EP2258553A1 - Device and method for drying paint on a printed substrate - Google Patents

Abstract

The dryer has an irradiation device for irradiating a printed substrate (1), which includes multiple radiation elements for every sheet or side of a web. A controller is provided for individually controlling the radiation elements. The radiation elements are arranged in a line-by-line or plane manner. Independent claims are also included for the following: (1) a rotary printing machine for printing on webs; (2) a method for controlling a dryer; and (3) a program for executing a dryer controlling method.

Description

The present invention relates to an apparatus and a method for drying paint on a printed substrate or a color-printed substrate with features according to the main claim.

When drying ink applied to a printing substrate or a substrate, in particular a web or a side of the substrate, in a printing process, in particular web printing or web printing, the problem often arises of making the drying efficient with respect to the printing speed. For example, it is necessary to match the drying energy and the residence time of the substrate in the drying device to one another such that sufficient drying of the ink can take place at an acceptable printing speed.

The DE 20 2008 005 106 U1 For this purpose, a printing machine with a dryer arrangement arranged in the web travel path of the printing material web in the printing press immediately after the printing unit for drying the printing material web at least in sections in the width direction of the printing material web is disclosed. The drying intensity caused by dryer units of the printing machine is adaptable, and the dryer units can also be made partially wide, side-wide or in other meaningful widths and then placed side by side or offset in the printing material web. Furthermore, according to this document, it is also possible to use partially-wide drying units which are realized movably over the web width. In the case of several, in the running direction of the printing material behind or next to each other arranged dryer units, these can also be designed separately switchable. According to a further embodiment of this teaching, it is advantageously possible to dry the printing material web in the width direction in sections with different intensities. However, the above-mentioned desire for a more efficient design of the ink drying is only partially met, since the expert is not explained how either an increase in the drying intensity per Area unit of the substrate web or a reduction in the speed of movement of the printing substrate can be controlled here so that a shorter residence time of the printing material in the dryer assembly, which includes a plurality of dryer units, could lead to a more efficient drying of the paint.

The object of the invention is therefore, a more efficient drying of the ink bzs. To achieve the color printed substrate. This object is solved by the subject matter of the independent claims. Advantageous embodiments of the invention will become apparent from the dependent claims. Features of different embodiments of the invention may be combined between different embodiments.

The word "or" is understood in the context of this invention in the usual logical sense as "inclusive or", ie includes the meaning of "either ... or" and also the meaning of "and", as far as the respective concrete context can give only a single one of these meanings.

The invention relates to a dryer for drying ink on a printed substrate or on a substrate printed with the ink, namely a web or sheet of a web-fed printing press or sheet-fed press, wherein the dryer at least one irradiation device for irradiating the substrate, the plurality of irradiation elements per sheet or side of the web, and includes a control device for individually controlling the irradiation elements.

The applied printing method can also be an offset printing method or wet-offset printing method. According to the invention, it is also possible to use it for newspaper printing (in particular for the production of large print runs) or for printing processes in which the web speed is greater than or equal to 10 m / s ,

The substrate in particular provides a printing substrate or a material to be printed, which may in particular comprise a paper or a cardboard and / or a film. The dryer is suitable for use in web presses or web-fed rotary presses or sheetfed presses (especially newspaper presses), but can be used in Connection with other types of printing machines are used. The substrate advantageously passes through the printing machine during the printing process, ie it moves relative to it. The substrate is thus introduced into the interior of the printing press for printing. In the dryer, the substrate is advantageously opposite the irradiation elements or is moved opposite them through the dryer or relative to the dryer. A position in which substrate can be dried with respect to the irradiation elements, depending on the geometric arrangement, is also referred to below as the drying position.

