Abstract: The present disclosure relates to a method of preventing corrosion of mating surfaces of components. The method comprising impregnating a polyester based carrier with an anaerobic acrylic adhesive to form an impregnated carrier and spraying a pressure sensitive acrylic adhesive on one surface of the impregnated carrier to form an impregnated carrier having a pressure sensitive acrylic adhesive layer, which is protected using a protective silicon release liner to configure a pasting surface. The pasting surface is pasted on a first component, such that pasting layer is in contact with first component. A second component is abutted to first component with the impregnated carrier there between and force is applied on first and second components such that the anaerobic acrylic adhesive oozes out from the impregnated carrier and coats both mating surfaces in absence of oxygen to commence and complete curing of anaerobic acrylic adhesive on the mating surfaces of the first and the second components.

Abstract: According to the utility model, there is provided a film laminator for cell phones, useful for film lamination on a surface of a cell phone, including: a cell phone fixing plate, on which a through hole for receiving the cell phone is established, and a top surface of which is a horizontal face; with at least one position limiting plate for abutting the cell phone within the through hole being also fixed on the top surface. The film laminator for cell phones further includes: a film laminating plate for fixing a cell phone film; one end of which is hinged to the cell phone fixing plate, and the other end of which is movable freely so that the film laminating plate is bonded with the top surface of the cell phone fixing plate.

Abstract: A machine for continuously forming heat-reflective blanks is provided. The heat-reflective blanks each include a blank of sheet material and a thermal film patch coupled to the blank. The machine includes an intake station configured to align a first blank of sheet material and a second blank of sheet material for application of a first thermal film patch and a second thermal film patch, respectively. The intake station is further configured to maintain a spacing between the first blank and the second blank. The intake station includes adjustable hold-down bars for maintaining an alignment and the spacing of the first and second blanks. The machine also includes an applicator station configured to apply the first and second thermal film patches to the first and second blanks, respectively, to form a first heat-reflective blank and a second heat-reflective blank, and an ejection station configured to eject the heat-reflective blanks.

Abstract: An additive manufacturing method for fabricating a component having a surface substantially free of imperfections may include providing a mold having a configuration corresponding to the component, and depositing a material on at least one surface of the mold to fabricate the component having the surface substantially free of imperfections.

Abstract: A three-dimensional object forming apparatus includes: a head unit; a curing unit that cures the liquid discharged from the head unit, and forms a dot; and a forming control unit that controls an operation of the head unit such that a three-dimensional object is formed as an aggregate of dots by representing a shape of the three-dimensional object to be formed as a voxel-set and forming a dot in a voxel of the voxel-set which is determined as a target in which the dot is formed by a determination unit. The determination unit determines a target voxel in which a dot is formed depending on a result of comparing a forming index value which is a value depending on a dot forming rate in a voxel of the voxel-set which is positioned on an inside of the three-dimensional object with a threshold of a dither mask.

Abstract: A photocurable resin composition for support regions for use in photochemical fabrication by an inkjet method, which has low viscosity and outstanding photocurability, and where the support regions, formed by the photocuring, have good supporting performance and, following the end of the photochemical fabrication, can readily be removed from the main body by dissolving in water and/or by a weak external force such as a water jet. The photocurable resin composition for support regions for use in photochemical 3D fabrication by the inkjet method contains, based on the total mass of photocurable resin composition, from 2 to 20 mass % of N-hydroxyalkyl (meth) acrylamide, from 2 to 20 mass % of (meth) acryloyl morpholine, from 3 to 30 mass % of (meth) acrylate compound having at least one (meth) acryloyloxy group, from 40 to 90 mass % of polyhydroxy compound containing two or more hydroxyl groups, and from 0.1 to 5 mass % of a photo-radical polymerization initiator.

