DE10227054A1 - Reusable printing form - Google Patents

Abstract

A reusable printing form comprises a printing area having a metal oxide surface that is treated with amphiphilic organic compound having a polar region with an acidic character. Independent claims are also included for: (a) a printing unit or printing machine having at least reusable printing form; (b) a method for imaging a reusable printing form comprising producing an image on the printing area by selectively inputting energy on a dot-by-dot basis, and erasing the image through large-surface input of energy subsequent to printing on a printing substrate; and (c) a method for creating an imageable printing area comprising treating the metal oxide surface with amphiphilic organic compound(s) having a polar region with an acidic character.

Description

The invention relates to a reusable printing form, in particular for use in offset printing, with a printing surface, and a method for imaging a reusable printing form.

Printing forms are used in printing units of printing machines in order to specified print pattern, a specified subject or image, on a printing material applied. Typical substrates are paper, cardboard, cardboard, organic polymers or similar. Printing forms are mainly used whose printing surface, part of the surface of the printing form, permanently the one to be printed Pattern applied, structured or described. Such printing forms can only simply be used. For various reasons, it is desirable to use printing forms use which is used several times, in particular described several times or can be illustrated several times. In other words, are of particular interest Print areas that are deleted after structuring in a first image and later in a second image can be structured. In the context of this presentation, see below a reusable printing form understood a printing form with a printing surface, which can be structured multiple times into different images.

In offset printing, the structuring of the printing area is different in different areas Wetting properties, especially hydrophilic / lipophobic and hydrophobic / lipophilic Areas, before. Offset printing is based on the use of the immiscibility of lipophilic substances, especially oily fluids or liquids, and hydrophilic substances, especially of aqueous fluids or liquids, on the Printing form, wherein the lipophilic substance or the ink or printing ink by the image-forming areas and the hydrophilic substance or water through the suitably prepared printing surface wetted with hydrophilic and lipophilic substance , the non-image areas preferably hold the hydrophilic substance back and repel the lipophilic substance, while the image areas the Accept lipophilic substance and reject the hydrophilic substance. As a result then the lipophilic substance in a suitable manner on the surface of a material transferred on which the image is to be fixed.

In the literature, various concepts for reusable, in particular rewritable printing forms presented and discussed.

EP 0 911 154 A1 proposes as materials for a surface of a printing form titanate (TiO ₂ ) or zirconate (ZnO ₂ ), which can be present in ceramic form both in pure form and with other metallic additives in various mixing ratios. This surface is non-excited hydrophobic and can be brought into a hydrophilic state by irradiation with ultraviolet light. This switching process can be reversed by heating. The imaging is now done by illuminating the entire surface of the plate with ultraviolet light and areas that are supposed to lead to color during printing are covered by a mask or a film. The image areas are then thermally deleted, e.g. B. switched back with a laser beam.

The hydrophobicity of such a metal oxide surface is based in particular on one with Hydrocarbon contaminated surface in air, as by means of measurements Fourier transform infrared spectroscopy (FTIR) using X-ray photoelectron Spectroscopy (XPS), using atomic force microscopy (AFM) or the like can be determined. The surface can be removed with the help of UV radiation or Hydrophilize wet chemistry, but it will be back within a few hours of storage uncontrolled hydrophobicity in air. So there is no defined, permanent hydrophobicity as the initial state.

Furthermore, it is known for example from EP 0 962 333 A1 to use printing forms, whose print pattern is changeable. Doing so will affect the printing form surface applied hydrophobic or hydrophilic materials, then the Wet the printing form surface with water and then onto the printing form surface Color applied. Due to the hydrophilic or hydrophobic properties of the Wetting process with water in the hydrophilic surface areas the water attracted so that the hydrophilic surface areas during the subsequent coating no longer take up printing ink with printing ink. After a predetermined number of The applied print pattern is removed again during printing processes. Then you can the printing form can be structured or described with a new printing pattern. there it is known to be a material for coating the printing form surface To use thiol compound. The thiol compound is exposed to heat removed from the printing form surface again.