The dryer can be designed to dry the ink with the aid of electromagnetic radiation, which can be in the ultraviolet spectral range and / or the visible spectral range, for example. For this purpose, the irradiation device can comprise irradiation elements, which in particular have at least one light-emitting diode or LED and / or laser diode. Preferably, the irradiation device comprises an array or a planar arrangement of a plurality of such diodes. The dryer may also be designed to dry the ink with the aid of electromagnetic radiation, which may be in the infrared spectral range, for example. For this purpose, the irradiation device can comprise irradiation elements, which are in particular designed as heat radiators and have, for example, a heating coil or a heating wire. The heat radiator may, however, also have at least one light-emitting diode or LED and / or laser diode emitting in the infrared spectral range. The dryer can be designed to dry the ink with the aid of electromagnetic radiation, which may be in the microwave range, for example. For this purpose, the irradiation device can comprise irradiation elements, which are in particular designed as microwave transmitters and have, for example, a dipole or a dipole antenna and / or an electromagnetic coil. Also possible according to the invention is a formation for drying by means of an electron beam method, for which purpose the irradiation elements can have an accelerating device for electrons. Furthermore, drying by means of hot air irradiation is possible, for which purpose the irradiation elements can be designed as air nozzles or hot air nozzles. Induction drying is also possible with the dryer according to the invention, wherein the drying takes place by means of electromagnetic radiation which inductively heats magnetic particles contained in the paint. For this purpose, the irradiation elements as magnetic Excitation device (which has, for example, an electromagnetic dipole or a dipole antenna and / or a coil and / or an electromagnet) may be formed. A combination of the different types of drying methods and irradiation elements is also possible according to the invention.

The irradiation elements are advantageously punctiform irradiation elements, ie irradiation elements, which in particular have a small spatial extent, in particular in comparison to the area of the printed substrate to be dried or to its width (ie to its geometric extent extending transversely to its direction of movement in the printing machine). The direction of movement of the substrate in the printing press is also referred to below as the conveying direction. Advantageously, the irradiation elements are provided in a tight arrangement in the following conveying direction and / or transversely to the conveying direction. A dense arrangement is understood in particular to mean that a plurality of, advantageously a plurality of irradiation elements per unit area of the printed substrate are arranged. The unit area of the substrate is understood to be that area which reproduces the printed portion on the surface of the substrate (in particular on the printed and to be dried side of the substrate). The radiation-emitting surface which is available in the irradiation device is therefore advantageously larger than the printed surface of the substrate ... The irradiation elements are advantageously arranged line by line and / or in a planar manner. In the case of a line-by-line arrangement, the arrangement may also be referred to as one-dimensional, a row-by-row arrangement means in particular a linear arrangement of a single row of irradiation elements either in the conveying direction or transversely thereto. However, the line-wise arrangement can also not be linear but additionally or alternatively curved, advantageously in a plane curvilinear. However, the row-wise arrangement can also extend on a curved surface, for example linearly circumferentially and / or linearly axially on a cylinder jacket. A planar arrangement designates in particular a two-dimensional arrangement and can also be referred to below as an array. Such an array thus designates in particular a planar, in particular polygonal and / or round or by a curved line limited (but in particular rectangular limited) arrangement of the irradiation elements. The irradiation elements can be arranged in a plane, but also on a curved surface. According to the invention is possible also a row-wise and / or planar arrangement of the irradiation elements in a direction which runs diagonally (ie in particular neither at right angles nor in parallel) to the conveying direction. Advantageously, the irradiation elements are arranged regularly, ie with uniform or uniform distances, in particular to their nearest neighbors.

Advantageously, at least two, preferably even more, irradiation elements are provided on a surface which, when the dryer is in operation, oppose the substrate or should dry the substrate or the ink printed on it. Advantageously, sufficient irradiation elements are arranged on this surface to allow the entirety of an arc or a side of the substrate at once, i. H. in particular during a single drying pass or while the total area (i.e., in particular length and width) of a sheet to be dried or a side to be dried is in the drying position. The drying takes place in this case then takes place, for example, by a plurality of lines of irradiation elements or an entire array, which are or are then driven in accordance with the printed image and the entire image is dried or dried at once. In addition to the above definition, a drying position is in particular a position in which the substrate is opposite to the irradiation elements or is moved through such a position relative to the irradiation elements. The term "drying position" in the context of this invention can also be understood as describing a position of the substrate in which the substrate is exposed or irradiated with the radiation intended for drying the ink.

