WO2024054132A1

WO2024054132A1 - Secure information carrier with optically variable effect and method for producing same

Info

Publication number: WO2024054132A1
Application number: PCT/RU2023/050202
Authority: WO
Inventors: Андрей Борисович КУРЯТНИКОВ; Георгий Валентинович КОРНИЛОВ; Елена Михайловна ФЁДОРОВА; Егор Сергеевич КАЗАРЦЕВ; Роман Николаевич КОНЯШКИН; Николай Иванович ДРАЧЕНКО; Игорь Васильевич ПАВЛОВ; Александр Игоревич МОЧАЛОВ
Original assignee: Акционерное общество "Гознак" (АО "Гознак")
Priority date: 2022-09-09
Filing date: 2023-08-31
Publication date: 2024-03-14

Abstract

The invention can be used in the production of banknotes, securities, passports and other security print products. A secure information carrier with an optically variable effect includes a paper, polymer or combined base having a region with a dotted raster structure applied thereto. The dots that make up said raster structure are in the form of geometric figures, and the area of the raster structure has a three-dimensional raster applied thereto, formed by embossing and/or by raised printing. When said region is viewed at an acute angle, a first image that is uniformly coloured in stripes is visible on the field of the secure carrier. When the same region of the information carrier is viewed at an acute angle and rotated through 90°, said first image changes to a second image that is uniformly coloured in a colour other than that of the first image, or in alternating stripes of different colour other than that of the first image. The technical result is an increase in the level of security.

Description

SECURED INFORMATION CARRIER WITH OPTICALLY VARIABLE EFFECT AND METHOD OF ITS MANUFACTURE

Technical field

The invention relates to the field of security printing and can be used in the production of banknotes, securities, passports, excise stamps, credit cards, identification documents and other security printing products, which is an urgent task for the security of our country.

One of the most effective and technically feasible solutions for monitoring the authenticity of banknotes, securities, identity cards, passports and other forms of valuable documents is the use of visual security features based on various visual effects. Such visual effects may include, in particular, the effects of movement of a graphic object, the effect of changing the shape and size of a given object, the effect of changing its color, the effect of volume (“3D” effects) or the combination of several visual effects.

The advantages of using these security features are the ease of determining authenticity for the public and cash register workers, short adaptation times for the population and speed of learning, high control performance and the high level of security achieved. Due to these advantages, visual security features are widely used in the field of anti-counterfeit protection, and the constant task of manufacturers of security printing products is to search for new effective and difficult-to-reproduce security features that have pronounced visual effects.

Solutions are known in which the information carrier is equipped with a structure with optically variable properties, for example, RU 2395842 C2, 08/11/2005, with an embossed structure and a coating that are combined relative to each other. In US Pat. No. 5,199,744, 06/04/1993, when viewing the embossed portion of the substrate from a different angle, each image and linear portion can be distinguished by combining multidirectional stripes in the horizontal and vertical planes.

Technical solutions with optically variable structures are known from the prior art, for example, from RU 2440248 C1, 08/03/2010, an information carrier is known, including a coating made in the form of printed and three-dimensional rasters. The optically variable structure is used as a feature that a person can check without the use of auxiliary means if necessary, along with other features to determine the authenticity of the information carrier. Cards that are used for personal identification or for making transactions or providing services can also be used as information carriers. From RU 2235021 C2, 08/27/2004, an information carrier is known in which the relative position of the printed and three-dimensional rasters ensures the formation of moire in the form of color stripes smoothly transitioning into each other.

The level of anti-counterfeiting provided by such embossed optically variable security elements can be further enhanced by creating additional visually distinctive effects by deliberately altering the line pattern or altering the embossed structure. Examples of such additional effects are described in WO 97/17211 and WO 02/20280.

The optically variable effect created by known security elements arises by combining the imprint with a blind embossing, preferably carried out by an intaglio printing plate. The disadvantage of blind embossing is that it cannot be integrated into a color printed image obtained by intaglio printing, but can only be used as a separate security feature. This is due to the fact that when applying paint to a printing plate for intaglio printing, it is possible to virtually eliminate the ink from getting into the recesses in the printing plate intended for blind embossing only if there is a sufficiently large distance between its areas intended for blind embossing and the areas rolled up with printing ink.

