Patent application number | Description | Published |
20090066758 | FLEXIBLE PRINTHEAD CIRCUIT - A flexible circuit for use within a printhead assembly and to connect a printhead body to an external circuit includes a substantially planar portion having one or more layers of conductive material and having a top surface substantially parallel to a top surface of the printhead body. One or more integrated circuits can be mounted onto the planar portion. Multiple leads extend from each integrated circuit, the leads electrically connected to the printhead body. One or more arms are attached to, and substantially perpendicular to, the planar portion, each arm including one or more external connectors configured to connect to the external circuit. | 03-12-2009 |
20090201341 | Adjustable Mount Printhead Assembly - A mounting assembly for a printhead assembly is described that can allow dynamic nozzle and drop placement adjustment in one or more directions. | 08-13-2009 |
20100091060 | Adjustable Mount Printhead Assembly - A mounting assembly for a printhead assembly is described that can allow dynamic nozzle and drop placement adjustment in one or more directions. | 04-15-2010 |
20100214359 | Fluid Ejecting with Centrally Formed Inlets and Outlets - An apparatus for ejecting droplets of a fluid includes a substrate, a first plurality of nozzles formed in a first region of a nozzle face of the substrate, and a second plurality of nozzles formed in a second region of the nozzle face. The second region is separated from the first region. An inlet and an outlet are both formed in an upper face of the substrate opposite a third region of the nozzle face, the third region being located between the first region and the second region, and a plurality of fluid paths formed in the substrate and fluidically connecting the first plurality of nozzles and the second plurality of nozzles with the inlet and outlet. | 08-26-2010 |
20100214380 | Apparatus for Reducing Crosstalk in the Supply and Return Channels During Fluid Droplet Ejecting - A fluid droplet ejection apparatus includes a substrate having a fluid inlet passage, a plurality of nozzles, and a plurality of flow paths each fluidically connecting the fluid inlet passage to an associated nozzle of the plurality of nozzles. Each flow path includes a pumping chamber connected to the associated nozzle and an ascender fluidically connected between the fluid inlet passage and the pumping chamber. The ascender is located proximate to an outside edge of the fluid inlet passage. | 08-26-2010 |
20100220146 | Moisture Protection of Fluid Ejector - A fluid ejection apparatus includes a substrate having a plurality of fluid passages for fluid flow and a plurality of nozzles fluidically connected to the fluid passages, a plurality of actuators positioned on top of the substrate to cause fluid in the plurality of fluid passages to be ejected from the plurality of nozzles, a protective layer formed over at least a portion of the plurality of actuators, a housing component having a chamber, the chamber adjacent to the substrate, and an absorbent layer inside the cavity. The absorbent layer is more absorptive than the protective layer. | 09-02-2010 |
20100253742 | MANIFOLD FOR A PRINTHEAD - A printhead assembly is described including multiple printheads, a manifold and multiple inlet tubes. The printheads each include: a fluid inlet to receive fluid into the printhead; and a set of one or more nozzles to deposit fluid on a substrate. The manifold is connected to the printheads and includes: a fluid inlet duct configured to receive fluid for delivery to the printheads; multiple fluid inlet channels for connecting the fluid inlet duct to the printheads; and multiple fluid inlet valves configured to control a flow of fluid from the fluid inlet duct to each of the fluid inlet channels. The inlet tubes each have a proximal end integral to either the manifold or one of the printheads, and a distal end connected to either the manifold or said printhead with a single fluid-tight connection. | 10-07-2010 |
20110006135 | FLUID EJECTOR HOUSING INSERT - A fluid ejector includes a fluid ejection assembly, a housing, and an insert. The fluid ejection assembly includes one or more silicon bodies and a plurality of actuators. The one or more silicon bodies includes a silicon body having a plurality of fluid passages for fluid flow and a plurality of nozzles fluidically connected to the plurality of fluid passages. The plurality of actuators cause fluid in the plurality of fluid passages to be ejected from the plurality of nozzles. The housing assembly includes one or more plastic bodies, at least one plastic body attached to at least one silicon body to form a sealed volume on a side of the fluid ejection assembly opposite the nozzles. The insert is embedded in the at least one plastic body in proximity to the at least one silicon body, the insert having a coefficient of thermal expansion of less than 9 ppm/° C. | 01-13-2011 |
20110007117 | MEMS Jetting Structure For Dense Packing - A fluid ejector includes a fluid ejection module having a substrate and a layer separate from the substrate. The substrate includes a plurality of fluid ejection elements arranged in a matrix, each fluid ejection element configured to cause a fluid to be ejected from a nozzle. The layer separate from the substrate includes a plurality of electrical connections, each electrical connection adjacent to a corresponding fluid ejection element. | 01-13-2011 |
