DE19612100B4 - Process for producing a metal gravure form - Google Patents

Abstract

Process for producing a metallic gravure form (1), with the following procedure:
- On the surface of the printing form (1), a thermosensitive, acid and / or electrolyte-resistant coating (2) is applied in a thickness between 2 and 10 microns, with a solvent-based varnish with binders, resins and dyes being used as the coating (2) becomes,
- The coating (2) is removed by means of at least one electronically stored print image and raster data position and power-controlled, thermally active focused laser beam (31) in desired areas (22, 22 ') of the surface (12), in a raster-like manner, the removal in the form of complete raster elements (22) with intervening raster webs (21) and in the form of raster element partial areas (22 '), for which purpose the coating (2) is a color with a color matched to the wavelength (s) of the laser beam (31) Has absorption spectrum,
- In the areas (22, 22 ') of the printing form (1) which are freed from the coating (2), a metal removal is produced by etching or electrolysis to produce fully and ...

Description

• – auf die Oberfläche der Druckform wird eine thermosensitive, säure- und/oder elektrolytbeständige Beschichtung in einer Dicke zwischen 2 und 10 μm aufgebracht, wobei als Beschichtung ein Lack auf Lösemittelbasis mit Bindemitteln, Harzstoffen und Farbstoffen verwendet wird,
• – die Beschichtung wird mittels mindestens eines nach Maßgabe elektronisch gespeicherter Druckbild- und Rasterdaten positions- und leistungsgesteuerten thermisch wirksamen fokussierten Laserstrahls in gewünschten Bereichen der Oberfläche unmittelbar rasterförmig abgetragen, wobei der Abtrag in Form von vollständigen Rasterelementen mit dazwischen verbleibenden Rasterstegen und in Form von Rasterelement-Teilflächen erfolgt, wozu die Beschichtung eine Farbe mit einem an die Wellenlänge(n) des Lasterstrahls angepaßten Absorptionsspektrum aufweist,
• – in den von der Beschichtung befreiten Bereichen der Druckform wird durch Ätzen oder Elektrolyse ein Me tallabtrag zur Erzeugung von voll- und teilflächigen Tiefdruck-Rasternäpfchen vorgenommen und
• – die noch vorhandenen Teile der Beschichtung werden mittels eines chemischen und/oder physikalischen Entfernungsprozesses von der Oberfläche der Druckform entfernt, gemäß Hauptpatent Nr. 195 44 272.

The invention relates to a method for producing a metallic rotogravure form, with the following method steps:

• A thermosensitive, acid and / or electrolyte-resistant coating with a thickness between 2 and 10 μm is applied to the surface of the printing form, a solvent-based varnish with binders, resin materials and dyes being used as the coating,
• - The coating is removed in a grid-like manner in desired areas of the surface by means of at least one electronically stored print image and raster data, position and power-controlled, thermally active focused laser beam, the ablation in the form of complete grid elements with grid webs remaining in between and in the form of grid element Partial areas take place, for which purpose the coating has a color with an absorption spectrum adapted to the wavelength (s) of the laser beam,
• - In the areas of the printing plate freed from the coating, a metal removal is carried out by etching or electrolysis to produce full-area and partial-area gravure wells and
• - The remaining parts of the coating are removed from the surface of the printing form by means of a chemical and / or physical removal process, in accordance with main patent no. 195 44 272.

 The the method mentioned has proven itself in practice. One of his special Advantages are that let him produce gravure forms with which prints with a particularly high contour sharpness and resolution and high light-dark contrasts can be produced and e.g. especially good for suitable for printing small, fine lines with fonts are. In addition, the gravure printing process is also used for the particularly high quality Color printing used in which a smooth transition as possible from dark to light color areas without recognizable levels and without a recognizable grid is desired is. To achieve a transition from dark to light color areas it is necessary to change the volume the rotogravure cup, that transmit the color of reduce the dark color areas to the light color areas. This volume reduction can be achieved by reducing the area and / or the Depth of gravure cups can be achieved. With the procedure mentioned at the beginning one could first come up with the idea of the area the gravure cups too reduce by removing the coating in the desired Areas of these areas simply reduced in area. To this Wise is also in the later etching or Electrolysis the area and thus the volume of the rotogravure cup smaller. However, this procedure would have the disadvantage that as a result the reduction of the area the rotogravure cup the gravure raster in the finished printed product is becoming increasingly clear would appear although the delicacy of the rotogravure screen itself remains unchanged.