The control device advantageously comprises a processor (in particular an electronic, advantageously digital processor or a CPU) and a random access memory (RAM) or an electronic data processing device, in particular a commercially available computer. Advantageously, there is a data connection between the control device and the irradiation device or the irradiation elements, wherein the data connection can run via data cable or also wirelessly (in particular via a radio network or WLAN).

Advantageously, the control device is configured to control the irradiation device in such a way that the irradiation elements irradiate the substrate in accordance with the printed image. This includes, in particular, selective drying of the surface of the printed substrate so that drying takes place only for the color-printed parts of the substrate. As a result, energy-saving and efficient drying of the substrate surface is promoted, as no energy is expended to dry or heat unprinted surface portions of the substrate. In addition, thereby an excessive material stress on the substrate, which can become brittle, for example, by the drying process, avoided. For this purpose, the control device controls the irradiation device or the irradiation elements such that there is a temporal and / or spatial change in the intensity and / or wavelength of the radiation emitted by the irradiation elements. The temporal and / or spatial variation of the intensity advantageously comprises switching on and / or switching off the irradiation elements so that radiation is emitted or not emitted by them. Advantageously, however, the change in intensity can also include a stepless change in the intensity between irradiation with maximum intensity and non-irradiation (that is to say a switched-on and switched-off state of the irradiation elements), so that in particular a different color coverage of the substrate surface and advantageously a different color coverage per Bow or side of the web can be responded. In particular, individual irradiation elements can be controlled so that they emit radiation during simultaneous operation (ie simultaneously switched on status) whose intensity differs from the intensity of a radiation that is emitted by other irradiation elements simultaneously. With stronger color coverage, ie with a higher thickness of the ink layer per unit area of the substrate, a higher radiation intensity usually appears necessary to achieve the same drying effect as with a lower ink coverage. A temporal and / or spatial change in the wavelength of the radiation can be used, in particular, for drying paints comprising substances (in particular solvents) which are volatile when irradiated with, in particular, electromagnetic waves of specific wavelengths, such that irradiation with these specific wavelengths causes drying the color allows or accelerates.

The control of the irradiation elements by the control device can be carried out on the basis of data stored on a storage medium via the print image (which are also referred to below as print image data). The image print data may be, for example, TIFF / G4 data or other digital graphics format. The storage medium comprises in particular a permanent, advantageously magnetic memory (for example a hard disk and / or a flash memory or USB memory) and / or an optical storage medium (for example a CD-ROM or a DVD). The data on the printed image advantageously contain information about which areas or at which locations of the surface of the printed substrate is or is not located. Further, information about the nature of the color, such as its hue and / or its chemical composition, may be included in the print image data. These data may be known and stored on the storage medium prior to the start of the printing process, so that they can then be read out by the control device during the printing or drying process. The control device can then send control pulses based on the print image data to the irradiation device or the irradiation elements. The controlling of the irradiation elements can thereby take place individually, ie individual irradiation elements can be controlled by the control device, while other irradiation elements of the totality of the irradiation elements are controlled differently (ie in particular with another instruction resulting from the control pulse). In particular, this may include an individual switching on and / or off of the irradiation elements and / or an individual temporal and / or spatial change of the intensity and / or wavelength of the radiation emitted by the irradiation elements. The change in intensity and / or wavelength of the radiation emitted by an irradiation element advantageously takes place independently of the change in intensity and / or wavelength of the radiation which is emitted by another or all the other irradiation elements. Advantageously, the control unit assigns the individual regions of the printed image to an irradiation element or individual, specific irradiation elements, so that a scheme results after which certain irradiation elements are to irradiate certain areas of the printed image. This supports image-dependent or imagewise or selective drying of the printed substrate.

