The present invention generally relates to a color control pattern for the optical measurement of colors printed on a sheet or web substrate by means of a multicolor printing press, especially by means of a multicolor security printing press, and to a printed sheet or web substrate comprising the same. The present invention further relates to a color measurement system making use of such a color control pattern, in particular for performing in-line color measurements in a multicolor printing press and, possibly, for automatically adjusting and/or setting inking units of the multicolor printing press. The present invention also relates to a multicolor security printing press for the production of security documents, such as banknotes, comprising such a color measurement system.
Color measurement systems, especially for performing in-line color measurements in a multicolor printing press and, possibly, automatic adjustment and/or setting of inking units of the printing press are already known as such in the field of commercial printing. Such known systems are typically used in connection with commercial offset printing presses that are used to print various types of commercial products using the well-known four-color CMYK (Cyan-Magenta-Yellow-Key Black) subtractive color model, i.e. by printing multicolor patterns consisting of a combination of halftone raster patterns printed using the four primary colors Cyan, Magenta, Yellow and Black.
International application No. WO 2007/110317 A1 (and corresponding US publication No. US 2010/0116164 A1), which is incorporated herein by reference in its entirety, for instance discloses a method for adjusting an inking unit of a printing press. During a setup phase of the printing press, a small number of sheets are run through the printing press and the resulting printed sheets are inspected by means of a first measuring device (which is not integrated into the printing press), such as a densitometer, color spectrometer or a measuring instrument for combined densitometric and colorimetric measurements. The values measured by the first measuring device are compared to predetermined reference values and adjustments of the inking units of the printing press are made so that the values measured by the first measuring device match as closely as possible the desired reference values. A set of “first actual values” representative of the desired settings are thereby determined and stored as a result of the setup phase and the printing press can be released for production runs. At least a second measuring device is provided downstream of the printing units of the printing press in order to inspect the sheets during production, which second measuring device is installed in the printing press. Such second measuring device is for instance embodied as an in-line inspection system comprising at least one camera system and at least one illumination unit. The camera system is typically a color camera system comprising a line-scan sensor or an array sensor based on CCD or CMOS technology. The illumination unit typically comprises light-emitting diodes, or LEDs, or like illumination elements. The second measuring device records an image of at least one, preferably of all of the sheets which are printed on the printing press and converts the recorded images to digital image data which is fed to an image processing system as a set of “second actual values”. During a learning phase, the set of “second actual values” is measured and stored as reference values for controlling an adjustment unit which adjusts the inking units of the printing press. Upon completion of the learning phase, all further printed products which are produced on the printing press are evaluated on the basis of the reference values that were established during the learning phase and any deviation between the reference values and the measured values which exceeds an acceptable tolerance is corrected by means of the adjustment unit.
According to WO 2007/110317 A1, measurements are typically made on at least one measuring strip (or “color control strip”) that forms part of the patterns printed on the sheets, which measuring strip is typically located in a margin of the sheet, such as the margin at the leading edge of the sheet, outside the effective printed region of the sheet where the actual prints are carried out.
An example of such a measuring strip is disclosed in German patent application No. DE 10 2008 041 426 A1. This measuring strip comprises a plurality of juxtaposed color control fields, including color control fields printed in the primary colors (i.e. Cyan, Magenta, Yellow, Black colors), which color control fields are positioned in dependence of the relevant inking zones of the inking units of the printing press where ink adjustments are carried out.
European patent No. EP 0 142 469 B1 (and corresponding U.S. Pat. No. 4,660,159—see also EP 0 142 470 B1 and U.S. Pat. No. 4,665,496) discloses a method for adjusting an inking unit of a printing press. Reference reflectance values for a printed sheet are determined outside of the printing press by means of a scanning device, such as a plate scanner. Actual reflectance values of printed sheets which are being printed on the printing press are measured during production using a densitometer. The actual reflectance values and the reference reflectance values are compared with one another in a computer system. Based on the results of this comparison, control values for adjusting the inking units are calculated and ink feed elements are controlled on the basis of these control values. According to EP 0 142 469 B1, measurements are made directly in the printed image itself, the printed image being subdivided into a plurality of image elements whose reflectance values are measured. In this way, the use of special color measuring strips may be eliminated.
