Abstract: In a method of manufacturing a piezoelectric element which includes a first electrode, a piezoelectric layer including a plurality of piezoelectric films, and a second electrode formed opposite a surface of the piezoelectric layer, a step of forming the first electrode metal layer includes forming the first electrode metal layer so as to include one or more iridium layer and permit the iridium layer to have the total thickness in the range from 2 to 5 nm to form the first electrode metal layer; and forming the first electrode film by heating the piezoelectric film at a temperature in the range from 400 to 650° C. for 30 minutes or more after the first piezoelectric film is formed in the step of forming the piezoelectric layer to oxidize the iridium contained in the first electrode metal layer.

Abstract: A liquid ejection head includes: an ejection port through which liquid is ejected; a liquid chamber which is connected to the ejection port, the liquid chamber being filled with the liquid; a pressurization device which is arranged on a wall of the liquid chamber, the pressurization device pressurizing the liquid in the liquid chamber; and a movable member which has a free end on a side of the ejection port and a fixed end on a side opposite to the ejection port, the free end being arranged at a prescribed distance from the wall of the liquid chamber so as to face the wall of the liquid chamber, the movable member including a first layer that is an internal layer, and second and third layers that are respectively arranged on both surfaces of the first layer, the second and third layers having a stress lower than the first layer.

Abstract: A liquid ejection device includes a liquid ejection member including a pressurized liquid chamber and a liquid ejection orifice which is in fluid communication with the pressurized liquid chamber to eject a liquid in the pressurized liquid chamber to the outside. A piezoelectric device is formed on the pressurized liquid chamber via a vibrating diaphragm. The piezoelectric device includes a lower electrode, a piezoelectric film and an upper electrode, which are disposed sequentially. The piezoelectric film is a thin-film piezoelectric material having a Curie point of 200° C. or more. The liquid ejection device further includes a heating element for heating a material, which has a melting point of not less than 150° C. and lower than the Curie point of the piezoelectric film, charged in the pressurized liquid chamber to a temperature not less than the melting point of the material.

Abstract: An original cover closer of which the energy absorption capability can be freely adjusted by a damper is described. The development period for the original cover closer is therefore shortened. The original cover closer comprises: an attachment member to be mounted on the main body of a device; a support member pivotally connected to the attachment member and operable to support an original cover; a first and a second slider slidably installed in the support member; a compression coil spring interposed between the first and second sliders and operable to urge the original cover to open; and a fluid damper located in the compression coil spring.

Abstract: In accordance with the invention, there are jet stacks, ink jet print heads, and methods of making jet stacks and ink jet print heads. The method of making an ink jet print head can include providing a partial jet stack including a diaphragm, a plurality of port holes, and having an ink outlet side and providing a polymer planarized piezoelectric array. The method can also include bonding the polymer planarized piezoelectric array to a side opposite to the ink outlet side of the partial jet stack using an adhesive, wherein the partial jet stack is aligned such that the planarized polymer covers the plurality of port holes, and using the partial jet stack as a mask to extend the port holes through the polymer by ablating the polymer and an excess portion of the adhesive from the ink outlet side using a laser.

Abstract: An ink-jet recording device which is equipped with a recording head to eject one type or plural types of inks containing a photo-curable component onto a recording medium and a light irradiation device to cure the ink by irradiating light onto the ink having deposited on the recording medium, wherein ink quantity cured by one time light irradiation is not less than 5 g/m2, and an amount of a photo-polymerization initiator in the ink is not more than 5 weight % based on the total weight of the ink.

Abstract: An inkjet head chip has an actuator plate, discharge channels formed in the actuator plate for discharging ink, and non-discharge channels arranged alternately in parallel with the discharge channels and which are not configured to discharge ink. The actuator plate has a piezoelectric layer and a low-permittivity substrate layer. The piezoelectric layer is formed of a piezoelectric material and the low-permittivity substrate layer is formed of an insulating low-permittivity material having a lower permittivity than that of the piezoelectric material. One end of each discharge channel extends to an end surface of the actuator plate in a state in which the insulating low-permittivity material is exposed on a bottom surface thereof, and another end of each discharge channel does not extend to the end surface of the actuator plate.

Abstract: A device and method of controlling fluid flow are provided. The method includes providing a moving fluid including a fluid flow characteristic; providing a fluid control device including a fluid control surface, the fluid control surface including a pattern; causing the fluid to contact the fluid control surface of the fluid control device; and causing the fluid to interact with the fluid control surface of the fluid control device using the pattern of the fluid control surface that, when activated, causes adjacent fluid drops to merge or coalesce while the fluid is in contact with the pattern of the fluid control device such that the fluid flow characteristic of the fluid after interacting with the fluid control surface of the fluid control device is different from the fluid flow characteristic of the fluid before interaction with the fluid control surface of the fluid control device.

Abstract: A method of printing and a printhead are provided. The printhead includes a nozzle array having a width; a gas flow source; and a gas flow duct in fluid communication with the gas flow source. The gas flow duct includes an expansion region and a compression region. The expansion region of the gas flow duct gradually expands along its cross sectional length to at least the width of the nozzle array. The compression region of the gas flow duct gradually contracts along its cross sectional length.

Abstract: A reciprocating apparatus includes a pair of guide members which extend in parallel with each other and in a first direction; a carriage which is reciprocateable in the first direction, supported and guided by the pair of guide members; and a carriage movement detector including (a) a sensor which is fixed to the carriage and (b) an encoder strip which extends in the first direction and which has sensible portions arranged in a lengthwise direction thereof and sensible by the sensor, such that a reciprocating movement of the carriage is detected based on sensing of the sensible portions by the sensor. The encoder strip is located between the pair of guide members in a second direction perpendicular to the first direction. The pair of the guide members are located on one of opposite sides of the carriage in a third direction perpendicular to the first and the second directions. The encoder strip is located on the other of said opposite sides of the carriage in the third direction.

