DE3628198A1 - Multicolour raster printed product and method and device for its manufacture - Google Patents

Abstract

In order reliably to obtain a subtractive colour tone mixture with a given colour tone by printing the individual colour dots (6, 9) on top of one another, even in the case of tolerance errors (so-called register errors), at least one colour dot (6) is distributed within its raster zone (3) whilst maintaining the saturation within said raster zone (3) so that the individual colour spots (6') thus produced each have a different saturation on the multicolour raster printed product. Alternatively or additionally, a plurality of raster dots of the same colour can also be provided within one raster zone (3) so that the probability of coverage is increased. To produce such a multicolour raster printed product and to carry out the method, a known device is expediently provided additionally with a cylinder for applying a solvent. <IMAGE>

Description

The invention relates to a halftone color printed product according to the preamble of claim 1, and a method and a device for producing the same according to the generic term fen of claims 2 and 7.

With halftone color printing, at least two colors, in general but mean at least three (e.g. printing black as the fourth "color" already to the state of the art to "depth" reach) one after the other according to a predetermined grid division printed. At least two color dots come in each a grid, the two grid points together the eye Give the impression of a certain mixed color. The mix is with low color saturation an additive, i.e. the color dots are printed side by side in such a way that the eye of the Impression of the mixed color from the addition of both separate colors points. An example of this technique can be found in the CH-PS 5 92 526.

However, other color printing processes are known in which a subtractive color mixture should be obtained that the color dots are printed on top of each other so that to the eye of the beholder one of the total light absorption of both Colors corresponding hue results. Such a process is described approximately in CH-PS 5 98 962. Although such They have processes that lead to a larger range of colors the disadvantage that the grids of the two colors are accurate must be congruent, otherwise the color dots will not on top of each other, but come to lie side by side and themselves so that instead of the desired subtractive color mixture, a - something different - additive results. To avoid this So far, only with increased accuracy of coverage of the two  Color grids were worked out, which was pretty difficult, so uncontrolled color variations were the result.

The invention is based on the object, a screen color to produce printed matter that with a high degree of certainty a sub tractive color mixture, without price increases due to increased Ge accuracy requirements results. This task is solved by the features of the characterizing part of claim 1. Because the Color dots of a color in the individual grid fields below have different saturation, it follows implicitly that for Achieve a predetermined color saturation by the respective area occupied by paint can be enlarged compared to previously got to. However, this can also be done in such a way that several grid points same color can be provided within a grid. In between, mixed solutions are also conceivable.

Such a halftone color print product can by a fiction according procedure with the characteristics of the identification of the contractor Proverb 2 are produced.

Although different to carry out such a procedure Devices would be conceivable, a device is preferred used with the features of claim 12.

Further details of the invention will become apparent from the following description of schematically in the drawing vivid examples. Show it:

Figure 1 three grids with two color dots of different sizes according to the prior art.

Fig. 2, the same grids, but printed by one embodiment according to the invention;

Fig. 3 shows a single grid according to another embodiment according to he invention;

Fig. 4 shows a first embodiment of a device according to the invention, namely for direct printing

Fig. 5 illustrates a preferred variant, namely for indirect printing.

In Fig. 1, three grids 1 , 2 and 3 are provided on a grid. These grid fields 1 to 3 correspond to grid points 4 , 5 and 6 of one color, the saturation of which is indicated by the narrowness of the cross-hatching. The grid fields 1 to 3 are of course shown enlarged many times over, since the side length of each of them actually only occupies about 1 sixth of a millimeter. The saturation of a color within a grid is therefore determined by the area of each of the grid points 4 to 6 . Thus, the saturation within the grid 1 is relatively large because of the relatively large color point 4 , while the grid 2 has a low saturation with only a small color point 5 . In this regard, the grid 3 shows an average saturation value. The distribution of the saturations results from the template to be printed.

Usually three basic colors, namely cyan, magenta and yellow are used to produce a halftone color printer's certificate. For the purposes of the present explanation, it is sufficient to consider two different colors, which in individual cases could be sufficient to produce a specific color mixture. It is assumed here that the mixing ratio of these two colors is 1: 1, so that the respective color dots of both colors should have the same size in each grid. The second color in each grid 1 to 3 is represented by dashed circles 7 , 8 and 9 . Of course, the grid division of these second color points 7 to 9 is the same as that of the first grid. Due to inaccuracies that cannot be avoided, the two grids may shift, for example, by shifting the center lines of the grid fields of both colors by a dimension a in the horizontal direction.

