DE4140996A1 - High speed electrophotographic printing - uses printing plate with transparent, anion-contg. polymer layer for image formation - Google Patents

Abstract

A novel electrophotographic printing process is claimed, as is also the printing plate used and a method for prodn. of the plate. The characteristic features of the printing process are that (i) the plate used consists of a photo-semiconductor layer (2) covered by a transparent polymer layer (4) contg. elec. field-diffusible anions and being reversibly changeable from an elec. conducting to an elec. insulating state; (ii) after prodn. of the charge image, layer (4) is conducted with an electrolyte soln. (7) which, on application of a fixing field, extracts anions from positions corresponding to charges in underlying layer (2) so as to give an elec. insulated fixed image in layer (4), this image being repeatedly toner transferred to the material to be printed; and (iii) the fixed image is erased by exposure of layer (4) and soln. (7) to a field opposing the fixing field. Prodn. of the printing plate is by applying in order to a carrier (e.g. supported on a drum) a photo-semiconductor or layer (2), a transparent, conductive electrode (3) and a polymer layer (4), this layer (4) being obtd. (pref. in situ) by polymsn. of an electrolyte soln. contg. a conductive salt as well as a monomer, esp. by oxidative polymsn. of a (hetero) aromatic monomer. ADVANTAGE - Higher printing speeds are attained than in prior-art electrophotographic processes with initial image formation effected directly from digitised data using a computer-controlled laser source (pref. an LCS or LED system) and with the image transfer effected in a high-speed rotary printing process. Fresh images can be directly introduced.

Description

The invention relates to electrophotographic printing method (according to the preamble of claim 1), an electrophotographic printing form (according to the Gat term of claim 3) and a method for Production of a photographic printing form (according to the preamble of claim 8).

In electrophotographic printing processes, a Fo semiconductor layer initially charged and then producing an electrical charge image partially unloaded. In the previously known methods then pigment particles (toner) on this in the Photo semiconductor layer generated electrical charge image captured and then on a print transfer fabric. It takes place through the image transfer process deletion of the image information instead. As a result, the image information must be printed before each print process again in the photo semiconductor layer of printing form can be read what the resulting Druckge speed very limited.

DE-A 37 05 439 is still a Druckma apparently known, the printing form an Ab to be printed image in the form of water-repellent and water-repellent areas. The printing form is here when made from a polymer by electrochemical Control from a water repellent to a water accepting state and vice versa.

The invention has for its object an electro photographic printing process (according to the Oberbe  handle of claim 1) so that the pressure form with a data record directly from the digital Illustrated database of an image processing system can be, the printing form once created for any repeated image transmission in a rotary Hochge speed printing process can be used and a Reimaging is possible directly in the printing press. The object of the invention is also one of these Requirements corresponding electrophotographic printing form and a method for producing such a to create printing form.

This object is inventively characterized by nenden features of claims 1, 3 and 8 solved. Purpose moderate embodiments of the invention are the subject of subclaims.

Referring to Figs. 1 to 8 of the drawing first the essential steps of the elektrofo tografischen pressure process of the invention will be explained.

The printing form used for the printing method according to the invention contains a photo semiconductor layer 2 on a base 1 , for example a drum. Above the photo semiconductor layer 2 there is a transparent electrode 3 and thereupon a transparent layer 4 made of a polymer which contains embedded anions (A-) which can migrate in an electrical field and which is reversibly changeable between an electrically conductive and an electrically insulating state.

In the first process step ( Fig. L), the photo semiconductor layer 2 is electrically charged according to one of the known methods (such as corona, induction or alpha particle induction processes). Preferably, a photo semiconductor layer is used, which leads to a negatively charged layer 2 a after charging.

A primary exposure ( FIG. 2) now generates an electrical charge image in the photo semiconductor layer 2 by partial discharge (image point 2 b). The exposure can be carried out by a computer-controlled light source, by means of a modulated laser beam, by an LCS (Liquid Cristal Shutter) or an LED (Light Emitting Diode) exposure system, since the polymer layer 4 located above the photo semiconductor layer 2 is opposite these Light sources have a high transparency. The template through which the exposure (arrows 5 ) takes place is identified in FIG. 2 by reference number 6 .

