Retransfer film curable by uv radiation, method of its production and use

FIELD: printing.

SUBSTANCE: present invention relates to the field of finishing materials, particularly relates to retransfer film curable by UV radiation, method of production and use of retransfer film curable by UV radiation. The retransfer film curable by UV radiation comprises a film of the substrate, a layer of release agent, a layer of the decorative pattern of printing ink curable by UV radiation, and a background layer of ink curable by UV radiation, at that the layer of release agent is on the film of the substrate, the layer of the decorative pattern of printing ink curable by UV radiation is on the layer of release agent, the background layer of ink curable by UV radiation is on the layer of the of the decorative pattern of printing ink curable by UV radiation. Alternatively, the retransfer film comprises a layer of release agent, a protective layer of ink curable by UV radiation, a layer of the decorative pattern of printing ink curable by UV radiation, and a background layer of ink curable by UV radiation, at that the layer of release agent is on the substrate, the protective layer of ink curable by UV radiation is on the layer of the of release agent, the layer of the decorative pattern of printing ink curable by UV radiation is on the protective layer of ink curable by UV radiation, and the background layer of ink curable by UV radiation is on the layer of the decorative pattern of printing ink curable by UV radiation. At that the layer of release agent is made of release agent which is a mixture of 20-50 wt % cellulose, 1-30 wt % wax, 0-10 wt % silicone oil, 0-20 wt % butanone, 0-15 wt % ethyl acetate, 5-20 wt % acrylate prepolymer, 5-20 wt % acrylate monomer, and 1-6 wt % photoinitiator.

EFFECT: proposed retransfer film provides a strong and durable transfer of the retransfer image.

18 cl, 2 dwg, 8 ex

 

The technical field

The present invention relates to the field of finishing materials, in particular relates to curable by UV radiation conversion film or a color conversion film received a uniform application of the curable UV ink (abbreviated as UV ink), the method of production and application of curing by UV radiation conversion film or a color conversion film.

The level of technology

Currently finishing materials for interior and exterior work, becoming more comfortable and requirements established by the state authorities to the level of environmental protection, energy saving and environmental friendliness of the process become higher. Criteria of energy saving and emission reduction in the production are becoming more and more hard. Currently, the existing conversion film for interior and exterior finishing materials, as a rule, are of hot stamping film for image transfer or water films for image transfer. However, the application of hot stamping film for image transfer or water films for image transfer is associated with the evaporation of large quantities of organic solvents and strong pollution emissions, as described in patent CN 101318420; moreover when using emaperiod films for image transfer or water films to transfer images to wood boards, cement boards, gypsum boards or metal panels hot stamping conversion film or water conversion film is prone to flaking. Fototerapia paint is an environmentally friendly paint that does not contain volatile organic compounds, and paint, cured by UV radiation, or printing ink, UV curable by radiation, have their own advantages, such as high curing speed, low power consumption, low cost, compactness and high performance equipment, etc., so applying curable by UV radiation (hereinafter, also UV) colour films for image transfer can have great advantages.

Brief description of the invention

The object of the present invention is to provide a UV conversion film or a UV-cured color conversion film, with rich colors and texture and has a high decorative and protective properties.

Another object of the present invention is the provision of a method of obtaining UV conversion film or color UV conversion film.

Another object of the present invention is the use of UV conversion film or color UV conversion film.

The CTE is edema UV radiation transfer film or a colored curable by UV radiation of the transfer film, described in the present invention, may include a film substrate, a layer of the separating agent layer of the decorative pattern of the cured UV ink and the background layer of the cured UV inks, with a layer separation structure is on the film substrate, a layer of a decorative pattern of cured UV ink is on the layer of separating agent and the background layer of the cured UV ink is on the layer of the decorative pattern of the cured UV ink;

or

the transfer film may include a film substrate, a layer of separating agent, a protective layer is cured by UV radiation of paint, a layer of a decorative pattern of cured UV ink and the background layer of the cured UV inks, with a layer of a separating agent on the film substrate, the protective layer is cured by UV radiation of paint is on the layer of separating agent layer of the decorative pattern of the cured UV ink is on the protective layer is cured by UV radiation of the colors, and the background layer curable by UV radiation of paint is on the layer of the decorative pattern of the cured UV ink.

The layer of separating agent must the thickness can be performed by spraying or printing, the preferred thickness is from 1 to 100 microns.

The layer of cured UV inks required thickness can be performed by spraying or printing, the preferred thickness is from 1 to 100 μm,

A layer of a decorative pattern of cured UV ink required thickness can be performed by spraying or printing, the preferred thickness is from 1 to 100 microns.

The background layer of UV-curing paints a necessary thickness can be performed by spraying or printing, the preferred thickness is from 1 to 100 microns.

A release agent that is used to create a layer separating agent is a mixture (wt.%): 20~50% cellulose, 1~30% wax, 0~10% silicone oil, 0~10% (preferably 10~20%), 0~15% ethyl acetate (preferably 5~15%), 5~20% acrylate prepolymer, 5~20% of acrylate monomer, 1~6% of photoinitiator.

UV-curable paint which is used for forming the protective layer of UV-curable paint is a mixture of (in wt.%):

A. a mixture of 10~80% of acrylate prepolymer, 5~50% of acrylate monomer, 1~6% of photoinitiator, 0~2% of adjuvants, 0~50% filler, 0~10% butanone, 0~15% ethyl acetate,

or

B. a mixture of 10~80% of acrylate prepolymer, 5~50% of acrylate monomer, 1~6% of photoinitiator, 0~2% of adjuvants, 0~50% filler, 1~50% matting is of Ghent, 0~10% butanone and 0~15% ethyl acetate.

UV-curable printing ink, which is used to create a layer of decorative pattern of UV-curable printing ink is a mixture (wt.%): 10~60% of acrylate prepolymer, 5~50% of acrylate monomer, 1~5% photoinitiator, 0~2% of adjuvants, 0~50% filler, 5~30% of the toner, 5~30% resin, 0~10% butanone and 0~15% ethyl acetate.

UV-curable ink, which is used to create a background layer of UV-curable paint is a mixture of (in wt.%): 10~50% of acrylate prepolymer, 10~40% of acrylate monomer, 1~5% photoinitiator, 0~2% of adjuvants, 0~30% filler, 5~30% of the toner, 5~50% resin, 0~10% butanone and 0~15% ethyl acetate.

The film substrate to be coated may be made of any material from the group of polypropylene film, polyethylene film, PVC film, polyethylenterephtalate film.

Polypropylene film can be modified polypropylene film.

As cellulose can be used Metalocalypse.

As the wax, you can use a modified paraffin wax, palm wax or a mixture.

Silicone oil may be chosen from at least one compound from the group comprising methanesiliconic oil, fenilmetilketenom oil, hydroxyslim the TV oil, etc.

Acrylate prepolymer may be selected from at least one compound from the group comprising: epoxyacrylate, fluorinated epoxyacrylate, polyurethanebased, fluorinated polyurethanebased, preferablyat, fluorinated preferablyat, aminoaryl, fluorinated aminoacetate, acrylate copolymer, fluorine-containing acrylate copolymer, etc.

Acrylate monomer may be represented as: (1) a monofunctional monomer such as butyl acrylate, cyclohexylacetate, hexyl acrylate (S), hydroxyethylacrylate (NEA), hydroxyethylmethacrylate (DUMB), cryptomaterial, cryptarithmetic, hexaferrocyanate, geksaftortantalatom, dodecafluoroheptyl or dodecyltrimethylammonium, and others; (2) a bifunctional monomer, for example, tripropyleneglycol (TPGDA), dipropylenetriamine (DPGDA), neopentylglycol (NPGDA), propoxypiperidine (PO-NPGDA), paladion-di-(diethylene glycol)diacrylate (PDDA), or 1,6-etilenglikolevye (HDDA) and so on; (3) a polyfunctional monomer, for example, trimethylolpropane (TMRCA), ethoxytrimethylsilane (SW-TMRCA), prepositionalphrase (PO-TMPTA), pentaerythrityl (PETA), dipentaerythritol (DPHA), etc. and, as a rule, selects at least any one compound iswise specified list of acrylate monomers.

As the resin can be used, at least one compound from the group comprising: a modified polyvinyl acetate, polyamide resin, thermoplastic acrylic resin, etc.

As the modified polyvinyl acetate may be a vinyl chloride-vinyl acetate, ethylene-vinyl acetate or combinations thereof.

Photoinitiator represents at least one compound from the group comprising: photoinitiator on the basis of the ether of benzoin, photoinitiator based benzylacetone, photoinitiator on the basis of acetophenone, photoinitiator based on anthraquinone, photoinitiator on the basis of thioxanthone, photoinitiator based on benzophenone, photoinitiator based acylphosphatase, photoinitiator based on benzoate.

Photoinitiator on the basis of the benzoin ether may be selected from at least one compound from the group comprising: methyl ether of benzoin, ethyl benzoin ether, isopropyl benzoin ether, etc. as photoinitiator based benzylacetone can be used, for example, benzyldimethylamine and so on. Photoinitiator on the basis of acetophenone represents at least one component from the list of: 2,2-dimethoxy-2-phenylacetophenone, 2,2-diethoxy-2-phenylacetophenone, 1,1-dichloroacetophenone, 1-hydroxyacetophenone, 1-hydroxycyclohexyl, 2-hydroxy-2-methyl-1-phenyl-1-acetone, 1-4-isopropylphenyl)-2-hydroxy-2-methyl-1-acetone, 1-[4-(2-hydroxyethoxy)phenyl]-2-hydroxy-2-methyl-1-acetone, 2-methyl-1-[4-(methylsulfinyl)phenyl]-2-morpholinyl-1-acetone, 2-benzyl-2 amido-dimethyl-1-(4-morpholinylmethyl)-1-butanone.

Photoinitiator based on the anthraquinone may be selected from at least one compound from the group comprising: 2-tert-butylanthraquinone, 1-chloroanthraquinone, 2-Melantrich.

Photoinitiator on the basis of thioxanthone may be selected from at least one compound from the group comprising: 2,4-dimethyldioxanes, 2,4-dietitican, 2-isopropylthioxanthone, 4-isopropylthioxanthone, 2-chlorothioxanthone, 2,4-diisopropylethylamine etc.

