RU2419548C2 - Protective film to protect documents - Google Patents

Abstract

FIELD: printing industry.

SUBSTANCE: invention relates to a protective film to protect documents. The protective film is applied onto a document paper. The film contains a substrate, one or several protective symbols or functional layers. Symbols or layers are arranged on the substrate and are equipped with a protective layer in the form of a protective varnish or a tape, or with an adhesive coating. The protective symbol or layer are not on a surface bordering the document paper. The protective film may contain an intermediate layer with proper adhesion. Functional layers are arranged as solid or partial. Functional layers or symbols have optical, electroconductive and/or magnetic properties.

EFFECT: provision of a reliable protection against falsifications and manipulation.

5 cl, 1 dwg

Description

The invention relates to a protective film for the protection of travel documents, providing them with increased security against fraud.

To provide protection against falsification of the film to protect travel documents, identification cards, driver’s licenses, etc. equipped with protective signs.

These films after individualization of the document are applied to the passport or to the ID card directly at the institution issuing the document.

The films have security elements, which in this case turn out to be open from the bottom side and therefore become a potential object for attacks by counterfeiters, for example, by using paper.

Therefore, the object of the invention is to provide a film for protecting documents, in particular passports, identity cards and the like, having security signs that, after being applied to the document, do not appear on the surface bordering the document and thereby provide it with increased protection against fakes.

Therefore, the subject of the invention is a protective film for protecting documents, having one or more security signs, characterized in that the security sign (or signs) are located under the protection of the protective layer and do not appear on the surface adjacent to the document.

This provides increased security against fraud, since security signs can no longer be the object of manipulation from the back or from the top.

Protective signs are applied to the substrate, which is then provided with an adhesive coating, for example a self-adhesive coating or cold or hot cured adhesive.

Using this adhesive coating, a substrate with appropriate security marks can then be applied to the paper of the security document.

After that, the protective elements are under the substrate and therefore become inaccessible for manipulation without destruction or damage to the substrate.

The drawing shows a film according to the invention, deposited on a protected document. On it, 1 means a substrate, 2a, b, c - protective elements that will be described below and optionally can be used in various combinations, 3 - an intermediate layer with good adhesion and 4 - an adhesive coating, 5 - a protected document.

As substrates, for example, film substrates can be used, preferably elastic transparent polymer films, for example, from PI, PP, MOPP, PE, PPS, PEEK, PEK, PEI, PAEK, LCP, PEN, PBT, PET, PA, PC , COC, POM, ABS, PVC. The film substrates preferably have a thickness of 5-700 microns, more preferably 5-200 microns, particularly preferably 5-50 microns.

One or more functional layers may be applied to the substrate. If necessary, before applying the functional layers to improve their adhesion to the substrate, a known intermediate layer with good adhesion is applied to it.

As functional layers, visually recognizable and / or machine-readable layers can be used.

The application of layers can be carried out by any method, for example, intaglio, flexographic, silk-screen, digital printing and the like. Individual characters may be solid or partial, for example, in the form of patterns, lines, letters, symbols, geometric shapes, rasters, and the like.

For marking with optical properties, pigmented and unpigmented compositions of varnishes and paints can be used. As pigments, all known pigments can be used, for example, inorganic based pigments, such as titanium dioxide, zinc sulfide, kaolin, ITO, ATO, FTO, aluminum, chromium and silicon oxides, or organic based pigments, such as: phthalocyanine blue, i-indolidine yellow, dioxacin violet paint and the like, as well as colored and / or encapsulated pigments in chemical, physical or reactively dried binder systems. As dyes, for example, 1,1- or 1,2-chromocobalt complexes can be used. At the same time, paint and varnish systems containing solvents, systems of aqueous solutions of varnishes, and also varnish systems without solvents are used. As binders, natural or artificial binders can be used.

In addition, luminous, phosphorescent or fluorescent varnishes and paints with a specific refractive index or thermochromic paints can be applied.

For marking with magnetic properties, paramagnetic, diamagnetic, and also ferromagnetic materials can be used, such as iron, nickel and cobalt or their compounds, or salts (for example, oxides or sulfides), or rare-earth metal alloys, such as cobaltsamaric alloys.

Magnetic pigment paints based on iron, iron, nickel, cobalt oxides and their alloys, barium or cobalt ferrites, magnetically hard and magnetically soft grades of iron and steel in aqueous dispersions or in dispersions containing solvents are especially convenient. As solvents, for example, isopropanol, ethyl acetate, methyl ethyl ketone, methoxy propanol and other mixtures can be used. Preferably, the pigments are used in dispersions of acrylate polymers with a molecular weight of 150,000-300,000, in dispersions of acrylate-urethanes, in dispersions of acrylate, styrene, nitrocellulose or in dispersions containing polyvinyl chloride, or in dispersions of the same kind containing solvents.

The magnetic layer can, for example, be applied and partially in the form of a code, the so-called barcode, which under certain conditions is machine-readable.

For applying a layer with electrical properties, for example, graphite, carbon black, conductive organic and inorganic polymers, metal pigments (e.g. copper, aluminum, silver, gold, iron, chromium, etc.), alloys can be added to the applied paints or varnishes, alloys metals, such as: copper-zinc and copper-aluminum alloys, or even amorphous or crystalline ceramic pigments, such as ITO, ATO, FTO, etc. In addition, doped or even undoped semiconductors, such as silicon, germanium, or doped, as well as undoped polymer semiconductors or ionic conductors, such as amorphous or crystalline metal oxides or metal sulfides, can also be used as impurities. In addition, to impart electrical properties to the layer, polar or partially polar compounds, such as tensides, or non-polar compounds, such as silicone additives or hygroscopic or non-hygroscopic salts, can be used or added to the varnish. If necessary, printed technology can also be used to obtain transistors on printed circuit boards.

