CH634666A5 - Method of producing planographic printing forms using laser beams - Google Patents

Description

The invention relates to a process for the production of planographic printing forms, in which an aluminum support covered with a recording layer containing diazo compounds is irradiated imagewise with a laser beam and thereby oleophilic or insoluble image areas are generated in the recording layer.

US Pat. No. 3,664,737 describes a printing plate which has a UV-sensitive layer, preferably a slide layer, on an aluminum support and which is irradiated with a laser.

In DT-PS 24 48 325 and DT-OS 25 43 820 the manufacture of printing plates by laser irradiation of non-light-sensitive recording layers is described, 40 the irradiated areas of the recording layer being permanently oleophilic or, if the layer was already oleophilic, in a suitable one Developer liquid become insoluble. Among other things, called anodized aluminum.

In the older German patent application P 27 25 308 45 it was also proposed to image a presensitized printing plate with a support made of anodized aluminum and a photosensitive layer containing a negative working diazo nium compound with laser radiation.

Swiss patent no. 625 893 describes a process for the production of planographic printing forms, in which a recording material with a layer support of anodically oxidized aluminum and a recording layer on the oxide layer is imagewise irradiated with a laser beam and thereby the irradiated parts of the recording layer are oleophilic and / or or 55 are made insoluble and then, if appropriate, the non-irradiated areas of the recording layer are washed out with a developer liquid, which is characterized in that a layer support with an oxide layer which has a layer weight of at least 3 g / m 2 is described. 60

The object of the invention was to increase the sensitivity of the recording material to be laser radiation and / or to increase the printing performance of printing forms produced therewith.

This object is achieved with the aid of the method according to the invention, which is characterized in that a recording layer is used which contains a negatively working light-curable diazo compound and an amine resin.

Negative working, light-curable diazo compounds which are suitable for use in the process according to the invention are, in particular, polycondensation products of diazonium salts, which are also referred to as diazo resins. Suitable polycondensation products are obtained by condensing aromatic diazonium salts, preferably optionally substituted diphenylamine-4-diazonium salts, with active carbonyl compounds, preferably formaldehyde, in a strongly acidic medium. Such products are e.g. in DT-PS 1 214 086 and DT-PS 1 292 001. Mixed condensation products of diazonium salt units and units of non-light-sensitive condensable second components, such as aromatic amines, phenols, thiophenols, phenol ethers, aromatic thioathers, aromatic hydrocarbons, aromatic heterocycles and organic acid amides, are particularly preferred. Such condensation products are described in U.S. Patents 3,849,392 and 2,867,147. In addition, negative-working diazo compounds of the p-benzoquinonediazide and p-iminoquinonediazide type, such as those e.g. are described in DT-PS 1 104 824.

Amine-fromaldehyde resins which are formed by condensation of formaldehyde with urea, urethanes (carbamic acid esters), aniline or Me-lamin are preferably used as amine resins. Such condensation products are known and are available in many versions as commercial products. Suitable representatives are e.g. described in the Kunststoff-Handbuch, Volume X, published by Vieweg and Becker at Carl Hauser Verlag Munich 1968.

To produce the laser-beam-sensitive recording layer, the amine resin is added to the solution, which contains the diazo compound to be used and is used to coat the anodized aluminum. The amount of resin can vary within wide limits. It is generally between 0.1 and 10 parts by weight of resin, based on one part by weight of the diazo compound used. Particularly good results are obtained if the addition of resin is between about 0.6 and 6.0 parts by weight per 1 part by weight of diazo compound.

The supports of the recording materials used in the process according to the invention are produced in a known manner. The aluminum is preferably roughened mechanically, chemically or electrolytically before the anodic oxidation. The combination of electrolytic roughening with anodic oxidation has proven particularly useful in the continuous process. The roughening takes place in a bath of dilute aqueous mineral acid, e.g. of hydrochloric or nitric acid, using direct or alternating current.