Photoinitiator based on benzophenone may be selected from at least one compound from the group comprising: diphenylmethane, 4-chlorodiphenylmethane, methylbenzophenone, 4-benzoyl-4'-methylbiphenyl tiefer etc.

Photoinitiator based acylphosphatase may be selected from at least one compound from the group comprising: 2,4,6-trimethylbenzenesulfonamide, di-(2,4,6-trimethylbenzoyl)phenylphosphine, di-(2,6-dimethylbenzoyl)-2,4,4-trimethylsilyloxy, 2,4,6-trimethylbenzenesulfonamide etc.

As a photo initiator based on benzoate may be selected, for example, methylbenzoate, methyl-ortho-benzoyl benzoate, or mixtures thereof.

Auxiliary additive is preferably of wybir the t of the matting agents (BKY Additives & Instruments, for example, BYK306, BYK358, or their mixture), Antiprotozoal (BKY Additives & Instruments, for example, BYK052, BYK055, or their mixture), as well as wetting and dispersing agents (BKY Additives & Instruments, for example, Disperbyk 103, Disperbyk 163, or a mixture thereof).

The filler may be selected from at least one compound from the group comprising: powdered talc, calcium carbonate, barium sulfate, etc.

The toner may be selected from at least one compound from the group comprising: carbon black, titanium pigment, titanium cyanine pigment, proflavin, pigment scarlet, etc.

As the matting agent can be applied matting wax (preferably matting wax, GIFU, Japan), matting powder or a mixture.

The method of obtaining UV conversion film in the present invention, includes:

uniform deposition or printing a separating agent onto the film substrate, followed by curing of the layer under the action of infrared radiation receiving layer separation structure on the film substrate;

uniform deposition or printing curing UV protective wear-resistant paint on the layer of separating agent layer, followed by curing under the action of infrared radiation with obtaining protective layer of cured UV inks;

even naneseniami print-curable UV ink creates a pattern or decorative effect on the layer of curable UV protective paint, followed by curing the layer of curable by UV radiation of the printed paint under the action of infrared radiation with the receiving layer of the decorative pattern of the cured UV ink;

uniform deposition or printing curing UV paint the background layer on the decorative layer cured UV ink, followed by curing curing UV paint the background layer under the action of infrared radiation receiving UV utverzhdenii conversion film;

or

uniform deposition or printing a separating agent to the substrate coating, followed by curing of the layer under the action of infrared radiation to obtain a layer of separating agent on the substrate;

uniform deposition or printing curing UV ink creates a pattern or decorative effect on a layer of separating agent layer, followed by curing under the action of infrared radiation with the receiving layer of the decorative pattern of the cured UV ink;

uniform deposition or printing curing UV paint the background layer on the layer of the decorative pattern of the cured UV ink, followed by curing curing UV paint the background layer under the action of infrared radiation with getting cured UV radiation from the conversion film.

The film substrate used in the present invention, may be preheated at a temperature in the range 60~200°C for pre-shrinkage of the film and removal of the electrostatic charge, thus the range is determined depending on the substrate material.

The curing process under the action of infrared radiation includes:

installation temperature infrared heating up to 20~150°C and exposure coverage within 0.01~10 min for uniform distribution of the separating agent and complete curing of the separation agent.

The curing process under the action of UV radiation include:

irradiation with UV-curable inks UV-curable inks UV-generated 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 2~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW installation for UV curing UV protective paint, UV ink, UV background colors; when the wavelength of the UV light source 300~600 nm and the speed of the conveyor installation for UV curing machine 1~200 m/min

Curing by UV radiation of the transfer film or cured by UV radiation of the color transfer film as the I in the present invention, available in various options of color, pattern and texture, including:

color transfer film with the texture of stone (e.g. cultured marble or granite), color transfer film with the wood texture, color transfer film with the effect of polished metal, color transfer foil mirror metallic effect, color transfer film with a crystal effect, color transfer film with symbols or pictures, color transfer film with a decorative effect, color transfer film depicting plants and animals, color transfer film depicting landscapes, etc.

Curing by UV radiation of the color transfer film, presented in this invention can be used as a decorative material for various items of street and domestic use.

Curing by UV radiation of the transfer film obtained by the method according to the present invention has such advantages as high strength, wear resistance, resistance to environmental effects, rich colors and decorative, integrity and durability of the film, high resistance to mechanical contact damage, ease of cleaning, resistance, etc. and has the best decorative and protective properties than existing thermal conversion film and in the data conversion film.

Curing by UV radiation of the transfer film or cured by UV radiation of the color transfer film described in the present invention, can be used for the production of plates, decorated using curable by UV radiation of the film.

The deposition process according to the present invention includes: applying a layer of UV-curable sealing agent (for example, UV-curable sealing agent described in patent application CN 200710120791.1) on the surface of the film substrate, for example, fiber reinforced cement boards, fiber reinforced calcium silicate boards, fiber reinforced magnesium oxide boards, light magnesium-chloride plate, magnesium-oxychloride boards or gypsum boards; applying a layer of filling curable UV ink on the surface layer is cured by UV radiation of the impregnating agent; applying a layer of UV-curable insulating primer to the surface layer filling curable by UV radiation paint; applying a layer of curable UV pigmented ink on the surface layer is cured by UV radiation insulating primer; applying a layer of curable by UV radiation of a bonding agent to the surface layer is cured by UV pigmented ink; applying conversion film on the surface is a layer curable by UV radiation of a coupling agent (transfer film can be applied using a conversion machine on the surface of the decorative plate, covered curable by UV radiation of the binding agent) to obtain dekorirovaniya panel cured with UV radiation conversion film;

or

applying a layer of curable by UV radiation insulating primer to the surface of the substrate (for example, plates made of solid wood, fibreboard or plywood plates); applying a layer of curable by UV radiation of a coupling agent on the surface of the cured UV radiation insulating primer; applying conversion film on top of the layer curable by UV radiation of a coupling agent (transfer film can be applied using a conversion machine on the surface of the decorative plate, covered with curable by UV radiation of the binding agent) to obtain dekorirovaniya panel cured with UV radiation conversion film;

or

applying a layer of curable by UV radiation of primer paint for metal on the surface of the substrate (for example, aluminum panels, steel panels or iron panel); applying a layer of UV-curable bonding agent to the surface layer is cured by UV radiation of primer paint for metal (transfer film can be applied using a conversion machine on the surface of the decorative plate, covered with a UV-curable binder agent) getting by dekorirovaniya panel cured with UV radiation of the conversion film.

The plate/panel, decorated with UV conversion film, then covered with a layer of UV-curable bonding agent, followed by applying a layer of UV protective varnish on the surface of the layer of UV-curable binder agent; in addition, polypropylene or polyethylene film may be deposited on the surface of the layer of UV protective varnish (if the transfer film has a protective layer, the process of applying a layer of UV-curable bonding agent to the surface of the transferable film, applying a layer of UV protective varnish on the surface of the layer of UV curable bonding agent and application of polypropylene or polyethylene protective film on the surface of the layer of UV protective varnish can be skipped).

Curing by UV radiation of a sealing agent may be applied by roller or brush with a flow rate of 50~500 g/m2to make fixing, water-resistant and alkali-resistant effects; after curing the UV-curable sealing agent is injected into the substrate in order to increase the strength of the substrate and to provide a strong binding between the decorative film and the substrate, and thereby provide a longer service life of the decorative plate/panel.

Layer filling curable UV ink thickness of 10~150 μm can b shall be applied with a roller or doctor blade.

The layer is cured by UV radiation insulating primer thickness of 10~150 μm may be applied by roller, spray drenching or spraying.

The layer of curable UV pigmented inks thickness of 10~150 μm may be applied by roller, spray drenching or spraying.

The layer is cured by UV radiation primer on metal thickness 2~150 μm may be applied by roller, spray drenching or spraying.

The layer is cured by UV radiation of a bonding agent thickness 2~150 μm may be applied by roller or spray to pour.

A layer of UV protective varnish thickness of 10~250 μm and a degree of brightness 10~100 degrees (measured with the help of a gloss with the reflection of light at an angle of 60 degrees) may be applied by roller, spray drenching or spraying.

Decorated plate/panel with curable by UV radiation conversion film according to the present invention receive according to the method comprising the following stages;

(1) Treating the surface of the substrate;

(2) applying a UV-curable sealing agent on a substrate, prepared in paragraph(1);

(3) Uniform distribution of the coating under the action of infrared radiation or naturally;

(4) the Application fills the UV-curable ink on a substrate, prepared in paragraph(3);

(5) Curing under the action of UV-irradiation

(6) Applying the curable by UV radiation of primer paint on a substrate, prepared in paragraph(5);

(7) Curing under the action of UV radiation;

(8) Sanding and dusting;

(9) Applying the curable by UV radiation of primer paint on a substrate, prepared in paragraph(8);

(10) the Curing under the action of UV radiation;

(11) Applying the curable UV pigmented inks on a substrate, prepared in paragraph(10);

(12) a Uniform distribution of the coating under the action of infrared radiation or naturally;

(13) the Curing under the action of UV radiation;

(14) Polishing and dusting;

(15) applying the curable by UV radiation of a bonding agent on a substrate, prepared in paragraph(14);

(16) the Curing under the action of UV radiation;

(17) Application conversion film on a substrate, prepared in paragraph(16);

(18) the Curing under the action of UV radiation;

(19) Remove foil;

(20) a Uniform distribution of the coating under the action of infrared radiation;

(21) applying the curable by UV radiation of a bonding agent on a substrate, prepared in paragraph(20);

(22) the Curing under the action of UV radiation;

(23) applying a UV-curable rucenim protective varnish on a substrate, prepared in paragraph(22);

(24) a Uniform distribution of the coating under the action of infrared on the receipt or in the natural way;

(25) the Curing under the action of UV radiation;

(26) Control;

(27) Application of protective film;

(28) Package.

Stage 19~27 can be omitted if the transfer film has a protective layer.

