DE2120650A1 - Process for generating particle-free image edges in photoelectrophoretic imaging - Google Patents

Description

Patent attorneys Dipl.-Ing. F. "Weickmann, 2120650

Dipl.-Ing. H. Weickmann, Dipl.-Phys. Dr. K. Fincke Dipl.-Ing. F. A. Weickmann, Dipl.-Chem. B. Huber

XPR

CORPORATION, Square, Rochester, Η.ΐ

8 MÜNCHEN 86, POST BOX 860 820 MÖHLSTRASSE 22, CALL NUMBER 48 3921/22

<983921/22>

Process for generating particle-free image edges in photoelectrophoretic processes Image generation

The invention relates to a method for generating particle-free image edges in the subtractive photoelectrophoretic process Imaging with electrically charged photosensitive particles in an electrically insulating Carrier liquid that forms image areas on an electrode after exposure to activating electromagnetic radiation and create image borders.

The photoelectrophoretic imaging process is through U.S. Patents 3,384,488, 3,384 x 565, 3,384,566 and 3,383,993 known. It works on the principle of the migration of electrically charged light-sensitive particles from an injecting electrode to a blocking electrode upon exposure to light within an electrical Field, which creates complementary images on the two electrodes. The photosensitive particles are dispersed in an electrically insulating carrier liquid and take on an electrical self-charge Interaction with the liquid or as a result of the action of a charge source.

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Voltages connected to the electrodes generate an electric field which causes large numbers of charged particles to be attracted to act as the injecting electrode, whereby an opaque layer is formed. It is believed that the particles in the opaque layer which absorb light undergo charge exchange with the injecting electrode, thereby reversing the direction of the electric force vector acting on a particle and causing the particle to migrate away from the injecting electrode. The barrier electrode has a dielectric layer that prevents charge exchange with the incoming particles. The particles that are peeled off from the opaque layer produce a negative image (in a photographic sense) while the particles remaining on the electrode produce not only a positive image, but also opaque image edges. The edges of the image often make the image unsuitable for commercial use. The image on the barrier electrode is free of image edges, but it cannot always be used commercially either, since it is a negative image.

The object of the invention is the photoelectrophoretic To improve imaging processes so that particle-free image edges are present. In particular is thought of those images that are generated by the subtractive photoelectrophoretic image generation process are. Here all execution forms should this Processes are included which produce an image and image edges on one of the electrodes used. There on both Electrodes are used to generate images, both are conveniently referred to as an imaging electrode. In the following description, however, the image forming electrode is the one on which an image and image edges appear *

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The above-mentioned object is achieved for a method of the type mentioned in accordance with the invention in that that either in the image areas or at the edges of the image an electrostatic charge with one of the initial polarity of the particles of opposite polarity is applied to the particles and that the particles in the Image areas and at the image edges exposed to an electric field generated with the electrode and a separating electrode will.

So there are electrostatic charges applied after imaging, which change the electrical forces that act on the image-forming particles. The electrostatic charge is applied over limited areas of an imaging electrode and / or separating electrode using a novel process. When a charge pattern is applied to a separating electrode (an electrode similar to the blocking electrode), the field between the electrodes changes due to a voltage difference acting on them. Therefore, different forces act on the particles inside and outside the charge pattern, which forces remove the particles in one area from the particles in the other area on one and the same electrode. If a charge pattern is applied directly to an image of an image generation electrode, the charge changes the polarity of the particles in the image edges and the image areas, so only the particles in one of these areas are removed when a field is applied between a separating electrode and an image generation electrode . The indicative separation electrode refers to the jeae electrode, which is a Fe ^ ä er? Eur-f, which causes a separation of a picture from its bill ^ 'rr'ern. A ^ bertrat-unctselektorifi- an electrode to which a ¹ ^ iIa an- ^ e ^ o- ^ e "v / irö, cas a ^ ildrtmd leaves or not.

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Further features and advantages of the invention emerge from the following description with reference to the figures. Show it:

1 shows a perspective illustration of an arrangement for generating photoelectrophoretically images and for generating an electrostatic charge pattern on a roller electrode, 2 shows a side view of a corotron with a shield for generating the electrostatic charge pattern,

Fig. 3 is a side view of the shield shown in Fig. 2,

Fig. 4 is a side view of an arrangement for photoelectrophoretic Imaging according to an embodiment of the invention and

Fig. 5 is a side view of an arrangement for photoelectrophoretic Imaging according to another embodiment of the invention.

