complex.

[0022] The proposed solution consists of adding a colorimetrically adjustable absorbent coating that absorbs solar radiation in the visible part of the spectrum onto one of the faces of a glazing substrate, said face not containing the functional coating.

[0023] The invention refers to a material comprising one or more transparent substrates, each substrate comprising two main faces, characterized by the fact that: - one of the faces of one of the substrates is coated with a functional coating capable of acting on radiation solar and/or infrared radiation, and - a side not coated with the functional coating of one of the substrates has a colorimetrically adjustable absorbent coating comprising an absorbent layer that absorbs solar radiation in the visible part of the spectrum.

[0024] The invention refers, in particular, to a material comprising a transparent substrate that has two main faces, characterized by the fact that: - one of the faces of the substrate is coated with a functional coating capable of acting on solar radiation and /or infrared radiation, - the other side of the substrate is coated with a colorimetrically adjustable absorbent coating comprising an absorbent layer that absorbs solar radiation in the visible part of the spectrum.

[0025] The invention relates, in particular, to a material (or system) containing: - a transparent substrate comprising two main faces, in which one of the faces of the substrate is coated with a functional coating capable of acting on solar radiation and /or infrared radiation, and - an additional substrate containing at least two main faces, characterized by the fact that: at least one face not coated with the functional coating of one of the substrates has a colorimetrically adjustable absorbent coating comprising an absorbent layer that absorbs solar radiation in the visible part of the spectrum, said face is chosen from: - the other uncoated face of the substrate coated with a functional coating, - one of the faces of an additional substrate. The invention also relates to: - a glazing containing a material according to the invention, - a glazing containing a material according to the invention installed in a vehicle or in a building, and - the method of preparing a material or of a glazing according to the invention, - the use of a glazing according to the invention as solar control and/or low-emission glazing for buildings or vehicles, - a building, a vehicle or a device containing a glazing according to the invention.

[0026] Preferably, the colorimetric adjustment absorbent coating is a neutralizing coating, that is, it imparts neutral colors to the material or glass in which it is contained.

[0027] However, in some particular applications, sometimes other colors are desired, especially a blue-green, bronze or silver appearance... The solution of the invention makes it possible to realize these different colors with ease.

[0028] The solution of the invention therefore proposes to use conventional or existing functional coatings, that is, not improved to improve colorimetry, and improve or modify their aesthetics by adding a colorimetric adjustment absorbent coating on another face of a substrate constituting the windowpane.

[0029] This solution separates the achievement of energy efficiencies (selectivity, emissivity, etc.), largely ensured by the functional coating, and the achievement of the aesthetic aspect, ensured by the absorbent coating with colorimetric adjustment. The colorimetrically adjustable absorbent coating influences energy efficiencies, but to a lesser extent.

[0030] The colorimetric adjustment absorbent coating has a less complex structure in terms of number and thickness of layers than the functional coating. Consequently, the solution of the invention therefore makes it possible to obtain a whole group of colors more easily compared to solutions that optimize functional coatings.

[0031] Finally, the solution of the invention has the additional advantage of starting from a single and the same functional coating with high light transmission, obtaining a whole range of panes with lower light transmission and/or different colors. It is no longer necessary to develop, for each light transmission band, a complex functional coating that at the same time presents energy efficiencies and colorimetric properties. Simply, starting from the same complex functional coating, select the colorimetrically adjustable absorbent coating with a less complex structure that makes it possible to obtain the desired colors.

[0032] Preferably, a material or glazing according to the invention is configured with the colorimetrically adjustable absorbent coating positioned on face 1 and the functional coating positioned on face 2.

[0033] This configuration is particularly advantageous because it avoids, in external reflection, double colored reflections when the coatings are on two different substrates.

[0034] The material according to the invention can be in the form of a monolithic, laminated and/or multiple pane of glass, in particular a double pane or a triple pane.

[0035] A monolithic glazing comprises a material comprising a transparent substrate. Face 1 is on the outside of the building and therefore constitutes the external wall of the window, face 2 is on the inside of the building and therefore constitutes the internal wall of the window.

[0036] A multiple pane comprises a material and at least one additional substrate, the material and the additional substrate are separated by at least one interlayer gas sheet. The glazing promotes a separation between an external space and an internal space.

[0037] A double pane of glass, for example, has 4 faces, face 1 is on the outside of the building and therefore constitutes the external wall of the pane, face 4 is on the inside of the building and therefore constitutes the internal wall of the pane. pane, faces 2 and 3 being inside the double pane.

[0038] A laminated pane comprises a material and at least one additional substrate, the material and the additional substrate are separated by at least one lamination insert. A laminated pane therefore has at least one additional material/lamination insert/substrate type structure. In the case of a laminated pane, we number all faces of the additional materials and substrates and do not number the faces of the lamination inserts. Face 1 is on the outside of the building and therefore constitutes the external wall of the glazing, face 4 is on the inside of the building and therefore constitutes the internal wall of the glazing, faces 2 and 3 being in contact with the insert of lamination.

[0039] A laminated and multiple glazing comprises a material and at least two additional substrates corresponding to a second substrate and a third substrate, the material and the third substrate are separated by at least one interlayer gas sheet, and - the material and the second substrate or - the second substrate and the third substrate, are separated by at least one lamination insert.

[0040] In the case of a multiple and/or laminated pane of glass, the colorimetric adjustment reflective coating is preferably positioned on face 1 and the functional coating capable of acting on solar radiation and/or infrared radiation is positioned on face 2 or 3.

[0041] All luminous characteristics described are obtained in accordance with the principles and methods of the European standard EN 410 which deals with the determination of the luminous and solar characteristics of panes used in glass for construction.

[0042] Conventionally, refractive indices are measured for a wavelength of 550 nm.