Or

(1) Treating the surface of the substrate;

(2) applying a curable UV primer paint on a substrate, prepared in paragraph(1);

(3) Curing under the action of UV radiation;

(4) Polishing and dusting;

(5) applying a UV-curable bonding agent on the substrate prepared in paragraph(4);

(6) Curing under the action of UV radiation;

(7) Application conversion film on a substrate, prepared in paragraph(6);

(8) Curing under the action of UV radiation;

(9) removing the film;

(10) the Uniform distribution of the coating under the action of infrared radiation;

(11) Applying the curable by UV radiation of a bonding agent on a substrate, prepared in paragraph(10);

(12) the Curing under the action of UV radiation;

(13) Applying the curable UV protective varnish on a substrate, prepared in paragraph(12);

(14) a Uniform distribution of the coating under the action of infrared radiation or naturally;

(15) the Curing under the action of UV radiation;

(16) Control;

(17) Application of protective film;

(18) Package.

Items 9~17 can be omitted if the transfer film has the protective layer.

Or

(1) Treating the surface of the substrate;

(2) applying a curable UV primer paint for metal on a substrate, prepared in paragraph(1);

(3) Curing under the action of UV radiation;

(4) applying a UV-curable bonding agent on the substrate prepared in paragraph(3);

(5) Curing under the action of UV radiation;

(6) Application conversion film on a substrate prepared in p.

(5);

(7) Curing under the action of UV radiation;

(8) removing the film;

(9) the Uniform distribution of the coating under the action of infrared radiation;

(10) Applying the curable by UV radiation of a bonding agent on a substrate, prepared in paragraph(9);

(11) the Curing under the action of UV radiation;

(12) applying a curable UV protective varnish on a substrate, prepared in paragraph(11);

(13) a Uniform distribution of the coating under the action of infrared radiation or naturally;

(14) the Curing under the action of UV radiation;

(15) Control;

(16) Application of protective film;

(17) Packing.

Paragraphs 8~16 can be omitted if the transfer film has a protective layer.

Surface treatment of the substrate surface includes: processing fundamentals of grinding and dust are removed from the substrate surface.

Applying the curable by UV radiation of the impregnant includes: n the carrying curable by UV radiation of the impregnant with a roller or a brush with a flow rate of impregnant 50~500 g/m 2.

Uniform distribution of the coating under the action of infrared radiation or naturally includes: the temperature setting in the installation of infrared smoothing in the range of 20~150°C, exposure of the coating to a uniform distribution within 0.1~10 minutes and complete evaporation of the solvent from the coating; if you use the leveling naturally, for uniform distribution of the coating and complete evaporation of the solvent from the coating to withstand covered the working parts within 1 minutes ~ 24 hours in natural conditions.

Applying a fill-curable UV ink includes: applying a fill-curable UV ink thickness of 10~150 μm by roller or doctor blade.

The curing under the action of UV radiation includes: accommodation covered working parts unit for UV curing, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW and curing the coating under the action of UV-irradiation; the wavelength of the UV light source is 200~600 nm, the conveyor speed curing of UV radiation installation 5~50 m/min

Applying a curable UV radiation insulating primer in the cancel: applying a layer of curable by UV radiation insulating primer thickness of 10~150 µm roller, jet drenching or spraying.

Sanding and dust removal includes: processing the working surfaces of the grinding machine with abrasive belt 80~800 mesh and remove dust from the surface of workpiece.

Applying a curable UV radiation insulating primer includes: applying a layer of curable by UV radiation insulating primer thickness of 10~150 μm by roller, spray drenching or spraying.

Applying a curable UV pigmented inks includes: applying a layer of curable UV pigmented inks thickness of 10~150 μm by roller, spray drenching or spraying.

Application of UV-curable binding agent includes: applying a layer of UV-curable bonding agent thickness 2~150 μm by roller, spray drenching or spraying.

Applying a curable UV primer for metal, includes: applying a layer of curable UV primer on metal thickness of 10~150 μm by roller, spray drenching or spraying.

Application conversion film is in the machine for transfer printing.

Removing the film includes: removing the film manually or using an automatic film-cleaning machine.

Applying a curable UV protective varnish includes: applying a curable UV protective varnish Valiko is, jet drenching or spraying thickness of 10~250 μm and a degree of brightness 10~100 degrees (measured by using a gloss meter with the reflection of light at an angle of 60 degrees).

Curing by UV radiation of a sealing agent filling curable UV ink, UV curable by radiation insulating primer, curing UV pigmented ink that is curable by UV radiation of the binder, cured by UV radiation primer for metal and cured by UV radiation protective lacquer is well known from the prior art. For example:

Curing by UV radiation of the binding agent contains (in wt.%): 10~80% of acrylate prepolymer, 10~89% of acrylate monomer, 1~5% photoinitiator, 0~2% of adjuvants and 0~50% of solvent.

Filling curable UV ink contains(in wt.%): 10~80% of acrylate prepolymer, 5~50% of acrylate monomer, 1~5% photoinitiator, 0~2% of adjuvants and 0~50% filler.

Curing by UV radiation insulating primer contains (in wt.%): 10~80% of acrylate prepolymer, 5~60% of acrylate monomer, 1~6% of photoinitiator, 0~2% of adjuvants and 0~50% filler.

Curing UV pigmented ink contains (in wt.%): 10~80% of acrylate prepolymer, 5~60% of acrylate monomer, 1~6% of photoinitiator, 0~2% of adjuvants, 0~50% filler and 0~50% pig is enta.

Curing by UV radiation of the binding agent contains (wt.%): 10~80% of acrylate prepolymer, 5~60% of acrylate monomer, 1~6% photo initiator, 0~2% of adjuvants and 0~50% filler.

Curing UV primer on metal contains (in wt.%): 10~80% of acrylate prepolymer, 1~80% of acrylate monomer, 1~15% of photoinitiator, 0~5% of adjuvants and 0~30% filler.

Curing UV protective varnish contains (in wt.%): 10~80% of acrylate prepolymer, 1~80% of acrylate monomer, 1~15% of photoinitiator, 0~5% of adjuvants, 0~30% filler and 0~30% of solvent.

Under the acrylate prepolymer should be understood acrylate prepolymer used to obtain UV-curable radiation conversion film or cured by UV radiation of the color conversion film of the present invention.

Under photoinitiators should understand photoinitiator used to obtain UV-curable radiation conversion film or cured by UV radiation of the color conversion film of the present invention.

Under auxiliary additive should be understood auxiliary additive used to obtain UV-curable radiation conversion film or cured by UV radiation colorful conversion film of the present invention.

The filler may be any substance of following the th group: powdered talc, calcium carbonate and powdered barium sulfate.

The solvent represents at least one component from the following group: methylbenzol, xylene, ethyl acetate, butyl acetate, butanone, cyclohexanone, isopropanol, monobutyl ether of ethylene glycol.

Decorative plates/panels cured with UV radiation conversion film/curing by UV radiation of the color conversion film obtained by the method according to the present invention have such advantages as high strength, high resistance to weathering, protection from adverse environmental effects; can have rich colors and complex designs; the integrity and durability of the film, high resistance to abrasion, easily washable, non-flammable and so on; and have the best decorative and protective properties than the existing film for thermal transfer image and water conversion film.

A method of obtaining a cured UV radiation conversion film according to the present invention has such advantages as compact equipment, low equipment costs, high productivity, low energy consumption, no pollution and so on, in addition, when the transfer film according to the present invention is applied to wood, cement is e, gypsum Board or metal surface of the transfer film is firmly attached to the surface of the boards/panels and not behind it.

Brief description of drawings

Figure 1 shows a view in section of the structure is cured by UV radiation conversion film according to the present invention;

Figure 2 shows a view in section of the structure is cured by UV radiation conversion film according to the present invention.

Legend:

1. the film substrate,

2. the layer of separating agent,

3. the protective layer of the cured UV ink

4. a layer of a decorative pattern of cured UV ink,

5. the background layer of the cured UV ink.

Detailed description of the implementation options

Variant implementation of the invention 1.

Color transfer film with the texture of marble Arabescato Coccoha or Black Marquina.

The structure of the color conversion film with a texture of marble Arabescato Coccoha or Black Marquina shown in figure 1.

Color transfer film includes a film substrate 1, the layer of separating agent 2, the protective layer of the cured UV ink 3, a layer of a decorative pattern of cured UV ink 4, the background layer of the cured UV ink 5.

The method of obtaining included the following steps:

1) Warming of the polyp is Obrenovac film (film substrate) at a temperature of 120°C for pre-shrinkage of the film and the removal of electrostatic charge.

2) Uniform distribution or printing a separating agent on the surface of the polypropylene film prepared in step 1, followed by curing of the layer under the action of infrared radiation, i.e. mounting temperature infrared heating to 60°C. and curing the coating for 1 min to evenly distribute the separating composition and the full curing of the separating composition with the formation of the layer of separating agent with a thickness of 1 μm.

The separating agent is a mixture of (in wt.%); 41% of Metalocalypse, 20% of the modified paraffin wax, 18% butanone, 5% ethyl acetate, 5% of fluorine-containing aminoacridine, 10% of butyl acrylate and 1% 2-hydroxy-2-methyl-1-phenyl-1-acetone.

3) Uniform application of curing UV protective paint over the layer of separating agent obtained in step 2 by applying or printing and then curing curing UV protective paint under the action of UV irradiation as follows: run one layer of rolled material, covered with UV protective paint after installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and the RV) with a capacity of 3~20 kW with high speed curing curing UV protective paint under the action of UV radiation and produce a protective layer thickness of 10 μm; the wavelength of the UV light source is 300~400 nm, the conveyor speed in the plant for curing by UV radiation is 1~200 m/min

curing UV inks for the protective layer is a mixture of (in wt.%):

A. 20% of fluorine-containing epoxyacrylate, 40% of fluorine-containing polyurethanecoated, 16% of ethoxytrimethylsilane (SW-TMRCA), 20% of prepositionalphrase (RO-TMRCA), 3% 1-hydroxycyclohexanone, a 0.5% BYK 052, and 0.5% Disperbyk 103;

or

B. 10% of fluorine-containing aminoacridine, 10% acrylate copolymer, 50% of the fluorine-containing acrylate copolymer, 9.5% hydroxyethylmethacrylate (DUMB), 10% cryptomaterial, 5% 1-hydroxycyclohexanone, and 0.2% BYK 052, 0,3% Disperbyk 103, 5% matting agent matting wax, GIFU, Japan).

