RU2674691C1 - Hidden image in the thin sheet material creation method from plurality of the volumetric nano-structures pairs for the securities and identification documents protection against forgery by several common characters - Google Patents

Abstract

FIELD: image forming devices; manufacturing technology.SUBSTANCE: hidden image in the thin sheet material body creation method from plurality of the volumetric nano-structures pairs for the securities and identification documents protection against forgery by several common characters. Method is implemented by acting on given points of the sheet material from the metal layer surface between two layers of plastic, located on the micro-lenses layer in the form of glass microbeads, deposited on the plastic substrate and partially immersed in the luminophor layer by the above-threshold power laser pulses. As a result, in the sheet material within the laser spot tremendous pressure occurs, displacing composing the laser beam light waves to the laser spot periphery. These waves penetrate inside the sheet material, within the laser spot fuse the micro-lenses with metal and luminophor particles, penetrate the plastic substrate, forming channels in it, and under the influence of enormous return pressure from micro-lenses reaching 100,000 atm., and high temperatures of the order of 3,000–4,000 °C in the adjacent to the metal layer plastic form between them the latent image points from the volumetric nanostructures pairs and nano-whiskers rows. In fact, the volumetric nanostructures pairs and nano-whiskers rows are formed as the result of the metal, glass, luminophor and plastic alloy high-speed crystallization. As a result of crystallization, on the sheet material front surface an image is formed from the points, which are a collection of crystals, and located between them the nano-whiskers rows represent the diffraction grids equivalent. With the sheet material turning relative to the light source, on the nano-whiskers rows its dispersion occurs, as a result of which, the subjected dispersion white light paints the crystal in different colors, creating a color iridescent image on the sheet material front surface. Proposed method enables creation of two more common characters to protect this material against counterfeiting, on the sheet material back side ensuring formation of the black and white image from the channels in the plastic substrate and visible in transmitted light the original color image inside the sheet material.EFFECT: proposed security features are created by the proposed method in a thin film, so that this method can protect both securities and identification documents against forgery.6 cl, 4 dwg

Description

A method for creating a latent image in a thin sheet material from a multitude of pairs of bulk nanostructures to protect against forgery of securities and identification documents by several public attributes.

The present invention relates to special types of printing and allows you to create in thin films the original color iridescent image with several public features to protect securities and identification documents from counterfeiting.

State of the art

There is a method of creating a latent image in a sheet material from a plurality of pairs of bulk nanostructures, visualized to obtain a colored iridescent image undergoing dispersion by the light flux (see, for example, RF application No. 2017119780 from 06/07/2017).

In the known method, the creation of a latent image from bulk nanostructures in a sheet material is carried out using two parallel diffraction gratings embedded in this material, which increases the thickness of the material and limits the scope for protecting only a number of identification documents, for example, passports.

There is also known a method of creating inside the sheet material a color protective image visible through the channels in this material in transmitted light. The same channels form on the back of the sheet material a black and white image visible in reflected light (see, for example, RF patent No. 2555500 class B42D 25/40, B42D 25/435, G02B 5/128).

Although the known method allows you to create a bright colorful image inside the sheet material, its color does not shimmer when turning the material, and the image itself is invisible in reflected light.

There is a method of forming bulk nanostructures in a sheet material to create protective images, which does not require the introduction of diffraction gratings inside this material (see, for example, RF application No. 217123612 of 05.07.2017).

The known method allows you to create bulk nanostructures in the sheet material in the form of nanowhiskers under conditions of a sharp local increase in temperature and pressure in the area of the laser spot. However, for the formation of many pairs of bulky nanostructures in a sheet material, such a high increase in these parameters is necessary that a laser operating in the normal mode cannot provide.

Disclosure of the image The invention is based on the task of creating a method for obtaining a latent image from many pairs of bulk nanostructures in a thin sheet material (films), equally suitable for obtaining protective images with several public features of both securities and identification documents.

