EA034165B1 - Method of manufacturing base holographic foil for hot pressing - Google Patents

Abstract

The invention relates to means of protection of securities and documents against counterfeit, in particular to a method of manufacturing a base holographic foil for hot pressing that comprises a polymer multilayer film with hidden polarization images being visualized via an identifier comprising a polaroid film and that is useful to hot press thereon holographic images retaining properties of said hidden polarization images. The base holographic foil manufactured by the claimed method comprises functional layers including a polymer oriented anisotropic layer comprising hidden polarization images being visualized via an identifier comprising a polaroid film and a layer for holographic pressing disposed thereon on which a reflecting layer is evaporated. In the based holographic foil manufactured by this method, the hidden polarization images do not disappear when hot pressing of holographic image is performed thereon and are not visualized without using the identifier comprising a polaroid film.

Description

The invention relates to means for protecting securities and documents from counterfeiting, in particular, to a method for manufacturing a base holographic foil that contains a polymeric multilayer film with latent polarizing images visualized using an identifier containing a polaroid film (hereinafter polarizer), and which is suitable for hot stamping on it holographic images without losing the properties of said latent polarizing images.

A known method of manufacturing a holographic foil for hot stamping, in which the basis is taken polyethylene terephthalate film coated on the basis of a thermoplastic binder and pigment [1]. A method of manufacturing this holographic foil does not include the inclusion in its structure of layers containing latent polarization images. If the method of manufacturing a basic holographic foil for hot stamping involves the formation of anisotropic zones by known methods of thermomechanical action on an isotropic polymer material and obtain latent polarization images in them [2], then subsequent hot stamping on such foil of holographic images will lead to a loss of the properties of latent polarization images ( they will disappear). Therefore, the known method for manufacturing a foil for hot stamping of holographic images cannot include operations associated with the formation of a layer with a hidden polarizing image in said foil, i.e. this method cannot be used for the manufacture of a base foil containing latent polarization images and suitable for subsequent embossing of holographic images in it without loss of properties of the said latent polarization images.

The closest analogue of the proposed method is a method of manufacturing a holographic foil for hot stamping, in which they take a polyester film-base, on which a separation layer, a protective lacquer layer, an additional special layer, metal and adhesive layers are successively applied [3]. As a special layer in the manufacture of the known holographic foil for hot stamping, a polymer layer is laid for embossing holographic images.

The disadvantage of this method of manufacturing a holographic foil for hot stamping is that, as in the previous analogue, it cannot include operations associated with the formation of a layer with latent polarization images in the said foil for the reasons stated above.

The objective of the invention is to develop a method of manufacturing a basic holographic foil for hot stamping, which contains a polymer layer with pre-formed latent polarizing images in it, in which subsequent embossing of holographic images does not lead to loss of contrast of polarized polarized images when they are visualized using a polarizer or visualization of these images without using the mentioned polarizer.

Thus, the base holographic foil obtained by the claimed method must satisfy the following requirements:

latent images should not disappear upon thermomechanical action on the base holographic foil upon receipt of holographic images on it;

latent images should be masked as much as possible and not visualized without the use of a polarizer.

The problem is solved by the claimed method of manufacturing a base holographic foil, comprising the following steps:

take the polymer film base and set it with the possibility of longitudinal movement;

moving the polymer base film and applying a separation layer composition to one of its sides, then drying it, and producing a separation layer on the polymer film base;

the polymer composition of the protective varnish layer is applied to the separation layer, then it is dried and a polymer protective varnish layer is obtained on the separation layer;

the polymer composition of the orienting layer is applied to the polymer protective varnish layer, then it is dried and a polymer orienting layer is obtained on the polymer protective varnish layer;

carry out rotational embossing of the polymer orienting layer and obtain a diffractive structure on it;

a polymer anisotropic composition is applied to the polymer orienting layer, it is dried and a polymer anisotropic layer is obtained, then the resulting polymer anisotropic layer is heated to the temperature necessary for its orientation, and a polymer oriented anisotropic layer is obtained on the polymer orienting layer;

UV polymerization of the polymer oriented anisotropic layer; after UV polymerization of a polymer oriented anisotropic layer, it is able to withstand thermomechanical effects during subsequent embossing of a holographic image without loss of function

- 1,034165 national properties, an irreversible polymer structure is formed, which can be destroyed only by destruction;

the polymer composition of the holographic stamping layer is applied to the polymer oriented anisotropic layer, drying is performed and a polymer layer for holographic stamping of such a thickness that provides an optical path length of 1.9-3.2 μm is obtained on the polymer oriented anisotropic layer.