In the next method step ( FIG. 3), the printing form is then fixed, ie the generation of an electrically insulating fixing image in the polymer layer 4 corresponding to the electrical charge image of the photo semiconductor layer 2 . For this purpose, the polymer layer 4 is brought into contact with an electrolytic solution 7 , an electrical fixing field being generated between the negatively charged photoconductor layer 2 and an ordered, positively charged counter electrode 8 in the electrolytic solution 7 , the anions (A-) from those locations of the polymer layer 4 into the electrolyte solution 7 , that is, they can flow away, which correspond to the negatively charged locations of the photo semiconductor layer 2 . In this way, an electrically insulating fixing image 4 b is formed in the polymer layer 4 .

The next process step can now be carried out in one of there are two variants:

According to Fig. 4a, the photo semiconductor layer 2 is recharged negative, as based on Fig. 1 already described.

According to Fig. 4b, the transparent electrode 3 is connected to a negative potential.

In both cases ( Fig. 4a and 4b) by the previous generation of an electrically insulating Fixierbil the 4 b in the polymer layer 4, a charge flow to the surface of the printing form is only possible at the locations of the polymer layer, which are still electrically conductive. The electrically conductive locations of the polymer layer 4 can transmit the electrical field induced in the photo semiconductor layer 2 ( FIG. 4a) or the field permanently applied to the transparent electrode 3 ( FIG. 4b) to the surface of the printing form, while the electrically insulating locations of the polymer layer 4 are unable to do so. This creates spots on the surface of the printing form which lead to a charge flow in an electric field, in addition to spots which are unable to do so.

The following development (accumulation of toner par particles on the surface of the printing form) can come back in go two ways:

Referring to Fig. 5a (reversal development) Toner 9 (ie, to the said insulating Fixierbild 4 b of the poly cell layer 4 corresponding points) to the electrically uncharged areas of the printing die surface attached.

In the variant according to FIG. 5b (direct development), on the other hand, it follows the accumulation of the toner 9 at the ge loaded points of the printing form surface. Dry or liquid toners can be used as toner materials in both cases.

In FIGS. 5a and 5b, the illustrated charging veran variant in Fig. 4b is adopted in which the transparent electrode is negatively charged. 3 Instead of this, of course, the variant shown in FIG. 4a (negative charging of the photo semiconductor layer 2 ) can also be used.

The toner 9 is now transferred to a printing substrate 10 . Fig. 6a shows the variant of reverse development and Fig. 6b the variant of direct development.

The transfer of the toner 9 to the printing medium 10 can be carried out by using electrostatic or adhesive processes when using dry toner. When using liquid toners, which appear to be particularly suitable for the described process due to their significantly higher resolution and possibly higher Anlagungsge speed and due to the easier fixation at high printing speeds, the toner transfer takes place through the absorbency of the paper with the support of a transfer printing corotron.

In the next process step ( Fig. 7) the Restto ner 9 a from the surface of the printing form, ie from the top of the polymer layer 4 is removed to ensure a uniform toner transfer ge with each sheet. This cleaning step can be carried out mechanically by means of a brush 11 , electrically (in the case of dry toners) or with a solvent (in the case of liquid toners).

When using dry toners, the fixation of the Toner by heat fixation, radiation fixation, cold Pressure fixation or by solvent fixation It may be possible when using liquid toners Lich to do without a fixing process; instead can also be a short heat or radiation fixation process be performed.

With the printing plate fixed in the manner described (ie using the electrically insulating fixing image generated in the polymer layer 4 ), a rotary printing process can now be carried out by repeating the process steps described with reference to FIGS . 4 to 7. The necessary in previous electrophotographic printing processes, the printing speed be limiting step of the image transfer required for each individual sheet to be printed on the printing form is eliminated according to the invention.

If the printing form, ie the electrically insulating fi xing image in the polymer layer 4 , is to be deleted (ie after the completion of a repeated rotary printing process), the printing form is brought into contact with the electrolyte solution 7 again after the last cleaning according to FIG. 7 ( see Fig. 8). The provided between the photo semiconductor layer 2 and the polymer layer 4 transparent electrode 3 is now placed on positive Po potential, while the counter electrode 8 located in the electrolyte solution 7 is switched as a cathode. Because of the electrical erasing field that is generated in the opposite direction to the fixing field, the previously incorporated anions (A-) are incorporated again into the polymer layer 4 . The electrically insulating fixing image in the polymer layer 4 thus disappears, and the initial state for renewed selective imaging of the printing form (starting with a charging of the photo semiconductor layer 2 according to FIG. 1) is thus restored.

