Abstract: A phase change ink printer may be operated so that multiple pressure pulses are applied to the ink in an ink flow path of the printer during a time that the ink is changing phase. During the phase change, a portion of the ink in the ink flow path is in liquid phase and another portion of the ink is in solid phase. The pressure pulses are applied at least to the liquid phase ink in the ink flow path. The phase change may involve a transition from solid to liquid phase, such as during a start-up operation, or may involve a transition from a liquid phase to a solid phase, such as during a power down operation. Application of pressure during either of these operations serves to reduce bubbles and voids in the phase change ink.

Abstract: A method detects the level of ink in a print head reservoir by monitoring the power drawn by a thermistor positioned within the print head reservoir by an electrical conductor.

Abstract: The Niyama number of a flow path for phase change ink is the ratio of cooling rate of the ink to the thermal gradient of the ink along the ink flow path. Print head assemblies can be designed and configured to achieve ink flow paths having Niyama numbers that are greater than a critical Niyama value. These designs reduce entrapment of air in the ink as the ink is changing phase and provide optimal bubble and void mitigation for phase change ink. The thermal gradient of the ink flow path can be achieved using passive and/or active thermal elements disposed along the ink flow path.

Abstract: A method for operating a printer having multiple printheads includes activating a heater that is operatively connected to a printhead that ejects ink having a single color in response to receiving a print job. The printer detects the presence of colors other than the single color in image data received in the print job, and activates heaters operatively coupled to printheads that eject ink drops that correspond to the detected colors.

Abstract: A heater for use in a phase change ink printhead reservoir is provided that includes a first insulating layer having at least one ink supply path opening, and a second insulating layer having at least one ink supply path opening that aligns with the at least one ink supply path opening in the first insulating layer. The heater includes a resistance heating trace arranged in a serpentine pattern between the first and the second insulating layers. The resistance heating trace is configured to receive electric current and to convert the electric current to heat. The resistance heating trace includes a trace ring for each ink supply path opening in the first and second insulating layers that forms a continuous perimeter around the corresponding ink supply path opening.

Abstract: System and methods for heating and transporting liquefied solid ink in an imaging device. The system includes an electroconductive tube that not only melts the solid ink, but also permits a control system to sense the ink temperature due to the tube's inherent properties. A controller operatively coupled to the electroconductive tube provides power to the tube, which in turn enables current flow. The flow of current resistively heats the electroconductive tube, thereby heating and melting the ink. Further, the controller is configured to control the current flowing through the tube.

Abstract: A process is implemented in a printer having a release agent application system that enables a controller in the printer to detect gel ink in the release agent application system exceeding a predetermined threshold. The process monitors a plurality of print characteristics with reference to print data and quantifies a risk of gel ink developing in the release agent application system. The print characteristics include a print area value identifying a total surface area of a print, an inked area value identifying an area of surface area covered with ink, and a print type indicating whether the print is a simplex print or a duplex print.

Abstract: A solid ink printer includes a solid ink measurement system that helps ensure an adequate supply of solid ink is in the feed channels delivering solid ink to a melting device within a printer.

Abstract: In an inkjet printer, an ink reclamation apparatus receives ink emitted from at least one printhead. The ink reclamation apparatus includes an ink receptacle and a liquid path member that extends from the ink receptacle to contact the face of at least one printhead proximate to a plurality of inkjets in the at least one printhead. The liquid path member draws liquid ink from the plurality of inkjets and the liquid ink enters the ink receptacle. The ink reclamation apparatus returns the ink to a reservoir in the printhead and reduces or eliminates wasted ink during operation of the at least one printhead.

Abstract: An in situ process for preparing a phase change magnetic ink including heating a phase change ink composition to a first temperature sufficient to provide a melt composition; wherein the phase change ink composition comprises a carrier, an optional colorant, and an optional dispersant; placing the melt composition under inert atmosphere; heating the melt composition to a second temperature sufficient to effect decomposition of a metal carbonyl; adding the metal carbonyl to the melt composition under inert atmosphere at this second temperature to form metal nanoparticles thus forming in situ a phase change magnetic ink including the metal nanoparticles; optionally, filtering the phase change magnetic ink while in a liquid state; and cooling the phase change magnetic ink to a solid state.

