EP1466731A1 - Method for drying an ink on a printed material in a printing press and printing press - Google Patents

Abstract

The printing machine (30) handles paper sheets pulled from a stack (36) on a continuous web. The sheets pass through a conditioning station (34) which may have wetting rollers (310) dipping in troughs of water and a half-tone picture printing roller (120). The wetting station is followed by printing stages (32) with clusters of lamps (10) near printing rollers (110) for applying individual colors of inks. The printed sheets pass through a final dryer to a collector (38).

Description

The invention relates to a method for drying an ink on a Printing material in a printing press, the printing material in a first position a path along which the printing material is moved through the printing press, is printed with at least one printing ink. Furthermore, the invention relates to a Printing machine with at least one printing unit and a drying device one along the path of a substrate through the printing press to the printing unit downstream position for supplying energy to the substrate.

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, flexographic printing machines and the like, which are known sheet-like or web-shaped printing materials, in particular paper, cardboard, cardboard and the like, process and which cause the ink to adhere to the substrate or assist by emitting radiant energy, particularly in the form of light, on the Printing material located printing material is supplied.

The so-called UV inks harden by polymerization, which by photoinitiation is triggered by light in the ultraviolet. In contrast, there is widespread use 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, whereby the resin molecules come closer and possibly can polymerize more easily. The drying process is also of the type of Substrate, for example the raw material used for paper, a primer or a dash, heavily dependent.

The specified combinations of substrate and Printing ink not coordinated with each other with regard to the drying process, so that drying a processed substrate is time-consuming. Although with one reinforced powder in the display of the risk of dropping ink in one Stack formation are encountered, however, this measure increases the environmental impact. In addition, long waiting times are not insignificant until the printed products or signatures can be processed.

For example, it is known from DE-OS-1 936 467 that a printing material or Print medium with a drying-promoting substance, a catalyst, in the Print carrier material or as a pigment line can be provided, so that at Application of printing ink to the substrate, the printing ink hardens or dries. The disadvantage here is that a direct, essentially uncontrolled reaction takes place directly during printing. For example, in an undesirable manner Dry the ink on the printing cylinder and contaminate the printing unit.

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 for heating solvent-based printing inks his. The radiation energy source is arranged outside of the printing press in order to avoid that due to unavoidable or shieldable heat loss parts of the printing machine are undesirably heated. However, this is disadvantageous. that an additional system component for the printing press is provided separately must become.

To remove solvent from a solvent-based printing ink and / or water further, e.g. from US 6,026,748 that a on a printing press Drying device with infrared lamps, which short-wave infrared light (near Infrared) or medium-wave infrared light can be provided. The Emission spectrum from lamp light sources is broadband and consequently leads to one Offer a variety of wavelengths. A disadvantage of such Drying equipment in the infrared is a relative part of the energy absorption takes place in the paper, whereby the color is only indirectly heated. A quick drying is only possible through a correspondingly high energy input. But there is under among other things, the risk that the substrate will dry out unevenly and become wavy can.

In electrophotographic printing technology e.g. known from DE 44 37 077 A1, a fixation of toner on a recording medium by diode laser 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.

It is also known from DE 101 07 682 A1 that an electrophotographic Printing machine or copying machine a plurality of fixing devices for toner may have, wherein each of the fixing devices has a wavelength range electromagnetic radiation is emitted, which is a maximum absorption wavelength corresponds to the type of toner assigned to this fixing device, but no or only a small amount Has absorption at absorption wavelengths of the other types of toners.

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 other chemical or physical drying processes as described above lie. In connection with the invention, the term solvent-based Printing ink means in particular colors whose solvent components are watery or can be organic in nature, based on binder systems that are oxidative, Allow to polymerize ionically or radically. An energy input for drying solvent-based printing inks are said to have the effect of evaporation of the solvent and / or the effect of knocking off the substrate and / or the effect of Support or promote polymerization, with undesirable side effects, such as, in particular, excessive heating of the solvent-containing printing ink, which leads to Component decomposition or overheating of the solvent can be avoided become. The energy input should not only, as in the case of toner fixing, for Melting of particles can be introduced.