Abstract: A control apparatus controls a three-dimensional object fabrication apparatus including a storing unit configured to store therein powder, a supplying unit configured to supply the powder to the storing unit in layers, and a discharge unit configured to discharge, onto the powder, a fabrication liquid for solidifying the powder. The control apparatus includes a controller configured to control a total amount of the powder supplied from the supplying unit to the storing unit based on fabrication data indicating a shape of a three-dimensional object and powder information indicating a change in dimension of a layer of the powder due to permeation of the fabrication liquid.

Abstract: An alignment method adopted by a 3D printer having a 3D nozzle for jetting material and a 2D pen-module for jetting colored ink is disclosed. The 3D printer first controls the 3D nozzle to print an alignment template on a printing platform, wherein the alignment template comprises multiple alignment blocks respectively and separately printed along an axis, and each alignment block respectively deviates from each center-line according to an accumulated offset. Next, the 3D printer controls the 2D pen-module to print an ink matrix on the alignment template, wherein the ink matrix comprises multiple ink blocks respectively and separately printed along the same axis, and each ink block is exactly corresponding to each center-line respectively. The 3D printer uses covering status of each alignment block and each ink block to determine a deviation between the 3D nozzle and the 2D pen-module, so as to perform an alignment action thereupon.

Abstract: Systems and methods for fabricating three-dimensional objects. The system includes an optical imaging system providing a light source; a photosensitive medium adapted to change states upon exposure to a portion of the light source from the optical imaging system; a control system for controlling movement of the optical imaging system, wherein the optical imaging system moves continuously above the photosensitive medium. The method includes moving a maskless optical imaging system providing the light beam in a continuous sequence; presenting the light beam on a portion of the photosensitive medium; lowering a plate upon which the photosensitive medium resides; and applying a new layer of the photosensitive medium.

Abstract: A hybrid additive manufacturing method that allows for precise deposition of various photo curable resins without the use of a vat has been developed. This method utilizes thermoplastics for an exterior shell and structural support. This method of resin or epoxy deposition allows for stronger parts to be printed more rapidly through hybridization of two additive manufacturing methods. This hybrid nature greatly expands material compatibilities from strictly thermoplastics to thermoplastics and any photo curable resins. Furthermore, reinforcing materials or dopants can be incorporated into the part using the method and apparatus.

Abstract: An apparatus and method for printing directly onto print media including smooth non-absorbent media substrates (e.g., polymer films) inks having a wide range in viscosity, so that flexographic, gravure, and lithographic inks can all be contemplated. The proposed method is able to print with variable data/imaging. Dampening fluid may be patterned onto an imaging roll by coating the imaging roll with a layer of the dampening fluid and selectively evaporating off a patterned portion via a laser imaging device. The imaging roll then contacts the print substrate and transfers the patterned dampening fluid onto the substrate via film splitting. The substrate then passes through an inker station where ink is deposited directly to the substrate for attachment thereto except where rejected by the dampening fluid.

Abstract: The invention provides for the use of pharmaceutical compositions comprising a thiazolide in the stimulation of the immune system in a subject in need thereof, thereby preventing and/or treating viral diseases, cancer and diseases caused by intracellular protozoan infections.

Abstract: Method and apparatus for coating selected regions of a surface of a substrate with a film. A cyclically moveable transfer member has an imaging surface which is coated with individual particles formed of, or coated with a thermoplastic polymer, and substantially all particles that are not in direct contact with the imaging surface are removed so as to leave a uniform monolayer particle coating on the imaging surface. Selected regions of the imaging surface are exposed to radiation to render the particles tacky within the regions, and the coated imaging surface and the substrate are pressed against one another to cause transfer of only the tacky particle coating, such that only the particles in the tacky regions form a film on the substrate. The monolayer on the imaging surface of the transfer member is replenished with fresh thermoplastic particles and the cycle repeats.

Abstract: An aqueous ink transfer process includes coating the surface of an image transfer member (ITM) with a coating composition to a first thickness, the coating composition including a hydrophilic composition and a surfactant, partially drying the coating composition to reduce its thickness and then applying aqueous ink onto the coating composition. The coating composition in the vicinity of the applied ink swells by absorbing water from the ink, and can further exhibit reduced adherence to the ITM. The ink is partially dried and then transferred onto a substrate.

