EP1348547B1 - Method for maintaining image information on imaged printing forms - Google Patents

Abstract

The method has image information recorded on a printing plate via regions having differing surface characteristics by application of an ink (31) in accordance with the image information and use of a photocatalytic effect for provision of hydrophile regions (20) in the uncovered areas and lipophile regions (30) in the covered areas. Also included are Independent claims for the following: (a) a device for recording image information on the surface of a printing plate; (b) a rotary offset printing machine

Description

The present invention relates to a method for obtaining image information of an imaged printing form.

Newspapers are mainly produced in wet offset. Printing machines, as it relates to the present invention preferably, typically contain printing units with blanket cylinders, plate cylinders, inking units and dampening units. A printing form stretched onto a printing form cylinder usually has a surface in the form of a top layer, which has hydrophilic (water-friendly) and hydrophobic (water-repellent) or lipophilic regions in the imaged state. Usually, the printing form is formed by a printing plate, which is mounted on a plate cylinder designed as a plate cylinder. The printing form has imagewise applied lipophilic areas. The non-image sites are hydrophilic and bind water more than the color used for printing. The lipophilic areas repel water and therefore have a color-friendly effect. In principle, any surface can be used for the offset process, which can be divided into hydrophilic and hydrophobic or lipophilic areas.

In the following, an imaging is understood to mean a process in which the printing form is acted on at the points which form the pixels, so that a template corresponding to the printed image is produced on the printing form by forming hydrophilic and lipophilic regions. For the purposes of the invention, a deletion is understood to mean a process in which the printing form is preferably treated, not as a function of the image, but over the entire surface in such a way that the image information applied in the imaging, that is to say the printed image, is removed again.

For the production of suitable printing plates or printing plates exist a variety of materials and methods. For example, it is possible to imagewise irradiate a printing plate with a laser and then develop it chemically. Also, printing forms can be produced by laser ablation. In this case, either lipophilic areas under a hydrophilic layer or hydrophilic areas under a lipophilic layer are exposed. Also, e.g. With an ink-jet process or by thermal diffusion imagewise applied material to a surface, thereby creating an offset printing form. The decisive for the imaging of the printing forme process can either be done in a separate system or within the printing press.

Immediately used in mass production printing forms are used only once. However, methods are also known for repeatedly imaging and deleting printing forms. When deleting the surface properties of the printing plate are influenced so that the printing plate is made evenly over the entire surface evenly hydrophilic or hydrophobic by erasing, so that it can be used again for a re-imaging process.

H. Kipphan: Handbuch der Printmedien, Springer Verlag 2000, Chapter 4.4, Computer to Press / Direct Imaging, pages 654-686, provides an overview of materials and mechanisms of action to image printing forms by creating hydrophobic and hydrophilic areas of different colors.

It is difficult to achieve high requirements with the erasable printing plates produced from known materials and with the known imaging and erasing methods, as they occur, for example, in newspaper printing. Because in the course of print production, it may happen that the hydrophilic or hydrophobic made areas of the printing form in an imaging lose these surface properties gradually. As a result, there may be a reduction in the contrast of the printed image. For example, cloning may occur as the hydrophilicity of hydrophilicized areas decreases and these areas progressively assume more ink used for printing.

The above problems exist not only with wet offset, but also with dry offset. Even with dry offset, the printing process is based on the different color transfer of image-wise areas. It is known that the print quality, in particular the print run stability, depends strongly on the observance of the production parameters, for example the temperature. Although the color transfer or repulsion is not based on the different hydrophilicity or hydrophobicity of the printing plate. Nevertheless, a dry offset printing process relies on interfacial processes. Thus, even in dry offset, the preservation of the surface properties of a printing form is of crucial importance for achieving high runs.

From US 4,718,340 a "Printing Method" is known, with reusable printing surfaces on which an image can be formed, refreshed or completely redesigned without having to interrupt the printing process. For this, the printing surface must be largely free, ideally completely free of ink and dampening solution. EP 0 402 942 A2 describes the printing of very fine structures. For this purpose, the smallest recesses are formed in a printing plate, which can be filled with ink and transferred to a medium to be printed. DE 196 12 927 describes a printing machine and an image forming method for a printing press. The printing press has printing cylinders which have a convertible material surface on which multiple image patterns can be formed and erased. It is acted on the convertible pressure surface only before the beginning of the pressure. Not included is exposure to the surface during printing to maintain or refresh the different surface properties, thereby allowing for consistent print product quality even for large runs.

