Described herein is/are cold foil adhesive methods for manufacturing temporary tattoo laminate devices, wherein the tattoos incorporate metallic foil and other decorative components. The methods provide a surprisingly rapid and efficient method for creating tattoo laminate devices which provide crisp, clear multi-color images temporary tattoos for the skin. The methods described herein provide a way to produce, in an offset printing press or flexographic printing press, numerous tattoo laminate devices at very high speeds, with unlimited colors, and crisp, clear images.

A manufacturing method for a decorated object is provided. In this manufacturing method, a foil is attached to a medium to obtain the decorated object. The manufacturing method includes: a foil layer forming step of attaching the foil to an adhesive layer formed on the medium, so as to form a foil layer in a manner that the adhesive layer is partly exposed; and an ink layer forming step of applying an ink to the foil layer on which the adhesive layer is partly exposed, so as to form an ink layer in a manner that the ink contacts an exposed part of the adhesive layer.

Provided is a gel nail sticker including: a lower laminated part which is a part directly attached to a nail or a toenail, and has a color or a pattern, and is formed of a flexible material to correspond to a curved surface of the nail or the toenail; and an upper laminated part which is a transparent coated layer positioned on the lower laminated part and providing glossiness to a color or a pattern of the lower laminated part, and is in a flexible semi-solid state to correspond to the curved surface of the nail or the toenail before being attached to the nail or the toenail, and is cured to a solid state while maintaining a form attached to the nail or the toenail when an ultraviolet ray is irradiated to the upper laminated part after the upper laminated part is attached to the nail or the toenail.

An image transfer sheet for producing a temporary tattoo having a base release sheet upon which a tattoo image is formed. The tattoo image comprising an image layer composed of a permanent adhesive and a water soluble adhesive having one or more inks integrated therewith. Wherein, after the tattoo image has been applied to a user and then subjected to water, the water soluble adhesive breaks apart and the permanent adhesive no longer has the ability to bond thereby allowing the tattoo image to easily be removed from the user.

A conductive transfer for application to a surface is described. The conductive transfer comprises first and second non-conductive ink layers and an electrically conductive layer positioned between the first and second non-conductive ink layers. The conductive transfer also includes an adhesive layer for adhering the conductive transfer to the surface of an article.

Retransfer printing methods and systems are described where a variable stripping process is utilized while stripping all or a portion of the retransfer film (also known as intermediate transfer media) from the surface of a substrate. The variable stripping process includes stripping the retransfer film from different sections of the substrate surface while applying different tensions to the retransfer film and/or at different transport speeds of the retransfer film and the substrate.

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).

An improved protected graphics assembly according to the invention comprises the following sequential layers: optionally, at least one adhesive layer; at least one graphics layer; and at least one outwardly exposed polymer layer that is essentially free of low surface energy materials and has a gloss value of greater than 90 when tested according to ASTM D2457-03 at a 60-degree angle. The assembly is beneficially applied to a variety of articles and used in a variety of related methods. In an exemplary embodiment, a race car comprises a protected graphics assembly that comprises: optionally, at least one adhesive layer; at least one outwardly exposed polymer layer that is essentially free of low surface energy materials; and at least one graphics layer substantially protected from exterior exposure by the polymer layer.

A method for producing a decorated mineral composite body, a decorated mineral composite body and the use of a multilayer film for producing a decorated mineral composite body.

The present invention addresses at least the problem of providing a method for forming a high-resolution foil image regardless of the hydrophilicity of a recording medium. In order to solve said problem, the present invention provides a method wherein an adhesive ink that is formed by dispersing or dissolving a polymer resin in water and in a water-soluble organic solvent is used as an adhesive for a foil, the adhesive is applied by means of inkjet printing, and a foil image is formed. The polymer resin of the adhesive ink is a polymer of a monomer that includes (meth)acrylic acid and a (meth)acrylic acid alkyl ester having a C.sub.2-12 alkyl group, the acid value of the polymer resin being 50-120 mg KOH/g, and the glass transition temperature of the polymer resin being 30-110 C.