DE102020129339A1 - Process for automatic error management on a printing press - Google Patents

Abstract

The invention relates to a printing press with a system for automatic error management for printing a running material web with a repetitive print image, with a control unit and with a camera connected to the control unit for inspecting the printed material web to detect printing errors. In order to improve the detection of printing errors on a printed material web, a web marking unit for applying web markings to the running material web and a function switch for enabling the web marking unit are provided, with a web marking being applied to the material web by the web marking unit as soon as the control unit detects a printing error recognized and the lane marking unit has been enabled by the operator.

Description

The invention relates to a method for automatic error management on a printing press, in which a repetitive print image is printed on a running web of material. The invention also relates to a printing press with a system for automatic error management for printing a running material web with a repetitive print image.

In this context, error management refers to the entirety of the actions with which printing errors on the printing machine are handled during the printing process. Error management usually consists of three phases, namely error detection (i.e. determining that an error is present), error diagnosis (i.e. assignment to a specific cause) and the actual error correction.

Furthermore, automatic error management in this context means that the operator of the printing press is automatically supported in all three phases of error management. Ideally, the automatic error management even automatically takes over all actions that are required in relation to a specific error on the printing press.

So-called inspection systems are used to carry out error management on a printing press. If a repetitive print image is printed on a running web of material, such inspection systems are basically set up so that the operator can observe and monitor the print image as a stationary image on a monitor during the ongoing printing process. The print image is usually recorded with a line scan camera. In contrast to an area scan camera, the line scan camera only ever records a single image line, since in this way, in comparison to an area scan camera, the entire print area can be recorded with high resolution and at the same time high web speed. The two-dimensional image is then created due to the movement of the web. Since this movement is subject to constant fluctuations, the feed is also synchronized with the help of an encoder to prevent image distortions.

As an alternative or in addition to the line camera, the inspection system can also be equipped with an area camera (also known as a matrix camera), which records a section of the printed image on the running web of material. By synchronizing the area camera with the repetitive print image, the operator is shown a stationary image on a monitor in the control station, which reproduces the selected section of the print image. The selected section is preferably a prominent area of the printed image in which printing errors have a particularly strong effect. Typically, the area scan camera is zoomable so that defective or problematic areas of the printed image can be examined with high resolution. If the operator detects printing errors in the displayed section (e.g. color errors or register errors), he can readjust the machine parameters (e.g. the print position, the longitudinal register or the side register) in order to correct the printing errors.

As an alternative or in addition to the line scan camera and the area scan camera, the inspection system can also be equipped with an optical spectrometer. An optical spectrometer breaks down the recorded light into its spectral components and evaluates the result in a computer system. Miniature spectrometers, which are installed in a compact housing and can be placed at a suitable location within the printing machine, are particularly suitable for the applications presented here. Such miniature spectrometers regularly consist of an aperture (i.e. an entrance slit), an optical grating and an optical sensor. The grating is located behind the aperture and scatters the spectral components of the incident light at slightly different angles, so that the scattered light can be evaluated by the optical sensor as light intensity over the wavelength of the respective light components. With such an optical spectrometer, the color components of a pixel within the printed image can be monitored during the printing process and deviations from a desired color result can be determined.

In addition, error detection algorithms are also known, which automatically detect certain errors in the printed image and then support the operator in further troubleshooting.

For example, an error detection algorithm can be based on a reference image captured at the beginning of the print job. The reference image can, for example, be recorded at the beginning of the printing process on the basis of the first print images (e.g. the first 50 images) with the line scan camera, the area scan camera and/or the optical spectrometer, with these first images being used to create the reference image (also called the "golden image"). to be integrated. In the integration phase, for example, the fluctuation range of the image information can be entered for each determine individual pixels so that tolerance limits for error detection can be defined. During the printing process, the currently recorded image is then subtracted from the reference image. If the difference obtained is outside the error tolerances, an error signal is generated and the defective image area is displayed on the control panel monitor.

Alternatively or additionally, the desired print result can also be specified by the so-called digital proof, which is provided by the pre-press department. In order to determine whether the print result meets the specifications, the image supplied by the inspection system is compared with the digital proof. The digital image processing techniques already described in connection with the reference image can also be used for this comparison.

The positions of the faults detected on the running web of material are stored in the inspection system in a so-called roll log. After completion of the printing process, it is then possible, for example with the help of a rewinder, to move to the defective area of the printed material web and cut it out. It is also possible that the defective areas on the material web are already marked during printing and then ejected in subsequent further processing.

Out of EP 3 132 936 A1 it is known in this context to provide the end of the web of material with a label after the printing process is complete, which label serves to define a zero mark when the tape is reinserted. When the printed web of material is fed to further processing, a sensor in the further processing machine detects the label as a zero mark. Since the distances between the individual printing errors are stored in the roll log, each printing error can be localized with reference to the zero mark.

With the procedure out EP 3 132 936 A1 can therefore be dispensed with in principle on a rewinder. The problem here, however, is the fact that the length of the material web is subject to fluctuations due to its extensibility, which are sometimes so great that the individual printing errors with reference to the zero mark can no longer be found during further processing. This problem also increases with increasing length of the material web.

