EA029186B1 - Protective mark - Google Patents

Abstract

Disclosed is a protective mark having a layer with a concealed polarisation image and a reflecting layer, wherein the layer with the concealed polarisation image has isotropic and anisotropic regions, the layer with the concealed polarisation image has phase polarisation capability and represents a quarter-wave plate. The technical result achieved is increasing level of protection against counterfeit by imitation and copying while providing a cheap and reliable method of authenticating marked articles.

Description

The invention relates to the means used to authenticate products, in particular, to protective labels containing latent images, and can be used to make protective labels applied to documents, securities, labels, excise stamps, etc.

From the prior art corresponding to the present invention, the known patent of the Russian Federation for useful model No. 87658, which describes a protective label made in the form of a multilayer film comprising a first polymer layer containing a latent polarization image, implemented due to the different degrees of anisotropy of individual sections of this polymer layer and a second polymeric layer with a reflective coating, visualized using a polaroid, containing a latent image read by a laser, which is formed as a flat optical th element, providing a predetermined direction of dispersion of the laser radiation, and connecting said layers of polymeric optically transparent adhesive layer applied to the side of the reflective coating of said second polymeric layer.

The disadvantage of this means of authentication is the lack of protection of the marked products.

The purpose of the present invention is to provide authentication tools with an increased level of protection against counterfeiting by imitation and copying and providing an affordable and reliable way to control the authenticity of products marked with these means.

The task underlying the present invention is solved using a security label containing a layer with a hidden polarization image and a reflective layer, while in a layer with a hidden polarization image, isotropic and anisotropic areas are made in which the layer with a hidden polarization image has the ability to phase polarization and is a quarter wave plate.

When inspecting such a protective label through a linear polarization filter, elements of the latent polarization image will appear and change their brightness when the filter is rotated.

In this case, when inspecting such a protective label through a circular polarizing filter, the isotropic areas (background) are darkened, and the anisotropic areas (elements of the hidden polarization image) have a brightness higher than the background brightness (isotropic areas). This effect does not change with the rotation of the circular polarization filter.

For the production of a protective tag, according to the invention, special technological equipment and highly qualified personnel are required. Imitation of the above effects in any other ways is practically impossible.

It is advisable to use polyvinyl alcohol as a layer material with a hidden polarization image.

For the case of polyvinyl alcohol and the above dyes, the maximum contrast of the latent polarization image is achieved with a layer thickness of 4 to 6 microns. The best result is achieved with a thickness of 5 microns.

Also, the problem underlying the present invention is solved by a security label containing a layer with a hidden polarization image, connected to the reflective layer by means of an adhesive layer, while the reflective layer is made in the form of a layer of thermoplastic varnish with a metallic coating, and in a layer with hidden polarization the image is made of isotropic and anisotropic regions, characterized in that the layer with hidden polarization has the ability to phase polarization and is a quarter-wave PL Steen.

The technical result achieved by this protective label is identical to that of the protective label described above. The presence of the adhesive layer and the type of execution of the reflective layer make it possible to ensure the mass production of this label with guaranteed assurance of the technical result achieved.

It is advisable to use polyvinyl alcohol as a layer material with a hidden polarization image.

For the case of polyvinyl alcohol and the above dyes, the maximum contrast of the latent polarization image is achieved with a layer thickness of 4 to 6 microns. The best result is achieved with a thickness of 5 microns.

A layer with a hidden polarization image can be connected by means of an adhesive layer with a metallic coating of the reflective layer, or with a layer of thermoplastic varnish. Thus, a protective label will be obtained, which can be placed on the substrate, which will ensure further transfer of the label to the product being marked.

Also, the problem underlying the present invention is solved using a security label containing a latent image, which appears when viewing a label through a polarization filter, which contains the background of the latent image and elements of the latent image, which is viewed through a linear polarization filter and rotated the elements of the latent image change their brightness, while, when inspecting the protective label through a circular polarizing filter, the background of the latent image is darker than the elements of the latent image I kind of hidden izobrazhe- 1 029186

does not depend on the angle of rotation of the circular polarization filter.

Such a set of effects of a hidden image is almost impossible to simulate, while the presence of these effects is easily determined by the consumer or expert, which provides a high level of protection against forgery by imitation and copying and an affordable and reliable way to control the authenticity of products marked with these means.

The following is a description of preferred embodiments of the present invention with reference to the accompanying drawings, in which:

FIG. 1 shows the amplitude and phase characteristic of a security label according to the present invention;

FIG. 2 - the first embodiment of the security label; FIG. 3 - the second embodiment of the protective label.

According to the present invention, in an authentication device (security label) a layer with a hidden polarization image is used, combined with a reflective layer.

The layer with the hidden polarization image is a dichroic light polarizer capable of phase polarization of light.

As a layer material with a hidden polarization image, for example, polyvinyl alcohol, or ethylcellulose, or any other material capable of phase polarization of light can be used.