Abstract: A printing apparatus includes a liquid absorption unit configured to absorb a liquid component from an ink image formed on a transfer member before transferring the ink image to a print medium. The liquid absorption unit includes a liquid absorbing member configured to absorb the liquid component, a support unit configured to support the liquid absorbing member to be movable cyclically, an applying unit arranged in a moving path of the liquid absorbing member and configured to apply a moisturizing liquid while contacting the liquid absorbing member, and a supply unit configured to supply the moisturizing liquid to the applying unit. The printing apparatus includes a control unit configured to control a supply amount of the moisturizing liquid to the applying unit supplied by the supply unit.

Abstract: Systems and methods for precision inkjet printing are disclosed. A method determining an actuation parameter associated with a pressure waveform. Based on the pressure waveform, the method also includes actuating a print head to eject a droplet from a nozzle and acquiring an image of the droplet. The method further includes processing the acquired image to estimate a volume of the droplet and based on the estimated volume of the droplet and a target volume, adjusting the actuation parameter.

Abstract: A liquid discharge apparatus includes a head to discharge liquid onto a conveyed object, at least one light source to irradiate the conveyed object with light having a high relative intensity in a range of wavelength in which a relative reflectance of the liquid is high, and a detector including at least one optical sensor to perform imaging of the conveyed object being irradiated by the at least one light source, to generate data. The detector is configured to generate a detection result based on the data. The detection result including at least one of a conveyance amount of the conveyed object and a conveyance speed of the conveyed object.

Abstract: In some examples, a print head comprises a plurality of nozzles comprising respective heaters on the print head, each heater of the heaters to be driven by a respective firing pulse to form a bubble in a corresponding nozzle. The print head further comprises a first time repository on the print head to store a first time instant, and a second time repository on the print head to store a second time instant, and a plurality of detect circuits provided onto the print head and coupled to corresponding nozzles of the plurality of nozzles, wherein each respective detect circuit of the plurality of detect circuits is to detect a change in respective impedances for a respective nozzle at the first time instant and the second time instant.

Abstract: An inkjet recording apparatus includes: a tank; a recording head; a display; an operation interface; a memory; and a controller. The controller performs: an inquiry process in which a displaying and receiving process is repeatedly performed for each of ink chambers of the tank to inquire whether ink has been injected into a target ink chamber; an operation determination process to determine whether all of operations received in the inquiry process are first operations; and, in response to the determination in the operation determination process that all of the operations received in the inquiry process are first operations, a confirmation process to prompt a user to input a third operation to confirm that ink has been injected into all of the ink chambers. The controller initializes, in response to receipt of the third operation in the confirmation process, count values for all of the ink chambers.

Abstract: A printer including: a first printhead and a second printhead configured to eject ink to a print medium; a conveyance mechanism configured to convey the print medium; a camera configured to photograph the print medium; a carriage configured to carry and move the first printhead, the second printhead, and the camera; and a processor configured to print a third mark by the first printhead, photograph the third mark by the camera, adjust driving the conveyance mechanism and the carriage based on a result of the photograph, print a first mark and a second mark by the first printhead and the second printhead respectively, photograph the first mark and the second mark by the camera, and based on the result of the photograph, adjust the ink ejection timing of the second printhead.

Abstract: An ejection volume of a liquid can more finely be adjusted without lowering the ejection speed. The liquid jet head includes a plurality of nozzles adapted to jet the liquid, a piezoelectric actuator having a plurality of pressure chambers corresponding respectively to the nozzles and filled with the liquid, and adapted to vary a capacity of each of the pressure chambers, and a control section adapted to apply a pulse signal to the piezoelectric actuator to thereby expand and contract the capacity of the pressure chamber so as to jet the liquid with which the pressure chamber is filled. The control section generates a drive waveform including a plurality of the pulse signals adapted to expand the capacity of the pressure chamber, and sets a crest value of either of the pulse signals other than the pulse signal applied last to a different value from a crest value of another of the pulse signals in the drive waveform.