20110080449 | Non-wetting Coating on Die Mount - Printing devices are described that have a printing die with a coplanar adjacent layer. The coplanar adjacent layer is sufficiently non-wetting to fluids that the layer can be easily wiped clean of fluid that is inadvertently deposited thereon. A non-stick surface is optionally applied to the adjacent layer which can withstand both mechanical and chemical abrasion that can be caused by corrosive ejection fluids or wiping mechanisms. | 04-07-2011 |
20110109696 | ADJUSTABLE PRINTHEAD MOUNTING - A system includes a mounting assembly to mount a printhead to a frame having a length in a first direction and a width in a second direction. The mounting assembly includes a fixed component affixed to the frame and a movable component that can move relative to the fixed component. A first pair of flexures connects a first end of the fixed component to a first end of the movable component, and a first adjustment mechanism is positioned at the first end. A second pair of flexures connects a second end of the fixed component to a second end of the movable component, and a second adjustment mechanism is positioned at the second end. A connector couples the mounting assembly to the printhead such that movement of the movable component imparts movement to the printhead. The first adjustment mechanism and the second adjustment mechanism can be operated individually or together. | 05-12-2011 |
20110115852 | ACTUATABLE DEVICE WITH DIE AND INTEGRATED CIRCUIT ELEMENT - A fluid ejector includes a fluid ejection module and an integrated circuit element. The fluid ejection module includes a substrate having a plurality of fluid paths, a plurality of actuators, and a plurality of conductive traces, each actuator configured to cause a fluid to be ejected from a nozzle of an associated fluid path. The integrated circuit element is mounted on the fluid ejection module and is electrically connected with the conductive traces of the fluid ejection module such that an electrical connection of the module enables a signal sent to the fluid ejection module to be transmitted to the integrated circuit element, processed on the integrated circuit element, and output to the fluid ejection module to drive the actuator. | 05-19-2011 |
20110122587 | FLEXIBLE CIRCUIT STRETCHING - A method of connecting electrical components and an electronic device formed using this method are disclosed. This method includes stretching a first substrate with a plurality of conductive traces to form a stretched substrate where at least one increased pitch (a spacing between two conductive traces plus a width of one conductive trace) is not greater than 40 microns; and electrically connecting the conductive traces on the first substrate to conductive traces on a second substrate. A device by which this method can be implemented is also disclosed, which includes a base, and platforms and stretchers mounted to the base that are configured to pull opposite ends of the first substrate to align the conductive traces thereon with the conductive traces on the second substrate. | 05-26-2011 |
20110128324 | METHOD AND APPARATUS FOR MOUNTING A FLUID EJECTION MODULE - A system and method for mounting a fluid droplet ejection module to a frame is disclosed, where the fluid ejection module includes a mounting component having a mounting surface. A connector is configured to detachably attach to the frame and is positioned between the frame and the mounting surface of the fluid ejection module. A portion of a mating surface of the connector is positioned adjacent the mounting surface of a corresponding fluid ejection module and is in direct contact with the mounting surface. One or more recesses are formed in at least one of either the mounting surface of the fluid ejection module or the mating surface of the connector. The one or more recesses have a substantially uniform thickness and are filled with an adhesive. The adhesive is cured after aligning the fluid ejection module to the frame. | 06-02-2011 |
20110128335 | CIRCULATING FLUID FOR FLUID DROPLET EJECTING - A fluid droplet ejection apparatus includes a printhead having a fluid supply and a fluid return. A substrate is attached to the printhead, and the substrate includes a fluid inlet and a fluid outlet on a surface of the substrate proximate to the fluid supply and fluid return. Nozzles are in fluid communication with the fluid inlet. The fluid inlet of the substrate is in fluid communication with the fluid supply, and the fluid outlet is in fluid communication with the fluid return. A first circulation path through the substrate is between the fluid inlet and the fluid outlet. The fluid supply is in fluid communication with the fluid return through a second circulation path that is through the printhead and not through the substrate. | 06-02-2011 |
20110187773 | NOZZLE LAYOUT FOR FLUID DROPLET EJECTING - A fluid ejection apparatus includes a printhead having a substrate. The substrate includes a nozzle face having a width direction and a length direction. The nozzle face includes a set of four columns of nozzles oriented in a column direction substantially along the width direction of the nozzle face, and the nozzles in each column are positioned on a straight line along the column. A spacing between two adjacent columns of the four adjacent columns is different than a spacing between another two adjacent columns of the four adjacent columns. In some implementations, a controller can control timing of ejection of fluid droplets from the nozzles to deposit lines of fluid droplets on a medium, and the medium can travel relative to the nozzle face. | 08-04-2011 |