Furthermore is off DE 32 49 518 T1 a method for producing gravure cells in a gravure cylinder is known. In this method, the peripheral surface of the intaglio cylinder is provided with an insulating coating, after which a first group of predetermined sections of the coated intaglio cylinder is exposed by optionally removing the insulating coating located on its peripheral surface. This first group of exposed sections of the rotogravure cylinder are removed to a certain depth and then the exposure and removal is repeated until a certain number of different groups of predetermined sections of the rotogravure cylinder have been exposed. Each previously exposed group has sections of the rotogravure cylinder that have been removed to a greater predetermined depth. As a result, an intaglio printing cylinder can be produced which has the desired pattern of intaglio printing cells with the desired depths. This is a method for the production of depth or area depth variable gravure cells by means of temporal modulation of the cylinder etching. Since the process of exposing and removing has to be repeated several times within the process, the overall result is a complex machining process which takes a long processing time. The processing sequence becomes longer, the greater the desired fineness of the gradation of the different depths of the gravure cells.

It the task therefore arises, the method mentioned at the beginning to further develop it with little effort and short processing times the production of metallic printing forms for the Gravure printing allowed with the gradual and smooth transitions from dark too bright color areas and vice versa are possible without the finished Printed matter the rotogravure grid especially in the light color areas, disturbing the viewer in Appearance occurs.

This object is achieved according to the invention with a method of the type mentioned at the outset according to main patent no. 195 44 272 characterized in that the removal of the coating takes place incompletely in at least some of the desired areas, the degree of removal in each area being controlled in accordance with a desired depth of the intaglio printing cup to be produced there.

This Further training of the method allows a targeted, individual Influencing the depth of the while of caustic or electrolysis process generated gravure cups. The more incomplete it is Coating in the desired Is worn away, the less intense can be in the etching or Electrolysis process the etching or electrolysis medium to the surface of the metallic printing form reach. The more complete the coating in the desired Areas is removed, the more intensive is the access of the etching or Electrolysis medium, so that hereby the mentioned to create different depths of the grid cells. For a grid bowl with minimal depth, the coating is removed to such an extent that a sufficient metal removal caused by the etching or electrolysis becomes; For the creation of a grid well at maximum depth, the coating is desired in the relevant Area completely removed, by one entirely unhindered access to the etching or electrolysis medium to ensure. That way, at for the entire printing form with the same etching or electrolysis time individually defined depth. About proportional to the depth behave the volume of the respective grid well that is used for the recording from printing ink to. disposal stands. In practice, brightness variations can be one Achieve hues in the range between about 5% and 100%. To this Wise one can very good, smooth transition from light to dark color areas and vice versa.

Prefers it is envisaged that for all rotogravure cups desired Depths in the form of electronic data along with the printed image and raster data electronically stored and for position and performance control of the thermally active beam can be called up. In this way is achieved in one pass not just the information for the contours of the printed image and for the gravure screen, but also the information for the respective brightness of the individual pixel of the printed image in the coating is brought. The processing time is thereby not extended; it's just a little bit more data to process, but which cannot lead to a delay in processing, because the processing of the data in relation to the maximum possible Switch-on and switch-off frequency of the thermally active beam very much is fast.

Farther provides a process design that the gravure screen with on a printing form constant fineness is generated and that all gravure cups the Printing form with an equal size area be generated. In this way, a color range from is changed light to dark colors or vice versa solely by variation the depth of the pitches without their area to change. This offers the particular advantage that even in the brightest color areas the gravure screen of the printed image on the finished printed product not visually disturbing appears.

