Patent application number | Description | Published |
20080316246 | METHOD FOR CALIBRATING AN INK SENSE RESPONSE IN AN APPARATUS CONFIGURED TO FACILITATE OPTICAL INK SENSING - A method for calibrating as ink sense response of an optical ink sensor device in an imaging apparatus configured to facilitate optical ink sensing for an ink tank having an ink sensing window includes obtaining a calibration response to a reference reflective surface having a known reflectivity, which is associated with a printhead carrier of the imaging apparatus that carries the ink tank, using the optical ink sensor device; and calibrating the ink sense response based on the calibration response. | 12-25-2008 |
20090167819 | Automatic printhead and tank install positioning - A system and method for automatically determining the appropriate printhead/ink tank installation position to move a carrier transporting the printhead/ink tanks for a printing device is presented. The carrier transporting the printhead/ink tank moves along a carrier frame and is covered by a protective cover. Once the protective cover is raised on the printing device, the status of the ink tank is sensed. Based on the ink tank status, the printing device carrier is moved to the appropriate printhead/ink tank installation position. In one embodiment, the status of the ink tank is determined by using the ink presence sensor. In another embodiment, the status of the ink tank is determined by using near field wireless communication with the memory of the ink tank. | 07-02-2009 |
20120169812 | CONSUMABLE SUPPLY ITEM, FLUID RESERVOIR AND RECIRCULATION SYSTEM FOR MICRO-FLUID APPLICATIONS - A consumable supply item for an imaging device holds an initial or refillable volume of ink. An interior retains the ink while exit and return ports define openings through a housing to fluidly communicate the interior to the imaging device. The opening of the return port is larger than the opening of the exit port. The design slows the return of fluid to the housing which minimizes air bubbles or frothiness in the fluid. During use, ink depletes toward a bottom surface of the interior beneath which the ink is prevented from occupying. A housing section below the interior retains a portion of the exit port so that a bottom of the opening of the exit port is substantially horizontally aligned with the bottom surface. It prevents stranding ink beneath the exit port. Further embodiments include port configuration, construction, and modular components, to name a few. | 07-05-2012 |
20120169813 | CONSUMABLE SUPPLY ITEM, FLUID RESERVOIR AND RECIRCULATION SYSTEM FOR MICRO-FLUID APPLICATIONS - A housing defines a fluid reservoir for an imaging device. One or more exterior walls define a volume for holding ink to set a fluid backpressure in the imaging device. An opening in the walls is positioned for overflowing excessive ink from the volume to maintain the fluid backpressure within a predetermined operating range. Fluid inlets and outlets connect the reservoir to both a supply item and an ejection head. Ink flows into the reservoir from the supply item. It fills until the fluid rises to a height where it overflows back to the supply item. Less full reservoirs fill as the pump operates, while full reservoirs simultaneously return fluid back to their supply containers. Fluid does not spill from the walls. | 07-05-2012 |
20120218356 | CONSUMABLE SUPPLY ITEM WITH CAPACITIVE FLUID LEVEL DETECTION FOR MICRO-FLUID APPLICATIONS - A consumable supply item for an imaging device holds an initial or refillable volume of fluid. Its housing defines an interior having a pair of opposed electrodes. The electrodes define a capacitance that varies in response to an amount of liquid between them. A volume space filled by the liquid varies along a length of the electrodes. The design facilitates abrupt changes in capacitance values at each change in the volume space. Devices can recalibrate fluid levels at these changes. Electrode interior surfaces face one another. At least one electrode has an open region, such as a hole or a cutout of material. In another design, a support material connects to each electrode to provide mechanical stability and create a region preventing filling by the liquid. Further embodiments contemplate material selection, construction, and modularity, to name a few. | 08-30-2012 |
20120306973 | CONSUMABLE SUPPLY ITEM WITH FLUID SENSING FOR MICRO-FLUID APPLICATIONS - A consumable supply item for an imaging device holds an initial or refillable volume of ink. A housing defines an interior having a pair of opposed electrodes. The electrodes have a capacitance that varies in response to an amount of liquid between them. A controller energizes one electrode and receives an output reading from the other. The controller processes the reading on board the housing and supplies it as a digital data stream to the imaging device during use. A memory stores calibration values for an empty and full housing. The controller writes back to the memory present fluid levels obtained from the output reading of the electrode. An enable output allows operation or not of a fluid pump in the imaging device. Materials, construction, modularity, and fluid communication ports are further embodiments, to name a few. | 12-06-2012 |
