RU2724562C1 - Method of making paper with transparent areas and paper with transparent sections, made using this method - Google Patents

Abstract

FIELD: pulp and paper industry.SUBSTANCE: invention relates to pulp and paper industry, in particular, to production of paper for making banknotes and other valuable documents, which require high protection against falsification. Disclosed is a method of making paper with transparent sections, which includes obtaining a paper base, forming an opaque region which increases contrast of the transparent portion, and applying a composition to increase transparency in the region of the transparent portion. According to the invention, an opaque region is formed by applying on the paper base at least two overlayer layers arranged one above the other on one or two sides of the paper base, note here that lower cover layer is colored by dark dye so that paper whiteness, measured on lower cover layer, is not more than 2 % less than paper whiteness measured on top cover layer.EFFECT: high opacity of the paper on the entire area of the printed article, with the exception of the transparent section, while maintaining high whiteness, good physical and mechanical properties and the ability of the paper to receive printing inks when sealing is subsequently printing.7 cl

Description

The invention relates to the pulp and paper industry, in particular, to the production of paper for the manufacture of banknotes and other valuable documents requiring increased protection against falsification.

A known method (US 3140959 A, 07/14/1964) for the manufacture of watermarked paper, in which sections of paper corresponding to the watermark pattern are impregnated with a solution of a thermosetting resin in an organic solvent in the presence of a curing agent. After evaporation of the solvent and curing of the thermosetting resin on the paper, transparent areas are formed that simulate a watermark.

A known method (RU 2568398 C1, 11/20/2015) of making paper with transparent areas, in which areas of paper are locally impregnated with a solution of glycidyl ethers of mono- and polyhydric alcohols in an organic solvent in the presence of a curing agent. After evaporation of the solvent and curing of these compounds, transparent areas of a certain shape are formed on paper.

A known method (RU 2639809 C1, 12/22/2017) of making paper with transparent areas, in which an aluminosilicate pigment with an average particle size of not more than 7 μm is used as a filler in the paper composition, and the fiber suspension is dyed with a dark dye to obtain the color coordinate L * of the paper not less than 90. The disadvantage of this technical solution is that the average particle size of the aluminosilicate pigment used in accordance with this method significantly exceeds the average particle size of titanium dioxide (about 0.3-0.5 microns), therefore, the introduction of aluminosilicate pigment into the paper contributes to a noticeable deterioration of its physical and mechanical properties.

Closest to the claimed technical solution is a method (RU 2530419 C2, 11/20/2013) for manufacturing a security element, in which to increase the contrast of the transparent area an opaque region is formed around it using printing inks with an optically variable effect, metallized or liquid crystal inks. The disadvantage of this technical solution is that the area of the opaque region formed on paper is limited by the design and size of the security element. In addition, the specified technical solution does not provide for the subsequent sealing of the above opaque area using all the main printing methods.

The problem solved by the invention is to increase the opacity of the paper over the entire area of the printed product with the exception of the transparent section while maintaining good physical and mechanical properties and the ability of the paper to accept printing inks during subsequent sealing.

This is achieved by the fact that the proposed method of manufacturing paper with transparent areas, including obtaining a paper base, forming an opaque region that increases the contrast of the transparent region, and applying a composition to the region of the transparent region to increase transparency, wherein the opaque region is formed by applying at least at least two coating layers arranged one above the other, on one or two sides of the paper base, the lower coating layer being colored with a dark dye so that the whiteness of the paper measured from the lower covering layer is no more than 2% less than the whiteness of the paper measured on the top cover layer.

Mostly, the paper base contains not more than 6% by weight of absolutely dry filler fiber or a mixture of fillers selected from the group: aluminosilicate pigments, silicate pigments, kaolin, talc, chalk, gypsum, barium sulfate.

Preferably, the coating layers contain titanium dioxide.

Advantageously, the coating layers are printed onto the paper using a two-component coating white ink with the addition of a hardener.

Mostly, the area of the opaque region corresponds to the area of the printed product minus the area of the transparent portion.

Advantageously, the opaque region has the ability to perceive printing inks during subsequent printing of paper by offset, type-offset, high, screen or metallographic printing methods.

A paper with transparent sections of a given shape made by the claimed method is proposed.

It is known that banknote paper (hereinafter - paper) contains anatase and / or rutile titanium dioxide as a filler. The use of titanium dioxide as a filler provides the paper with good physical and mechanical properties, high opacity (at least 90%), low luminescence under UV radiation and some other characteristics. However, the presence of titanium dioxide in paper makes it difficult to obtain transparent areas on it by applying the so-called compositions to increase transparency, which are usually used known from the field of technology compositions for simulating watermarks. Therefore, in the inventive method, it is preferable not to use titanium dioxide as a filler for paper, or to use in an amount not exceeding 0.5% by weight of absolutely dry fiber.