International application No. WO 2005/108083 A1 (and corresponding U.S. Pat. No. 7,515,267 B2) discloses a method for determining color and/or density values for monitoring and/or regulating a printing process in a printing apparatus, especially for use in a sheet-fed commercial offset printing press. According to WO 2005/108083 A1, measuring areas of a printed sheet are measured photoelectrically during the printing process and color and/or density values for the relevant measuring areas are determined. Deviations in the measured color and density values, as compared to measurements made outside of the printing press, are corrected.
International application No. WO 2005/108084 A1 (and corresponding U.S. Pat. No. 7,398,733 B2) discloses a method for in-line measurement of spectral, densitometric or color values measured on sheets being printed on a sheet-fed commercial offset printing press, which method involves a color calibration process. Measurements are made on a color control strip (see FIG. 9 of WO 2005/108084 A1) that is printed next to the effective printed region where the actual prints are carried out. Such color control strip comprises a plurality of juxtaposed color control fields, including control fields printed in the primary colors (i.e. Cyan, Magenta, Yellow, Black colors), which control fields are positioned in dependence of the relevant inking zones of the inking units.
U.S. Pat. No. 5,724,259 discloses a system and method for monitoring color in a commercial offset printing press. Measurements are made on a color bar (or “color control strip”—see in particular FIG. 5a of U.S. Pat. No. 5,724,259) comprising a plurality of juxtaposed color control fields printed in the primary colors (i.e. Cyan, Magenta, Yellow, Black colors) and with different tones (e.g. 100%, 75%. 50%, 25%) and combinations thereof including Blue (i.e. subtractive addition of Cyan and Magenta colors), Red (i.e. subtractive addition of Magenta and Yellow colors) and Green (i.e. subtractive addition of Cyan and Yellow colors).
European patent No. EP 0 394 681 B1 (and corresponding U.S. Pat. No. 5,023,812) discloses a method for controlling ink feed of a printing press wherein a sheet printed by the printing press is measured photoelectrically in a color control strip having a plurality of juxtaposed color-measuring fields, color measurement being carried out by a measuring head forming part of a densitometer or spectrometer, which measuring head scans the color control strip. A similar approach is disclosed in European patent No. EP 0 337 148 B1 (and corresponding U.S. Pat. No. 5,122,977).
European patent application No. EP 0 434 072 A2 also discloses color control strips for use in conventional four-color commercial offset printing. Further examples of color control strips or like color control elements are disclosed in European patent No. EP 0 590 282 B1, German patent publication DE 10 2007 029 211 A1 (see also corresponding US publication No. US 2008/0314268 A1), and U.S. Pat. No. 4,947,746.
All of the above known solutions are used for performing color measurements in commercial offset printing presses, i.e. printing presses of the type based on four-color composite printing using the CMYK subtractive color model. Printing presses of this type comprises at least four distinct printing towers which are each designed to print one of the four primary colors. Additional printing towers may be provided to print special colors and/or for the purpose of coating the printed substrates.
The above solutions are satisfactory as far as applications to commercial offset printing presses are concerned and basically require the use of a rather simple color control strip comprising a plurality of color control fields representative of the relevant primary colors that are printed (i.e. Cyan, Magenta, Yellow, Black) and, possibly, simple combinations thereof (e.g. Blue/Cyan+Magenta, Red/Magenta+Yellow, and Green/Cyan+Yellow) and/or additional special colors.
Commercial four-color offset printing is based on the printing of different raster patterns of each one of the four primary colors which are combined together to create, by subtractive color combination, a visual impression of various multicolor tones. In that respect, the design of the color control strip, and more precisely the locations of the relevant color control fields, bears no real importance, all of the relevant primary colors being typically distributed over the whole surface of the printed product.
The typical approach in terms of design of the relevant color control strips is to design those in dependence of the relevant ink zones where ink is applied and can be adjusted. The known color control strips therefore typically consist of a repetition, for each ink zone, of a predetermined succession of color control fields.
In contrast to commercial (offset) printing, security printing (as applied for instance for the production of banknotes) is not at all based on the use of a four-color printing process relying on the CMYK subtractive color model. Rather, solid patterns are printed using different printing inks of the desired colors (i.e. a blue pattern is printed using a blue printing ink, a brownish pattern using a brownish ink, a copper-like pattern using a copper-coloured printing ink, etc.).
