DE10122413B4 - Method of imaging and erasing a printing surface of zirconate - Google Patents

Abstract

Method of imaging and erasing a reusable zirconate printing surface comprising the steps of:
Providing a rewritable zirconate pressure surface in a substoichiometric, hydrophobic initial state,
Generating an image on the printing surface by selective pointwise oxidation,
- Deleting the image after printing a substrate by large-scale reduction, displacing oxidizing substances to promote the reduction
or a reducing agent is used.

Description

The present invention relates to a method of imaging and erasing a printing surface comprising zirconate (ZrO ₂ ).

since some time will be efforts undertaken materials for the manufacture of printing plates and methods of using the same to develop a controlled imaging and deletion of a Print subjects on the printing form allow. You can do this in particular oxide ceramics, which, for example, in the form of coatings on a printing surface present, find use.

In the US 5,743,188 A For example, the use of zirconate (ZrO ₂ ) in ceramic-pure or otherwise-added form as an active material in the surface is proposed. The surface is exposed pointwise with laser radiation, ie melted and is thereby converted from a hydrophilic, stoichiometric to a hydrophobic, substoichiometric state. This conversion to the substoichiometric state is accomplished by ablation of small amounts of the surface of the ceramic. The surface can be returned to the stoichiometric state by being thermally oxidized. An Nd: YAG laser is used to generate the infrared radiation at 1060 nm.

In the DE 198 14 852 A1 is the imaging and erasing of a printing surface, which zirconate has as essential for the imaging component, the erasing should be done by heating the zirconate of the printing surface in air or oxygen. It is further described to image a hydrophobic substoichiometric zirconate surface by selective oxidation and to quench it by reduction. In addition, in this document, as an alternative to thermal oxidation, the use of a carbon dioxide laser emitting at a wavelength of 10600 nm or an argon ion laser emitting at a wavelength of 488 nm is proposed to render the surface hydrophilic stoichiometric offset.

In the DE 198 26 377 A1 is an optical imaging unit for imaging a printing form, which may have zirconate is described. By UV exposure, the printing surface of the printing plate is reduced to a substoichiometric state, and oxidized back to a stoichiometric state by an IR exposure under oxygen supply.

The use of oxide ceramics as a printing surface leads to significant difficulties. When imaging a zirconate surface by point ablation remain after the subsequent deletion of the image wells in the image grid. The underlying chemical reactions and physical transformations have so far had no influence. As a result, when printing the next image, the printing result may be degraded in that the remaining recesses continue to contribute to the formation of the print image on the substrate and cause undesirable so-called ghosting. In addition, point-to-point ablation involves a removal of material, so that only a limited number of possible images can take place. The use of elaborate laser systems (Nd: YAG, CO ₂ or argon ions), as in US 5,743,188 A and DE 198 14 852 A1 has been proposed, is costly and results in a high operating effort, so that a successful commercial use appears questionable.

Around Economical printing with zirconia printing in Direct Imaging Printing machines in which the subject to be printed with the help of a Lasers directly on a printing surface imaged or CtP systems (computer-to-plate systems) enable, it is necessary to transition from the hydrophilic state to the hydrophobic state and vice versa to design.

task The present invention is a method for imaging and delete to propose a zirconate printing plate, which improved to an Transformation of the surface from the hydrophilic to the hydrophobic state.

These The object is achieved by a Method for imaging and deletion a reusable printing surface with the features according to claim 1 solved.

According to the invention is on the device for imaging and deletion of a printing surface Zirconate means for delivering at least one reaction promoting Provided by means. To the transition the surface hydrophilic, stoichiometric to a hydrophobic, substoichiometric Condition becomes the reduction by offering a reducing agent promoted. Accordingly, the transition from hydraphobic, substoichiometric to the hydrophilic, stoichiometric State promoted by an offer of an oxidizing agent. In this case, the imaging of a rewritable printing surface takes place Oxidation while the reduction for deletion serves. The necessary minimum wavelength of photons for pointwise Oxidation is in the infrared spectral range, while ultraviolet reduction Radiation is required.

