EA035961B1 - Method for production of transparent inserts for fraud protection of identification cards and polycarbonate sheets of biometric passports - Google Patents

Abstract

The invention relates to fraud protection of valuable documents, in particular identification cards and polycarbonate sheets of biometric passports, which are used to certify somebody's identity and include visual data and data recorded on the electronic chip. According to the method, two polymer film rolls are used, a continuous or discontinuous oriented anisotropic polymer liquid-crystal layer is formed on one of the films, the layer including the first latent images, a continuous or discontinuous oriented anisotropic polymer liquid-crystal layer is formed on the other polymer film and includes the second latent images. That side of each of the films on which the oriented anisotropic polymer liquid-crystal layer including latent images is formed is attached with adhesive to one of the sides of a transparent thin-film polarizer having two working sides, and transparent inserts for fraud protection of ID cards and polycarbonate sheets of biometric passports are punched out, said transparent inserts including the first and second latent images.

Description

The invention relates to the field of protection against counterfeiting of valuable documents, in particular identification cards and biometric passports, which are used for identification and include visual information and information recorded in an electronic chip.

Currently, identification cards are usually made in the format of a plastic card and are made from polymer sheets sintered in press-laminators. Polyvinyl chloride (PVC) is most often used as the material for these sheets, and polycarbonate is used for documents with a validity period of at least ten years. Polycarbonate is also used to make sheets of biometric passports.

Manufacturing technology and design of identification cards and polycarbonate sheets of biometric passports are the same. Transparent and opaque sheets assembled in bags made of the same polymer are sintered together in special press laminators. In the middle of this packet are opaque sheets with permanent data printed on the outside. In contact with the opaque sheets, there are transparent sheets on which, after sintering, variable data is applied. Transparent sheets, on which variable data are subsequently applied, are protected from external influences and from changes to variable data by protective transparent sheets.

The most effective is the method in which through holes of one shape or another are made in opaque sheets of plastic identification cards and polycarbonate sheets of biometric passports, transparent inserts are made to protect against counterfeiting, which in shape and size correspond to through holes in the opaque sheets of the mentioned documents. When assembling packages of sheets of plastic identification cards and polycarbonate sheets of biometric passports for sintering, the said transparent inserts are installed into the through holes in the opaque sheets.

Transparent inserts can carry various anti-counterfeiting elements, for example, visible and / or latent images, images having a color-changing effect in transmitted and reflected light, diffractive, holographic and other optical effects. Among security elements with variable optical properties, the most difficult to reproduce are elements containing latent images visible only in certain lighting conditions or when using special optical devices, including polarizers.

There is a method of protecting documents from counterfeiting, in which the first and second through holes are made in the opaque sheets of the document to be protected, the first optical security element is installed in the first through hole, the second optical security element is installed in the second through hole. In this case, the first through hole and the second through hole in the opaque sheets of the security document are made in such a way that the first and second optical security elements installed therein can be brought into an overlapping mutual position. The first optical security element contains the first transmission field of microlenses, and the second optical security element contains the second transmission field of microlenses, while the optical effect is caused when the second transmission field of the microlenses is aligned with the first transmission field of the microlenses [1].

The disadvantage of this method is that in order to verify a document protected from counterfeiting by this method, it is necessary to have a flexible basis in it for combining optical security elements, which cannot be done for currently produced plastic identification cards and polycarbonate sheets of biometric passports, since their design is strictly regulated and does not allow for a flexible base.

A known method of manufacturing transparent inserts to protect against counterfeiting identification cards and polycarbonate sheets of biometric passports, containing the stages at which: a) provide a transparent thin-film polarizer having two working sides, each of which is used to form independent latent images; b) the latent images are imprinted on at least one area of the first working side of the transparent medium by direct printing with a colorless liquid composition and curing; c) structuring is carried out in a predetermined direction to a predetermined depth of at least one area on the first working side of a transparent thin-film polarizer carrying a latent image to provide optical anisotropy in the specified area, as a result, the first latent polarized images are obtained on the first side of said polarizer, which remain invisible when viewed with the naked eye and are clearly visible in polarized light; d) a thin transparent protective layer is applied over the entire surface of the first working side of the transparent thin-film polarizer with the first latent polarized images formed in it. Further, on the second working side of the transparent thin-film polarizer, the steps are similar to steps b) -d) on its first working side, and the second latent polarized images are obtained on it [2].

