A printing system may comprise printheads for printing on a printing medium by firing a printing fluid through nozzles. The printing quality may vary over time or from printing system to printing system, potentially resulting in lower printing quality.
Various example features will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, wherein:
A printhead assembly can include a printhead or fluid ejection device which ejects drops of ink or fluid through a plurality of orifices or nozzles. In one example, the printing system is a thermal inkjet printing system whereby the ejection of a drop is using the heat produced by a resistor. In another example, the printing system is a piezo inkjet printing system whereby the ejection of a drop is using the mechanical energy produced by a piezo electrical element. In one example, the drops are directed toward a medium, such as a print medium, so as to print onto the print medium. A print medium includes any type of suitable sheet material, such as paper, card stock, transparencies, Mylar, fabric, and the like. In one example, nozzles are arranged in a column such that properly sequenced ejection of ink from nozzles causes characters, symbols, and/or other graphics or images to be printed upon print medium as printhead assembly and print medium are moved relative to each other.
An example ink supply assembly supplies ink to a printhead assembly and includes a reservoir for storing ink. As such, in one example, ink flows from a reservoir to a printhead assembly. In one example, a printhead assembly and an ink supply assembly are housed together in an inkjet or fluid-jet print cartridge. In another example, an ink supply assembly is separate from a printhead assembly and supplies ink to a printhead assembly through an interface connection or physical interface connection such as a supply tube.
An example carriage assembly positions a printhead assembly relative to a print media transport assembly and a print media transport assembly positions a print medium relative to a printhead assembly. Thus, a print zone is defined adjacent to nozzles in an area between a printhead assembly and a print medium. In one example, a printhead assembly is a scanning type printhead assembly such that a carriage assembly moves a printhead assembly relative to a print media transport assembly. In another example, a printhead assembly is a non-scanning type printhead assembly such that a carriage assembly fixes a printhead assembly at a prescribed position relative to a print media transport assembly.
An example service station assembly provides for spitting, wiping, capping, and/or priming of a printhead assembly in order to maintain a functionality of a printhead assembly and, more specifically, of nozzles. For example, a service station assembly may include a rubber blade or wiper which is periodically passed over a printhead assembly to wipe and clean nozzles of excess ink. In addition, a service station assembly may include a cap which covers a printhead assembly to protect nozzles from drying out during periods of non-use. In addition, a service station assembly may include a spittoon or a secondary or additional spittoon into which a printhead assembly ejects ink to insure that a reservoir maintains an appropriate level of pressure and fluidity, and help avoid that nozzles do clog or weep excessively. Functions of a service station assembly may include relative motion between a service station assembly and a printhead assembly. During operation, clogs in the printhead can be periodically cleared by firing a number of drops of ink through each of the nozzles in a process known as “spitting,” with the waste ink being collected in a spittoon reservoir portion of the service station. In another example a service station comprises a web wipe where printheads are cleaned through a web of cloth. Such cloth may or may not be impregnated with a fluid participating in the cleaning process of the nozzles. An example of such fluid is low molecular weight PEG (polyethylene glycol).
An example electronic controller communicates with a printhead assembly, a carriage assembly, a print media transport assembly, and a service station assembly, Thus, in one example, when a printhead assembly is mounted in a carriage assembly, an electronic controller and a printhead assembly communicate via a carriage assembly, An example electronic controller also communicates with an ink supply assembly such that a new (or used) ink supply may be detected, and a level of ink in the ink supply may be detected. In an example, the controller is an electronic controller which includes a processor and a memory or storage component and other electronic circuits for communication including receiving and sending electronic input and output signals.
An example electronic controller receives data from a host system, such as a computer, and may include memory for temporarily storing data. Data may be sent to an inkjet printing system along an electronic, infrared, optical or other information transfer path. Data represent, for example, a document and/or file to be printed. As such, data form a print job for an inkjet printing system and include print job commands and/or command parameters.