The object of the present invention is to provide a method to enable the preservation of image information of a printing plate in a simple manner and thus to enable the printing of long runs. A preferred application relates to the preservation of image information of erasable printing forms, preferably in offset printing, more preferably in wet offset printing.

This object is achieved by a method having the features of claim 1. Preferred developments are the subject of the dependent claims.

According to the invention, the image information of an imaged printing form is maintained by acting on the imaged printing form with the color transferred to it in such a way that surface properties of the printing form corresponding to the imaging are obtained or refreshed. It is advantageous that the rewritable printing form for maintaining a sufficient print quality is not first deleted and then reimaged with fresh image information, but the surface properties that are responsible for color transfer, print quality, etc., are maintained during production or refreshed again , The inventive method thus enables high print runs while maintaining print quality. Since the printing form used must not be erased and rewritten or replaced by another printing form, production can preferably be made without interruption while maintaining print quality.

Thus, the differently hydrophobic and hydrophilic areas of the printing plate responsible for the image formation are influenced so that the hydrophobic and hydrophilic properties of imagewise areas of the imaged printing plate with the ink transferred thereto are modified according to the strength of the action on the printing plate, so that overall the imaging on the printing form is maintained. Very particular preference is given to influencing the surface properties of the same by the action on the imaged printing form, which in turn may have an influence on image transfer properties and / or ink adhesion properties of the imaged printing form, the effect being such that the achievable print quality remains substantially constant.

According to a particularly preferred embodiment, the action on the imaged printing plate takes place during production at a plate cylinder rotating essentially at normal printing speed, so that no slowing down of the current production occurs. Basically, however, the impact can also during a comparatively short stoppage of production, without the image being deleted and the printing form being reprinted. Rather, the printing form cylinder is rotated comparatively slowly, while the action on the printing form to maintain the responsible for the print quality surface properties of the printing form.

The action on the printing form during production is possible, for example, when the image data forming the printed image is transmitted to actuators or process means which, in correspondence with the transmitted image data, are directed specifically to the image sites or to the non-image sites of the printing form or printing process The hydrophobic or hydrophilic areas act. Examples of such action mechanisms are described in the Handbuch der Printmedien by H. Kipphan, supra, so that details may be omitted for reasons of clarity. The image-wise action is particularly preferably carried out during production with essentially stationary or only slowly rotating printing form cylinder, since the currently known actuators can act only comparatively slowly on the printing plate.

According to a very particularly preferred embodiment, however, the action during production takes place essentially over the entire area of the printing form. This is described by way of example with reference to a wet offset printing process in which, as is known, the image areas or hydrophobic sections of the printing form are affixed with a color layer during the printing process, whereas the non-image areas are not covered with printing ink. In the case of the wet offset printing process, the action mechanism can be chosen such that the hydrophobic and hydrophilic sections of the printing form are influenced differently due to the applied ink layer, wherein the applied ink layer is utilized for the required differentiation of the action mechanism.

If, for example, an optical radiation acts on a printing form that responds to optical radiation during printing, the influence of the optical radiation on the non-image areas differs from that of the image locations because the radiation is imagewise filtered because of the color layer applied to the printing form. Despite the whole area Irradiation of the printing form is thus due to the overlying color layer automatically an imagewise different influence on the image locations and non-image areas of the printing form.

For example, in wet offset two effects come into play, which can be further influenced by suitable additives in printing ink and dampening solution. If, for example, a printing plate is used whose hydrophilicity was brought about by optical radiation, in particular UV radiation, then radiation, in particular in the UV range, acts in such a way that the hydrophilicity is retained. Since the non-hydrophilic or lipophilic image areas are covered with the printing ink, the effect of the radiation, in particular of the UV radiation, on these areas is lower (for example due to absorption or scattering effects in the printing ink). Thus, there is automatically an imagewise preservation of the surface properties of the printing plate.

This effect is enhanced when optical radiation is applied to the printing form whose frequency is in an absorption band of the color used for printing. By suitable choice of the maximum of the absorption band, the spectral width of the absorption band and the frequency of the optical radiation used, the visual preservation of the interface properties of the printing form can be optimally adapted to the operating conditions.