In the previously registered document DE 102 34 076.5 it is disclosed that one in one Printing unit printing ink an infrared absorber - a substance which in the absorbed near infrared spectral range - is added. By means of a Narrow downstream radiation energy source, preferably a pressure gap Laser light source, the printing ink is illuminated on the substrate. The feeding of Light of a wavelength that is substantially resonant to an absorption wavelength of the infrared absorber is, causes, enables or supports an energy input into the Ink such that the ink is dried. The wavelength of the Radiation energy source and the absorption wavelength of the infrared absorber are such chosen that at the same time the wavelength used is non-resonant to water, so that the energy input into the substrate is reduced or avoided.

The object of the present invention is a method for drying an ink to create on a substrate in a printing press and a printing press which enable the drying of printing ink printed in the printing press on the substrate.

This object is achieved according to the invention by a method with the features according to Claim 1 and solved by a printing press with the features according to claim 9. Advantageous developments of the invention are in the dependent claims characterized.

According to the invention, the method for drying an ink comprises on a Substrate in a printing press at least the following steps: The substrate is moved along a path through the printing press. In a first position of the Path is the substrate with at least one printing ink, especially one solvent-based printing ink, printed. In a second position on the Printing material applied a treatment agent, which accelerates the Dries the ink on the substrate. In other words, that Treatment agent serves as a catalyst for accelerated drying of the printing ink on the substrate or for accelerated energy consumption, especially as direct catalyst, which the required energy consumption for drying the Printing ink relieved.

By using a treatment agent, it is advantageously not necessary, the recipes of the printing inks used, especially the ones used solvent-based printing inks, modified to accelerate drying. It standard printing inks can therefore be used. The dosage and Composition of the treatment agent is in function of the material of the Substrate, the printing ink to be printed and the processing parameters, Application parameters or process parameters to choose. The goal to be optimized is one maximum possible drying of the printing ink on the substrate when leaving the printing press, i.e. in the delivery of sheet-shaped substrates or at Entry into the folder with web-shaped substrates. Advantageously, one Adaptation of the treatment agent used to the substrate used possible: A processing parameter-specific coordination of the Effectiveness of the treatment agent on the properties of the Printing material, the printing machine and the printing inks used can be reached.

In addition, at least a third position of the path can be arranged at a later time the substrate is dried by exposure to radiation energy. In particular, the treatment agent accelerates the drying of the Ink at this third position.

In a first embodiment of the method, the first position can be timed before second position can be passed by the substrate, and the treatment agent is in Form of a coating, for example as an added component in one commercially available protective varnish, applied. In a second embodiment of the The first position can move after the second position of the substrate happen, and the treatment agent is in the form of a primer, for example as an added component of a commercially available primer paste, applied.

The treatment agent can also be a catalyst, especially one directly for the Energy absorption acting catalyst, or a reaction trigger. In other Words, the treatment agent can on the one hand in front of the printing substrate Applying the printing ink so that subsequent drying facilitates is accelerated or simplified. On the other hand, the treatment agent can alternatively to this or in addition to the applied or to be applied Apply printing ink that their drying easier, accelerated or simplified becomes. The treatment agent can have a switching function or trigger function: It can act in such a way that the effect on drying only after the interaction of the Treatment agent is triggered with the energy introduced. In other words, that Treatment agent can be such that it is only after a time delay Effectiveness unfolds. The treatment agent can be such that it is neither Components of the printing ink still chemically modified additives in the printing ink. Different expressed, the treatment agent directly causes the acceleration of the Energy consumption, not indirectly by changing the printing color or the Ink additives.

The treatment agent can in particular be a desiccant or a basic solution, in particular a metal hydroxide in aqueous solution, for example sodium hydroxide solution or Potash lye, or a binder or comprises.

