Abstract: A method of forming a nip with a skewed transfix roll includes positioning a first axis of rotation of a transfix roll at a skewed angle with respect to a second axis of rotation of an image drum, forming a nip with the skewed transfix roll and the image drum, and operating the printer with the nip formed with the skewed transfix roll.

Abstract: A phase change ink imaging device includes a fluid transport apparatus that facilitates flow of fluid from a source to a receptacle. The fluid transport apparatus includes a deforming member positioned proximate a fluid transport conduit to deform a portion of the fluid transport conduit selectively and propel fluid through the fluid transport conduit, and a restoring member positioned proximate the fluid transport conduit to exert a force against the fluid transport conduit that opposes the deforming of the fluid transport conduit.

Abstract: A method for delivering molten ink to a printing mechanism alternates between a first and second reservoir receiving molten ink from a receiving ink reservoir while providing ink from the other of the first and second reservoirs to a printing mechanism. The alternation of the two reservoirs is achieved with coordinated operation of two actuators operatively connected to two seal members.

Abstract: A liquid ejection apparatus includes a liquid storing unit that stores a liquid, a liquid ejection head that ejects the liquid, a supply tube having one end connected to the liquid storing unit and the other end connected to the liquid ejection head so that the liquid is supplied from the liquid storing unit to the liquid ejection head, a heating unit that heats a fluid, and a circulation tube in which the fluid that has been heated in the heating unit circulate therethrough, wherein the circulation tube is wound on the supply tube at least on the side of the liquid ejection head.

Abstract: A system for recycling waste phase change ink in a phase change ink imaging device includes a printhead having an on-board phase change ink reservoir and a waste ink collector for receiving ink from an ejecting face of the printhead. The printhead is supplied ink from a remote ink reservoir, which is also fluidly connected to the waste ink collector by a waste phase change ink conveyor, which is configured to convey melted waste phase change ink from the waste ink collector to the remote ink reservoir.

Abstract: A solid ink stick for use in solid ink printers is provided that enables adjacent ink sticks to be separated and retained at a predetermined location in the feed channel.

Abstract: A solid ink loading system for a phase change ink imaging device includes an ink loader having a first end, a second end, and at least one feed channel extending between the first and the second end. The at least one feed channel includes an insertion region intermediate the first and the second end where ink sticks enter the at least one feed channel. The at least one feed channel is configured to guide ink sticks in a feed direction from the insertion region toward the second end. An ink stick retractor is configured for movement between a forward position and a rearward position substantially parallel to at least a portion of the at least one feed channel. The forward position is closer to the second end of the feed channel than the first position. The ink stick retractor is configured to selectively move ink sticks in the at least one feed channel in a retraction direction toward the first end.

Abstract: A volumetric container for storing phase-change ink includes a housing that is comprised primarily of a thermally insulating material and a heater element positioned within the housing. The heater element is positioned in the container to melt solid ink quickly to enable printing operations.

Abstract: A fluid transport apparatus facilitates flow of fluid from a source to a receptacle. The fluid transport apparatus includes a fluid transport conduit for transporting fluid, the fluid transport conduit having an inlet end that is coupled to a fluid supply and an outlet end that is coupled to a receptacle, a deforming member positioned proximate the fluid transport conduit and configured to deform a portion of the fluid transport conduit selectively and propel fluid through the fluid transport conduit, and a restoring member positioned proximate the fluid transport conduit and configured to exert a force against the fluid transport conduit that opposes the deforming of the fluid transport conduit.

Abstract: An ink umbilical provides different colors of heated ink to multiple print heads in an integrated structure. The ink umbilical includes a first plurality of ink carrying conduits mounted on one side of a heater and a second plurality of conduits mounted on a second side of the heater opposite the first side of the heater. The heater is operated to keep the ink in the conduits on each of the heater in a predetermined temperature range.

Abstract: A system and method is provide for delivering molten ink to a printing mechanism including receiving molten ink in a receiving reservoir, and alternating which of a plurality of reservoirs is opened to the receiving reservoir to receive molten ink while at least one other of the plurality of reservoirs is opened to dispense molten ink to the printing mechanism, in response to the level of ink in a reservoir dispensing molten ink to the printing mechanism.

