RU2732772C1 - Multilayer protective device and its manufacturing method - Google Patents

Abstract

FIELD: means of counterfeit protection of valuable documents.

SUBSTANCE: invention relates to means of counterfeit protection of valuable documents, in particular, to multilayer protective device and method of its manufacturing. Device comprises at least one protective element (9) located between polyethylene terephthalate (PET) carrier film and PET film (7). At that, at least one protective element is made in the form of various visually-visible multi-color images formed on and / or in the transparent surface in the visible spectrum, isotropic, thermoplastic polycarbonate layer (PL) on the side of PET film (7). Each of visually visible image images forming corresponding protective element is provided with corresponding set ξi (x,y) of spatially spaced diffraction gratings, each of which is characterized by different and / or identical for each grid predetermined parameters, comprising: spatial frequency ωi strokes, angular orientation θi strokes in space, depth hi and shape of strokes, partially reflecting layer (5) located above at least one protective element (9), and adhesive layer (6) provided between partially reflecting layer (5) and PET film (7). PET carrier film (1) is configured to be removable when the protective device is applied to the object to be protected.

EFFECT: good interlayer adhesion, mechanical strength, absence of deformation during high-temperature bonding of the relief structure, high heat resistance, reinforcement of the protective element, high wear resistance.

29 cl, 4 dwg

Description

The invention relates to means of protection against counterfeiting of valuable documents, in particular to a multilayer security device and a method for its manufacture, and can be used for placement on the surface or inside the volume of various valuable products of the printing industry, such as check and credit cards, passports, passes, identity cards and other similar polymeric products for protection of identification and / or personal information stored in them.

LEVEL OF TECHNOLOGY

From the existing level of technology in the field of information protection, including personalized information stored in a variety of information and identification documents such as cards and plastic documents of particular value, in recent years, the most widespread are security devices based on diffraction (holographic) and polarization effects.

Known is a multilayer polymer structure and a method for its manufacture, developed at ZAO "Holographic Industry" (Belarus), described in patent EA 027391, IPC B42D 25/328, publ. 31.07.2017, having a security feature in the form of a latent polarization image obtained by the method of mechanical and chemical structuring of the surface of the polymer layer from the following components: polycarbonate, polystyrene, fluoride varnish.

The disadvantage of the proposed structure is insufficient security due to a limited number of (one) security features and poor protection against falsification.

In patent RU 2 386 544, IPC B42D 25/328, publ. On April 20, 2010, the patent holder FSUE "Goznak" proposed a security technology to protect identity documents, credit cards, banknotes and securities from counterfeiting, including multilayer transparent plastic structures with security features based on the moiré effect of two rasterized reflective, luminescent, and / or relief images.

The disadvantage of the proposed structure is also insufficient security due to a limited number of (one) security features and weak protection against falsification.

The patent of the Federal State Unitary Enterprise "Goznak": RU 2 433 048, IPC B32В 29/00, publ. 10.11.2011 disclosed an identification document containing a multilayer information page with a multilayer security element. The specified security element is applied to the printed surface of at least one inner layer of the specified identification page, and under the outer layer of transparent polymer is introduced a polymer metallized a film with high reflectivity, on which the identification variable information is applied, and a transparent foil with holographic images is applied to the outer surface of the information page from at least one side thereof.

Analogs of the claimed technical solution can be considered the protective elements disclosed in patents RU 2 374 080, IPC B42D 15/00, publ. 27.11.2009, and RU 2 344 047, IPC B42D 15/00, publ. 20.01.2009 ., in which security elements are made on the basis of multilayer transparent color-contrast destructible polymer structures for secure printed products, for example, banknotes, securities, credit cards, documents, certificates and other similar products and methods of obtaining them.

The closest analogue of the claimed multilayer security device and the method for its manufacture is the technical solution disclosed in RU 2 557 620, IPC B42D 25/328, publ. 27.07.2015, which discloses a multifunctional identification multilayer polymer structure containing a wide range of information features required for identifying the identity of a specific user, performing banking operations, accessing government services, payment terminals and having reliable protection against attempts to forge or falsify.

