RU2706825C2 - Objects against forgery protection method by the protective label application - Google Patents

Abstract

FIELD: manufacturing technology.SUBSTANCE: invention relates to the documents protection against forgery. Method comprises the protective label manufacturing, containing a three-dimensional texture, and its authenticity identification. Label texture is obtained by the contact replication on the polymer film. On the label texture a reflective coating is located, on which the adhesive layer is applied. Texture contains areas with the rough surface. During the authenticity identification, having the rough surface the checked label texture area is illuminated with the coherent radiation beam, and comparing the scattered by it radiation speckle patterns with the speckle pattern of the radiation scattered by the genuine label corresponding portion. Chaotic irregularities of the rough surface have characteristic dimensions, commensurate with the illuminating radiation wavelength. Label texture may contain accessible to the visual observation elements (with the naked eye or with the optical microscope) during the identification.EFFECT: technical result consists in increase in the protection reliability by elimination of the possibility of the label holographic copying.9 cl

Description

The invention relates to the field of protection of documents, securities and other objects from counterfeiting by applying a protective mark on them to determine the authenticity.

A known method of protecting documents by applying a holographic mark (RU 2195400 C1, publ. 12/27/2002), which includes obtaining this mark by applying a relief layer to a polymer film base, embossing a holographic microrelief on it, spraying a reflective coating, applying an adhesive to this mark layer, its gluing to the protected document and lamination. The adhesive layer is applied to the side opposite to the informative side of the mark, and the corresponding gluing of the holographic mark is produced by the informative side of the protected document.

In this method, the holographic relief is protected from contact copying, including removing the replica from the relief surface, using lamination, which is not described in the patent, which does not allow to evaluate the degree of this protection.

To complicate the contact copying of the holographic relief in (RU 2113358 C1, publ. 06/20/1998, RU 2127197 C1 publ. 10.03.1999) it is proposed to use special profiles of the relief strokes (with varying stroke widths and inclined strokes, respectively). These methods significantly complicate the technology, and the possibility of their implementation on an industrial scale is questionable.

Reliable protection against contact copying is provided by methods in which the adhesive layer is applied on the microrelief side with a reflective coating. In this case, after fixing the glue, it cannot be removed without destroying the hologram. One of such methods is described in (RU 2035315 C1 publ. 05/20/1995) (prototype), where a multilayer dielectric structure containing a separation, protective thermoplastic layer is applied to a flexible base. On the thermoplastic layer, the relief phase hologram of the mark is fixed. Then, reflective and adhesive layers are applied to this layer. A label is transferred to the security to be secured and fixed with an adhesive layer. Thus, the holographic mark is protected from mechanical action by dielectric layers, therefore, contact copying of the holographic relief without damaging the hologram is not possible.

All methods of protection using holographic marking have one common drawback. They can complicate and even exclude the possibility of contact copying of a holographic relief, but the possibility of holographic copying of a mark cannot be excluded. During holographic copying, the image from the hologram is restored by a beam of coherent radiation and the hologram of the reconstructed image is re-registered. The hologram copy already allows contact copying and replication.

The aim of the invention is to increase the level of security of securities and other objects from counterfeiting.

This goal is achieved due to the fact that the relief of the protective label contains at least one area having a rough surface. Such a section is not a hologram, which excludes the possibility of holographic copying of the mark.

A method is proposed that includes applying a protective mark containing a three-dimensional relief to the protected object and identifying its authenticity, in which the three-dimensional relief of the mark is obtained by contact replication on a polymer film, the mark is glued to the protected object using an adhesive layer that is applied to the reflective coating located on a three-dimensional relief, characterized in that the three-dimensional relief contains at least one area having a rough (containing random irregularities) surface, and if authenticity fractions, the three-dimensional relief site of the security mark being checked, having a rough surface, is illuminated with a beam of coherent radiation and the speckle picture of the radiation scattered by it is compared with the speckle picture of the radiation scattered by the corresponding portion of the genuine security mark, while random roughnesses of the rough surface are characteristic ( there are, average) sizes, commensurate with the wavelength of the illuminating radiation. In this case, we call the parameters of the same order of magnitude comparable.

