DE19602307A1 - Printing machine with coated cylindrical film written by infrared laser - Google Patents

Abstract

The machine incorporates a cylinder (2) to which the printing forme is attached and from which it is removed automatically. The forme consists of a film (1) with a substrate (3) of anodised aluminium or specially coated polyester (especially polyethylene terephthalate), a conductive layer (4) of e.g. aluminium, bismuth, tin or tellurium, and a polysiloxane coating (5). The laser beams modify the oil- or water-repellent properties of the surface of the coating, which incorporates an acid-forming photoinitiator and a polymer with groupings unstable in acid. The film is either rolled on to and off the cylinder, or applied from a stack of prepared sheets.

Description

The invention relates to a printing press with at least one printing unit with a forme cylinder carrying a printing plate, on which the printing plate by means of an automatic device can be applied, can be imaged in the printing unit and is exchangeable for a new printing plate after the print job has ended.

A printing press is already known from DE 43 03 872 A1 Forme cylinder a renewable printing plate is mounted in the form of a printing film. Each time a print job is completed, the printing film is placed over the Shell surface of the forme cylinder pushed forward by a first roll new printing film is unwound, while the used printing film on a second roll is wound up. Both rollers are inside the forme cylinder appropriate. There is also an imaging device within the printing press Laser writing system or a thermal writing system, provided so that the Printing film can be reimaged within the printing press.

A printing press is known from US Pat. No. 4,718,340, the forme cylinder of which is a erasable printing plate. Inside the press is one hydrophilic surface on the forme cylinder as a whole with a hydrophobic Material coated. A coating device applies a liquid to the The outer surface of the forme cylinder, which is used to produce a uniform Layer thickness is doctored. This layer is then attached to the imaging Locations removed either by electroerosion or by laser ablation. After A print job can be carried out by the applied layer according to existing areas using a cleaning device remove a solvent. A knife scrapes the remnants of the layer from the hydrophilic surface of the forme cylinder while the solvent is evaporated at the same time.

An erasable printing form is also known from DE 44 26 012 A1. After Finishing a print job becomes a cleaning fluid or a nozzle  Plate cleaner sprayed onto the surface of the forme cylinder. Then will this remedy along with the dirt it has loosened from one Cleaning cloth soaked up. Then the surface of the Dry the forme cylinder with hot air to remove solvent components.

When using an erasable, reusable printing plate that is on the Surface of the forme cylinder is formed by a layer that can be applied thereon , it is necessary to carry out several process steps within the printing press to be carried out one after the other. First, z. B. the material in which the Image information to be written is applied to the forme cylinder will. Possibly there is a post-treatment step z. B. that Drying this layer, required. Then the image information is in the Material registered, there may be another one after that Post-treatment step required. Only now can the print job be printed will. After printing, a cleaning step, e.g. B. to remove Ink, needed. Only then can the actual deletion process take place connect, which in turn can consist of several process steps, before the next cycle can start applying new material into the the image information is written.

An economical use of erasable printing forms requires that erasing can be done faster and cheaper than the automatic or semi-automatic Change the printing plate by means of a plate feeder on each Printing unit of the printing press. However, as stated above, this requirement is only very difficult to reach. The large number of process steps required prevents a sufficiently quick rewritability. The to carry out the Process steps required consumables, e.g. B. cleaning agents, occasionally reach or exceed the cost of a new printing plate. For Carrying out the process steps requires additional devices that the Increase the cost of the press and have additional space that the Use of the erasable plate is not permitted on all existing printing machines. Air containing solvents must also be removed. The number also leads the process steps, the devices and the required process materials into one Complexity in the printing press that the reliability and availability of the Printing press reduced.

It is the object of the present invention to provide a printing press which on the one hand is simple and on the other hand a quick change between different print jobs allowed.

This object is, as stated in claim 1, solved. According to the Invention, only a few process steps are required to switch between perform two print jobs. A new printing plate will automatically introduced, it is imaged within the printing press Print job is printed and finally the printing plate becomes automatic changed by ejecting the old pressure plate and a new pressure plate is introduced. In this way the number of process steps is compared to that Processes known from the prior art are significantly reduced. The time of Printing plate change is essentially due to the illustration required time determined. As an additional device, only one Pressure plate changing device needed.

Printing plates are preferably used for imaging within the printing press suitable for the exposure, especially in the infrared wavelength range absorb electromagnetic waves and either none or one need a quickly realizable development step. It is either sufficient that the Printing film at the image or at the non-image points of thermal energy is applied, or there is still an additional development step It is necessary to apply a liquid to the forme cylinder. Preferably carry out this development step in that the dampening solution Development liquid is added so that the printing form during the Pressure process is developed. Another print film is peelable Layer as a layer, which after laser imaging those parts of the layer underneath it that was not illustrated. This method is called laser ablation transfer (LAT).