This is achieved by the fact that this structure is made with a variety of information and identification features in the form of color-variable printed images and photographs of the owner of the document, security elements, stripes and / or labels of various shapes from a transparent film with a security image, such as photopolymer volumetric or embossed ("rainbow ») Hologram, diffraction or latent image that appears when the viewing angle is changed.

At the same time, at least one layer of the claimed structure is made of a composite material based on polycarbonate, including components that cannot be visually detectable in an article, such as magnetic microparticles, microfibers, pigments or quantum dots, as well as elements of a microchip radio-frequency structure.

The technology proposed in the prototype patent imposes on layers with optical security features based on diffractive structures, for example, rainbow holograms, serious requirements for the resistance of features during the manufacturing process, for example, an ID card.

Nevertheless, the disadvantages of the identification document described in the prototype patent include:

1) insufficient interlayer adhesion of the layers with the signs formed in them in the PC card, as a result of which it can be divided into these layers, i.e. insufficient mechanical strength of the multilayer material of the protected product (personified card);

2) it is technologically difficult to use features based on surface microrelief (relief-phase "hologram"), due to its deformation during high-temperature gluing of layers ("sintering"), which reduces the degree of protection of the security element itself.

The proposed invention eliminates these disadvantages by the fact that the proposed multilayer security device with at least one security element stored inside it is made on the basis of a polyethylene terephthalate (PET) layer (1) and a polycarbonate layer (2), on the surface of which the embossed structuring of the surface (3) with the formation of a visually visible picture color in the spatial orientation of the strokes of diffraction grating images (4), forming at least one protective element (4), while the specified structure and composition of these layers provides indestructible the connection between the security element in the security device and the object to be protected, and the increase in the thermal resistance of the proposed relief structure of the security element ensures complete preservation of its information content, due to the absence of deformation of the said relief structure. In this case, the reinforcement of the protective element with a PET layer (7) provides an increased wear resistance of the protective device. An important aspect of the claimed invention is the placement of a security element (4) inside the product, in contrast to the prototype, where information signs and identification signs are located on a substrate made of an opaque polymer material, and only individual nanosized particles are introduced into the polycarbonate layer, the presence of which can be recorded by special equipment. At the same time, the presence of information and identification signs on the surface of the upper and lower layers in RU 2 557 620 C1 violates the flatness of the valuable product to be protected, which is critical for such products as banknotes, identification documents, etc., and is eliminated by the design proposed in the present description of the multilayer security device and the method for its manufacture.

In addition, an important aspect of the claimed invention is to provide at least one security element (4) made in the form of visually visible picture, usually multicolor images based on a plurality of spatial orientation of the lines of diffraction grating images, based on individual diffraction gratings, each of which is distinguished by such machine-readable security features as spatial frequencies, orientation and shape of the strokes in them, which provides a unique multi-level security structure, which is located inside a multilayer security device, which makes it practically impossible for unauthorized reproduction of the element itself.

The essence of the invention

According to a first aspect of the invention, a method for manufacturing a multilayer security device is provided, comprising the steps of:

1) provide a polyethylene terephthalate (PET) carrier film (1) having a thickness in the range of 40-50 μm, on which a security element (4) is formed;

1.1.) A release agent is preliminarily applied to one surface of the said PET carrier film (1), which is an alcohol release varnish RESR007, in order to ensure the possibility of removing the said PET carrier film (1) when applying a protective device to the object to be protected. treating the other surface of the PET carrier film (1) with a corona discharge or chemical treatment to ensure uniform separation of the protective device from the PET carrier film (1);

2) a carrier film (1) with an applied anti-adhesive agent, a liquid layer of a polycarbonate solution (PC) is applied to the specified surface of the PET;

3) provide the formation of an isotropic, transparent in the visible region of the spectrum, thermoplastic polycarbonate layer (PC) (2) from a liquid layer of a polycarbonate (PC) solution;

4) on the surface (3) of an isotropic transparent thermoplastic PC layer (2) by the method of cold or hot embossing, relief microstructuring of the surface (3) is provided in the form of at least one set ξ i (x, y) of spatially spaced diffraction gratings, where i = 1 , 2,3 ... N is the number of diffraction gratings in the set, while each of the indicated diffraction gratings is characterized by different and / or the same preset parameters for each grating, containing: spatial frequency ω i grooves, angular orientation θ i grooves in space, depth h i and the shape of the strokes, which provides the formation of various visually-visible multicolor images (4), forming at least one security element (4), while the predetermined parameters of each of the diffraction gratings are additional machine-readable security features;