The object of the invention is therefore to improve the detection of printing errors on a printed web of material.

The solution according to the invention consists of a printing machine with a system for automatic error management for printing a running material web with a repetitive print image, with a control unit, with a camera connected to the control unit for carrying out an inspection of the printed material web to detect printing errors, with a web marking unit for applying web markings to the running material web, and with a function switch for releasing the web marking unit, with a web marking being applied to the material web by the web marking unit as soon as a printing error has been detected by the control unit and the web marking unit has been released by the operator.

In addition, the solution according to the invention consists of a corresponding method for automatic error management on a printing press, in which a repetitive print image is printed on a running material web, in which a control unit and a camera connected to the control unit carry out an inspection of the printed material web to detect printing errors is carried out, in which a web marking unit for applying web markings to the running material web and a function switch for enabling the web marking unit are provided, with a web marking being applied to the material web by the web marking unit as soon as a printing error has been detected by the control unit and the web marking unit from has been released to the operator.

An essential advantage of the solution according to the invention is that several web markings can also be applied to the running material web during the printing process, with the application of an uncontrolled number of markings being able to be avoided at the same time due to the existing function switch. Especially with so-called 100% inspection systems, it can happen that the inspection system detects a large number of errors within a very short time (e.g. if an inking unit fails). In such a case it is important that the operator is able to attribute the failure to a single mark on the web and that an uncontrolled number of marks are not automatically applied to the web because of the failure.

The marking can consist of a bar code or a QR code, for example. The QR code (English Quick Response) is a two-dimensional code that is used, for example, in EP 0 672 994 A1 is described. The QR code consists of a square matrix with black zen and white squares that represent the encoded data in binary form. A special marking in three of the four corners of the square provides orientation. The data in the QR code is enhanced with an error-correcting code. This tolerates the loss of up to 30% of the code. Further developments are the micro QR code, the secure QR code (SQRC), the iQR code and the frame QR code.

According to a preferred embodiment, it is provided that the marking is assigned further information in addition to the location of the error, for example the type of error, the relative distance of the error to the marking, the extent of the error in running meters and/or other remarks or comments by the operator . Alternatively, a first marking could mark the beginning of the error using appropriate information, and another marking could mark the end in a corresponding manner. It is also possible for the information from a number of errors to be summarized on the marking.

Depending on the amount of information, the information can be integrated as a whole in the QR code or it can also be stored in a separate database, in which case the QR code only contains the database entry for the relevant information.

According to a further preferred embodiment, the camera consists of a line camera for seamless inspection. Alternatively or additionally, a zoomable area camera can be provided for inspecting certain areas of the printed image.

The solution according to the invention can in principle be used for all types of printing presses. Preferred applications are flexographic printing machines, gravure printing machines or digital printing machines. In this context, a distinction must be made: Flexographic printing machines and gravure printing machines are equipped with fixed printing forms, so that only the repetitive print image can be printed with these printing forms. With digital printing machines, on the other hand, it is possible to print both repetitive print images and changing motifs. The combination of repetitive print images and individual motifs is also possible. In practical terms, this means that with a digital printing machine, the web marking can be printed directly with the repetitive print image. If the track marking is a QR code, you do not need an additional QR printer, for example.

• 1 zeigt eine Gesamtansicht der erfindungsgemäßen Druckmaschine am Beispiel einer Flexodruckmaschine,
• 2 zeigt eine Detailansicht von 1 mit einer Zeilenkamera und einer laufenden Materialbahn in einem ersten Druckzustand, und
• 3 zeigt eine Detailansicht von 1 mit einer Zeilenkamera und einer laufenden Materialbahn in einem zweiten Druckzustand.

Further details and advantages of the invention are described with reference to the accompanying drawings.

• 1 shows an overall view of the printing machine according to the invention using the example of a flexographic printing machine,
• 2 shows a detailed view of 1 with a line camera and a running web of material in a first printing state, and
• 3 shows a detailed view of 1 with a line camera and a running web of material in a second printing state.

1 shows an overall view of the printing machine according to the invention using the example of a flexographic printing machine 101 with a camera 102, a prepress stage 103, a control unit 104 and a control station 106. The control unit is installed at position 105 in the flexographic printing machine 101 and is shown separately for reasons of clarity.

The flexographic printing machine 101 is a so-called central cylinder machine and accordingly has a central cylinder 107 around which the eight inking units are arranged in a star shape. Each of these inking units has a printing roller, an anilox roller and a doctor blade chamber, each of which is mounted on machine-side anchors. Of these eight inking units with the components described, inking unit 108 is designated as an example.

In order to print the material web 109, it is pulled off the material roll 111 in the unwinding station 110 and guided to the pressure roller 112 via a plurality of deflection rollers. The pressure roller 112 applies the material web 109 to the central cylinder 107 for onward transport, so that the material web 109 is guided past the inking units and the intermediate inking unit dryers (not shown in more detail) with register accuracy.

After the material web 109 has left the central cylinder 107, it is guided through a web marking unit 121, which is designed here as a QR printer for optionally printing web markings in the form of QR codes.