The aforesaid radiation absorption can also be used to suppress the hydrophilization of these areas due to local heating due to absorption in the color areas above the image areas. In principle, optical radiation having other wavelengths, for example wavelengths in the visible wavelength range or in the infrared wavelength range, can also be used for such locally different heating, as long as the optical radiation of pigments or other constituents of the printing ink used, for example additives, is sufficiently absorbed. These additives can z. B. absorb only in the UV range and thus have no effect on the print quality.

According to a preferred embodiment, a printing plate is used in which a permanent hydrophilization can be achieved on the surface, for example by photocatalysis. From the co-pending German patent application DE 101 15 435.6 of the applicant, a printing forme is known, which can be rendered hydrophilic by UV radiation. This leads to an excitation of the atoms in a higher energetic state, which allows an interaction with water molecules of the environment. In the presence of water in the environment, such as fountain solution, it will bind the water to the surface of the printing plate, thereby retaining the hydrophilicity even after the irradiation is stopped. However, if there is no water in the environment, they return to their original energetic state and do not remain permanently hydrophilic. If such a printing form is used according to the invention in a wet offset printing process, the non-image areas are covered with a water film, whereas the image areas are covered with an oily color layer which contains only relatively little water. If such a printing form with image-adhering ink over its entire surface with optical radiation, in particular UV radiation, irradiated, the UV radiation reaches not only the color-free non-image areas, but also passes through the ink layer through to the image locations (apart from absorption - and scattering effects) and can in principle stimulate the surface of the printing plate. However, comparatively little water will be present in the image areas, that is to say the areas of the printing form covered with ink, in the surroundings of the surface, so that permanent hydrophilization can not be effected at these locations. However, at the non-image areas covered with a water film, a permanent hydrophilization can be effected or these can be refreshed again. Thus, according to the invention, despite full-surface exposure to the offset printing form, image-wise refreshing or obtaining of the image information of the imaged printing plate is achieved. Thus, the relevant for the print quality surface properties of the printing form can be maintained.

In principle, the wavelength of the optical radiation, the absorption wavelength of the printing ink and the width of the absorption of the color are available as parameters. These parameters can be changed by changing the wavelength of the light or using Adjustments to the color to be adjusted in order to allow an optimal image refreshing of the imaging with full-area irradiation of the printing plate.

In order to obtain the imaging of the printing for full-surface exposure, in principle, other physical and chemical effects can be used. For example, an electric field or an electrostatic potential may be applied to the surface of the printing form, for example by means of a high-voltage electrode which is arranged at a uniform, small distance from the surface of the printing form. The effect of an electric field or electrostatic potential is different on image sites and non-image sites and can be exploited according to the invention. Additives can render the dampening solution used in the wet offset printing process conductive, so that charges which form on sections of the printing form surface which are not covered with ink can be diverted, while the insulating, oily printing ink without such an additive prevents discharges of charges. Thus, the insulating, oily ink remains electrostatically charged. Thus, despite full-surface exposure to the printing plate by means of an electric field or electrostatic potential imagewise action can be achieved, so that, for example, the ink adhesion properties and / or the image transfer properties of the printing plate to a downstream roller, such as blanket cylinder, are imagewise modifiable.

Also, the surface of the printing form can contain ferroelectric materials, for example ceramics, multilayer ceramic systems or also polymers, as are known for direct imaging systems of the prior art. By applying a sufficient electric field strength, the orientation of the ferroelectric materials can be changed pixel by pixel. Due to the known hysteresis curve, which describes the dependence of the polarization on the electric field strength, the ferroelectric material can usually be in three excellent states, which are referred to as electrically positive, electrically negative and neutral, and between which the material can be switched back and forth , where the states are each stable. In principle, the ink layer adhering to the printing form may be in the form of a dielectric Be treated layer. The dielectric constant of the ink layer can be further enhanced by dielectric additives. Thus, the acting dielectric displacement D is different at image sites and non-image sites, so that despite full-surface application of an electrostatic potential or electric field imagewise influencing the surface properties of the printing plate can be effected to imagewise modifying Farbhaftigenschaften and / or image transfer properties.

Even by applying the entire surface of the printing form surface with chemical substances and / or gas and / or vapor, a pictorial action on the printing form can be achieved. For this purpose too, use is made of the fact that the ink applied to the printing form adheres to it imagewise, so that image areas are covered with a color layer, while non-image areas are essentially not covered. Thus, the chemical substances, the gas or the vapor can only come in contact with the surface of the printing form at the non-image locations or in wet offset printing in contact with the moisture film above it. According to the invention, the applied chemical substance, the gas or the vapor should be chosen such that interface properties of the printing form are modified at these points in such a way that the information (non-image point) is retained locally. Suitable chemical substances, gases or vapors will be apparent to one skilled in the art upon studying this application.

