WO2008000327A2 - Method for the production of an embossed blank, and blank - Google Patents

Abstract

Disclosed is a method for producing blank lids from printed and embossed stock such as metal films, plastic films, papers, and layered materials or laminates made therefrom. The stock is printed in a printing press by means of ink-conducting printing groups and is embossed in the same printing press or another printing press located behind the first one. Printing elements of the printing forme are applied to the stock as an embossed pattern. For this purpose, the stock is guided between the form cylinder and the impression cylinder in the printing group and is embossed in said process. As a printing forme, the form cylinder is provided with engraved, e.g. recessed, and/or raised printing elements, for example. The stock comprises the embossed pattern and, if applicable, a single-colored or multi-colored printed pattern. The embossed pattern can boost the effect of the colored subject and can also have functional properties, e.g. as a tearing aid or as Braille writing. Blank lids are removed from the stock, e.g. punched out. The inventive blank lids are easy to separate from a stack and are therefore particularly suitable for processing in filling stations in order to put lids on cups or similar.

Description

 Method for producing an embossed circuit board and circuit board

The present invention relates to a method for producing a printed and embossed lid board and a lid board.

It is known, for example, to print on and emboss lid materials. Typical examples are plastic, metal or plastic-bonded metal foils that are printed, for example. Cover sheets are cut out of the films and fed into the stack of a filling and sealing machine. The cover plates are prone to mutual adhesion by the "glass plate effect", and separation of the cover plates is not reliably possible, resulting in malfunctioning during capping of containers in the sealing machine, therefore, the cover materials are embossed by means of embossing rollers with a damask or Worm embossing etc. provided

Preferably, the embossing of films, in particular for industrial quantities, is carried out continuously between embossing rollers. The films to be embossed can already be printed repetitively with advertising imprints, texts, logos, etc. It presents the difficulty of embossing on the initially printed sheets in a further separate pass through the embossing device in the register, i. continuously congruent with the imprint to emboss. Furthermore, the printing process is distorted by the embossing process and a possible gloss disappears. In addition, the procurement and provision of embossing rolls is a very expensive project.

Object of the present invention is to overcome the disadvantages mentioned and to propose an improved manufacturing process for easily isolatable cover plates and cover plates with new optical benefits.

According to the invention, this is achieved by a method according to which the printing elements or printed motifs of a cover plate are printed by means of one or more printing plates and embossed printing elements or print motifs of the cover plate are embossed by means of one or more embossing printing plates and the cover plate from a substrate in at least one printing unit is excluded from the substrate. In addition to the mentioned printing motifs, a sealing edge made of a sealing lacquer, the cover plate essentially delimiting, can be printed onto the printing material by means of a further printing form as a further printing motif.

Preferably, in only one printing unit, the printing elements or the printing motif are embossed by means of the first printing form the substrate as an embossing.

Suitable printing units for carrying out the inventive method are, for example, printing units in gravure printing machines or flexographic printing machines.

In gravure printing or copper gravure printing by gravure printing machines, the print motif is engraved on a form cylinder. The recesses of the engraving pick up the color from a paint tray. The excess paint is stripped off with a squeegee. A printing cylinder or impression roller presses the printing material against the forme cylinder, which then delivers the ink to the material to be printed.

Flexographic printing by means of flexographic printing machines is a high-pressure process. The ink is transferred via an anilox roller to the raised elements of the printing form and from there directly to the substrate. In flexographic printing, the printing form is a prefabricated photopolymer plate which is mounted on a forme cylinder applied.