In Fig. 1 is an arrangement for photoelectrophoretic Creation of an image 1 and image edges "2 as well as for separating the image from the edges. The image is created by the action of light 4 on an image material suspension 3 with the simultaneous generation of an electrical Field generated between a roller electrode 5 and a plate electrode 6. After imaging on of the plate, the roller is once again passed over the image suspension, but this is an electrostatic one Charge pattern 8 is provided which is aligned with the image. The charge pattern is made with a corotron 9 and a Shield 10 is created when the roller electrode and the corotron are connected to a voltage source 11 and 12 are.

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The photoelectrophoretxsche image suspension 3 contains photosensitive particles dispersed in an electrically insulating carrier liquid. If all light-sensitive particles in one and the same wavelength band of electromagnetic radiation sensitive react, the image suspension is monochromatic. Do different particles react within two or If there are more wavelength bands of electromagnetic radiation, the image suspension is polychromatic. Under the The term "light-sensitive" should be understood to mean the properties of a particle, the energy of the acting To absorb radiation and at least in the presence of an electric field a change in it To experience self-charge polarity through interaction with a charge source, i.e. a charged conductor. The radiation causing the charge exchange is called "activating electromagnetic radiation", sometimes it can also be briefly referred to as "light". An image suspension with three different types of particles, namely with yellow, magenta and cyan pigments, each for blue, green and red electromagnetic radiation is sensitive, is a polychromatic image suspension that is fully colored Can generate images. The above-mentioned patents contain descriptions of various substances, which are suitable for photosensitive particles and electrically insulating carrier liquids.

Take the light-sensitive particles of a monochromatic and a polychromatic image suspension an electric self-charge on contact with the carrier liquid. The particles can also by acting a charge source can be charged in an electric field, i.e. by the action of the charge flow of a

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Corotrons. The charged particles experience a force, when exposed to an electric field, for example with the roller electrode 5 and the plate electrode 6 is generated. The plate electrode has a transparent layer 14 on conductive material, for example made of tin oxide, on a transparent base 15 »made of glass, for example. The roller electrode has one inner core 16 and an electrically insulating outer

ψ layer 17. An electric field is generated between the roller electrode and the plate electrode when a voltage difference is generated between the conductive roller core 16 and the layer 14- on the plate electrode. If, for example, the image material particles have a negative intrinsic charge, the roller electrode is connected to a negative voltage and the plate electrode is connected to earth potential, in the process the particles are bound to the plate layer 14. If light from the light source 18 acts on the particles, they experience a charge exchange with the layer 14 and are moved towards the roller electrode. This is provided with the insulating layer 17 in order to prevent a charge exchange between it and the particles. For better "understanding it can be assumed that the particles are insulating in the dark, but become conductive when exposed to light, whereby they take on the charge of the plate when they are exposed to light or are exposed to activating electromagnetic radiation. As already described, the It is possible to reverse these functions so that the roller electrode is transparent instead of the plate electrode.

The light 4 is with image-wise distribution through the

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Lamp 18 and a transparent original image 19 is generated. The light image is with an optics 20 through the transparent Plate electrode through focused on the interface between it and the electrically attracted image particles.

A two-dimensional image of the original 19 is produced on the plate electrode 6 if it or the roller electrode is provided with an image suspension layer. The roller electrode can move over during its rotation the image substance suspension are guided, with a potential difference is generated between the plate electrode and the roller electrode and the light image on the image substance suspension is projected. The image 1 is therefore line by line in the gap formed between the roller electrode and the plate electrode. The gap is the interface between the roller and the plate and optionally filled in with image suspension. At this point it should be noted that the plate is also supported by a cylinder can be replaced, instead of the full image exposure with the lamp 18 and the optics 20 also a Slot scanning can be performed. The original can then also be opaque. The respective execution the arrangement for photoelectrophoretic imaging is therefore not intended to cover the basic idea of the invention in any way Restrict way.

The image edges 2 arise from the fact that the image covers a smaller area than it is covered by the image substance suspension is formed on the electrode. The edge of the image can be avoided if the image size is limited to areas which are equal to or larger than the dimensions of the indexing and blocking electrodes. Such a solution of course, limits the versatility of imaging.

