EP0906193A1

EP0906193A1 - Process for producing dies

Info

Publication number: EP0906193A1
Application number: EP97928209A
Authority: EP
Inventors: Wittich Kaule; Karlheinz Mayer
Original assignee: Giesecke and Devrient GmbH
Current assignee: Giesecke and Devrient GmbH
Priority date: 1996-06-17
Filing date: 1997-06-16
Publication date: 1999-04-07
Anticipated expiration: 2017-06-16
Also published as: US6840721B2; EP0906193B1; AU3259297A; PL330529A1; ATE206356T1; UA46854C2; CA2258663C; DE19624131A1; DE59704798D1; PL186295B1; ZA975252B; CA2258663A1; AR007596A1; US20010043842A1; JP2000512231A; RU2183558C2; ES2165066T3; PT906193E; WO1997048555A1; BG64251B1

Abstract

The description relates to a process for producing dies, especially of deep-drawn steel. Here, a surface component is obtained from a line drawing, where the edge of the surface component defines a nomimal outline (9). From the nominal outline and a nominal depth allocated to the surface component, a tool path (12, 17, 18, 19, 20) is then calculated by means of which an engraving tool is guided in such a way that the partial surface is removed.

Description

Process for the production of embossing plates

The invention relates to a method for producing embossed plates, in particular steel gravure plates, according to the preamble of claim 1.

For the production of embossing plates, in particular steel intaglio printing plates, as are usually used in the printing of high-quality printed products such as securities, banknotes or the like, it has hitherto been used to have the embossing plates produced by an artist in a complex process. In this case, an image motif available to the artist is converted into a line pattern, with differently wide, deep and different numbers of lines per area representing the gray levels of the original image. With the help of a stylus, the artist inserts this motif into the metal plate, such as steel or copper, in time-consuming manual work. The plates produced in this way are characterized by their high quality with regard to their use in gravure printing. However, the possibilities of correction for the artist when manufacturing the plate are extremely small. If this original plate is damaged or lost, an identical plate cannot be produced, since each plate is individually made.

It is also known to mechanically engrave a printing cylinder. As described, for example, in EP 0 076 868 B1, wells are introduced into the printing form which, depending on their raster width and engraving depth, represent the gray value of a printing original. Luminous tones and tonal value-dependent changes in the print template are generated by changing the focus value of the electron beam in the printing form, whereby different cells can be formed in their volume. From DE 3008 176 C2 it is also known to use a laser to engrave a printing cylinder. A template is scanned and the resulting signal is used via an analog-digital converter to control the laser, with which engraved cells of defined depth and extension are introduced into the printing cylinder.

With the decomposition of the original into gray values and its implementation on the printing plate by means of cups, however, the essential components required for gravure printing are lost, since with the aid of this technique only color can be transferred to the printing medium point by point. However, the steel gravure is characterized by the fact that a continuous line print pattern, which can be felt with the application of ink, is transferred to the print carrier, which is characterized in particular by its filigree lines.

The object of the invention is accordingly to propose a method with which a simple and automated production of embossing plates, in particular steel intaglio printing plates, is possible.

This object is achieved by the characterizing features of claim 1.

The invention is based on the knowledge that it is possible to treat a two-dimensional line template graphically in such a way that the present lines are interpreted as surfaces. These areas are each delimited by edges, these edges defining a desired structure of the area. Starting from this target structure, a tool path is now determined, along which an engraving tool can be guided so that material is removed within the area which is delimited by the target contour. The engraving tool is controlled so that the material within the target contour is removed in the form of continuous or broken lines in a certain depth profile. This depth profile can be determined by a constant or variable depth value within the target contour.

A data processing system is preferably used in the method according to the invention, with the aid of which it is possible to record, save and further process two-dimensional line templates. The two-dimensional line template, which is generated, for example, in a computer or read in via input devices, can be processed further with the aid of a suitable computer program in such a way that data for controlling an engraving tool are available along a tool path. For this purpose, a surface element is defined in a first work step from the two-dimensional line template, which consists, for example, in a single line of the line template. The edge surrounding the line then defines a target contour that is free of crossings. To produce the engraving, a depth profile is assigned to the interior of the surface element as the target depth for the engraving and then a tool path is calculated from the target contour data and the assigned target depth, along which the engraving tool is guided and removes material within the surface element.

This procedure is then repeated for each individual surface element to be engraved, so that a tool path of the engraving tool for the entire surface to be engraved, which is composed of the sum of the individual surface elements to be engraved, can be determined.