[0043] The luminous characteristics are measured according to the illuminant D65 at 2°, perpendicular to the material mounted on a double pane of glass (unless otherwise indicated): - TL corresponds to the light transmission in visible light in %, - Rext corresponds to the reflection of external light in visible light in %, observer on the external space side, - Rint corresponds to the reflection of internal light in visible light in %, observer on the internal space side, - a*T and b*T correspond to the colors in transmission a* and b * in the L*a*b* system, - a*Rext and b*Rext correspond to the colors in the reflection a* and b* in the L*a*b* system, observer on the side of outer space, - a*Rint and b*Rint correspond to the colors in reflection a* and b* in the L*a*b* system, observer on the side of internal space.

[0044] Unless otherwise indicated, colorimetric properties, such as L*, a* and b* values, and all values and value ranges of optical and thermal characteristics, such as selectivity, reflection of external or internal light, light transmission, are calculated with: - materials comprising a substrate coated with a functional coating mounted on a double glazing, - the double glazing has a configuration: 6-16(Ar-90%)-4, i.e. a configuration consisting of a material comprising a 4 mm common soda-lime glass substrate and another 4 mm soda-lime glass substrate, the two substrates are separated by an interlayer gas layer with 90% argon and 10% air of a thickness of 16 mm, - the functional coating is preferably positioned on face 2.

[0045] An objective of the invention may be to obtain exceptionally neutral aesthetics in external, internal reflection and transmission. Preferably, we favor neutrality in external reflection. According to the invention, neutral paints in external reflection, internal reflection or transmission are defined by: - values of a* comprising, in ascending order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1. - values of b* comprised, in ascending order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1.

[0046] Another objective of the invention may be to obtain colors in the external reflection in the blue or blue-green range. “Blue-green colors” correspond to negative values for a* and b* in the L*a*b* color measurement system. a* is between -10.0 and 0.0, preferably between -5.0 and 0.0 and b* is between -10.0 and 0.0, preferably between -5.0 and 0.0 .

[0047] The glazing according to the invention is installed in a building or a vehicle.

[0048] The invention therefore also relates to: - a glazing installed in a vehicle or a building, and - a vehicle or a building containing a glazing according to the invention.

[0049] A window pane for the building generally delimits two spaces, a space qualified as “external” and a space qualified as “internal”. We consider that the sunlight that enters a building goes from the exterior to the interior.

[0050] The functional coating is located: - on face 2, that is, on the outermost substrate of the building; on its face facing the interlayer gas blade, or - on face 3, that is, on the innermost substrate of the building; on its face facing the interlayer gas blade.

[0051] Preferably, the colorimetrically adjustable absorbent coating is positioned on face 1, and the functional coating capable of acting on solar radiation and/or infrared radiation is positioned on face 2.

[0052] According to advantageous embodiments, the material of the invention in the form of a double pane containing the functional coating positioned on face 2 makes it possible to achieve in particular the following efficiencies: - a light transmission of between 40 and 60% , and/or - values of a* and b* in external reflection comprised, in increasing order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1, and/or - values of a* and b* in internal reflection comprised, in increasing order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1, and/or - values of a* and b* in the transmission comprising, in ascending order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1.

[0053] This double pane has neutral colors.

[0054] According to another advantageous embodiment, when the material is mounted on a double glazing with the functional coating positioned on face 2, the double glazing presents: - values of a* in external reflection comprised, in ascending order preferably, between -10 and -3, - values of b* in the external reflection comprised, in increasing order of preference, between -20 and -10.

[0055] This double pane has a blue color.

[0056] According to another advantageous embodiment, when the material is mounted on a double pane of glass with the functional coating positioned on face 2, the double pane of glass presents values of a* and b* in the external reflection between 5 and 20 .

[0057] This double pane has a bronze color.

[0058] In a double glazing configuration, the present invention makes it possible to obtain a high S selectivity, in particular greater than 1.6, preferably greater than 1.7, a solar factor (FS), less than 30%, of neutral colors in transmission and in external and internal reflection.

[0059] The invention also relates to: - the method of obtaining a material or a glazing according to the invention, - the use of a glazing according to the invention as solar control and/or low emission glazing for buildings or vehicles.

[0060] The functional coating and/or colorimetric adjustment absorbent coating are deposited by sputtering assisted by a magnetic field (magnetron-type method). According to this advantageous embodiment, all layers of the coatings are deposited by sputtering assisted by a magnetic field.

[0061] The invention also relates to the method of obtaining a material and a pane according to the invention, in which the coating layers are deposited by magnetron sputtering.

[0062] The preferred characteristics appearing in the description below apply both to the material and the glazing according to the invention and, as the case may be, to the method, use, building or vehicle according to the invention.

[0063] In the absence of specific stipulation, the expressions “above” and “below” do not necessarily mean that two layers and/or coatings are arranged in contact with each other. When it is specified that a layer is deposited “in contact” with another layer or with a coating, this means that there cannot be one (or several) layer(s) sandwiched between these two layers (or layer and coating).

[0064] In the present description, unless otherwise indicated, the expression “based on”, used to qualify a material or a layer as to what it or she contains, means that the mass fraction of the constituent that he or she comprises is at least 50%, in particular at least 70%, preferably at least 90%.

[0065] In order to determine for a pane of glass containing a known functional coating which absorbent coating with colorimetric adjustment allows obtaining the sought thermal and colorimetric properties, through numerical simulations we can identify which absorbent coatings with colorimetric adjustment are suitable for use.

[0066] Unless otherwise specified, the thicknesses cited in this document, in the absence of other specifications, are physical, real or geometric thicknesses called Ep and are expressed in nanometers (and not optical thicknesses). The optical thickness Eo is defined as the physical thickness of the layer considered multiplied by its refractive index for the wavelength of 550 nm: Eo = n*Ep. The refractive index being a dimensionless value, we can consider that the optical thickness unit is the one chosen for the physical thickness.

[0067] According to the invention, a dielectric coating corresponds to a sequence of layers with at least one dielectric layer. If a dielectric coating is composed of several dielectric layers, the optical thickness of the dielectric coating corresponds to the sum of the optical thicknesses of the different dielectric layers that constitute the dielectric coating.

[0068] According to the invention, a colorimetrically adjustable absorbent coating is a coating that modifies the color of the material or a pane of glass containing a functional coating. Colorimetric adjustment is carried out using an absorbent layer.