Calibration method 100 comprises in block 101 printing a diagnostic pattern representative of decap time. For inkjet printheads and pens, “decap” arises when nozzles sit in a non-jetting state while exposed to the open atmosphere for a span of time, and subsequently receive a request to jet. As the nozzles return to actuation following such an idle period, they may display a number of non-ideal characteristics that include missing drops, mis-directed drops, weak drops, and even drops that are enriched or depleted in color compared to the bulk ink. Drops that misbehave in such manners frustrate attempts to facilitate high-quality image production.
Decap responses can be grouped into example categories. In a first example category, in pigmented ink systems, the evaporation of water from the open bores may cause the ink's pigment and the remaining vehicle in the firing chamber to self-sequester into partitioned zones. This phenomenon is referred to as pigment-ink-vehicle separation (PIVS). In another example category, the evaporation of water from the open bores may serve to increase the viscosity of ink within the jetting architecture and thereby create another decap dynamic from the formation of either in-bore or in-chamber viscous plugs.
Evaluating the decap time of nozzles in a printing system corresponds to evaluating the maximum time during which a nozzle may remain decap without having a detrimental effect on printing quality. Once the decap time of nozzles is known, printing can be optimized by balancing printing speed and printing quality. In an example, if a decap time is relatively low, nozzles should be serviced relatively often, thereby reducing printing speed to maintain quality. In an example, if a decap time is relatively low, nozzles should spit more frequently. In an example, if a decap time is relatively low, printing speed is accelerated to increase the frequency at which nozzles are spitting. In an example, if a decap time is relatively low, nozzles should spit more frequently on the fly, implying that nozzles are spitting ink in addition to the spitting built into print a print job, the additional spitting being added to reduce the time during which a nozzle is exposed to ambient air without spitting. Such additional spitting on the fly can have an impact on print quality and increase ink consumption. In an example, a printing system comprises a spit bar which permits additional spitting outside of a print job area, permitting additional printing without consequences on quality. If decap time is relatively high, nozzles can be serviced less often, thereby increasing printing speed while maintaining printing quality. If the decap time is not appropriately evaluated, either printing speed or printing quality will suffer. If the decap time taken into account in a printing process is higher than the effective decap time, nozzles will be serviced less frequently than they should, thereby affecting printing quality, for example by missing drops. If the decap time taken into account in a printing process is lower than the effective decap time, nozzles will be serviced more frequently than they should, thereby lower the printing speed. It is therefore of interest to evaluate the decap time of nozzles as precisely as possible to run a printing system at optimal quality and speed. Such an evaluation takes place in calibration method 100 by printing the diagnostic pattern.
In block 101 of
In block 102, the calibration method 100 comprises scanning the resulting diagnostic pattern with a sensor to collect decap data in digital form.
In an example, the sensor is a reflection densitometer which can comprise an inexpensive optical sensor that has a single light emitting diode (LED) light source at 30°, lenses and light baffles, and a photodetector IC (integrated circuit) at 0°. In another example the sensor is a three-light-source reflection densitometer or a reflection densitometer with a ring shaped mirror.
In an example, the sensor is a line sensor which measures diffuse reflectance from the surface of print media when illuminated by LED illuminants (for example: red, green, blue). The sensor can function by projecting illumination at an angle onto the paper. Light may strike the paper at the intersection of the optical axis of a central diffuse-reflectance imaging lens. A reflected illumination may be imaged onto a detector such as a light-to-voltage converter or LTV for example. An LTV can capture the diffuse component of an illumination reflectance. A source of illumination, a magnitude of detected signals and a relationship between reflectance components can provide the information to perform sensor functions.