Abstract: There are provided a liquid jetting apparatus in which the deterioration of production efficiency is suppressed in a case in which the floating of a medium occurs, and a method of coping with the floating of a medium.

Abstract: In one example, a printhead having an electrically-functional optical target. The printhead includes a substrate. An optical target having an optically-distinguishable shape and formed from at least one polysilicon strip is deposited on the substrate. An electrical connection to at least one of the polysilicon strips connect the strip into a circuit that is deposited on the substrate.

Abstract: According to an example, a fluid ejection device may include a fluid feed slot, a plurality of fluid ejection chambers in fluid communication with the fluid feed slot, a plurality of drop ejecting elements, in which a drop ejecting element of the plurality of drop ejecting elements is positioned within each of the plurality of fluid ejection chambers, a fluid circulation channel in fluid communication at a first end of the fluid circulation channel with the fluid feed slot and in fluid communication at multiple second ends of the fluid circulation channel with the plurality of fluid ejection chambers, and a fluid circulating element within the fluid circulation channel. The fluid ejection device may also include a bubble dissipating structure positioned within the fluid circulation channel outside of the plurality of fluid ejection chambers.

Abstract: A print head (1) for depositing a liquid on a substrate comprises a layer structure including a stop layer (5) made of a dielectric material, an electrically conducting device layer (6), and an insulator layer (7) made of a dielectric material. A nozzle (3) is formed in the layer structure. The nozzle has a nozzle opening (34) for ejecting the liquid. A ring trench (31) is formed around the nozzle. The nozzle opening and the ring trench are radially separated by an annular nozzle wall (32). An ejection channel (37) is formed adjacent to the ring trench along the direction of ejection. An extraction electrode (8) is arranged on the insulator layer (7) and surrounds the nozzle.

Abstract: A liquid ejection head includes a recording element board, a support member that supports the recording element board, and includes a first surface having a plurality of first openings that communicate with a first supply port and a second supply port, a second surface contacting a supply member and having a second opening that communicates with a supply path, and a flow path through which the plurality of first openings and the second opening communicate with each other. The support member includes a beam that is provided between the plurality of first openings and extends from the first surface to middle of the flow path, and in an arrangement direction of the plurality of first openings, a length of the second opening is shorter than a sum of lengths of the plurality of first openings and a length of the beam on the first surface.

Abstract: Provided is a liquid ejection head comprising: an ejection opening row along a first direction; a pressure chamber with print-element; a passage communicating with the pressure chamber; a supply opening row along the first direction with supply openings extending in a second direction to supply liquid to the passage; a collection opening row along the first direction with collection openings extending in the second direction to collect a liquid from the passage; a first common supply passage along the first direction to supply a liquid to the supply opening row; a first common collection passage along the first direction to collect a liquid from the collection opening row; a first supply side communication opening extending in the second direction to supply a liquid to the first common supply passage; and a first collection side communication opening extending in the second direction to collect a liquid from the first common collection passage, wherein at least one of the first supply side communication openi

Abstract: A hierarchically aligned inkjet printhead includes a plurality of printhead units and a base holding the printhead units. Each printhead unit includes a plurality of drop ejector array devices, each of which includes at least one drop ejector array; a first butting edge having a first mechanical alignment feature; and a second butting edge having a second mechanical alignment feature. Each printhead unit includes an ink manifold that is fluidically connected to each of the plurality of drop ejector array devices in the printhead unit; and a mounting member to which the drop ejector array devices are affixed. A pair of opposing alignment edges of each printhead unit are substantially parallel to the butting edges of the drop ejector array devices. A first of the opposing alignment edges includes an outwardly-extending projection, and a second of the opposing alignment edges includes a niche that is substantially complementary to the projection.

