A printing apparatus comprises a depositing device and a sublimation device. The depositing device may deposit a print fluid on a first surface of a print medium. The print fluid comprises a sublimation agent to sublimate at a sublimation temperature. The sublimation device may sublimate the sublimation agent deposited on the print medium by generating heat radiation in a direction from a second surface of the print medium towards the first surface, the second surface being opposite to the first surface.

Pattern transfer sheets and methods are provided for printing paste patterns (e.g., thin fingers) with a high aspect ratio and for increasing throughput in pattern transfer printing. Trenches in the pattern transfer sheets, that are configured to be filled with printing paste and to enable releasing the printing paste from the trenches onto a receiving substrate upon illumination by a laser beam—are coated internally by a coating configured to disintegrate upon the illumination. The coating is configured to enhance the releasing of the paste—increasing throughput and printing accuracy. The receiving substrate may be cleaned after paste deposition by removing disintegration products of the coating therefrom. Alternatively or complementarily, laser absorbing dye may be mixed into the printing paste to facilitate its release from the trenches.

An illustrative dye sublimation apparatus may include a texture sheet with a pattern to be applied to a substrate. More specifically, the texture sheet is pressed into the substrate during the dye sublimation process in order to apply the pattern from the texture sheet while the substrate is heated and simultaneously being infused with an image from a printed sheet. The pressure applied to the texture sheet can vary, for example based on the temperature. Compared to the conventional systems in which substrates are pre-textured, the embodiments disclosed herein describe a process for simultaneous image-infusion and texture-application, which results in a substrate that is both infused and textured.

An illustrative dye sublimation apparatus may include a texture sheet with a pattern to be applied to a substrate. More specifically, the texture sheet is pressed into the substrate during the dye sublimation process in order to apply the pattern from the texture sheet while the substrate is heated and simultaneously being infused with an image from a printed sheet. The pressure applied to the texture sheet can vary, for example based on the temperature. Compared to the conventional systems in which substrates are pre-textured, the embodiments disclosed herein describe a process for simultaneous image-infusion and texture-application, which results in a substrate that is both infused and textured.

Methods and systems for adjusting formulation of pigments for dye sublimation are disclosed. In one embodiment, the method includes receiving, by a processor, a selection of the substrate and the image to be dye sublimated into the substrate. The method also includes determining, by the processor, an amount of each pigment of sublimation ink to be used to print the image on a sheet based on a characteristic of the substrate. The method further includes printing, by a dye sublimation apparatus, the image on the sheet using the amount of each pigment of sublimation ink and infusing, by the dye sublimation apparatus, the image from the sheet into the substrate.

Methods and systems for adjusting formulation of pigments for dye sublimation are disclosed. In one embodiment, the method includes receiving, by a processor, a selection of the substrate and the image to be dye sublimated into the substrate. The method also includes determining, by the processor, an amount of each pigment of sublimation ink to be used to print the image on a sheet based on a characteristic of the substrate. The method further includes printing, by a dye sublimation apparatus, the image on the sheet using the amount of each pigment of sublimation ink and infusing, by the dye sublimation apparatus, the image from the sheet into the substrate.

An illustrative dye sublimation apparatus may include a pair of printed sheets placed on either side of a substrate that allows for image infusion on both sides of the substrate. A second heat source, such as a heated plate, is included in order to heat the second printed sheet. Compared to the conventional systems in which a single heat source heats a single printed, the embodiments disclosed herein describe a process for simultaneous double-sided image infusion, which results in a substrate with sublimated images on both sides.

A thermal transfer sheet, a combination of an intermediate transfer medium and a thermal transfer sheet, method for producing a printed material using the thermal transfer sheet, and a decorative material, wherein the thermal transfer sheet includes a transfer layer on one surface of a substrate, the transfer layer having a single layer structure consisting only of a heat seal layer or a multilayer structure including a heat seal layer, and in a case where the transfer layer has the multilayer structure, the heat seal layer among the layers constituting the transfer layer is positioned closest to the substrate. The heat seal layer contains one or both of (i) a polyester having a glass transition temperature (Tg) of 55° C. or more and a number average molecular weight (Mn) of 15000 or less, and (ii) a polyester having a glass transition temperature (Tg) of less than 55° C.

A thermal transfer sheet, a combination of an intermediate transfer medium and a thermal transfer sheet, method for producing a printed material using the thermal transfer sheet, and a decorative material, wherein the thermal transfer sheet includes a transfer layer on one surface of a substrate, the transfer layer having a single layer structure consisting only of a heat seal layer or a multilayer structure including a heat seal layer, and in a case where the transfer layer has the multilayer structure, the heat seal layer among the layers constituting the transfer layer is positioned closest to the substrate. The heat seal layer contains one or both of (i) a polyester having a glass transition temperature (Tg) of 55° C. or more and a number average molecular weight (Mn) of 15000 or less, and (ii) a polyester having a glass transition temperature (Tg) of less than 55° C.

A method for manufacturing a tableware article having a thermal-transfer printed pattern includes the following steps. Firstly, a PET resin composition including 3 to 15% by weight of an inorganic filler is provided. Next, the PET resin composition is granulated to obtain plastic granules. Then, the plastic granules are molded into the tableware article and the tableware article is post-crystallized. Finally, a thermal transfer printed pattern is printed on a surface of the post-crystallized tableware article.