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The invention now provides a method for producing Images of different formats based on the subtractive principle, with no opaque image edges are.

An edge-free image is produced by electrically separating the image material particles in one area from corresponding particles in the other area. The two areas are normally image area 1 and the edge area. The case also occurs in which the edge of a certain image format should remain or in which only a very specific area is required within an image. The invention also enables the generation of images with a border of very specific dimensions or the cutting out of image parts. The terms “image area” and “edge area” are therefore intended to relate to areas which are complementary to one another and which can contain all particles adhering to an electrode.

The electrical separation of particles in image areas and edge areas takes place by applying an electrostatic charge to certain areas of the image substance suspension and / ■ through the action of an electric field on the entire image substance suspension. An embodiment of this method is shown in FIGS. 1 and 4-, FIG. 5 shows a further embodiment. In Fig. Λ and 4- the steps of applying an electrostatic charge and the action of an electric field on the image material suspension are the same. carried out in good time, in the embodiment shown in FIG. 5 they are carried out separately. In Fig. 1, an electrostatic charge pattern 8 is generated on the roller electrode 5, which is aligned with the image area 1 on the plate electrode 6. The potential difference between the roller core 16 and the grounded plate

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layer 14 generates an electric field which is applied in the same way to the image substance suspension in the image areas and acts on the edge areas. In the areas provided with an electrostatic charge, the electrical Field changed so that the particles can only migrate in one of the two areas. Are all image particles for example negatively charged on the plate electrode 6, the electrostatic charge pattern 8 is negative, and the potential connected to the roller core is positive with respect to the grounded plate, so that the particles in the edge areas migrate onto the roller, while the particles in the image areas migrate to the plate electrode remain.

In the embodiment shown in Fig. 5, the electrostatic charge applied directly to the image suspension. The dielectric constant of the particles at Darkness is selected to be higher than the dielectric constant of the carrier liquid. Therefore the electric fields between the corotron 21 and the plate electrode 24 converge on the particles, see above that charge is applied to the particles and also with charges of opposite polarity on the conductive Layer of the plate electrode 24 is combined. The charge applied to the particles in this way has a polarity opposite to that of the charge polarity already present on the particles. The shield 22 prevents an application of the charge to the particles in the edge areas. This results in a charge on the particles in the image areas and the edge areas with opposite polarity after the corotron passed over them became. This means that when the roller 23 moves over the plate 24 with the voltage switched on the particles in one area on the plate 24

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while the particles stay in the other area the roller electrode 23 migrate. Have the image particles for example a negative charge, the! Corotron 21 brings a positive charge to the particles in the image areas on, and a negative potential with respect to the grounded plate 24 is applied to the roller electrode 25 turned on. The positively charged image particles in the image areas migrate to the roller 23, while the negatively charged particles in the edge areas on the plate electrode 24 remain.

The electrostatic charge patterns are generated in both embodiments with a corotron and a shield. Corotron 25 and shield 26 in FIGS. 2 and 3 are detailed representations of corotrons 9, 21 and 28 and shields 10, 22 and 29 in FIGS. 1, 4- and 5. The corotrons contain a corona wire 30 which is connected to a voltage source 11, 31 and 32 of FIGS. 1, 4 and 5, respectively. The shield or the housing 35 can be conductive or non-conductive and is optionally connected to a voltage. According to a preferred embodiment, the housing j 5 consists of conductive material, for example aluminum, and it is electrically connected to a potential, for example ground potential. The electric field between the wire 30 and the housing 35 ionizes the air rinis around the wire, creating a flow of positive and negative ions and electrons whose direction depends on the direction of the field, ie on the relative polarity of the potential difference between the wire and dep. Housing depends. The housing 35 is provided with an opening 36 which is at a distance from the surface to be charged. The ions and / or electrons pass through the opening 36 when close to it

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opening a charged conductive surface is arranged, as indicated by rollers 5 and 37 in Figs. 1 and 4 and Figs Plate 24 in Pig. 5 is formed. The cross section of the flow of electrons and / or ions through the opening 36 depends on the dimensions of this opening. A narrowing of the width of the opening 36 also has the effect a constriction of the charge flow, with complete Closing the opening also cuts off the flow. This throttling effect is provided by the shield 26 achieved. This also exists, but not necessarily, made of a conductive material, for example aluminum, and is also, but not necessarily, grounded. The shield is part of a hollow cylinder 38 with an opening 39 »which is provided in its wall is, thereby forming left and right fingers 41 and 4-2. The concentric cylindrical plates 43 to 46 are attached to the fingers 41 and 42 and together with these form a telescopic lock with which the Size of the opening, 39 can be brought down to zero.