Abstract: A liquid jetting apparatus jetting a liquid onto a recording medium conveyed in a first direction includes head units arranged in a second direction orthogonal to the first direction. One head unit includes nozzle chips; one nozzle chip has a nozzle arrangement area wherein nozzles are aligned in a third direction crossing the first and second directions. The nozzle chip is arranged to be shifted relative to another nozzle chip in a direction crossing the first and second directions and different from the third direction. The head unit has a first overlapping portion wherein nozzle arrangement areas of first and second nozzle chips included in the nozzle chips partially overlap with each other in the first direction. The liquid jetting apparatus has a second overlapping portion wherein nozzle arrangement areas of third and fourth nozzle chips included in the head units partially overlap with each other in the first direction.

Abstract: A liquid ejecting apparatus includes a liquid ejecting unit that can eject a first liquid and a second liquid to a medium, a first rotating body having a circumferential surface that can receive the first liquid ejected from the liquid ejecting unit, a first sliding contact member that can be slidably in contact with the circumferential surface of the first rotating body, a first collection unit that collects the first liquid that is collected from the circumferential surface by the first sliding contact member, a second rotating body having a circumferential surface that can receive the second liquid ejected from the liquid ejecting unit, a second sliding contact member that can be slidably in contact with the circumferential surface of the second rotating body, and a second collection unit that collects the second liquid that is collected from the circumferential surface by the second sliding contact member.

Abstract: The invention relates to a print head of a binary continuous jet printer comprising: means for producing a plurality of ink jets in a cavity, delimited by lateral walls, and by an upper wall and a lower wall, means for separating drops or sections of one or more of said jets intended for printing from drops or sections that do not serve for printing, a slot, which passes through the lower wall, enabling the exit of ink drops intended for printing, a gutter for recovering drops or sections not intended for printing, means for injecting gas into the cavity, and for making this gas circulate, in the cavity, to the means for producing a plurality of ink jets in said cavity, then to the gutter.

Abstract: A recording head of the present disclosure includes an ink ejection surface where a plurality of ink ejection ports for ejecting ink onto a recording medium are disposed. A plurality of cleaning liquid supply ports for supplying a cleaning liquid are disposed on an upstream side with respect to the ink ejection ports in a wiping direction which is a direction in which a wiper wipes the ink ejection surface. The plurality of cleaning liquid supply ports each have a chamfer portion formed at a portion thereof that intersects a surface to be wiped by the wiper, the chamfer portion being R-shaped in section.

Abstract: A liquid ejecting apparatus includes: a liquid ejecting unit that ejects, to a target, a liquid which is supplied from a liquid supply source via a liquid supply channel; a carriage on which the liquid ejecting unit is mounted and which moves with respect to the target; a gas containing chamber mounted on the carriage; and a pump that is disposed outside the carriage of the liquid ejecting apparatus and sends gas out to one system of a gas channel connected to the gas containing chamber and suctions gas from the gas channel.

Abstract: At least some issues such as making it difficult for liquid to leak to the outside, making it easy for liquid contained in a buffer chamber to return to a liquid storage portion, and suppressing an increase in the installation area of the entirety of a printing apparatus is achieved. A liquid supply apparatus includes a liquid tank that contain a liquid, a connection channel member connected to the liquid tank, and a buffer tank that is configured separately from the liquid tank, is connected to the liquid tank via the connection channel member, and is communicated with the atmospheric air. The liquid tank includes a liquid storage chamber provided inside of the liquid tank, and a liquid inlet portion for injecting liquid into the liquid storage chamber. The buffer tank has a buffer chamber, bottom face of the buffer chamber is positioned at a position higher than a maximum liquid level of the liquid tank.

Abstract: A method for maintaining a fluidic dispensing device includes providing a fluidic dispensing device having a fluid reservoir containing fluid, the fluid reservoir being defined in part by a base wall, and having a stir bar located in the fluid reservoir adjacent to the base wall, and having a fluid ejection chip having a fluid ejection direction; positioning the fluidic dispensing device at a predetermined orientation, wherein the fluid ejection direction is oriented in a range of upward vertical, plus or minus 90 degrees; and rotating the stir bar in a first rotational direction starting with a first rotational speed and increasing rotational velocity from the first rotational speed to a second rotational speed.