In particular, the substrate is moved during drying relative to the irradiation elements, so that the dryer according to the invention can rapidly change the intensity and / or wavelength of the radiation emitted by the irradiation elements. This is particularly necessary when the irradiation elements are arranged in a single line or only a few lines transversely to the direction of movement of the substrate. Finally, then there is only a small extent of irradiation elements in the direction of movement of the substrate for drying available and at the usual high speeds of movement of the substrate in a web-fed rotary printing press and the associated dryer usually changes the printing image located in the drying position in rapid succession. Accordingly, the control power or computing capacity of the control device and the switch-on and off characteristics or the control response of the irradiation elements of the dryer according to the invention are adjusted.

Also possible according to the invention is the online acquisition of the print image data if they were not available in digital form at the beginning of the printing process. For this purpose, the dryer may comprise a recognition device for recognizing the printed image, which captures the print image data and sends it to the control device or the storage medium to be read by the control device and optionally stores it there. In particular, the recognition device may comprise an optical scanner which detects the printed image present on the substrate and sends digital signals to the control device or the storage medium which contain information about the printed image.

Advantageously, irradiation elements are arranged on both sides of the substrate to be dried, when the substrate to be dried is in a drying position. This allows the drying of even two-sided printed substrates.

Advantageously, the dryer comprises a radiation measuring device, in particular a photodiode and / or an infrared sensor, which detects the radiation emitted by the irradiation elements. This makes it possible to check whether a selected intensity and / or wavelength of the emitted radiation actually from the Irradiation elements is emitted. A corresponding measured value determined by the radiation measuring device (for example the radiation intensity and / or radiation wavelength) can then be compared with a nominal value in the control device, and the control device can accordingly regulate the irradiation elements so that the actual intensity and / or wavelength (ie the actual value ) of the selected or desired intensity and / or wavelength (ie the desired value) is adjusted. For this purpose, the radiation measuring device can detect directly the radiation emitted by the irradiation elements or else a spectrum remitted by the substrate or the color.

Advantageously, the dryer comprises a protective device for at least one irradiation element. In particular, however, a protective device is provided in common for each individual irradiation element or a protective device for all irradiation elements. Such a protective device may include, for example, a (transparent) protective cover which is transparent to the emitted (in particular electromagnetic) radiation and is at least partially made of, in particular, a plastic or a plexiglass or also a conventional glass. However, the protective device can also consist of a material that is not transparent to the emitted radiation (opaque) or contain such a material. In this case, an opening in the protective device is advantageously provided, through which the radiation can be directed onto the substrate or the ink to be dried. In this case, it is advantageous in the opening or at the opening or in the beam path of the opening to have a focusing device or bundling device, for example a lens optic and / or a light guide and / or a mirror and / or a nozzle for the radiation emitted by the irradiation elements arranged. However, the lens optics and / or the light guide and / or the mirror and / or the nozzle can also be provided for the case of a transparent to the radiation protection device. The focusing device supports the most precise or precise alignment of the radiation on the substrate to be dried and the color printed areas of the substrate. As a result, the number of irradiation elements required for drying can be adapted to an efficient number and thus the energy efficiency of the dryer can be improved compared to conventional arrangements. Also part of the invention is a printing press or rotary printing machine (or any other type of printing press suitable for carrying out the previously mentioned printing processes) for printing webs comprising at least one printing unit forming at least one nip for a web and a dryer having the features described above. The rotary printing press is advantageously a web-fed rotary printing press. However, the rotary printing machine can also have a plurality of printing gaps, advantageously two, three or four printing gaps, so that multi-color printing is also supported by the dryer according to the invention. The printing machine is in particular an offset printing machine or a newspaper printing press, but may also be an inkjet printing machine (inkjet printing press). Preferably, the dryer is placed in the printing machine between the printing tower and the folder. In particular, the printing machine is a printing machine that can print on multiple webs, at least one of which is dried.

The device or the method according to the invention for drying can also be combined with a device or a method for predrying or heating the ink or the substrate, wherein the predrying takes place temporally before the method according to the invention is carried out. The device for predrying is advantageously formed tubular, wherein the printed substrate for predrying is passed through the interior of the tube. Predrying is thus advantageously distributed uniformly over the entire substrate.