5) applying a partially reflective layer (5) by vacuum deposition on a microstructured surface with at least one protective element (4) of PC layer 2;

6) an adhesive layer (6) is applied, made in the form of an acrylic composition on a solvent basis with a hardener, on the surface of a partially reflecting layer (5);

7) provide a polyethylene terephthalate (PET) film (7) over said adhesive layer (6). PET film (7) has a thickness in the range of 13-17 microns and is designed to protect the protective element (4) from chemical and mechanical damage

At the same time, at stage 2) of the method, a liquid layer of a polycarbonate solution is applied to a PET carrier film (1) by a polygraphic method, which is flexographic printing or intaglio printing, and at stage 3) of the method, a solid-state transparent PC layer (2) is formed from a liquid layer solution of polycarbonate (PC) through the implementation of evaporation of the solvent from the liquid layer of the solution of polycarbonate (PC). In this case, the solid-state transparent isotropic PC layer (2) has a thickness in the range of 0.3-10 microns.

In addition, the partially reflecting layer (5) is configured to transmit radiation in the visible region of the spectrum and is made of at least one of: ZnS, ZnSe, NiO _2, and the thickness of said layer (5) is from 10nm to 50nm, preferably about 20nm.

The security element (4) has a dimension in the range of 2mm-1cm and is a corresponding set of spatially spaced diffraction gratings made with the possibility of forming predetermined symbols in the form of at least one of: letters, numbers, symbols, or their combinations.

In this case, the parameters of the diffraction gratings can be as follows: the spatial frequency (ωi) of the grooves of each diffraction grating of the set of spatially spaced diffraction gratings is in the range from 50 to 2000 lines / mm, the angular orientation (θi) of the grating grooves is in the range from 0 to 180 angular degrees, and the depth (hi) of the grooves (relief) of the grating is in the range from 100 nm to 0.6 µm, while the shape of the grooves in the diffraction grating is straight or curved lines.

In this case, the set of diffraction gratings is at least one hologram, preferably a rainbow hologram.

According to a second aspect of the invention, there is provided a multi-layer security device according to the method disclosed above and comprising:

- at least one security element (4) located between the polyethylene terephthalate (PET) carrier film (1) and PET film (7), while at least one security element (4) is made in the form of various visually visible multicolor images formed on and / or in the surface (3) of a transparent in the visible region of the spectrum, isotropic, thermoplastic polycarbonate layer (PC) (2) from the side of the PET film (7), with each of the visually visible picture images forming a corresponding at least at least one protective element (4) is provided by the corresponding set ξ i (x, y) of spatially separated diffraction gratings, where i = 1,2,3 ... N is the number of diffraction gratings in the set, each of the indicated diffraction gratings is characterized by different and / or identical for each lattice with predetermined parameters containing: the spatial frequency ω i of the lines, the angular orientation θ i of the lines in space, the depth h i and the shape of the lines, at this, the predetermined parameters of each of the diffraction gratings represent additional security features;

- a partially reflective layer (5) located over at least one security element (4), and

- an adhesive layer (6) provided between the partially reflective layer (5) and the PET film (7),

wherein the PET carrier film (1) is removable when the security device is applied to the object to be protected.

In this case, the security device according to the second aspect of the invention is configured to form a set of visible color images in the plane of the location of the security element when viewed in the visible range of the spectrum, while changing the viewing angle or illumination provides a color change of individual spatial parts of these images.

In this case, the protective element (4) has a dimension in the range of 2 mm - 1 cm.

The security device is adapted to be used as a sticker for protecting an object to be protected, in the form of a transparent window in at least a part of the value document to be protected, or as a translucent region in at least a part of the value document to be protected.

In this case, the object to be protected is one of: banknotes, licenses, passport pages, plastic card, voucher, promotion, checkbook, excise stamp, identification document.

List of drawing figures

FIG. 1 is a general cross-sectional view of a multilayer security device.

FIG. 2 is a general cross-sectional view of a multilayer security device placed on an object to be protected.

