According to an embodiment of the present invention, a printing apparatus that satisfactorily sucks and recovers a printhead is provided. A printing apparatus that includes a transfer member, and the first and second printheads has the following arrangement. The apparatus includes the first and second suction units which suck a plurality of nozzles of the first and second printheads, a common negative-pressure generation unit which generates a negative-pressure for suction by these suction units, and a moving unit which moves these suction units from one end to the other end of each printhead. Then, the moving unit moves the first and second suction units so as to pass through concave gaps with respect to ink discharge surfaces of the first and second printheads corresponding to the first and second suction units at different timings.

A control method of a liquid ejection device having an ejection unit, and a maintenance unit for maintaining the ejection unit, the ejection unit having a first head having a first nozzle configured to eject the liquid, and a second head having a second nozzle configured to eject the liquid and a third nozzle configured to eject the treatment liquid, the maintenance unit having a first receiving portion configured to receive the liquid, and a second receiving portion configured to receive the treatment liquid, and the control method includes executing a first flushing in which the liquid is ejected from the first nozzle to the first receiving portion, executing a second flushing in which the liquid is ejected from the second nozzle to the first receiving portion, and executing a third flushing in which the processing liquid is ejected from the third nozzle to the second receiving portion.

A printing apparatus includes a detection unit that is arranged to face an ejecting surface on which a plurality of nozzles of a printing head that ejects liquid droplets are arrayed, and detects an ejecting condition of the liquid droplets, a recovery unit that recovers an ejecting condition of nozzles of the printing head; and a control unit that determines whether to perform or skip inspection of the ejecting condition by the detection unit based on a state of each of the nozzles of the printing head, and controls a nozzle for which the inspection of the ejecting condition is determined to be skipped so as to perform the inspection of the ejecting condition by the detection unit after the recovery unit recovers the ejecting condition of the nozzle.

An ink jet printhead, an ink-jet printing device and a display manufacturing device are provided for eliminating or reducing droplets on areas outside of the printing area during the ink-jet printing process, thereby improving product quality. The ink jet printhead provided in the disclosure comprises at least one nozzle and a droplet removing component disposed in at least one edge area around the area where the at least one nozzle is located, the droplet removing component being used for eliminating or reducing droplets at positions corresponding to the edge area where the droplet removing component is located.

Screen printer 10 is for screen printing solder paste 13 loaded on an upper surface of stencil 12 onto board S using one of first and second squeegees 71 and 72. Screen printer 10 is provided with a stencil frame holding rail that holds stencil frame 12a of stencil 12, pair of board holding members 36 and 38 that hold board S, raising and lowering table 16 that raises and lowers board holding members 36 and 38, and pair of stencil supporting members 50 and 52 that support stencil 12 from below at a portion outside a printing region of stencil 12 used for screen printing. Stencil supporting members 50 and 52 are provided independently from raising and lowering table 16. Therefore, the load applied to raising and lowering table 16 is reduced. Also, there is increased design freedom with respect to members and the like loaded on raising and lowering table 16.

A liquid ejecting device on which a waste liquid storage unit is mounted includes an ejecting unit that ejects a liquid, a maintenance unit and a collecting unit. The maintenance unit includes a receiving unit and a wiping unit that wipes a nozzle surface in which a nozzle is open, by moving together with the receiving unit in one direction. The receiving unit includes a receiver including a receiving tank that receives the liquid discharged from the nozzle, and a receiving gutter in which a discharging hole for dropping the liquid received by the receiving tank onto the collecting unit is open.

The collecting unit includes a discharging gutter that directs the liquid dropped through the discharging hole to the waste liquid storage unit, and the discharging gutter extends in the one direction and overlaps with at least a part of the receiver as viewed in a vertical direction.

An ink jet recording device includes a record head, a waste ink container, and a suction mechanism that sucks gas from the waste ink container. The waste ink container includes a suction port connected to the suction mechanism, a first receiving port that receives ink, a porous absorbing member, and a first air duct formed as a space without the absorbing member, so as to connect the first receiving port and the suction port. The waste ink container further includes a blocking member having a lower gas permeability than the absorbing member, and the blocking member is disposed on a path from the first receiving port to the suction port via inside the absorbing member without passing through the first air duct.

A recording device includes: a drive source; a driven portion having a driven gear; a drive transmission mechanism having a drive gear driven by the drive source and capable of swing between a first position where the drive gear is engaged with the driven gear and a second position where the drive gear is not engaged with the driven gear; and a regulating mechanism capable of swing between a regulating position where swing of the drive transmission mechanism is regulated and a non-regulating position where the swing of the drive transmission mechanism is not regulated. In the recording device, the regulating mechanism is capable of swing around a rotation axis of the driven gear.

A maintenance apparatus includes: a cap contactable with a nozzle surface of a liquid discharge head; a suction unit coupled to the cap to suck a liquid in the cap; a valve coupled to the cap with a first path, the valve to cause the first path to be opened and closed to an atmosphere; a second path branched from the first path; and an opening port coupled to the second path and communicating with the atmosphere.

An image recording apparatus includes a head having nozzles, an expelling device, a discharge-testing device to output condition signals according to discharging conditions of the nozzles, a storage to store information concerning the condition signals, and a controller. In response to receipt of a record command, the controller controls the expelling device to expel a liquid from the nozzles based on the information concerning the condition signals stored in the storage, and thereafter, controls the head to discharge the liquid for recording an image on a recording medium. In response to receipt of a particular signal indicating a potential for receiving the record command, the controller executes a discharging-test process in which the controller controls the discharge-testing device to output the condition signals according to the discharging conditions of the nozzles and a storing process in which the information concerning the condition signals is stored in the storage.