A medium heating device is provided, which is configured to heat a medium that is conveyed in a state where liquid is ejected onto the medium, and which includes: a support unit configured to support the medium that is conveyed in a state where the liquid is ejected onto the medium; a first heater configured to heat a first surface, of the medium, onto which the liquid ejected; and a second heater configured to heat a second surface of the medium opposite from the first surface. A region heated by the second heater includes a region downstream from a region facing the first heater.

A medium heating device includes a heating unit configured to heat a medium; a first control unit and a second control unit configured to control the heating unit; and a housing including the first control unit and the second control unit inside the housing. Each of the first control unit and the second control unit includes an air inlet and an air outlet. The first control unit and the second control unit include an air intake and exhaust fan installed at at least one of the air inlet and the air outlet of the first control unit, and at at least one of the air inlet and the air outlet of the second control unit. The first control unit and the second control unit are disposed such that the air outlet of the first control unit and the air outlet of the second control unit face each other.

A method is provided for printing a surface of a non-absorbent substrate with an ink to be applied by an inkjet printing device. An ink that contains water as a solvent is used for printing the substrate. An ink having a water content of at least 70% is used. The substrate to be printed is supported by a workpiece support and is moved relative to the inkjet printing device. During this relative movement, ink is applied by the inkjet printing device to the surface of the substrate to be printed. The ink that is applied to the surface of the substrate is heated to a temperature that is above the temperature of the air surrounding the substrate and that is below the boiling point of the solvent contained in the ink. Above a liquid phase of the ink, a vapor layer, consisting of the solvent that is contained in the ink, is formed. The vapor layer that is formed above the liquid phase of the ink is transported away by an air flow emitted by at least one blower nozzle unit. The air output by the respective blower nozzle unit is heated or is dehumidified beforehand. A digital printing press is provided for carrying out this method.

A light irradiation device according to the disclosure comprises: a light source comprising a plurality of light-emitting elements; a heat-dissipating member thermally connected to the light source; an air blower section capable of blowing air on the heat-dissipating member; a drive section which drives the light source; and a housing which receives therein the light source, the heat-dissipating member, the air blower section, and the drive section, the housing comprising a plurality of ventilating slots serving as inlets and outlets for outside air, a lower face provided with an irradiation opening for external irradiation of light from the light source, a side face which is vertically oriented, and an inclined face which is located on an upper side of the housing and is opposed to the lower face, and the inclined face is provided with at least one ventilating slot.

Provided is an ink jet printer including an electromagnetic wave generator that includes an electromagnetic wave generation section, a high-frequency voltage generation section, a transmission line, an ink jet head, and a control section. The electromagnetic wave generation section includes a first electrode, a second electrode, a first coil coupled to the first electrode or the second electrode in series, an impedance matching circuit constituted by a second coil and a capacitor coupled between the first coil and the high-frequency source. A thin ink film discharged from the ink jet head and attached to the recording medium is heated and dried by the electromagnetic wave generator. The control section controls a constant of the second coil or a constant of the capacitor of the impedance matching circuit according to information on the thin ink film.

A method and equipment to form a digital print by applying dry colourants on a surface of a panel, bonding a part of the colourants with a binder and removing the non-bonded colourants from the surface. The method of forming a digital print on a surface of a panel includes displacing the panel under a digital drop application head, applying a liquid binder with the digital drop application head on the surface; applying colourants on the liquid binder and the surface; bonding a part of the colourants to the surface with the liquid binder; removing non-bonded colourants from the surface such that a digital print is formed by the bonded colourants; and applying heat and pressure on the panel, the surface and the bonded colorants such that the colourants are permanently bonded to the surface.

An example apparatus for determining dryness of an agent on print media includes an infrared prism, a source of infrared radiation to direct infrared radiation into the infrared prism, and a detector. The infrared prism includes a surface, the surface having an outer side to contact a portion of the agent on the print media, the infrared prism having a refractive index that is higher than a refractive index of the agent. The source of infrared radiation is to direct infrared radiation into the infrared prism and onto an inner side of the surface. The detector is to generate a signal based on infrared radiation reflected by the inner side of the surface to indicate the dryness of the portion of the agent.

An inkjet printing apparatus for printing on a substrate, such as a flexible packaging material, includes at least three inkjet heads including a first inkjet head, a second inkjet head, and at least one further inkjet head. At least one drying unit includes a first drying unit arranged opposite a first drying location which is located between the first and second inkjet location, the first drying unit being configured for physically removing liquid from ink applied by the first inkjet head. At least a first drum and a second drum, where the first and second inkjet locations as well as the first drying location are located on an outer surface of the first drum; and the at least one further inkjet location is located on an outer surface of the second drum.

A system for printing at least one stretchable ink on a thermoformable substrate including a first surface and a second surface opposite the first surface. The system includes an unwinder, a printing module and a rewinder. The unwinder is arranged to feed the thermoformable substrate from a first roll into a printing module. The printing module includes a flood coater arranged to deposit a coating layer on the first surface of the thermoformable substrate. The rewinder is arranged to receive the thermoformable substrate and to form the thermoformable substrate into a second roll.

A structure forming apparatus includes a printing unit which prints a photo-thermal conversion material, a white material, and a coloring material in order on an expanding layer in an overlapping manner, where the expanding layer is expanded when heated with thermal energy of light. The apparatus also includes a heating unit which irradiates light on the expanding layer from a side of the coloring material to expand the expanding layer, and a controlling unit which sets a printing density of the photo-thermal conversion material lower by a level corresponding to a quantity of heat conducted from the coloring material than the printing density of the photo-thermal conversion material to be printed when the coloring material has no photo-thermal conversion characteristic in the case in which the coloring material has photo-thermal conversion characteristic, and prints the photo-thermal conversion material of the set printing density.