As other fillers in the present method, pigments with a refractive index of less than 2 are used, which are selected from the group: aluminosilicate pigments, kaolin, talc, chalk, gypsum, barium sulfate. The content of these fillers in the paper can vary in the range from 0 to 6%, calculated on the weight of absolutely dry fiber. If their content in paper exceeds 6%, then there is a noticeable deterioration in the physical and mechanical characteristics of the paper (tearing resistance according to Elmendorf, fracture strength at repeated bends).

Covering white inks (hereinafter referred to as inks) are widely used in printing. The main component of paints is also titanium dioxide. For example, they are used for printing on transparent polymer films in order to obtain white opaque substrates susceptible to subsequent color printing. Such properties are, for example, casings for food products, etc. Typically, these inks are applied to the substrate by offset, flexographic or intaglio printing methods.

In the claimed method, water-based or alcohol-based inks are used, cured by heating or UV radiation, which are applied to paper by flexographic or intaglio printing methods. Most preferably, these paints are a two-component system, consisting of the actual paint and hardener for the paint (hereinafter - two-component paints). For example, two-component paints manufactured by Janecke + Schneemann Druckfarben Gmbh can be used. If the properties coincide, you can apply paints from other manufacturers. A prerequisite for choosing paints is the production of white opaque coatings on paper, capable of accepting subsequent printing and resistant to hot alkaline aqueous solutions.

Using these inks, coating layers are applied to the paper from one or two sides. Moreover, the total number of coating layers on each side of the paper is determined by the required opacity and other characteristics.

One of the lower cover layers, at least on one side of the paper, is dyed with a dark dye so that the whiteness of the paper measured on this cover layer is no more than 2% less than the whiteness of the paper measured on the upper unpainted cover layer. Compliance with this condition can significantly increase the opacity of the paper while maintaining high whiteness, without resorting to applying additional coating layers, which is not economically feasible.

In one embodiment, a colored coating layer is formed directly on the surface of the paper, and at least one, unpainted coating layer is applied on top of it. The total number of unpainted coating layers applied over the painted coating layer may be no more than two.

In another embodiment, a colored coating layer is formed on paper between two unpainted coating layers. In this case, it is preferable that one unpainted coating layer is disposed on and under the colored coating layer. In the particular case above the painted cover layer there can be no more than two unpainted cover layers.

The term "dark dye" refers to gray or black dyes, as well as mixtures of colored dyes that give a gray color when mixed. Such mixtures can be prepared, for example, by combining among themselves dyes of additional colors: yellow and purple, orange and blue, turquoise and red, and others. Depending on the composition of the paint (water or alcohol based), the dyes must first be dissolved in an appropriate solvent and the resulting solution added to the paint. In the particular case, the dyes are dispersed and added to the paint, for example, in the form of an aqueous dispersion.

As a dye in the claimed method use nigrosin in water or alcohol-soluble form. It is added to the paint in the form of a solution, respectively, in water or alcohol and mixed. If the properties coincide, you can use other dyes. Moreover, in each case, the amount of dye added to the paint depends on the required opacity of the paper and other characteristics. For nigrosine, the maximum amount of dye added should not exceed 0.003% in May. in terms of the weight of the paint.

The coating layers applied on one or two sides should form an opaque area on paper, the area of which corresponds to the area of the printed product minus the area of transparent sections located on this printed product. This allows you to provide the required opacity and other characteristics that are not achievable on paper that does not contain titanium dioxide. In addition, the resulting opaque region should well accept printing inks when subsequently printing paper with offset, type-offset, high, screen or metallographic printing methods.

The inventive method is as follows.

The fibrous raw material, which consists mainly of cotton fibers, is milled, and paper pulp is prepared. Dyes (direct or acidic), additives to increase the strength of the paper in the dry and wet state (sodium salt of carboxymethyl cellulose, sodium alginate, starch, polyamide (amine) epichlorohydrin resin) and, if necessary, substances for internal paper sizing (dimers) are introduced into the prepared paper pulp alkyl ketene). Fillers selected from the following group are introduced into the prepared paper pulp: aluminosilicate pigments, silicate pigments, kaolin, talc, chalk, gypsum, barium sulfate.

As aluminosilicate pigments in the method of the invention, commercial products of the SIPERNAT trademark manufactured by Evonik Resource Efficiency GmbH or commercial products of other manufacturers with similar properties are used. In addition, not more than 0.5% titanium dioxide by weight of absolutely dry fiber is used as a filler in paper. Moreover, it is most preferable that titanium dioxide be used in paper in a mixture with another filler or with several other fillers. So in the method of the invention it is possible to use a mixture of fillers, consisting of: chalk and titanium dioxide; kaolin and titanium dioxide; aluminosilicate pimento and titanium dioxide; talc and titanium dioxide; chalk, aluminosilicate pigment and titanium dioxide; chalk, kaolin and titanium dioxide, etc. (in all cases, it is preferable to use chemically precipitated chalk).

