EP0048287A1 - Process for manufacturing a heat-reflecting wall-paper or covering - Google Patents

Abstract

An elastic support material, in particular a plastics film or a plastics-coated material, is covered on one or both sides with an optional adhesion-promoting layer, a thin metal layer, followed by an adhesion-promoting protective layer and finally a coating. To prevent accidents, such a wallpaper should ideally have virtually no transverse electrical conductivity. This object is achieved by various special manufacturing processes for the wallpaper. In a first process, the adhesion-promoting layer between the support material and the metal layer is a material which has hardened or is hardenable into a frangible layer and the layer arrangement is then mechanically deformed to break the hardened adhesion-promoting layer and hence to form cracks in the metal layer above. In another process, the adhesion-promoting protective layer on top of the metal layer is formed as a masking layer which forms a certain pattern, the metal layer is then subdivided in an etching process in accordance with this pattern into a multiplicity of island-like areas, and then finally the coating is applied. In a further process, the thin metal layer, optionally after the application of the protective layer but before the subsequent layers have been applied, is subdivided by mechanical treatment with brushes or combs into a multiplicity of areas. In a further suitable process, a mask is laid on top of the support material, the metal layer is vapour-deposited through the mask on to the support material in a structure which corresponds to the mask and then, after the mask has been removed, the adhesion-promoting protective layer and the coating are applied.

Description

The invention relates to a method for producing a heat-reflecting wallpaper or wall covering, in which on an elastic support material, in particular a plastic film or with plastic-coated materials, on one or both sides, if appropriate, an adhesion-promoting layer, a thin metal layer, an adhesion-promoting lacquer protective layer thereon and then one Paint can be applied.

In European ^- Patent Application 80101943.1 the Applicant a heat reflective wallpaper or a wall covering of the above-mentioned type has already been described. The essential features of this heat-reflecting wallpaper are that the metal layer, which is applied to the substrate and serves to reflect the infrared (heat) radiation, is practically thinner than 30 nm, that a protective layer protecting the metal layer from corrosion and / or adhesive agent of a few microns thick is applied to the metal layer and that on the paint protective layer a paint of a few -10 microns thick, which is largely transparent in the wavelength range of 4 to 20 microns.,. in the range λ = 0.4 to 0.8 µm,
but appears colored, is applied. Such a heat-reflecting wallpaper has a particularly high heat reflection and yet has a particularly pleasing appearance. Overall, it has a comfort-increasing and heating cost-saving effect.

A particular further advantage of the wallpaper is that the metal layer is torn into small parts by mechanical processing of the entire wallpaper, so that the wallpaper has practically no transverse conductivity and there is no danger when using such wallpaper, for example through contact with electrical lines or electrical devices is. As has been found, however, if the backing material of the wallpaper consists of an elastic or plastic material, such as a plastic film, the case may occur that the metal layer does not tear when the layer arrangement is mechanically affected, such as when stretched, but also just stretched. However, this has the disadvantage that the metal layer retains a reduced but still relatively high electrical conductivity.

The present invention is therefore based on the object of developing a method for producing a To specify electrostatic wallpaper or a wall covering of the type mentioned at the outset, with which, even when elastic or plastic carrier materials are used, the metal layer practically loses its electrical conductivity.

A first solution to this problem according to the invention is that a hardening or hardenable material to form a breakable layer is used as the adhesion-promoting layer between the carrier material and the metal layer, and that the layer arrangement for breaking the hardened adhesion-promoting layer and thus for the formation of cracks in the overlying metal layer is mechanically deformed. An essential idea of this method is that the metal layer rests on a hard, breakable layer. I.e. the adhesive layer is said to be hard with respect to the elastic or plastic carrier material and to be breakable in the event of mechanical deformation. To produce the adhesion-promoting layer, materials can be used which either harden themselves or can be hardened by external influences, for example with the aid of light, in particular UV or IR radiation, or with the aid of electron beams. The adhesion-promoting layer does not need to be cured over its entire surface. It may also be sufficient if the layer has only hardened in one pattern, so that it breaks only in certain areas during mechanical deformation. Self-curing or curable lacquers, such as polyesters, polyurethanes, epoxies, phenols or acrylates, as are readily known to the person skilled in the art, can be used as materials for such adhesion-promoting layers. Mechanical deformation of the entire layer arrangement expediently consisting of a carrier material, an adhesion-promoting layer, the metal layer, a further adhesion-promoting lacquer protection layer, and the lacquer can be carried out, for example, by flexing.