The plate 45 has an edge 48 which corresponds to a recess in the finger 41 is adapted. This has an edge 49 which is adapted to a recess in the plate 43. the Edges and depressions are dovetail-shaped so that the plate 43 is attached to the finger 41, but can be displaced parallel to the axis of the cylinder 38 · Similarly, the sinker 44 has a Edge 50 * the one dovetail lock with one Forms recess of the plate 43, the plate 43 has an edge 51 »äie a corresponding locking with the Plate 44 forms. Projections 52 and 53 on plates 44 and 43 serve to limit the movement of the plates to the left and form stops for the edges 51 and 49.

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The edges 50 and 48 strike the edges 51 and 49 and limit the movement of the plates to the right. Right finger 4-3 and plates 45 and 46 are similar Connected together so that the plates 45 and 46 telescopically outward toward the left finger 41 are moved »The maximum dimension 59 of the opening 39 results when the plates 42, 43 »44 and 45 in their fully retracted arcs are as shown in Fig. 3 is. The dimension 59 is preferably selected so that that they are less than the length of a corotron, however equal to or greater than the width of a roll or plate is to which kadung is to be applied * The panels 43 and 45 are moved towards each other by the width of the Opening 39 to decrease. The rope 54 and the pulleys 55 and 56 serve to enlarge or reduce the opening 39. The rollers are rigid with the inner wall of the cylinder 38 connected and rotatably mounted. The ends of the rope are connected together so that there is a forms a continuous loop and can be guided on the should, Me left plate 43 is with one side the loop with an element 5? connected to the plate 45 is to the other side of the loop with an element 58 connected. When the rope is counterclockwise (FIG. 3), the plates 43 and 45 move towards one another and reduce the opening 39. If the rope is led clockwise, the opening is enlarged.

The shield 26 is held with fasteners 60 and 61, in which the axes 62 and 63 are rotatably mounted. These are in turn connected to the cylinder 38 by means of spokes 64 and 65 connected. The opening 36 in the corotron housing • 35 is made by rotating the shield around the corotron 25 open and closed around.

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The width of an electrostatic charge pattern applied by a shielded corotron is controlled by rotating the shield until fingers 41 and 42 face opening 36. The width is decreased from a maximum value given by dimension 59. The reduction takes place by to the value zero, in that the plates 43 to 46 are moved telescopically towards one another. The length of the electrostatic The charge pattern is set by the time that the opening 36 is open. The opening 36 completely prevents a charge flow when the Cylinder 38 is rotated so that the body 66 of the opening facing. The electrostatic charge pattern 8 in Fig. 1 is generated by the corotron 9 with a predetermined Speed is moved relative to the surface of the roller 5, i.e. the roller is rotated. The cylinder 38 of the Shield 10 is initially arranged so that a body 66 closes opening 36. The cylinder 36 is rotated relative to the corotron 9 by hand or with a suitable drive mechanism to the fingers 41 and 42 and facing the opening 39 of the opening 36. A charge flow can therefore hit the insulating surface of the roller 5, whereby the "leading edge 68 of the charge pattern 8 is formed. The side edges or Boundaries 69 and 70 of the charge pattern 8 are determined by the Width of the opening 39 is determined. The rear edge (not shown) of the charge pattern 8 is made by rotating the Cylinder 38 is formed back to its initial position, with the opening 36 of the corotron housing through the body 66 is closed. The charge pattern is on the roller 37 in Fig. 4 with the corotron 28 and the shield 29 generated in the same way. The same is true of the image material suspension of plate 24 in FIG generated in the same way with the difference that the charge on the image material particles on the plate 24

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is brought.