Paper is made on a round-mesh or flat-mesh paper machine. In the manufacturing process, the pre-dried paper web is treated in a size press or impregnation bath with a surface sizing composition containing polyvinyl alcohol and other necessary additives (plasticizers, defoamers, biocidal additives).

In the next step, coating layers forming an opaque region are applied on paper from one or two sides by flexographic printing. At the same time, areas intended for subsequent obtaining of transparent areas are left unsealed on paper. Then, formulations are applied to these unsealed areas to increase transparency, for which watermarking compositions can be used, which are described in detail in the following documents: US 3085898 (04.16.1963), US 3288628 (11.29.1966), US 3985927 (12.10.1976 ), GB 1489084 (10.19.1977), US 4919044 (04.24.1990), US 5118526 (02.07.1992), US 2014/0178589 (06.26.2014). In a particular case, the invention uses compositions developed by the applicant based on glycidyl ethers of mono- and polyhydric alcohols, applied to paper by flexographic printing method and described in detail in document RU 2568398, 11/20/2015.

After that, on paper with transparent areas and an opaque region, printing is performed by offset, metallographic, high or screen printing methods. In addition, it is possible to first seal the paper with the above printing methods, and then apply a composition to the paper to increase transparency.

Further, the claimed method is explained in detail in the following examples.

Example 1

Banknote paper weighing 90 g / m ^{2 was} produced on a round-mesh paper machine using the known technology and using known materials, with the difference that in the manufacture of paper chemically precipitated chalk was used as a filler in an amount of 4% wt. by weight of absolutely dry fiber. In the manufacturing process, the paper web was treated in an impregnation bath with a surface sizing composition containing 4% polyvinyl alcohol solution. After manufacture, the opacity (ISO 2471) and whiteness (ISO 2470) of the paper were determined.

Example 2

As in example 1, only instead of chemically precipitated chalk, SIPERNAT 350 aluminosilicate pigment was used as a filler for paper in an amount of 2% of the weight of absolutely dry fiber.

Example 3

As in example 1, only instead of chemically precipitated chalk, kaolin was used as a filler for paper in an amount of 3% by weight of absolutely dry fiber.

Example 4

On a paper made in accordance with Examples 1-3, one coating layer weighing 5-7 g / m ^{2 was} applied on each side by flexographic printing method using a white two-component ink-based ink with hardener (FL-2 Pack White high Opaque Gr 7/2 article 366665-14401, Janecke + Schneemann Druckfarben Gmbh). When applying paper on one side, nigrosine was preliminarily added to the ink, changing its ratio in terms of ink weight from 0.001% to 0.005%. On paper, they provided for the presence of local zones without coating layers intended for the subsequent production of transparent areas. After curing, paints were applied to the paper on each side with one more coating layer weighing 5-7 g / m ² using the same paint, but without the addition of nigrosin. After the curing of the ink, the opacity and whiteness of the paper were determined in the areas of applying the coating layers.

Example 5

On a paper made in accordance with Examples 1-3, one coating layer weighing 5-7 g / m ^{2 was} applied on each side by flexographic printing method using a white two-component alcohol-based ink with hardener (FL-2 Pack White high Opaque Gr 7/2 article 366665-14401, Janecke + Schneemann Druckfarben Gmbh). When applying on both sides of the paper, nigrosine was preliminarily added to the ink, changing its ratio in terms of ink weight from 0.001% to 0.005%. On paper, they provided for the presence of local zones without coating layers intended for the subsequent production of transparent areas. After curing, paints were applied to the paper on each side with one more coating layer weighing 5-7 g / m ² using the same paint, but without the addition of nigrosin. After the curing of the ink, the opacity and whiteness of the paper were determined in the areas of applying the coating layers.

Example 6

On a paper made in accordance with Examples 1-3, three coating layers weighing 5-7 g / m ² each were applied on each side by flexographic printing method using a white two-component alcohol-based ink with hardener (FL-2 Pack White high Opaque Gr. 7/2 article 366665-14401, Janecke + Schneemann Druckfarben Gmbh). On one side of the paper, nigrosine was added to the intermediate coating layer located between the lower and upper coating layers, changing its ratio in terms of ink weight from 0.001% to 0.005%. On paper, they provided for the presence of local zones without coating layers intended for the subsequent production of transparent areas. After the curing of the ink, the opacity and whiteness of the paper were determined in the areas of applying the coating layers.