Due to the hardened adhesion-promoting layer, which breaks at a large number of points during such mechanical deformation, the metal layer also tears. As a result, the metal layer is divided into a large number of practically non-contiguous partial areas, which increases the ohmic resistance of the wallpaper so much. or the electrical conductivity of the layer is reduced to such an extent that there is no longer any risk of contact with electrical lines.

In order to stabilize the cracks in the metal layer, a method that is carried out as follows has proven particularly useful when using carrier materials which comprise a thermoplastic. The layer arrangement of the carrier material, the adhesion-promoting layer applied thereon, at least hardened in a pattern, and the metal layer applied thereon, and optionally with the further adhesion-protective coating layer and the lacquer applied, is guided over an embossing roller for mechanical deformation of the hardened, adhesion-promoting layer. Before this step, however, the layer arrangement is first heated to a temperature which is so high that the thermoplastic material of the carrier material is already permanently deformable, but which is on the other hand so low that the adhesion-promoting layer remains in a hard, even at this temperature. breakable condition. In contrast, the embossing roller is at a lower temperature, specifically at a temperature at which the thermoplastic material can no longer be permanently deformed. The heated layer arrangement is then expediently guided over the embossing roller such that the carrier material is in contact with the embossing roller. Due to the low temperature of the embossing roller, the con a so-called "shock embossing" takes place in the layer arrangement with the embossing roller due to the rapid cooling of the thermoplastic material. After leaving the embossing roller, the thermoplastic material permanently retains its new shape. This permanent deformation ensures that the cracks formed in the metal layer are permanently fixed. This method can be used to treat both carrier materials which consist entirely of a thermoplastic, for example pure plastic films, such as carrier materials made of another basic material, such as textiles or nonwoven fabric or paper, which are provided with a plastic coating or are impregnated with a plastic, for example.

According to another embodiment, the object is achieved according to the invention in that the adhesion-promoting lacquer protective layer is formed on the metal layer as a masking layer forming a predetermined pattern, in that the metal layer is subdivided into a multiplicity of island-shaped partial surfaces in accordance with this pattern and in that the lacquer is finally applied is applied. In this method, it may be expedient to also provide an adhesion-promoting layer between the carrier material and the metal layer, but such an adhesion-dispersing layer is not absolutely necessary, depending on the type of carrier material chosen and the vapor-deposited partial layer. A photoresist known from photoresist technology can be used as the adhesion-promoting lacquer protective layer, which is exposed in a pattern with a desired image. Depending on the choice of the photoresist in question, the exposed or unexposed parts are then hardened and can be removed in a subsequent washing process. The metal layer exposed in this way in a pattern can then be etched out in a known etching process, so that only the bottom the partial layer lying not washed off photoresist areas remains. The coating can then be applied directly to the layer arrangement of support material, island-shaped metal layer surfaces and photoresist surfaces treated in this way.

A further, particularly simple method according to the invention for solving the above problem consists in mechanically processing the thin metal layer or the surface of the adhesion-promoting lacquer protective layer already applied to the metal layer in such a way that the metal layer along a large number is cut by lines. Since the metal layer itself is extremely thin, namely, preferably thinner than 30 microns, and since the already optionally applied thereto adhesion-promoting lacquer protective layer is also extremely thin, _E ind it meets a thickness of only a few microns aufweisi a mechanical processing such as by means of brushes or combs to form the desired dividing lines in the metal layer. For this purpose, the carrier material with the metal layer applied thereon is preferably allowed to run past the surrounding brushes or combs. A lattice-like pattern can thus be easily carved into the surface, so that a multiplicity of partial surfaces which are no longer connected to one another are likewise formed from the metal layer. The IR-permeable coating is then finally applied to this treated metal layer, on which the adhesion-promoting lacquer protective layer is usually already applied to prevent corrosion of the metal layer.