When identifying authenticity, the illumination of the area of the security mark being checked with a rough surface with a coherent radiation beam and the comparison of the speckle pattern of the radiation scattered by it with the speckle pattern of the radiation scattered by the corresponding portion of the genuine security mark can be repeated at least one more time using another wavelength and / or other angle of incidence of the beam of coherent radiation. Comparison of the indicated speckle patterns can be made using an incoherent optical correlator.

The three-dimensional relief of the security label may contain elements that are accessible to visual observation during the identification process. In this case, in the process of identifying the authenticity, the elements of the volumetric relief can be observed with the naked eye and / or with an optical microscope. Images obtained by an optical microscope when focusing in different planes within the depth of a three-dimensional relief are compared with the corresponding three-dimensional relief images of a genuine security mark.

The three-dimensional relief of the security mark may contain areas that are a hologram.

We describe the options for implementing the proposed method. Let's start by making a security label.

The initial three-dimensional relief containing elements accessible to visual observation is obtained by known methods, for example, by engraving. In the obtained relief, the surface of the elements accessible to visual observation usually contains random microroughnesses with a characteristic size commensurate with the wavelength of the visible range. Thus, the necessary roughness of the relief can be formed naturally, without the use of operations specifically aimed at this. Next, you need to transfer the resulting three-dimensional relief to a protective mark.

The methods of transferring the relief form to the totality of protective marks (replication) depend on the required number of protective marks with this form of relief (volume of replication). For a small amount of replication, it is more convenient to first remove the primary replica from the original terrain, and then form the relief of the protective label by removing the replicas from the primary replica. With an increase in the volume of replication, it is more convenient to manufacture a metal matrix and to replicate by embossing the relief from this matrix.

The manufacture of a metal matrix includes the following operations: removing the replica from the surface of the original relief, applying a thin metal coating to it, the process of electroforming. We describe the indicated technological operations in more detail:

Known methods for producing replicas are used to make replicas, for example, using heated polymer films or liquid polymerization-capable compositions. To apply a thin metal coating to the relief, one of two methods can be used: the method of chemical deposition from a solution and the method of vacuum spraying. Chemical deposition of silver, nickel, gold, copper, etc., has been developed and applied in practice. As a result, a thin (tens of angstroms) metal layer is deposited on the surface of the relief. For spraying, thermal evaporation in a vacuum can be used. For example, the deposition of aluminum in a vacuum installation. Magnetron, electron beam, and other methods may also be used. Coating thickness control can be done by measuring reflection and transmission coefficients. A nickel layer of 50-100 microns thick is applied to the obtained metallized surface by the method of electroforming. In addition to nickel, alloys are also used: nickel-cobalt, nickel-phosphorus, nickel-tungsten. As a result of the process, a metal matrix is formed.

Duplication with a metal matrix is usually done on a polymer film. Duplication is carried out by stamping on a rotary machine. The metal matrix is mounted on the rotor of the machine. A polymer film extends between the rotor and the second metal shaft. Both shafts are hot. The surface relief on the film is formed due to the thermoplastic effect as a result of pressure and temperature. Depending on the materials used, the temperature can vary from 20 to 180 degrees Celsius. As the materials can be used: lavsan, polyamide, polycarbonate, polyvinyl chloride, etc. Polymeric films with a surface layer of another polymer with better thermoplastic properties can also be used. Instead of a rotary machine, the method of flat pressing (for small sizes and medium runs) can be used for replication.

Then, a reflective coating is applied to the obtained three-dimensional relief of the polymer film, usually a thin layer of metal is applied. To do this, use one of the methods described above. A variant is possible when replication is carried out on a metallized polymer film. In this case, the operation of applying a reflective coating is not required. Then, an adhesive layer is applied over the reflective coating and the label is glued to the protected object.