After imaging printing plates, removal can be an additional step of the remainder of the image created by wiping, brushing or Vacuuming become necessary.  

The imaging of such printing plates is outside the printing press is known, however, it has disadvantages which, according to the invention, are advantageous the integration of plate production into the printing machine can be solved. A plate setter would be fully utilized, to supply the printing plates for a printing press. In this case, one Printing machine with automatic plate changing and exposure device essential advantages within the printing press. A Plate receiving device (for printing plates from the platesetter) is anyway in the Printing machine available. The fact that the printing film on the lateral surface of the If the cylinder is imaged, the image is already registered. In addition, a very thin plate substrate can be used.

The invention will now be described in exemplary embodiments with reference to the drawings explained in more detail. Show it:

Fig. 1 is a applied to a forme cylinder pressure foil with two layers,

Fig. 2 is a pressure foil with two layers,

Fig. 3 is a printing film with four layers

Fig. 4 shows a sleeve-shaped printing forme on a forme cylinder,

Fig. 5 is a printing unit with a forme cylinder on which a windable printing film is applied,

Fig. 6 is a printing film with a peelable layer and

Fig. 7 a forme cylinder covered with the printing film, which is imaged by a print head.

A printing film 1 ( FIG. 1) on a forme cylinder 2 has a substrate 3 on which at least one layer 4 is applied. Roughened, anodized aluminum or specially coated polyester, in particular polyethylene terephthalate, are suitable as substrate materials. These materials are generally known for this purpose. The printing film 1 carries the layer 4 on the substrate 3 , which serves as an absorber layer. It absorbs laser beams from a YAG laser, argon laser or from a semiconductor laser. The layer 4 is for example a conductive layer, it consists for example of a metal, in particular aluminum, bismuth, tin or tellurium. It can also consist of carbon in the form of graphite or carbon black. It can also contain dyes or pigments or metal oxides. Suitable dyes are known from US 4,833,124, EP 0 321 923 A1, US 4,772,583, US 4,942,141, US 4,948,776, US 4,948,777 etc. A layer 5 , which contains polysiloxane, is applied above layer 4 . Such a layer structure is known for example from EP 0 573 091 A1.

Instead of two layers 4 and 5 applied to the substrate 3 , in another embodiment ( FIG. 2) only the layer 5 is present on the substrate 3 . In this case, layer 5 contains the absorbent substance as a finely divided dispersion in the material containing the polysiloxane.

Another structure is shown in Fig. 3. In addition to the layers 4 and 5 provided according to FIG. 1, a further layer, the primer layer 6 , is applied to the substrate 3 below the layer 4 . The layer structures shown in FIGS. 1 to 3 are known, for example, from US Pat. No. 5,339,737 or US Pat. No. 5,353,705 and US Pat. No. 5,379,698.

All in Fig. 1 to Fig. 3 constructions shown for the printing sheet 1 can be used when the printing sheet 1 in the form of a sleeve is constructed 31 (Fig. 4). In the exemplary embodiment shown, the sleeve 31 has the layer structure shown in FIG. 2. The sleeve 31 can also be imaged within the printing press. It can be replaced, as described in DE 35 43 704 A1.

Based on the exemplary embodiments described above, it can be seen that the electromagnetic energy, in particular in the form of laser radiation, is coupled either into the layer 4 serving as an absorption layer ( FIGS. 1, 3) or directly into the layer 5 itself ( FIG. 2), which should contain the information to be printed. The material combinations described above for the layer structure are suitable for the waterless lithographic printing process. Layer 5 has an oleophobic surface. At the points where it is ablated by the laser radiation, the oleophilic surface of the underlying layer 4 or the substrate 3 emerges. The debris at the image points of the layer 5 that results from laser imaging can be removed, for example, by means of cloths or brushes. They can also be sucked off by negative pressure using an air stream.

A dampening solution is used for the conventional lithographic printing process used. In this case, the substrate is preferably ink-repellent and dampening properties, while the surface of the top layer is oleophilic. A layer structure that is used for a printing process Is suitable dampening solution, is known for example from EP 0 625 728 A2. The Again, the substrate is a polyester film on which one for both ultraviolet and layer sensitive to infrared radiation is also applied, which is either positive or works negative. It contains a resol resin, a novolak resin, a latent Bronsted acid and an infrared absorber. The substrate can also be of a anodized aluminum surface. After exposure, the Layer can still be developed by an alkaline solution. This is in the printing press an additional device for applying z. B. spraying, to provide this solution. It can also be provided that the solution to the Fountain solution is added so that the development step during the Pressure phase takes place.

Layer structures for a wet printing process that do not require a development step Development solutions are, for example, from the patent applications EP 0 652 483 A1 and EP 0 600 615 A2 are known. According to EP 0 600 615 A2 a the non-image parts hydrophilizing agent the dampening solution of the printing press added.

