EP4225837A1 - Transparent conductive film and use of same - Google Patents

Abstract

The invention relates to a transparent conductive film, comprising a transparent substrate, wherein a conductive metallization is formed on the main surface thereof in the form of a close-meshed, continuous network with a plurality of openings having different geometric shapes, wherein the transparent conductive film is additionally provided with a full-area transparent coating reflecting IR radiation.

Description

Transparent conductive film and use of the same

The invention relates to a transparent, conductive film and uses thereof.

Transparent, conductive films that are suitable, for example, for equipping the windshield of a vehicle have been described in the prior art, see, for example, EP 2764996 B1, EP 2284134 B1 and WO 2016/192858 A1. According to WO 2016/192858 A1, a transparent, conductive film is produced on the basis of a multi-stage process in which a washable coating is first applied to a transparent carrier substrate and, when it dries, forms numerous cracks in the form of a dense, cohesive network. This is followed by metal sputtering, followed by removal of the cracked, washable coating in a washing step. The product obtained is such that it has a transparent, conductive metallization in the form of a densely meshed, coherent network above the carrier substrate.

In practice, it has been shown that transparent, conductive films with additional, advantageous properties are desirable. In particular, measures are desirable through which excessive heating of the interior of a motor vehicle could be avoided. Furthermore, it was found that the electrical conductivity of the previously known transparent, conductive films is insufficient. A high electrical conductivity is particularly advantageous in the case of transparent, conductive electrodes for heating windows in motor vehicles and for operating LED foils with a high component density. Next in particular, it was found that especially with Kuper-based Metallizations, the reddish color impression of the metal on a transparent foil is visually striking and therefore disturbing for the viewer. In the case of other metals, such as aluminum or silver, a highly reflective metal surface can be seen when viewed in reflected or transmitted light, primarily as a gloss at the specular angle. It would therefore be desirable to provide a transparent, conductive film that has a neutral color impression compared to the previously known films.

The object of providing a transparent, conductive film that has at least one of the additional, advantageous properties mentioned above is achieved by the combinations of features defined in the independent claims. Developments of the invention are the subject matter of the dependent claims.

Summary of the Invention

1. (First aspect of the invention) Transparent, conductive film, comprising a transparent substrate, on the main surface of which a conductive metallization in the form of a densely meshed, coherent network with a large number of openings of different geometric shape is formed, the transparent, conductive film additionally having is provided with a full-surface, transparent, IR-radiation reflecting layer.

2. (Preferred embodiment) Transparent, conductive film according to paragraph 1, wherein the full-area, transparent, IR radiation-reflecting layer is arranged between the transparent substrate and the conductive metallization in the form of a densely meshed, coherent network.

3. (Preferred embodiment) Transparent, conductive foil according to paragraph 1, wherein the conductive metallization is arranged in the form of a close-meshed, cohesive network between the transparent substrate and the full-area, transparent, IR-radiation-reflecting layer.

4. (Preferred embodiment) Transparent, conductive film according to paragraph 1, wherein the full-area, transparent, IR-radiation-reflecting layer is arranged on the side of the transparent substrate opposite the conductive metallization in the form of a dense-meshed, cohesive net.

5. (Preferred embodiment) Transparent, conductive film according to one of paragraphs 1 to 4, wherein the full-area, transparent, IR radiation-reflecting layer is electrically conductive.

6. (Preferred embodiment) Transparent, conductive film according to paragraph 5 with reference to claim 2 or 3, wherein the conductive metallization in the form of a densely meshed, coherent network and the electrically conductive, full-area, transparent, IR radiation-reflecting layer are electrically conductively connected to one another are.

7. (Preferred embodiment) Transparent, conductive foil according to one of paragraphs 1 to 5, wherein the conductive metallization is embedded in an electrically insulating filling material in the form of a densely meshed, coherent net. 8. (Preferred embodiment) Transparent, conductive film according to one of paragraphs 1 to 7, wherein the transparent, conductive film has a first transparent substrate, on the main surface of which there is a conductive metallization in the form of a densely meshed, coherent network with a large number of openings of different geometrical configurations Form is formed, and having a second transparent substrate, the main surface of which is provided with a full-surface, transparent, IR radiation-reflecting layer, wherein the first substrate and the second substrate are connected to one another by means of an adhesive layer.