Abstract: A solid ink includes an ink vehicle that is solid at room temperature, including a ketone wax and at least one resin selected from a branched amide resin, a branched urea resin, and a branched urethane resin, a colorant, and optional additives.

Abstract: An imaging device includes a media supply and handling system configured to move media along a path. A printing system is disposed along the path that includes at least one printhead for applying melted phase-change ink of at least one color to the media to form images thereon. A fixing assembly is disposed along the path downstream of the printing system that is configured to apply heat and/or pressure to the melted phase change ink of the images on the media. A coating system is disposed along the path downstream from the spreader. The coating system includes at least one printhead for applying a clear ink on top of the images formed on the media by the printing station.

Abstract: An imaging device includes at least one ink reservoir located within a housing in the imaging device. The housing at least partially encloses the at least one ink reservoir and includes a top, a bottom, and a plurality of side walls extending vertically between the top and the bottom of the housing. The side walls are spaced from the at least one reservoir to define a first air gap between each of the side walls and the at least one reservoir.

Abstract: A pressurized ink delivery system having two delivery reservoirs in an inkjet printer enables a control system to alternate between the two reservoirs for printhead supply without coupling pressurized air from a delivery reservoir to a low pressure source of ink. Each delivery reservoir includes a conduit having an orifice that enables the pressure within a delivery reservoir to exit the reservoir before the ink delivery reservoir is fluidly connected to the low pressure source of ink for refilling of the delivery reservoir. By dropping the high pressure reservoir to atmosphere and then switching the seal actuators for the two reservoirs, the spray of ink is avoided.

Abstract: A check valve unit is provided for a high-speed phase change ink image producing machine between a reservoir for receiving and holding a volume of melted ink from a source and a receiving unit, which may be a printhead system. The check valve unit includes a plurality of ball elements trapped between upper and lower housings defining a like plurality of inlet and discharge passageways. The passageways are configured to optimize flow of melted ink through the unit during charging of the secondary reservoir. The check valve unit is scalable as to size and number of reservoirs for a particular application. The unit further incorporates features that simplify the manufacturing and assembly process while maintaining optimal performance.

Abstract: A liquid ink transport assembly mitigates the migration of ink dye from one conduit in a plurality of conduits to another conduit in the plurality of conduits. The liquid ink transport assembly includes a plurality of conduits, each conduit in the plurality having a first end and a second end, the conduits in the plurality being arranged in a parallel configuration with at least one conduit being spatially separated from an adjacent conduit by a first distance that is greater than a second distance spatially separating other conduits in the plurality of conduits, and a heater, the plurality of conduits being positioned proximate to a first side of the heater to enable the heater to heat ink being carried between the first and the second ends of the plurality of conduits.

Abstract: A phase change ink imaging device includes an ink loader operatively connected within a housing of the imaging device. At least a portion of the ink loader is configured to be withdrawn from the housing to enable ink stick insertion.

Abstract: A phase change ink imaging device includes a transfix apparatus configured to apply ultrasonic action to ink pixels deposited onto an image bearing surface to facilitate transfer and/or fixing of the ink pixels to print media.

Abstract: An apparatus and method that operates a flattener in an ink-based printing apparatus. The printing apparatus can include a media path configured to transport media sheets. The printing apparatus can include a marking module configured to jet ink drops to generate images on the media sheets. The printing apparatus can include a flattener configured to flatten the ink jet drops of the images on the media sheets in a flattener nip. The printing apparatus can include a release agent distributer configured to distribute release agent on a first rotational flattener member. The printing apparatus can include a controller configured to control the printing apparatus to reduce an inter-copy gap distance between a first media sheet and a second media sheet to prevent a first rotational flattener member from contacting a second rotational flattener member between the first media sheet and the second media sheet.

Abstract: A print head assembly for an ink jet printer includes an ink flow path configured to allow passage of a phase-change ink. A pressure unit is fluidically coupled to the ink flow path to apply a pressure to the ink. The applied pressure is controlled by a control unit during a time that the ink in the ink flow path is undergoing a phase change. During the phase change, a portion of the ink in a first region of the ink flow path is in liquid phase and another portion of the ink in another region of the ink flow path is in solid phase. A constant or variable pressure can be applied at least to the liquid phase portion of the ink during a phase transition from a liquid phase to a solid phase or from a solid phase to a liquid phase.

Abstract: An ink composition including one or more oxazoline compounds or oxazoline derivatives having either crystalline, amorphous or even semi-crystalline properties for use in a particular printing application, such as in a direct-to-paper print process.

