EP3766703A1 - Method for producing a structure on a surface - Google Patents

Abstract

The present invention provides a method for producing a structured surface on a flat workpiece, in which tools available in conventional production systems can be used and which is sufficiently flexible that when a structure is changed, the respective tool (the roller or the Press plate) must be changed. In addition, the method according to the invention provides the possibility of producing nanostructures on the workpiece surface. In the process, a surface of the flat workpiece is painted, a transfer film with a fine structure is applied to the painted surface before the paint hardens, so that the fine structure is in contact with the painted surface of the flat workpiece, the paint of the painted surface in contact with the Transfer film cured or allowed to cure and the transfer film is removed from the cured, lacquered surface so that a copied structure is left on the target surface.

Description

The present invention relates to a method for producing a structure on a surface of a flat workpiece.

BACKGROUND OF THE INVENTION

Structured surfaces are widespread, for example, in the furniture industry and in the construction industry, for example for the finishing of kitchen fronts, furniture panels and building materials. In the industrial production of flat workpieces, e.g. in the coating and finishing of chipboard, MDF boards for furniture, floors, interior and exterior cladding, and in the cement fiber board industry, surface finishing, especially with a replica of a structure, is common nowadays. These replicas of structures can be modeled wood pores, simulated stone surfaces or fantasy structures. There are various processes for producing these surface structures that are tailored to the coating process for the surface. Different embossing matrices are used, which are pressed into the surface using melamine pressing, for example, or a structure that is painted onto the surface. For example, a paper that has been printed with a wood look is impregnated with a melamine resin, dried and then pressed onto a chipboard in a heating press with an embossing plate. Structures with a depth of approximately 20 µm to 150 µm then result on the surface through the embossing plate.

In addition to this so-called melamine pressing process, there are other processes for coating wood-based panels. In a further known method, for example, a wood-based panel is painted, printed and then with a provided with a transparent top coat. In order to obtain a corresponding surface structure here too, there is the option of applying a structure with a structured topcoat roller. Such a procedure is for example in the DE 10 2007 019 871 A1 described.

All these methods of structuring the surface have in common that they are relatively less flexible and that when a structure is changed, the respective tool (the roller or the press plate) has to be changed.

In order to circumvent these disadvantages, methods for digitally applying a structure have been proposed. One such is that, for example, in the DE 10 2009 044 802 A1 described. However, this digital method also has disadvantages: it uses a large amount of radiation-curing ink, which is very expensive.

The EP 3 109 056 B1 finally describes a method for producing a structure on a surface, in which in a first step the surface of a workpiece to be coated is coated with a liquid base layer and in a second step a structure is created in this still liquid base layer with the help of sprayed, liquid droplets that will be fixed later. This process is also comparatively complex and requires elaborately manufactured tools.

The disadvantage of all these methods is that no nanostructures can be produced on the flat workpieces. If nanostructures are applied with an embossing roller, there is a risk of the structure ripping off or flowing away. The structures applied by means of an inkjet process have elevations of 5 µm to 300 µm. Finer ones Structures cannot be achieved due to a lack of resolution.

Against this background, the present invention provides a method for producing a structure on a surface, in which tools available in conventional production systems can be used, and which is sufficiently flexible that when a structure is changed, the respective tool (the roller or the Press plate) must be changed. In addition, the method according to the invention provides the possibility of producing nanostructures or holographic surfaces on the workpiece surface.

This object is achieved by the features of claim 1. Preferred embodiments are given in the subclaims.

SUMMARY OF THE INVENTION

1. (a) eine Transferfolie mit Feinstruktur wird hergestellt, indem eine Feinstruktur mit einer Profiltiefe von 100 nm bis 150 µm mittels eines strukturierten Zylinders oder eines strukturierten Sleeves in die Transferfolie geprägt wird,
2. (b) eine Oberfläche des flächigen Werkstück wird mit einer härtbaren Beschichtung beschichtet,
3. (c) auf die in (b) beschichtete Oberfläche wird vor Aushärtung der Beschichtung eine strukturierte Transferfolie aufgebracht, so dass die Struktur in Kontakt mit der beschichteten Oberfläche des flächigen Werkstücks steht,
4. (d) die Beschichtung der beschichteten Oberfläche wird in Kontakt mit der Transferfolie ausgehärtet oder aushärten gelassen,
5. (e) die Transferfolie wird von der ausgehärteten, beschichteten Oberfläche entfernt, so dass eine kopierte Struktur auf der Zieloberfläche hinterlassen wird.

