DE10234076A1 - Device and method for supplying radiation energy to a printing material in a planographic printing press - Google Patents

Abstract

The invention relates to a device for supplying radiation energy of a wavelength in the near infrared to a printing material (14) in a planographic printing machine, with at least one radiation energy source (10), the light (12) of which on the printing material (14) is on the path (16) of the printing material (14) by the printing press at a position (116) which is arranged downstream of at least one printing nip (18) in a printing unit, which is characterized in that the radiation energy source (10) only emits narrowband light (12), the wavelength of which is non-resonant to absorption wavelengths of water and is preferably between 700.00 nm and 2500.00 nm. A method of supplying radiation energy is further disclosed. By supplying energy in this frequency range while avoiding water absorption resonances, undesired drying out or unnecessary heating of the printing material is advantageously reduced, while the printing ink is provided with energy for its special drying process. The energy input of the radiation energy into the printing ink is supported by an infrared absorber added to the printing ink.

Description

The invention relates to a device for supplying radiation energy Wavelength in the near infrared on a substrate in a planographic printing machine at least one radiation energy source, the light of which is on the substrate on the path of the printing material hits by the printing press at a position which at least is arranged downstream of a printing nip in a printing unit. Furthermore concerns the Invention a method for supplying radiation energy of a wavelength in the near Infrared on a substrate in a planographic printing machine.

Depending on the type of ink and the underlying special Drying process are various devices on printing machines, in particular Planographic printing machines, such as lithographic printing machines, rotary printing machines, Offset printing machines and the like, which are arcuate or web-shaped Process, known, printing materials, in particular paper, cardboard, cardboard and the like, which trigger or support the ink to adhere to the substrate by Radiation energy of the printing ink located on the printing material is supplied.

The so-called UV inks harden by polymerization, which by photoinitiation is triggered by light in the ultraviolet. On the other hand, they are widely used solvent-based printing inks, which are both a physical and a chemical drying process. Physical drying includes evaporation of solvents and diffusion into the substrate (knocking away), while under chemical drying or oxidative drying due to a Polymerization of the oils, resins, binders or contained in the color formulations the like may be understood with the participation of atmospheric oxygen. The Drying processes are generally interdependent, because of the Knocking away the solvent separating within the binder system between Solvents and resins takes place, causing the resin molecules to come closer and can polymerize more easily if necessary.

For example from EP 0 355 473 A2 is a device for drying Printed products known that have a source of radiation energy in the form of a laser includes. The radiation energy is applied to the surface of the substrates that are on move a web by means of a transport device through the printing press, on one Position between individual printing units or after the last printing unit before or in directed to the boom. The radiation source can be a laser in the ultraviolet UV inks or a laser light source in the infrared for heating solvent-based Printing inks. The radiation energy source is outside the printing press arranged to avoid that due to unavoidable or shieldable Heat loss undesirable parts of the printing press are heated. The disadvantage is here, however, that an additional system component for the printing press user must be provided separately.

Furthermore, it is known, for example from document US Pat. No. 6,026,748, that on a Printing machine a drying device with infrared lamps, which short-wave Infrared light (near infrared) or medium-wave infrared light can be provided can. The emission spectrum from lamp light sources is broadband and consequently leads to a variety of wavelengths. A disadvantage of such Drying devices in the infrared is a relevant part of the Energy absorption takes place in the paper, whereby the ink is only indirectly heated. A fast drying is only possible through a correspondingly high energy input. there However, there is a risk, among other things, that the substrate will dry out unevenly and can become wavy.

In electrophotographic printing technology, for example, from DE 44 35 077 A1 known, a fixation of toner on a recording medium by diode lasers emitted radiation energy in the near infrared. By using a narrow-band light source, heating of the toner particles is achieved in order to melt, form into a colored layer and on the surface of the To anchor the record carrier. Since a large number of common paper types have broad absorption minima, it is possible that a most of the energy in the toner particles can be absorbed directly.

The simple knowledge of the window in the paper absorption spectrum can, however do not use directly in printing technology with solvent-based printing inks, because as described above other chemical or physical Underlying drying processes. In connection with the invention The term solvent-based printing ink means in particular colors whose Solvent proportions can be aqueous or organic in nature, based on Build binder systems that polymerize oxidatively, ionically or radically to let. An energy input for drying solvent-based printing inks should Effect of evaporation of the solvent and / or the effect of knocking off in the Support or promote printing stock and / or the effect of the polymerization, wherein at the same time undesirable side effects, such as excessive heating of the solvent-based printing ink, which leads to decomposition of components or Overheating of the solvent can be avoided. The energy input should not only, as in the case of toner fixation, introduced for melting particles become.