The need to obtain the thickness of the polymer special layer for holographic embossing within the specified limits when converting it to the optical path length is explained as follows. The oriented anisotropic polymer layer receives the corresponding azimuthal direction due to the diffraction structure of the orienting layer. The parameters of the diffraction structure of the orienting layer are such that visible radiation diffracts onto them with decomposition into spectral components. This leads to the unmasking of latent polarization images that are formed in the polymer oriented anisotropic layer, when the spectral component of the visible radiation is reflected from the first boundary, namely between the polymer orienting layer and the polymer oriented anisotropic layer. The reflection of the spectral component can be excluded if the refractive indices of the polymer oriented and oriented anisotropic layers are equal. However, this is impossible, since the polymer oriented anisotropic layer in its physical essence is a birefringent structure that has two refractive indices: ordinary n ,, and extraordinary n _e . One of these refractive indices, namely the ordinary n ,,. almost equal to the refractive index of the polymer orienting layer. In this case, the diffraction effects will be leveled. The unusual refractive index n _e in this case will not be equal to the refractive index of the polymer orienting layer, and the diffraction effects associated with this refractive index cannot be eliminated, which will lead to undesirable visualization of the latent polarization image without using a polarizer.

This drawback can be eliminated if a periodic dependence of diffraction efficiency on the optical path length of the polymer layer for holographic stamping is used with local minima and maxima, i.e. using reflection at the second boundary, namely between the polymer layer for holographic stamping and the reflective layer. To do this, choose the optical path length of the polymer layer for holographic stamping, and, accordingly, its thickness in the region where the minimum diffraction efficiency is located. Since the dependence of diffraction efficiency on the optical path length of the polymer layer for holographic stamping is periodic, the second condition for eliminating the undesirable visualization of the latent polarization image without using a polarizer is to create such a thickness of the polymer layer for holographic stamping, in which a reflective wave is created at the second reflecting boundary, which is located in antiphase with the wave, which is formed by the second refractive index of the polymer oriented anisotropic layer on the first reflective boundary (between the polymer and the polymer alignment layer oriented anisotropic layer). In the inventive method, a layer for holographic embossing is obtained of such a thickness that provides an optical length in the range of 1.9-3.2 μm.

In other words, radiation is generated at the second reflecting boundary due to the optimal thickness of the polymer layer for holographic embossing, which is in antiphase with the unmasking radiation at the first reflecting boundary and thereby eliminates it. Of course, we are talking about a specific spectral component.

A reflective layer is sprayed onto the polymer layer for holographic embossing.

An advantage is the method in which the polymer protective varnish layer is made of polycarbonate. Polycarbonate among polymers is highly resistant to mechanical and chemical influences, which is important for hot stamping foils. A method also has an advantage in which the thickness of the polymer oriented anisotropic layer is set so as to provide an optical path difference between the ordinary and extraordinary rays equal to a quarter of their wavelength. This thickness of the polymer oriented anisotropic layer provides the most contrast visualization of latent polarization images.

An advantage is the method in which the reflective layer is made of metals (aluminum, copper, chromium, etc.) or substances with a refractive index of more than two units, such as zinc sulfide, titanium oxide, etc.

The proposed method is illustrated in the drawing, which schematically shows in section a basic holographic foil obtained as a result of the implementation of this method.

In the drawing, there are the following notation:

- polymer film base;

- separation layer;

- polymer protective varnish layer;

- polymer orienting layer;

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- diffraction structure;

- polymer oriented anisotropic layer;

- a polymer layer for holographic stamping;

- reflective layer.

The inventive method is illustrated by the following examples.

Example 1. The manufacture of the base holographic foil, which was used as a hot stamping foil.

A roll of a polymer film-base 1, the material of which is polyethylene terephthalate with a thickness of 19 μm, was installed on the coating unit and the movement was set at a speed of 20 m / min. An anilox roll applied to one side of the composition of the separation layer, dried by removing the solvent, and received the separation layer 2, consisting of wax. A polymer composition of a protective lacquer layer was applied to the separation layer 2 at the same installation by anilox roll, dried by removing the solvent, and a polymer protective lacquer layer 3 consisting of polycarbonate was obtained. A polymer composition of the orienting layer was applied to the polymer protective varnish layer 3 on the same installation with an anilox roll, dried by removing the solvent, and a polymer orientating layer 4 was obtained, the main components of which are polymethyl methacrylate and nitrocellulose.

The refractive index of the polymer orienting layer 4 is = 1.505. Then, on the installation for holographic embossing with a nickel matrix at a speed of 20 m / min, the polymer orienting layer 4 was embossed and a diffraction structure 5 was obtained on it.

