DE3008479A1 - METHOD AND DEVICE FOR THE ELECTROPHOTOGRAPHIC PRODUCTION OF COLOR HALFTONE COPIES - Google Patents

Description

ÄGFA-GEVAERT 5090 Leverkusen, Bayerwerk

SHARED COMPANY

Patent department HRS-by-c

H. MAR. 1980

Method and apparatus for the electrophotographic production of color halftone copies

The invention relates to a method and an apparatus for the electrophotographic production of color halftone copies from a transparent original or a supervision template, with at least three Color separation images are copied one after the other on an image carrier material and developed.

The invention also includes the possibility of the copied original as a negative or as a positive of the original when the photoconductors or developers are appropriately selected.

Another advantage of the invention is to be seen in the fact that the color image with 3 or more color separations on one uncoated, commercially available, transparent image carrier material, for example a film, inexpensive can be reproduced.

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ORIGINAL INSPECTED

Charge transfer printing processes are known in which charge images are formed from a photoconductive layer, e.g. Selenium layer on a second, non-light-sensitive, insulating support, e.g. a polyester film, be transmitted. A simple transfer printing process consists, for example, in that a one-sided metallized, insulating film is placed on a selenium layer, which carries a charge image that is generated by charging and imagewise exposure of the layer is made.

The selenium layer is on a conductive surface, e.g. a metal plate. A DC voltage of 1000 to 2000 V in such a way that the metallization of the foil and the metal plate are negative positive polarity is under the selenium layer if there is a positive charge image on the selenium surface is located. If you now separate both layers from each other while maintaining the tension on the coverings, this is what happens to an image-wise controlled charge transfer in such a way that a positive mirror image in relation to the film on the original image.

A special feature of this process is the contact with the surface of the charge carrying the charge image Photoconductor layer with the image side of the film in front of the. Separation.

According to another known method, this direct contact is made between the surfaces carrying the charge image thereby avoided that as the acceptor of the charge image instead of the one-sided metallized film a completely

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insulating film is used, the copied charge image being created on the outside of the film. Man for example, again starts from a selenium layer on a metal base and produces on the layer in a known manner Create a charge image through charging and exposure. Then you put an insulating film on the Selenium layer and charges with known devices for generating a charge current by corona discharge the free side of the film to a constant potential everywhere. After removing the charged foil from the selenium layer on the side that was charged from the outside, a congruent charge image of the original image on the layer, which depending on the sign of the applied charge as positive or as The original can be represented negatively if in the subsequent development the places of higher charge density are colored more strongly than the places of lower charge density.

The two methods described and others., Similar Transfer printing processes have the common disadvantage that with the process step., with which the insulating layer or the insulating film is separated from the photoconductive layer by strong spark and sliding discharges Disturbances in the electrical picture. Furthermore, there is the electrical contact between the applied film or layer with the photoconductor layer in practice not possible in a simple way without air inclusions if larger areas are covered at the same time will. Air inclusions in the boundary layer can cause strong density fluctuations in the charges, which do not belong to the charge picture and therefore

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have a disfiguring effect. Especially when transferring halftone images, which not only have to reproduce black and white tones, but also a multitude of intermediate tones, the disturbances described are very significant and prevent the transfer of the charge image in the required manner Quality.

Processes are also known according to which a fully developed color image is produced in just one process step can, if developer suspensions are used, the light-sensitive pigment particles of all primary colors contain. These so-called photoelectrophoretic ones Processes are very difficult to master and hardly lead to sufficiently reproducible results Quality because of the charging and movement of the pigment particles under the influence of simultaneous exposure in all colors and under the additional influence of an externally applied electric Strong mutual disturbances occur.

From DE-OS 2 625 393 a method is known, which the use of highly light-sensitive, colored or black photoconductors that enable a fast copying process to be carried out sufficient sensitivity to light in all of them coming spectral ranges are suitable. This process requires transfer of the charge image from a photoconductor to an insulating support, e.g. a plastic film. For the generation of the full color image is a multiple transfer

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of partial images with an exact fit of the partial images required. Since only thin foils are used as image carriers can be carried in the form of a tape from one transfer point to the next must, a high level of equipment is required to achieve a sufficiently good fit. The type of electrical charge image transfer used here only delivers sharp images high resolution, if the film material is highly insulating and thin enough and with an exact fit to be led.

