Abstract: An inkjet print head includes a main body including carbon allotrope, and an ink storage configured to store an ink and including a space defined in the main body. A protecting layer is on an inner surface of the main body, and includes parylene. An inorganic layer is on the protecting layer. An organic layer is on the inorganic layer.

Abstract: By appropriately defining a flow path capacity from an opening of an ink supply path to a nozzle in a pressure chamber, a progress of thickening ink toward the pressure chamber is suppressed. In other words, by setting the individual flow path capacity to be large, specifically, to 4400 pl or higher, desirably 6210 pl or higher, it is possible to suppress the progress of the thickening of the ink even in a small-sized liquid ejecting head of which the shortest formation pitch between each of the nozzles is 1/300 inches. More specifically, a nozzle communication opening is provided between the pressure chamber and the nozzle, and a total capacity of the nozzle communication opening and the pressure chamber is configured to be 4400 pl or higher, desirably 6210 pl or higher.

Abstract: An image processing apparatus is provided that is capable of very accurately and efficiently reducing uneven color caused by variation in ejection characteristics among nozzles that eject ink and that occurs in a color image that is formed by mixing a plurality of different kinds of ink. A patch is printed by ejected ink from a plurality of nozzles, a region is specified so as to perform color correction in a test color image that is printed on a printing medium, a plurality of different color correction processing is performed on color signals that correspond to a color correction region, a plurality of color correction patches are printed, a color correction patch to be used is selected from among the plurality of different color correction patches and table parameters that correspond to the nozzles are created based on the selected color correction processing.

Abstract: A method and an inkjet printing device for single pass printing on an ink-receiver having a surface includes a plurality of sets of nozzles for jetting N inks on the surface, wherein N is larger than or equal to one, the N inks including a first ink, and wherein the plurality of sets of nozzles includes a first and a second set of nozzles for jetting the first ink; the device further including a radiation curing device arranged to cure the first ink when jetted on the surface by the first set of nozzles, wherein the radiation curing device is positioned between the first set of nozzles and the second set of nozzles.

Abstract: An inkjet nozzle device includes a main chamber having a floor, a roof and a perimeter wall extending between the floor and the roof. The main chamber includes: a firing chamber having a nozzle aperture defined in the roof and an actuator for ejection of ink through the nozzle aperture; an antechamber for supplying ink to the firing chamber, the antechamber having a main chamber inlet defined in the floor; and a baffle structure partitioning the main chamber to define the firing chamber and the antechamber, the baffle structure extending between the floor and the roof. The firing chamber and the antechamber have a common plane of symmetry.

Abstract: Nozzle layouts for printheads are described. In an example, a printhead includes a first set of drop ejectors having orifices with circular bores, and a second set of drop ejectors having orifices with non-circular bores. A processor receives printing data representing an image to be printed to media, and provides firing data to the printhead for activating the drop ejectors. The firing data selects the drop ejectors with the circular bores to print graphic elements of the image and selecting the drop ejectors with the non-circular bores to print textual elements or line elements of the image.

Abstract: Provided is an inkjet printing apparatus. The inkjet printing apparatus includes a nozzle. The nozzle includes at least two nozzle parts. A first of the at least two nozzle parts has a first tapered shape, and a second of the at least two nozzle parts has a second tapered shape and extends from the first nozzle part. The first and second tapered shapes have a same taper direction.

Abstract: A head chip for a liquid jet head of a recording apparatus has liquid jet channels arranged in a longitudinal direction of the head chip, and nozzle holes that communicate with the liquid jet channels. A flow path plate covers the liquid jet channels and has first and second circulation paths that extend in the longitudinal direction of the head chip and communicate with the liquid jet channels to supply liquid thereto. First and second inflow ports are provided at opposite longitudinal ends of the head chip for inflowing liquid into the first and second circulation paths, respectively, so that liquid flows through the first and second circulation paths in opposite directions while being supplied to the liquid jet channels. The sum of pressures of liquid supplied to each liquid jet channel from the first and second circulation paths is uniform throughout the longitudinal direction of the head chip so that high image quality is realized.