9. (Preferred embodiment) Transparent, conductive film according to one of paragraphs 1 to 8, wherein the full-area, transparent, IR radiation-reflecting layer is a metal layer or a metal oxide layer, in particular indium tin oxide (ITO) or aluminum-doped zinc oxide (AZO) or with Gallium-doped zinc oxide (GZO), or is based on a combination of a metal layer and a metal oxide layer.

10. (Preferred embodiment) Transparent, conductive film according to one of paragraphs 1 to 8, wherein the full-area, transparent, IR-radiation-reflecting layer also reduces the visual perceptibility of the conductive metallization in the form of a dense, coherent network and is based on a material, that of the group consisting of a metal or an alloy, preferably chromium, aluminum, nickel, iron, silicon, titanium or a combination of two or more of the above elements, a metal oxide layer, preferably chromium oxide or one based on copper oxide or on a substoichiometric aluminum oxide Metal oxide layer, with an anti-reflective thin-film structure in particular the layer sequence metal/dielectric/metal or the layer sequence dielectric/metal/dielectric/metal, black chrome, black nickel, a metal sulfide layer, an overprint based on a colored lacquer or a pigmented lacquer, an anti-reflection layer formed by a nanostructure or moth-eye structure and a combination of two or several of the above elements is selected.

11. (Preferred embodiment) Transparent, conductive film according to one of paragraphs 1 to 10, wherein the transparent, conductive film has two separate, full-surface, transparent, IR radiation-reflecting layers, each on the top and on the bottom of the conductive Metallization are arranged in the form of a dense, cohesive network.

12. (Preferred embodiment) Transparent, conductive foil according to one of paragraphs 1 to 11, wherein the conductive metallization in the form of a densely meshed, coherent network is based on copper, gold, silver or aluminum.

13. (Second aspect of the invention) Use of the transparent, conductive film according to one of paragraphs 1 to 12 for equipping the windscreen or other windows of a vehicle, in particular for heating, as electromagnetic shielding or as an antenna, furthermore as a transparent and possibly flexible electrode for solar cells or for use in smart windows, in displays or touch panels or touch buttons as well as LED or OLED applications. Detailed Description of the Invention

The present invention is based on the technology known from WO 2016/192858 A1 for the fine structuring of metallizations, on the basis of which electrical devices, e.g. films for use in the windshield of a vehicle, can be provided. The technology includes the use of a crack-forming coating, preferably a dispersion or solution of a polymer. The crack-forming coating is applied to the transparent substrate, e.g. by means of printing, so that a thin film is produced which forms cracks in the form of a dense-meshed, coherent network during drying. This is followed by metal sputtering, followed by removal of the cracked, washable coating in a washing step. The product obtained is such that it has, above the transparent substrate, a transparent, conductive metallization in the form of a close-meshed, coherent network.

The present invention is based on the finding that an IR-reflecting function of a transparent, conductive film based on a metal network can be achieved by additionally providing the film with a full-area, transparent, IR-radiation-reflecting layer. This is done in particular by means of a thin vapor-deposited and therefore optically transparent metal layer, by optically transparent metal oxides such as indium tin oxide (ITO), aluminum-doped zinc oxide (AZO) or gallium-doped zinc oxide (GZO), or by a combination of a thin metal layer and metal oxide layer. Furthermore, it was found that if a transparent, conductive film based on a metal network is provided with an electrically conductive, full-area, transparent layer that reflects IR radiation, a particularly advantageous electrical conductivity of the metal network can be achieved. The electrically conductive, full-surface, transparent layer ensures full-surface conductivity, while the metal network as the backbone ensures low surface resistance. Such a film is of particular advantage for various applications, for example with regard to the provision of transparent, conductive electrodes for organic photovoltaics and light-emitting diodes, as well as smart windows based on electrochromic and liquid-crystalline materials.

Furthermore, it was found that in the course of producing a metal network using a crack template according to the technology known from WO 2016/192858 A1, a uniform substrate is advantageous in order to ensure that crack formation is always the same. An electrically conductive, full-surface, transparent layer offers just such a uniform substrate, because crack formation is not always the same when different substrates are used, so that the formulation of the crack template would have to be adapted for the respective specific substrate.