The object of the present invention is an apparatus and a method within a planographic printing press in which solvent-based printing inks are used create, which shortens the drying time of such ink.

This object is achieved by a device for feeding Radiant energy of a wavelength in the near infrared with the characteristics according to Claim 1 and by a method for supplying radiation energy with the Features solved according to claim 11. Advantageous developments of the invention are in characterized the dependent claims.

The device according to the invention for supplying radiation energy of a wavelength in the near infrared to a printing substrate in a planographic printing machine has at least one radiation energy source, the light of which strikes the printing substrate, in particular the freshly printed printing substrate, at one position on the path of the printing substrate through the printing machine. which is arranged downstream of at least one printing nip in a printing unit, and is characterized in that the radiation energy source essentially only, preferably only emits light, the wavelength of which is non-resonant to absorption wavelengths of water (H ₂ O). In the context of the invention, non-resonant to absorption wavelengths of water is to be understood that the absorption of light energy by water at 20 ° Celsius is not more than 10.0%, in a preferred embodiment not more than 1.0%, in particular below 0.1%. In the context of the inventive concept, the radiation energy source emits only very low intensity of light, preferably no light at all, which is resonant to absorption wavelengths of water (H ₂ O).

In an advantageous embodiment, the radiation energy source is narrow-band. The Radiation energy sources can, for example, be up to ± 50 nm wide by one Emit wavelength, it can also be one or more individual spectroscopic trade narrow emission lines. Furthermore, this is in an advantageous embodiment Emission maximum of the narrowband radiation energy source or the wavelength the radiation energy between 700.00 nm and 3000.00 nm, preferably between 700.00 nm and 2500.00 nm, in particular between 800.00 nm and 1300.00 nm, in one Part of the so-called window in the paper absorption spectrum. Particularly advantageous is an emission at 870.00 nm ± 50.00 nm and / or 1050.00 nm ± 50.00 nm and / or 1250.00 nm ± 50.00 nm and / or 1600.00 nm ± 50.00 nm.

The invention is based on the knowledge that absorption bands of water contribute to the paper absorption spectrum. Even the typical water content of substrates in waterless (dampening solution-free) planographic printing leads to undesirable, sometimes unacceptably strong, energy absorption in the substrate. Accordingly, this absorption is even more pronounced in planographic printing with dampening solution. Too much energy input into the printing substrate can consequently be avoided by irradiating a wavelength which is non-resonant to an absorption line or absorption band (absorption wavelength) of water. According to the Hiltran database at a temperature of 296 K, in 1 m absorption section, 15,000 ppm water, the following absorption by water, more precisely by water vapor, results: at 808 nm less than 0.5%, at 870 ± 10 nm less than 0 , 01%, at 940 ± 10 nm less than 10%, at 980 ± 10 nm less than 0.5%, 1030 ± 30 nm less than 0.01%, 1064 nm less than 0.01 nm, 1100 nm less than 0.5% and 1250 ± 10 nm less than 0.01%. If one considers an area of the printing material, in particular the paper, of 1 m ² and an air gap of 1 m above, the air contains an amount of water of about 12 g at an absolute humidity of 1.5%. As long as in one embodiment of the device according to the invention the light source is not more than 1 m away from the printing material and the absolute humidity is not significantly above 1.5%, the above-mentioned absorptions by water and / or water vapor will not be exceeded. Additional absorption can take place through the moisture content of the printing material, if the light penetrates through the ink layer into the printing material, or through dampening solution, which was transferred to the sheet by the printing process.

Depending on the functional groups of the individual components in the Printing ink, in particular the pigment, the dye or the colorant Binder (varnish), the solvent, the oil or the resin, the filler, the Auxiliaries, additives or additives, or the like, can be the printing ink absorb different wavelengths. By means of the device according to the invention the printing ink on the substrate in the planographic printing press light in the near infrared while avoiding water absorption wavelengths, for example by the irradiation of only a few wavelengths emitting a line spectrum Light source, offered.

