Abstract: An ink jet ink composition is provided that can form an image having excellent weather resistance, abrasion resistance, and coloring property. The non-aqueous ink jet ink composition includes at least one solvent represented by R1O—(R2O)m—R3 and having a flash point of 140° C. or lower and C.I. Pigment Orange-43 (PO-43) as a pigment, wherein R1 and R3 each independently represent hydrogen or an alkyl group having 1 to 5 carbon atoms, R2 represents an alkylene group having 2 or 3 carbon atoms, and m represents an integer of 2 to 6.

Abstract: An ink jet recording method includes attaching ink by ejecting an ink composition from a head to attach to a recording region of a recording medium, and drying by heating the recording medium to which the ink composition is attached, in which the ink composition is a water-based ink composition including a resin and an amide compound represented by General Formula (1) as an organic solvent, and the drying dries the organic solvent in the recording region of the recording medium to be 2.0 mg/inch2 or less. In Formula (1), R1 represents a linear or branched alkyl group having 1 to 6 carbon atoms; R2 and R3s represent each independently H or a linear or branched alkyl group having 1 to 4 carbon atoms.

Abstract: Provided are a curable composition for inkjet, which not only allows surface curability in formation of a coating film by an inkjet system to be enhanced, but also is not reduced in characteristics conventionally provided, such as solder heat resistance and gold plating resistance, and a cured product and a printed wiring board using the curable composition. The curable composition for inkjet of the present invention includes (A) an alkylene chain-containing bifunctional (meth)acrylate compound, (B) an ?-aminoalkylphenone-based photopolymerization initiator, and (C) an acylphosphine oxide-based photopolymerization initiator, wherein, when the thickness is 10 ?m, the absorbance at a wavelength of 365 nm is 0.08 to 0.8 and the absorbance at a wavelength of 385 nm is 0.05 to 0.3.

Abstract: A cable slack controller may include a deflector coupled to a movable carriage device; at least one end of a cable coupled to the carriage device; and an engagement tab formed with the cable wherein the engagement tab engages a notch defined in a portion of a channel on which the movable carriage device translates across.

Abstract: A liquid ejection head includes: head units arranged in a first direction; first individual heat dissipators each corresponding to one of the head units and disposed on a first side of the head unit in a second direction; and a first common heat dissipator disposed on the first side of the head units in the second direction. The first common heat dissipator extends in the first direction and shared among the head units. Each head unit includes: a unit body including an actuator; and a first driver integrated circuit disposed on the first side of the unit body in the second direction. Each of the first individual heat dissipators is disposed between the first driver integrated circuit and the first common heat dissipator of the head unit so as to be in thermal contact with the first driver integrated circuit and the first common heat dissipator.

Abstract: A fluid ejection device is described. The fluid ejection device has a set of coding elements and a trap element. Each coding element is movable between an initial position and a coded position. The trap element is capable of trapping one or a plurality of the coding elements in the initial position when one or a plurality of other ones of the coding elements is moved from the initial position to the coded position.

Abstract: A factory server receives part requests from customer devices and controls one or more manufacturing tools, such as 3D printers, to fabricate the requested parts. The factory server implements several features to streamline the process of fabricating parts using the manufacturing tools. For instance, the factory server can facilitate the design of a part by extracting features from the part request and identifying model files having those features. The factory server can also select an orientation in which to fabricate the part and determine print settings to use when fabricating the part. In addition, the factory server can implement a process to fabricate a three-dimensional part with a two-dimensional image applied to one or more of its external surfaces. Furthermore, the factory server can also generate a layout of multiple part instances on a build plate of a 3D printer so that multiple part instances can be fabricated at once.

Abstract: An ink set is provided including a first ink containing a polyvalent metal ion and a second ink containing a copolymer having a structural unit represented by the following general formula (1): wherein R1 represents hydrogen atom or a methyl group, and R2 represents one linking group or a combination of two or more linking groups selected from a group consisting of the following linking groups: —COO—, —OCO—, —O—, —NHCONH—, NR3CO— (R3 represents hydrogen atom or an alkyl group having 1 to 6 carbon atoms), an alkylene group having 1 to 12 carbon atoms, an alkyl ether group having 1 to 12 carbon atoms, and —NR4- (R4 represents hydrogen atom or an alkyl group having 1 to 6 carbon atoms).