Abstract: The present disclosure provides systems and methods for supplying solid-ink pellets from a container to a printing apparatus. The solid-ink pellets are held in a collapsible, hermetic bag, which is carried in the container. The bag is partially or fully transparent. A vacuum interface provides an access point to the bag. Further, a perforated nozzle, adapted to engage the vacuum interface, provides airflow within the bag and is configured to apply a suction force to extract solid-ink pellets from the bag.

Abstract: A solid ink stick delivery apparatus uses a rotating member mounted within a plurality of hollow sleeves to transport solid ink sticks to a melting device. The interior surface of the hollow sleeves are configured with a surface that frictionally engages the rotating member, but enables the member to slip past the interior surface when the hollow sleeve is stopped from proceeding along the length of the member.

Abstract: A liquid ink transport assembly mitigates the migration of ink dye from one conduit in a plurality of conduits to another conduit in the plurality of conduits. The liquid ink transport assembly includes a plurality of conduits, each conduit in the plurality having a first end and a second end, the conduits in the plurality being arranged in a parallel configuration with at least one conduit being spatially separated from an adjacent conduit by a first distance that is greater than a second distance spatially separating other conduits in the plurality of conduits, and a heater, the plurality of conduits being positioned proximate to a first side of the heater to enable the heater to heat ink being carried between the first and the second ends of the plurality of conduits.

Abstract: A printhead having a circulation device to create a directed flow of ink and a separator to divert particulate matter, which can be present in the ink, to a location where the particulate matter falls out of the directed flow. The circulation device can include a heater configured to provide the directed flow of ink and the separator can include a divider to provide a location for particulate matter to be separated and screened from the ink and a bin to catch particulate matter falling from the ink during circulation.

Abstract: According to one aspect of the present disclosure, a print system is provided comprising a plurality of networked print engines in communication with one another, a presence detector, and a controller to communicate with the presence detector to determine a user presence and to access usage data of each of the plurality of print engines. The controller combines and shares the user presence and the usage data to adjust operations of the plurality of print engines enabling quick entry to, and quick exit from, power saving mode of at least two of the plurality of print engines.

Abstract: The present disclosure provides systems and methods for supplying solid-ink pellets from a container to an image-forming device. The system includes a delivery tube within the container, with one or more openings to receive solid-ink pellets from the container. An agitating structure coupled to the delivery tube disturbs the solid ink pellets. The movement of the delivery tube moves the agitating structure, resulting in disturbing the solid-ink pellets and maintaining flowability of the pellets to the image-forming device.

Abstract: A solid phase change ink melter assembly in a phase change ink image producing machine includes an array of a plurality of spaced apart fins, the array defining a top face for receiving the solid pieces of phase change ink, a bottom face for discharging melted ink, and opposite melter surfaces for melting the solid pieces in contact therewith. The assembly further including a number of heat transfer devices extending through and in heat transfer contact with the plurality of fins, the heat transfer devices including a heating element for heating the device. The bottom edge of the fins defines a plurality of apexes which serve as drip points for molten phase change ink.

Abstract: This disclosure is generally directed to curable solid inks, such as radiation-curable solid inks, and their use in forming images, such as through transfuse printing. More specifically, this disclosure is directed to radiation-curable solid inks, such as ultraviolet-light-curable phase-change inks, that comprise curable and non-curable waxes.

Abstract: A system controls application of heat with a melt plate to an ink stick in a solid ink imaging device. The system includes a melt plate, a heater configured to heat the melt plate to a temperature sufficient to melt solid ink, a feed channel configured to direct solid ink sticks towards the melt plate to enable a leading edge of a solid ink stick to be melted by the heated melt plate, and a controller configured to separate the heater and the leading edge of the ink stick by a distance that arrest melting of the ink stick.

Abstract: An ink jet recording apparatus includes: a head that ejects droplets of ink; a flow passage portion; and a temperature adjustment unit. The flow passage portion supplies the ink to the head. The flow passage portion includes, in a part thereof, a reservoir unit that reserves the ink. The temperature adjustment unit is capable of adjusting temperatures of the flow passage portion and the head independently of each other. The temperature adjustment unit controls the temperatures of the flow passage portion and the head so that the ink in the head becomes liquid from solid after ink in the flow passage portion is turned to liquid from solid.

