WO2009134162A1

WO2009134162A1 - Protective optical polarisation element and a method for the production thereof

Info

Publication number: WO2009134162A1
Application number: PCT/RU2009/000127
Authority: WO
Inventors: Андрей Львович КАРАСЕВ; Валентинович СМИРНОВАндрей; Леонид Игоревич СМИРНОВ; Михаил Владимирович ЮРЕНКОВ
Original assignee: Открытое Акционерное Общество "Научно-Производственное Объединение "Криптен"
Priority date: 2008-04-30
Filing date: 2009-03-16
Publication date: 2009-11-05
Also published as: EA200801017A3; EA200801017A2; EA011838B1

Abstract

The invention relates to counterfeit protection and authentication of value documents, in particular to the design and production of latent image carrying optical protective elements, which image is invisible to an unaided eye in natural light and is visualised when examined through a polarisation filter. The inventive method for producing a protective optical polarisation element involves applying a reflective layer (2) at least on one area of a substrate (1), imprinting a latent image (3) onto at least one area of the substrate (1), which is coated by the reflective layer (2) by means of a direct printing method with the aid of a colourless transparent liquid composition, carrying our the preset structuring of at least one area of the layer, which carries said latent image, at a preset depth in such a way that the optical anisotropy in the structured layer area, which is responsible for the image (3) invisibility to an unaided eye and for a sharp contrast image examined in a polarised light, is provided, and applying a thin transparent protective layer (4) through the entire surface of the protective polarisation element, wherein the refraction factor of the protective layer (4) coincides with the refraction factor of the latent image (3) carrying area. The protective optical polarisation element produced according to the above method is also disclosed.

Description

OPTICAL POLARIZATION PROTECTIVE ELEMENT AND METHOD FOR ITS MANUFACTURE

Technical field

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

BACKGROUND OF THE INVENTION At present, various means of printing protection (watermarks, microtext, guilloche, etc.), magnetic, holographic, optical and other methods are used to protect against counterfeiting and as signs (identifiers) of the authenticity of protected objects. 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 bulk of the polymer layer - the carrier of the latent image as a result of the formation of optical anisotropy in the local region of the aforementioned polymer layer, namely, a change in the magnitude of 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 parts of it, or by changing the thickness of the transparent anisotropic material in certain areas of the layer. These effects are achieved by mechanical, chemical effects (US 5284364, published 08.02.1994, IPC B42D 15/00), photophysical effects (US 6100967 published 2000.08.08, IPC B42D 15/00), photochemical effects (US 6124970, published 26.09. 2000, IPC G02B 27/28), thermomechanical effects (WO 2006/005149 A2, published January 19, 2006, IPC GОЗF 7/00). In all the cases presented, a latent polarized image is formed in a polymer layer previously 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, then cutting is performed and the final product is obtained - self-adhesive labels and tags. The labels and tags obtained in this way are attached to the protected item either manually or using the 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 methods used for manufacturing the latent image, see, for example, US 5,284,364 lead to contours 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 removal of solid anisotropic polymeric 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 protective optical polarizing element with a high degree of protection against reuse by directly imprinting the latent image into the protected object, and subsequent predefined structuring of at least one section of the layer carrying the specified latent image to a given depth with optical anisotropy in the specified processed layer. Moreover, due to imprinting the latent image by direct printing directly onto the substrate, it is covered with a reflective layer, as well as the subsequent structuring of the specified area in a predetermined manner, the possibility of reproducing the specified protective element is virtually eliminated. In addition, in the claimed method, the refractive index of the protective layer according to essentially coincides with the refractive index of the portion of the layer carrying the latent image, which eliminates the appearance of the contour (halo) of the latent image visible with the naked eye in the structuring region, as a result of mechanical or chemical treatment of the surface area. Thus, due to this embodiment of the protective element, it has high mechanical, chemical, radiation resistance and stability over a wide temperature range that is invisible to the naked eye and visualized with high contrast when using a polarizing filter. SUMMARY OF THE INVENTION

According to a first aspect of the invention, there is provided a method of manufacturing an optical polarizing protective element, according to which a) a substrate is provided, b) a reflective layer is applied to at least one portion of the substrate, c) a latent image is imprinted on at least one portion of the substrate coated with a reflective layer by direct printing using a colorless transparent liquid composition, g) carry out a predetermined structuring of at least one section of the layer carrying the specified hidden image to a predetermined depth with optical anisotropy in the specified structured portion of the layer, which determines the invisibility of the image when observed with the naked eye and a clear contrast image when viewed in polarized light, e) apply a thin transparent protective layer over the entire surface of the protective polarizing element, when this, the refractive index of the protective layer essentially coincides with the refractive index of the portion of the layer carrying a hidden the battle

In this case, the reflective layer of the substrate is made of aluminum; a reflective hologram or a hot stamping holographic foil can be used as the reflective layer of the substrate.

