RU2802458C1 - Multilayer product containing protective element, and method for its production - Google Patents

Abstract

FIELD: security technologies.

SUBSTANCE: method is proposed for producing a reflective layer for protection of valuable documents against forgery, a reflective layer for protection of valuable documents against forgery, a diffractive protective element in the form of a film with a reflective layer, and a multilayer product with an identifying optically variable image, which is a valuable document. Preliminarily, a holographic grating is applied to the polymer substrate in the form of a rolled polymer material to form a lacquer layer with an embossed grating and a layer containing valuable information. Vacuum deposition of a mixture of indium and tin at a mass ratio of indium to tin from 10:90 to 2:98 is carried out by the magnetron method. The said deposition is carried out in an argon atmosphere at an operating pressure of 10^-3 -10^-4 mmHg on a rolled polymeric material moving by reeling, located on a shaft cooled to a temperature of -15 to +15°C. After the said deposition, oxidation is carried out in the air.

EFFECT: simplification of the technology for obtaining a reflective layer of a security element of valuable documents.

12 cl, 1 dwg, 3 ex

Description

The invention relates to the field of security technologies for various types of printed products, including security documents made of composite multilayer polymer materials.

More precisely, the invention relates to security documents including an optically active security element.

Preferably, holograms are used for this purpose, which are widely used in the field of product protection and therefore have a high degree of recognition, recognition and safety.

Typical holograms, which are currently used for product protection and as security elements for valuable documents, usually have a primarily metallic shiny appearance, which, when the viewing angle changes, due to the diffraction of light, creates a play of colors of the rainbow spectrum on the hologram structures. These diffraction effects, however, are always very similar, and all such products have a metallic luster in common. Therefore, there is a need for new optically variable effects that differ from conventional ones not only in the hologram motif, but also in the main color, or, accordingly, in a different gloss.

In addition, there is a need for a stable conductive film capable of freely controlling chemical resistance to acids, alkalis and the like. without deteriorating the electrical and optical characteristics of the film. There was a problem that the film was not adapted to the application conditions.

Currently, the urgent task is to create a method for producing ITO coatings (films based on indium tin oxide) with a controlled refractive index value, which makes it possible to control their optical properties.

From RU 2637044 C2, publ. 11.29.2017, there is a known method for producing a coating based on indium and tin oxide on the surface of a substrate, which includes sputtering indium and tin oxide onto the substrate to ensure the required value of the refractive index of the coating by selecting a technological parameter of the sputtering process. According to the invention, sputtering is carried out at normal orientation of the substrate relative to the flow of the sputtered substance; the process of sputtering indium and tin oxide onto the substrate includes the sequential sputtering operation of indium and tin oxide by the method of electron beam evaporation or magnetron sputtering at a temperature of 400 to 500 °C and the sputtering operation indium and tin oxide by magnetron sputtering at temperatures from 15 to 75 °C, while ensuring the required value of the refractive index of the coating by selecting the mass of the substance applied at each of these sputtering operations.

From RU 2575423 C2, publ. 02/20/2016, a security label or adhesive tape with a manipulation indication is known, having a flexible carrier substrate based on a flexible synthetic film. The following layers are applied to the surface of the supporting substrate: an embossed layer of varnish, a translucent metal layer, or a layer with a high refractive index, a partial separating layer of varnish in the form of letters, signs, symbols, lines, guilloches, numbers or strokes, one or more layers of varnish with optical properties, self-adhesive coating. In areas not covered with a separating layer of varnish, the adhesion of all layers to each other and the adhesion of the layer to the protected object is greater than the adhesion of the layer to the layer, or the adhesion of all layers to each other is greater than the adhesion of the layer to the protected object. Moreover, in areas covered with a separating layer of varnish, the adhesion of all layers to each other and the adhesion of the layer to the protected object is greater than the adhesion of layer to layer or adhesion of layer to layer.

From JP3163015 B2, publ. 06/09/2016, a transparent conductive film based on indium and tin is known, formed by forming a composite metal oxide film consisting of indium, tin and zinc, where the composite metal oxide film contains at least one oxide In ₄ Sn ₃ O ₁₂ .

From RU 2053558 C1, publ. 01/27/1996, it is known that in the production of valuable documents, in order to obtain a clearly visually distinguishable mark of authenticity and additionally provide electrical conductivity for machine reading, an electrically conductive layer based on indium and tin is used.

As the closest analogue, document RU 2591770 C2, publ. 07/20/2016, according to which an achromatic security element is known for valuable documents, such as banknotes, cards, identity documents and similar documents, as well as a method for producing such security elements, for valuable documents including these security elements. The achromatic security element includes a thermoplastic or radiation-curable polymer layer, wherein said layer is embossed with diffusely reflective non-diffractive microstructures based on indium and tin, wherein the microstructures have dimensions that are outside the wavelength range of visible light in the non-diffraction mode and provide non-periodicity surface topography such that incident light is diffusely reflected or scattered by statistical irregularities in the surface.