Abstract: In an embodiment, a method of fabricating an integrated orifice plate and cap structure includes forming an orifice bore on the front side of a product wafer, coating side walls of the orifice bore with a protective material, grinding the product wafer from its back side to a final thickness, forming a first hardmask for subsequent cavity formation, forming a second hardmask over the first hardmask for subsequent descender formation, forming a softmask over the second hardmask for subsequent convergent bore formation, etching a latent convergent bore using the softmask as an etch delineation feature, etching a descender using the second hardmask as an etch delineation feature, and anisotropic etching of convergent bore walls and cavities using the first hardmask as an etch delineation feature.

Abstract: A liquid ejection head includes a substrate, an energy-generating element provided on a front surface side of the substrate, the energy-generating element generating energy for ejecting liquid, sidewall members of a liquid flow path, and an ejection port forming member that defines an ejection port from which the liquid is ejected. In the liquid ejection head, sidewalls of the liquid flow path are formed of the sidewall members and a top wall of the liquid flow path is formed of the ejection port forming member, the sidewall members are each formed of a core member that extends from a front surface of the substrate and a covering member that covers the surface of the core member, the covering member covers the front surface of the substrate, and the ejection port forming member is formed of an inorganic material.

Abstract: A silicon nozzle plate has excellent liquid resistance on an inner surface of a nozzle opening and a discharge surface. A plurality of the nozzle openings are disposed in a silicon substrate of the nozzle plate. A first tantalum oxide film is disposed by atomic layer deposition on both surfaces of the silicon substrate and the inner surface of the nozzle opening, and a second tantalum oxide film that is formed by plasma CVD is stacked on the first tantalum oxide film of the discharge surface.

Abstract: Nozzle device and nozzle for atomisation and/or filtration as well as methods for using the same. The present invention relates to a nozzle and nozzle device for atomisation, in particular a micro-machined reinforced nozzle plate, that may produce small liquid droplets in air (spray) or into a liquid (emulsion) with a narrow droplet size distribution and to make small air bubbles into a liquid (foam) and to methods of making the same. The invention is further related to a nozzle part for filtration as well as means and methods to facilitate atomisation and filtration.

Abstract: A print head includes an energy generating element, a chamber for accommodating liquid, and an ejection opening for ejecting liquid from the chamber, thus applying the energy to the liquid in the chamber from the energy generating element to eject the liquid from the ejection opening, wherein the ejection opening includes at least two projections convex to an inside of the ejection opening in a cross section perpendicular to a liquid ejecting direction and has a tapered angle ?1 in regard to the liquid ejecting direction, enabling a meniscus of the liquid to be formed therebetween at the liquid ejecting time, and an outer edge portion has a tapered angle ?2 in regard to the liquid ejecting direction, wherein the tapered angles ?1 and ?2 are defined to meet a formula of 0°??1?10° and a formula of ?2>?1.

Abstract: A microfluidic device having a substrate with an electrically conductive element made using a conductive ink layer underlying a hydrophobic layer.

Abstract: An example provides a fluid ejection apparatus including a plurality of nozzles, a common fluid supply channel in fluid communication with the plurality of nozzles, and a compressible material forming, at least in part, a wall of the common fluid supply channel.

Abstract: A liquid ejection head is provided with a recording element substrate having a plurality of ejection orifices for ejecting a liquid, the plurality of ejection orifices being arranged to form a row of the ejection orifices. In at least some of the plurality of the ejection orifices, the area of an inner wall of the ejection orifices is set to be larger on the other side than on one side, the other side and the one side being defined by a plane which passes through the center of the ejection orifice, intersects with the row of the ejection orifices at right angles and extends along the direction of the depth of the ejection orifice.

Abstract: An apparatus and method are for printing a fluid material by a continuous jet printing technique. The apparatus includes a flow restricting structure arranged near an outflow opening for restricting a flow of the material between a reservoir and the outflow opening by a restricted passage through the flow restricting structure. Furthermore, the flow restricting structure, an actuating surface, and a nozzle are arranged to bind a micro volume directly adjacent an inside of the outflow opening for the purpose of guiding or reflecting pressure variations generated by the pressure regulating mechanism towards the outflow opening.