When proceeding according to the technical teaching of document EP 0 962 333 A1, it is very complex and time-consuming, a defined and highly ordered monomolecular layer on any untreated surface. A possible technological In particular, the costs of the gold substrate and the costs used are also applicable self-organizing molecules with thiol groups (-SH).

The object of the present invention is to provide a reusable printing form create, the printing area allows multiple creation and deletion of images.

This object is achieved by a reusable printing form with the Features solved according to claim 1. Advantageous developments of the invention are in characterized the dependent claims.

According to the invention, a reusable, in particular rewritable or reimageable, printing form with a printing surface, which one with at least one Amphiphilic organic compound whose polar region has an acidic character has treated treated metal oxide surface. The amphiphilic organic The compound can be a surfactant-like compound. The amphiphilic organic Compound may be one substituted with an aliphatic or aromatic residue be inorganic or organic acid, which contains at least one element from IV., V. or VI. Main group of the periodic table, especially carbon (C), phosphorus (P), Sulfur (S) or nitrogen (N) has. The rest can be an unsubstituted or a substituted aliphatic or a substituted or unsubstituted aromatic. The rest can in particular have a carbon chain, the number of carbons is greater than or equal to 12 and less than or equal to 25.

In a preferred embodiment of the reusable printing form according to the invention, the amphiphilic organic compound can be n-heptadecane-hydroxamic acid {CH3- (CH2) 16-C (O) -NH-OH} or n-octadecane-phosphonic acid {CH3- (CH2) 17-P (O) - (OH) 2}. The metal oxide surface can be a natively oxidized titanium surface, natively oxidized stainless steel surface, for example Hastelloy, natively oxidized aluminum surface, titanate (TiO ₂ ) or zirconate (ZnO ₂ ). The invention is therefore based, inter alia, on the idea of treating technically rough metal oxide surfaces with amphiphilic, surfactant-like organic compounds, in particular applying or coating amphiphilic, surfactant-like organic surfaces on technical rough metal oxide surfaces. The reusable printing form can thus also be referred to in particular as a recoatable printing form.

In other words, the printing form according to the invention has a surface on which by the action of an amphiphilic organic compound on a Metal oxide surface is obtained. Details of the underlying process of Provision of a printing form according to the invention are described below.

The rewritable printing form according to the invention is particularly advantageous in an offset printing process, especially in direct or indirect flat printing, used. It can therefore also be used in particular as a rewritable offset printing form or be referred to as a re-coatable offset printing form.

With the help of amphiphilic, surfactant-like organic compounds it is possible to reproducibly defines hydrophobic metal oxide surfaces, in particular Titanium oxide surfaces. That through an amphiphilic organic compound treated printing area can be hydrophobic. In a preferred embodiment, the amphiphilic, surfactant-like organic compounds n-heptadecane-hydroxamic acid (CH3- (CH2) 16-C (O) -NH-OH) - also their tautomeric form - and / or n-octadecane Phosphonic acid (CH3- (CH2) 17-P (O) - (OH) 2). The metal oxide surface is divided into one brought hydrophobic, color-carrying state, which is the initial state for a Illustration can serve for an offset printing process. The contact angle, measured against water, these hydrophobic metal oxide surfaces are values from the Number set of the interval of real numbers between 80 and 120 degrees. The The metal oxide surface can then be transformed into a hydrophilic, ink-carrying condition. The contact angles, measured against water, in The hydrophilic state are values from the number set of the interval of real numbers between 0 and 10 degrees. The stroke between the two states is therefore sufficient great for offset printing. The printing form according to the invention is switchable, in particular between a hydrophilic and a hydrophobic state. After structuring the rewritable printing form according to the invention in areas in the hydrophilic and An offset printing process can be carried out in the region in the hydrophobic state.