Abstract: The invention relates to a method and a device for producing and deflecting ink drops in a continuous ink-jet printer in which a continuous cohesive ink jet exits from a nozzle of a pressure chamber, and in which at least one acoustic pulse (140, 142, 142a) strikes the cohesive ink jet (9) transversely to the propagation direction, and one segment of the ink jet (9) upon which the acoustic pulse (140, 142, 142a) acts is separated from the cohesive ink jet (9) and deflected from its original propagation direction (100), the separated segment forming an ink drop (11) during its travel due to cohesion forces.

Abstract: An improved printer and method of printing uses an electrostatic field at the point of ink contact with the print medium to improve ink application. This improved printer and printing method makes possible a higher resolution final image; provides for greater control of the application of ink on the print medium; permits the use of a wider range of inks having variable viscosities, surface tensions, and elasticities; and permits the use of a variety of ink application speeds.

Abstract: A continuous inkjet system includes a plurality of nozzles producing a respective liquid jet through each nozzle. A stimulation device at each nozzle is responsive to different types of stimulation signals to produce a modulation in the respective liquid jet to selectively control droplet break off relative to phases of the cycle of a varying voltage source that is connected to a charge electrode. The break off phase of a droplet relative to the voltage phase of the voltage source will determine whether the droplet is charged or not charged. Droplets that become charged may be deflected from their paths and a deflection mechanism including the charge electrode determines which droplets are allowed to reach a surface for say printing and which droplets are collected and not deposited upon the surface.

Abstract: A method of printing and an apparatus for controlling the directionality of liquid emitted from nozzles of a printhead are provided. Example embodiments of the apparatus include directionality control of liquid jets or liquid drops using a liquid jet directionality control mechanism. Example embodiments of the liquid jet directionality control mechanism include asymmetric energy application device configurations, nozzle geometry configurations, liquid delivery channel geometry configurations, or combinations of these configurations.

Abstract: A printhead includes a catcher and a negative pressure source. The catcher includes a liquid drop contact structure. The liquid drop contact structure includes a plurality of pores, each of the plurality of pores having a substantially uniform size when compared to each other. The plurality of pores have a critical pressure point above which air can displace liquid from the plurality of pores. The negative pressure source is in fluid communication with the plurality of pores of the liquid contact structure. The negative pressure source includes a pressure regulator to control the negative pressure such that the negative pressure remains below the critical pressure point of the plurality of pores of the liquid drop contact structure.

Abstract: The present invention provides a dielectric film structure having a substrate and a dielectric film provided on the substrate and in which the dielectric film has (001) face orientation with respect to the substrate, and in which a value u in the following equation (1) regarding the dielectric film is a real number greater than 2: u=(Cc/Ca)×(Wa/Wc)??(1) where, Cc is a count number of a peak of a (001?) face of the dielectric film in an Out-of-plane X ray diffraction measurement (here, 1? is a natural number selected so that Cc becomes maximum); Ca is a count number of a peak of a (h?00) face of the dielectric film in an In-plane X ray diffraction measurement (here, h? is a natural number selected so that Cc becomes maximum); Wc is a half-value width of a peak of the (001?) face of the dielectric film in an Out-of-plane rocking curve X ray diffraction measurement; and Wa is a half-value width of a peak of the (h?00) face of the dielectric film in an In-plane rocking curve X ray diffraction measurement.

Abstract: Provided are a printing head and an inkjet printing apparatus, which eject liquid droplets without leaving behind any bubble in each nozzle, thus having an enhanced durability. An ejection port of the printing head includes a first ejection port part communicating with the atmosphere and a second ejection port part having a cross-section orthogonal to an ejection direction being larger than a cross-section of the first ejection port part orthogonal to the ejection direction, and being formed between the energy effect chamber and the first ejection port part. In addition, the second ejection port part is formed to be eccentric to an electrothermal transducing element in an ink supply direction in which ink is supplied from an ink supplying port to the bubbling chamber.

Abstract: An inkjet head chip has an ink chamber containing ink, channels separated by piezoelectric elements and disposed parallel to each other along a width direction of the inkjet head chip, and a nozzle hole for discharging an ink droplet. The channels include a discharge channel disposed in a middle portion of the parallely disposed channels and communicating with the ink chamber and nozzle hole, dummy channels disposed outside of the discharge channel at respective ends thereof, and non-discharge channels toward the recording medium and supply of the ink from the ink chamber to the dummy channels is interrupted. The discharge of an ink droplet from the non-discharge channels toward the recording medium and the supply of ink from the ink chamber to the non-discharge channels are interrupted.

Abstract: An inkjet printing system is provided, which comprises: a stage on which a substrate including at least two alignment keys is mounted; an inkjet head device disposed above the stage; and an alignment key sensing device disposed above the stage, wherein the inkjet head device comprises a head unit including an inkjet head, and a supporting unit which supports the head unit and scanning the substrate in a first direction, and wherein the alignment key sensing device comprises: at least two alignment key sensors for sensing positions of the alignment keys; a sensor supporting unit for supporting the at least two alignment key sensors; and a sensor position adjustment device for adjusting positions of the alignment key sensors with respect to the alignment key sensing device.

Abstract: A printing method and apparatus using a shuttle thermal print head (TPH), which can print by moving the TPH in a transverse direction. The apparatus and printing method include (a) printing an image on a medium using the TPH while feeding the medium in a positive longitudinal direction; (b) moving the TPH in the transverse direction by a predetermined value; and (c) printing an image on the medium using the TPH while feeding the medium in a negative longitudinal direction.