The disadvantage of all known solutions for obtaining an information carrier with a protective effect is the impossibility of forming hidden information images that have a stable color-variable image effect, suitable for simple visual inspection and, at the same time, have increased resistance to external conditions and durability of use of such an information carrier.

There are known solutions used to create a secure storage medium that have a new optical visual effect and an increased degree of protection of banknotes, securities, identity cards, passports and other forms of valuable documents on a multilayer media from unauthorized modification using visual features based on a combination of printed and three-dimensional rasterized elements to obtain a stable optically variable image effect. Such a solution is known from RU 2661222 C1, 08/25/2017, in which the carrier is made on paper, polymer or a combination base and contains an area with a dotted raster regular and/or irregular structure. A three-dimensional raster is applied on top of the raster structure, made in the form of an embossed linear spatial structure such as a lattice and/or a concentric and/or cellular spatial structure. The points of the printed raster are placed on the side edges, bottoms or white-space elements of the three-dimensional structure, regardless of the positioning of the printed and three-dimensional rasters, to obtain an image on the carrier that has the form of intersecting linear structures. When observed at an angle of 90 degrees from the plane of the carrier, the protective element is visible in the form of a uniform field of the integral color of the substrate paints, and when the carrier is observed at an acute angle, a change in the color of the element to an integral, mixed color of two substrate paints is observed, while when the carrier is rotated, a moire pattern appears, and depending on the angle of rotation, a color change and/or character of the moire pattern is observed, and the pattern appears in the form of continuous moire stripes, intermittent stripes and/or may have a lattice structure in the form of intersecting moire stripes. A similar solution is known from RU 2659989 C1, 08/25/2017.

In addition to the above-mentioned disadvantages of known solutions, it is necessary to take into account that the most important disadvantage for all currently known solutions is that very quickly each patented technology becomes available for copying by unscrupulous persons for the purpose of falsifying documents.

This circumstance requires the rapid development of new technologies, which must be regularly updated, improved and changed to overcome the possibility of counterfeiting.

Disclosure of the invention

Thus, the technical result of the invention is the elimination of these disadvantages and the actual development of another technology that is inaccessible for forging documents and securities.

The problem to be solved by the proposed invention is to create a secure storage medium that would have a new optical visual effect and an increased degree of protection of banknotes, securities, identity cards, passports and other forms of valuable documents on a multilayer media from unauthorized modification using visual features based on a combination of printed and three-dimensional rasterized elements to obtain a stable optically variable image effect.

As stated above, the main technical result is the creation of another new security printing technology, expanding the arsenal of technical means for creating visual security features based on various visual effects.

To achieve a technical result, a protected information carrier with an optically variable effect includes a paper, polymer or combined base containing an area with an applied dot raster regular and/or irregular structure, and the points that make up the raster structure are made in the form of geometric figures containing straight lines, broken, curvilinear lines, several colors, and in the area of the raster structure a three-dimensional raster is applied, made by metallographic inkless embossing and/or relief embossing and/or blind embossing and/or relief printing, and when observing the area at an angle of 90° from the plane of the information carrier a uniformly colored field is visible with the color formed as a result of the synthesis of paints of a point structure, and when observing the zone at an acute angle on a uniform field of the protective medium, the first image is visible, uniformly colored with color or stripes alternating with different colors, in addition, when observing the zone of the information carrier at an acute angle and rotated 90°, the first image changes to a second image uniformly colored with a color different from the color of the first image, or alternating stripes of different colors from the color of the stripes of the first image, or alternating stripes of different colors from the color of the stripes of the first image, and changing orientation of alternating stripes on the plane of the information carrier, while the three-dimensional raster is formed by the superposition of two gratings made with parallel multidirectional elements so that the gratings partially overlap each other in an area of 5 - 95% of the three-dimensional raster in such a way that the overlap of the gratings forms a section or sections with mutually perpendicular the arrangement of the elements of each of the specified two lattices or with the mutual arrangement of the elements of each of the specified two lattices at an angle from 0.02° to 89.8°, and the other part of the three-dimensional raster is formed by non-overlapping parts of the lattices with their unidirectional elements with an area of 5 - 95% of the area of the three-dimensional raster, and unidirectional elements are located without forming an angle to the horizontal or vertical plane, respectively, or are located at an angle from 0.02° to 89.8° to the horizontal or vertical plane, respectively.