Typical color control strips as used in commercial printing are not suitable for security printing applications for the purpose of measuring the printed colors, even less for the purpose of automatically controlling the ink supply. There is therefore a need for a new and improved solution which can suitably cope with the specific requirements of security printing.
A general aim of the invention is therefore to improve the known color control elements and provide a solution that is adapted to the specific requirements of security printing.
More specifically an aim of the present invention is to provide such a solution that permits optimal measurement of the colors printed on the sheet or web substrate, in particular for the purpose of performing in-line color measurements in a multicolor printing press, especially in a multicolor security printing press.
Still another aim of the present invention is to provide such a solution that is suitable for carrying out closed-loop color control operations in a multicolor printing press, especially in a multicolor security printing press.
These aims are achieved thanks to the solution defined in the claims.
There is accordingly provided a color control pattern as defined in claim 1, namely a color control pattern for the optical measurement of colors printed on a sheet or web substrate by means of a multicolor printing press, especially by means of a multicolor security printing press, which substrate exhibits an effective printed region having a multicolor printed image comprising a plurality of juxtaposed colored areas printed with a corresponding plurality of printing inks of different colors, wherein the color control pattern is located in a margin portion of the substrate next to the effective printed region. Such color control pattern comprises one or more color control strips extending transversely to a direction of transport of the substrate, each color control strip comprising a plurality of distinct color control fields consisting of printed fields of each relevant printing ink that is printed in the effective printed region. These color control fields are coordinated to actual application of the relevant printing inks in the effective printed region and are positioned transversely to the direction of transport of the substrate at locations corresponding to actual positions where the relevant printing inks are applied in the effective printed region.
Preferably, the effective printed region consists of a matrix of individual multicolor prints, especially multicolor security prints, arranged in multiple rows and columns and the color control pattern comprises an individual color control pattern for each column of individual multicolor prints. All such individual color control patterns are advantageously identical.
Advantageous designs of the color control pattern are described hereinafter.
Also claimed is a printed sheet or web substrate comprising a color control pattern as defined above, which color control pattern is printed on one or both sides of the substrate.
There is also provided a color measurement system, comprising an optical measurement system for measuring the colors printed on the substrate, wherein the optical measurement system is designed to carry out measurement of the colors printed on the sheet or web substrate in a color control pattern as defined above.
Advantageously, portions of the color control pattern that are affected by features embedded within, applied or printed onto, or otherwise provided in or on the substrate, such as security threads, watermarks, applied foil material, iridescent stripes and the like, are not considered for the purpose of color measurement.
There is also claimed a multicolor security printing press for the production of security documents, such as banknotes, comprising a color measurement system as defined above. Such multicolor security printing press is preferably an offset printing press, especially a Simultan-type offset printing press for the simultaneous recto-verso printing of sheets or webs.
The instant color control pattern and printed sheet or web substrate (and color measurement system) can advantageously be used for the purpose of:
(i) performing in-line color measurements in a multicolor printing press, especially in a multicolor security printing press; and/or
(ii) automatically adjusting and/or setting inking units of a multicolor printing press, especially of a multicolor security printing press.
Similarly, the instant color control pattern and printed sheet or web substrate (and color measurement system) can advantageously be used for the purpose of performing off-line color measurements.
Also claimed is a set of printing plates for the impression of a color control pattern or the impression of a sheet or web substrate as defined above, wherein each of the printing plates of the set comprises a relevant subset of the color control fields forming the color control pattern.
Advantageous embodiments of the invention form the subject-matter of the dependent claims and are discussed below.
Other features and advantages of the present invention will appear more clearly from reading the following detailed description of embodiments of the invention which are presented solely by way of non-restrictive examples and illustrated by the attached drawings in which:
The invention will be described hereinafter in the context of a sheet-fed offset printing press for the simultaneous recto-verso printing of sheets for the production of security documents, such as banknotes. Such a security printing press is illustrated in
The security printing press illustrated in
Sheets are fed from a feeding station 1 located at the right-hand side of the printing group illustrated in
The chain gripper system 5 typically comprises a pair of chains holding a plurality of spaced-apart gripper bars (not shown) each provided with a series of grippers (designated by reference numeral 55 in
At the two extremities of the chain gripper system 5, namely below the blanket cylinders 10, 20 and at the outermost left-hand-side part of the sheet delivery station 6, there are provided pairs of chain wheels 51 and 52 for driving the endless chains of the chain gripper system 5.
