EA028236B1 - Method for producing an optical polarization protection means and design thereof - Google Patents

Abstract

The proposed technical solution claimed as the invention is related to protection of securities and documents against forgery and to verification of their authenticity. A method for producing an optical polarization protection means and a design of such means are claimed as an invention. In accordance with the invention, the method for producing an optical polarization protection means includes the following steps: application of an uninterrupted coating of a colourless, transparent, polymer composition on one of format sides of a base substrate followed by drying to produce a colourless, transparent, optically isotropic polymer layer; placement of a template having at least one projection in the form of a definite symbol on the format side of the base substrate free of the colourless, transparent, optically isotropic polymer layer; structuring of the colourless, transparent, optically isotropic polymer layer at the place of location of at least one projection to produce an optically anisotropic area followed by removal of the template; introduction of a service substrate consisting at least of a base and a transferrable reflective layer, the service substrate being separable from its reflective layer; application of a transparent adhesive composition with residual stickiness to the reflective layer of the service substrate or to the colourless, transparent polymer layer of the base substrate including optically isotropic and optically anisotropic areas, and joining them to each other; removal of the service substrate base; application of an uninterrupted coating in the form of a thermally activated, transparent adhesive composition on the side of the reflective layer followed by drying to produce a layer of thermally activated, transparent adhesive. The optical polarization protection means produced in accordance with claims 1-9 comprises a base substrate with a colourless, transparent polymer layer that consists of optically isotropic and optically anisotropic areas, and a reflective layer. In the optical polarization protection means according to the invention, the colourless, transparent polymer layer is joined to one of the sides of the reflective layer by means of a transparent adhesive composition with residual stickiness, and the opposite side of said reflective layer includes a layer of thermally activated, transparent adhesive.

Description

The present invention relates to the field of protection of securities and documents from counterfeiting, as well as to the field of verification of their authenticity. In particular, to the manufacture and production of optical protective elements carrying a latent polarizing image, invisible in natural light to the naked eye and visualized by a circular polaroid.

Currently, for protection against counterfeiting and as signs (marks) identifying the authenticity of documents, securities, etc., various means of printing protection are used watermarks, microtext, guilloche, etc., using 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 polarization images are obtained in the volume of the polymer layer of the latent image carrier as a result of the formation of optical anisotropy in the local region of the aforementioned polymer layer, which leads to 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, or chemical, or photophysical, or thermomechanical effects. In all these cases, a latent polarization image is formed in a polymer layer prepared in a special way or on the surface of a solid substrate.

Known methods for manufacturing a latent image and a protective element based on it suggest the presence, as a rule, of a polymer layer carrying a latent polarized image, on the back of which glue is applied, after which cutting is performed and the final product is obtained - self-adhesive labels and tags.

The labels and tags thus obtained are attached to the item to be protected either manually or using an automatic applicator.

A known method of manufacturing a latent image using local mechanical removal of solid anisotropic polymer material from the surface of a rigid substrate [1].

However, the known method leads to the formation of a contrasting polarized image with a clearly visible contour of the image with the naked eye and does not guarantee protection against reuse.

The closest in technical essence to the claimed as a invention method of manufacturing a protective agent is an optical polarizing protective element and a method for its manufacture [2].

The known method consists in the fact that a reflective layer is applied to the substrate, a latent image is formed by direct printing using a colorless transparent liquid composition, a portion of the latent image layer is structured to provide optical anisotropy in the indicated portion of the layer, in which the image remains invisible when observed with the naked eye and is clearly contrasted in polarized light.

After that, a thin transparent protective layer is applied over the entire surface of the protective element. In this case, the refractive index of the protective layer essentially coincides with the refractive index of the portion of the latent image layer.

However, the known method has a significant drawback, namely, when applying a thin transparent protective layer with a refractive index equal to the refractive index of a portion of the latent image layer over the entire surface of the protective element, their invisibility in natural light is not guaranteed due to diffraction effects around the perimeter of the hidden layer portion image, since the protective layer on the portion of the latent image layer and on the reflective layer is located in different planes and there is a transition section between these planes.

The objective of the proposed invention as a method of manufacturing an optical polarizing protective means is to ensure the invisibility of the latent image in natural light and contrast visualization of the latent image in polarized light.