A Alternative to the procedure described last stipulates that on the gravure screen with different subtleties in different areas the printing form surface is produced. In this way it is achieved that a particularly fine gravure screen, the higher one Processing time in the production of the printing form requires as a less fine gravure screen, only in the surface areas the printing form must be generated where it is actually needed. These areas in which a high fineness of the gravure screen required are e.g. Font representations in very fine lines; Areas of Printing form used for the production e.g. serve from colored illustrations, come with a lower fineness of the gravure screen out without the quality reduce the finished printed product noticeably. Since that too Gravure screen in the form of electronic, i.e. digital data can be processed before the printing form is processed of the data in such a way that the transition from the one delicacy to a different fineness of the gravure screen in the finished printed product becomes optically recognizable.

The degree of removal of the coating in the desired areas, each corresponding to a gravure raster cup, is preferably controlled in that the removal takes place in the form of a positive or negative additional raster whose density can be changed, the fineness of which compared to the fineness of the gravure raster by at least one factor 3 is higher. It is advantageously achieved in this way that only the working states "on" and "off" are required for the thermally active jet, since at each point of the coating it is either removed or left. The removed areas or the left areas of the coating can optionally represent the additional grid. The density of the additional grid is defined here as the ratio between non-removed and removed areas of the coating, viewed for the area of a grid cell. The increased fineness of the additional screen compared to the intaglio screen is necessary in order on the one hand to change the depth of the generated screen sufficiently fine To enable wells and, on the other hand, to avoid "islands" remaining within the grid well after the etching or electrolysis process. The surface area of the parts of the coating remaining within the additional grid in the desired areas, each delimiting a grid well, may only be so large that they are completely "infiltrated" in the subsequent etching or electrolysis process during metal removal, so that they no longer connect to the keep metallic printing form. The parts of the coating which initially remain on the surface of the printing form to form the additional grid are thus detached from the surface of the printing form during the etching or electrolysis process and removed with the etching or electrolysis medium. These removed coating parts are expediently filtered out of the etching or electrolysis medium in a filter process in order not to impair the effect of the etching or electrolysis medium by entrained coating particles.

alternative could an incomplete This also removes the coating in the desired areas done that the Coating only over part of its thickness from the outside removed by the thermally effective jet and so the coating with part of their original Thickness on the printing form surface remains. The one for this Intermediate levels of performance to be set and controlled of the thermally effective beam, with which a with regard to the Thickness of the coating partial removal could be achieved but technically much more complex and difficult to master. in principle but can in this way also the depth of the later etching or electrolysis process generated gravure cups influence in a targeted manner.

The previously mentioned Additional grid to control the depth of the gravure cups created later can be carried out in different ways; preferred versions are in the claims 6, 7 and 8.

On The following is an example of the procedure using a drawing explained. The figures in the drawing show:

1 a section of the surface of a printing form after removal of a coating in desired areas, in plan view,

2a the printing form in partial section along the line II-II in 1 .

2 B the printing form during an etching or electrolysis process,

2c the printing form at the end of the etching or electrolysis process,

3 another surface section according to the printing form 1 , also in top view, and

4 cut out the surface of the printing form 3 in partial section after an etching or electrolysis process.

As can be seen from the description of the main patent, the surface of a printing form 1 first of all with a coating 2 Mistake. Then this coating 2 ablated directly in desired areas of the surface by means of at least one thermally active focused beam, for example a laser beam, which is position and power controlled according to electronically stored data. The condition of the surface of the printing form 1 after this removal process is in 1 shown. First of all, it can be seen that the coating 2 in areas forming webs 21 on the surface of the printing form 1 remained. These areas 21 depict the contours of rotogravure raster webs between the rotogravure cups to be subsequently produced on the surface of the printing form 1 should remain. The areas 21 form a regular grid of intersecting lines, as it is known as a gravure grid. In practice, the width of the linear areas is 21 down to a few μm. The fineness of the gravure screen is given in lines per cm.