4) Evenly applying the black curable UV ink or white-curable UV ink creates a pattern on the surface to be coated UV protective layer prepared in stage 3, by applying or printing and then curing curing UV ink under the action of UV irradiation as follows: run one layer of rolled material, covered with curable by UV radiation of the black printing ink or UV curable by radiation of a white printing ink after curing of the UV emission is m installation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing curable by UV radiation of the black printing ink or UV curable by radiation of white ink under the action of UV radiation and the receiving layer of the decorative illustration of a black printing ink thickness of 10 μm or layer of decorative painting white ink thickness of 10 μm; the wavelength of the UV light source is 365~410 nm, the conveyor speed UV curing install 1~200 m/min

Black curable UV printing ink layer for decorative figure is a mixture of (in wt.%): 18.5% of fluorine-containing epoxyacrylate, 25% of fluorine-containing polyurethanecoated, 15% of propoxypiperidine (PO-NPGDA), 15% paladion-di-(diethylene glycol)diacrylate (PDDA), 3% 1-hydroxycyclohexanone, 3% 2,4-diisopropylethylamine, and 0.2% BYK 052, 0.3% Disperbyk 103, 10% carbon black M-E, and 10% polyamide resins;

White-curable UV printing ink layer for decorative figure is a mixture of (in wt%): 5% aminoacridine, 25% of fluorine-containing aminoacridine, 5% acrylate copolymer, 10% tripropyleneglycol (TPGDA), 9.8% CI is propilenglikolstearat (DPGDA), 2% 1-hydroxycyclohexanone, 3% 2,4,6-trimethylbenzenesulfonyl oxide (TPO), 0.1% BYK 052, 0.1% Disperbyk 103, 5% powdered talc, 25% titanium pigment, 10% polyamide resins.

5) Uniform application of curing UV white ink on the surface layer of the decorative illustration of a black curable UV ink or the surface layer of the decorative illustration white-curable UV ink prepared in stage 4, by applying or printing and then curing curing UV ink under the action of UV irradiation as follows; run one layer of rolled material, covered with curable by UV radiation of the white printing ink after curing by UV radiation installation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing curable UV white ink under the action of UV radiation and obtaining a color conversion film with a texture of marble Black Marquina or color of the applied coating with a texture of marble Arabescato Coccoha;

White-curable UV printing ink for the background layer is the Oh mixture (wt.%): 10% of fluorine-containing epoxyacrylate, 25% of fluorine-containing aminoacridine, 5% acrylate copolymer, 15% of ethoxytrimethylsilane (SW-TMRCA), 9.8% of dipropylthiocarbamate (DPGDA), 3% 1-hydroxycyclohexanone, 3% 2,4,6-trimethylbenzenesulfonyl oxide (TPO), 0.2% BYK 052, 22% of titanium pigment and 7.2% polyamide resins.

An embodiment of the invention 2.

Color transfer film with the texture of marble Royal Batticino beige color or texture of marble Royal Batticino light brown color.

The structure of the color conversion film with a texture of marble Royal Batticino beige color or texture of marble Royal Batticino light brown color is the same as in variant implementations of the invention 1. The method of obtaining included the following steps:

1) Heating of the plastic film (film substrate) at a temperature of 160°C for pre-shrinkage of the film and the removal of electrostatic charge.

2) Uniform distribution or printing a separating agent on the surface of the polyethylene film prepared in step 1, followed by curing of the layer under the action of infrared radiation, i.e. mounting temperature infrared heating up to 150°C and exposure coverage for 0.01 min for uniform distribution of the separating agent, complete evaporation of the solvent from the coating, full cure separating agent with the formation of CL is I the separating composition with a thickness of 5 μm.

The separator composition is a mixture of (in wt.%): 30% of Metalocalypse, 25% palm wax, 15% butanone, 5% acetate, 11% of fluorine-containing polyurethanecoated, 10% polyesteracrylates and 4% of 1-hydroxycyclohexanone.

3) Uniform application of curing UV protective paint over the layer of separating agent obtained in step 2 by applying or printing and then curing curing UV protective paint under the action of UV irradiation as follows: run one layer of rolled material, covered with a curable UV protective paint across UV-curing installation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW with high speed for curing curable UV protective paint under the action of UV radiation and produce a protective layer of a thickness of 15 μm; the wavelength of the UV light source is 250~380 nm, the conveyor speed curing of UV radiation installation 1~200 m/min

curing UV paint for the protective layer is a mixture (wt.%):

A. 20% of fluorine-containing epoxyacrylate, 40% of fluorine-containing polyurethanecoated, 10% etoc is trimethylolpropane (SW-TMRCA), 20% of prepositionalphrase (RO-TMRCA), 3% 1-hydroxycyclohexanone, a 0.5% BYK 052, 0,5% Disperbyk 103 and b% butanone;

Or

B. 14% of fluorine-containing aminoacridine, 10% acrylate copolymer, 50% of the fluorine-containing acrylate copolymer, 9.5% hydroxyethylmethacrylate (DUMB), 10% cryptomaterial, 2% 1-hydroxycyclohexanone, 0.2% BYK 052, 0.3% BYK 358 and 4% matting agent matting wax, GIFU, Japan).

4) Uniform application of UV beige printing inks or UV light brown ink creates a pattern on the surface of the UV-curable protective layer prepared in section 3, by buttering or printing and then curing the UV-curable ink under the action of UV irradiation as follows: run one layer of rolled material, coated with UV beige printed with dye or UV light brown printing ink through the installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing UV-curable beige printing inks or UV light brown ink under the action of the UV radiation and the receiving layer of the decorative pattern beige printing ink 15 μm thick layer or decorative pattern light brown ink thickness of 18 μm; when the wavelength of the UV light source 300~420 nm, the speed of the conveyor in the plant for curing UV radiation 1~200 m/min

Beige UV-curable printing ink layer for decorative figure is a mixture of (in wt.%): 20% of the fluorine-containing acrylate copolymer, 20% of fluorine-containing aminoacridine, 9.3% hydroxyethylacrylate (NEA), 20% of dipentyldithiocarbamate (DPHA), 2% 1-hydroxycyclohexanone, 3% 2-methyl-1-[4-(methylsulfinyl)-phenyl]-2-morpholinyl-1-acetone, 0.2% BYK 052, 0.3% Disperbyk 103, 15% of proflavine, 0.2% pigment scarlet, 10% of a copolymer of vinyl chloride and vinyl acetate;

Light brown UV-curable printing ink layer for decorative figure is a mixture of (in wt.%): 10% of fluorine-containing epoxyacrylate, 20% of fluorine-containing aminoacridine, 17.4% dipropylthiocarbamate (DPGDA), 20% of dipentyldithiocarbamate (DPHA), 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 3% 2-methyl-1-[4-(methylsulfinyl)-phenyl]-2-morpholinyl-1-acetone, 0.3% BYK 052, 0.3% Disperbyk 103, 2% of proflavine, 20% titanium pigment and 5% of a copolymer of vinyl chloride and vinyl acetate.

5) Uniform application of UV-curable white ink on the surface layer of the decorative pattern of beige UV-curable ink or the surface layer of the decorative pattern of light brown UV-curable printing inks and then curing the UV-curable ink is under the action of UV irradiation as follows: run one layer of rolled material, covered with a UV-curable white printing ink through the installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing UV-curable white ink under the action of UV radiation and obtaining a color conversion film with a texture of marble Royal Batticino beige color or the color of the applied coating with a texture of marble Royal Batticino light brown color, respectively;

White UV-curable printing ink for the background layer is a mixture of (in wt.%); 20% of fluorine-containing epoxyacrylate, 25% of ethoxytrimethylsilane (SW-TMRCA), 2% 1-hydroxycyclohexanone, 3% 2,4,6-trimethylbenzenesulfonyl oxide, 2.9% butanone, 0.1% Disperbyk 103, 20% titanium pigment, 27% polyamide resins.

An embodiment of the invention 3.

Color transfer film with the texture of the tree.

The structure of the color conversion film with the texture of the tree shown in figure 2. Color transfer film includes a film substrate 1, the layer of separating agent 2, a layer of a decorative pattern of cured UV ink 4, the background layer from curing the second UV paint 5.

The method of obtaining included the following steps:

1) Warming of the polyvinylchloride film (film substrate) at a temperature of 180°C for pre-shrinkage of the film and the removal of electrostatic charge.

2) Uniform distribution or printing a separating agent on the surface of the polyvinylchloride film, prepared according to claim 1, followed by curing of the layer under the action of infrared radiation, i.e. mounting temperature infrared heating up to 80°C and curing the coating for 2 minutes to evenly distribute the separating agent, complete evaporation of the solvent from the coating, full cure separating agent with the formation of the layer of separating agent with a thickness of 100 μm.

The separating agent is a mixture of (in wt.%): 30% of Metalocalypse, 5% of the modified paraffin wax, 15% palm wax, 10% hydroxyl silicone oil, 11% butanone, 5% acetate, 12% of fluorine-containing polyurethanecoated, 10% triftoratsetata, 0.5% 2-hydroxyl-2-methyl-1-phenyl-1-acetone and 1.5% 1-hydroxycyclohexanone.

3) Uniform application of UV-curable printing ink color French grey, creating a decorative texture French grey oak, on top of the layer separating agent obtained in step 2 by applying or printing or even Nan is giving UV red-grey ink creates a decorative texture red-grey wood on top of the layer of separating agent, obtained in step 2 by applying or printing, and then curing the UV-curable printing inks creating a decorative texture French grey oak or curing of UV-curable printing inks creating a decorative texture red-grey wood under the action of UV irradiation as follows:

run one layer of rolled material, covered with a curable UV printing ink creates a decorative texture French grey oak on top of the printed or coated paint creates a decorative texture red-grey wood through the installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing UV protective paint under the action of UV radiation and produce a protective layer thickness of 10 μm; when the wavelength of the UV light source 250~420 nm, and the speed of the conveyor in the plant for curing UV radiation 1~200 m/min

Curing UV printing ink creates a layer of painting with texture French grey oak is a mixture of (in wt.%): 23% of fluorine-containing polyurethanecoated, 15% of polyesteracrylates, 0.4% dipentyldithiocarbamate (DPHA), 15% of 1,6-etilenglikolevye (HDDA), 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 3% 2,4,6-trimethylbenzenesulfonyl oxide, and 0.2% BYK 052, 0.3% Disperbyk 103, 0.1% of carbon black, 20% titanium pigment, 4% of a copolymer of vinyl chloride and vinyl acetate, 5% polyamide resin and 2% butanone.

