In printing systems, a medium or substrate may be moved over a platen in a printing zone area in which printing on the medium takes place. Printing systems may use suction force, such as vacuum pressure, to control motion and flatness of the medium over the printing zone area. A source for providing the suction force may comprise fans working at a certain rotation speed (duty, rpm) in order to provide enough suction force to hold down the medium onto the platen in the printing zone area.
Examples will now be described, by way of non-limiting examples, with reference to the accompanying drawings, in which:
Referring now to
As shown in
The printing system comprises a suction force generator 18 for generating a suction force to hold down media 16 onto platen 10 while it is moved through the printing zone by drive rollers 12. Suction force generator 18 may comprise a suction force source 20, such as a fan, suction force openings 22 in a top plane of platen 10 and suction force channels 24 fluidically connecting suction force source 20 to suction force openings 22.
The printing system comprises a sensor 26 to monitor movement of medium 16 through the printing zone in a media advance direction. Sensor 26 may comprise a camera to capture several pictures of medium 16 successively while medium 16 is moved through the printing zone by drive rollers 12. Camera 16 may be arranged to capture pictures of the underside of the medium. The camera may be stationary in that it is focused on a fixed region of the printing zone over which the medium is moved. For each of the pictures, an image correlation versus the previous one may be performed and the result may be output by the image sensor. Sensor 26 extracts features from the pictures and performs the correlation based on the extracted features. The features may be features of the medium itself, such as fibers thereof, or may be features provided on the medium, such as printed marks.
For example, the sensor may be an optical media advance sensor, which is used to control movement of medium 16 through the printing zone area. An example of such an optical media advance sensor is known as optical media advance sensor (“OMAS”) sensor from Hewlett-Packard Company, USA.
Several pictures are taken during the media movement, wherein the term “media movement” may refer to a movement of the medium over a distance corresponding to the width of a print swath. The medium is advanced by a nominal distance from picture to picture. For each of the pictures an image correlation versus the previous one may be performed. By doing so, the actual distance of the medium moved from picture to picture can be determined. The actual distance may be compared to the nominal distance. If a value indicating a deviation of the actual distance from the nominal distance exceeds a threshold, this may be determined as representing a miscorrelation between pictures. For example, the threshold may be set to 10% of the nominal distance.
The values obtained while the medium is moved over the nominal distance corresponding to a swath may be considered to determine whether a misnavigation takes place. For example, a misnavigation may be determined in case a specific percentage of the values, such as 25% of the values, indicate a miscorrelation. Thus, a misnavigation is considered if there is too poor or no correlation.
The output of the sensor may be used to control movement of the medium. The medium is advanced by a nominal distance from picture to picture plus a delta value coming from the correlation between pictures. By adding together the total advance from the pictures taken (while the medium is moved a nominal distance corresponding to a swath), a total advance error may be computed and fed to the drive (which may include a media movement servo) to increase or decrease the movement length for the next movement. Once the media movement has ended, an additional picture may be taken to obtain a real stop position. This information may be used to calculate a media advance factor (OLF) for the next movement.
Thus, in examples, the sensor is to determine a media advance factor based on the monitored movement, wherein the media advance factor indicates the distance by which the medium is moved between printing swaths on the medium.
The printing system comprises a controller 28 in communication with sensor 26 and suction force source 20 as shown by broken lines in
In an example, the printing system may be an inkjet printing system in which at least one inkjet printhead (not shown in
Different media types and backing substrate layers may have different friction factors in the printing zone area and, thus, may have different associated suction force (vacuum) values. The suction force applied influences media hold down on the platen but also media advance traveling while printing. In some cases a suction force which is appropriate for media advance may not be enough for holding down the medium and vice versa. Thus, generally some type of calibration is done during the development phase in advance to preset suction force values associated with a specific printing system and specific types of media. A preset suction force value may be provided for each media type including media that share similar behavior for the specific printing system. Since in some instances the range where suction force values work well for most of the media may be narrow the suction force value preset or proposed for a particular media type may not be good enough for a specific substrate used at the consumer's end. Thus, using pre-loaded vacuum values depending on the media type or substrate family may result in poor performance.
