CS248004B2 - Production method of blocks by the photography process - Google Patents

Abstract

PURPOSE:To enable higher working efficiency to be achieved in a method of engraving antimoire halftone gravure plates by printing the halftone negative obtained by simultaneously printing and developing the photosensitive material printed with a halftone positive and a gravure screen. CONSTITUTION:A photosensitive material 6 having transparency and halftone positive 2 are laminated on the photosensitive layer side of a photosensitive material in such a manner that their respective emulsion faces oppose to each other, thence parallel light is radiated from the positive 2 side. In this way, the dots of the positive 2 and printed without being blurred to the materials 1, 6 and the halftone negative 9 is obtained through development of the material 6. Next, a gravure acreen, diffusion sheet 4 and negative 9 are laminated on the photosensitive layer side of the material 1 and light is radiated from the negative side. This produces the effect similar to that when continuous gradation negatives are used, causes the screen 7 to be not printed on the light part and to be printed on the other shadow parts and prevents the production of moire between the positive 2 and screen 7.

Description

The invention relates to processes for the production of printing plates, which may be. used in the gravure printing process, allowing the use of several photosensitive materials and autotypic positives.

Furthermore, the invention relates to an improved process which gives excellent gravure printing with a wide gradation and good reproducibility.

With respect to conventional gravure printing methods, the conventional gravure printing method and the network gravure printing method are generally known. In the conventional gravure printing method, the density gradation is given by differences in the depth of the color cells,. The density gradation is given by differences in the size of the color cells or variations in both the depth and dimensions of the color cells.

In a conventional gravure printing process, several types of etching baths are necessary to etch the printing plate through a layer of photosensitive material, since the gradation must be given only by the depths of the color cells formed in the printing plate. The network gravure printing method, or so-called autotypic gravure printing method, is an improvement to the conventional prior art method, but if the gradation of the original is only due to the different size of the color cells, the gradation of the resulting 'prints' is not satisfactory. In a method using combinations of both cell size and depth, the effect of depth variation may be diminished as a cell size factor is added and is therefore preferred in terms of reproducibility.

However, in the known method, called the double positive method, where color cells differ in both size and depth, two types of positives must be used, an gravure autotypic positive and a continuous color positive. That is, the photosensitive material, such as carbon .resist, is first illuminated in this process via an autotypic positive to create dots of a network block, then illuminated through a positive color contour to obtain different depths of dots of the network block, whereupon the printing plate is formed successively. transfer, recall and etching steps. In this process, a perfect registration of the autotypic positive with the continuous color positive is necessary, which is very difficult and, moreover, the exposure process is complicated. Therefore, it is to this. process needed high skills.

The method according to the invention eliminates the aforementioned disadvantages. There is no need for a continuous staining positive and differences in color cell sizes and depths can be achieved using mere autotypic. positive. In addition, any of the autotypic positives for gravure printing, planographic printing and embossing can be a method. according to the invention.

The essence of the method of the invention using an autotypic positive is that it comprises the steps of illuminating the photosensitive material with a light source through a gravure printing. a network having a transparent lattice, further re-illuminating the photosensitive photomaterial with a light source through an autotypic positive, further illuminating the photosensitive material with a light source with an interposed foil between the autotypic positive and the photosensitive material, and following the steps of the plate. The order of exposure steps described is not fixed.

The present invention further comprises the steps of illuminating a photosensitive material with a light source through an autotypic positive having. transparent grid gravure nets, further illumination of photosensitive material with light source with diffuser insertion. foils between autotypic positives and photosensitive material; and. following steps of plate production.

It is also an object of the invention to include photosensitive lighting steps. of the material by a light source by placing an intaglio grid thereon and placing the intaglio grid on them. layers of autotypic negative and dispersion foil, illumination of photosensitive material by light source through autotypic positive, as well as photosensitive illumination. material with a light source with the insertion of a diffusion foil between the autotypic positive. and photosensitive material and the subsequent steps of manufacturing the board. Autotypic layers. negative and scattering films can be replaced by a continuous color positive.

It is also an object of the invention to include the steps of illuminating the photosensitive material with a light source through a gravure network, again photosensitive lighting. the light source material through an autotypic positive, having no transparent grating intaglio meshes, and further illuminating the photosensitive material with light through a continuous color positive or approximately continuous color positive.

Examples of these are documented as autotypic positives, planographic autotypic positives, embossed autotypic positives, and gravure auto-print positives that are. used in conventional plate production processes for planographic, embossed and gravure printing. Planographic autotypic positives and embossed autotypic positives have no lattices, while gravure autotypes have the desired number of transparent lattices.

Examples are. as photosensitive materials, carbon resists such as thin raw carbon paper, gravure protective films, photosensitive resin layers formed on gravure cylinders. When the carbon resist is used as a photosensitive material, the described sequential steps in manufacturing the plate are as follows: placing the exposed carbon resist on the gravure cylinder, inducing the carbon resist, and etching the gravure cylinder over the carbon resist.

