LT6306B - Method of manufacture of optical polarized transparent security unit and construction of this unit - Google Patents

Abstract

The invention relates to securities and document secure against forgery field, as well as the originality verification area. Optical polarizing transparent security element manufacturing method comprising: a transparent polymer composition applying a layer on a substrate; at least one transparent layer of polymer composition structuring in order to ensure the optical anisotropy of at least in one transparent polymer composition layer area; heat-activated transparent cement composition having refractive rate equal to at least two units, preparation by adding to the cement composition being based on a transparent inorganic compounds having a refractive rate of at least two units; heat-activated transparent cement compositions containing inorganic compounds with a refractive index of at least two units, applying on a transparent polymer composition.

Description

The present invention relates to the protection of securities and documents against counterfeiting and to the verification of their originality. Specifically, for the manufacture of optical security features having a hidden image not visible to the naked eye in natural light.

Currently, in order to protect against counterfeiting and as signs (markings) identifying documents, securities, etc. t. originality, uses various polygraphic means - watermarks, microtext, guilloche, etc., using magnetic, holographic, optical and other methods.

Among security features with variable optical properties, the most difficult to reproduce are those with hidden images only visible in polarized light.

In most cases, latent polarized images are obtained by forming optical anisotropy on or within the surface of the polymeric layer-carrier, in particular by changing the magnitude of the birefringence.

Local change in the size of the dual beam refraction can be achieved by resizing the optical anisotropy of the transparent material and / or changing its thickness, or by changing the thickness of the transparent anisotropic material in the defined regions of the layer.

These effects are achieved by mechanical, or chemical, or photophysical, or thermomechanical effects. In all these cases, the latent polarized image is formed in a pre-formulated polymer layer, or on a solid substrate surface.

Known techniques for producing a hidden image and security element on its substrate imply that there is, as a rule, a continuous polymeric layer having a hidden polarized image which is covered with glue on the other side, which is then removable to produce the final product, adhesive labels and markings.

The labels and markings thus obtained shall be affixed to the protected object either manually or by an automatic applicator.

Thus, in both cases, a very strong layer with a hidden image is required, which determines the possibility of reusing the element.

A known method for producing a hidden image is to locally mechanically remove a solid anisotropic polymer material from a solid substrate surface, as described in U.S. Pat. No. 5284364, published 08-08-1994.

However, the contrast polarized image formed in a known manner has a clearly visible image to the naked eye and does not guarantee reuse protection.

The closest technique to the optical protection element proposed in the art is the optical polarization protection element and its method of manufacture described in EA patent no. 011838, TPK G02B 1/08, G09F 3/02, posted on 2008-10-30.

The essence of the known method is to apply a reflective layer on a substrate, to print a hidden image, to structure the area of a layer having a hidden image at a predetermined depth, resulting in optical anisotropy of said layer in the structured area. contrasting visibility when viewed in polarized light.

Thereafter, the entire surface of the security element is coated with a thin transparent protective layer, wherein the refractive index of the protective layer substantially coincides with the refractive index of the area layer having a hidden image.

The known method has a major drawback, namely: the reflective layer according to the present invention is opaque in the visible range of the electromagnetic rays and, when this security element is placed on the document, the area of the document containing the security element is hidden from visual viewing, because the original signature, such as that of the owner of the document, or the characters executed with fluorescent inks, which are only displayed in the presence of, for example, ultraviolet light, cannot be positioned and protected accordingly.

The present invention provides a method of manufacturing an optical polarization transparent protective element and the construction of the element thus produced, and seeks to eliminate the above disadvantages.

The essence of the problem solution is that the proposed method of manufacturing the optical polarization transparent protective element comprises the following steps:

applying a layer of transparent polymeric composition to the surface of the substrate; structuring at least one region of the layer of the transparent polymeric composition to obtain optical anisotropy in at least one region of the layer of the transparent polymeric composition; preparing a thermally activated transparent adhesive composition having a refractive index equal to at least two units by adding inorganic compounds having a refractive index of at least two units to the base of the transparent adhesive composition; applying a thermally activated transparent adhesive composition containing inorganic compounds having a refractive index of at least two units onto the transparent polymeric composition.

In addition, polycarbonate, polystyrene, fluorocarbon, polyimide, polyvinyl alcohol, nitrocellulose and the like are used in the proposed process as a transparent polymeric composition for application to a substrate. i.e., the structuring of the layer of the transparent polymeric composition, in at least one of its regions, is accomplished either mechanically or by thermomechanical action, or by a thermoprinting head, or by treatment with a heavy ion beam or by laser treatment.

In addition, the process uses inorganic compounds having a refractive index of at least two units containing titanium dioxide, zinc sulfide, tin oxide (IV) and the like. i.e., while using pallets made of polypropylene or polyethylene terephthalate; together with Thermodex as a thermally activated transparent adhesive backing.