Significant disadvantages inherent in the known technical solutions described above include the complexity of implementing the method for producing a protective element.

The problem solved by the invention is to simplify the technology for obtaining the reflective layer of the security element of securities. This is achieved through the following aspects.

According to the first aspect, a method is proposed for producing a reflective layer to protect against counterfeiting of valuable documents, including vacuum deposition of a mixture of indium and tin onto a polymer substrate followed by oxidation in air, characterized in that vacuum deposition of a mixture of indium and tin is carried out in one stage on a previously prepared side polymer substrate in the form of a rolled polymer material with an applied holographic lattice with the formation of a varnish layer with an embossed lattice and a layer containing valuable information, while vacuum deposition of a mixture of indium and tin with a mass ratio of indium to tin from 10:90 to 2:98 is carried out by the magnetron method in an argon environment at a working pressure of 10-3 –10-4 mm. rt. Art. on a rolled polymer material moving by rewinding on a shaft cooled to a temperature from -15°C to +15°C, at a temperature on the surface of the rolled polymer material of 25–30°C, the linear speed of movement of the rolled polymer material is 0.5 - 15 m /min and magnetron power supply power in the range of 0.5 - 5.0 kW.

According to the second aspect of the proposed invention, the reflective layer for protecting against counterfeiting of valuable documents, obtained by the method described above, is an infrared mirror and has an optical property that provides the appearance of a metallized surface in incident light, and the appearance of a translucent element in transmitted light. In particular, the reflective layer has a microcrystalline or amorphous structure.

According to the third aspect of the claimed invention, the diffraction protective element is a film comprising the aforementioned reflective layer, a translucent indium-tin layer, a partially oxidized indium-tin layer and an outer protective oxide film of indium and tin with a thickness of 20-40 angstroms, with the total thickness of the film being up to 300 angstroms (when measured at a wavelength of 555 nm).

According to the fourth aspect of the claimed invention, a multilayer optically variable image identification product is provided, which is a value document containing said diffractive security element deposited on a polymer substrate. In particular, a valuable document is a security, a banknote or an identity document.

The invention is illustrated by the drawing (Fig. 1), which shows a multilayer product with an identifying optically variable image, consisting of:

A – polymer substrate;

B – varnish layer with an embossed diffraction grating;

C – layer containing valuable information, for example, personal graphic and text data;

D – translucent indium-tin layer;

E – partially oxidized amorphous indium-tin layer (In2O3 + ITO layer);

F – indium-tin oxide layer.

It should be noted that the number and sequence of layers was established by the authors empirically.

Detailed Description of the Invention

The claimed invention is implemented in accordance with the following technology of coating an indium - tin - ITO layer.

Example 1.

Coating a polymeric material (substrate - such as PMMA (polymethyl methacrylate), PC (polycarbonate), PS (polystyrene) or

similar materials) is carried out on a roll vacuum installation. The installation provides rewinding of rolled polymer material at operating pressures of 10 ^-3 - 10 ^-4 mm Hg. Art., which are selected depending on the coating application mode. The mass ratio of indium to tin by alloy corresponds to 2:98 for a metal target. An indium-tin layer is applied from a metal target to a previously prepared side with an applied holographic grating, thus forming a varnish layer with an embossed grating (layer B) and a layer containing valuable information, personal graphic and text data (layer C). Coatings are applied using the magnetron method in an inert gas environment, argon. The working gas ensures the maintenance of low-temperature plasma on the magnetron sputtering source.

During the coating process, the material (substrate) moves at a uniform speed directly above the sputtering target (InSn). The ions produced in the plasma bombard the surface of the target, which is under a negative potential, thereby sputtering it. Particles knocked out of the target condense on a moving substrate, forming a continuous coating. In this case, ideally, the stoichiometry of the initial target material on a moving polymer substrate is preserved. Since the coating is applied on a process shaft cooled to a temperature of -15°C in a vacuum, the temperature on the surface of the substrate does not exceed 25 - 30°C.

The required coating thickness is determined by the linear speed of the substrate, which can reach 10 m/min, as well as the power of the magnetron power source, which lies in the range of 0.5 - 2.5 kW. The upper limit on the applied power to the magnetron source is determined by the efficiency of its cooling, as well as the temperature resistance of the general structure of the substrate.

A polymer substrate coated with a given thickness of 25 - 30 nm is wound into a roll onto a plastic sleeve in the winding unit. Taking into account the high chemical activity of the indium-tin alloy, already at the stage of target sputtering, the initial oxidation of atoms occurs before the process of their condensation on a moving substrate. The final formation of the coating is completed directly on the roll at atmospheric pressure under normal conditions.