Of course, this mechanism of action can also be combined with other mechanisms of action. Thus, for example, the chemical substance in the form of a liquid or as an additive to a liquid sprayed over the entire surface or applied over the entire surface by means of a dampening unit. Due to the imagewise applied ink layer, the liquid comes into contact only at the non-image areas with the surface of the printing plate. If the printing form is chosen so that hydrophilization of the surface can be effected by photocatalysis or other optical effects, then the liquid required for the hydrophilization is automatically available at the non-image sites. By appropriate irradiation, thus, the hydrophilization at the non-image sites can be suitably obtained.

Another example is the supply of airflow to the surface of the printing plate. In particular, in wet offset can be promoted by means of an air flow, the evaporation of fountain solution, which rests on the non-image areas. At these points, the printing form is thus removed from the heat of evaporation and cooled the printing form surface locally. The cooling effect is less at the image points if the ink evaporates less strongly, and stronger if the ink contains volatile substances. Despite full-surface exposure of the printing plate surface with the air flow thus imagewise influencing the relevant parameters for the print quality can be achieved, for example, the ink adhesion properties and / or ink transfer properties of the printing plate.

Of course, the air flow may be mixed with a chemical substance which enhances or alleviates the aforementioned effects.

Fig. 1

schematisch ein Verfahren gemäß der vorliegenden Erfindung darstellt;

Fig. 2

einen vergrößerten Ausschnitt der Druckform gemäß Fig. 1 darstellt; und

Fig. 3

schematisch ein Druckwerk einer Nassoffset-Rotationsdruckmaschine darstellt.

The invention will now be described by way of example with reference to the accompanying drawings, in which:

Fig. 1

schematically illustrates a method according to the present invention;

Fig. 2

an enlarged section of the printing form of FIG. 1 represents; and

Fig. 3

schematically represents a printing unit of a wet offset rotary printing machine.

Fig. 1 shows schematically a method according to the present invention. On a support of the printing form 1 are imagewise applied hydrophilic region 20 and hydrophobic regions 30, which are formed by known methods on the printing plate. For example, the printing form 1 can have a photocatalytically and / or thermally changeable material, as disclosed, for example, in DE 101 15 435. The hydrophilic and hydrophobic regions can also be produced, for example, by laser ablation, ink-jet processes, toner application, polarization of ferroelectric materials of the printing form or by locally different image-wise heat input. In a wet offset printing process, as exemplified by FIG. 1, a water layer 21 is located on the hydrophilic areas, while a color layer 31 rests on the hydrophobic areas 30. On the surface of the printing plate 1 is in shape the differently hydrophilic and hydrophobic regions 20, 30 applied an imaging corresponding to the current print production, in particular in the form of areas of different surface properties.

Near the surface of the printing form 1 is a process means 40, which acts on the surface of the printing form 1 to obtain or refresh the image information of the imaging of the printing form 1. As shown in FIG. 1, the process means 40 comprises a number of processing means 41, which are preferably arranged in the axial direction of the printing form 1 at a substantially constant distance therefrom in order to ensure uniform action on the printing form 1.

According to a first embodiment, the processing means 40 can act imagewise on the printing form 1. As a result of the action, the hydrophilic properties of the hydrophilic region 20 can be refreshed or obtained and / or the hydrophobic properties of the hydrophobic regions 30 can be maintained or refreshed again. The image information required for this purpose is applied to the process means 40 in a known manner, for example as a bitmap file, and serves for imagewise control of the process means 41 serving as actuators, which act locally on the printing form surface in accordance with the image information of the imaging.

According to a second embodiment, the process means 40 acts on the surface of the printing form 1 over the whole area. Since the surface of the printing form 1 includes both areas covered with a coloring layer 31 and areas not covered with a coloring layer, for example, portions covered with the fountain solution film 21, the action on the surface of the printing form 1 locally becomes different be. Thus, in spite of full-surface impact automatically imagewise acted on the surface. The physical and / or chemical effect underlying the action only has to be chosen such that the action is attenuated or intensified by the ink layer 31 adhering to the surface of the printing form 1. Suitable physical and / or chemical effects will become apparent to those skilled in the art upon studying this application.

