PL214152B1 - Cardboard with biocidal properties and method for obtaining cardboard with biocidal properties - Google Patents

Description

The subject of the invention is cardboard with biocidal properties and a method of obtaining cardboard with biocidal properties for the production of multi-layer cardboard packaging.

There are known methods of producing materials with antiseptic properties by adding an impregnating agent containing an antiseptic to the mass of the material or by coating a layer of the material with a coating containing an impregnating agent containing an antiseptic.

From the patent description JP8151037 there is known a method of obtaining cardboard with antibacterial properties, in which a paper layer is covered with an impregnating mixture prepared by adding or dispersing a solid antibacterial agent to the binder used to cover the material or incorporated into the paint applied to the surface of the material. The antibacterial agent contains metals with antibacterial properties, such as silver, copper, zinc, tin, and an inorganic carrier such as zeolites, silica gel, active alumina and calcium sulphate.

In known methods, cardboard with biocidal properties is obtained by creating and applying a biocidal layer to its surface or by introducing an antibacterial agent into the entire mass of material.

Cardboard with biocidal properties made of paper layers is characterized according to the invention by having a biocidal zone with a thickness of not more than 3 mm containing antibacterial components in the form of nanosilver Ag ° particles and / or Cu ⁺¹ ions and / or Zn ²⁺ ions and / or ions Ti ⁴⁺ .

The method for obtaining a cardboard with biocidal properties made of paper layers by treating the surface layer with preparations containing metal ions is characterized according to the invention in that the surface layer is treated with a water-in-oil microemulsion. The dispersed phase is water with a droplet size below 20 nm in an amount up to 5% by weight of the preparation containing an antibacterial agent in the form of Ag ⁺ ions and / or Cu ²⁺ ions and / or Zn ²⁺ ions and / or Ti ⁴⁺ ions in an amount of 5 up to 2500 mg / kg of the preparation. The continuous phase is cyclohexane and / or dodecane and / or heptane and / or decane and / or octane in an amount of at least 95% by weight of the formulation. The microemulsion contains stabilizers up to 10% by weight, such as surfactants with an HLB of 3 to 6, such as sodium (bis- (2-ethylhexyl) sulfonosuccinate and / or p-1,1,3,3-tetramethylbutylphenyl polyethyleneglycol ether and / or monooleate) sorbitan and / or sorbitan monostearate and / or co-surfactants such as iso-propanol and / or hexanol and / or n-butanol and / or n-octanol The process of obtaining the microemulsion is carried out at a shear rate of at least 800 s ^-1 . The microemulsion is evenly applied to the surface of the cardboard until the content of the antibacterial agent is at least 30 mg / m ^2. Preferably, the cardboard is irradiated with UV-Vis rays and / or heated to 80 ° C and / or a reducing formulation is added.

The method in a variant of the invention is characterized in that the reducing preparation is a microemulsion containing water, preferably with a droplet size <10 nm, aluminum borohydride and / or citric acid and / or hydrazine and / or benzaldehyde and / or cyclohexane and / or dodecane and / or heptane; and p-1,1,3,3-tetramethylbutylphenyl polyethylene glycol ether and / or sorbitan monooleate.

In another embodiment of the invention, the method for obtaining a cardboard with biocidal properties made of paper layers, which consists in treating the surface layer with preparations containing metal ions, is characterized in that the surface layer is treated with an oil-in-water microemulsion. The dispersed phase is up to 5% by weight of the preparation, an oil phase with a droplet size below 20 nm containing cyclohexane and / or dodecane and / or heptane and / or decane and / or octane and containing an antibacterial agent in the form of Ag ⁺ ions and / or Cu ^{2+ ions} and / or Zn ²⁺ ions and / or Ti ⁴⁺ ions in an amount from 5 to 2500 mg / kg of the formulation. The continuous phase is water in an amount of at least 95% by weight of the formulation. The microemulsion contains stabilizers or a mixture of stabilizers with an HLB of 8 to 12 in an amount up to 10% by weight, such as polyoxyethylene sorbitan monooleate, polyoxyethylene glycol monolaurin ether, and / or cetyl trimethyl ammonium bromide, and / or sodium dodecyl sulfate, the microemulsion process being carried out by Shear rate of at least 800 s' ¹ . The microemulsion is evenly applied to the cardboard surface until the content of the antibacterial agent is at least 30 mg / m ² . Preferably, the cardboard is irradiated with UV-Vis rays and / or heated to a temperature of 80 ° C and / or a reducing agent is added.