In an example, the system comprises a sensor which is an optical sensor that detects light reflected from a page in a sequence of measurements, and a processor which is coupled to the sensor and manages the calibration operation. In some implementations, the sensor is a scan sensor which can include a combination of an illumination component and a light sensor. In operation, the illumination component illuminates print media (e.g., paper) and detects reflected light from the print media using the light sensor. In an example the sensor is embedded in the printer, for example mechanically coupled to a carriage, producing an inherent alignment between the sensor and a print head. Such alignment can be leveraged to evaluate decap regardless of variances brought on by, for example, the mounting of components of the printing system, as well as the variances which may be present with the print zone (e.g., variance within the media, stack up tolerances, height of plate and ribs, warpage of the print media, tilt of the carriage, platen droop and/or flute size). Using a sensor to scan the diagnostic pattern increases significantly the reliability of a diagnostic leading to a close estimate of the decap time of nozzles compared to using a human eye for example. Use of a sensor compared to a human eye can for example significantly improve the diagnostic when an ink color is difficult to identify in contrast with the color of the background of printing media, for example when an ink is yellow on a white sheet of paper. Use of a sensor compared to a human eye can for example significantly improve the diagnostic when detecting that a line is more fuzzy or diffused than it should be, for example due to spray or an excess of satellite drops between lines. Use of a sensor will permit increasing the precision of the diagnostic, leading to a more precise estimate of decap time, allowing a more precise calibration of a printing system, and servicing of nozzles, leading to a high printing speed and high printing quality combination.
The sensor collects decap data in that it scans the diagnostic pattern. In an example, the sensor first scans the first pattern element and then scans the second pattern element, collecting decap data in a digital form for both the first and the second pattern elements. Such data is in digital form to facilitate a subsequent analysis.
The sensor may include a non-volatile memory device on a sensor PCB with a standard communication interface with the printing system to read or write calibration data. Such memory device may store sensor calibration data during assembly. Such sensor calibration data may be related to calibrating an LED response to a special calibration patch. This process may occur in the manufacturing chain. Such memory device may allow reading sensor calibration data stored in a printer data storage. Such calibration data may be used to improve color measurement consistency and accuracy. Such a process may provide robustness against manufacturing variability of sensor, LEDs and inks.
At block 103, the calibration method analyses the decap data, the digital analysis comprising identifying a quantitative difference between the first and the second pattern elements. In the example illustrated in
At block 104 the method modifies a servicing process of the printing system if the quantitative difference passes a predetermined threshold. For example, if a first line of a second pattern element is detected as missing (for example because the count collected by the sensor from the second pattern element at the level of a first line of the first pattern element is passing or exceeding a threshold corresponding to the count level 151 characteristic of an area between lines), the servicing frequency of nozzles could be increased due to detecting an impact on quality at a decap time lower than expected. Increasing service frequency would result in nozzles being services more frequently and in effectively reducing decap time.
In
In
Such pattern elements are reproduced using different predetermined time periods T2, T3, T4, T5 to Tn. In this example, for each predetermined time period and corresponding pattern element, a reference pattern element is printed with a predetermined time period T0, preceded by an area such as area 110 of
In an example, the first predetermined time period is of less than 1 second, and the second predetermined period is of more than 1 second. In an example, the first predetermined time period is of less than 0.5 second, and the second predetermined period is of more than 1 second. In an example, the first predetermined time period is of less than 0.1 second, and the second predetermined period is of more than 0.3 second. In an example, the first predetermined time period is of less than 0.5 second, and the second predetermined period is of more than 0.5 second. In an example, the first predetermined time period is of less than 0.2 second, and the second predetermined period is of more than 0.4 second.
One can for example observe in
One also can observe in
One can also observe in
In
In
Moving to graph 230, one can observe that the plateau section 232 is longer than plateau section 222, and that 9 and not 10 valleys are appearing. This is due to the fact that the corresponding pattern element 231 scanned is missing the first line, due to nozzles firing magenta ink being affected by a long T5 predetermined time period being decapped, such that the first line could not be printed, possibly due to dry ink pigment preventing ink ejection. One can also observe that the valley 233 is at a level lower than the following 8 valleys, possibly due to the corresponding line being fuzzy, also due to the excessive time during which the nozzles were left decapped. In an example, the sensor count corresponding to the deepest point of valley 233 is of 100 counts.
As per these example, the diagnostic pattern includes a plurality of lines, whereby the digital analysis comprises detecting if a line is missing and detecting if a line is fuzzy. In such an example, each line is a component of the diagnostic pattern. In other examples, components of other shapes may be considered, such as substantially circular or round components, substantially rectangular or square components, or other shapes including polygonal shapes. In further examples, the diagnostic pattern can include in a single pattern components of various shapes.
