DE2229491C3 - Process for producing images - Google Patents

Description

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The invention relates to a method of manufacture of images in which a recording material consists of a layer support and a light-sensitive Layer exposed imagewise and, if necessary, the unexposed parts of the image washed out with a solvent or transferred to an image receiving material.

There are already various methods of manufacture of images known in which by imagewise exposure of a layer support and a Photosensitive layer existing recording material images are generated, if desired can be transferred to an image receiving material. The light-sensitive used In their light-sensitive layer, recording materials contain compounds which, upon exposure to them converted by light into dyes or colorants. These connections are common around diazo compounds, which transform into colored azo compounds under the action of light, or around Leuco dyes, which convert to the corresponding dyes under the action of light, or in order to be oxidized by compounds or light-sensitive redox systems that act on the address visual exposure and deliver a corresponding colored image (compare e.g. the German Interpretation documents 12 75 863 and 10 58 845).

However, the above-described known methods have the disadvantage that to produce the Colorant or dye, two or more compounds must be used after one complicated mechanism so that it is difficult to form the desired image to control. Frequently, such compounds also have the disadvantage that they are not stable in storage and are poisonous. Since in the known processes in addition to the color-forming component at least one further component must be used, it is difficult to obtain a uniformly thick photosensitive Create a layer in which the various components are evenly distributed. It is therefore also extremely difficult to obtain good resolving power with such a photographic material.

The object of the invention is therefore to provide a method for producing images in which a Recording material is used, the photosensitive layer of which consists of a uniform photosensitive organic compound exists.

This object is achieved according to the invention in that, in a method of the type described above a recording material having a photosensitive layer made of an organic sensitizing dye is used.

Using the process of the present invention, which is easy to control, one gets clear, very persistent images with a high resolution.

According to a preferred embodiment of the process of the invention, the sensitizing dye used is a diphenylmethane, triphenylmethane, xanthene, Th ^; azine or acridine dye. A particularly advantageous diphenylmethane dye is auramine, a particularly advantageous triphenylmethane dye is malachite green, brilliant green, crystal violet, rosaniline, Victoria blue or methyl violet, a particularly advantageous xanthene dye is rhodamine, erythrosine, pyronine G or eosin B, a particularly advantageous thiazine dye is methylene blue is acridine orange.

According to this preferred embodiment, particularly clear color images are obtained.

According to a further preferred embodiment of the invention, a recording material is used with a photosensitive layer made of the sensitizing dye, which is preferably 0.1 to 10 μm thick. So you get Images with a particularly high resolution.

According to a further preferred embodiment of the invention, the unexposed parts of the image are washed with a weakly polar solvent or paper is used as the image receiving material, a Cellulose or plastic film or a sheet of glass, metal or plastic. This can be used on a produce the desired images in a particularly simple and easily reproducible manner.

The practical implementation of the method of the invention is explained in more detail below.

First, according to the invention, there is one composed only of an organic sensitizing dye Layer applied to a carrier using a wide variety of methods. For example, the light

sensitive layer by vacuum evaporation on the Layer carrier are applied. The support can also be applied by a conventional method coating, for example by brushing on, Pouring on or coating with a roller a solution that dissolves the organic sensitizing dye has been prepared in a solvent, which is then followed at the appropriate time removed the solvent.

For the purposes of the present invention, any carrier known per se to the person skilled in the art can be used use. A glass plate, a metal plate or foil, paper, for example, are recommended as a carrier or processed paper, wood or a film ans a high molecular compound or a corresponding one Layer that is transparent, translucent, or opaque are.

When using a photosensitive layer made of an organic sensitizing dye in accordance with the present invention is applied to a layer support by vacuum vapor deposition or coating, it is advisable to to treat the surface beforehand in the usual way, for example washing and degreasing, e.g. B. with an alkaline, organic solvent or a chromic acid mixture.