The method according to the invention for producing a structure on a surface of a flat workpiece comprises the following steps:

1. (a) A transfer film with a fine structure is produced by embossing a fine structure with a profile depth of 100 nm to 150 µm into the transfer film using a structured cylinder or a structured sleeve,
2. (b) a surface of the flat workpiece is coated with a hardenable coating,
3. (c) A structured transfer film is applied to the surface coated in (b) before the coating hardens, so that the structure is in contact with the coated surface of the flat workpiece,
4. (d) the coating of the coated surface is cured or allowed to cure in contact with the transfer film,
5. (e) the transfer film is removed from the cured, coated surface so that a copied structure is left on the target surface.

With the method according to the invention, a structure is produced on the workpiece surface by means of a transfer film, on the surface of which there is an original fine structure. In connection with the present invention, a structured surface is to be understood as a three-dimensional structure. The structured transfer film consists of a material that is suitable for this purpose, for example thermoplastic. The structured transfer sheet used in the method can be made as part of the process of manufacturing the fine structure of the target surface, or a transfer sheet that has been previously made or procured elsewhere that has the desired original fine structure can be used in the method.

The surface can in principle be any surface of a workpiece, such as a wood surface, a plastic surface, a metal surface or a coated paper surface. The target surface can be flat or curved (sheet or roll goods).

The coating can be a lacquer, a paint or another curable coating. Acrylic lacquers are preferred. Lacquers that are UV-curable are very particularly preferred.

The selected transfer film is placed on the target surface in such a way that its original fine structure is the Touches the target surface while the coating is not yet cured. After the coating has cured, the transfer film is removed from the surface of the workpiece. The material of the transfer film that adheres to the target surface creates a copied fine structure that is a mirror image of the original fine structure of the transfer film.

The height of the copied fine structure produced on the target surface is preferably somewhat smaller in the direction of the normal to the target surface than the height of the original fine structure. With the method according to the invention, surface structures with a profile depth of, for example, 100 nm to 500 nm, preferably 100 nm to 200 nm, more preferably 120 nm to 150 nm can be produced without the structures ripping out or flowing. With the method according to the invention, however, haptic structures can also be produced which preferably have a profile depth of 10 μm to 150 μm, more preferably, without having to use special profiled rollers for this purpose. Diverse functional surfaces such as lotus blossom effects, moth eye effects or shark skin effects, light deflection effects, retroreflection, backlight effects with a profile depth of 100 nm to 50 μm, preferably 350 nm to 20 μm, can be produced on the flat workpieces with the method according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

The fine structure with a profile depth of 100 nm to 150 µm is embossed into the transfer film using a structured cylinder or a structured sleeve. For this purpose, it is not intended that the transfer film is first coated with a curable lacquer, which is then embossed and cures, because with such a procedure there would again be the risk of the structure ripping off or flowing. However, the transfer film can definitely be multi-layered. The cylinders or sleeves for embossing the transfer film can be made of nickel, copper or chrome, for example. Exemplary methods for imparting the structured surface on the cylinders or sleeves include electron beam lithography, laser technology, such as the use of pico or nano lasers and engraving, chemical or plasma etching. The structure can be transferred to the film, for example, by thermal embossing or ultrasonic embossing. The original fine structure of that used in the process. Thermal embossing can be done with a roll-to-roll printing machine or by static embossing.

The structured transfer foils can be transparent or opaque, in particular if the lacquer underneath can be cured by irradiation, such as UV irradiation, as will be explained later.

The material of the transfer film can be selected, for example, from polyethylene, polypropylene, polyvinyl chloride, polystyrene, polyester, polycarbonate, cellophane. Other plastics, such as bio-based plastics, e.g. polycactide, cellulose acetates and starch blends can also be used as the material of the transfer film. Preferred plastics are cellulose acetates, such as cellulose diacetate or cellulose triacetate. Also composite materials of different foils or foil / paper. Composite materials of different foils or foil / paper are also suitable for the transfer foils. The connection of two materials to produce a composite material can be done, for example, by gluing using dispersion, LF or LH adhesives, co-extrusion or using ultrasound.

The film thickness of the transfer film is preferably 10 μm to 250 μm. Most preferred is a film thickness between 50 µm and 90 µm, so that the transfer film has an advantageous stiffness and yet a sufficient balance between flexibility and stiffness to be used in the method according to the invention. In the case of thinner films, the structured transfer film can also have a thermoreactive adhesive layer, for example made of EVA / PE, to improve the rigidity. Foil thicknesses between 60 µm and 80 µm are preferred for structuring furniture surfaces. Foil widths can be from 10 mm to 2500 mm. Foil widths of 800 mm to 2100 mm are provided for structuring furniture surfaces.