Example 7

On a paper made in accordance with Examples 1-3, three coating layers weighing 5-7 g / m ² each were applied on each side by flexographic printing method using a white two-component alcohol-based ink with hardener (FL-2 Pack White high Opaque Gr. 7/2 article 366665-14401, Janecke + Schneemann Druckfarben Gmbh). On both sides of the paper, nigrosine was added to the intermediate coating layers located between the lower and upper coating layers, changing its ratio in terms of ink weight from 0.001% to 0.005%. On paper, they provided for the presence of local zones without coating layers intended for the subsequent production of transparent areas. After the curing of the ink, the opacity and whiteness of the paper were determined in the areas of applying the coating layers.

Example 8

As in example 7, only for applying on paper used a white two-component water-based ink with a hardener (FL-White Gr.22 article 357160-64701, Janecke + Schneemann Druckfarben Gmbh).

Example 9

All paper samples made in accordance with examples 2-8 were sealed according to the full production cycle of a printing product (banknote) by standard offset, metallographic and high printing methods. Printing was carried out on an opaque region formed on paper. Then, seven days after sealing, the resulting prints were tested for washing resistance in hot solutions of soap and detergent.

Example 10

All paper samples made in accordance with Examples 2-8 were coated with a rubber stamp in an amount of 18 g / m ² to 20 g / m ^{2 a} composition for increasing transparency, consisting of a solution of melamine-formaldehyde resin in dimethylformamide. The composition was cured for 1 minute at 120 ° C, and then three days at a temperature of 20-22 ° C. After curing the composition, the opacity of the paper in the areas of application of the composition was determined.

Example 11

As in example 10, only for applying to paper used a solution of epoxy resin in ethylene glycol monoethyl ether in the presence of a hardener. After the composition was cured, the opacity of the paper was determined in the areas where the composition was applied.

Example 12

As in Example 10, a solution of triglycidyl ether of polyoxypropylene triol in ethyl acetate in the presence of a hardener was used only for printing on paper. After the composition was cured, the opacity of the paper was determined in the areas where the composition was applied.

Explanation of examples

In examples 2-8, the opacity of the paper was controlled by changing the ratio of nigrosin in the lower painted coating layers located under the upper unpainted layers, as well as the total number of coating layers applied to the paper. In this case, depending on the dosage of nigrosin in the stained coating layers, the opacity of the paper in the area of opaque areas varied in the range from 92% to 95%, and the whiteness in the range from 86% to 82% (initial optical characteristics of the paper: opacity - from 81% to 83%, whiteness - from 84% to 85%). When choosing a dosage of nigrosin, the best result from the point of view of balance of opacity and whiteness of the paper was obtained if the whiteness of the paper, measured by the lower painted cover layer, was no more than 2% less than the whiteness of the paper, measured by the upper unpainted cover layer. This result was achieved when the ratio of nigrosine in terms of the weight of the paint is not more than 0.003%.

All paper samples showed good printing properties when sealing, and the resulting prints showed good resistance to the effects of hot solutions of soap and washing powder (example 9). In addition, all paper samples showed high transparency in the area of transparent areas after applying compositions to increase transparency on paper (examples 10-12). Moreover, the maximum difference in opacity between the opaque region and the transparent areas on paper in this case amounted to more than 50%.

Thus, the inventive method allows to increase the opacity of the paper over the entire area of the printed product, with the exception of the transparent section, while maintaining high whiteness, good physical and mechanical properties and the ability of the paper to accept printing inks during subsequent printing.

Claims (7)

1. A method of manufacturing paper with transparent sections, including obtaining a paper base, forming an opaque region that increases the contrast of the transparent region, and applying a composition to increase the transparency in the region of the transparent region, wherein the opaque region is formed by applying at least two on top of the paper substrate on the other side of the coating layers, on one or two sides of the paper base, the lower coating layer being painted with a dark dye so that the whiteness of the paper measured on the lower coating layer is no more than 2% less than the whiteness of the paper measured on the upper coating layer. 2. The method according to p. 1, characterized in that the paper base contains not more than 6% by weight of absolutely dry filler fiber or a mixture of fillers selected from the group: aluminosilicate pigments, silicate pigments, kaolin, talc, chalk, gypsum, barium sulfate. 3. The method according to any one of paragraphs. 1 or 2, characterized in that the coating layers contain titanium dioxide. 4. The method according to any one of paragraphs. 1-3, characterized in that the coating layers are applied to the paper base in a printed manner using a two-component coating white ink with a hardener. 5. The method according to any one of paragraphs. 1-4, characterized in that the area of the opaque region corresponds to the area of the printed product minus the area of the transparent area. 6. The method according to any one of paragraphs. 1-5, characterized in that the opaque region has the ability to accept printing inks during subsequent printing of paper offset, type offset, high, screen or metallographic printing methods. 7. Paper with transparent areas of a given shape, obtained by the method described in any of paragraphs. 1-6.