The reflective layer obtained in Example 1 has the following characteristics:

- when observed in incident light, the layer appears as a metallized surface, and in transmitted light as a translucent element;

- the layer is tinted and has no gray shades.

- the layer can be transparent or translucent;

- the layer has a reflection coefficient of up to 2.0-2.1;

- the layer contains the compound In ₄ Sn ₃ O ₁₂ .

The reflective layer is part of a diffraction security element for protecting against counterfeiting of valuable documents, which is a film including a reflective layer and an outer oxide film that has a protective function and has a thickness of 28 angstroms, with the total thickness of the film being up to 250 angstroms.

Example 2

To form a diffraction protective element, the deposited layer of indium and tin is subjected to oxidation in air at normal pressure, resulting in the formation of the following layers:

D – translucent indium-tin layer;

E – partially oxidized indium-tin layer (In ₂ O ₃ + ITO layer)

F - indium-tin oxide layer.

The mass ratio of indium to tin by alloy corresponds to 5:95 for a metal target

The topmost pure oxide layer of indium and tin forms an outer oxide film with a protective function, having a thickness of 28 angstroms, while the total film thickness is up to 140 angstroms.

The diffraction security element may further comprise a support substrate which consists of a transparent synthetic film.

The diffraction element obtained in this way conveys the optical impression of a hologram with a colored background and does not have the reflective character characteristic of metal .

Example 3

The methods described in Examples 1 and 2 are used to obtain a multilayer product with an identifying optically variable image, such as a security paper, banknote, document, including a metal-ceramic film - by treating layers B and C with an indium-tin composition and oxidation. The sequence of product layers is shown in Fig. 1. The mass ratio of indium to tin in the alloy corresponds to 10:90 for a metal target.

Layer C, containing valuable information, can be made using known technologies and using digital encryption of information. A multilayer product for protecting against counterfeiting of valuable documents includes a diffraction element and contains:

A – polymer substrate;

B – varnish layer with an embossed diffraction grating;

C – layer containing valuable information, for example, personal graphic and text data;

D – translucent indium-tin layer;

E – partially oxidized indium - tin layer (In ₂ O ₃ + ITO layer);

F – indium-tin oxide layer.

Claims (12)

1. A method for producing a reflective layer to protect against counterfeiting of valuable documents, including vacuum deposition of a mixture of indium and tin onto a polymer substrate followed by oxidation in air, characterized in that vacuum deposition of a mixture of indium and tin is carried out in one stage on the previously prepared side of the polymer substrate in in the form of a rolled polymer material with an applied holographic lattice with the formation of a varnish layer with an embossed lattice and a layer containing valuable information, while vacuum deposition of a mixture of indium and tin with a mass ratio of indium to tin from 10:90 to 2:98 is carried out by the magnetron method in an argon environment at operating pressure 10 ^-3 –10 ^-4 mm Hg. Art. onto a rolled polymer material moving by rewinding on a shaft cooled to a temperature of -15 to +15 °C, at a temperature on the surface of the rolled polymer material of 25–30 °C, the linear speed of movement of the rolled polymer material is 0.5-15 m/min and power of the magnetron power supply in the range of 0.5-5.0 kW. 2. A reflective layer for protection against counterfeiting of valuable documents, obtained by the method according to claim 1, which is an infrared mirror and has an optical property that provides the appearance of a metallized surface in incident light, and the appearance of a translucent element in transmitted light. 3. The reflective layer according to claim 2, characterized in that it is tinted and does not have gray shades. 4. The reflective layer according to claim 2, characterized in that it is made transparent or translucent. 5. Reflective layer according to claim 2, characterized in that it has a reflection coefficient of 2.0-2.1. 6. Reflective layer according to claim 2, characterized in that it contains the compound In ₄ Sn ₃ O ₁₂ . 7. Reflective layer according to claim 2, characterized in that it has a microcrystalline or amorphous structure. 8. A diffraction security element in the form of a film with a reflective layer according to claim 2 for protection against counterfeiting of valuable documents, including the said reflective layer, a translucent indium-tin layer, a partially oxidized indium-tin layer and an external protective oxide film of indium and tin with a thickness of 20- 40 angstroms, while the total film thickness is up to 300 angstroms. 9. The diffraction protective element according to claim 8, characterized in that it additionally contains a supporting substrate made of a transparent synthetic film. 10. The diffractive protective element according to claim 8, characterized in that it conveys the optical impression of a hologram with a colored background and does not have the reflective nature characteristic of metal. 11. A multilayer product with an identifying optically variable image, which is a valuable document containing a protective diffraction element according to claim 8, deposited on a polymer substrate. 12. The multi-layer product according to claim 11, wherein the valuable document is a security document, a banknote or an identity document.