When using an intaglio protective film as a photosensitive material, the plate manufacturing process comprises the steps of: inducing the first exposed intaglio protective film with developing agents, transferring the protector film to the intaglio printing cylinder, reloading with hot water and etching the intaglio printing cylinder through the protective film. When using a photosensitive resin layer formed on a gravure cylinder, the next step in manufacturing the plate is simply to induce the resin layer itself.

Incidentally, the described exposure steps can be performed in any order, since a single photosensitive material is repeatedly illuminated by a light source without any effect of the exposure order.

The invention will now be described in more detail for purposes of illustration only, with reference to the accompanying drawings, in which FIGS. 1 to 4 are enlarged schematic illustrations of a photosensitive material showing the principle of the method of the invention, FIG. 1a is a plan view of part of a carbon resist illuminated by light source and contacted with gravure-network. Giant. 1b is a cross-section of the carbon resist of FIG. 1a. Giant. 2a is a plan view of a carbon resist illuminated by a light source by contacting -with the brightest portion of the autotypic positive. Giant. 2a is a plan view of a carbonaceous resist as in FIG. 2a in the portion having a 50% density. Giant. 2c is also a plan view like -2a, but in a shaded area. Giant. 2d is a cross-section of the carbon resist of FIG. 2a. Giant. 2e is a cross-section of the carbon resist of FIG. 2b. -Giant. 2f is a cross-section of the carbon resist of FIG. 2c. Giant. 3a is a cross-section of the carbon resist in the lightest part, which is obtained by exposure by inserting a diffusion sheet between an autotypic positive and a carbon resist. Giant. Fig. 3 is a cross-section of a carbon resist as Fig. 3a in the area of 50% density; Fig. 3c is also a cross-section of a carbon resist as Fig. 3a showing a shaded area. Giant. 4a is a cross-sectional view of the illuminated portion showing the state after transferring, developing and etching to a copper gravure cylinder. Giant. 4b is a cross-section as in FIG. 4-a in the region of 50% density and FIG. 4c is a cross-section as in FIG. 4a in the shading area.

Giant. Figures 5 to 8 are diagrams or schematic views of an alternative method according to item 2 of the present invention, wherein Figure 5 is a block diagram for preparing an intaglio autotypic positive; Fig. 6 is an enlarged cross-section of the layers of material in the preparation of an gravure autotypic positive; Fig. 7 is a cross-section of the layers of material in the second step of the method;

Giant. Figures 9 to 15 are schematic drawings showing an alternative method according to the third aspect of the invention, wherein Figure 9 is an enlarged plan view of the most illuminated portion of an autotypic positive showing the state of the network block points; Fig. 11 is an enlarged cross-sectional view of the shaded portion of the autotypic positive; Fig. 12 is an enlarged cross-section showing the first step of the method; Fig. 13 is an enlarged cross-section showing another variation of Fig. 12; and FIG. 15 is an enlarged plan view of the shaded portion formed in the second step.

Giant. 16 to 19 are schematic diagrams showing another alternative method according to the fourth aspect of the invention, wherein Fig. 16 is an enlarged cross-sectional view of layers of materials for preparing positives of approximately continuous coloration; step of the fourth method. Giant. 18 is an enlarged cross-section showing the state of contact printing in a second step, and FIG. 19 is also an enlarged cross-section showing the state of contact printing in a third step according to the method of the invention.

Giant. Figures 20 and 21 are cross-sections of layers of respective materials in light exposure steps through diffuser films simultaneously preparing negatives. Giant. 22 to 24 are plan views of an intaglio network, an autotypic positive, and a carbon resist, provided with a registration edge for use in the pin system. Giant. 25 is a perspective view of a pin plate. Giant. Figures 26-28 are cross-sectional views of the printing steps of the invention using a pin system, wherein Fig. 26 shows printing of an intaglio network, Fig. 27 shows printing of an autotypic positive over a diffuser film, and Fig. 28 shows a contact printing of an autotypic positive.

The basic method of the first aspect of the invention is described below. In the first step of the method, the photosensitive carbon resist is illuminated over the intaglio network by a light source, the intaglio network having the desired density of a transparent lattice (see FIG. 1). As well as the carbon resist, other photosensitive materials can be used. The sensitization of the carbon resist is accomplished by immersing the carbon resist in a solution of potassium dichromate and then drying it. In addition, an intaglio screen having transparent lines and used in a conventional method can be used in the invention. The number of meshes of the gravure screen may be 150, 175, 200, 250 or 300 meshes per 2.54 cm or the like.

This intaglio mesh and carbon resist is placed in a vacuum frame and illuminated by a light source. The light source for this exposure may be an arc lamp, a mercury lamp, a xenon lamp, a halogen lamp, and the like.

In the case of using an autotypic positive, where š points of the network block in the center of 240000

dyeing to the shaded parts are. Continuous, such as a planographic autotag positive or embossed autotypic positive, the continuous portion is provided with an intaglio grid line image described by the intaglio screen exposure in the first step to prevent ink from flowing in the range of medium color to the shaded portion. If the grid block points in the shaded section are isolated from each other as an gravure autotypic positive, this gravure grid exposure step may be omitted.

