An inkjet recording apparatus includes a conveyance portion, a recording head, a detection portion, and a control portion. The recording head is disposed opposite the conveyance portion, and includes a plurality of nozzles which eject ink to the recording medium conveyed by the conveyance portion. The detection portion detects the thickness of the recording medium. The control portion controls the ink ejection speed from the recording head based on the thickness of the recording medium detected by the detection portion.

An inkjet recording apparatus includes a conveyance portion, a recording head, a detection portion, and a control portion. The recording head is disposed opposite the conveyance portion, and includes a plurality of nozzles which eject ink to the recording medium conveyed by the conveyance portion. The detection portion detects the thickness of the recording medium. The control portion controls the ink ejection speed from the recording head based on the thickness of the recording medium detected by the detection portion.

A print head assembly (PHA) includes a microelectromechanical systems (MEMS) die mounted to a substrate with an application specific integrated circuit (ASIC). The die includes an opening defined in the die, a plurality of nozzles adjacent to the opening in fluid communication with the opening, and a pad to receive electrical control signals. The ASIC includes a communication link and a plurality of transmission lines that transmit electrical signals to the MEMS die.

An ink printing process employs per-nozzle droplet volume measurement and processing software that plans droplet combinations to reach specific aggregate ink fills per target region, guaranteeing compliance with minimum and maximum ink fills set by specification. In various embodiments, different droplet combinations are produced through different printhead/substrate scan offsets, offsets between printheads, the use of different nozzle drive waveforms, and/or other techniques. These combinations can be based on repeated, rapid droplet measurements that develop understandings for each nozzle of means and spreads for expected droplet volume, velocity and trajectory, with combinations of droplets being planned based on these statistical parameters. Optionally, random fill variation can be introduced so as to mitigate Mura effects in a finished display device. The disclosed techniques have many possible applications.

An ink printing process employs per-nozzle droplet volume measurement and processing software that plans droplet combinations to reach specific aggregate ink fills per target region, guaranteeing compliance with minimum and maximum ink fills set by specification. In various embodiments, different droplet combinations are produced through different printhead/substrate scan offsets, offsets between printheads, the use of different nozzle drive waveforms, and/or other techniques. These combinations can be based on repeated, rapid droplet measurements that develop understandings for each nozzle of means and spreads for expected droplet volume, velocity and trajectory, with combinations of droplets being planned based on these statistical parameters. Optionally, random fill variation can be introduced so as to mitigate Mura effects in a finished display device. The disclosed techniques have many possible applications.

An electrohydrodynamic inkjet printing device, including: a support part; a jet printing module; a substrate bearing and moving module; and a roll-to-roll thin film conveying module. The jet printing module is disposed on the support part and includes a nozzle for ejecting printing fluid onto a substrate for pattern printing. The substrate bearing and moving module is disposed on the support part, and fixedly bears a rigid substrate as the substrate for pattern printing, and drives the rigid substrate to move with respect to the jet printing module. The roll-to-roll thin film conveying module is disposed on the support part, and transfers a flexible thin film as the substrate for pattern printing, and drives the flexible film to move with respect to the jet printing module.

A capacitive load driving circuit for repeating between charging and discharging for a capacitive load includes a charge supply source, a first signal path through which a first voltage is applied by the charge supply source, a second signal path through which a second voltage higher than the first voltage is applied by the charge supply source, and a connection path selector configured to electrically connect the capacitive load and the charge supply source via at least one of the first signal path and the second signal path, in accordance with a control signal. The charge supply source is arranged and configured to supply voltage to the connection path selection section.

A capacitive load driving circuit for repeating between charging and discharging for a capacitive load includes a charge supply source, a first signal path through which a first voltage is applied by the charge supply source, a second signal path through which a second voltage higher than the first voltage is applied by the charge supply source, and a connection path selector configured to electrically connect the capacitive load and the charge supply source via at least one of the first signal path and the second signal path, in accordance with a control signal. The charge supply source is arranged and configured to supply voltage to the connection path selection section.

A controller is configured to: (a) control a head according to a recording command received to eject liquid through ejection openings toward a recording medium; (b) control a discharger to discharge the liquid toward a receiving member through at least one of the ejection openings; (c) determine whether a remaining amount representing an amount of the liquid on the receiving member and based at least on an amount of the liquid discharged onto the receiving member in the step (b) is equal to or greater than a first predetermined amount; and (d) control the remover to remove the liquid on the receiving member. The controller is configured to perform the step (a) before the step (d) when it is determined in the step (c) that the remaining amount is less than the first predetermined amount.

A controller is configured to: (a) control a head according to a recording command received to eject liquid through ejection openings toward a recording medium; (b) control a discharger to discharge the liquid toward a receiving member through at least one of the ejection openings; (c) determine whether a remaining amount representing an amount of the liquid on the receiving member and based at least on an amount of the liquid discharged onto the receiving member in the step (b) is equal to or greater than a first predetermined amount; and (d) control the remover to remove the liquid on the receiving member. The controller is configured to perform the step (a) before the step (d) when it is determined in the step (c) that the remaining amount is less than the first predetermined amount.