In the embodiment shown in Fig. 4, the roller electrodes 71> 37 and 72 are similar to the roller electrode 5 in Fig. 1 and have a conductive inner core 73 and insulating outer layers 74- · It should be noted, however, that the dielectric or insulating layers on each of the rollers are not of absolute importance, but are provided so as not to create an electrical connection between the rollers and the conductive plate when insufficient amounts of the insulating liquid are present. Like the plate 6, the plate 75 is provided with a transparent and conductive layer 76 on a transparent base 77. A layer of photoelectrophoretic image suspension 78 is applied evenly to plate 75. An image with a smaller format compared to the plate 75 and therefore with an image border is generated on the plate 75 by activating electromagnetic radiation acting on the image substance suspension through the transparent electrode, while the barrier electrode roller 71 moves from left to right across the plate 75 will. Assuming that the Bildstoffteilchen have a negative intrinsic electrical charge of the core of the roll ¹ is connected JΛ with a negative potential relative to the grounded plate, so that the measures taken by the light! Particles are removed from the plate and migrate to the roller electrode 71, whereby a positive image with a border remains on the plate (the exposure device is not shown in FIG. 4 for the sake of simplicity, it is designed (however, similar to the device in FIG. 1 and operates with a lamp, a transparent image and an optical system).

If the photo is interrupted, the Holle 57 is displayed via the image generated on the plate 75 is guided. The role 37 is

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moves away and rotates at a speed at which the leading edge and the side edges (similar to edges 68 to 70 in Figure 1) a charge pattern on its surface aligned with the leading edge of the image on plate 75 i.e. the charge oyster is aligned with the image. The side edges of the charge meter are on the side edges of the image aligned by opening 39 between the fingers 41 and 42 of the shield 29 adjusted accordingly is. The leading and trailing edges of the charge pattern and the image are aligned by the Charge flow of the corotron 28 for a side pawn is generated by the speed of rotation of the roller If the particles on the plate 75 are to be charged negatively, the ball 37 is positive Potential connected to the grounded plate 75, the! Corotron 28 is «it a negative potential connected to the hell, it then becomes a charge pattern (similar to the charge bus 8 in Fig. 1) from negative »charges on the roll 57. I moved roll 37 over the plate 75, ao become "the negatively charged particles of formation attracted by the field between the roller and the plate electrode in the band area, however, the particles remain in the image areas on the plate because the field in these areas either increases is weak to effect transmission, or is aligned with the hell and not the plate, so that the negative particles remain on the plate. The negative charges on the reel do not migrate to the Plate as they will be more attracted to the conductive core of the roll.

In the example above, the field between deai Charge pattern on roller 37 and plate 75 have a direction that further development of the particles in

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the image areas, i.e. these particles are exposed to light and a field a second time exposed. However, the intensity of the field is usually not strong enough to allow photoelectrophoresis generate, in which 'the image particles have a charge with Replace the plate 75 when exposed to light. The reason for this is that on the surface of the roller 37 there is insufficient Charge can be accumulated which generates a field strength sufficient for photoelectrophoresis. The problem is that the charge is dissipated by flashing the air around the roller.

A bordered image is formed on the platen 75 when the barrier electrode roller 71 is passed over the platen. The edge is removed from the plate when the separation roller 37 is passed over. The image will be removed when the Transfer roller 72 is passed over the plate. the Image particles of the image are negatively charged, therefore generate the positive voltage of the source 31 on the Roller 72 and the grounded plate 75 an electric field, with which the image can be removed from the plate 75. In this embodiment, a roller 72 is used Paper tape or recording medium 82 out to record the image. The image can be on the tape after a the known methods are fixed, for which purpose, for example, a synthetic resin is sprayed on. The tape comes with a suitable guide device on the surface of the roller 72, which is similar to the rollers 71 and is moved and rotated at a speed which has a relative speed with the value zero between the circumference of the rollers and the plate electrode.

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After imaging, the edge of the image is separated from the image and the image is transferred to belt 82. the The plate and the rollers are brought to their initial positions, their surfaces are cleaned of residual image suspension and it becomes fresh image suspension applied as a layer on the plate 75 in order to prepare this for a next image formation.

In the embodiment shown in FIG. 5, rollers 85, 86 and 23 have a conductive one, similar to roller 5 Core 87, which is provided with an insulating layer 88. The main reason for the presence of the insulating Layers 88 are to prevent electrical connection between a roller and the plate. the Plate 24-, like plate 6, has a transparent conductive layer 89 on a transparent base 90 » A uniform layer of photoelectrophoretic image suspension 91 is applied to the plate 24. the Voltage source 32 supplies the required potentials to the various electrodes and to a! Corotron 21. An image is generated with the image material suspension by the roller electrode. 85 is passed over the plate, for example a negative potential to the core of the roll 85 is turned on. The image suspension is an activating electromagnetic radiation by means of a suitable device (for example lamp, transparency, optics) exposed through the transparent plate. If the image particles have a negative charge, they exchange charge with the plate when exposed to light 24 and migrate to roller 85, with a positive image with a margin on the plate, remains. The particles in the image areas are exposed to light and to electrical Field exposed a second time when the second barrier electrode 86 is moved across the plate.