An advantageous embodiment of the present invention is an optical polarization transparent protective element comprising a substrate coated with a layer of a transparent polymeric composition having at least one area of structuring applied thereto, and a layer of a thermally activated transparent adhesive composition comprising a mixture applied thereto. inorganic compounds with a refractive index of at least two units are introduced into the adhesive backing.

The present invention improves the protective functions associated with the visibility of the symbols, inscriptions and 1.1. In addition, the constructional embodiment of the present invention provides the ability to display hidden images contained within that security element. Symbols placed on optically anisotropic regions are invisible in normal light without polaroids, since the human eye does not detect polarization of light. A transparent security feature allows you to see the area of the document or security that is beneath the security feature.

The invention is explained in more detail by the drawings where:

FIG. 1 illustrates a structure of an optical polarization transparent protective element manufactured in a claimed manner according to claims 1-6 of the invention.

FIG. Figure 2 is a diagram illustrating the use of an optical polarizing transparent security element for protecting a document or security from being reused or tampered with.

The method of the invention comprises the steps described below:

Covers a 16-20 µm thick substrate made of polypropylene or polyethylene terephthalate and overlays a 1-3 µm transparent polymeric composition layer on one surface based on a series of optically transparent polymers of polycarbonates, polystyrenes, fluoride, polyimides, polyvinyl alcohol, nitrocellulose and 1.1. The refractive index of these polymers is in the range of 1.5-1.6 units. The layer of the transparent polymeric composition is then structured (processed), for example, by mechanically generating certain symbols in at least one area. Such structuring can be accomplished not only mechanically (for example, by a fetal treatment), but also by thermomechanical operation of a plotter needle comb, or by treatment with ion beam or laser radiation.

It then produces a thermally activated transparent adhesive composition. For this purpose, 5 to 10% by weight of a high-transparency layered lamellar compound consisting of inorganic compounds having a refractive index of at least two units is added to a thermally activated adhesive base such as Thermodex, namely: titanium dioxide, zinc sulfide, tin oxide (IV). , which, on thin sheets of transparent material of artificial or natural origin, such as mica, contained in a thermally activated transparent adhesive composition, form a layer of 50 to 250 nm. Direct transfer of inorganic compound data to the polymeric layer is possible.

The prepared thermally activated transparent adhesive composition comprising inorganic compounds having a refractive index of at least two units is deposited on the transparent polymeric composition to form a layer of 4-6 µm thickness which does not normally stick.

The drawings (Figs. 1 and 2) illustrate not only the operation of the method of manufacture of the transparent security element of the invention, but also the understanding of the construction and use of the security element itself.

A concrete example of a method implementation.

On a substrate 1 made of 16 µm thick polyethylene terephthalate, a 2 µm layer 2 of a transparent polymeric composition based on polycarbonate is formed and forms isotropic regions 3 and anisotropic structured regions 4. It then prepares a layer 5 of a thermally activated transparent adhesive composition.

For this purpose, the Thermodex E / V 143 skin thermally activated transparent adhesive composition adds 7% by weight of a high-transparency layered wafer composition 103 made in China and prepares the corresponding base mixture with a layered wafer composition by applying a 5 µm layer on the transparent polymeric composition. layer 2 and dries. It then cuts strips, for example, 8 mm wide, which are then placed on a paper carrier by means of, for example, DRENT GOEBEL roll-to-roll, in the following modes: spindle-cliche temperature 140 ° C and transfer speed 40 m / min

In this way, an optical polarization transparent protective element is obtained, the construction of which is explained in the drawing of FIG. 1 marked positions.

The construction of the inventive optical polarization transparent protective element shown in FIG. 1, comprises: a tray 1, a layer 2 of a transparent polymeric composition comprising optically isotropic regions 3 and structured (optically anisotropic) regions 4, performed as certain symbols, and a thermally activated transparent adhesive composition, layer 5 containing inorganic compounds having the refractive index is at least two units. This is essentially an optical transparent security element.

The optical polarization transparent protective element of the invention is used in the manner described below (Fig. 2).

heated to 90-140 ° C by a metal cliche 7, through a substrate 1, a layer 2 of a transparent polymeric composition comprising optically isotropic regions 3, and structured (optically anisotropic) regions 4, performed as certain symbols, carried and affixed to document 6 thermally activating transparent adhesive compositions comprising inorganic compounds having a refractive index of at least two units.

Within the specified temperature range, the adhesive composition (layer 5) acquires adhesive properties and attaches layer 2 to document 6. Thereafter, tray 1 is removed.

The symbols placed on the optically anisotropic regions 4 are invisible in normal light without polaroids, as the human eye does not detect polarization of light. The transparent security feature allows you to see the area of the document or security 6 that is beneath the security feature.

In the case of a circular polaroid (not shown in the drawings), non-polarized light passes the circular polaroid from the source and obtains circular polarization.

The optical isotropic regions 3 do not alter the circular polarization of the light and the light achieves a thermally activated transparent adhesive composition comprising inorganic compounds having a refractive index of at least two units.