As a layer with electrical properties, the metal layer can also be partially applied, and partial application is carried out by etching (applying a continuous layer of metal followed by partial removal) or by demetallization method. When using the demetallization method, in the process of performing a single technological operation, the paint is applied in a solution of some solvent (if necessary, in the form of reverse coding), then, if necessary, after activating the substrate by plasma or electric spark treatment, a metal layer is applied, after which a soluble paint layer as a result treatment with an appropriate solvent is removed along with the metal coating of these areas.

In addition, an electrically conductive polymer layer can be applied as an electrically conductive layer. The electrically conductive polymers can be, for example, polyaniline or polyethylenedioxythiophene.

Other surface relief structures, for example, diffraction gratings, holograms and the like, can also be used as security signs, and these structures, if necessary, can be fully or partially metallized.

These optically effective structures can be made by any known method. However, it is preferable to fabricate these diffraction structures by applying to the substrate, which under certain conditions already has one or more of the above layers, an electron beam curing varnish pre-cooled to a gel point by radiation with a specific wavelength, while forming a surface structure, further (basic ) curing of varnish during electron beam curing is carried out by excitation of radiation with a wavelength different from the radiation wavelength I at preliminary curing, after which, if necessary, the final curing is carried out.

An electron beam curing varnish can be, for example, a varnish system based on a polyester, epoxy or polyurethane system containing two or more different photoinitiators known to the person skilled in the art, which at different wavelengths can initiate curing of the varnish system to various degrees. So, for example, one photoinitiator can be activated at a wavelength of about 200-400 nm, followed by a second photoinitiator at a wavelength of about 370-600 nm. A sufficient interval must be observed between the activation wavelengths of both photoinitiators so that during the activation of the first photoinitiator the second photoinitiator is not excited too much. The excitation range of the second photoinitiator should be in the wavelength range of the substrate used. For basic curing (activation of the second photoinitiator), electron emission can also be used.

As an electron beam curing varnish, a varnish diluted with water can also be used. Polyester based varnish systems are preferred.

The formation of a surface, that is, diffraction or relief structure, in the varnish layer for electron beam curing occurs, for example, by means of a matrix or mold during temperature control, and the varnish layer, as a result of activation to the gelation point, must be pre-cured and at the time of formation be in this stage.

If an electron beam curing varnish is used, diluted with water, then, if necessary, preliminary drying can be carried out first, for example, using an infrared emitter.

The thickness of the applied electron-beam curing varnish layer can vary depending on the requirements for the final product and the thickness of the substrate and is generally 0.5-50 μm, preferably 2-10 μm, particularly preferably 2-5 μm.

The form can be transparent, it can be welded, glued, soldered or seamless metal or plastic envelope. Nickel envelopes are preferably used. In order to achieve a precise minting of the surface structure, it is preferable to mount the minting stamp on a pneumatic mounting cylinder with water cooling or heating, subject to temperature control.

In this case, the substrate is brought into contact with the positioning cylinder with thermoregulation, the minting of the surface structure occurs preferably only after the substrate coated with the electron beam curing varnish comes into contact with the cylinder. At the same time, in order to avoid a quick or too slow change in the state of the varnish layer, strict control over the process parameters is carried out, such as pressure and, in particular, temperature. In this case, the curing of the varnish occurs using ultraviolet radiation, and then the final cooling.

As a reflective layer for optically efficient structures, either a metal electrically conductive layer or a metal or metallized coating can be used. In addition, a layer with a high refractive index can be used as a reflective layer.

In addition, coatings can be applied that exhibit different color effects (color relaxation effect) at different viewing angles. In this case, these signs consist of at least one layer reflecting electromagnetic waves, one separation layer, and one layer formed by metal clusters.

In this case, it is preferable to first apply a partial or continuous layer reflecting electromagnetic waves, and then one or more partial or continuous polymer layers of a certain thickness. After that, a layer of metal clusters manufactured by the vacuum method or from solvent-based systems is applied to the separation layer.

In addition, if necessary, the so-called biomarkers are applied in the form of a DNA code, which can also be located in the adhesive coating or in the applied varnish.

Then the layered structure is covered with a protective layer. As a protective layer, a known protective varnish coating or protective tape can be used.

If necessary, a well-known intermediate layer with good adhesion can also be applied to improve adhesion. A protective layer can also be an adhesive coating (extruded layer, self-adhesive coating, cold or hot curing adhesive). Then, when using a layer of protective varnish or protective tape, a corresponding adhesive coating is applied to the layer of protective varnish.

In addition, the layer of protective varnish may be a layer with different areas of adhesion, and when you try to manipulate, for example when peeling the protective film from the substrate, the protective element is destroyed.

Claims (5)

1. A protective film for protecting documents by applying a document to a paper containing a substrate, as well as one or more security signs or functional layers, in which a security sign or signs or a functional layer or layers are placed on said substrate and provided with a protective layer in the form of a protective varnish or a protective tape or adhesive coating, moreover, after applying the protective film to the document, the protective sign or layer does not appear on the surface adjacent to the document paper, and the protective film, if necessary, contains it is an intermediate layer with good adhesion to improve the application of the protective layer. 2. The protective film according to claim 1, characterized in that the adhesive layer is additionally applied to the protective layer. 3. The protective film according to any one of claims 1 and 2, characterized in that the functional layers are made continuous and / or partial. 4. A protective film according to any one of claims 1 to 3, characterized in that the functional layers or signs have optical, optically active, optically variable, electrically conductive and / or magnetic properties. 5. Valuable documents having a protective film according to any one of claims 1 to 4.

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