Abstract: A drum maintenance system for use in an imaging device includes a reservoir having a supply of release agent. An applicator is configured to receive release agent from the reservoir and to apply the release agent to an imaging surface of an imaging device. A metering blade is positioned to meter the release agent on the imaging surface applied by the applicator. The metering blade is arranged in doctor mode with respect to the imaging surface and includes a tip positioned adjacent the imaging surface. The tip has a square portion positioned proximate the imaging surface and a beveled portion opposite the imaging surface.

Abstract: An imaging device includes a substantially continuous web of media, and a web transport system configured to transport the continuous web along a web path. A print station is positioned along the web path and is configured to apply ink to the continuous web. A temperature leveling ink spreader is disposed along the web path downstream from the print station. The temperature leveling ink spreader includes a leveler roller including a heater configured to generate thermal energy to heat the leveler roller to a spreading temperature. The leveler roller is positioned to be partially wrapped by the continuous web to generate a predetermined dwell time between the continuous web and the leveler roller as the continuous web is being transported to equalize the temperatures of the web and ink on the web to within a predetermined range about the spreading temperature.

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: A method enables adjustment of a print speed for a phase change ink imaging device with reference to an ink level sensor in a print head reservoir indicating an open loop or a closed loop state. The adjustment may also be made with reference to a measured image density, which may be a rolling solid area coverage average.

Abstract: An inkjet printer operates to produce a print with at least one component operating at less than a normal operating parameter. The printer identifies an image density for an image to be printed and operates the printer with operational parameters different than normal operational parameters to enable printing operations before all of the components in the printer reach their operational parameters.

Abstract: Among other things, ink is jetted onto a substrate, the ink includes (a) a pigment and (b) a wax, and the jetted ink on the substrate is heated to fire the pigment on the substrate.

Abstract: A method has been developed that reduces the electrical energy consumption of an inkjet printing system. The method regulates the energy consumption of the printing system with reference to a monitored temperature of at least one component in the inkjet printing system.

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 acidic 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 an acidic group mass percentage, measured as a total mass of acid groups to an entire weight of the ink, is from about 1% to about 35%.

Abstract: A solid phase change ink melter assembly in a phase change ink image producing machine comprises 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 comprises 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: A method is implemented to control movement of a solid ink stick from an insertion port to a corresponding feed channel to help ensure that each feed channel in a plurality of feed channels contains only ink sticks corresponding to the feed channel. The method includes receiving solid ink sticks in an insertion port located at one end of a feed channel in the solid ink printer, identifying each ink stick received in the insertion port, and removing a passage barrier from the feed channel in response to the ink stick being identified as corresponding to ink configured for passage through the feed channel.

Abstract: A phase change magnetic ink including a phase change ink carrier; an optional colorant; an optional dispersant; an optional synergist; an optional antioxidant; and an inorganic oxide coated magnetic nanoparticle comprising a magnetic core and an inorganic oxide shell disposed thereover.

Abstract: A solid phase change ink melter assembly in a phase change ink image producing machine comprises 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 comprises 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: A phase change magnetic ink and process for preparing same including comprising a phase change ink carrier; an optional colorant; an optional dispersant; an optional synergist; an optional antioxidant; and a polymer coated magnetic nanoparticle comprising a magnetic core and a polymeric shell disposed thereover.

Abstract: A phase change magnetic ink including a phase change ink carrier; an optional colorant; an optional dispersant; an optional synergist; an optional antioxidant; and a carbon coated magnetic nanoparticle comprising a magnetic core and a carbon shell disposed thereover.

Abstract: A phase change magnetic ink and process for preparing same including comprising a phase change ink carrier; an optional colorant; an optional dispersant; an optional synergist; an optional antioxidant; and a coated magnetic nanoparticle comprising a magnetic core and a shell disposed thereover.

Abstract: A phase change magnetic ink including a phase change ink carrier; an optional colorant; an optional dispersant; an optional synergist; an optional antioxidant; and a surfactant coated magnetic nanoparticle comprising a magnetic core and a shell disposed thereover.