The invention further relates to a method of controlling a dryer as described above comprising the steps of: first, image data including information about a printed image printed on a substrate with color is read. In particular, these image data are read in by a control device described above; the control device advantageously reads in the image data from a storage medium described above. According to the image data, at least one irradiation element of the dryer is driven, as already explained above.

The method just described may be written as a program that, when executed on or loaded into a data processing device, causes the data processing device to execute the method described above. The data processing device advantageously comprises an electronic or digital processor (a CPU) and a random access memory (RAM) and may include a commercially available computer.

The program just described can be stored on a permanent storage medium, in particular a magnetic storage medium such as a hard disk, a floppy disk and / or a flash or USB memory and / or an optical storage medium, such. As a CD-ROM or a DVD to be stored.

Figur 1

zeigt einen Querschnitt durch einen Teil eines erfindungsgemäßen Trockners mit lichtemittierenden Flächen und einem Schutzglas für selbige.

Figur 2

zeigt einen Querschnitt durch einen Teil eines erfindungsgemäßen Trockners mit lichtemittierenden Flächen sowie einer Linsenoptik.

Figur 3

zeigt einen Querschnitt durch einen Teil eines erfindungsgemäßen Trockners mit lichtemittierenden Flächen sowie einer Spiegeloptik.

Figur 4

zeigt einen Querschnitt durch einen Teil eines erfindungsgemäßen Trockners mit lichtemittierenden Flächen und einem Lichtwellenleiter.

The program and / or the method steps or information about the method steps of the method described above for controlling the dryer can also be transmitted as a signal wave (for example in the form of radio waves) between a transmitter and a receiver.

FIG. 1

shows a cross section through a portion of a dryer according to the invention with light emitting surfaces and a protective glass for selbige.

FIG. 2

shows a cross section through a portion of a dryer according to the invention with light-emitting surfaces and a lens optics.

FIG. 3

shows a cross section through a portion of a dryer according to the invention with light-emitting surfaces and a mirror optics.

FIG. 4

shows a cross section through part of a dryer according to the invention with light emitting surfaces and an optical waveguide.

According to one embodiment of the invention, radiation elements in the form of electromagnetic radiation sources in the UV range (with a wavelength in the range of about 200 to about 400 nm), visible range (in a wavelength range of about 400 nm to about nm) or infrared range (in a wavelength range from about 800 nm to about 3000 nm) for use. Such irradiation elements may, for example, comprise LEDs or semiconductor laser diodes, in particular VCSELs (Vertical Cavity Surface Emitting Laser Diode). Each irradiation element thus has a light-emitting surface which may have a size in a surface area whose lower limit is, for example, 0.001 mm ² or 0.005 mm ² or 0.01 mm ² and whose upper limit is 10 mm ² , 15 mm ² or 50 mm ² . Also possible is a size of the light-emitting surface of 0.001 mm ² , 0.01 mm ² , 10 mm ² or 50 mm ² .

FIG. 1 shows a cross section through a printed substrate 1, the light emitting surfaces 3 (hereinafter referred to simply as the light surfaces 3) opposite and from these with light rays 5 is applied. The light surfaces 3 are arranged on a support 2 and at least partially surrounded by a protective glass 4. The light surfaces 3 in each case irradiate a portion of the substrate 1 which is advantageously opposite to them or is in the drying position, wherein the portions irradiated by different light sources 3 can at least partially overlap one another. The protective glass 4 may, for. Example, a glass or a transparent plastic plate used for the radiation used for drying. According to the embodiment of FIG. 1 the protective glass 4 is arranged on carriers 2a, wherein the carriers 2a advantageously rearrange the light surface 3 outside the beam path of the light beams 5. The protective glass 4 is intended to protect the emitting surface of the light surface 3 from contamination or damage.