Abstract: Nozzle layouts for printheads are described. In an example, a printhead includes a first set of drop ejectors having orifices with circular bores, and a second set of drop ejectors having orifices with non-circular bores. A processor receives printing data representing an image to be printed to media, and provides firing data to the printhead for activating the drop ejectors. The firing data selects the drop ejectors with the circular bores to print graphic elements of the image and selecting the drop ejectors with the non-circular bores to print textual elements or line elements of the image.

Abstract: A ink jet type recording head which circulates ink between a first manifold and a second manifold via a pressure generation chamber is provided, the flow path member has a first and second bypass flow paths which connect the first and second manifolds, respectively in two locations of one end side and the other end side of a nozzle row on the outside of the nozzle row on which the nozzle openings are formed, and a relationship between a flow path resistance R of the first and second bypass flow paths, and a flow path resistance r of a flow path portion including the pressure generation chamber which connects the first and second manifolds is R<r/N (wherein, N is the number of all nozzle openings).

Abstract: Described is a process for producing an inkjet printhead comprising an aperture face having an oleophobic surface. The process includes forming an aperture plate by disposing a silicon layer on an aperture plate; using photolithography to create a textured pattern on an outer surface of the silicon layer; and chemically modifying the textured surface by disposing a conformal, oleophobic coating on the textured surface. The oleophobic aperture plate may be used as a front face surface for an inkjet printhead.

Abstract: A nozzle plate includes a nozzle base; a nozzle hole to discharge droplets and formed on the nozzle base; and a water-repellent film formed on at least a liquid discharging surface of the nozzle base. The nozzle base is formed of a stainless material that includes a surface layer area on which the water-repellent film is formed. The surface layer area has a higher chrome density than the chrome density of the stainless material itself, and a ratio of Cr to Fe (Cr/Fe) in the surface layer area is equal to and more than 0.8. The nozzle plate production method as such includes polishing with a polishing agent a surface of the nozzle base; removing Fe in a surface layer area of the stainless material by etching using a polishing agent; and combining chrome with oxygen.

Abstract: A liquid ejection head has an element substrate constituted of a substrate body having a plurality of energy generating elements for liquid ejection and a nozzle plate having a plurality of ejection ports arranged corresponding to the respective energy generating elements so as to form a plurality of ejection port rows each extending in a first direction, the rows being arranged side by side so as to expand in a second direction intersecting the first direction. The nozzle plate has also a groove section, or a plurality of hollow sections arranged to form a hollow section row, as extending in the first direction, at least between one of the opposite edges as viewed in the second direction of the nozzle plate and the ejection port row arranged close to the same edge.

Abstract: A liquid-jet head includes: a plurality of individual passages communicating with nozzle orifices that jet liquid; a manifold communicating with the plurality of individual passages, in which a surface of the manifold on the liquid-jetting face side is sealed with a sealing member; and a rib provided in the manifold on the sealing member side.

Abstract: A liquid-ejecting head includes a nozzle plate having a nozzle opening that serves for liquid ejection; a channel-forming substrate including pressure-generating chambers that are in communication with the nozzle opening; a pressure generator that serves to generate pressure change in a liquid in the pressure-generating chambers; and a communication plate provided between the nozzle plate and the channel-forming substrate, the communication plate having a communication channel that forms a communication between the pressure-generating chambers and the nozzle opening. The communication plate has a circulation channel that is in communication with a common liquid chamber through the communication channel, the common liquid chamber being in communication with a plurality of the pressure-generating chambers in common.

Abstract: An ink jet printing device includes a pressure chamber, a first actuator membrane being arranged to form a first flexible wall of the pressure chamber, a first piezo-electric part being operatively connected to a surface of the first actuator membrane, a second actuator membrane being arranged to form a second flexible wall of the pressure chamber and a second piezo-electric part being operatively connected to a surface of the second actuator membrane, wherein the second flexible wall is mechanically decoupled from the first flexible wall.

Abstract: A process, which produces a liquid ejection head including a recording element substrate having a principal surface and a support member having a color separation wall for ink flow paths and an outer wall, the substrate being narrower than the support member, a plane formed by conducting translation of a lower side of a substrate outer surface perpendicularly to the principal surface having an intersection with an outer wall top surface at a position distant from an inner edge of the outer wall top surface by an outward distance, includes applying an adhesive onto top surfaces of the outer and color separation walls such that a surface height of the adhesive at the intersection is higher than that at a position distant from an inner edge of the color separation wall top surface by the outward distance, and bonding and fixing the substrate to the support member with the adhesive.