Abstract: A printing apparatus including a discharge unit, a movement unit and an adjustment unit. The discharge unit discharges ink and penetration liquid onto one side of the recording medium. The penetration liquid promotes penetration of the ink into the other side of the recording medium. The movement unit moves the discharge unit and the recording medium relative to each other. The adjustment unit adjusts a discharge amount of the penetration liquid discharged from the discharge unit onto the recording medium based on at least a relative movement speed of the discharge unit to the recording medium.

Abstract: The application provides an ink cartridge chip, an ink cartridge and an operation method for giving response to printing work, and belongs to the technical field of printing. The ink cartridge chip comprises a storage module at least provided with a first ink quantity data block and a second ink quantity data block which share data with a printer and make the printer have one printing mode, wherein the first ink quantity data block is fixed in the printing mode, and the second ink quantity data block is variable in the printing mode. The ink cartridge comprises the ink cartridge chip. The application with a printing system is easy, convenient and fast, universality is high, printing at a high ink utilization rate is achieved in one printing mode, and the problems of resource waste, consumable loss, high cost and the like are solved.

Abstract: A liquid cartridge includes a front wall, a rear wall, a bottom wall, first and second storage chambers, a liquid flow path, and a communication opening. The rear wall is spaced away from the front wall in a rear direction perpendicular to a gravitational direction in an upright posture, and is spaced away from the front wall in an upward direction in a rotated posture. The communication opening is provided at the bottom wall and is configured to provide communication therethrough between the first and second storage chambers. The communication opening defines an imaginary horizontal plane. The first storage chamber in the rotated posture defines a first capacity above the imaginary horizontal plane and a second capacity below the imaginary horizontal plane. The first capacity is less than the second capacity. The liquid flow path is positioned downward relative to the imaginary horizontal plane in the rotated posture.

Abstract: An inkjet printing apparatus includes a tank, a print head including a pressure chamber filled with ink supplied from the tank and an ejection opening which is communicated with the pressure chamber and which ejects ink filled in the pressure chamber a supply flow path for supplying ink from the tank to the print head, a collection flow path for collecting ink from the print head to the tank, a circulation unit configured to circulate ink so as to flow through the supply flow path, an inside of the pressure chamber, and the collection flow path, and a buffer chamber disposed inside the print head or in the collection flow path and which is volume variable. The tank is disposed higher than the print head in a vertical direction, and a one-way valve is provided between the buffer chamber and the tank in the collection flow path.

Abstract: A server device comprising: a communication unit, a storage unit storing device identification information for identifying an image forming apparatus communicable with the server device via the communication unit. Recording material is contained in a cartridge attachable to and detachable from the image forming apparatus. The control unit is configured to perform: (a) receiving residual amount information about residual amount of the recording material; (b) determining whether or not the residual amount of the recording material is equal to or less than a first threshold; (c) determining whether or not the residual amount information is about the cartridge that has been delivered in accordance with an order instruction; and in response to affirmative determination made in (b) and affirmative determination made in (c), transmitting the order instruction to the external device via the communication unit.

Abstract: A liquid container is enabled to contain a liquid therein. An outer wall of the liquid container has a first surface, a second and a third surfaces are adjacent to the first surface, and the second surface and the third surface face each other. The first surface has a space in which a storage element storing the information on the liquid container is contained. The first surface and the second surface have a first recessed portion that crosses a boundary between the first surface and the second surface, and the first surface and the third surface have a second recessed portion that crosses a boundary between the first surface and the third surface. The first recessed portion and the second recessed portion face each other across the space.

