DE1271548B - Electrophotographic process - Google Patents

Description

Electrophotographic Process The invention relates to an electrophotographic process Process for the production of toner images, in which a recording material with a transparent, electrically conductive, possibly a free, lenticular lens Layer carrier having surface, an electrically conductive intermediate layer and a photoconductive layer, optionally pre-exposed, charged, with one of an insulating layer, an electrically conductive layer and one optionally insulating, optionally a free, lenticular surface having layer support existing, optionally charged image receiving material brought into contact, between the intermediate layer and the electrically conductive Layer applied a DC voltage, exposed imagewise, the image receiving material separated from the recording material and developed the charge image with a toner will.

The invention also relates to an electrophotographic process for the production of deformation images, in which a recording material with a transparent, electrically conductive substrate, an electrically conductive intermediate layer and a photoconductive layer, optionally pre-exposed, charged, with one of a thermoplastic layer, an electrically conductive layer and an optionally insulating layer support, optionally charged Image receiving material brought into contact between the intermediate layer and the a DC voltage applied to the electrically conductive layer, exposed imagewise, the image receiving material is separated from the recording material, the thermoplastic Layer heated, cooled and, if necessary, briefly heated again for smoothing will.

The invention also relates to an electrophotographic process with electrolytic development for the production of images in which a recording material with a transparent, electrically conductive, optionally a free lenticular lens Layer carrier having surface, an electrically conductive intermediate layer and a photoconductive layer, optionally pre-exposed, with one of a current-sensitive layer, an electrically conductive layer and optionally one insulating, optionally having a free lenticular surface Layer carrier brought into contact with existing image receiving material, between the A DC voltage is applied between the layer and the electrically conductive layer, imagewise exposed, the image receiving material separated from the recording material, the image receiving material is optionally heated and the image is optionally heated made visible or amplified in the image receiving material by means of a chemical reaction will.

So far, the image has been applied directly to the electrophotographic layer let act with such a brightness distribution that in every point of the Image template corresponds to. It has been shown, however, that this method is used for original images with halftone character do not lead to success. This tends to be the case with these types of images Powder image so that the powder settles on the distinctive image contours and on little or not at all applies to the areas enclosed by these contours. The consequence of this is that an image is created with very little detail. To overcome this disadvantage, it is already known to use a grid that divides the picture surface into individual, discrete areas. It is thereby achieved that Also grays and halftones are reproduced because the powder is inside each one The area is deposited in the areas where charges are generated as a result of lower exposure stayed.

For example, U.S. Patent 2,598,732 discloses an electrophotographic Method has become known that uses a grid that is in front of the photoconductive Layer is arranged. The disadvantage here is that this grid becomes effective always only in the form of a pre- or post-exposure to the actual exposure the halftone image is made, never at the same time as it. It is an embodiment, though proposed the one coinciding with the halftone image exposure in time Raster exposure permitted, but this is unsuitable for practical use, since it requires the use of two projectors.

US Pat. No. 2,599,542 discloses an electrophotographic plate conventionally composed of a base plate and a photoconductive layer, the base plate being provided with a plurality of depressions or, what is the same, with a network which is welded to it for the purpose of raster formation is. The photoconductive layer is then pressed into the grid openings. This electrophotographic plate is intended to complete an electrophotographic process which is the subject of U.S. Patent No. 2,297,691 . Although this document also mentions the recording of halftone images by means of a halftone screen, there is no information about the design, location and operation of such a screen.

The rasterization of the US Pat. No. 2599542 has the disadvantages that it is difficult to carry out and that, since it is made purely mechanically, it cannot exceed a certain limit number. It also does not allow exposure through the base plate, since it is made of an opaque material.

All known methods and devices also suffer from this fundamental deficiency for the exposure of 35mm films for amateur cameras not to be suitable.

The invention has the task of providing an electrophotographic Develop a process that can also be used for thermoplastic image recording and results in 35mm electrophotographic film used in amateur cameras can be exposed and a resolution as well as a halftone reproduction such as a photographic film shows.

This object is achieved in that a recording material such is used with a grid-like intermediate layer in which the grid is formed from an opaque, electrically conductive material.

