EP0703092A1 - Sleeve for printing and transfer forms - Google Patents

Abstract

The sleeve (1) is formed from a thin rectangular plate bent into a cylindrical shape and joined along the adjacent edges. It can be of aluminium, and for use in offset printing it can be chemically roughened including the joint seam (2), anodised and provided with a sealing photo-sensitive coating. Alternatively, it can be provided with a water-guiding coating. For rotogravure printing it can be provided with an engraved copper coating. For use with a transfer block, the surface can be provided with a continuous laminar rubber coating. It can also be used as a direct support for a flexible block used in flexographic printing.

Description

The invention relates to a carrier sleeve for printing and transfer forms made of a metallic material, the starting form of which is a rectangular, thin-walled plate piece which is bent into the desired hollow cylindrical shape and the mutually facing edges of the plate piece are firmly connected to one another.

It is well known today from flexographic printing to apply sleeve-shaped printing and transfer forms to electroplated nickel sleeves. The printing and transmission forms produced in this way can be pushed on in a known manner by means of compressed air over a pressure cylinder core and can be fixed thereon by switching off the air supply. Carrier sleeves made of glass fiber reinforced plastic (GRP) or even carbon fiber reinforced plastic (CFRP) have also been used for this purpose. However, the use of nickel GfK or even CfK for a carrier sleeve is comparatively very expensive.

With the German patent application P 41 40 768 a sleeve-shaped offset printing form has become known, which is manufactured from a rectangularly cut metal plate by connecting the mutually facing edges of the plate by means of a weld seam. The carrier sleeve produced in this way is coated and exposed all around except for the weld seam.

DE 42 17 793 C1 discloses a sleeve-shaped offset rubber blanket which is also made from a cut carrier plate, to which a rubber layer is applied in the flat state, by welding the beginning and end of the carrier plate together with the rubber layer.

By means of these sleeve-shaped printing and transmission forms, channel-free printing is possible, but not endlessly. H. it can only be used to produce finite printed products. The use of an endless offset printing form has not yet become known.

Proceeding from this, it is the object of the present invention to provide comparatively inexpensive carrier sleeves for both printing and transfer forms, by means of which continuous printing is possible.

This object is achieved by a carrier sleeve according to claim 1 and the characterizing method steps of claim 8.

By a support sleeve for printing and transfer forms made of a metallic material, the starting form of which is a rectangular, thin-walled plate piece which is bent into the desired hollow cylindrical shape and the mutually facing edges of the plate piece are firmly connected to one another, in which the sleeve surface forms a homogeneous surface is processed, so that continuous printing can be carried out, an advantageous alternative to the nickel, GRP and CFRP sleeves was found from both an ecological and economic point of view, which is also universally applicable for various printing processes.

The manufacturing costs of a welded precision sleeve machined according to the invention are many times lower than the manufacturing costs of galvanic nickel sleeves or even wound GfK or CfK carrier sleeves, especially since it is becoming increasingly difficult to produce nickel sleeves galvanically, since this manufacturing process entails great environmental pollution.

Furthermore, in a particularly advantageous manner, the carrier sleeves according to the invention can be made of aluminum, steel, stainless steel, copper or brass, depending on the particular application.

Fig. 1 shows a highly schematic embodiment of a carrier sleeve 1 made of a metallic material, which can be aluminum, steel, stainless steel or brass. The initial shape is a rectangular, thin-walled plate piece that has been bent into the desired hollow cylindrical shape. The mutually facing edges of the plate piece are preferably firmly connected to one another by means of a weld seam 2.

Fig. 2 shows the possibility of producing the carrier sleeve 1 quasi continuously, as is done today for pipe welding. The welding process itself is carried out using a laser beam. The precision sheets made of aluminum, steel, stainless steel, copper or brass preferably have a wall thickness s of 0.1 to 0.6 mm. The carrier sleeves can also be manufactured with the welding device known from DE 43 11 078.

The outer surface of the whitened carrier sleeve 1 is processed so that a homogeneous, continuous outer surface is obtained. Known manufacturing processes such as turning, grinding or the like, which make a metal surface smooth, can be used for surface processing. The original wall thickness of the thin-walled plate piece must be chosen so that the material removal from the outer surface of the welded carrier sleeve is taken into account.

A particularly advantageous embodiment of the weld seam, as shown in FIG. 3, is to provide a seam elevation 3 on the outer surface of the sleeve 1 and to process it in a subsequent process step in such a way that a continuous, endless jacket surface is formed on the carrier sleeve surface without material removal from the precision sheet is necessary, or this material removal is at least less.

The seam increase 3 is by welding filler materials such. B. wire or powder, or by targeted protective gas guides, or achieved by build-up welding following the actual welding process.