Curing UV printing ink creates sketch layer with the texture of red-gray wood is a mixture of (in wt.%): 10% of fluorine-containing epoxyacrylate, 23% of fluorine-containing polyurethanecoated, 12% of dipropylthiocarbamate (DPGDA), 2% 1-hydroxycyclohexanone, 3% 2,4,6-trimethylbenzenesulfonyl oxide, 3%, 0.3% BYK 052, 0.1% Disperbyk 103, 1% pigment scarlet, 0.1% of carbon black, 21% of titanium pigment, 3% calcium carbonate, 10% polyamide resins, 4.5% butanone, 10% ethyl acetate.

5) Uniform application of curing UV white ink on a layer of paint creates a decorative texture French grey oak or paint layer creates a decorative texture red-grey wood, prepared in step 3 and then curing curing UV ink under the action of UV radiation as follows: run one layer of rolled material, covered with a UV-curable white printing ink through the installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal is halogen (iodine-gallium lamp, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW for curing UV-curable white ink under the action of UV radiation and obtaining a color conversion film with a texture French grey oak or color conversion film with a texture red-grey wood, respectively.

Curing UV printing ink for the background layer is a mixture of (in wt.%): 10% of fluorine-containing epoxyacrylate, 17.5% of fluorine-containing aminoacridine, 10% acrylate copolymer, 10% ethoxytrimethylsilane (SW-TMRCA), 10% dipropylthiocarbamate (DPGDA), 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 3% 2,4,6-trimethylbenzenesulfonyl oxide, and 0.2% BYK 052, 25% titanium pigment, 10% thermoplastic acrylate, 2.3% ethyl acetate.

An embodiment of the invention 4.

Color transfer film with the crystal texture of the red diamond. The structure of the color conversion film with a texture crystal red diamond is the same as in variant implementations of the invention 1. The method of obtaining included the following steps:

1) Warming up polyethylenterephtalate film (film substrate) at a temperature of 60°C for pre-shrinkage of the film and the removal of electrostatic charge.

2) Uniform distribution or printing a separating agent on the surface polyethylenterephtalate the second film, prepared in step 1, followed by curing of the layer under the action of infrared radiation, i.e. mounting temperature infrared heating to 90°C and curing the coating for 1 min for uniform distribution of the separating agent, complete evaporation of the solvent from the coating, full cure separating agent with the formation of the separation layer composition thickness of 10 μm.

A release agent is a mixture of (in wt.%): 20% Metalocalypse, 10% of the modified paraffin wax, 9% phenylmethylene silicone oil, 20% butanone, 15% ethyl acetate, 20% of fluorine-containing polyesteracrylates, 5% PO-NPGDA, 0.5% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 0.5% of 1-hydroxycyclohexanone.

3) Uniform application of curing UV protective paint over the layer of separating agent obtained in step 2 by applying or printing and then curing curing UV protective paint under the action of UV irradiation as follows: run one layer of rolled material, covered with a curable UV protective paint across UV-curing installation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion what Anami and others) with a capacity of 3~20 kW high speed for curing UV protective paint under the action of UV radiation and produce a protective layer of a thickness of 15 μm; the wavelength of the UV light source is 385~400nm, the speed of the conveyor installation for curing UV radiation 1~200 m/min

Curing UV printing ink for the protective layer is a mixture of (in wt.%):

A. 10% of fluorine-containing epoxyacrylate, 34.3% of fluorine-containing aminoacridine, 30% of geksaftoratsetilatsetonata, 20% of dodecyltrichlorosilane, 3% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 2% 1-hydroxycyclohexanone, 0.2% BYK 052 and 0.5% Disperbyk 103;

or

B. 10% of fluorine-containing aminoacridine, 50% of the fluorine-containing acrylate copolymer, 17.8% triftoratsetata, 10% ethoxytrimethylsilane (EO-TMPTA), 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 3% 1-phenylcyclohexylpiperidine, 0.1% BYK 052, 0.1% Disperbyk 103, and 7% matting agent GIFU (matting wax, GIFU, Japan).

4) Uniform application of UV pearlescent ink or UV bright red ink creates a pattern on the surface of the UV-curable protective layer prepared in section 3, by applying or printing and then curing the UV-curable ink under the action of UV irradiation as follows: run one layer of rolled material, coated with UV pearl printed with dye or UV bright red printing ink through the installation for UV curing, equipped with 1~3 ultrafi letovima lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamp, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing UV-curable pearlescent ink or UV bright red ink under the action of UV radiation and reception of the decorative layer pearlescent ink thickness of 20 μm or decorative layer of bright red ink thickness of 20 μm; when the wavelength of the UV light source 300~420 nm, and the speed of the conveyor installation for UV-curing 1~200 m/min

Pearl UV-curable printing ink layer for decorative figure is a mixture of (in wt.%): 15% of fluorine-containing polyurethanecoated, 15% of aminoacridine, 15% of hexaferrocyanate, 20% of dodecafluoroheptyl, 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 2.7% 2,4,6-trimethylbenzenesulfonyl oxide, 0.2% BYK 052, 0.1% Disperbyk 103, 20% dye "pearl essence", 10% polyamide resins.

Bright red UV-curable printing ink layer for decorative figure is a mixture of (in wt.%): 12% acrylate copolymer, 12.4% of fluorine-containing polyurethanecoated, 10% polyesteracrylates, 10% ethylhexyl acrylate (S), 15% of ethoxytrimethylsilane (SW-TMRCA), 10% methacrylic acid, 2% 1-hydroxycyclohexanone, 3% 2,4,6-trimethylbenzenesulfonyl oxide, 0.3% BYK 052, 5% red iron oxide, 20.3% in amidnoi resin.

5) Uniform application of UV-curable white ink on the surface layer of decorative painting curable by UV radiation pearlescent paint or surface layer of decorative painting curable by UV radiation of bright red paint and then curing the UV-curable ink under the action of UV irradiation as follows: run one layer of rolled material, covered with a UV-curable white printing ink through the installation for UV curing, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and others) with a capacity of 3~20 kW high speed for curing UV-curable white ink under the action of UV radiation and receiving pearly conversion film with the texture of the red diamond or bright red conversion film with the texture of the red diamond, respectively.

White-curable UV printing ink of the background layer is a mixture of (in wt.%): 15% of fluorine-containing epoxyacrylate, 32% of ethoxytrimethylsilane (SW-TMRCA), 5% dipropylthiocarbamate, 2% 1-hydroxycyclohexanone, 3% 2,4,6-trimethylbenzenesulfonyl oxide, 20% titanium pigment, 5% powdered talc is, 18% polyamide resins.

An embodiment of the invention 5.

Color transfer film with a decorative effect. The structure of the color conversion film with decorative effect is the same as in variant implementations of the invention 1. The method of obtaining included the following steps;

1) Warming of the polyvinylchloride film (film substrate) at a temperature of 140°C for pre-shrinkage of the film and the removal of electrostatic charge.

2) Uniform distribution of the separating agent on the surface of the polyvinylchloride film prepared in step 1, followed by curing of the layer under the action of infrared radiation, i.e. mounting temperature infrared heating up to 120°C and curing of the coating within 0.5 min for complete evaporation of the solvent, the complete curing of the separation agent and the receiving layer of the separating agent in the thickness of 20 μm.

A release agent is a mixture of (in wt.%): 33% methylcellulose, 5% of the modified paraffin wax, 15% palm wax, 2% methanesiliconic oil, 3% fenilmetilketenom oil, 20% butanone, 5% ethyl acetate, 5% of fluorine-containing aminoacridine, 10% dipropylthiocarbamate (DPGDA) and 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone.

3) Uniform application of UV protective paint over the layer of separating agent obtained in etape, by applying or printing and then curing curing UV protective paint under the action of UV irradiation as follows: run one layer of rolled material, covered with a curable UV protective paint after installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing curable UV protective paint under the action of UV radiation and produce a protective layer with a thickness 15 μm; when the wavelength of the UV light source 200~380 nm, and the speed of the conveyor in the plant for curing UV radiation 1~200 m/min

Curing UV paint for the protective layer is a mixture of (in wt.%):

A. 30% of the fluorine-containing preferability, 30% of fluorine-containing polyurethanecoated, 16% of triftoratsetata, 18.5% of prepositionalphrase (RO-TMRCA), 3% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 0.1% BYK 052, 2% powdered talc and 0.4% ethyl acetate;

B. 20% of fluorine-containing aminoacridine, 10% polyurethanecoated, 30% of fluorine-containing acrylate copolymer, 14% of ethoxytrimethylsilane (EA-TMRCA), 10% cryptomaterial, 5% hydroxycyclohexanone, 0.4% powdered talc, 0.6% acetic acid ethyl ester and 10% matting powder.

4) Uniform application of UV-curable silver mirror paint or UV gold mirror paint creates a decorative effect on surface UV protective layer prepared in stage 3, by applying or printing and then curing the UV-curable ink under the action of UV irradiation as follows: run one layer of rolled material, covered with a UV-curable silver mirror paint or UV gold mirror paint after installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing UV-curable silver mirror paint or UV gold mirror paint under the action of UV radiation and reception of the decorative layer silver mirror paint thickness of 25 microns or decorative layer gold mirror coating thickness of 25 μm; when the wavelength of the UV light source 250~400 nm, and the speed of the conveyor installation for curing UV radiation 1~200 m/min

Silver mirror UV paint DL the decorative layer is a mixture of (in wt.%):

14.5% of fluorine-containing polyurethanecoated, 15% of fluorine-containing epoxyacrylate, 15% of hexaferrocyanate, 15% of geksaftoratsetilatsetonata, 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 3% 2,4,6-trimethylbenzenesulfonamide, 0.2% BYK 052, 0.3% butanone, 15% pigment silver powder and 20% of a thermoplastic acrylic resin.