Abstract: A printing system for printing a fluid includes a print head for ejecting droplets of the fluid; a first fluid storing section for storing a first amount of the fluid; a second fluid storing section for storing a second amount of the fluid, the second fluid storing section being in fluid communication to the pressure chamber in a power down situation; and a pre-tension device configured for arranging the second amount of the fluid in a pre-tension state in the second fluid storing section, thereby providing a positive fluid pressure on the nozzle in a power down situation, which positive fluid pressure is selected such that a third amount of fluid passes through the nozzle in response to said positive fluid pressure and forms a film on the nozzle plate. The printing system according to the invention supports the recovery of the print head after a power down situation.

Abstract: An inkjet recording method includes a step of forming an image by imparting an actinic ray curable ink composition containing a pigment, a polyfunctional polymerizable compound in which a content ratio to a total polymerization component is 80% by mass or more and a sensitizer in which a molecular weight is 1,000 or more onto a recording substrate which is an aggregate of a nonabsorbable or a low absorbable fiber material from an inkjet head under the conditions in which an amount of ink droplets is from 25 pl to 200 pl and a distance between the recording substrate and the inkjet head is from 5 mm to 20 mm, and a step of curing the image by irradiating the formed image with an actinic ray under the conditions in which an oxygen partial pressure is 1.5×10?2 MPa or less.

Abstract: A liquid ejection head includes a silicon substrate and an orifice plate disposed on or above the silicon substrate. The silicon substrate has a concave portion formed therein, and the orifice plate is disposed in the concave portion.

Abstract: Provided is an inkjet printing device. The inkjet printing device includes a passage forming substrate having a plurality of pressure chambers and a nozzle substrate. The nozzle substrate includes a plurality of nozzle blocks extending in a first direction, a plurality of nozzles connected to the pressure chambers and penetrating the nozzle blocks, and a plurality of trenches. Each of the trenches is disposed in a second direction perpendicular to the first direction with respect to the nozzle blocks, recessed from a bottom surface of the nozzle blocks, and extends in the first direction.

Abstract: A printing apparatus includes a first nozzle substrate having a first tapered nozzle unit aligned with a pressure chamber and a second nozzle substrate having a second tapered nozzle unit aligned with the first tapered nozzle unit and attached to the bottom of the first nozzle substrate.

Abstract: A manufacturing method of nozzle plate for liquid ejection head includes, providing a substrate having a first base material of Si and a second base material, of which the etching rate in Si anisotropic dry etching is lower then that of Si, provided on one side of the first base material, forming a film as a second etching mask on the surface of the second base material, forming a second etching mask pattern having a small-diameter opening shape in the second etching mask film, etching until the etching part is extended through the second base material, forming a film as a first etching mask film on the surface of the first base material, forming a first etching mask pattern having a large-diameter opening shape in the first etching mask film, and Si anisotropic dry etching until the etched part is extended through the first base material.

Abstract: A fluid dispenser is disclosed herein. An example of such a fluid dispenser includes a member configured to define a plurality of orifices through which a fluid is ejected and a manifold including a plurality of fluid passageways each of which is configured to have a different angle relative to the member. This example of a fluid dispenser additionally includes a plurality of slots each of which is coupled to a different one of the fluid passageways of the manifold to conduct the fluid from the fluid passageways towards the orifices. Additional features and modifications of this fluid dispenser are disclosed herein, as are other examples of fluid dispensers.

Abstract: According to one embodiment, an inkjet head includes actuators configured to pressurize ink. The actuators include piezoelectric elements provided on an insulating layer, first electrodes electrically connected to the piezoelectric elements, and second electrodes connected to the piezoelectric elements and configured to hold the piezoelectric elements in cooperation with the first electrodes. The first electrodes of all the actuators are electrically connected to a common first energization pattern. The second electrodes of all the actuators are individually electrically connected to second energization patterns. The first energization pattern and the second energization patterns are separated from each other without overlapping each other on the insulating layer.