In a preferred embodiment of the method according to the invention at least the third position of the path of the substrate with light one narrowband radiant energy source illuminated. The treatment agent then comprises an infrared absorber, which has an absorption wavelength that is substantially resonant to the wavelength of that emitted by the narrowband radiation energy source Light is. Examples of infrared absorbers are already mentioned above previously disclosed document DE 102 34 076.5. This document DE 102 34 076.5 is incorporated by reference into the disclosure of this illustration. On Another example of an infrared absorber is indium zinc oxide, a substance that is used in Lacquer systems are used. Other infrared absorbers are in the following Documents described: DE 100 22 037 A1, WO 00/140127, JP-A-070278795 and JP 63319192, and in the dissertation "Monomers and polymeric rylene dyes as functional materials "by S. Becker, Department of Chemistry and Pharmacy, Johannes Gutenberg University Mainz, 2000.

In an inventive manner, the treatment agent can be an infrared absorber (also called Infrared absorber called) have. A coupling of the light into the Printing ink and / or absorption of the radiation energy in the printing ink is caused by the as a primer or coating with the printing ink on the processed Printing material in contact with infrared absorbers creates, enables, supports, 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, as enumerated in interaction or as alternatives. The energy input at the third position, which is used to Heat can lead to accelerated drying of 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 can also be used as an infrared absorber, IR absorber, or IR absorber substance or the like. 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 nationwide job on a substrate of an infrared absorber requires very good transparency of the infrared absorber in the visible spectral range. A Correction of a color location shifted by an infrared absorber at non-image areas by printing ink is of course not possible. It is therefore advantageous to have one To use infrared absorber, which is still a light one when applied Has intrinsic coloration in the visible spectral range, but at the latest at Drying, that is, loses on interaction with the acting radiation energy. An example of a class of infrared absorbers and individual examples of such Infrared absorbers are described in US2002 / 0148386A1, the disclosure of which is described in US Pat this representation is recorded.

A relatively high energy input directly into the printing ink, especially solvent-based ones Printing ink, especially supported by an infrared absorber in the substrate, in a primer layer or in a coating, is advantageously possible without getting an unwanted energy input into the substrate. This explains itself on the one hand because the light cannot be directly absorbed by the substrate, and secondly by the fact that the energy absorbed by the color layer decreases Fraction of seconds spread over ink and substrate. The heat capacity and the proportions are distributed so that a short heating of the color 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 by means of the method according to the invention avoided.

In other words, the method according to the invention enables one Drying of the printing ink, in particular solvent-based printing ink, on the Substrate without influencing its drying out too much.

At this point it should also be noted that in the case of a large-area application, a Treatment agent, in particular an infrared absorber, a homogeneous heating or Temperature control of the printing material can be achieved regardless of the printed image or subject can, so that warping or curling of the printing material can be avoided.

The drying method according to the invention can advantageously be carried out in one Printing unit with a drying device, as described in this document, be performed. In particular, the emission of a Radiant energy source of the drying device and the absorption of the Infrared absorbers set or adjusted or provided to match each other. In in other words, the radiation energy source is said to be one of the absorption of the infrared absorber corresponding wavelength or more of the absorption of the infrared absorber corresponding wavelengths, in particular only this one or more Wavelengths, emit. So the light emitted by the radiation energy source is particularly preferably quasi-resonant, essentially resonant, in particular resonant an absorption maximum of the infrared absorber, so that the best possible Agreement of the absorption maximum of the infrared absorber with the Emission maximum of the radiation energy source is achieved. The absorption spectrum of the infrared absorber used has in the area of emission Radiation energy source at least 50% of the absorption maximum of the infrared absorber on, preferably at least 75%, in particular at least 90%. An infrared absorber can have one or more local absorption maxima.