The invention therefore provides for the grid in the form of a conductive layer relocate. Such layers can now be combined with particular advantage rasterize photographic reproduction and etching processes. As examples are the manufacture of optical line grids and display tubes for color television called. In addition, the grid is in a place where particularly high resolving power is achieved, namely immediately below a very thin one photoconductive layer. The union of grid and photoconductive layer brings also because of the special advantages, because for good resolving power on a conductive one Grid layer just at this one; Body care must be taken.

Such grid-like intermediate layers with the specified design cause positive and negative charges to lie close to one another. Without such a network would result in a more uniform charging of the layer, what brings the aforementioned impoverishment of image contours with it.

The electrophotographic processes of the invention can be used for electrophotography as well as copying technology can be used to advantage.

In an apparatus for carrying out the above-mentioned method with a recording material made of a transparent, electrically conductive, optionally a substrate of an intermediate layer having a free lenticular surface and a photoconductive layer, with an exposure station, an image receiving material, a transfer station, a battery, a DC-DC converter, an imaging station and an image viewing station and optionally an image cutting station also required according to the invention that they be a recording material with a grid-like Has intermediate layer, in which the grid consists of an opaque, electrically conductive material is formed.

According to the invention, this device is also used as a transmission station a base preferably made of glass for the recording material and a pressure device congruent with the base or coils for rolling up and Keeping the image receiving material taut.

A recording material with a grid-like intermediate layer in which the grid is formed from an opaque, electrically conductive material is, in an embodiment of the invention, also for a device for implementation of the above-mentioned method used with a recording material from a transparent, electrically conductive, optionally a free lenticular lens Co-operating layer support having surface, furthermore with an intermediate layer and a photoconductive layer and one together with the recording material image receiving material that can be unwound from a common reel, an exposure station, optionally a transmission station, a device for separating the image receiving material from the recording material, a battery, a DC voltage converter, an image generation station, an image viewing station and possibly an image cropping station.

These devices for performing the above method can have the shape of a camera in a further embodiment of the invention, the necessary additional parts in addition to the usual equipment, in particular one transparent support with a conductive layer and the photoconductive layer, a Battery, a DC voltage converter for the supply voltages, contact devices, Contains tools for converting the charge image into a visible image as well finally, optical means for viewing this image.

Furthermore, when using a camera as a device for implementation of the above method required that the photoconductive layer after underlay with a conductive layer on a flat or slightly cylindrically curved, preferably from .Glass existing solid base is applied, and that for contacting of the image receiving material with the photoconductive layer a congruent pressure device or special means for rolling up and holding the recording material taut are provided.

The photoconductive layer is also considered to be expedient to apply to a tape or film coated with a conductive layer, and even before the exposure, possibly even on the supply roll with the image receiving material to contact, so that the DC voltage to charge the insulating layer except during exposure can remain permanently applied, and that the tape or the film with the photoconductive layer after exposure inside or outside the The camera is separated and reused in the form of an endless loop or on a special role wound up will. Especially for color film recordings it may be appropriate to use the image receiving material and / or the recording material To be provided with a lenticular grid on the back for the purpose of taking pictures according to the known lenticular process.

With a camera equipped in this way, the various operations for contacting, call charging, exposure and conversion of the charge image into a visible image, e.g. B. toner image, necessarily coupled with the tape transport. This camera can also have a cutting device for separating the images contain.

These and other features of the invention are illustrated in FIGS F i g. 1 to 9 illustrated embodiments explained.

F i g. 1 shows a schematic side view of the arrangement of the individual layers together with their carrier and the pressure plate before contacting, FIG. 2 the same arrangement after contacting. The individual components are: photoconductive layer 1, which is located on the glass substrate 2 and is underlaid with the conductive, opaque, preferably mesh-like interrupted intermediate layer 3. The image receiving material consists of the transparent film 4, which is covered with the likewise transparent, electrically conductive layer 5 and the highly insulating layer 6, hereinafter referred to as the image layer. The flat plate 7, which is preferably made of glass, represents the pressure plate. In FIG. 2, the objective 8 is also shown, which creates a light image on the photoconductive layer 1 through the electrically conductive intermediate layer 3 designed as a mesh electrode.