An additional advantage can be achieved in that, in the case of special, full-area, transparent layers, a neutral color impression with low reflection can be brought about. In this way, the visually disturbing, reddish color impression of the metal can be avoided, particularly in the case of copper-based metal networks. The production of the products according to the invention can be carried out in a technically simple manner because the additional layers can be applied over the entire area above and/or below the metal network.

According to a preferred embodiment, the full-area, transparent, IR-radiation-reflecting layer is arranged between the transparent substrate and the conductive metallization in the form of a close-meshed, cohesive network.

According to a further preferred embodiment, the conductive metallization is arranged in the form of a close-meshed, cohesive network between the transparent substrate and the full-area, transparent, IR-radiation-reflecting layer.

According to a further preferred embodiment, the full-area, transparent, IR-radiation-reflecting layer is arranged on the side of the transparent substrate opposite the conductive metallization in the form of a densely meshed, cohesive net.

In the event that the full-area, transparent, IR-radiation-reflecting layer is electrically conductive, a transparent, conductive film with particularly high electrical conductivity can be achieved in that the conductive metallization in the form of a dense, cohesive network and the electrically conductive, full-area , transparent, IR radiation-reflecting layer are electrically conductively connected to each other. According to a special variant, the conductive metallization is embedded in an electrically insulating filling material in the form of a densely meshed, coherent network.

A metal layer or a metal oxide layer, in particular indium tin oxide (ITO) or aluminum-doped zinc oxide (AZO) or gallium-doped zinc oxide (GZO), or a combination of a metal layer and a metal oxide layer. With respect to the metal layer, the metal is preferably selected from the group consisting of aluminum, chromium, silver and an alloy comprising one or more of the above elements.

A material selected from the group consisting of a metal or an alloy, preferably chromium, aluminum, nickel, iron, silicon, titanium or a combination of two or more, is particularly suitable for achieving the advantageous effect of reducing the visual perceptibility of the metallic network of the above-mentioned elements, a metal oxide layer, preferably chromium oxide or a metal oxide layer based on copper oxide or a substoichiometric aluminum oxide, an antireflective thin-layer structure with in particular the layer sequence metal/dielectric/metal (e.g. a Cu/SiCb/Cr structure) or the layer sequence

dielectric/ metal/ dielectric/ metal (e.g. a SiCh/Cr/SiCh/ Al structure, a SiCL/ Cr/SiCb/ Cu structure or a SiCb/ Al/SiCL/ Cu structure), black chrome (ie black passivated chrome) , black nickel (ie black passivated nickel), a metal sulfide layer, an overprint based on a colored lacquer or a pigmented lacquer, an overprint formed by a nanostructuring or moth's eye structure antireflection layer and a combination of two or more of the above elements.

Antireflective thin film structures are known in the art, see for example Sang-Hwan Cho et al., Journal of the Korean Physical Society, Vol. 2 Aug 2009, 501-507.

Thin-film elements with a multi-layer structure with a dark-appearing nanostructured area (so-called

moth-eye structure) are known, for example, from EP 2453269 A1. An antireflection layer formed by nanostructuring is based in particular on a metal, e.g. Cu, a metal oxide, a nitride, a polymer or on a dielectric.

If necessary, the structure according to the invention can also be provided with a transparent coating that levels the layer structure, e.g. a UV-curing or heat-curing primer lacquer. The product thus obtained can then be provided with an adhesive layer, which is arranged, for example, on the side of the transparent substrate opposite the layer structure. The adhesive layer can alternatively be placed over the transparent leveling coating. A heat-seal lacquer, for example, is suitable as an adhesive layer. According to a special variant, the adhesive layer used, e.g. a heat-sealing lacquer, can be identical to the transparent coating used for leveling the layer structure.

The transparent substrate is in particular a glass substrate or a plastic film, eg a polyethylene terephthalate (PET) film. In order to achieve an advantageous conductivity, the conductive metallization is preferably chosen from a copper, gold, aluminum or silver layer.