The reusable printing form according to the invention can be in various Embodiments with different topological and geometric properties be executed. The printing form according to the invention can be used as the surface of a full cylinder or be realized as a surface of a hollow cylinder. The cylinder, full or hollow, can in particular be a straight circular cylinder. Under the surface is especially the lateral one To understand the surface. Alternatively, the printing form according to the invention can also be used as be designed as a sleeve or as a plate. A sleeve has two surfaces (Inner surface and outer surface) and has two edges. The sleeve can be cylindrical with a uniform diameter, in particular inner diameter or Outside diameter, (circular hollow cylindrical) or conical, that is with variable, especially uniformly increasing or decreasing diameter, in particular Inner diameter or outer diameter. Inside diameter and Outside diameters can vary. It is therefore in the topological sense an object that is not simply connected. A plate has two surfaces (Top and bottom) and has a border. It is therefore in a topological sense simply connected object. The plate can in particular be cuboid or be rectangular.

The reusable printing form according to the invention can be used in a printing unit, especially in an offset printing unit. It can be the surface form a printing cylinder or be recorded on the surface of a cylinder. A printing unit according to the invention is therefore characterized by at least one Reusable printing form according to the invention. The printing unit according to the invention can be part of a printing press, in particular an offset printing press. The Printing machine can be a sheet-processing or a web-processing printing machine his. A sheet-fed printing press can be a feeder, a number of Have printing units and a delivery. A printing press according to the invention has at least one printing unit according to the invention.

In the inventive context with the reusable according to the invention A printing method according to the invention is also available for imaging a printing form reusable, especially rewritable or reimageable, Printing form with various advantageous further training. The invention Process is based on the endeavor to create a cycle in which one printing form according to the invention can be illustrated and deleted several times, so that the printing form is particularly suitable for offset printing. The method according to the invention can be used for imaging both inside and outside a printing unit or a Printing machine can be carried out. The printing area can be imaged by exposure processed by a mask-like template. However, point by point is preferred direct exposure with digital information.

The method according to the invention for imaging a reusable printing form includes the following steps: It will be reusable, in particular rewritable or reimageable printing form with a printing area, which treated one with at least one amphiphilic organic compound Has metal oxide surface provided. The rewritable printing form can in particular be carried out as described in more detail above in this illustration. A picture becomes point-by-point through selective, especially spatially and temporally selective Energy supply generated on the printing surface. In other words, it will be digital Imaging done. Due to the illustration, the printing form is made by one converted into a hydrophobic state. After printing one Printing material, especially in an offset printing process, the image through large-scale energy supply deleted. To the reusable printing form for a new one To prepare the imaging, the printing surface of the printing form with a solution treated amphiphilic organic compound. In other words, providing the Printing form is iterated or repeated. The steps of imaging and deleting can can therefore be carried out several times with different print patterns or subjects. The The inventive method enables a cycle.

In the method according to the invention, the step of providing can be carried out in an advantageous manner the reusable printing form the treatment of the printing surface with a amphiphilic organic compound whose polar region has an acidic character has: The printing surface is covered with an aqueous solution or with a alcoholic solution, especially ethanol, wetted, which has at least one amphiphilic organic compound in a suitable concentration, close to the saturation limit, preferably in the concentration 1 mmol / l. Through this step the Metal oxide surface exposed to an amphiphilic organic compound. In other Words, the amphiphilic organic compound is applied.

In the method according to the invention, the step of providing can be carried out in an advantageous manner of the reusable printing form include the following steps: The printing area is cleaned by irradiating the metal oxide surface with a UV light source. Non-adherent compounds will be removed from the treated metal oxide surface away. This cleaning of the treated metal oxide surface can in particular with an alcoholic solution, preferably with ethanol. The treated, cleaned Metal oxide surface is treated with an anhydrous process gas, in particular with nitrogen, dried.