FIG. 3a is a general view of the diffraction grating.

FIG. 3b is a schematic view of a moth-eye structure based on diffraction gratings.

Preferred Embodiments of a Multilayer Security Device

The multilayer security device and its manufacturing method will be described with reference to FIGS. 1, 2 and 3a, 3b.

1 is a general cross-sectional view of a multilayer security device. Reference numeral 1 denotes a polyethylene terephthalate (PET) carrier film (1) on which a multilayer security device (A) is formed. The PET carrier film has a thickness in the range of 40-50 µm.

Position 2 denotes an isotropic, transparent in the visible region of the spectrum, thermoplastic polycarbonate layer (PC) (2) (hereinafter PC layer (2)), formed from a liquid layer of a polycarbonate (PC) solution. Initially, the PC layer (2) with a flat surface (3) has a thickness in the range of 0.3-10 microns.

At least one protective element (4) is formed on the flat surface (3) of the isotropic transparent thermoplastic PC layer (2). At least one security element (4) is formed by relief microstructuring the surface (3) of the PC layer (2) in the form of at least one set ξ i (x, y) where i = 1,2,3 ... N (where N is number of diffraction gratings in the set) of spatially spaced diffraction gratings, each of which is characterized by preset parameters that differ for each grating, including: spatial groove frequency ω i = ψ (x, y) (see Fig.3b), angular orientation of grooves in space θ i = ϕ (x, y) (see Fig. 3a), depth h i = H (x, y)) (see Fig.3b) and the shape of the strokes, which ensures the formation of various visually visible multicolor images (4) forming at least one visually distinguishable security element (4), and additional machine-readable security features (not indicated) formed by the parameters of spatially spaced diffraction gratings containing the spatial frequency of the grooves, the angular orientation of the grooves in space, the depth and shape w trichomes specified by the manufacturer of the protective device.

Numeral 5 denotes a partially reflective layer applied to the surface (3) with at least one security element (4) and completely repeating the relief of the security element 4, therefore, in FIG. 1 and 2, positions 4 and 5 are conventionally indicated by one arrow. The reflectivity of the partially reflective layer (5) is 27-30%. The partially reflecting layer (5) is configured to transmit radiation in the visible region of the spectrum from at least one of the components: ZnS, ZnSe, NiO ₂ . The thickness of the partial reflective layer (5) is in the range from 10 to 50 nm, preferably about 20 nm.

On the surface of the partially reflecting layer (5), an adhesive layer (6) is applied in the form of an acrylic compound on a solvent basis with a hardener for attaching the PET film (7). PET film (7) is designed to protect at least one security element (4) from chemical and mechanical damage.

PET film (7) has a thickness in the range of 13-17 μm.

FIG. 2 is a general cross-sectional view of a multilayer security device placed on an object to be protected (polyethylene terephthalate (PET) carrier film (1) is previously removed).

Position 2 denotes an isotropic, transparent in the visible region of the spectrum, thermoplastic polycarbonate layer (PC) (2) (hereinafter PC layer (2)), formed from a liquid layer of a polycarbonate (PC) solution. PC layer (2) has a thickness in the range of 0.3-10 microns.

At least one protective element (4) is formed on the flat surface (3) of the isotropic transparent thermoplastic PC layer (2). The specified protective element (4) is formed by means of relief microstructuring of the surface (3) of the PC layer (2) in the form of at least one set ξ i (x, y) of spatially separated diffraction gratings, each of which is characterized by preset parameters differing for each grating ( see Fig. 3a, 3b) containing: lattice period ν = 1 / ω i; the spatial frequency of the strokes ω i = ψ (x, y), the angular orientation of the strokes in space θ i = ϕ (x, y), the depth h i = H (x, y) and the shape of the strokes, which provides the formation of various visually visible multicolor images (4), forming at least one visually distinguishable security element (4), and additional machine-readable security features (not indicated) formed by the parameters of spatially spaced diffraction gratings containing the spatial frequency of the grooves, the angular orientation of the grooves in space, the depth and the shape of the lines specified by the manufacturer of the protective device.