The effect of such an unwanted shifting of the raster fields is shown in FIG. 1: only the largest color dots 4 and 7 will partially overlap, whereas medium and small color dots 6 , 9 and 5 , 8 will be more or less clearly next to each other come, so that a subtractive color mixture does not arise, but in this case a completely unintentional additive color mixture. This would mean that the color reproduction or the color saturation gets out of control.

If one takes the hue of points 7 to 9 as given, a remedy may be in a method illustrated in FIG. 2. For point 4 (cf. FIG. 1), a considerably tighter grid with a distance between the center lines b is used , a multiple of this distance b corresponding to the mass of a grid 1 to 3 . Thus, as shown in FIG. 2, for point 4 a ver one third smaller grid is used, there are four correspondingly smaller points 4 a to 4 d in a grid field 1 instead of a single point 4 . However, since according to the area formula the area grows with the square of the radius, instead of the one color point 4 according to FIG. 1, there are four color points each with only half the radius of the color point 4 .

Even if the color point 7 is offset by the dimension a from the rest of the grid exactly as in the case of FIG. 1, it can be clearly seen from the grid fields 1 to 3 of FIG. 2 that the probability of an overlap of the color points and thus one better color mixture has already become much larger. Since the area of the color points 4 a to 4 d corresponds to the area of the color point 4 ( FIG. 1), the saturation of the corresponding color within the grid 1 has remained the same despite the distribution of the color points 4 a to 4 d . Based on the density of the hatching of these color points 4 a to 4 d , it can also be seen that the same standard color as for the color point 4 of FIG. 1 can be used. It is understood that the probability of overlapping the colors increases even more if the color dots 7 to 9 are resolved or distributed in a similar manner.

The reduction of the grid from the division of the grid 1 (or 2 or 3 ) to a grid size b cannot, however, be carried out in all cases, most likely with a rough division of the grid 1 to 3 . FIG. 3 is now another way of distribution shows a color within a grid 3 while maintaining the saturation within the grid 3. If the color point 6 belonging to the grid 3 is treated with a solvent, it will be more or less distributed over the grid 3 . It results from a relatively large color spot 6 ', the saturation of which corresponds to the amount of color entered with the color point 6 , ie the color spot 6 ' will be significantly more unsaturated than about the color point 6 in Fig. 1 (as from the further hatching of the Color spots 6 'can be seen), where at the edge and in the middle if necessary saturation differences arise. These differences in saturation do not interfere because of the small size of each grid, but can be avoided more easily if the solvent is not applied to the substrate only after the application of the color point 6 , but earlier. In this case, the printing material (in general paper) is already slightly damp and absorbs the color of the color point 6 while being distributed within the grid 3 .

The limitation of the color patch 6 'on the grid 3 can be obtained more easily that the solvent is applied to the grid 3 only in the size of the color patch 6 , so that the solvent is distributed inside the grid 3 from the inside out. Theoretically, it would be possible to treat the entire printing material evenly with solvent, but there is then a certain risk that the color point 6 entered in each case will spread out into the neighboring field, so that somewhat more blurred contours result (which is particularly important to achieve Effects may also be desirable).

From what has been said above it already follows that it should be preferred must, the solvent unevenly over the substrate distribute, especially omitting where there is no color anyway points are provided. As a rule, this is appropriate to be made with its own printing form for the solvent leagues, this printing form then (in the case of a high Druckes) will have surveys in all those grid areas where only one of the colors should have a halftone dot. In many printed products, especially when printing Photogra phien and other images, but is little in each grid at least one fine color dot printed.

Experiments have shown that it is expedient to choose the amount of solvent as a function of the amount of color entered in the respective grid, preferably complementary to the amount of all colors entered in this grid. In this case, the sum of all the color components duty unpaid Lich the amount of the solvent - in the ideal case - provide a substantially constant size. This can be achieved by producing a printing form for the solvent which is analogous to the printing forms for the individual colors (for which a color separation is produced). This will result in the greatest amount of solvent in those grids where little color is added.

FIG. 3 illustrates the result of such a method with the aid of a further raster field 32 with a color point 33 that is substantially larger in comparison to color point 6 of raster field 3 or also to color point 4 of FIG. 1. While now in the case of the color dots 6 and 9, which are significantly smaller than the color dots 33, a complementary (and thus relatively large) amount of solvent was added, which allowed distribution over a large part of the grid 3 , in the case of a large raster dot 33 (which already fills most of the grid 32 ) only added an amount of solvent that corresponds approximately to a cross-dashed circle 34 . From this point 34 , the solvent is then distributed on the respective printing substrate, as indicated by different shading of the point 33 . The result is therefore a printed product, the individual color points of which will have different saturation.