The problem is solved in that in the method of creating a latent image in a thin sheet material from a multitude of pairs of bulk nanostructures for protection against counterfeiting of securities and identification documents by several public features, which consists in the action of laser radiation pulses on specified points on the surface of the sheet material from a metal layer between two layers of plastic located on a layer of microlenses in the form of glass beads deposited on a plastic substrate and partially immersed in a layer of lumi support, the creation by each pulse of laser radiation within the laser spot of intense evaporation of metal, the penetration of metal particles at a tremendous speed into the plastic above and below the layer of metal and shock, the increase in the recoil pressure from the evaporation of the metal, characterized in that the sheet is affected by pulses of laser radiation above the threshold power cause the creation in the sheet material within the laser spot of such a high pressure, under the action of which the component is displaced to the periphery of the laser spot separate light waves that act on the laser beam act on these microlenses by these waves, cause them to fuse with metal particles and phosphors, penetrate the plastic substrate on the back of the sheet material with these waves and form under the influence of tremendous recoil pressure from microlenses and high temperature in the metal adjacent to the layer plastic the point of a latent image of pairs of bulk nanostructures and ridges of nanowhiskers between them.

With this method of forming a latent image in the sheet material, by creating huge pressures and temperatures in the area of the laser spot, it is possible to obtain latent image points in thin sheet material (films) from pairs of bulk nanostructures and ridges of whiskers between them.

It is advisable that, from the combination of individual points, a hidden protective image is formed in the sheet material.

With this method of obtaining a latent image in the sheet material, conditions are provided for reliable protection of securities and identification documents from counterfeiting.

It is advisable that on the ridges of nanowhiskers of the latent image points cause white light dispersion during the rotation of the sheet material, they act on the pairs of volumetric nanostructures of the latent image points under the dispersed light, cause their visualization and form a colored iridescent image from the set of these pairs.

With this method of obtaining a latent image in the sheet material, reliable visualization of its points is ensured and a bright iridescent protective image is visible on the sheet material, which is visible in reflected light.

It is advisable that the luminescence of the latent image nanowhiskers is amplified by white light passing through the channels in the metal layer into the sheet material and reflected from glass microlenses fused with metal particles and phosphor.

With this method of obtaining a latent image in the sheet material, the luminescence of nanowhiskers is enhanced due to the effect of light reflected from microlenses on them, which helps to obtain a brighter protective image on the sheet material.

It is advisable that they create a black-and-white image from the channels formed in the plastic substrate by light waves of laser beams on the back side of the sheet material.

With this method of obtaining a protective image in a sheet material, its protection against falsification is enhanced, since different public protective images are created on its front and back sides.

It is advisable that inside the sheet material create an original color protective image of microlenses fused with particles of metal and phosphor, visible in transmitted light.

With this method of obtaining a protective image in the sheet material, its protection against falsification is enhanced, since it will be simultaneously protected by three public protective images: on the front, back of the sheet material and inside it.

Brief Description of the Drawings

The invention is further illustrated by the description of a specific, but not limiting embodiment of the present invention and the accompanying drawings, in which:

FIG. 1 illustrates the proposed method for creating a latent image in the body of thin sheet material from points of pairs of bulk nanostructures;

FIG. 2 shows the points of a latent image in the body of sheet material from pairs of bulk nanostructures and ridges of nanowhiskers between them;

FIG. 3 shows ridges of nanowhiskers between a pair of bulk nanostructures in the body of a sheet material;

FIG. 4 shows images created as a result of the implementation of the proposed method:

a) a colored iridescent image on the front side of a thin sheet material (film);

b) a black and white image on the back of a thin sheet material (film);

c) the original color image inside a thin sheet material (film).

The best embodiments of the invention

The proposed method for creating a latent image in a thin sheet material (film) from a variety of pairs of bulk nanostructures to protect against counterfeiting of securities and identification documents by several public features is as follows:

At specified points on the surface of the sheet material (1) from a metal layer (2) between two layers of plastic (3) and (4) located on a layer of microlenses (5) in the form of glass beads deposited on a plastic substrate (6) and partially immersed in the phosphor layer (7), is affected by pulses (8) of laser radiation above the threshold power.