Typically, a suction force nominal for a specific medium type is applied upon loading a medium to be printed on into the printing system. During a media loading process, if the printer does not know in advance which media type is loaded, a nominal suction force (vacuum) is applied to perform the medium calibration movements using a carriage having optical sensors to check the width and the position of the medium. This may lead to crashes because, if the friction of the medium is too high, the medium gets stuck in the printing zone while advancing, forms a bulge and grows in height over the printing zone and may provoke a crash with the carriage.
Examples described herein provide for an approach of calibrating the suction force appropriate for each medium or each medium type according to information provided by monitoring the movement of the medium through the printing zone in a medium advance direction by means of a media advance sensor. Calibration takes place before printing on the medium starts. In examples, suction force calibration takes place before any substrate calibration movements using a carriage having optical sensors, such as a carriage arranged above the printing zone and the medium, takes place. Thus, the number of crashes with such a carriage due to an inappropriate suction level applied may be reduced.
Examples provide for a printing system comprising a printing zone comprising a platen, a drive to move a medium through the printing zone, a suction force generator to generate suction force to hold down the medium onto the platen while the drive moves the medium through the printing zone, a media advance sensor to monitor movement of the medium through the printing zone in a medium advance direction, and a controller to perform suction force calibration prior to printing. As shown in
In examples, the media type of a medium loaded into the printing system is not known in advance. In examples, a default initial suction force level, such as a minimum suction force level, may be used as an initial suction force level for the calibration. In examples, the suction force calibration is performed upon a media sensor detecting a new medium loaded. In examples, the media sensor may detect the type of the new medium loaded and an initial suction force level used in the calibration may be selected based on the detected media type. In examples, a user interface may be provided giving a user the possibility to input a media type and the initial suction force level may be selected based on the input media type. Different initial suction force levels may be stored associated with different media types.
In examples, the media sensor may be to detect a new medium loaded into a media tray of the printing system. In examples, the media sensor may be to detect a new medium loaded from a media tray of the printer to a print starting position. Thus, the initial position may be a position of the medium within the media tray or may be the print starting position of the medium.
In examples, suction force calibration may take place during the operation of the printing system in addition to any calibration conducted during development of the printing system. Nominal values determined for different media types during the development of the printing system may be used as initial suction force levels in the suction force calibration described herein. Upon determining a suction force level to be used during printing on the medium this suction force level may be used for a single piece of medium loaded into the printing system or for a number of pieces of medium, such as a charge of media loaded into a media tray or such as for all pieces of medium until a new media type is detected by the media sensor. Determined suction force levels may be stored associated with the medium type in a storage of the printing system and may be accessed by the controller when printing on a corresponding medium type. In examples, the controller is to print on the medium using the determined suction force level. In examples, the controller is to print on the medium and other media of the same medium type using the determined suction force level.
In examples, suction force calibration is based on monitoring the movement of the medium through the printing zone. It has been recognized that situations of inappropriate suction force can be identified by monitoring the movement of the medium through the printing zone. Controller 28 may receive an output of sensor 26 and may determine that the suction force generated by the suction force generator is inappropriate to hold down the medium properly on the platen based on an output of sensor 26. For example, controller 28 may determine that the suction force generated by the suction force generator is inappropriate if the output of sensor 26 indicates a misnavigation.
In examples, the medium is moved back and forth through the printing zone several times during the suction force calibration. Movement in both directions or in one direction (generally the forward direction) may be monitored by the media advance sensor. The suction force may be changed between different passes through the printing zone or may be changed within one pass.
