A drying unit for a printing device for printing with ink to a recording medium in the form of a web includes at least one heating element. The recording medium to be dried is movable along an emission region of the heating element. The emission region is arranged angled in the transport direction of the recording medium.

A transport device includes a transport unit that transports a sheet-like transport material without holding a one-end-side portion of the transport material in a transport direction; and a blowing unit that blows air against a lower surface of the transport material that is transported by the transport unit via multiple blowing holes that open with respect to the lower surface, an arrangement interval of the multiple blowing holes in the transport direction being inconstant in the transport direction.

A liquid ejecting apparatus includes a transport unit that transports a medium, an ejecting unit that ejects a liquid onto the medium in an ejection area, a mist-collecting unit that collects mist that occurs with the ejection of the liquid from the ejecting unit, and a contaminant-collecting unit that is formed upstream of the ejection area in a transport direction of the medium and that collects contaminants that have attached to the medium.

A printing apparatus includes a head which discharges liquid onto a printing medium; and a light irradiation unit which is aligned with the head in a first direction and which irradiates the liquid on the printing medium with light. The light irradiation unit has light source arrays arranged in the first direction, each of the light source arrays includes light sources aligned in a second direction, and the light source arrays include a first light source array which is disposed most closely to the head in the first direction. The light, which is radiated by each of the light sources included in the first light source array, has an intensity that is smaller than an intensity of the light which is radiated by each of the light sources included in the light source arrays different from the first light source array.

An ink jet printing method includes a metallic ink application step of ejecting a metallic ink composition containing a metallic pigment from an ink jet head to apply the metallic ink composition onto a printing medium, a heating step of heating the metallic ink composition applied on the printing medium with an infrared heater, and a coloring ink application step of ejecting a coloring ink composition containing a coloring material from an ink jet head to apply the coloring ink composition onto the metallic ink composition on the printing medium. Each of the metallic ink composition and the coloring ink composition is a water-based ink or a solvent-based ink.

A liquid discharging apparatus includes a head that discharges a liquid onto a medium, a medium supporting portion that supports the medium, a heater that heats the medium supported by the medium supporting portion, and a detecting unit that performs sensing and detects energy. The radiation energy of the heater is controlled on the basis of the energy detected by the detecting unit. The medium supporting portion is provided with a sensing target portion that can be sensed by the detecting unit.

A recording method includes: ejecting aqueous ink to a surface of a recording medium by an ejection head, the aqueous ink containing a colorant, polymer particles having a glass-transition temperature Tg of 35° C. to 65° C., and a solvent containing water and an aqueous organic solvent, the aqueous ink having a viscosity ratio (V35/Vi) of a viscosity V35 that is obtained when the aqueous ink is heated at 35° C. for 30 minutes to an initial viscosity Vi of the aqueous ink being lower than 2.0 and a viscosity ratio (V65/Vi) of a viscosity V65 that is obtained when the aqueous ink is heated at 65° C. for 30 minutes to Vi being 8.0 to 20.0; and drying the aqueous ink ejected to the recording medium. The head temperature Th of the ejection head, the glass-transition temperature Tg, and the drying temperature Td satisfy an expression: Th<Tg<Td.

An ejection surface extends in a first direction as a scanning direction and a second direction orthogonal to the first direction and is externally exposed. A plurality of nozzles opens at the ejection surface. A plurality of partial channels is located inside the ejection surface, and at bottom surfaces on a side of the ejection surface, the nozzles open. The plurality of nozzles is arranged in a direction intersecting with the first direction in plural rows to constitute a plurality of nozzle rows. The number of the nozzles arranged in each row is greater than the number of the plural rows. Between the nozzles in each nozzle row, the nozzles in other nozzle rows appear as seen in the first direction. A position of openings in the bottom surfaces of the partial channels differs across at least some of the nozzles in each nozzle row.

A printing apparatus includes a transport unit for transporting a continuous sheet, a printing unit for printing by discharging ink to the continuous sheet, and a drying unit for drying the ink deposited on the continuous sheet. The drying unit includes a first heater unit for heating a printed surface of the continuous sheet and a second heater unit for heating the opposite surface of the continuous sheet to the printed surface. The first heater unit includes a plurality of first heaters that are disposed at the same position in a transport direction and that are arranged in width directions. The second heater unit includes a plurality of second heaters that are disposed at a position superposed on the first heater unit in the transport direction and that are disposed at positions between adjacent ones of first heating elements of the first heaters in the width directions.

A dye printing method and an ink capable of performing printing on more types of media than in the related art are shown. A dye printing method using ink 10 containing a solvent 11, and particles of a thermoplastic resin dispersed in the solvent 11 and containing a dye 13 is characterized by including a printing process of performing a printing on a medium 20 with the ink 10, a particle fixing process of fixing the particles 12 to the medium 20 by drying the solvent 11 of the ink 10 ejected to the medium 20 by the printing process, and a resin fixing process of fixing the thermoplastic resin to the medium 20 by heating the particles 12 fixed to the medium 20 by the particle fixing process, at least at a glass-transition temperature or higher.