The disadvantages of the known method are as follows:

a transparent thin-film polarizer is repeatedly (at least six times) exposed to mechanical and thermal influences, which negatively affects its functional properties;

- 1 035961 the structuring of the area to provide optical anisotropy is carried out in a predetermined direction, i.e. is unidirectional, which makes the optical security element obtained by a known method, easily reproducible for counterfeiters, since structuring in one direction of the optical axis is easy to obtain by many available methods using widespread devices;

the optical anisotropy of the area, obtained by structuring the methods proposed in the known method (mechanical processing using rolls covered with felt, or thermomechanical action - drawing strokes in the machine direction, i.e. in the direction of tape movement using a direct image plotter or thermal printer), provides the difference in the path of the extraordinary and ordinary beams is no more than a quarter of the wavelength of visible radiation, which makes it possible to obtain only black-and-white latent polarized images, which also reduces the security of documents in which an optical security element made by this method is used. The impossibility of increasing the path difference of the extraordinary and ordinary rays by more than a quarter of the length is fundamental for this method, since an increase in the thickness of the anisotropic section can be provided only by increasing the intensity of the thermomechanical effect on this section, which leads to the destruction of the material from which this section is made, and the image becomes visible without using a polarizer.

The objective of the invention is to develop a method for the production of transparent inserts to protect against counterfeiting identification cards and polycarbonate sheets of biometric passports, which will provide the above documents with higher security.

The inventive method contains the following steps:

a) provide a transparent thin-film polarizer with two working sides;

b) take the first polymer film and install it with the possibility of longitudinal movement;

c) the first polymer film is moved, the polymer composition of the alignment layer is applied to one of its sides, then it is dried and an alignment layer is obtained on the first polymer film;

d) rotary embossing of the orienting layer is carried out on the first polymer film and the diffraction structure of the first latent images is obtained on it.

The diffractive structure made by rotary embossing of the orienting layer contains areas of multidirectional orientation of the optical axes, which makes it possible to obtain dynamic visualization of polymer latent images. In addition, in the claimed method, the orienting layer is formed as a separate layer and, unlike the known method [2], it is not used to provide optical anisotropy. In the inventive method, when forming at stage e) an anisotropic layer, it is possible to vary its thickness depending on which latent image needs to be formed: color or black and white. In the prototype, it is not possible to obtain color latent images, since the orienting (structured) layer and the anisotropic layer are aligned in it, and the anisotropic areas with latent images in this aligned layer are thermomechanical. To make them thicker, it is necessary to enhance this effect, and when the effect is increased, the polymer of the said combined layer undergoes destruction, and the resulting latent images become visible without a polarizer;

e) the composition of liquid crystal monomers is applied to the orienting layer having the diffraction structure of the first latent images in a continuous or discontinuous layer, it is dried and a continuous or discontinuous liquid crystal layer is obtained, it is heated to the temperature required for its orientation, and obtained on the orienting layer by the first polymer film of a continuous or discontinuous oriented anisotropic liquid crystal layer, while the composition of liquid crystal monomers is applied in a continuous or discontinuous layer of such a thickness that the obtained continuous or discontinuous oriented anisotropic liquid crystal layer provides a path difference between the extraordinary and ordinary rays of at least a quarter of the wavelength of visible radiation.

The birefringence Δn of an oriented anisotropic liquid crystal layer based on liquid crystal monomers averages 0.2.

In order for an oriented anisotropic liquid crystal layer to be visualized with the appearance of a color image, it is necessary that the following condition for the difference ΔL of the paths of the extraordinary and ordinary rays be satisfied

Db = Δη x d> λ \ 4, where d is the thickness of the oriented anisotropic liquid crystal layer; λ is the wavelength of visible radiation.

If, for example, it is assumed that AL should be equal to 240 nm, which is more than a quarter of the λ / 4 light wavelength, then from the above relation AL = Δn x d it follows that the thickness d of the oriented anisotropic liquid crystal layer should be equal to 1200 nm, what is techno