Moreover, according to the method, the protective layer is a thin layer of transparent plastic with a thickness of 6-12 microns or a phase plate with a thickness of 6-12 microns, or a thin transparent polymer layer containing a holographic image with a thickness of 1-3 microns. In addition, the protective element is formed in such a way that withstands the temperature of 180 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 this method, a latent transparent image is made using a colorless transparent liquid composition containing from 5 to 30% polymer in an organic or inorganic solvent or an aqueous emulsion containing from 10 to 30% polymer. In addition, in the method according to the invention, the refractive index of the protective layer essentially coincides with the refractive index of the portion of the layer carrying the latent image.

Moreover, before the structuring step, the imprinted latent image is dried. At the same time, the structuring of the resulting image is a mechanical processing using rolls coated with felt, or strokes in the machine direction using a plotter or thermal printer.

According to a second aspect of the invention, there is provided an optical polarizing element comprising a substrate with a latent image imprinted on it onto at least one portion of the substrate with a reflective layer by direct printing using colorless transparent ink, and made according to the method disclosed above.

DESCRIPTION OF THE DRAWINGS OF THE DRAWINGS The features, elements, and advantages of the invention arise from the following description of embodiments of the invention with reference to the accompanying drawings, in which

FIG. 1 is a top view in circular polarized light of a protective polarizing element in a finished state. FIG. 2 is a cross-sectional view A-A of a protective polarizing element in a structuring step, FIG.

Fig.Z is a view in cross section AA of a protective polarizing devices in finished condition.

DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION A description of an optical polarizing protective element and a method for its manufacture will be described with reference to FIG. 1-3. According to a method for manufacturing an optical polarizing element, a reflective layer 2 is applied to the substrate 1, namely to at least one portion of the substrate 1.

Reflective layer 2 can be either a metal foil, or a metal-coated polymer film, or a reflective hologram or holographic hot stamping foil, or the surface of a document or plastic card with a pre-printed reflective portion, or paper or cardboard coated with paint with reflective properties.

Impress the latent image 3 (letters, numbers, logos, ornaments, etc.) onto at least one portion of the substrate 1, coated with a reflective layer 2 by direct printing using a colorless transparent liquid composition.

A colorless transparent liquid composition is a polymer solution in an organic or inorganic solvent with a concentration of from 5 to 30% or an emulsion with a polymer content of from 10 to 30%. The above ranges of polymer content in liquid compositions are generally accepted in industry and laboratory practice for producing polymer films.

Direct printing makes it completely impossible to reuse a security element. All methods of manufacturing a latent image and a protective element based on it, known from the prior art, presuppose the presence of a continuous, usually polymeric, layer that carries a latent polarized image, on which the adhesive is applied, then cutting is carried out and the final product is obtained - self-adhesive labels and tags. The labels and tags obtained in this way are attached to the protected item either manually or using the automatic applicator, in both cases a sufficiently high rigidity of the layer carrying the latent image is required, which makes it possible reuse item. In the method proposed by the authors, the continuous layer carrying the latent image is absent, there is no adhesive layer - the latent image is imprinted by any printing method directly onto 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 any printing method: flexographic, offset, deep, screen, etc.

As a result of printing with a colorless transparent polymer composition, the resulting image 3 is transparent for both natural and polarized light, that is, it is invisible in both natural and polarized light. In order for image 3 to be visualized in polarized light, it is necessary to make it anisotropic, for which purpose it is structured. For example, felt machining is standard for structuring the boundary layer of a polymer surface in the production of oriented panels for liquid crystal screens (Jos vap Naagep, Natuge, V.411, 3 Mau 2001, N ° 6833, p. 29-30). This method of treating the surface of polymers has been known for a long time, it has been used both in industry and in laboratory practice (H.Wei, A Dissertatiopoge Degheef PhDipusiсs, Upiversitu Califora at Berkloupu, 2000, Sum-Frépoussoupresu. Sugfase Aligmept of Rolomers. "). Other methods of orienting polymer molecules in the surface layer are irradiating the surface with a beam of heavy ions at an acute angle, applying strokes, scratches to the surface of the polymer film. In all cases, as a result of such a treatment, the polymer molecules are oriented and aligned in a boundary layer with a thickness depending on the type of processing along the direction of the strokes — scratches, and the optical properties of the polymer film change — birefringence occurs. This effect occurs during the machining of many isotropic polymeric materials: polyimides, polyvinyl alcohol, polyethylene, polyethylene terephthalate, polypropylene, etc. In the above method for obtaining a latent polarized image structuring the surface to a depth of 0.5-2 μm leads to the appearance of birefringence, which allows you to visualize a latent image using a polarizing filter. In the proposed method for manufacturing a latent polarized image 3, three processing (structuring) methods are used: (a) machining using an additional felt-coated shaft mounted in a line along the path of the tape with an imprinted latent image; in circular polarized light after such processing a white image is visualized on a blue background; (b) thermomechanical manifestation of the latent image using a needle comb of the writing head of the direct image output plotter installed in a line in the path of the tape with the imprinted latent image, while continuous strokes are applied to the material with the latent image in the machine direction; in circular polarized light after such processing a white image is visualized on a blue background; (c) thermomechanical manifestation of the latent image with the help of the thermal printer's writing head, installed in a line in the path of the tape with the imprinted latent image, while continuous strokes are applied to the material with the latent image in the machine direction; in circular polarized light after such processing a white image is visualized on a blue background.