A method for producing a secure information carrier with an optically variable effect involves applying a zone with an applied dot raster regular and/or irregular structure to a paper, polymer or combined base, wherein the points that make up the raster structure are made in the form of geometric shapes containing straight lines, broken lines, curved lines, several colors, and in the area of the raster structure a three-dimensional raster is applied using the method of metallographic inkless stamping and/or relief embossing and/or blind embossing and/or relief printing at a pressure in the range of 5 - 200 MPa and as materials for creating a three-dimensional raster brass, copper, nickel, photopolymer based on elastomers are used, and when observing a zone at an angle of 90° from the plane of the information carrier, a uniformly colored field with a color formed as a result of the synthesis of paints of a point structure is visible, and when observing a zone at an acute angle on a uniform field of the protective carrier a first image is visible, uniformly colored with a color or stripes alternating with different colors, in addition, when observing the area of the information carrier at an acute angle and rotated by 90°, the first image changes to a second image, uniformly colored with a color different from the color of the first image, or alternating with different colors stripes different from the color of the stripes of the first image, or alternating stripes of different colors, different from the color of the stripes of the first image, and changing the orientation of the alternating stripes on the plane of the information carrier, wherein a three-dimensional raster is created by superimposing two gratings made with parallel multidirectional elements so that the gratings are partially overlap each other over an area of 5 - 95% of the three-dimensional raster in such a way that the overlap of the gratings forms a section or sections with a mutually perpendicular arrangement of the elements of each of the two specified gratings or with a mutual arrangement of the elements of each of the two specified gratings at an angle from 0.02° to 89 ,8°, and the other part of the three-dimensional raster is formed by non-overlapping parts of the gratings with their unidirectional elements with an area of 5 - 95% of the area of the three-dimensional raster, and the unidirectional elements are located without forming an angle to the horizontal or vertical plane, respectively, or are located at an angle of 0.02° up to 89.8° to the horizontal or vertical plane, respectively.

An embossing tool, such as an embossing stamp or a printing plate, with an engraved surface allowing the production of a protective medium is characterized by the arrangement of the side walls of the first and second multi-directional grids having a profile of any shape, or having a trapezoidal profile with an angle of the side edge to the long base in range from 45° to 75°.

A tool for manual engraving for the manufacture of an embossing tool is made in the form of a graver, or a tool for automated engraving for the manufacture of an embossing tool is made in the form of a cutter or laser.

The authors have experimentally found that an embossing tool, such as an embossing die or a printing plate with an engraved surface, should have a trapezoidal profile with an angle of the side edge to the long base ranging from 45° to 75°. Since it is precisely this shape profile with a side edge angle in the range from 45° to 75° that provides a three-dimensional raster height sufficient for the clarity of the first image when observing the information carrier area at an acute angle and for the clarity of the second image when observing the information storage area at an acute angle and rotation at 90°.

In the manufacturing process, the following can be used: a manual engraving tool for the production of an engraving tool in the form of a gravel, for example, "Vallorbe", an automated engraving tool for the production of an engraving tool in the form of a carbide rod cutter, for example, TCLR-035-330, laser, for example manufactured by Coherent.

Particularly noteworthy is the fact that the change from the first image to the second occurs precisely in the area of overlap of the gratings.