The problem is solved in that the claimed method of manufacturing an optical polarizing protective means includes the following steps:

applying a continuous coating to one of the formatted sides of the base substrate in the form of a colorless transparent polymer composition, followed by drying to obtain a colorless transparent polymer optically isotropic layer;

placing the form with at least one protrusion, made in the form of a certain symbol, on the format side of the base substrate, free of a colorless transparent polymer optically isotropic layer;

structuring a colorless transparent polymer optically isotropic layer at the location of at least one protrusion to obtain an optically anisotropic region and then removing the mold;

the introduction of a technological substrate, consisting of at least a base and a portable reflective layer, configured to separate the basis of the technological substrate from its reflective layer;

applying a transparent adhesive composition with residual stickiness to the reflective layer of the technological substrate or to the colorless transparent polymer layer of the base substrate, including optically isotropic and optically anisotropic sections and their connection with each other;

removal of the basis of the technological substrate;

applying a continuous coating in the form of a thermally activated transparent adhesive composition from the side of the reflective layer, followed by drying and obtaining a layer of thermally activated transparent adhesive;

In addition, in the inventive method, polymers from the series: polycarbonate, polystyrene, fluoride, polyimide, polyvinyl alcohol, nitrocellulose, etc. are used as a colorless transparent polymer layer, and the structure of a colorless transparent polymer optically isotropic layer placed on a base substrate is carried out processing with a felt circle at the location of at least one protrusion of the mold.

As the base substrate in the claimed production method, a substrate made of polyethylene terephthalate or polypropylene is used, while the mold used with at least one protrusion is made of either a photopolymer or a metal alloy with the possibility of heating.

The technological substrate used in the manufacture of an optical polarizing protective agent consists of at least a base and a portable reflective layer.

Moreover, the basis of the technological substrate is made with the possibility of separation from the reflective layer. The technological substrate in this case includes printing, diffraction and holographic foils with a detachable base.

In addition, the reflective layer is a metal layer or coating made of transparent materials with a high refractive index, and acrylic-based adhesives are used as an optically transparent adhesive composition with residual stickiness used to connect the components in the manufacture of the protective agent.

The inventive method of manufacturing an optical polarizing protective agent is as follows.

On one of the two formatted sides of the base substrate, a continuous coating of a colorless transparent polymer composition is applied, which consists of a polymer dissolved in an appropriate organic solvent and then dried.

After drying, i.e. organic solvent removal, a colorless polymer transparent optically isotropic layer forms on this formatted side of the base substrate.

On the other opposite to the formatted side of the base substrate, the surface of which is free of a colorless polymer transparent optically isotropic layer, a mold is provided with at least one protrusion made in the form of a certain symbol. The form is connected to the base substrate.

Then, using a special mechanical device, such as a felt wheel, a colorless transparent polymer optically isotropic layer is placed on the formatted side of the base substrate.

The felt circle is brought into contact with a colorless polymer transparent optically isotropic layer, rotated and moved relative to a colorless polymer transparent optically isotropic layer.

You can only rotate the felt circle, and move the colorless polymer transparent optically isotropic layer together with the base substrate and the shape relative to the circle.

When this processing is performed, only those sections of the colorless polymer transparent optically isotropic layer that are under the protrusions of the shape and include certain symbols are subjected to structuring (thus, optically anisotropic regions are formed, which together with optically isotropic regions form latent images).

In fact, the structuring of areas at the location of the protrusions of the mold occurs, which are optically anisotropic zones of a colorless polymer transparent layer of the base substrate, and the areas free from protrusions remain unstructured and remain optically isotropic zones, since the felt circle does not process colorless in these zones polymer transparent optically isotropic layer due to lack of support and the inability to create the necessary force contact with colorless polymer transparent pticheski isotropic layer to translate it into an optically anisotropic state.

Thus, the regions of a colorless transparent polymer layer containing symbols after being structured are optically anisotropic, and the regions of a layer containing no symbols remain optically isotropic.

- 2 028236

It is important that the optically isotropic and optically anisotropic sections are located in the same layer, as a result of which there is no transition section between them.

Then, the aforementioned form is removed from its place and a technological substrate is introduced, including a base and a reflective layer.

In this case, the technological substrate is arranged so that its base is easily separated from the reflective layer.

At the next stage of production of the protective agent, a transparent adhesive with residual tack is applied to a colorless transparent polymer layer of the base substrate, including optically isotropic and optically anisotropic regions, or to a reflective layer of the technological substrate. Then, the base substrate with a colorless transparent polymer layer is tightly connected to the technological substrate with a reflective layer and the transparent adhesive composition between them with residual stickiness forms a single whole of these components. Immediately separate the basis of the technological substrate.

The use of a transparent adhesive composition with a residual stickiness between a colorless transparent polymer layer of the base substrate, including optically isotropic and optically anisotropic sections, and a reflective layer of the technological substrate eliminates even minor irregularities that arise between optically isotropic and optically anisotropic sections.

Mentioned elimination occurs due to the ductility of the transparent adhesive composition with residual stickiness.

On the free side of the reflective layer, a continuous coating of the thermally activated transparent adhesive composition is applied, it is dried and a layer of thermally activated transparent adhesive is obtained.

The manufacturing process of the optical polarizing protective means is completed.