A protective layer 4 is applied over the entire surface of the protective polarizing element.

The protective layer 4 is a thin transparent polymer layer that protects the latent polarized image 3 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 4 is made. As the protective layer 4, a varnish layer is used, which is resistant to abrasion and scratches and has a refractive index essentially equal to the refractive index of the polymer used to record the latent image. Also, a phase plate, for example a quarter-wave plate, can be used as a protective layer, in this case, in addition to the protective function, it performs the function of the polarized light transducer — in linear polarized light, the type of visualized image depends on the angle of rotation of the polarizer. The use of a transparent hologram as a protective layer 4 without its own reflector, in addition to the direct function of mechanical protection, 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 following are examples of the implementation of an optical polarizing protective element. Example 1

As the substrate 1 (Fig. 1-3), a 36 μm thick polyethylene terephthalate film is used, on which an 8 μm thick aluminum foil is applied as a reflective layer 2 (Fig. 1-3), onto which a 10% gravure printing solution of fluorolone in butyl acetate figure 3 is applied (latent image) (FIG. 1-3), after drying with warm air (70 ⁰ C) image thickness is 3 microns, then the film portion of the latent image is subjected to the structuring of the entire width of the belt in the thermal printer and the printhead is then covered termou tainable varnish 4 (FIGS. 1, 3) about 3 microns thick. The result is an image invisible to the naked eye, in a circularly polarized light, a white image is visualized on a blue background (Fig. 1). The resulting product withstands a temperature of 180 °, since all components of the obtained product withstand a temperature of 180 ° and above. The polyethylene terephthalate film dubbed with aluminum foil 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.

Example 2 As a substrate 1 (Fig. 1-3), paper is selected (document page), a reflective window 2 (reflective layer) is applied on the selected part of the page (reflective layer), (Fig. 1-3) within which 30% aqueous polypropylene emulsion flexography method Figure 3 is applied (Fig. 1-3), the image thickness after IR drying is 3 μm, the image surface is structured using the writing comb of a direct image output plotter, then within the reflection window 2 (reflection layer) (Fig. 1-3) a transparent holographic hot stamping foil is pressed as a protective layer 4 (Fig. 1, 3). As a result, on a transparent holographic background, an image 3 is obtained, which is invisible to the naked eye and visualized in circularly polarized light (Fig. 1). The security mark in this case is an integral part of the paper substrate (document page), the transparent holographic layer is destroyed when you try to separate it from the substrate, the sign as a whole cannot exist separately from the paper substrate and, therefore, cannot be reused.

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

Claims

CLAIM

1. A method of manufacturing an optical polarizing protective element, comprising the steps of: a) applying a reflective layer to at least one portion of the substrate, b) forming a latent image on at least one portion of the substrate, coated with a reflective layer by direct printing using colorless transparent liquid composition, c) structuring at least one portion of the latent image layer to provide optical anisotropy in the specified portion of the image layer, in which the image this remains invisible when observed with the naked eye and is clearly contrasted in polarized light; d) a thin transparent protective layer is applied over the entire surface of the protective polarizing element, while the refractive index of the protective layer essentially coincides with the refractive index of the latent image layer portion.

2. The method according to claim 1, wherein the reflective layer of the substrate is made of aluminum.

3. The method according to claim 1, wherein a reflective hologram is used as the reflective layer of the substrate.

4. The method according to claim 1, wherein a holographic hot stamping foil is used as the reflective layer of the substrate.

5. The method according to p. 1, in which the protective layer is a thin layer of transparent plastic.

6. The method according to claim 1, wherein the protective layer is a phase plate.

7. The method according to p. 1, in which the protective layer is a thin transparent polymer layer containing a holographic image.

8. The method according to p. 1, in which the protective element is formed in such a way that withstands the temperature 18O ⁰ C.

9. The method according to claim 1, wherein the security element is formed such in a way that represents at least part of one of: a document, a plastic card, packaging.

10. The method according to claim 1, wherein the latent image is made using a colorless transparent liquid composition containing from 5 to 30% polymer in an organic or inorganic solvent or an aqueous emulsion containing from 10 to 30% polymer.

11. The method according to claim 1 or 9, in which, before the processing step, the imprinted latent image is dried.

12. The method according to p. 1, in which the structuring of the image is a mechanical processing, using rolls coated with felt, to a depth of not more than 0.5 microns.

13. The method according to p. 1, in which the structuring of the resulting image is the application of strokes using the plotter's writing head to a depth of not more than 2 μm.

14. The method according to p. 1, in which the structuring of the resulting image is the application of strokes using the print head of the thermal printer to a depth of not more than 2 μm.

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

16. An optical polarizing element made according to the method according to claims 1-15, comprising a substrate, in at least one portion of which there is a reflective layer formed by direct printing using a colorless transparent composition with a hidden structured image, and on the surface the polarizing element has a thin protective layer, the refractive index of which essentially coincides with the refractive index of a portion of the latent image layer.