Thus, it is proposed to use the same technological operations for replicating and gluing a security mark as for holographic security labels. Therefore, the use of combined protective marks does not cause any additional difficulties, the three-dimensional relief of which, in addition to areas containing a rough surface, also contains holographic areas.

We now describe the authentication of the security label.

When authenticating, the verifiable security tag is compared to a knowingly genuine security tag. Particularly attractive is the use of a protective mark, containing both a three-dimensional relief with visually distinguishable elements and areas with a rough surface (with a random micro-relief). As indicated above, a visually distinguishable element may directly contain a random microrelief. Primary identification of the authenticity of the label with visually distinguishable elements can be carried out first with the naked eye, and then using an optical microscope. In the second case, changing the focus plane allows you to get an image at different depths of the three-dimensional relief, which is an additional tool for identifying it. For example, when focusing on the top of the three-dimensional relief of the security mark to be checked, the microscope will form one image, and when pointing to the “bottom” of the relief, another. Each of these images is compared with the corresponding three-dimensional relief images of a genuine security tag.

For further identification of the authenticity of the site of the three-dimensional relief of the security label being checked, having a rough surface is illuminated with a beam of coherent radiation. Scattered by the indicated portion of the radiation will form on the screen at a certain distance from the mark a speckle pattern (speckles from English speckle - speck, speck). A speckle pattern is a spotted structure in the intensity distribution of coherent light reflected from a rough surface, whose random irregularities are commensurate with the wavelength of light (Goodman JW Some fundamental properties of speckle. J. Opt. Soc. Am, v. 66, N. 11 , pp. 1145-1150, 1976; Encyclopedia of Physics and Technology http://femto.com.ua/articles/part_2/3770.html). Between the mark and the screen there may be some optical elements, for example, a lens. The average speckle size depends on the radiation wavelength and the aperture of the optical system. The shape and location of speckles (speckle pattern spots) depends on the specific microrelief of the protective mark. The resulting speckle pattern is compared with a speckle pattern generated by radiation scattered by the corresponding portion of the three-dimensional relief of the genuine security mark, using the same optical design and lighting conditions. If the corresponding sections of the relief are identical, then the speckle patterns will be the same. In this case, the conclusion is that the checked label is genuine.

Comparison of the speckle pattern of radiation scattered by a portion of a three-dimensional relief of a security mark being checked, having a rough surface with a speckle pattern of radiation scattered by the corresponding portion of a genuine protective mark, can be made using an incoherent optical correlator (G. Vasilenko. Holographic pattern recognition. - M. : Sov. Radio, 1977, p. 77). For this, the images of the indicated speckle patterns are introduced into the correlator, the signal of which is maximum when they coincide and quickly decreases when their differences increase. If the signal exceeds the set threshold, a conclusion is made about the authenticity of the label. The threshold value is set for reasons of reliable identification in the presence of real noise. The image of the speckle picture relating to the genuine mark can be entered into the correlator in advance and stored there.

