EA028237B1 - Method for formation of concealed polarization images in a polymer layer, and device for implementation thereof - Google Patents

Abstract

The invention is related to the field of protection of documents and securities against forgery. The method for formation of concealed polarization images in a polymer layer comprises formation of an optically isotropic polymer layer on a substrate, creation of optically anisotropic areas containing concealed polarization images on said optically isotropic polymer layer by way of a thermomechanical impact thereon. In accordance with the invention, the thermomechanical impact on the optically isotropic polymer layer is provided by means of a metal rotational cliche heated to a temperature not exceeding the softening temperature of the optically isotropic polymer layer, projections of the cliche are brought into contact with said layer, the substrate with the optically isotropic polymer layer and the metal rotational cliche are moved in the same direction while providing conditions under which linear velocity of the substrate with the optically isotropic polymer layer is lower than linear velocity of the projections of the metal rotational cliche.

Description

The invention relates to the field of protection of documents and securities from counterfeiting, in particular to the field of manufacturing a polymer layer with latent polarizing images that are invisible in natural light under ordinary lighting and are visualized using circularly polarized light produced using a circular polaroid be used as protective marks on various documents, securities, banknotes, as well as in the production of excise stamps, identification marks, ethics labels, tags, and the like.

As a rule, latent polarization images are obtained in the volume of an optically isotropic polymer layer placed on a substrate in a roll by creating optically anisotropic sections in it. Currently, optically anisotropic sections are produced using printing processes from roll to roll technology, and parallel rows of said sections are formed along the entire length of the optically isotropic polymer layer. From one roll you can get from several thousand to millions of protective labels, i.e. parts of the polymer layer, including optically isotropic and optically anisotropic sections with latent polarization images that are transferred from the substrate to the protected object, since the area of one protective mark is 1-2 cm ² . The main requirement for optically anisotropic regions obtained in an optically isotropic polymer layer with hidden polarization images, determining and characterizing their quality, is the absence of visible contours or traces of a hidden polarization image during normal visualization in natural light and contrast visualization of hidden polarization images when using a circular polaroid.

A known method of obtaining an optical polarizing protective element with a hidden polarizing image, in which a reflective layer is applied to the substrate, is formed on at least one portion of the substrate coated with a reflective layer by direct printing using a colorless transparent liquid composition, a latent image. Further, optical anisotropy is obtained in the indicated section of the latent image layer. Then, a thin transparent protective layer is applied over the entire surface of this section, while the refractive index of the protective layer coincides with the refractive index of the portion of the latent image layer. [one]. According to this method, optical anisotropy in the aforementioned section can be obtained by various methods (by machining with felt, applying strokes using the plotter’s writing head, applying strokes using the thermal printer’s print head).

The main disadvantage of this method is that it does not provide the above basic requirements for the quality of the obtained latent polarization image, namely the absence of its visible contour during normal visualization. Failure to do so is due to the equidistant repeatability of the relief structure of optically anisotropic sections and adjacent portions of the reflecting layer with a thin transparent protective layer. The reflective layer is a flat surface on which letters, numbers, logos, ornaments, etc., which protrude above the surface of the reflective layer, are applied using a colorless transparent liquid composition. Subsequent application of a thin transparent protective layer repeats the resulting relief, and leads to a difference in thicknesses in the transition region of the reflecting layer - anisotropic section. In a certain perspective, due to diffraction phenomena, this difference, i.e. the contours of letters, numbers, logos, ornaments, etc., is visible in normal lighting.

In addition, the known method has low productivity, since obtaining a latent polarization image in the polymer layer occurs in three successive stages (forming a latent image, obtaining optical anisotropy in the area of the polymer layer with a hidden image and applying a protective layer).