Gold mirrored UV paint for a decorative layer is a mixture of (in wt.%):

15% of fluorine-containing acrylate copolymer, 16.1% aminoacridine, 15% of dipentyldithiocarbamate (DPHA), 2% 1-hydroxycyclohexanone, 2% 2,4,6-trimethylbenzenesulfonamide, 0.2% BYK additives 052, 0.2% supplements Disperbyk 103, 18% of the Gold pigment powder, 10% polyamide resin and 1.5% of a thermoplastic acrylic resin.

5) Uniform application of black UV paint over a layer of decorative painting UV silver mirror paint or UV gold mirror paint and then curing the coating under the action of UV irradiation as follows: run one layer of rolled material, covered with black UV-curable through the installation for curing UV radiation, equipped with 1~3 UV lamps (high-voltage mercury lamps) with a capacity of 3~20 kW and 0~3 metal halide lamps (iodine-gallium lamps, iron lamps, disposistion lamps and other) with a capacity of 3~20 kW high speed for curing black UV ink under the action of UV radiation and receive a silver mirror color conversion film with a decorative effect or gold mirror color conversion film with a decorative effect.

Black UV paint for the background layer is a mixture of (in wt.%): 15% of the fluorine-containing preferability, 27.7% of fluorine-containing aminoacridine, 7% of triftoratsetata, 20% of dipropylthiocarbamate (DPGDA), 2% 1-hydroxycyclohexanone, 3% 2,4-diisopropylethylamine, 0.1% BYK additives 052, 0.2% supplements Disperbyk 103, 8% carbon black, and 2% powdered talc and 15% polyamide resins.

An embodiment of the invention 6.

Decorative plate with marble texture

The basis for the decorative plate was a reinforced fiber cement slab, fiber reinforced calcium silicate plate, fiber reinforced magnesium oxide plate, light magnesium-chloride cement Board, magnesium-oxochloride plate or gypsum plate. The base is polished and removed the dust from the surface, was applied by brush layer is cured by UV radiation of the impregnating agent to the surface of the substrate with a flow rate of 120 g/m2and kept for 30 minutes to evenly distribute the coating in a natural way; put a cushion layer filling curable UV ink thickness of 20 μm; load the base with the coating in the curing of UV radiation installation, equipped with a UV lamp (high voltage mercury lamp) with a capacity of 9.6 kV and running soon with the STU conveyor 15 m/min, for curing of the coating; applied layer is cured by UV radiation transparent primer paint thickness of 40 μm on top of the layer fill-curable UV ink; loaded plate with the coating in the curing of UV radiation installation, equipped with two UV lamps (high-voltage mercury lamps) 13 kW and operating at a belt speed of 15 m/min to cure the coating; polished plate on the grinding machine with abrasive belt grit 240 and removed the dust from the surface of the plate; put a layer of curable by UV radiation of primer paint thickness of 10 μm on the surface of already existing curable by UV radiation transparent insulating primer paint roller; loaded plate coated in UV-curing installation, equipped with a UV lamp (high voltage mercury lamp) with a capacity of 9.6 kW and operating at a belt speed of 15 m/min to cure the coating; put a layer of white cure UV primer paint thickness of 10 μm on top of the layer curable by UV radiation of primer paint; loaded plate coated in UV-curing installation, equipped with five UV lamps (metal halide lamps) with a capacity of 16.8 kW and operating at a belt speed of 15 m/min to cure the coating; polished plate on the grinding article is the NCA with abrasive tape grit 400; put a layer of curable by UV radiation of a bonding agent thickness of 10 μm on top of the white layer curable by UV radiation of primer paint; nanoscale color the transfer ribbon with Black marble texture Marquinac or color the transfer ribbon with Arabescato marble texture Coccoha, as described in variant implementations of the invention 1, the surface of the curable by UV radiation of a coupling agent; loaded plate with the coating in the curing of UV radiation installation, equipped with six UV lamps (metal halide lamps) with a capacity of 16.8 kW and operating at a belt speed of 15 m/min to cure the coating; remove foil and kept under infrared irradiation for 2 min at 90°C for uniform distribution of the coating; loaded plate coated in UV-curing installation, equipped with three UV lamps (high-voltage mercury lamps) 13 kW and operating at a belt speed of 15 m/min to cure the coating; after testing coverage at the end on the surface of the plate was applied protective polypropylene film to obtain a decorative plate with a marble texture.

Curing by UV radiation of the impregnating agent is a mixture of (in wt.%): 20% of epoxyacrylate, 50% TMRT, 10% TPGDA, 4% 2-hydroxy-2-methyl-1-phenyl-1-acetone and 16% ethyl acetate.

Zapadnaya the cured UV ink is a mixture of (in wt.%): 40% of epoxyacrylate, 20% preferability, 16% TMRT, 20% talc powder, 3.5% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 0.2% BYK additives 052 and 0.3% supplements Disperbyk 163.

curing by UV radiation of the priming paint is a mixture (wt.%): 20% of fluorine-containing epoxyacrylate, 30% of polyurethanecoated, 10% TPGDA, 20% EO-TMPTA, 15% talc powder, 4.5% 1-hydroxycyclohexanone, 0.2% BYK additives 055 and 0.3% supplements Disperbyk 103.

White-curable UV primer paint is a mixture of (in wt.%): 20% of epoxyacrylate, 30% of the fluorine-containing preferability, 20% of the PET, 10% PO-NPGDA, 15% titanium pigment, 2% 1-hydroxycyclohexanone, 2.5% 2,4,6-trimethylbenzenesulfonamide, 0.2% BYK additives 052 and 0.3% supplements Disperbyk 103.

Curing by UV radiation of the binding agent is a mixture of (in wt.%): 35% of polyurethanecoated, 30% of the fluorine-containing preferability, 20% of the PET, 10% PO-NPGDA, 2.5% 1-hydroxycyclohexanone, 2% 2-hydroxy-2-methyl-1-phenyl-1-acetone, 0.2% BYK additives 052 and 0.3% supplements Disperbyk 103.

An embodiment of the invention 7.

Decorative plate with wood

The basis for the decorative plate is a plate made of solid wood, MDF or plywood. The substrate was polished and removed the dust from the surface; layer applied curable by UV radiation of primer paint thickness of 40 μm on the surface of the foundations of the; load the plate with the coating in the curing of UV radiation installation, equipped with two UV lamps (high-voltage mercury lamps) with a capacity of 9.6 kW and operating at a belt speed of 8 m/min to cure the coating; polished plate and remove dust from the surface of the plate; put a layer of curable by UV radiation of a bonding agent thickness of 10 μm on top of the layer curable by UV radiation of primer paint; utverjdali layer curable by UV radiation of a coupling agent; put the transfer ribbon color with wood grain (French grey oak or red-grey wood), as described in variant implementations of the invention 3; loaded plate coated in UV curing radiation installation, equipped with three UV lamps (metal halide lamps) with a capacity of 16.8 kW and operating at a belt speed of 8 m/min to cure the coating; remove foil and kept under infrared irradiation for 2 min at 90°C for uniform distribution of the coating; applied layer is cured by UV radiation of a bonding agent thickness of 10 μm on the surface of the cured UV radiation conversion film; utverjdali layer curable by UV radiation of a coupling agent; inflicted roller layer is cured by UV radiation protective Matt lacquer thickness of 20 μm when the gloss level 0 hail (measured with by using a gloss meter with the reflection of light at an angle of 60 degrees); kept under infrared irradiation for 1 min at 50°C for uniform distribution of the coating; loaded plate coated in UV-curing installation, equipped with three UV lamps (high-voltage mercury lamps) with a capacity of 16.8 kW and operating at a belt speed of 8 m/min to cure the coating; after testing coverage at the end on the surface of the plate was applied protective polypropylene film to obtain a decorative plate with a wood structure.

Curing by UV radiation of the priming paint is a mixture of (in wt.%): 10% of epoxyacrylate, 40% of polyurethanecoated, 20% SW-TMRCA, 10% PO-NPGDA, 15% talc powder, 4.5% 1-hydroxycyclohexanone, 0.2% BYK additives 052 and 0.3% supplements Disperbyk 103.

Curing by UV radiation of the binding agent is a mixture of (in wt.%); 35% of polyurethanecoated, 30% of the fluorine-containing preferability, 20% of the PET, 10% PO-NPGDA, 4.5% 1-hydroxycyclohexanone, 0.2% BYK additives 052 and 0.3% supplements Disperbyk. 103.

Curing by UV radiation Matt protective varnish is a mixture (wt.%): 30% of polyurethanecoated, 30% of fluorine-containing polyurethanecoated, 10% acrylate copolymer, 10% TMRT, 10% of the PET, 4% 1-hydroxycyclohexanone, 5% matting powder, 0.2% BYK additives 055, 0.3% additive BYK 306 and 0.5% of the additive Disperbyk 103.

Option to implement the AI of the invention 8.

Decorative panel with texture crystal red diamond is the Basis for the decorative panel is an aluminum panel, steel plate or iron plate. The substrate was cleaned, removing oily stains, foreign matter and dust from the surface; inflicted roller layer is cured by UV radiation primer on metal thickness of 10 μm on the surface of the substrate; loaded plate with the coating in the curing of UV radiation installation, equipped with three UV lamps (high-voltage mercury lamps) 13 kW and operating at a belt speed of 10 m/min to cure the paint, put a layer of curable by UV radiation of a bonding agent thickness of 10 μm on top of a layer of curable UV primer on metal; utverjdali layer curable by UV radiation of a coupling agent; put the transfer ribbon color with texture crystal red diamond, as described in variant implementations of the invention 4, the surface of the curable by UV radiation of a coupling agent; loaded plate with the coating in the curing of UV radiation installation, equipped with three UV lamps (metal halide lamps) with a capacity of 16.8 kW and operating at a belt speed of 10 m/min to cure the coating; remove foil and kept under infrared irradiation for 2 min at 90°C for uniform is raspredeleniya coating; load the plate with the coating in the curing of UV radiation installation, equipped with four UV lamps (metal halide lamps) with a capacity of 16.8 kW and operating at a belt speed of 10 m/min for the complete curing of the coating; after testing coverage at the end on the surface of the plate was applied protective polypropylene film to obtain a decorative panel with texture crystal red diamond.