Alternatively or in addition, the wavelength of the light can be 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 the light energy by water at 20 ° C. 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 idea, the radiation energy source emits only a 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 narrowband: the Radiation energy sources can be up to ± 50 nm wide, for example emit a wavelength of less than ± 50 nm width, it can also be one or trade several individual spectroscopically narrow emission lines. Furthermore lies in advantageous embodiment, the emission maximum of the narrowband Radiation energy source or the wavelength of 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 a partial area of the so-called window in Paper absorption spectrum. An emission at 870.00 nm ± 50.00 is particularly advantageous 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 also 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 Heitran database at a temperature of 296K, in 1m absorption section, 15000 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%, 1100nm 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 further than 1 m 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 of the Treatment agent can absorb different wavelengths. By means of the The device according to the invention is the one located on the printing substrate Treatment agent in the planographic printing press light, preferably in the near infrared, below Avoiding water absorption wavelengths, for example due to the radiation only a few wavelengths of a light source emitting a line spectrum are offered.

According to the invention, a printing press with at least one printing unit is on a first Position of a path of a substrate through the printing press and one Drying device on a third downstream of the printing unit along the path Position for supplying energy to the substrate, suitable for carrying out a Process for drying according to this illustration: An inventive Printing press comprises at a further, upstream of the drying device second position a conditioning unit for applying a treatment agent, which accelerates the drying of the substrate at the third position. The Depending on the arrangement, the conditioning unit can also be used as a treatment agent priming unit or Treatment agent coating plant are called.

In an advantageous embodiment, the conditioning unit is designed in such a way that the treatment agent can be applied to the printing material from both sides is. In a first variant, the conditioning unit can be used as a separate one Processing unit of a printing press can be executed. In an alternative second Variant, the conditioning unit is modular as an insert for a printing unit.

In a preferred embodiment, the drying device comprises a narrowband radiation energy source, which light of a wavelength in the near infrared emitted. In order to achieve a narrow-band emission with a high spectral one To achieve power density, the radiation energy source is preferably a laser. Alternatively, a broadband light source, for example an IR carbon emitter, be used 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, Nd: YAG. 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. However, imaging optics can also be used, particularly suitable for focusing the emitted light on the substrate.

In an advantageous development, the printing unit according to the invention has a number of laser light 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 the light of which is incident on the number of positions Substrate meets. By using a number of individual laser light sources for individual areas on the printing material, the maximum required output power of the laser light sources is reduced. Laser light sources with lower output power are usually cheaper and have a longer life expectancy. In addition, unnecessarily high heat loss is avoided. The radiation energy introduced per area by the supply of light is between 100 and 10,000 mJ per cm ² , preferably between 100 and 1,000 mJ per cm ² , in particular between 200 and 500 mJ per cm ² . The printing material is irradiated for a length of time between 0.01 ms and 1 s, preferably between 0.1 ms and 100 ms, in particular between 1 ms and 10 ms.

It is particularly advantageous if that which strikes the printing material at one position Light in its intensity and exposure time for each laser light source independent of the other laser light sources can be controlled. For this purpose, a control unit, regardless of or integrated into the machine control of the printing press his. By controlling the laser light source parameters, it is possible to Regulate energy supply at different positions on the substrate. A Energy supply can then cover the printing material at the present positions can be adjusted on the substrate. It is also advantageous that To set up the printing unit according to the invention with a number of laser light sources in such a way that at one position on the substrate there is light of at least two Radiant energy sources strikes. On the one hand, it can be partial, on the other hand are completely overlapping beams of light. The required maximum The output power of a single laser light source is then lower, moreover there is redundancy if a failure of a laser light source occurs.

The printing press according to the invention can be a direct or indirect one Planographic printing machine, lithographic printing machine, offset printing machine, flexographic printing machine or the like. On the one hand, the position at which the light is on hits the substrate in the path through the printing press, the last printing nip of the last printing unit subordinate to the number of printing units, i.e. all printing columns his. On the other hand, the position can also be arranged after a first pressure gap and one upstream of the second printing nip, ie at least between two printing units. The Printing machine can be a sheet-processing or a web-processing printing machine his. A sheet-fed printing machine can have at least one feeder Printing unit, possibly a finishing unit (punching unit, coating unit or the like) and one Have booms. A web-processing printing machine can have a reel changer, a number of printing units printing the printing material web on both sides, one Include dryer and folder.

