EP0473973B1 - Process for the treatment of intaglio printing plates - Google Patents

Description

The present invention relates to a method for processing gravure printing forms consisting of at least one base body and a metallic outer layer carried by it, as well as a printing form suitable for carrying out this method.

The formation of the grid cells in the outer layer of printing forms by means of laser beams is already known. DE-PS 23 54 323, which deals with the processing of a printing form with an outer layer made of plastic by means of laser beams, describes the problems which occur in the laser processing of printing forms (see in particular column 1, lines 46-62). Furthermore, in this German patent specification are found to solve these problems.

DE-PS en 27 09 554 and 27 19 275 describes devices for laser processing of gravure cylinders of a conventional type, that is to say of gravure cylinders with an outer layer of electrolytically applied copper. In practice, however, the laser processing of gravure cylinders with an outer copper layer could not prevail.

The present invention has for its object to provide a method of the type mentioned for the laser processing of the metallic outer layer of printing forms, which can be used successfully under the conditions prevailing in practice.

With regard to the solution to this problem according to the invention, reference is made to the claims.

The present invention is based on the finding that the laser processing of gravure forms, in particular gravure cylinders, of the conventional type with an outer layer made of copper is associated with difficulties for the following reasons.

• 1. Sehr starke Reflexion der Kupferschicht
• 2. Hohe Schmelz- bzw. Verdampfungstemperatur von Kupfer
• 3. Hohe Schmelz- bzw. Verdampfungswärme von Kupfer
• 4. Gute Wärmeleitfähigkeit von Kupfer und damit starke Wärmeabgabe an die Umgebung der Rasternäpfchen.

The removal of the grid cells from the copper layer by means of laser beams is associated with a relatively high expenditure of energy, for the following reasons:

• 1. Very strong reflection of the copper layer
• 2. High melting or evaporation temperature of copper
• 3. High melting or evaporation heat of copper
• 4. Good thermal conductivity of copper and thus strong heat transfer to the surroundings of the cell.

There are additional requirements especially for gravure forms. In particular, a high quality of the print surface and a short processing time is required Training the grid cells requires. However, these requirements are very difficult to meet with conventional gravure printing forms with an electroplated copper outer layer.

Various measures will now be explained with reference to the drawing, with which the disadvantages described above, which occur when forming raster cups in conventional printing forms by means of laser beams, can be avoided.

Figures 1-4 show excerpts from differently designed gravure forms.

The printing form 1 shown only in part in FIG. 1 (in the present case a gravure cylinder as a preferred embodiment) has a base body 2 made of a suitable material, e.g. Steel, aluminum or plastic. A metallic intermediate layer 3 is applied to this base body 2 in a known manner, preferably galvanically. The intermediate layer 3 consists for example of copper or zinc. This intermediate layer 3, which serves to adapt to different cylinder diameters, is also present in the embodiments according to FIGS. 2-4, but is no longer shown in these figures.

• 1. Sein Absorptionsfaktor 1-R ist grösser als derjenige von Kupfer,
• 2. Er weist eine geringere Schmelz- bzw. Verdampfungswärme Q auf als Kupfer,
• 3. Er weist eine geringere Schmelz- bzw. Verdampfungstemperatur T auf als Kupfer, und
• 4. Seine Wärmeleitfähigkeit k ist geringer als diejenige von Kupfer.

A metallic outer layer 4 is connected to the intermediate layer 3 and is likewise applied galvanically. In this outer layer 4, scanning pits 5 are formed by means of laser beams. The outer layer 4 is not made of electrolytically applied copper but consists of it from or contains a material with the following properties:

• 1. Its absorption factor 1-R is greater than that of copper,
• 2. It has a lower heat of melting or evaporation Q than copper,
• 3. It has a lower melting or evaporation temperature T than copper, and
• 4. Its thermal conductivity k is lower than that of copper.