With the help of this method, the speed for producing the embossing plate can be increased considerably. There are also errors Ren excluded by the exact guidance of the engraving tool, so that a variety of stamping plates can be produced with the same accuracy. The method also offers simple correction options by changing the line drawing data. The exact reproducibility of the engraving to be introduced also means that printing plates can also be produced directly without having to resort to a galvanic impression process. Several engraving tools can also engrave several plates at the same time. In addition, several optionally different engraving tools can be controlled so that they process a plate at the same time, so that the processing time is optimized.

Further advantages and advantageous designs are explained with reference to the following figures, in which the representation has been omitted to scale in the interests of clarity. The individual shows:

1 shows a schematic overview of the method according to the invention,

2 shows a schematic example of the method according to the invention,

3 shows a schematic example of the method according to the invention,

4 shows a schematic example of the method according to the invention,

5 shows a schematic example of the method according to the invention,

6 shows a schematic cross section through an embossing plate, 7/48555 PC17EP97 / 03120

7 shows a schematic example of the method according to the invention,

8 shows a schematic example of a tool path,

9 schematically shows two tool tip shapes,

10 shows a schematic cross section through an embossing plate,

11 shows a schematic cross section through an embossing plate.

As shown in FIG. 1, the method according to the invention is based on a two-dimensional line template 1, which consists of a simple black line 2 on a light background 3 to represent the principle according to the invention. The template z. B. is available on paper, can be digitally recorded in a computer with the aid of a scanner or other suitable data input means. As an alternative to this, it is also possible to create the line template directly on the computer interactively, for example with the aid of a drawing or graphics program, or to have computer-generated graphic data generated by mathematical algorithms. With the latter template design, for example, guilloche lines or other graphic elements could be generated with the aid of implemented programs, the interactive input or specification of data is just as possible as the calculation of the structures with the aid of random algorithms. In a second method step, line template 1 defines a surface, for example surface 4, that represents a partial surface of the plate. A target contour 5 is defined by the edge of this surface and serves as the first of two elements as the starting point for the later calculation of a tool path along which the embossing plate is engraved shall be. As a second element for the calculation of the tool path, the assignment of a depth profile within the target contour is required, which is referred to as a so-called target depth. This can, for example, be specified constantly for the entire engraving. It can also depend on the shape of the engraving tool used. From the target depth 6 and the target contour 5, a tool path 10 lying within the surface 4 is then calculated, along which the engraving tool must be moved so that the engraving corresponding to the line drawing can be introduced into the embossing plate. Since different engraving tools can be used to engrave the plate, it is clear that data of the respective engraving tool are also included in the calculation of the tool path. For example, when using a laser beam, the width of the beam which acts on the embossing plate can be included in the calculation. When using a mechanical stylus, the stylus shape and here in particular the shape of the tip or its radius of curvature are of essential importance when calculating the tool path.

Following the determination of the tool path, the engraving tool is controlled in such a way that it moves within the area 4, does not violate the desired contour 5 during engraving and removes the area 4 at the predetermined desired depth 6.

In a specific embodiment, which is shown in FIG. 2, the number “7” is generated as a line template on a sheet of paper and read into a computer with the aid of a scanner. The number “7” exists, as in FIG. 2a shown from lines 7. Using the procedure described above, as shown in FIG. 2 (b), 7 areas 8 are defined from the present lines, the edges of which form the desired contours 9. These serve as Starting point for the calculation of a tool path. By assigning a constant target depth in this case, taking into account the respective tool data, tool paths 10, 11 and 12 can be determined along which the engraving tool is controlled over the embossing plate, so that the line drawing is transferred into the embossing plate can be. These tool paths are exemplarily shown in Fig. 2 (c). The tool paths 10, 11 and 12 are preferably determined in such a way that the tool is guided along the desired contours 9 within the surfaces 8 without thereby violating the desired contours.

Since the width of the material removed with the engraving tool is limited, the line drawings can be used to define surface elements with a size that can no longer be removed completely if the engraving tool is only guided along the desired contour lines. A very simple form of the line drawing is shown as an example in FIG. 3. A line element 8, which has a contour line 9, is defined by the line drawing in FIG. 3 (a). If the tool path 13, as shown in FIG. 3 (b), is now calculated on the basis of this predetermined data, then depending on the dimensioning of the surface 8 and the shape of the engraving tool, the engraving tool can remove the surface to be removed during one revolution not completely removed.