According to EP 0 646 476 A1, the printing film 11 is imaged without subsequent development by electromagnetic radiation, in particular in the IR range, or by heat. The layer 5 is built up on the substrate 3 as a hydrophilic layer with a hydrophilic polymer acting as a binder and a microencapsulated oleophilic material which forms the image surface when heated. The hydrophilic polymer forms bridging bonds and cross-links in three-dimensional space and has a functional group that combines with the oleophilic material in the microcapsule when it is dissolved, while the oleophilic material has a functional group that connects with the hydrophilic binder. The hydrophilic layer takes on dampening solution at the non-image areas, while the decapsulated oleophilic material binds the hydrophilic polymer at the image areas and causes the oleophilic printing ink to adhere to the free surface.

From EP 0 652 483 A1 a material for the layer 5 of the printing film 1 is also known, which by the action of heat, for. B. by IR radiation emitting laser, becomes hydrophilic, while it was hydrophobic and oleohil before the irradiation, so that it takes on printing ink at the non-irradiated areas. The hydrophilization can be supported by the addition of an acid, the acid being able to be applied to the layer 5 like the dampening solution or together with this in the printing press. The material to be irradiated contains a photothermal converter and a polymer with hydrophobic side chains, e.g. B. t-alkyl carboxylates, t-alkyl carbonates, benzyl carboxylates or alkoxyalkyl esters.

In another method for also to be used in the printing press Imaging a printing film is a layer structure with an adhesive layer or a sequence of peelable layers used, the adhesive strength of one the laser radiation absorbing layer on the by the laser radiation changes the imaged areas so that they remain on the substrate, while the areas not imaged by the laser radiation from the peelable Layer to be taken. Such a layer structure is, for example, from EP 0 510 174 A1, EP 0 160 395 A2 and WO 88/04237.

When using a layer which can be stripped off by radiation with electromagnetic waves to produce a printing form, a layer structure is used which comprises at least three layers 21 , 22 , 23 ( FIG. 6). The layer 21 comprises a transparent material, through which a laser light source 24 irradiates the layer 22 to be exposed to the laser radiation in accordance with the print image to be generated. Layer 21 may include a variety of sheet materials, with polymeric sheet materials being particularly preferred. Polystyrene, polyethylene terephthalate, polyethylene, polypropylene, poly (vinyl) chloride, polycarbonate, poly (vinylidene chloride), cellulose acetate, cellulose acetate butyrate, copolymer materials, for example copolymers of styrene, butadiene, acrylonitriles, e.g. B. Poly (styrene-coacrylonitrile). Layer 22 comprises an image-forming material which is attached to the surface of layer 21 and forms a porous and particulate coating. Layer 22 preferably has a colorant dispersed in a binder, the colorant being a pigment or dye or any color that is in the earth at the higher temperatures required to form the image. Soot is also preferably added to this layer 22 . After imaging by the laser light source 24, the layer 23 forms together with the remaining on its non-image portions of the layer 22, the printing plate or the printing sheet 1, while the peelable layer 21 drives the form cylinder 2 covers the image portions of the layer 22nd The layer 21 together with these portions of the layer 22 is drawn off from the forme cylinder 2 by a gripping device, as is known for example from DE 43 03 872 A1. The layer 23 consists of either a plastic or a paper material or a polymeric material. In addition to layers 21 , 22 and 23 , further layers can be present, as are known, for example, from WO 92/09443 A1, WO 88/04237 A1 or EP 0 590 205 A1. The printing film 1 shown in FIG. 6 is suitable either for driographic printing or for printing using a dampening solution.

For the preparation of an imageable by ablative laser irradiation printing sheet 1 as shown for example in Fig. 1 to Fig. 4, a layer 5, the tetra decanoic acid, hexadecanoic Octadekansäure, oleic acid or isostearic acid can be applied to the substrate 3 be present, salts of these acids, metallic Soaps, e.g. As potassium stearate, ethoxylated carboxylic acid, anhydrides of such carboxylic acids, polyvinyl butyral or acrylic resins can be used, as is already known from US 4,718,340.

Since the printing foils and materials described above are not reusable for printing foil 1 , the printing foil, which has a layer structure as disclosed in the patents and patent applications mentioned above, must be changed after a print job has ended. It must be removed from the printing unit so that a new printing film can be provided for imaging and printing in the printing unit. For this purpose, arrangements and devices can be used, as are already known from DE 43 03 872 A1. According to this document, a forme cylinder 2 is wrapped with the printing film 1 , in which printing film can be unwound from a first roll 14 , which, after it has been used up, can be wound onto a second roll 15 . The roller 14 and the roller 15 are mounted within an opening 13 in the forme cylinder 2 (see FIG. 5). The printing film is imaged by means of an inking unit 7 . If a dampening solution is used, a dampening unit 8 is also present. If the printing film has to be developed by means of a solvent, there is preferably a trough which can be adjusted to the forme cylinder 2 in order to carry out the development process and which is switched off by the forme cylinder 2 after the development process has ended. In order to facilitate the further winding of the printing film 1 on the forme cylinder 2 , rollers are preferably provided at the corners 9 , as are already known from US Pat. No. 3,156,182. In the interior of the forme cylinder 2 , means are preferably provided for braking and for latching the printing film at a certain position, as are also known from US Pat. No. 3,156,182. The forme cylinder 2 works together with an impression cylinder 11 . Sheets or a printing material web are moved through between the forme cylinder 2 and the printing cylinder 11 in order to image them with the image to be printed that is shown on the printing film 1 . If the printing unit shown in FIG. 5 works according to the offset principle, a transfer cylinder is also present between the forme cylinder 2 and the printing cylinder 11 .

