DE4338976C3 - Arrangement of several control fields - Google Patents

Description

The invention relates to an arrangement of several Control fields to control and / or control the Multi-color printing according to the preamble of the claim 1.

Such arrangements of several control fields are called control strips or control blocks. According to DIN 16527 Part 1 , March 1993, a control strip is understood to mean a one-dimensional sequence of control fields. Similarly, a control block is a two-dimensional arrangement of control fields. There are control strips printed in one color or intended for single-color printing, as well as control blocks printed in multicolor or for multi-color printing. Control strips which are exclusively intended for the control, control or regulation of printing are specifically called print control strips, those which are used exclusively for monitoring the copy are specifically called copy control strips, while strips which can serve both purposes are only referred to as control strips become.

According to DIN 16 527 Part 1, a control field is understood to be an area on which one or more picture elements are arranged for test purposes. B. Ra dots, lines or full tones. According to DIN 16 527 Part 1 , the term control field refers to a test area that is transferred to a flat substrate (e.g. film, printing form, printing material) in a directly visible form, regardless of whether the information was previously in analog (e.g. B. film) or digital (z. B. magnetic memory, image plate) form stored was present. Examples of control strips and control blocks according to the prior art can be found in the publications GATF Technical Services Report No. 10, 1983; Groff, Kanonik: Test Images for Printing, GATF, Pitt burgh, PA, 1992; Products Catalog 1991-1992 , RIT, Roche ster, 1990; Gretag color measuring strips CMS, Gretag AG, Regensdorf / Zurich, Switzerland. Other control strips or control blocks according to the state of the art are produced without a copy by direct exposure of the printing form blank or by output on printers, color printers or so-called digital proofing devices (digital proofing devices).

Control strips and control blocks become visual or for metrological control of copying and printing processes used, with the latter name proof and production printing on printing machines according to the principles of planographic printing, gravure printing, letterpress printing, Printing is understood as well as the proof or pressure substitute with procedures that the specialist and un under the names "Cromalin" "Matchprint", "Color Art "are known.

Another application of such control means is Control or regulation of pressure during produc tion. The former can be based on a visual as well as an egg ner metrological evaluation of one or more Kon Troll fields take place, the latter only after metrological off evaluation. For this purpose, Densi tometer or color measuring devices, such as. B. Spectrophotometer used. Both devices record with a circular or elliptically shaped measuring spot printed by a optical energy reflected in the control panel.

Control intended for metrological evaluation Fields either consist of a solid field, i. H. one fully printed or pre-printed for full surface printing viewed area or a grid, d. H. one in ge printed or intended to print halftone dots or -li surface. Both full tones and grids tones can be monochrome or multi-colored. in the the latter cases are on the copy days of those involved Separation colors at the relevant point in the control field printing areas provided. On the substrate is called a control field is multicolored when it is through the Overprinting of several printing inks has arisen. Overprinting here means a pressure that is on the same surface of different colors are. Pigment layers are used here as printing inks stood, either as suspensions by pressure machine or in a test printing process as a toner party kel, as an inkjet printer ink, as a thermal transfer mass or as a layer on the Be are transferred. Scale printing inks are printing inks whose pigments use those for multi-color printing primary colors, e.g. B. Black, Cyan, Magenta, Yellow in four-color printing.

Of the multi-colored grid fields are particularly important those in which the areas of coverage of the printing inks involved are in such a numerical ratio that a print produced under undisturbed, average printing conditions appears achromatic to the eye, ie neutral gray. Such control fields are named according to DIN 16527 part 1 gray balance fields. From a minimum viewing distance, achromatic-looking, printed gray balance fields cannot be distinguished from grid fields that are only printed with the achromatic ink black.