The invention is illustrated by drawings, where:

- gratings 1 and 2 are shown - with formed areas of non-overlapping of gratings 3 and one overlap area 4;

- shows a variant of a point structure consisting of fragments, the boundaries of which are indicated by solid lines 5;

- shows a fragment of a dot structure consisting of a square 3a, for example, blue, a square 3b, for example, magenta and a square 3c, for example, yellow;

- , 5, 6, 7 options for applying a three-dimensional raster, made by inkless metallographic embossing and/or hot stamping and/or blind embossing and/or relief printing, onto a dot structure ;

- , 9, 10, 11 - options for visual observation of the carrier from different angles;

- , 13, 14, 15 - options for the location of multidirectional sections of the gratings.

- – the execution of geometric figures containing curved lines is presented.

- – the execution of geometric figures containing broken lines is presented.

Carrying out the invention

Execution examples.

Example 1.

The production of a secure information carrier with an optically variable effect was carried out using the following technology - applied to a paper base (in other tests a polymer base was used, then a combined base).

A zone was created on which a regular dotted raster structure was applied (we also tried an irregular or combined structure). The dots and raster structures were made with multi-colored geometric shapes - yellow, purple, blue, green, cyan.

Then a three-dimensional raster was applied to the area of the raster structure; all methods turned out to be suitable during testing: metallographic inkless embossing, embossing, blind embossing, relief printing.

The three-dimensional raster is applied at a pressure in the range of 5 – 200 MPa, the material for creating the three-dimensional raster is brass, copper, nickel, photopolymer based on elastomers.

A three-dimensional raster was created by superimposing two gratings made with parallel, multidirectional elements.

Make sure that the gratings partially overlap each other. In various examples, such overlap was used over an area from a minimum of 5 to a maximum (in other examples) of 95% of the three-dimensional raster.

The overlap was ensured in such a way that the overlap of the lattices formed one (in other examples, 2, 5, 8 sections were created) section with a mutually perpendicular arrangement of the elements of each of these two lattices or with the arrangement of the elements of each of these two lattices at an angle in the range from 0. 02° to 89.8°.

During the manufacturing process, the other part of the three-dimensional raster was formed by non-overlapping parts of the gratings with their unidirectional elements with an area of 5 (other values were studied when developing examples - 12, 20, 35, 50, 65, 78, 95 - all showed the achieved effect) % of the area of the three-dimensional raster , and the unidirectional elements were located at an angle of 0.02° to the horizontal or vertical plane.

On shows the implementation of a variant of a point structure consisting of fragments, the boundaries of which are indicated by solid lines 5.

On shows the manufacture of a fragment of a dot structure, consisting of square 3a, blue, square 3b, purple and square 3c, yellow.

In the horizontal and vertical directions, squares 3a, 3b, 3c are located with indentation from each other (in another example, a variant of arrangement of squares 3a, 3b, 3c was made without indentation from each other).

Area 3d was left unsealed. In other examples, a variant was created with sealing area 3d with a square, other colors with or without indentation from squares 3a, 3b, 3c.

Dot structure on covers the storage medium. In the area of the dot structure, a three-dimensional raster is applied ( ). For many additional examples of applying a three-dimensional raster during the testing process, it was created using various acceptable combinations of inkless metallographic embossing and/or relief embossing and/or blind embossing and/or relief printing.

All examples gave a structure with the following results: when observing the resulting structure at an angle of 90° from the plane of the information carrier, the protective element has the appearance of a uniformly colored field of color, resulting from the synthesis of dot structure paints ( ).

In all cases, when viewing a data carrier at an acute angle, an image of the number 1 appears on a uniform field of the protective element ( ).

In all cases, when viewing the storage medium at an acute angle and rotated by 90°, the number 1 is replaced by the letter A ( ).

Example 2.

The technology being implemented was the same as in example 1. In the area of the point structure ( ) applied a three-dimensional raster ( ) by methods (similar to a series of test examples described as example 1) metallographic inkless stamping and/or relief stamping and/or blind stamping and/or relief printing.

During the manufacturing process, the other part of the three-dimensional raster was formed by non-overlapping parts of gratings with their unidirectional elements with an area of 5 (other values were studied when developing examples - 12, 20, 35, 50, 65, 78, 95 - all showed the achieved effect) % area of the three-dimensional raster , and the unidirectional elements were located at an angle of 89.8° to the horizontal plane.