For use in offset printing as a carrier sleeve 1 for a printing form, the entire sleeve surface including the connecting seam, in the present case a weld seam 2, is chemically roughened, anodized and provided with a final photosensitive layer, as is already known from the process steps in the production of printing plates. Seen from the printing properties, this printing form sleeve is identical to the usual printing plates, except that continuous printing is possible with this printing form sleeve. Aluminum sheets are preferably used for this.

However, it is also possible to apply a water-bearing layer to an aluminum sleeve or another metallic sleeve if the sleeve material itself is not water-bearing, but should be made water-bearing. For example, ceramic materials can be applied as water-bearing layers by means of thermal spray processes.

For high pressure, in particular for flexographic printing, this welded precision sleeve 1, which is also surface-treated as described above, can be used directly as a carrier for a flexible printing form, rubber stereo or engraved rubber printing form and thus replaces the known nickel, GfK and CfK sleeves.

For use in gravure printing, a welded carrier sleeve 1, which is surface-treated as described above, is galvanized or sprayed all around, a metallic layer, preferably a copper alloy, which in turn is engraved in a subsequent step. Plastic layers can also be applied, which are then also engraved.

For use in offset printing as a carrier sleeve 1 for a transfer form, the entire surface-treated sleeve surface, including the connecting seam 2, is covered with an endless rubber layer structure, so that from a printing point of view, these blanket sleeves are identical to the usual blankets, but with these blanket sleeves, continuous printing is possible.

The type of rubber layer depends on the respective printing process and regardless of the material of the carrier sleeves.

Claims (17)

Carrier sleeve (1) for printing and transfer forms made of a metallic material, the starting form of which is a rectangular, thin-walled plate piece which is bent into the desired hollow cylindrical shape and the mutually facing edges of the plate piece are firmly connected to one another, characterized in that the sleeve surface is processed to form a homogeneous, endless lateral surface, so that continuous printing can be carried out. Carrier sleeve according to claim 1, characterized in that the thin-walled plate piece is made of aluminum. Carrier sleeve according to Claim 1, characterized in that the entire sleeve surface including the connecting seam (2) is chemically roughened, anodized and provided with a final photosensitive layer for use in offset printing. Carrier sleeve according to claim 1, characterized in that the entire sleeve surface including the connecting seam (2) is provided with a water-conducting layer for use in offset printing. Carrier sleeve according to claim 1, characterized in that the entire sleeve surface including the connecting seam (2) is provided with an engraved copper coating for use in gravure printing. Carrier sleeve according to claim 1, characterized in that the entire sleeve surface including the connecting seam (2) is covered with an endless rubber layer structure for use in a transfer form. Carrier sleeve according to claim 1, characterized in that it can be used directly as a carrier (1) of a flexible printing form for flexographic printing. Process for the production of a carrier sleeve (1) for printing and transfer forms, in which a carrier plate is cut from a thin-walled sheet drawn from a roll in the flat state to the extent corresponding to the circumference and the width of the printing cylinder used, the carrier plate by bending in the desired cylindrical shape is brought and the mutually facing edges of the carrier plate are firmly connected to one another, characterized in that the connection of the mutually facing edges of the carrier plate is produced by means of a weld seam (2) which is carried out in such a way that a seam overlap on the outer surface (3) arises and the seam elevation (3) is machined into this homogeneous jacket surface during processing of the entire sleeve surface to form a homogeneous, endless jacket surface. Method according to claim 8, characterized in that the seam elevation (3) is achieved by means of filler metals. Method according to claim 8, characterized in that the seam elevation (3) is achieved by targeted protective gas guides. Method according to claim 8, characterized in that the seam elevation (3) is achieved by a build-up welding following the actual welding process. A process for producing an offset printing form using a carrier sleeve according to claim 8, characterized in that the entire sleeve surface for formation a homogeneous, endless outer surface is machined, the hollow cylindrical shape (1) of the carrier plate is chemically roughened and anodized all around on the outer surface and then provided with a photosensitive layer and thus made into a printing form sleeve for continuous printing. A method according to claim 12, characterized in that aluminum is used as the material for the carrier plate. Method for producing a rotogravure form using a carrier sleeve according to claim 8, characterized in that a metallic layer is applied to the processed, outer surface of the hollow cylindrical form (1), which is then mechanically processed. A method according to claim 14, characterized in that a copper alloy is used for the metallic layer. A process for producing a transfer form using a carrier sleeve for printing and transfer forms according to claim 8, characterized in that an endless rubber layer structure is applied to the entire processed sleeve surface. A process for producing a printing form using a carrier sleeve according to claim 8, characterized in that an endless ceramic layer is applied to the entire processed sleeve surface.

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