In an inventive manner, the printing ink can have an infrared absorber. A Coupling of the light into the printing ink and / or absorption of the radiation energy in the printing ink is created, enabled, supported by the infrared absorber, improved or relieved. In the context of this representation of the invention linguistically simplifying only speaks of support, and it should all Gradations of the effect of the infrared absorber are meant. The energy input, which can lead to the generation of heat leads to accelerated drying the ink. On the one hand, a high temperature in the printing ink (in the Ink layer) are generated on the substrate, on the other hand, if necessary, in Depending on the composition of the printing ink, chemical reactions are stimulated or be initiated. The infrared absorber, also as infrared absorber, IR absorber, IR Designated absorber substance or the like, on the one hand, a component in the Be printing ink which has a functional group which is in the near infrared absorbed, or may otherwise be an additive or an additive which the Ink is added or added before printing. In other words expressed, the printing ink may have been supplemented with an infrared absorber or comprise a component modified to form an infrared absorber. Preferably the Infrared absorber has the property that it has little or no Absorption in the visible range of wavelengths, so that the color impression of the Ink is influenced or changed little or not at all.

A relatively high energy input directly into the printing ink, especially supported by an infrared absorber, is advantageously possible without an undesirable To get energy input into the substrate. This is explained on the one hand by the fact that the light cannot be directly absorbed by the substrate, and secondly in that the energy absorbed by the color layer changes after fractions of Spread over seconds on ink and substrate. The heat capacity and the Quantity ratios are distributed so that a short heating of the paint layer is possible before the entire printed sheet is a homogeneous moderate Experiences temperature increase. This reduces the total energy input required. The selective supply of energy can be supported in particular by a Wavelength is radiated, which is resonant or quasi-resonant to absorption lines a component of the ink or to an absorption line or one Absorption maximum of an infrared absorber in the printing ink. The absorption the radiation energy in the printing ink is more than 30%, preferably 50%, in particular 75%, can even be more than 90%.

In addition, avoiding energy absorption in water reduces the Drying of the substrate. This is advantageous because, among other things, one Drying of the substrate leads to a change in its format: due to of the so-called swelling process depends on its drying state or its moisture content of the substrate different formats on. The swelling process between individual printing units leads to the requirement different print formats in the individual printing units. A change in Moisture content between the printing units due to the influence of a Radiation induced dehydration, which only requires great effort in advance determinable and correctable deviations is caused by the Ink drying avoided by means of the device according to the invention.

In other words, the device according to the invention enables one Drying the solvent-based ink on the substrate without it To influence drying out too much.

In order to achieve a narrow-band emission with a high spectral one at the same time To achieve power density, the radiation energy source is preferably a laser. Alternatively, a broadband light source, for example an IR Carbon emitter, with a suitable filter arrangement, so that a narrow-band radiation energy source in combination. A filter can in particular be an interference filter. Preferred for spatial integration within In the planographic printing machine, the laser is a semiconductor laser, (diode laser) or a Solid state lasers (titanium sapphire, erbium glass, NdYAG, Nd glass or the like). On Solid-state lasers can preferably be pumped optically by diode lasers. The Solid-state lasers can also be a fiber laser or optical waveguide laser, preferably a Ytterbium fiber laser, which has 300 to 700 W light output at the workplace at 1070 nm Can provide 1100 nm. Such lasers can advantageously be used in limited extent can also be coordinated. In other words, the The output wavelength of the laser can be changed. This allows a vote on a desired wavelength, for example in resonance or quasi-resonance to one Absorption wavelength of a component in the printing ink, especially one Infrared absorber in the printing ink can be achieved.

Diode lasers or semiconductor lasers are in the context of the invention Device particularly advantageous since it already has no special beam shaping optics the purpose of supplying radiation energy to a printing material can be used. The light leaving the resonator of a semiconductor laser is very divergent, so that a light beam that widens as the distance from the coupling mirror increases becomes.

In an advantageous development, the device for supplying radiation energy has a plurality of radiation energy sources which are arranged in a one-dimensional, in a two-dimensional field (locally curved, globally curved or flat) or in a three-dimensional field and whose light is present at a number of positions meets the substrate. By using a number of individual radiation energy sources for individual areas on the printing material, the maximum required output power of the radiation energy sources is reduced. Light sources with lower output power are usually cheaper and have a longer life expectancy. In addition, unnecessarily high heat loss is avoided. The energy introduced per area by the supply of radiation energy is between 100 and 10,000 mJ / cm ² , preferably between 100 and 1000 mJ / cm ² , in particular between 200 and 500 mJ / cm ² . The printing material is irradiated for a length of time between 0.5 ms and 1 s, preferably between 1 ms and 50 ms, in particular between 5 ms and 25 ms.