Likewise, sensors for measuring the consumption of the printing film 1 or for specifying a specific tension of the printing film 1 can also be arranged in the forme cylinder 2 .

A gripper device can also be present within the printing unit according to FIG. 5 in order to exchange the rollers 14 , 15 .

The supply of printing film can also be arranged on a supply roll outside the forme cylinder 2 . With the gripping device known from DE 43 03 872 A1, the front beginning of the printing film can then be pulled off the supply roll, placed around the forme cylinder 2 while it is rotating at the same time, and then after the forme cylinder 2 has made a full rotation cut a cutting device, which is also arranged on a gripper arm. In a further exemplary embodiment, which is not shown here, the printing film 1 is arranged as a stack of printing film sheets within the printing press. In this case, the individual sheets of printing film are brought to the forme cylinder 2 by means of a gripping device which is modeled on the sheet feeder of a sheet printing machine. The forme cylinder 2 is simultaneously designed as a gripper cylinder, as is known from DE 44 33 380 A1. The grippers of the forme cylinder 2 thus grip the front ends of the printing foils. The printing films 1 are then either, as already shown above, held electrostatically on the surface of the forme cylinder 2 , or they are attached to it by means of an adhesive or an adhesive layer. An adhesive that can be removed is preferably used. The detachment process can be supported, for example, by heat. A device for applying this adhesive in the manner of the dampening unit 8 or the inking unit 7 can also be arranged within the printing press. The used printing film can be removed with a gripping device in all cases. The gripping device can have mechanical grippers, for example. In another exemplary embodiment, the gripping device has vacuum grippers which pull the printing film 1 off the forme cylinder 2 by forming a negative pressure.

The forme cylinder 2 can also consist of a material which is permeable to air, for example a sintered material, as is already known from DE 43 03 872 A1, as a result of which the printing film 1 can be sucked onto the forme cylinder 2 by means of negative pressure.

The removed printing film 1 is preferably pressed together in order to keep the space required for the used printing film low. The used printing film 1 is preferably also fed to a recycling process for plastics.

Since the thin printing film 1 has no mechanical stability, it must be imaged directly on the forme cylinder 2 . Their position must not change during the printing process. Since both shear and normal forces act on the printing film 1 in the gaps between the cylinders and rollers, it must be non-positively connected to its base over the entire surface. For this purpose, the adhesion, as already described above, is supported by measures which increase the adhesion of the printing film 1 to the surface of the forme cylinder 2 . The forme cylinder preferably has a surface roughness R _{a of} 0.2 μm. The adhesive is applied either to the back of the printing film or to the surface of the forme cylinder or to both surfaces. An adhesive is preferably used, the adhesive force of which can be influenced by means of pressure, temperature or by applying electrical fields, on the one hand to achieve good adhesion during printing, but on the other hand not to make it difficult to change the printing film.

If below the printing film to the porous surface of the cylinder, as above shown, a vacuum is applied, the process of changing the printing film by forming an overpressure through the porous forme cylinder surface support.

The adhesion of the printing film 1 to the surface of the forme cylinder 2 can be increased by electrostatic forces between it and the forme cylinder 2 . The cylinder surface, which receives the printing film 1 , serves as a first electrode, while the second electrode is formed by an electrically conductive layer in the printing film 1 . Both electrodes are separated by a dielectric which is either an insulation layer on the conductive surface of the forme cylinder 2 or which is formed by the substrate 3 of the printing film 1 or which is an additional insulation layer which separates the conductive layer on the printing film from the conductive cylinder surface, which receives the printing film 1 , isolated.

Since the printing film 1 is preferably less than 100 microns thick, the function of the blanket cylinder, which serves to compensate for the paper roughness, can be taken over by the forme cylinder 2 if the forme cylinder 2 is covered with an elastic layer, which is designed like a rubber blanket. This elastic layer, which can also serve as a dielectric, is covered by the printing film 1 and is non-positively connected to it. Due to its small thickness, the elastic layer is able to compensate for paper roughness and in this way also achieve the quality of offset printing in direct printing processes.