Figur 1

eine schematische Darstellung zur Erläuterung einer Ausführungsform des erfindungsgemäßen Verfahrens zum Trocknen,

Figur 2

eine schematische Darstellung einer vorteilhaften Weiterbildung einer Ausführungsform des erfindungsgemäßen Verfahrens,

Figur 3

eine Ausführungsform einer erfindungsgemäßen Druckmaschine mit einem den Druckwerken nachgeordneten Konditionierwerk und einer Trocknungseinrichtung, und

Figur 4

eine Ausführungsform einer erfindungsgemäßen Druckmaschine mit einem den Druckwerken vorgeordneten Konditionierwerk und einer Trocknungseinrichtung.

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

Figure 1

1 shows a schematic illustration to explain an embodiment of the drying method according to the invention,

Figure 2

1 shows a schematic representation of an advantageous development of an embodiment of the method according to the invention,

Figure 3

an embodiment of a printing press according to the invention with a conditioning unit downstream of the printing units and a drying device, and

Figure 4

an embodiment of a printing press according to the invention with a conditioning unit upstream of the printing units and a drying device.

FIG. 1 shows a schematic illustration to explain an embodiment of the drying method according to the invention. A radiation energy source 10, in particular a laser, preferably a diode laser or solid-state laser is within one Planographic printing machine arranged such that the light 12 emitted by it onto a Printing material 14 on its path 16 through the planographic printing press at a third position 116 strikes, which is arranged after a first position 18, here a pressure gap. While the printing substrate 14 is shown by way of example in the form of an arc in FIG. 1, the Printing material can also be guided in web form through the planographic printing machine. The Orientation of the path 16 of the printing material 14 is indicated by an arrow. The path here is generally curved or unrestricted non-linear course, in particular lying on a circular arc, shown linearly. The first position 18, here the pressure gap is in the embodiment shown in FIG. 1 by the interaction of the impression cylinder 110 and an impression cylinder 112 defines the printing ink on the substrate when the press is in operation is transmitted. Depending on the special printing process in the Planographic printing machine can be a printing form cylinder or a printing cylinder 110 Be a blanket cylinder. At a second position 124, which of the first position 18th is arranged upstream along the path 16, a treatment agent 118, in particular a Infrared absorber, as already described in more detail above, on a printing substrate 14 applied when the printing substrate 14 passes the third position. The second position 124 is through the interaction of a raster cylinder 120, which the treatment agent 118 transported to the printing material 14, and a guide cylinder 122 defined. In In the situation according to FIG. 1, printing ink 114 is in particular on printing material 14 solvent-based printing ink, shown. The light emitted by the radiation source 10 12 falls in a bundle or carpet shape at the second position 116 on the printing material 14. The treatment agent 118, in particular the infrared absorber within this third Position 116 can absorb energy from the light 12 so that the ink 114 can be dried. By advantageously choosing a wavelength that is non-resonant to absorption wavelengths of water, in a development of the invention absorption in the printing substrate 14 is reduced.

FIG. 2 is a schematic illustration of an advantageous further development of a Embodiment of the method according to the invention. It is an example of a field 20 from Radiation energy sources 10 outlined here three times four, i.e. twelve Radiation energy sources 10. In addition to the two-dimensional field 20 shown here also a one-dimensional field or a one-dimensional line, oriented across the width of the printing material 14 may be provided. A two-dimensional field, as well as one three - dimensional field, the light of which is distributed in two dimensions onto the Printing material 14 meets, among other things, the advantage that a quick drying parallel or simultaneous irradiation of a group of positions in a column of the Field 20 is achieved. The speed at which the substrate adapts to the Radiation energy sources 10 moved past can consequently be higher than in the case of only one one-dimensional field. The field 20 can also have a different number of Have radiation energy sources 10. From each of the number of Radiation energy sources 10 are supplied with light 12 on the printing material 14. The third Positions 116 where the light 12 is on the printing substrate 14, which a path 16 followed by the planographic printing press, are a printing nip 118 defined by an impression cylinder 110 and an impression cylinder 112, downstream. Individual third Positions 116 can partially coincide, as is the case in FIG. 2 for the front lying row of radiation energy sources 10 is shown, or even in substantially completely overlap. The field 20 of radiation energy sources 10 is a control device 24 is assigned to which it is connected by means of a connection 22 Can exchange control signals. By means of the control device 24, a Control of the field 20 can be carried out such that an energy supply corresponding to the amount of printing ink at the third position 116 on the printing substrate 14 is carried out.