In Fig. 3, the color point 9 is also entered into the grid 3. For the purpose of comparison, the color point 9 has the same shift by the distance a as in Fig. 1. It is obvious that in this way a subtractive one Color mixture occurs, but it should be mentioned that the color point 9 is only maintained the size shown if a rapidly volatile solvent is used and / or between the printing of the color point 6 and that of the color point 9 a period of time which is sufficient, let the solvent evaporate. In this case, the color point 9 would have to be treated separately with a solvent if a similar distribution would be sought as in the case of the color point 6 . However, this would not necessarily give a favorable effect, because if the color point 9 is shifted relative to the color point 6, there would also be a risk of inaccuracy in the second imprint of a solvent. It is therefore preferred if we print the solvent together for at least two colors, ie that the solvent is chosen in this way, or the time span between the printing of the color point 6 and that of the color point 9 is so short that the Solvent is also effective for the color point 9 and this is thus also distributed over the area of the color spot 6 '. This has the additional advantage that this results in a certain correction of the grid offset by the distance a (see FIG. 1).

A halftone color print product thus produced will, as already mentioned, have halftone fields in which the color spots 6 'have different saturation depending on the size of the respective color point 6 , although a standard color with a given saturation is used. While for printing each individual color the respective printing form corresponds to the respective color separation, the printing form for the solvent preferably has screen dots in all those grid fields in which only one of the colors used should have a screen dot.

This can be clearly seen from FIG. 4, in which three printing form cylinders 11 , 12 , 13 a printing cylinder 14 are arranged along the surface. The printing plates 15 to 17 located on the cylinders 11 to 13 are shown with relatively few elevations 18 distributed over their circumference, as will be the case with a high-pressure process.

As can be seen, the pressure cylinder 14 rotates in the clockwise direction, and another cylinder 19 is - seen in this direction of movement according to an arrow 20 - preferably in front of the printing form cylinders 11 to 13 . The attached to the other cylinder 19 printing form 21 has - compared to the number of elevations 18 of the printing form 15 to 17 - a larger number of elevations 18 '. Each of the cylinders 11 to 13 and 19 , on the one hand, inking cylinders 22 and, on the other hand, an analogue solvent application cylinder 23 are assigned, which, in a known manner, uniformly apply the respective liquid from a paint container 24 or from a solvent container 25 to the printing forms 15 to 17 or Apply 21 .

A printing material 26 , generally paper, is fed via a feed guide 27 to the printing cylinder 14 , the cylinders 19 and 11 to 13 being distributed over the circumference of the printing cylinder 14 in such a way that their grid fields come to lie exactly one above the other on the printing material 26 , wherein any tolerances in the manner discussed above with reference to FIGS . 2 and 3 are compensated for with the help of the application cylinder 19 for the solvent. The solvent is chosen so that the speed in the direction of arrow 20 is such that the solvent applied by the cylinder of 19 has not yet evaporated when the printing material 26 has reached the last printing form cylinder. In general, as mentioned, each of the printing form cylinders 11 to 13 will be assigned one of the commonly used colors cyan, magenta and yellow. At the end of the printing cylinder 14 , the printing material is placed on a storage surface 28 , from which it is either removed in a known manner or conveyed on.

Fig. 5 shows a particularly suitable for carrying out the inventive method, apparatus, in the same parts having equivalent function carry reference numerals as in Fig. 4, while only parts of similar function have an added hundreds digit.

As in the embodiment according to FIG. 4, the printing plate cylinders 11 to 13, indicated only as circles, are arranged around a printing cylinder 114 . This printing cylinder 114 rotates clockwise in accordance with arrows 29 and works together with an impression cylinder 30 , between which cylinders the printing material 26 passes. In itself, as already explained with reference to FIG. 3, it would be conceivable to use a cylinder 31 for applying the solvent, but it is again preferred if the solvent cylinder 19 (seen in the direction of movement according to arrow 29 ) in front of the printing form cylinders 11 , 12 and 13 for the individual colors cyan, magenta and yellow. The cylinder 31 can be formed analogously to the Druckformzylin countries 11 to 13 and serve to apply a fourth "color", namely black, as is proposed, for example, in US Pat. No. 4,062,688. Accordingly, an inking cylinder 22 and a corresponding ink tank 24 are also assigned to it.

