A liquid discharge head is configured to achieve decrease in temperature difference in the liquid discharge head, and includes a recording device including the liquid discharge head. The liquid discharge head includes a channel member having a plurality of discharge holes, a plurality of pressurization chambers, and a plurality of common channels, and a plurality of pressurizing parts. The plurality of common channels extends in a first direction and configures a common channel group aligned in a second direction crossing the first direction, the common channels are connected with the plurality of pressurization chambers disposed along the common channels among the plurality of pressurization chambers, and the channel member is disposed outside, in the second direction, with respect to the common channel group, and further includes a first end channel extending in the first direction, and the first end channel is lower in channel resistance than the common channels.

A fluid ejector for ejecting discrete volumes of ejectant includes a body with opposing first and second surfaces. One or more nozzles are defined as conduits extending through the body between the surfaces to connect first and second orifices at the first and second surfaces respectively. The fluid ejector further includes a gas supply means having a gas outlet and an ejectant supply means. The ejectant supply means supplies the ejectant to the nozzles at a pressure above ambient via their supply orifices. The supply orifice is defined in a conduit's side or is the second orifice. Relative movement of the gas supply means and body exposes first orifices to the gas outlet allowing the gas supply means to supply gas at a pressure above ambient, wherein a pressure difference thereby created between the first and second orifices causes ejection of the ejectant from the nozzles through the second orifices.

A fluid ejector for ejecting discrete volumes of ejectant includes a body with opposing first and second surfaces. One or more nozzles are defined as conduits extending through the body between the surfaces to connect first and second orifices at the first and second surfaces respectively. The fluid ejector further includes a gas supply means having a gas outlet and an ejectant supply means. The ejectant supply means supplies the ejectant to the nozzles at a pressure above ambient via their supply orifices. The supply orifice is defined in a conduit's side or is the second orifice. Relative movement of the gas supply means and body exposes first orifices to the gas outlet allowing the gas supply means to supply gas at a pressure above ambient, wherein a pressure difference thereby created between the first and second orifices causes ejection of the ejectant from the nozzles through the second orifices.

A method for forming an image, the method including forming an image by irradiating an ink that absorbs light with a laser beam that has a wavelength corresponding to a light absorption wavelength of the ink to fly the ink by an energy of the laser beam in a direction in which the laser beam is emitted, to attach the ink on an attachment target.

A fluid ejector for ejecting discrete volumes of ejectant includes a body with opposing first and second surfaces. One or more nozzles are defined as conduits extending through the body between the surfaces to connect first and second orifices at the first and second surfaces respectively. The fluid ejector further includes a gas supply means having a gas outlet and an ejectant supply means. The ejectant supply means supplies the ejectant to the nozzles at a pressure above ambient via their supply orifices. The supply orifice is defined in a conduit's side or is the second orifice. Relative movement of the gas supply means and body exposes first orifices to the gas outlet allowing the gas supply means to supply gas at a pressure above ambient, wherein a pressure difference thereby created between the first and second orifices causes ejection of the ejectant from the nozzles through the second orifices.

An image forming system includes: a first image forming apparatus that is disposed at an upstream side in a feeding direction of a belt-like continuous recording medium; and a second image forming apparatus that is disposed at a downstream side in the feeding direction of the recording medium, wherein each of the first image forming apparatus and the second image forming apparatus includes: a recording head that forms images on the recording medium by ejecting droplets from ejection outlets of the recording head; a closing member that serves to close the ejection outlets; and a controller that monitors head drive data for driving of the recording head, and closes the ejection outlets with the closing member in case a droplets non-ejection state is beyond a predetermined first allowable condition during printing.

A printing apparatus includes a transfer drum configured to support a transfer member on an outer peripheral surface, a printing unit configured to form an ink image on the transfer member by discharging ink to the transfer member, a pressurizing drum arranged facing the transfer drum and configured to transfer the ink image on the transfer member to a print medium, an axial distance adjusting unit configured to displace a rotation-center axis of the transfer drum with respect to a rotation-center axis of the pressurizing drum, and a supporting unit displaced together with the rotation-center axis of the transfer drum and configured to support the printing unit.

A liquid discharge head is configured to achieve decrease in temperature difference in the liquid discharge head, and includes a recording device including the liquid discharge head. The liquid discharge head includes a channel member having a plurality of discharge holes, a plurality of pressurization chambers, and a plurality of common channels, and a plurality of pressurizing parts. The plurality of common channels extends in a first direction and configures a common channel group aligned in a second direction crossing the first direction, the common channels are connected with the plurality of pressurization chambers disposed along the common channels among the plurality of pressurization chambers, and the channel member is disposed outside, in the second direction, with respect to the common channel group, and further includes a first end channel extending in the first direction, and the first end channel is lower in channel resistance than the common channels.

An image forming system includes: a first image forming apparatus that is disposed at an upstream side in a feeding direction of a belt-like continuous recording medium; and a second image forming apparatus that is disposed at a downstream side in the feeding direction of the recording medium, wherein each of the first image forming apparatus and the second image forming apparatus includes: a recording head that forms images on the recording medium by ejecting droplets from ejection outlets of the recording head; a closing member that serves to close the ejection outlets; and a controller that monitors head drive data for driving of the recording head, and closes the ejection outlets with the closing member in case a droplets non-ejection state is beyond a predetermined first allowable condition during printing.

A method for forming an image, the method including forming an image by irradiating an ink that absorbs light with a laser beam that has a wavelength corresponding to a light absorption wavelength of the ink to fly the ink by an energy of the laser beam in a direction in which the laser beam is emitted, to attach the ink on an attachment target.