RU2354558C1 - Holographic element and method for making thereof - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: disclosed inventions concern a topographic element and method for its making. A holographic element contains a base comprising a polymeric plated film. This base contains an unplated segment with a distant metal layer and a plated hologram segment shaped as a topographic microrelief formed by ridges and groove on a metal surface of said base. The unplated segment is optically transparent, while the hologram segment is optically opaque. The interface of the unplated and hologram segments matches to that of the topographic relief.

EFFECT: disclosed invention ensures making the topographic element with improved forgery-proof properties.

2 cl, 4 dwg, 1 ex

Description

The present invention relates to a holographic element and a method for its manufacture. The proposed holographic element can be used for marking, in order to protect against forgery of a variety of documents, in particular, such as banknotes, checks, excise stamps, etc.

The closest to the proposed device in technical essence and in the number of essential features is a topographic element containing a base in the form of a metallized polymer film, a section with a hologram formed in the form of a holographic microrelief of protrusions and grooves, and a section with a removed metal layer / information from the site http://www.vera.com.pl/go.live.php/html _default / PrintHTML / 61.html, received on July 6, 2007 /. In the described device, a section with a removed metal layer is created by treating the base with a laser beam. In this case, the characteristics of the laser beam are chosen such that during the laser beam treatment the polymer lining of the metallized film remains intact, and only a fragment of the metal layer is removed from the surface of the metallized film. As the metal layer in the described construction, an aluminum layer is used.

The optimal geometric parameters of the hologram microrelief are: height - 0.1-0.3 microns, and the period of alternation of protrusions and grooves - 0.3-4.0 microns. These parameters are optimal for creating a hologram designed for visual perception with the naked eye when illuminated with visible light. With such geometric parameters of a site with a topographic relief, the hologram, when considered, is brightly iridescent with rainbow colors. An increase or decrease in the geometric parameters of the holographic relief leads to a loss of topographic effects and brightness. In the described device, in the process of demetallization, a part of the holographic image is lost, since the process is carried out with certain capabilities of the equipment, work tolerance. That is, at the demetallization stage, it is impossible to precisely get the laser beam into the design of the hologram, which leads to a significant loss of brightness. Thus, the described holographic element has limitations on the reproduction of the hologram design, since the laser allows you to demetallize the lines with an accuracy of coincidence of the demetallization and hologram sections of at least 0.3 millimeters, which is much more than the geometric parameters of the hologram microrelief: height - 0.1- 0.3 microns and the alternation period of the protrusions or grooves is 0.3-4.0 microns.

Closest to the proposed method in terms of technical nature and the number of essential features is a method of manufacturing a holographic element, including the operation of forming on the surface of a base made of metallized polymer film, a section with a hologram in the form of a topographic microrelief from alternating protrusions and grooves, and a demetallized section - section with a removed metal layer / information from the site http://www.vera.com.pl/go.live.php/html _default / PrintHTML / 61.html. Received July 6, 2007 /. In the described method, a section with a removed metal layer is created by dimensionally processing the substrate with a laser beam. In this case, the characteristics of the laser beam are chosen such that during processing the polymer lining of the metallized film remains intact, and only a fragment of the metal layer on the surface of the metallized film is removed. As a metal layer in the described metallized film, aluminum foil is used.

Given the above, as well as the technical capabilities of modern lasers, the described method does not allow to demetallize a hologram with an accuracy of coincidence of demetallization and hologram sections higher than 0.3 millimeters, which is much more than the geometric parameters of the hologram microrelief: height - 0.1-0 , 3 microns and the alternation period of the protrusions or grooves is 0.3-4.0 microns.

Moreover, the aforementioned method is inefficient, since the process of thermal demetallization is rather inert and requires relatively large exposures of laser radiation. Attempts to use lasers with higher power lead to the destruction of the polymer base together with the metal layer, which is unacceptable.

The basis of the proposed inventions is the task of creating such a holographic element and such a method of its manufacture, which would make it possible to obtain a topographic element with enhanced protective properties, which would significantly complicate their fake.