Abstract: An object is to provide a liquid ejection apparatus that allows suppression of a fluctuation in a pressure of a liquid in a flow path caused by a liquid delivery unit, enabling the liquid to be stably ejected through an ejection port. The liquid ejection apparatus including a liquid ejection head having an ejection port through which a liquid is ejected, a flow path configured to communicate with the ejection port, and a liquid delivery unit configured to feed the liquid to the flow path. A relation between an angular frequency ? of the liquid delivered from the liquid delivery unit, a coefficient of kinematic viscosity ? of the liquid, and an equal diameter a of at least a part of a section of an extra-head flow path in a direction normal to a direction in which ink flows satisfies ?(?/2?)×a>1.

Abstract: In an implementation, a printhead includes a nozzle and a fluid channel. A sensor plate is located within the fluid channel. An impedance measurement circuit is coupled to the sensor plate to measure impedance of fluid within the channel during a fluid movement event that moves fluid past the sensor plate.

Abstract: A fluid ejection device may include a discharge port, an energy generating element to discharge liquid through the discharge port, a first liquid supply on a first side of the discharge port, a second liquid supply on a second side of the discharge port opposite the first side, a first liquid flow path extending from the first liquid supply to the discharge port, a second liquid flow path extending from the second liquid supply to the discharge port and a fluid displacement actuator in the first liquid flow path.

Abstract: A liquid discharge head includes: a substrate, where a recording element is disposed; and a discharge orifice forming member, where a discharge orifice, facing the recording element, and configured to discharge the liquid, is formed. The liquid discharge head has a pressure chamber, a first liquid channel configured to supply liquid to the pressure chamber, and a second liquid channel configured to recover liquid from the pressure chamber. The substrate has a liquid supply channel connected to the first liquid channel to supply liquid to the first liquid channel, and a liquid recovery channel connected to the second liquid channel, to recover liquid from the second liquid channel. Pressure at an inlet portion of the liquid supply channel is higher than pressure at an outlet portion of the liquid recovery channel, and a flow velocity of liquid within the pressure chamber is 3 to 140 mm/s.

Abstract: An image formation device includes a plurality of first nozzles which eject a first ink, a plurality of second nozzles which eject a second ink, a processor which forms an image of a resolution R [dpi] on the basis of print data, and a memory which stores computer-readable instructions that, when executed by the processor, perform a process including performing an ejection control, when printing of adjacent D×R pixels is performed by the first ink at a high density Ph [%] that is higher than a unit density Pu [%], such that total densities of the second ink ejected onto each of the pixels in the pixel array by the plurality of times of scanning are, respectively, substantially the same as a maximum density of the second ink able to be ejected at one time from the second nozzles.

Abstract: An image formation device includes a plurality of nozzles arranged at an interval D [in], a processor which forms an image of a resolution R [dpi] on the basis of print data and a memory which stores computer-readable instructions that, when executed by the processor, performs a process including performing ejection control, ejection control including relatively moving the nozzles in the sub scan direction a plurality of times from a print start position on the basis of a reference LF value, when performing printing with respect to each of pixels of adjacent pixels at a high density Ph [%], relatively moving the nozzles in the main scan direction less than a (j×R×D) number of times, and a total of the densities of the ink of each of the pixels of the adjacent pixels is caused to be the high density Ph [%].

Abstract: An inkjet printer includes a first ink head to eject a first ink, and a second ink head to eject a second ink. A generator generates dot groups including at least a first dot group and a second dot group including ink dots of the second ink. The dot groups include all the ink dots of the second ink. A first printing controller forms, on a recording medium, a first printing layer of the first ink and the first dot group. A second printing controller forms a second printing layer of the second dot group, above or below the first printing layer.

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: Provided is a printing apparatus which includes a thermal head having a plurality of heat generation elements whose temperatures are controlled by applying a voltage and performing printing on a printing medium and a head drive circuit being supplied periodically with a control signal and print data to control application of a voltage to each of the plurality of heat generation elements. One period of the control signal includes first and second voltage application control periods which are separated from each other. The first voltage application control period is a period in which the printing is performed by controlling the application of a voltage, and the second voltage application control period is a period in which the printing is not performed and a temperature of the thermal head is adjusted by controlling the application of a voltage.