Abstract: A nozzle plate includes: a flow channel opening in a first surface of the nozzle plate; a liquid chamber communicating with the flow channel; and a nozzle hole communicating with the liquid chamber and opening in a second surface of the nozzle plate. The liquid chamber has a flat portion which is substantially parallel to the second surface. The nozzle hole communicates with the liquid chamber in the flat portion. A method for producing a nozzle plate includes: forming a liquid chamber which opens in a first surface of a plate-like body; forming a flat portion in a bottom of the liquid chamber; and forming a nozzle hole which communicates with the flat portion and opens in a second surface of the plate-like body.

Abstract: A liquid ejection head includes a nozzle plate having a plurality of nozzles formed therein from which droplets are ejectable. The nozzle plate includes a nozzle substrate in which a plurality of nozzle holes each constituting a nozzle is formed, and a liquid-repellent film formed on a surface of the nozzle substrate on a droplet ejection side of the nozzle plate and on an inner wall of the nozzle on at least the droplet ejection side of the nozzle plate. A number of liquid-repellent groups per unit area in the liquid-repellent film formed on the inner wall of the nozzle decreases continuously from the droplet ejection side of the nozzle plate to a side opposite the droplet ejection side of the nozzle plate.

Abstract: A liquid ejecting head includes: a flow channel member made of silicon; a nozzle plate made of silicon; a manifold member, which cooperates with the flow channel member to define a manifold in fluid communication with a plurality of pressure generation chambers; and a cover member, wherein the cover member is made of a different material than the nozzle plate, and wherein the cover member is affixed to the surface of the flow channel member that is affixed to the nozzle plate. The cover member fluidly blocks the manifold from the ambient atmosphere.

Abstract: A device and method for preparing a device having a superoleophobic surface are disclosed. The method includes providing a substrate; coating a lift-off resist layer on the substrate; baking the lift-off resist layer; layering a photoresist layer on the lift-off resist layer; performing photolithography to create a textured pattern in the photoresist layer and the lift-off resist layer, and chemically modifying the textured pattern to create a superoleophobic surface.

Abstract: A liquid ejecting head includes: an orifice plate provided with an ejection port forming face which has an ejection port row formed thereon, the ejection port row including a plurality of ejection ports which eject a liquid arrayed in a first direction, wherein each of the ejection ports is formed inside a plurality of grooves which are provided on the ejection port forming face and extend in a second direction that intersects with the first direction, and with respect to a cross section of the groove in the first direction, which includes centers of the ejection ports, the groove has an inner wall surface in a circular arc shape, and the groove has an aperture larger than an aperture of the ejection port, in the first direction.

Abstract: A printing device using a print head ejecting ink from a plurality of nozzles to print ink dots of a plurality of dot diameters, includes a print-characteristic acquisition unit obtaining print characteristic information on dot diameters of ink dots to be printed per each predetermined portion of the plurality of nozzles, a distribution ratio determination unit determining a distribution ratio for distributing image data to the predetermined portions of the plurality of nozzles based on the information, a dot print position determination unit quantizing the image data to determine a dot print position based on the image data and sizes and an array of thresholds; and a plurality of masks based on dot distribution order determined according to the distribution ratio, distributing printing of each of the ink dots of the plurality of dot diameters to the dot print position determined by the dot print position determination unit.

Abstract: An object is to provide a method of manufacturing a water repellent film, a nozzle plate, an inkjet head, and an inkjet recording device which are able to improve dynamic water repellency of a water repellent film which includes a straight-chain fluorine-based organic material. The method of manufacturing a water repellent film includes forming a first organic film on a silicon substrate with a silicon compound which does not include a fluorine atom as a raw material, forming an inorganic oxide film on the first organic film, and forming a second organic film on the inorganic oxide film with a straight-chain fluorine-containing silane coupling agent as a raw material.

Abstract: A continuous liquid ejection printhead includes a plurality of nozzles having a nozzle to nozzle spacing of X. Each nozzle of the plurality of nozzles is in fluid communication with a liquid supply channel through a liquid dispensing channel. The liquid supply channel includes a liquid inlet. The liquid inlets of the liquid supply channels have a center to center inlet to inlet spacing that is greater than X.