Then, in the second step, this carbon resist, which was illuminated through the intaglio network in the first step, is further exposed using an autotypic positive (see Fig. 2).

The autotypic positive used in this step may be any of those for gravure, planographic or embossing, and the exposure may be performed in a similar manner to the first step.

This exposure of the autotypic positive in the second step is carried out to produce polylines of the network block whose respective dimensions vary.

In the next third step, a diffuser film is placed between the autotypic positive and the carbon resist exposed in the previous steps, and the autotypic positive is printed over the film (see FIG. 3).

The disclosed diffusion film creates a space between the autotypic positive and the carbon resist according to the thickness of the diffusion film and also causes the diffusion effect. As an example of a material having a scattering effect, high-quality matt film, opal glass, super-fine ice glass and the like can be mentioned, and exposure can be performed as in the preceding first and second steps.

In this third-stage scattering exposure, the light rays passing through portions other than the autotypic patch network points are scattered by the scattering effect of the scattering film in the space between the autotypic positive and the carbon resist, and the carbon resist below the grid block in accordance with the grid block point sizes and makes moiré formation imperceptible. In this step, the obtained density curve can be controlled by controlling the amount of scattering depending on the type and thickness of the scattering film and the amount of illumination. It can be noted, incidentally, that the three steps can be performed in any order.

Then, in a fourth step, the exposed carbon resist 1 formed by the preceding steps is transferred to the surface of the gravure cylinder 2 and then etched to form the gravure plate (see FIG. 4).

The fourth step of this method can be performed in a conventional manner, wherein the exposed carbon resist 1 is attached to the surface of the prepared gravure cylinder 2 in its predetermined position with a suitable supply of water. After this transfer of the carbon resist, the uncured gel is washed by immersion in hot water to give an image and then dried. During this process, the grid block color dots of the autotypic positive are formed.

In the next step, the surface of the roll 2 is etched over the remaining gelatin film using an etching solution containing ferric chloride and, after etching to the desired depth, the etched surface can, if necessary, be chromed to increase printing durability.

By the method of the first aspect of the invention, an intaglio plate having a mesh block points of different dimensions and depths can be formed using an autotypic positive without the need for a continuous color positive, whereby the photographic step and printing step can be simplified and facilitated in a conventional double positive method. In addition, fine gravure prints can be produced with good reproducibility and excellent density gradients since color is transmitted by combining the size and depth of each color cell. In addition, the gradient is little affected by the etching variation, so that reproducibility becomes stable and the etching control becomes easy.

In addition, autotypic positives not only for gravure printing but also for planographic printing and embossing can be used in the method of the invention. Thus, for example, if a planographic autotypic positive that is made directly from the original is used, the conventional network gravure printing method in which the autotypic positive is formed using a dual positive method can be greatly simplified, which facilitates the process and reduces cost. In addition, the range and gradation of the autotypic positive for planographic printing is greater than the autotypic positive for gravure printing, so that excellent and stable printing plates and prints can be produced using the autotypic positive planographic positive.

The alternative method of the second aspect of the present invention is described in detail below, wherein as a first step an autotypic positive with transparent lines is prepared. The following two methods are given as examples for the preparation of such autotypic positives.

In the first example shown in Fig. 5, a double exposure is performed using a reproducing photographic apparatus or copier by exposing an autotypic negative of a photosensitive film through a positive continuous color film 3 'and then' exposed by contact over an intaglio network. It is then invoked to obtain an autotypic negative 6 with black lines. This is then reversed in contact to an unexposed film to create an autotypic positive with transparent lines. In another example, as shown in Fig. 6, the autotypic negative 10 is given in layers with a black line network 8, the unexposed film 12 is unfolded beneath these layers and exposure is performed to obtain an autotypic positive with transparent lines.

In preparing this autotypic positive 7 with transparent lines, it is necessary to arrange a typical negative film 6 or 10 and the gravure grid lines at an angle to minimize moiré formation by intersecting the autotype negative mesh block points with the gravure grid lines. For example, if an autotypic positive with 175 lines per 2.54 cm and a mesh with 250 lines per 2.54 cm is used, the tangent angle may be 80c to 85 ° in the case of a yellow plate.

As gravure webs, webs of 150, 175, 200, 250 and 300 lines per 2.54 cm can be used conventionally in the method of the invention. When using them, the angular deviation must be determined by the grid number to prevent moiré formation.

In a second step, the automatic positive 7 obtained according to the described first step is contacted to the photosensitive carbon resist 15 and is illuminated with a light source (see Fig. 7).

Exposure with an autotypic positive · 7 · in the second step is performed to create mesh block points having mesh lines, and latent images of mesh block points are formed from the intermediate color area to the shaded areas, which are separated by mesh lines.

In the next third step, as shown in Fig. 8, a diffusion film is inserted between the autotypic positive 7 and the carbon resist 15 of the second step and the autotypic positive is reprinted over the diffusion film 14.