In an embodiment of the process according to the invention, the reducing preparation is a microemulsion containing water, preferably with a droplet size <10 nm, aluminum borohydride and / or citric acid and / or hydrazine and / or benzaldehyde and / or cyclohexane and / or dodecane and / or heptane and ether p-1,1,3,3-tetramethylbutylphenyl polyethyleneglycol and / or sorbitan monooleate.

PL214 152 Β1

Thanks to the use of the invention, cardboard obtains bactericidal and fungicidal properties, as well as anti-hydrogen properties and does not discolor.

The invention is presented in more detail in the examples of its implementation.

Example I.

The paper backing at a weight of 120 m ² / g, fluting with a weight of 110 m ² / g and a cover layer is not printed or printed with a weight of 200 m ² / g and a web width of 1200 mm are delivered to the technological consisting of corrugator and kaszerownicy.

The nanoparticles are introduced in such a way that a microemulsion containing metal nanoparticle precursors is applied to one of the surfaces - the primer used to produce the multilayer cardboard. A transparent, stable microemulsion was obtained by adding to 350 ml of a solution of 0.05M p-1,1,3,3-tetramethylbutylphenyl polyethyleneglycol ether in cyclohexane and 0.01 M 1-hexanol and 1.44 ml of 0.5M silver citrate aqueous solution, and then subjected to shear at a speed of 1600 s ^-1 for 5 seconds. The microemulsion is applied to the surface of the primer by spraying. The atomization is carried out in a chamber saturated with vapors of the dispersion phase. The microemulsion is transported deeper into the material through a system of voids resulting from its porosity at a linear speed of 0.5 mm / s. The microemulsion treated surface of the primer is irradiated on the penetration side of the microemulsion with UV radiation in the range 320 to 380 nm to initiate the reduction of Ag ⁺ to Ag °. Spraying makes it possible to control the amount of applied microemulsion and thus control the thickness of the biocidal zone.

The base prepared in this way is connected with fluting by gluing the base with a starch glue and fluting in a cardboard machine on heated rolls at a temperature of 180 ° C. The starch glue binds the primer to the fluting. Under the influence of temperature, the fluting layer is formed into a B wave. This creates a 2-layer cardboard, which is directed to the laminating machine, where the third layer of paper is glued, the so-called cover that can be printed on. The result is a three-layer cardboard consisting of a smooth base with a biocidal zone (inner layer), a layer of corrugated fluting (middle layer) and a smooth cover layer (outer layer). On the laminating machine, the web is cut into sheets with a length of 1400 mm. The three-layer cardboard thus obtained is directed to the cutting device - bobst. Cutting consists of cutting out a box shape from the sheet. The boxes cut in this way are directed to seasoning, gluing and confectioning.

Microbiological tests showed inhibition of the growth of Candida albicans, Saccharomyces cerevisiae, Escherichia coli and Staphylococcus aureus bacteria on the surface of cardboard with a grammage of 430 g / m ² containing 50 mg Ag / m ^{2 of} cardboard.

Example II

The paper backing at a weight of 140 m ² / g, fluting with a weight of 120 m ² / g and a cover layer is not printed or printed with a weight of 180 m ² / g and a web width of 1200 mm are delivered to the technological consisting of corrugator and kaszerownicy.