[0069] According to the invention, an absorbing layer that absorbs solar radiation in the visible part of the spectrum is a layer that absorbs some wavelengths in the visible. The optical index of an absorbing layer can be decomposed into a real part and an imaginary part. The real part, n, corresponds to the index of refraction. The imaginary part or attenuation factor k, is linked to the absorption of light by the layer.

[0070] By “absorbent layer” in the sense of the present invention is meant a layer of a material that has an n/k ratio between 0 and 5, excluding these values, by at least 60%, preferably at least 80%, including 100%, of the visible wavelength range (from 380 nm to 780 nm). A percentage of 100% means that the material has an n/k ratio between 0 and 5 for all wavelengths in the range. n designates the real refractive index of the material for a given wavelength and k represents the imaginary part of the refractive index for a wavelength; the ratio n/k being calculated for a given wavelength identical for n and for k.

[0071] The absorption of light energy in an absorbent coating depends both on the nature of the absorbent layer, the thickness and the material from which it is formed, but also on its position in the coating. Furthermore, an absorbent material modifies the reflection to a certain degree. Therefore, it is possible to selectively increase or reduce the absorption and reflection properties of the glass pane for some wavelengths. The adaptation of the color of the window pane is carried out using this absorption and reflection.

[0072] According to the invention: - light reflection corresponds to the reflection of solar radiation in the visible part of the spectrum, - light transmission corresponds to the transmission of solar radiation in the visible part of the spectrum, - light absorption corresponds to absorption of solar radiation in the visible part of the spectrum.

[0073] According to the invention, the light absorption due to the absorbing layer, measured from the side of the glass by depositing only this absorbing layer confined between two non-absorbing dielectric layers on an ordinary clear glass of 4 mm to 6 mm thick: - is greater than 5%, including greater than 10% or - is between 5 and 65%, between 5 and 55%, between 10 and 45%, preferably between 10% and 35%.

[0074] The absorbent layer is chosen from: - layers based on one or more metals and/or metalloids, - nitride layers of one or more metals and/or metalloids, - oxynitride layers of one or more metals and/or metalloids, of elements chosen from palladium, niobium, tungsten, iron especially in the form of stainless steel, titanium, chromium, molybdenum, zirconium, nickel, tantalum, zinc, tin and silicon.

[0075] The absorbent layer can essentially be in the elementary form of metal or metalloid. According to the invention, a material in elemental form means that such material is not voluntarily combined or bonded with another element, such as oxygen, nitrogen or carbon. This means, for example, that this material is not in oxidized, nitrided or carbonated form.

[0076] Although essentially in elemental form, the metal or metalloid may present traces of nitridation as a result of the deposition atmosphere polluted by nitrogen from neighboring deposition regions. The absorbent layer may be a layer of a metal or nonmetal chosen from silicon, palladium, niobium, tungsten, stainless steel, titanium, chromium, molybdenum, zirconium, nickel, tantalum, zinc , alloys of these elements such as NiCr, NiCrW, WTa, WCr, NbZr, TaNiV, CrZr and NbCr.

[0077] The absorbent layer can be a nitride or a subnitride, that is, a substoichiometric nitride of nitrogen. Preferably, the absorbent layer is a nitride layer chosen from SnZnN, TiN, NiCrWN, NiVN, TaN, CrN, ZrN, CrZrN, TiAIN, TiZrN, WN, SiZrN and SiNiCrN.

[0078] According to preferred embodiments, the absorbent layer is chosen from a nickel and/or chromium nitride layer, a titanium nitride layer, a niobium nitride layer or a silicon-based layer. .

[0079] The layer based on nickel and chromium nitride has, in ascending order of preference, a weight ratio between nickel and chromium between 90/10 and 70/30, preferably a ratio of 80/20.

[0080] The thickness of the absorbent layer is comprised, in increasing order of preference, from 0.1 to 20, 0.2 to 10 nm, from 0.3 to 8, from 0.5 to 5 nm, from 1, 0 to 4 nm, 1.5 to 3.0 nm.

[0081] The absorbent nature of the colorimetric adjustment layer has the effect of the fact that this layer necessarily decreases the light transmission of the material or glass that contains it. To mitigate this effect, it is possible to add dielectric coatings to the absorbent layer containing dielectric layers whose materials and thicknesses are carefully chosen. For example, the absorbent layer can be arranged between two dielectric coatings containing dielectric layers with high and low refractive indices that allow, to a certain extent, to modulate light transmission and absorption.

[0082] These dielectric coatings also allow the absorbent layer to be protected.

[0083] The colorimetrically adjustable absorbent coating may comprise a dielectric coating and an absorbent layer.

[0084] The colorimetric adjustment absorbent coating may comprise, starting from the substrate: - optionally a lower dielectric coating, - an absorbent layer, - an upper dielectric coating.

[0085] The colorimetrically adjustable absorbent coating may comprise, starting from the substrate: - optionally a lower dielectric coating, - an absorbent layer, - an intermediate dielectric coating, - an absorbent layer, - an upper dielectric coating.

