HU230884B1 - Method for producing hygiene paper products - Google Patents

Description

Process for producing a hygienic paper product

The present invention relates to a process for the production of a sanitary paper product.

Technical background of the invention:

The paper was initially made from the same vegetable fibers as the fibers used to weave clothing: cotton, hemp, and flax. Later, they wanted to replace the filament with a cheaper material, so they tried to replace it with straw of grain and then eventually wood. Today, wood is the most important raw material for the production of cheap mass-produced paper.

The main steps in the production of wood paper are the preparation of the raw material, the soaking, peeling and shredding of the wood. In the next step, the shredded wood chips are pulped with water and then taken to a chemical solution. During this chemical solution, the fibers of the wood and the lignin are separated. During the process of cooking into cellulose, chemicals with different pH: acidic and alkaline, possibly neutral, are added to the mixture. After chemical dissolution, the pulp consisting of fibers broken down into finer fibers is washed, followed by grinding. This grinding breaks down the wall of the tiny fibers, fibrils it. This operation increases the surface area of the resulting fibers and helps them to stick together. The length of the fibers after this milling is 0.1-2-2 mm. It is the raw material for paper made on a dipstick or sieve. Before adding the pulp to the sieve, various additives are added. These will give the paper its special quality characteristics. For example, clay mineral fillers increase the opacity of the paper. Chlorine, hydrogen peroxide, oxygen and ozone are used to bleach fibers. Paper on water repellency and i

SZTNH-100115816 is added to achieve tonnage. They make the paper moisture-proof by adding organic alcohols.

After the pulp is placed on a sieve, a continuous strip is formed from it, which runs on a row of rollers several meters wide. From the screen section, the pulp is conveyed in the air between the press rolls, where the paperboard passing between them is compressed to the desired thickness. The compressed sheet of paper is already strong enough to dry for a long time as it passes over the next heated roller section, the tension rollers. The dried paper web is finally wound up.

The sieve section is suitable for performing specific operations on the paper being made. An example is watermark printing. At the end of the drying roll, a protective or surface-enhancing material may be applied to the surface of the finished paper, or only to one side (eg polishing, painting, etc. of one side).

In the production of tissue papers, the bleaching of the fibers is not followed by milling, but by sheet formation directly. During sheet formation, the fibers bond loosely together, which is why the strength of these paper products is so low. During rewinding, the tissue paper acquires its final width size, and embossing tools are used to increase the surface area to be more absorbent, and perforating tools to help settle the sheets within the roll. Such an embossed paper and method for its production are known from European patent E009490.

Tissue papers used for hygienic purposes are described in the Paper Industry Handbook (Műszaki Könyvkiadó Budapest 1980.). The tissue paper type is suitable for the selective or complete retention of particles in suspensions or emulsions. Glued, with minimal ash content, porous papers, the pore size between the fibers is large, loose structure. Its material composition, degree of grinding, structure, thickness, weight per square meter (20-40 g / m ^A 2), surface area, air permeability and absorbency can be changed depending on the intended use. Tissue papers can be used in the following locations, for household and medical use, hospital, medical, industrial and clothing use. Such papers are soft grip but good hold papers. The raw material can be sulphated, sulphite-digested wood fiber, the introduction of waste paper is not recommended from a hygienic point of view. During processing, the surface is machined in various ways (embossed, creped, perforated, etc.).

Many other examples are known from the prior art. CN 104005303A, KR 20110006307, US 2012/114722, among others, and the following documents are relevant for the assessment of the state of the art DE 10 2010 041 291, EN E 004984, Hu E 009 264 and US 2008/280088.

CN 104005303A discloses a paper product with antibacterial activity through the use of nano-silver for the packaging of medical devices. A significant difference between the present patent and D1 is that silver nitrate is sprayed on the surface of the paper sheets and then, after drying, a reducing agent (hydrogen peroxide, ascorbic acid, sodium borohydrate, glucose or citric acid) is sprayed on the surface. After both steps, extra energy investment is required due to the evaporation of the solvent for 1-15 hours. In the present patent, an ultrasonically homogenized nanocolloid is sprayed on the surface, so no drying is required! time. Wetting and drying the paper sheets leads to a deterioration in the quality of the fibers, so the present patent is preferred where these steps are not required. We cannot read the proportion of nanoparticulate cellulose fiber from document D1, but it is very important and critical from a health point of view that e.g. the nanosilver concentration should not exceed 5 mg / g of fiber, as in this case cell poisoning may already occur during human contact. However, proper use of the product does not avoid contact with the human hand, so it is a condition that the product does not cause poisoning, but at the same time has an antibacterial effect.