The production of the products according to the invention is based on the production described in WO 2016/192858 A1.

According to the invention, a dispersion, more preferably a colloidal dispersion, is preferably used as the crack-forming coating. Particularly suitable are e.g conducting electrode based on highly interconnected Cu wire network", J. Mater. Chem. C, 2014, Volume 2, pages 2089-2094. See also the document US 10626279 B2. In addition, the crack-forming coating on a solution present The polymer solution is applied to the substrate, e.g. by printing, so that a thin polymer film is produced. The thin polymer film forms cracks during drying.

Crack formation depends on the choice of raw materials and the choice of substrate, the layer thickness of the crack-forming coating and the drying parameters. The line widths that can be achieved at the end of the manufacturing process are in the range from 0.5 μm to 50 μm, with the lines usually being so fine that they can only be recognized as lines when a magnifying glass is used. The human eye does not resolve the individual lines on the surface, but you can see one in reflected light (or reflection) as well as in transmitted light (or transmission). Difference compared to the untreated or bare film. Because the fine lines form an irregular, connected network, unwanted diffraction effects can be minimized. By varying the size of the island and the width of the crack, the reflectance or the light transmittance can be adjusted in a suitable manner.

The method of removing the cracked coating is advantageously by dissolving with a suitable solvent. The solvent is expediently selected in coordination with the coating. Typically the following solvents can be used: methyl acetate, ethyl acetate, propyl acetate, butyl acetate, methoxypropyl acetate, acetone, methyl ethyl ketone, methyl isobutyl ketone, cyclopentanone, cyclohexanone, methylene chloride, chloroform, toluene, xylene, methanol, ethanol, 2-propanol. Furthermore, acetals or mixtures of the aforementioned solvents can be used. Alternatively, the crack-forming coating can also be detached by infiltration. In this case, in addition to the solvents mentioned, it is also possible to use aqueous solutions, mixtures of solvents and water, optionally with surfactants, optionally with defoamers and other additives. The detachment or dissolution of the cracked coating can also be assisted by spray nozzles or else mechanically by brushes, rollers or by felts.

The metallization according to the invention in the form of a densely-meshed, cohesive network exhibits an electrical conductivity and an optical transmission which is comparable to a full-area ITO layer. The fine metallic lines can be used in combination with conventional embossing lacquers, conventional primer compositions and conventional heat-sealing lacquers and act as a reflector. Another aspect of the present invention is the use of the transparent, conductive film, e.g. as a heating film, in particular in the windshield of a vehicle, in other windows or in the glazing of buildings, and for coupling in electricity without visible leads, e.g. for use in EED films, in Solar cells, in smart glass applications, in OEEDs or in touch panels.

Further exemplary embodiments and advantages of the invention are explained below with reference to the figures, which are not shown to scale and proportions in order to improve clarity.

Show it:

FIG. 1 shows a transparent, conductive film according to a first exemplary embodiment in plan view;

FIG. 2 shows the transparent, conductive film according to the first exemplary embodiment in a cross-sectional view;

FIG. 3 shows a transparent, conductive film according to a second exemplary embodiment in a cross-sectional view;

FIG. 4 shows a transparent, conductive film according to a third exemplary embodiment in a cross-sectional view;

FIG. 5 shows a transparent, conductive film according to a fourth exemplary embodiment in a cross-sectional view; FIG. 6 shows a transparent, conductive film according to a fifth exemplary embodiment in a cross-sectional view;

FIG. 7 shows a transparent, conductive film according to a sixth exemplary embodiment in a cross-sectional view;

FIG. 8 shows a transparent, conductive film according to a seventh exemplary embodiment in a cross-sectional view; and

FIG. 9 shows a transparent, conductive film according to an eighth exemplary embodiment in a cross-sectional view.

FIG. 1 illustrates a transparent, conductive film 1 according to a first exemplary embodiment in a plan view. A transparent, conductive, copper-based metallization can be seen in the form of a densely meshed, coherent network.