The invention is based on the object of finding a simple method and a device, which under Use of highly sensitive photoconductor layers Allow color halftone copies to be made on a thin substrate with high resolution and without misregistration .

According to the invention the object was achieved in that for exactly fitting one on top of the other Color separation images for the duration of the entire copying process a photoconductor layer, the image carrier material and a projection device in one with one another rigid arrangement and

Chargers combined with imaging units, further chargers, exposure openings with color separation filter discs and bezels and developing units with air nozzles together in one opposite the rigid arrangement movable unit housed and used.

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This solution has been found to ensure that the template to be projected always precisely matches the assigned one Photoconductor layer falls, no matter which and how many individual color separation images are exposed and developed.

The method according to the invention is further characterized in that for the duration of the entire copying process for a color halftone copy

I) an image carrier material to a photoconductor layer, which is applied to a conductive surface, held taut and pressed on,

II) and that the movable unit is continuous to produce the partial images of the color halftone copy is moved under the image carrier material, so

• J5 that for each sub-picture

a) the image carrier material is charged homogeneously

becomes, at the same time the photoconductor layer diffuse through the image carrier material is exposed

b) then a charge of the image carrier material with opposite charge carriers Sign to the existing first charge without simultaneous exposure of the photoconductor layer is made

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c) the imagewise exposure of the photoconductor layer through aperture and color separation filter the image carrier material is carried out

d) the charge image obtained on the image carrier material is developed

e) and that this process is repeated in the order a) to e) until all Partial images have been applied to the image carrier material and developed, and that afterward,

III) after the end of the copying process, the image carrier material detached from the photoconductor layer and transported on to a drying device and dried during the production of a subsequent color halftone copy and then with a suitable material is laminated.

The invention also includes a device for carrying out the method, which is characterized in that that it has a fixed device and a movable device, wherein

in the stationary device, a photoconductor layer of a projection device attached to a conductive suction plate is arranged rigidly opposite, and means are provided to an image carrier material to be transported and temporarily brought into close contact with the photoconductor layer

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and wherein the movable means is between the photoconductor layer with the image carrier material stretched over it and the projection device on one Rail can be moved and a combined charging and exposure unit / transfer unit, an exposure opening with a color separation filter and exposure diaphragm and a developing unit with an air nozzle one behind the other are arranged in the movable device.

In an advantageous embodiment, the next following color halftone copy is used Image carrier material braked by a feed device under tension over two pulleys Supply roll peeled off, with the image carrier material

-J _{5 is} worn on an air cushion over the photoconductor layer. After the image carrier material has been transported by an image length, the overpressure which creates the air cushion is switched off and replaced by a negative pressure which causes the image carrier material to be pressed firmly against the photoconductor layer and held in this position during the production of the color halftone image.

The main advantage of the method and the device is that the copying process Original image by means of an optical system of a known type and the photoconductor layer covered with the image carrier material is mapped, while all functional units necessary for image generation in a single

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one-time movement continuously one after the other through the Exposure field passed through close to the photoconductor layer covered with the image carrier material will. Because of the immobility of Image carrier material, photoconductor layer and imaging optics during the entire process eliminate registration problems away and very thin image carrier materials such as polyester films or polycarbonate films can be used 2 to 10 μm strength can be used, which increases the sharpness of the image favor significantly. The process includes the following procedures for the display of each individual partial image ens steps:

1. Homogeneous charging of the to the photoconductor layer pressed image carrier material, e.g. negative, with simultaneous diffuse exposure of the photoconductor layer.

2. Homogeneous charging of the image carrier material with opposite signs, in this case positive, without simultaneous exposure of the photoconductor layer.

3. Imagewise exposure of the photoconductor layer a transparent original or a reflected light original through the charged image carrier material with the interposition of the first extract filter, e.g. a purple filter.

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4. Development of the resulting charge image, in this case with a developer suspension Contains positively charged toner particles. The color of the partial image is blue-green, corresponding to the as Example given preconditions. The excess developer liquid is removed by a sharp air flow from a slot nozzle, which is arranged close to the development unit, carried along with the unit in the direction of movement. It remains about 1 to 3 μm thicker Liquid film adheres to the surface of the image carrier material.