The printing plates for the method according to the present invention are generally forme cylinders with the printing elements or printing motifs attached thereto. Arranged opposite to the respective form cylinder, a printing cylinder or impression roller rolls off. The printing material is carried out between the two cylinders. Between the forme cylinder and the impression cylinder creates a surface pressure. When printing with colors, the colors are transferred to the substrate. Depending on the number of colors when printing, whether black and white Printing, three-color printing or four-color printing, etc., can be a color-leading printing unit or several color-leading printing units, in particular with the colors black, cyan, magenta and yellow, be arranged in the printing machine. To carry out the inventive method, in addition to the color-guiding printing units, one or more cases several printing units, for example arranged in the same printing machine, are provided, which attach the embossing to the printing material. The printing unit or the printing units for executing the embossing are arranged before and advantageously after the color-leading printing units or. In the method according to the invention, for example for intaglio printing, the printing form for embossing is in particular a forme cylinder with engraved printing elements. In the printing press, the forme cylinder of the or the printing units, which attach the embossing on the substrate and occasionally the printing unit, which imprints the sealing edge, the same circumference or diameter, as the printing plates in the ink-conducting printing units and the printing units can by the same drive or individually driven by separate drives. In another form, in the printing machine, the forme cylinder of the printing unit (s) which apply the embossment to the printing material and print on the sealing edge have a different circumference or diameter than the printing forms in the ink-conducting printing units, and the printing units are driven in this case by separate drives. wherein the drives are synchronously controlled with respect to the peripheral speed of the printing plates.

An advantageous embodiment of the inventive method is that the coloring printing, occasionally the imprint of the sealing edge and the embossing in the same printing machine, by directly successively arranged printing units, takes place. This makes it possible to attach the printing inks, the sealing wax as well as the embossing in the register, in particular against each other without displacement and distortion, to the printing substrate.

Another advantageous embodiment of the inventive method is that the coloring printing and occasionally the imprint of the sealing edge on the substrate in the same printing press, by directly successively arranged printing units, and that the embossing of the printing material takes place in a further downstream printing press. The downstream printing machine applies the embossing on the printing material via one or more engraved forme cylinders. The downstream printing press can remove the cover plates from the printing substrate by means of corresponding punching or cutting rollers. Or, subsequent to the downstream printing machine, a punching or cutting device can remove the cover plates from the printed matter. Or, downstream of the printing press, an embossing and punching device can emboss the printed substrate and then punch out the cover boards from the printing substrate.

According to the present invention, the embossing process, which is arranged within the printing process, is carried out in the same way as a printing process, likewise with an engraved forme cylinder, occasionally with a plurality of engraved forme cylinders, but without paint application, as dummy printing. In the present process, in particular in the one or more printing units for embossing no color on the forme cylinder, respectively. given the printing form. The form cylinder, resp. the printing form, attaches alone the embossing on the substrate.

The said printing units are advantageously operated at room temperature. The embossing of the printing material is usually carried out at ambient or room temperature. An energy supply to the cylinder surfaces or the printed matter, such as heating, during embossing is generally not provided. A heating of the printing unit or parts thereof, such as the heating of the forme cylinder and / or the printing cylinder and / or the printing material may be expedient for the embossing of substrates from or containing plastic layers. As a result of the heating, the viscosity of the plastic layer may sink and thereby influence the embossing process. The printing substrate may also contain reactive layers which change their behavior or state by physical or chemical reaction, eg curing, polycrystalline merge, swell, foam, change in solubility, etc., and the change in behavior may occur during imprinting, occasionally by external energy input.

Form cylinders with engraved printing elements can be produced by electromechanical engraving of cylinders with a metal surface. For example, a text or image is read by a reader and stored digitally. The stored data is transferred to the positioning and the drive of a stylus. The effect of the movements of the stylus that are engraved in material removal from the surface of the forme cylinder, the text or the image motif to be printed in itself or as a grid in the surface of the forme cylinder as printing elements.

According to the present invention, the forme cylinders for the printing inks, the sealing edge and for embossing can be used, for example, in the same layout program or print image program and preferably by the same image processing processor and the mechanical screen or gravure production connected thereto, in particular in the same machine bed. to be edited. By controlling the engraving depth, the engraving screen, the grid width of the engraving or the engraving screen by generating cells and partitions, i. the pressure elements and support grid, and the stylus shape can be produced both for the printing and for the embossing optimized form cylinder. It is also possible to attach not only in depth engraving as printing elements to the forme cylinder for embossing, but also alternately raised printing elements.

The imprint itself can u.a. be influenced by the material or the surface of the printing cylinder or impression roller and the hardness or deformability of the surface layer of the printing cylinder or impression roller and also by the Gleitfak- factors between the cylinders and the substrate.

In the forme cylinder, for example for gravure printing or copper gravure printing, placed, the embossment generating, printing elements can be engraved with respect to the surface of the forme cylinder in a depth of 60 to 500 .mu.m, suitably from 60 to 250 .mu.m, advantageously from 80 to 200 .mu.m and in particular from 100 to 200 microns.