Figure 3 relates schematically to an embodiment of an inventive Printing machine 30 (perfecting press) with one of the printing units 32 downstream conditioning unit 34 and a drying device, here Radiation energy sources 10, particularly suitable for carrying out the inventive method. The printing press 30 has one feeder 36, several Printing units 32, shown here two, a conditioning unit 34 and a delivery 38. Sheet-like printing material is printed along the path 16 by the printing press 30 emotional. Each printing unit 32 includes an inking unit and a, not explained here in detail Dampening system and carries printing ink, especially solvent-based printing ink, in the from associated pressure cylinder 110 and impression cylinder 112 formed pressure gap, through which the path 16 runs onto the printing material. Between those in FIG. 3 shown printing units 32, a turning device is provided so that a printing material can be processed on both sides in the printing press 30. The printing material arrives finally on its path 16 into the conditioning plant 34. In the shown Embodiment, the conditioning unit has two anilox cylinders 120, which the Contact printing material from one side at a time, so that treatment agents, especially infrared absorber, is applied. The treatment agent, in particular Infrared absorber is removed from a reservoir by means of an immersion roller 310 and transfer over a large area to the substrate. In other words, the conditioning plant In one embodiment, components can be similar or identical to components in have a conventional coating unit, so that the treatment agent as possible is evenly fed to the substrate and applied. The conditioning plant can be carried out independently of the printing unit or printing units. In the here The embodiment shown in FIG. 3 is the dryer device in the arm 38 arranged: The substrate is illuminated on both sides by lighting with light from Radiation energy sources 10 dried by the treatment agent, in particular the Infrared absorber, which supports drying, especially energy absorption.

FIG. 4 is a schematic illustration of an embodiment of a Printing machine 30 according to the invention (perfecting press) with a Printing units 32 upstream conditioning unit 34 and a drying device, here radiation energy sources 10, which at different positions in the Printing machine 30 can be arranged. The printing press 30 has a feeder 36, a conditioning unit 34, a plurality of printing units 32, here shown two, and one Boom 38 on. Arc-shaped printing material is along the path 16 through the Printing machine 30 moves. The printing material comes first from the feeder 36 on his Path 16 through the printing press 30 into the conditioning unit 34. In the shown In one embodiment, the conditioning unit 34 has two anilox cylinders 120 which support the Contact printing material from one side at a time so that there are treatment agents on both sides is applied. The treatment agent is one by means of an immersion roller 310 Remove the reservoir and transfer it over a large area to the substrate. Every printing unit 32 includes, not explained here, an inking unit and a dampening unit and carries Printing ink, solvent-containing printing ink, in the associated printing cylinder 110 and Counter pressure cylinder 112 formed pressure gap through which the path 16 runs the substrate. Between the printing units 32 shown in FIG Turning device is provided so that a printing material on both sides in the printing press 30 can be processed.

In the embodiment shown here in FIG. 4, three variants of the arrangement of the Radiation energy sources shown for drying: The three variants are only for Simplification of the representation of the invention within one embodiment in one Figure shown. Printing machines according to the invention can also do these three variants each individually or in combination of two or all three at the same time. In In a first variant, radiation energy sources 10 can directly be those of printing cylinders 110 and impression cylinders 112 are formed in a printing unit 32 be subordinate. The radiation energy sources 10 already illuminate the printing material on the impression cylinders 112 after ink has been transferred to the substrate has been. In a second variant, radiation energy sources 10 can be used in the last Printing unit 32 can be arranged such that at least one first radiation energy source 10 a first side of the printing material and at least one second radiation energy source 10 illuminate a second side of the printing material. This configuration can For example, can be realized in that a radiation energy source 10 den Printing material on the impression cylinder 112 and another radiation energy source 10 the printing material on the cylinder directly downstream of the impression cylinder 112 illuminated (see Figure 4). In a third variant, radiation energy sources 10 are such arranged in the arm 38 that the printing material with light from Radiation energy sources 10 is illuminated. The substrate will dry accelerates by the treatment agent supports energy absorption.