Abstract: An apparatus controls dissipation of heat from melted ink within a component storing melted ink within a solid ink imaging device. The apparatus includes a housing, a passage within the housing that is configured to store melted ink, and a temperature control connector mechanically coupled to the housing and passage, the temperature control connector being configured to mitigate void formation in melted ink as the melted ink cools in the passage.

Abstract: A method for calibrating in situ a plurality of printheads in an imaging device has been developed. Firing signals operate a plurality of printheads to form ink test patterns on an image receiving member. Reflectance measurements of light reflected from the test patterns and optical density measurements for a portion of the patterns formed by only one printhead in the plurality of printheads are used to adjust the firing signals and enable the printheads to print within a predetermined range about an average reflectance value and a predetermined optical density.

Abstract: A melt plate for use in a solid ink printer is formed with a drip plate to provide controlled flow of melted ink from the melt plate to a drip point. The melt plate includes a first portion having a perimeter, a second portion having a perimeter, the second planar portion angling from the first portion along a transition boundary at a first angle, a first rim extending around the perimeter of the first portion except along the transition boundary, the first rim angling from the first portion at a second angle, and a second rim extending around the perimeter of the second portion except along the transition boundary and a drip point, the second rim angling from the second portion at a third angle, the third angle being different than the second angle.

Abstract: An insulation container has an insulation material, a filter arranged to encase the insulation material, the filter of a material that prevents escape of the insulation material while allowing air to pass through, and a container arranged to encase the filter, the container being heat sealable. A printer has an ink supply, a print head arranged to receive ink from the ink supply and configured to receive electrical signals from a controller and to dispense ink in accordance with the electrical signals onto a print substrate, and an insulator to absorb heat from the print head.

Abstract: A printing system has a print mechanism to dispense a curable ink onto print media, a texture roller having a textured surface arranged to transfer a texture through a film to the curable ink on the media resulting in textured ink, and a curing mechanism to cure the textured ink. A printing system has a print head to dispense a curable ink onto print media, a film arranged adjacent a side of the media upon which the ink is dispensed, a texture roller arranged on a side of the film opposite the media to transfer texture to the curable ink, resulting in textured ink, and a curing mechanism to cure the textured ink. A method of controlling gloss in a printed image includes forming a printed image on print media using curable ink, using a roller to transfer a texture pattern to the curable ink, and curing the ink such that the pattern cures into the ink.

Abstract: A solid phase change ink melter assembly in a phase change ink image producing machine includes an array of a plurality of spaced apart fins, the array defining a top face for receiving the solid pieces of phase change ink, a bottom face for discharging melted ink, and opposite melter surfaces for melting the solid pieces in contact therewith. The assembly further includes a number of heat transfer devices extending through and in heat transfer contact with the plurality of fins, the heat transfer devices including a heating element for heating the device. The bottom edge of the fins defines a plurality of apexes which serve as drip points for molten phase change ink.

Abstract: An ink removal system includes a drip bib and a flexible member. The drip bib collects melted ink flowing down the face of a printhead and the flexible member captures ink dropping from the drip bib after an ink receptacle has received most of the ink collected by the drip bib. When the ink receptacle returns to the position where the receptacle catches melted ink from the drip bib, the receptacle also bends the flexible member and releases the captured ink, which falls into the ink receptacle.

Abstract: A solid ink printer is configured to learn the identity of solid ink sticks for printer operation. The solid ink printer includes a feed channel having an insertion opening configured to receive solid ink sticks, a sensor positioned near the insertion opening of the feed channel and configured to obtain solid ink stick type data from a solid ink stick inserted into the insertion opening of the feed channel, and a controller communicatively coupled to the sensor to receive the solid ink stick type data, the controller being configured to store the solid ink stick type data in a memory in response to an initialization signal and to operate the solid ink printer with reference to the solid ink stick type data stored in the memory by the controller.

Abstract: A pressurized ink delivery system having two delivery reservoirs in an inkjet printer enables a control system to alternate between the two reservoirs for printhead supply without coupling pressurized air from a delivery reservoir to a low pressure source of ink. Each delivery reservoir includes a conduit having an orifice that enables the pressure within a delivery reservoir to exit the reservoir before the ink delivery reservoir is fluidly connected to the low pressure source of ink for refilling of the delivery reservoir. By dropping the high pressure reservoir to atmosphere and then switching the seal actuators for the two reservoirs, the spray of ink is avoided.