The energy required for imaging the printing film 1 is preferably supplied by laser radiation. A printing head is provided within the printing press in order to image the printing film 1 applied to the form cylinder 2 , as is already known in principle from US Pat. No. 5,126,531. A Nd: laser, for example an Nd: YAG laser, or a semiconductor laser, for example an edge-emitting semiconductor laser or a surface-emitting semiconductor laser diode (Vertical Cavity Surface Emitting Laser (VCSL)), is particularly suitable as a laser. The wavelength of the lasers should preferably be 830 nm or 1060 nm. The wavelength of the laser or lasers should preferably be selected so that it is close to the maximum sensitivity of the printing film 1 . The radiation from the laser diodes or the individual laser is focused on the printing film 1 by means of a lens or a plurality of lenses. The surface of the printing film 1 is scanned, as described, for example, in US Pat. No. 5,126,531. A rotating polygon mirror, as is known for example from DE 30 25 469 A1, is also suitable. A holographic polygon is also suitable. The laser beams are deflected by the polygon along the forme cylinder axis, while the forme cylinder itself is moved forwards by the scan line width at a rotation speed corresponding to the scanning speed. The entire length of the forme cylinder can also be covered by several scanning systems. Such a system using a polygon mirror is also known from JP 6-991.

In another exemplary embodiment, the laser beams are displaced along the longitudinal axis of the forme cylinder carrying the printing film 1 , while the forme cylinder 2 rotates at a rotational speed corresponding to the advancing speed of the laser beams. The distance between the individual laser beams can be equal to the distance between the individual scan lines, it can also be a multiple of this distance.

The main scanning movement predetermined by the advance of the laser beams leaves overlap by a rapid sub-scanning movement, in which the laser beam for example by an acousto-optical deflector by several scan line widths is deflected and thus several scan lines in one cylinder revolution to be written.

According to another embodiment, a print head covers the entire width of the forme cylinder 2 , whereby as many laser beams are generated from a single laser or a plurality of lasers as there are scan lines along the width of the forme cylinder 2 carrying the printing film 1 side by side. In this case, no feed movement along the longitudinal axis of the forme cylinder 2 is required. The inscription takes place during a single revolution of the forme cylinder 2 .

According to the exemplary embodiment shown in FIG. 7, a print head is arranged on a plate 20 , which comprises a laser light source 21 for generating a primary light beam 22 . The laser light source 21 can be, for example, a semiconductor laser, an array of semiconductor lasers, a solid-state laser pumped by a semiconductor laser or an array of solid-state lasers. A pump laser 23 can be provided in order to optically pump the laser light source 21 by means of a laser beam 24 . The laser beam 24 can also be passed through an optical waveguide. The laser beam 22 of the laser light source 21 is radiated into a generator 25 for generating a multiplicity of light beams. The generator 25 can be a grid, for example. The divergent bundle of rays 26 emerging from the generator 25 is fed to a second optical element 27 , which can also be a grating, for example, in order to generate a bundle 28 of mutually parallel light beams. The light beams 28 are modulated in a modulator 29 in accordance with a print image to be written on the printing film 1 . The modulation information is fed to the modulator 29 from a computer 30 . The light rays 31 emerging from the modulator 29 are fed to a focusing unit 32 which, depending on the number of rays, has individual lenses or a plurality of lenses arranged one behind the other, in order to direct the light rays 33 onto the layer absorbing them, for example the layer 4 ( Fig. 1) focus the printing film 1 . A stepper motor (not shown here) serves to move the plate 20 parallel to the longitudinal axis of the forme cylinder 2 , while the forme cylinder 2 rotates, controlled by an angle encoder. The coordination between the rotary movement of the forme cylinder 2 and the transverse movement of the plate 20 is already known from US Pat. No. 3,636,251. Either an acousto-optical or an electro-optical modulator, but also any other type of modulator can serve as the modulator 29 . The computer 30 serves as a raster image processor (RIP).

Instead of modulating the beam 28 as shown in FIG. 7, the pumping current of the laser light source 21 can also be modulated in addition or in connection with this form of modulation, which can in particular be a multiplicity of semiconductor lasers. In the case of a plurality of laser beams, these can also be modulated by arrays of modulators. Such modulators have been developed, for example, by Micro Mirror Devices from Texas Instruments or as selectively controllable reflective diffraction gratings from Bloomfield at Stanford University.

Either the laser beams come from one or a plurality of lasers and strike the modulator elements as discrete, individually distinguishable light beams. Or the laser radiation comes from a single laser, e.g. B. a high-power semiconductor laser (laser bar), wherein the modulator illuminates the slide in a "condenser beam path" similar to a projector and the intensity points corresponding to the print information are generated on the printing film by imaging the transmission pattern of the modulator. The transmission pattern is formed, for example, from a photographic film. The known methods are used for guiding and focusing the laser radiation onto the printing film 1 : for example, an autofocus system is used, as is known, for example, from WO 92/16374. The imaging of the laser beams reflected from the polygon mirror or of the laser beams coming out of the modulator 29 takes place either with holographic diffraction means or with f-θ lenses based on the use of classic lenses. With such lenses, the focal point lies on a flat surface regardless of the angle of incidence of the light beam. However, lenses or arrangements of several lenses with a curved image field can also be used, if this is necessary.

