An illustrative dye sublimation apparatus may include a sealed chamber and a heating section. More specifically, the sealed chamber is thermally insulated and substantially airtight in order to keep the heat generated by the heating section within the sealed chamber. Compared to the conventional systems that are open-air and require direct heat, the embodiments disclosed herein generate a uniform or nearly uniform heat distribution throughout the sealed chamber, which results in a more consistent and efficient dye sublimation process.

An illustrative dye sublimation apparatus (also referred to as a dye sublimation machine) may have at least four stations, each station implementing a discrete step of a sublimation cycle. Multiple beds are rotatably mounted such that the beds pass through the stations to perform the corresponding steps. Therefore, the sublimation apparatus may perform multiple sublimation cycles simultaneously with the beds containing printed sheets and substrates at different steps of the multiple sublimation cycles. As the beds are rotatably mounted, the sublimation apparatus may allow for a fixed loading and unloading station proximate to a fixed, dedicated personnel station.

The present invention provides a method of multi-pass inkjet printing comprising: (i) providing an inkjet ink comprising a radiation-curable monomer and a photoinitiator; (ii) jetting the ink via a printhead on to a substrate, wherein the ink is applied in multiple passes of the printhead with respect to the substrate, with each pass jetting a portion of ink in a layer on the substrate, with a first layer being jetted directly on to the substrate and subsequent layers being jetted onto the preceding layer, to build an image formed of the multiple layers; and (iii) exposing all of the layers of ink to actinic radiation to cure the ink, wherein the order of jetting the layers and curing is that pairs of layers are applied to the substrate without exposing the first layer of the pair to actinic radiation prior to the second layer of the pair of layers being applied, curing the pair of layers simultaneously by exposing the pair of layers to actinic radiation, and repeating until the image is formed.

A conveyor line system including an image processing device configured to irradiate a recording part with laser light to perform at least one of image recording and image erasing, the conveyor line system being configured to manage at least one conveying container each including: the recording part in which the image recording is performed by irradiation with the laser light; and an image part in which a displayed image has been drawn, wherein a formula below is satisfied at a wavelength of the laser light with which the recording part is irradiated during the image recording: A+30>B where A denotes an absorbance of the recording part and B denotes an absorbance of the image part of the conveying container.

A conveyor line system including an image processing device configured to irradiate a recording part with laser light to perform at least one of image recording and image erasing, the conveyor line system being configured to manage at least one conveying container each including: the recording part in which the image recording is performed by irradiation with the laser light; and an image part in which a displayed image has been drawn, wherein a formula below is satisfied at a wavelength of the laser light with which the recording part is irradiated during the image recording: A+30>B where A denotes an absorbance of the recording part and B denotes an absorbance of the image part of the conveying container.

A drawing system according to an embodiment of the present disclosure includes a storage, an operation section, and a drawing section. The storage stores a characteristic function that derives output setting values of light sources on the basis of drawing coordinates, an absorbance correlation value, and gradation values in a leuco color space. The operation section derives the output setting values by inputting, to the characteristic function, the drawing coordinates, gradation values of leuco image data described in the leuco color space, and an absorbance correlation value obtained by measuring the recording medium. The drawing section includes the light sources, and controls output of the light sources on the basis of the output setting values derived by the operation section to thereby perform drawing on the recording medium.

A drawing system according to an embodiment of the present disclosure includes a storage, an operation section, and a drawing section. The storage stores a characteristic function that derives output setting values of light sources on the basis of drawing coordinates, an absorbance correlation value, and gradation values in a leuco color space. The operation section derives the output setting values by inputting, to the characteristic function, the drawing coordinates, gradation values of leuco image data described in the leuco color space, and an absorbance correlation value obtained by measuring the recording medium. The drawing section includes the light sources, and controls output of the light sources on the basis of the output setting values derived by the operation section to thereby perform drawing on the recording medium.

A laser recording device of an embodiment is for a thermal recording medium in which at least one color development layer developing a color through heat and a protective layer protecting recorded information obtained through color development of the at least one color development layer are laminated, and has light transmission properties before recording. The laser recording device includes a recording head in which emitters emitting laser light from laser light sources are arranged, and a recording controller performing parallel processing of control for causing the laser light sources to emit light independently of each other and guiding the laser light from the emitters to the thermal recording medium.

A mounting device for holding a hollow cylindrical object, particularly a screw cap, in a printing system, comprises a support member, and a mandrel for receiving a hollow cylindrical object arranged at the support member, and a heating device for heating the hollow cylindrical object mounted at the mandrel. A printing system for printing on hollow cylindrical objects, preferably screw caps, comprises at least one mounting device, and at least one printhead configured to print on surfaces of cylindrical objects, preferably screw caps.

A mounting device for holding a hollow cylindrical object, particularly a screw cap, in a printing system, comprises a support member, and a mandrel for receiving a hollow cylindrical object arranged at the support member, and a heating device for heating the hollow cylindrical object mounted at the mandrel. A printing system for printing on hollow cylindrical objects, preferably screw caps, comprises at least one mounting device, and at least one printhead configured to print on surfaces of cylindrical objects, preferably screw caps.