FIG. 2 shows the transparent conductive film 1 according to the first embodiment in a cross-sectional view (along the dashed line A-A′ shown in FIG. 1). The film 1 is based on a transparent substrate 2, in the present case a polyethylene terephthalate (PET) film, which is provided with a full-surface, IR-reflecting layer 3 made of indium tin oxide (ITO) with a thickness in a range from 50 nm to 300 nm . Above the full-area, IR-reflecting layer is a copper-based metallization 4 in the form of a dense, cohesive network. The metallization 4 is produced in accordance with WO 2016/192858 A1 known methods. Accordingly, the IR-reflecting layer 3 is first provided with a crack-forming coating, which is based, for example, on dispersions of SiCh nanoparticles or of acrylic resin nanoparticles. The crack-forming coating is preferably applied by printing, for example by means of gravure printing, flexographic printing or by means of an inkjet process. When drying, the crack-forming coating develops numerous cracks in the form of a dense, coherent network. In a further step, a conductive Cu layer is vapor-deposited, which is deposited both above the cracked coating and within the cracks in the coating. The cracked coating, including the Cu layers above the coating, is then removed in a washing step. Washing is done by dissolving with a suitable solvent, eg methyl acetate. On the IR-reflecting indium tin oxide (ITO) layer 3 remains a transparent, conductive Cu metallization 4 in the form of a dense, cohesive network. The transparent, conductive film 1 is particularly advantageous as a result of its IR-reflecting function and is suitable, for example, for use in window glass in the automotive sector, in order to prevent the vehicle interior from heating up.

FIG. 3 shows a transparent, conductive film 5 according to a second exemplary embodiment in a cross-sectional view. In the present case, the transparent substrate 2, ie the polyethylene terephthalate (PET) film, is provided on its upper side with a copper-based metallization 4 in the form of a dense, cohesive network, with the underside of the transparent substrate 2 having a full-area IR - Reflective layer 3 is located. In the present exemplary embodiment, the IR-reflecting layer 3 is a thin Ag layer with a thickness μm Range from 1 nm to 20 nm, which, in addition to its IR-reflecting function, also ensures full-surface conductivity. Compared to the Ag layer 3, the metal network 4 has a low sheet resistance. The transparent, conductive film 5 is advantageous if an IR-reflecting function is desired, but no direct contact of the IR-reflecting layer with the dense, cohesive network.

FIG. 4 shows a transparent, conductive film 6 according to a third exemplary embodiment in a cross-sectional view. In the present case, the transparent substrate 2, i.e. the polyethylene terephthalate (PET) film, is initially provided on its upper side with a copper-based metallization 4 in the form of a dense, coherent network, followed by a full-surface, IR-reflecting layer 3. The In the present exemplary embodiment, the IR-reflecting layer 3 is a thin Ag layer which, in addition to its IR-reflecting function, also ensures full-area conductivity and is also in electrically conductive contact with the metal network 4 .

FIG. 5 shows a transparent, conductive film 7 according to a fourth exemplary embodiment in a cross-sectional view. In the present case, the transparent substrate 2, ie the polyethylene terephthalate (PET) film, is initially provided on its upper side with a copper-based metallization 4 embedded in an electrically insulating filling material 8 in the form of a dense, cohesive network, followed by a full-surface , IR-reflecting layer 3. In the present exemplary embodiment, the IR-reflecting layer 3 is a thin Ag layer which, in addition to its IR-reflecting function, also ensures full-area conductivity. Compared to the third exemplary embodiment shown in FIG. 4, in which components 3 and 4 are in are electrically conductive contact, are the components 3 and 4 in the case of the fourth embodiment shown in Figure 5 before electrically decoupled. The transparent, conductive film 7 is therefore particularly advantageous for special electronic applications in addition to its IR-reflecting function.

Figures 6 to 9 each illustrate a fifth, sixth, seventh and eighth embodiment, in which the transparent, conductive film 9, 12, 13 and 14 each have a first transparent substrate 2, on whose main surface a conductive metallization 4 in the form a densely meshed, cohesive network with a large number of openings of different geometric shapes, and has a second transparent substrate 10, the main surface of which is provided with a full-surface, transparent, IR radiation-reflecting layer 3, the first substrate 2 and the second substrate 10 are connected to one another by means of an adhesive layer 11 . The production of the transparent, conductive film 9, 12, 13, 14 starting from two separate film elements by means of gluing simplifies the manufacturing process and allows the manufacturer freedom of design.