It is particularly advantageous if that which strikes the printing material at one position Light in its intensity and duration of exposure for each radiation energy source is controllable independently of the other radiation energy sources. For this purpose can be a control unit, independent of or integrated into the machine control of the Planographic printing machine can be provided. By controlling the Radiant energy source parameters, it is possible to adjust the energy supply at different To regulate the positions of the substrate. An energy supply can then cover the area of the substrate at the current position on the substrate become. It is also advantageous to use a device according to the invention Set up a plurality of radiation energy sources such that at a position on the Substrate light hits from at least two radiation energy sources. It can partly partly completely overlapping beams of light act. The required maximum output power of an individual Radiant energy source is then lower, there is redundancy if one Failure of a radiation energy source occurs.

Draws a planographic printing machine according to the invention with at least one printing unit are characterized in that they have a device according to the invention for feeding Has radiant energy. The planographic printing machine according to the invention can be a direct one or indirect offset printing machine, a flexographic printing machine or the like. On the one hand, the position at which the light is on the substrate in the path through the Flat printing machine hits, the last printing nip of the last printing unit of the number of Printing units, that is, all printing columns. On the other hand, the position also arranged after a first pressure gap and upstream of a second pressure gap, that is, at least between two printing units.

In connection with the inventive idea is also a method for feeding of radiation energy of a wavelength in the near infrared on a substrate in one Flat printing machine, more precisely for feeding into the printing ink on the printing material. in the The inventive method is a substrate with light from at least one Radiant energy source illuminated, the light on the substrate on the path of the printing material hits by the printing press at a position which at least is arranged downstream of a printing nip in a printing unit. So that the absorption of the Radiation energy in the ink is supported or enabled, the ink at least one infrared absorber added. In other words, the absorption of the Radiation energy in the printing ink is supported by an infrared absorber, which is added to the printing ink. The infrared absorbers can be used for a Absorption at a certain wavelength, which results in a wavelength of one Light source, in particular laser, fits, can be synthesized tailor-made. For one present infrared absorber with an absorption at a certain wavelength can special light sources, in particular lasers, which determine this Wavelength emitted, to be developed.

The method according to the invention for supplying radiation energy can be found in advantageously with a device for supplying radiation energy, as in described in this document. In particular, in inventive way the emission of the radiation energy source and the absorption of the Infrared absorber material set or adjusted to match each other. In In other words, the radiation energy source is said to be one of the absorption of the Emit the appropriate wavelength of infrared absorber. That from the Light source emitted is therefore particularly preferably quasi-resonant, in essentially resonant, in particular resonant to an absorption maximum of Infrared absorber so that the best possible match of the Absorption maximum of the infrared absorber with the emission maximum of Radiation source is achieved. The absorption spectrum of the used Infrared absorber has at least in the area of the emission of the radiation source 50% of the absorption maximum of the infrared absorber, preferably at least 75%, especially at least 90%. An infrared absorber can be one or more local Have absorption maxima.

The method according to the invention for supplying radiation energy can also be used as a Process for drying ink or as a process for supporting or to accelerate the drying of printing ink, because by means of Absorption of the infrared absorber and avoidance of Absorption wavelengths of water contribute to strong energy absorption in the printing ink simultaneous low, preferably vanishingly low, energy absorption in the Substrate is reached. In other words, the method according to the invention enables drying the solvent-based ink on the substrate without it To influence drying out too much.

The method according to the invention for supplying radiation energy can also be used particular advantage in a planographic printing machine with a number of printing units, in which are printed with a number of printing inks. At least one of the number of inks is covered with an infrared absorber before Prepared for printing. The preparation can be made before the ink is taken up Printing unit or within the printing unit, for example, a specific Amount of an infrared absorber at least one of the number of printing inks can be added or added. The proportion by weight of the infrared absorber can less than 10%, preferably less than 3%, in particular less than 1% of the Total weight of the printing ink (with infrared absorber). If at least two the number of inks prepared, the same can be done for both inks Infrared absorber or a first for the first of the two printing inks Infrared absorber and a second one for the second of the two printing inks Infrared absorber can be used. The first and the second infrared absorber can at least have the same or a similar absorption maximum or have different absorption maxima. The same applies to more than two Infrared absorber materials. If the infrared absorbers used have a number of have different absorption maxima, can have a number of wavelengths Radiant energy can be supplied.

Further advantages and advantageous embodiments and developments of the invention are shown using the following figures and their descriptions. It shows in detail:

Fig. 1 is a schematic diagram for explaining the arrangement of the device according to the invention in a lithographic printing press,

Fig. 2 is a schematic representation of an advantageous development of the device according to the invention in a planographic printing press, and

Fig. 3 is a schematic representation of a planographic printing press with various alternative arrangements of the device according to the invention on the printing units or after the last printing unit.