Another solution to the object of the invention is that a mask is placed on the carrier material, that the metal layer through the mask in a structuring corresponding to the mask; is evaporated onto the carrier material and that after the mask has been removed the adhesion-promoting protective coating and the coating are applied. This is preferably done in such a way that a mask is brought into contact with the carrier material, in which recesses are provided which correspond to the pattern which the applied metal layer should finally have. The metal layer is preferably applied by vapor deposition through the mask _/ although deposition from a solution bath is possibly possible. After the vapor deposition process, the mask is removed from the carrier material. Subsequently, the adhesion-promoting lacquer protective layer and the lacquer are then applied to the metal layer in a pattern. The mask can consist, for example, of an infinite circumferential wire mesh tape, which is brought into contact with the carrier material in front of a vapor deposition zone for vapor deposition of the metal layer and, lying on the carrier material, is guided through the vapor deposition zone at the same speed. The vaporization of the carrier material then takes place through the wire mesh. After leaving the deposition zone, the wire mesh is then lifted off the carrier material and returned to the inlet side of the vapor deposition zone.

Evaporation of the metal layer has the advantage over the application of the metal layer from a solution that a metal layer with a higher degree of reflection is generally obtained and that the metal layer is more economical to produce.

• Fig. 1 Eine Tapete, die nach einer ersten Ausführungsform der Erfindung hergestellt ist,
• Fig. 2 eine Tapete, die nach einer zweiten Ausführungsform gemäß der Erfindung hergestellt ist und,
• Fig. 3 eine schematische Darstellung eines anderen erfindungsgemäßen Verfahrens zur Herstellung der gewünschten wärmereflektierenden Tapete.

The invention will be explained in more detail below with reference to preferred exemplary embodiments shown in the drawing. The drawing shows:

• 1 is a wallpaper that is made according to a first embodiment of the invention,
• 2 is a wallpaper which is produced according to a second embodiment according to the invention and
• Fig. 3 is a schematic representation of another method according to the invention for producing the desired heat reflecting wallpaper.

Figure 1 shows the structure of a finished wallpaper, in which the carrier material consists of a plastic film 10, namely a polyester film. A cross-linked acrylate system was applied to this plastic film as a self-curing adhesion-promoting layer 11. The layer 11 itself only had a thickness of a few μm. An aluminum layer 12 of about 25 nm thickness was then evaporated onto this adhesion-promoting layer 11. Finally, an adhesion-promoting lacquer protective layer 13 made of a linear polyester and finally the lacquer 14 was applied. The layer arrangement 16 thus formed was then subjected to a milling process in which the hardened layer 11 was broken at a plurality of points 15. By breaking the layer 11, the aluminum layer 12 was torn at the same locations 15. The cracks 15 are exaggerated for illustration only and are not shown to scale.

In the wallpaper shown in FIG. 2, the backing material consisted of a textile 20 to which a vinyl layer 21 was applied. An adhesion-promoting layer 25 made of an acrylate system was applied to the vinyl layer 21. A metal layer made of copper 22 was evaporated thereon. The metal layer could also have been vapor-deposited directly onto the vinyl layer 21, leaving out the layer 25.

A photoresist layer 23 was then applied to the metal layer 22, which by irradiation with UV light, was exposed in a pattern, for example at points 27. The exposed areas were then washed out in a subsequent process and the metal layer 22 was then etched away at the areas 27 exposed by the photoresist 23 in an etching process. In this way, furrows penetrating the thickness of the entire metal layer 22 were formed, as shown at 27. Finally, the coating 24 was then applied to the layer arrangement. In total, a layer arrangement 26 was obtained in which the metal layer 22 only consists of essentially non-contiguous islands.

