DE1062708B - Process for the electromechanical production of screen printing stencils - Google Patents

Description

The invention relates to a method for the electromechanical production of screen printing stencils.

The photomechanical production of screen printing stencils is known, with a fine, close-meshed one Sieve or net or fabric made of silk, plastic or metal thread is assumed, which is clamped in a frame. The fabric is provided with a light-sensitive gelatin layer on which a right-sided slide is placed the original image to be reproduced is copied. The exposed areas are due to the exposure hardened and insensitive to water or developers. Those not exposed by the slide Parts are loosened and washed out during development. This makes the sieve permeable at the points where the printing ink should pass through according to the template during printing.

There are still different variants of this procedure, but there are no major differences or Result in advantages.

Furthermore, an electrothermal production of screen printing stencils is known. An image template is used here, which can also contain semitones, scanned photoelectrically line by line. By doing this according to the changing blackness of the scanned image points of the original triggered fluctuating Photocurrents are the density and intensity of spark breakdowns between a conductive one Pad and a cell-shaped, pointed electrode, between which a flammable thin plastic film is guided. The spark discharges cause a perforation as a result of combustion instead of the film, the density and hole diameter of which increase with increasing blackness of the original. During the printing process, more or less color appears through the holes in the screen printing film Print paper through. With this method a reproduction of quasi-semitones is possible.

Thanks to modern electronic printing machines, in which an image template is placed point by point in successive lines are photoelectrically scanned and by depending on the image brightness fluctuating photoelectric currents the depth of penetration of an engraving tool in a printing plate is controlled, it is possible to produce screen printing stencils electromechanically perform.

According to the invention, this is done in such a way that a thin film made of plastic or metal is firmly applied to a machinable or combustible base, that a cliché is engraved in the film together with the base by means of an electronic cliché machine, in such a way that the film perforates is, and that after the end of the engraving process for electromechanical
Manufacture of screen printing stencils

Applicant:
Dr.-Ing. Rudolf Hell, Kiel, Grenzstr. 1-5

Dipl.-Ing. Heinz Taudt, Kiel,
has been named as the inventor

the screen printing film is removed from the base again.

According to a further idea of the invention, the cliché to be cut into the thin film is preferred a grid in the manner of the autotypical gravure grid is used.

The invention is explained in more detail with reference to FIGS. 1 and 2, of which

Fig. 1 shows a detail from the engraved screen printing stencil in plan and
Fig. 2 shows the screen printing stencil and the base in section.

In Fig. 1, a screen printing grid is shown in the manner of the autotypical intaglio cross grid. This exists of square grid elements 1 of different sizes, the centers of which are placed across the corner form a square network.

When printing, the printing ink passes through the openings in the raster elements onto the printing paper. The area of the grid elements is proportional to the blackening of the original image points. With increasing brightness, i.e. decreasing blackness, the raster elements become smaller and smaller, so that small black dots still reach the printing paper in the case of white areas. With decreasing brightness, that is to say with increasing blackness, the raster elements become larger and larger, so that more printing ink reaches the printing paper. In contrast to letterpress printing, however, the grid elements must not grow so far that neighboring ones overlap, but only up to a maximum size such that narrow webs 2 from ¹ Z ₄ to V _{5 of} the largest cell width remain. This is important so that the screen printing stencil to be engraved retains its cohesion in the shadows. The middle shade of gray (50% black or white) is obtained when the

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Claims (2)

The area of the grid elements is approximately equal to the area of the (changeable) bar border, the iron color remains free. The grid elements are placed at a corner so that the preferred directions of the grid, which run parallel to the edges of the grid elements, form angles of 45 or 135 ° with the print image edges, making them less disruptive. The grid elements can also be circular or oval-shaped. Fig. 2 shows the thin screen printing film 3 made of metal or plastic, which is applied to support on a stronger machinable or combustible base 4 so that it can be removed again later. The screen printing film 3 is so thin or the minimum penetration depth of the engraving stylus is so great that the film in the lights 5 is just pierced by the stylus. In the shadow 6, however, the engraving is only so deep that narrow webs 7 still remain between the individual grid points, which is achieved by limiting the engraving current. The base 4 is used to give the thin screen printing film a firm hold and to catch the tip of the stylus. The stylus cuts a cliché on the base with a variable depth. The grid elements correspond to the variable penetration depth of the stylus tip. This document cliché, the production of which cannot be avoided, is not used and is removed again after the engraving has been completed. If a positive original image is assumed and a positive print is required, the printing machine must contain an electronic tonal value reversal stage, similar to what is the case with a picture telegraph. The photocell of the photoelectric scanning device reacts to bright pixels with a large photocurrent, which must control the electromagnetic drive system of the engraving device in such a way that the penetration depth of the engraving stylus is inversely proportional to the photocurrent. On the other hand, it is possible to obtain a positive print image from a negative without a reversal step, and vice versa. The engraving can be carried out in a known manner with a parallel or diagonal cut. The former comes into consideration when a wedge-shaped engraving stylus is used which, with its periodic up and down movement, which is generated in a known manner by a screen frequency superimposed on the image signal, cuts rhombus-shaped surface elements from the printing form material. The grid elements of successive lines must each be offset by half the distance between two adjacent elements so that they lie above or below the gaps between the grid elements of the preceding line. The line spacing is then (in the case of a square grid) equal to half the distance between two adjacent grid elements in a line. The offset of the grid elements is achieved in a known manner by a phase shift of the grid frequency by 180 ° after each line has been engraved. In the case of a diagonal cut, it is not necessary to offset the grid elements, since the center points ίο of corresponding grid elements of different lines are perpendicular to one another. Square-shaped grid elements cannot be cut with a wedge-shaped graver, but must be burned out with a truncated pyramid-shaped burning stylus with a square cross-section. However, this is only possible in plastic material. On the other hand, the raster elements can also be burned out with parallel cuts. A spoon-shaped graver can also be used to engrave in a diagonal cut. The screen printing film can be glued, rolled, soldered or poured onto the supporting surface. After the engraving is finished, the finished screen printing stencil must be removed from the base. In the case of gluing and rolling, this is done by peeling off the template. The base can also be physically or chemically dissolved using a suitable solvent that does not attack the stencil. In the case of soldering, the solder is heated until it flows for the purpose of separation. If the base is made of a readily fusible metal, e.g. B. lead, was poured onto the foil, the base is melted. If the screen printing film is made of metal, it may be necessary to briefly re-etch it after it has been removed from the substrate in order to remove the burr. Patent claims: 1. A method for the electromechanical production of screen printing stencils, characterized in that that a thin sheet of plastic or metal on a machinable or combustible surface is firmly applied that in the film together with the base by means of an electronic A cliché machine is engraved in such a way that the film is perforated is, and that after the engraving is finished, the screen printing film is removed from the base will. 2. The method according to claim 1, characterized in that for the to be cut into the thin film Cliché preferably uses a screen in the manner of the autotypical gravure screen will. 1 sheet of drawings