After leaving the QR printer 121, the material web 109 reaches the bridge dryer 113 for the printing ink to dry and is then wound up onto the material roll 115 in the winding station 114.

The camera 102 is equipped in such a way that it can be operated by the control unit both as a line camera and as a zoomable area camera. To operate the camera 102 this is connected to the control unit 104 via the line 116 . Alternatively, it is of course also possible for two separate cameras to be provided in the form of a line camera and an area camera, with the two cameras being able to be operated either together or individually.

The monitor of the control station 106 is designed as a touchscreen, so that the operator can execute specific commands for controlling the flexographic printing machine 101 directly on the monitor, guided by menus.

The prepress stage 103 transmits the digital proof to the control unit 104 via the line 117 in a data container 118. On the basis of the digital proof, error detection algorithms run on the control unit 104, which detect printing errors due to target/actual print image deviations. The related actions between the control unit 104 and the control station 106 are transmitted via the lines 119 and 120 and are based on the following 2 and 3 described in more detail.

2 shows a detailed view of 1 with a line camera and a running web of material in a first printing state. The corresponding reference numbers 1 were adopted, so that extent to the description of 1 is referenced. In addition, reference numeral 201 designates a repetitive print image that is printed onto material web 107 by one or more inking units 108 .

In this first printing state, it is now assumed that one of the print images was printed with a printing error 202. The print image 201 and the print error 202 are recorded by the camera 102 as an actual print image and forwarded to the control unit 104 via the line 116 . In the control unit 104, the actual print image is subjected to an error detection algorithm. If, as in this case, a printing error is detected, a function switch in the form of a software button is displayed on the control station 106 2 shown as button 203. At this point, the operator has the option of assessing the printing error and optionally adding additional information, such as remarks or comments. As soon as the operator then presses or clicks on the software button 203, the QR printer 121 is activated and prints a QR code on the material web 107 to mark the printing error 202. The previously collected information on the printing error (position, type of error, comments on the operator, etc.) are saved as part of the QR code. Another possibility is that a link is stored in the QR code, which, when called up, refers to the information on the printing error (position, error type, operator comments, etc.).

3 shows a detailed view of 1 with a line camera and a running web of material in a second printing state. The corresponding reference numbers 1 and 2 were adopted, so that extent to the description of 1 and 2 is referenced. In addition, reference numeral 301 designates a subsequent print image compared to the first print state. Also, reference numeral 302 shows a QR code printed in the first printing state according to FIG 2 was printed by the QR printer 121 and which now appears in the picture taken by the camera 102.

In the second printing state according to 3 the exact position information between the printing error 202 and the QR code 302 can now be determined automatically, since the camera 102 can detect both the position of the printing error 202 and the position of the subsequent QR code.

In principle, the distance between printing error 201 and QR code 302 is not relevant for this assignment. However, the distance chosen by the operator should not be too great in order to avoid errors in recognition due to different web tensions and web elongations.

During further processing, the recognition then runs in reverse order. When the printed web of material is unwound, the QR code 302 is first recognized by a QR code reader before the printing error 202 then appears on the unwound web of material. After the QR code 302 has been recognized, an action can then be started during further processing that was previously assigned to the printing error 202 in the roll log, such as ejecting the faulty section of the material web from further processing.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• EP 3132936 A1 [0011, 0012]
• EP 0672994 A1 [0017]

Claims (10)

Printing machine with a system for automatic error management for printing a running web of material with a repetitive print image, with a control unit, with a camera connected to the control unit to carry out an inspection of the printed material web to detect printing errors, with a web marking unit for applying web markings to the running material web, and with a function switch for activating the web marking unit, a web marking being applied to the material web by the web marking unit as soon as a printing error has been detected by the control unit and the web marking unit has been activated by the operator. printing press claim 1 , where information about the printing error is integrated in the lane marking. printing press claim 1 - 2 , whereby the camera consists of a line camera for the complete inspection of the printed images. Printing press according to one of Claims 1 - 3 , whereby the camera consists of a zoomable area camera for the inspection of specific areas of a printed image. Printing press according to one of Claims 1 - 4 wherein the printing machine is a flexographic printing machine, a gravure printing machine or a digital printing machine. Procedure for automatic error management on a printing press, in which a repetitive print image is printed on a running web of material, in which an inspection of the printed material web is carried out with a control unit and with a camera connected to the control unit in order to detect printing errors, in which a web marking unit is provided for applying web markings to the running web of material, and in which a function switch is provided for enabling the lane marking unit, wherein a web marking is applied to the material web by the web marking unit as soon as a printing error has been detected by the control unit and the web marking unit has been enabled by the operator. procedure after claim 6 , whereby information about the printing error is integrated into the web marking. procedure after claim 6 - 7 , whereby the camera consists of a line camera for the complete inspection of the printed images. Procedure according to one of Claims 6 - 8th , whereby the camera consists of a zoomable area camera for the inspection of specific areas of a printed image. Procedure according to one of Claims 6 - 9 wherein the printing machine is a flexographic printing machine, a gravure printing machine or a digital printing machine.

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