It should be noted that each set ξ i (x, y) of spatially spaced diffraction gratings is configured to generate predetermined symbols in the form of at least one of letters, numbers, symbols, or combinations thereof.

In this case, the spatial frequency (ωi) of the grooves of each diffraction grating of the set ξ i (x, y) of spatially spaced diffraction gratings is in the range from 50 to 2000 lines / mm, the angular orientation (θi) of the grating grooves is in the range from 0 to 180 angular degrees and the depth (hi) of the grooves (relief) of the grating is in the range from 10 nm to 0.6 μm. An example of a diffraction grating with angular orientation (θi) of grating grooves is shown in FIG. 3a. FIG. 3b shows a schematic view of the microstructured surface (3) of PC layer 2, where the depth (hi) of the grooves (relief) of the grating and the grating period ν = 1 / ω i are conventionally shown .

The position (5) denotes a partially reflective layer applied to the surface 3 with at least one security element (4) and completely repeating the relief of the security element (4), therefore, in FIG. 1 and 2, positions 4 and 5 are conventionally indicated by one arrow.

The reflectivity of the partially reflective layer (5) is 27-30%. The partially reflecting layer (5) is configured to transmit radiation in the visible region of the spectrum from at least one of the components: ZnS, ZnSe, NiO _2, TiO _2. The thickness of the partially reflecting layer (5) is in the range from 10 to 50 nm, preferably about 20 nm.

On the surface of the partially reflecting layer (5), an adhesive layer (6) is applied in the form of an acrylic compound on a solvent basis with a hardener for attaching the PET film (7). PET film (7) is designed to protect at least one security element (4) from chemical and mechanical damage.

PET film (7) has a thickness in the range of 13-17 μm.

As already mentioned above, each set ξ i (x, y) of spatially spaced diffraction gratings made on the surface (3) of the PC layer (2) is a hologram, preferably a rainbow hologram with the ability to form predetermined images. Strictly speaking, such a hologram is a set of regions, each of which is filled with special relief microstructures in the form of separate diffraction gratings synthesized on a computer, differing in the spatial frequency and orientation and spatial direction of the grooves, as well as the depth and shape of the grooves between them.

In this case, the parameters of the diffraction gratings can vary depending on the image being formed, for example, the spatial frequency (ωi) of the grooves of each diffraction grating of a set ξ i (x, y) of spatially separated diffraction gratings is in the range from 50 to 2000 lines / mm, the angular orientation (θi ) of the grating grooves is in the range from 0 to 180 angular degrees and the depth (hi) of the grating grooves (relief) is in the range from 10 nm to 0.6 μm.

Such sets of diffraction gratings, when irradiated with radiation in the visible region of the spectrum, as a result of the known from the prior art optical effects of diffraction on micro-sized structures and interference on them, in the general case, color images are formed, observed in the plane of the location of such a hologram. When the angle of observation or illumination changes, the diffraction structure of the transmitted and / or reflected light beam through these holograms changes and, accordingly, the color composition of the images formed on them changes. Features of image visualization based on diffraction gratings, including holograms, are disclosed in the following publications: RU 2370376, US 4856857, US 4788116.

In accordance with the proposed invention, when reproducing the image formed in the security element (A), the light incident on it is divided into transmitted and reflected in a ratio determined by the partial reflection of the layer (5), which is about 30%.

Since the surface (3) of the PC layer (2) is structured with diffraction gratings, the transmitted and reflected beams are additionally divided into diffraction beams, the deflection angle of which depends on the spatial frequency of the diffraction gratings and the angular orientations of the lines of the diffraction gratings, as well as the wavelength of the light at which the observation is carried out. ... When viewed in natural light, the diffraction grating is observed in a specific color. If the direction of illumination or observation is changed, then the color of the rendered image of this diffraction grating also changes.

To form a set of diffraction gratings, two main methods are currently used: dot matrix hologram (DMG), frame matrix hologram (FMG) (see Rudolf L. van Renesse. Security aspects of commercially available dot matrix and image matrix origination systems / / SPIE International Conference on Optical Holography and its Applications, 24-27 May 2004, Kiev, Ukraine).

DMG (or diffractive optically variable images) consist of an array of well-diffracted points. The DMG points have the same diffraction pattern. The period of the diffraction grating (DG) and its orientation may or may not change from point to point, depending on the design of the security element.