The method according to the invention, in particular the provision of the reusable printing form, can advantageously include the following steps for preparing the metal oxide surface. The metal oxide surface can be one of the following surfaces: natively oxidized titanium surface, natively oxidized stainless steel surface, natively oxidized aluminum surface, titanate and zirconate. To be more precise, the following preparation steps can precede a first provision of the reusable printing form. The metal oxide surface is pre-cleaned. Cleaning may include the step of rinsing with acetone, ethanol, isopropanol, ethyl acetate, or other suitable organic solvent. A particular purpose is to degrease the surface. The metal oxide surface can then give an aqueous solution of the composition a volume fraction of 25% NH ₄ OH solution and a volume fraction of 30% H ₂ O ₂ solution in four volume portions of H ₂ O at a temperature of about 60 ° C. for about 10 minutes get abandoned. This step is particularly advantageous for a natively oxidized titanium surface. One purpose is in particular an oxidation of hydrocarbons located on the metal oxide surface. A main cleaning can be done by etching the metal oxide surface. The etching can be carried out by a solution of the composition, a volume fraction of 40% HF solution and three volume fractions of 30% H ₂ O ₂ in 20 volume fractions H ₂ O at room temperature for about 1 minute. One purpose is in particular the removal of some individual metal oxide layers and the setting of a defined roughness on the metal oxide surface. A defined oxide film, in particular a hydrophilic surface, can be achieved by oxidation of the cleaned and etched surface. For the oxidation, the surface of a solution of the composition can be exposed to a volume fraction of 25% NH ₄ OH solution and a volume fraction 30% H ₂ O ₂ solution in four volume portions H ₂ O at a temperature of approximately 60 ° C. The steps of etching and generating a defined oxide film is particularly advantageous for a natively oxidized titanium surface.

In a preferred embodiment of the method according to the invention, an image on the printing surface by selective selective supply of energy for hydrophilizing with Generated with the help of electromagnetic radiation. The electromagnetic radiation can are in the range of 150 to 1200 nanometers wavelength. In particular, the Energy is supplied in the infrared spectral range. The digital imaging can by a laser, preferably with a wavelength of approximately 1100 nanometers. The picture is in the preferred embodiment by large-area energy supply for hydrophobing erased by irradiating the printing surface with electromagnetic radiation. In particular, the large-area irradiation can take place in the ultraviolet spectral range. A preferred light source is an excimer emitter.

In an advantageous embodiment of the method according to the invention Printing on the printing material cleaned or freed the printing surface from printing ink. In particular, cleaning using a conventional one Paint cleaner or a conventional detergent, a surfactant-containing aqueous solution, for example the laundry detergent sold under the name EUROSTAR, be made.

The invention provides a reusable, especially rewritable or reimageable, printing form with reliably reproducible behavior regarding the Imaging and deletion processes are available. The creation of an image or one Structure on the printing surface is simple and reliable. It is not necessary that a monolayer of the amphiphilic organic compound on the metal oxide surface self-organizing. The imaging process therefore requires a small amount Provision time of the printing form according to the invention. The application from above connections mentioned within a period of a few minutes is sufficient to a sufficiently strong hydrophobization of the metal oxide surfaces, especially for one Use in an offset printing process. In particular, this enables The inventive method, the hydrophobization of rough metal oxide surfaces, such as they are manufactured in common industrial production processes.

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 flow diagram of an advantageous embodiment of the inventive method for imaging a reusable printing plate according to the invention, and

Fig. 2 is a schematic representation of the structure of a reusable printing plate according to the invention, the pressure surface comprises a treated with at least one amphiphilic organic compound metal surface by the inventive method.

Without restricting the general public regarding the amphiphilic organic Compounds and in terms of metal oxide surfaces will be advantageous Embodiment of the reusable printing form according to the invention and a advantageous embodiment of a method according to the invention for imaging a reusable printing form using a natively oxidized titanium surface and using n-Octadecane-phosphonic acid exemplified.