Control fields of the prior art are e.g. T. formed so that their shape to the usual shape of the measuring spots of densitometers and other reflectometers is fitted. They are therefore rectangular in the case of devices with an elliptical measuring spot and square, circular or hexagonal in the case of circular measuring spots. In the case of a control strip of the prior art, the control strip CMS 2 from Gretag AG, the gusset between the circular, actual control field with 50% area coverage of the gusset created by the module size of the control strip is used for checking the highlight points of the same printing ink , Gusset and control field form a multi-area control field, which consists of a core area and four edge areas, the gussets.

Control strips and in particular pressure control strips the state of the art, as described in the EU A-518 559, CH-A-681 929 check the optical density and the color location biger prints of the scale printing colors black, cyan, ma genta, yellow or special printing inks. Likewise are multi-colored control fields for visual assessment tion or measurement available, such as the secondary colors Blue, green and red, the tertiary color black by the overprinting of the primary colors cyan, magenta, Yellow arises as well as gray balance fields.

The control strips and control blocks of the state of the Technology and the control fields that make it up have the Disadvantage that they take up too much space. This applies in particular to control fields used to control the multicolored overprint are provided like those of secondary and tertiary colors. For example, these are for the control strip FOGRA PMS pressure control bar summarized in a so-called "freestyle part", which in Contrary to the "mandatory part" only then put on the form if there is enough space. With the be Known control strips is also the print order not directly detectable. The glaze or the Transparency of the colored scale printing inks only indirectly via capture the appearance of the secondary colors.  

The invention is therefore based on the object order of several control fields according to the Oberbe handle of claim 1 to develop such that a less space is required without the Scope of control and testing options reduced becomes.

According to the invention, this object is achieved by the characterizing feature of claim 1, in that the control field is provided with at least one core area ( 2 ) and one edge area ( 4 ) which have a different number of overprinted printing inks.

The space required for multi-colored control fields, such as B. the full tones of the secondary colors greatly reduced that this at least z. T. in the Mes edge areas that cannot be used are laid. This be does not indicate a major disadvantage as secondary colors and tertiary colors are usually not measured be printed and therefore not printed on such large areas have to be like the primary colors. In the latter, the Core area to be able to measure the measuring spot of the reflecto meters with a generous tolerance. On An essential part of the inventive concept is the Be evaluation of the secondary colors and the tertiary color cyan (C) plus magenta (M) plus yellow (Y) through direct visual Comparison of the color of the edge that cannot be used for the measurement area with that of the core area, whereby the number of each other in the core area overprinted inks from those in the marginal area a different printing ink differs.

Further advantages and configurations are the subject of the subclaims and are based on the description some embodiments and the drawing he closer purifies.

Show in the drawing

FIG. 1a to 1d chen a schematic representation of con troll fields with at least two different preparation,

FIG. 2a is a schematic representation of a control strip,

Fig. 2b is a schematic illustration of a control blocks,

FIGS. 3 and 4 is a schematic representation of a con troll field with different printing of the different areas and

Fig. 5 is a schematic representation of a control block with a quadruple of abutting, he inventive control fields.

1a to 1d show control panel according to the invention of FIG. 1 , which has at least two regions, namely a core region 2 and at least one edge region 4 , with a different number of overprinted printing colors. The outline of the core area 2 should suitably be modeled on the shape of a measuring spot 3 of the densitometer or colorimeter used for evaluation, for example. Ordinary measuring spots 3 have either elliptical ( Fig. 1a) or circular ( Fig. 1b) shape. The core area 2 is kept slightly larger than the measuring spot 3 , so that inaccuracies in the positioning of the measuring device do not immediately lead to incorrect measurements.

The remaining area of the control field that does not belong to the core area 2 forms the edge area 4 . The control field 1 , which is formed in a quadratic manner in FIG. 1c, has a central core region 2 which is at least partially delimited by the triangular edge regions 4 a, 4 b, 4 c, 4 d arranged in the corners of the control field.

In the rectangular control field 1 according to FIG. 1d, the edge area 4 is arranged as a simply coherent surface above the measuring spot 3 .