Abstract: A temperature leveling system for thermally conditioning ink deposited onto a print media includes a non-contact cooling device for reducing temperatures of ink deposited onto a print media to a first average temperature. A leveler includes a thermal control for maintaining the leveler at a second temperature that is different than the first average temperature. The leveler is configured to bring the temperatures of the ink to within a predetermined range about the second temperature after the reduction in temperature at the non-contact cooling device. A heater is positioned to heat the ink and media to a third temperature after the leveler, the third temperature being greater than the second temperature.

Abstract: A printhead provides selective heating to a supply of molten ink within an ink flow channel. The printhead is adapted to be in electrical communication with a controller and programmed to determine ink required by a print job. Based on the determined ink required by the print job, the controller accordingly provides selective heating to the printhead. The printhead includes an ink inlet, a nozzle in fluid communication with the ink inlet, and an ink flow channel having a length and extending between the ink inlet and the nozzle. A molten ink supply from a solid ink supply retaining device is received by the ink inlet and ejected from the nozzle on a print medium. A plurality of heating zones is also disposed along the length and adjacent to the ink flow channel to provide heating to the molten ink supply adjacent to each of the plurality of heating zones.

Abstract: A solid printer includes a solid ink container that expels solid ink units in predetermined amounts for delivery to a melting device within the printer. The solid ink container includes a housing in which solid ink pellets are stored, an opening in the housing through which solid ink units are expelled, a first moveable member located within the housing proximate to the opening, the first moveable member being configured to move solid ink units through the opening, and a second moveable member located within the housing, the second moveable member being configured to move solid ink pellets to the first moveable member to enable the first moveable member to expel solid ink pellets through the opening in the housing.

Abstract: A solid ink printer selectively enables solid ink sticks to be inserted into an insertion port. The solid ink printer includes a plurality of feed channels, each feed channel terminating at a melting device that heats solid ink sticks to a melting temperature at one end of the feed channel, an insertion port operatively connected to another end of each of the plurality of feed channels, the insertion port being configured with an opening through which solid ink sticks are inserted for movement through one of the feed channels operatively connected to the insertion port, a member positioned proximate the opening in the insertion port, an actuator operatively connected to the member and configured to move the member with respect to the opening of the insertion port, and a controller operatively connected to the actuator, the controller being configured to detect at least one event and operate the actuator to move the member to block solid ink sticks from entering through the opening of the insertion port.

Abstract: A solid phase change ink melter assembly in a phase change ink image producing machine having 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: 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: An ink loader for a phase change ink imaging device includes an automated access control system that enables ink stick insertion based on user initiated ink load requests with reference to the operating state of the imaging device.

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: The present disclosure provides apparatus and method for maintaining the flowability of solid-ink pellets in a system for delivering the pellets to an image-forming device. The apparatus includes a container storing the solid-ink pellets, and an extraction assembly for extracting the solid-ink pellets. The extraction assembly includes a tubular housing, extending from the bottom portion of the container, and an auger member rotatably placed within the tubular housing. The tubular housing receives the solid-ink pellets from the container and the auger member rotates to break up the obstructions to pellet flow.

Abstract: A container for storing phase-change ink includes a housing that is comprised primarily of a thermally insulating material and an inductive heater element positioned within the housing. The inductive heater element is formed in a manner that increases the surface area of the heater and enables frozen ink in the vicinity of a reservoir outlet to melt quickly to enable printing operations.

Abstract: To provide a method for fixing an image, wherein the image has a high fastness even immediately after being recorded, and is free from inconveniences such as thermal influence or unfavorable curing inherent to the conventional fixing device, as well as safety problems. To achieve such an object, in a method for fixing an image recorded on a recording medium with a recording material containing a component curable by a plasma processing, the image is fixed on the recording medium by the plasma processing at a normal pressure.