- 2 035961 a logically acceptable value for the implementation of this method. In this case, the thickness of the oriented anisotropic liquid crystal layer is not limited, as in the known method [2], and can be any, which makes it possible to obtain both black and white and color images;

f) produce UV polymerization of a continuous or discontinuous oriented anisotropic liquid crystal layer on the first polymer film and obtain on it a continuous or discontinuous oriented anisotropic polymer liquid crystal layer, including the first latent images;

g) take the second polymer film and install it with the possibility of longitudinal movement;

steps h) -l) with the second polymer film are performed similarly to the above-described steps c) -f) with the first polymer film, as a result, in step l), a continuous or discontinuous oriented anisotropic polymer liquid crystal layer is obtained on the second polymer film, including the second latent images;

l) connecting with an adhesive one working side of the transparent thin-film polarizer with that side of the first polymer film, which contains a continuous or discontinuous oriented anisotropic polymer liquid crystal layer, including the first latent images;

m) bonding with an adhesive the other working side of the transparent thin-film polarizer to that side of the second polymer film that contains a continuous or discontinuous oriented anisotropic polymer liquid crystal layer including the second latent images;

o) transparent inserts are cut out using a punching stamp to protect against counterfeiting identification cards and / or polycarbonate sheets of biometric passports.

Thus, a transparent thin-film polarizer is used in this method no more than two times.

The advantage has a method in which a thin-film polarizer is used, which is a metal grating deposited on a polymer base, with a period that is comparable to the wavelength of visible radiation.

When sintering plastic identification cards made of polycarbonate and polycarbonate sheets of biometric passports, high temperatures (up to 180 ° C) and pressure are used, as well as long exposure. Under these conditions, polarizers made of polymers generally lose their functional properties. The aforementioned thin-film polarizer, which is a metal grid, also performs its functions after sintering identification cards and polycarbonate sheets of biometric passports.

Description of the preferred embodiment of the proposed method.

We took a roll with the first polymer film. Triacecylcellulose with a thickness of 50 μm was used as the material of the first polymer film.

This roll was installed on a coating installation and the polymer composition of the orienting layer was applied to one of its sides, dried and an alignment layer 500 nm thick was obtained on the polymer film.

Then, on the installation for holographic embossing, rotary embossing of the orienting layer was carried out and the diffraction structure of the first latent images was obtained on it.

On a flexographic printing machine, a continuous layer of liquid crystal monomer composition was applied with an anilox roller onto an orienting layer having a diffractive structure of the first latent images, then it was dried and a continuous liquid crystal layer 1400 nm thick was obtained on the orienting layer. Such a thickness of this layer allows you to subsequently obtain latent images, which are colored during rendering. The liquid crystal layer was heated to a temperature of 48 ° C, required for its orientation, it acquired a spatial orientation depending on the direction of the grooves of the diffraction structure, and a continuous oriented anisotropic liquid crystal layer was formed. It was UV polymerized using an installation for UV polymerization of a flexographic printing machine with a specific power of 100 W / cm ² , and a continuous oriented anisotropic polymer liquid crystal layer was obtained, including the first latent color images, since the difference in the path of the extraordinary and ordinary rays ΔL was 280 nm, which is more than a quarter of the wavelength of visible radiation and therefore visualization of color images will occur.

Took a roll with a second polymer film. Triacecylcellulose with a thickness of 50 μm was also used as the material for the second polymer film. This roll was installed on a coating installation and the polymer composition of the orienting layer was applied to one of the sides, dried and an alignment layer 500 nm thick was obtained on the polymer film.

Further, on the installation for holographic embossing, rotary embossing of the orienting layer was carried out and the diffraction structure of the second latent images was obtained on it.

- 3 035961

On a flexographic printing machine, a continuous layer of liquid crystal monomer composition was applied with an anilox roller onto the orienting layer, then it was dried and a continuous liquid crystal layer 700 nm thick was obtained on the orienting layer. The liquid crystal layer was heated to a temperature of 48 ° C, depending on the direction of the grooves of the diffraction structure, it received a spatial orientation and a continuous oriented anisotropic liquid crystal layer was formed. It was UV polymerized using an installation for UV polymerization of a flexographic printing machine with a specific power of 100 W / cm ² , and a continuous oriented anisotropic polymer liquid crystal layer was obtained, including the second latent black and white images, since the difference in the path of the extraordinary and ordinary rays ΔL is 140 nm, which corresponds to a quarter of the wavelength of visible radiation.

We took a roll of a transparent thin-film polarizer having two working sides. A polarizer with an aluminum metal grating was used as such a polarizer. A roll of a thin-film polarizer and a roll of a first polymer film were installed on the laminating machine. One working side of the thin-film polarizer was connected with an adhesive to that side of the first polymer film, which contains a continuous oriented anisotropic polymer liquid crystal layer including the first latent images.

