WO2009154506A1

WO2009154506A1 - Protective optical reflective element and a method for the production thereof

Info

Publication number: WO2009154506A1
Application number: PCT/RU2009/000125
Authority: WO
Inventors: Андрей Львович КАРАСЕВ; Андрей Валентинович СМИРНОВ; Леонид Игоревич СМИРНОВ; Михаил Владимирович ЮРЕНКОВ
Original assignee: Открытое Акционерное Общество "Научно-Производственное Объединение "Криптен"
Priority date: 2008-06-20
Filing date: 2009-03-13
Publication date: 2009-12-23
Also published as: EA200801396A2; EA200801396A3; EA011567B1

Abstract

The invention relates to a protective optical reflective latent-image carrying element and to a method for the production of said element. The inventive method for producing a protective optical reflective element consists in applying a reflective layer (2) to at least one area of an anisotropic translucent substrate (1) on one of the sides thereof; forming a reflective latent image (4) by hidden printing on at least one area of the substrate (1) on the other side thereof in such a way that the above-mentioned at least one area with the latent image (4) is in the form of sealed sub-areas (4a) situated within the image outline and background sub-areas (4b) situated beyond the image outline on the latent-image carrying element, wherein the above-mentioned at least one area with the latent image corresponds to the substrate area with the reflective layer applied to the relevant substrate side; uniformly applying a thin translucent protective layer (3) through the entire surface of the area with the latent image, wherein the reflective power of the protective layer substantially differs from the reflective power of the area with the latent image, and the reflective power and colour of the reflective layer of the sealed sub-areas substantially coincide with the reflective power and the colour of the background sub-areas and the area with the latent image, thereby rendering the image invisible to the unaided eye and providing a sharp contrast image in polarized light.

Description

OPTICAL REFLECTIVE PROTECTIVE ELEMENT AND METHOD

HIS PRODUCTION

Technical field

The invention relates to the field of protection against falsification and authentication of valuable documents, in particular to the manufacture and production of optical security elements carrying a latent image that is practically invisible in natural light to the naked eye and visualized when observed through a polarizing filter.

BACKGROUND OF THE INVENTION An object of the present invention is to provide a protective optical element with a high degree of protection against reuse by directly imprinting a metallic latent image into a protected object. Moreover, thanks to such a protective element, it has a high mechanical, chemical, radiation resistance and stability in a wide temperature range, invisible in natural light to the naked eye and visualized with high contrast when using a polarizing filter.

At present, various means of printing protection (watermarks, microtext, special inks, latent images based on colorless embossing and kipp effect, etc.), magnetic, holographic, optical and other methods. Among the protective elements with variable optical properties, the most difficult to reproduce are elements containing latent images visible only in polarized light. As a rule, latent polarized images are obtained on the surface or in the volume of a continuous polymer layer - the carrier of the latent image by changing the optical anisotropy in the local regions of the aforementioned polymer layer, namely, changing the magnitude of the birefringence. A local change in the magnitude of birefringence can be achieved either by changing the magnitude and / or direction of the optical anisotropy of the transparent material in certain sections, or by changing the thickness of the transparent anisotropic material in certain areas of the layer.

These effects are achieved by mechanical (US 5,284,364 publ. 08.02.1994, IPC B42D 15/00), chemical (US 5284364), photophysical (US 6,100,967 publ. 2000.08.08, IPC B42D 15/00), photochemical (US 6,124,970 publ. 09/26/2000, MPKG02B 27/28), thermomechanical (WO 2006 / 005149A2, publ. 19.01.2006, MPKG03F 7/00) impacts. In all the cases presented, a latent polarized image is formed in a polymer layer prepared in a special way (US 6,124,970; WO 2006/005149 A2), or on the surface of a solid substrate (US 5,284,364; US 6,100,967). The methods for manufacturing a latent image and a protective element based on it, described in these patents, assume the presence of a continuous, usually polymeric, layer that carries a latent polarized image, on which the adhesive is applied on the reverse side, then cutting is performed and the final product is obtained - self-adhesive labels and tags. Labels and tags obtained in this way are attached to the protected item either manually or using an automatic applicator; in both cases, a sufficiently high rigidity of the layer carrying the latent image is required, which determines the possibility of reuse of the element. In addition, the latent image manufacturing methods used in US 5,284,364 lead to contours that are visible to the naked eye — traces of mechanical formation or chemical etching.