The anodization also takes place in aqueous acid, e.g. in sulfuric acid or phosphoric acid, preferably using direct current. The current densities and anodizing times are coordinated in such a way that oxide layer thicknesses in the specified ranges are obtained. The layer thickness should be at least 3 g / m2. The upper limit of the layer thickness is not critical, but no significant improvements are generally achieved above 15 g / m2. If the layer thickness is much higher, for example above 30 g / m2, there is also the risk that cracks may form in the oxide layer during bending. Oxide layer weights of about 5 to 12 g / m 2 are generally preferred.

The UV-light-sensitive diazo layers according to the invention are developed after the laser irradiation with aqueous alkaline or acidic solutions or with water itself. Lacquer emulsions or lacquers such as are known for planographic printing plates are also suitable. These paint emulsions and paints can be developed and lacquered in one step.

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or after development with aqueous solutions.

Suitable for the purposes of the present invention are power-appropriate shorter-wave lasers, for example argon lasers and krypton lasers, which, depending on the type of mirrors used, have beam powers of 0.5 to approximately 2.5 watts in the UV range or beam powers of in the visible range Emit 1 to 25 watts. Dyes, e.g. Rhodamines, triphenylmethane dyes, such as crystal violet; Astrazon orange, eosin and methylene blue are added, which absorb strongly in the emitted area and exert a sensitizing effect.

The laser beam is controlled by means of a predetermined programmed line and / or raster movement. Methods and devices for regulating the laser beam by computer and the bundling, modulation or deflection of the beam are not the subject of this invention; they have been described several times, for example in German Offenlegungsschriften 2,318,133, pages 3 ff., 2,344,233, pages 8 ff. and in US Pat. Nos. 3,751,587, 3,745,586, 747,117, 3,475,760,3 506 779 and 3 664 737.

The layers are preferably imagewise irradiated with an argon laser of 1 to 10 watts. Depending on the sensitivity or absorption capacity of the layers used, speeds of up to 110 m and more are achieved per second. Focusing the laser beam with a lens creates hardened spots of less than 50 | in diameter on the layer.

The invention brings about a very permanent oleophilization of the surface, so that long print runs can be achieved. In addition, the sensitivity of the marking materials used for laser radiation is particularly high.

The following examples illustrate preferred embodiments. Unless otherwise stated, percentages are percentages by weight. 1 g should be set as part by weight if 1 ml is selected as part by volume (Vt).

example 1

A bright rolled aluminum roll is roughened electrolytically in the run and anodically oxidized for 75 seconds at 40 ° C. with a direct current of 9 A / dm2 in an aqueous bath which contains 150 g sulfuric acid per liter. A 5 g / m2 thick anodic oxide layer is formed. It is then treated for 30 seconds at 70 ° C. with a 0.25% solution of polyvinylphosphonic acid in water and then dried. Subsequently, sensitization is carried out using a solution of 0.4% of a diazopolycone condensate, prepared by condensing 1 mol of 3-meth-oxy-diphenylamine-4-diazonium sulfate with 1 mol of 4,4'-bismeth-oxymethyl-diphenyl ether in 85% strength Phosphoric acid at 40 ° C and isolation as methanesulfonate, 0.72% of a highly reactive non-plasticized urea resin, with a dynamic viscosity in 60% solution in isobutanol of approximately 2500 mPas (cP) at 20 ° C and an acid number below 2 (Resin I) and 0.4% rhodamine 6 GDN (C.1.45 160) in ethylene glycol monoethyl ether.

It is irradiated with an Ar laser, which emits in the UV range, mainly at the wavelengths 363 and 351 nm, with 0.8 watt beam power and a recording speed of 100 m / sec. The areas not hit by the jet are stripped with a solution of 0.65% sodium metasilicate 9 water and 3.8% benzyl alcohol in water. The areas hit by the beam are oleophilically hardened and take on a bold color. You get over 85,000 good prints in an offset press.