As a result, when observed at an angle of 90° from the plane of the information carrier, the protective element has the appearance of a uniformly colored field of color, resulting from the synthesis of dot structure paints ( ).

When observing a data carrier at an acute angle, an image of a circle appears on a uniform field of the protective element ( ).

When viewing the storage medium at an acute angle and rotated by 90°, the circle is replaced by a triangle ( ).

Example 3.

The technology used was the same as in example 1.

When observing a data carrier at an acute angle, an image of the number 1 appears on a uniform field of the protective element ( ).

When viewing the storage medium at an acute angle and rotated by 90°, the number 1 is replaced by a triangle ( ).

Example 4.

The technology used was a series of examples 1.

In the area of the point structure ( ) applied a three-dimensional raster (shown in ) by metallographic inkless stamping and/or relief stamping and/or blind stamping and/or relief printing.

When observing a data carrier at an acute angle, an image of the letter A appears on a uniform field of the protective element ( ).

When viewing the storage medium at an acute angle and rotated by 90°, the letter A is replaced by a triangle ( ).

A number of experiments were carried out with different angles from the stated range.

Example 5.

During the manufacturing process, the other part of the three-dimensional raster was formed by non-overlapping parts of gratings with their unidirectional elements with an area of 5 (other values were studied when developing examples - 12, 20, 35, 50, 65, 78, 95 - all showed the achieved effect) % area of the three-dimensional raster , and the unidirectional elements were located at an angle of 45° to the horizontal plane.

Example 6.

During the manufacturing process, the other part of the three-dimensional raster was formed by non-overlapping parts of the gratings with their unidirectional elements with an area of 5 (other values were studied when developing examples - 12, 20, 35, 50, 65, 78, 95 - all showed the achieved effect) % of the area of the three-dimensional raster , and the unidirectional elements were located at an angle of 89.8° to the vertical plane.

Example 7.

During the manufacturing process, the other part of the three-dimensional raster was formed by non-overlapping parts of gratings with their unidirectional elements with an area of 5 (other values were studied when developing examples - 12, 20, 35, 50, 65, 78, 95 - all showed the achieved effect) % area of the three-dimensional raster , and the unidirectional elements were located at an angle of 65° to the horizontal plane.

Example 8.

During the manufacturing process, the other part of the three-dimensional raster was formed by non-overlapping parts of gratings with their unidirectional elements with an area of 5 (other values were studied when developing examples - 12, 20, 35, 50, 65, 78, 95 - all showed the achieved effect) % area of the three-dimensional raster , and the unidirectional elements were located at an angle of 1° to the horizontal plane.

Example 9.

During the manufacturing process, the other part of the three-dimensional raster was formed by non-overlapping parts of gratings with their unidirectional elements with an area of 5 (other values were studied when developing examples - 12, 20, 35, 50, 65, 78, 95 - all showed the achieved effect) % area of the three-dimensional raster , and the unidirectional elements were located at an angle of 12° to the horizontal plane.

Please note that the effect is achieved over the entire range of angles from 0.02° to 89.8° when using this method.

In addition, it should be noted that the printing and embossing process does not require precise alignment of the substrate and grid elements.

All of the above confirms the compliance of the proposed technical solution with the conditions for patentability of the invention: “novelty”, “inventive step” and “industrial applicability”.

Thus, as shown by a series of examples, a secure information carrier has been manufactured that has a public security feature of a high level of security, which has the property of unambiguously changing the information content when viewing conditions change, and does not require highly qualified users, special devices and control methods.

The resulting visual effects are not limited to the examples presented. When designing a security element, any letters, numbers, geometric shapes, images, etc. are used.