From the areas 21 in which the coating 2 areas still exist 22 bounded in which the coating 2 is more or less completely removed. In the in 1 The example shown is the coating 2 in the fields of 22 apart from a number of punctiform coating residues 21 ' away. The points 21 ' form a regular grid of dots in 1 relatively low density. The points 21 ' in which the coating 2 still on the surface of the printing form 1 has been left, by briefly switching off the thermally active jet when scanning over the corresponding surface areas of the printing form 1 or the coating applied to this 2 generated.

2a shows in partial section along the line II-II in 1 a near-surface section from the printing form 1 whose outer layer here is covered by a copper layer 15 is formed. On the surface of the copper layer 15 are the areas 21 and 21 ' in which the coating was not removed. As the 2a clearly shows the coating in the areas 21 and 21 ' a uniform, the original thickness of the coating 2 ent speaking thickness. Between the areas 21 . 21 ' are the areas 22 in which the coating is removed.

Furthermore clarify the 1 and 2a that the surface extension of the punctiform areas 21 ' is relatively small in relation to the area extension of the areas 21 ,

2 B shows the printing form 1 during an etching or electrolysis process, in which metal is removed by means of an etching or electrolysis medium in order to produce gravure wells. The etching or electrolysis medium flows in the direction of the flow arrows 5 over the surface of the printing form 1 , wherein as intensive an etching or electrolysis as possible is desired in order to achieve a uniform metal removal and a rapid removal of removed metal parts. This forms in the copper layer 15 Wells that grow over time both in their depth and their lateral extent, as the metal removal in the vertical and horizontal direction of the copper layer 15 progresses. Because of the areas that still exist 21 ' the coating becomes the access of the etching or electrolysis medium to the copper layer 15 to a certain extent specifically hindered or slowed down. This leads to a slowdown in the removal of metal from the copper layer 15 compared to a surface completely free of any coating.

This braking or hindering the access of the etching or electrolysis medium to the copper layer 15 leads like that 2c clearly shows, with the same etching or electrolysis time to a gravure well 4 whose depth is somewhat reduced. The depth of a grid well that would be preserved if there were no areas 21 ' the coating 2 would have been left, is by a dashed line below the bottom of the grid 4 indicated.

Furthermore shows the 2c clearly that the areas 21 ' the coating, which is initially still on the surface of the copper layer 15 the printing form 1 remained at the end of the etching or electrolysis process completely from the printing form 1 are replaced. This is done in that the etching or electrolysis process is not only in the direction of the interior of the printing form 1 , ie in the drawing downwards, but also to the sides, so that the areas with a progressive etching or electrolysis process and due to the associated metal removal 21 ' be completely infiltrated until they no longer connect to the copper layer 15 the printing form 1 to have.

After removing the remaining parts 21 the coating from the surface of the printing form 1 this is ready for printing. If necessary, the surface of the printing form can then be chrome-plated 1 to increase the mechanical resistance.

3 the drawing shows the same representation as before 1 a section of the surface of the printing form 1 , in which an intaglio printing cup with a smaller depth is to be generated. This area of the printing form 1 thus serves to generate a printed image area with a lighter color tone, which is achieved by a smaller volume of the gravure cell. This is also in this area of the surface of the printing form 1 the regular gravure screen through the remaining web-shaped areas 21 the coating 2 set, the fineness of the gravure screen and the width of the areas 21 with those according to the 1 to match.

In that of the remaining areas 21 the coating 2 bounded areas 22 is the coating here too 2 incompletely removed, again with punctiform areas 21 ' the coating 2 within the area 22 on the surface of the printing form 1 have been left. In contrast to 1 but are in the in 3 shown area of the surface of the printing form 1 the punctiform areas 21 ' provided in a significantly greater density. This means that over the area of the area 22 averaged only a slight removal of the coating 2 is done as in the example of the area 22 according to 1 was the case.