Furthermore, an organic sensitizing dye can be used in the present invention be used, which has the property that the color develops when exposed, disappears or fades and that the exposed part and the unexposed part in the solvent are soluble to different degrees, for example a basic diphenylmethane dye such as auramine. a basic one "i'riphenylmethane dyes such as malachite green, brilliant green, crystal violet, rosaniline, victoria blue and Methyl violet, a basic xanthene dye, such as rhodamine, erythrosine, pyronine G and eosin B. basic thiazine dye such as methylene blue and a basic acridine dye. like acridine orange.

The sensitizing dye used in the invention is not in the leuco form, but in a color developing state. If it is applied by vapor deposition in a vacuum, then becomes the color of the basic triphenylmethane dye or the basic thiazine dye so pale that at Exposure to a light absorbed by the dye the color density becomes much higher and a so-called color-developing image is created. Even if any of the other sensitizing dyes is applied by evaporation in vacuo, a residual color remains in the dye and if if it is exposed to a light absorbed by the dye, it is similarly decolored or bleached or a so-called decolorizing or bleached image is created.

For vacuum vapor deposition, the general rule is that the higher the vacuum, the higher the strength of the film applied by vacuum vapor deposition. However, it is usually convenient, reduce the vacuum to lO ^'4 Torr m. It is also desirable to keep the temperature of the evaporation source slightly above the melting point of the substance to be evaporated, that is, the organic sensitizing dye.

In addition, it is preferably used in the one according to the present invention Vacuum vapor deposition process is useful for producing a more compact coating, the vapor deposition rate keep pretty low.

In the coating method according to the invention can be used as a solvent for dissolving the organic sensitizing dye any or use a mixture of two or more known solvents, such as e.g. B. hydrocarbons, such as hexane, cyclohexane, benzene. Toluene or xylene, halogenated hydrocarbon solvents such as chloroform, Carbon tetrachloride, trichlorethylene, monochlorobenzene, ο-dichlorobenzene and trichlorobenzene, Alcohols, phenols and ethers such as methanol, ethanol, propyl alcohol. Butyl alcohol, phenol, dioxane, tetrahydrofuran, Ethylene glycol and propylene glycol. Acids or their esters, such as acetic acid, methyl acetate, ethyl acetate and butyl acetate, ketones such as acetone, methyl ethyl ketone and methyl isobutyl ketone, and other solvents, such as nitrobenzene, dimethylformamide. Dimethyl sulfoxide and water.

According to the invention, the concentration of the organic sensitizing dye is as mentioned above Solvents not particularly limited because, for example, the supernatant liquid of the solution prepared by dissolving can also be used. Preferably the concentration is but at about 1.0 to about 0.01 g / l.

Further, in the method of the present invention, the thickness of the layer is made of the organic sensitizing dye not limited, but preferably from about 0.1 to about 10 microns.

When according to the invention a layer of an organic seisibilizing dye on a support applied and then with a light absorbed by the dye in the layer, e.g. B. by a usual Contact exposure method or a projection exposure method by an optical system an original is exposed, then the color in the photosensitive layer in the exposed part is developed. discolored or bleached so that a visible image is created.

The light used can be ultra-violet light or visible light. One can also use infrared radiation and, for example, a mercury lamp, a xenon lamp, a tungsten lamp or use an infrared lamp.

After using the light that can be absorbed by the dye, the photosensitive layer from which the sensitizing dye has been exposed becomes a solvent on the exposed surface according to a known application process, for example by brushing on, spraying on, dipping, pouring on or roller coating, so that the photosensitive layer in the unexposed part is selectively is resolved and removed to form a permanent visible image. In addition, according to the Invention, the exposed surface after irradiation with the light absorbed by the dye with brought into contact with an image receiving material to which it can be transferred, and it becomes a Solvent onto the exposed surface by the usual coating process either from the side of the image receiving material or applied from the other side, so that the layer in the unexposed Part is dissolved by the solvent and at the same time a selective solvent transfer on the image receiving material to produce permanent visible images.