During printing, particles, such as aerosol particles coming from the ink firing process or fibers coming from medium like cloths or woven materials, may deposit in areas different from the medium and may in the end be aspired by the suction force openings 22 in the upper face of platen 10. These particles may deposit at suction force openings 22 and/or within suction force channels 24. With time these particles tend to reduce the suction force and capacity of the suction force generator. Thus, a nominal suction force generated by the suction force generator for a specific media type may not be enough to hold down properly the medium onto platen 10. Holding down the medium properly means that the medium rests on the platen while the drive moves the medium through the printing zone. Not holding down the medium properly may result in crashes and ink smears since the printhead may touch the medium. In examples, suction force calibration may reduce or avoid such situations since it is performed while the printing system is in the condition of reduced suction force explained above. Since the extent of particle deposition may depend on the amount of ink or toner consumed by the printing system and an amount of media printed upon by the printing system (for example since a last maintenance of the printing system), an initial value used in the calibration may be selected or set based on at least one of an amount of ink or toner consumed by the printing system and an amount of media printed upon by the printing system. Thus, the time the calibration takes may be reduced.
In examples, in determining a suction force level to be used during printing on the medium, the controller is to determine whether the output of the media advance sensor indicates that the medium is moved properly. The controller may be to determine that the medium is not moved properly if the output of the sensor indicates at least one of specific conditions. A specific condition may be that a distance by which the medium is moved is not determined or deviates from a nominal distance by more than a distance deviation threshold. Another condition may be that the sensor does not determine the media advance factor. Another condition may be that a change of the media advance factor exceeds a media advance factor change threshold. Another condition may be that a rate of change of the media advance factor exceeds a media advance factor change threshold. Another condition may be that a difference of the media advance factor from a nominal media advance factor exceeds a media advance factor difference threshold. Another condition may be that pictures captured by the camera are out of focus.
Thus, in examples, the controller determines that the medium is not moved properly if the media advance factor is not obtained or changes too much too frequently or if the pictures taken are too much out of focus compared to a reference. In examples, determination that the medium is not moved properly is determined or estimated if the sensor cannot navigate properly. Navigating by the sensor means that the sensor provides control signal for the drive in order to compensate for deviations of the actual movement from the nominal movement.
In examples, the output of the media advance sensor may indicate the speed of the medium and the output of the media advance sensor indicates that the medium is not moved properly if the speed is not within specific speed thresholds, i.e. deviates from a target speed by more than a specific amount. In examples, the media advance sensor may be to generate an output including control values for the drive based on the monitored movement and the output of the media advance sensor indicates that the medium is not moved properly if the control values are not within specific control value thresholds, i.e., deviate from a target control value by more than a specific amount.
In examples, the media advance sensor may be an optical media advance sensor (OMAS) which is a sensor that basically takes photos to detect the back of the medium as it moves across the platen. The sensor may be able to evaluate the exact movement of the medium and to communicate any small adjustments to be done by the system to move the substrate smoothly in an intended manner. In other words, the sensor may be able to detect the media advance factor and to provide feedback to the system, such as controller 28 or a drive servo, that permits controlling the drive to move the medium through the printing zone in an intended manner. Several pictures are taken during media movement and for each of them, an image correlation versus the previous one is performed and the output is reported. The presence of problems with such kind of sensor is usually reported when the correlation between images has failed, i.e., if there is a poor or no coincidence between images. Thresholds are programmed for the sensor to make self compensation values on cases of a small number of pictures for which the correlation failed, and can be deactivated if further errors above a certain threshold are achieved. While this information may not be used for the medium (substrate) advance itself, it may be analyzed to be used in determining that the medium is not moved properly and/or in determining reduction of suction force power.
Generally, the sensor may be located at the back of the medium, such as under the printing zone. Window optics may be provided to detect the back of the medium and to periodically take photos that are compared one to each other (autocorrelation of images) to determine how the substrate advance may be modified to have a smoother advance. When the image comparison becomes difficult because the optics of the sensor gets out of focus because the substrate is not properly hold down because of an inappropriate suction force (such as a vacuum loss) then a proper advance factor cannot be calculated.
In examples, specific tailored methods or processes may be used to analyze and decide an operating range for any medium loaded in the printing system, i.e., to determine a suction force level to be used when printing on the medium.