KR 20110006307 discloses a kitchen towel and a process for its production, wherein the paper towel is coated with a silver solution, thereby enhancing its antibacterial property. This patent describes the preparation of a kitchen towel specifically used for the absorption of oil and water by contact with kitchen food, in 3 layers (weighing 50-80 g / m ² per square meter above the value described in the present process), placed below and above the prepared food, to deodorize and collect steam. The production of kitchen wipes requires the simultaneous use and combination of 3 different types of paper and high temperature drying. The foregoing is in no way related to the purposes and functions set forth in this patent specification, and differs significantly therefrom. It is not apparent from the description of D2 whether nanosized silver is used in the process or a silver solution.

In the described processes, the use of nano-solution and the use of discrete, nano-sized silver can be well separated technologically and physically.

US 2012/114722 discloses a coating process in which a paper product is coated with a dispersion which may contain nanosilver particles and / or zinc oxide. From this document a method is described in which polymer fibers are formed by an electrospray process into which antibacterial particles are introduced. The present reference cannot be made in connection with the present patent because the polymer-based monomer is a petroleum derivative and is not wood-based cellulose from natural spinning. The film-making process is an electroplating process, not a conventional paper-forming process. The polymers used are brought into solution so that they can be applied by spraying. Document D3 mentions the following polymers: PTFE-Teflon, PEEK-polyether ketone, PVDF-polyvinyl fluoride, etc. (solution 3, left column). Polyethylene oxide is used to make nanosilver, nor is it related to the present patent, and none of the listed polymers have been used or mentioned.

The processing technology of the polymers listed in D3 is completely different from the processing of pulp fibers in the paper industry. The processing of polymers requires a high temperature at which the cellulose is already decomposed and therefore cannot be mixed. The other problem with said polymers is that they cannot be made into an absorbent material such as a sheet of paper, so their use cannot be linked to the present patent, where hydrophilicity is an essential property of the product.

In document D4 (DE 10 2010 041 291 A1), blocking agents are applied to the surface of paper, a non-hygienic paper product which dissolves blocking agents in cyclohexane, dodecane, heptane or dean and / or octane, preparing a microemulsion. The use and function of the above-mentioned compounds cannot be deduced from the present document.

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U.S. Pat. No. 2008/280088 discloses a paper product in roll form, in which the line of perforations is not perpendicular to the longitudinal side of the roll, the deviation from the perpendicular being 5-26 mm for a roll 30 cm wide. In the present patent specification, this deviation is max. It means 10 mm.

The text of the European patents E 009264 and HU E 004984, which is also valid in Hungary, is multi-ply tissue paper. a paper processing device and method for producing multi-ply tissue paper. The present invention provides a multilayer tissue paper. which combines high strength and absorbency with adequate softness and favorable contact properties, while also having the necessary thickness to create a pleasant feeling in the wearer when in contact with the human body.

In the last decade, the paper industry has also developed the practical implementation of the electrostatic layering method (eg at the University of Sopron), in which a nanoparticle-thin film is formed on large surfaces and microparticles relative to the size of the nanoparticle. Layer-by-layer Ibi technology has become the most applicable in various areas of the paper industry, resulting in the formation of a film layer ordered by multi-stage adsorption. This made it possible to coat the surface of the paper fibers and their cavities with different chemicals according to the function of the product. The physical properties of custom paper created with nanotechnology are changing. This makes the paper inimitable, unique and identifiable.

However, the present invention is a process for producing a hygienic paper product which has properties beyond the prior art, since an ultrasonically homogenized nanocolloid is sprayed on the surface, which binds chemically immediately and the solvent is absorbed due to the hygroscopicity of the product. drying time. Wetting and drying of the paper sheets leads to a deterioration in the quality of the fibers and a change in the size of the pores, so the present invention is preferred where these steps are not required, and the surface quality of the fibers is more energetically produced and the product.

The essential properties are based on the fact that according to the state of the art there is no available tissue paper product that would be used to keep the flush toilet bowl clean. Another important property is that, in addition to the cleanliness property, the product also has antibacterial properties in such a way that it is not harmful to human skin, has a destructive effect and can be used in places where prior art is not used but antibacterial properties are required. effect. Compared to the process described in D1, the present patent! The process is aimed at realizing a product with much more favorable properties from an energy point of view, because after using the nanosilver solution it is not necessary to evaporate the solvent, thus the surface of the fibers forming the product does not horn, its water uptake will be more favorable and the sheet structure will be more mechanically resistant. The process therefore creates a hygienic paper product that will allow the product to be used in a new form of use. Furthermore, due to the polarity of the nano-solutions used, they bind better to the cellulose fibers, more chemical bonds are formed between the fibers as well, resulting in a mechanically stronger sheet structure and increased absorbency. Mechanically stronger paper decomposes into its fibers with a delay in the aqueous environment, so that the protective function of the blanket or cover can be realized effectively, and at the same time the antibacterial effect. The new paper product does not come into direct contact with the human body surface - although this is not excluded, but its use keeps the toilet cups clean and has an antibacterial effect. Its use helps to significantly increase the sense of hygiene and comfort of successive users, while reducing the amount of energy, detergent, water and human labor used, which can help maintain and develop a “green” approach and reduce maintenance costs. With its spread, you can provide adequate hygiene values for the use of washbasins and toilets.