In the solvent treatment according to the invention, the solvent used depends on the one used sensitizing dye. However can

any solvent that has the property can be used. the layer in the unexposed part to solve selectively. A solvent that possesses this property can be selected from the number of listed solvents can be selected.

According to the invention, a solvent tends with high polarity in general for the simultaneous resolution of both the exposed and the unexposed part, while a solvent with weak polarity comparatively difficult the Film layer in the exposed part and the film layer in the unexposed part dissolve comparatively well. A not polar solvent tends to affect the film layer both in the exposed part and in the unexposed part dissolve.

Therefore, for the purpose of the present invention, it is desirable in the case of manufacture an image by exposing the film layer to light absorbed by the sensitizing dye, and subsequent treatment of the exposed surface as such, using a solvent as a solvent weak polarity to selectively dissolve and remove the film layer in the unexposed part Formation of a permanent visible image by the developed, discolored or bleached sensitizing dye to be used in the film layer in the exposed part on the support.

Furthermore, for the purposes of the invention, it is desirable that in the case of the manufacture of a Image by exposing the film layer to light absorbed by the sensitizing dye and then Carrying out a solvent transfer to another carrier material to which the Transfer of the exposed surface can be carried out using a solvent with weak polarity to dissolve the film layer in the unexposed part and to selectively transfer the film layer to the Carrier material! is used, after which a transfer can be carried out to produce a permanent visible image on the substrate, while, on the other hand, an image by the sensitizing dye in the unexposed part on the Support material on which the transfer can be carried out is formed.

For example, an acid such as acetic acid can be used as a solvent with a weak polarity, Boric acid. Oxalic acid or hydrogen peroxide / water, an aqueous solution of a salt such as ammonium chloride or ammonium nitrate, hydrocarbons such as toluene. Xylene, hexane or cyclohexane, halogenated hydrocarbons, such as trichlorethylene or esters such as ethyl acetate or butyl acetate.

For the purpose of the invention, as solvents for the solvent treatment, there can be two or use several mixed solvents to adjust the dissolution properties. Furthermore can you can only use one of these solvents with weak polarity, but also a solvent with Weak polarity and strong polarity or a non-polar solvent can be free to adjust the dissolution properties are mixed.

As an image receiving material to be transferred upon solvent treatment can, for example, paper or treated paper, a cellulose film, a glass plate is used. (15 a metal plate or foil, wood, or a film or layer made of a high molecular compound.

For the purposes of the invention it is for that Solvent treatment and transfer before / .u prefer that both the substrate and there The solvent can always penetrate the image receiving material or absorb the solvent.

The mechanism by which the film layer in the nijh irradiated part is selectively dissolved and removed by the solvent treatment is not yet known, however, it can be assumed that if the layer consists of the organic sensitization is irradiated with light or heat energy, the dye in the irradiated part in a more stable State passes over to the solvent, so that there is a difference in the solubility of the film layers with respect to the solvent between the irradiated part and the non-irradiated part.

If in the course of the process according to the invention a film layer made of an organic sensitizing dye on a support by a vacuum vapor deposition method or a coating method applied from a solution and then irradiated with light or heat energy through a template and then the irradiated surface is treated, for example with a solvent, then the film layer is in the non-irradiated part dissolved and removed, and when the film layer in the irradiated part on the Support is left so that each image is formed by the dye alone on the support and then the image surface with an image receiving material to which the transfer is to be carried out, is treated with a solvent or heat, the image on the substrate is affected by the Solvent or heat transferred to the image receiving material to which the transfer was carried out is intended to form a permanent visible image that has a very high resolution, wherein the formation of the image solely by the organic sensitizing dye on the image receiving material takes place to which the transfer can be made.

