This application claims Paris Convention priority of DE 103 12 153.6 filed Mar. 17, 2003 the complete disclosure of which is hereby incorporated by reference.
The invention concerns a machine for sheet-fed rotary printing or sheet coating comprising the features of the independent claim.
Corona treatment involves electric flaming at a high voltage. The ionised air between the electrodes corrodes the surface of the plastic material in response to ozone and oxygen, i.e. oxidation. Polar groups are generated on the plastic surface which are easy to wet.
In practice, corona treatment has advanced to one of the most frequently used methods for surface refinement. It increases the surface tension of polymeric films and foils, aluminium foils, laminated paper and cardboard as well as sandwiched materials before they are printed, glued or coated. This surface treatment improves adhesion between the layers to be connected or adhesion of the coating substance or color. The final effects of the treatment depend on various parameters such as the power of the electrodes, duration of discharge, type of material treated, temperature and moisture, possible impurities, surface morphology and mainly the minimum gap width.
The mechanical construction must be robust. The electrode segments must maintain their settings despite vibration of the system and other unfavorable conditions.
JP 591 31 460 A discloses a device for treatment of sheet-like substrates. However, full-surface corona treatment does not require precise, registered transport and therefore no gripper technology is used for the sheet transport. The flat sheets are transported on belts using vacuum and without grippers. Setting of the gap width is therefore straightforward, resulting in stable handling.
DE 100 41934 discloses a corona device which is used after the last printing mechanism. This reference does not address the problem of minimum gap width, since the gap width is less critical for this varnish coating of printed paper. This corona device is used at a completely different location than in the present invention.
Corona treatment of sheet-like materials in the printing industry is an established technology (DE 199 10 740, DE 198 43 955, DE 101 06 385). The gap width of a few millimeters includes the thickness of the substrate sheet plus a gas gap above the substrate surface to be treated.
The sheet-like substrates require gripper elements for exactly registered transport whose gripper backs must therefore be disposed several millimeters above the substrate surface. The gap width above the substrate surface to be treated is therefore too large for optimum corona treatment.
DE 100 39 073 represents the principal prior art and main reference point, wherein, despite the use of grippers, an optimum gap width is nevertheless obtained by providing a lifting device or gripper recesses.
The substantial disadvantage of this arrangement is that a lifting motion at high speeds is a problem per se and also includes the risk of vibrations. A drum with gripper recess is format-related and therefore relatively large and expensive due to additional insulation.
Moreover, drums of such large size cannot be integrated in the first printing or coating mechanism due to access problems.
A sheet acceleration path is required between the stacked feeder and the first printing mechanism. The printing cylinder moves constantly at the printing speed. The supply system must precisely guide the sheet, bring it up to the printing speed, and transfer it to the grippers of the printing cylinder.
This object has been achieved in many machines using pivoting grippers, disposed above or below the sheet.
Alternatively, a so-called ranger drum, stop drum system or suction drum system can be used. None of the above-mentioned feed systems can accommodate surface refinement systems, so-called e.g. corona treatment systems, for reasons of space.
These sheet substrates can be pre-treated in a separate working step, which involves additional cost and time. Moreover, the corona charge loses its effectivity with time.
In accordance with a press report by the company König and Bauer in “Deutscher Drucker” dated 13 Nov. 2003, the printability of e.g. plastic materials can be improved by installing an additional upstream corona tower. This arrangement requires great expense and space (grosso modo 75% of the price of a printing mechanism).
Alternatively, the printing material can be coated with a primer as primary coating, which necessitates an additional printing mechanism and associated dryers in the printing machine (see DE 100 04 997 A1). Printing machines having such equipment are therefore expensive.
It is the underlying purpose of the invention to develop a novel sheet supply system, with appropriate geometry, to exactly guide and bring the sheet up to the subsequent printing speed and to transfer it to the grippers of the printing cylinder, wherein the front side and/or the back side of the sheet is/are subjected to surface treatment, e.g. corona treatment, and without additional upstream drums, transfer cylinders or printing mechanisms.
This object is achieved in accordance with the present invention by a sheet supply system having the characterizing features of the independent claim. Reference is made to the dependent claims with respect to further important embodiment features.
Further details and advantageous effects of the invention can be extracted from the following description and the drawings which show embodiments of the inventive sheet printing machine.
The side view of the system shown in
Exact alignment is effected e.g. at a stopping moment approximately at 9, wherein the sheet is aligned in the peripheral direction e.g. via a conveying mark (not shown) and laterally e.g. via a side mark 8 before being accelerated e.g. by the drawing rollers 7.
A surface treatment system 6 is integrated in this system 2 arrangement such that the sheet can be treated from the top and/or from below, e.g. through corona treatment.
The feed system including its surface refinement system 6, e.g. a corona treatment system, drawing rollers and sheet alignment mechanisms can be adjusted in height by an amount X to permit deflection of the substrate at that moment when the sheet is guided to the stop within the grippers 5, in dependence on the paper thickness. Thicker substrates such as cardboard are introduced almost horizontally. For more flexible and curved substrates, the feed system 2 is downwardly adjusted.
The gripper strip 5 can be adjusted to produce a peripheral and diagonal register.
To ensure that the sheet flatly abuts on the cylinder shell of the counterpressure cylinder 11, one of the chambers can be loaded with suctioned air to facilitate slight slowing of the substrate.
The vacuum belts are sunk in this vacuum belt system 22 such that e.g. electrodes 12 can be integrated in an upper chamber and e.g. opposing terminals 13 can be integrated in a lower chamber to permit surface treatment such as e.g. corona treatment.
One particular feature of these feeders is their high speed and the fact that they permit processing of very thick materials (up to 4 mm thickness).
The upper processing cylinder 10 is part of the sheet-fed rotary printing or coating machine 3, wherein the system 2 and feeder 1 are connected upstream of the machine 3.
In one embodiment shown in
Number | Date | Country | Kind |
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103 12 153 | Mar 2003 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
5103733 | Drapatsky et al. | Apr 1992 | A |
5135724 | Dinter et al. | Aug 1992 | A |
6311616 | Kamoda | Nov 2001 | B1 |
6349641 | Bayer et al. | Feb 2002 | B1 |
6490974 | Wadlinger et al. | Dec 2002 | B1 |
Number | Date | Country |
---|---|---|
100 04 997 | Sep 2000 | DE |
100 39 073 | Feb 2002 | DE |
100 41 934 | Mar 2002 | DE |
101 06 385 | Apr 2002 | DE |
591 31 460 | Jul 1984 | JP |
Number | Date | Country | |
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20040245712 A1 | Dec 2004 | US |