In the proposed method, the protective label contains areas having a rough surface, and may also contain elements that are accessible to visual observation. Since the listed areas of the relief are not a hologram, their holographic copying is impossible. On the other hand, identical copying of the relief of the protective mark by photographic methods is also impossible, since this relief is three-dimensional. However, you can register a hologram of such areas of the relief. In this case, the checked mark instead of a three-dimensional relief will contain a hologram of the three-dimensional relief of the genuine mark. When this hologram is illuminated with a coherent beam corresponding to the reference wave during the registration of the hologram, a three-dimensional image of the relief can be restored. But the image of any object reconstructed from the hologram is easy to distinguish from the real object, since the geometry of the image reconstructed from the hologram will depend on the wavelength and angle of incidence of the recovery beam. When using a hologram with spectral and / or angular selectivity, a change in the wavelength or angle of incidence of the recovery beam that goes beyond the line of selectivity will lead to a sharp decrease in the brightness of the image or even complete disappearance. This will immediately lead to the conclusion that this is not a genuine security mark, but its holographic copy. In order to make a conclusion about the authenticity of the security mark being verified by the identity of speckle patterns, one also needs to exclude the case when instead of a mark containing a section with a rough relief, its holographic copy is used. For this, the operation of illuminating the checked and genuine security labels with coherent radiation beams and comparing speckle patterns is repeated several times, while the radiation wavelength and / or the angle of incidence of the illuminating beam are changed in the same way, both for the three-dimensional relief section of the security label being checked and for the corresponding plot of a three-dimensional relief of a genuine protective mark. Then, if the checked security mark is also genuine, the corresponding speckle patterns will remain identical, and if the checked security mark is a hologram of the genuine mark, the corresponding speckle patterns will differ from each other.

Thus, the technical result of the invention is to increase the reliability of protection of documents, securities and other objects from counterfeiting by eliminating the possibility of holographic copying of a security mark and a reliable multi-stage identification process of the mark. At the same time, the protection method remains simple and technological.

Claims (9)

1. A method of protecting documents, securities and other objects from counterfeiting, including applying a protective mark on them containing a three-dimensional relief and identifying its authenticity, in which a three-dimensional relief of the mark is obtained by contact replication on a polymer film, the mark is glued to the protected object using adhesive layer, which is applied to a reflective coating located on a three-dimensional relief, characterized in that the three-dimensional relief contains at least one area having a rough surface, and when identifying In case of authenticity, the area of the three-dimensional relief of the checked security mark having a rough surface is illuminated with a beam of coherent radiation and the speckle picture of the radiation scattered by it is compared with the speckle picture of the radiation scattered by the corresponding portion of the genuine security mark using the same optical design and lighting conditions, with random irregularities rough surfaces have characteristic dimensions commensurate with the wavelength of the illuminating radiation. 2. The method according to p. 1, characterized in that when identifying authenticity, illuminate a portion of the security mark being checked with a rough surface with a coherent radiation beam and compare the speckle pattern of the radiation scattered by it with the speckle pattern of radiation scattered by the corresponding portion of the genuine security mark when using the same optical design and lighting conditions are repeated at least one more time using a different wavelength of coherent radiation. 3. The method according to p. 1, characterized in that when identifying authenticity, illuminate a portion of the security label being checked with a rough surface with a coherent radiation beam and compare the speckle pattern of the radiation scattered by it with the speckle pattern of radiation scattered by the corresponding portion of the genuine security tag when using the same optical design and lighting conditions are repeated at least one more time using a different incidence angle of the coherent radiation beam. 4. The method according to p. 1, characterized in that the comparison of the speckle pattern of radiation scattered by the three-dimensional relief of the checked protective mark having a rough surface, with the speckle pattern of radiation scattered by the corresponding portion of the genuine protective mark when using the same optical design and lighting conditions are produced using an incoherent optical correlator. 5. The method according to p. 1, characterized in that the three-dimensional relief of the security label contains elements that are accessible to visual observation during authentication. 6. The method according to PP. 1 and 5, characterized in that when identifying the authenticity of the elements of the three-dimensional relief, accessible to visual observation, observe with the naked eye. 7. The method according to PP. 1 and 5, characterized in that when identifying the authenticity of the elements of the three-dimensional relief, accessible to visual observation, is observed under an optical microscope. 8. The method according to PP. 1, 5 and 7, characterized in that when observing with an optical microscope the images of the three-dimensional relief elements of the checked protective mark that are accessible to visual observation, obtained by focusing the microscope in different planes within the three-dimensional relief depth, are compared with the corresponding three-dimensional relief images of the genuine protective mark. 9. The method according to p. 1, characterized in that the three-dimensional relief of the security label contains at least one section, which is a hologram.