The network structure of the conductive intermediate layer 3 has the consequence that the light image acts on the photoconductive layer 1 in the form of discrete points of light. This subdivision is particularly useful if the intention is to transform the charge image into a streak image using the thermoplastic process, since a periodically curved surface appears as a luminous surface in the streak beam path. Without the network structure, only the area border would be visible in the playback picture. In addition, the network-like subdivided exposure to light has the advantage that tunnel-like zones of increased conductivity are formed within the photoconductive layer, which counteract a widening of the image point due to the finite layer thickness of the photoconductive layer 1, especially with a small aperture of the imaging optics. In the usual electrophotographic image reproduction using a toner image, the subdivision can also lead to an improvement in the halftone reproduction.

F i g. Finally, FIG. 2 also shows the two connection terminals 10 and 10 11, which are connected to the conductive layers 3 and 5 and to which, for example the DC battery 9 can be connected. To on the insulating layer 6 to record a charge image corresponding to the photograph can be followed in two ways will.

The first way presupposes that the image layer 6 is already charged before contact is made, for example by a corona discharge or by contact with an electrode carrying DC voltage. After the contacting, the image layer 6 is then discharged to different degrees locally by exposure of the photoconductive layer 1. During the discharge, the terminals 10 and 11 can be short-circuited, or a voltage of such polarity is applied that the discharge process is supported. The timing of the process is shown in FIG. 3 shown. F i g. 3a relates to the illuminance E on the photoconductive layer 1, FIG. 3 b on the charge density q on the image layer 6. At time t1, the image layer is charged to the charge density q1 6, wherein t "is the contacting and at the same time the exposure, t3 occurs indicates the time of the separation of the image receiving material from the photoconductive layer 1. After After the contacting, the charge density decreases as a result of the charge transfer to the photoconductive layer 1 and then runs at an exposed image area according to curve q ″. At an unexposed and therefore almost insulating point of the photoconductive layer 1, however, the charge gradually sinks according to curve q ″ The entirety of the picture shows the charge.

The second way is characterized in that the image layer 6 is only charged during the contacting. For this purpose, for example, the battery voltage 9 can be applied to the terminals 10 and 11 and exposed at the same time. Larger charge differences are obtained, however, if, as in FIG. 4 shown, moves. According to this method, the image layer 6 is initially charged uniformly through the photoconductive layer 1 by applying pulsating direct voltage to the terminals 10 and 11 and, if necessary, uniformly preexposing it. Pulsating direct voltage has the advantage over static voltage that a stronger dielectric remanence or a greater polarization charge is obtained. F i g. 4 a shows that the applied voltage U1 is reversed at the point in time t., At which the image irradiation begins. Uz then represents the voltage curve in the exposure period. F i g. 4 b shows the course of the illuminance. The curve E1 relates to the uniform pre-exposure of the photoconductive layer 1 to promote the call charge, while the curve E2 represents the course of the illuminance during the exposure to the image to be recorded. The curve F i g shows the course of the charge density as a function of time. 4 c. Without additional exposure, the charge density would increase according to curve q), with additional exposure according to curve q1. After reversing the polarity of the voltage, the charge density first drops and then runs at a light image area according to curve q "but at a dark image area according to curve q, '. At time t. The image layer 6 is detached from the photoconductive layer 1. What is essential is, that the detachment does not take place until some time after the exposure and that the voltage remains applied during this time so that any inertia phenomena of the photoconductive layer 1 can also be evaluated to reinforce the charge image twice the field strength acts on the image layer 6 than without this additional measure. This feature also contributes to increasing the sensitivity 6 has the greater capacity, with approximately the same dielectric Zitätskonstante the two layers is therefore proposed to choose the thickness of the photoconductive layer 1 to be significantly greater than the thickness of the image layer 6. According to a further proposal, the storage capacity of the image layer 6 can be increased significantly if it consists of a ferroelectric or contains ferroelectrics added . This group of substances includes, for example, seignette salt, barium titanate and certain phosphates. Their dielectric constant is between 300 and 3000 and thus exceeds the dielectric constant of conventional photoconductors such as selenium and antimony trisulfide by 50 to 500 times. As a result of their high dielectric constant, the materials not only store a significantly larger charge than other insulating materials, but they also show the appearance of dielectric remanence, which corresponds to permanent magnetism.