Abstract: Provided is an eco-friendly rotogravure hot melt ink composition. More specifically, the present invention provides the rotogravure hot melt ink composition meeting requirements of a carbon footprint system by using, as a vehicle, poly propylene carbonate prepared using carbon dioxide as a raw material. The rotogravure hot melt ink prepared by the composition of the present invention has a higher printing density and more easily performs printing at low temperature than a poly vinyl acetate based hot melt ink according to the related art.

Abstract: A system has been developed that controls application of heat with a melt plate to an ink stick in a solid ink imaging device. The system includes a melt plate, a heater configured to heat the melt plate to a temperature sufficient to melt solid ink, a heat transfer unit configured to cool the melt plate to arrest the melting of the solid ink within a predetermined time, and a controller configured to actuate the heat transfer unit to selectively cool the melt plate in response to reaching a heater power off phase.

Abstract: An ink stick for use in a phase change ink imaging device has a protrusion with a predetermined height that is configured to enable a sensor in an ink loader of the imaging device to detect the height of the protrusion. The predetermined height of the protrusion corresponds to a control parameter for the imaging device.

Abstract: A microfluidic device includes a first substrate, and a phase change ink deposited on a surface of the first substrate. The phase change ink includes an ink vehicle including a polymeric material having one or more hydroxyl groups, and an optional colorant, wherein the phase change ink is solid at room temperature but is liquid at a jetting temperature of from about 60 to about 150° C., and a hydroxyl group mass percentage, measured as a total mass of hydroxyl groups to an entire weight of the ink, is from about 1% to about 35%.

Abstract: A solid ink stick for use in an imaging device, such as a phase change inkjet printer, is provided. The solid ink stick has a retrieval feature located on a top surface thereof. When the ink stick is incorrectly loaded through the insertion opening of a feed channel of the printer, the retrieval feature has a vertical dimension such that the ink stick can be grasped, such as by two fingers of a user, to remove the ink stick through the insertion opening. The retrieval feature generally includes two lower surfaces interconnected with at least one upper surface.

Abstract: A material for an inkjet ink composition, including an organic solvent; and a siloxane compound comprising at least one organic group having an optically active site and an associative site in the molecule, wherein the organic solvent satisfies the following requirements a) to c): a) the siloxane compound is soluble in the organic solvent and does not precipitate after dissolved at room temperature; b) the siloxane compound can form an associative structure in the organic solvent at room temperature; and c) an inkjet ink composition prepared by dissolving the siloxane compound in an organic solvent is dischargeable from an inkjet nozzle.

Abstract: The present disclosure provides apparatus and method for supplying uninterrupted flow of solid-ink pellets to an image-forming device. The apparatus includes a container for retaining solid-ink pellets, and a selectably-inflatable bladder disposed within the container. Further, the apparatus includes a tube communicating the bladder with a pressure supply.

Abstract: An airflow system for a solid-ink melter tank is disclosed, which prevents clogging of drop tube supplying solid ink to the solid-ink melter tank. An inlet may provide airflow as well as solid ink to the melter tank and an outlet maintained at a temperature higher than temperature of the inlet, promotes a convective air current. The inlet may be coaxial with the drop tube or is present as a separate opening in the solid-ink melter tank. The outlet can be taller, externally insulated, and fabricated with a thermally conductive material as compared to the inlet. The heated outlet promotes expulsion of hot air from the solid-ink melter tank and prevents heating of drop tube, which leads to drop tube clogging by partially melting the solid ink.

Abstract: An ink including (a) a carrier and (b) a colorant comprising nanodiamond black.

Abstract: A molten ink supply for a solid ink printing machine includes a container for storing solid ink pellets and a withdrawal tube having an inlet end disposed within the container. A vacuum generator is disposed at the outlet end of the withdrawal tube operable to draw a vacuum within the tube. A feed conduit is connected to the outlet end for receiving solid ink pellets drawn therein by said vacuum generator and conveying the pellets to a melting station operable to melt the solid ink pellets. An assist tube is provided within the container with a discharge nozzle disposed within the withdrawal tube at the inlet end and operable to provide a flow of air into the withdrawal tube to agitate solid ink pellets and facilitate withdrawal of the pellets by the vacuum generator.