The structured transfer foils can, for example, be applied to the surface of a flat workpiece using commercially available calander coating inert machines, as is practiced, for example, in the furniture industry for the production of high-gloss surfaces. Calander coating inert machines of this type are available, for example, from Hymmen GmbH (Hamm, Germany) and Cefla s.c. (Imola, Italy). In this industrial coating process for the panel industry, UV lacquers are applied using a roller process. Then a film or tape smooths the still liquid paint surface. The curing takes place through the film by means of UV radiation with direct surface contact. The film is then removed from the surface. It is not necessary to adapt the calendar coating inert machines.

With the help of the structured transfer film, decorative or functional structures can be transferred to the surfaces of a flat workpiece. The flat workpiece as a format or rolled goods can be chipboard, MDF boards (e.g. for furniture), HDF boards, raw chipboard, veneer, paper, floors, interior and exterior cladding and in the cement fiber boards, but also aircraft, automotive, Railway parts. For example, it is provided according to the invention to transfer functional structures to aircraft wings and tail units with the aid of the method according to the invention, so that, for example, their air flow (shark skin) is favorably influenced, a self-cleaning effect (lotus blossoms) is achieved or for anti-reflective coating (moth's eye effect).

Another application of the structured surfaces according to the invention is the provision of test marks such as holograms or hidden security features based on micro- or nano-fonts or images, which can facilitate the identification of counterfeit products. Of course, the method according to the invention can also be used to produce decorative optical or haptic effects on the surfaces of the workpieces.

Transfer effects can be applied over the whole area or partially.

The coating applied to the surface of the flat workpiece is preferably a thermal and / or UV-curing lacquer or a thermal and / or UV-curing paint. If a UV-curing lacquer is used, the film is preferably transparent, so that curing with UV light is facilitated. Conventional varnishes or paints based on polyacrylate or those based on alkyd resins are preferred. The lacquers or paints can be those with or without electrical conductivity. The conductivity can be established, for example, by mixing with polyanilline in the paint composition. Polyaniline is a polymer with excellent electrical conductivity, which has an anti-corrosive effect due to its passivation. If biodegradability is desired, varnishes based on vegetable oils can also be used Find. In principle, there are no limits to the use of certain paints in the process according to the invention.

Claims (12)

Method for producing a structure on a surface of a flat workpiece with the following steps: (a) A transfer film with a fine structure is produced by embossing a fine structure with a profile depth of 100 nm to 150 µm into the transfer film using a structured cylinder or a structured sleeve, (b) a surface of the flat workpiece is coated with a hardenable coating, (c) A structured transfer film is applied to the surface coated in (b) before the coating hardens, so that the structure is in contact with the coated surface of the flat workpiece, (d) the coating of the coated surface is cured or allowed to cure in contact with the transfer film, (a) The transfer film is removed from the cured, coated surface so that a copied structure is left on the target surface. Method according to Claim 1, characterized in that the transfer film is transparent or opaque. Method according to Claim 2, characterized in that the lacquering of the lacquered surface is cured in contact with the transfer film by means of radiation. Method according to Claim 3, characterized in that the lacquering of the lacquered surface is cured in contact with the transfer film by means of UV radiation. Method according to one of the preceding claims, characterized in that the material of the transfer film is acetyl cellulose or paper. Process according to Claim 5, characterized in that the material of the transfer film is cellulose diacetate or cellulose triacetate. Method according to one of the preceding claims, characterized in that a fine structure is generated in a surface of a flat workpiece which has a height in the direction of the normal to the target surface of 100 nm to 500 nm, preferably 100 nm to 200 nm, more preferably 120 nm to 150 nm nm. Method according to one of the preceding claims, characterized in that a fine structure is produced in the surface of a flat workpiece, which creates a decorative optical effect. Method according to one of the preceding claims, characterized in that a fine structure is generated in the surface of a flat workpiece, which creates a holographic optical effect. Method according to one of the preceding claims, characterized in that a fine structure is produced in the surface of a flat workpiece, which creates a lotus blossom effect. Method according to one of the preceding claims, characterized in that a fine structure is produced in the surface of a flat workpiece, which creates a moth-eye effect. Method according to one of the preceding claims, characterized in that transfer film with a fine structure is used on both sides by applying it in a second pass of the method to another flat workpiece with the opposite side of the previous pass, with the front and back of the transfer film being different Can include fine structures.