In an imaging method an image or multiple images, an ink specification and substrate or substrates for imaging are selected. A central computing device (CCD) determines a volume of ink required to form the images and communicates with a plurality of printers that are geographically remote from the CCD. Each of the plurality of printers communicates to the CCD an ink specification available at the printer, a volume of ink available and optionally substrates that are available at the printer location. The CCD selects a printer or printers from the plurality of printers to fulfill the print job considering the geographic location of the printer(s), the ink specification available to the printer, and the volume of ink available at the printer. The CCD provides to the printer information and specifications which may include an image specification, an ink specification, a waveform specification and a substrate specification.

The present disclosure is drawn to printing systems. In one example, a printing system can include a pretreatment head, an inkjet print head, and a post-treatment head. The pretreatment head can include a first plasma generator to apply a plasma treatment to a media substrate. The inkjet print head can be positioned with respect to the pretreatment head to form a printed image on the media substrate after the plasma treatment. The post-treatment head can include a second plasma generator positioned with respect to the inkjet print head to treat the printed image on the media substrate.

An inkjet recording apparatus and an inkjet recording method which enable changing a droplet amount without changing a droplet speed of an ink discharged from the same nozzle, and including an inkjet head which expands and contracts a capacity of a pressure chamber by applying a driving signal to an actuator and a driving circuit which applies the driving signal to the actuator, the driving signal including a first expansion pulse which starts from a reference potential and expands the capacity of the pressure chamber, a first contraction pulse which contracts the capacity of the pressure chamber to discharge the ink from the nozzle, a second expansion pulse which expands the capacity of the pressure chamber, and a second contraction pulse which contracts the capacity of the pressure chamber and returns to the reference potential in the mentioned order, the driving circuit being configured to enable discharging different droplet amounts of the ink from the same nozzle by changing a potential difference between a start edge and an end edge of the first contraction pulse.

In an imaging method an image or multiple images, an ink specification and substrate or substrates for imaging are selected. A central computing device (CCD) determines a volume of ink required to form the images and communicates with a plurality of printers that are geographically remote from the CCD. Each of the plurality of printers communicates to the CCD an ink specification available at the printer, a volume of ink available and optionally substrates that are available at the printer location. The CCD selects a printer or printers from the plurality of printers to fulfill the print job considering the geographic location of the printer(s), the ink specification available to the printer, and the volume of ink available at the printer. The CCD provides to the printer information and specifications which may include an image specification, an ink specification, a waveform specification and a substrate specification.

The print head 10 includes a nozzle region NA1 in which a distance between a nozzle array 23Y and a nozzle array 23C is a distance D1 and a nozzle region NA2 in which a distance between a nozzle array 23Y and a nozzle array 23C is a distance D2. When a ratio of sizes of a plurality of ink droplets ejected from nozzles of a nozzle region NA1 is defined as a first ratio and a ratio of sizes of a plurality of ink droplets ejected from nozzles of a nozzle region NA2 is defined as a second ratio, a control section 30 executes a first print in which a ratio of ink droplets having a size other than a maximum size in the second ratio is smaller than a ratio of ink droplets having a size other than a maximum size in the first ratio.

A recording device includes a recording head (a printing head) with multiple nozzles arranged therein to discharge droplets (ink droplets) onto a recording medium (a printing medium), and a recording controller (a printing controller) configured to control recording of a recording image, the recording including moving the recording head relative to the recording medium while the droplets are discharged. The recording controller is configured to control the recording for pixel data of the recording image that have a prescribed gray scale value or larger under conditions that a nozzle duty corresponding to the number of nozzles, included in the multiple nozzles and being able to discharge the droplets per unit area on the recording medium, is smaller than or equal to an upper limit value and that a discharge amount of the droplets discharged per the unit area is variable.

White-balance is improved when printing on colored media, while minimizing the time and use of costly materials required by present approaches. In an embodiment, the typical solid white fill or background layer is altered by including in the white layer one or more of the other colors already available in the printer to shade this layer. Thus, a small amount of cyan, for example, helps balance a pink-ish (red) media; yellow is used for blue media; and magenta is used for green media; as well as combinations thereof. A combination of transparent process inks and opaque white helps to maintain brightness (luminosity).

An image recording device and an image recording method capable of matching landing positions between droplet types in a consecutive ejection drive method are provided. The object is resolved by an image recording device in which a drive waveform for forming a dot of a small droplet is a drive waveform for ejecting a liquid droplet by a first ejection waveform element arranged in a first half of one drive cycle, and a drive waveform for forming a dot of a medium droplet is a drive waveform for ejecting the liquid droplet by the first ejection waveform element and a second ejection waveform element arranged after the first ejection waveform element in time series, and the liquid droplet ejected by the first ejection waveform element and the liquid droplet ejected by the second ejection waveform element are not combined while reaching onto a recording medium.

A supporting member includes a first supporting portion disposed on a first and second recording element substrate side, and a second supporting portion disposed on a side opposite to the first and second recording element substrate side with respect to the first supporting portion, the first supporting portion includes a first individual flow path for supplying liquid to a first recording element substrate, and a second individual flow path for supplying liquid to a second recording element substrate, and the second supporting portion includes a common flow path for supplying liquid to the first and second individual flow paths.

White-balance is improved when printing on colored media, while minimizing the time and use of costly materials required by present approaches. In an embodiment, the typical solid white fill or background layer is altered by including in the white layer one or more of the other colors already available in the printer to shade this layer. Thus, a small amount of cyan, for example, helps balance a pink-ish (red) media; yellow is used for blue media; and magenta is used for green media; as well as combinations thereof. A combination of transparent process inks and opaque white helps to maintain brightness (luminosity).