The printing elements engraved in the forme cylinder for embossing can have a reduced support grid or be free of support grid. When engraving form cylinders for ink transfer, a typical print support grid is targeted for optimum color pickup, ink transfer, and color output. According to the present invention, no colors are transferred with the printing cylinder for embossing. Therefore, the support grid, based on the surface of the engraved printing element, completely - to 100% - eliminate, or the support grid can only up to 80% and in particular up to 50% of the supporting surface of a pressure-typical support grid have. The supporting grid is completely eliminated or the supporting surface is reduced, since the support grid can be troublesome to the formative influence of the forme cylinder.

Relative to the effective, i. On the printing substrate unrolling surface of a forme cylinder, the engraved printing elements for embossing can be up to 80% and preferably up to 50%. Appropriately, this also applies to support grid-free printing elements. The engraved printing elements for embossing are advantageously designed in such a way that the embossings are distributed on the finished cover plate in such a way that the cover plates do not sag, lie flat.

For example, in flexographic printing or another high-pressure process, the printing form has raised or protruding printing elements. The printing elements which produce the embossing are raised in flexographic printing or another high-pressure process relative to the surface of the printing form and can protrude from 60 to 500 .mu.m, suitably from 60 to 250 .mu.m, advantageously from 80 to 200 .mu.m and in particular from 100 to 200 .mu.m. To impress in the printing unit, the printing elements of the printing form the substrate as an embossing, the printing material is passed between the forme cylinder and a printing cylinder. The two cylinders roll on the substrate, usually under pre-set pressurization.

The printing cylinder may have an undeformable, deformable or elastic surface layer. The surface of the printing cylinder is usually smooth and has no printing elements. For example, the impression cylinder may be a steel roll having a surface of steel. The printing cylinder can occasionally also be a steel roller with a surface layer of elastic material, such as rubber, or of paper or a rubber roller. The contact pressure of the impression cylinder to the forme cylinder can be adjusted. For the present embossing process, for example, pressures of up to 3 t per meter effective cylinder width, conveniently up to 2 t per m, advantageously up to 1, 5 t per m, more preferably up to 1 t per m and in particular up to 0.5 t be applied per m. The minimum pressures may be 0.2 t per m effective cylinder width, and preferably 0.4 t per m. Typical cylinder widths range from 200 mm to 5600 mm and preferably from 500 to 1200 mm. In some cases, a base, a so-called underlay, can be used in the printing unit. The contact pressure of the printing cylinders is adjusted as usual in printing processes such that no dimensional change, e.g. no reduction in thickness, stitch reduction or the like., Of the substrate takes place.

Between the pair of rollers made of forme cylinder and impression cylinder, the printing material is imprinted on the printing material corresponding to the printing elements on the forme cylinder. The embossing depth of the printing material can be changed by the depth of the engraving in the forme cylinder, by the control of the contact pressure of the printing cylinder to the forme cylinder and the material properties of the surface layer of the printing cylinder.

In an alternative embodiment, the impression cylinder may also be a form cylinder. represent linder and have printing elements. Such a cylinder used as a forme cylinder can in particular the negative image, resp. the printing elements in negative form, and the printing elements of the forme cylinder and the negative pressure elements of the printing cylinder act simultaneously on the substrate. This means that the printing cylinder is also a form cylinder with the embossed negative of the printing elements of the other forme cylinder. The described printing cylinder, resp. other form cylinder, thus represents the counter-mold or male. In particular, raised parts of the embossed motif on the one cylinder surface can be engraved in the engraved, resp. deepened, engaging motifs in the surface of the other forme cylinder. The printing material passing through between the two cylinders is correspondingly strongly deformed and embossed.

In another optional embodiment, the impression cylinder or impression roller may also have a surface layer of paper or paperboard. The surface layer of paper or cardboard is moistened and without intermediate printing material, the forme cylinder is unrolled on the printing cylinder. The printing elements of the forme cylinder are transferred to the moist surface layer and the negative image is imprinted in the surface layer, resp. the pressure elements in negative form, the forme cylinder. During the subsequent embossing process on the printing substrate, the printing elements of the forme cylinder and the negative printing elements of the printing cylinder act simultaneously on the printing material. According strengthened passing through the two cylinders printing substrate is deformed and provided with the embossing.