In the same way as described, only with different colored extract filters, are created on the same Image area of the image carrier material a second and then a third color separation or even more further color extracts from the original.

Surprisingly, the other necessary charges, exposures and developments can be carried out on the covered only by a few \ in the thick liquid film display material after the completion of the first field, without the quality of Gesamthalbton color obtained copy suffers. The image carrier material is only dried after the entire copying process by means of a drying device, while a subsequent copying process takes place.

In an expedient embodiment, the resulting partial color separations can be optimized in that an the loading and development units variably adjustable

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bare voltages are applied to the conductive Plate or suction plate. On which the photoconductor is layered is applied., are related. By adapting the Potential ratios by means of an adjustable bias voltage can change the transmission conditions to a large extent Dimensions are optimized.

The process is suitable for the production of color halftone copies with three partial color separations., Where When developing the separation images, the colors are preferably in the order of blue-green, purple and Yellow can be chosen. The corresponding color separation filters will then be red, green and in the order Blue used. Of course, other sequences and colors and more than three partial color separations can also be used to be carried out with the procedure, when the movable Unit expanded by further sub-units and other filter colors or filter designs provided and coordinated with the developer liquids will.

Further advantages and possible applications are given in the following description in connection with the enclosed Drawings to be seen. It shows:

Figure 1 shows the arrangement of the parts of the device for performing the method

Figure 2 a combined charging and exposure

unit

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Figure 3 a reloading unit (Scorotron)

FIG. 4 shows an exposure opening with a color separation filter disk and exposure aperture

FIG. 5 shows a development unit with an attached air nozzle.

As shown in Figure 1, the image carrier material 1 as a film tape from a braked supply roll 2 through a pair of preferred rollers 4 is drawn off over two deflection rollers 3 and moved past the photoconductor layer 5 under tension. The photoconductor layer 5 is applied to a suction plate 6. The suction plate 6 is also provided with air ducts 7 which are connected to a suction and pressure pump 8 via a pressure line. To the The image carrier material 1 is produced by sucking the air out of the contact zone between image carrier material 1 and photoconductor layer 5 pressed against the photoconductor layer 5 by means of the vacuum pump 8 by the normal air pressure and held in this position.

After the copying process is finished, the Pump 8 in a known manner by changing the direction of rotation or by switching from the suction to the On the pressure side of the pump 8, the image carrier material 1 is detached from the photoconductor layer 5 and placed on an air cushion advanced by one image length. To advance the image carrier material 1 by one Image length can be both switching the pump 8

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used, thereby for the time required the braking effect of the negative pressure on the film is canceled and the transport is released or it the preferred roller pair 4 can be used, the image carrier material 1 by one of the image length corresponding number of revolutions of the preferred rollers is continued. The preferred rollers 4 are used here also at the same time as a laminating device, whereby the Image fixation by pressing on a laminating material ni with colorless adhesive layer on the picture side of the Image carrier material 1 is made. The lamination material 13 is through the feed rollers 4 of a Supply roll 12 withdrawn, at the same time a protective film 14 by a pair of rollers 15 for exposure the adhesive layer of the laminating material 13 is peeled off will.

The lamination material 13 can be white paper, lacquered paper, white or transparent Be foil or a metal foil. It can be finished with brighteners to increase the brilliance Image. The protective film 14 omitted. The side of the laminating material 13 facing the colored layer of the carrier material 1 is provided with a provided with a colorless self-adhesive layer. Known adhesive compositions can be used for the self-adhesive if they are compatible with the dyes.

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It is also possible to apply an adhesive application to the lamination material 13 only after it has been withdrawn from the supply roll 12 to provide or to activate an already applied colorless adhesive, such as Heat sealant by heating or applied gelatin by moistening with water.

The produced color copy 38 then consists of a laminating material 13 and the image carrier material 1 as Protective film for the color image, which is in the limit TO area lies between the two materials.

The individual color copies are then cut in the usual way from the color copy tape 38.

When making the color halftone copy, all Partial images exposed one after the other on the side of the image carrier material 1 facing away from the photoconductor layer 5 and developed, with the other side of the image carrier material firmly attached to the photoconductor layer is pressed.

The photoconductor layer 5 consists for example of amorphous selenium, which on the electrically conductive Suction plate 6 is applied by vacuum evaporation.