In the case of a web width of the substrate 1 of 1.5 m, 1500 light areas 3 arranged next to one another can be present in one row of light areas, for example, so that a spatial resolution of 10 cm ^-1 or 25 dpi. can be achieved. In a preferred embodiment of the invention, the spatial resolution is in the range of 2 to 50 dpi. For example, a two-dimensional arrangement of light surfaces 3 with two to 100 lines of LEDs can be made. The number of rows grouped into such arrays depends on the number and power of the individual LEDs or semiconductor laser diodes of a row, and also on the radiation energy required to dry all the applied color layers and the maximum speed of the printed substrate 1.

For example, the web or substrate 1 to be dried has a width of 1600 cm. One row of the light area array consists of 800 LEDs, each of which irradiates an area of 2 mm × 2 mm = 4 mm ² . The UV radiation emanating from each LED on the line have a capacity of 250 mW. The energy required to cure a colored layer is 40 mJ / cm ² . There are up to three layers of paint applied on top of each other, ie the total energy requirement is 120 mJ / cm ² . The web speed is 12 m / s in this example. A 2 mm x 2 mm image site is then exposed to the radiation of an LED during 0.167 milliseconds and receives an energy input of 0.041 mJ or about 1 mJ / cm ² . Thus, in the presence of this operational data, a two-dimensional array consisting of 120 lines can dry a web of the substrate 1 at a conveying speed of 12 m / sec. The size of such an array is then 1600 mm x 240 mm and contains 96000 LEDs. In particular, the light surfaces (LEDs or semiconductor laser diodes) can emit electromagnetic radiation in the range between 200 nm and 3000 nm wavelength.

FIG. 2 illustrates in cross-section the arrangement of the printed substrate 1 with respect to light surfaces 3 on carriers 2, the light beams 5 before passing on the surface of the substrate 1 through a lens optics, which is arranged between the light surface 3 and the substrate 1. The lens optics advantageously comprises at least one associated lens 6 for each light surface 3. The lens optics serves to concentrate the light rays 5 and thus the energy available for drying such that, in contrast to FIG. 1 the light beams 5 irradiate no longer overlapping areas of the surface of the substrate 1. Thus, each light surface 3 dries a surface portion of the substrate 1 which is not irradiated by any other light surface 3, resulting in energy saving by preventing double irradiation and double drying of surface portions of the substrate 1. In addition, the risk of damage to the substrate 1 is reduced by excessive irradiation. Advantageously, the lenses 6 are arranged closer to the light surface 3 than to the substrate 1 or to the surface area of the substrate 1 to be dried by the relevant light surface 3 when this is in the drying position.

FIG. 3 shows in cross-section the arrangement of light surfaces 3 on carriers 2 near a substrate 1, wherein the light beams 5 are deflected before striking the surface of the substrate 1 of a mirror optics or of mirrors 8 such that they advantageously not overlapping areas of the substrate 1 irradiate. The mirrors 8 can while flat mirror, but also be curved mirror or concave mirror. Advantageously, the surfaces of the mirror acted upon by the light beams 5 have a high reflectivity or a high reflection coefficient, so that due to the reflection of the light at the mirror surface, a low energy transfer to the mirror takes place and as much light energy as possible from the light surfaces 3 to the surface to be dried or to be irradiated surface of the substrate 1 passes.

FIG. 4 shows a further embodiment of the invention, wherein the optical waveguide or light guide 7, the function of the mirror 8 of the embodiment of FIG. 3 take. The light guides 7 may be, for example, fiber optic cables or Plexiglas tubes. But they can also have the shape of cuboid, curved or curvilinear or angled profiles made of a light-conducting material (eg., A plastic). Advantageously, the light guides 7 have a thickness or a diameter of a few millimeters (for example 1 mm or 2 mm) and are coupled to the light surfaces 3 in particular light-conducting, advantageously cohesively (for example by means of a light-conducting adhesive or a light-conducting paste) , However, the light guides 7 may also be formed cuboid or in the form of an edged tube to support a complete irradiation of the substrate. Each light surface 3 is advantageously associated with a light guide 7. According to the invention, however, it would also be possible to associate a plurality of light surfaces 3 with a light guide 7, so that the radiation transmitted through a light guide 7 is increased in comparison to the variant with a light surface 3 per light guide 7. The light guides 7 are advantageously arranged such that the end on which the radiation provided for drying is emitted to the substrate 1 when it is in the drying position.

