The invention discloses a process for the production of partially metalized carrier substrates.
Partially metalized carrier substrates are used for e.g. in the electronics industry as traces, antennae, RF-antennae, conductive contacts, contact surfaces for printed circuits or contact pins for ICs.
In addition, metalized or partially metalized carrier substrates are used as safety elements in various forms (strips, threads, patches etc.) in or on data carriers, securities such as bank notes, passports, etc., in or on packaging etc.
WO 99/13157 A1 discloses protective foils for securities, in which a metallic coat is applied on a translucent foil, which does not cover the whole surface but instead has open areas which should be clearly visible with transmitted light. The production of these foils includes a carrier foil printed with a highly-pigmented printing ink, wherein the colour application is not on the complete surface; the printing ink is dried under formation of a porous colour coat, finally a metallic top coat is applied and in a further step the highly-pigmented printing ink is removed by washing out with a solvent or if required also by mechanical action. Thus, in areas where the printing ink is removed, the metallic top coat is also removed, thereby forming the open areas seen with transmitted light. The metallic top coat has a thickness of 0.01 to 1 μm.
WO 02/31214 A1 discloses a partially metalized foil and a process for its production, whereby a pattern is printed, with a dissolvable colour, on a substrate or a carrier foil, and/or the basic materials are cleaned directly in a vacuum by means of plasma treatment and simultaneously seeded with target atoms, wherein a metal is metalized and finally the structured layer is created by washing out of the dissolvable colours or through etching.
Especially when using a wash process for removing the partially applied dissolvable colour with the separated top metal coat, mechanical support for the washing process is necessary. Most often this leads to the scratching of the residual metal coat applied on the substrate.
Moreover, both processes are relatively time-consuming consisting of numerous process steps. Generally therefore, high production speeds cannot be achieved.
The function of the invention was to prepare a process for the production of a partially metalized carrier substrate, which would allow high production speeds with sufficient precision and high quality.
Object of the invention is therefore, a process for production of a partially metalized carrier substrate, characterized by the following process steps:
Carrier substrates could be for e.g. carrier foils, preferably flexible plastic foils made of PI, PP, OPP, PPS, PEEK, PEK, PEI, PSU, PAEK, LCP, PEN, PBT, PET, PA, PC, COC, POM, ABS, PVS, Fluor polymers such as Teflon, etc. The carrier foils preferably have a thickness of 5-700 μm, better 5-200 μm, most preferred 36-75 μm.
Carrier substrates could also be made of metal foils such as for e.g. Al, Cu, Sn, Ni, Fe or stainless steel, with a thickness of 5-200 μm, preferably 10 to 80 μm, most preferred 10-40 μm. The foils can also be surface treated, coated or covered with for e.g. plastics or paint.
Moreover, carrier substrates made of paper or composite materials with paper e.g. composites with plastics with a grammage of 20-500 g/m2, preferably 40-200 g/m2 can be used.
Non-wovens such as filament fleece, staple fibre fleece, etc. can also be used as carrier substrates, which can then be needled or calendered, if required. Preferably such fleece contains plastics such as PP. PET, PA, PPS, etc., however, fleece made of natural and treated fibres such as viscose fibres can also be used. The fleece used has a grammage of around 20-500 g/m2.
Subsequently a weak adhesive paint or coat is partially applied to this first carrier substrate. The paint can be applied as lines, samples, tracks, symbols, drawings, etc.
This helps in applying the paint in those areas where there are metal-free areas in the finished product.
In a particular design type, the pattern on the second carrier substrate can show the finished product after the separation. Through this for e.g. traces made of materials such as polypropylene can be produced, which are not temperature stable during direct vaporization.
The removal of the weak adhesive coat on the carrier substrate can be done by means of a process such as gravure printing, flex printing, screen printing, digital printing, etc.
Weak adhesive paint coats that come into question are for e.g. paints or coats with methacrylate bases, with bases of polyamide, polyethylene, fluoropolymers, silicone, strong or thin oil coats.