Closest to the claimed method is a method of manufacturing a latent image using local mechanical or chemical removal of solid anisotropic polymer material from the surface of a rigid substrate (US 5,284,364). This method leads to the formation of a contrasting polarized image, but with the image contour clearly visible to the naked eye and does not guarantee protection against reuse.

The objective of the present invention is to provide a method of forming and manufacturing a latent polarized image, invisible in natural light to the naked eye and eliminating the presence of image contours and visualized with high contrast when using polarizing filter; an image formed in such a way as to completely exclude the possibility of reuse of the protective element; images with high mechanical, chemical, radiation resistance and stability over a wide temperature range.

SUMMARY OF THE INVENTION

According to a first aspect of the invention, there is provided a method for manufacturing an optical reflective protective element according to which: a) a transparent substrate is provided so as to provide optical anisotropy substantially uniformly throughout the entire volume of the substrate; b) applying a reflective layer to at least one portion of the substrate on one side of the specified substrate; c) a reflective latent image is formed by direct printing on at least one portion of the substrate on its other side so that the specified at least one portion with the latent image is a sealed sub-area located within the image contour and white space sub-areas outside the contour of the image in the area with a hidden image, while the specified at least one area with a hidden image corresponds to a portion of the substrate with a reflective layer on the respective sides e substrate; d) uniformly apply a thin transparent protective layer over the entire surface of the area with the latent image, while the reflectance of the protective layer differs from the reflectivity of the area with the latent image, that is, the reflectance of the protective layer is 5-10% more, the reflectance plot with a hidden image or the reflectance of the protective layer is less by 10-25% of the reflectivity of the plot with a hidden image.

In addition, the reflectance value and the color of the sealed sub-areas essentially coincide with the reflectance and the color of the white sub-areas, the area with the latent image, which determines the invisibility of the image when observed with the naked eye, while hiding visible traces of formation latent image, and clear contrast image when viewed in polarized light.

Moreover, according to the claimed method, the substrate can be made of transparent depolarizing material. In addition, a phase plate may be used as the substrate, and the reflective layer may be made of metal, or a reflective hologram may be used as the reflective layer.

Moreover, in the inventive method, the formation of a latent image is carried out using metal, and the latent image can be a reflective hologram.

In addition, the formation of a latent image using the direct printing method is a thermal transfer printing, hot stamping or vacuum spraying.

Moreover, according to the claimed method, a varnish layer or a transparent hologram is used as a protective layer.

In addition, according to the invention provides for the application on the surface of the protective layer of a multicolor visible image.

According to the invention, the protective element is formed in such a way that withstands a temperature of 180 degrees C and represents at least part of one of: a self-adhesive label, document, plastic card, packaging.

In this case, the visualization of the latent polarized image is carried out using a circular polarizer or a linear polarizer, and when visualizing the latent image in circularly polarized light, the sealed sub-sections look dark blue, and the blank sub-sections look like a light background, and when rendering the latent image in linearly polarized light, the sealed sub-sections look light, and whitespace subsections, like a dark background.

According to a second aspect of the invention, an optical polarizing protective element comprising a substrate with a reflective layer deposited on at least one portion on one side and a latent image formed on it on the other side on at least one portion substrates by direct printing, and made according to the steps of the method in accordance with the first aspect of the invention.

The result is a virtually invisible image when observed with the naked eye and a clear contrast image when viewed in polarized light. In this case, the condition that must be fulfilled in the manufacturing process of the protective invention according to the invention is that the reflectance of the protective layer should differ significantly i.e. be significantly larger (by 5–10%) or vice versa significantly lower (by 10–25%) of the reflectance of a portion with a latent image, for example, for a latent image having a reflectivity of 60%, protective layers with a reflectivity of 40% or 70% the indicated ranges of permissible differences between the reflectivity of the protective layer from the area with the latent image are quite acceptable obtained experimentally by the inventors. In this case, the reflectance value and the color of the sealed sub-areas must essentially coincide with the reflectance and the color of the white sub-areas, the area with the latent image, which determines the invisibility of the image when observed with the naked eye, eliminates the image contours that are traces of the formation of the latent image when printing directly prior art solutions and a clear contrast image when viewed in polarized light.