According to the present invention, there is provided a film layer of an organic sensitizing dye on a support applied by vacuum evaporation or by coating from a solution and then with light or Heat energy irradiated through a template. Then the irradiated surface after placing a Image-receiving material to be transferred with a solvent treated so that the film layer in the non-irradiated part by the solvent on the image receiving material is transmitted. The film layer in the irradiated part remains on the substrate, so that a permanent visible image with high resolution on the support and on the image receiving material forms. Furthermore, the support with the image receiving material lying thereon is coated with a Solvent or heat treated so that the image on the support by the solvent or the Heat is transferred to the image receiving material and a permanent, visible image with high resolution is created by the organic sensitizing dye forms solely on the image receiving material.

In the event that the image receiving material on which transfer is to be carried out, to the with the solvent-treated surface is placed so that an image is formed by solvent transfer, as mentioned above, is produced when the image already formed on the support is on top of the film layer the irradiated part is, it is desirable to have a strong

use polar solvent which tends to dissolve the film layer.

As such a solvent with strong polarity, one can use solvents such as methanol, ethanol, Use acetone or methyl ethyl ketone. In the case of making an image by heat transfer by placing the image receiving material to be transferred, as above mentioned, the heating temperature is different and depends on the kind of organic Dye, the support or the image receiving material, but it is preferably about 130 to 300 ° C.

As can be seen from the above explanations, in the method according to the invention, if only one A film layer of the organic sensitizing dye with a light absorbed by the dye is exposed, the color in the exposed part is immediately developed, decolored or bleached, so that an immediately visible image arises without performing any development.

When in the method of the invention a film layer of an organic sensitizing dye is passed through Vacuum evaporation or coating from a solution exposed to light to form an image and is then treated with a solvent, the film layer in the unexposed part is dissolved and removed or transferred by the solvent so that a permanent visible image on the support or Image receiving material is produced to which the transfer is to be made.

When a film of an organic sensitizing dye through in the method of the present invention Vacuum evaporation or coating from a solution as mentioned above, then that is the film formed on the substrate is a uniform film of the image receiving material, and if an image is made by using such a uniform film, the image shows high resolution and is clear, uniform and stable.

In the case of an image according to the invention by dissolving and removing or solvent transferring the film layer in the unexposed part by taking advantage of the difference in the solubility of the film layer the solvent is produced between the exposed part and the unexposed part, becomes the support or the image receiving material to which a transfer is to be made is self-exposed, whereby the contrast between the image part and the non-image part increases and the image quality noticeably increases is improved.

In addition, according to a further embodiment of the invention, by suitable selection of the organic dye a positive image from a negative image or a positive image from one positive image can be obtained, and in particular, in the case of an image being produced by a Solvent transfer has the advantage that a negative image and a positive image are formed at the same time can be, and in the case of dissolving and removing the film layer, there is an advantage that. if the organic dye is chosen accordingly and the film in the unexposed part is removed, a Negative-positive image can be achieved.

Since, according to the invention, a layer of only an organic sensitizing dye on only one Layer support is provided, the image generation is simplified, further components, for example a

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Binding agents, a substance for the formation of free radicals or an oxidizing agent are not required and thus, there are no unstable elements, and there is also an advantage that handling is very simplified.

When making an image by placing the image receiving material onto which the transfer is made is to be, on the surface treated with the solvent, the color image as a whole can be applied the image receiving material to which the transfer can be carried out are transferred and the The advantage of being able to produce both negative and positive images.

The method according to the invention is suitable for the most varied of covering materials and is precise Templates for letters, umbrellas and other intricate patterns. In particular, is a see-through Layer support, such as a glass plate on which a picture can be made, a very essential feature, for example as a color mask for integrated circuits.

The invention is illustrated in more detail by the following examples.

Example!

A photosensitive recording material having a photosensitive layer 0.26 micron thick was prepared by vacuum vapor deposition of malachite green hydrochloride on a glass plate about 0.5 mm thick. The glass plate used for this was well degreased and washed beforehand by immersing it in a chromic acid solution. When coating the tension of the vapor deposition source was raised at a vacuum of ⁴ Torr IO gradually to 2 volts. Then, the photosensitive material was brought into close contact with an original in a vacuum copying frame and exposed for 3 minutes at a distance of 10 cm using a high-voltage mercury lamp of 250 watts as a light source. The exposed part, which had a weak, thin color during the vapor deposition, assumed a deep green color and a clear, green negative-positive image with an absorption maximum at 500 ιτιμ was obtained.