Abstract: A unit head has an inlet section that introduces ink from a side of a sub-tank through a porous member. The sub-tank has a pressure control section corresponding to each unit head, individually, and has an outlet section that delivers the ink from the pressure control section through a porous member. The pressure control section has a valve and a film that is displaced in response to a pressure change. The film is provided in an upper surface of the sub-tank. A frame has an inlet-side connection section to which the outlet section of the sub-tank is connected, an outlet-side connection section to which the inlet section of the unit head is connected, and a communication flow path that communicates with both connection sections. Both of the connection sections include porous members, and supply and receive the ink by a surface contact of the porous members with each other.

Abstract: The invention provides a liquid ejection head including a substrate provided with an energy-generating element for generating energy utilized for ejecting a liquid; and a nozzle plate provided with an ejection orifice from which the liquid is ejected as a droplet and an opening from which a static-removable gas for electrically neutralizing the droplet is jetted, the nozzle plate being joined to the substrate.

Abstract: Disclosed is an ejection device for an inkjet printer that includes an ejection chip having a substrate and at least one fluid ejecting element. The ejection device further includes a fluidic structure configured over the ejection chip. The fluidic structure includes a nozzle plate composed of an organic material and includes a plurality of nozzles. The fluidic structure further includes a flow feature layer configured in between the ejection chip and the nozzle plate. The flow feature layer is composed of an organic material and includes a plurality of flow features. Furthermore, the fluidic structure includes a liner layer encapsulating the nozzle plate. The liner layer further at least partially encapsulates each flow feature of the plurality of flow features. The liner layer is composed of an inorganic material. Further disclosed is a method for fabricating the ejection device.

Abstract: A mold having an open interior volume is used to define patterns. The mold has a ceiling, floor and sidewalls that define the interior volume and inhibit deposition. One end of the mold is open and an opposite end has a sidewall that acts as a seed sidewall. A first material is deposited on the seed sidewall. A second material is deposited on the deposited first material. The deposition of the first and second materials is alternated, thereby forming alternating rows of the first and second materials in the interior volume. The mold and seed layer are subsequently selectively removed. In addition, one of the first or second materials is selectively removed, thereby forming a pattern including free-standing rows of the remaining material. The free-standing rows can be utilized as structures in a final product, e.g., an integrated circuit, or can be used as hard mask structures to pattern an underlying substrate. The mold and rows of material can be formed on multiple levels.

Abstract: A nozzle portion in a recording head includes a first nozzle portion of which cross-sectional area is a first area and which is formed at the side of a pressure generation chamber and a second nozzle portion of which cross-sectional area is a second area which is smaller than the first area, which is formed to be continuous to the first nozzle portion through a step portion and of which front end portion is a nozzle opening. Further, when a cross-sectional area of an ink supply path is set to Ss, a cross-sectional area of the first nozzle portion is set to Sn, a flow path resistance of the first nozzle portion is set to Rn?, and a flow path resistance of the second nozzle portion is set to Rn, relationships of Sn/Ss?1/3 and Rn?/Rn?0.6 are satisfied.

Abstract: Provided is a liquid ejection head including a substrate on a first surface of which an energy-generating element for generating energy for ejecting liquid is formed; and a flow path forming member formed on the substrate, the flow path forming member forming an ejection orifice for ejecting the liquid and a liquid flow path communicating with the ejection orifice. The flow path forming member includes, at a position surrounding the liquid flow path, a first depression that opens to an upper surface of the flow path forming member and a groove that opens to the first depression. The angle between the upper surface of the flow path forming member and a slope surface of the first depression on the flow path forming member side is an obtuse angle. The groove has a serrated side wall.

Abstract: An inkjet printhead includes a bi-layered nozzle plate having a plurality of nozzle apertures. The bi-layered nozzle plate being includes a lower first nozzle plate formed from a first material and an upper second nozzle plate disposed on the first nozzle plate, the second nozzle plate being formed from a second material. The first and second materials are different from each other and are each independently selected from the group consisting of: silicon nitride, silicon oxide and silicon oxynitride.

Abstract: Without being dependent on design changes, a liquid ejection head and a method of production thereof are provided in which when time-division driving, liquid drop landing deviance in the direction of printing is capable of being corrected. In order to achieve this, before performing an exposure in order to form an ejection port, after forming a cavity that is shifted with respect to the location at which the ejection port is formed, exposure is performed.