As the optically anisotropic substrate, polymer films obtained by the extrusion method and having high transparency are selected. The total optical loss due to the passage of light through the substrate should not exceed 10%. Materials such as thin layers of polypropylene, polyethylene terephthalate, polyvinylidene fluoride, polytrifluorochlorethylene and some other polymers meet these conditions. To reduce optical loss, the substrate thickness is selected to be the minimum possible for each specific protected object, usually 12-36 microns. The nature of the optical anisotropy is determined by the spatial microstructure of the polymer material, for example, biaxially oriented polyethylene terephthalate depolarizes circular light, and uniaxially oriented polypropylene is a phase plate. So the use of a phase plate as a substrate, for example a quarter-wave one, leads to the appearance of a bright colored background when visualizing a latent image in both linear and circularly polarized light, the type of image being visualized depends on the angle of rotation of the polarizer.

In this case, metal is used as the reflective layer of the substrate, and a reflective hologram or a hot stamping holographic foil can be used as the reflective layer of the substrate. In addition, according to the method, a portion of the substrate with the latent image formed is covered with a thin protective layer of transparent plastic, or coated with a protective thin transparent polymer layer containing a holographic image. In addition, this protective layer reduces the differences in reflectance of the reflective layers and hides visible traces of the formation of a latent image. To perform these functions, layers were used whose surface has a reflectivity significantly different from the reflectance of a latent image. The reflectivity of the surface of the protective layer is much higher, as well as significantly lower than the reflectivity of the latent image, narrows the value of the solid angle of visibility in the volume of the layered structure of the element and thereby hides the print contours of the latent image and the difference in reflectivity of the reflective layer and the hidden images when viewing the protective element with the naked eye at an angle different from normal within ± 45 °, with large deviations of the viewing angle From the normal, the internal structure of the layered element and, therefore, traces of the formation of a latent image are invisible. Reducing the reflectivity of a transparent protective layer is achieved by applying a transparent visible multicolor image or a relief colorless ornament onto its surface. The application of a polymer film containing a transparent holographic image as a protective layer leads to an increase in the reflectivity of the protective layer and, among other things, increases visual appeal and protective properties of the element.

In addition, the protective element is formed in such a way that withstands the temperature 18O ⁰ C.

Moreover, in the method according to the first aspect of the invention, the protective element is formed in such a way that it represents at least part of one of: a document, a plastic card, packaging.

In addition, in the indicated method, the latent reflective image is made using a thermal transfer metal foil, either a hot stamping metal foil, or a sprayed metal. In this case, methods of thermal transfer printing, hot stamping, and also vacuum deposition of various metals are used.

According to a second aspect of the invention, there is provided an optical reflective security element comprising a transparent optically anisotropic substrate, imprinted therein with a latent image by direct printing using metal or reflective pigment onto at least one portion of the substrate on one side thereof corresponding to the portion with the reflective layer on the other side the substrate, while the color and reflectivity of the sealed sub-areas and blank sub-areas of the latent image essentially coincides with each other friend, which ensures the invisibility of the latent image with the naked eye, and made according to the method disclosed above.

Description of the figures of the drawings

The features, elements and advantages of the invention result from the following description of embodiments of the invention with reference to the accompanying drawings, in which: FIG. 1 is a top view in circularly polarized light of a protective reflective element, FIG. 2 is a cross-sectional view of an AA of a protective the reflecting element and the course of light rays when viewing it through a circular polarizer, namely the course of light rays when reflected from the whitespace sub-sections 4b of section 4 with a hidden image corresponds to position t B and the path of the rays of light reflected from the sealed subsections 4a plot 4 with a hidden image corresponds to position C.

DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION A description of an optical reflective protective element and a method for its manufacture will be described with reference to FIG. 1, 2. According to a method for manufacturing an optical reflective protective element on a substrate 1, in the form of a polymer film obtained, for example, by extrusion, and having an optical anisotropy, namely on at least one portion of the substrate 1, a reflective layer 2 is applied on one side thereof. The reflective layer 2 may be either metallic th foil or vacuum deposited metal or a reflective hologram or a holographic hot stamping foil, or the surface of a document or a plastic card with a pre-applied reflective portion, or paper or cardboard, colored paint with reflective properties. On the other side of the substrate, at least on one of its sections, a latent image 4 is formed (hereinafter, a portion with a latent image 4), for example, a latent image (letters, numbers, logos, ornaments, etc.) is imprinted, which are separate characters, direct printing method. In this case, the portion with the latent image 4 on the other side of the substrate corresponds to the portion with the reflective layer 2 on the first side of the substrate. In this case, the areas with the latent image 4 can be divided into sealed sub-areas 4a, i.e. areas along the contour of the latent image or the image itself and whitespace sub-sections 4b, i.e. the remaining areas within the specified area with the latent image 4. In this case, the latent image, for example, can be imprinted on at least one portion of the substrate 1 on one side thereof, coinciding with the portion covered by the reflective layer 2 on the other side of the substrate 1, by direct printing using metal or reflective pigments, while the whitespace sub-sections 4b remain bright. It should be noted that the reflectance value and the color of the whitespace sections 4b essentially coincide with the reflectance value and the color of the sealed sub-section 4a of the section with the latent image 4, which leads to ensuring the invisibility of the image when observed with the naked eye and a clear contrast image when viewed in polarized light.

As materials for forming a latent image, a foil for thermal transfer printing with a metal pigment, a foil for hot stamping with a metal or a hologram, standard reflective holograms, vacuum sprayed metal are used.

It should be noted that the direct printing method makes it completely impossible to reuse the security element. All methods of manufacturing a latent image and a security element based on it, known from the prior art, for example, US 6 124 970 and WO / 2006/005149, presuppose the presence of a continuous, usually polymeric, layer that carries a latent polarized image, on the back of which adhesive is applied, then cutting is carried out and the final product is obtained - self-adhesive labels and tags. Labels and tags obtained in this way are attached to the protected item either manually or using an automatic applicator; in both cases, a sufficiently high rigidity of the layer carrying the latent image is required, which determines the possibility of reuse of the element. In the method proposed by the authors, a continuous layer carrying a latent image is absent, there is no adhesive layer - the latent image is imprinted directly on the surface of the protected object - a document blank, plastic card, packaging material. In this case, the reuse of the protective element is not possible. Imprinting a latent image can be done using thermal transfer printing with metal, hot stamping, vacuum spraying, as well as printing methods.

Apply a protective layer 3 over the entire surface of the plot with a hidden image of a protective reflective polarizing element. The protective layer 3 is a thin transparent polymer layer that protects the area with the latent image 4 (hereinafter, when using the term “hidden image” is meant the area 4 with the hidden image) from scratches and abrasion. In addition, the optical properties of this layer are selected so as to completely hide the print contours, which is ensured by the choice of the material from which the protective layer 3 is made. As the protective layer 3, a varnish layer is used, which is resistant to abrasion and scratches and has a surface reflectance significantly different from the reflectivity of the reflective layer and the latent image . In this case, the main condition that must be fulfilled in the manufacturing process of the protective element according to the invention is that the reflectivity of the protective layer should be significantly different i.e. be greater (by 5-10%) or vice versa less (by 10-25%) of the reflectance of the area with the latent image, and the reflectivity and color of the sealed sub-areas should essentially coincide with the reflectance and the color of the white space sub-areas of the hidden image, which determines the invisibility of the image when observed with the naked eye, eliminates the image contours that are traces of the formation of a latent image in direct printing characteristic solutions m of the prior art, and a clear contrast image when viewed in polarized light.

The use as a protective layer 3 of a transparent hologram without its own reflector, in addition to the direct function of mechanical protection, increases the reflectivity of the protective layer and increases the level of protection against counterfeiting and the external attractiveness of the product. The hologram used is transparent to visible light and does not block polarized light.