In the subsequent etching or electrolysis process, this leads to higher density of the areas 21 ' , which again form a regular dot pattern, to the fact that an intaglio cup 4 is generated with a relatively shallow depth, as in 4 is shown in a sectional view. Also in the example according to 3 and 4 in which the punctiform areas 21 ' the coating 2 although a coarser density, but individually about the same size as in the example according to 1 have in the etching or electrolysis process by infiltration completely from the copper layer of the printing form 1 replaced. However, due to the greater density of the areas 21 ' the coating 2 during the etching or electrolysis process, the access of the etching or electrolysis medium to the surface of the copper layer 15 braked to a noticeably greater extent than in the example as described in 2 B is shown during the etching-wire electrolysis process, which was the case. Accordingly, even with the same etching or electrolysis time, there is less metal removal in total, which results in the desired lower depth of the intaglio well 4 leads.

Instead of the one shown in the drawing Dot grid of the areas 21 ' the coating 2 can also have the shape of a geometric grid with surfaces and / or lines or a frequency-modulated grid or a crystal grid. Also the areas 21 ' not only be varied in their density, but also in their area extension. The fineness of the rotogravure screen as well as the width of the rotogravure raster webs can be varied if necessary by changing the data stored therefor, this also being possible within a printing form.

Claims (8)

Process for the production of a metallic gravure form ( 1 ), with the following procedures: - on the surface of the printing form ( 1 ) a thermosensitive, acid and / or electrolyte resistant coating ( 2 ) applied in a thickness between 2 and 10 μm, with the coating ( 2 ) a solvent-based varnish with binders, resin materials and dyes is used, - the coating ( 2 ) by means of at least one thermally active focused laser beam which is position and power-controlled and electronically stored in accordance with the requirements of the printed image and raster data ( 31 ) in desired areas ( 22 . 22 ' ) the surface ( 12 ) removed immediately in the form of a grid, the removal in the form of complete grid elements ( 22 ) with grid bars remaining in between ( 21 ) and in the form of grid element partial areas ( 22 ' ), which is why the coating ( 2 ) a color with a to the wavelength (s) of the vice ( 31 ) has an adapted absorption spectrum, - in the of the coating ( 2 ) exempted areas ( 22 . 22 ' ) the printing form ( 1 ) metal is removed by etching or electrolysis to produce full-area and partial-area gravure wells and - the parts still present ( 20 ) the coating ( 2 ) are removed from the surface using a chemical and / or physical removal process ( 12 ) the printing form ( 1 ) removed, according to main patent no. 195 44 272, characterized in that the removal of the coating ( 2 ) at least in part of the desired areas ( 22 ) is incomplete, with the degree of removal in each area ( 22 ) in accordance with a desired depth of the rotogravure cup to be produced there ( 4 ) is controlled. Method according to claim 1, characterized in that for all gravure printing cups ( 4 ) the desired depths in the form of electronic data are stored electronically together with the printed image and raster data and are called up for the position and power control of the thermally active beam. Method according to claim 1 or 2, characterized in that on a printing form ( 1 ) the rotogravure screen is produced with constant fineness and that all rotogravure cups ( 4 ) the printing form ( 1 ) with an area of the same size. Method according to claim 1 or 2, characterized in that on a printing form ( 1 ) the rotogravure screen is produced with different finenesses in different areas of the printing form surface. Method according to one of claims 1 to 4, characterized in that that the Degree of removal is controlled by the removal in the form of a changeable in density, positive or negative additional grid, its delicacy across from the fineness of the rotogravure screen is at least a factor of 3 higher. Method according to one of claims 1 to 5, characterized in that that this Additional grid is a geometric grid of areas and / or lines. Method according to one of claims 1 to 5, characterized in that that this Additional grid is a grid of points. Method according to one of claims 1 to 5, characterized in that that this Additional grid a frequency-modulated grid or a crystal grid is.