The thickness of a selenium layer is about 50 μ, πι. the Photoconductor layer 5 can also consist of several layers, for example of a first layer Manganese on which the amorphous selenium layer is vapor-deposited. A tellurium layer can also be used as the lower layer from 10 to 50 nm and on this

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a selenium layer with a layer thickness of 20 to 100 μm can be vapor-deposited. Such photoconductor layers and their production are described in detail in DE-PS 2,808,757. In the process and the device can also contain selenium-arsenide-ZnO layers or sensitized organic photoconductor layers be used.

Below the described arrangement of suction plate 6, photoconductor layer 5 and the image carrier material 1 is a projection device 9 is arranged, with both of a transparent template 10 and of a top view template 10 an image in the plane of the photoconductor layer can be projected. Accordingly, the projection device is provided with a light source for Transmitted light and / or equipped with a light source for incident light.

Between the photoconductor layer 5 with the stretched over it Image carrier material · 1 and the projection device 9 are guide rails 17 arranged on them a movable unit 16 can be moved in the direction of the arrow. The movable unit 16 carries all of them further components and functional units essential for image generation and is in the starting position in FIG shown. The part 18 is a cover, which in the starting position of the unit 16 the Photoconductor layer 5 optically covers and protects it from pre-exposure. For every color separation process the following components are arranged one behind the other in the movable unit 16:

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a combined charging and exposure unit 19, (Figure 2)

a transfer unit 20 (Scorotron) for the subsequent Reloading without exposure (Figure 3)

an exposure opening 21 for the exposure of the Color original 10 on the photoconductor layer 5, wherein the exposure opening 21 is provided with an exposure diaphragm and the appropriate extract filter 36 (Figure 4)

a developing unit 22, which is provided with air nozzles 35 for mechanical removal of the developer liquid of the respective partial image is combined (Figure 5).

All components can be opened as often as required in this order according to the desired number of color separations of the movable unit 16 are arranged and are designed in the dimensions so that they are in motion on the carriage in the direction of the arrow, the image area on the photoconductor layer 5 in full Cover the width.

The color halftone copy of the original 10 is produced in the copying process in the following way:

At the beginning of the copying process, the movable unit 16 is in the position shown in FIG. During the previous return of the unit 16

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The image carrier material ΐ transported by an image length and is now in close contact with the photoconductor layer 5, the is still covered by the panel 18. When starting, after the template 10 is in the usual way in the projection unit 9 was introduced, the projection unit 9 switched on and the unit 1S set in motion in the direction of the arrow to the left (FIG. 1). the Functional units built into the unit 16 are all or one after the other either simultaneously at the start or by a special switching system, each individually in operation before entering the image zone taken.

The photoconductor layer 5 is, for example, positively chargeable by using amorphous selenium, which is sensitive to light in the visible spectral range due to its special preparation.

First, the combined charging and exposure unit pushes itself 19 over the photoconductor layer 5 covered with the image carrier material 1 and charges the image carrier material 1 while being diffuse at the same time Exposure of the photoconductor layer through the image carrier material 1 through homogeneously negative. the The following unit, the transfer unit 20 (Scorotron), darkens the image field and loads the image carrier material positive on. During the further movement of the unit 16, an image-wise exposure occurs through the exposure opening 21.

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exposure of the photoconductor layer 5 through the image carrier material 1, the opening 21 being provided with an exposure diaphragm 37 and with a color separation filter disk 36 is covered. This creates a potential field above the charged image carrier material 1, the is characterized by image-wise graded potential values.

Images of this type can be visualized with electrophoretic developers, which are essentially consist of an insulating liquid in which electrically charged toner particles are dispersed, the Contains color pigments. Electrophoretic developer for the subtractive primary colors blue-green, purple and Yellow are described in detail in DE-OS 2 502 933 (GB-PS 1 484 582).

After the first separation image has been exposed through a red filter, the developing unit 22 is over the Image area guided, the development electrode 32 from the image area, for example, 0.5 mm away is. In this case, a developer liquid 29 is pumped through the intermediate space 34 (FIG. 5), which is positive contains charged toner particles with the dye cyan. By the deposition of the toner under action of the electric field between the charged image carrier material surface 1 and the developing electrode 32 creates a negative image of the original in blue-green, i.e. at the light areas of the projected image A stronger blue-green coloration occurs in the image than in the darker areas of the image.