The operation was repeated with the second side of the thin-film polarizer, then the transparent inserts for plastic identification documents were cut out on the punching machine with a punching die. In these inserts, the latent images were rendered in color on one side and black and white on the other. In addition, when you rotate the inserts during rendering, there is a dynamic color change for the side where the color images are rendered, or the transition from white to black and vice versa from black to white for the side where black and white images are rendered.

Thus, the proposed method for the manufacture of transparent inserts, including the creation of optically anisotropic areas using two layers (an orientation layer and an oriented anisotropic polymer liquid crystal layer) instead of one, as in the prototype, made it possible to obtain a multidirectional structure and the possibility, along with black-and-white latent polarized images, to obtain color latent polarized images, which provide higher protection against counterfeiting plastic identification cards and polycarbonate sheets of biometric passports equipped with these inserts. Mechanical and thermal stresses on the transparent thin-film polarizer are minimized.

Sources of information.

1. Patent RU 2376642, publication date 20.12.2009

2. Patent EAPO No. 014380, publication date October 29, 2010 (prototype).

Claims (2)

CLAIM 1. A method of manufacturing transparent inserts to protect against counterfeiting identification cards and polycarbonate sheets of biometric passports, which contains the following steps: a) take the first polymer film and install it with the possibility of longitudinal movement; b) the first polymer film is moved, the polymer composition of the orienting layer is applied to one of its sides, then it is dried and an orienting layer is obtained on the first polymer film; c) rotary embossing of the orienting layer is carried out on the first polymer film and the diffraction structure of the first latent images is obtained thereon; d) the composition of liquid crystal monomers is applied to the orienting layer having the diffraction structure of the first latent images in a continuous or discontinuous layer, it is dried and a continuous or discontinuous liquid crystal layer is obtained, it is heated to the temperature required for its orientation, and obtained on the orienting layer by the first a polymer film of a continuous or discontinuous oriented anisotropic liquid crystal layer, while the composition of liquid crystal monomers is applied in a continuous or discontinuous layer of such a thickness that the resulting continuous or discontinuous oriented anisotropic liquid crystal layer provides a path difference between the extraordinary and ordinary rays of at least a quarter of the wavelength of visible radiation; e) produce UV polymerization of a continuous or discontinuous oriented anisotropic liquid crystal layer on the first polymer film and obtain on it a continuous or discontinuous oriented anisotropic polymer liquid crystal layer, including the first latent images; f) take the second polymer film and install it with the possibility of longitudinal movement; g) carry out the movement of the second polymer film, apply polymer to one of its sides - 4 035961 composition of the orienting layer, then it is dried and an orienting layer is obtained on the second polymer film; h) performing rotary embossing of the orienting layer on the second polymer film and obtaining on it the diffraction structure of the second latent images; i) the composition of liquid crystal monomers is applied to the orienting layer having the diffraction structure of the second latent images in a continuous or discontinuous layer, it is dried and a continuous or discontinuous liquid crystal layer is obtained, it is heated to the temperature required for its orientation, and a second is obtained on the orienting layer a polymer film of a continuous or discontinuous oriented anisotropic liquid crystal layer, while the composition of liquid crystal monomers is applied in a continuous or discontinuous layer of such a thickness that the thickness of the obtained continuous or discontinuous oriented anisotropic liquid crystal layer provides a path difference between the extraordinary and ordinary rays of at least a quarter of the wavelength of visible radiation; j) produce UV polymerization of a continuous or discontinuous oriented anisotropic liquid crystal layer and obtain on the second polymer film a continuous or discontinuous oriented anisotropic polymer liquid crystal layer, including the second latent images; k) bonding with an adhesive one working side of the transparent thin-film polarizer with that side of the first polymer film that contains a continuous or discontinuous oriented anisotropic polymer liquid crystal layer including the first latent images; l) connecting with an adhesive the other working side of the transparent thin-film polarizer with that side of the second polymer film that contains a continuous or discontinuous oriented anisotropic polymer liquid crystal layer including the second latent images; m) cut transparent inserts with a punching stamp to protect against counterfeiting identification cards and / or polycarbonate sheets of biometric passports. 2. The method according to claim 1, characterized in that it uses a transparent thin-film polarizer, which is a metal grating deposited on a transparent polymer base with a period that is comparable to the wavelength of visible radiation.