Curing by UV radiation of primer paint on the metal is a mixture of (in wt.%): 15% of epoxyacrylate, 35% of polyurethanecoated, 20% TMRT, 10% PO-NPGDA, 15% talc powder, 4.5% 1-hydroxycyclohexanone, 0.2% BYK additives 052 and 0.3% supplements Disperbyk 103.

Curing by UV radiation of the binding agent is a mixture of (in wt.%); 35% of polyurethanecoated, 30% of the fluorine-containing preferability, 20% of the PET, 10% PO-NPGDA, 4.5% 1-hydroxycyclohexanone, 0.2% BYK additives 052 and 0.3% supplements Disperbyk 103.

1. Curing by UV radiation of the transfer film which comprises a film substrate,
the layer of separating agent,
a layer of a decorative pattern of cured UV ink and
the background layer of the cured UV ink,
and
the layer of separating agent is on the film substrate,
a layer of a decorative pattern of cured UV printing the ink is on the layer of separating agent,
the background layer of the cured UV ink is on the layer of the decorative pattern of the cured UV ink; or
transfer film includes
the layer of separating agent,
the protective layer of the cured UV ink,
a layer of a decorative pattern of cured UV ink and
the background layer of the cured UV ink,
and
the layer of separating agent on the substrate,
the protective layer of the cured UV ink is on the layer of separating agent,
a layer of a decorative pattern of cured UV ink is on the protective layer of the cured UV inks, and
the background layer is cured by UV radiation of paint is on the layer of the decorative pattern of the cured UV ink, with a layer of a separating agent is made of a separating agent, which is a mixture of 20~50 wt.% cellulose, 1~30 wt.% wax, 0~10 wt.% silicone oil, 0~20 wt.% butanone, 0~15 wt.% ethyl acetate, 5~20 wt.% acrylate prepolymer, 5~20 wt.% acrylate monomer and 1~6 wt.% photoinitiator.

2. Curing by UV radiation of the transfer film according to claim 1, in which the protective layer is cured by UV radiation of paint made of cured UV inks, which PR is dstanley a mixture of 10~80 wt.% acrylate prepolymer, 5~50 wt.% acrylate monomer, 1~6 wt.% photoinitiator, 0~2 wt.% adjuvants, 0~50 wt.% filler, 0~10 wt.% butanone and 0~15 wt.% ethyl acetate;
or
a mixture of 10~80 wt.% acrylate prepolymer, 5~50 wt.% acrylate monomer, 1~6 wt.% photoinitiator, 0~2 wt.% adjuvants, 0~50 wt.% filler, 1~50 wt.% matting agent, 0~10 wt.% butanone and 0~15 wt.% ethyl acetate.

3. Curing by UV radiation of the transfer film according to claim 1, in which a layer of a decorative pattern of cured UV ink made of cured UV ink, which is a 10~60 wt.% acrylate prepolymer, 5~50 wt.% acrylate monomer, 1~5 wt.% photoinitiator, 0~2 wt.% adjuvants, 0~50 wt.% filler, 5~30 wt.% toner, 5~30 wt.% resin, 0~10 wt.% butanone and 0~15 wt.% ethyl acetate.

4. Curing by UV radiation of the transfer film according to claim 1, in which the background layer curing UV inks made of cured UV ink, which is a mixture of 10~50 wt.% acrylate prepolymer, 10~40 wt.% acrylate monomer, 1~5 wt.% photoinitiator, 0~2 wt.% adjuvants, 0~30 wt.% filler, 5~30 wt.% toner, 5~50 wt.% resin, 0~10 wt.% butanone and 0-15 wt.% ethyl acetate.

5. Curing by UV radiation of the transfer film according to claim 1, in which the film substrate represents the t of any film, selected from the following group: polypropylene film, polyethylene film, polyvinyl chloride film, polyethylene terephthalate film.

6. Curing by UV radiation of the transfer film according to claim 5, in which the polypropylene film is a modified polypropylene film.

7. Curing by UV radiation of the transfer film according to claim 1, in which cellulose is a methylcellulose; wax is a modified paraffin wax, palm wax or a mixture thereof; silicone oil represents at least one component selected from the group comprising: methanesiliconic oil, benzylimidazole oil, hydroxyl silicone oil.

8. Curing by UV radiation of the transfer film according to claims 1, 2, 3, or 4, in which the acrylate prepolymer represents at least one component selected from the group comprising: epoxyacrylate, fluorinated epoxyacrylate, polyurethanebased, fluorinated polyurethanebased, preferablyat, fluorinated preferablyat, aminoaryl, fluorinated aminoacetate, acrylate copolymer and a fluorine-containing acrylate copolymer;
acrylate monomer constitutes at least one component selected from the group comprising: butyl acrylate, cyclohexylacetate, hexyl acrylate, hydroxyethylene is at, hydroxyethylmethacrylate, cryptomaterial, cryptarithmetic, geksaftorbenzola, geksaftortantalatom, dodecafluoroheptyl, dodecyltrimethylammonium, tripropyleneglycol, dipropylenetriamine, neopentylglycol, propoxy-neopentylglycol, paladion bis(diethylene glycol)diacrylate, 1,6-hexyleneglycol, trimethylolpropane, ethoxytrimethylsilane, prepositionalphrase, pentaerythrityl and dipentaerythritol;
photoinitiator represents at least one component selected from the group comprising: photoinitiator on the basis of the ether of benzoin, photoinitiator based benzylacetone, photoinitiator on the basis of acetophenone, photoinitiator based on anthraquinone, photoinitiator on the basis of thioxanthone, photoinitiator based on benzophenone, photoinitiator based acylphosphatase and photoinitiator based on benzoate.

9. Curing by UV radiation of the transfer film according to claim 3 or 4, in which the resin constitutes at least one component selected from the group of modified polyvinyl acetate, polyamide resin and a thermoplastic acrylic resin; a toner represents at least one component selected from the group of: carbon black, titanium pigment, phthalocyanine blue, etc the flavin and the pigment scarlet.

10. Curing by UV radiation of the transfer film according to claim 9, in which the modified polyvinyl acetate is a copolymer of vinyl chloride and vinyl acetate, ethylene vinyl acetate or a mixture.

11. Curing by UV radiation of the transfer film according to claim 2, 3 or 4, in which an additive represents at least one component selected from the group comprising: a leveling agent, Antiprotozoal, wetting and dispersing agent; a filler constitutes at least one component selected from the group including: powdered talc, calcium carbonate and barium sulfate.

12. Curing by UV radiation of the transfer film according to claim 2, in which the matting agent represents at least one component selected from the group including: matting wax, matting powder or a mixture.

13. Curing by UV radiation of the transfer film of claim 8, in which photoinitiator on the basis of the ether of benzoin represents at least one component selected from the group comprising: methyl ether of benzoin, ethyl benzoin ether, isopropyl benzoin ether; photoinitiator based benzylacetone is benzyldimethylamine; photoinitiator on the basis of acetophenone represents at least one component selected from the group comprising: ACE opinon, 2,2-dimethoxy-2-phenylacetophenone, 2,2-diethoxy-2-phenylacetophenone, 1,1-dichloroacetophenone, 1-hydroxyacetophenone, 1-hydroxycyclohexyl, 2-hydroxy-2-methyl-1-phenyl-1-acetone, 1-(4-isopropylphenyl)-2-hydroxy-2-methyl-1-acetone, 1-[4-(2-hydroxyethoxy)phenyl]-2-hydroxy-2-methyl-1-acetone, 2-methyl-1-[4-(methylsulfanyl)phenyl]-2-morpholinyl-1-acetone and 2-benzyl-2-dimethylamino-1-(4-phenylmorpholine)-1-butanone;
photoinitiator based on anthraquinone represents at least one component selected from the group comprising: 2-tert-butylanthraquinone, 1-chloroanthraquinone and 2-Melantrich;
photoinitiator on the basis of thioxanthone represents at least one component selected from the group comprising; 2,4-dimethyldioxanes, 2,4-dietitican, 2-isopropylthioxanthone, 4-isopropylthioxanthone, 2-chlorothioxanthone, 2,4-diisopropylethylamine;
photoinitiator based on benzophenone represents at least one component selected from the group comprising: diphenylmethane, 4-chlorodiphenylmethane, methylbenzophenone and 4-benzoyl-4'-methyldiphenylamine thioether;
photoinitiator based acylphosphatase represents at least one component selected from the group comprising: 2,4,6-trimethylbenzenesulfonamide, di-(2,4,6-trimethylbenzoyl)phenylphosphine, di-(2,6-dimethylbenzoyl)-2,4,4-trimethylsilyloxy and 2,4,6-trimethylene elfenliedwastoosad;
photoinitiator-based benzoate is methylbenzoate, methyl-ortho-benzoylbenzoate or their mixture.

14. A method of obtaining a cured UV radiation conversion film according to any one of claims 1 to 13, including:
uniform deposition or printing a separating agent onto the film substrate, and then curing the separating agent under the action of infrared radiation receiving layer separating agent on the film substrate;
uniform deposition or printing curing UV protective paint on the layer of separating agent, and then curing the ink under the action of UV-irradiation with obtaining protective layer curing UV inks;
uniform deposition or printing curing UV ink, creating a pattern and decorative effect, the protective layer is cured by UV radiation of the paint, and then curing the printed ink under the action of UV radiation with the receiving layer of the decorative pattern of the cured UV ink; and
uniform deposition or printing curable by UV radiation of the background paint on a layer of a decorative pattern of cured UV ink and then paint curing under the action of UV irradiation with getting cured by UV radiation conversion film;
or
uniform deposition is whether the seal separating agent onto the film substrate, and then curing the separating agent under the action of infrared radiation receiving layer separation structure on the film substrate;
uniform deposition or printing curing UV ink with drawing and decorative effect, the layer separating agent, and then curing the printed ink under the action of UV-irradiation with the receiving layer of the decorative pattern of the cured UV ink; and
uniform deposition or printing curable by UV radiation of the background paint on a layer of a decorative pattern of cured UV ink and then paint curing under the action of UV-irradiation with getting cured by UV radiation conversion film.