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After the first development unit 22 has passed through, the following second functional unit 19 is used Image carrier material 1 with the first color separation image and the overlying liquid film, again with diffuse exposure of the photoconductor, homogeneously negative charged. It then repeats the positive charging in the dark by the second unit 20 and the subsequent imagewise exposure through the second opening 21, in this case with a green filter is provided. At this stage the photoconductor must be exposed through the cyan dye layer already present of the first extract, which is sufficient for the green light is permeable. For the visualization of the resulting second extract image with the second Development unit 22 uses a magenta developer, the toner particles of which are also positively charged are. This is followed by the third combined negative charge and exposure with positive recharge the units 19 and 20. The third imagewise exposure through a blue separation filter is the photoconductive layer covered with the layers of color of the blue-green and purple part of the picture. Both dyes are, however, according to the prerequisite, subtractive primary colors and therefore permeable to blue light.

The third and here the last development unit 22 delivers the third partial image in yellow and completed thus the color image.

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During the return of the movable unit 16 under Switching off all units 19, 20, 21 in the starting position is the image carrier material 1 by compressed air detached from the suction plate 6 and with the pair of rollers 4 by at least one image length on an air cushion moved on. The or a previous pre-dried image comes into the area of a Drying device 11 and is completely dried there. The drying device 11 can consist of a 1Q hot air blower, as shown in FIG. However, other drying devices such as infrared dryers, microwave dryers or the like can also be used Facilities are used.

The fixation can be done after this or one of the next steps by pressing together with white paper, which has been prepared with an adhesive layer at point 4.

If a transparent image is desired, a transparent one is used as the laminating material 13 instead of the white paper Foil used with a clear adhesive layer. It is also possible to have the picture on one metallic base by applying a metal foil is used. A white plastic film can also be used to create a waterproof image obtain. As already described, the lamination material 13 can be a protective film 14 or an adhesive-repellent one Have a back layer or an adhesive that is only activated before the fixing process.

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The complete copying process takes a few seconds.

In principle, the image can be reproduced as a negative or a positive of the original. which of both types of image as a copy is dependent on the electrical properties of the photoconductor and the sign of the charge of the toner in the developer. For example, when using the positive charged toner represent a positive-positive copy if instead of positively chargeable selenium negatively chargeable photoconductors such as polyvinyl carbazole or multilayer photoconductors for example Selenium-polyvinylcarbazole are used and the Foil charging under diffuse exposure is first positive and then negative in the dark.

A positive-positive process is also obtained when when a negatively charged toner having a positively chargeable photoconductor layer in that described above Way is used.

To adapt the potential relationships, it is advantageous in any case to include both the development electrodes 32 and the charging units 19, 20 to assign an adjustable bias voltage and thus set the optimal transmission conditions.

Figure 2 shows the combination of charging and exposure elements to a unit 19. In the housing 23, which consists of a metal tub with U-shaped

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Cross-section, there are the elongated Light source 24 and two spray wires 25, which are stretched in an electrically insulated manner. As a light source 24 can For example, a simple incandescent lamp with an elongated filament can be used. As spray wires 25, 50 μm thick tungsten wires are suitable, which are sufficient when a voltage of 5 to 6 kV is applied Generate a uniform corona discharge. The tub is made of walls 26 on the front sides sealed insulating material, to which the lamp 24 and the spray wires 25 are attached. the The top of the housing formed in this way closes off a metal grid 27, which acts as an electrode for limiting the charge level is used.

The entire unit is electrically isolated on the movable unit 16 (Figure 1) and attached to a connected to a low-resistance voltage source (not shown), the DC voltages in the range from 0 to 1000 V supplies. In the operating state, all parts, the spray wires 25, the light source 24 and the grid 27 is supplied with the voltages and currents corresponding to their intended use.

The reloading unit 20 according to FIG. 3 is similar in construction, but has a simpler design, since there is no exposure is required during the charge. The grid 27 and the spray wire 25 fulfill the same functions as in the unit 19. The transfer unit is electrically isolated behind the unit 19 on the movable unit 16 mounted (Figure 1).

