The inventions relates to a method for producing a decorative workpiece with a structured surface comprising the following steps: (B) applying a first liquid lacquer having a coarse structuring over the entire surface, wherein a difference in thickness between thicker regions and thinner regions is at least 50 m, in particular at least 100 m; (E) applying a second liquid, at least partially transparent lacquer for producing a fine structuring in some regions.

Furthermore, an apparatus for performing the method and a workpiece produced by the method are claimed.

A method for producing a decorative and structured surface with different gloss levels is disclosed, which comprises the following steps: feeding of a workpiece (1.0) to a lacquer application device, application of a first liquid lacquer layer (1.4) over the entire surface with a coarse structure in which a difference in thickness between thicker areas and thinner areas is at least 50 m, in particular at least 100 m, in particular digital spraying of droplets on partial areas of the first lacquer layer (1.4) on the workpiece (1.0), preferably with an, at least partially transparent, lacquer in order to apply a second lacquer layer (1.5) on the first lacquer layer (1.4), wherein after curing the second lacquer layer (1.5) has a different gloss level than the first lacquer layer (1.4).

Further disclosed is an apparatus for carrying out the method according to the invention.

A method for producing a decorative surface on a workpiece (1) is disclosed, the method comprising the following steps: - feeding (S10) of the workpiece (1) coated with a liquid layer (2) to a digital printing station; - application (S12) of an agent capable of at least partially absorbing electromagnetic radiation, at least on a partial area of the surface of the liquid layer (2), or which, in contact with the surface, produces a reaction product which is capable of at least partially absorbing electromagnetic radiation; - irradiation (S14) of the surface of the liquid layer (2) and of the agent with electromagnetic radiation having a wavelength of less than 300 nm, preferably less than 250 nm, particularly preferably less than 200 nm. Furthermore, an apparatus (1) for carrying out this method is disclosed.

A method for producing a decorative surface on a workpiece (1) is disclosed, the method comprising the following steps: - feeding (S10) of the workpiece (1) coated with a liquid layer (2) to a digital printing station; - application (S12) of an agent capable of at least partially absorbing electromagnetic radiation, at least on a partial area of the surface of the liquid layer (2), or which, in contact with the surface, produces a reaction product which is capable of at least partially absorbing electromagnetic radiation; - irradiation (S14) of the surface of the liquid layer (2) and of the agent with electromagnetic radiation having a wavelength of less than 300 nm, preferably less than 250 nm, particularly preferably less than 200 nm. Furthermore, an apparatus (1) for carrying out this method is disclosed.

A three-dimensional image forming system according to an embodiment of the present invention is a system that expands the front side of a thermally expandable sheet formed by laminating a thermally expanding layer on a base material and forms irregularities in a desired area, the system includes a print data density adjusting unit that adjusts, in print data for printing, on the back side of the thermally expandable sheet, a grayscale image for expanding the thermally expandable sheet to a surface height according to a density, the density of an outline part obtained by setting a region from a boundary between adjacent two regions having different densities in the grayscale image to a predetermined distance as the outline part in at least either of the two regions having different densities such that steep steps are formed on the front side of the thermally expandable sheet at the boundary.

The present invention provides a method for manufacturing a decorative construction plate, the method including subjecting a metal siding material including: a metallic substrate on which a recess-projection pattern having a height difference of 0.5 mm or more is formed and on which an ink receiving layer formed from a resin composition is provided; a core material; and a back-side material, to flame treatment by exposing the metal siding material to flame with an output of 250 kJ/h to 12000 kJ/h per 10-mm width of a flame port of a burner so that the surface temperature of the substrate does not exceed 300 C., followed by performing inkjet printing using an active ray curable ink.

A method is provided for manufacturing a panel. The method may involve supplying a substrate having an upper side. A layer may be provided onto the upper side. The upper side may be irradiated so as to cure at least a part of the layer by irradiation, hence forming the panel. The layer may include a liquid coating on substantially the entire upper side and a substance which is digitally printed locally on the upper side. The substance and the liquid coating may cooperate such that either (1) the coating and the substance react with each other, whereas the substance is a liquid that is printed on the upper side before the coating is applied and wherein the substance and the coating have different surface tensions, or (2) the coating is non-curable or only curable to a limited extent by the irradiation, whereas the substance makes the coating curable by the irradiation at locations where they meet each other.

An aqueous colored pigment-based ink that is capable of fluorescence, has a pigment colorant in an amount of 1-7 weight %; a non-polymeric fluorophore that when excited by fluorescence-exciting radiation having a peak of at least 200 nm and up to and including 400 nm, exhibits an emission peak of at least 400 nm and up to and including 750 nm, and which non-polymeric fluorophore is present in an amount of 0.1-2 weight %; and an aqueous medium comprising water. This aqueous colored pigment-based ink can be included in an ink set that also includes one or more aqueous colored pigment-based inks that are non-fluorescent. All of these inks can be applied using continuous inkjet (CIJ) printing, onto non-UV fluorescent substrates to provide images that can be detected when excited as noted above, which images can be provided on articles such as security documents, currency, and lottery tickets.

An aqueous colored pigment-based ink that is capable of fluorescence, has a pigment colorant in an amount of 1-7 weight %; a non-polymeric fluorophore that when excited by fluorescence-exciting radiation having a peak of at least 200 nm and up to and including 400 nm, exhibits an emission peak of at least 400 nm and up to and including 750 nm, and which non-polymeric fluorophore is present in an amount of 0.1-2 weight %; and an aqueous medium comprising water. This aqueous colored pigment-based ink can be included in an ink set that also includes one or more aqueous colored pigment-based inks that are non-fluorescent. All of these inks can be applied using continuous inkjet (CIJ) printing, onto non-UV fluorescent substrates to provide images that can be detected when excited as noted above, which images can be provided on articles such as security documents, currency, and lottery tickets.

A manufacturing system manufactures a predetermined product by printing and applying a coating agent to a base material made of resin. In a coating device of the manufacturing system, as a nozzle spraying the coating agent moves once in a first direction, a linear coating agent being the coating agent in a line shape with the first direction as a longitudinal direction is applied to the base material. A host control device creates application data for applying the coating agent to the base material by the coating device based on image data as data of an image to be printed on the base material by printing devices, and the application data includes, for applying the linear coating agents to the base material, spray range data of the coating agent from the nozzle in the first direction, and application interval data of the linear coating agents in a second direction.