The closest in technical essence to the claimed as an invention method is a method for obtaining latent polarization images in a polymer layer, described in [2]. According to this method, a thin layer of a polymer solution prepared in advance is applied to the substrate, this layer is dried, as a result of which an optically isotropic polymer layer is obtained. Then, by thermomechanical action of the working body, optically anisotropic sections are created in the obtained optically isotropic polymer layer. In an example of the implementation of this method, the working body is a metal needle heated to 100 ° C, with which microstrikes of 1-3 microns deep are applied to the polymer layer at a speed of 10-50 m / min at a temperature of 10-60% below the melting point or degradation of the polymer and time the contact of the working body with the polymer layer of 0.015-0.65 ms [2]. The known method has low productivity when used to obtain latent polarization images in the polymer layer, carrying constant information. Essentially, the known method is an analogue of digital printing with its inherent efficiency, but low productivity in print runs with constant information. The limiting stage in this method is the process of creating in the optically isotropic polymer layer sections with anisotropic properties by the thermomechanical action of the working body on the polymer layer by applying micro bars. Microstrikes are applied on thermal printers or thermoplotters, the speed of microstrikes is limited by the capabilities of the thermal heads of these devices, since

- 1 028237 increased speeds they overheat. In addition, the width of the polymer layer on which strokes can be applied using these devices is limited, which also leads to a decrease in productivity.

The objective of the invention is to provide a method for obtaining latent polarization images in a polymer layer, which would provide higher performance than obtaining the same images in a known manner. Another objective of the present invention is to provide a device for implementing this method.

To solve the problem in a method for producing latent polarization images in a polymer layer, comprising forming an optically isotropic polymer layer on a substrate, creating in the said optically isotropic polymer layer by thermomechanically acting on it optically anisotropic sections containing latent polarizing images, thermomechanical affecting the optically isotropic polymer the layer is rendered using a metal rotary cliche, which is heated to a temperature not increasing the softening temperature of the optically isotropic polymer layer, and the protrusions of which are brought into contact with this layer, move the substrate with the optically isotropic polymer layer and the metal rotary cliche in one direction, while creating conditions under which the linear speed of the substrate with the optically isotropic polymer layer is less than linear the speed of the protrusions of a metal rotary cliche.

An advantage is the method in which the linear velocity of the substrate with an optically isotropic polymer layer is 3-12% lower than the linear velocity of the protrusions of the metal rotary cliche.

To solve the problem, the device for implementing the method comprises three shafts mounted so that the first and second shafts form a first friction gear, and the second and third shafts form a second friction gear, while the third shaft is a metal rotary cliché that is equipped with a heating device . According to the invention, the first and second shafts, as well as the second and third shafts, are additionally connected to each other by the first and second kinematic gears, respectively, wherein the first kinematic gear has a gear ratio equal to the gear ratio of the first friction gear, and the second kinematic gear has a gear ratio smaller than the gear second gear ratio.

An advantage is the device in which the second kinematic gear is made with a gear ratio lower than the gear ratio of the second friction gear by 3-12%.

A device is also advantageous in which the protrusions of the metal rotary cliche are characters or spaces.

An advantage is also a device in which the first and second kinematic gears are made in the form of gears.

An advantage is also a device in which the metal rotary cliche is equipped with a thermoelectric heater located on its axis.

In the method and device according to the invention, a metal rotary cliche is used as the third shaft, which is an analogue of the metal rotary cliche used in printing for gravure printing, in particular in flexography, which is characterized by high productivity.

The increase in the productivity of obtaining latent polarization images in a polymer layer using the proposed method is due to the use of a metal rotary cliché with high print run resistance, the ability to work without overheating and, accordingly, for thermomechanically acting on an optically isotropic polymer layer to obtain optically anisotropic sections containing hidden polarization images not requiring periodic stops associated with overheating of metal Wow rotation cliche. In addition, the metal rotary cliche can be made of considerable length (the length can reach one meter or more), which allows to increase the width of the substrate with a polymer layer. All this leads to an increase in the productivity of the claimed method and device.

The method and apparatus according to the invention are illustrated by the accompanying drawings, in which in FIG. 1 schematically shows an example of the inventive device for obtaining a latent polarizing image in the polymer layer;

in FIG. 2 schematically shows the kinematic relationships of the elements of this device.