With equal success, instead of the urea resin mentioned, the same amounts of the following non-plasticized ones can be used

Urea resins are used:

Resin II: acid number below 3; dynamic viscosity in 65% solution in butanol / xylene at 20 ° C approx. 6000 mPas (cP)

Resin III: acid number below 3; dynamic viscosity in 60% solution in isobutanol at 20 ° C approx. 650 mPas (cP)

Example 2

An Al plate pretreated with polyvinylphosphonic acid with an anodic oxide layer of 3 g / m 2 is treated with a solution of 1.0% of a diazopolycondensate as in Example 1, but which was isolated as mesitylene sulfonate, 1.8% of resin II and 0.4% Crystal violet coated in ethylene glycol monomethyl ether.

It is irradiated with an Ar laser in the visible range, mainly with the wavelengths 488 and 514 nm, with 5 watt beam power and a recording speed of 50 m / sec. The areas not hit by the jet are coated with a solution of 6% magnesium sulfate 7 water, 20% n-propanol and 0.7% of a non-ionic wetting agent (alkyl-phenol-polyglycol ether) in water. The spots hit by the jet take on bold color in an offset printing press and allow a good print run.

Example 3

An Al plate with an anodic oxide layer of 10 g / m2 is coated with a solution of the following composition:

2 pbw of 1- (4'-methyl-benzenesulfonylimino) -2- (2 ", 5" -dimethylphenylaminosulfonyl) -benzoquinone- (1,4) -diazide- (4) and

0.7 pbw of an unplasticized, highly reactive melamine resin with a dynamic viscosity in 50% solution in ethanol at 20 ° C. of approximately 450 mPas (cP) and an acid number below 1 (resin IV) in.

80 pbw of ethylene glycol monomethyl ether and

20 pbw of butyl acetate.

It is irradiated with a krypton-ion laser in the UV range, mainly with the wavelengths 406 to 423 nm, and with 0.9 watt beam power and a recording speed of 80 m / sec. The solution is decoated with a solution of 1.3% sodium silicate and 1.2% trisodium phosphate (both anhydrous) in water and good print runs are obtained.

Example 4

An Al plate with an anodic oxide layer of 5 g / m2 is made with a solution of 0.4 pbw of a crude condensation product of parafomaldehyde and diphenylamine-4-diazonium chloride, made in 85% phosphoric acid, 1 pbw of a liquid urethane resin Butyl urethane and formaldehyde with a density of 1.1 at 20 ° C and a dynamic viscosity at 20 ° C of 6-20 mPas (cP) and 0.2 pbw of astrazone orange (CI 48 040) in 50 pbw of tetrahydrofuran, 40 pbw of ethylene glycol monomethyl ether and 10 > Coated with butyl acetate.

It is irradiated with an argon laser in the visible range with 5 watt beam power and a recording speed of 60 m / sec. Then the coating is removed with water.

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Claims (4)

634 666 2nd PATENT CLAIMS 1. A process for the production of planographic printing plates, in which a recording material with a layer support of anodically oxidized aluminum with an oxide layer weight of at least 3 g / m 2 and a light-sensitive recording layer on the oxide layer is imagewise irradiated with a laser beam and thereby the irradiated parts of the recording layer made oleophilic and / or insoluble and then the non-irradiated areas of the recording layer are washed out with a developer liquid, characterized in that a recording layer is used which contains a negative-working photo-curable diazo compound and an amine resin. 2. The method according to claim 1, characterized in that that one uses a substrate with an oxide layer 15, which has a layer weight of 5 to 12 g / m2. 3. The method according to claim 1, characterized in that a recording layer is used which contains 0.6 to 6 parts by weight of amine resin per 1 part by weight of negative working diazo compound. 4. The method according to claim 1, characterized in that a diazo nium salt condensation product is used as the negative working diazo compound. 20th