A combined receipt and label roll comprises a core, and a web having a longitudinally-extending axis and wound on the core along the axis. The web includes (i) a substrate having a front side and a back side opposite the front side, (ii) a thermally-sensitive coating disposed on the front side of the substrate, and (iii) a water-based microsphere adhesive disposed on the back side of the substrate along the web axis. The water-based microsphere adhesive comprises at least four separate adhesive patches. The at least four adhesive patches are both sized relative to each other and positioned relative to each other on the back side of the substrate such that additional tack desired can be obtained by increasing volume of the adhesive patches without having to increase coat weight of the adhesive patches.

A thermal transfer sheet includes a substrate and a transfer layer, in which the transfer layer after transfer has a reduced peak height (Spk) of 0.6 μm or more. A method for producing a printed material using a thermal transfer sheet including a particle layer disposed on a substrate and an image-receiving sheet including a thermal protrusion-and/or-recess forming layer and a receiving layer stacked in that order on a second substrate, the receiving layer including an image that has been formed, includes the steps of heating the image-receiving sheet to form a protrusion and/or a recess at the image-receiving sheet, and heating the thermal transfer sheet to transfer the particle layer to at least part of the protrusion of the image-receiving sheet.

A thermal transfer sheet includes a substrate and a transfer layer, in which the transfer layer after transfer has a reduced peak height (Spk) of 0.6 μm or more. A method for producing a printed material using a thermal transfer sheet including a particle layer disposed on a substrate and an image-receiving sheet including a thermal protrusion-and/or-recess forming layer and a receiving layer stacked in that order on a second substrate, the receiving layer including an image that has been formed, includes the steps of heating the image-receiving sheet to form a protrusion and/or a recess at the image-receiving sheet, and heating the thermal transfer sheet to transfer the particle layer to at least part of the protrusion of the image-receiving sheet.

A label comprises a facestock adapted to be adhered or attached to an object. A direct thermal coating is on the facestock, the direct thermal coating configured to selectively darken by heat activation when direct thermal printed. A cured ultraviolet coating is on the direct thermal coating, the cured ultraviolet coating having photoinitiators with substantial activation at an exposure limited to radiation at a 315 nm-450 nm wavelength range, and configured to allow direct thermal printing of the direct thermal coating therethrough. The ultraviolet coating is cured without heat activating the direct thermal coating.

A label comprises a facestock adapted to be adhered or attached to an object. A direct thermal coating is on the facestock, the direct thermal coating configured to selectively darken by heat activation when direct thermal printed. A cured ultraviolet coating is on the direct thermal coating, the cured ultraviolet coating having photoinitiators with substantial activation at an exposure limited to radiation at a 315 nm-450 nm wavelength range, and configured to allow direct thermal printing of the direct thermal coating therethrough. The ultraviolet coating is cured without heat activating the direct thermal coating.

The present invention further relates a sublimation printing process of a multilayer system comprising a polyester top layer and at least one heat sensitive polymer layer whereby a temperature gradient is applied during sublimation printing such that the heat sensitive polymer layer is maintained at a temperature below its melting temperature and the polyester top layer is maintained at a temperature above its glass transition temperature to allow diffusion of a sublimation dye into the polyester top layer. The temperature gradient is maintained by using a heat sink element beneath the heat sensitive polymer layer. The temperature gradient can also be maintained by cooling the heat sink element. The cooling preferably occurs with a circulating coolant. The heat sink element comprises a polymer, a ceramic or a metal. The invention further relates to a sublimation printed multilayer system comprising a polyester top layer and at least one heat sensitive polymer layer. The present invention also relates to the multilayer system in the manufacturing of textile, tents, outdoor gear, apparel, clothing, bags, jackets, gloves.

A thermal transfer sheet includes a dye layer disposed on a first surface of a substrate film. The dye layer includes a decolorizable dye. The decolorizable dye has a color difference ΔE*ab between a color A and a color B of 10 or less, where the color A is a color of a transfer-receiving body before the decolorizable dye is transferred to the transfer-receiving body, the color B is a color of a portion of the transfer-receiving body with the decolorizable dye having been transferred thereto, and the color of the portion is a color after the portion is irradiated by a xenon lamp at an irradiation intensity of 1.2 (W/m.sup.2) for 50 hours, the portion having a reflection density of 0.5 or greater before being irradiated by the xenon lamp.

A thermal transfer sheet includes a dye layer disposed on a first surface of a substrate film. The dye layer includes a decolorizable dye. The decolorizable dye has a color difference ΔE*ab between a color A and a color B of 10 or less, where the color A is a color of a transfer-receiving body before the decolorizable dye is transferred to the transfer-receiving body, the color B is a color of a portion of the transfer-receiving body with the decolorizable dye having been transferred thereto, and the color of the portion is a color after the portion is irradiated by a xenon lamp at an irradiation intensity of 1.2 (W/m.sup.2) for 50 hours, the portion having a reflection density of 0.5 or greater before being irradiated by the xenon lamp.

A combination of a thermal transfer sheet and an intermediate transfer medium of the present disclosure is characterized in that the thermal transfer sheet includes a first substrate and a coloring layer, a peel-off layer, and a heat seal layer disposed on the first substrate; the intermediate transfer medium includes a second substrate and a transfer layer; the peel-off layer is a layer for removing a portion of the transfer layer from the intermediate transfer medium; and an absolute value of a difference in 45-degree specular gloss between the heat seal layer and the transfer layer is 20% or more.

A combination of a thermal transfer sheet and an intermediate transfer medium of the present disclosure is characterized in that the thermal transfer sheet includes a first substrate and a coloring layer, a peel-off layer, and a heat seal layer disposed on the first substrate; the intermediate transfer medium includes a second substrate and a transfer layer; the peel-off layer is a layer for removing a portion of the transfer layer from the intermediate transfer medium; and an absolute value of a difference in 45-degree specular gloss between the heat seal layer and the transfer layer is 20% or more.