A method for producing a decorative panel, appearing and/or feeling like a machined metal, including taking a glass substrate, including at least one first surface; and one or more solid metal films, made of one or more metal(s) or metal alloy(s); generating a pulsed LASER beam; directing a metal deposition on at least the first surface, disposing the one or more metal film(s) facing the at least first surface, between the substrate and the LASER source, and applying the LASER beam on the one or more metal film(s) transferring the one or more metal(s) or metal alloy(s) onto the at least first surface, forming a coating including a metal layer covering all or part of the at least first surface, the metal layer including a top surface; and surfacing the metal coating top surface to alter the surface condition giving it the appearance and/or feel of a machined metal.

A method for producing a decorative panel, appearing and/or feeling like a machined metal, including taking a glass substrate, including at least one first surface; and one or more solid metal films, made of one or more metal(s) or metal alloy(s); generating a pulsed LASER beam; directing a metal deposition on at least the first surface, disposing the one or more metal film(s) facing the at least first surface, between the substrate and the LASER source, and applying the LASER beam on the one or more metal film(s) transferring the one or more metal(s) or metal alloy(s) onto the at least first surface, forming a coating including a metal layer covering all or part of the at least first surface, the metal layer including a top surface; and surfacing the metal coating top surface to alter the surface condition giving it the appearance and/or feel of a machined metal.

The present invention relates to a decal for producing a decoration, comprising a non-leafing pigment layer and a first protective layer, characterized in that the decal is designed so that the non-leafing pigment layer can be applied closer to a substrate that the first protective layer. Furthermore, the present invention describes a method for producing the decal as well as its use.

A printed matter foil stamping system includes: a printing device that forms a toner layer or an ink layer on a paper sheet in accordance with print data; and a foil stamping device that performs foil stamping on the toner layer or the ink layer, wherein the printing device or a control device that controls the printing device includes a hardware processor that generates print data capable of forming a portion in which a thickness of the toner layer or the ink layer is relatively large and a portion in which the thickness is relatively small in an area in which foil stamping is to be performed, and, in accordance with the print data, the printing device forms the toner layer or the ink layer having a portion with a relatively large thickness and a portion with a relatively small thickness on the paper sheet.

A sparkling fabric includes: a fabric substrate; and a tri-layer adhered to the fabric substrate. The tri-layer includes: an adhesive layer that adheres the tri-layer to the fabric substrate; an exposed design layer; and a metal plating layer between the exposed design layer and the adhesive layer. The tri-layer is distributed as a plurality of separable and identifiable tri-layer pieces across the fabric substrate such that the distribution of tri-layer pieces has a density on the order of 15-25 pieces per centimeter squared (pcs/cm2) and a size of a piece is less than 1 millimeter (mm).

A sparkling fabric includes: a fabric substrate; and a tri-layer adhered to the fabric substrate. The tri-layer includes: an adhesive layer that adheres the tri-layer to the fabric substrate; an exposed design layer; and a metal plating layer between the exposed design layer and the adhesive layer. The tri-layer is distributed as a plurality of separable and identifiable tri-layer pieces across the fabric substrate such that the distribution of tri-layer pieces has a density on the order of 15-25 pieces per centimeter squared (pcs/cm2) and a size of a piece is less than 1 millimeter (mm).

A method wherein a bulky three-dimensional emblem can be made of a thermoplastic synthetic resin containing a vapor-deposited-metal laminated film. An apparatus for producing a three-dimensional emblem made of a thermoplastic synthetic resin includes a slide jig in which an electrode flat plate die and an electrode projecting die are slidable in a horizontal plane, an electrode recessed die capable of approaching and separating from the slide jig in a vertical direction and at a position where it can oppose the electrode flat plate die and the electrode projecting die, and a high-frequency oscillator that performs high-frequency dielectric heating by continuously generating a high-frequency voltage across the opposing dies, wherein recesses form in a surface of the electrode flat plate die opposing the electrode recessed die, and during high-frequency dielectric heating, a portion of the lower layer material enters the recess and is held on the electrode flat plate die.

A method wherein a bulky three-dimensional emblem can be made of a thermoplastic synthetic resin containing a vapor-deposited-metal laminated film. An apparatus for producing a three-dimensional emblem made of a thermoplastic synthetic resin includes a slide jig in which an electrode flat plate die and an electrode projecting die are slidable in a horizontal plane, an electrode recessed die capable of approaching and separating from the slide jig in a vertical direction and at a position where it can oppose the electrode flat plate die and the electrode projecting die, and a high-frequency oscillator that performs high-frequency dielectric heating by continuously generating a high-frequency voltage across the opposing dies, wherein recesses form in a surface of the electrode flat plate die opposing the electrode recessed die, and during high-frequency dielectric heating, a portion of the lower layer material enters the recess and is held on the electrode flat plate die.

A method and device of embossing individually light-reflecting areas on a foil material, the method and device comprising feeding a foil material into a roller nip between a pair of rollers, wherein the pair of rollers comprises a first roller and a second roller, providing each of the first roller and second roller at their respective surfaces at least in a determined perimeter, respectively with a plurality of polyhedron-shaped positive projections and a plurality of negative projections complementary to the positive projections, whereby the plurality of positive projections are arranged according to a 2-dimensional grid. The plurality of polyhedron-shaped positive projections seamlessly and gaplessly join with those corresponding negative projections at the intended embossing of the foil material, hence enabling a homogeneously jointed embossed polyhedron-like shape in the foil. The method and device further comprise, for the purpose of providing a plurality of light-reflecting areas on the foil material, that are intended to reflect light in line with a table of reflectivity values for the 2-dimensional grid, according to an orientation and shape of each of the plurality of light-reflecting areas, and enabling a perception by the human eye of a user, of the intended reflected light on a determined wide viewing angle covered by reflected light from any of the light-reflecting areas, a step of adjusting for each of the plurality of light-reflecting areas to be provided, an orientation and shape of the corresponding positive projection in the 2-dimensional grid, that is intended to emboss the light-reflecting area.

The invention provides a method for enhancing printed products (3), wherein the method comprises partially coating a substrate (2) with a varnish (4) on one side (20) such that there are at least one coated area (22) and at least one uncoated area (21) on the side (20). Subsequently, a foil (6) is applied to the side (20) that is coated with the varnish (4) and is adhesively bonded to the substrate (2), wherein the foil (6) is designed so as to adhere to the material of the substrate, but not to the varnish (4), so that the adhesive bonding of the foil (6) occurs selectively in the at least one uncoated area (21). Following the adhesive bonding, the foil (6) is severed along the dividing line (23) between the coated and uncoated areas (21, 22), so that a substrate (2) is obtained which has at least one area (22) of a side (20) coated with varnish (4), and an adjoining area (21) not coated with the varnish (4), wherein a foil (6) is adhesively bonded to the substrate in the area not coated with the varnish (4), with the edge (60) of the foil adjoining the area (22) coated with varnish (4).