[0086] The dielectric coatings of the colorimetrically adjustable absorbent coating may satisfy one or more of the following characteristics: - the intermediate or upper dielectric coating comprises a high index layer with a refractive index, in increasing order of preference, greater than 1, 85, greater than 1.90, greater than 2.00, greater than 2.10, greater than 2.20, and/or - the intermediate or upper dielectric coating comprises a low index layer with an index of refraction, in order preferably increasing, less than 1.75, less than 1.60, or less than 1.50 and/or - the intermediate or upper dielectric coating comprises a sequence of at least two dielectric layers, wherein the variation of the refractive index between at least two layers is, in increasing order of preference, greater than 0.2, greater than 0.4, greater than 0.5, greater than 0.6, greater than 0.7, greater than 0.8 and/ or - the intermediate or upper dielectric coating comprises a sequence of at least two dielectric layers where: - a low index layer has a refractive index of less than 1.75, preferably less than 1.60, including less than 1.50 and - a high index layer has an index of refraction, in ascending order of preference, greater than 1.85, greater than 1.90, greater than 2.00 greater than 2.10, greater than 2.20, greater than 2.30 and/or - the intermediate or upper dielectric coating comprises a low index layer situated below a high index layer, and/or - the lower dielectric coating comprises a high index layer having a refractive index, e.g. ascending order of preference, greater than 1.85, greater than 1.90, greater than 2.00, greater than 2.10, greater than 2.20, and/or - the lower dielectric coating comprises a low index layer that has a refractive index, in increasing order of preference, of less than 1.75, less than 1.60, or less than 1.50 and/or - the lower dielectric coating comprises a sequence of at least two dielectric layers, wherein the variation in the refractive index between at least two layers is, in increasing order of preference, greater than 0.2, greater than 0.4, greater than 0.5, greater than 0.6, greater than 0.7, greater to 0.8 and/or - the lower dielectric coating comprises a sequence of at least two dielectric layers where: - a high index layer has a refractive index, in ascending order of preference, greater than 1.85, greater than 1 .90, greater than 2.00, greater than 2.10, greater than 2.20, - a low index layer has a refractive index of less than 1.75, preferably less than 1.60, even less than 1 .50, and/or - the lower dielectric coating comprises a high index layer situated below a low index layer.

[0087] High refractive index layers preferably have a refractive index strictly greater than 1.85, greater than 1.90, strictly greater than 2.00, and even preferably greater than or equal to 2. 30. These layers may be based on titanium oxide or mixed titanium oxide and another component chosen from the group consisting of Zn, Zr and Sn, or based on zirconium oxide or based on niobium oxide or based on mixed silicon and zirconium nitride, or based on mixed silicon, zirconium and aluminum nitride.

[0088] The high index layers according to the invention can be chosen from: - a layer of zinc oxide (index for 550 nm: about 1.95), - a layer of zinc and tin oxide (index for 550 nm: approx. 2.04), - a layer of silicon nitride Si3N4 (index for 500 nm: approx. 2.06) - a layer of tungsten oxide WÜ3 (index for 550 nm: approx. 2.15 ), - a layer of manganese oxide MnO (index for 550 nm: approximately 2.16), - a layer of silicon and zirconium nitride (index for 550 nm: between approximately 2.15 and 2.55 ), - a layer of niobium oxide Nb2O5 (index for 550 nm: approx. 2.30), - a layer of titanium oxide TiO2 (index for 500: approx. 2.45), - a layer of zirconium nitride Zr3N4 (index for 550 nm: about 2.55), - a layer of bismuth oxide Bi2O3 (index for 550 nm: about 2.60).

[0089] The low refractive index layers are essentially made of silicon oxide.

[0090] The choice of an absorbent layer also adds flexibility to the design, removing the degeneration of spectra in reflection on each side of a non-absorbent coating.

[0091] The material according to the invention can also comprise various colorimetric adjustment coatings. According to this embodiment, the material has at least two colorimetric adjustment coatings comprising an absorbent layer, each located on different faces of one of the substrates, with the exception of the face or faces coated with the functional coating.

[0092] To obtain a pane of glass that belongs to a certain light transmission range, we choose a functional coating that belongs to a higher light transmission range to which we add the colorimetrically adjustable absorbent coating.

[0093] The functional coating may comprise one or more metallic functional layers, preferably silver-based, each disposed between two dielectric coatings. The functional coating may especially comprise one, two, three or four metallic functional layers. According to these embodiments: - the functional coating comprises at least one silver-based functional metallic layer, or - the functional coating comprises at least two silver-based functional metallic layers, or - the functional coating comprises at least least three silver-based functional metallic layers.

[0094] The silver-based metallic functional layers comprise at least 95.0%, preferably at least 96.5% and preferably at least 98.0% by mass of silver relative to the mass of the functional layer. Preferably, a silver-based functional metal comprises less than 1.0% by mass of metals other than silver relative to the mass of the silver-based functional metal.

[0095] Preferably, the thicknesses of the functional metal layers increase from the substrate. The increase in thickness between two successive functional layers is greater than 0.8 nm, greater than 1 nm, greater than 2 nm, greater than 3 nm, or greater than 4 nm.

[0096] According to advantageous embodiments of the invention, the functional metallic layers satisfy one or more of the following conditions: - the thickness ratio between two successive functional layers is between 1.05 and 2.30, including these values, - the thickness of each functional metallic layer is between 6 and 20 nm.

[0097] The stack may additionally comprise at least one blocking layer located in contact with a functional metal.

[0098] Blocking layers traditionally have the function of protecting the functional layers from possible degradation during the deposition of the upper anti-reflective coating and during any high-temperature heat treatment, such as annealing, bending and/or tempering.

[0099] The blocking layers are chosen from metallic layers based on a metal or a metallic alloy, metallic nitride layers, metallic oxide layers and metallic oxynitride layers of one or more elements chosen from titanium , nickel, chromium and niobium, for example a layer of Ti, TiN, TiOx, Nb, NbN, Ni, NiN, Cr, CrN, NiCr, NiCrN. When these blocking layers are deposited in metallic, nitrided or oxynitrided form, they can undergo partial or total oxidation depending on their thickness and the nature of the layers that surround them, for example, at the time of deposition of the next layer or by oxidation. in contact with the underlying layer.

[0100] According to advantageous embodiments of the invention, the blocking layer or layers satisfy one or more of the following conditions: - each functional metallic layer is in contact with at least one blocking layer chosen from a blocking sublayer and a blocking overlayer, and/or - each functional metallic layer is in contact with a blocking overlayer, and/or - the thickness of each blocking layer is at least 0.1 nm, preferably comprised between 0.2 and 2 ,0nm.

[0101] According to the invention, the blocking layers are considered not to form part of a dielectric coating. This means that its thickness is not taken into account for the purpose of calculating the optical thickness of the dielectric coating that is located in contact with it.