The resulting latent image is invisible when viewed with the naked eye, because the color and reflectivity of the sealed portion of the portion with the latent image 4 essentially coincides with the color and reflectivity of the whitespace portion of the portion with the latent image 4.

The latent image is visualized using a circular polarizing filter 5. In circularly polarized light, a high-contrast dark blue image (sealed sub-sections) against a light background (white sub-sections) is visualized. The following are examples of the implementation of an optical reflective polarizing protective element.

Example 1

As the substrate 1, a transparent film of biaxially oriented polyethylene terephthalate was selected, which depolarizes circularly polarized light. On one side of the film (substrate 1), at least on one area, a reflective layer 2 made of aluminum with a thickness of 600 nm is applied by vacuum deposition. On the other side of the substrate in at least one of the sections, imprint the latent image 4 (Fig. 1, 2), using aluminum by direct printing, while the portion with the latent image 4 coincides with the portion with the reflective layer 2 on the other side of the substrate 1 The surface of the latent image thus formed on one side of the substrate 1 within the specified area, having a reflective layer 2 on the other side of the substrate 1, is covered with a protective layer 3 (Fig. 1, 2) - heat-resistant varnish.

The manufacturing process of the optical reflective optical security element (Fig. 1, 2) is completed. The design of the whitespace sub-sections 4b of section 4 with the latent image is as follows: Reflective layer 2 / Substrate / The whitespace subsection 4b / 3 of the protective layer 3 (Figure 2-B), and the design of the sealed sections 4a of section 4 with the hidden image is as follows: Reflective layer 2 / Substrate 1 / Sealed sub-section 4a / 3 backing layer 3 (Figure 2-C). The resulting product (protective element) can withstand temperatures of 18 ⁰ C, since all components of the obtained element withstand temperatures of 180 ⁰ C and above. A polyethylene terephthalate film (substrate 1), duplicated by an aluminum layer (reflection layer 2), is a standard packaging material, the protective sign in this case is an integral part of this material, cannot exist separately from the packaging material and, therefore, cannot be reused. The course of light rays when reflected from the whitespace sub-sections 4b of section 4 with a hidden image can be illustrated as follows: the light passes through the polarizer 5 (Figure 2 - B) - is converted into circular polarized, passes through an optically anisotropic substrate 1 (FIG. 2 - B) —depolarizes, reflects from the region with the reflective layer 2 (FIG. 2 - B), passes through the substrate 1 and polarizer 5 again. The incident light intensity in this process decreases by the magnitude of the reflection loss and the doubled absorption loss in the polarizer 5 and the substrate 1. The blank sub-areas 4b of the latent image appear bright when viewed through a circular polarizer.

The path of the light rays when reflected from the sealed sections 4a of the portion with the latent image is as follows: the light passes through the polarizer 5 (Figure 2-C) - is converted into circularly polarized, reflected from the latent image 4 imprinted by the metal (Figure 2-C) - rotation of the vector polarization is reversed - polarizer 5 does not transmit light with this form of polarization. The sealed sub-sections 4a of the latent image portion appear dark blue when viewed through the circular polarizer 5.

Visualization is carried out using a circular polarizer 5 - white space sections 4b of the section with the latent image look bright, sealed sections 4a of the section with the latent image are dark blue, resulting in a very high contrast. Example 2

As the substrate 1, a transparent anisotropic polymer film is selected, which is a quarter-wave phase plate, an aluminum layer is applied to at least one portion on one side of the layer as a reflection layer 2. The latent image 4 (Fig. 1, 2) is imprinted with metal on the other side substrate 1 within the area on the first side of the substrate having a reflective layer (Fig. 1, 2) and cover with a protective layer 3 the surface of the area with a latent image 4 on one side of the substrate within areas having reflective th layer 2 on the other side of the substrate 1. This protective layer 3 - a transparent film containing a holographic image, is applied by hot embossing. The presence of a holographic image as part of a transparent protective layer or the presence of only one protective layer reduces the reflectivity surface and, as a result, blocks the visibility of traces of the formation of a latent image 4 when the element is examined with the naked eye at an acute angle to the surface. When viewing an element at right angles to the surface or deviations from the normal within ± 45 °, traces of the formation of a latent image are not visible in natural light and without a protective layer.