Abstract: The present invention relates to a water-based ink that contains pigment-containing polyester-based resin particles A, pigment-free polyester-based resin particles B, an organic solvent and water, in which a content of an organic solvent C having a boiling point of not higher than 235° C. in a whole amount of the organic solvent is not less than 90% by mass. The water-based ink of the present invention can be improved in rub fastness, solvent resistance and adhesion to a non-water absorbing printing medium with good balance therebetween, even when printed on the non-water absorbing printing medium.

Abstract: In a printer, an accommodating portion accommodates printing agent supplied from a first cartridge. A print execution device prints with the printing agent supplied from the accommodating portion. A processor acquires first information concerning a residual quantity of the printing agent remaining in the first cartridge. The processor acquires second information concerning a preparation of a second cartridge to be replaced with the first cartridge. If the residual quantity is below a reference quantity and if the second information is acquired, the processor allows the print execution device to perform printing under a cartridge removed state where the first cartridge is removed from the mount portion. If the residual quantity is larger than or equal to the reference quantity or if the second information is not acquired, the processor prohibits the print execution device from printing under the cartridge removed state.

Abstract: Provided is a liquid ejecting apparatus that can reduce situations where surrounding areas are soiled by spilled liquid. The liquid ejecting apparatus includes: a liquid tank 47, the liquid tank 47 being mounted in a carriage 20 configured to move back and forth in the X axis direction, and the liquid tank 47 including a liquid resupply unit 23 configured to accept resupply of a liquid from the exterior; and a housing 48 configured to cover the liquid tank 47. The housing 48 includes: an upper wall 49 that covers the liquid tank 47 from the upper side; and a first recess part 61 and a second recess part 62, which are provided in the upper wall 49 to receive a spilled liquid that has spilled to the exterior of the liquid resupply unit 23, and which are recessed downward.

Abstract: A valve type nozzle controls discharge of a liquid by opening and closing a discharge port by a valve element. The discharge port discharges the liquid, and the valve element moves by applying a predetermined voltage to a piezoelectric element. When the predetermined voltage is applied to the piezoelectric element, the piezoelectric element extends and the valve element moves in a direction where the moving mechanism opens the discharge port. This allows the liquid to be discharged. Further, when the application of the voltage to the piezoelectric element is released, the moving mechanism returns to an original shape by which the valve element closes the discharge port to prevent the discharge of the liquid.

Abstract: Disclosed is a process for printing on polyester fabric comprising (1) contacting polyester fabric with an aqueous solution comprising (A) 5% to 35% by weight of at least one multivalent cationic salt; (B) 0.1% to 5% by weight of a blocked polyisocyanate crosslinking agent, and (C) 3% to 40% by weight of a waterborne resin, all percentages based on the weight of the aqueous solution; (2) drying the polyester fabric to remove the water from the polyester fabric; and (3) digitally printing the pretreated and coated polyester fabric with a water-based textile ink.

Abstract: An object is to keep continuity of data in a case where print data for which inclination correction processing has been performed is transferred sequentially. The present invention is a printing apparatus including: a print head in which a plurality of nozzle rows is arrayed, each of the nozzle rows having an inclination with respect to a direction intersecting with a conveyance direction of a printing medium; a creation unit configured to create a plurality of pieces of divided data by dividing image data corresponding to an entire printing-target image area in the conveyance direction; and an image processing unit configured to create print data corresponding to the divided data by performing image processing including inclination correction in accordance with an inclination of the nozzle row for the divided data, and the creation unit divides the image data so that areas necessary for the inclination correction overlap.

Abstract: A photocurable ink composition is provided, the composition including: a resin that includes at least one of a structural unit (1) below or a structural unit (2) below; and at least one of a monofunctional radical-polymerizable monomer or a bifunctional radical-polymerizable monomer, in which a total content of the monofunctional radical-polymerizable monomer and the bifunctional radical-polymerizable monomer is 50% by mass or more relative to a total amount of the photocurable ink composition.

