A conveying belt has a plurality of flushing openings and a detection hole, and the plurality of flushing openings are arranged in at least two rows along the main scanning direction. Furthermore, the discharge timing controller (a) detects a position of the detection hole in the main scanning direction with a belt sensor, (b) identifies the flushing opening corresponding to the nozzle based on the position of the detected detection hole in the main scanning direction, and (c) causes the print engine to perform flushing of the nozzle at a timing corresponding to the flushing opening.

A liquid ejecting apparatus includes an ejecting head that ejects a liquid containing a humectant and water from a nozzle, a cap configured to form a closed space to which the nozzle opens, and a controller that controls the ejecting head, wherein the controller includes a calculation unit and a discharge controller, wherein the calculation unit calculates an available water amount of the liquid in the cap, and when the available water amount is smaller than a preset initial available water amount, the discharge controller discharges an amount of the liquid, where the amount includes, as the available water amount, an amount obtained by multiplying a difference between the available water amount and the initial available water amount by a predetermined coefficient larger than one.

A printing device includes a printing portion, a maintenance portion, and a controller. The printing portion includes an ejection head and prints using ink. The maintenance portion performs maintenance on the ejection head. The maintenance involves consumption of ink. The controller has a manual maintenance mode and an automated maintenance mode. In the manual maintenance mode, the controller executes a maintenance using the maintenance portion in response to a maintenance command signal based on a manual operation. In the automated maintenance mode, the controller automatically executes a maintenance using the maintenance portion in response to a maintenance execution condition being met. Based on control information acquired, the controller switches an operating mode of the printing device from a first operating mode of selectively executing the manual maintenance mode and the automated maintenance mode to a second operation mode of executing the automated maintenance mode without executing the manual maintenance mode.

Various embodiments provide an ejection device for a fluid. The ejection device includes a first semiconductor wafer, housing, on a first side thereof, a piezoelectric actuator and an outlet channel for the fluid alongside the piezoelectric actuator; a second semiconductor wafer having, on a first side thereof, a recess and, on a second side thereof opposite to the first side, at least one inlet channel for said fluid fluidically coupled to the recess; and a dry-film coupled to a second side, opposite to the first side, of the first wafer. The first and the second wafers are coupled together so that the piezoelectric actuator and the outlet channel are set directly facing, and completely contained in, the recess that forms a reservoir for the fluid. The dry-film has an ejection nozzle.

A liquid ejecting apparatus includes: a first head disposed such that an arrangement angle is a first angle; a second head disposed such that an arrangement angle is a second angle, which is greater than the first angle; a first circulation mechanism circulating liquid between a first reservoir and the first head; a second circulation mechanism circulating liquid between a second reservoir and the second head; and a control unit controlling the first and the second circulation mechanisms. The control unit performs circulation cleaning, in which the liquid is circulated, on multiple heads including the first head and the second head. The amount of the liquid circulating through the first head during the circulation cleaning is a first amount, and the amount of the liquid circulating through the second head during the circulation cleaning is a second amount that is greater than the first amount.

The object of the present disclosure is to optimize the time necessary for filling and the ink consumption. One embodiment of the present disclosure is a printing apparatus having: a storage unit; a print head having an ejection port from which ink supplied from the storage unit is ejected; an ink supply path that connects the storage unit and the print head; a suction unit configured to perform suction at the ejection port; and a supply control unit configured to supply ink stored in the storage unit to the ink supply path and the print head by performing suction at the ejection port by the suction unit, and the printing apparatus has an acquisition unit configured to acquire information relating to ink discharge from the ink supply path and the supply control unit determines the number of times of suction by the suction unit based on the information.

There is provided a maintenance apparatus for an image recording apparatus provided with a head having a nozzle configured to discharge a liquid. The maintenance apparatus includes: a foam configured to absorb the liquid discharged from the nozzle; and an accommodating box which is opened upwardly and which accommodates the foam. An inner bottom surface of the accommodating box has a projection supporting a bottom surface of the foam so that the bottom surface of the foam is positioned separated from the inner bottom surface of the accommodating box.

A single pass inkjet printer that utilizes a modular printing system with one or more self-contained printing modules, where each printing module is easy to remove and replace from a large printing machine, thus resulting in an overall system that is easy to service and maintain Each module is a self-contained printer including an ink supply, printhead drive electronics, and printhead assembly in order to provide one color or fluid of inkjet printing capability. Each module includes a precise three-point compliant self-aligning mount system to obtain accurate printhead positioning, and a unique integrated printhead tending system that includes a compact movable vacuum knife for cleaning the printheads, and a printhead capping station for sealing and protecting the printheads from the ambient environment when not in use.

A liquid discharging device includes a head, a cap, a first wiper, a discharge channel, and a controller. The head ejects liquid from a nozzle. The cap is configured to abut against a nozzle surface at a covered position and to separate from the nozzle surface in a retracted position. The first wiper wipes the nozzle surface. The discharge channel connects an internal space of the cap to an outside of the cap. The controller executes a first maintenance process and a second maintenance process. In the first maintenance process, a first maintenance liquid contacts the cap in the retracted position and the first wiper. In the second maintenance process, a second maintenance liquid different from the first maintenance liquid is distributed to the internal space of the cap and the discharge channel.

A liquid discharging apparatus includes a controller configured to execute: a recording processing, a first determining processing, a pre-recording flushing processing, a first flushing processing, and a second flushing processing. In a case that the controller determines, by the first determining processing, that the recording processing is to be executed in the second mode, the controller is configured to make a first flushing interval between the pre-recording flushing processing and the first flushing processing to be longer than a second flushing interval between the first flushing processing and the second flushing processing.