In addition, this material has an abrasion and compressive strength that is at least as high as that of copper. Furthermore, this material can be machined at least as well as copper and allows the reproducibility of the grid pattern to be reproduced, which is comparable to that of copper.

A material that has these properties and that also meets the printing requirements is in particular zinc or a zinc alloy.

There are the following significant differences between the material properties of copper and zinc that are important in connection with laser engraving: Evaporation energy Cu: 892 J / mm³ Zn: 31.4 J / mm³ Evaporation temperature Cu: 2595 ° C Zn: 907 ° C Absorption factor (1-R) (at 1 »m and room temperature) Cu: 0.06 Zn: 0.5 Thermal conductivity Cu: 3.94 W / cm ° C Zn: 1.13 W / cm ° C

In order to dig out a grid well with a diameter of 120 »m and a depth of 30» m, 165 mWs for copper and 6 mWs for zinc are necessary.

In addition to zinc and its alloys, materials with comparable properties are also suitable.

When selecting the suitable materials, the following must also be observed:
The metals and metal alloys used for the outer layer 4 must have an abrasion and compressive strength that is at least as high as that of copper and must be machinable at least as well as copper. In addition, the reproducibility of the grid pattern from printing form to printing form must be comparable to that with outer layers made of copper.

Of course, these metals and metal alloys must also meet the printing requirements and in particular enable a very high quality of the surface 4a of the outer layer 4. Furthermore, it is important that the ratchet cups 5 can be lifted in the outer layer 4 by means of laser beams at a very high speed. The latter requirement is particularly important for the processing of gravure cylinders.

In the embodiment shown in FIG. 2, a heat-insulating intermediate layer 6 is arranged below the metallic outer layer 4, which largely prevents the outflow of the heat generated during laser processing from the outer layer 4 into the intermediate layer 3 or the base body 2. This heat insulation can be influenced on the one hand by the choice of a material with heat-insulating properties and on the other hand by the thickness of the layer 6. Possible materials for this heat-insulating layer 6 are: plastic, ceramic, metals or metal alloys with poorer thermal conductivity than the material from which the outer layer 4 is made. Such metals with poor thermal conductivity are e.g. Titanium, tin, zinc etc. In addition, other suitable heat insulation materials can of course also be used.

In the embodiment shown in FIG. 2, in addition to the materials already mentioned in connection with FIG. 1, the outer layer 4 can also be formed from copper.

In the embodiment according to FIG. 3, the outer layer 4 is designed as a so-called dispersion layer, which consists of a carrier or matrix material 8 and particles 7 embedded therein, made of a heat-insulating one Material exists. These particles 7 can be made of plastic, metal oxides, ceramics, silicon carbide, molybdenum and the like materials, for example. Zinc, copper or other metallic materials or their alloys can be used as the carrier or matrix material 8.

The incorporation of the particles 7 into the outer layer 4 can have a positive influence on the properties of the outer layer 4 which significantly influence laser processing, for example the evaporation energy, the conductivity and the absorption properties of the layer 4. The heat flow is not only influenced as in the embodiment according to FIG. 2 towards the base body 2, but also spatially, i.e. also in the direction of the course of the outer layer 4. In other words, the heat flow in the outer layer is also considerably reduced by these particles 8, as a result of which, for example, the deformation of extremely thin well walls can be prevented. The embedded particles 7 are selected in terms of shape, size and number per unit volume so that the respective printing requirements (e.g. print quality) can be met.

Another embodiment is described in FIG. 4. In this variant, a cover layer 9, which consists of an abrasion and wear-resistant material, for example of chrome or a metal oxide, is applied to the surface 4a of the outer layer 4 before the laser processing. The grid cells 5 are then worked directly through this wear-resistant cover layer 9 into the underlying material of the outer layer 4.