For a rotating 14 stylus, these relationships are shown in perspective in FIG. 4. The stylus 14 rotates about its own axis z and, after penetrating into the embossing plate 15, removes material from the embossing plate along the tool path 13 at a predetermined depth. By guiding the rotating stylus 14 along the tool path 13, the target contour line 9 remains unharmed. Because of the limited width of the stylus, however, a residual surface 16 of the surface 8 to be removed can be in one revolution of the Engraving tool can not be removed. Only in a further work step can the remaining surface 16 be removed with the aid of a second predetermined tool path, which can differ in shape from the first tool path 13.

As can be seen in FIG. 5 (a), it is necessary in this case to also take into account the residual surface 16 that cannot be removed in the first step when calculating the tool path for removing the surface 8. When removing the remaining surface 16, different tool paths can be determined, depending on the desired engraving results. Thus, as shown in FIG. 5 (b), the tool path can initially run along the desired contour and the remaining surface 16 can then be removed in a meandering manner, the engraving tool continuously removing the remaining surface within the surface 16 in a meandering path 17. 5 (c) shows a further possibility, wherein the remaining surface 16 is removed by guiding the engraving tool along tool paths which are similar to the first calculated tool path 12 in the mathematical sense, i. H. that the tool paths 18, 19 and 20 correspond in shape to the tool path 12 but have a different dimension than the tool path 12. In particular in the case of curved contour lines, the remaining surface 16 can be removed accordingly with the aid of tool paths which run parallel to the contour, ie that have the same distance to the contour line in every point.

As can be seen in a cross section through an embossing plate 15 in FIG. 6 (a), a tool path was calculated from the contour line 9, along which the engraving tool was guided and an engraving line 28 was generated which includes a remaining surface 16 which is still to be engraved . When removing the remaining surface 16, any one, but preferably one of the ones, can already be removed procedures described above can be applied. Regardless of the respective method, a defined roughness structure is generated at the base of the engraving of the remaining surface, which is determined by the offset and the shape of the engraving tool. Such a roughness structure is shown in FIG. 6 (b), wherein a pointed, rotating gravers was used during the engraving, with which the embossing plate was removed at a defined depth T. The stylus used had a diameter D at the exit surface from the embossing plate and was displaced inward by the amount ^d / ₂ when the remaining surface was removed, while the offset in the example ³ Λ d shown in FIG. 6 (c) is. In both examples, the engraving tool was moved in accordance with the tool paths shown in FIG. 5 (c).

The surface structuring described at the base of the embossing has several advantages in the production of steel gravure plates. Because with the use of steel intaglio printing plates, only limited line widths have so far been printable, which is due to the fact that the steel intaglio printing ink can only be introduced into engravings of the plate which have a certain maximum width. However, this obstacle is eliminated by the newly proposed engraving, since the roughness can now be set as a basic pattern at the base of the engraving, which can serve as a color catcher for a steel intaglio printing ink. This color can thus also be held in very wide engraving lines, so that it is now possible for the first time to also print wide lines using the steel gravure printing process. As shown in Figs. 6 (b) and 6 (c), the roughness of the bottom can be controlled by the size of the offset of the engraving tool. Since different offset widths of the stylus can also be taken into account when calculating the tool path, the roughness can be designed differently in different areas of the remaining surface and thus can be superimposed with an engraving line or surface with an additional modulation of the roughness of the basic pattern, so that it is also possible to introduce further information into an engraving line solely by the specific production of the roughness of the basic pattern.

Since glazing colors are usually used in steel engraving, the different engravings in a line on the document to be printed can be used to correspondingly produce a different color impression within a line. This impression of color can be further improved in particular if the engraving which has already been created is provided with a second engraving in a further method step, the desired depth of which has a different definition than that of the first engraving. An example is shown in FIG. 7 (a) in which there is a line drawing 18 which has lines 19. The lines 19 are delimited by target contour lines 20. Surfaces 21 lie within the lines 19, which in turn are delimited by second nominal contour lines 22. This line template is in turn introduced as a digital data image into a computer or generated directly in this. As shown in a detail in FIG. 8, a tool path 23 is calculated from the contour lines 20 together with a target depth which is in this case fixedly predetermined, along which a first engraving takes place. Any remaining area that has remained is, as already described above, removed in a predetermined target depth. The surface 21 lying within the line drawing 19 is converted in the same way into a tool path 24, the contour of the surface 21 and a second desired depth which is different from the first being included in the determination of the tool path as the basis for the implementation. In this way, engravings can be produced which also contain additional information about a larger area, which can also be transferred to the document when the steel intaglio printing method is used. The tapered edges of the line drawing 19 can be represented exactly by a suitable choice of the stylus shape. It is possible to use a single fine stylus for the engraving or, after engraving the surface with a coarse stylus, to rework the tapered edges with a fine stylus. As an alternative to this possibility, the depth profile can also be adapted to the requirements of the surface 19 to be engraved. In this case, the depth profile is specified so that the engraving tool removes less material at the tapered edges, so that especially when using a rotating mechanical stylus, the stylus always comes out of the material to be processed and, due to its conical shape, the removed material Line becomes narrower. These two techniques can also be used for the exact engraving of corners or edges