It is also possible to have two different forme cylinders in separate printing units act on the substrate in such a way that the one forme cylinder imprints the embossing in one direction, the other forme cylinder imparts further embossing in the other direction to the substrate. A stamping on both sides of the substrate can also be done by deflecting the printing material by means of a turning cross in the printing press. It is also possible to perform the printing material between different form cylinders pressed against the same pressure roller or against separate pressure rollers and to memorize the printing material successively different, superimposed or stepped depressions print images or motifs.

Finally, the possibility should also be mentioned of using the printing unit in the method according to the invention only for embossing or embossing and for printing the edge of the seal, and to use no ink-conducting printing units. This application is of great interest for the production of printing substrates and for printing substrates per se, on which only embossing, resp. Embossing and sealing edge to be attached.

According to the present invention, for example, the printing elements or the printing motif of the printing form can be embossed onto the printing material as embossing, as a protruding pattern, as relief-like elevations, as a hologram-suitable pattern or as dot or braille writing or as a weakening, as a perforation or as a perforation or fold lines. Of course, the different embossings can be made in a printing unit by the same forme cylinder on the same substrate in any combination.

The in one or more printing units between by the forme cylinder and the printing cylinder attached to the substrate imprints as surveys or depressions can occasionally in another printing unit with form and impression cylinder with a smooth surface for limiting or embossing depth, respectively. for smoothing or damping the embossed structure, be performed. By controlling the contact pressure, the embossing depth can be adjusted.

According to the later use as a lid on a container can be attached to the substrate printing with a sealing wax. The sealing wax can be printed over the entire surface of the substrate. Prefers is a print motif of the sealing wax, this print motif is essentially an annular or endless seam. The shape of the seam corresponds in particular to the contour of the shoulder region of the container to which the lid is to be sealed later. Of course, the print motif can be printed from the sealing wax at any point in any extent according to the required sealing surfaces. Instead of a paint, a sealing wax is printed by means of a separate printing form in the printing unit or in one of the printing units. The sealing wax may contain solvents and / or fillers. The fillers may be, for example, silicates, talc, glass, polymers, etc. in granular or fine-grained form. It is also possible to use intumescent or expandable fillers. For example, by chemical initiators or by energy input such fillers increase their volume and a thin printed seal seam foams up or puffs up to the desired greater thickness. The sealed seam should have a thickness of 2 to 100 microns, suitably from 2 to 50 microns and advantageously from 2 to 20 microns. Since the sealing wax is incorporated in a solvent, there is a disadvantage in that, in order to achieve the stated layer thicknesses, a great deal of sealing wax should be printed and accordingly a great deal of solvent should be evaporated. In a fast-running printing process, the required evaporation rate may not be reached. Therefore, it is advantageous to use sealing lacquers with fillers.

The sealing edge may be delimited on its outside and / or on its inside by a stamping applied in the printing unit. The seam forming the sealing edge can consist of the sealing lacquer over its entire surface. It may be advantageous to provide the seam by interruptions, in particular labyrinthine, interruptions. Such interruptions in the seam of sealing wax form air channels. In the stack of lids, trapped air can escape between two lids or vice versa, air can penetrate through the air ducts between two lids and facilitate or enable the separation of the lid. If such a lid is sealed onto a container, the interruptions or openings close in the Sealing seam by melting the sealing wax under the pressure and the heat of the sealing tool and it is achieved a tight seal between the container and lid.