The transparent electrode 3 suitably consists of egg nem in a vacuum on the photo semiconductor layer 2 vaporized conductive material.

The function of this transparent electrode 3 can also be fulfilled by a reversible photo semiconductor layer 2 provided with additives.

The polymer layer 4 suitably consists of a polymer produced by oxidative polymerization of heteroaromatics or aromas.

The polymer layer is advantageously made by Polymerisa tion of a monomer generated in an electrolyte solution, which contains a conducting salt in addition to the monomer. As a monomer can use aromatics or heteroaromatics find such as thiophene, furan, indole, pyrrole, carbazole, Benzthiophene or its substitution products.

The polymer layer is expediently produced in such a way that the monomer or monomers in a Lö Solvent are dissolved, the solvent under  inert to the conditions of the electrochemical reaction Conductive salt is added and the polymerization then in an electrochemically controlled reaction on the Surface of the transparent conductive electrode follows.

According to the invention, anorga is expediently used as the conductive salt African substances, such as quaternary ammonium salts, alkyl sulfonates or anionic surfactants used under inert to the conditions of the electrochemical reaction are.

Organic solvents are preferably used as the solvent solvent use, such as acetonitrile, dichloromethane, Sulfolan, nitrobenzene or water or aqueous Gemi with the above-mentioned organic solutions average.

Within the scope of the invention, a photo semiconductor layer 2 can advantageously be used, which is provided with additives to achieve a particularly effective charge exchange.

The invention is further as follows example explained in more detail:

On a drum pre-coated with a photo semiconductor mel becomes a transparent conductive electrode Gold evaporated. In an electrolyte bath consisting of Acetonitrile in which 0.1 mol of tetrabutylammonium Trafluoraborate dissolved as the conductive salt and that with 0.01 mol  2,2'Bithienyl was added as a monomer, by the application of an electric field constant chip voltage of 1.5 V is a transparent layer of poly bithienyl on the surface of the transparent conductive polymerized gold layer. This turns gold layer anodically connected in the electric field. The printing form produced in this way is in the Printing machine installed.

After charging in a known manner the printing form with the photo-semiconducting layer one of the usual electrophotographic exposure facilities by data using an electronic Image and sentence processing system were created, be forms, so that a charge in the exposed areas outflow takes place in the photo semiconductor.

Starting from that in the photo semiconductor layer the residual charge is given electric charge pattern now in the polymer layer a corresponding, elec tric isolating fixation generated. To this end the polymer layer is coated with an electrolyte solution Brought in contact from a 10% aqueous solution alcoholic solution consisting of 0.1 M tetra butylammonium tetrafluoroborate added as the conductive salt has been. By applying an electrical field between the transparent gold electrode and one in the positively charged electrolyte solution Counterelectrode are connected to the electric charge image corresponding to the photo semiconductor layer the polymer layer which migrates in the electric field capable tetrafluoroborate incorporated in the polymer Anions are incorporated into the electrolyte solution. These Anion exorporation converts the polymer to that  electrical charge image of the photo semiconductor layer ent speaking points from an electrically conductive in an isolating state. It arises in the Polymer layer an electrically insulating fixation.

The above process steps (charging the Photo semiconductor, exposure and fixation) he can if necessary, be repeated provided that the remaining la of the photo semiconductor is not yet complete exporter of the tetrafluoroborate anions has led.

Then the transparent electrode is negated ves potential, and the printing form is created with ei contacted normal liquid toner. Because of the voltage can create electrical charge particles only at the points of the polymer layer on the surface the printing form, which is above the image clear areas of the printing form, d. H. only at the still conductive zones of the polymer layer. With egg In direct development, toner substances on these Places attached to the surface of the printing form. On then the transfer of the toner substances takes place on the substrate and a short cleaning of the Printing form.

In contrast to conventional electrophotographic ver can then drive without recharging and exposure new toner is applied directly to the printing form and be transmitted.