FMGs consist of an array of DR microimages (an array of frames). A frame is a single “pixel” of a holographic image. The image inside the frame can consist of uniform gratings or randomly arranged different gratings (with different spacing and orientation). The entire set of microframes forms a total protective device, consisting of many different grilles.

Examples of obtaining holograms based on dot matrix technology are disclosed in publications: WO9829767, US5262879, US5822 879, US6263104, US2003 / 0152274.

One aspect of the invention is a method of manufacturing a multi-layer security device.

The method of manufacturing a multilayer security device comprises the following steps: 1) A polyethylene terephthalate (PET) carrier film (1) is provided on which the security element is formed. It should be noted that the production of security devices, for example, in the form of labels, as a carrier film (1), a polyethylene terephthalate (PET) carrier film (1) with a thickness of 40-50 microns is used, with an alcohol release applied to it on one side, for example - RESR007 varnish with anti-adhesive properties and treated on the reverse side by corona discharge or chemical treatment to ensure the subsequent uniform descent of the resulting protective devices, for example, in the form of labels (A) without sticking to the PET carrier film roll (1).

2) Next, a liquid layer of a polycarbonate (PC) solution is applied to this carrier film (1) by almost any printing method, for example, flexographic or gravure printing, with the formation of a transparent isotropic PC layer (2) 0.3-10 μm thick after evaporation of the solvent.

3) on the surface (3) of an isotropic transparent thermoplastic PC layer (2) by the method of cold or thermal embossing (temperature 150-180 ° C, pressing pressure 1.5-2 bar) provide relief microstructuring of the surface (3) in the form of at least one set ξ i (x, y) of spatially separated diffraction gratings, each of which is characterized by different and / or the same preset parameters for each grating, containing: the spatial frequency ω i grooves as a function of the spatial distribution ω i = ψ (x, y) in the set ξ i (x, y) of spatially separated diffraction gratings; angular orientation Ɵ i lines as a function of the spatial distribution of angles θ i = ϕ (x, y) in a set ξ i (x, y) of spatially separated diffraction gratings; the depth hi with the spatial distribution of depths as a function of the spatial distribution h i = H (x, y) in the set ξ i (x, y) of spatially separated diffraction gratings and the shape of the grooves, which ensures the formation of various visually visible multicolor images (4), forming at least one security element (4).

In this case, the original of the security element (4) was originally manufactured using the Dot-matrix holography (DMG) technology on a KineMax setup (Polish Holographic systems) with a resolution of 24,000 dpi and a relief depth of 100 to 500 nm. The recording was carried out on a positive photoresist with a diode laser with a wavelength of 440 nm. The spacing of the diffraction gratings recorded in the RDRE and their orientation varied depending on the design.

5) To increase the brightness of the glow of at least one security element (4), a partially reflecting layer (5) is applied, made with the possibility of transmitting radiation in the visible region of the spectrum, from a material, for example, ZnS, ZnSe, NiO ₂ , TiO2 with a reflectivity of about 27 -30% on a microstructured surface in the form of at least one security element (4) by vacuum deposition. The thickness of the partially reflective layer (5) is in the range from 10 to 50 nm, preferably about 20 nm.

6) Apply an adhesive layer (6) in the form of an acrylic compound on a solvent basis with a hardener on the surface of the partially reflective layer (5).

When applying the protective device (A) to the object to be protected, indicated by pos. 9 (hereinafter the item to be protected) in FIG. 2. The protected item is one of: banknotes, licenses, passport pages, plastic card, voucher, promotion, checkbook, excise stamp, identification document.

The (PET) carrier film (1) is previously removed from the protective device (A). The protective device (A) is placed on the protected item (9) by means of a sintering layer (8).

In the technology of manufacturing "plastic" (currently, usually polycarbonate (PC)) valuable documents, such as pages of passports (for example, a foreign passport of the Russian Federation) or identification (ID) cards, high temperature bonding is used (professional slang "sintering") between by themselves under the pressure of polycarbonate layers of different functionality (printed layer, carrier layer, anti-counterfeiting layer, layer that prevents any mechanical or chemical damage, etc.). As a result, after such “sintering” a monolithic polycarbonate card or information page is formed with functional, including security elements located inside. FIG. The second layer (8) of sintering serves for high-temperature bonding of the protective device (A) with the protected product (9).