Example 2

Using the same support (glass plate), a photosensitive recording material was made made of which the photosensitive layer was 0.13 microns thick and made of crystal violet duration. The same vapor deposition as in Example 1 was used. Then this became photosensitive Recording material exposed using an original as in Example 1, the exposed Part of the image which, during vapor deposition, had a pale blue color with a density of 0.03, a deep blue Color assumed a density of 0.17. In this way, a blue image with an absorption maximum was obtained at about 600 mu-

Example 3

Following the procedure given in Example 1, using the same support (Glass plate) and a photosensitive recording material using the vapor deposition method with a 0.13 micron thick photosensitive layer

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made from rhodamine. This photosensitive recording material was carried out as in Example I. an original is exposed, the purple-red color present at the time of vapor deposition with a Absorption maximum at 580 ηιμ to a red-orange Color with an absorption maximum at 510 ΐημ has been decolorized. A clear picture was obtained.

Example 4

IO

According to the method described in Example 1, a photosensitive layer was applied to a glass plate of auramine evaporated to a thickness of 0.15 microns to form a photosensitive Recording material. This was exposed through an original as in Example 1, then the exposed part discolored and a clear, yellow positive-negative image was obtained with an absorption maximum at 450 Γημ.

20 Example 5

According to the method described in Example 1, a photosensitive layer was applied to a glass plate evaporated from methylene blue to form a photosensitive recording material. This was brought into close contact with an original in a vacuum frame and using a Infrared lamp with 100 watts as a heat source for 15 minutes at a distance of about 5 cm Infrared light irradiated. As soon as the photosensitive layer had absorbed the heat energy, it was created from the time of vapor deposition, a pale blue color became a deep blue color, and a clear one was obtained Image.

Example 8 Example 6

A methyl alcohol solution of pyronine G was applied to a thickness of 0.5 mm on a glass plate the glass plate being degreased beforehand by immersing it in a sodium hydroxide solution for 10 minutes and washed. Then the coated plate was dried to remove the solvent evaporate.

The photosensitive recording material produced in this way was copied from a template such as exposed in Example 1, the image part colored purple at the time of application of the solution also being an absorption maximum at 570 πιμ decolorized whereby a red-orange color with an absorption maximum at 540 Γημ was created. In this way one got a clear picture.

A methyl alcohol solution of eosin B was applied to a thickness of 0.5 mm on a glass plate. the The glass plate was previously degreased by immersing it in a sodium hydroxide solution for 10 minutes and washed. The coated glass plate was then dried to remove the solvent, whereby a photosensitive recording material was obtained. This was as in Example 1 by a template exposed, then the pale yellow color at the time of application of the layer in the exposed Part deeply and you got a clear picture.

Example 9

A glass plate that had previously been well degreased and washed by dipping it in a chromic acid mixture. was evaporated in vacuo with a 0.3 mm thick crystal violet layer. The evaporation voltage was slowly increased to 2 volts under a vacuum of ΙΟ " ⁴ Torr to obtain a photosensitive material having a photosensitive layer 0.13 mm thick. This was brought into close contact with an original in a vacuum copying frame and used a high-voltage mercury lamp of 250 watts as a light source at a distance of 10 cm for 3 minutes. The exposed part, which was colored pale blue at the time of vapor deposition, now turned deep blue Hydrogen peroxide solution dissolved the pale blue color of the unexposed part from the surface of the photosensitive material and a clear blue image was obtained with an absorption maximum at about 600 μm.