The printing material may be in the form of sheets, but preferably as rolls, ie wound up as a supply roll, roll or coil. The substrate is unwound continuously and fed to the press or the series of presses. For example, the substrate can be printed in one or more printing units with the colors and occasionally the sealing wax. Thereafter, the printing material or printing elements can be embossed on the printing material - as blank printing. After the printing and the embossing process in the press or the printing plates, the cover plates can be excluded from the substrate. This can be done by cutting, punching or other removal methods. It is possible to integrate the punching by a punching roller in the printing press or to combine the embossing and punching by an embossing roll with punching knives. It is also possible to arrange a separate punching device immediately after the printing press or printing presses. It can be a printing machine for the color and occasionally the sealing wax and a printing machine for attaching the embossing and a punching machine arranged one after another. Also, a printing press for the color and occasionally the sealing wax and a, advantageously register-controlled, printing press for attaching the embossing and punching can be arranged one after the other. A sequence is preferred, starting with printing by means of the ink-carrying printing forms or the color, then with a separate printing form applying the sealing wax, over the entire surface or as a seam, then with the or the embossing printing forms attach the embossing as a blank print on the substrate and then remove the cover plates from the substrate. Accordingly, the cover plates can be punched out of the printing substrate, for example by means of a punching roller arranged in the printing press or one of the printing presses downstream of the printing press, advantageously register-controlled, punching device. In the processing of the printing material and in particular in the case that the substrate is passed through more than one printing press, a controlled tension of the printing material is advantageous. It should be avoided that the substrate stretches or the embossments are stretched. The tension can, for example, via sensors, the speed of the printing press or printing machines, the punching device and / or the winding machine, respectively. the tensile force acting on the substrate, taxes, be influenced.

The present invention also relates to cover plates containing a stamped print motif, wherein the print motif in a printing unit by means of the printing elements or the print motif of a printing plate, in particular a printing forme on or on a forme cylinder, mounted.

Examples of substrates for the cover plates according to the present invention, are those whose print motif or printing element as embossing of the surface of the printing material 20nm (nanometers) to 500 microns, expedient of 20 microns, resp. 50 μm, up to 250 μm, advantageously from 70 μm to 200 μm and in particular from 80 μm to 200 μm, protrudes. Embossments of, for example, 20 nm (nanometers) to 200 nm, with a thickness of 10 to 100 μm, preferably 12 to 30 μm, for example for the design of holograms, can be applied to metal foils, such as aluminum foils. As a rule, the print motif image protrudes from the substrate on one side. If the embossing between two form cylinders or embossed from both directions, carried out, the embossing mutually correspondingly on each side of the substrate in the specified height protrude.

In particular, sheet-like materials can be used as printing material. Examples are metal foils, such as steel or copper foils, and in particular

Aluminum foils, plastic films, papers or cardboard. Other examples are

Composite films, laminates and laminates of plastics, of plastics and metal foils, of plastics and paper, of plastics and cardboard, of metal foils and paper, of metal foils and cardboard or of plastics, metal foils and paper or metal foils, plastics and cardboard.

If plastic films are used as printing materials or as part of printing substrates, e.g. suitable plastic films of polyvinyl chloride, polyamides, polyesters, such as polyethylene terephthalate (PET), polycarbonates, polyolefins, in particular polyethylene or polypropylene, oriented polypropylene (oPP), polystyrenes, etc. The plastic films can also represent copolymers. The plastic films may also be laminates formed from two or more layers by lamination, coextrusion, etc. The thickness of the individual plastic films or plastic layers can be from 10 to 250 μm, expediently from 12 to 100 μm and advantageously from 20 to 50 μm. The films can be transparent, translucent, opaque or colored. The plastic films may be sealable or be provided on one or both sides with a sealing layer or sealing wax. In some cases, plastic films are processed at elevated temperatures in the printing unit.

If films of metal, such as aluminum, steel or copper, are used as printing materials or in substrates, their thickness may be from 12 to 200 μm, advantageously from 15 to 100 μm and advantageously from 20 to 50 μm. The preferred aluminum foils may e.g. of pure aluminum with a purity of 99% to 99.9% or of an aluminum alloy, for example from the series δxxx, e.g. 8021 or 8014, be prepared. The material state of the aluminum can be soft to hard or hard toughened. The aluminum foils can be brushed on one or both sides, etched, dyed, anodized, neutralized, protective lacquered and / or lacquered.

Other substrates include laminates of metal foil underneath, of plastic films underneath or of plastic and metal foils. As an example

Laminates of an aluminum foil, which is coated on one or both sides with polyester films or with polyolefin films or laminated. SITUATE Nete substrates are also laminates or laminates of cardboard or paper and at least one plastic layer. The experts are such materials known eg as Mixpap. Between the individual layers of the laminates or laminates, adhesives, primers and barrier layers etc. may be arranged on a case-by-case basis, barrier layers and sealing layers, etc., on the outward-facing sides.