[0102] By “dielectric layer” in the sense of the present invention, it must be understood that, from the point of view of its nature, the material is “non-metallic”, that is, it is not a metal. In the context of the invention, this term designates a material with an n/k ratio across the entire visible wavelength range (from 380 nm to 780 nm) equal to or greater than 5.

[0103] The dielectric layers of the coatings have the following characteristics, alone or in combination: - they are deposited by magnetic field-assisted sputtering, - they are chosen from oxides or nitrides of one or more elements chosen from titanium , silicon, aluminum, zirconium, tin and zinc, - they have a thickness greater than 2 nm, preferably between 4 and 100 nm. According to advantageous embodiments of the invention, the dielectric coatings of the functional coatings satisfy one or more of the following conditions: - the dielectric layers may be based on oxide or nitride of one or more elements chosen from silicon, zirconium, titanium, aluminum, tin, zinc, and/or - at least one dielectric coating has at least one dielectric layer with a barrier function, and/or - each dielectric coating has at least one dielectric layer with a barrier function, and/or - the dielectric layers with barrier function are based on silicon and/or aluminum compounds chosen from oxides such as SiO2 and AI2O3, silicon nitrides Si3N4 and AIN and oxynitrides SiOxNy and AIOxNy, based on zinc and tin oxide or based on titanium oxide, - the dielectric layers with barrier function are based on silicon and/or aluminum compounds, optionally comprising at least one other element, such as aluminum, hafnium and zirconium, and/or - at least one dielectric coating comprises at least one dielectric layer with a stabilizing function, and/or - each dielectric coating comprises at least one dielectric layer with a stabilizing function, and/or - the dielectric layers with a stabilizing function are, preferably based on an oxide chosen from zinc oxide, tin oxide, zirconium oxide or a mixture of at least two of them, and/or - the dielectric layers with a stabilizing function are preferably at based on a crystallized oxide, especially based on zinc oxide, optionally doped with at least one other element, such as aluminum, and/or - each functional layer is above a dielectric coating whose upper layer is a dielectric layer with function stabilizer, preferably based on zinc oxide and/or below a dielectric coating whose lower layer is a dielectric layer with a stabilizing function, preferably based on zinc oxide.

[0104] Preferably, each dielectric coating consists exclusively of one or more dielectric layers. Preferably, therefore, there is no absorbent layer in the dielectric coatings in order not to reduce light transmission.

[0105] If a dielectric coating of a functional coating comprises an absorbent layer for which the refractive index for 550 nm comprises an imaginary part of the non-zero (or non-negligible) dielectric function, for example, a metallic layer, the thickness of this layer is not taken into account for the purpose of calculating optical thickness.

[0106] Dielectric layers can exhibit a barrier function. Dielectric layers with barrier function (hereinafter barrier layer) are understood as a layer in a material capable of forming a barrier against the diffusion of oxygen and water at high temperature, originating from the ambient atmosphere or the transparent substrate, to the layer functional. Such dielectric layers are chosen from the following layers: - based on silicon and/or aluminum compounds chosen from oxides such as SiO2 and AI2O3, nitrides such as nitrides such as Si3N4 and AIN, and oxynitrides such as SiOxNy, AlOxNy optionally doped with at least one other element, - based on zinc and tin oxide, - based on titanium oxide.

[0107] Preferably, each coating has at least one dielectric layer consisting of: - a nitride or an oxynitride of aluminum and/or silicon, or - a mixed oxide of zinc and tin, or - a titanium oxide .

[0108] These dielectric layers have a thickness: - less than or equal to 40 nm, less than or equal to 30 nm or less than or equal to 25 nm, and/or - greater than or equal to 5 nm, greater than or equal to 10 nm or greater than or equal to 15 nm.

[0109] The functional coatings of the invention may contain dielectric layers with a stabilizing function. In the sense of the invention, “stabilizing” means that we select the nature of the layer so as to stabilize the interface between the functional layer and this layer. This stabilization reinforces the adhesion of the functional layer to the surrounding layers, and in fact it will oppose the migration of its constituent material.

[0110] The dielectric layer or layers with a stabilizing function may be directly in contact with a functional layer or separated by a blocking layer.

[0111] Preferably, the last dielectric layer of each dielectric coating located below a functional layer is a dielectric layer with a stabilizing function. In fact, it is advantageous to have a layer with a stabilizing function, for example based on zinc oxide, below a functional layer, because it facilitates the adhesion and crystallization of the silver-based functional layer and increases its quality and stability in high temperature.

[0112] It is also advantageous to have a layer with a stabilizing function, for example based on zinc oxide, above a functional layer, to increase adhesion and adequately oppose diffusion from the side of the stack opposite the substrate.

[0113] The dielectric layer(s) with stabilizing function may therefore be located above and/or below at least one functional layer or each functional layer, either in direct contact or separated by a blocking layer.

[0114] Advantageously, each dielectric layer with a barrier function is separated from a functional layer by at least one dielectric layer with a stabilizing function.

[0115] The zinc oxide layer may eventually be doped with at least one other element, such as aluminum. Zinc oxide is crystallized. The zinc oxide-based layer comprises, in ascending order of preference, at least 90.0%, at least 92%, at least 95%, at least 98.0% by mass of zinc relative to the mass of other elements other than oxygen in the zinc oxide-based layer.

[0116] Preferably, the dielectric coatings of the functional coatings comprise a zinc oxide-based dielectric layer located below and directly in contact with the silver-based metallic layer.

[0117] The zinc oxide layers have, in increasing order of preference, a thickness: - of at least 3.0 nm, of at least 4.0 nm, of at least 5.0 nm, and/or - of maximum 25 nm, maximum 10 nm, maximum 8.0 nm.

[0118] The functional coating may eventually comprise a top protective layer. The upper protective layer is preferably the last layer of the stack, i.e. the layer furthest from the coated substrate of the stack. These upper protective layers are considered to be comprised of the last dielectric coating. These layers generally have a thickness of between 2 and 10 nm, preferably 2 and 5 nm.