The division of core area 2 and edge area 4 shown in FIGS . 1c and 1d are only to be understood as examples and can be varied as desired depending on the type of requirements and / or the shape of the measurement spot.

Different arrangements of several control fields are shown in FIGS. 2a and 2b. A control strip 5 is schematically illustrated in FIG. 2a, which has at least two control fields 1 according to the invention, for example according to FIG. 1c or 1d.

Compared to the one-dimensional arrangement of the control fields at the control strip 5 , the control fields at the control block 6 according to FIG. 2b are lined up in two dimensions.

Depending on the application, both the control strip 5 and the control block 6 can expediently see the following different types of control fields: sliding and duplication control field, highlight spot grid, shadow point grid, single-color solid field, multi-color solid color superimposed print field, gray balance field , Halftone field, copy control field, micro line field and dot matrix field.

FIG. 3 shows a control field 1 , which corresponds to the control field according to FIG. 1c in terms of its division of the individual areas. The core area 2 is printed in one color with the full tone of the printing ink A, while the marginal areas 4 a, 4 b, 4 c, 4 d are formed from the overprinted full tones of the printing inks A and B. If the printing inks A and B are the scale printing inks black and yellow, then the control field 1 can advantageously recognize an incorrect color sequence. If, contrary to normal practice, the black is above the yellow, its optical effect is covered by the non-glazing printing ink black, so that the eye makes no difference between the core area 2 and the edge areas 4 a, 4 b, 4 c, 4 d, especially when viewed under inclusion of the gloss. On the other hand, if the yellow print color is on the top, you can see the characteristic, almost metallic gloss of the yellow under the glossy angle. If the glaze of the yellow is not very good, you can recognize the yellow on top by a slight yellow shimmer of the overprint even if the gloss is reflected away.

In an analogous manner, it can be determined in general for printing inks with a non-ideal glaze whether the printing ink in question is below or above the printing ink black. This question is particularly important in the proofing test, since proofs with black as the last printed ink reflect a print result that can hardly be achieved with the color sequence usual in the edition printing with yellow as the last printing ink. The shrinking of the superimposed printing field "solid color of the printing ink yellow plus solid color of the printing ink black" and its shift into the edge area 4 of a control field 1 , the core area 2 of which has only a single print, such as, for. B. a "solid ink yellow" or a "solid ink black" saves compared to the prior art the space of a control panel. In addition, there is the advantage that in many cases an incorrectly chosen color sequence can be identified. The test options described are not tied to the fact that the Kernbe area 2 is printed with a single and the edge area 4 with two printing inks, swapping the color assignment would not restrict the testing options. According to the invention, it is only necessary to differ in the number of layers of printing ink printed in each case in order to make the visual comparisons described here feasible.

Analogous to the combination of yellow and black, the Color order for other combinations of print colors determine ben A and B. The only requirement is that the from A and B formed secondary colors depending on the color series distinguish sequence.

A control field 1 with black (S) as printing ink A can be used to control the glaze or the transparency of a second printed printing ink B, the cyan (C), magenta (M) and yellow (Y) printing inks being of course particularly important. Fig. 4 shows an here advantageous embodiment of a control panel 1. It includes an edge area 4 , which is divided into four different parts ( 4 a, 4 b, 4 c, 4 d). Each part is formed from the overprint of the full tone of the printing ink black and the full tone of a different scale printing ink, with a color assignment possibly occurring twice. The control field 1 consists of a black solid as a core area 2 , while each of the four parts of the edge area 4 is formed by overprinting the solid black with a scale printing ink. For example, be in the upper left part 4 b of the superimposed S + C, in the upper right part 4 a S + M and in the lower right part 4 d S + Y; the printing ink names are selected according to DIN 16539 part 1 . In the lower left part 4 c, a special printing ink can be accommodated or the repetition of a scale printing ink. The visual comparison of the color of part of the edge area 4 with the color of the core area 2 provides information about glaze and transparency. The glaze is perfect and the transparency is high if there is no color difference. The greater the difference, the worse the glaze and the lower the transparency.