The problem is solved by the proposed device due to the use in its design of an optically opaque section with a hologram and an optically transparent demetallized section, the boundaries of which coincide with the boundaries of the hologram.

The problem is solved by the proposed method through the use of the capillary effect of the topographic relief in the process of selective demetallization (metal removal) from the surface of a metallized film on which the topographic relief is applied.

The proposed one, like the known topographic element, contains a base in the form of a polymer metallized film, on the base there is a demetallized area with a removed metal layer and a metallized area with a hologram formed in the form of a holographic microrelief of protrusions and grooves on the metal surface of the base, and in accordance with the invention , the demetallized portion is optically transparent, the hologram portion is optically opaque, and the boundaries of the demetallized portion and c ologrammoy coincide with the boundaries of topographic relief.

The proposed, as well as the known method of manufacturing a topographic element, includes the operation of forming on the surface of the base made of metallized polymer film, a section with a hologram in the form of a holographic microrelief of alternating protrusions and grooves, and a demetallized section - a section with a removed metal layer, and in accordance with the invention previously formed on the metal surface of the base, made of metallized polymer film, at least two sections with a topograph With a microrelief, the height of which is 0.1-0.3 microns, and the period of alternation of protrusions and grooves is 0.3-4.0 microns, one of the sections is saturated with a protective liquid, for example, paint, and the section saturated with a protective liquid is held until the protective liquid hardens , the surface of the metallized film from the side of the metal surface is subjected to chemical etching to remove from the base, free from the layer of hardened protective liquid, the metal layer of the metallized film and get a topographic element that contains deme a crystallized optically transparent region without a hologram and a metallized optically opaque region with a hologram, and the boundaries of the metallized and demetallized regions coincide with the boundaries of the topographic relief.

Traditionally, holographic elements are replicated on a polymer film with a sawn metal coating by embossing with a matrix with a topographic relief.

The authors experimentally revealed that the hologram - a microrelief of alternating protrusions and grooves - after applying liquid to it, due to the capillary effect, “sucks” the liquid onto the entire surface of the hologram. In this case, the protective fluid does not go beyond the hologram, that is, the protective fluid, such as paint, covers only the surface strictly limited by the surface with the hologram. Due to the revealed hologram features, conditions arose for selective demetallization (removal of metal) of the sawn-on film, namely, the metal layer in areas where there is a holographic relief or in adjacent places where it is not. Moreover, the proposed method allows to obtain a demetallized area, the boundaries of which exactly (without tolerances) coincide with the boundaries of the topographic relief. At the same time, the prototype method allows you to get a demetallized area, which can coincide with the holographic relief only with an accuracy (tolerance) of up to 0.3 millimeters, which necessarily leads to the loss of hologram fragments.

Using the proposed method allows you to create a new visual sign of the reproduction, for example, of a control topographic image against the background of a demetallized structure, which will be inherent only to a certain document or product marked with such a holographic element. To reproduce such a topographic element, it is necessary to use not only holographic technologies, but also a new demetallization technology. All this complicates the process of falsification or imitation of the proposed protective element, and therefore increases its protective properties.

The method is carried out as follows. The customer proposes the idea of an image and / or words to be reproduced on a holographic element. At the customer’s choice, the holographic element may contain an image and / or inscription made using the demetallization process, which corresponds, for example, to the aesthetic needs of the customer. So, at the customer’s choice, the image and / or inscription can be invisible when observed with the naked eye and can be observed with a microscope or be visible and can be observed with the naked eye depending on the size of the proposed image and / or inscription. In addition, at the option of the customer, the holographic element may contain an encoded image that can be used to automatically verify the authenticity of the holographic element.

The essence of the invention is illustrated using schematic drawings.

Figure 1, 2, 3 shows General views of the samples of the proposed topographic element.

Figure 4 for comparison shows topographic elements of traditional and proposed designs.