The device for implementing the method according to this example consists of three shafts (1, 2, 3), and shaft 3 is a metal rotary cliche. Shafts 1 and 2 form the first friction gear, and shafts 2 and 3 form the second friction gear. The shafts 1, 2 and 2, 3 are additionally connected by the first and second kinematic gears formed by gears 5, 6 and 7, 8, respectively, while the said kinematic gears are designed so that they do not interfere with the frictional contact of the shafts with each other. Shafts 1 and 2 are made of steel, they can have rubber, polyurethane, polyamide, polyimide, etc. on the periphery. coating. The shaft 3 (rotary cliche) is made of a metal alloy, in particular brass, has projections 4, which are elements of a latent image, such as characters or spaces. The first kinematic gear, made, for example, in the form of two gears 5 and 6, which provide a gear ratio equal to the gear ratio of the first friction gear formed by the shafts 1 and

2.

The second kinematic gear is made in the form of gears 7 and 8, has a gear ratio less than the gear ratio of the second friction gear formed by the shafts 2 and 3. This ratio of the gear ratios of the second kinematic gear and the second friction gear causes the linear velocity U _{1 of the} substrate with optically isotropic polymer layer is less than the linear velocity of ₂ protrusions of a metal rotary cliche. The shaft 3 is equipped with means 9 for forced heating, for example a thermoelectric heater (TEN) located on its axis. An optically isotropic polymer layer 11 is formed on the substrate 10. The technical result achieved by the invention is ensured by the fact that the thermomechanical action on the optically isotropic polymer layer is created using a metal rotary cliche and due to the fact that the shafts 1, 2, 3 are additionally that they form the first and second friction gears are associated with the first and second kinematic gears, respectively. In this case, the first kinematic gear has a gear ratio equal to the gear ratio of the first friction gear, and the second kinematic gear has a gear ratio less than the gear ratio of the second friction gear. The indicated mismatch between the gear ratios leads to a difference in the linear velocity V _{1 of the} substrate and the linear velocity V _{2 of the} protrusions of the metal rotary cliché, which creates a shift of the surface regions of the polymer layer during their contact and, ultimately, in the optically isotropic polymer layer in contact with The protrusions of the metal rotary cliche form optically anisotropic sections.

The method of creating optically anisotropic sections in the polymer layer is as follows.

Preliminarily, on a transparent substrate 10 in a roll made, for example, of polypropylene or polyethylene terephthalate, is applied by any known method, for example, using an anilox roll, a layer of a polymer solution in an organic solvent, the polymer being selected from the range including polycarbonate, polystyrene, nitrocellulose, fluoride varnish , with obtaining an optically isotropic polymer layer 11 with a thickness of 2-4 microns after evaporation of the organic solvent during the drying of the deposited polymer layer at elevated temperatures. The substrate 10 with an optically isotropic polymer layer 11 is tucked between the shafts 1, 2, 3 as shown in FIG. 1. The optically isotropic polymer layer 11 faces the protrusions 4 of the shaft 3. The shaft 3 is heated by a thermoelectric heater 9 to a temperature of 80-120 ° C depending on the material of the polymer layer 11. The shafts 1 and 3 are constantly pressed against the shaft 2, for example, by pneumatic cylinders and forced rotation, for example, by means of a shaft 2 connected to an external electric drive. In the contact between the shafts 1 and 2, both the substrate 10 and the polymer layer 11 have the same linear speed Y1, since the gear ratios of the first friction gear formed by shafts 1 and 2 and the first kinematic gear formed by gears 5-6 are equal.

The difference between the gear ratio of the second friction gear formed by the shafts 2 and 3 and the second kinematic gear formed by the gears 7 and 8 (the gear ratio of the second kinematic gear is 312% less than the gear ratio of the second friction gear), leads to the shaft protrusions 4 3 move with a linear velocity Y ₂ greater than the linear velocity Y _{1 of the} movement of the substrate 10, i.e. ahead of the substrate 10, shifting (dragging along) the surface zones of the optically isotropic polymer layer 11, which leads to the formation. The joint shift of the substrate 10 and the polymer layer 11 is excluded due to the retention of their first friction gear formed by the shafts 1 and 2.