The light beams generated by semiconductor laser elements, which can be individually modulated and belong to a laser diode chip, can also be imaged directly on the printing film 1 .

Fiber-coupled laser diodes can also be used. In this case, the light beams are coupled from the laser diodes, for example using a lens glued to the exit surface of each laser diode, the fiber ends of which are brought together, for example, to form a “fiber head”. The optical waveguides can preferably be glued in a V-shaped trench on a solid plate, so that a fixed geometric relationship to the scanning geometry is created. The ends of the optical waveguides can then be aligned with the surface of the printing film 1 , for example with glued-on lenses or lenses attached individually behind them. Instead of individual lenses for each of the optical waveguides, there can also be a single lens or a single arrangement of a plurality of lenses arranged one behind the other in the beam path. A substrate is already known from EP 0 379 704 A2, on which optical waveguides are integrated in trenches.

Instead of the printing film 1, it is also possible to use a printing film which is constructed as a sleeve 31 ( FIG. 4). All layer structures and material connections can also be used for the sleeve 31 , as are also used in the printing film 1 . The sleeve 31 shown in FIG. 4, for example, like the printing film 1 shown in FIG. 2, only has the substrate 3 and the layer 5 . As shown in FIG. 6, the sleeve 31 can be applied to a forme cylinder 32 , which is only supported on one side during the changing process, in which a section 33 is pivoted out or folded out of a side wall 34 of the printing unit, so that the sleeve 31 can be pushed onto the outer surface of the forme cylinder 32 . This technology is already from DE 35 43 704 A1 and from US Re. 34 970 known.

The invention creates a thin printing film 1 which, for example, can also be constructed in the form of a sleeve like the sleeve 31 , and which can be applied in many ways to the surface of a forme cylinder 2 or a forme cylinder 32 by means of an adhesive, electrostatically or by means of negative pressure, etc. leaves. The printing film 1 can either be wound up by means of rollers 14 , 15 on the surface of the form cylinder 2 and unwound from it, or it is applied to the surface of the printing cylinder in a stack of printing film sheets. The printing film 1 or the sleeve 31 can be imaged within the printing machine by means of a printhead with a laser light source 21 , the laser light source 21 being able to include a large number of lasers, in particular semiconductor lasers.

Claims (49)