The transparent, conductive film 9, 12, 13, 14 in the respective fifth, sixth, seventh and eighth exemplary embodiment is based on the first, second, third and fourth exemplary embodiments described above with regard to the material selection of the components 2, 3 and 4.

Claims

P atentClaims

1. Transparent, conductive film, comprising a transparent substrate, on the main surface of which a conductive metallization in the form of a densely meshed, coherent network is formed with a large number of openings of different geometric shapes, characterized in that the transparent, conductive film is additionally provided with a full-surface, transparent layer that reflects IR radiation.

2. Transparent, conductive film according to claim 1, wherein the full-area, IR radiation-reflecting layer is arranged between the transparent substrate and the conductive metallization in the form of a close-meshed, coherent network.

3. Transparent, conductive film according to claim 1, wherein the conductive metallization is arranged in the form of a close-meshed, cohesive network between the transparent substrate and the full-area, transparent, IR-radiation-reflecting layer.

4. Transparent, conductive film according to claim 1, wherein the full-area, IR radiation-reflecting layer is arranged on the opposite side of the transparent substrate from the conductive metallization in the form of a densely meshed, cohesive network.

5. Transparent, conductive film according to any one of claims 1 to 4, wherein the full-area, transparent, IR radiation-reflecting layer is electrically conductive.

6. Transparent, conductive film according to claim 5 with reference to claim 2 or 3, wherein the conductive metallization in the form of a close-meshed, coherent network and the electrically conductive, full-area, transparent, IR-radiation-reflecting layer are electrically conductively connected to one another.

7. Transparent, conductive film according to any one of claims 1 to 5, wherein the conductive metallization is embedded in the form of a dense, cohesive network in an electrically insulating filling material.

8. Transparent, conductive film according to one of claims 1 to 7, wherein the transparent, conductive film has a first transparent substrate, on the main surface of which a conductive metallization in the form of a densely meshed, coherent network with a large number of openings of different geometric shapes is formed, and a second transparent substrate, the main surface of which is provided with a full-area, transparent, IR radiation-reflecting layer, the first substrate and the second substrate being connected to one another by means of an adhesive layer.

9. Transparent, conductive film according to one of claims 1 to 8, wherein the full-area, transparent, IR-radiation-reflecting layer is a metal layer or a metal oxide layer, in particular indium tin oxide (ITO) or zinc oxide doped with aluminum (AZO) or zinc oxide doped with gallium ( GZO), or is based on a combination of a metal layer and a metal oxide layer.

10. Transparent, conductive film according to one of claims 1 to 8, wherein the full-area, transparent, IR-radiation-reflecting layer additionally reduces the visual perceptibility of the conductive metallization in the form of a dense-meshed, cohesive network and is based on a material from the group consisting of a metal or an alloy, preferably chromium, aluminum, nickel, iron, silicon, titanium or a combination of two or more of the above elements, a metal oxide layer, preferably chromium oxide or a metal oxide layer based on copper oxide or on a substoichiometric aluminum oxide, an anti-reflective Thin-layer structure with, in particular, the layer sequence metal/dielectric/metal or the layer sequence dielectric/metal/dielectric/metal, black chromium, black nickel, a metal sulfide layer, an overprint based on a colored lacquer or a pigmented lacquer, an N anostructuring or moth eye structure formed antireflection layer and a combination of two or more of the above elements is selected.

11. Transparent, conductive film according to one of claims 1 to 10, wherein the transparent, conductive film has two separate, full-surface, transparent, IR radiation-reflecting layers, each on the top and on the bottom of the conductive metallization in the form of a close-meshed, coherent network are arranged.

12. Transparent, conductive film according to any one of claims 1 to 11, wherein the conductive metallization in the form of a dense, cohesive network is based on copper, gold, silver or aluminum. - 21 -

13. Use of the transparent, conductive film according to any one of claims 1 to 12 for equipping the windshield or other panes of a vehicle, in particular for heating, as electromagnetic shielding or as an antenna, also as a transparent and possibly flexible electrode for solar cells or for Use in Smart Windows, in displays or touch panels or touch buttons as well as LED or OLED applications.