LIST OF REFERENCE NUMBERS

10

Radiant energy source

12

light

16

path

14

substrate

18

first position

110

pressure cylinder

112

Impression cylinder

114

printing ink

116

third position

118

treatment agents

120

screened cylinder

122

guide cylinder

124

second position

20

Field of radiation energy sources

22

Connection for the transmission of control signals

24

control unit

30

press

32

printing unit

34

Konditionierwerk

36

investor

38

boom

310

dipping roller

Claims (16)

Method for drying an ink (114) on a printing material (14) in a printing machine (30), the printing material (14) at a first position (18) of a path (16) along which the printing material (14) passes through the printing machine (30) is moved, printed with at least one printing ink (114),
characterized in that a treatment agent (118) which accelerates the drying of the printing ink (114) on the printing material (14) is applied to the printing material (14) at a second position (124) of the path (16). A drying method according to claim 1,
characterized in that the printing substrate (14) passes the first position (18) before the second position (124) and the treatment agent (118) is applied in the form of a coating. A drying method according to claim 1,
characterized in that the first position (18) is passed by the printing material (14) after the second position (124) and the treatment agent (118) is applied in the form of a primer. A drying method according to claim 1, 2 or 3,
characterized in that the printing substrate (14) is dried at least at a third position (116) of the path (16) by exposure to radiation energy. A drying method according to claim 1, 2, 3 or 4,
characterized in that the treatment agent (118) is or comprises a desiccant or a basic solution or a binder. The method for drying according to claim 4, wherein at least the third position (116) of the path (16) the printing material is illuminated with light (12) from a narrow-band radiation energy source (10),
characterized in that the treatment means (118) comprises an infrared absorber which has an absorption wavelength which is essentially resonant to the wavelength of the light (12). A drying method according to claim 6,
characterized in that light (12) has a wavelength between 700 nm and 3000 nm. A drying method according to claim 6 or 7,
characterized in that the wavelength of the light (12) is non-resonant to absorption wavelengths of water (H ₂ O). Printing machine (30) with at least one printing unit (32) at a first position (18) of a path (16) of a printing material (14) through the printing machine (30) and a drying device on one along the path (16) of the printing unit (32) downstream third position (116) for supplying energy to the printing substrate (14), suitable for carrying out a method for drying according to one of claims 4 to 8,
characterized in that the printing machine (30) at a further second position (124) upstream of the drying device has a conditioning unit (34) for applying a treatment agent (118) which accelerates the drying of the printing ink on the printing material at the third position (116 ) causes includes. Printing machine (30) according to claim 9,
characterized in that the conditioning unit (34) is designed in such a way that the treatment agent (18) can be applied to the printing material (14) from both sides. Printing machine (30) according to claim 9 or 10,
characterized by
the drying device comprises a narrowband radiation energy source (10) which emits light (12) of a wavelength in the near infrared. Printing machine (30) according to claim 11,
characterized in that the narrow band radiation energy source (10) is a laser light source. Printing machine (30) according to claim 12,
characterized in that
the laser light source is a semiconductor laser or a gas laser or a solid-state laser. Printing machine (30) according to one of claims 11, 12 or 13,
characterized in that the printing press (30) has a plurality of radiation energy sources (10) which are arranged in a one-dimensional field, a two-dimensional field or a three-dimensional field and whose light (12) is at a number of positions on the printing material (14) meets. Printing machine (30) according to one of claims 10 to 14,
characterized in that the light (12) incident on the printing material (14) at one position can be controlled in its intensity and exposure duration for each radiation energy source (10) independently of the other radiation energy sources (10). Printing machine (30) according to one of claims 10 to 15,
characterized in that light (12) from at least two radiation energy sources (10) strikes the printing material at a position.

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