An example of a calibration method is shown in
The initial suction force level may be the minimum suction force level the suction force generator is able to generate and S36 may include increasing the generated suction force level. The initial suction force level may be the maximum suction force level the suction force generator is able to generate and S36 may include decreasing the generated suction force level. The initial suction force level may be an intermediate suction force level, such as 50% of the suction force generator's maximum suction level, and S36 may include increasing the suction force and, if this does not result in an indication that the medium is moved properly, afterwards decreasing the suction force level when compared to the initial suction force level. The order of increasing and decreasing the suction force level may be different.
In case S36 does not result in an indication that the medium is moved properly, the controller may be to inform a user that calibration of the suction force is not possible, such as via a user interface.
Another example of a calibration method is shown in
According to examples, a suction force (vacuum) interval appropriate for the medium loaded is determined or estimated. The determination may include additional parameters of the printer (printing system), such as usage, last status or media loaded, media rewinder parameters, and a number of media advance sensor navigations missed. For example, the initial suction force level used in the calibration may be set based on at least one of these parameters. For example, the initial suction force level used in the calibration may be increased if the printing system has consumed more than a specific amount of ink or toner, such as more than 20l, 50l or 100l of ink. With the known information, the suction force to apply for the medium may be determined between maximum and minimum for each medium and condition.
According to an example, a media sensor may detect a new medium, such as a new paper, loaded. A suction force calibration process may be started using the OMAS by means of making a few advances and retraces of the medium while taking measurements. Methods (which may be performed by the processor of the printing system) may determine the printer behavior according to the OMAS response to determine suction force values lying within an acceptable operational range. The process may start at predetermined highest and lowest levels and may include a few iterations to determine a final range of suction force levels. An suction force level within the final range may then be selected for the medium.
After the suction force calibration, further medium monitoring may be performed such as during a rest of a media load process and during subsequent printing. For example, OMAS normal duties may be monitored. Thus, quality of the determined printing suction force value can be validated.
In examples, suction force calibration may be performed upon detecting new media loaded into the printing system, such as upon detecting new media loaded into a media tray of the printing system. In examples, suction force calibration may be performed upon receiving a print job at the printing system and before starting printing. In examples, suction force calibration may be performed upon receipt of a user request, such as a user request to perform calibration by means of a user interface. The suction force calibration is performed prior to printing and includes moving the medium back to an initial position.
As described herein, examples may permit determining a suction force level to be used in printing regardless of the media type and regardless of vacuum inefficiencies. Examples may reduce the number of crashes with print carriages due to inappropriate suction force levels, such as too high or too low vacuum levels. Examples may automatically compensate for different atmospheric pressures at different heights above sea level, such as low air pressures for printing systems operated in high regions.
Referring now to
The printing system comprises a platen 50, a sensor 52, drive rollers 54 and 56 to move medium 58 through a printing zone comprising platen 50, pinch rollers 60a and 60b, a print unit 62, an input spindle 64, a rewinder mechanism 66 and a controller 68. The medium is loaded onto the input spindle 64. The input spindle 64 may be driven by rewinder mechanism 66 to provide back tension to the medium 58. The medium 58 is fed around drive roller 54 under the pinch wheel 60a, over platen 50 in the printing zone and finally the medium 58 is driven out by means of drive roller 56 and pinch roller 60b, wherein the direction of movement is shown by an arrow in
Controller 68 may be in communication with drive rollers 54, 56, sensor 52 and print unit 62 as shown by broken lines in
An enlarged view of the printing zone area is shown in
As set forth above, during printing, aerosol deposits may accumulate in the suction force channels 84 and may impair the vacuum suction capability of the vacuum suction generator.