Abstract: A liquid discharge head includes a plurality of nozzles to discharge a liquid, a plurality of individual chambers communicating with the plurality of nozzles, respectively, a supply-side common chamber communicating with each of the plurality of individual chambers, and a recovery-side common chamber communicating with each of the plurality of individual chambers. The supply-side common chamber and a part of the recovery-side common chamber are aligned in a longitudinal direction of the plurality of individual chambers orthogonal to a nozzle array direction along Which the plurality of nozzles is arrayed.

Abstract: An ink jet recording apparatus includes a line head, a purging mechanism, a wiper blade, a blade moving mechanism, a waste liquid passage forming portion, and a maintenance control portion. The maintenance control portion performs a first maintenance process of allowing a cleaning liquid ejection nozzle to eject cleaning liquid without allowing ink ejection nozzles to eject ink, and then allowing the wiper blade to move from a first end edge to a second end edge on a liquid ejection surface, and a second maintenance process of allowing the ink ejection nozzles to eject ink while allowing the cleaning liquid ejection nozzle to eject the cleaning liquid, and then allowing the wiper blade to move from the first end edge to the second end edge on the liquid ejection surface, after the first maintenance process.

Abstract: A droplet deposition head includes: one or more manifold components, providing one or more fluid inlets, each of which is connectable to a fluid supply system so that the head can receive a corresponding droplet fluid; and two or more arrays of fluid chambers, each chamber being provided with a respective actuating element and a respective nozzle, each actuating element being actuable to eject a droplet of fluid in an ejection direction through the corresponding one of the nozzles, each array extending in an array direction. The head extends, in the ejection direction, from a first end, at which the one or more fluid inlets are located, to a second end, at which the arrays of fluid chambers are located.

Abstract: A liquid ejection head includes a substrate having an ejection opening through which a liquid is ejected, a recessed member having a wall defining a recess in which the substrate is disposed away from the wall with a gap therebetween, and a sealing member filling the gap. The sealing member includes a cured product of a composition containing a first polyol compound, an isocyanate compound having an isocyanate group, and a second polyol compound that is more reactive with the isocyanate group than the first polyol compound.

Abstract: There are provided a head chip, a liquid jet head, and a liquid jet recording device capable of improving the ejection stability. The head chip according to an embodiment of the disclosure includes an actuator plate having a plurality of ejection grooves each filled with liquid, a nozzle plate having a plurality of nozzle holes individually communicated with the plurality of ejection grooves, and a cover plate having a through hole through which the liquid flows into and/or from the ejection groove, and a wall part adapted to cover the ejection groove. A flow channel of the liquid in a part adapted to communicate the through hole and the ejection groove with each other includes a principal flow channel section, and an expanded flow channel section provided to the wall part, and adapted to increase a cross-sectional area of the flow channel.

Abstract: An ejector for ink-jet printers, comprising a main body (2) and a through hole (3), arranged through the main body (2), which has a surface (4). At least the surface (4) of the through hole (3) is made of an elastic material.

Abstract: An ink set comprises black ink having a static surface tension A and yellow ink having a static surface tension B, wherein the static surface tension A is by 0.6 mN/m or more greater than the static surface tension B, wherein the ink set is used in an image forming device including an inkjet head including a nozzle plate including a first nozzle array and a second nozzle array disposed adjacent to the first nozzle array, the first nozzle array including multiple first nozzles configured to discharge the black ink and a second nozzle array including multiple second nozzles configured to discharge the yellow ink, wherein each nozzle of the multiple first nozzles and the multiple second nozzles has a cylindrical portion having a length of 25 ?m or longer along an axial direction with an opening on an ink discharging side of the nozzle plate.

Abstract: An ink jet recording method is provided for recording white and non-white ink compositions onto a moving recording medium. The recording medium includes a first region where both the white and non-white ink compositions are adhered, and a second region where only the white ink composition is adhered. Further, one or both of Conditions (i) and (ii) is satisfied. Condition (i): The amount of the white ink composition adhered in the first region is less than the amount of the white ink composition adhered in the second region. Condition (ii): The number of times the white ink composition is scanned across the first region is less than the number of times the white ink composition is scanned across in the second region.

Abstract: The disclosure provides methods and compositions therefor for treating a surface wherein a surface treatment layer is formed on the surface, thereby minimizing or preventing pattern collapse as the surface is subjected to typical cleaning steps in the semiconductor manufacturing process.