Fig. 1 shows a flow diagram of an advantageous embodiment of the inventive method for imaging a reusable printing plate according to the invention. Samples with titanium surfaces can be purchased from Goodfellow. In order to first clean the titanium surface to be treated, it is irradiated with light in the ultraviolet wavelength range. The step of providing 10 a reusable printing form comprises the application of the amphiphilic surfactant-organic compounds: The titanium surface is wetted with a solution containing the above-mentioned compounds in a suitable concentration. The titanium surface is immersed in 1 mM ethanolic solution of n-octadecane-phosphonic acid (stearin-phosphonic acid) at room temperature for about 5 minutes. The treated titanium surface is cleaned by rinsing with ethanol, which removes the non-adhering compounds from the n-octadecane-phosphonic acid solution. The cleaned, treated titanium surface is completely dried with an anhydrous, a so-called dry process gas, here nitrogen.

Titanium surfaces prepared or provided in this way are hydrophobic and can be imaged with intensive UV or IR light sources. Imaging creates hydrophilic areas. In an advantageous embodiment, a diode-pumped yttrium-doped fiber laser from SDL is used as the light source. Local, selective, digital imaging can be carried out using 30 micron light spots (spots, 1 / e ² waste). The wavelength is 1100 nanometers, the power is 3 watts and the intensity or fluence is 15 to 30 joules / square centimeter. In the process step of imaging 12 titanium surfaces with an infrared laser, a visible structure or a visible pattern is created.

Examples of these visible structures with different color impressions are listed in the following table for a titanium surface treated with an amphiphilic organic compound, the polar region of which has an acid-like character:

The following color impressions were observed for a simple titanium surface:

The following examples were observed for a titanium surface treated several times - without treatment with an amphiphilic chemical compound whose polar region has an acid-like character:

The variable v denotes the scanning speed (scanning speed) of the Printing surface. A pattern can be illustrated over the entire surface (full surface) or over a pixel surface (pixel surface) his. The pixel size is 40 microns.

Different laser energies lead to different color impressions on the Surface. The color impressions are due to the oxides of titanium, which are not necessarily have a stoichiometric composition. XPS measurements have shown that after the one-time wet chemical preparation, especially as detailed above was described at a depth of 6 nanometers on the titanium surface Oxidation levels of titanium are present. For example, TiO, TiO2, and Ti2O3 metallic Ti are present in these first 6 nanometers of the surface. To single laser irradiation, the oxide film on the surface becomes thicker than 6 Nanometers, the 6 nanometers detectable using the XPS method exist in the frame measuring accuracy 100% or completely made of TiO2. A unique, full-surface Laser treatment is a very advantageous one after the single wet chemical preparation Initial state for reversible (erasable) imaging on this titanium surface. Repeated imaging with IR laser on the same areas of the surface result in slight color changes, but have no influence on the Wetting properties of these areas. In other words, by the Irradiation of the hydrophobic surface always creates hydrophilic areas.

In the third process step of printing 14 , the subject is reproduced on a printing material using an offset printing process. After printing, the titanium surface can optionally be cleaned by contact with a solution of a suitable composition of printing ink. In the advantageous embodiment, color cleaner from the company EUROSTAR is used.

In the fourth method step of erasing 18 , the titanium surface is exposed to ultraviolet light of a wavelength of approximately 172 nanometers over a large area for approximately 5 minutes. A xenon excimer emitter from Xeradex (OSRAM) with an optical output of 5 watts and an electrical output of 20 watts serves as the light source.

It is now possible to repeat 110 the individual steps, starting with the step of providing 10 the reusable printing form. The cycle can be done in less than 30 minutes.