In such examples, the decap data represents a succession of peaks and valleys, the digital analysis comprising a measurement of a characteristic breadth and depth of the peaks and valleys. For example, the depth of valley 233 compared to the plateau 232 is of about 900 counts. For example, the depth of valley 223 compared to the plateau 222 is of about 800 counts. Characteristic breadth of valley 223 may be corresponding to the length of a segment 225 intersecting peak 224 and the slope between plateau 222. Another characteristic breath measurement for a valley may be the breadth of the valley at mid depth or at another predetermined depth, meaning for example at 50% or at another predetermined percentage of the height between the bottom of the valley and a neighboring peak, illustrated by measuring the length of segment 226.
Moving to graph 250, an example of collected decap data for a first and a second pattern element is represented. An example of a quantitative difference is the distance 243 separating curves 242 and 252 at the point corresponding to the first line of the first pattern element illustrated by curve 242. In this example, the difference is of about 800 sensor counts. If a predetermined threshold of for example 100 sensor count is defined to detect the absence of a line, a quantitative difference of 800 would exceed the threshold. Passing a threshold can occur by exceeding or by falling below the threshold value. In this case, the threshold is considered passed when it is exceeded. In this same graph, quantitative difference can be taken into account as a difference 244 in valley depth, such a difference in valley depth corresponding to detecting a fuzzy line. In this example, the peak to valley distance of the valleys of 252 following valley 244 is lower than the peak to valley distance of 242, 242 being in an example a reference pattern element. In an example, a peak to valley distance of 25 sensor counts is a predetermined threshold, in that the threshold is considered passed and the servicing is for example rendered more frequent if the quantitative difference is of less than 25 sensor counts. Such lower peak to valley distance may be associated with increased line fuzziness. Such quantitative differences are identified and analyzed according to block 103 to method 100.
According to block 104 of method 100 of
In some examples, more than one quantitative difference is identified, and a servicing process is modified if one or a plurality of predetermined threshold is passed by a respective quantitative difference.
If at block 301 the threshold was passed, in an example spitting procedures are evaluated. In an example, the threshold is passed is the quantitative difference is above a threshold. In another example, the threshold is passed if the quantitative difference is below a threshold. Spitting settings can be changed to a higher frequency, for example in relation to the amount for which the threshold was passed. For example, nozzle spitting frequency could be raised by 5% if the threshold is passed by 5%, and nozzle spitting frequency could be raised by 10% if the threshold is passed by 10%. Spitting settings can be changed to for example increase the number of drops spitted in relation to the amount for which the threshold was passed. For example, if the threshold is passed by a given percent amount, the number of drops spitted could be raised by the same or by a proportional or formulaically linked percent amount.
In the example of
If following block 305 a threshold is passed, it is possible that the actions taken at blocks 302 and 303 have not been sufficient to resolve an issue of decaping and that further actions should be taken in block 306. Such further actions could for example include alerting a user, processing the decap data further through additional analysis, comparing the decap data with past decap data to detect trends or system drifts, suggest further actions, suggesting the modification of an image placement, or continue printing until a further calibration takes place.
The controller 400 comprises a storage 402. Data storage may include any electronic, magnetic, optical, or other physical storage device that stores executable instructions. Data storage 402 may be, for example, Random Access Memory (RAM), an Electrically-Erasable Programmable Read-Only Memory (EEPROM), a storage drive, an optical disk, and the like. Data storage 402 is coupled to the processor 401.
The controller 400 comprises an instruction set 403. Instruction set 403 cooperates with the processor 401 and the data storage 402. In the example, instruction set 403 comprises executable instructions for the processor 401, the executable instructions being encoded in data storage 402.
The instruction set 403 cooperates with the processor 401 and the storage 402 to fire nozzles after an exposure to ambient air during a first predetermined time period to produce a first pattern element and fire nozzles after an exposure to ambient air during a second predetermined time period to produce a second pattern element. The instruction set 403 also cooperates with the processor 401 and the storage 402 to operate a printer embedded sensor to scan the pattern elements; collect data from the sensor in a digital form; analyze the collected data to identify a quantitative difference between the first and the second pattern elements; and service the nozzles if the quantitative difference passes a predetermined threshold.