Visualization is carried out in the light with any form of polarization. In circularly polarized light, a contrasting dark blue image is obtained on a yellow background, the color arises due to the influence of the phase plate used as substrate 1. Using a phase plate as substrate 1 allows us to visualize the latent image in linearly polarized light: the color and nature of the image being visualized depends on the relative orientation of the polarizer and the phase plate, as a rule, using a linear polarizer, a contrast image is obtained - light sealed portions Ki on a purple background.

Industrial applicability

The claimed invention can be used to protect against falsification of valuable documents: passports, vouchers, banknotes, stocks, check books and to identify the authenticity of these documents.

Claims

CLAIM

1. A method of manufacturing an optical reflective protective element, which contains the following steps: a) provide a transparent substrate, made in such a way as to provide essentially uniformly throughout the volume of the substrate optical anisotropy; b) applying a reflective layer to at least one portion of the substrate on one side of the specified substrate; c) a reflective latent image is formed by direct printing on at least one portion of the substrate on its other side so that the specified at least one portion with the latent image is a sealed sub-area located within the image contour and white space sub-areas outside the contour of the image in the area with a hidden image, while the specified at least one area with a hidden image corresponds to a portion of the substrate with a reflective layer on the respective sides e substrate; d) uniformly apply a thin transparent protective layer over the entire surface of the area with a latent image, while the reflectance of the protective layer differs from the reflectivity of the portion with the latent image, while the reflectance and color of the sealed portions substantially coincide with the reflectance and the color of the white spaces of the area with a latent image, which determines the invisibility of the image when observing it with the naked eye st, at the same time hiding the visible signs of the formation of a latent image, and a clear contrast image when viewed in polarized light.

2. The method according to claim 1, wherein the substrate is made of a transparent depolarizing material.

3. The method according to claim 1, wherein a phase plate is used as the substrate.

4. The method of claim 1, wherein the reflective layer is made of metal.

5. The method of claim I ₅ in which the formation of a latent image is carried out using metal.

6. The method according to claim 1, in which a reflective hologram is used as a reflective layer.

7. The method according to claim 1, wherein the latent image is a reflective hologram.

8. The method according to p. 1, in which the formation of a latent image is carried out using the direct printing method, which is a thermal transfer printing.

9. The method according to p. 1, in which the formation of a latent image is carried out using the direct printing method, which is a hot stamping.

10. The method according to p. 1, in which the formation of a latent image is carried out using the direct printing method, which is a vacuum deposition.

11. The method according to claim 1, wherein a varnish layer is used as a protective layer.

12. The method according to claim 1, wherein a transparent hologram is used as a protective layer.

13. The method according to claim 1, wherein an additional multicolor visible image is applied to the surface of the protective layer.

14. The method according to p. 1, in which the protective element is formed in such a way that withstands the temperature of 180 ° C.

15. The method according to p. 1, in which the protective element is formed in such a way that it represents at least part of one of: a self-adhesive label, document, plastic card, packaging.

16. The method according to claim 1, wherein the visualization of the latent polarized image is carried out using a circular polarizer or a linear polarizer.

17. The method according to clause 16, in which when visualizing the latent image in circularly polarized light, the sealed sub-sections look dark blue, and the white sub-sections look like a light background.

18. The method according to clause 16, in which when visualizing the latent image in linearly polarized light, the sealed sub-sections look light, and the white sub-sections look like a dark background.

19. The method according to claim 1, wherein the reflectance of the protective layer is 5-10% greater, the reflectance of the area with a hidden image.

20. The method according to claim 1, wherein the reflectance value of the protective layer is 10-25% less than the reflectance value of the latent image portion.

21. An optical polarizing protective element comprising a substrate with a reflective layer deposited on at least one portion on one side and a latent image formed on it on the other side onto at least one portion of the substrate by direct printing, and made according to the method of PP. 1-20.