The embodiment of the FIG. 3 has the advantage that the light surfaces 3 relative to the substrate 1 need not necessarily be arranged in parallel when this is in the drying position. Rather, you can also, for example, for reasons of space - as in the FIG. 3 represented - may be located perpendicular or at another angle to the surface of the substrate 1, when this is in the drying position. This provides the designer of the dryer or the printing press a greater freedom in planning the space requirement.

Compared to the embodiment of FIG. 3 has the embodiment of FIG. 4 the additional advantage that the light surfaces 3 can be arranged at a greater distance from the surface of the substrate 1, since the transmission of the light beams 5 through the light guide 7 can be done almost lossless and even at a greater distance to be overcome at the output of the light guide. 7 which is located above the surface to be dried of the substrate 1, an excellent bundling of the light energy is made possible.

LIST OF REFERENCE NUMBERS

1

substratum

2

carrier

3

light area

4

protective glass

5

light rays

6

lenses

7

optical fiber

8th

mirror

Claims (15)

A dryer for drying ink on a printed substrate (1), namely a web or a sheet of a web-fed printing press or sheet-fed press, the dryer comprising: a) at least one irradiation device for irradiating the substrate (1), which comprises a plurality of irradiation elements (3) per sheet or side of the web; b) a control device for individually controlling the irradiation elements (3). Dryer according to the preceding claim, wherein the irradiation elements (3) are arranged line by line and / or surface. Dryer according to one of the preceding claims, wherein the control device can be configured to control the irradiation device such that the irradiation elements (3) irradiate the substrate (1) corresponding to the printed image. Dryer according to the preceding claim, wherein the controlling of the irradiation device comprises a temporal and / or spatial variation of the intensity and / or wavelength of the radiation (5) emitted by the irradiation elements (3). Dryer according to one of the preceding claims, wherein the irradiation Einriehiung optical irradiation elements (3), in particular at least one LED comprises. Dryer according to one of the preceding claims, in which the irradiation elements (3) emit electromagnetic radiation (5) in the infrared and / or ultraviolet spectral range and / or in the microwave range. Dryer according to one of the preceding claims, in which the control device carries out the control of the irradiation elements (3) on the basis of data stored on a storage medium via the printed image. A dryer according to any one of the preceding claims, wherein the substrate (1) is moved during drying relative to the irradiation elements (3) and the irradiation elements (3) are arranged transversely and / or longitudinally to a direction of movement of the substrate (1). Dryer according to one of the preceding claims, in which irradiation elements (3) are arranged on both sides of the substrate (1) to be dried. Dryer according to one of the preceding claims, further comprising a radiation measuring device, in particular a photodiode and / or an infrared sensor, which detects the radiation emitted by the irradiation elements (3) radiation (5). Dryer according to one of the preceding claims, comprising a protective device (4) for at least one irradiation element (3). Dryer according to one of the preceding claims, comprising a focusing device (6, 7, 8), in particular a lens optic and / or a light guide and / or a mirror and / or a nozzle, for the radiation (5) emitted by the irradiation elements (3). includes. Rotary printing machine for printing webs, the rotary printing press having the following features: a) at least one printing unit which forms at least one nip for a web, b) a dryer according to any one of the preceding claims. A method of controlling a dryer according to any one of claims 1 to 15, comprising the following steps: a) reading in image data containing information about a printed image printed with ink on a substrate (1); b) driving at least one irradiation element (3) of the dryer according to the print image data. Program which, when executed on or loaded into a data processing device, causes the data processing device to carry out the method according to the preceding claim and / or permanent storage medium on which such a program is stored, and / or data processing device on which the Program is running or in whose memory the program is loaded, and / or signal wave, in particular digital signal wave, which contains information representing the program and / or the method steps of the method according to the preceding claim.

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