This embodiment has the advantage that printing form 1 is available for printing directly after laser processing, since chrome layer 9, which is usually only applied after engraving, is already present. The material that is used to form the cover layer 9 should form a very stable oxide on its surface, which makes the adhesion of other materials very difficult or even prevents it. This is the case with chrome, for example. When the grid cups 5 are formed, material which is thrown out and condenses on the edge of the grid cup 5 is repelled by this oxide layer of the cover layer 9, so that no adhesive bond can take place between this cover layer 9 and the deposited material. Thus, no disturbing material deposits can take place in the edge region of the grid cells 5.

In this embodiment according to FIG. 4, the metallic outer layer 4 can consist of zinc or its alloys or also other metals and metal alloys including copper. In addition, it is also conceivable to produce the outer layer 4 from a suitable plastic.

The absorption of the laser beams is increased if the outer layer 4 to be engraved is additionally covered with a black layer. This layer can consist of a chemically or electrochemically applied chromium or chromate layer. The layer can also be applied by means of a plasma or vacuum coating process and can also consist of other materials, such as lacquer or plastics.

Experiments have shown the following:
With CO₂ lasers, the best material removal rates can be achieved with an outer layer 4 made of unalloyed zinc (Zn). However, outer layers 4 made of pure zinc have the disadvantage that the printing requirements, such as pressure resistance in particular, can only be met with difficulty.

In contrast, it was found that with outer layers 4 made of zinc alloys, which were processed with a YAG laser, a significantly better quality of the raster cups 5 could be achieved and that the printing technology requirements already mentioned can be met much better.

Nevertheless, no disadvantages were found in the case of outer layers 4 made of zinc alloys processed with YAG lasers with regard to material removal rates.

From this it can be concluded that the desired results can be achieved when using zinc alloys for the outer layer 4 and when processing with a YAG laser.

Claims (10)

1. Process for the treatment of intaglio printing plates (1) which consist of at least one basic body (2) and of a metallic outer layer (4) carried by the latter, in which process the screen cups (5) are formed in the outer layer (4) by means of laser beams, characterized in that a printing plate (1) with a metallic outer layer (4) which consists of zinc or a zinc alloy or which contains zinc or a zinc alloy is used.
2. Process according to Claim 1, characterized in that there is arranged under the metallic outer layer (4) a heat-insulating intermediate layer (6) which consists of an insulation material, for example plastic, or which is formed by a metal layer with lower heat conductivity than the outer layer (4).
3. Process according to Claim 1, characterized in that particles (7) of a heat-insulating material, for example plastic, metal oxide, silicon carbide, ceramic or molybdenum, are embedded in the metallic outer layer (4).
4. Process according to Claim 1, characterized in that, before the laser treatment, the metallic outer layer (4) is provided with a covering layer (9) consisting of abrasion-resistant and wear-resistant material, for example a metal oxide or chromium.
5. Process according to Claim 1, characterized in that the outer layer (4) is provided with a black layer causing an increase in the absorption of the laser beams.
6. Intaglio printing plate (1) suitable for the formation of screen cups (5) by means of laser beams and consisting of at least one basic body (2) and of a metallic outer layer (4) carried by the latter, characterized in that the outer layer (4) consists of zinc or a zinc alloy or contains zinc or a zinc alloy.
7. Intaglio printing plate according to Claim 6, characterized in that there is arranged under the outer layer (4) a heat-insulating intermediate layer (6) which consists of an insulation material, for example plastic, or which is formed by a metal layer having lower heat conductivity than the outer layer (4).
8. Intaglio printing plate according to Claim 6, characterized in that particles (7) of a heat-insulating material, for example plastic, metal oxide, silicon carbide, ceramic or molybdenum, are embedded in the metallic outer layer (4).
9. Intaglio printing plate according to Claim 6, characterized in that the metallic outer layer (4) is provided with a covering layer (9) consisting of an abrasion-resistant and wear-resistant material, for example a metal oxide or chromium.
10. Intaglio printing plate according to Claim 6, characterized in that the outer layer (4) is provided with a black layer causing an increase in the absorption of the laser beams.

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