So that the image layer 6 remains transparent despite these admixtures, it is proposed to put the substances in a highly insulating transparent plastic of approximately the same occupancy index and possibly also with a wafer-thin layer of this plastic without any admixtures. Even so-called electrets can be used as materials for the highly insulating layer. As is well known, this denotes substances which, when heated, under the influence of a field and subsequent cooling take on permanent polarization.

The charge image generated in this way can either be immediately converted into a visible one Image converted or kept for some time before conversion if for that care is taken that the image layer 6 during storage with a high quality Insulating material is covered, which prevents the discharge of the charges. To this Purpose is suggested to use the back of the image receiving material as well to cover a highly insulating layer and the tape with the recorded The charge images are wound onto a drum in a spiral, as is usually the case with film material. Preferably, however, the charge image is taken immediately after the recording converted into a visible image using known methods. As an illustration Fig. 5 shows a cross section through the image conversion result Image receiving material. The three forms of image recording are shown: a) Charge image, b) Reformation image for viewing in the Schlieren beam path, obtained obtained by the method of thermoplastic image recording, c) toner image by the electrophotographic process.

The notations are the same as in Figs. 1 and 2. F i G. 6 shows schematically the mechanical and optical structure of a roll film camera according to the suggestion. It consists of the housing 12 with the lens 13. Except for one viewfinder, not shown, it contains the magnifying glass 14 for viewing the playback image, which is illuminated by the ground glass 15. At the location of the photograph to be recorded is the glass plate 16 (2 in F i g. 1) with the net-like conductive layer 3 in FIG. 1 facing the image receiving material 17 (4 to 6 in FIG. 1). The transparent image receiving material 17 (4 to 6 in F i g.1) is between the Supply roll 18 and the take-up roll 19 connected to one another via the two movable rollers 20 and 21 inserted so that the image layer 6 of the photoconductive Layer 1, as in FIG. 2 is shown facing. With the two rollers 20 and 21, a slip-free drawing of the film onto the glass plate 16 (2 in FIG. 1) can be achieved with the photoconductive layer 1. Are the roles in the position 20 ', 21' shown with broken lines, the film is with the photoconductive layer 1 brought into contact. It becomes useful in this Position held under tension by means of spring force. After completing the exposure process, which, as described, leads to the build-up of the charge image, becomes the roller mechanism moved back from position 20 ', 21' to position 20, 21. It should be mentioned that the Roller 20 only touches the edge of the film in order to dissipate the recorded charges to prevent, the roller 21, however, lies in its entire width on the film base at. If necessary, the electrode 22 is also connected to the roller mechanism 20, 21, it serves to spray - charges by means of Koran discharge, if the picture layer 6 should be charged before contact is made. After the exposure and charging process, the film is moved so that the charge image in front of the Ground glass 15 arrives. In this position the charge image becomes a visible image transformed, in the thermoplastic process by heating, in the usual electrophotographic process Powder application process. The image can be viewed through the magnifying glass 14. All handling operations are appropriately coupled with the conveyor belt. Also can for A cutting device may be useful in removing the images. Not shown are the electrical aids, among them z. B. Contact rails for the conductive Film layer. These contacts can, for example, be on both sides of the focusing screen 15 be provided. With a suitable design of the film, the contacting but also across the film at a point between two successive images be made. It is also advantageous to use the electrically conductive layer 28 (5 in FIG. 1) between two successive images. These Measures are particularly indicated when the conductive layer is intended to be heated by means of Joule heat in order to convert the heat effect on the particular Constrain image.

F i g. 7 shows the special case that the photoconductive layer 26 (1 in F i g. 1) not on a solid base but like the image receiving material is also applied to a flexible film. This particular arrangement has the advantage that the contact between the photoconductive layer 26 (1 in F i g. 1) and the image receiving material 27 to 29 (4 to 6 in FIG. 1) already from Beginning to exist. In this way adjustment and contact difficulties become avoided. It is also possible to use the image layer 29 (6 in FIG. 1) beautiful to charge while in storage in the supply roll. In Fig. 7 designated 24 (2 in FIG. 1) the transparent base for the photoconductive layer 26 (1 in Fig. 1). 25 (3 in FIG. 1) is the conductive layer which is subdivided into a network. With 27 is the base of the image receiving material, 28 is a transparent one Conductive layer and 29 the image layer on which the charge image is recorded target. It is provided that the film with the photoconductive layer 23 (1 in F i G. 1) and the image receiving material 4 to 6 in FIG. 1 after recording the Separate charge image from each other.

