Abstract: A liquid ejecting apparatus includes: a liquid ejecting head that can eject liquid; a pressure pump that discharges pressurized air during operation; at least one liquid container that contains liquid; a pressurized-air feed channel that feeds the liquid container with the pressurized air discharged from the pressure pump; a liquid feed channel that feeds the liquid ejecting head with the liquid discharged from the liquid container in accordance with the pressure of the pressurized air that is fed to the liquid container through the pressurized-air feed channel; a hydraulic-pressure measuring device disposed in a no pressure region that is not under the pressure of the pressurized air, for measuring the pressure of the liquid fed from the liquid container to the liquid ejecting head; a determining section that determines, if the hydraulic-pressure measuring device detects a value lower than a threshold hydraulic pressure predetermined as the lower limit of the hydraulic pressure necessary for feeding the liqu

Abstract: An inkjet head including a plurality of restrictors to reduce crosstalk. The inkjet head includes a channel plate in which an ink channel is formed, an actuator formed on the channel plate, and an ink-supply bezel including a manifold. The ink channel includes an ink inlet to receive ink from the manifold, reservoirs to store ink received through the ink inlet, chambers filled with ink supplied from the reservoirs, nozzles to eject ink filled in the chambers, first restrictors connecting the reservoirs to the chambers, and second restrictors connecting the reservoirs to the ink inlet. Each of the reservoirs includes a first reservoir and a second reservoir that are separated by a central separation wall, and the separation wall includes a third restrictor connecting the first and second reservoirs. Therefore, crosstalk caused by a back flow of ink and transmission of a pressure wave can be prevented during ejection of ink.

Abstract: An ink delivery system is provided for delivering ink to a plurality of printhead modules. The ink delivery system includes a channel structure defining a channel and a first pair of locating formations on either side of the channel. A printhead module location molding defines both a bight configured to receive the channel structure and a second pair of locating formations which form a complementary fastening arrangement with the first locating formations. An ink delivery extrusion is configured to be located within the channel and defines a plurality of internal ink channels. The extrusion further defines a plurality of groups of holes for engaging with respective printhead modules. The holes of each group extend from respective ink channels. An endcap is configured to cap the ink channels at an end of the ink delivery extrusion.

Abstract: A method of making a micro-fluid ejection head structure and micro-fluid ejection heads made by the method. The method includes applying a tantalum oxide layer to a surface of a fluid ejection actuator disposed on a device surface of a substrate so that the tantalum oxide layer is the topmost layer of a plurality of layers including a resistive layer, and a protective layer selected from a passivation layer, a cavitation layer, and a combination of a passivation layer and a cavitation layer. The tantalum oxide layer has a thickness (t) that satisfies an equation t=(¼*W/n), wherein W is a wavelength of radiation from a radiation source, and n is a refractive index of the tantalum oxide layer. A photoimageable layer is also applied to the substrate. The photoimageable layer is imaged with the radiation source and then developed.

Abstract: An apparatus and method which print a biomolecular droplet onto a solid substrate using an electric charge concentration effect comprises: a needle shaped electric field forming electrode which is made of a conductive material, is disposed vertically, and comprises an accommodating area and a nozzle formed on a bottom end of the accommodating area; a solid substrate which is electrically grounded, is disposed below the electric field forming electrode, and comprises a moisture thin film and a target surface onto which the biomolecular droplet is discharged from the nozzle of the electric field forming electrode; and an open circuit type voltage applying unit which is electrically connected to the electric field forming electrode, applies a charge to the electric field forming electrode, and causes the biomolecular droplet to be ejected onto the target surface.