The proposed holographic element contains a base 1 made in the form of a metallized film. A hologram 2 in the form of a microrelief of alternating protrusions and grooves that recreate the image and text is reproduced on a thin metal layer of the base 1. On the basis of 1, there is a section without a holographic relief 3. Pre-protective liquid - paint saturates the area with the hologram 2. After the paint layer 4 has dried, the latter protects the metal layer of the base 1 from the action of the etching solution, and the metal is removed in places unprotected by the hardened paint layer. At the same time, the boundaries of the demetallized sections 5 and those with the hologram 2 coincide. Figure 4 shows for comparison the traditional non-metalized hologram 6, the demetallized hologram, where the metal is removed from areas without relief 7 and the demetallized hologram, where the metal is removed from sites without relief 8.

Example. The proposed topographic element was made as follows. The designer, by order of the owner or customer of the product, created an image and / or text, including a hologram 2 in the form of a microrelief from alternating protrusions and grooves, and a demetallized section 5, which corresponded to a single integral design concept. A metal matrix was made with the created hologram 2 and the future demetallized section 5. The metal matrix was used to reproduce the hologram 2 and the future demetallized section 5. The mechanical reproduction of the hologram 2 and the future demetallized section 5 on the basis of 1 was performed on traditional equipment - a mechanical press for embossing holograms by embossed with a nickel matrix with topographic relief on the basis of 1 - metallized aluminum foil 50 mm thick lavsan film ikrometrov. The base 1 after its treatment with a nickel matrix with a holographic relief was covered with a layer of protective liquid 4. An acrylic aqueous dispersion was used as a protective liquid. The protective liquid was impregnated by using the capillary effect of the sections of the base 1 with a microrelief of the hologram 2. Then, the excess protective liquid from the surface of the base 1 and from section 3 was removed by exposing it to a stream of compressed air. In this case, the protective fluid layer 4 was retained only in areas with a microrelief of hologram 2. The protective layer 4 was dried by heating the film to a temperature of + 60 ... + 70 ° С. Then the film was immersed in an etching solution - a solution based on caustic soda, where a thin layer of metal was etched from the surface of the base 1, which was not protected by the hardened layer 4 of the protective fluid. The resulting film was washed with running water, immersed in a solvent of the protective layer and washed off the film. The film was dried and a holographic element was obtained containing a base 1 with an optically opaque section 2 made in the form of a hologram on the side of the metal surface of the base 1 and an optically transparent demetallized section 5 with a removed metal layer, the boundaries of which coincided with the boundaries of the holographic relief with an accuracy commensurate with the geometrical parameters of the hologram microrelief 2. To obtain the opposite effect, an etching solution was added to the protective liquid, which etched the metal layer th base 1 in areas with a holographic relief 2 (figure 3).

The manufactured holographic element with enhanced protective properties, which significantly complicate its fake or imitation, was used for marking, in order to protect documents from falsification, in particular, such as banknotes, checks or excise stamps.

Claims (2)

1. A holographic element containing a base in the form of a polymer metallized film, on the base there is a demetallized portion with a removed metal layer and a metallized portion with a hologram formed in the form of a topographic microrelief of protrusions and grooves on the metal surface of the base, characterized in that the demetallized portion is optically transparent, the portion with the hologram is optically opaque, and the boundaries of the demetallized portion and the portion with the hologram coincide with the boundaries of ograficheskogo relief. 2. A method of manufacturing a holographic element, including the operation of forming on the surface of the base, made of metallized polymer film, a section with a hologram in the form of a holographic microrelief of alternating protrusions and grooves, and a demetallized section - a section with a removed metal layer, characterized in that it is preliminarily on a metal at least two sections with a holographic microrelief, the height of which is formed on the surface of a base made of a metallized polymer film it is 0.1-0.3 microns, and the period of alternation of protrusions and grooves is 0.3-4.0 microns, one of the sections is saturated with a protective liquid, for example paint, withstand the area saturated with protective liquid until the protective liquid has hardened, the surface of the metallized film on the metal surface side, they are subjected to chemical etching until the metal layer of the metallized film is removed from the base, which is free from the layer of hardened protective liquid, and a topographic element is obtained which contains a demetallized optically transparent section es holograms and metallised optically opaque region of the hologram, and the boundaries of metallized and demetalized areas coincide with the boundaries of topographic relief.

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