The operation of placing the protective device (A) on the protected item (9) can be carried out in two ways:

- hot pressing with heat-sensitive glue;

- gluing with adhesive with a permanent tacky composition, which is a mixture of polymer, resin and hydrocarbon diluent.

Before this, the operation of separating the security device (A) shown in FIG. 1 from the PET carrier film (1) is performed. The separation is carried out by cutting the protective device (A) to a depth of 13-17 microns, equal to the thickness of the PET layer (7), using rotary cutters with magnetic flexible stamps and knives.

Industrial applicability

The claimed multilayer security device can be placed on the surface or inside the volume of various valuable products of the printing industry, such as check and credit cards, passports, passes, identity cards and other similar polymer products in order to protect the identification and / or personal information stored in them with the help of at least one visually visible security element and additional machine-readable security features that are preset parameters of diffraction gratings containing the spatial frequency of the grooves, the angular orientation of the grooves in space, the depth and shape of the grooves.

Claims (41)

1. A method of manufacturing a multilayer security device, comprising the following steps, in which: 1) provide a polyethylene terephthalate (PET) carrier film (1) on which the security element is formed; an anti-adhesive agent is preliminarily applied to one surface of said PET carrier film (1) to enable the said PET carrier film (1) to be removed when the protective device is applied to the object to be protected; 2) a carrier film (1) with an applied anti-adhesive agent, a liquid layer of a polycarbonate solution (PC) is applied to the specified surface of the PET; 3) provide the formation of an isotropic, transparent in the visible region of the spectrum, thermoplastic polycarbonate layer (PC) (2) from a liquid layer of a polycarbonate (PC) solution; 4) on the surface (3) of an isotropic transparent thermoplastic PC layer (2) by the embossing method, a relief microstructuring of the surface (3) is provided in the form of at least one set ξ i (x, y) of spatially separated diffraction gratings, where i = 1.2, 3 ... N is the number of diffraction gratings in the set, while each of the indicated diffraction gratings is characterized by different and / or the same for each diffraction grating preset parameters, containing: spatial frequency ω i grooves, angular orientation θ i grooves in space, depth h i strokes and the shape of the strokes, which provides the formation of various visually visible multicolor images (4), forming at least one security element (4), while the specified predetermined parameters of each of the diffraction gratings are additional security features; 5) applying a partially reflective layer (5) by vacuum deposition on a microstructured surface with at least one protective element (4) of PC layer 2; 6) applying an adhesive layer (6) to the surface of the partially reflecting layer (5); 7) provide a polyethylene terephthalate (PET) film (7) over said adhesive layer (6). 2. A method according to claim 1, wherein the PET carrier film (1) has a thickness in the range of 40-50 µm. 3. The method of claim 1, wherein the release agent is an alcohol release varnish RESR007. 4. A method according to claim 1, wherein the other surface of the PET carrier film (1) is pretreated with a corona discharge or chemical treatment to ensure uniform separation of the security device from the PET carrier film (1). 5. The method according to claim 1, wherein in step 2) a liquid layer of the polycarbonate solution is applied to the PET carrier film (1) by a polygraphic method, which is flexographic printing or gravure printing. 6. The method according to claim 1, wherein at step 3) the formation of a solid-state transparent PC layer (2) from a liquid layer of a polycarbonate (PC) solution is provided by evaporating the solvent from a liquid layer of a polycarbonate (PC) solution. 7. The method according to claim 1, wherein the solid-state transparent isotropic PC layer (2) has a thickness in the range of 0.3-10 microns. 8. A method according to claim 1, wherein at step 4) relief structuring of the surface (3) is provided by cold or hot stamping. 9. The method according to claim 1, in which the partially reflecting layer (5) is configured to transmit radiation in the visible spectral region and is made of at least one of: ZnS, ZnSe, NiO _2, TiO ₂ and the thickness of said layer (5) lies in the range from 10 nm to 50 nm, preferably about 20 nm. 10. A method according to claim 1, wherein the adhesive layer (6) is in the form of a solvent-based acrylic compound with a hardener. 11. A method according to claim 1, wherein the PET film (7) has a thickness in the range of 13-17 μm and is configured to protect the security element (4) from chemical and mechanical damage. 