According to a preferred embodiment, the process means 40 is a light source with a number of individual light sources 41 (for example LEDs or laser diodes with associated imaging optics) which irradiate the surface of the printing form 1 uniformly and over the entire surface. The light source 40 is aligned in a strip parallel to the printing form 1 and illuminates a strip-shaped portion of the printing form 1. The irradiation causes a locally different modification of print quality relevant parameters, such as the ink adhesion properties and / or ink transfer properties of the printing form 1. This is required in that interfacial properties of the printing form 1 are suitably modified by the interaction of the printing form surface with the optical radiation 42. For this purpose, the printing forme 1 preferably comprises a material which, by irradiation with light, is photocatalytically displaceable into a hydrophilic state and thermally, namely by heating, into a lipophilic state. At the sections covered with the water film 21, the optical radiation 42 passes substantially unhindered onto the surface of the printing form 1. At that point, atoms are locally excited to higher energetic states. This results in an interaction with the environment, namely in the water film 21, existing water molecules. As a result, the hydrophilic properties of the sections 20 are refreshed and maintained. However, the ink layer 31, which contains relatively few water molecules, prevents sufficient water molecules from being available at the regions 30 in order to be able to effect hydrophilization of the surface sections 30 by means of the photocatalytic effect. Thus, the hydrophobic regions 30 remain hydrophobic. A possible hydrophilization of the regions 30, for example due to residual moisture in the printing ink, can be even more inhibited if the wavelength of the optical radiation 42 is chosen so that it is in an absorption band of the dye contained in the ink layer 31 and / or a therein Addition lies. Most preferably, the optical radiation 42 is UV light and is said absorption band in the ultraviolet spectral range. Despite full-surface irradiation of the surface of the printing form, the imaging can thus be obtained or refreshed again. In the enlarged partial section according to FIG. 2, this effect is more clearly recognizable.

The action on the printing form 1 with the aid of the process means 40 can be continuous or discontinuous. For example, a fixed program may specify that the action be turned on at constant time intervals or after printing a predetermined number of copies or a predetermined length of substrate for a given time interval. The time interval can be varied depending on characteristics of the current print production.

Both in a continuous and in a discontinuous action on the printing plate 1, the strength and / or duration of the action can be adjusted by means of an automatic control or regulation. For example, an operator can determine the conditions of the action, in particular strength and / or duration; initially set manually, in accordance with the expected or achievable production conditions. Then the further setting of the relevant parameters of the automatic control or regulation can be transferred. This automatically makes an adjustment of the strength and / or duration of the action based on measurements. The parameters to be set depend on the action mechanism underlying the action. If the action takes place, for example, with the aid of optical radiation, then the wavelength and / or intensity and / or focusing and / or polarization and / or duration and / or modulation of the optical radiation can be varied.

The following are examples of some metrics that can be used as an input to the control: printed copies or the printed web can be measured using optical sensors to assess the print quality; For this purpose, with the knowledge of the printed image information, it is possible to measure selected sections by means of which the print quality can be suitably assessed. Examples are little or no sections to be printed, which give information about the so-called toning of the printing plate or the blanket cylinder. Another example is transition areas between low-printed areas and heavily printed areas, from which contrast information can be derived. Another example is test patterns that are printed, for example, at the edge of the current print production. Measurements can also be taken directly from the printing form are derived and later removed, for example, can be separated. For example, the electrostatic charge of the printing form can be measured or the light scattering or the degree of coverage of the printing plate surface with color can be measured by reflection measurement in order to obtain information about the surface properties of the surface of this printing plate.

According to a further embodiment, the action may also be based on a different physical and / or chemical effect. Suitable mechanisms of action will become apparent to those skilled in the art upon study of this application. In particular, by applying an electric field or electrostatic potential and / or a magnetic field to the printing plate 1 and / or by the action of heat and / or a gas and / or blown air and / or a liquid and / or a vapor on the printing form. 1 the image obtained in the aforementioned manner or be refreshed.