Abstract: Example implementations relate to liquid adsorption. In an example, a liquid adsorption system includes a vapor barrier container having a sealable internal volume, a liquid dispensing device in the internal volume, where the liquid dispensing device includes liquid in a liquid flow path extending through at least a portion of the liquid dispensing device to an opening in communication with the internal volume, and a liquid adsorbing material in the internal volume.

Abstract: The present invention relates to an image forming method and an image forming apparatus by an inkjet method using a gel ink, which minimize a gloss difference between an image-formed region and an image-less region, regardless of a type of a paper substrate used. The image forming method of the present invention is a method for forming an image on a paper substrate by using an inkjet ink that undergoes a temperature-induced sol-gel phase transition. The image forming method includes: a step of subjecting a paper substrate to a corona discharge treatment; a step of ejecting liquid droplets of inkjet ink and landing the droplets on a surface of the paper substrate subjected to the corona discharge treatment; and a step of irradiating the droplets of the inkjet ink landed on the paper substrate with an actinic light ray to cure the inkjet ink.

Abstract: A channel structure includes a channel is formed in a channel member and a plurality of openings that allow the channel to communicate with an outside. The plurality of openings are closed by respective lid members. At least one of the lid members that closes at least one of the plurality of openings has air permeability.

Abstract: Described herein is a method for priming a print substrate for subsequently receiving a liquid electrophotographic (LEP) inkin which a surface of a print substrate is coated with a first primer using an analogue printing technique and a second primer is digitally printed to the surface of the print substrate coated with the first primer.

Abstract: A printable glitter paper includes a first adhesive layer onto which glitter has been deposited, and a second adhesive layer covering the first adhesive layer and glitter. A coating covers the second adhesive layer. Another adhesive layer covers the back side of the printable glitter paper. The printable glitter paper provides excellent retention of the glitter, and a high level of smoothness for high quality printing.

Abstract: There is provided an ink jet printing method including: an image forming process of applying ink onto an image forming surface of a transfer body to form a first intermediate image; an auxiliary liquid applying process of applying an auxiliary liquid containing a thermoplastic resin onto the first intermediate image on the transfer body to form a second intermediate image; and a transferring process of contacting the second intermediate image on the transfer body with a printing medium and separating the second intermediate image from the transfer body while maintaining a contact state with the printing medium to transfer the second intermediate image to the printing medium, wherein in the auxiliary liquid applying process, an area difference between an area of a first intermediate image and an area of an auxiliary liquid application area in the image forming surface is adjusted.

Abstract: A liquid ejecting unit includes a flow channel portion that includes a flow channel through which a liquid passes, a liquid ejecting head that is stacked on the flow channel portion in a first direction and ejects the liquid, which passes through the flow channel, from a nozzle, and a support body that supports the flow channel portion, and a concave portion that is recessed in the first direction and accommodates at least a portion of the flow channel portion is formed in the support body.

Abstract: The invention provides a method for height difference measurement between the print heads and a 3D printer using the method. The 3D printer includes a printing module, a contact sensor, a movement sensor and a controller. The controller makes a 3D print head and the contact sensor contact to each other vertically for generating a contact signal, and obtains a first height value according to a vertical movement distance between the printing module and the contact sensor. The controller makes a color head and the contact sensor contact to each other vertically for generating the contact signal, and obtains a second height value according to a vertical movement distance between the printing module and the contact sensor. The controller obtains a height difference between the 3D print head and the color head according to the first height value and the second height value.

Abstract: Energy efficient printheads are disclosed. An example printhead includes a substrate with channels to direct ink toward a plurality of nozzles of the printhead. The example printhead further includes a passivation layer on the substrate. The passivation layer includes a first thin film of a first dielectric material formed using atomic layer deposition.

Abstract: A droplet deposition head includes: one or more manifold components, providing one or more fluid inlets, each of which is connectable to a fluid supply system so that the head can receive a corresponding droplet fluid; and two or more arrays of fluid chambers, each chamber being provided with a respective actuating element and a respective nozzle, each actuating element being actuable to eject a droplet of fluid in an ejection direction through the corresponding one of the nozzles, each array extending in an array direction. The head extends, in the ejection direction, from a first end, at which the one or more fluid inlets are located, to a second end, at which the arrays of fluid chambers are located.