During this dispersion exposure ^; In the third step, light passing through areas other than the autotypic positive network grid points is scattered in the small space between the autotypic positive 7 and the carbon resist 15 as well as the scattering effect of the scattering foil 14 so that an approximately continuous positive color effect and degree Cure of the carbon resist 15 varies according to the density of the autotypic positive. As a result, the thickness of the carbon resist 15 after developing is different and thus provides for a different dots depth of the network printing plate and hence the color cell depths on the printing plate during the process of forming the network gravure printing plate by etching the copper cylinder over the carbon resist 15 film.

By this gradation effect of exposure through the rooftop foil 14, moiré formation can be imparted by the unobservable simultaneous variation of the depths of the points of the network block.

The gradation of the reproduced color can be controlled by controlling the length and intensity of the exposure and selecting the type, thickness and dispersibility of the diffuser sheet 14.

In the next, fourth step, the carbon resist 15, which was illuminated in the second and third steps, is transferred to the surface of the gravure cylinder and etched to form the gravure printing plate.

According to an alternative method according to the second aspect of the invention, there is no need for a continuous coloring positive as used in the prior art carbon resist printing method, and the size and depth of the mesh block points can only be controlled using an autotypic positive with transparent grid. In addition, the conventional photographic step and exposure step can be simplified in a double positive method. In addition, the density is determined by the combination of the dimensions and depths of the color cells, so that the density gradation range expands and produces excellent printing and reproduced coloration becomes very stable without substantial fluctuation of the etching effect in the etching step, thereby facilitating control of the etching stage.

In addition, according to this method of the invention, countermeasures can be taken against the formation of a moire in the step of preparing an autotypic positive 7 having a transparent lattice so that adjusting the inclination of the autotypic network in the production of a gravure plate becomes almost unnecessary. At the same time, the efficiency of the printing work, previously accompanied by the angle adjustment, can be increased, and poor network contact and network blur can easily be prevented by the impact of airborne dust on the carbon resist, so that overall work efficiency can be greatly improved.

Since the network printing points of the gravure nets are arranged in a regular manner, and the network printing points of the autotypic positives are also arranged regularly, when using both the gravure network and the autotypic positivity as in the method of the invention will in some cases cause moiré between gravure grid and autotypic positive. Therefore, when printing both an intaglio network and an autotypic positive on a photosensitive material such as intaglio paper, it is desirable to minimize the appearance of moiré.

To minimize moiré formation, · the relative position of the gravure grid and the autotypic positive is regulated so as to minimize moiré printing, and a pin system can be used to avoid deviations from optimal positioning. If a pin system is used, a deviation of the gravure grid position and the autotypic positivity from the minimum moiré position can be avoided and, moreover, if the autotypic positives are printed on photosensitive material twice, the registration operation can be done quite easily.

An example of a pin system below.

As shown in Figs. 22, 23, the intaglio network 20, the autotypic and carbon resist 21 all have a registration edge 60 having pin holes 61. The size of the holes 61 is determined to exactly match the size of the pins 62 that are attached to the pin plate 65, described and 24, are positive 40 as shown in FIG. The distance between the holes for the pins 61 is the same as the distance between the pins 62 on the pin plate 65.

As shown in FIG. 26, when printing is performed, the pin plate 65 is placed on the glass plate 63 of the printing frame and the slots 62 are inserted into the pin holes 61 formed in the registration edges 60 and thereby the gravure net 20 and the carbon resist 21 and then the materials are covered with a rubber foil 64 and bonded to vacuum. Thereafter, light rays are applied from the side of the glass plate 63.

The autotypic positive can be printed likewise as shown in Fig. 27, the autotypic positive 40 and the carbon resist 21 are assembled so that the pins 62 are inserted into the pin holes 61 formed in the registration edges 60 and covered with a rubbery The materials under the rubber film 64 are brought into intimate contact by vacuum and the light rays are fed from the side of the glass plate 63.

If a scattering film 24 is further used, the film 24 may be sandwiched between the autotypic positive 40 and the carbon resist 21 as shown in FIG. 28.

If a pin system is used according to the described procedure, the coverage of the gravure grid and the autotypic positive can be achieved quite easily.

In addition, when the diffuser film 24 is pulled out and the autotypic positive 40 is printed over the diffuser film 24 as shown in Fig. 28, this procedure can be easily accomplished when compared to the inverse procedure.

If the minimization of moiré formation cannot be achieved by controlling the relative position of the gravure network and the autotypic positive, moiré formation can be prevented in the following alternative manner.

Next, an alternative method according to the third aspect of the invention is explained. In this way, which can be used for any planographic, embossed or gravure printing, moiré formation can be prevented.

As previously explained, the coloring of the original is reproduced in traditional intaglio printing by varying the depths of the color cells, whereas in the etching step, after transferring the carbon resist, several types of etching baths must be used separately to form the color cells. In this case, it is very difficult to form color cells with an exact order of one micrometer in depth using different types of etching baths, considering the thickness of the protector. For example, if the brightest part of the original is to be etched to 2 ym and using a gravure grid of 175 lines per 2.54 cm and a line ratio of 1: 2.5, the color volume in the color cell will be (104 ym) ² x 2 μπι = 2 χ 104 μ 1 _Ώ 3 = = 2 χ 10 · 5 mm ³ .