An optically anisotropic layer is obtained from the optically isotropic layer by any method known and suitable for the polarizer used, in particular, by mechanical or thermo-mechanical action.

Optically anisotropic regions are formed to form a hidden polarization image in an optically isotropic layer. Thus, a layer with a hidden polarization image is a layer with optically isotropic and optically anisotropic regions. The mutual arrangement of optically isotropic and optically anisotropic regions determines the latent polarization image.

When inspecting a protective label provided with a layer with a hidden polarization image, according to the present invention, in unpolarized light, any elements of the latent image will not be visible.

When inspecting a protective label provided with a layer with a latent polarization image, in accordance with the present invention, through a linear polarization filter, the elements of the latent image will be revealed. In this case, when a linear polarization filter rotates (changes in the angle between the plane of polarization of light and the plane of polarization of the optically anisotropic regions), the elements of the latent polarization image will change their brightness.

The effect of phase polarization is manifested in the fact that when a beam of linearly polarized light passes through an anisotropic layer, the phases of the components of this beam shift. Components are the projection of the beam on the axis of polarization of the filter and the projection of the beam on the axis perpendicular to the axis of polarization of the filter.

At angles equal or close to 0, 90, 180 and 270 °, one of the components is missing or small, the other component is equal to or close to the most transmitted beam of linearly polarized light. Thus, at these angles, the effect of phase polarization does not appear or is only slightly manifested.

At angles equal or close to 45, 135, 225 and 315 °, the beam components are equal or close to each other. Thus, the effect of the phase shift of the components and, accordingly, the effect of phase polarization is most pronounced.

When reflected from a reflecting layer of light polarized in a circle, the direction of circular polarization changes (from right to left or from left to right). When light passes back through a layer with a hidden polarization image, light is converted from circularly polarized light to linearly polarized light. However, due to a change in the direction of circular polarization upon reflection, the plane of polarization of this linearly polarized light is perpendicular to the plane of polarization of the incoming linearly polarized light beam and is not transmitted by the linear polarization filter.

Thus, at angles equal or close to 45, 135, 225 and 315 °, there will be a darkening of the anisotropic regions relative to the isotropic regions (background).

FIG. 1 shows the amplitude-phase characteristic of the protective label, namely, position 1 denotes the characteristic of isotropic regions of the layer with a hidden polarization image. Position 2 - anisotropic regions.

Preferably, the layer with the hidden polarization image is performed in the form of a quarter-wave plate, at the exit of the layer the phase displacement of the components is equal to 1/4 of the phase. Thus, the effect of circular polarization and maximum contrast of the latent polarization image is achieved. Obviously, a quarter-wave plate is formed in anisotropic regions, isotropic regions do not have the effect of phase polarization.

When inspecting the protective label through a circular polarization filter, the isotropic regions are then 2 029186

The anisotropic regions have a brightness higher than the background brightness (isotropic regions). This effect does not change with the rotation of the circular polarization filter.

As shown in FIG. 2, the security label in accordance with the first embodiment of the invention consists of a layer 3 with a hidden polarization image and a reflective layer 4 with protective elements interconnected by an adhesive layer.

The surface of layer 3 with a hidden polarization image is covered with protective varnish 8.

The reflective layer 4 with the elements of protection is connected to the carrier 6 by an adhesive joint 7.

The reflective layer 4 with protective elements is a layer with protective elements that appear when light is reflected. Holograms, layers with a laser-readable image, as well as combined elements, such as a hologram with a laser-readable image, can be assigned to the reflective layer 4 with security elements.

Preferably, a reflective layer 4 with protective elements, which is a hologram with a laser readable image, is used in the security label.

A reflective layer 4 with protective elements is formed on the layer 9 of thermoplastic varnish.

Protective label, according to the first embodiment of the invention, is made as follows.

A protective varnish is applied to the temporary substrate. The thickness of the protective varnish layer is preferably 5 μm.

An optically isotropic polymer layer is applied to the protective varnish 8.

Then, optically anisotropic regions are formed on the surface of the isotropic layer. The formation of optically anisotropic regions can be performed using a plotter or by passing through a thermal transfer printer.

Thus, a layer 3 is formed with a latent polarization image on a temporary substrate.

Next on the layer 3 with a hidden polarization image is applied adhesive layer 5.

In parallel, a reflective layer 4 is made with protective elements.

The preferred reflective layer 4 with protective elements, which is a hologram with a laser-readable image, is produced by hot-stamping a metal-coated foil.

The original stamp for embossing is made by electroforming using a relief image, which is obtained, for example, by electron beam lithography.

The metal-coated foil is a layer 9 of a thermoplastic lacquer coated with a metal coating (dusting). On the side of layer 9 of thermoplastic varnish, the foil is connected to a temporary carrier (not shown in Fig. 2).

After the formation of the protective elements, the metal coating is a reflective layer 4 with protective elements.