Fig. 1 shows a schematic diagram for explaining the arrangement of the device according to the invention in a lithographic printing press. A radiation energy source 10 , in particular a laser, preferably a diode laser or solid-state laser, is arranged within a planographic printing press in such a way that the light 12 emitted by it strikes a printing material 14 on its path 16 through the planographic printing press at a position 116 which is arranged downstream of a printing nip 18 , While the printing material 14 is shown in an arc-shaped manner by way of example in FIG. 1, the printing material can also be guided in a web shape through the planographic printing machine. The orientation of the path 16 of the printing material 14 is indicated by an arrow. The path is shown here linearly without restriction of a generally curved or non-linear course, in particular on a circular arc. The pressure gap 18 is defined in the embodiment shown in FIG. 1 by the interaction of the pressure cylinder 110 and an impression cylinder 112 . Depending on the special printing process in the planographic printing press, the printing cylinder 110 can be a printing form cylinder or a blanket cylinder. Ink 114 is shown on printing material 14 . The light 12 emitted by the radiation source 10 falls in a bundle or carpet shape at a position 116 on the printing material 14 . Ink 114 within this position 116 can absorb energy from the light 12 . Due to the advantageous choice according to the invention of a wavelength which is non-resonant to absorption wavelengths of water, absorption in the printing substrate 14 is reduced.

The Fig. 2 is a schematic representation of an embodiment in an advantageous further development of the device according to the invention in a lithographic printing press. A field 20 of radiation energy sources 10 is sketched as an example, here three times four, that is to say twelve radiation energy sources 10 . In addition to the two-dimensional field 20 shown here, a one-dimensional field or a one-dimensional line, oriented over the width of the printing substrate 14, can also be provided. A two-dimensional field, as well as a three-dimensional field, the light of which strikes the printing material 14 in a two-dimensional distribution, has the advantage, among other things, that rapid drying is achieved by parallel or simultaneous irradiation of a group of positions in a column of the field 20 . The speed at which the printing material moves past the radiation energy sources 10 can consequently be higher than in the case of an only one-dimensional field. The field 20 can also have a different number of radiation energy sources 10 . Light 12 is supplied to the printing substrate 14 from each of the number of radiation energy sources 10 . The positions 116 at which the light 12 strikes the printing material 14 , which follows a path 16 through the planographic printing press, are arranged downstream of a printing gap 118 , defined by a printing cylinder 110 and an impression cylinder 112 . Individual positions 116 can partially coincide, as is shown in FIG. 2 for the row of radiation energy sources 10 lying in front, or even essentially completely overlap. A control device 24 is assigned to the field 20 of radiation energy sources 10 , with which control device 24 can exchange control signals by means of a connection 22 . The control device 24 can control the field 20 in such a way that an energy supply corresponding to the amount of printing ink is carried out at the position 116 on the printing material 14 .

Fig. 3 illustrates schematically a lithographic printing machine, in this embodiment, a sheet-processing printing machine, with various alternative arrangements of the inventive device on the printing units and from the last printing unit. For example adhesive, the planographic printing press has four printing units 30, a feeder 32 and a boom 34 , Various cylinders are shown within the planographic printing press, which on the one hand serve to guide the sheet through the machine and on the other hand provide a planographic printing surface, be it directly as a printing form cylinder or as a blanket cylinder. Not shown in detail in detail, typical printing units 30 in planographic printing presses also have an inking unit and, if appropriate, a dampening unit. Each printing unit 30 comprises a printing cylinder 110 and an impression cylinder 112 , which define a printing nip 18 . At the first and second printing units 30 , a central radiation energy source 36 is shown, from which light is guided to the projection elements 310 assigned to the printing units 30 by means of light guide elements 38 , for example optical waveguides, mirrors, imaging optics and the like. The projection elements 310 emit light 12 at positions 116 on the path 16 of the printing substrate 14 through the planographic printing press, which are arranged downstream of the respective printing columns 18 of the assigned printing units 30 . The use of light-guiding elements 38 makes it possible to arrange the radiation energy source 36 at a suitable location within the planographic printing press, at which installation space is available. Radiation energy sources 10 are shown on the third and fourth printing unit 30 , from which light 12 is fed directly in positions 116 downstream of the printing nip 18 of the respective printing unit 30 onto the path 16 of the printing material 14 . Furthermore, an alternative radiation energy source 312 and a further alternative radiation energy source 314 are shown within the bracket 34 .

Analogous to the arrangements shown in FIG. 3 on the basis of a sheet-processing printing press, devices according to the invention for supplying radiation energy can also be used advantageously in a web-processing printing press, in particular so-called web-fed rotary printing presses, be it for commercial or newspaper printing.