12. The method according to claim 1, wherein the security element (4) is a suitable set of spaced apart diffraction gratings configured to generate predetermined symbols in the form of at least one of letters, numbers, symbols, or combinations thereof. 13. The method according to claim 1, in which the spatial frequency (ωi) of the grooves of each diffraction grating of the set of spaced diffraction gratings is in the range from 50 to 2000 lines / mm, the angular orientation (θi) of the grating grooves is in the range from 0 to 180 angular degrees and depth (hi) of grooves (relief) of the grating are in the range from 100 nm to 0.6 μm. 14. The method of claim 1, wherein the shape of the grooves in the diffraction grating is straight or curved lines. 15. The method according to claim 1, wherein the predetermined parameters of spatially spaced diffraction gratings containing the spatial frequency of the grooves, the angular orientation of the grooves in space, the depth and shape of the grooves are additional machine-readable security features. 16. The method according to claim 1, wherein the security element (4) has a dimension in the range of 2 mm - 1 cm. 17. The method of claim 1, wherein the set of diffraction gratings is at least one hologram. 18. The method of claim 1, wherein the at least one hologram is at least one rainbow hologram. 19. The method according to claim 1, in which the set of diffraction gratings is preliminarily provided using the Dot-matrix holography technology on the KineMax installation. 20. Multilayer security device made by the method according to one of paragraphs. 1-19 containing: - at least one security element (4) located between the polyethylene terephthalate (PET) carrier film (1) and PET film (7), while at least one security element (4) is made in the form of various visually visible multicolor images formed on and / or in the surface (3) of a transparent in the visible region of the spectrum, isotropic, thermoplastic polycarbonate layer (PC) (2) from the side of the PET film (7), each of the visually visible picture images forming a corresponding security element (4 ) is provided by the corresponding set ξ i (x, y) of spatially separated diffraction gratings, where i = 1,2,3 ... N is the number of diffraction gratings in the set, each of the indicated diffraction gratings is characterized by different and / or identical preset parameters for each grating containing: the spatial frequency ω i of the grooves, the angular orientation θ i of the grooves in space, the depth h i and the shape of the grooves, while the preset pa the dimensions of each of the diffraction gratings represent additional security features; - a partially reflective layer (5) located over at least one security element (4), and - an adhesive layer (6) provided between the partially reflective layer (5) and the PET film (7), wherein the PET carrier film (1) is removable when the security device is applied to the object to be protected. 21. The device according to claim 20, configured to form a set of visible color images in the plane of the security element when viewed in the visible range of the spectrum, while changing the viewing angle or illumination provides a change in the color of individual spatial parts of said images. 22. The device according to claim. 20, in which the security element (4) is a corresponding set of spatially spaced diffraction gratings, configured to generate predetermined symbols in the form of at least one of: letters, numbers, symbols, or combinations thereof. 23. The device according to claim 20, in which the spatial frequency (ωi) of the grating grooves is in the range from 50 to 2000 lines / mm, the angular orientation (θi) of the grating grooves is in the range from 0 to 180 angular degrees and the depth (hi) strokes (relief) of the grating are in the range from 10 nm to 0.6 μm. 24. The device according to claim. 20, in which the predetermined parameters of the spaced diffraction gratings containing the spatial frequency of the grooves, the angular orientation of the grooves in space, the depth and shape of the grooves are additional machine-readable security features. 25. Device according to one of paragraphs. 20-24, in which the security element (4) has a dimension in the range of 2 mm - 1 cm. 26. Device according to one of paragraphs. 20-24 adapted to be used as a sticker to protect an object to be protected. 27. Device according to one of paragraphs. 20-24, adapted to be used as a transparent window in at least part of the value document to be protected. 28. Device according to one of paragraphs. 20-24 configured to be used as a translucent region in at least a portion of the value document to be protected. 29. Device according to one of paragraphs. 20-28, in which the object to be protected is one of: banknotes, licenses, passport pages, plastic card, voucher, promotion, checkbook, excise stamp, identification document.

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