In view of the above, the present invention relates to a manufacturing process for producing a sanitary paper product whose protective and antibacterial function can be easily improved. In the process of producing tissue paper, a nanosized silver, zinc oxide colloid at a fiber concentration of 0.5-1.2 mg / g is applied to the dry tissue strip during the rewinding stage of the tissue web, thereby refining the surface of the fibers. Silver and zinc oxide nanoparticles are typically less than 30 nm in size. The nanocolloid solution itself must be treated by ultrasonic homogenization at least 2 hours before refining. The homogenizer generates a high shear force in the liquid, which is suitable for introducing the nanomaterials homogeneously between the separating liquid parts. The colloid prepared in this way can be applied to the surface of the paper product by spraying, after which spraying the final product is obtained, no further production process method (e.g. drying) is required. The individual coating of the special paper fiber will eventually be 30-70 nanometers “thick, which surface paper is already suitable for the desired functions.

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The advantage of surface treatment of the hygienic paper produced by this process is that a very small amount of material (silver and / or zinc oxide colloid) must be used, it can be applied in a controlled and uniform manner, thus achieving the simultaneous realization of several functions and many technological processes. there is no need.

One such possible function is that the surface of the paper can be coated with an antibacterial coating as a result of the treatment, so that it is resistant to any type of bacterial effect, attack and does not carry bacteria living on its surface during use. However, due to the fiber size of 30-70 nanometers, it is impermeable. neither liquid nor solids are discharged into the drain during rinsing. Due to this property, the surface of the toilet remains cleaner than if only water rinsing was used. The hygienic paper product can be embossed (embossed) if desired, which samples can also draw the users' attention to the method of application or can be perfumed.

The sanitary paper provided with the coating and then wound and embossed in a known manner is then perforated. In the present method, the perforation is realized in such a way that the edges are not perpendicular to each other, so that the shape of a unit is not square or rectangular, but a parallelogram. The size of the "a" side of the perforated unit sheets shall be 215 to 225 mm and the size of the 'b' side shall be 195 to 205 mm. ' This is important to distinguish the present hygiene product from toilet paper or hand towels. Of course, the deviation can be further enhanced by a pattern printed on the surface, a different color, or an inscription. Unless otherwise indicated, chemical properties refer to the physical state at 23 ° C.

A preferred embodiment of the present invention is illustrated in the drawing of Figure 1, wherein:

Figure 1 is a three dimensional view of a sanitary paper product of the invention

Figure 1 shows the design of a sanitary paper product in which the perforation 1 is carried out in such a way that a unit of sides 'a' ^: and 'b' forms a parallelogram-shaped sheet 4. The upper end point 2 of each inclined side "a" of the parallelogram is offset by a distance of 0.1-10 mm from the lower end point 3, along the horizontal side "b".

The product according to the invention is already suitable for creating a good state of hygiene when placed in a cup before the use of a flush toilet. The hygienic paper product created by the method presented in the present description thus protects and covers the inner surface of the toilet bowls, which facilitates keeping clean, has an antibacterial design, thus significantly increasing the comfort of the users.

Claims (5)

Claims A process for producing a hygienic paper product for keeping toilet bowls clean, in which the surface of the tissue paper produced in a known manner is treated with nanotechnology by surface finishing processes, characterized in that the dry tissue paper strip is spray-sonicated in the rewinding stage. mg / g fiber concentration, silver and / or zinc oxide colloid, coated! the rolled and / or embossed (embossed) sanitary paper product is then perforated and packaged. The method of claim 1, wherein the coating is selected to have a thickness of 30 to 70 nanometers. Process according to Claim 1 or 2, characterized in that the silver and / or zinc oxide nanoparticles are typically selected to have a size below 30 nm. 4. Figures 1-3. Process according to any one of claims 1 to 4, characterized in that the nanocolloid itself is treated at least 2 hours before breeding by ultrasonic homogenization. Method according to one of Claims 1 to 4, characterized in that, after the surface treatment, the perforation-shaped sheets (4) are formed by perforation in such a way that the upper end point of the perforation (1) is connected to the lower end point (3). ) between 0.1 and 10.0 mm along the horizontal side b.