A heat transfer film having a) a carrier film, b) at least one coating layer arranged directly on the carrier film, and c) at least one hot-sealable polymer adhesive layer is disclosed. The coating layer is based on a non-aqueous, radiation-curable, liquid composition which contains at least 60 wt %, based on the total weight of the composition, of curable constituents selected from organic oligomers which have ethylenically unsaturated double bonds. Use of the heat transfer films for the dry coating of surfaces, production of such heat transfer films, and methods for coating or lacquering surfaces of objects using the heat transfer films are also disclosed.

Printing process in which a substrate to be printed is disposed opposite an ink carrier having an ink layer, the ink layer being irradiated regionally by a laser beam, said layer accelerating by absorption of the laser beam in the substrate direction, wherein for laser absorption the ink layer comprises reflective particles, a solvent, and a soluble polymer, wherein the reflective particles have an aspect ratio>25, the aspect ratio being defined as the average particle size/average particle thickness.

A three-dimensional out sole having a pattern having improved quality and durability has a dye permeated into the surface of the outsole. A depth to which the dye penetrating the micropores is 0.08 mm to 0.12 mm. The dye is permeated into the microspores through vacuum suction. The dye is digitally printed on a thermoplastic sheet. The thermoplastic sheet on which the dye is printed is heated to be softened with flexibility. The softened sheet having flexibility is closely attached to a surface of the shoe outsole having the three-dimensional shape through vacuum adsorption and then is permeated therein.

A plastic card is printed on by transferring an adhesive to a surface of the plastic card from a thermal transfer ribbon using a thermal printhead. A donor material is then applied over the transferred adhesive to adhere the donor material to the card surface with portions of the card surface not containing the transferred adhesive not being covered by the donor material. The techniques described herein permit the addition of high value features, such as three dimensional features, matte finishes, metallic or metallic appearing features, optical structures, and the like, to the surfaces of plastic cards. In addition, the techniques described herein can be integrated into existing card processing systems, such as central issuance card processing systems, that use thermal printing technology.

A plastic card is printed on by transferring an adhesive to a surface of the plastic card from a thermal transfer ribbon using a thermal printhead. A donor material is then applied over the transferred adhesive to adhere the donor material to the card surface with portions of the card surface not containing the transferred adhesive not being covered by the donor material. The techniques described herein permit the addition of high value features, such as three dimensional features, matte finishes, metallic or metallic appearing features, optical structures, and the like, to the surfaces of plastic cards. In addition, the techniques described herein can be integrated into existing card processing systems, such as central issuance card processing systems, that use thermal printing technology.

A foil transfer method of performing foil transfer onto a surface of a transfer subject includes preparing a foil transfer tool including a light output portion, preparing the transfer subject and a transfer foil, stacking the transfer foil and a light absorbing film with optical absorptivity on a surface, of the transfer subject, on which the foil transfer is to be performed, to produce a stack body, and while moving either one of the stack body and the foil transfer tool with respect to the other, putting the foil transfer tool into contact with a surface of the stack body at which the light absorbing film is provided and outputting light from the light output portion.