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In FIG. 4, one of the exposure openings 21 built into the movable unit 16 is shown enlarged. By means of a diaphragm 37, the intensity of the exposure can be individually adjusted for the individual openings will. Underneath, the color separation filter disk 36 is inserted exchangeably into the opening 21 and is held in the opening 21 together with the diaphragm 37 by a snap ring or the like.

Figure 5 shows one of the developing devices 22 in details. The operation of this fluidized bed developing device is as follows: In the lower part of the container 28 there is the developer liquid 29, which is generated by means of a submersible pump 30 is pumped into the funnel-shaped extension 31 of the riser pipe of the pump 30. By a metal plate 32 perforated by a multiplicity of channels 33, the surface of which simultaneously acts as a developer electrode is used and passed through just below the image carrier material 1 with the electrical charge image is, the developer liquid 29 escapes upwards and fills the space between the metal plate 32 and the image carrier material 1. The excess of developer liquid 29 flows over the Edge of the metal plate 32 in the lower part of the container 28 back. At the top of the container 28 an air nozzle 35 is arranged, from which an air stream from a narrow nozzle gap of for example 0.2 mm emerges and strikes against the lower surface of the image carrier material 1. It is achieved in such a way that

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during the forward movement of the developing units with the movable unit 16, the developer liquid 29 does not exit over the edge of the container 28. At the same time, the air from the air nozzle 35 causes the air on the underside of the image carrier material 1 located liquid except for a film of 1-3 μΐη Mechanically stripped thickness. This film of liquid then surprisingly has a sufficient insulation capacity to record a next charge image and to keep it stable for the necessary time. This fact enables the short-term succession the pictorial charges and development of the color separations and thus a high process speed.

Due to the advantageous merging of the work processes

Return of the movable unit 16 and advance of the image carrier material 1

Complete drying of an image during the copying process of another image and finally

Fixing of the image with a laminating material 13 to form a finished image 38 in a further cycle of the copying process

the time cycle is only determined by the running time of the slide and leads with this advanced device a very economical method of making color halftone copies.

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1. Image carrier material

2nd supply roll (braked)

3. Pulleys

4. Pull rollers

5. Photoconductor layer

6. Suction plate

7. Air ducts

8. Positive and negative pressure pump 9 =. Projection device

10. See-through or supervision copy

1ΐ. Drying device

12. Supply roll of lamination material

T3. Laminating material

14. Protective film

15. Pull-off device protective film

16. Movable unit

17. Guide rails

18. Aperture

19. combined charging and exposure units

20. Transfer unit (Scorotron)

21. Exposure openings with pullout filter disks and bezels

22. Development Units

23. Housing (of 19)

24. Light source

25. Spray wires

26. End walls

27. Metal grille

28 developer container

29. Developer liquid

30. Submersible pump

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31. funnel-shaped enlargement

32. Distribution plate and developing electrode

33. Outflow channels

34. Interspace

35. Air nozzle

36. Extract filter disc

37. End of exposure

38. Color copy tape

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Claims (15)

