This application is the national stage entry under 35 U.S.C. § 371 of International Patent Application No. PCT/EP2020/078826 filed on Oct. 14, 2020, and claims the benefit of German Patent Application No. 10 2019 127 994.1 filed Oct. 16, 2019, the disclosures of which are incorporated herein by reference in their entirety.
The invention relates to a method for automated error management in a printing machine, in which a recurring print image is imprinted on a moving material web.
In this context, error management refers to all actions taken to handle printing errors in the printing machine during the printing process. Error management typically includes three phases, namely error detection (i.e. the determination that an error is present), error diagnosis (i.e. allocation to a specific cause), and the actual error elimination.
So-called inspection systems are used to carry out error management in a printing machine. Such inspection systems are generally designed to enable the operator to observe and control the print image as a stationary image in the ongoing printing process on a monitor. The print image is typically acquired by a line scan camera. In contrast to an area scan camera, the line scan camera only acquires a single image line at a time since this allows for achieving a higher resolution and a higher readout speed compared to an area scan camera. The two-dimensional image is then created based on the movement of the conveyor. However, since this movement is subject to continuous fluctuations, the feed is synchronized via an encoder to prevent image distortions.
As an alternative or in addition to the line scan camera, the inspection system may also feature an area scan camera (also called matrix camera) that acquires a section of the print image on the moving material web. Synchronizing the area scan camera with the recurring print image ensures that a stationary image representing the selected section of the print image is displayed to the operator on the monitor of the control station. Preferably, the selected section is a distinctive area of the print image in which printing errors have a particularly relevant effect. The matrix camera is typically capable of zooming so that faulty or problematic areas of the print image may be examined in high resolution. If the operator detects printing errors in the displayed section (for example, color or register errors), the operator is in a position to readjust the machine parameters (for example the impression setting, the longitudinal register or the lateral register) to correct the printing errors.
Alternatively or in addition to the line scan camera and the area scan camera, the inspection system may further feature an optical spectrometer. An optical spectrometer breaks the light absorbed by a light point into its spectral components and evaluates the result in a computer system. Miniature spectrometers that are installed in a compact housing and may thus be placed in a suitable location within the printing machine are particularly suitable for the applications of the present invention. Such miniature spectrometers generally consist of an aperture (i.e. an entry gap), 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 varying angles, thus enabling the optical sensor to evaluate the scattered light as light intensity over the wavelength of the respective light components. Such an optical spectrometer is thus capable of monitoring the color components of a pixel within the print image during the printing process and of identifying deviations from a desired color result.
The positions of the errors detected by the operator on the moving material web are saved in the inspection system. After the completion of the printing process, it is then possible, for example with the aid of a rewinder, to move to, and separate the faulty portion of the imprinted material web. It is equally feasible to mark the faulty areas on the material web during printing and to discard them during subsequent processing.
Furthermore, error recognition algorithms are known that are able to automatically recognize specific errors in the print image and to subsequently support the operator in fulfilling his tasks.
For example, an error recognition algorithm may be based on a reference image acquired at the start of the print order. For example, the reference image may be acquired via the line scan camera, the area scan camera, and/or the optical spectrometer at the start of the printing process based on the first print images (for example, the first 50 images), using a process in which these first images are integrated to create the reference image (also called “Golden Image”). In the integration phase, the fluctuation range of the image information may, for example, be determined for each individual pixel to set tolerance limits for error recognition. The currently acquired image is then subtracted from the reference image during the printing process. If the resulting difference is outside of the error tolerances, an error signal is generated, and the faulty image range is displayed on the control station monitor.
Alternatively or additionally, the desired print result may also be specified by means of the so-called digital proof provided by the prepress phase. To determine whether the print result meets the specifications, the image supplied by the inspection system is compared to the digital proof. The digital image processing techniques described above for the reference image may also be used for this comparison.
However, the above-described inspection systems and error recognition algorithms do not yet, or only to a minor extent, enable automatic error management in printing machines. Automatic error management in this context means that the printing machine operator is supported in all three phases of error management. Ideally, the automatic error management will even take over all actions that are required regarding a specific error in the printing machine.
The task of the invention is therefore to improve the automatic error management for existing inspection systems.
This task is solved by the characteristics of claim 1. Further preferred specific embodiments are given in the subclaims.
The attached drawings describe further details and advantages of the invention.