20110226807 | Bonded Circuits and Seals in a Printing Device - A fluid ejection device includes a circuit layer having a fluid outlet on a lower surface, a chamber substrate having a fluid inlet on an upper surface, an electrical contact electrically connecting the chamber substrate to the lower surface of the circuit layer, and a seal forming a fluid connection between the fluid outlet of the circuit layer and the fluid inlet of the chamber substrate. The seal and the electrical contact are a eutectic material. The seal and the electrical contact may be the same material. | 09-22-2011 |
20110234668 | Jetting Device with Reduced Crosstalk - A printing device for jetting a liquid includes a flow path body having a plurality of jetting flow paths, a liquid in the plurality of jetting flow paths, a piezoelectric actuator associated with each jetting flow path, a feed substrate having a plurality of fluid inlets, and a driver configured to apply a voltage pulse to the piezoelectric actuator. The first jetting flow path is adjacent to the second jetting flow path and a fluidic travel distance from the piezoelectric actuator of the first jetting flow path to a nozzle of the second jetting flow path is greater than a speed of sound in the liquid times the break off time of a droplet of the fluid from the nozzle. | 09-29-2011 |
20120018032 | MANIFOLD FOR A PRINTHEAD - A printhead assembly is described including multiple printheads, a manifold and multiple inlet tubes. The printheads each include: a fluid inlet to receive fluid into the printhead; and a set of one or more nozzles to deposit fluid on a substrate. The manifold is connected to the printheads and includes: a fluid inlet duct configured to receive fluid for delivery to the printheads; multiple fluid inlet channels for connecting the fluid inlet duct to the printheads; and multiple fluid inlet valves configured to control a flow of fluid from the fluid inlet duct to each of the fluid inlet channels. The inlet tubes each have a proximal end integral to either the manifold or one of the printheads, and a distal end connected to either the manifold or said printhead with a single fluid-tight connection. | 01-26-2012 |
20120160925 | FLUID RECIRCULATION IN DROPLET EJECTION DEVICES - A fluid ejection apparatus includes a fluid distribution layer between a fluid manifold and a substrate. The fluid distribution layer includes fluid supply channels and fluid return channels. Each fluid supply channel receives fluid from the fluid supply chamber and circulates a fraction of the received fluid back to the fluid return chamber through a return-side bypass. The substrate include a plurality of flow paths, each flow path includes a nozzle for ejecting fluid droplets. Each flow path receives fluid from a respective fluid supply channel, and channel un-ejected fluid into a respective fluid return channel. Each fluid return channel can collect the un-ejected fluid from one or more flow paths and a supply-side bypass, and return the collected fluid back to the fluid supply chamber. | 06-28-2012 |
20120162316 | NOZZLE LAYOUT FOR FLUID DROPLET EJECTING - A fluid ejection apparatus includes a printhead having a substrate. The substrate includes a nozzle face having a width direction and a length direction. The nozzle face includes a set of four columns of nozzles oriented in a column direction substantially along the width direction of the nozzle face, and the nozzles in each column are positioned on a straight line along the column. A spacing between two adjacent columns of the four adjacent columns is different than a spacing between another two adjacent columns of the four adjacent columns. In some implementations, a controller can control timing of ejection of fluid droplets from the nozzles to deposit lines of fluid droplets on a medium, and the medium can travel relative to the nozzle face. | 06-28-2012 |
20120206014 | PIEZOELECTRIC TRANSDUCERS USING MICRO-DOME ARRAYS - An ultrasonic piezoelectric transducer device includes a transducer array consisting of an array of vibrating elements, and a base to which the array of vibrating elements in the transducer array are attached. The base include integrated electrical interconnects for carrying driving signals and sensed signals between the vibrating elements and an external control circuit. The base can be an ASIC wafer that includes integrated circuitry for controlling the driving and processing the sensed signals. The interconnects and control circuits in the base fit substantially within an area below the array of multiple vibrating elements. | 08-16-2012 |
20120235539 | PIEZOELECTRIC TRANSDUCERS USING MICRO-DOME ARRAYS - An ultrasonic piezoelectric transducer device includes a transducer array consisting of an array of vibrating elements, and a base to which the array of vibrating elements in the transducer array are attached. The base include integrated electrical interconnects for carrying driving signals and sensed signals between the vibrating elements and an external control circuit. The base can be an ASIC wafer that includes integrated circuitry for controlling the driving and processing the sensed signals. The interconnects and control circuits in the base fit substantially within an area below the array of multiple vibrating elements. | 09-20-2012 |
20130292529 | Fluid Ejection Module Mounting - A bracket includes a support strut configured to carry the fluid ejection module and an alignment strut coupled to the support strut. The alignment strut is configured to affix to the frame so as to orient the support strut with respect to the frame in each of three orthogonal linear directions and three orthogonal angular directions. The alignment strut includes three alignment mechanisms. Each of the first and second alignment features is held mechanically fixed on the alignment strut in a respective aligned position, and the third alignment mechanism is movable on the alignment strut. | 11-07-2013 |