Referring to
The controller may determine that the suction force is insufficient if the output of the media advance sensor fulfils at least one of the conditions set forth above with respect to proper movement of the medium. Examples herein permit determining that suction force is insufficient due to aerosol particles deposited in suction force channels and/or suction force openings of a suction force generator. In examples, vacuum effectiveness can be improved on printing systems where vacuum applied pressure is diminished because of aerosol deposits. In examples, vacuum losses may be detected early. In examples, printer vacuum conditions can be ensured due to timely service maintenance actions. In examples, misbehavior of the printer due to crashes or smears (if the medium comes into contact with a printhead) can be avoided. In examples, additional costs due to early user complaints can be avoided. In examples, waste of ink and/or media due to ruined jobs can be avoided.
The controller may be to determine that the suction force generated by the suction force generator is insufficient based on the output of the media advance sensor. In examples, this determination may include at least one of additional parameters of printer usage, such as for example the printing time, the distance by which the substrate is moved, the type of substrate, etc. In examples, the controller is to consider additional parameters in determining that the suction force is insufficient, wherein the additional parameters comprise an amount of ink or toner consumed by the printing system (for example since a last maintenance) and/or a distance by which the medium is moved through the printing zone upon properly loading the medium into the printer. In examples, the controller may determine that the suction force is insufficient if the output of the sensor fulfills at least one of the above conditions and if the amount of ink or toner consumed is above a consumption threshold. In examples, the controller may determine that the suction force is insufficient if the output of the sensor fulfills the condition and if the medium is moved through the printing zone by not more than a specific distance upon properly loading the medium into the printer. The fact that the medium is properly loaded into the printer may be determined by the optical media advance sensor or additional sensors. Properly loaded means that the medium is at a desired position after loading. In examples, a corrective action is taken in response to the determination. In examples, the controller may be to control the suction force generator to increase the suction force if it is determined that the suction force is insufficient. For example, the duty of at least one fan may be increased so as to increase the vacuum force and to compensate for the degradation in vacuum force. In examples, the controller may be to inform a user that the suction force is insufficient via a user interface, which may be at least one of a visual interface and an acoustical interface. For example, feedback may be provided to a user so as to enable corrective actions before service maintenance actions are performed. Thus, a risk of a failure of the printing system before service maintenance actions may be reduced.
Because different scenarios may happen when taking back substrate pictures (also known as substrate navigation herein), as cited above, additional parameters may be taken into account to enhance detection and response. For instance, it may not be expected to have problems with the suction force generator if not more than 20 liter of ink have been consumed since maintenance of the suction force generator was performed last. Thus, in examples, even if the output of the sensor fulfills the condition, this will not result in a determination in that the suction force generated by the suction source generator is insufficient if not more than a predetermined amount of ink or toner has been consumed since the printing system was put into operation or since maintenance of the suction force generator was performed last. For instance, a medium that has been properly loaded and can be properly detected by the optical media advance sensor during the loading process is not expected to fail by any means in terms of problems of the sensor itself (sensor misdetection) during advance by a specific distance, such as the first 50 cm of the plot. Thus, in examples, if the output of the sensor fulfills the condition during this advance, this is taken as an indication that the suction force is insufficient.
These additional inputs may be used at 124 by a process performed by the processor in determining whether the printer misbehavior is due to usage and aerosol problems and not another problem, such as a problem that the substrate cannot be distinguished or such as a problem of the sensor itself. For example, if the media type indicates that the medium is transparent or textile with open mesh, this may be interpreted by the process as an indication that the navigation failure is not due to insufficient suction power. For example, if a number of failed navigations exceeds a threshold or if the time period since the last failed navigation is below a time threshold, this may be interpreted by the process as an indication that the navigation failure is due to problems with the suction power.
Generally, the first signal of vacuum loss may be the inconsistency of the media factors calculated for a given substrate. It may not be big enough as to give early signals, but monitoring the tendencies of the media factor for a given loaded roll (taking also into account maybe other values like media roll left) may be the first to do. Defocused photos may occur in more extreme cases, but the level of focus may also be monitored and may act as another indicator that can be used in connection with other factors.