In the example of
Turning to the inspection system, the printing press shown in
More precisely, the inspection device 100 is disposed in such a way that the first line image sensor 110 visually acquires an image of a printed sheet while the printed sheet is still adhering onto the surface of the first blanket cylinder 10 of the printing press and immediately before the printed sheet is transferred to the down-stream located transfer cylinder 60. In the embodiment of
The other inspection device 200 similarly comprises a line image sensor 210 (such as a CCD or CMOS color camera) for performing line-scanning image acquisition of the other side of the printed sheets while these are transported by the first transfer cylinder 60. No mirror is required in this case, as the first transfer cylinder 60 enables presenting the other side of the printed sheets directly in front of the line image sensor 210. A light source 230 is also disposed in order to appropriately illuminate the inspected zone on the sheet carried by the transfer cylinder 60.
In the example of
As shown in
In the example shown in
As further illustrated in
In the context of the present invention, it will be assumed that the above-described inspection devices 100, 200 are both adapted to take an image of the entire sheet S (or substantially the whole surface thereof), including the effective printed region EF and the color control pattern CP. For the purpose of color measurement (and possibly automatic regulation of the inking units), it may however suffice to take only an image of the portion of the sheet S where the color control pattern CP is printed. It will also be appreciated that a color control pattern CP would in practice be provided on both sides of the sheets S (unless the printing press is only designed to print one side of the sheets at a time).
As shown in greater detail in
In this particular example, each individual color control pattern consists of up to thirty-two color control fields CF along each color control strip a, b, c, d, i.e. a total of hundred and twenty-eight color control fields CF are provided in each individual color control pattern. As this will be described hereinafter, these color control fields CF are coordinated to the actual application of the relevant printing inks in the effective printed region EF and are positioned transversely to the direction of transport T of the sheet S at locations corresponding to the actual positions where the relevant printing inks are applied in the effective printed region EF. The number of color control fields CF is purely illustrative and actually depends on various factors, including the length (transversely to the direction of transport T) of each individual print and the dimensions of each color control field CF.
In the particular example of
According to the preferred embodiment of
In
In contrast to the known solutions, it may already be appreciated that the color control pattern CP is not designed in accordance with the ink zone subdivision, but in accordance with the actual printed image that is printed in the effective printed region EF.
As the matrix arrangement of individual prints P does not (necessarily) match the ink zone subdivision (i.e. the length of each individual print P transversely to the direction of transport T of the sheet S is generally not an integer multiple of the ink zone width), this also means that the distribution of the relevant color control fields CF will differ from one ink zone to the other. This may for instance be appreciated by comparing the distribution of the color control fields CF in ink zone Zi+1, where color control fields CF of the first and second color control patterns CP1 and CP2 are present, with that of the color control fields CF in ink zone Zi+7 where only part of the color control fields CF of the third color control pattern CP3 are present. As a consequence, it should also be appreciated that the relationship between the ink zone subdivision and the individual color control patterns (and associated color control fields) will typically differ from one column of prints P to the other.
Depending on the actual printed design (and possibly other factors such as the presence of interfering features present into or onto the sheet S), it may not actually be possible to provide (or measure) all relevant color control fields CF of the desired colors in each ink zone where the corresponding inks are applied. In such a case, it may suffice to provide such a color control field CF in one or both of the immediately adjacent ink zones and derive a color measurement from this other color control field CF. While this does not allow a direct measurement of the desired color in the relevant ink zone, this may nevertheless enable the operator to derive an indirect measurement of the relevant color in the desired ink zone.
Preferably, the color control pattern CP should be designed in such a way that at least one color control field CF (ideally more than one) of each relevant color is provided within each ink zone where the corresponding printing is applied.
The illustration of
As schematically illustrated in
While
As illustrated in the example of
In the illustrated example, the color control fields CFA, CFB and CFC corresponding to areas A to C are concentrated on the left-hand side of the color control pattern CPi while the remaining color control fields CFD to CFH corresponding to areas D to H are located on the right-hand side of the color control pattern CPi.