FIG. 3 shows a process step in the process for producing a heat-reflecting wallpaper, with which the metal layer can be formed in the form of non-contiguous partial surfaces even during the vapor deposition process. A drum or roller is shown schematically at 30, around which the carrier material to be coated with a metal layer runs, possibly with an adhesion-promoting layer in the form of a band 34, already applied thereon. The belt 34 is guided by rollers 31 and 32 such that it lies practically over 3/4 of the circumference of the roller 30. The roller itself is rotated in the direction of arrow 35. For vapor deposition of the strip 34 is a metal vaporization is provided ^ource 41st There is also an endless belt 40 made of a wire mesh forming a mask; which is guided over the rollers 36, 37, 39, 38. The belt 40 runs in the direction of the arrows indicated at a speed corresponding to the peripheral speed of the drum 30. After it has passed around the roller 38, the belt 40 lies on the side of the belt 34 facing the evaporation source 41 on the carrier material. The belt 40 is finally lifted from the surface of the belt 34 again after passing through the vaporization zone on the roller 36 and then runs over the rollers 37 and 39 to the roller 38 at the entrance to the vaporization zone back. During the passage through the vapor deposition zone, the wire mesh rests on the carrier material and has the effect that metal is only vapor-deposited on the surface of the carrier material in the areas free of the wire mesh. After the metal layer has been formed in the form of non-contiguous islands, the further layers, such as the adhesion-promoting lacquer protective layer and the lacquer, are finally applied. These processes are not shown in detail.

Claims (10)

1. A method for producing a heat-reflecting wallpaper or wall covering, both on an elastic carrier material, in particular a plastic film or with plastic-coated materials, on one or both sides optionally an adhesion-promoting layer, egg thin metal layer, on this an adhesion-promoting lacquer protective layer and then a varnish be applied, characterized in that as an adhesion-promoting layer between the carrier material and the metal layer one at a brechb _a r _e n layer hardening or curable material is used and in that the layer arrangement is mechanically deformable for breaking of the cured bonding layer and thus to the formation of cracks in the overlying metal layer. 2. The method according to claim 1, characterized in that the mechanical deformation is achieved by a flexing process. 3. The method according to claim 1 or 2, characterized in that the adhesion-promoting shaft is pattern-hardened before the application of the metal layer. 4. The method according to any one of claims 1 to 3, characterized in that the adhesion-promoting layer is hardened with light or UV or IR radiation. 5. The method according to any one of claims 1 to 3, characterized in that the adhesion-promoting layer is hardened with electron beams. 6. The method according to any one of claims 1 to 5, characterized in that the carrier material comprises a thermoplastic material, that the layer arrangement is heated to a temperature at which the thermoplastic material of the carrier material is already permanently deformable while the adhesion-promoting layer is still in is in a hard, breakable state, and that the heated layer arrangement for mechanically deforming the adhesion-promoting layer is guided over an embossing roller which is at a lower temperature than the layer arrangement. 7.Method for producing a heat-reflecting wallpaper or wall covering, in which, on an elastic support material, in particular a plastic film or with plastic-coated materials, on one or both sides, if necessary, an adhesion-promoting layer, egg thin metal layer, an adhesion-promoting lacquer protective layer and a lacquer thereon are characterized in that the adhesion-promoting lacquer protective layer is formed on the metal layer as a masking layer forming a predetermined pattern, that the metal layer is divided into a plurality of island-shaped partial areas in an etching process according to this pattern and that the lacquer is finally applied. 8. A method for producing a heat-reflecting wallpaper or wall covering, in which, on an elastic support material, in particular a plastic film or with plastic-coated materials, on one or both sides, if necessary, an adhesion-promoting layer, a thin metal layer, an adhesion-promoting lacquer protective layer and then a coating applied are characterized in that the thin metal layer, if necessary after the application of the lacquer protective layer, but before the application of the following layers, is subdivided into a plurality of sub-areas by mechanical processing with brushes or combs. 9. A method for producing a heat-reflecting wallpaper or wall covering, in which an adhesive layer, a thin metal layer, an adhesive coating layer and a coating is applied to one or both sides of an elastic carrier material, in particular a plastic film or with plastic-coated materials are characterized in that a mask is placed on the carrier material, d _ate the metal layer through the mask in a structure corresponding to the mask is evaporated onto the carrier material, and that after the mask has been removed the adhesion-promoting lacquer protective layer and the lacquer are applied. 10. The method according to claim 9, characterized in that the mask is in the form of an endless wire mesh tape which is continuously brought into contact with the carrier material in front of the vapor deposition zone, is passed together with the carrier material at the same speed through the vapor deposition zone and after leaving the Evaporation zone is lifted off the carrier material again.

Images