20120306974 | CONSUMABLE SUPPLY ITEM WITH FLUID SENSING AND PUMP ENABLE FOR MICRO-FLUID APPLICATIONS - A consumable supply item for an imaging device holds an initial or refillable volume of ink. A housing defines an interior having a pair of opposed electrodes. The electrodes have a capacitance that varies in response to an amount of liquid between them. A controller energizes one electrode and receives an output reading from the other. The controller processes the reading on board the housing and supplies it as a digital data stream to the imaging device during use. A memory stores calibration values for an empty and full housing. The controller writes back to the memory present fluid levels obtained from the output reading of the electrode. An enable output allows operation or not of a fluid pump in the imaging device. Materials, construction, modularity, and fluid communication ports are further embodiments, to name a few. | 12-06-2012 |
Patent application number | Description | Published |
20130074594 | FLUID TILT SENSOR WITHIN INK TANK SUPPLY ITEM FOR MICRO-FLUID APPLICATIONS - A container for holding a volume of fluid and having a housing defining an interior for retaining the volume of fluid; at least one in-tank tilt sensor connected to a controller and disposed inside the housing for generating a signal corresponding to a level of fluid inside the housing; and a support material attached to the housing and connected to the at least one in-tank tilt sensor to mechanically support the at least one in-tank tilt sensor such that the at least one in-tank tilt sensor is not in direct contact with the fluid inside the housing. The in-tank tilt sensor detects a change in fluid level which may only be caused by tilting of the imaging device. When tilting is registered, protective action is taken to prevent fluid from leaking. | 03-28-2013 |
20130074595 | FLUID TILT SENSOR WITHIN INK TANK SUPPLY ITEM FOR MICRO-FLUID APPLICATIONS - A container for holding a volume of fluid and having a housing defining an interior for retaining the volume of fluid; at least one in-tank tilt sensor connected to a controller and disposed inside the housing for generating a signal corresponding to a level of fluid inside the housing; and a support material attached to the housing and connected to the at least one in-tank tilt sensor to mechanically support the at least one in-tank tilt sensor such that the at least one in-tank tilt sensor is not in direct contact with the fluid inside the housing. The in-tank tilt sensor detects a change in fluid level which may only be caused by tilting of the imaging device. When tilting is registered, protective action is taken to prevent fluid from leaking. | 03-28-2013 |
20130286064 | Fluid Tilt Sensor Within Ink Tank Supply Item for Micro-Fluid Applications - A container for holding a volume of fluid and having a housing defining an interior for retaining the volume of fluid; at least one in-tank tilt sensor connected to a controller and disposed inside the housing for generating a signal corresponding to a level of fluid inside the housing; and a support material attached to the housing and connected to the at least one in-tank tilt sensor to mechanically support the at least one in-tank tilt sensor such that the at least one in-tank tilt sensor is not in direct contact with the fluid inside the housing. The in-tank tilt sensor detects a change in fluid level which may only be caused by tilting of the imaging device. When tilting is registered, protective action is taken to prevent fluid from leaking. | 10-31-2013 |
20130300786 | Fluid Tilt Sensor Within Ink Tank Supply Item for Micro-Fluid Applications - A container for holding a volume of fluid and having a housing defining an interior for retaining the volume of fluid; at least one in-tank tilt sensor connected to a controller and disposed inside the housing for generating a signal corresponding to a level of fluid inside the housing; and a support material attached to the housing and connected to the at least one in-tank tilt sensor to mechanically support the at least one in-tank tilt sensor such that the at least one in-lank tilt sensor is not in direct contact with the fluid inside the housing. The in-tank tilt sensor detects a change in fluid level which may only be caused by tilting of the imaging device. When tilting is registered, protective action is taken to prevent fluid from leaking. | 11-14-2013 |
Patent application number | Description | Published |