Subsequently a metallic coat is applied. This coat consists of a metal, a metal composite, or an alloy. Coats made of Al, Cu, Fe, Ag, Au, Cr, Ni, Zn, etc. are suitable as metallic coats. As metal composites for e.g., oxides or sulfides of metals, especially TiO2, Cr-oxide, ZnS, ITO, ATO, FTO, ZnO, Al2O3 or silicium oxide are appropriate. Suitable alloys are for e.g. the Cu—Al alloys, Cu—Zn alloys, etc.
The metallic coat is preferably consists of copper, aluminum, silver or gold.
This metallic coat can be applied by known processes such as metallization, sputtering, printing (gravure, flexo-graphic screen, digital, etc.), spraying, galvanization etc. The thickness of the functional coat is 0.001 to 50 μm, preferably 0.1 to 20 μm.
For clear identification of a certain production charge or an individual component or part of a production charge of the metalized carrier substrate produced as per the invention, in a particular design type the weak adhesive paint or coat can be applied individually by means of a digital printing process. Thereby the weak adhesive paint and/or coat can, if required, be applied additionally to the functional patterns described earlier, in such a way, that it covers the contour of the desired individualized code.
Subsequently, the design produced in such a manner is covered in the usual way against a carrier substrate with an adhesive coat. Preferably the carrier substrate has a self-adhesive coating. As carrier substrates one can consider a flexible plastic foil for e.g. made of PP, OPP, PE, PEI, PEN, PBT, PET, PA, PC, COC, POM, ABS, PVC etc.
Carrier substrates could also be made of metal foils such as for e.g. Al, Cu, Sn, Ni, Fe or stainless steel, with a thickness of 5-200 μm, preferably 10 to 80 μm, most preferred 10-40 μm. The foils can also be surface treated, coated or covered with for e.g. plastics or paint.
Moreover, carrier substrates made of paper or composite materials with paper e.g. composites with plastics with a grammage of 20-500 g/m2, preferably 40-200 g/m2 can be used.
Non-wovens such as filament fleece, staple fibre fleece, etc. can also be used as carrier substrates, which can then be needled or calendered, if required. Preferably such fleece contains plastics such as PP. PET, PA, PPS, etc., however, fleece made of natural and treated fibres such as viscose fibres can also be used. The fleece used has a grammage of around 20-500 g/m2.
Moreover, carrier substrates made of paper or composite materials with paper e.g. composites with plastics with a grammage of 20-500 g/m2, preferably 40-200 g/m2 can be used.
Non-wovens such as filament fleece, staple fibre fleece, etc. can also be used as carrier substrates, which can then be needled or calendered, if required. Preferably such fleece contains plastics such as PP. PET, PA, PPS, etc., however, fleece made of natural and treated fibres such as viscose fibres can also be used. The fleece used has a grammage of around 20-500 g/m2. In addition, composite materials with fleece, etc. can also be used.
Subsequently this carrier substrate is removed from the carrier substrate with the metallic coat.
Thereby the weak adhesive paint with the metallic coat over it, separates from the first carrier substrate and metallic, functional structures remain on the carrier substrate. Similarly, sometimes those metallic structures which form the individualized code on the carrier substrate remain.
The process as per the invention is simple and economical and can be executed with few process steps.
Since no washing or etching solution is used for making the partially metalized structures, this process is more environment-friendly and cost-effective as compared to present processes available.
The partially metalized carrier substrate produced as per the invention can be used for electronic components such as traces, antennae, RF-antennae, conductive contacts, contact surfaces for printed circuits or contact pins for ICs, if needed with an individualized code, etc.
In addition, the carrier substrates manufactured as per the invention can be used as safety elements in or on data carriers such as access cards, prize coupons, container covers with prize coupons, etc., or on securities such as bank notes, passports, in or on packaging etc.
On a 50 μm thick PEN foil, paint with a methacrylate base is applied partially by means of a gravure printing process.
Subsequently a metallic coating made of copper (0.5 μm) covering the entire surface, is applied using a PVD process.
The design produced in this manner is bonded against a PET foil with a conventional self-adhesive coating and subsequently separated again.
Through this removal process the coat of paint with the top coat separates displaying the metallic structure on the first carrier substrate.
Number | Date | Country | Kind |
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06002358.7 | Feb 2006 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/000941 | 2/5/2007 | WO | 00 | 7/24/2008 |