When determining the tool path, a determined target contour is generally combined with an engraving depth profile in accordance with the method according to the invention, so that a tool path is determined from these two data, along which the engraving tool is guided, so that the material accordingly the line drawing can be removed in the depth corresponding to the depth profile. The depth profile, that is to say the target depth, can be specified as a constant for each individual engraving line or for the engraving as a whole. Likewise, target depths for individual engraving lines or parts of engraving lines can be different, so that the respective tool path is modulated accordingly. In addition, it is also possible to use different engraving tools of the same or different types in successive process steps in order to produce the desired engraving result. When using rotating mechanical styluses, it is particularly advantageous to use different stylus tips. zen, shapes and sizes to use, so that optimal embossing plates can be produced in this way.

With the manufacture and use of different stylus shapes and sizes, the embossing result can be influenced in a variety of ways. This is because the shape and size of the embossing tool, depending on the depth of penetration of the engraving tool into the plate, determine the shape of the engraved cross-sectional area produced therewith. 9 shows two examples of possible cross-sectional areas of stylus tips. 9a the stylus tip is shaped such that the cutting line 28 of the conical surface forms an angle of 45 ° to the rotational symmetry axis S of the engraving tool. As a result, when the plate is engraved with this tool, an engraving path is created, the side walls of which likewise run towards the base of the engraving at an angle of 45 °. From this example it can be seen that the production of engraving tools with different angles can produce different wall inclinations in the engraving plate. In addition to the slope of the wall, the shape of the engraving tool can also be used to influence the shape of the wall. For this purpose, the cross-sectional line 29 of a rotationally symmetrical engraving tip is shown in FIG. 9b, with the aid of which different degrees of angle of the engraving walls can be produced at different engraving depths. From these two examples it can be seen that the use of different engraving tools has a considerable influence on the desired engraving result or that optimal results can be achieved with the aid of specially manufactured engraving tools or engraving tool tips for a specific line template. In particular, it is possible to manufacture the engraving tools in their angulation and shape in such a way that even very fine surfaces to be engraved can be removed, with the tool path along which the engraving tool is guided being only once within the surface to be removed in the case of fine lines is guided along the predetermined line. Due to the special shape of the engraving tool, the material within the target contour is removed by a single working path of the engraving stylus. In these cases, the tool path can also run along a center line that lies between two nominal contour lines and is at the same distance from both. With a given depth profile, a suitable stylus shape must then be selected.

The method according to the invention offers the decisive advantage that the engraving can be carried out exactly with exact lines even with extremely small engraving areas or lines. The target depths that can be achieved in the method according to the invention are preferably between 10 and 150 μm, the target depths also being able to be predetermined by different gray values of the line template.

If the template is formed, for example, from a uniform line pattern, for example a guilloche, then by varying the line depth, line width, line density or the contour according to the method described above, visible information, such as a portrait, can be introduced. Instead of the visually recognizable information, however, another, e.g. B. bring machine-readable information in this way.

Although the use of different engraving tools already offers a wealth of options for introducing defined roughness structures at the base of the engraving or additional information, which in the present case can be referred to as micro-engravings, into the embossing plate, the method according to the invention can of course also be used ¬ be applied to the flanks of the engraving along the target contours modify. An example of this is shown in FIG. 10, an engraving being introduced into an embossing plate 15, which in the present case consists of a flank 28 and an engraving 29 lying on the bottom. In an additional operation, additional information in the form of so-called sub- or microstructure lines 30 was introduced into the flank 28. The flank of the engraving line can thus be provided with an additional information content which can consist, for example, of simple lines, a staircase function, characters, patterns, images or the like. In particular in the case of gently sloping edges 28, it is therefore possible to introduce additional information into the flank of an engraving line which runs downward from the target contour line 26.

Of course, the method according to the invention can also be used if a negative image of the line template is to be generated. As shown in FIG. 11, the calculation of the tool path already described can also be carried out if there is a further surface area 25 within the surface to be removed, which area is to be removed from the removal. The tool path is preferably calculated so that the engraving tool is the workpiece, i. H. So the stamping plate, in a first step, moves so that the stamping plate is removed along the desired contour line 26. In a further step, the engraving tool is guided along the second target contour 27, while any remaining surface that may still exist between the target contours 26 and 27 is cleared out, as already described above.