1. Printing machine with at least one printing unit and a form cylinder carrying a printing form ( 2 ), onto which the printing form can be imaged by means of an automatic device in the printing unit and can be exchanged for a new printing form after completion of the print job, characterized in that the printing form is used as a printing film ( 1 ) is formed and has a substrate ( 3 ) on which a first layer ( 5 ) which can be written by the action of energy with information to be printed is applied. 2. Printing machine according to claim 1, characterized in that the energy source for describing the layer ( 5 ) is a laser, in particular a laser emitting in the infrared or in the UV range. 3. Printing machine according to claim 1 or 2, characterized in that the printing film ( 1 ) is imageable after it has been applied to the outer surface of the forme cylinder ( 2 ). 4. Printing machine according to one of claims 1 to 3, characterized in that the layer ( 5 ) by the treatment with the energy source changes its surface property such that it is either oleophilic or oleophobic or hydrophilic or hydrophilic at the irradiated or non-irradiated points. 5. Printing machine according to claim 4, characterized in that the layer ( 5 ) contains a photoinitiator, in particular diphenyl iodonium salt, which forms an acid when irradiated, and contains a polymer with acid-labile groups. 6. Printing machine according to claim 5, characterized in that the layer ( 5 ) is wetted at the irradiated points by a hydrophilizing agent, so that it becomes hydrophilic at these points and the printing ink is repellent. 7. Printing machine according to claim 6, characterized in that the hydrophilizing agent also the printing film ( 1 ), while it is clamped on the forme cylinder ( 2 ), wiped, sprayed on, knife-coated or in connection with the dampening solution, in particular during the pressing phase, in particular with a dampening roller, can be applied. 8. Printing machine, in particular according to one of the preceding claims, characterized in that it has an ablatable layer ( 5 ). 9. Printing machine according to claim 8, characterized in that the layer ( 5 ) contains a resole resin, a novolak resin, a latent Bronsted acid and an infrared absorber, that the printing film ( 1 ) can be imaged by infrared laser radiation and then by an aqueous alkaline solution can be developed, whereby the non-imaged areas can be removed, the solution being able to be applied to the printing film ( 1 ), in particular by means of nozzles or a wiping cloth, while this is being applied to the forme cylinder ( 2 ). 10. Printing machine according to claim 9, characterized in that the aqueous solution is added to the dampening solution, whereby the printing film ( 1 ) can be developed during the pressing phase of a printing process. 11. Printing machine according to one of the preceding claims, characterized in that the layer ( 5 ) contains polysiloxane, can be clad by laser radiation and is particularly suitable for dry offset printing, the layer ( 5 ) either itself an absorber material, in particular carbon black, graphite , contains a dye, bismuth, tellurium, tin, etc. which absorbs in the infrared range, or wherein below the layer ( 5 ) there is a further layer ( 4 ) which serves as an absorption layer for the laser radiation and which is made in particular of aluminum, bismuth , Tellurium, tin or another metal. 12. Printing machine, in particular according to one of the preceding claims, characterized in that the illustrated portions of the layer ( 22 ) of the printing film ( 1 ) containing the printing image after imaging with a laser light source ( 24 ) can be peeled off in conjunction with a peelable layer ( 21 ) while the non-imaged portions of the image layer ( 22 ) on the substrate ( 23 ) of the printing film ( 1 ) thus remain on the forme cylinder ( 2 ). 13. Printing machine according to claim 12, characterized in that the peelable layer ( 21 ) polystyrene, polyethylene terephthalate, polyethylene, polypropylene, poly (vinyl) chloride, polycarbonate, poly (vinylidene chloride), cellulose acetate, cellulose acetate butyrate, copolymeric materials, copolymers of styrene, butadiene or acrylonitrile, in particular poly (styrene-coacrylonitrile), while the layer ( 23 ) forming the substrate consists of a plastic, paper or a polymeric material. 14. Printing machine, in particular according to one of the preceding claims, characterized in that the removable layer ( 21 ) in connection with the radiation-exposed portions of the layer ( 22 ) by a gripping device from the forme cylinder ( 2 ) is removable, which in particular also for application the printing film ( 1 ) on the forme cylinder ( 2 ) is used before the printing film ( 1 ) is imaged. 15. Printing film ( 1 ), in particular according to one of the preceding claims, characterized in that there is a layer absorbing the laser radiation between the substrate ( 3 ) or the carrier material and the layer ( 4 ) containing the polymer, in particular the layer absorbing the laser radiation Layer ( 4 ) is electrically conductive. 16. Printing device, in particular according to one of the preceding claims or using a printing film ( 1 ) according to one of the preceding claims, characterized in that there is a printing film supply which can be placed on the forme cylinder ( 2 ), clamped thereon and after carrying out an imaging process is removable. 17. Printing device according to claim 16, characterized in that the printing film supply is arranged either on a supply roll ( 14 ) inside or outside the forme cylinder ( 2 ) as a stack of printing film sheets. 18. Printing device according to claim 16 or 17, characterized in that the used printing film by a gripping device with mechanical or  pneumatically operated grippers, especially vacuum grippers, or with one Suction device is equipped. 19. Printing device according to one of claims 16 to 18, characterized in that the printing film ( 1 ) after its removal from the forme cylinder ( 2 ) can be compressed and preferably fed to a recycling process. 20. Printing device according to one of the preceding claims, characterized in that it has a forme cylinder ( 2 ) with a surface roughness of R _a 0.2 µm. 21. Printing device, in particular according to one of the preceding claims, characterized in that the forme cylinder ( 2 ) has on its surface an adhesive which can be removed preferably when the printing film is subjected to tensile stress or another means which increases the static friction of the printing film on the surface of the forme cylinder. 22. Printing device with a forme cylinder ( 2 ), in particular according to one of the preceding claims, characterized in that the forme cylinder ( 2 ) has an adhesive on its surface or that the printing film ( 1 ) has an adhesive on its back or that both the forme cylinder ( 2 ) and the printing film ( 1 ) on the side on which they adhere to one another are provided with an adhesive. 23. Printing device according to claim 22, characterized in that a Adhesive is used, its adhesive force either by pressure, temperature or can be influenced by the application of an electrical field. 