Thus, the metal-coated foil is used to form a reflective layer 4 with protective elements and a protective label thermoplastic varnish layer 9.

The reflective layer 4 with the protective elements is connected to the carrier 6 by means of adhesive bonding 7. Self-adhesive paper on a siliconized substrate can be used as a carrier. After connecting with the carrier 6 from the layer 9 of thermoplastic varnish, the temporary carrier is removed.

The layer 3 with the hidden polarization image is connected to the reflective layer 4 with the protective elements by means of the adhesive layer 5. The connection is made from the side of the reflective layer 4. After the layer 3 is connected with the hidden polarization image with the reflective layer 4, the temporary substrate is removed from the protective varnish 8.

After that, the product is ready for further cutting and use.

As shown in. FIG. 3, the security label in accordance with the second embodiment of the invention consists of a layer 3 with a latent polarization image and a reflective layer 4 with protective elements interconnected by an adhesive layer 5.

The surface of layer 3 with a hidden polarization image is covered with protective varnish 8.

A reflective layer 4 with protective elements is formed on a layer 9 of thermoplastic lacquer deposited on a carrier 10. As a carrier 10, for example, a film of polyethylene terephthalate can be used.

A layer 9 of thermoplastic lacquer is connected to the carrier 10.

The reflective layer 4 with the security elements according to the second embodiment of the invention is the same layer 4 with the security elements described with respect to the first embodiment of the invention, and is made in the same way.

The security mark according to the second embodiment of the invention is made as follows.

A protective varnish is applied to the temporary substrate. The thickness of the protective varnish layer is preferably 5 μm.

An optically isotropic polymer layer is applied to the protective varnish 8.

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Then, optically anisotropic regions are formed on the surface of the isotropic layer. The formation of optically anisotropic regions can be performed using a plotter or by passing through a thermal transfer printer.

Thus, a layer 3 is formed with a latent polarization image on a temporary substrate.

Next on the layer 3 with a hidden polarization image is applied adhesive layer 5.

In parallel, a reflective layer 4 is made with protective elements.

The reflective layer 4 with protective elements is left on the carrier 10.

Layer 3 with a hidden polarization image is connected to the reflective layer 4 with protective elements by means of adhesive layer 5.

After this, the temporary substrate is removed from the product from the side of the protective varnish 8 and the product is ready for further cutting and use.

The security label according to the second embodiment of the invention has better performance properties, in particular, is more water resistant. In this case, the security label, according to the first embodiment of the invention, is more protected, since it is destroyed when any attempt is made to re-paste it from one protected article (document) to another.

FIG. Figures 2 and 3 indicate by convention the anisotropic regions made in layer 1 with a hidden polarization image.

In accordance with the best embodiments of the invention, polyvinyl alcohol is used as the material of the layer 3 with a hidden polarization image.

The thickness of the layer 3 with a hidden polarization image corresponds to a quarter-wave plate and ranges from 4 to 6 microns.

The best technical result (the greatest contrast of the latent image) is achieved when the thickness of layer 3 with the latent polarization image is 5 μm.

The presence of protective elements made on the reflective layer 4, provides additional degrees of protection.

For example, a consumer can estimate the presence of a hologram on a security label without using any special devices.

If a laser-readable image is made on the reflective layer 4, this image can be detected by using special means. In this case, it can be determined not only where and by whom this protective label was produced, but also by the specific stamp with which this image was made and, accordingly, the approximate production time and the batch of protective labels.

Claims (10)

CLAIM 1. A security label containing a layer with a hidden polarization image and a reflective layer, while in the layer with a hidden polarization image, isotropic and anisotropic areas are made, characterized in that the layer with the hidden polarization image has the ability to phase polarization and is a quarter-wave plate. 2. Protective label according to claim 1, characterized in that polyvinyl alcohol is used as the material of the layer with a hidden polarization image. 3. Protective label according to claim 2, characterized in that the thickness of the layer with the hidden polarization image is from 4 to 6 microns. 4. Protective label according to claim 3, characterized in that the thickness of the layer with hidden polarization image is 5 μm. 5. Protective label according to claim 1, characterized in that the layer with the hidden polarization image is connected to the reflective layer by means of an adhesive layer, while the reflective layer is made in the form of a layer of a thermoplastic varnish with a metallic coating. 6. Protective label according to claim 5, characterized in that polyvinyl alcohol is used as the material of the layer with hidden polarization image. 7. Protective label according to claim 6, characterized in that the thickness of the layer with the hidden polarization image is from 4 to 6 microns. 8. Protective label according to claim 7, characterized in that the thickness of the layer with the hidden polarization image is 5 μm. 9. Protective label according to any one of paragraphs.5-8, characterized in that the layer with the latent polarization image is connected by means of an adhesive layer with a layer of thermoplastic varnish of the reflective layer. 10. Protective label according to any one of paragraphs.5-8, characterized in that the layer with the latent polarization image is connected by means of an adhesive layer with a metal coating of the reflective layer. - 4 029186