Example 10

Following the procedure described in Example 9, a 0.13 micron thickness was obtained by vapor deposition photosensitive layer of rhodamine on a glass plate a photosensitive recording material manufactured. This was carried out as in Example 1

an original exposed imagewise, the exposed part, which was colored purple at the beginning, turns red-orange discolored. The recording material was then immersed in an aqueous 50% hydrogen peroxide solution for 5 seconds immersed, making the unexposed

The purple part was completely dissolved and removed and a clear, red-orange image was obtained an absorption maximum at 510 πιμ.

25th

30th

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Example 7

By vacuum evaporation of a photosensitive layer of crystal violet to a thickness of 0.13 Microns on a polyester film 1 mm thick, the surface of which had been washed with carbon tetrachloride as a solvent, was after im Example 1 given method a photosensitive recording material prepared. This was exposed through an original as in Example 1 and a clear, blue image with an absorption maximum was obtained at about 600 Γημ.

55

60 Example 11

^N ^ ^{ch that} described ⁱⁿ Example 9 was prepared by evaporation of a 0.16 micron-thick photosensitive layer of pyronine G on a glass plate a light-sensitive material. As in Example 9, this was exposed imagewise through an original, the part colored purple at the time of vapor deposition becoming discolored according to Kotorange. The recording material was then immersed in an ethyl acetate solution for a few seconds, as a result of which the unexposed purple-red part was completely dissolved and removed and a clear, red-orange image was obtained with ^an absorption maximum at 540 μm.

Example 12

A photosensitive recording material was produced in accordance with the procedure given in Example 9 by vacuum vapor deposition of a 0.11 micron thick photosensitive layer of methylene blue on a glass plate. This was irradiated 2 minutes at a distance of 10 cm long through an original with an infrared lamp of 100 watts, with the weak blue-colored portion was irradiated at the beginning due to dp ^r absorbed heat energy deep blue. When this recording material was immersed in an aqueous 20% acetic acid solution for 5 seconds, the undeveloped part was completely dissolved out and removed, and a clear blue image was obtained.

Example 13

An aluminum plate that is degreased by immersing it in a sodium hydroxide solution for 10 minutes and washed, was coated with a methyl alcohol solution containing 0.1% rhodamine and dried. The photosensitive recording material thus obtained was as in Example 9 through an original exposed imagewise, with the initially bluish-purple colored exposed part discolored to red-orange. The recording material was then for 5 seconds in an aqueous 20% Acetic acid solution immersed, whereby the unexposed part was completely dissolved and removed and a clear, oiranger-red image was obtained.

Example 14

Following the procedure given in Example 9, a 1 mm thick polyester film was applied in vacuo a 0.13 micron thick photosensitive layer of crystal violet evaporated to form a photosensitive Recording material. The polyester film used was previously with carbon tetrachloride as Solvent washed. Then, as in Example 9, the recording material was through a Original exposed, the exposed part which was light blue colored at the time of vapor deposition became deep blue by developing. Then the recording material was soaked in toluene for about 15 seconds immersed, the unexposed part completely dissolved and a clear blue one was obtained Image with an absorption maximum at 600 ιτιμ.

Example 15

By vapor deposition of a 0.15 micron thick photosensitive layer of auramine on top of a Alurv; inium plate, which by immersion for 10 minutes in a sodium hydroxide solution had been degreased and degassed, in a vacuum after the im Example 9 prepared a photosensitive recording material. This recording material was exposed through an original as in Example 9, whereby the at the time of Evaporation yellow-colored exposed part was decolorized. Then the recording material became 10 seconds immersed in a 20% aqueous hydrogen peroxide solution for a long time, which causes the yellow color of the unexposed part completely disappeared and the discolored exposed part turned yellow again. To this In this way a clear, yellow image was obtained.