It is also important to note that in the manufacture of the said protective agent, polymers from the following series are used as a colorless transparent polymer layer: polycarbonate, polystyrene, fluoride, polyimide, polyvinyl alcohol, nitrocellulose, etc.

The aforementioned polymers are transparent to visible radiation and have a sufficient degree of crystallinity to produce optically anisotropic regions by crosslinking.

The base substrate is, as a rule, a substrate made of polyethylene terephthalate or polypropylene with a thickness of 15-25 μm, and the mold used in the manufacture of the protective agent is made either of a photopolymer using the usual technology for producing forms for flexographic printing, or of a metal alloy, such as brass, milling with the possibility of heating the latter to 100 ° C. This allows one to intensify the structuring process, since the colorless polymer transparent optically isotropic layer is preheated at the locations of the protrusions of the metal form and the formation of optically anisotropic zones is facilitated.

Technological substrate, as a rule, includes printing, diffraction or holographic foils.

The use of a reflective layer of these types of foil, firstly, provides visualization of the latent image when using a polaroid, and secondly, enhances the protective properties of the optical polarizing protective means by introducing an additional protective element.

It should also be noted that the layer of thermally activated transparent glue formed during the production of the protective agent is activated at a temperature of 90 to 100 ° C and promotes the permanent connection of the protective agent with the protected object without the transfer of optically anisotropic zones to an optically isotropic state, which is possible when heating optically anisotropic zones above 100 ° C.

In FIG. 1-3 show a method of manufacturing an optical polarizing protective agent and an intermediate structure of an optical polarizing protective agent obtained by the claimed method (FIGS. 1 and 2), as well as a finished construction of an optical polarizing protective agent (FIG. 3) manufactured by the above method.

In FIG. 1, 2 presents the initial stages of manufacture and the intermediate design of an optical polarizing protective agent in accordance with the claimed method;

in FIG. 3 - the final stages of manufacture and the finished design of an optical polarizing protective agent made by the claimed method of the invention.

The intermediate structure of the optical polarizing protective means shown in FIG. 1 and 2, clearly illustrates the essence of the claimed method, an example of its specific implementation and includes the following positions:

- base substrate (Fig. 1, 2);

- colorless transparent polymer optically isotropic layer (Fig. 1, 2);

- form (Fig. 1);

- protrusions on the form 3, made in the form of certain characters (Fig. 1);

- optically anisotropic regions in a colorless transparent polymer optically isotropic

- 3 028236 layer 2 (Fig. 1, 2);

- felt circle (Fig. 1);

- technological substrate (Fig. 2);

- the basis of the technological substrate (Fig. 2);

- a reflective layer of the technological substrate (Fig. 2);

- optically transparent adhesive composition with residual stickiness (Fig. 2).

An example of a specific implementation of the inventive method and the intermediate structure of an optical polarizing protective agent made by the inventive method is explained in the aforementioned FIGS. 1 and 2

One of the formatted sides of the base substrate 1, made of polyethylene terephthalate with a thickness of 20 μm, is coated with a continuous coating in the form of a colorless transparent polymer composition, which after drying forms a colorless, transparent optically isotropic layer 2 on this surface, the thickness of which is from 2 to 4 μm.

In this example of the method, as a continuous coating in the form of a colorless transparent polymer composition, a polycarbonate-based polymer composition is applied with a thickness of 6 μm, which, after drying, forms a colorless transparent optically isotropic layer 2 of 3 μm thickness on the surface of the base substrate 1.

On the other formatted side of the base substrate 1 is placed a form 3 made, for example, of a photopolymer and containing protrusions 4 made in the form of certain characters.

Then, by rotating the felt circle 11 and moving it with respect to the colorless transparent optically isotropic layer 2, the latter is structured at the locations of the protrusions 4 of form 3, as a result of which optically anisotropic sections 5 are formed in the layer 2.

Optically anisotropic sections 5 formed during the structuring process include certain symbols.

As the technological substrate 6, for example, printing (gilding), diffraction or holographic foils, including those with an original holographic image, are used.

These foils consist of a detachable base 7 and a reflective layer 8.

On a reflective layer 8 or on a colorless transparent polymer layer of the base substrate, consisting of optically isotropic 2 and optically anisotropic 5 sections, a transparent adhesive composition with a residual stickiness of 9 is applied, for example, acrylic-based adhesive.

The resulting structure is combined into a single whole, and the base 7 of the technological substrate 6 is separated and removed.

On the opposite side of the reflective layer 8, a continuous layer of thermally activated transparent adhesive composition with a thickness of 11 μm is applied and dried to obtain a layer of thermally activated transparent adhesive 10 with a thickness of 6 μm.