Abstract: Micro-fluid ejection heads and methods for extending the life of micro-fluid ejection heads. One such micro-fluid ejection head includes a substrate having a plurality of thermal ejection actuators. Each of the thermal ejection actuators has a resistive layer and a protective layer thereon. A flow feature member is adjacent the substrate and defines a fluid feed channel, a fluid chamber associated with at least one of the actuators and in flow communication with the fluid feed channel, and a nozzle. The nozzle is offset to a side of the chamber opposite the feed channel. A polymeric layer having a degradation temperature of less than about 400° C. overlaps a portion of the at least one actuator associated with the fluid chamber and positioned less than about five microns from at least an edge of the at least one actuator opposite the fluid feed channel.

Abstract: Methods for fabricating micro-fluid ejection heads and micro-fluid ejection heads are provided herein, such as those that use non-conventional substrates. One such micro-fluid ejection head includes a substrate having first and second glass layers disposed adjacent to a surface thereof and a plurality of fluid ejection actuators disposed adjacent to the second glass layer. The first glass layer is thicker than the second glass layer and the second glass layer has a surface roughness of no greater than about 75 ? Ra.

Abstract: In a flexible wiring board for use in, for example, a liquid discharge head, wires disposed on a substrate in parallel are covered with a film material. The flexible wiring board is bendable towards one of a front surface side and a back surface side of the substrate and includes a bending line. The bending line is formed by bending the flexible wiring board along a bending direction crossing a longitudinal direction of the wires. The bending line contains the wires. Both ends of the flexible wiring board in the bending direction are located on the bending line. A distance between one of the wires located closest to one end of the flexible wiring board and the one end is larger on the bending line than in another part of the flexible wiring board. Accordingly, even if the flexible wiring board is bent at a small bend radius, peeling does not easily occur between a base film and a cover film.

Abstract: A heating structure of an inkjet printhead and an inkjet printhead including the heating structure. The heating structure includes a substrate, a heater formed on the substrate, an electrode formed on the heater, a passivation layer formed to cover the heaters and the electrodes, and carbon nanotubes (CNTs) formed in the passivation layer.

Abstract: A liquid transport apparatus includes liquid transport channels disposed on an insulating surface of a substrate, individual electrodes disposed in regions corresponding to respective ones of the liquid transport channels, and wiring portions extending along the insulating surface of the substrate. The apparatus further includes a first insulating layer disposed so as to cover the electrodes and in which the wetting angle with respect to a conductive liquid changes according to an electrical potential difference between the conductive liquid and the electrodes, a second insulating layer which is disposed so as to cover the wiring portions disposed in contact with the first insulating layer, and a potential applying unit which applies an electric potential to the electrodes.

Abstract: A recording head configured to discharge ink from a nozzle includes a cantilever and a liquid chamber. The cantilever has a free end and a fixed end and bends to generate a pressure for discharging ink. The liquid chamber communicates with the nozzle. The cantilever is disposed in the liquid chamber. The cantilever has a stepped portion on or in a surface facing the nozzle and in the vicinity of the free end.

Abstract: This invention relates to a cover assembly for a cradle unit of a pagewidth print engine. The cover assembly defines a docking port for a refill unit configured to refill a cartridge unit of the print engine. The cartridge unit is housed in the cradle. The docking port includes a rim portion, engagement means and a push rod. The rim portion is for receiving a base portion of the refill unit so that the refill unit is able to pass through the cover assembly, in use, to dock with the cartridge unit. The engagement means is located within the rim portion, the engagement means being configured to engage the refill unit to retain the refill unit securely in position to facilitate refilling of the cartridge unit. The push rod extends through a hole in the rim portion for operatively actuating the refill unit to incrementally dispense ink.

Abstract: A nozzle arrangement ejects ink through apertures that each have an externally projecting peripheral rim. The nozzle arrangement has a substrate assembly defining an ink inlet passage and including heater element drive circuitry, a nozzle chamber structure formed on the substrate assembly, the nozzle chamber structure defining nozzle chambers in fluid communication with the ink inlet passage and apertures through which ink in each of the nozzle chambers can be ejected, and heater elements positioned between the drive circuitry and the apertures. The heater elements are connected to the drive circuitry and are individually supplied with current to eject ink from one of the apertures respectively.