Other substrates are papers with basis weights of 80 to 300 g / m ² and suitably from 100 to 270 g / m ² . The papers can be laminated on one or both sides or luster-laminated.

Typical examples of printing materials have a layer sequence: Al 7 - 50 μm / PET 12 - 70 μm / Al 7 - 50 μm or Al 7 - 50 μm / PET 12 - 70 μm / Al 7 - 50 μm / oPP 12 - 70 μm , The substrates and the cover plates thereof, in particular, should have a high flatness and no tendency to curl, both before and after the pressure embossing. Symmetrical composites are particularly suitable in this regard.

At present substrates, the embossed print motif can be an embossing or protruding pattern. The embossing may be an optically protruding pattern, any number or sequence of letters, graphic elements, motifs, images, any repetitive pattern, e.g. Ornaments, damask or paisley pattern, etc. Hologram-compatible patterns can also be created. A cover or Braille label may be attached to coverslip substrates of the present invention. It is possible to attach to the substrate smallest imprints, such as picture motifs or fonts, in a picture or font height of 0.5 mm and smaller. The present invention also includes lid blanks with embossments, such as picture motifs or fonts, with a picture or font height of 0.5 mm and smaller.

The imprinted in the substrate print motif can weakening, a Lo tion and / or perforation. Of course, all mentioned imprints can be attached individually or in any combination to a substrate.

On a lid board the color-bearing print motifs and in particular the embossed print motifs are arranged substantially within the sealing edge. It is also possible to limit the sealing edge outside and / or inside with embossing.

According to the method of the present invention, the color motives, seal margins and embossments produced in at least one and especially in the same printing machine are applied to the substrate for the cover blanks. The printing plates, such as the forme cylinders with the engraved printing elements, can be produced in the same simple and cost-effective manner both for the ink-conducting and the embossing printing plates and the sealing edge and can be mounted or replaced in the press in the same simplicity and speed. This allows a quick and cost-effective change, both the colored print motifs, the contour of the sealing edge, as well as the embossments on the substrate.

The cover plates made from the printing materials produced according to the invention are used, for example, as packaging materials for objects of all kinds, including food packaging, such as cover plates for cups for yoghurt, cream, cream cheese and other milk products, cups and containers with food preparations and ready meals, pet food containers, packaging in medicine and pharmacy, drug packaging such as blister or blister packs, or packaging for smokers. If the substrates are processed into cover plates, the imprints can represent unalterable safety, origin and authenticity proofs on a covered packaging. The indentations can complement or enhance the printed image or print motif produced by printing ink through the optically raised elements. During the process of oppression may be on the substrate - in addition to or as embossing - weakening, for example as later tear-open or tear lines, such as perforations, or point or Brailleschriften, in particular in the register, ie in the correct position, are appropriate. Print motifs and optically elevated elements and / or weakenings can overlap one another. Since the individual elements in the same printing on the substrate in the register up, resp. be attached, the respective position of the elements to or above each other can be predetermined and after leaving the printing unit, the elements are at a predetermined location next to each other or one above the other on the substrate. For example, printing materials which are to be used as packaging materials may contain weakenings, such as perforations as tear-open aids or tear lines, and associated image motifs, such as information on the tear-open aid, and it is possible in the simplest manner to remove the cover plates from the printing material in a very precise manner. High-quality lid blanks are produced with respect to the superimposition of print motif, optically detectable elevations, sealing edge and tear-off aids.

It can not be ruled out that the embossed motifs of the individual cover plates fall into one another when stacking cover plates produced according to the invention. This may degrade machine unstacking in a device for covering, the mutual adhesive effect may occur. Depending on the selected print motif, it may therefore be advantageous to distribute the same print motif multiple times over the circumference of the first printing form, which generates the embossing. The print motifs are then expediently slightly shifted from one another or the print motifs differ in details barely perceptible to the eye. After punching and stacking the lid boards, the embossed motifs can not fall into each other and the desired beneficial effect of easy unstacking remains fully effective.