A specific example of the method.

They took a substrate 10 of polyethylene terephthalate (PET) 16 μm thick in a roll of 1350 linear meters and 300 mm wide. A 12% solution of polycarbonate in methylene chloride was applied onto the substrate with an anilox roll, dried to obtain a layer 11 of an optically isotropic polycarbonate with a thickness of 4 μm.

The substrate 10 with an optically isotropic polymer layer 11 was tucked between the shafts 1, 2, 3 as shown in FIG. 1, the optically isotropic polymer layer 11 is facing the protrusions 4 of the shaft 3. The shaft 3 was heated by a heating element 9 to a temperature of 110 ° C (softening temperature of polycarbonate 130 ° C). The shafts and 3 were constantly pressed by pneumatic cylinders to the shaft 2 and forced into rotation by the shaft from the electric drive with a linear speed of the shaft periphery of 10 m / min. In the contact between the shafts 1 and 2, both the substrate 10 and the polymer layer 11 have the same linear speeds, since the gear ratio of the first friction gear formed by the shafts 1 and 2 is equal to the gear ratio of the first kinematic gear made on the gears 5 and 6.

Due to the difference between the gear ratios of the second friction gear formed by the shafts 2 and 3 and the second kinematic gear formed by the gears 7 and 8 (these gears were made so that the gear ratio of the second kinematic gear is less than the gear ratio of the second friction gear by 8%), the protrusions 4 of the shaft 3 moved with a linear velocity Y ₂ greater than the linear velocity VI of the substrate movement, also by 8%, i.e. ahead of the substrate 10, dragging along the surface zones of the optically isotropic polymer layer 11 and thereby forming optically anisotropic regions with a hidden polarization image.

This method and device ensures the fulfillment of the basic requirements for optically anisotropic regions with latent polarization images obtained in an optically isotropic polymer layer, which determines and characterizes their quality, i.e. the absence of visible contours or traces of a hidden polarization image during normal visualization in natural light and contrast visualization of hidden polarization images when using a circular polaroid over the entire length and width of the roll. Almost 100% yield of protective labels is also provided. Performance exceeds 2-8 times the performance that is achieved in the prototype.

Claims (7)

CLAIM 1. A method of obtaining hidden polarization images in a polymer layer, including the formation on the substrate of an optically isotropic polymer layer, creating on said optically isotropic polymer layer by thermomechanical exposure to it optically anisotropic sections containing hidden polarization images, characterized in that the thermomechanical effect on the optically isotropic the polymer layer is rendered using a metal rotary cliche, which is heated to a temperature not exceeding The softening temperature of the optically isotropic polymer layer, and the protrusions of which come into contact with this layer, moves the substrate with the optically isotropic polymer layer and the metal rotary cliche performs such a movement that the linear velocity of the substrate with the optically isotropic polymer layer is less than the linear velocity of the metal rotary cliche in the area of contact with him. 2. The method according to claim 1, characterized in that the linear velocity of the substrate with an optically isotropic polymer layer is less than the linear velocity of the protrusions of the metal rotation plate by 3-12%. 3. A device for implementing the method according to claim 1, comprising three shafts installed so that the first and second shafts form the first friction gear, and the second and third shafts form the second friction gear, while the third shaft is a metal rotary cliché, which is equipped the heating device, the first and second shafts, and the second and third shafts are additionally interconnected by the first and second kinematic transmission, respectively, with the first kinematic transmission having a gear ratio equal to datochnomu against the first friction gear and the second kinematic transmission has a gear ratio smaller than the gear ratio of the second friction gear. 4. The device according to claim 3, characterized in that the gear ratio of the second kinematic transmission is less than the gear ratio of the second friction transmission by 3-12%. 5. The device according to claim 3, characterized in that the protrusions of the metal rotary cliche are characters or spaces. 6. The device according to claim 3, characterized in that the first and second kinematic transmissions are made in the form of gears. 7. The device according to claim 3, characterized in that the metal rotary cliche is equipped with a thermoelectric heater located on its axis.