15. The method according to 14, in which the curing process under the action of infrared radiation includes: installation temperature infrared heating in the range of 20~150°C, exposure to distribute the separating agent in the course of 0.01~10 min and curing the separating agent; curing under the action of UV-irradiation includes the processing of UV irradiation curing of UV radiation installation, equipped with 1~3 UV lamps (high-voltage mercury lamp) power 2-20 kW and 0-3 metal halide lamps with a capacity of 3~20 kW, at a wavelength of 200~600 nm for curing Oteri emeu UV protective paint, curing UV inks and UV curable by radiation background colors when the speed of the conveyor UV curing radiation installation 1~200 m/min

16. The use of curable by UV radiation conversion film according to any one of claims 1 to 13 in the manufacture of decorative panels cured with UV radiation conversion film.

17. The application of article 16, which includes:
applying a layer of curable by UV radiation of the impregnating agent to the surface of the reinforced fiber cement panels, reinforced fiber calcium silicate panels, reinforced fibers, magnesium oxide panels, lightweight magnesium-chloride cement panels, magnesium-oxychloride panel or drywall,
applying a layer of filling curable UV ink on top of a layer of curable by UV radiation of the impregnating agent,
applying a layer of curable by UV radiation insulating primer layer on top of the filling curable UV ink,
applying a layer of curable UV pigmented ink on top of a layer of curable by UV radiation insulating primer,
applying a layer of curable by UV radiation of a bonding agent on top of a layer of curable UV pigmented inks,
application conversion film on curing UV bonding agent with obtaining on corative panel cured with UV radiation conversion film;
or
applying a layer of curable by UV radiation insulating primer to the surface of a plate made of solid wood, fibreboard or plywood plates,
applying a layer of curable by UV radiation of a bonding agent over a layer curable by UV radiation insulating primer and
application conversion film on top of the layer curable by UV radiation of a coupling agent with obtaining decorative panels cured with UV radiation conversion film;
or
applying a layer of curable UV primer on metal on the surface of the aluminum plate, steel plate or an iron plate,
applying a layer of curable by UV radiation of a bonding agent over a layer curable by UV radiation primer for metal and
application conversion film on top of the layer curable by UV radiation of a coupling agent with obtaining decorative panels cured with UV radiation conversion film.

18. The application 17, further comprising applying a layer of curable by UV radiation of a coupling agent on the surface of the cured UV radiation conversion film on the surface of the decorative panel and applying a layer of curable UV protective varnish on the surface layer is cured by UV radiation of a bonding agent.



 

Same patents:

FIELD: textile, paper.

SUBSTANCE: method includes preparation of a paper base with weight of 55-90 g/m2 and specified parameters of absorbency with one-sided wetting and air permeability, application of a coating on it with weight of 6-12 g/m2, consisting of a binder and a filler with their specified ratio, besides, the base is prepared with the value of absorbency in the range of 28-55 g/m2 by Cobb60 and value of air impermeability in the range of 190-480 cm3/min.

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2 cl, 1 tbl

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4 cl

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5 cl, 6 dwg, 3 ex

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4 cl, 3 tbl, 3 ex

FIELD: physics, labelling.

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20 cl, 11 dwg, 3 tbl

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10 cl, 3 dwg, 8 tbl, 4 ex

FIELD: technological processes.

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12 cl, 4 dwg, 13 ex

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4 cl, 3 tbl, 3 ex

FIELD: soft wares, paper.

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20 cl, 1 dwg, 2 tbl, 2 ex

The invention relates to processes of transfer of image to different surface of products made of different materials

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EFFECT: higher resistance to scratch formation.

19 cl, 4 dwg, 1 ex

FIELD: process engineering.

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5 cl, 1 tbl, 3 ex

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11 cl, 8 ex, 8 tbl

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4 dwg, 5 ex

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7 cl, 2 tbl, 5 ex

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EFFECT: invention provides improvement of printing on textiles.

24 cl, 7 dwg

FIELD: physics.

SUBSTANCE: coating is obtained in an electrostatic field by successive deposition of layers. A support layer from a polymer powdered composition is deposited in an electrostatic field, followed by heat treatment at temperature below the temperature of formation of the polymer powdered composition. An information mark of the corresponding colour is formed on top of the support layer on a mask from similar polymer powdered composition with heat treatment similar to that of the support layer. Subsequent deposition of a reflecting layer with optical microspheres is carried out in an electrostatic field. After depositing the reflecting layer, final heat treatment is carried out until fixation thereof, followed by deposition of a protective layer from a transparent polymer material. The apparatus has a housing (1) with a handle (2), a hopper (3) for feeding microspherical particles, a shaft (4) with a channel (5) for flow of microspherical retroreflective particles and a voltage multiplier (6) with a corona electrode (7) lying in the outlet of the shaft (4). A spray seat includes a cylindrical housing (8) with a conical section at the outlet, in which in series, in the direction of flow, there is a central channel (9) with a closed end at the outlet, and at the inlet connected to the channel (5) for flow of microspherical retroreflective particles, an annular cylindrical channel (10) which transforms at the outlet into an annular conical channel (11), respectively formed by a cylindrical bushing (12) and a conical reflector (1) at the outlet, lying coaxially with the housing (8). The central channel (9) is connected to the annular channel (10) at its inlet by tangential holes (14) on the circular surface of the cylindrical bushing (12). On the surface of the conical reflector (13) there are grooves (15) for ordered movement of microparticles on the annular conical channel (11) to the article, as well as under the action of air ejected through a row of holes (16) and (17) on the housing (8). The central channel (9), at the inlet of the spray seat, has a section (18) which narrows in the direction of flow, and at the end surface of the central channel (9), there is a conical splitter (19) with a vertex which is directed opposite the flow of microspherical retroreflective particles.

EFFECT: invention simplifies the process, improves quality and prolongs the service life of the article.

9 cl, 4 dwg

Barrier fabric // 2473428

FIELD: process engineering.

SUBSTANCE: invention relates to hygiene and sanitary, particularly, to barrier fabric. Fabric with layer of nanofibre for mechanical trapping of organic matter consists of sandwich structure containing bearing nonwoven material to support, at least, one layer of nanofibre. Note that said layer of nanofibre has protective layer wherein separated sandwich structures are interconnected. Layer of nanofiber creates barrier to prevent an ingress of allergens and consists of organic polymer material. Said coating layer may be made of nonwoven material of spanbond type, meltblown type, cotton fabric and/or mix of cotton with polyester. In compliance with one version, at least one layer of nanofibre is arranged on case material to create barrier against microorganisms. Note also that said layer consists of organic hydrophobic material of polyurethane or PVDF, or their copolymers. Note that separate layers of sandwich structure are interconnected. In compliance with another version, barrier fabric consists of sandwich structure including base spanbond-type nonwoven material to carry, at least, one layer of nanofibre secured thereto consisting of hydrophobic polymer of polyurethane or fluoropolymer PVDF, or copolymer thereof. Note here that separate sandwich structures are interconnected.

EFFECT: higher efficiency of entrapping organic substances and fluids.

9 cl, 2 dwg, 4 ex

FIELD: process engineering.

SUBSTANCE: proposed method is intended for producing such 3D components as branches, T-joints, crossovers in 3D structures, protective bodies and cases, machines and mechanisms, submarine hulls and motor boats, etc. In compliance with proposed method, forming reinforcing material with preset properties is used to cut out contour complying with structure being developed. Water-and-gas-tight thermoplastic material is used to make sealed cylinder shaped to said structure. Forming material outer surface is impregnated with cold-curing thermosetting resin to force working medium into sealed cylinder during resin polymerisation at pressure sufficient to ensure preset shape and sizes.

EFFECT: whatever spatial shape without using molding tooling.

2 cl

FIELD: transport.

SUBSTANCE: invention relates to aerospace engineering, particularly, to production of platforms including those located outside the spaceship. In compliance with first version, platform is composed of composite spatially closed structure made by two panels with cutouts, side walls and end flanges. Cutouts of second panel are located asymmetrically relative to those of the first panel. Second panel surface area is smaller than that the first panel. End flanges comprise hinge assemblies and are made from metallic alloy. Second panel is thicker than the first one, or elasticity modulus of second panel exceeds that of the first one at identical thermal linear expansion factors approximating to zero. In compliance with second version, platform is composed of composite spatially closed structure made by two panels with cutouts, side walls and end flanges. Cutouts of second panel are located asymmetrically relative to those of the first panel. Second panel surface area is smaller than that the first panel. End flanges comprise hinge assemblies and are made from metallic alloy. First panel thermal linear expansion factor approximates to zero while that of second panel is negative at equal thickness and elasticity modulus.

EFFECT: decreased spatial thermal deformations.

2 cl, 2 dwg

FIELD: production of the materials intended to protect people in industrial, administrative and living premises against action of electromagnetic fields of the radio-frequency range.

SUBSTANCE: the invention is pertaining to production of materials intended to protect people in industrial, administrative and living premises against action of electromagnetic fields of the radio-frequency range generated by operation of electrical circuits, electric appliances, mobile and radio telephones, and also for protection of the people against a geopathogenic environmental activity. The material based on schungite mineral represents a three-layered material, two exterior layers of which consist of a carton or a plastic sheet, on each side of which a printing ink containing fragments of a schungite mineral is applied, and in the capacity of the middle layer the aluminum foil is used. At that the layers are connected by a glue. To increase the strength of the three-layered material it is drawn for example through rollers or placed under a press. The printing ink contains particles of the schungite mineral, these particles have dimensions of 5-10 microns and make 90 % of the mass of the printing ink, in which they are dispersed. The printing ink containing the particles of the schungite mineral makes 6-7 % of the mass of the board or 3-3.5 % of the mass of the plastic material. The layer of the carton has a depth of 0.3 mm, and the layer of plastic material has the depth of 0.6 mm. The technical result of the invention is production of the material from the accessible raw being an effective and low-cost material for protection of people against action of electromagnetic fields of the radio-frequency range generated in the process of the operation of electric appliances, electrical circuits, at exploitation mobile and radiophones, and also from a geopathogenic action of the environment.

EFFECT: the invention ensures production from an accessible raw material of an effective and low-cost material for protection of people against action of the radio-frequency range electromagnetic fields generated during operation by different electrical appliances, circuits and telephones.

5 cl, 4 ex, 1 tbl

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