The Fig. 2 is a schematic representation of the structure of a reusable printing plate according to the invention, the printing surface with at least one of an amphiphilic organic compound whose polar region has an acidic character, including treated metal surface, by the inventive method. FIG. 2 shows three states of the printing plate 30, the temporal order is indicated by the arrows. First, the printing form 30 is present with a large-area hydrophobic printing area 32 . Local, point-by-point, selective imaging creates hydrophilic regions 34 on the surface of the printing form 30 . The surface thus has a structure of hydrophobic areas 32 and hydrophilic areas 34 , so that it can be used for printing, in particular in an offset printing process. After irradiation of the surface of the printing form 30 over a large area and treatment with an amphiphilic organic compound, the polar region of which has an acid-like character, it is achieved that the printing form again has a hydrophobic printing area 32 over a large area. REFERENCE SIGN LIST 10 Deployment step
12 step of imaging
14 step of printing
16 deletion process step
110 Repeat steps
30 printing form
32 hydrophobic printing surface
34 hydrophilic areas

Claims (16)

1. Reusable printing form, in particular for use in offset printing, with a printing surface, characterized in that the printing surface has a metal oxide surface treated with at least one amphiphilic organic compound, the polar region of which has an acid-like character. 2. Reusable printing form according to claim 1, characterized, that the amphiphilic organic compound is one with an aliphatic or aromatic residue is substituted inorganic or organic acid, which at least one element from IV., V. or VI. Main group of the periodic table having. 3. Reusable printing form according to claim 2, characterized, that the rest have a carbon chain, the number of carbons is greater than or equal to 12 and less than or equal to 25. 4. Reusable printing form according to claim 1, 2 or 3, characterized, that the amphiphilic organic compound n-heptadecane hydroxamic acid {CH3- (CH2) 16-C (O) -NH-OH} and / or n-octadecane phosphonic acid {CH3- (CH2) 17-P (O) - (OH) 2}. 5. Reusable printing form according to one of the preceding claims, characterized, that the metal oxide surface is a surface from the set of the following Surfaces is: Natively oxidized titanium surface, natively oxidized stainless steel surface, natively oxidized aluminum surface, titanate and zirconate. 6. Reusable printing form according to one of the preceding claims, characterized, that the treated printing area by an amphiphilic organic compound is hydrophobic. 7. Reusable printing form according to one of the preceding claims, characterized, that the printing form as the surface of a solid cylinder, as the surface of a Hollow cylinder, is designed as a sleeve or as a plate. 8. printing unit, marked by at least one reusable printing form according to one of the preceding Expectations. 9. printing machine, marked by at least one printing unit according to claim 8. 10. A method for imaging a reusable printing form, characterized by - Providing ( 10 ) a reusable printing form with a printing surface, according to one of the preceding claims 1 to 7; - Generating ( 12 ) an image on the printing surface by selective point-by-point energy supply; - Deleting ( 16 ) the image after printing on a printing material, in particular in an offset printing process, by supplying large amounts of energy. 11. The method according to claim 10, characterized, that providing the reusable printing form is wetting the Printing area with a solution containing at least one amphiphilic organic Compound whose polar region has an acidic character contains. 12. The method according to claim 10 or 11, characterized in that the provision of the reusable printing form comprises the following steps: - Cleaning the printing surface by irradiating the metal oxide surface with a UV light source; - removing non-adherent compounds from the treated metal oxide surface; and - Drying the metal oxide surface with an anhydrous process gas, especially with nitrogen. 13. The method according to claim 10, 11 or 12, characterized, that providing the reusable printing form is a step towards Preparation of the metal oxide surface comprises, in which the metal oxide surface is pre-cleaned. 14. The method according to any one of claims 10 to 13, characterized in that the provision of the reusable printing form comprises the following steps for the preparation of a natively oxidized titanium surface: - etching the natively oxidized titanium surface; and - Generation of a defined oxide film, in particular a hydrophilic surface. 15. The method according to any one of claims 10 to 14, characterized, that the creation of an image on the printing surface by selective point by point Energy supply for hydrophilizing with the help of electromagnetic radiation, in particular in the infrared spectral range, and that the deletion of the image through large-area energy supply for hydrophobizing by means of irradiation of the Printing area with electromagnetic radiation, especially in the ultraviolet Spectral range. 16. The method according to any one of claims 10 to 15, characterized, that after printing on the substrate, cleaning the printing surface from Printing ink, especially using a conventional color cleaner, is made.