The print head includes a nozzle layer with a plurality of nozzles for printing ink onto a target. It further includes ventilation openings including blow openings for feeding a gas to the region between the nozzles and the target as well as suction openings for feeding gas away from this region. This allows maintaining a desired atmosphere at the region in order to better control the printing process.

An apparatus for printing discrete high-resolution high-density features on a surface is provided using an aerosol stream. An aerosol chamber has a transport gas that enters through a port and entrains aerosol in an aerosol chamber to form an aerosol-laden transport gas. A flow cell is provided that has a flow cell channel and sheath gas conduits. The aerosol-laden transport gas passes through the flow cell channel and is surrounded by sheath gas passed through the sheath gas conduits. At least one aerodynamic lens receives the aerosol-laden transport gas surrounded by sheath gas. A method of printing the aerosol droplets from the aerosol-laden transport gas onto the substrate with a mean diameter of 0.5 to 8 microns is also provided.

A liquid ejecting head includes a plasma generator which includes a first electrode and a second electrode and in which an alternating voltage is applied to at least the first electrode to generate an atmospheric-pressure plasma around the first electrode. The atmospheric-pressure plasma accelerates the liquid ejected through the nozzle. The first electrode is disposed on a surface of the nozzle substrate in the ejection direction. The second electrode is disposed opposite the first electrode in the ejection direction.

A liquid discharge apparatus includes a conveyance path, a conveyor, and a liquid discharger. The conveyor conveys a medium in a conveyance direction along the conveyance path. The liquid discharger is disposed above the conveyance path to discharge a liquid toward the medium conveyed by the conveyor. The liquid discharger includes a discharge head, a housing, an airflow generator, and slit. The discharge head has a nozzle from which the liquid is discharged. The housing accommodates the discharge head. The housing has a lower face from which the nozzle of the discharge head is exposed and a slit adjacent to the discharge head in the lower face of the housing. The airflow generator generates an airflow flowing through the housing and discharged from the slit toward the conveyance path.

An industrial printhead comprising an array of piezoactuated flow channel dispensers enclosed in a chamber with a multi-orifice plate allowing fluid exit.

Embodiments of the disclosed subject matter provide a device that may have a first depositor that includes one or more delivery apertures surrounded by one or more exhaust apertures, where the one or more delivery apertures and the one or more exhaust apertures are enclosed within a perimeter of a boss that protrudes from a substrate-facing side of the one or more delivery apertures. The delivery channels for the one or more delivery apertures and exhaust channels for the one or more exhaust apertures may be routed orthogonally to each other. The one or more delivery apertures may be configured to permit jets of delivery gas pass through a lower surface of the first depositor. The lower surface of the first depositor may include the one or more exhaust apertures to remove surplus vapor from a delivery zone. Embodiments may also provide a method of forming a print head.

An industrial printhead comprising an array of piezoactuated flow channel dispensers enclosed in a chamber with a multi-orifice plate allowing fluid exit.

The print head includes a nozzle layer with a plurality of nozzles for printing ink onto a target. It further includes ventilation openings including blow openings for feeding a gas to the region between the nozzles and the target as well as suction openings for feeding gas away from this region. This allows maintaining a desired atmosphere at the region in order to better control the printing process.

An application apparatus includes a first roller configured to apply a treatment liquid to a recording medium conveyed; and a second roller disposed in contact with the first roller and forming, with the first roller, a conveyance nip in which the recording medium is nipped. The application apparatus further includes a third roller disposed in contact with the first roller at a position different from the conveyance nip, and a fourth roller disposed in contact with the second roller at a position different from the conveyance nip. The third roller has a rigidity higher than a rigidity of the first roller, and the fourth roller has rigidity higher than a rigidity of the second roller.

Disclosed herein is a material ejector (e.g., print head) geometry having alignment of material inlet channels in-line with microchannels, symmetrically disposed in a propellant flow, to obtain smooth, well-controlled, trajectories in a ballistic aerosol ejection implementation. Propellant (e.g., pressurized air) is supplied from above and below (or side-by-side) a microchannel array plane. Obviating sharp (e.g., 90 degree) corners permits propellant to flow smoothly from macroscopic source into the microchannels.