In one example of the disclosure, a print agent is applied upon a length of web substrate. A dryer is utilized to dry the web substrate length. Moisture is applied to the web substrate length. The moisturized web substrate length is wound upon a spool to form a top liner length, with no dryer to be utilized to dry the web substrate length between the moisture application and the winding.

In one example, a system for a partially dried inkjet media conditioner includes a heated pressure roller to apply pressure to a first side of partially dried inkjet media and apply heat to a second side of the partially dried inkjet media.

An overcoat to be applied to an ink printed on fabric or fabric to be printed with an ink, includes: an oxazoline group-containing compound.

A method for inkjet printing glass to have a metallic appearance by an inkjet process is disclosed herein. It comprises the following steps of cleaning and drying a glass to be inkjet printed; inkjet printing an ink bottom layer on a surface of the glass and a metallic ink layer on the ink bottom layer; and inkjet printing a transparent protective ink layer on the metallic ink layer.

The invention provides dispersed inorganic mixed metal oxide pigment compositions in a non-aqueous media utilizing a dispersant having polyisobutylene succinic anhydride structure to disperse a mixed metal oxide pigment in the media. The metal oxide pigment is of the type used to colour ceramic or glass articles. A milling process using beads is also described to reduce the mixed metal oxide particle size to the desired range. A method of using the mixed metal oxide dispersion to digitally print an image on a ceramic or glass article using the dispersion jetted through a nozzle and subsequently firing the coloured article is also described.

According to certain embodiments, a method of producing a pattern on a substrate comprises securing a flexible polymeric substrate, printing a layer of ink as a negative pattern on the substrate, and placing the flexible polymeric substrate in a vacuum chamber. The method further includes uniformly applying, while the flexible polymeric is under a vacuum in the vacuum chamber, a layer of material over both the layer of ink and the substrate via physical vapor deposition and then removing the flexible polymeric substrate from the vacuum chamber. The method further includes removing the ink and material applied over the ink by immersing the flexible polymeric substrate in a solvent such that it results in a desired pattern of the material on the flexible polymeric substrate.

A can curing oven including a housing assembly, a transfer assembly, and a number of heating units. The housing assembly defines a generally enclosed space. The transfer assembly is structured to support and move a number of can bodies. The transfer assembly includes an elongated transfer belt. The transfer belt is movably coupled to the housing assembly and is structured to move through the housing assembly enclosed space. The number of heating units are structured to generate an effective amount of received heat.

The ink jet recording method according to the invention is characterized by that at least one of an ink and a surface treatment agent contains a resin that melts or softens at a fixing temperature by heat treatment; the surface treatment agent contains at least two kinds of particles different in particle size that do not melt at the fixing temperature; the particles contain first particles and second particles having a particle size larger than that of the first particles; and the second particles have a particle size falling within a range of more than 50 nm to less than 110 nm.

Examples described herein include printing systems that include a transfer medium, a binder material applicator to apply a layer of binder material to a surface of the transfer medium, and a print engine to apply printing material to the layer of binder material. The system can also include a roller to press the transfer medium against a print medium to transfer the binder material and the printing material to the print medium.

A method for introducing a reflective and/or diffractive metallic variable and/or non-variable image to a substrate by use of thermal transfer printing includes simultaneously transferring a defined portion of each of a protective coating layer, a metal layer, and an adhesive layer from a carrier film of a transfer ribbon to the substrate by applying heat to the transfer ribbon. The defined portions of the metal layer and the protective coating layer are adhered to the substrate using the adhesive layer. Subsequent to transferring the protective coating layer, the metal layer, and the adhesive layer, durability is provided to the metal layer by cross-linking the protective coating layer that is over the metal layer by exposing the protective coating layer to a radiation source after the defined portions of the protective coating layer, the metal layer, and the adhesive layer are transferred from the carrier film.