Advantageously, by the offer a reducing agent improves the transition of the surface from the hydrophilic, stoichiometric to hydrophobic, stoichiometric state. Accordingly, by providing an oxidizing agent, the transition from the hydrophobic, substoichiometric to the hydrophilic, stoichiometric state is improved.

In a preferred embodiment lies the printing surface of zirconate in substoichiometric, hydrophobic state before. This surface is made by irradiation by a laser, in particular in the infrared spectral range, pointwise oxidized, creating hydrophilic, localized areas on the surface be generated. The energy supply in the form of infrared radiation is preferably done by a diode laser. The hydrophilic, localized Areas are non-pressurizing while the hydrophobic surface is printing. So it is made a negative illustration. The oxidation is due to an oversupply supported by oxygen, z. B. by blowing oxygen through a nozzle at that point becomes where the pointwise hydrophilization takes place.

The erasing of the printing form is accomplished by irradiating the entire surface with ultraviolet light, such as emitted by an excimer lamp or a short pulsed laser, typically an excimer laser. The pulse length is typically shorter than 30 ns, advantageously between 15 and 20 ns. The energy deposited on the surface is a few 100 nJ / cm ² , advantageously between 500 and 1000 nJ / cm ² . Since the reduction associated with material removal occurs uniformly on the whole plate under the same conditions, the so-called ghosting (the presence of a "shadow" of the erased image on the plate) is avoided. There is again a smooth surface to reprint. The reduction is promoted by a reduced supply of oxygen.

In an advantageous development of the invention, other oxidizing substances in various physical states and modifications can also be used as the oxidizing agent; H ₂ O ₂ or ozone in particular can be used here. Likewise, other reducing substances in various states of aggregation and modifications are possible as reducing agents. This may in particular be propane, butane or their mixture, NH ₄ F or urea.

Around even more even Clear Achieve in another advantageous development the invention before the large-scale reduction also first a large-scale oxidation occur. This can, for example, by hot air or by large-area exposure done with laser radiation in continuous wave mode.

Further Advantages and advantageous embodiments The invention will be described with reference to the following figures and their Descriptions shown.

It show in detail:

1 Apparatus for imaging and erasing a printing surface comprising zirconate,

2 schematic representation of a device for imaging and erasing in a printing unit,

3 Process steps of imaging and deletion of a printing surface comprising zirconate.

In the 1 the essential elements of an embodiment of the invention are shown. The printing plate 10 has a carrier 12 Made of suitable material, such as aluminum, and a pressure surface 14 which has zirconate. From the laser 16 starting, by means of optics 18 a ray of light 110 generated. This light beam is used for pointwise oxidation. The device 112 for the delivery of an oxidizing agent is at the site of the reaction, the oxidizing agent 114 to disposal. In advantageous embodiments of the invention, the oxidizing agent is 114 to gaseous oxygen, ozone or liquid hydrogen peroxide. The laser 16 and the device 112 be through a control unit 116 operated and influenced. Starting from the laser 118 , is by means of optics 120 a fan of light 122 placed. From a facility 124 for the delivery of a substance supporting the reduction, the delivery of a substance to support the reduction takes place at the site of the large-scale reduction 126 ,

In a particular embodiment of the invention, the substance supporting the reduction is 126 gaseous nitrogen, which displaces the atmospheric oxygen at the point where the reduction is to take place. The laser 118 and the device 124 be with the control unit 128 operated, inter alia, to influence the pulse operation. The described invention, for example in this in the 1 embodiment shown may, in this or similar topology, which z. B. to other optics or electronics can be added, be realized inside or outside of a printing unit or a printing press.

In an advantageous development of the invention, for example for use in a pressure In addition, by means of the connections to the exchange of data 130 the control units 116 and 128 with the machine control unit 132 connected.