Fig. 3 shows schematically a printing unit for the inventive method. This comprises a printing form cylinder 52, an associated blanket cylinder 58 and an impression cylinder 59, which forms a printing gap for a web 57 to be printed with the blanket cylinder 58. On the printing form cylinder 52, two pressure plates 51 are fixed in a known manner. However, each of the two printing plates 51 is formed by a printing plate according to the invention, as shown for example in FIGS. 1 and 2. Distributed over the circumference around the printing form cylinder 52 are arranged in the printing machine an imaging device 53 for imaging, inking rollers 55 and a dampening roller 56. About the dampening roller 56 in a known manner a dampening solution film, preferably a water film, brought to the printing plates 51. By means of the inking rollers 55 imagewise ink is transferred to the printing plates 51 during printing in a known manner, which is first transferred from the hydrophobic or lipophilic image locations of the printing plates 51 on the blanket cylinder 58 and from there to the printing substrate 57. The counter-pressure cylinder 59 may itself be a blanket cylinder of another printing unit for double-sided printing, a steel cylinder for only a single pressure point or a steel cylinder of a satellite printing unit, for example a 9 or 10 cylinder printing unit.

Furthermore, a process means 54 is provided, which acts on the printing form cylinder 52 in the aforementioned field. In addition, erasing means (not shown) may be provided in known manner to erase the artwork on the printing plates.

The process means 54 is directly facing the surface of the printing forme 51 to be imaged and arranged parallel to the axis of rotation of the printing forme cylinder 52. Thus, a full-surface impact on the surface of the plate cylinder 52 can be achieved. During imaging and print production, the quenchers, not shown, are turned off. During the print production, the process agent 54 continuously or discontinuously acts on the surface of the plate cylinder 52 in the manner described above to refresh the image provided on the printing plates 51. The refreshing or preservation of the imaging is preferably carried out at substantially with the normal printing speed rotating printing plate cylinder 52. The print production can also be interrupted for a short time and the rotational speed of the plate cylinder 52 significantly lowered or brought to a standstill with the aid of the processing means 54, the imaging to refresh or receive again. This procedure is particularly suitable for a pictorial refreshing or preservation of the imaging, so that the duration of the action can be sufficiently selected. Also, for refreshing or preserving the imaging, the erasers, not shown, preferably remain switched off and an ink layer is applied to the image areas, which allows the image conservation or refreshment of the invention despite full-surface exposure to the plate cylinder 52 and the printing plates 1.

Claims (13)

1. A method for maintaining image information of an illustrated printing block (1) which comprises regions (29, 30) having different surface properties, wherein in said method:

   a) colour (31) is transferred onto the illustrated printing block (1) in accordance with an illustration;

   b) the illustrated printing block (1), onto which the colour (31) has been transferred, is acted on over its entire area, in order to maintain the surface properties of the printing block in accordance with the illustration, wherein

   c) a colour layer applied to the printing block (1) by means of the colour (31) is used to differentiate the action mechanism from region to region.
2. The method according to claim 1, wherein the action modifies hydrophobic and hydrophilic properties of image regions of the illustrated printing block in accordance with the strength of the action.
3. The method according to any one of the preceding claims, wherein the action influences boundary area properties of the printing block (1), in order to modify the image transfer properties and/or colour adhesion properties of the illustrated printing block (1).
4. The method according to any one of the preceding claims, wherein the action is exerted during production while the printing block cylinder (52) bearing the illustrated printing block (1) is rotated substantially at its printing speed.
5. The method according to any one of claims 1 to 3, wherein the action is exerted during production while the printing block cylinder (52) bearing the illustrated printing block (1) is substantially at rest or is only rotated slowly.
6. The method according to any one of the preceding claims, wherein the action is exerted continuously or discontinuously.
7. The method according to any one of the preceding claims, wherein the strength and/or duration over time of the action can be set.
8. The method according to claim 7, wherein the strength and/or duration over time of the action is set by automatic control or regulation.
9. The method according to claim 8, wherein said control or regulation is performed on the basis of an evaluation of printed specimens or a printed web.
10. The method according to any one of the preceding claims, wherein electromagnetic radiation, in particular radiation in the optical wavelength range, is used for the action.
11. The method according to claim 10, wherein the electromagnetic radiation comprises at least UV portions.
12. The method according to claim 10 or 11, wherein the radiation comprises spectral portions in an absorption band of a colour which is used and transferred onto the printing block (1).
13. The method according to any one of the preceding claims, wherein the action on the printing block (1) is exerted by applying an electric field or electrostatic potential and/or a magnetic field to the printing block (1) and/or by the action of heat and/or a gas and/or blast air and/or a liquid and/or a vapour on the printing block (1).

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