The configurations of control fields 1 according to FIGS. 3 and 4 are also advantageous for assessing the color acceptance and lying, ie the uniformity, of a second printed ink on a first printed ink. For these controls, a control field 1 is advantageously used, which has a core area 2 and an edge area 4 divided into several parts. The core area 2 consists of the solid color of a printing color A, each part of the edge area 4 consists of the overprinting of the solid color of printing ink A with a solid color of one of several other printing colors. For example, printing ink A is formed by the scale printing ink cyan and the other printing inks are formed by the scale printing inks cyan, magenta and yellow. The control field 1 thus consists of a solid cyan as the core area 2 , while each of the four parts of the edge area 4 is in each case formed by overprinting the solid cyan with a scale printing ink. For example, the overlap C + M can be found in the upper left part, C + Y in the upper right and C + S in the right lower part. A special color can be accommodated in the lower left part or the repeat of a scale print color. The examination of the overprints present in the parts of the edge area 4 , possibly with the aid of a magnifying glass, provides information about the ink acceptance and the lying of the second printed ink on the first printed, in this case the cyan printing ink. The ink acceptance is OK if the color of the overprint matches the target color of such a secondary color. The lying of the second printed ink is judged to be good if there are no gross irregularities in the color distribution.

In another exemplary embodiment, not shown in the drawing, the core area 2 of a control field 1 consists of a solid color of the swan printing ink and its edge area 4 consists of the full-area printing of the cyan, magenta and yellow printing inks. In the case of undisturbed color recording, the edge area 4 appears in a neutral black color which comes close to that of the core area 2 . If, on the other hand, the visual comparison of the colors of the core and edge areas reveals marked differences, then the color acceptance of one or more of the printing colors cyan, magenta and yellow is probably disturbed. Of course, it is also possible to swap the color assignment of the core and edge area. It is important for the feasibility of the test described here, however, that the number of layers of printing ink applied in the two areas differs. For example, would one of the three intended printing colors printed for the edge region 4 be omitted and e.g. B. printed on the core area 2 , so no meaningful examination is possible.

In a further exemplary embodiment, also not shown, the core area 2 consists of a gray balance field and its edge area 4 consists of a grid of the printing ink black, the tonal values in both ranges being selected such that the control field 1 is printed as a uniform tone area under normal pressure appears. The interchangeability of the color assignment of the areas also makes sense where the core area 2 then consists of a grid of printing color black and the edge area 4 consists of an overprinting of suitably graded area coverage cyan, magenta and yellow. The tonal values in both areas are chosen so that the control field 1 appears under normal pressure as a visually uniform tone surface. Here, too, it is essential that the number of layers of printing ink applied in both areas be different.

In Fig. 5, an advantageous embodiment of the invention is shown, in which at least four of the present invention con troll panels 1 with their identically printed edge portions 4 or parts thereof abut each other directly. This results from the abutting of four equally printed parts of Randbe range 4 a larger, uniformly printed area, the visual assessment of which is easier and safer than is the case with a single control field 1 .

For the person skilled in the art, it is readily possible within the scope of the invention to technically implement the described configurations of the various arrangements of control fields in the various printing processes. There are several ways to do this. In the way of film who reproduced the parts to be printed with a certain printing ink in an arrangement of control fields 1 as blackened areas of the color separation film in question and then transferred in the positive process to the blank provided for printing with the printing ink in question. If the printing form is produced in the negative process, a film must be used which represents the negative of the first-mentioned film. With the printing forms thus produced for multicolor printing, the printing medium, also called printing material, is successively printed with the associated printing inks using the respective printing forms. However, the production of the printing forms can also take place without prior production of color separation films, e.g. B. in a Vorrich device in which the printing form is exposed with the aid of a laser exposure. The exposure is controlled by an electronic computer program that contains the information about the arrangement of several control fields to be printed. In this case, the information on the structure of the arrangement must be available in digital form. A suitable data record can be produced, for example, using the FreeHand program from Aldus or directly using a page description language such as the Adobe PostScript programming language. The data can e.g. B. be organized as a CMYK file in TIFF (Tag Image File Format) format or in their data formats that allow printing-related information.