The optically anisotropic (structured) regions 4, by virtue of double beam refraction, change the circular polarization of light into an elliptical and the elliptically polarized light also achieves a thermally activated transparent adhesive composition comprising inorganic compounds having a refractive index of at least two units.

If the thermally activated transparent adhesive composition does not include inorganic compounds having a refractive index of at least two units, then the polymeric backbone of the thermally activated transparent adhesive composition itself would have a refractive index of 1.5-1.6 units. y. it would not differ from the refractive index of the layer 2 of the transparent polymeric composition.

In this case, in accordance with the Frenel formula, the intensity of the reflected wave reflected by parallel and perpendicular polarization is minimal and insufficient to render hidden images in layer 2.

As practice shows, in order to provide clear contrast visual understanding of hidden images in areas 4 (anisotropic) rendered using a circular polaroid, it is imperative that the perpendicular light incident from the boundary separating the transparent polymeric composition layer 2 having ni = 1.5 , and thermally activated layer 5 of the transparent adhesive composition, the reflectance would be 2%.

This is possible if the difference in refractive indices of layers 2 and 5 is at least 0.5 units, ie layer 2 must have at least n ₂ = 2.0. Then, according to the Frenel formula, when the beam falls perpendicular to the boundary separating the two materials (layer 2 and layer 5, fig. 1 and fig. 2), the reflection coefficient R is:

(n ₂ - thi) ² (n ₂ + n _x ) ²

^0.5h

3Λ * = 0.0204 = 2%

The addition of inorganic compounds having a refractive index of at least two units to the thermally activated transparent adhesive composition allows the reflection coefficient from the boundary between layers 2 and 5 to reach the desired level. There is also an important change in the phase of the reflected wave and it changes 180 ° for both polarizations as the angle of incidence exceeds the Bruster angle.

Under the conditions examined above, we return to the analysis of the behavior of polarized light by reflecting the boundary between two dielectrics - a transparent polymeric composition, i.e., layer 2 having optically isotropic regions 3 and optically anisotropic regions 4 (refractive index ni = 1.5) and adhesive compositions, ie layer 5 (n ₂ = 2.0) containing inorganic compounds with a refractive index of at least two units.

The elliptically polarized light obtained after passing the anisotropic regions 4 is reflected at sufficient intensity from the boundaries of layers 2 and 5 and exits the polaroid, i. y. the areas where the symbols are placed will be bright.

The light having circular polarization characteristic of the isotropic regions 3 is also reflected from the boundaries of layers 2 and 5, but due to phase change it acquires another direction of rotation of the electric voltage vector, which results in non-linear polarization of the light with a polaroid skip plane. Therefore, isotropic domains 3, vol. y. background, is dark. In this way, hidden images (symbols) placed only in areas 4 are rendered by contrast.

Thus, the problem is solved.This provides an optical polarization transparent protective element.

The technical solutions according to the present invention relate to the method of manufacturing the polarization transparent protective element and the construction of the element manufactured by the claimed method, are technically feasible and have a high technical level.

Claims (7)

DEFINITION OF INVENTION 1. A method of manufacturing an optical polarization transparent security element comprising coating the substrate with a layer forming a hidden image, wherein: (a) the substrate coating layer is a layer of a transparent polymeric composition; b) structuring at least one region of the layer of said transparent polymeric composition to obtain optical anisotropy in at least one region of the layer of the transparent polymeric composition; c) preparing a thermally activated transparent adhesive composition having a refractive index of at least two units by introducing into the base of the transparent adhesive composition an inorganic compound having a refractive index of at least two units; d) applying said thermally activated transparent adhesive composition containing inorganic compounds having a refractive index of at least two units to said transparent polymeric composition. 2. A process according to claim 1, wherein polycarbonate, polystyrene, fluorocarbon, polyimide, polyvinyl alcohol, nitrocellulose and 1.1 are used as transparent polymeric compositions for application to the substrate. 3. A process according to claim 1 or 2, wherein the structuring of the layer of the transparent polymeric composition in at least one region thereof is carried out either mechanically or by thermomechanical action, or by a thermal printer head, or by heavy ion beam processing or laser processing. 4. A process according to claim 1, wherein the inorganic compounds having a refractive index of at least two units include titanium dioxide, zinc sulfide, tin oxide (IV) and 1.1. 5. The method of claim 1, wherein the pallet comprises films made of polypropylene or polyethylene terephthalate. 6. A process according to claim 1, wherein the thermally activated transparent adhesive composition uses Thermodex. 7. An optical polarization transparent security element, characterized in that it is made by a method according to claims 1-6, comprising a substrate covered with a layer of a transparent polymeric composition having at least one area of its structuring and a thermally activated transparent adhesive composition applied thereto on the layer of the transparent polymeric composition. a layer comprising a mixture of inorganic compounds with a refractive index of at least two units.