Abstract: Stable, solid triamine compositions are disclosed. The pressed, cast, extruded or other solid compositions are suitable for antimicrobial, sanitizing and disinfectant applications. Ready-to-use solutions are obtained by dissolving the solid triamine compositions with water and the methods of use thereof are particularly suitable for cleaning, disinfecting, sanitizing, rinsing and/or lubricating. Beneficially, the solid triamine compositions are at least partially neutralized, allowing activity of 90% and greater of the biocidal triamine, and provide at least substantially similar or superior performance and micro efficacy to liquid formulations.

Abstract: A three-dimensional object printer has a controller that operates pluralities of ejectors ejecting drops of different materials having different colors, at least one color of which is white, to produce objects with different levels of color saturation. The controller operates the pluralities of ejectors with reference to a function of a sum of an average number of drops per voxel in each layer, a target value of an average number of drops per voxel of colorants other than white in each layer, and a distance from a closest surface of the object for each material ejected by the ejectors. At a predetermined distance from a closest surface and greater, the controller operates the pluralities of ejectors to form voxels in layers of the object with only clear and white drops. At distances less than the predetermined distance, the number of clear drops increases and the number of white drops decreases.

Abstract: A radiation curable inkjet ink set containing a plurality of inkjet inks having a viscosity of no more than 50 mPa·s at 25° C. and a shear rate of 90 s-1, each of the inkjet inks including a) at least one non-polymerizable, non-polymeric bisacylphosphine oxide present in a concentration of no more than 4.0 wt % based on the total weight of the inkjet ink; b) at least one monomer including at least one vinyl ether group and at least one polymerizable group selected from the group consisting of an acrylate group and a methacrylate group; and c) at least one polymerizable or polymeric thioxanthone, with the proviso that if the at least one polymerizable or polymeric thioxanthone contains no tertiary amine group, then the inkjet ink further includes at least one tertiary amine co-initiator selected from the group consisting of ethylhexyl-4-dimethylaminobenzoate and a polymerizable co-initiator containing a tertiary amine.

Abstract: A printer includes a head and a connector. The head is configured to eject ink. The connector is configured to connect a first storage to the head, and configured to connect a second storage to the head via a joint component. The first storage stores the ink. The second storage stores a greater amount of the ink than the first storage.

Abstract: A three-dimensional (3D) printer includes a frame, a first calibration device coupled to the frame, a dispensing system having a cartridge holder with a sensor mounted at a location relative to the cartridge holder, and a multi-axis positioning system for moving the dispensing system relative to the frame. Methods for calibrating the 3D printer are also disclosed.

Abstract: A printer includes a carriage including a main plate, which vertically sandwiches a guide rail and is in a fixed relative vertical positional relationship with the guide rail, and a head plate provided with an ink head, the ink head including a nozzle surface, a cap attachable to and detachable from the ink head and defining a sealed space between the cap and the nozzle surface, and a shifter causing the cap to shift between a capping position and a separated spaced position. When the cap is at the capping position, the cap pushes the ink head upward to a maintenance position.

Abstract: There are provided a head chip which ejects a liquid based on an electric signal; a first conductive path for connecting the head chip to a ground on the outside of a liquid ejecting head; and a second conductive path for connecting a shield of the head chip to the ground.

Abstract: A liquid ejecting apparatus includes a liquid ejecting head that has a nozzle to eject a liquid and a plurality of surfaces including a nozzle surface in which the nozzle opens, a wiping unit including a first wiping unit for wiping the nozzle surface and a second wiping unit for wiping a surface different from the nozzle surface of the liquid ejecting head, a moving mechanism to relatively move the wiping unit and the liquid ejecting head, and a cleaning member including a cleaning section for cleaning the first wiping unit and the second wiping unit.

Abstract: An inkjet printhead includes: an elongate fluid manifold including a longitudinally extending channel having a pair of opposite longitudinal sidewalls and a base defining a floor of the channel; a plurality of printhead chips bonded to the base of the fluid manifold, each printhead chip receiving ink from fluid outlets defined in the floor of the channel; and a plurality of transverse ribs extending across the channel between the sidewalls, each transverse rib extending upwardly from the floor of the channel.