In one embodiment of the method according to the invention for feeding Radiation energy of a wavelength in the near infrared on a substrate becomes a Infrared absorber, which by the location of its absorption maximum or its Absorption maxima in the so-called window of the paper absorption spectrum, in particular is used in the so-called window of the water absorption spectrum. A required amount of the infrared absorber is used as an additive or additive Printing ink added. This can be done, for example, by stirring the ink the infrared absorber happen outside or inside the planographic printing press. An addition is usually only for the so-called chromatic colors, especially for the Four-color offset printing for the colors yellow, magenta and cyan (Y, M and C) makes sense. An addition for the contrast color, in four-color offset printing for the color Black (K), is usually not necessary since black ink is generally relevant throughout relevant and addressed wavelength range between 700 nm and 2500 nm sufficiently well absorbed. However, an addition can be made. The required amount of infrared absorber is calculated according to the Lambert-Beerschen Extinction law, the layer thickness of the printing ink on the substrate and the Extinction coefficient. That on the Lambert-Beers extinction law In this illustration, calculations are based on immediate resonance, i. H. the Emission wavelength is in the immediate vicinity of the absorption maximum. With easy deviating laser wavelengths, an equally slightly deviating absorption is obtained and accordingly, preferably proportionally more infrared absorber required. to Illumination of the printing material uses a radiation energy source, the light of which is essentially resonant to the absorption maximum of the infrared absorber. The Printing process in the planographic printing machine can in this embodiment without further Measures and carried out without deviations from the conventional printing process become.

In a first embodiment of the embodiment of the method according to the invention, 3-butyl-2 (2 - [- 2- (3-butyl-1,1-dimethyl-1,3-dihydro-benzo [e] indol-2-y-lidenes is used as the infrared absorber ) ethylidene] -2-chlorocyclohex-1-enyl] -ethenyl) -1,1-dimethyl-1H-benzo [e] indolium perchlorate with the empirical formula C ₄₆ H ₅₂ Cl ₂ N ₂ O ₄ and a molecular weight of 767.84 g mol ^-1 used. The structural formula of the infrared absorber is included


specified. This infrared absorber has an absorption maximum at 819 nm and a max. Absorbance of 615276 (mol.cm) ^-1 . 1.4% by weight of the infrared absorber material is required for approximately 90% laser light absorption as an additive in the colors C, M and Y for a layer thickness of 2 µm (according to the Lambert-Beer extinction law). (For comparison: 0.9 percent by weight for approximately 75%, 0.4 percent by weight for approximately 50% and 0.2 percent by weight for approximately 30%.) The device for supplying radiation energy comprises a laser as a radiation energy source which emits at 808 nm, For example, an InGa (Al) As Quantum world laser of the MB series from DILAS can be used. The named laser from DILAS has a maximum optical output power of 24 W. The beam geometry after the collimator is 4 mm × 12 mm. The emission wavelength is therefore sufficiently resonant to the absorption maximum of 819 ± 15 nm; the infrared absorber shows an absorption greater than 50%. In this exemplary embodiment, a beam profile and an irradiation time of 2 ms have been selected for an energy per area of 100 mJ / cm ² at a printing speed of 2 m / s (corresponds to 14400 prints per hour with an arc length of 50 cm). The absorption of radiation by water vapor in the air is less than 0.5%.

In a second exemplary embodiment of the embodiment of the process according to the invention, 2 [2- [2Chloro-3- [2- (3-ethyl-1,3-dihydro-1,1-dimethyl-2H-benzo [e] indol-2ylidenes is used as the infrared absorber ) -ethylidenel-1-cyclohexen-1-yl) -ethenyl) 3-ethyl-1,1-dimethyl-1H-benzo [e] indolium tetrafluoroborate with the empirical formula C ₄₂ H ₄₄ BClF ₄ N ₂ and a molecular weight of 699.084 g mol ^-1 used. The structural formula of the infrared absorber is included


specified. This infrared absorber has an absorption maximum at 816 nm and a max. Absorbance of 898704 (mol.cm) ^-1 . 0.9% by weight of the infrared absorber material is required for approximately 90% laser light absorption as an additive in the colors C, M and Y for a layer thickness of 2 µm (according to the Lambert-Beer extinction law). (For comparison: 0.5 percent by weight for approximately 75%, 0.3 percent by weight for approximately 50% and 0.1 percent by weight for approximately 30%.) The device for supplying radiation energy comprises a laser as a radiation energy source, which emits at 808 nm, For example, an HLU 100c 10 × 12 diode laser from LIMO can be used. The LIMO laser has a maximum optical output power of 100 W. The beam geometry after the collimator is 10 mm × 12 mm. The emission wavelength is therefore sufficiently resonant to the absorption maximum of 816 ± 15 nm; the infrared absorber shows an absorption greater than 50%. In this exemplary embodiment, a beam profile and an irradiation time of 40 ms have been selected for an energy per area of 833 mJ / cm ² at a printing speed of 0.5 m / s (corresponds to 3600 prints per hour with an arc length of 50 cm). The absorption of radiation by water vapor in the air is less than 0.5%.