As shown in
As illustrated in
As further illustrated in
In
In
The above-described color control pattern can be suitably used for performing color measurements, especially on substrates carrying multicolor prints for the production of security documents, such as banknotes. Such color measurements can be carried out off-line by means of a dedicated measurement tool or in-line on the printing press. In this latter case, and taking the example of
Preferably, such in-line color measurement is carried out on a multicolor offset printing press for the production of security documents, advantageously on a Simultan-type offset printing press for the simultaneous recto-verso printing of sheets (or webs) as depicted for instance in
In the context of the production of security documents, features embedded within the substrate (such as security threads or watermarks), applied or printed onto the substrate (such as foil material or iridescent stripes), or like features provided in or on the substrate may partly affect measurements in portions of the color control pattern.
As shown in
Depending on the actual printed design, entire portions of the color control pattern may ultimately be unusable for the purpose of carrying out color measurements. In such a case, the color control pattern needs to be designed in such a way as to cope with such situations and ensure that at least one color control field is present in the vicinity of the location where a measurement would have to be undertaken, possibly in one or both of the immediately adjacent ink zones.
The above-described color control pattern may be used for other purposes than merely for the purpose of carrying out color measurements. Advantageously, the color control pattern of the invention could be used for automatically adjusting and/or setting inking units of a multicolor printing press, especially of a multicolor security printing press of the type shown in
Any suitable methodology for performing automatic ink control of the security printing press can potentially be applied as long as it is capable of making use of the color control pattern of the invention. A preferred methodology which can suitably be used with the color control pattern of the invention is the one disclosed in International application No. WO 2007/110317 A1, which publication is discussed in the preamble hereof and is incorporated by reference in its entirety.
Each inspection system 100, 200 would output corresponding digital image data to first and second image processing systems 150, 250, which image processing systems 150, 250 would perform the necessary processing to extract the required color measurements from the corresponding color control patterns. The results of such color measurements could be displayed to an operator on dedicated screens (not shown) for information and monitoring purposes, and possible manual adjustments, if required.
Automatic adjustment and setting of the inking units 13, 23 of the printing press would be carried out on the basis of the optical color measurements derived by the relevant image processing systems 150, 250 in dependence of predetermined reference settings as for instance disclosed in International application No. WO 2007/110317 A1. To this end, appropriate control units 160, 260 for controlling each set of inking units 13, 23 are provided, which control units 160, 260 receive the necessary input signals for effecting ink adjustments from the relevant image processing systems 150, 250. It is to be appreciated that adjustment of the inks printed on the recto side is performed by way of adequate settings of the inking units 23 under the control of unit 160, while adjustment of the inks printed on the verso side is performed by way of adequate settings of the inking units 13 under the control of unit 260.
As this is self-evident from reading the above description, the invention also relates to and encompasses any printed substrate comprising a color control pattern according to the invention, which color control pattern is printed on one or both sides of the substrate. Similarly, the invention also relates to and encompasses any set of printing plates for the impression of a color control pattern according to the invention, wherein each of the printing plates of the set comprises a relevant subset of the color control fields forming the color control pattern.
As regards the above-described color control pattern, it should further be appreciated that such color control pattern would typically be prepared jointly with the corresponding design and origination of the printing plates. Nowadays, such preparation is typically carried out on digital prepress systems. The claimed color control pattern therefore also encompasses any digital version of the color control pattern, in addition to its actual, tangible realization on the relevant printed substrates.
Various modifications and/or improvements may be made to the above-described embodiments without departing from the scope of the invention as defined by the annexed claims. For instance, while the invention was described in the context of a printing press adapted for sheet printing, the invention is equally applicable to the printing on a continuous web of material.
Furthermore, while the invention was specifically devised with the goal to find a suitable solution for application to security printing, the invention could nevertheless still be applied in commercial printing, especially in the case where special colors are used in addition to or as a replacement of the usual four primary colors used in commercial printing.
It is also possible to make use of any other type of inspection system than that shown in
Number | Date | Country | Kind |
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10187099 | Oct 2010 | EP | regional |
This application is a divisional of U.S. application Ser. No. 13/878,336 filed Aug. 9, 2013, which is the U.S. national phase of International Application No. PCT/IB2011/054453 filed Oct. 10, 2011 which designated the U.S. and claims priority to EP 10187099.6 filed Oct. 11, 2010, the entire contents of each of which are hereby incorporated by reference.
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Number | Date | Country | |
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Parent | 13878336 | US | |
Child | 16275188 | US |