A system for transferring graphical representations on an object by sublimation is provided. The system has a first loading device configured to load on a work plane, a support having a graphical representation to be transferred, a second loading device configured to load, the object over the support on the work plane. The system further includes a sublimation apparatus having a catenary, and a plurality of pendulum components hooked to the catenary, each component having ends and jaws configured to cooperate with the work plane so that, by suction, said support wraps the object, is made to adhere to the object and is moved together with the object by way of the catenary in an oven arranged for transferring the support graphical representation from the support to the object. The invention relates also to a method for transferring graphical representations on an object by sublimation.

The present invention relates to a method for decorating a drinking or eating vessel, the method comprising: a. providing: i. a drinking or eating vessel, wherein the vessel comprises an inner surface that defines a volume for receiving a liquid or a solid food and an outer surface comprising a polymeric coating; and ii. a transfer sheet, wherein the transfer sheet comprises a printed decoration; and iii. a supporting means comprising a recess for receiving the vessel; and b. arranging the vessel within the recess of the supporting means thereby defining a lower portion of the outer surface of the vessel occluded from contact with the transfer sheet and an upper portion of the outer surface of the vessel for contacting the transfer sheet; and contacting the upper portion of the outer surface of the vessel and the supporting means with the transfer sheet under at least a partial vacuum, wherein the printed decoration is transferred from the transfer sheet to the upper portion of the outer surface of the vessel, and wherein the supporting means reduces stretching of the transfer sheet from the upper portion of the outer surface of the vessel to the lower portion of the outer surface of the vessel. Also described are associated uses, an apparatus, and drinking or eating vessels obtainable by the methods of the invention.

An ink film construction comprising: (a) a printing substrate; and (b) at least one ink film, fixedly adhered to a top surface of the printing substrate, the ink film having an upper film surface distal to the top surface of the substrate, wherein a surface concentration of nitrogen at the upper film surface exceeds a bulk concentration of nitrogen within the film, the bulk concentration measured at a depth of at least 30 nanometers below the upper film surface, and wherein a ratio of the surface concentration to the bulk concentration is at least 1.1 to 1.

Systems and methods are provided for thermal sublimation imaging and more generally thermal pressing through a continuous or intermittent feed-through thermal pressing system. Cutting assemblies may be configured to cut, connect, advance, and/or align transfer media. The transfer media may have images created using inks, dyes, or the like that are configured to be sublimated into a substrate material within a sublimation assembly. The substrate may be interposed between upper and lower transfer media to allow for dual-side imaging via thermal sublimation. A thermal sublimation chamber may include a pre-confinement zone to reduce ghosting, a preheat zone, a thermal saturation zone to effectuate sublimation and image transfer, and/or a post-sublimation cooling zone to reduce ghosting. A post-sublimation collection system may separate transfer media from substrate(s).

An ink film construction comprising: (a) a printing substrate; and (b) at least one ink film, fixedly adhered to a top surface of the printing substrate, the ink film having an upper film surface distal to the top surface of the substrate, wherein a surface concentration of nitrogen at the upper film surface exceeds a bulk concentration of nitrogen within the film, the bulk concentration measured at a depth of at least 30 nanometers below the upper film surface, and wherein a ratio of the surface concentration to the bulk concentration is at least 1.1 to 1.

An ink film construction including: (a) a printing substrate; and (b) at least one ink film, fixedly adhered to a top surface of the printing substrate, the ink film having an upper film surface distal to the top surface of the substrate, wherein a surface concentration of nitrogen at the upper film surface exceeds a bulk concentration of nitrogen within the film, the bulk concentration measured at a depth of at least 30 nanometers below the upper film surface, and wherein a ratio of the surface concentration to the bulk concentration is at least 1.1 to 1.

An inkjet printer for forming, on a base, an image layer and an adhesive layer on which foil is to be formed includes a first head, a second head, and processing circuitry. The first head discharges an ink for the image layer. The second head discharges inks for the adhesive layer including a first ink and a second ink. The second ink has a lower wet spreadability than a wet spreadability of the first ink. The processing circuitry controls the second head to form an image area included in the adhesive layer with the second ink in a case where a width of the image area is less than a threshold, and form the image area with the first ink in a case where the width of the image area is not less than the threshold.

A laser transfer printing device and a laser transfer printing method are provided. The laser transfer printing device includes a laser, a beam expander, a beam splitter and a focusing module. The laser is configured to generate a laser beam. The beam expander is disposed on an optical path of the laser beam generated by the laser to expand the laser beam generated by the laser. The beam splitter is disposed on an optical path of the laser beam expanded by the beam expander to reflect the expanded laser beam to the focusing module. The focusing module is disposed on an optical path of the laser beam reflected by the beam splitter to focus the laser beam and project the focused laser beam to a predetermined transfer processing position.

An image forming system capable of performing foil stamping printing, which appropriately selects a color of a toner used as an adhesive on the basis of setting regarding the foil stamping printing, is provided. The image forming system includes an image former, a processor, and a foil transfer. The image former has a plurality of imaging units that form an image by toners of different colors. The processor is capable of receiving various types of setting regarding the foil stamping printing, and selects an image formation color, which is a color to be used for forming a foil stamping image, on the basis of the received setting. The foil transfer transfers a foil on the foil stamping image, which is formed by the image former, by using the toner of a color corresponding to the image formation color selected by the processor.

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.