Under the influence of these pulses (8), so great pressure arises in the sheet material (1) within the laser spot (9) that the light waves that make up the laser beam (10) are displaced to the periphery of the laser spot (9). These light waves (10) act on the microlens layer (5), cause their fusion within the laser spot with metal particles (2) and phosphor (7) and penetrate the plastic substrate (6) on the back of the sheet material (1). At the same time, they cause enormous recoil pressure from microlenses (5) and, under the influence of this pressure and huge temperature, form a point (11) of a latent image from a pair of bulk nanostructures (12) and ridges of nanowhiskers (13) between them in the plastic adjacent to the metal layer .

In fact, pairs of bulk nanostructures and ridges of nanowhiskers are formed as a result of high-speed crystallization of an alloy of metal, glass, phosphor and plastic at a temperature of 3000-4000 ° C and a pressure of 10,000 to 100,000 atm.

As a result of crystallization, an image is formed on the front surface of the sheet material from points that are a collection of crystals, and the nanowhisker ridges located between them represent the equivalent of diffraction gratings. Therefore, when the sheet material is rotated relative to the light source, it disperses on the ridge of nanowhiskers, as a result of which the dispersed white light colors the crystals of each image point in different colors, creating a colored iridescent image in the sheet material.

The brightness of the crystal image created in the sheet material is enhanced by the white color passing through the channels in the metal layer into the sheet material, reflected from the fused microlenses and focused on the corresponding image points on the nanowhiskers and crystals.

In addition to the colored iridescent image on the front surface of the sheet material, visible in reflected light and which is a clear public sign to establish its authenticity, the proposed method provides the creation of two more public security features - a black-and-white image from channels in a plastic substrate on the back of the sheet material visible in reflected light, and the original color image inside the sheet material of microlenses fused with particles of metal and phosphor and visible in transmitted light.

Industrial applicability

The proposed method for creating a hidden image in a thin sheet material from a multitude of pairs of bulk nanostructures visualized by white light dispersed opens up new possibilities for protecting securities and identification documents from counterfeiting.

Protective images created using this method are universal, because formed in thin films that are equally suitable for protecting securities as well as for protecting identification documents.

These security images have enhanced reliability for protection against fakes, as each of them is protected by three public features.

Claims (6)

1. A method for creating a latent image in a thin sheet material from a multitude of pairs of bulk nanostructures to protect against counterfeiting of securities and identification documents by several public features, which consists in applying laser radiation pulses to specified points on the surface of the sheet material from a metal layer between two layers of plastic located on a layer of microlenses in the form of glass beads deposited on a plastic substrate and partially immersed in a phosphor layer, each laser creating a pulse radiation within the laser spot of intense evaporation of metal, the penetration of metal particles at a tremendous speed into the plastic above and below the metal layer and the shock build-up of the recoil pressure from the metal evaporation, characterized in that the sheet material is subjected to an over threshold power with laser pulses, causing material within the laser spot of such a high pressure, under the action of which individual light waves constituting the laser beam are displaced to the periphery of the laser spot these waves act on the microlenses layer by these waves, cause them to fuse with the metal and phosphor particles, penetrate the plastic substrate on the back side of the sheet material with these waves and, under the influence of huge recoil pressure from microlenses and high temperature, form a latent image point in the plastic adjacent to the metal layer pairs of bulk nanostructures and ridges of nanowhiskers between them. 2. The method according to p. 1, characterized in that from the totality of the individual points form a hidden protective image in the sheet material. 3. The method according to p. 1, characterized in that on the ridges of the nanowhiskers of the latent image points cause white light dispersion during rotation of the sheet material, they act on the pairs of volume nanostructures of the latent image points under the dispersed light, cause their visualization and form a colorful iridescent from the set of these pairs picture. 4. The method according to p. 1, characterized in that the luminescence of nanowhiskers and pairs of volumetric nanostructures of a latent image is enhanced by white light transmitted through channels in the metal layer into the sheet material and reflected from glass microlenses fused with metal particles and phosphor. 5. The method according to p. 1, characterized in that they create on the reverse side of the sheet material a black and white image from the channels formed in the plastic substrate by light waves of laser beams. 6. The method according to p. 1, characterized in that inside the sheet material create an original color protective image of microlens fused with metal particles and a phosphor, visible in transmitted light.

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