The art of ink-jet technology is relatively well developed. Commercial products such as printers, graphics plotters, copiers, and facsimile machines employ ink-jet technology for producing a hard copy. In ink-jet apparatuses, the print medium on which the printing will be performed is loaded upon a flat structure (i.e., platen), the planarity of which may realize an efficient printing process.
In the following description and figures, some example implementations of systems and/or methods for compensating platen defects based on a printhead-to-platen spacing (PPS) profile in a printing apparatus are described. The printing apparatus includes a platen locating a print medium, at, least one printhead for marking on the print medium, a carriage holding the printhead, and a rod supporting the carriage for scanning motion across the print medium.
As platen structure is not immune from defects (e.g., imperfect planarity or cylindricity of the platen), some apparatuses may include a feature that allows firing of printing fluid drops to be adjusted (e.g., delayed) to compensate these defects. This feature may be facilitated through a module of a chipset (e.g., field-programmable gate array (FPGA) or application-specific integrated circuit (ASIC)) that is in charge of transforming the input plot into firing drops for the printhead, referred to as Dynamic X compensation (DNX).
The defaults (e.g., mechanical defects) of the planarity of the platen may be detected by printing a plot, scanning the plot and comparing the scanned plot with the original plot sent to be printed. The differences between the scanned plot and the original plot (i.e., difference between expected plot and actually printed plot) may be processed in order to program the DNX module. However, this process may compromise on the final image quality of the plots or the printer integrity. For example, the print quality may also be affected due to various other factors such as printhead health, printhead position within the carriage, printhead orientation, printhead energy calibration, type of substrate, and the like. Therefore, all these factors may generate artifacts to the printed plot that may be interpreted as the platen defaults.
Further, as the platen analysis requires printing a plot, the actual process may endanger the printer integrity. If the platen has a default due to either a bad assembly or a bad shape of one of the components, it may result in a printhead collision with the platen/print medium that may damage the printhead. Furthermore, printing, scanning and analyzing the plot may be a relatively long process, which may result in consuming significant resources, such as printing fluid, substrate, operator working time, and the like.
Various examples described below relate to a sensor, at least partially mounted to the carriage, for measuring relative distances between the printhead and an upper surface of the print medium or the platen, herein referred as PPS (printhead-to-platen spacing or printhead-to-print medium spacing). In one example, the sensor may be a short range distance sensor with a precision of 0.1 mm to characterize the platen profile and apply corrections. Furthermore, various examples described below relate to a PPS analysis module for computing a PPS profile by sampling the measured PPS at multiple positions along the scanning axis and programming a dynamic compensation module to adjust/control the firing of printing fluid drops (e.g., ink drops) from the at least one printhead to compensate the platen defects based on the computed PPS profile. The dynamic compensation module is a feature of a chipset (e.g., ASIC or FPGA) in charge of transforming the input plot into firing printing fluid drops for the printhead. In one example, the dynamic compensation module can be dynamically/automatically programmed to delay the firing of printing fluid drops (e.g., to compensate the defects in planarity of the platen) from the at least one printhead based on the computed PPS profile, position and/or speed of the carriage, and velocity of propagation of the printing fluid drops from the printhead towards the print medium.
Also, various examples described below relate to loading a bare print medium (i.e., unprinted print medium) on to a platen in the printing apparatus, measuring a PPS along scanning axis by a sensor at least partially mounted to a carriage by initiating the carriage movement along the complete scanning axis, and adjust firing of printing fluid drops from the at least one printhead to compensate the platen defects based on the measured PPS. In one example, the sensor may measure the PPS substantially along the length of the complete scanning axis without actually printing on the print medium.
Further, the printing apparatus 102 includes a sensor 112 at least partially mounted to the carriage 108. Furthermore, the printing apparatus 102 includes an integrated circuit 114. For example, the integrated circuit 114 can include a chipset such as ASIC, FPGA, and the like. In one example, the integrated circuit 114 includes a dynamic compensation module 116 and a PPS analysis module 118. The dynamic compensation module 116 allows firing of printing fluid drops to be delayed to compensate the defects/imperfections of the platen 104. In the example shown in
The PPS sensor (i.e., included in the carriage 108 as illustrated in
Referring now to
In one example, the sensor measures printhead-to-print medium spacing by projecting the beam to a print medium disposed at the printing-medium position, and receives the beam reflected from the print medium. In another example, the sensor measures printhead-to-platen spacing by projecting the beam to the platen disposed substantially at the printing-medium position when the print medium is absent or not loaded, and receives the beam reflected from the platen. In this case, a distance allowance corresponding to the thickness of the print medium that is absent from the platen can be included for computing a PPS profile.
