Decals with dimensional offsets are disclosed. The decals may be part of a decal kit or may be applied to an article. The decals include an overlay having multiple dimensional spacers. When applied to an article, the decal overlay bonds to the article, securing the dimensional spacers between the overlay and the article creating dimensional offsets. The dimensional offsets are positioned on an interior surface of the article so that contact with a wearer's skin is minimized, reducing the perception of cling.

A golden effect heat transfer label includes a carrier and a golden effect design layer on the carrier. The golden effect design layer is formulated from an ink having a golden effect pigment present in a concentration of about 5 percent to about 35 percent by weight of the ink. The golden effect heat transfer label is transferred from the carrier to a target object as a golden effect feature and the golden effect feature exhibits a robust golden effect on the target object. The golden effect feature exhibits no adhesion failure and no visual change after being subjected to standard testing. The golden effect heat transfer label can be transferred onto target objects including apparel items, plastics, metals and carbon fiber objects.

A method includes storing a design in a database. The design includes (i) a print component and an inner crop mark that are configured to be printed, and (ii) a foil component configured to be foil-stamped. The method further includes storing a foil-press die that is embossed with both the foil component and a foil alignment mark. The foil alignment mark is configured to be aligned with the inner crop mark.

A thermal transfer sheet includes a support film and a transfer layer provided on one surface of the support film. The transfer layer at least includes a decorative layer and an adhesive layer provided on an obverse side of the decorative layer. The adhesive layer includes a first adhesive layer and a second adhesive layer laminated on the first adhesive layer. The first adhesive layer is positioned on an obverse side of the second adhesive layer. The first adhesive layer is made of a first resin having thermal plasticity and has a lower viscosity than the second adhesive layer. The second adhesive layer is made of a second resin having thermal plasticity and has a higher glass-transition point than the first adhesive layer. Monomer units constituting the first resin and monomer units constituting the second resin are partly or entirely identical.

Decals with dimensional offsets are disclosed. The decals may be part of a decal kit or may be applied to an article. The decals include an overlay having multiple dimensional spacers. When applied to an article, the decal overlay bonds to the article, securing the dimensional spacers between the overlay and the article creating dimensional offsets. The dimensional offsets are positioned on an interior surface of the article so that contact with a wearer's skin is minimized, reducing the perception of cling.

Decals with dimensional offsets are disclosed. The decals may be part of a decal kit or may be applied to an article. The decals include an overlay having multiple dimensional spacers. When applied to an article, the decal overlay bonds to the article, securing the dimensional spacers between the overlay and the article creating dimensional offsets. The dimensional offsets are positioned on an interior surface of the article so that contact with a wearer's skin is minimized, reducing the perception of cling.

Described herein are shaped articles comprising a monolayer of microspheres partially embedded in its surface. The shaped articles are made via a transfer article (20), which comprises a microsphere monolayer (22) comprising a plurality of microspheres partially embedded in a first major surface of a transfer polymer layer (23), which is disposed on a support layer (21). The transfer article is shaped and a conformable substrate is contacted with the shaped transfer article, transferring the microspheres to the conformable substrate forming a shaped finished article having a surface comprising a monolayer of partially embedded microspheres.

A controller includes a memory that stores image data in a vector format representing a shape in the vector format, a contour extractor that extracts a contour of the shape based on the image data in the vector format, a reduced-size contour generator that generates reduced-size contours inside the contour by sequentially reducing inwardly the contour extracted by the contour extractor, and a moving controller that controls a carriage moving mechanism such that a foil transfer tool moves along the reduced-size contours and the contour in order from an innermost reduced-size contour to the contour at an outermost side.

A method for introducing a reflective and/or diffractive metallic variable and/or non-variable image to a substrate by use of thermal transfer printing includes simultaneously transferring a defined portion of each of a protective coating layer, a metal layer, and an adhesive layer from a carrier film of a transfer ribbon to the substrate by applying heat to the transfer ribbon. The defined portions of the metal layer and the protective coating layer are adhered to the substrate using the adhesive layer. Subsequent to transferring the protective coating layer, the metal layer, and the adhesive layer, durability is provided to the metal layer by cross-linking the protective coating layer that is over the metal layer by exposing the protective coating layer to a radiation source after the defined portions of the protective coating layer, the metal layer, and the adhesive layer are transferred from the carrier film.

A foil transfer device includes a first projector projecting light toward a foil film, and a second projector projecting light toward the foil film. The second projector and the first projector are staggered relative to each other.