If photoconductive layer 23 (1 in FIG. 1) consists of one in the Darkness highly insulating material, so the double film has 24 to 26 and 27 to 29 according to FIG. 7 still has the further advantage that the charge image before the conversion may be stored in an optically evaluable image for a longer period of time can without fear that the charge image will be lost due to external influences. The double film can then be used like photographic film with a latent charge image Camera removed and later optically or with an electronic Sampling method are evaluated.

A camera with the necessary modifications for the use of this double film is shown schematically in FIG. 8 shown. The figure shows the camera housing 30 with the lens 31, the focusing screen 32 and the viewing magnifier 33. The layer group 24 to 26 according to FIG. 1 is located on the storage drum 34. 7, shown in FIG. 8 is designated 35, in close contact with the group of layers 27 to 29 in FIG. 7, shown in FIG. 8 is denoted by 36. Behind the image window 37, the layer group 35 is peeled off from the layer group 36 and arrives at the take-up drum 38. The group 36 with the charge image continues to run over the rollers 39, 40 and is finally picked up by the take-up drum 41 after the charge image has been converted into a visible image. However, if the charge image is to be converted into a visible image outside the camera, the double film is placed on the take-up drum 41 without being separated. F i g. 8 shows, as a further detail, a bar grid 42 which is intended for magnifying observation of the deformation image in the dark field. The webs are inclined towards the lines of sight in such a way that the eye is not struck by direct light, but only perceives the light that is diffracted by streaks.

Finally it should be mentioned that the recording process also suitable for recording colored photos using the lenticular lens method. If the double-layer film 24 to 29 shown in FIG. 7 used, so you can z. B. according to FIG. 9 congruent lens grids 41, 42 on the two outer sides of the double layer film 24 to 29. As is well known, the color impression comes with Lenticular process comes about that light sources, which from different Directions, different colored filters corresponding to the primary colors, happen. As indicated, z. B. the light rays from the direction 43 a green image, the rays from the direction 44 correspond to a red image. on of the photoconductive layers 1 and 26, respectively, the red image and the green image are displayed effective in different places and will be in the same position on the image layer 6 transferred in the form of juxtaposed charge picture elements. When playing of the charge image that has been converted into a deformation image in this way one just like in the case of recording, in which one rays of light hitting the lenticular screen pass in different directions, colored by different filters. In further It is proposed to design this method for color image recording, to provide only the image receiving material 4 to 6 or 27 to 29 with a lenticular screen and the photoconductive layers 1 and 26, respectively, through the image receiving materials 4 to 6 or 27 to 29 to expose through. In this case difficulties will arise the assignment of the picture elements to the lenticular screen avoided.

Claims (11)