In the 2 is shown a schematic representation of the imaging and deletion within a printing unit or a printing press, in which the invention is advantageously used. The printing cylinder 20 has a carrier 22 and a printing surface of zirconate 24 on. By means of the device 26 the pointwise oxidation is carried out with the offer of an oxidizing agent. This device is powered by a control unit 28 operated. From the device 210 the large-scale reduction is carried out under displacement oxidizing substances and / or with the addition of a reducing agent. It is from the control unit 212 operated. In an advantageous development, the control units 28 and 212 with connections to exchange data 214 from the machine control unit 216 addressed.

The 3a - 3d serve to explain the essential process steps for imaging and deletion of a printing surface, which has zirconate. In 3a There is a pressure plate on a support 30 the printing surface 32 which zirconate is in the substoichiometric, hydrophobic state 34 having. After pointwise oxidation, advantageously with the addition of an oxidizing agent, are in 3b pointwise places 36 which have zirconate in the stoichiometric, hydrophilic state. After printing a printing material, the printing plate is first, as in 3c shown, oxidized over a large area, leaving the surface 38 Having zirconate in the stoichiometric, hydrophilic state. This is followed by the actual deletion of the printing plate by the large-scale reduction, advantageously with displacement of oxidizing agent and / or addition of reducing agents takes place. In 3d indicates the printing surface 32 again a large area of zirconate in the substoichiometric, hydrophobic state 34 on, and is on the carrier 30 ,

10

printing plate

12

carrier

14

Printing surface, which Having zirconate

16

laser

18

optics

110

beam of light

112

Facility for dispensing an oxidizing agent

114

oxidant

116

control unit

118

laser

120

optics

122

light fan

124

Facility for delivering a substance to aid the reduction

126

substance for support the reduction

128

control unit

130

links to exchange data

132

Engine control unit

20

pressure cylinder

22

carrier

24

print area

26

Facility for pointwise hydrophilization

28

control unit

210

Facility for large-scale water repellency

212

control unit

214

connection to exchange data

216

Engine control unit

30

carrier

32

Surface, which Having zirconate

34

Area that Zirconate in substoichiometric State

36

zirconate in stoichiometric Status

38

Surface, which Zirconate in stoichiometric State

Claims (15)

Method of imaging and erasing a reusable, Zirconate-containing printing surface with the steps: - Provision a rewritable zirconate printing surface in one stoichiometric, hydrophobic starting state, - Create an image the printing surface by selective pointwise oxidation, - Delete the picture after one Printing a substrate by large-scale reduction, wherein the advancement the reduction of oxidizing substances displaced or a reducing agent is used. Method according to claim 1, characterized in that one of the substances displaced to promote the reduction Oxygen is. Method according to claim 1 or 2, characterized in that nitrogen oxidizing to the displacement Substances is used. Method according to one of claims 1 to 3, characterized in that as reducing agent propane, butane, a mixture of propane and butane, NH ₄ F or urea is used. Method according to one the claims 1 to 4, characterized in that the deletion of the image by large-scale reduction with the help of electromagnetic radiation. A method according to claim 5, characterized ge indicates that the electromagnetic radiation for reducing ultraviolet radiation ( 122 ). Method according to claim 5 or 6, characterized in that the electromagnetic radiation for the reduction of a laser ( 118 ) is emitted. Method according to one the claims 1 to 7, characterized in that to promote the oxidation of an oxidizing agent is offered. A method according to claim 8, characterized in that the oxidizing agent from a device ( 112 ) is discharged oxygen. Method according to one the claims 1 to 9, characterized in that the selective pointwise oxidation with the help of electromagnetic radiation. A method according to claim 10, characterized in that the electromagnetic radiation for the oxidation of infrared radiation ( 110 ). A method according to claim 10 or 11, characterized in that the electromagnetic radiation for the oxidation of a laser ( 16 ) is emitted. Method according to claim 12, characterized in that the laser ( 16 ) is a diode laser. Method according to one the claims 1 to 13, characterized in that after the printing of the printing material and before deleting of the picture the print area oxidized over a large area becomes. Method according to one the claims 1 to 14, characterized in that the imaging and deletion within a printing unit or a printing press.