If we cause a 0.5 μΐη depth error to occur, the color density reproducibility will be 75% of the intended value. In the conventional method, the yield ratio is poor because it is difficult to etch with an accuracy of the order of 0.5 · (Um. To eliminate these disadvantages, however, we have a gravure mesh method where gradation is only due to changes *. is not enough to represent the gradation of the original, as is well known in the art.

In contrast to this, when using a combination of different mesh block sizes and depths, the etching depth error does not cause such a large variation in the color of the printing, since variations in mesh block sizes also cause this effect, thereby achieving stable reproduction color. For example, a color cell having the same color content as a conventional 2 μΐη deep color cell, with 175 lines and a 1: 2.5 line ratio, has a depth of 5 µs when the mesh block point is 20%, a deviation of 0.5 µm results in only 10% change in total cell volume. Hence, when compared to the conventional method, this method reduces the difficulty of the flying step and, moreover, it will be apparent that control of the printing operation can be facilitated.

The network gravure printing method, using variations in color cell sizes and depths, uses two gravure positives, an autotypic positive and a continuous color positive, and the method is called the two positives method, as previously said. In this process, the carbon resist is exposed to a light source using an autotypic positive to create mesh block points, and further exposed using a continuous color positive to create variations in the mesh block polka dots depth, and then • the printing plate is obtained sequentially · transferring, developing and etching and it is necessary to place the autotypic positive and the continuous color positive in a position where they perfectly coincide. This requires technical skill because of the difficulty and complexity of the process described, various materials are used, so it is economically disadvantageous and the method is not generally accepted.

Taking these facts into consideration, the method of the first aspect of the invention has been designed to eliminate the difficulties described. In this method, as a first step, the photosensitive carbon resist is illuminated by a light source over an intaglio network having the desired number of transparent lattices, then in a second step the carbon resist is exposed again via an autotypic positive a. in a third step, a diffusion film is inserted between the autotypic positive and the carbon resist used in the second step, and the autotypic positive is reprinted over the diffusion film. Such an autotypic positive fulfills the same function that the positive zabar248004 performed

14 vení. Following these steps, the same steps are to be carried out as in the conventional method to obtain an intaglio printing plate having ink bursts of the desired size and depth. Meanwhile, it is well known that moiré formation can be prevented or minimized by varying the angles of the respective lines of color plates in planogrophic or embossed printing.

In the described process, however, the autotypic positive (including any planographic, embossed, or gravure) is combined with an intaglio network having the same or different mesh lines, so that there is a tendency to form moiré, which has an undesirable effect on the printed material.

In order to prevent moiré formation, it has been shown that the following alternative method according to the third aspect of the invention is very effective.

The alternative method of the third aspect of the invention is explained below.

The autotypic positive for planographic or embossed printing has a generally checked pattern, as shown in Figures 9, 10 and 11. If the point area is less than 50 ° / o, each point of the network block exists separately and if the point area is greater than 50 ° / o, points are connected to adjacent points. That is, the mesh block points 16 in the most illuminated portion, 10% of the dot area, are shown to an enlarged scale in Fig. 9, the mesh block points 17 in the middle hue portion, 50% of the polka dot area, are shown in Fig. 10, and points 18 in the shaded parts having 80% point areas as shown in Fig. 11.

In gravure printing, the printing operation is performed at a high speed and the viscosity of the printing ink is very low, so that the entire surface of the printing plate from the lighted part to the shaded part must be covered with a large number of independent color cells.

When an autotypic positive for embossing or planographic gravure printing is used, portions of greater than 50% density, having larger mesh block points, should be provided with color cell walls, but the brightest portion already has independent mesh block points, so there is no need to secure the walls of color cells by intaglio network. In addition, if the most illuminated portion is provided with such color cell walls, this impedes color reproduction. Accordingly, the intaglio network must be effected efficiently on the parts from the medium color to the shaded parts.

As it has been shown, if the luminous part is provided with walls using an intaglio network, this causes both moiré formation and the described deficiencies in the color density. In order to avoid the formation of moiré, an irregularly dotted or dashed network may be used instead of the usual gravure network.

For example, if an intaglio network of sand-grained is used, the loss in color reproduction is large and the printing surface is coarse, since it suffers from a sand-grained sample which is not desirable for printing. Hence the sand-grained gravure network is used for special purposes only.

In addition, if a 5- to 10% autotypic dot pattern, made using an autotypic mesh having fine transparent lines, such as 300 lines or 600 lines per 2.54 cm, is used instead of an intaglio screen, the walls for carrying the ink stripping knife are formed. and the formation of moiré and creep can almost be prevented, but the volume of the color cell in the shaded portion is greatly reduced, so that we cannot expect the high-density execution characteristic of gravure printing.