The nanoparticles are introduced in such a way that a microemulsion (1) containing metal nanoparticle precursors is applied to one of the surfaces - the primer used to produce the multilayer cardboard. A transparent, stable water-in-oil microemulsion (I) was obtained by adding to 1 dm ^{3 of a} solution of 0.2M sodium bis (2-ethylhexyl) sulfonosuccinate and 0.01 M isopropanol in heptane 5 ml of an aqueous solution of 1 M silver nitrate and 2M copper nitrate II and subjected to shear at 1000 s ^-1 for 3 seconds. The microemulsion is applied to the surface of the primer by spraying. The microemulsion is transported deep into the material through the system of voids resulting from the porosity of the material at a linear speed of 1 mm / s. Then a microemulsion is made (2). To 1000 ml solution of 0.2 M bis- (2-ethylhexyl) sodium sulfonobursztynianu in heptane were added 5 ml of an aqueous solution of sodium borohydride with a concentration of 3M and is subjected to a shear rate of 1000 ^s-1 for 3 seconds. This way, a transparent, stable water-in-oil microemulsion with reducing properties is obtained. The microemulsion (2) is sprayed onto the surface of the substrate treated with the microemulsion (1). As a result of the reaction between the silver and copper ions from the microemulsion (1) and the reducer from the second microemulsion (2), silver, metallic copper and Cu ₂ O particles with sizes below 20 nm are deposited in the system of voids resulting from the porosity of the material. Spraying enables the control of the amount of applied microemulsions and thus the thickness of the biocidal zone.

The base prepared in this way is combined with fluting by combining the base with a starch glue and fluting in a cardboard machine on heated rollers at a temperature of 180 ° C. The starch glue binds the primer to the fluting. In this way, a 2-layer cardboard is created, which is directed to the laminating machine where the third layer of paper is glued, the so-called cover that can be printed on. Under

PL214 152 Β1 due to temperature, the fluting layer is formed into a B wave. This creates a 2-layer cardboard, which is directed to the laminating machine where the third layer of paper is glued, the so-called cover that can be printed on. The result is a three-layer cardboard consisting of a smooth base with a biocidal zone (inner layer), a layer of corrugated fluting (middle layer) and a smooth cover layer (outer layer). On the laminating machine, the web is cut into sheets with a length of 1400 mm. The three-layer cardboard thus obtained is directed to the cutting device - bobst. Cutting consists of cutting out a box shape from the sheet. The boxes cut in this way are directed to seasoning, gluing and confectioning.

Microbiological tests showed inhibition of the growth of Candida albicans, Saccharomyces cerevisiae, Escherichia coli and Staphylococcus aureus bacteria on the surface of cardboard with a grammage of 440 g / m ² containing 50 mg Ag / m ² and 10 mgCu / m ² and 25 mgCu ₂ O / m ^{2 of} cardboard.

Example III

Paper for the base, 140 m ² / g-140, fluting, 120 m ² / g and the cover layer, unprinted or printed, 200 m ² / g, web width 1200 mm, are delivered to the process line consisting of a cardboard and laminating machine . The nanoparticles are introduced in such a way that a microemulsion containing metal nanoparticles is applied to one of the surfaces - the primer used to produce the multilayer cardboard. Transparent, stable water-in-oil microemulsion was obtained by adding to 350 ml of a solution of 0.05 M Triton roztworu-100 in cyclohexane and 0.01 M 1-hexanol 1.44 ml of an aqueous solution of 0.5 M silver nitrate and subjecting it to shear at a speed of 1600 s' ¹ for 5 seconds. The resulting microemulsion was applied to the surface of the substrate by wetting the surface with a rotating roller dipped in the microemulsion. The microemulsion was transported deeper into the material through the system of voids resulting from the porosity of the material at a linear speed of 0.5 mm / s. The microemulsion treated skin surface was irradiated on the penetration side of the microemulsion with UV radiation in the range 320 to 380 nm to initiate the reduction of Ag ⁺ to Ag °. Wetting the surface with the help of a rotating roller made it possible to control the amount of microemulsion applied and thus control the thickness of the biocidal zone.

The base prepared in this way is combined with fluting by combining the base with a starch glue and fluting in a cardboard machine on heated rollers at a temperature of 180 ° C. The starch glue binds the primer to the fluting. In this way, a second-layer cardboard is created, which is directed to the laminating machine where the third layer of paper is glued, the so-called cover that can be printed on. Under the influence of temperature, the fluting layer is formed into a B wave. This creates a 2-layer cardboard, which is directed to the laminating machine where the third layer of paper is glued, the so-called cover that can be printed on. The result is a three-layer cardboard consisting of a smooth base with a biocidal zone (inner layer), a layer of corrugated fluting (middle layer) and a smooth cover layer (outer layer). On the laminating machine, the web is cut into sheets with a length of 1400 mm. The three-layer cardboard thus obtained is directed to the cutting device - bobst. Cutting consists of cutting out a box shape from the sheet. The boxes cut in this way are directed to seasoning, gluing and confectioning.