'12

Example 16

An aluminum plate that can be degreased and removed by immersion in sodium hydroxide solution for 10 minutes Was washed, was coated with a 0.1% ethyl alcohol solution of pyronine G and dried. The photosensitive recording material thus obtained was then processed as in Example 9 exposed imagewise through an original, whereby the initially purple-colored exposed part follows Roiorange discolored. The recording material was then immersed in an aqueous 10% strength solution for 10 seconds Ammoniinchloride solution immersed, whereby the magenta-colored unexposed part completely i_s was dissolved and removed, and a clear, red-orange image with an absorption maximum at 540 m μ.

Example 17

A photosensitive recording material with a photosensitive layer consisting of pyronine G was produced by the method described in Example 11 and exposed imagewise through an original. Then, a quality paper weighing 52.5 g / m ^{2 was} brought into contact with the color image surface of the light-sensitive material and rubbed 2 or 3 times on the back with an absorbent cotton impregnated with ethyl acetate. The unexposed purple-red part dissolved in the ethyl acetate and was simultaneously transferred to the quality paper, so that a clear, red-orange, positive image was obtained on the photosensitive recording material and a purple, negative image was obtained on the quality paper.

Example 18

A photosensitive recording material with a photosensitive layer of rhodamine B was produced by the method described in Example 10 and exposed imagewise through an original. The colored image surface of the insensitive recording material was then ^{brought into contact with a quality paper weighing 52.5 g / m 2} and the reverse side was rubbed 2 or 3 times with a cotton impregnated with an aqueous 50% hydrogen peroxide solution. The unexposed purple-red part dissolved in the aqueous hydrogen peroxide solution and was simultaneously transferred to the quality paper, a clear, red-orange image being obtained on the photosensitive recording material.

Example 19

A photosensitive recording material prepared as in Example 9 with a photosensitive Layer of crystal violet was exposed imagewise through an original and with a solvent treated to obtain a blue image.

Then a quality paper with a weight of 52.5 g / m ² with the color image surface was this:

Photosensitive recording material brought into contact and rubbed on its back evenly with an absorbent, with ethylene alcohol impregnated cotton. The blue violet picture solves *

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in the alcohol and at the same time was completely transferred to the quality paper, creating a blue Image on the quality paper (image receiving material) was obtained. On the photosensitive recording material nothing remained.

Example 20

A photosensitive recording material with a photosensitive layer of rhodamine was produced by the process given in Example 10, exposed imagewise and treated with a solvent as in Example 10. Then a quality paper with a weight of 52.5 g / m ^{2 was} brought into contact with the color image surface of the light-sensitive material and the same on the reverse side! rubbed with an absorbent cotton impregnated with ethyl alcohol, the red-orange image of the rhodamine in the ethyl alcohol dissolved and at the same time completely transferred to the quality paper, forming a red-orange image on the quality paper. Nothing was left on the photosensitive recording material.

Example 21

A photosensitive manufactured according to Example 11 Recording material with a light-sensitive layer of pyronine G was passed through a template imagewise exposed and then treated with a solvent as in Example 17, with images both originated on the quality paper as well as on the photosensitive recording material.

A quality paper with a weight of 52.5 g / m ² was brought into contact with the color image surface of the photosensitive recording material and rubbed evenly on the back with an absorbent cotton impregnated with ethyl alcohol, the red-orange image of pyronine G in the ethyl alcohol and was completely transferred to the quality paper, so that a red-orange image was obtained on the quality paper. Nothing was left on the photosensitive recording material.

Example 22

Following the procedure described in Example 10, a photosensitive recording material was obtained produced with a photosensitive layer of rhodamine, exposed imagewise through an original and treated with a solvent as in Example 17 to produce images on the quality paper and on the photosensitive recording material.

A quality paper weighing 52.5 g / m ^{2 was} brought into contact with the colored image surface of the light-sensitive material, and the back was rubbed evenly with an absorbent cotton impregnated with ethyl alcohol, the red-orange image of rhodamine B being dissolved in the ethyl alcohol and completely transferred to the quality paper, so that a red-orange image was obtained on the quality paper. Nothing remained on the photosensitive recording material.