24. Printing device, in particular according to one of the preceding claims, characterized in that the adhesion of the printing film ( 1 ) on the surface of the forme cylinder ( 2 ) can be increased by applying a vacuum to the forme cylinder ( 2 ), the forme cylinder being made of a porous, for example, a sintered material. 25. Printing device according to claim 24, characterized in that the changing process of the printing film ( 1 ) can be supported by forming an overpressure on the outer surface of the forme cylinder below the printing film ( 1 ). 26. A printing apparatus, in particular according to one of the preceding claims, characterized in that the adhesion of the printing sheet (1) can be amplified on the lateral surface of the forme cylinder (2) by electrostatic forces between the printing sheet (1) and the surface of the forme cylinder (2). 27. Printing device, in particular according to one of the preceding claims, characterized in that the cylinder surface which receives the printing film serves as a first electrode, while the conductive layer contained in the printing film ( 1 ) serves as a second electrode, the electrodes being provided by a dielectric are layer separated from each other, which is applied above the conductive surface of the forme cylinder (2) either, or is formed by the substrate of the printing sheet (1) or be applied regardless of the printing sheet (1) to the conductive cylindrical surface below the printing sheet (1) and in particular is glued. 28. Printing device, in particular according to one of the preceding claims, characterized in that the print image of the printing form applied to the form cylinder ( 2 ), in particular the printing film ( 1 ), can be applied directly to the printing material, one of which is on the surface of the form cylinder Elastic layer compensating for roughness is applied. 29. Printing device, in particular according to claim 28, characterized in that the printing form, in particular the printing film ( 1 ), applied to the outer surface of the forme cylinder ( 2 ), by laser radiation, in particular by a neodynium laser, by edge-emitting semiconductor laser diodes, surface-emitting semiconductor laser -Diodes (VCSL), especially at a wavelength between 830 nm and 1060 nm can be imaged. 30. Printing device, in particular according to one of the preceding claims, characterized in that the image data in a data memory  are stored and that the laser beams on the surface of the printing film focused according to the data stored in the data memory and scan the surface of the printing film. 31. Printing device, in particular according to one of the preceding claims, characterized in that the laser beam or the laser beams can be deflected along the forme cylinder axis by means of a rotating polygon mirror or a holographic polygon, while the forme cylinder ( 2 ) carrying the printing film ( 1 ) moved forward by the scan line width at a rotation speed corresponding to the scanning speed. 32. Printing device according to claim 31, characterized in that a plurality of scanning systems are present, through which the forme cylinder ( 2 ) can be imaged at the same time. 33. Printing device, in particular according to one of the preceding claims, characterized in that the laser unit is displaceable parallel to the longitudinal axis of the forme cylinder while the forme cylinder ( 2 ) rotates. 34. Printing device, in particular according to one of the preceding claims, characterized in that the distance between the individual laser beams is the same the distance of the individual scan lines or a multiple thereof. 35. Printing device, in particular according to claim 34, characterized in that an additional scanning movement is superimposed on the scanning movement, in which the laser beam can be deflected by several scanning line widths, in particular by acousto-optical deflector, so that several scanning lines can be written on during one revolution of the forme cylinder ( 2 ) . 36. Printing device, in particular according to one of the preceding claims, characterized in that as many laser beams are used as are side by side on the width of the printing cylinder ( 1 ) carrying forme cylinder ( 2 ) scan lines side by side. 37. Printing device, in particular according to one of the preceding claims, characterized in that those to be printed by means of the laser beams Information with appropriate signals from the raster image data load processor (RIP) can be modulated. 38. Printing device according to claim 37, characterized in that the image data by an acousto-optical or by an electro-optical modulator are modular. 39. Printing device, in particular according to one of the preceding claims, characterized in that the laser unit comprises semiconductor lasers whose Pump current can be modulated. 40. Printing device, in particular according to one of the preceding claims, characterized in that several laser beams can be modulated, wherein Arrays of modulators can be used, preferably micromirrors or have selectively controllable reflective or transmissive diffraction gratings. 41. Printing device, in particular according to one of the preceding claims, characterized in that the laser beams either from one or several lasers come as discrete and individually distinguishable Laser beams hit the modulator elements or that the laser radiation comes from a single laser, which in particular is a high-performance Is semiconductor laser or a gas laser, the modulator in one Condenser beam path a medium containing the pressure information illuminated and the intensity points corresponding to the print information of the printing film by imaging the transmission pattern. 42. Printing device, in particular according to one of the preceding claims, characterized in that the laser unit contains an autofocus system that focuses in particular the laser beams by means of photographic diffraction means by means of lenses, in particular by means of f-θ lenses, onto the surface of the forme cylinder ( 2 ). 43. Printing device, in particular according to one of the preceding claims, characterized in that they have focusing means with a curved image field having. 44. Printing device, in particular according to one of the preceding claims, characterized in that the laser beams emerging from the semiconductor lasers can be individually modulated and can be imaged directly on the surface of the forme cylinder ( 2 ). 45. Printing device, in particular according to one of the preceding claims, characterized in that the laser beams from the semiconductor lasers can be coupled into optical fibers and can be focused from them onto the surface of the forme cylinder ( 2 ). 46. Printing device, in particular according to claim 45, characterized in that the ends of the optical fibers are brought together on a substrate and in particular are fastened in V-shaped trench mounts. 47. Printing device, in particular according to claim 45, characterized in that the ends of the optical fibers open in front of focusing means, wherein the light beams from the focusing means can be focused on the surface of the forme cylinder ( 2 ). 48. Printing device according to one of the preceding claims, characterized in that the printing film ( 1 ) is constructed as a sleeve ( 31 ). 49. Printing device according to claim 48, characterized in that the sleeve can be applied to the forme cylinder ( 2 ) by means of a gripping device through an opening in a side wall of a printing unit.