The arrangement according to FIG. 5 differs from that according to FIG. 4 essentially in that it is an indirect printing process, ie the individual printing form cylinders 11 to 13, 19 and 31 do not directly print on the printing material 26 . Rather, the pressure cylinder 114 has an at least wettable, possibly also absorbent surface, that is, for example, it is provided with a surface layer made of nonwoven material. Its diameter is expediently chosen so that the halftone dots of each printing form cylinder 11 to 13 , 19 and 31 always return to the same place, ie the circumference of the printing cylinder 114 should be an integral multiple of the circumference of these printing form cylinders. In this way, it is avoided that with each revolution of the printing cylinder 114 any ink residues from the previous circulation are printed, which ink residues would otherwise have to be removed with the aid of a cleaning cylinder. By using an indirect printing method, as illustrated with reference to FIG. 5 the colors will lie even better on top of each other and distributed in the individual grid fields, so that the desired subtractive color mixture becomes even more pronounced.

Numerous variants are conceivable within the scope of the invention. So the expression "solvent" should be used in the broadest sense stand around, namely by the mere application of heat can grasp if, for example, the individual color particles within a Are dispersed thermoplastic, which after the Apply more over a grid by exposure to heat can be distributed. Thus, the invention is suitable Processes for electrostatic and other printing processes.

It is understood that the respective cylinder 23 and the associated container 25 can be omitted if the solvent is to be distributed evenly on the printing material, the cylinder 19 and the printing plate 21 being replaced by a mere application cylinder, to which the solvent is inside or is fed outside in any way.

Claims (15)

1. halftone color print product with a divided into a plurality of halftone image area of an image on a printing material, in which halftone fields are printed at least two halftone dots of different color, characterized in that the halftone dots ( 6 ') of a color in the individual halftone fields within the image ( 1-3 ) have different saturation and / or several halftone dots ( 4 a - 4 d ) of the same color are provided. 2. A method for producing a halftone color print according to claim 1, in which at least two colors are successively printed dot by dot into the individual image fields of a raster in accordance with an image to be displayed, characterized in that to achieve a subtractive color mixture by overlapping halftone dots ( 4 , 7 or 5 , 8 or 6 , 9 ) the area of at least one color is distributed over the grid ( 1-3 ), but the color saturation per unit area is reduced to such an extent that the saturation of this color per grid ( 1 -3 ) is maintained. 3. The method according to claim 2, characterized in that at least one color is printed on the printing material ( 26 ) and then on the printing material ( 26 ) over most of a grid of the ( 1-3 ), in particular over the entire grid ( 1- 3 ), is divided. 4. The method according to claim 3, characterized in that a raster image of at least one color is printed in succession in a selected order and another time a solvent is carried over the surface of the respective raster field ( 1-3 ). 5. The method according to claim 4, characterized in that the solvent is applied before the colors. 6. The method according to claim 4 or 5, characterized in that the solvent is unevenly applied to the substrate will wear, for example, have only one color point the grids. 7. The method according to claim 6, characterized in that the solvent is applied with the aid of a corresponding printing form ( 21 ). 8. The method according to claim 6 or 7, characterized in that the amount of solvent applied per grid in Depends on the amount of paint applied there becomes. 9. The method according to claim 8, characterized in that the amount of solvent applied per grid to the Amount of the color applied there is so complementary that the sum of all the amounts of paint together with the amount of Solvent forms a substantially constant size. 10. The method according to any one of claims 2 to 9, characterized ge indicates that the area corresponds to at least two colors accordingly enlarged and the colors decreased in their saturation and that this is preferably with all the colors used is carried out. 11. The method according to claims 3 and 10, characterized records that at least two colors are printed and shared by applying solvent, especially before printing of colors. 12. An apparatus for performing the method according to any one of claims 2 to 11, with at least two printing form cylinders for receiving a printing form corresponding to a color separation, to which at least one inking cylinder is assigned, through which ink can be transferred from a color reservoir to the printing form cylinder, characterized that in addition to the inking cylinders ( 11-13 or 31 ) at least one further cylinder ( 19 ) is provided for applying a solvent. 13. The apparatus according to claim 12, characterized in that the further, preferably as a printing form cylinder for receiving me a pressure plate ( 21 ) corresponding printing form ( 21 ) formed cylinder ( 19 ), a solvent application cylinder ( 23 ) for transfer is assigned to the solvent from a solvent container ( 25 ). 14. The apparatus according to claim 12 or 13, characterized in that the printing form cylinder ( 11-13 , 31 ) and the solvent supplying further cylinder ( 19 ) - for the implementation of an indirect pressure - on a cylinder ( 114 ) with be wettable or absorbent surface, optionally with a fleece covering, via which the image to be generated can be transferred to the printing material ( 26 ). 15. The device according to one of claims 12 to 14, characterized in that the solvent-applying further cylinder ( 19 ) - seen in the direction of movement ( 20 or 29 ) of the loading material ( 26 ) - in front of the printing form cylinders ( 11-13 or 31 ) is arranged.