After completing the entire printing process, the Printing form again in contact with the above Brought electrolyte solution and it is by applying  a positive voltage to the transparent electrode an electri opposite to the fixing field quenching field generated so that anions from the Electrolyte solution incorporated into the polymer layer be, the electrically insulating fixation in the Polymer layer deleted and thus the initial state is restored.

The method according to the invention allows significantly higher here printing speeds than the previously known electrophotographic process. The printing form can with a data record directly from the digital database of an image processing system. The Once the printing form has been created, it can then be used for image transfer in a high speed rotary printing process be used. New imaging can be done directly in the Printing machine can be made. Intermediate steps between between the creation of the data record in the computer and the pressure in the printing press are avoided. There these intermediate steps, especially for smaller and medium-sized ones editions in multi-color printing compared to effec tive printing time can be relatively time-consuming is by shortening the for one edition change the set-up time the printing speed significantly increased. It is also possible in this way Lich, in several printing units, multi-color prints in small and medium-sized runs very economically put.

Claims (13)

1. Electrophotographic printing process in which a photo semiconductor layer is first electrically charged and then partially discharged to produce an electrical charge image, an image being transferred to a printing material by means of a toner, characterized by the following features:

• a) there is a printing form used, which consists of the photo semiconductor layer and a covering, transparent layer made of a polymer, which contains embedded anions which can migrate in an electric field and which is reversibly changeable between an electrically conductive and an electrically insulating state;
• b) after generation of the electrical charge image, the transparent polymer layer of the printing form is brought into contact with an electrolytic solution, and anions are exported into the electrolytic solution by means of an electrical fixing field from the locations of the polymer layer corresponding to the charged positions of the photoconductor layer, wherein in the polymer layer forms an electrically insulating fixing image corresponding to the electrical charge image of the photo semiconductor layer;
• c) starting from the fixing image thus generated in the polymer layer, an arbitrarily repeatable, direct image transfer to a printing material takes place;
• d) for deleting the fixing image in the electrolytic solution and in the polymer layer, an ent opposing to the fixing field directed electrical erasing field is generated.

2. The method according to claim 1, characterized in that that the electrical charge pattern in the photo half layer by a computer controlled light source, by means of a modulated laser beam, through an LCS or an LED exposure system is fathered. 3. Electrophotographic printing form with a photo half conductor layer for generating an electrical La image, characterized by a photo half transparent layer covering the conductor layer a polymer that is stored in an electri contains anions capable of migration and between an electrically conductive and an elec tric isolating state reversibly changeable is. 4. Printing form according to claim 3, characterized in that between the photo semiconductor layer and the poly layer a transparent conductive electrode is arranged. 5. Printing form according to claim 4, characterized in that the transparent electrode from a in a vacuum evaporated on the photo semiconductor layer material.   6. Printing form according to claim 3, characterized in that the polymer layer from a by oxidative Po lymerization of heteroaromatics or aromatics posed polymer. 7. Printing form according to claim 3, characterized by a with additions and at the same time the function egg a reversible photo half that fulfills an electrode layer. 8. Process for making an electrophotography rule printing form, characterized in that on one preferably formed by a drum Carrier first a photo semiconductor layer, on top a transparent conductive electrode and on it a polymer layer is applied, the Po polymer layer by polymerizing a monomer in an electrolytic solution is generated which besides that Monomer contains a conductive salt. 9. The method according to claim 8, characterized in that aromatics or heteroaromatics, such as Thiophene, furan, indole, pyrrole, carbazole, benzthio phen or their substitution products used will. 10. The method according to claims 8 and 9, characterized ge indicates that the monomer (s) in one Solvent are dissolved, the solvent under the conditions of the electrochemical reaction inert conductive salt is added and the Polymerisa tion then in an electrochemically controlled  Reaction on the surface of the transparent conductive capable electrode. 11. The method according to claim 10, characterized in that as conductive salt inorganic substances, such as quar tary ammonium salts, alkyl sulfonates or anionic Surfactants, used under the conditions are inert to the electrochemical reaction. 12. The method according to claim 10, characterized in that that as a solvent organic solvents, such as Acetonitrile, dichloromethane, sulfolane, nitrobenzene, or water or aqueous mixtures with the foregoing organic solvents mentioned will. 13. The method according to claim 8, characterized in that a photo semiconductor layer is used, which with additives to achieve a particularly effective seed charge exchange is provided.