The design of the finished optical polarizing protective means made in accordance with claims 1 to 9 of the claims is presented in FIG. 3 and includes a base substrate - 1; optically isotropic sections - 2; optically anisotropic sections - 5; reflective layer - 8;

optically transparent adhesive composition with a residual stickiness of 9; a layer of transparent thermally activated adhesive - 10.

An optical polarizing protective agent, aimed at solving the problem and performed in accordance with claims 1 to 9 of the method claimed as an invention, contains a base substrate with a colorless transparent polymer layer, which consists of optically isotropic and optically anisotropic sections and a reflective layer, while a colorless transparent polymer layer is connected to one of the sides of the reflective layer by means of a transparent adhesive composition with residual stickiness, and the opposite side of the aforementioned reflective layer comprises a layer of a transparent heat activated adhesive.

Mentioned optical polarizing protective agent, made in accordance with claims 1 to 9 of the claimed invention as a method, includes layer-by-layer interconnected base substrate 1, a colorless transparent polymer optical layer consisting of optically isotropic 2 and optically anisotropic 5 sections, reflective layer 8 , an optically transparent adhesive composition 9 with residual stickiness, connecting the transparent polymer optical layer with optically isotropic sections 2 and optically anisotropic sections 5 with a reflective layer m 8, the opposite side of which contains a layer of thermoactivirus transparent adhesive 10 (Fig. 3).

The design of the finished optical polarizing protective device of FIG. 3, works as follows.

This design is applied to an object protected from forgery, for example, to an excise stamp, namely, a heated metal cliche, which is located on the side of the base substrate 1, and the protective agent is pressed against the excise stamp 4 028236.

The thermal and power effects from the cliche are transferred to a layer of thermally activated transparent adhesive 10, which is activated and secures the protective agent on the excise mark. Next, the cliche and the base substrate 1 are removed.

When illuminating a protective device with the base substrate 1 removed, polarized light with circular polarization after reflection of light from the reflecting layer 8, the optically isotropic regions 2 will be dark and contrast with light optically anisotropic regions 5.

The technical solutions claimed as inventions related to a method for manufacturing an optical polarizing protective agent and to the design of an optical polarizing protective agent made by the claimed method are technically feasible and have a high technical level.

Sources of fame.

1. US patent No. 5284364.

2. EA-patent No. 011838, IPC C 09P3 / 02, C 02B1 / 08.

Claims (10)

CLAIM 1. A method of manufacturing an optical polarizing protective agent, including: a) applying to one of the main sides of the base substrate a continuous coating in the form of a colorless transparent polymer composition, followed by drying to obtain a colorless transparent polymer optically isotropic layer; b) placing the mold with at least one protrusion made in the form of a certain symbol on the main side of the base substrate, free of a colorless transparent polymer optically isotropic layer; c) structuring a colorless transparent polymer optically isotropic layer at the location of at least one protrusion to obtain an optically anisotropic region and subsequent removal of the form; b) the introduction of a technological substrate, consisting of at least a base and a portable reflective layer, configured to separate the basis of the technological substrate from its reflective layer; f) applying a transparent adhesive composition with residual stickiness to the reflective layer of the technological substrate or to the colorless transparent polymer layer of the base substrate, including optically isotropic and optically anisotropic sections, and their connection with each other; 1) removal of the basis of the technological substrate; I) applying a continuous coating in the form of a thermally activated transparent adhesive composition from the side of the reflective layer, followed by drying and obtaining a layer of thermally activated transparent adhesive. 2. The method according to claim 1, in which polymers from the series: polycarbonate, polystyrene, fluoride, polyimide, polyvinyl alcohol, nitrocellulose are used as a colorless transparent polymer layer. 3. The method according to claim 1, in which the structuring of a colorless transparent polymer optically isotropic layer placed on the base substrate is carried out by processing with a felt circle at the location of at least one protrusion of the form. 4. The method according to claim 1, in which the base substrate is a substrate made of polyethylene terephthalate or polypropylene. 5. The method according to claim 1, in which the form with at least one protrusion is made of a photopolymer. 6. The method according to claim 1, in which the form with at least one protrusion is made of a metal alloy with the possibility of heating. 7. The method according to claim 1, in which the technological substrate contains printing, diffraction and holographic foils. 8. The method according to claim 1, in which the reflective layer is a metal layer or coating made of transparent materials with a high refractive index. 9. The method according to claim 1, in which acrylic-based adhesives are used as an optically transparent adhesive composition with residual tack. 10. An optical polarizing protective agent made according to the method according to claims 1 to 9, comprising a base substrate with a colorless transparent polymer layer, which consists of optically isotropic and optically anisotropic sections and a reflective layer, while the colorless transparent polymer layer is connected to one of the sides a reflective layer by means of a transparent adhesive composition with residual stickiness, and the opposite side of the said reflective layer contains a layer of thermally activated transparent adhesive.