[0119] The protective layer can be chosen from a layer of titanium, zirconium, hafnium, zinc and/or tin, this or these metals being in metallic, oxidized or nitrided form. Advantageously, the protective layer is a titanium oxide layer, a zinc tin oxide layer or a titanium zirconium oxide based layer.

[0120] A particularly advantageous embodiment refers to a coated substrate with a defined stack, starting from the transparent substrate, as containing: - a first dielectric coating containing at least one layer with a barrier function and a dielectric layer with a stabilizing function, - optionally a blocking layer, - a first functional layer, - optionally a blocking layer, - a second dielectric coating containing at least one dielectric layer with a stabilizing function and a layer with a barrier function, - optionally a protective layer.

[0121] Another particularly advantageous embodiment refers to a coated substrate with a defined stack, starting from the transparent substrate, which comprises: - a first dielectric coating containing at least one layer with a barrier function and a dielectric layer with a stabilizing function , - optionally a blocking layer, - a first functional layer, - optionally a blocking layer, - a second dielectric coating containing at least a lower dielectric layer with a stabilizing function, a layer with a barrier function and an upper dielectric layer with a stabilizing layer, - optionally a blocking layer, - a second functional layer, - optionally a blocking layer, - a third dielectric coating containing at least one dielectric layer with a stabilizing function, a layer with a barrier function, - optionally a protective layer .

[0122] Another particularly advantageous embodiment refers to a coated substrate with a defined stack, starting from the transparent substrate, which comprises: - a first dielectric coating containing at least one layer with a barrier function and a dielectric layer with a stabilizing function , - optionally a blocking layer, - a first functional layer, - optionally a blocking layer, - a second dielectric coating containing at least a lower dielectric layer with a stabilizing function, a layer with a barrier function and an upper dielectric layer with a stabilizing layer, - optionally a blocking layer, - a second functional layer, - optionally a blocking layer, - a third dielectric coating containing at least one lower dielectric layer with a stabilizing function, a layer with a barrier function, an upper dielectric layer with stabilizing function, - optionally a blocking layer, - a third functional layer, - optionally a blocking layer, - a fourth dielectric coating containing at least one dielectric layer with a stabilizing function, a layer with a barrier function, - optionally a layer of protection.

[0123] The transparent substrates according to the invention are preferably produced from a rigid mineral material, such as glass, or organic polymer-based (or polymer) material.

[0124] The organic transparent substrates according to the invention can also be produced in rigid or flexible polymers. Examples of suitable polymers according to the invention include, in particular: - polyethylene, - polyesters such as polyethylene terephthalate (PET), polyethylene butylene terephthalate (PBT), polyethylene naphthalate (PEN); - polyacrylates such as polymethyl methacrylate (PMMA); - polycarbonates; - polyurethanes; - polyamides; - polyimides; - fluorinated polymers such as fluoroesters, such as ethylene tetrafluoroethylene (ETFE), polyvinylidene fluoride (PVDF), polychlorotrifluoroethylene (PCTFE), chlorotrifluoroethylene ethylene (ECTFE), fluorinated ethylene-propylene copolymers (FEP); - photocrosslinkable and/or photopolymerizable resins, such as thiolene, polyurethane, urethane-acrylate, polyester-acrylate resins and - polythiourethanes.

[0125] The substrate is preferably a glass or glass-ceramic sheet.

[0126] The substrate is preferably transparent, colorless (this is clear or extra-clear glass) or colored, for example blue, gray or bronze. The glass is preferably of the silica-soda-lime type, but it can also be a borosilicate or alumino-borosilicate type glass.

[0127] The light transmission (TL) of common soda-lime glass substrates, without stacking, is greater than 89%, preferably 90%.

[0128] A common clear glass 4 to 6 mm thick has the following luminous characteristics: - a light transmission of between 89 and 91.5%, - a light reflection of between 7 and 9.5%, - a light absorption between 0.3 and 3%.

[0129] According to a preferred embodiment, the substrate is glass, especially silica-soda-lime or an organic polymeric substance.

[0130] The substrate advantageously has at least one dimension greater than or equal to 1 m, 2 m and even 3 m. The thickness of the substrate generally varies between 0.5 mm and 19 mm, preferably between 0.7 and 9 mm, especially between 2 and 8 mm, even between 4 and 6 mm. The substrate can be flat or domed, even flexible.

[0131] The material, i.e. the coated substrate of the functional coating, may be subjected to a high temperature heat treatment such as annealing, for example an instantaneous annealing such as laser or flame annealing, quenching and/or a curvature. The heat treatment temperature is greater than 400°C, preferably greater than 450°C, and preferably greater than 500°C. The coated substrate of the functional coating may therefore be dished and/or tempered.

[0132] The glazing is preferably chosen from multiple glazing, especially a double glazing or a triple glazing.

[0133] According to advantageous embodiments, the glazing of the invention in the form of a double glazing containing the functional coating positioned on face 2 makes the following efficiencies particularly possible: - a solar factor g less than or equal to 40%, less than 30%, preferably less than or equal to 29% and/or - a light transmission, between 25 and 70%, between 40% and 70%, between 40% and 60% or between 50 and 60 % and/or - a high selectivity, in increasing order of preference, of at least 1.6, and/or - a variable reflection of light on the external side, especially in some applications less than or equal to 25%, but for other applications greater than or equal to 25%, and/or - a reflection of light on the internal side less than or equal to 25%, preferably less than or equal to 15%, and/or - values of a* and b* in the external reflection comprising, for example, ascending order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1, and/or - values of a* and b* in internal reflection comprised, in ascending order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1, and/or - values of a* and b* in the transmission comprised, in increasing order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1 .

[0134] The details and advantageous features of the invention will emerge from the non-limiting examples that follow.

EXAMPLES I. NATURE OF LAYERS AND COATINGS

[0135] The functional coatings defined below are deposited on 4 mm thick clear soda-lime glass substrates.