Referring back to
When the potential defects that prevent printing operation or damage the printhead are determined, then the PPS analysis module 118 may generate an alert message or a warning tone. When there are no potential defects that prevent the printing operation or damage the printhead, the dynamic compensation module 116 delays the firing of printing fluid drops from the printhead 110 to compensate the platen defects based on the computed PPS profile, position and/or speed of the carriage 108, and velocity of propagation of the printing fluid drops from the printhead 110 towards the print medium 106. In one example, the PPS analysis module 118 may program the dynamic compensation module 116 to delay the firing of printing fluid drops from the printhead 110 to compensate for PPS fluctuations due to imperfections of the platen based on the computed PPS profile, position and/or speed of the carriage 108, and velocity of propagation of the printing fluid drops from the printhead 110 towards the print medium 106. This is explained in detail in
Referring now to
The ratio of PPS to the printing fluid drop velocity defines the “flight time” of the printing fluid drop. The distance [X0,X1] depends on the “flight time” and on the carriage speed. If the PPS distance is not constant along the scanning axis, the “flight time” will vary accordingly. The distance [X0,X1] can be different for the printing fluid drops along the scanning axis resulting in IQ problems. In this case, the dynamic compensation module 116 workarounds this issue by compensating the “flight time” by a delay. A delay is applied to the fire pulse of the printing fluid drop to compensate for the flight time variations, for example, the smaller the flight time, the bigger the delay.
Referring back to
At step 506, firing of printing fluid drops from at least one printhead is delayed to compensate the platen defects based on the measured PPS. In one example, the firing of printing fluid drops from the printhead is delayed by computing PPS profile by sampling the measured PPS at multiple positions along the scanning axis and transforming the computed PPS profile into a format associated with an input of the dynamic compensation module and providing the transformed PPS profile to the dynamic compensation module to delay the firing of printing fluid drops from the printhead. For example, a print zone area of the printing apparatus is defined into a set of zones with each zone having a start position, an end position, and a specific slope. Further, programming the dynamic compensation module includes providing the computed PPS profile corresponding to the set of zones to the dynamic compensation module through 3 parameters, i.e., the start position, the end position, and the specific slope. As explained above, speed of the carriage and velocity of propagation of the printing fluid drops from the printhead towards the print medium are also considered along with the transformed PPS profile for programming the dynamic compensation module.
In another example, the computed PPS profile is analyzed to determine any potential defects that may prevent printing operation or may damage the printhead, and the firing of the printing fluid drops from the printhead is delayed to compensate the platen defects based on the computed PPS profile when there are no potential defects that prevent the printing operation or damage the printhead. In this example, the potential defects that prevent the printing operation or damage the printhead are determined by comparing each computed PPS profile along the scanning axis with a pre-defined threshold value.
The method and apparatus described through
The machine-readable storage medium 606 may store instructions 608 and 610. In an example, instructions 608 and 610 may be executed by processor 604 to provide a mechanism for programming a dynamic compensation module for compensating platen defects in a printing apparatus. Instructions 608 may be executed by the processor 604 to receive printhead-to-platen spacing (PPS) from a sensor. The PPS is measured along the scanning axis by the sensor at least partially mounted to a carriage by initiating the carriage movement along a length of the scanning axis. Instructions 610 may be executed by processor 604 to delay firing of printing fluid drops from the printhead to compensate platen defects based on the received PPS.
It may be noted that the above-described examples of the present solution is for the purpose of illustration only. Although the solution has been described in conjunction with a specific embodiment thereof, numerous modifications may be possible without materially departing from the teachings and advantages of the subject matter described herein. Other substitutions, modifications and changes may be made without departing from the spirit of the present solution. All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive.
Although the flow diagram of
The terms “include,” “have,” and variations thereof, as used herein, have the same meaning as the term “comprise” or appropriate variation thereof. Furthermore, the term “based on”, as used herein, means “based at least in part on.” Thus, a feature that is described as based on some stimulus can be based on the stimulus or a combination of stimuli including the stimulus.
The present description has been shown and described with reference to the foregoing examples. It is understood, however, that other forms, details, and examples can be made without departing from the spirit and scope of the present subject matter that is defined in the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2015/013760 | 1/30/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/122592 | 8/4/2016 | WO | A |
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Entry |
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Webpage, DESIGNJET 800PS Service Manual, Jan. 13, 2014. |
Number | Date | Country | |
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20170361606 A1 | Dec 2017 | US |