Abstract: A printhead integrated circuit (IC) with a planar array of droplet ejectors, each having data distribution circuitry, a drive transistor, a printing fluid inlet, an actuator, a chamber and a nozzle, the chamber being configured to hold printing fluid adjacent the nozzle so that the drive transistor activates the actuator to eject a droplet of the printing fluid through the nozzle. The array has more than 700 of the droplet ejectors per square millimeter. With a high density of droplet ejectors fabricated on a wafer substrate, the nozzle array has a high nozzle pitch and the printhead has a very high ‘true’ print resolution—i.e. the high number of dots per inch is achieved by a high number of nozzles per inch.

Abstract: A nozzle arrangement is provided for ejecting ink. The nozzle arrangement includes a substrate assembly defining an ink inlet passage. A nozzle chamber structure extends from the substrate assembly to define a nozzle chamber in fluid communication with the ink inlet passage. The nozzle chamber structure defines an aperture through which ink in the nozzle chamber can be ejected. A pair of parallel heater elements extends from the nozzle chamber structure and into the nozzle chamber, and can be supplied with current so that ink in the nozzle chamber is ejected out through the aperture. The heater elements include legs embedded within the nozzle chamber structure and terminate in feet embedded within the substrate assembly.

Abstract: The ejection restoration apparatus for a liquid ejection head having a plurality of nozzles which are disposed in a planar nozzle surface and from which liquid is ejected, includes: a first suction cap which covers a partial region of the planar nozzle surface and which has a contact portion being constituted by an elastic body and making contact with the planar nozzle surface, the partial region being smaller than area of the planar nozzle surface in which the nozzles are disposed and being larger than cross-sectional area of one of the nozzles; a suction cap movement device which moves the first suction cap in parallel with the planar nozzle surface while causing the contact portion of the first suction cap to make contact with the planar nozzle surface; a nozzle abnormality detection device which detects an abnormal nozzle suffering an abnormality, in the nozzles; and a suction control device which causes the first suction cap to suction the liquid in the abnormal nozzle detected by the nozzle abnormality

Abstract: Provided is a pagewidth printhead assembly having a plurality of printhead modules. Each of these modules includes a printhead integrated circuit (IC) having a plurality of ink ejection nozzles, and an ink distribution assembly formed from a stack of ink distribution layers. Each layer defines apertures therein at predetermined locations, with the layers laminated together so that the apertures complementarily define ink distribution channels to the printhead IC. Each module also includes a tape automated bonding (TAB) film connected to the printhead IC for arranging said IC in signal communication with a controller of the printhead assembly.

Abstract: A liquid recording head includes a thermal energy generating element, having a flat plate configuration, for generating a bubble by thermal energy; a pressure chamber in which the thermal energy generating element is provided; a flow path for introducing liquid into the pressure chamber; a supply port in fluid communication with the flow path; and an ejection outlet provided at a position opposing the thermal energy generating element in fluid communication with the pressure chamber. The thermal energy generating element includes a first major surface facing the ejection outlet and a second major surface opposite the first major surface, and a distance between the first major surface and a ceiling surface of the pressure chamber in which the ejection outlet is formed is shorter than a distance between the second major surface and a bottom surface of the pressure chamber.

Abstract: An inkjet printhead has a plurality of nozzle arrangements. Each nozzle arrangement comprises an ink chamber having an ink supply channel and an ink ejection port; an ink spreading prevention rim provided around and spaced apart from the ink ejection port to define a pit between the ink ejection port and the ink spreading prevention rim; and a thermal actuator mechanism configured to operatively eject ink from the chamber via the ejection port. The plurality of nozzle arrangement are grouped into pods, each pod having two rows of nozzle arrangements spatially staggered with respect to each other.

Abstract: An inkjet head assembly and a printing method using the same. The inkjet head assembly includes an ultraviolet (UV) emitting unit to emit UV light, and a printhead to move together with the UV emitting unit and to eject ink through nozzles using inkjet technology.