In a third exemplary embodiment of the embodiment of the method according to the invention, benzene amine-N, N'-2,5-cyclohexadiene-1,4-diylidene bis [4- (dibutylamino) -N- [4- (dibutylamino) phenyl] diperchlorate is used as the infrared absorber with the Molecular formula C ₆₂ H ₉₂ Cl ₂ N ₆ O ₈ and a molecular weight of 1120.37 g mol ^-1 are used. The structural formula of the infrared absorber is included


specified. This infrared absorber has an absorption maximum at 1064 nm and a max. Absorbance of 81300 (mol.cm) ^-1 . 4.8% by weight of the infrared absorber material is required for about 50% laser light absorption as an additive in the colors C, M and Y for a layer thickness of 2 µm (according to the Lambert-Beer extinction law). (For comparison: 15.9 percent by weight for approximately 90%, 9.6 percent by weight for approximately 75% and 2.5 percent by weight for approximately 30%.) The device for supplying radiation energy comprises a laser as a radiation energy source which emits at 1075 nm, for example, a ytterbium fiber laser YLR-100 from IPG Photonics can be used. The aforementioned laser from IPG Photonics has a maximum optical output power of 100 W. The beam geometry in focus can be 3 mm × 3 mm. The emission wavelength is therefore sufficiently resonant to the absorption maximum of 1064 ± 15 nm; the infrared absorber shows an absorption greater than 50%. In this exemplary embodiment, a beam profile and an irradiation time of 5 ms and an energy per area of 417 mJ / cm ^{2 have been} selected at a printing speed of 2 m / s (corresponds to 14400 prints per hour with an arc length of 50 cm). The absorption of radiation by water vapor in the air is less than 0.1%.

In a fourth exemplary embodiment of the embodiment of the process according to the invention, bis (3,4-dimethoxy-2'chlorodithiobenzil) nickel with the empirical formula C ₃₂ H ₂₆ Cl ₂ NiO ₄ S ₄ and a molecular weight of 732.4 g mol ^{-1 is} used as the infrared absorber , The structural formula of the infrared absorber is included


specified. This infrared absorber has an absorption maximum at 885 nm and a max. Absorbance of 160000 (mol.cm) ^-1 . 3.2% by weight of the infrared absorber material is required for about 75% laser light absorption as an additive in the colors C, M and Y for a layer thickness of 2 µm (according to the Lambert-Beer extinction law). (For comparison: 5.3 percent by weight for approximately 90%, 1.6 percent by weight for approximately 50% and 0.8 percent by weight for approximately 30%.) The device for supplying radiation energy comprises, as radiation energy source, a laser which emits at 870 nm, for example, a fiber-coupled laser diode system DLDFC-50 from Laser2000 can be used. The laser from Laser2000 has a maximum optical output power of 50 W and can be used in cw mode or pulse mode. The emission wavelength is therefore sufficiently resonant to the absorption maximum of 885 ± 15 nm; the infrared absorber shows an absorption greater than 50%. In this exemplary embodiment, a beam profile and an irradiation time of 5 ms have been selected for an energy per area of 152 mJ / cm ² at a printing speed of 2 m / s (corresponds to 14400 prints per hour with a sheet length of 50 cm). The absorption of radiation by water vapor in the air is less than 0.1%. LIST OF REFERENCE SIGNS 10 radiation energy source
12 light
14 substrate
16 Path of the substrate
18 pressure gap
110 impression cylinders
112 impression cylinders
114 ink
116 Position on the substrate
20 field of radiation energy sources
22 Connection for the transmission of control signals
24 control unit
30 printing unit
32 investors
34 outriggers
36 central source of radiant energy
38 light-guiding element
310 projection element
312 alternative source of radiant energy
314 further alternative sources of radiant energy

Claims (15)