20090153601 | SYSTEMS AND METHODS FOR COMMUNICATION OF DATE INFORMATION BETWEEN AN INK TANK AND PRINTING DEVICE - Some or all of the needs above can be addressed by embodiments of the invention. According to one embodiment of the invention, a method for determining ink evaporation from at least one ink tank can be provided. The method can include determining a removal time associated with removal of at least one ink tank from a printing device. The method can also include determining an insertion time associated with insertion of the at least one ink tank into a printing device. In addition, the method can include estimating an amount of ink evaporation from the at least one ink tank during the time between the removal time and insertion time based at least in part on the difference between the removal time and insertion time. | 06-18-2009 |
20090160893 | METHODS AND APPARATUS FOR OPTIMIZING ENERGY SUPPLIED TO A PRINT HEAD HEATER - Methods and apparatuses for optimizing the energy supplied to a print head heater are disclosed. A resistance associated with the print head heater or actuator is determined. A range of fire pulse values is determined based at least in part on the determined resistance and a velocity optimization procedure is executed based at least in part on the determined range of fire pulse values. An optimal fire pulse for the print head heater is selected based at least in part on the results of the velocity optimization procedure. | 06-25-2009 |
20100123747 | METHOD FOR DETECTING PURGING INK FLOW THROUGH PRINTHEAD HEATER CHIP NOZZLES BY THERMAL ANALYSIS - A method for detecting ink flow through a printhead, due to a successful purging of the nozzles of a heater chip of the printhead, includes moving the printhead to a location in preparation for a purging operation such that a purge pump is connected in flow communication with heater chip nozzles, setting the manner in which the purge pump operates to suction ink through nozzles of the heater chip from a source of ink, performing a thermal analysis on the heater chip concurrently as the purge pump operates to determine whether ink is flowing through the heater chip nozzles and whether the purge pump should continue to operate, and adjusting the manner in which the purge pump continues to operate in response to the thermal analysis. | 05-20-2010 |
20100295882 | METHOD FOR MEASURING INK FLOW RATE IN AN INKJET PRINTHEAD - A method of determining the state of a printhead/cartridge in a thermal inkjet printer. An inkjet printhead undergoes a jetting operation in which a jetting frequency is selected and a corresponding steady state printhead temperature is known. The printhead is heated to the steady state temperature. Then the printhead is jetted with all nozzles for a predetermined period of time. Temperature samples from the printhead are obtained and the change in the printhead temperature for a short period of time is used to determine a slope in the temperature change. From the slope of printhead temperature changes, the ink flow rate through the printhead can be determined. The flow rate of ink through the printhead can be used to determine the various states of the printhead, including out of ink, clogged, deprimed, a taped printhead, etc. | 11-25-2010 |
20120026222 | SYSTEMS AND METHODS FOR COMMUNICATION OF DATE INFORMATION BETWEEN AN INK TANK AND A PRINTING DEVICE - Some or all of the needs above can be addressed by embodiments of the invention. According to one embodiment of the invention, a method for determining ink evaporation from at least one ink tank can be provided. The method can include determining a removal time associated with removal of at least one ink tank from a printing device. The method can also include determining an insertion time associated with insertion of the at least one ink tank into a printing device. In addition, the method can include estimating an amount of ink evaporation from the at least one ink tank during the time between the removal time and insertion time based at least in part on the difference between the removal time and insertion time. | 02-02-2012 |
20140015877 | SYSTEMS AND METHODS FOR COMMUNICATION OF DATE INFORMATION BETWEEN AN INK TANK AND A PRINTING DEVICE - Some or all of the needs above can be addressed by embodiments of the invention. According to one embodiment of the invention, a method for determining ink evaporation from at least one ink tank can be provided. The method can include determining a removal time associated with removal of at least one ink tank from a printing device. The method can also include determining an insertion time associated with insertion of the at least one ink tank into a printing device. In addition, the method can include estimating an amount of ink evaporation from the at least one ink tank during the time between the removal time and insertion time based at least in part on the difference between the removal time and insertion time. | 01-16-2014 |