Claims

A secure information carrier with an optically variable effect, including a paper, polymer or combined base containing an area with an applied dot raster regular and/or irregular structure, and the points that make up the raster structure are made in the form of geometric shapes containing straight, broken, curved lines lines, several colors, and in the area of the raster structure a three-dimensional raster is applied, made by metallographic inkless embossing and/or relief embossing and/or blind embossing and/or relief printing, and when observing the area at an angle of 90° from the plane of the information carrier, a uniformly colored field with a color formed as a result of the synthesis of paints of a point structure, and when observing the zone at an acute angle on a uniform field of the protective medium, the first image is visible, uniformly colored with color or stripes alternating with different colors, in addition, when observing the zone of the information carrier at an acute angle and turning it 90° the first image is changed to a second image uniformly colored with a color different from the color of the first image, or alternating stripes of different colors from the color of the stripes of the first image, or alternating stripes of different colors from the color of the stripes of the first image, and changing the orientation of the alternating stripes on the plane of the information carrier, while the three-dimensional raster is formed by the superposition of two gratings made with parallel multidirectional elements so that the gratings partially overlap each other in an area of 5 - 95% of the three-dimensional raster in such a way that the overlap of the gratings forms an area or areas with mutually perpendicular arrangement of the elements of each from the said two lattices or with the relative arrangement of the elements of each of the said two lattices at an angle from 0.02° to 89.8°, and the other part of the three-dimensional raster is formed by non-overlapping parts of the lattices with their unidirectional elements with an area of 5 - 95% of the area of the three-dimensional raster, and unidirectional elements are located without forming an angle to the horizontal or vertical plane, respectively, or are located at an angle from 0.02° to 89.8° to the horizontal or vertical plane, respectively.
A method for producing a secure information carrier with an optically variable effect, including applying a zone with a dot raster regular and/or irregular structure to a paper, polymer or combined base, wherein the points that make up the raster structure are made in the form of geometric shapes containing straight lines, broken lines, curved lines, several colors, and in the area of the raster structure a three-dimensional raster is applied using the method of metallographic inkless stamping and/or relief embossing and/or blind embossing and/or relief printing at a pressure in the range of 5 - 200 MPa and as materials for creating a three-dimensional raster brass, copper, nickel, photopolymer based on elastomers are used, and when observing a zone at an angle of 90° from the plane of the information carrier, a uniformly colored field with a color formed as a result of the synthesis of paints of a point structure is visible, and when observing a zone at an acute angle on a uniform field of the protective carrier a first image is visible, uniformly colored with a color or stripes alternating with different colors, in addition, when observing the area of the information carrier at an acute angle and rotated by 90°, the first image changes to a second image, uniformly colored with a color different from the color of the first image, or alternating with different colors stripes different from the color of the stripes of the first image, or alternating stripes of different colors, different from the color of the stripes of the first image, and changing the orientation of the alternating stripes on the plane of the information carrier, wherein a three-dimensional raster is created by superimposing two gratings made with parallel multidirectional elements so that the gratings are partially overlap each other over an area of 5 - 95% of the three-dimensional raster in such a way that the overlap of the gratings forms a section or sections with a mutually perpendicular arrangement of the elements of each of the two specified gratings or with a mutual arrangement of the elements of each of the two specified gratings at an angle from 0.02° to 89 ,8°, and the other part of the three-dimensional raster is formed by non-overlapping parts of the gratings with their unidirectional elements with an area of 5 - 95% of the area of the three-dimensional raster, and the unidirectional elements are located without forming an angle to the horizontal or vertical plane, respectively, or are located at an angle of 0.02° up to 89.8° to the horizontal or vertical plane, respectively.
An embossing tool, such as an embossing stamp or a printing plate, with an engraved surface, allowing to obtain a protective medium according to claim 1, characterized by the arrangement of side walls of the first and second multi-directional grids having a profile of any shape.
The embossing tool according to claim 3, characterized by the arrangement of the side walls of the first and second multidirectional gratings having a trapezoidal profile with an angle of the side edge in the range from 45° to 75°.
A tool for manual engraving for the manufacture of an embossing tool according to claim 3, characterized by execution in the form of a graver.
A tool for automated engraving for the manufacture of an embossing tool according to claim 3, characterized by being made in the form of a cutter or laser.