On a flexographic printing machine, a layer of a polymer anisotropic composition was applied to the polymer orienting layer 4 with an anilox roll, then it was dried and a polymer anisotropic layer 6 of 650 nm thickness was obtained on a polymer orienting layer 4, which provided a difference in the path of the extraordinary and ordinary rays equal to a quarter of their wavelength (AL = 130 nm). A certain thickness of the polymer anisotropic layer (in this case, 650 nm) was obtained by choosing the parameters of the anilox roll taking into account the properties of the polymer anisotropic composition and the application conditions. The polymer anisotropic layer was heated to a temperature of 48 ° C, depending on the direction of strokes of the diffraction structure 5, the polymer anisotropic layer received a spatial orientation and a polymer oriented anisotropic layer 6 was formed. A composition based on acrylate liquid crystal monomers was used as the polymer anisotropic composition. The refractive indices of the polymer oriented anisotropic layer 6 are equal to Io = 1.5, c = 1.69, respectively, for ordinary and extraordinary rays.

The UV polymerization of a continuous polymer oriented anisotropic layer 6 was performed using a UV polymerization apparatus for a flexographic printing press with a specific power of 100 W / cm ² .

Next, a polymer composition of the holographic stamping layer was applied to a continuous polymer oriented anisotropic layer 6, and after drying, a polymer layer for holographic stamping 7, which consisted of polycarbonate, was obtained. The physical thickness of the polycarbonate layer was 1.6 μm. The refractive index of polycarbonate is equal to _pc = 1.59. Therefore, the optical path length was 2.54 μm.

In the installation for vacuum deposition, a reflective layer 3 of aluminum with a thickness of 60 nm was applied to the polymer layer for holographic embossing 7.

Example 2. Obtaining a basic holographic foil, which was used for the manufacture of self-destructive, self-adhesive stickers.

The only difference between the method of obtaining this base foil is that the polymer base film, for example, of polyethylene terephthalate was taken with a thickness of 50 μm.

The use of basic holographic foil obtained by the proposed method, then occurred according to conventional technology. The original topographic images were embossed on the base holographic foil, the corresponding adhesive was applied, given a certain shape and size, and a holographic security mark was obtained and transferred to the product to be protected. When embossing original holographic images by thermomechanical impact on the polymer layer for topographic stamping and, therefore, on the remaining layers, latent polarization images that were formed due to the polymer oriented anisotropic layer were not subjected to changes that would lead to a loss of contrast when visualized by their polarizer. In addition, the unwanted visualization of the diffraction structure of the polymer orienting layer involved in the formation of latent polarization images was eliminated in two ways. First, the diffraction efficiency due to the ordinary refractive index of the oriented anisotropic polymer layer was quenched due to its equality with the refractive index of the orienting layer. Secondly, the diffraction efficiency due to the extraordinary refractive index was quenched by obtaining the thickness of the polymer layer for holographic embossing in the above range. Thus, from the above examples, it is obvious that the claimed technical result in the implementation of the invention is achieved.

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Sources of information.

1. RU 2340461, 2005.12.10.

2. EA 0014380, 2010.10.29.

3. http: // book. calculate.ru/book/otdelka_tari_i_produkcii_drugih_vidov_posle_pechati/ so stav_folj gi_dlya_ goryachego_tisneniya /, 2000-2018 CALCULATE.

Claims (4)

CLAIM 1. A method of manufacturing a base holographic foil for hot stamping, comprising the following steps: take the polymer film base and set it with the possibility of longitudinal movement; moving the polymer base film and applying a separation layer composition to one of its sides, then drying it, and producing a separation layer on the polymer film base; the polymer composition of the protective varnish layer is applied to the separation layer, then it is dried and a polymer protective varnish layer is obtained on the separation layer; the polymer composition of the orienting layer is applied to the polymer protective varnish layer, then it is dried and a polymer orienting layer is obtained on the polymer protective varnish layer; carry out rotational embossing of the polymer orienting layer and obtain a diffractive structure on it; a polymer anisotropic composition is applied to the polymer orienting layer, it is dried and a polymer anisotropic layer is obtained, then the resulting polymer anisotropic layer is heated to the temperature necessary for its orientation, and a polymer oriented anisotropic layer is obtained on the polymer orienting layer; UV polymerization of the polymer oriented anisotropic layer; the polymer composition of the holographic stamping layer is applied to the polymer oriented anisotropic layer, it is dried and a polymer layer for holographic stamping of such a thickness that provides an optical path length of 1.9-3.2 μm is obtained on the polymer oriented anisotropic layer; a reflective layer is sprayed onto the polymer layer for holographic embossing. 2. The method according to claim 1, characterized in that the polymer protective varnish layer is made of polycarbonate. 3. The method according to claim 1, characterized in that the polymer oriented anisotropic layer is obtained of such a thickness that provides an optical difference in the path of ordinary and extraordinary rays equal to a quarter of their wavelength. 4. The method according to claim 1, characterized in that the reflective layer is made of metals, in particular aluminum, copper or chromium, or substances with a refractive index of more than two units, in particular zinc sulfide, titanium oxide or zirconium oxide.