An illustrative dye sublimation apparatus may include a sealed chamber and a heating section. More specifically, the sealed chamber is thermally insulated and substantially airtight in order to keep the heat generated by the heating section within the sealed chamber. Compared to the conventional systems that are open-air and require direct heat, the embodiments disclosed herein generate a uniform or nearly uniform heat distribution throughout the sealed chamber, which results in a more consistent and efficient dye sublimation process.

An illustrative dye sublimation apparatus (also referred to as a dye sublimation machine) may have at least four stations, each station implementing a discrete step of a sublimation cycle. Multiple beds are rotatably mounted such that the beds pass through the stations to perform the corresponding steps. Therefore, the sublimation apparatus may perform multiple sublimation cycles simultaneously with the beds containing printed sheets and substrates at different steps of the multiple sublimation cycles. As the beds are rotatably mounted, the sublimation apparatus may allow for a fixed loading and unloading station proximate to a fixed, dedicated personnel station.

There are disclosed methods for producing curable elastomeric compositions comprising carbon black particles, as well as their corresponding cured products. Such compositions, once cured, can be used for the preparation of numerous articles of wide industrial applicability.

An illustrative dye sublimation apparatus may comprise a pressure housing in the heating component. The pressure housing may apply a positive pressure on a membrane covering a combination of a printed sheet and a substrate. The positive pressure applied by the pressure housing may cause the printed sheet and substrate to snugly press against each other throughout a heating cycle. Furthermore, the positive pressure applied by the pressure housing may be even or approximately even throughout an upper surface of the membrane. The dye sublimation apparatus may utilize the pressure housing in addition or as an alternative to a negative pressure applied by a vacuum pump.

The present invention relates to a continuous printing apparatus using a vacuum suction roller, and it is to provide a continuous printing apparatus and method using a vacuum suction roller capable of reducing costs and improving productivity by continuously printing on the surface of a woven fabric using the vacuum suction roller.

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.

The present invention relates to a continuous printing apparatus using a vacuum suction roller, and it is to provide a continuous printing apparatus and method using a vacuum suction roller capable of reducing costs and improving productivity by continuously printing on the surface of a woven fabric using the vacuum suction roller.

Method and system for thermal transfer printing are disclosed. The system includes a transfer member having an imaging surface on the front side, a coating station at which a monolayer of particles made of, or coated with, a thermoplastic polymer is applied to the imaging surface, an imaging station at which electromagnetic radiation (EM) is applied via the rear side of the transfer member to selected regions of the particles-coated imaging surface to render the particles thereon tacky within the selected regions, and a transfer station at which only the regions of the particles coating that have been rendered tacky are transferred to a substrate. The transfer member includes on its rear side a body transparent to EM radiation and on its front side an EM radiation absorbing layer, the imaging surface being formed on, or as part of, the absorbing layer.

A method for printing uses at least one ink. The method includes: a step of focusing a laser beam so as to generate a cavity in an ink film; a step of forming at least one ink droplet from a free surface of the ink film; and a step of depositing the droplet onto a depositing surface of a receiving substrate positioned at a given distance from the film. The laser beam is oriented in the direction opposite the gravitational force. The free surface of the film is oriented upwards towards the depositing surface placed above the ink film.

Examples relate to methods to print a garment and sublimation devices. A sublimation device comprises a heating system to heat an air flow and a holder to receive a garment. The holder comprises an outer surface to contact an inner side of the garment opposite to an outer side of the garment in which a print agent is to be deposited and an opening on the outer surface in fluid communication with the heated air flow.