Claims 1. Process for electrophotographic production of color halftone copies of a transparent original or a reflective original, with at least three color separation images one after the other on an image carrier material copied and developed one above the other, characterized in that for exactly fitting one on top of the other Color separation images for the duration of the entire copying process a photoconductor layer (5), the image carrier material (1) and a projection device (9) can be accommodated in an arrangement that is rigid to one another and Chargers combined with imaging units (19), further chargers (20), exposure so ff now gen (21) with color separation filter discs (36) and exposure diaphragms (37) and development units (22) with air nozzles (35) together in a relative to the rigid arrangement (5.9) movable unit (16) housed and used. 2. Process for the electrophotographic production of color halftone copies of a transparent or Supervision template, with at least three color separation images are copied one after the other on an image carrier material according to claim 1, da- AG 1696 130038/0276 characterized in that for the duration of the entire Copying process for a color halftone copy I) an image carrier material (1) on a photoconductor layer (5), which is applied to a conductive base (6), taut ge hold and is pressed, II) and that for the production of the partial images of the color halftone copy the movable unit (16) continuously under the image carrier material (1) is shifted so that for each part image a) the image carrier material (1) is charged homogeneously, with the photoconductor layer at the same time (5) through the image carrier 5 diffusely exposed through the material (1) will. b) then a charge of the image carrier material (1) with opposite charge carriers Sign to the existing first charge without simultaneous exposure of the Photoconductor layer (5) is made c) the imagewise exposure of the photoconductor layer (5) via aperture and color separation filter is carried out through the image carrier material (1) AG 1696 130038/0276 d) the charge image obtained on the image carrier material is developed e) and that this process is repeated in the order a) to e) until all Partial images on the image carrier material (1) have been brought and developed, and that subsequently, III) after finishing the copying process, the Image carrier material (1) from the photoconductor .JQ layer (5) dissolved and to a dry one direction (11) transported further and during the production of the following color halftone copies is dried and then laminated with a material (13). 3. The method according to claim 1 and 2, characterized in that for fastening and releasing the Image carrier material (1) on and from the photoconductor layer (5) air pressure is used. 4. The method according to claim 1 to 3, characterized in that after the development of the first Partial image, the other partial images on the image carrier material wetted with the developer liquid (1) can be generated. AG 1696 130038/0276 3008473 5. The method according to claim 1 to 4, characterized in that the loading and development units (19, 20, 22) variable voltages are applied, which are applied to the conductive suction plate (6) the photoconductor layer (5) are related. 6. The method according to claim 1 to 5, characterized in that for the preparation of three partial color separations When developing the separation images, the colors are chosen in the order blue-green, purple and yellow. 7. The method according to claim 1 to 6, characterized in that the drying of a finished-exposed and developed color halftone copy during manufacture a subsequent color halftone copy takes place and the fixing of the color image with a laminating material (13) for a colored image (38) in the production of another color halftone copy will. 8. The method according to claim 1 to 7, characterized in that that during the return of the movable unit (16) the transport of the image carrier material Ies (1) takes place by at least one image length. 9. Apparatus for performing the method according to claim 1 and 2 for electrophotographic production of color halftone copies of a trans- AG 1696 130038/0276 Parent original or a superimposed image original , with at least 3 color separation images being copied one on top of the other on a thin insulating image carrier material, characterized in that the device has a stationary device and a movable device, wherein in the fixed facility one on one
conductive suction plate (6) attached photoconductor layer (5) of a projection device (9) is arranged rigidly opposite, and means (2, 3 x, 4, 7, 8) are provided to transport an image carrier material (1) and temporarily bring it into close contact with the photoconductor layer (5) and whereby the movable Device (16) between the photoconductor layer (5) with the stretched over it
Image carrier material (1) and the projection device (9) can be moved on a rail (17) and a combined charging and loading function for the generation of each color halftone partial image Exposure unit (19), a transfer unit (20), an exposure opening (21) with color separation filter disk (36) and exposure diaphragm (37) and a developing unit (22) with an air nozzle (35) arranged one behind the other in the movable device are. AG 1696 130038/0276 10. Apparatus according to claim 9, characterized in that means for temporary Transport of the image carrier material (1) from a braked supply roll (2), pulleys (3) and driven feed rollers (4) and as devices for pressing the image carrier material (1) to the photoconductor layer (5) during manufacture of the color halftone image a vacuum pump (8) and a suction plate connected to it (6) are provided, the pump (8) after the completion of the picture to release of the image carrier material (1) can be switched to upper pressure. 11. Apparatus according to claim 9 and 10, characterized in that that a drying device (11) for drying the fully developed image so arranged at their distance from the photoconductor layer (5) is that during the production of a following picture the drying of a previously her-2η provided image. 12. Apparatus according to claim 9 and 10, characterized in that for the respective first homogeneous Charging and diffuse exposure of the photoconductor layer (5) of each color halftone partial image a combined charging and exposure unit (19) is provided. AG 1696 130038/0276 13. Apparatus according to claim 9 to 12, characterized in that that the movable unit (16) consists of at least three identical, one behind the other Components, each with a charging and exposure device (19), a transfer unit (20), an exposure opening (21) and a developing unit (22). 14. The device according to claim 9, characterized in that that the photoconductor layer (5) from IQ consists of amorphous sensitized selenium, which is applied to the suction plate (6). 15. The device according to claim 9, characterized in that the photoconductor layer (5) from consists of several sub-layers which are applied to the suction plate (6) one after the other or together are. AG 1696 130038/0276