Example 23

According to the procedure given in Example 10, a photosensitive recording material with a photosensitive layer of rhodamine was prepared, exposed imagewise through an original and treated as in Example 10 with a solvent to produce a red-orange image. When a quality paper weighing 52.5 g / m ² mil

ίο brought the color image surface of the photosensitive recording material into contact and the photosensitive recording material on the back was ^{treated for about 20 seconds with an iron heated to 180 0} C, the red-orange image remaining on the photosensitive recording material was completely transferred to the quality paper, so that on the Quality paper a red-orange image was obtained. Nothing remained on the photosensitive recording material.

Example 24

A photosensitive recording material with a photosensitive layer of crystal violet produced by the process given in Example 9 was exposed imagewise and treated with a solution as in Example 9, so that a blue image was formed. When a quality paper with a weight of 52.5 g / m ^{2 was} brought into contact with the colored image surface of the photosensitive recording material and the backside of the photosensitive recording material was ^{treated for 20 seconds with an iron heated to 200 °} C., this became on the photosensitive recording material the remaining blue image was completely transferred to the quality paper, a blue image being obtained on the quality paper. Nothing remained on the photosensitive recording material.

Example 25

According to oem in the example! 17 specified procedure a photosensitive recording material, the photosensitive layer of which consisted of pyronine G,

imagewise exposed and treated with a solvent as in Example 17 to produce a magenta Image on the quality paper and a red-orange image on the photosensitive recording material.

A quality paper with a weight of 52.5 g / m ² was brought into contact with the color image surface of the photosensitive recording material, and the back of the photosensitive recording material was heated to 190 ^° C. for 20 seconds

Heated iron treated, creating the red-orange image on the photosensitive recording material has been completely transferred onto the quality paper, forming a red-orange image on the Quality paper. Nothing was left on the photosensitive recording material.

Example 26

A photosensitive recording material whose

The photosensitive layer consisted of rhodamine, was exposed imagewise as in Example 10. Then became a

Quality paper with a weight of 52.5 g / m ² with

the color image surface of the photosensitive image

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Drawing material brought into contact and 2 or 3 times! evenly on the back with one with Methyl acetate impregnated absorbent cotton rubbed. That does not expose '·; bluish purple Part dissolved in the ethyl acetate and was transferred to the quality paper at the same time Formation of a clear, red-orange, positive image on the photosensitive recording material and of a bluish puipur-colored, negative image on the quality paper.

If a quality paper with the color image surface

of the photosensitive recording material was brought into contact and the backside of the photosensitive recording material was ^{treated for 20 seconds with an iron heated to 180 °} C., the red-orange image on the photosensitive recording material was completely transferred to the quality paper, a red-orange image being formed on the quality paper . Nothing was left on the photosensitive recording material.

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Claims (7)

Patent claims: 1. Process for the production of images, in which a recording material consists of a layer support and a photosensitive layer exposed imagewise and optionally the unexposed Parts of the image washed out with a solvent or transferred to an image receiving material are characterized in that a A recording material having a photosensitive layer made of an organic sensitizing dye is used. 2. The method according to claim 1, characterized in that a sensitizing dye Diphenylmethane, triphenylmethane, xanthene. Thiazine or acridine dye is used. 3. The method according to claim 2, characterized in that auramine as diphenylmethane dye. as triphenylmethane dye malachite green, brilliant green, Crystal violet, rosaniiin. Victoria blue or methyl violeit, methylene blue as the xanthene dye and acridine orange is used as the acridine dye. 4. The method according to claim 1, characterized in that a recording material with a photosensitive layer composed of the sensitizing dye applied by vapor deposition is used will. 5. The method according to claim 1, characterized in that a recording material with a 0.1 to 10 μm thick light-sensitive layer is used. 6. The method according to claim 1, characterized in that that a weakly polar solvent is used to wash out the unexposed parts of the image is used. 7. The method according to claim 1, characterized in that that paper, a cellulose or plastic film or a glass, Metal or plastic plate is used.