In addition, it has been found that using a network of parallel lines instead of a gravure network of intersecting lines does not give any desired result.

In general, moiré forms with gravure printing in the most illuminated area up to the medium hue. This depends on the fact that the wall thicknesses in the shaded part are greatly reduced by lateral etching during the etching operation and the ink, due to its low viscosity, intersects and permeates capillaryly into the paper fibers. In addition, the colored dots are smeared to some extent by printing pressure and bonded to form a continuous color film. Therefore, the regularity of the orientation of the network block points is lost. From here it will hardly appear in the medium-colored area until the moiré shading area.

Meanwhile, in the area of greatest illumination, the side etching in the etching step is very small and the color volume in (each color cell is very small compared to the shaded area, so that even the color cell sizes are somewhat enlarged, the regularity of dot shapes and orientation can be maintained.

The first step of the method according to the third aspect of the invention is the network exposure process. For example, as shown in FIG. 12, a continuous color negative 19 having the same dimensions as a planographic, embossed or gravure autotypic positive and the gravure network 20 are laid in layers on the photosensitive carbon resist 21 and then exposed to the light source. The arrows 22 indicate the direction of the exposure light in the illustration.

In this case, the optical density of the initially most illuminated region a (FIG. 12) in the negative of the continuous color 19 is very high, so that during exposure the light barely passes, i.e. the intaglio network 20 is not printed on the carbon resist 21.

Meanwhile, the optical density of the continuous shade 19 in the initially shaded portion b is very low, so that the intaglio screen 20 is not affected by the continuous shade 19, and the grid lines are imprinted on the carbon resist 21. whose intentions-

The rye is proportional to the negative density of the continuous color 19, i.e. the walls hardly form on the side of the most illuminated part a, while the walls form on the shaded side b. As a result, moiré formation can be prevented in all parts from the brightest to the shaded part and, in addition, a gravure grid is provided in the areas from the intermediate color c to the shaded b.

This alternative method according to the third aspect of the invention can also be performed as follows. An autotypic negative 23 (see FIG. 13) is used in place of the described continuous color negative 19 (see FIG. 13) and a diffuser film 24 is inserted below the autotypic negative 23. they are applied to the intaglio screen 20 similar to the previous stage, and the layers are contacted with the carbon resist 21 to be exposed to the light source. The arrows 22 also indicate the direction of the light rays.

As shown, the diffuser film 24 as a spacer has the function of separating the autotypic negative 23 and the gravure grid 20 as well as scattering the light for exposure. Hence, the autotypic negative 23 acts as a continuous color negative so that moiré formation caused by the autotypic negative 23 and the gravure screen 20 can be prevented in a manner similar to the method of item 2.

In the second step of this method, the carbon resist 21, which was printed using the gravure printing network in the first step, is further exposed to the light source by contacting with an autotypic positive that is used for planographic, embossed or gravure printing.

How . 14, while in the most illuminated part and the walls are scarcely formed by the intaglio network, only a few small color cells 25 are dispersed there, in the shaded portion b, as shown in also enlarged FIG. 15, large color cells 27 are defined by the walls 26 and small points of the network block are printed

28.

In the next third step, a diffusion film is inserted as an intermediate between the autotypic positive and the carbon resist 21 used in the second step, and the autotypic positive is re-exposed through the diffusion film.

When this scattering exposure is performed in the third step, light passing elsewhere than the network block points of the autotypic positive arrives at the network block points on the carbon resist according to the size of the respective network block points and thus the autotypic positive works in a gradation effect approximately as a continuous color. Thus, the rate of cure of the carbon resist varies according to the polka dot density of the network block of the positive, and hence the depth of the points of the network block changes. As a result, during the etching process, an intaglio printing plate with color cells of different depths is formed.

In a subsequent fourth step, the carbon resist exposed to light in the first, second and third steps is transferred to the surface of the gravure cylinder and is then developed and then the gravure cylinder is etched to achieve the gravure printing plate. This etching step is the same as the conventional etching process using a carbon resist.

It is preferred that the negatives obtained as intermediates in the conventional process can be directly used as continuous color negatives or autotypic negatives for the method of the third aspect of the invention, so that there is no cost disadvantage.

In addition, the continuous color negative or the autotypic negative used in the method of the third aspect of the invention can be produced by the following procedure. If we print an autotypic positive for a carbon resist by layering - an autotypic positive film on the carbon resist, the photosensitive negative acquisition material is simultaneously printed - with the autotypic positive - and - then the photosensitive negative material is induced to produce the negative. In this case, as shown in FIG. 20, the diffuser film 24, photosensitive — the negative material 41 and the autotypic positive 40 in layers, is placed on the carbon resist 21 in that order — and then illuminated by the autotypic positive 40. In another 21, the photosensitive material 41, the diffuser film 24, and the autotypic positive 40 may be placed respectively on the carbon resist 21 and then illuminated by the autotypic positive 40. In these two described procedures, it is necessary for the photosensitive material to be photosensitive. material 41 for creating - negative transparent or translucent. Examples of such photosensitive materials 41 are vesicular films, negative-type chromarin films and silver salt-type films on transparent substrates.