[0136] The functional metallic layers (CF) are silver (Ag) layers. The blocking layers are metallic layers in a nickel and chromium alloy (NiCr). The dielectric coatings of functional coatings comprise barrier layers and stabilizing layers. The barrier layers are based on silicon nitride, doped with aluminum (Si3N4: Al) or based on mixed zinc and tin oxide (SnZnOx). The stabilizing layers are zinc oxide (ZnO). The protective layers are made of titanium oxide (TiOx).

[0137] The absorbent layers of the colorimetric adjustment absorbent coatings tested are nickel and chromium metallic layers, tin and zinc metallic layers, zinc and tin nitride layers, niobium nitride layers, titanium nitride layers.

[0138] The dielectric coatings of colorimetric adjustment absorbent coatings comprise: - silicon oxide layers that correspond to the low index layers, - titanium oxide layers and silicon nitride layers that correspond to the high index layers.

[0139] The deposition conditions of the layers, which were deposited by spraying (called “magnetron-type cathodic” spraying), are summarized in table 1

II. COLORIMETRIC ADJUSTMENT ABSORBENT COATINGS

[0140] Table 2 below summarizes the characteristics linked to the thicknesses of the absorbent layers and dielectric layers that constitute the dielectric coatings of colorimetric adjustment absorbent coatings.

[0141] The thicknesses of the absorbent layers and dielectric layers are physical thicknesses.

III. FUNCTIONAL COATINGS

[0142] Functional coatings providing solar control properties were deposited using a magnetic field-assisted sputtering device (magnetron).

[0143] The first functional coating, hereinafter referred to as RF1, is an Ag bilayer, comprising successively from the substrate an alternation of two silver layers (functional metallic layers) and three dielectric coatings, each dielectric coating including at least one dielectric layer , so that each functional metallic layer is arranged between two dielectric coatings. The total thickness of this functional coating is between 150 and 200 nm.

[0144] The second functional coating, hereinafter referred to as RF2, is an Ag bilayer, comprising a stack including successively from the substrate an alternation of two silver layers and three dielectric coatings, each dielectric coating including several dielectric layers, so that each silver layer is placed between two dielectric coatings. The total thickness of this functional coating is between 150 and 200 nm.

[0145] The third functional coating, hereinafter referred to as RF 3, is an Ag trilayer, successively comprising from the substrate an alternation of three silver layers (functional metallic layers) and four dielectric coatings, each dielectric coating including at least one layer dielectric, so that each functional metallic layer is arranged between two dielectric coatings. The total thickness of this functional coating is between 200 and 250 nm.

[0146] Table 3 below lists the main optical characteristics of materials comprising a transparent substrate, one side of which is coated with one of the functional coatings RF1, RF2 or RF3 assembled in the form of double glazing with the structure 6/16/ 4: 6 mm glass / 16 mm insert space filled with 90% argon and 10% air / 4 mm glass, the functional coating being positioned on face 2.

IV. CONFIGURATION OF DOUBLE GLAZING AND LAMINATED GLASS

[0147] Materials comprising a transparent substrate, in which one side of the substrate is coated with a functional coating, were assembled in the form of double glazing or in the form of laminated glazing.

[0148] Double glazing, hereinafter “DGU” configuration, has a 6/16/4 structure: 6 mm glass / 16 mm insert space filled with 90% argon and 10% air / 4 mm glass, the functional coating being positioned on face 2. The colorimetrically adjustable absorbent coating of the invention, when it is present, is positioned on face 1 or face 3.

[0149] Laminated panes, hereinafter “Lam.” configuration, have a first substrate / sheet(s) / second substrate structure. The functional coating is positioned on face 2 and the color-adjustable absorbent coating is positioned on face 1 or 3.

V. EFFICIENCY OF “SOLAR CONTROL” AND COLORIMETRY

[0150] Table 3 below lists the main optical characteristics of materials comprising a transparent substrate, one of which is coated with a functional coating, assembled in the form of multiple panes or laminated panes and optionally a colorimetrically adjustable absorbent coating. .

[0151] Comparing lnv.2 and Ref.1, it is noted that we obtain, from a high TL functional coating (Ref. 1 with RF1), a glazing with a light transmission, an internal and external reflection close to the of a pane of glass with an average TL (Ref. 2 with RF2), but with much more neutral colors.

[0152] Through the invention, it is also possible to modulate the TL. In effect, from a pane containing a functional coating of high TL (Ref. 1 with RF1), we obtain a range of pane without TL restriction, for example, between 60% and 30% (Inv. 1 to Inv. 4 ) and still preserving excellent neutrality.

[0153] Due to the invention, it is also possible to modulate the reflection colors and obtain, from a pane containing a high TL functional coating (Ref. 1 with RF1), a whole range of pane that displays any color whatsoever, especially blue, bronze or neutral, as we can see in table 4.

[0154] The neutralization layer can be placed on any face of the glass without a functional coating, such as, for example, face 1 (Inv. 1 to 6) or face 3 (Inv. 7).

[0155] The material can be installed in a DGU (Inv1 to 7) or laminated (Inv. 8 and Inv. 9) configuration or in any other configuration (triple glazing, laminated double glazing, etc.).

[0156] The invention is not restricted to the use of high TL stacks as functional coatings, nor to functional coatings with two layers of silver. Inv. 10 presents, for example, the case of a pane of glass with a very low TL (5%), obtained according to the invention using a functional coating with three layers of silver with intermediate light transmission (50%).