In an example represented in
Collecting and storing data over time allows accumulating past of historical decap data from calibration and to possibly determine or detect trends or long term evolution of decap characteristics. This can apply do a single printer, whereby one could for example detect that a decap evolves and changes in function of ambient conditions, for example ambient temperature, ambient humidity, or exposure to light or direct sunlight. Decap characteristics may also change in function of the printing medium used or of the ink used. Storing and monitoring decap data over time can allow to fine tune the servicing process of a printer to optimize it in view of such changing conditions. Such trends may evolve in a continuous or in a discontinuous fashion over time. Transmitting such data over a network to a multi printer management system can permit controlling or optimizing the use of a multi printer environment such as a print farm. Such trends can lead to predicting potential issues with printers which have not encountered such issues yet, and permit avoiding such issues for example through an update of instructions stored in a storage medium.
In an example, the instruction set 403 further cooperates with the processor and the storage to propose modifying an image placement if the quantitative difference exceeds another threshold. Modifying and image placement may for example have an impact on nozzle health if the image to print is elongated, having a length and a width, the length being longer than the width. In an example, it is proposed to align the length of such an image with a scanning direction of a printhead. In this manner nozzles could print substantially continuously along the length of the image, printing the image in a number of swaths lower than if the width of such an image is aligned with a scanning direction of a printhead.
In
As examples, the printers comprised in the multiple printers may be located on a local network, or on a remote network, or on different networks or on a combination of these. Such printers comprised in the multiple printers may be provide decap data to be collected over different periods of time and different geographies.
In an example, the decap value representative of a decap characteristic is a specific time at which decap introduces quality issues for the respective printer. In an example, the decap value representative of decap is an average over time of specific times at which decap introduces quality issues for the respective printer. In an example, the decap value representative of decap is relates to a specific color or ink for the respective printer. In an example, the decap value representative of decap comprises multiple values, for example including average or ink specific values. The decap characteristic may be related to for example a number of missing lines or missing pattern components in a diagnostic pattern. The decap characteristic may be related to for example a number of fuzzy lines or fuzzy pattern components in a diagnostic pattern.
A statistical analysis of trends comprises in an example detecting an increasing trend of decap value representative of a decap characteristic. A trend may develop itself for example over time, or for example over a specific printer population, or for example over ink types. A decreasing decap value may also be detected, for example suggesting a positive nozzle health impact which could be for example linked to a change in ambient conditions of to a change of ink. Such statistical analysis of trends may use statistical tools such as comparing a trend to a theoretical trend, detecting an underlying pattern or behavior which would otherwise be partly or nearly hidden by noise. Such data treatment may lead to an update of instructions encoded in a storage medium or to a change of ink for example.
In an example, the instruction set 503 is to cooperate with the processor 501 and the storage 502 to recommend modified servicing processes if the trend indicates that an average decap value passes a pre-determined servicing trend threshold.
In an example, the instruction set 503 is to cooperate with the processor and the storage to recommend a change of ink if the trend indicates that an average decap value passes a pre-determined ink change trend threshold.
In an example, the instruction set 503 is to cooperate with the processor and the storage to group the printers in different classes in function of printer attributes, whereby the trend is detected on a per class basis. Example of printer attributes include the type of printer, ambient conditions, the type of printhead, the type of ink, the type of media, the manufacturing lot of a media or other consumable such as ink, other printer attributes or a combination of these.
The preceding description has been presented to illustrate and describe certain examples. Different sets of examples have been described; these may be applied individually or in combination, sometimes with a synergetic effect. This description is not intended to be exhaustive or to limit these principles to any precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is to be understood that any feature described in relation to any one example may be used alone, or in combination with other features described, and may also be used in combination with any features of any other of the examples, or any combination of any other of the examples.
Filing Document | Filing Date | Country | Kind |
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PCT/US2018/012845 | 1/8/2018 | WO | 00 |