After the materials, as shown in Figs. 20 or 21, are illuminated by the autotypic positive 40, the photosensitive material 41 is developed to obtain the negative. In the case of FIG. 20, since the photosensitive material 41 for the negative is there with the autotypic positive 40, the obtained negative is an autotypic negative, while in the case of FIG. 21 the network block points of the autotypic positive 40 disperse by the diffusion foil 24 and obtain a continuous color negative, since a diffuser film 24 is interposed between the autotypic positive 40 and the photosensitive negative material 41 in both cases. FIGS. 20 and 21, there is a diffuser film 24 between the carbon resist 21 and the autotypic positive 40, so that the incrementally printed on carbon resist 21.

A continuous color negative or autotypic negative, achieved by the described steps of 24004 degrees, is used to print an intaglio network 20 onto a carbon resst 21, as shown in Figures 12 or 13.

In accordance with the method of the third aspect of the invention, the most illuminated portion is reproduced very stably and the color quality such as planographic printing or embossing can be reproduced without any defect. Furthermore, in the region of the intermediate color up to the shaded region, the walls of the color cells are formed to support the color wiper blade so that gravure printing with a very high color density can be performed, and moiré formation can be successfully prevented in the most illuminated part.

In addition, in addition to the intaglio network, masks other than the autotypic negatives described or autotypic positives may be used. For example, it is an economical method for obtaining an autotypic negative image having reversibility with light, magnesium, or pressure from an autotypic positive.

In addition, by modifying the first and second steps of the method of the third aspect of the invention, an autotypic positive having a transparent lattice applicable to the alternative method of the third aspect of the invention can be made. That is, in this method, a photographic film is used as a photosensitive material in place of the carbon resist or something similar to produce an autotypic positive having a transparent lattice only in the medium to shaded areas.

More specifically, the first step of this method is exposure through the trellis. As already explained, there are two methods for this step, i.e., the method using the continuous color negative 19 of Figure 12 and the method using the autotypic negative 23 and the diffuser film 24 of Figure 13.

The autotypic positive used for the second aspect of the invention may be any of the methods described, but it should be noted that in the first step of the method according to the third aspect of the invention, a photographic film is used instead of the carbon resist 21. During the first step, the transparent lattice is printed on the photographic film only in portions of medium tint to shaded. In these two steps, the order of exposures through transparent lattice and autotypic positives is not fixed. By these methods, in the areas of medium color to shadow through transparent lattice, the lattice is printed and exposure is performed through an autotypic positive so that by developing a photographic film, an autotypic negative having a black lattice can be obtained.

When an autotypic black mesh screen negative is contacted on a photographic film and then induced, an autotypic positive can be obtained having a transparent lattice in areas of medium to darkness and having no lattice in the brightest area. The autotypic positive thus obtained having a transparent lattice in the medium to shadow areas can be used as an autotypic positive for the method of the second aspect of the invention.

If a rotogravure printing plate is produced using a method of the second aspect of the invention using an intaglio positive lattice in the mid-to-shaded areas of the gravure printing area and the printing plate so formed, no moiré is formed like those printed using intaglio printing printing plates produced by the method of the third aspect of the invention.

According to the method of the fourth aspect of the invention, an intaglio network having the desired density of a transparent lattice is first contacted onto a photosensitive carbon resist to form the color cell walls in the medium to shadow areas, then the carbon resist is further illuminated via planographic positive. network block points. Further, the carbon resist is re-illuminated via a continuous color positive or approximately continuous color positive to mediate variations in mesh block point depths. Finally, the treated carbon resist is transferred to a conventional gravure cylinder and then the induction and etching process takes place. This creates an intaglio printing plate, where the gradation according to the original is performed by variations in the dimensions and depths of the points of the network printing block.

In the first step of this method, a contact impression of the intaglio network D having the desired number of transparent lines is performed on the photosensitive carbon resist E (see FIG. 17).

The purpose of this exposure using intaglio network D is to create the walls of the color cells in the medium to shaded areas to prevent ink from creeping.

In the following second step, the carbon resist E, which is exposed using the intaglio network in the first step, is again contacted with an autotypic positive A for planographic or embossed printing (see Figure 18). Using the autotypic positive A, the coloring of the original is represented by variations of the mesh block points and the exposure can be performed similarly to the previous first step. That is, the printing of the autotypic positive in the second step is carried out to form the points of the network block.

In the next third step, the carbon resist E, which was printed with the autotypic positive in the second step, is illuminated using a continuous color positive V or an approximately continuous color positive C (see Fig. 19).

In this third step, each point of the network block is different. both in depth and in magnitude of exposures using a continuous color positive or approximately continuous color positive to form an intaglio printing plate having mesh block points of different depths and sizes.

Conventional positive can be used as a continuous color B positive, and as an approximately continuous color positive C, an autotypic positive for planographic printing is first prepared and then graded.

There are two methods for preparing an approximately continuous color positive.