The printing forms can also be made by other filmless ar processing methods with an arrangement of several Control fields are illustrated. It is possible to print gravure forms and flex printing forms through program-controlled To manufacture laser ablation. The generation of the color guides The cell on a gravure cylinder can also be used an electronically controlled engraving.

Finally, with some test printing processes it is possible to print without a printing form. In the process working from film, the color separation films with previously described color separations of the arrangements of the control fields 1 are each used by an exposure process for printing ink in the form of toner particles or a layer detached from a color film on the printing substrate, in accordance with the blackening present on the film transfer. In the filmless process that works directly from the data set, the printing color is computer-controlled, e.g. B. in the form of ink jet ink, thermal transfer printing mass or thermal sublimation dye transfer one after the other on the printing medium. The application of these arrangements, ie the application of the control strips 5 or control blocks 6 , with their control fields 1 , however, is analogous to that by printing with printing presses of conventional design generated arrangements possible. Here, too, the printing shows the core areas 2 and the edge areas 4 with a different number of printing inks, advantageous testing options while at the same time saving space.

Claims (10)

1. Arrangement of several control fields for control and / or control of multicolor printing, with at least one control field at least partially at least partially at least two different printing inks are printed on top of one another, characterized in that the control field is richly provided with at least one core area and at least one edge area which have a different number of superimposed printing inks, the core area being designed for measurement with a reflectometer and the edge area for visual comparison with the core area. 2. Arrangement according to claim 1, characterized in that the one area (core area 2 ; edge area 4 ) with a single printing ink and the other loading area (edge area 4 ; core area 2 ) is printed with a plurality of printing inks. 3. Arrangement according to claim 2, characterized in that the one area (core area 2 ) from the full tone of an ink (A) and the other area (edge area 4 ) from the overprint of the full tones of the inks (A) and (B ) consists. 4. Arrangement according to claim 2, characterized in that the two areas are formed by a core area ( 2 ) and one in several parts ( 4 a, 4 b, 4 c, 4 d) glazed edge area ( 4 ), the Core area ( 2 ) is generated from the full tone of a printing ink (A) and each part of the edge area 4 consists of the overprinting of the full tone of the printing ink (A), each with a full tone of one of several other printing inks. 5. Arrangement according to claim 3, characterized in that the control field ( 1 ) is formed so that the printing inks (A) and (B) are the scale printing colors black and yellow or yellow and black. 6. Arrangement according to claim 4, characterized net that the printing ink (A) the scale printing ink Is black and the other inks are the three buns scale inks cyan, magenta and yellow conclude. 7. Arrangement according to claim 2, characterized in that the control field is formed so that the one area (core area 2 ; edge area 4 ) as a gray balance field and the other area (edge area 4 ; Kernbe area 2 ) as a monochrome, black grid field Det is, the area coverage of the participating printing inks in both areas are selected so that the control field ( 1 ) appears as a uniform tone at normal pressure. 8. Arrangement according to one of the preceding claims, characterized in that at least two control fields, each with the same printed area (edge area 4 ) are arranged directly next to each other. 9. Arrangement according to claim 8, characterized in that the areas printed in the same way (edge area 4 ) consist of the overprint of the full tones of the printing inks (A) and (B) and the other areas (core areas 2 ) of a control fields with the printing ink (A) and the other control field with the printing ink (B). 10. Arrangement according to one of the preceding claims, wherein the control field is square, characterized in that the two areas are formed by a centrally provided core area ( 2 ) and an at least partially delimiting edge area ( 4 ), the edge area ( 4 ) consists of four triangular parts ( 4 a, 4 b, 4 c, 4 d) arranged in the corners of the control field.