1. Device for supplying radiation energy of a wavelength in the near infrared to a printing material ( 14 ) in a planographic printing machine with at least one radiation energy source ( 10 ), the light ( 12 ) of which on the printing material ( 14 ) on the path ( 16 ) of the printing material ( 14 ) by the printing press at a position ( 116 ) which is arranged downstream of at least one printing nip ( 18 ) in a printing unit, characterized in that the radiation energy source ( 10 ) essentially only emits light ( 12 ) whose wavelength is non-resonant with absorption wavelengths of water (H ₂ O). 2. Device for supplying radiation energy according to claim 1, characterized in that the radiation energy source ( 10 ) emits narrowband light ( 12 ) whose wavelength is between 700.00 nm and 2500.00 nm. 3. Device for supplying radiation energy according to claim 1 or 2, characterized in that the radiation energy source ( 10 ) is a laser. 4. Apparatus for supplying radiation energy according to claim 3, characterized, that the laser is a semiconductor laser or a solid-state laser. 5. Device for supplying radiation energy according to one of the preceding claims, characterized in that the device has a plurality of radiation energy sources ( 10 ) which are arranged in a one-dimensional field, a two-dimensional field ( 20 ) or a three-dimensional field and whose light is on a number of positions ( 116 ) meets the printing material ( 14 ). 6. Device for supplying radiation energy according to one of the preceding claims, which is additionally assigned a control unit ( 24 ), characterized in that the light ( 12 ) incident on the printing material ( 14 ) at a position ( 116 ) in terms of its intensity and exposure time is controllable for each radiation energy source ( 10 ) independently of the other radiation energy sources ( 10 ). 7. Device for supplying radiation energy according to one of the preceding Expectations, characterized, that the wavelength is 870.00 nm ± 50.00 nm and / or 1050.00 nm ± 50.00 nm and / or 1250.00 nm ± 50.00 nm and / or 1600.00 nm ± 50.00 nm. 8. Device for supplying radiation energy according to one of the preceding claims, characterized in that light ( 12 ) from at least two radiation energy sources ( 10 ) strikes at a position ( 116 ) on the printing substrate ( 14 ). 9. Device for supplying radiation energy according to one of the preceding claims, wherein the planographic printing press has at least two printing units ( 30 ), characterized in that the position ( 116 ) at which the light on the printing material ( 14 ) in the path ( 16 ) through the planographic printing machine hits, the last printing nip ( 18 ) of the last printing unit ( 30 ) is the number of printing units downstream. 10. planographic printing machine with at least one printing unit ( 30 ), characterized by a device for supplying radiation energy according to one of the preceding claims. 11. A method for supplying radiation energy of a wavelength in the near infrared to a printing material ( 14 ) in a planographic printing machine, by illuminating the printing material ( 14 ) with light ( 12 ) from at least one radiation energy source ( 10 ), the light ( 12 ) being applied to the Printing material ( 14 ) on the path ( 16 ) of the printing material ( 14 ) through the printing machine at a position ( 116 ), which is arranged after at least one printing nip ( 18 ) in a printing unit, characterized by supporting the absorption of the radiation energy in the printing ink at least one infrared absorber, which is added to the printing ink. 12. A method for supplying radiation energy according to claim 11, marked by Inserting a device for supplying radiation energy according to one of the Claims 1 to 9. 13. A method for supplying radiation energy according to claim 12, characterized in that the light emitted by the radiation source ( 10 ) is substantially resonant to an absorption maximum of the infrared absorber. 14. A method for supplying radiation energy according to claim 11, 12 or 13, characterized, that the infrared absorber substance is one of the following substances: benzene ammonium-N, N'-2,5- cyclohexadiene-1,4-diylidenebis [4- (dibutylamino) -N- [4- (dibutylamino) phenyl] Diperchlorate, bis (3,4-dimethoxy-2'chlorodithiobenzil) nickel, 3-butyl-2 (2 - [- 2- (3- butyl-1.1-dimethyl-1,3-dihydro-benzo [e] indol-2-y lidene) ethylidene] -2-chlorocyclohex-1-enyl] ethenyl) -1,1-dimethyl-1H-benzo [e ] indolium perchlorate and 2 [2- [2Chloro-3- [2- (3-ethyl-1,3-dihydro-1,1-dimethyl-2H-benzo [e] indol-2ylidene) - ethylidene] -1-cyclohexen-1-yl] ethenyl] 3-ethyl-1,1-dimethyl-1H-benzo [e] indolium Tetraflouroborat. 15. A method for supplying radiation energy according to claim 11, 12, 13 or 14, wherein the method is carried out in a planographic printing press with a number of printing units ( 30 ) in which a number of printing inks are printed, characterized by preparing at least one of the Number of inks with an infrared absorber before printing the inks.