Claims

claims

1. Method for producing a printed and embossed cover plate,

characterized in that

a printed material in at least one printing unit printed the printed motifs of a printed circuit board printing plate by means of one or more printing forms and the embossed printing elements or print motifs of the Deckelpla- tine be imprinted by means of a printing plate or multiple printing plates and the lid board is excluded from the substrate.

2. The method according to claim 1, characterized in that the printing material in a printing unit, the colored print motifs of the lid board by means of one or more printing forms printed and in another

Printing the embossed printing elements or print motifs of the lid board are embossed by means of a printing form or multiple printing plates and the lid board is excluded from the substrate.

3. The method according to claim 1, characterized in that the printed material printed in at least one printing unit, the colored print motifs of the lid board by means of one or more printing forms and embossed in a further printing unit, the embossed printing elements or print motifs of the lid board by means of a printing plate or several printing forms and the cover plates are punched out of the printing material.

4. The method according to claims 1 to 3, characterized in that the cover plates are punched out of the substrate by means of a stamping roller arranged in the printing press or one of the or the printing press downstream punching device.

5. The method according to claim 1 to 4, characterized in that a Sealing edge of a sealing wax, essentially delimiting the cover plate is printed by means of another printing form on the substrate.

6. Process according to Claims 1 to 5, characterized in that the embossing printing form is a forme cylinder with printing elements engraved as recesses.

7. The method according to claim 1 to 6, characterized in that mounted in the formative printing cylinder printing elements with respect to the

Surface of the forme cylinder are engraved at a depth of 60 to 500 .mu.m, expediently from 60 to 250 .mu.m, advantageously from 80 to 200 .mu.m and in particular from 100 to 200 .mu.m.

8. The method according to claims 1 to 7, characterized in that the attached in the formative printing cylinder printing elements are engraved with reduced support grid or without support grid.

9. The method according to claims 1 to 5, characterized in that the embossing printing forme form a cylinder with a printing forme with protruding

Is printing elements.

10. The method according to claim 9, characterized in that the printing block mounted on the formative printing cylinder contains printing elements which are opposite to the surface of the forme cylinder from 60 to 500 .mu.m, suitably from 60 to 250 .mu.m, advantageously from 80 to 200 .mu.m and in particular from 100 protrude to 200 microns.

11. The method according to claims 1 to 10, characterized in that in the printing unit on the substrate, the embossments for the lid circuit forming, the printing elements of the embossing printing form are embossed as embossing, wherein the substrate between the forme cylinder and a Printing cylinder is embossed and the printing cylinder has the negative pressure elements of the printing form and the printing elements of the forme cylinder and the negative pressure elements of the printing cylinder are transferred simultaneously to the substrate.

12. The method according to claims 1 to 11, characterized in that in the printing unit, the printing elements or the print motif of the embossing printing form, the embossing for the lid circuit forming the substrate, as a protruding pattern, as a hologram suitable pattern or as a point or Braille is impressed.

13. The method according to claims 1 to 12, characterized in that in the printing unit, the printed image of the embossing printing form, the embossments for the lid circuit forming, the substrate is embossed as weakening, as a perforation or as a perforation.

14. cover plate, characterized in that the cover plate contains an embossed print motif, mounted in a printing unit by means of the printing elements or the print motif of a printing plate.

15. The cover plate according to claim 14, characterized in that the print motif of the surface of the cover plate 20 nm (nanometers) to 500 microns, suitably from 50 microns to 250 microns, preferably from 70 .mu.m to 200 .mu.m and in particular from 80 .mu.m to 200 .mu.m protrudes.

16, lid plate according to claims 14 and 15, characterized in that the cover plate is a metal foil, in particular a steel foil or an aluminum foil, a plastic film, a paper, a cardboard or composite films of plastics, plastics and metal foils, of plastics and paper, of plastics and cardboard, made of metal foils and paper

Metal foils and cardboard, of plastics, metal foils and paper or of plastics, metal foils and cardboard, containing or consisting of.

17. A cover plate according to claims 14 to 16, characterized in that the imprinted in the lid board print motif is an embossing, a protruding pattern, a hologram suitable pattern and / or a point or Brailleschrift.

18. lid plate according to claims 14 to 17, characterized in that the imprinted in the lid board print motif is a weakening, a perforation and / or a perforation.