The first method is that the planographic autotypic positive A is contacted on the photosensitive film to form an autotypic negative 29, and the autotypic negative 29 is then printed on an additional photosensitive film 30, wherein a diffuser film 31 is inserted between them, as shown in FIG. 16, and so the points of the mesh block are graduated by the separating effect of the diffusion film 31 and produce a positive continuous color C.

In the second method, an autotypic negative is formed by contact printing a planographic autotypic positive A on a photosensitive film and the thus obtained autotypic negative is unfocused photographed using a reproducing photographic apparatus, thus creating a positive continuous approximately color T in which the grid block points are scaled to hardly condition.

Both positives of approximately continuous staining obtained by the methods described can be used similarly.

In addition, the planographic autotypic positive A prepared from the negative color B negative can be used for contact printing in the third step. In this case, the following two methods can be used.

In one of these, the method is prepared by the conventional method of continuous staining and forms a planographic autotypic positive A using a copier and a suitable lattice.

In another method, a Planographic Autotypic Positive A is prepared by autotyping a photograph using a conventional reproduction photo apparatus.

In the fourth step, the carbon resist to be processed in the first, second and third steps is transferred to the surface of the gravure cylinder and then developed and etched to form the gravure printing plate of the invention.

The fourth step may be carried out in accordance with a conventional method.

Using the method of the fourth aspect of the invention, after printing an intaglio screen, the gradation of the original is represented by variations in the size of the grid block dots created by printing an autotypic positive, a continuous color positive of the same size or an approximately continuous color positive. in the size of the nodes of the network block so that fine gravure printing with a wide gradation can be performed.

Further, in this alternative method, the planographic or redissected autotypic positive A, the continuous color positive B, and the approximately continuous color positive C for the exposure to the carbon resist are prepared separately, according to which these positives can always be retouched without difficulty. Therefore, the retouched positives can be used to expose the carbon resist E and thus the gradation of the original can be fully reproduced in gravure prints.

In addition to the use of ordinary autotypic positives for gravure printing, planographic and embossing as described, autotypic positives may also be used where the gradation of the original is represented by irregularly shaped and spaced dots.

If it has an autotypic positive having irregularly shaped and spaced dots like that made using a grainy screen, the occurrence of moiré between the autotypic positive and the intaglio network having transparent lattice or between the color separating plates on multicolored printing can be prevented.

Claims (11)

CLAIMS 1. A method of making a photographic path using an autotypic positive, characterized in that it comprises illuminating the photosensitive material over an intaglio network having the desired number of transparent lattices, illuminating the photosensitive material through an autotypic positive, illuminating the photosensitive material after inserting the diffuser film. between the autotypic positive and photosensitive material and the subsequent production of the printing plate, the order of exposure steps being arbitrary. 2. The method of claim 1, wherein the autotypic positive comprises transparent grating intaglio meshes, and the method comprises illuminating the photosensitive material through a gravure grid having the desired number of transparent lattices, illuminating the photosensitive material through the autotypic positive. the photosensitive material after inserting the scattering film between the autotypic positive and the photosensitive material and the subsequent production. the order of exposure steps is arbitrary. , 3. The method of claim 1, further comprising illuminating the photosensitive material by placing an intaglio network thereon and then laying on it layers of autotypic negative and diffuser film illuminating the photosensitive material over an autotypic positive, illuminating the photosensitive material after inserting the diffuser film. between the autophotic positive and photosensitive material and the subsequent production of the printing plate, the order of exposure steps being arbitrary. 4. The method according to claim 1, wherein the used -autotypic positive-does not comprise transparent -gravure intaglio nets, and the method of -lighting-photosensitive material through a gravure-mesh having a transparent lattice, -lighting photosensitive material through -autotypic positive , illuminating the photosensitive material over a positive continuous color positive and subsequently producing the printing plate, wherein the order of exposure steps is arbitrary. 5. The method of claim 2, wherein the autotypic positive uses transparent lattice only in areas from medium to shaded. 6. The method of claim 3, wherein the layers of the autotypic negative and the diffusion sheet are replaced by a continuous color negative. 7. The method of claim 4, wherein the approximately continuous color positive is replaced by the continuous color positive. 8. The method of claim 1, wherein the photosensitive material is a carbon resist and the subsequent steps of manufacturing the plate consist of transferring the carbon resist to the surface of the gravure cylinder, inducing the carbon resist and etching the gravure cylinder over the carbon resist. 9. The method of items 1 to 4, wherein the photosensitive material is an intaglio protective film, and the subsequent steps to produce the plate consist of inducing the intaglio protective film with developing agents, transferring the intaglio protective film to the intaglio cylinder, recreating the intaglio film with hot. water-and etching - gravure cylinder over gravure protective film. 10. The method of claim 1, wherein the photosensitive material is a photosensitive resin layer formed on the gravure cylinder and the following steps for producing the plate include the step of developing the photosensitive resin layer on the gravure cylinder. 11. A method according to any one of Claims 1 to 5, characterized in that the autotypic positive, representing the original, with irregularly shaped and spaced dots, is used as the autotypic positive.