20130293630 | Printhead Module - A printhead module includes a substrate and a head mount. The substrate includes a bottom surface having a plurality of nozzles formed therein and a top surface on a side of the substrate opposite the bottom surface. The substrate includes a plurality of actuators. Each actuator of the plurality of actuators is configured to cause a fluid to be ejected from a nozzle of the plurality of nozzles. The head mount is secured to the substrate and extends over the top surface of the substrate. The head mount includes a first side surface extending upwardly from the bottom surface and a groove formed in the first side surface. The groove is sized and shaped to cause fluid on the first side surface to be drawn by capillary action into the groove. | 11-07-2013 |
20130293641 | BYPASS FLUID CIRCULATION IN FLUID EJECTION DEVICES - A fluid ejection device includes a fluid manifold, a substrate coupled to the fluid manifold, and a fluid distribution structure disposed between the fluid manifold and the substrate. The fluid manifold includes a fluid supply chamber and a fluid return chamber. The substrate defines a flow path including a flow path inlet for receiving fluid, a nozzle for ejecting fluid droplets, and a flow path outlet for channeling away un-ejected fluid. The fluid distribution structure includes a fluid supply channel including a supply inlet fluidically coupled to the fluid supply chamber and a supply outlet fluidically coupled to the flow path. The fluid distribution structure also includes a fluid bypass channel including a bypass inlet fluidically coupled to the fluid supply chamber, a bypass outlet fluidically coupled to the fluid return chamber, and a flow inhibitor between the bypass inlet and the bypass outlet providing a supplemental flow resistance to the fluid bypass channel. The flow inhibitor includes a convergent-divergent throat section. | 11-07-2013 |
20130293642 | Systems And Methods For Delivering And Recirculating Fluids - Among other things, a device for use in printing is described. The device comprises a first chamber for receiving a liquid and a first filter member in the first chamber. The first filter member separates the first chamber into a first part and a second part laterally adjacent to the first part. The first filter member comprises pores having an average size. The pores are configured to filter the liquid passing from the first part to the second part. The first filter member further comprises an opening adjacent to a top of the first chamber for air to pass from the first part to the second part. The opening has a size at least 10 times larger than the average size of the pores. There is a first inlet in fluid communication with the first part and a first outlet in fluid communication with the second part. | 11-07-2013 |
20140043404 | FLUID RECIRCULATION IN DROPLET EJECTION DEVICES - A fluid ejection apparatus includes a fluid distribution layer between a fluid manifold and a substrate. The fluid distribution layer includes fluid supply channels and fluid return channels. Each fluid supply channel receives fluid from the fluid supply chamber and circulates a fraction of the received fluid back to the fluid return chamber through a return-side bypass. The substrate include a plurality of flow paths, each flow path includes a nozzle for ejecting fluid droplets. Each flow path receives fluid from a respective fluid supply channel, and channel un-ejected fluid into a respective fluid return channel. Each fluid return channel can collect the un-ejected fluid from one or more flow paths and a supply-side bypass, and return the collected fluid back to the fluid supply chamber. | 02-13-2014 |
20140055528 | ACTUATABLE DEVICE WITH DIE AND INTEGRATED CIRCUIT ELEMENT - A fluid ejector includes a fluid ejection module and an integrated circuit element. The fluid ejection module includes a substrate having a plurality of fluid paths, a plurality of actuators, and a plurality of conductive traces, each actuator configured to cause a fluid to be ejected from a nozzle of an associated fluid path. The integrated circuit element is mounted on the fluid ejection module and is electrically connected with the conductive traces of the fluid ejection module such that an electrical connection of the module enables a signal sent to the fluid ejection module to be transmitted to the integrated circuit element, processed on the integrated circuit element, and output to the fluid ejection module to drive the actuator. | 02-27-2014 |
20140239089 | MEMS Jetting Structure For Dense Packing - A fluid ejector includes a fluid ejection module having a substrate and a layer separate from the substrate. The substrate includes a plurality of fluid ejection elements arranged in a matrix, each fluid ejection element configured to cause a fluid to be ejected from a nozzle. The layer separate from the substrate includes a plurality of electrical connections, each electrical connection adjacent to a corresponding fluid ejection element. | 08-28-2014 |
20140259595 | FLUID EJECTION MODULE MOUNTING - A fluid ejection module mounting apparatus, including a module mount having a horizontal portion and a vertical portion, a fluid ejection module mounted to the module mount, and a clamp assembly including a recessed portion, a clamp along a wall of the recessed portion, and a lever coupled to the clamp and configured to move the clamp from an open position to a closed position. The horizontal portion has an opening configured to receive a fluid ejection module and the vertical portion has a protruding portion. The protruding portion of the module mount is configured to mate with the recessed portion of the clamp assembly. | 09-18-2014 |