Claims: 1. Electrophotographic process for the production of toner images, in which a recording material with a transparent, electrically conductive layer carrier (2), an electrically conductive intermediate layer (3) and a photoconductive layer (1) - optionally having a free, lenticular surface optionally pre-exposed - charged, with one of an insulating layer (6), an electrically conductive layer (5) and a - placed image-receiving material into contact, - the charged layer carrier (4) existing -where appropriate - if appropriate, insulating, having optionally a free, lenticular lens-like surface A direct voltage is applied between the intermediate layer (3) and the electrically conductive layer (5), exposed imagewise, the image receiving material is separated from the recording material and the charge image formed on the image receiving material is developed with a toner, characterized in that a recording material with a grid-like intermediate layer (3) is used, in which the grid is formed from an opaque, electrically conductive material. 2. Electrophotographic process for the production of Deformation images in which a recording material with a transparent, electrically conductive layer support (2), an electrically conductive intermediate layer (3) and a photoconductive layer (1) - optionally pre-exposed - charged, with one of a thermoplastic layer (6), an electrically conductive layer (5) and an - optionally insulating - layer support (4) existing - if necessary charged - image receiving material brought into contact, between the intermediate layer (3) and the electrically conductive layer (5) applied a direct voltage, imagewise exposed, the image receiving material separated from the recording material. the thermoplastic Layer (6) is heated and cooled, characterized in that a recording material with a grid-like intermediate layer (3) is used in which the grid is made an opaque, electrically conductive material is formed. 3. Electrophotographic Electrolytic development process for the production of images, at a recording material with a transparent, electrically conductive - if necessary having a free lenticular surface - layer carrier (2), one electrically conductive intermediate layer (3) and a photoconductive layer (1) - optionally pre-exposed - with one of a current-sensitive layer (6), an electrically conductive layer (5) and an - optionally insulating, optionally having a free lenticular surface - layer support (4) existing image receiving material brought into contact between the intermediate layer (3) and the electrically conductive layer (5) applied a direct voltage, imagewise exposed, the image receiving material is separated from the recording material, if necessary heats the image receiving material and, if necessary, the image on the image receiving material is made visible or amplified by a chemical reaction, characterized in that, that a recording material with a grid-like intermediate layer (3) is used in which the grid is made of an opaque, electrically conductive material is formed. 4. Device for performing the method according to the claims 1, 2 or 3 with a recording material made of a transparent, electrically conductive - possibly having a free lenticular surface - Support of an intermediate layer and a photoconductive layer, with a Exposure station, an image receiving material, a transfer station, a Battery, a DC / DC converter, a development station and an image viewing station - optionally with an image cropping station - characterized in that they comprises a recording material with a grid-like intermediate layer, at which formed the grid from an opaque, electrically conductive material is. 5. Apparatus according to claim 4, characterized in that the transfer station a base preferably made of glass for the recording material and a pressure device congruent with the base or coils for rolling up and Contains holding the image receiving material taut. 6. Device for implementation of the method according to claims 1, 2 or 3 with a recording material a transparent, electrically conductive one - possibly a free lenticular lens Surface having - substrate, an intermediate layer and a photoconductive Layer and one together with the recording material from a common spool Developable image receiving material, an exposure station - possibly one Transfer station - one. f Device for separating the image receiving material from recording material, a battery, a DC voltage converter, a development station and an image viewing station - possibly with an image clipping station - characterized in that it is a recording material with a grid-like Has intermediate layer, in which the grid consists of an opaque, electrically conductive material is formed. 7. Apparatus for carrying out the method according to claims 1, 2 or 3, in particular in the form of a camera, characterized in that, in addition to the usual equipment of a camera, it also has the necessary additional parts, in particular the image receiving material (35, 36), means for rolling up (18, 19, 34, 41) as well as means (20, 21, 37, 39, 40) for making contact and for keeping the recording material taut, finally also aids for converting the charge image into a visible image and optical means (14, 15, 32 , 33) for viewing this image (Figs. 6 and 8). B. Apparatus according to claim 7, characterized in that the recording material (35) consists of a photoconductive layer (26) which over-; drawn tape or a film (24) is applied and already before the exposure - possibly already on the supply roll (34, F i g. 8) -is in contact with the image receiving material36, so that the DC voltage for charging the insulating layer (29) of the image receiving material except for Exposure can remain constantly applied, and that the tape-shaped recording material (35) after exposure inside or outside the camera of the image receiving material detachable and reusable in the form of an endless loop or on a special one Roll (38) can be wound up (Figs. 7 and 8). 9. The device according to claim 7, characterized in that the image receiving material (36) - optionally also the recording material (35) - has a layer support (42a or 41a), the free surface of which carries a lenticular lens (42 or 41) (F i g. 9). 10. Device according to claims 7 to 10, characterized in that the various devices for making contact, Charge to contact the materials for exposure and development of the charge image in a visible image necessarily coupled with the conveyor belt are. 11. Device - according to at least one of claims 7 to 10, characterized in that that it contains a cutter for separating the developed images. Considered publications: = German Auslegeschriften No. 1022 092, 1041061; French Patent No. 1105,940; U.S. Patent Nos. 2,297,691, 2,298 732, -2299542.