Abstract: A MEMS device includes a wire that is formed of a conductive portion embedded into a recess opened in a first face of a substrate and a bump electrode that is electrically connected to the wire. A total width, in a second direction intersecting a first direction along which the wire extends on the first face, of an opening of the recess in a connection region where the wire and the bump electrode are electrically connected to each other is narrower than a width, in the second direction, of an opening of the recess in a region outside the connection region.

Abstract: Methods and apparatus to detect if an authorized thermal print head (TPH) has been installed in a specific model or manufacturer printer are provided. The method provides a system to check the resistivity or impedance value at the TPH side, either upon printer boot-up or during printing operation. During printing operation, the impedance measurement may be executed for a time period at a fixed periodicity and/or one or more events. Based on the impedance measurement, the printer may determine that the impedance value matches the authorized TPH range value. In a case of non-matching impedance values or change of impedance values, the printer may prevent printing operation until an authorized TPH is installed.

Abstract: A printing apparatus having an ink application unit applying a first ink containing at least resin as a solid content onto a discharge medium, a reaction liquid application unit applying a reaction liquid reacting with a component in the ink to aggregate the solid content in the first ink onto the discharge medium, and a liquid absorbing unit for bringing a liquid absorbing member of a porous body into contact with an ink image formed by the ink and the reaction liquid on the discharge medium to absorb liquid to thereby reduce the amount of the liquid in the ink image, in which a layer is formed with the first ink and the reaction liquid on the discharge medium, and then a test pattern utilized for detection is printed by applying a second ink different from the first ink to a part of the layer by the ink application unit.

Abstract: There is provided a liquid discharge apparatus including: a liquid-chamber that communicates with a nozzle and a flow-chapel; a liquid chamber driving unit that changes a volume of the liquid-chamber; and a valve that changes a volume of the flow-channel. At least one of first control of increasing the volume of the liquid-chamber, such that a change amount of the volume of the liquid-chamber is equal to or larger than a volume of the liquid flowing from the flow-channel into the liquid-chamber due to the decrease in volume of the flow-channel by the valve, and second control of decreasing the volume of the liquid-chamber, such that a change amount of the volume of the liquid-chamber is equal to or larger than a volume of the liquid flowing from the liquid-chamber out to the flow-channel due to the increase in volume of the flow-channel by the valve, is executed.

Abstract: There is provided a printing apparatus including: a transport mechanism; an ink jet head; a camera; a light source that irradiates a capturing area of the camera with light at a predetermined angle with respect to a print surface of the print medium; a carriage that includes the ink jet head, the camera, and the light source; and a controller (processor) that acquires reflectance characteristic data of irradiation light from the light source based on a captured image obtained by capturing an image of a printed test pattern by the camera, determines a specific initial-and-final-image-data range or a specific acquisition range in which the reflectance is within a specific reflectance range based on the acquired reflectance characteristic data, and acquires captured image data corresponding to the specific initial-and-final-image-data range or the specific acquisition range.

Abstract: A liquid ejection head includes a substrate, a heat generating resistor element arranged on the substrate and a flow channel forming member for forming a flow channel. The flow channel forming member has a side wall surrounding at least part of the heat generating resistor element. The heat generating resistor element has a pair of oppositely disposed sides and a pair of electrical connection regions which extend along the respective ones of the pair of sides and are separated from the respective ones of the pair of sides by a distance. The side wall has at least one concave corner which is comprised of a curved surface or a surface extending obliquely to the pair of sides and the heat generating resistor element has at least one convex corner which faces the at least one concave corner of the side wall and is rounded or chamfered.

Abstract: An ink discharge device is provided including an ink, an ink discharge head, and a circulator. The ink discharge head includes a nozzle, an individual liquid chamber communicated with the nozzle, a flow-in channel, and a flow-out channel. The circulator circulates the ink by letting the ink flow into the individual liquid chamber via the flow-in channel and flow out from the individual liquid chamber via the flow-out channel. A flow rate of the circulated ink is 0.10 to 1.50 times a maximum dischargeable rate of the ink discharge head. A dynamic surface tension A of the ink at 25° C. is 34.0 mN/m or less when measured by a maximum bubble pressure method at a surface lifetime of 15 msec, and the dynamic surface tension A and a static surface tension B of the ink at 25° C. satisfy the following relation: 10.0(%)?[(A?B)/(A+B)]×100?19.0(%).