A printing apparatus includes an ejection head including a first nozzle row configured to eject, toward a recording medium, a first liquid containing a photopolymerization initiator and a second nozzle row configured to eject, toward the recording medium, a second liquid containing the polymerizable compound and a color material and not containing the photopolymerization initiator, a driving unit configured to change relative positions of the ejection head and the recording medium, and an irradiation unit configured to irradiate, with the light, the recording medium onto which the first liquid and the second liquid are deposited. The first liquid and the second liquid are ejected from the ejection head so that the second liquid overlaps the first liquid on a surface of the recording medium. A distance between the irradiation unit and the first nozzle row is longer than a distance between the irradiation unit and the second nozzle row.

There is provided a printer including a head configured to discharge a liquid onto a printing surface of a printing medium, the liquid being curable by applying energy; an energy applying unit; a moving device which relatively moves the head and the energy applying unit with respect to the printing medium; and a controller. The controller executes discharge of the liquid from the head onto the printing surface while relatively moving the head and the printing medium; application of first energy and second energy from the energy applying unit to the liquid, while relatively moving the energy applying unit and the printing medium; and decision of an added-up energy amount of the first energy applied to the liquid on the printing surface from the energy applying unit until the second energy is applied after the application of the first energy depending on a state of the printing surface.

A printer includes a head, a lamp, a first sensor, and a processor. The head is configured to eject photocurable ink onto the object to be printed supported by a platen. The lamp is configured to irradiate light onto the object to be printed on which the ink is ejected. The first sensor is provided inside the printer, and is configured to detect a temperature inside the printer. The processor causes the first sensor to acquire the temperature inside the printer. The processor acquires, based on the print data, a duty ratio indicating a printing ratio when ejecting the ink onto an ejection region of the object to be printed. The processor sets an illuminance of the light irradiated by the lamp, based on the temperature acquired by the first sensor and the acquired duty ratio.

A printer includes a head, a lamp, a first sensor, and a processor. The head is configured to eject photocurable ink onto the object to be printed. The lamp is configured to irradiate light onto the object to be printed. The first sensor is configured to detect a temperature inside the printer. The processor causes the first sensor to acquire the temperature inside the printer. The processor acquires, based on the print data, a duty ratio indicating a printing ratio when ejecting the ink onto an ejection region of the object to be printed. The processor increases a number of times of a flushing operation compared to a predetermined reference number of times, when the acquired duty ratio is a low duty ratio lower than a predetermined reference duty ratio, and the temperature detected by the first sensor is higher than a predetermined reference temperature.

An aqueous inkjet printer also ejects drops of UV material on an aqueous ink image and exposes the aqueous ink image and the UV material to UV radiation before passing the aqueous ink image and UV material through a thermal dryer. The exposure to UV radiation pins the UV material to the aqueous ink image and underlying substrate and the thermal dryer fixes the aqueous ink image to the substrate while releasing free radicals from the UV material. Thus, the printer produces textured prints that do not have free radicals that can irritate skin or produce noxious odors.

A printer includes a platen, a head, and an irradiation device. The platen is configured to support a printing object and to move the printing object in a first scanning direction. The head is configured to move in a second scanning direction relative to the printing object. The second scanning direction crosses the first scanning direction. The head ejects light-curable ink onto the printing object. The irradiation device is configured to move in the second scanning direction relative to the printing object. The irradiation device irradiates light onto the light-curable ink deposited on the printing object. The irradiation device includes a first light source configured to emit light having a first wavelength, and a second light source configured to emit light having a second wavelength different from the first wavelength. The first and second light sources are disposed on one side of the head in the second scanning direction.

A curing device includes a light emitting member, and a control device. The light emitting member has a light source configured to emit light to cure liquid on a printing medium. The light source and the printing medium are configured to be located with a gap therebetween. The gap is variable among a plurality of distances including a first distance and a second distance greater than the first distance. The control device is configured to perform: controlling the light source to emit light of an intensity based on the gap so that the intensity when the gap is the second distance is greater than when the gap is the first distance.

Provided is an inkjet printing device including an ink storage unit configured to store an ink, an ejection head configured to eject the ink to form a print layer, and a heating unit configured to heat a material to be printed, wherein the ink is an aqueous clear ink including a resin and water, the inkjet printing device has a low gloss printing mode that is a printing mode for imparting low gloss, and a high gloss printing mode that is a printing mode for imparting high gloss, and the heating unit is configured to heat to satisfy the following formula T.sub.matte>T.sub.gloss, where T.sub.matte (degrees Celsius) is a temperature of a low gloss printing region of the material to be printed where the low gloss printing region is printed with the low gloss printing mode when the aqueous clear ink is deposited on the material to be printed, and T.sub.gloss (degrees Celsius) is a temperature of a high gloss printing region of the material to be printed where the high gloss printing region is printed with the high gloss printing mode when the aqueous clear ink is deposited on the material to be printed.

The invention relates to an ink jet printer having a print carriage, a curing unit and a holder arranged to move a recording medium relative to the carriage assembly in a sub-scanning direction, wherein the print carriage is movable in a main scanning direction normal to the sub-scanning direction, and a print head unit arranged on the print carriage for printing a swath of an image onto the recording medium in each scan pass of the print carriage, the print carriage further having a mirror assembly arranged to deflect light from the curing unit onto an exposure area on the printed swath.

A printing apparatus includes a printing unit configured to form an ink image by discharging ink on a medium, and a heating unit configured to heat the ink image on the medium. The heating unit includes a heat generating unit configured to generate radiant heat, a reflecting unit that includes a reflecting surface configured to reflect the radiant heat of the heat generating unit, and a cooling unit configured to cool the reflecting surface by supplying a gas to the reflecting surface.