Abstract: A printer for transferring a phase-change ink onto a substrate includes components for conveying the substrate along a path through the printing machine, a printing station including a plurality of printheads disposed along the path and configured to transfer the phase-change solid ink onto the substrate as it is conveyed along the path, a plurality of metal backing rollers facing the plurality of printheads and arranged to support to the substrate passing between the backing rollers and the printheads, and a spreader station receiving the substrate from the printing station and configured to spread the phase-change solid ink on the substrate, the spreader station including a spreader roller and a metal pressure roller opposing the spreader roller. Each of the non-oiled metal rollers includes a coating that is oleophobic that has low adhesion toward the solid ink image but sufficient lateral friction as to not slide against the ink or paper web.

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: 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 fluid transport apparatus facilitates flow of fluid from a source to a receptacle. The fluid transport apparatus includes a fluid transport conduit for transport of fluid through the conduit, the conduit being coupled between a fluid supply and a fluid receptacle, a compressor conduit proximate the fluid transport conduit along a portion of the fluid transport conduit between the fluid supply and the fluid receptacle, and a pump coupled to the compressor conduit for injecting fluid into the compressor conduit, and a vent that is operated to selectively enable pressurization and venting of the compressor conduit to compress and decompress the portion of the fluid transport conduit proximate the compressor conduit to pump fluid through the fluid transport conduit.

Abstract: A fluid transport apparatus maintains temperature of a fluid transported through a conduit. The fluid transport apparatus includes a fluid transport conduit that is selectively deformed by a pressure within a compressor conduit and allowed to return to its original shape by venting the pressure through a venting valve. The alternating pressurization and release of pressure from the compressor conduit moves fluid through the fluid transport conduit. A thermal conductor is associated with the fluid transport conduit to maintain the temperature of the fluid in the fluid transport conduit within a predetermined range.

Abstract: An ink status conveyance system comprises a maximum monitored ink level sensor operable with respect to an ink source for holding a supply of ink and delivering the ink to a printhead. The ink level sensor is configured to detect when an available amount of ink in the ink source corresponds to an ample ink level. A notification controller is configured to track the available amount of ink in the ink source between an ample ink level and an ink out level. The notification controller is configured to compare the user designated low ink notification set point to the available ink volume value to generate a low ink notification when the available ink volume value corresponds to the user designated low ink notification set point.

Abstract: In the image-recording of an intermediate transfer system applying an ink jet recording method, reactive liquid reactable with ink is properly formed on the intermediate transfer body. By using the intermediate transfer body having a pattern consisting of lyophilic and lyophobic sections on a surface thereof, the reactive liquid is uniformly applied to the intermediate transfer body to form a layer having a suitable thickness. Thereby, it is possible to form an ink image on the intermediate transfer body while preventing the miss landing of ink droplets and restricting the deformation of an ink dots. By transferring this ink image to a recording medium, it is possible to form a high-quality ink image on various kinds of recording media in a stable manner.

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: A volumetric container for storing phase-change ink includes a housing that is comprised primarily of a thermally insulating material and a heater element positioned within the housing. The heater element is positioned in the container to melt solid ink quickly to enable printing operations.

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: A machine, such as a phase change or solid ink printing apparatus, has at least one multiple supply unit in the form of an ink stick disposed therein. The ink stick has an electronically-readable memory device associated therewith, and the memory device has stored therein electronic data related to the ink stick and readable by the machine. The memory device is attached to the ink stick and removed before the ink stick is used for printing in the machine. In another aspect, the memory device is attached to a container for the ink stick. The container is a cartridge for use in the machine, or a container for packaging the ink stick. The machine may include a coupler configured to read electronic data from the memory device while the memory device is positioned external to the printing apparatus, thus allowing the machine to verify the suitability of the ink stick before it is installed in the machine.

Abstract: A method of feeding ink sticks into an imaging device enables identification of data useful for device control. The method includes inserting at least one ink stick into an ink loader, the at least one ink stick including a plurality of code element patterns formed in the ink stick, each code element pattern having a plurality of code elements that include a first code element identifying a start of a code element pattern and a second code element identifying an end of the code element pattern, each code element pattern being configured to generate a same coded signal pattern; urging the ink stick toward a melt device; actuating at least one sensor in the imaging device with the plurality of code element patterns to generate a predetermined coded pattern of signals; and comparing the predetermined coded pattern of signals to identify a code word.