Microbiological tests showed inhibition of the growth of Candida albicans, Saccharomyces cerevisiae, Escherichia coli and Staphylococcus aureus bacteria on the surface of cardboard with a grammage of 460 g / m ² containing 50 mg Ag / m ^{2 of} cardboard.

Claims (5)

1. Cardboard with biocidal properties made of layers of paper, characterized in that it has a biocidal zone of a maximum thickness of 3 mm containing antibacterial components in the form of nanosilver Ag ° particles and / or Cu ions and / or Cu ⁺¹ ions and / or Zn ions ²⁺ and / or Ti ⁴⁺ ions. 2. A method of obtaining cardboard with biocidal properties made of paper layers by treating the surface layer with preparations containing metal ions, characterized in that the surface layer is treated with a water-in-oil microemulsion, the dispersed phase of which is water with a droplet size below 20 nm in an amount up to 5% by weight of the preparation containing the antibacterial agent in the form of Ag ⁺ ions and / or Cu ²⁺ ions and / or Zn ²⁺ ions and / or Ti ⁴⁺ ions in the amount of 5 to 2500 mg / kg of the preparation, and the continuous phase is cyclohexane and / or dodecane and / or heptane and / or decane and / or octane in an amount of at least 95% by weight of the formulation, the microemulsion containing PL214 152 Β1 stabilizers up to 10% by weight, such as surfactants with HLB from 3 to 6, such as (sodium bis- (2-ethylhexylisulfonosuccinate and / or p-1,1,3,3-tetramethylphenyl polyethyleneglycol ether and / or sorbitan monooleate) , and / or sorbitan monostearate and / or co-surfactants such as iso-propanol and / or hexanol and / or n-butanol and / or n-octanol, the microemulsion preparation process being carried out at a shear rate of at least 800 s- ¹ whereafter the microemulsion is evenly applied to the surface of the cardboard until the content of the antibacterial agent is at least 30 mg / m ² , after which the cardboard is preferably irradiated with UV-Vis rays and / or heated to a temperature of 80 ° C and / or a reducing agent is added. 3. The method according to p. A method according to claim 2, characterized in that the reducing preparation is a microemulsion containing water preferably with a droplet size <10 nm, aluminum borohydride and / or citric acid and / or hydrazine and / or benzaldehyde and / or cyclohexane and / or dodecane and / or heptane and ether p-1,1,3,3-tetramethylbutylphenyl polyethyleneglycol and / or sorbitan monooleate. Method for obtaining cardboard with biocidal properties made of paper layers, consisting in treating the surface layer with preparations containing metal ions, characterized in that the surface layer is treated with an oil-in-water microemulsion, the dispersed phase of which constitutes up to 5% by weight of the preparation, the oil phase with a droplet size below 20 nm containing cyclohexane and / or dodecane and / or heptane and / or decane and / or octane and containing the antibacterial agent in the form of Ag ⁺ ions and / or Cu ²⁺ ions and / or Zn ²⁺ ions and / or Ti ^{4+ ions} in the amount of 5 to 2500 mg / kg of the preparation, and the continuous phase is water in the amount of at least 95% by weight of the preparation, the microemulsion containing stabilizers or a mixture of stabilizers with an HLB of 8 to 12 in the amount of up to 10% by weight, such as polyoxyethylene sorbitan monooleate, polyoxyethylene glycol monolauric ether and / or cetyl trimethyl ammonium bromide and / or sodium dodecyl sulfate, the microemulsion process being carried out at a shear iu at a speed of at least 800 s- ¹ , after which the microemulsion is evenly applied to the surface of the cardboard until the content of the antibacterial agent is at least 30 mg / m ² , after which the cardboard is preferably irradiated with UV-Vis rays and / or heated to a temperature of 80 ° C and / or a reducing agent is added. 5. The method according to p. A process as claimed in claim 4, characterized in that the reducing preparation is a microemulsion containing water preferably with a droplet size <10 nm, aluminum borohydride and / or citric acid and / or hydrazine and / or benzaldehyde and / or cyclohexane and / or dodecane and / or heptane and ether p-1,1,3,3-tetramethylbutylphenyl polyethyleneglycol and / or sorbitan monooleate.