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 light irradiator includes a light source and its drive, a heat-dissipating member, and a rectangular housing with vents and a light-emission opening. The housing includes a first surface having a first side with a first dimension and a second side with a second dimension, a second surface having the second side and a third side with a third dimension, and a third surface having the first and third sides. The light-emission opening is in the first surface. First and second vents are in the second surface, with the first vent nearer the opening than the second vent, and the second vent opposite to the opening. An axial fan and a first plate are at the second vent. The first plate faces the axial fan with a spacing less than or equal to the first dimension between them. A second plate outside the housing separates the first and second vents.

Digital printing machine for printing workpieces, including a print head carrier to which a print head for dispensing ink droplets in a printing direction and a drying unit for curing the ink droplets are attached, wherein the print head and the drying unit define a working space in which an application of a print image to an outer surface of a workpiece with the print head and a drying of the print image on the workpiece with the drying unit is provided, wherein the drying unit provides electromagnetic waves for a photochemical polymerization of the ink droplets, wherein the drying unit includes a radiation source to provide electromagnetic waves with an intensity maximum at a wavelength from the group of: 395 nanometers, 385 nanometers, 365 nanometers.

Disclosed are an inkjet print system and an inkjet printing method using the same. An inkjet print system according to one embodiment of the disclosure may include a stage on which a printing medium is loaded and which moves the printing medium in a first direction, an inkjet head which moves in a second direction perpendicular to the first direction and in which a plurality of nozzles configured to eject an ink on the printing medium are formed, a measurement instrument which moves in the second direction independent of the inkjet head and measures a height for each section of an impacted coating layer on the printing medium, and a processor which allows the nozzles to be opened or closed on the basis of height information of the coating layer.

An illumination control method of LED lamps for ink-jet printers including a recording head in which ink discharge printing ranges are formed in a printing direction and an LED lamp in which light emitting diodes are arranged at a rear side of the recording head with respect to the printing direction. In an ink-jet printer in which the light-emitting diodes are divided into plural areas and the light amount for each area can be individually controlled by a controller, and among the light-emitting diodes, the light amount of the light-emitting diode that first scans a glossy printed surface is set to a light amount that does not cause ink curing. The light amount of the light-emitting diode of the area that first scans is set so the total light amount on the glossy printed surface is less than or equal to the critical exposure amount of the integrated illuminance.

An apparatus for inkjet printing and curing process for performing on more than one side of a workpiece in one continuous sequential process, the workpiece is shaped as a cube configured with a first surface, a second surface opposite to the first surface, and side surfaces connected between the first surface and the second surface. The apparatus for inkjet printing and curing integration process comprises a base, a supporting module, a printing module, a rotary module, and a transporting module, wherein the transporting module moves the workpiece under the printing module for being printed and cured on one side, then the rotary module rotates the workpiece such that a different side is presented for inkjet printing and curing. The printing module thus performs a continuous inkjet printing and curing process on more than one side of a workpiece, and the working efficiency is improved.

A method for providing a substrate coating comprises transferring a substrate to an enclosed ink jet printing system; printing organic material in a deposition region of the substrate using the enclosed ink jet printing system, the deposition region comprising at least a portion of an active region of a light-emitting device on the substrate; loading the substrate with the organic material deposited thereon to an enclosed curing module; supporting the substrate in the enclosed curing module, the supporting the substrate comprising floating the substrate on a gas cushion established by a floatation support apparatus; and while supporting the substrate in the enclosed curing module, curing the organic material deposited on the substrate to form an organic film layer.

A recording device includes transport units, a corona irradiation unit, an ejecting unit, and a control unit, and changes intensity of irradiation, performed the corona irradiation unit, according to ejection density of the white ink, when a target recording medium is formed with a colored image with a colored ink on the background image after the target recording medium is formed with a background image with a white ink.

Provided is a light source device in which the housing is not full of heat, and the risk of inhaling dust in the housing or the risk of reduction of life of the fan device becomes reduced. In an aspect, a light source device according to the present disclosure includes a light source; a light source control unit for controlling turning on/off and a quantity of light of the light source; a cooling fan for cooling the light source; and a fan control unit for controlling a number of revolutions of the cooling fan, wherein the fan control unit is configured to: control the number of revolutions of the cooling fan to become a first number of revolutions depending on the quantity of light of the light source when the light source is turned on, and control the number of revolutions of the cooling fan to become a second number of revolutions lower than the first number of revolutions by waiting for a predetermined waiting time when the light source is turned off.

A liquid ejecting apparatus, a liquid ejecting method and an ink are provided, so as to appropriately increase the strength of ink after fixing. The liquid ejecting apparatus is configured to eject an ink by an inkjet method, and includes an inkjet head configured to eject the ink. The inkjet head has a nozzle configured to eject the ink. The ink includes a resin particle having a size capable of passing through the nozzle. The resin particle contains a fibrous substance. The fibrous substance is, for example, fibers of cellulose.