Claims (27)

1. Material comprising one or more transparent substrates, each substrate comprising two main faces, characterized by the fact that: - one of the faces of one of the substrates is coated with a functional coating capable of acting on solar radiation and/or infrared radiation containing at least one silver-based metallic (sic) functional layer, each disposed between two dielectric coatings, and - a face not coated with the functional coating of one of the substrates has a colorimetrically adjustable absorbent coating that contains, from the substrate: - an absorbent layer that absorbs solar radiation in the visible part of the spectrum, - a top dielectric coating. 2. Material, according to claim 1, comprising a transparent substrate that has two main faces, characterized by the fact that: - one of the faces of the substrate is coated with a functional coating capable of acting on solar radiation and/or infrared radiation, - the other side of the substrate is coated with a colorimetrically adjustable absorbent coating comprising an absorbent layer that absorbs solar radiation in the visible part of the spectrum. 3. Material, according to claim 1, containing: - a transparent substrate comprising two main faces, wherein one of the faces of the substrate is coated with a functional coating capable of acting on solar radiation and/or infrared radiation, and - an additional substrate containing at least two main faces, characterized by the fact that: at least one face not coated with the functional coating of one of the substrates has a colorimetrically adjustable absorbent coating comprising an absorbent layer that absorbs solar radiation in the visible part of the spectrum, said face is chosen from: - the other uncoated face of the substrate coated with a functional coating, - one of the faces of an additional substrate. 4. Material according to any one of the preceding claims, characterized in that the absorbent layer is a layer of a material that has an n/k ratio between 0 and 5, excluding these values, by at least 60% of the visible wavelength range (from 380 nm to 780 nm). 5. Material according to any one of the preceding claims, characterized by the fact that the light absorption due to the absorbing layer, measured on the side of the glass by depositing only this absorbing layer confined between two non-absorbing dielectric layers on a common clear glass of 4 mm to 6 mm thickness, measured, is greater than 5%. 6. Material according to any of the preceding claims, characterized in that the absorbent layer is chosen from: - layers based on one or more metals and/or metalloids, - nitride layers of one or more metals and/or metalloids, - the oxynitride layers of one or more metals and/or metalloids, of elements chosen from palladium, niobium, tungsten, iron especially stainless steel, titanium, chromium, molybdenum, zirconium, nickel, tantalum, zinc, tin and silicon. 7. Material according to any of the preceding claims, characterized in that the absorbent layer is chosen from a nickel and/or chromium nitride layer, a titanium nitride layer, a niobium nitride layer or a silicon-based layer. 8. Material according to any of the previous claims, characterized in that the absorbent layer has a thickness between 0.1 and 20 nm. 9. Material according to any one of the preceding claims, characterized in that the colorimetrically adjustable absorbent coating comprises a dielectric coating and an absorbent layer. 10. Material according to any one of the preceding claims, characterized in that the colorimetrically adjustable absorbent coating comprises, starting from the substrate: - a lower dielectric coating, - an absorbent layer, - an upper dielectric coating. 11. Material according to any one of the preceding claims, characterized in that the colorimetrically adjustable absorbent coating comprises, starting from the substrate: - a lower dielectric coating, - an absorbent layer, - an intermediate dielectric coating, - a layer absorbent, - a superior dielectric coating. 12. Material according to any one of claims 10 to 11, characterized in that the lower dielectric coating comprises a high index layer having a refractive index greater than 1.85. 13. Material according to any one of claims 10 to 12, characterized in that the lower dielectric coating comprises a sequence of at least two dielectric layers whose refractive index variation is greater than 0.2. 14. Material according to any one of claims 10 to 13, characterized in that the lower dielectric coating comprises a sequence of at least two dielectric layers in which: - a low index layer has a refractive index of less than 1 .75, and - a high index layer has a refractive index greater than 1.85. 15. Material according to any one of claims 10 to 13, characterized in that the upper or intermediate dielectric coating comprises a high index layer with a refractive index greater than 1.85 and/or a low index layer with a refractive index of less than 1.75. 16. Material according to any one of the preceding claims, characterized in that the functional coating comprises one or more metallic functional layers, each disposed between two dielectric coatings. 17. Material according to any of the preceding claims, characterized in that the substrate is glass, especially silica-soda-lime, or an organic polymeric substance. 18. Material, according to any of the previous claims, characterized by the fact that the colorimetrically adjustable absorbent coating is positioned on face 1 and the functional coating capable of acting on solar radiation and/or infrared radiation is positioned on face 2. 19. Material according to any one of the preceding claims, characterized by the fact that it comprises at least two colorimetric adjustment coatings comprising an absorbent layer, each located on different faces of one of the substrates, with the exception of the face(s) coated with the functional coating. 20. Glazing containing a material, as defined in any one of claims 1 to 19, characterized by the fact that it is in the form of monolithic, laminated and/or multiple glazing. 21. Multiple glazing, according to claim 20, characterized by the fact that, when the material is assembled into a double glazing with the functional coating positioned on face 2, the double glazing presents: - a light transmission comprised between 40 and 60%, - values of a* and b* in external reflection comprised, in increasing order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1, - values of a* and b* in internal reflection comprised, in increasing order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between -2 and +2, between -1 and +1, - values of a* and b* in the transmission comprising, in increasing order of preference, between -5 and +5, between -4 and +4, between -3 and +3, between - 2 and +2, between -1 and +1. 22. Multiple glazing, according to claim 20, characterized by the fact that, when the material is assembled into a double glazing with the functional coating positioned on face 2, the double glazing presents: - values of a* in external reflection comprised, in increasing order of preference, between -10 and -3, - values of b* in external reflection comprised, in increasing order of preference, between -20 and -10. 23. Multiple glazing, according to claim 20, characterized by the fact that, when the material is mounted in a double glazing with the functional coating positioned on face 2, the double glazing presents values of a* and b* in the external reflection comprised, in ascending order of preference, between 5 and 20. 24. Multiple glazing according to any one of claims 20 to 23, characterized in that it comprises a material and at least one second substrate, wherein the material and the additional substrate are separated by at least one interlayer gas sheet. 25. Laminated glazing according to claim 20, characterized in that it comprises a material and at least one additional substrate, wherein the material and the additional substrate are separated by at least one lamination insert. 26. Laminated and multiple glazing according to claim 20, characterized in that it comprises a material and at least two additional substrates corresponding to a second substrate and a third substrate, wherein the material and the third substrate are separated by at least one interlayer gas blade, and - the material and the second substrate or - the second substrate and the third substrate, are separated by at least one lamination insert. 27. Multiple and/or laminated glazing, according to any one of claims 20 to 26, characterized by the fact that the colorimetrically adjustable absorbent coating is positioned on face 1 and the functional coating capable of acting on solar radiation and/or The infrared radiation is positioned on face 2 or 3.