In addition, the process may determine if an action can be taken, such as increasing the vacuum power or alerting a user. In examples, the controller will in either case output an alert to a user in addition to increasing the suction power. For example, for substrates using a high suction power it may be determined that the suction power cannot be further increased. In such cases no action concerning the suction power will be taken, but a user alert will be output. At 126, the determined action is taken. For example, the vacuum fan duty may be increased, a user alert may take place, the user may be informed that maintenance should take place, the user may be suggested to increase the vacuum level manually, the user may be suggested to perform small cleaning actions on the most problematic part of the suction force generator, etc.
Column A shows that a non-proper navigation of the medium yields frequent errors in the media factor. This is shown by the values 1000000 in column “getCurrentOLF”. Column B shows a case in which the medium is out of focus because of poor vacuum applied, i.e. because the suction force is too low. This results in a consistent error in the media factor calculations. Column C shows a case in which the substrate is navigating normally so that a proper media advance factor can be calculated. Slightly different values are shown in column C according to fine advance adjustments.
Determination of whether pictures are out of focus may be made in any conceivable manner. For example, the output of the sensor may be a grayscale image. Every pixel has a grayscale value from absolutely black (0) to pure white (255). The more contrast a pixel has with respect to its neighbours the more focused the image is. The differences between neighbours can be determined as shown in
In examples, iterative methods can be used. After a certain condition is fulfilled, a proactive compensation can be performed around a nominal value, the result may be monitored and it may be decided if the nominal value should be adjusted or may be maintained. In examples, if a possible problem is detected based on the output of the sensor, the suction force may be increased by a first amount and the effect can be monitored. If there is no change this may be an indication that the change is not sufficient to compensate. Thus, the suction force may be further increased by a second amount larger than the first amount, the process may be repeated, and so on. Upon increasing the suction force and upon determining that the problem has been solved (i.e., proper navigation is obtained), the suction force may be decreased again to the nominal level to see if, back to the nominal level, proper navigation is still obtained. If so, this situation may be considered as representing a transitory status solved by temporarily increasing the suction power.
Any method or process described herein may be performed by controllers 28 or 68 or another computing device of the printing system.
Examples relate to a non-transitory machine-readable storage medium encoded with instructions executable by a processing resource of a computing device to perform methods described herein.
Examples relate to a non-transitory machine-readable storage medium encoded with instructions executable by a processing resource of a computing device to operate a printing system comprising a printing zone comprising a platen, a drive to move a medium through the printing zone, a suction force generator to generate suction force to hold down the medium onto the platen while the drive moves the medium through the printing zone, and a media advance sensor to monitor movement of the medium through the printing zone in a medium advance direction to perform a method comprising: performing suction force calibration prior to printing. The suction force calibration comprises causing movement of the medium from an initial position at least partly through the printing zone while the suction force generator is controlled to generate at least one suction force level, determining a suction force level to be used during printing on the medium based on the output of the sensor during the movement, and moving the medium back to the initial position. The instructions may be to operate the printing system to achieve any of the functionalities of the printing system and the methods described herein. Examples relate to corresponding instructions executable by a processing resource of a computing device to operate a printing system accordingly.
It will be appreciated that examples described herein can be realized in the form of hardware, machine readable instructions or a combination of hardware and machine readable instructions. Any such machine readable instructions may be stored in the form of volatile or non-volatile storage such as, for example, a storage device like a ROM, whether erasable or rewriteable or not, or in the form of memory such as, for example, RAM, memory chips, device or integrated circuits or an optically or magnetically readable medium such as, for example, a CD, DVD, magnetic disk or magnetic tape. It will be appreciated that the storage devices and storage media are examples of machine-readable storage that are suitable for storing a program or programs that, when executed, implement examples described herein.
All of the features disclosed in the specification (including any accompanying claims, abstract and drawings), and/or all the features of any method or progress disclosed may be combined in any combination, except combinations where at least some of such features are mutually exclusive. In addition, features disclosed in connection with a system may, at the same time, present features of a corresponding method, and vice versa.
Each feature disclosed in the specification (including any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example of a generic series of equivalent or similar features.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/066435 | 7/17/2015 | WO | 00 |