The flexographic printing machine 101 is a so-called color impression machine and thus has a color impression drum 107 around which the eight color decks are installed in a satellite arrangement. Each of these color decks has a plate cylinder, an anilox mandrel and a doctor blade chamber, each of which are mounted on machine-side anchorages. Color deck 108 is labeled with the described components as an example of these eight color decks.
To imprint the material web 109, it is pulled off the material roll 111 in the unwinding station 110 and guided over several deflection rollers to the nip roller 112. The nip roller 112 places the material web 109 on the color impression drum 107 for further transport so that the material web 109 is moved with register accuracy past the color decks and the between-color dryers not shown in detail.
Once the material web 109 has left the color impression drum 107, it is moved through a bridge dryer 113 for drying the ink and is then wound onto the material roll 115 in the rewinding station 114.
The flexographic printing machine also features an inspection system for error recognition. For this purpose, an initial print image 118 (composite file) is saved together with the color separations from prepress 103 in the control unit 104, the prepress being connected to the control unit 104 via the cable. 117. The initial print image 118 is then compared to the actual print image acquired by the line scan camera 102 in the control unit 104, the line scan camera being connect to the control unit 104 via the cable 116.
The method according to the invention is described by way of example in
The material web moving out of bridge dryer 113 was imprinted by the color decks 108 and thus features a recurring print image. The print image is not shown in FIG. 2 for reasons of simplicity. The line scan camera 102 acquires the print image and forwards it to the control unit 104 via cable 116. An error recognition algorithm is implemented in the control unit 104 to recognize printing errors.
If a print error is recognized by the error recognition algorithm, said error is saved by the control unit together with a position information and a status information, the position information including at least the position from the margin of the error on the material web.
Reference sign 201 designates a first print error and reference sign 202 designates a second print error on the moving material web 107, print errors 201 and 202 being of the same type. If the print error is recognized by the error recognition algorithm, the method according to the invention is not limited to merely displaying this error to the operator. Rather, the print error 201 is entered into a cluster image to thus provide an error diagnosis to the operator.
A cluster image as defined by the present invention generally is a multidimensional space, in which the control unit enters the recognized print errors depending on a position information and a status information of the respective print error.
Print errors within a cluster 303 thus are print errors that occur periodically at the same position crosswise to the web. Such errors are generally caused by defective rollers because the periodicity (i.e. the relative spacing of print errors in the movement direction of the web) matches the circumference of the corresponding damaged roller.
Rollers having a direct influence on the print image in a flexographic printing machine include, for example, the plate cylinders, the anilox mandrels, or the impression cylinder. Contamination, mechanical damage, or other irregularities are passed on to the print image during printing and generate the corresponding errors.
If the plate cylinder is the cause of the print error, the print error always appears in the same position in the print image. In that case, every rotation of the plate cylinder generates an error in the print image. The spacing between the errors thus corresponds exactly to the plate length (i.e. the circumference of the plate cylinder).
The situation is different for an anilox mandrel or the impression cylinder. In that case, the print error is only visible in the print image if there is a printable area in the position of the print error. However, the error does not necessarily appear in the print image with every turn of the cylinder. Rather, the relative spacing of the errors corresponds to the circumference of the impression cylinder and thus differs from the print length of the plate cylinder. That means the print error occurs at a different position of the print image.
If the circumferences of the corresponding cylinders are known, the spacing between the errors may be compared to these circumferences. This allows for assigning a cause to the error: If the print has the same periodicity as the longitudinal distance Δa and a specific cylinder also has the circumference Δa, the print error may be assigned to this cylinder.
In the case of the impression cylinder, the cause can thus be clearly identified. Furthermore, it may be feasible to specify the causal location on the impression cylinder based on suitable tracing of the web into the printing machine. If the operator therefore wants to stop the print order, it is further feasible for the control unit to stop the impression cylinder in such a way that the cause of the error on the impression cylinder is easily accessible to the operator.
In general, it is understood that the cluster image according to the invention as shown in
Number | Date | Country | Kind |
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10 2019 127 994.1 | Oct 2019 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/078826 | 10/14/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/074179 | 4/22/2021 | WO | A |
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International Searching Authority—International Search Report, pertaining to International Application No. PCT/EP2020/078826, dated Dec. 23, 2020, together with the Written Opinion of the International Searching Authority and translation pages of ISR, 12 pages. |
Number | Date | Country | |
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20240109284 A1 | Apr 2024 | US |