Claims

Patent claims

1. A process for the production of embossing plates, in particular steel gravure printing plates, which have at least one depression in the form of a line which is introduced into the surface of the embossing plate, characterized in that at least one partial area of the surface delimited by lines is defined, the edge of the at least one partial area defining a target contour and a tool path is determined from the target contour and a target depth determining the penetration depth of the engraving tool, which lies within the target contour and along which an engraving tool is controlled so that the material of the partial surface is removed within the target contour at the predetermined target depth.

2. The method according to claim 1, characterized in that at least part of the tool path runs parallel to the contour of the target contour.

3. The method according to claim 1 or 2, characterized in that the target contour is free of crossings.

4. The method according to any one of claims 1 to 3, characterized in that the target depth is variable within the tool path.

5. The method according to any one of claims 1 to 3, characterized in that the target depth is constant within the tool path.

6. The method according to any one of claims 1 to 5, characterized in that the material is removed along the tool path within the target contour by a single working path of the engraving stylus.

7. The method according to any one of claims 1 to 6, characterized in that a non-engraved residual surface lying within the partial surface is removed along a second tool path.

8. The method according to claim 7, characterized in that the remaining surface is removed in that the engraving tool is controlled so that it removes the surface of the remaining surface in paths that are similar to the target contour or parallel to the contour.

9. The method according to claim 7, characterized in that the remaining surface is removed in that the engraving tool is controlled so that the surface of the remaining surface is meandered.

10. The method according to any one of claims 7 to 9, characterized in that the remaining surface is removed in such a way that a new surface of defined roughness arises.

11. The method according to claim 10, characterized in that the Gra¬ four tool is controlled so that the roughness is formed in the form of grooves.

12. The method according to any one of claims 1 to 11, characterized in that at least a part of the surface removed at a predetermined depth is further deepened in one or more further engraving steps.

13. The method according to claim 12, characterized in that with the one or more further engraving steps a human-recognizable or machine-readable information is generated.

14. The method according to any one of claims 1 to 13, characterized in that the target contour is defined with the aid of a data processing system.

15. The method according to any one of claims 1 to 14, characterized in that the engraving tool is a laser beam.

16. The method according to any one of claims 1 to 14, characterized in that the engraving tool is a mechanical stylus.

17. The method according to claim 16, characterized in that the mechanical stylus rotates during engraving.

18. The method according to any one of claims 1 to 17, characterized in that engraving tools of different types or dimensions are used in the manufacture of the embossing plate.

19. The method according to claims 1 to 18, characterized in that several plates are engraved simultaneously.

20. The method according to claims 1 to 18, characterized in that a plate is engraved with several engraving tools simultaneously.

21. The method according to claim 12 or 13, characterized in that the at least one further engraving step is carried out with a finer engraving tool than the engraving in the first engraving step.

22. The method according to claim 21, characterized in that the at least one further engraving step is carried out in a flank falling off the desired contour.

23. Engraved object, in particular plate, such as embossing or printing plate, which has at least one depression in the form of a line which is engraved into the surface and has the flanks and a bottom, characterized in that the depression has a substructure whose width is smaller than that of the depression on the surface of the object.

24. Object according to claim 23, characterized in that the substructure is present on the bottom and / or on at least one of the flanks of the depression.

25. Engraved object according to one of claims 23 or 24, characterized in that the substructure extends parallel to the direction of the line at least in partial areas.

26. Object according to one of claims 23 to 25, characterized gekennzeich¬ net that the substructure is meandering.

27. Object according to one of claims 23 to 26, characterized in that the substructure defines a roughness.

28. Engraved object according to one of claims 23 to 27, characterized in that the substructure is introduced in the form of characters, images, patterns or the like.

29. Engraved object according to one of claims 23 to 28, characterized in that the substructure represents machine-readable information.

30. Engraved object according to one of claims 23 to 29, characterized in that the substructure is designed in the form of grooves.

31. Engraved object according to one of claims 23 to 30, characterized in that the substructure is introduced with the aid of a laser beam.

32. Engraved object according to one of claims 23 to 30, characterized in that the substructure is introduced with a mechanical stylus.

33. Use of the engraved object according to one of claims 23 to 32 for the production of embossing or printing plates.

34. Use of the engraved object according to one of claims 23 to 32 for the production of documents such as securities, banknotes, identity cards and the like.