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The corotron 21 and the shield 22 are then passed over the re-irradiated image in order to generate an electrostatic charge pattern on the particles in the image areas. The shield 22 is rotated to open the opening 36 when the corotron 21 is over the leading edge of the image. The opening will be closed when it arrives at the trailing edge of the picture. The width of the opening 39 of the shield is adjusted to match the width of the image. The corona wire of the corotron is connected to a positive voltage so that a flow of positive charges towards the grounded plate 24 is generated. The positive charges are deposited on the image particles in the image areas, while the particles in the edge areas retain their negative charge because the fingers 4-1 and 42 of the shield 26 shield the positive charge flow towards the particles in the edge areas. Then the roller 23 (a transfer and separating roller) is passed over the plate, and since it carries a negative voltage with respect to the grounded plate, the positively charged particles in the image areas are attracted to the roller 23 and are stored on the paper tape 92 away. The image can be fixed on the tape by one of the known methods, for which purpose, for example, a synthetic resin is sprayed on. ;

I ί

The embodiment shown in Fig. 5 has some significant advantages). One of these parts of the gate admits that the charge ni <| ht on a permanently insulating surface is accumulated, as is the case with the embodiment shown in FIG. Another benefit is there in the fact that the charge meters appear more easily on the picture the plate electrode can be aligned. In the In the embodiment shown in FIG. 4, the corotron 28 must be used the charge indicator on the part 37 in alignment with a «

Apply imaginary image, after which the imaginary image on the surface of the roller 37 on the real image on the Plate 75 needs to be aligned. Another advantage is that the charge is not carried on a surface that is exposed to the air, which can potentially cause air flashover and other undesirable Spark formation could be generated.

The embodiments shown in FIGS. 4 and 5 can be combined so that a charge pattern is applied to a Separating electrode and is applied directly to image material particles. For example, a shielded corotron of the type shown in FIGS. 2 and 3 between rollers 37 and 72 above plate 75. The polarities of the various roles and the plate as well as that of the image material particles and the corotrons must then be relative be adjusted to each other so that the respective consequences of separation occur.

The plates 6, 24 and 75 can also be replaced by transparent drums. A slot scanning can be used can be used in place of the exposure device shown in FIG. Different image suspension layers can be generated, for example a roller can be coated with image suspension instead of the plate be. The relative polarities of the voltages connected to the various components and the polarities the charge on the particles as well as the corotrons can be changed. The polarities can be selected so that always an image is transferred to a transfer electrode, so that the transfer electrode is also a Separating electrode is.

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Claims (11)

- 20 - Patent claims: Process for generating particle-free image edges in subtractive photoelectrophoretic imaging with electrically charged photosensitive particles in an electrically insulating carrier liquid, the image areas and edges of an image on an electrode after the action of activating electromagnetic radiation generate ,, characterized in that either in the image areas (1) or at the image edges (2) an electrostatic Charge with a polarity opposite to the initial polarity of the particles is applied to the particles and that the particles in the image lines (1) and at the image edges (2) an electric field generated with the electrode (6) and a separating electrode (5) be set. 2. The method according to claim 1, characterized in that the application of the electrostatic charge and the Generation of the electric field can be carried out simultaneously by removing the electrostatic charge first applied to the separating electrode (5) and this as well the electrode (6) can be provided with a potential difference, the charged surface (8) of the separating electrode (5) is brought close to the particles present on the electrode (6). 3. The method of claim 1 _t wherein the electrostatic charge is applied by a corotron (21) which is guided over the located on the electrode (24) particles (91), wherein the particles (91) on the image edges be covered by a shield (22). 109846/1679 4. The method according to any one of claims Λ to 3 »characterized in that the particles (9Ό in the image areas are transferred to a recording medium (92) after they have been separated from the particles at the image edges · 5. The method according to any one of claims 1 to 3 »characterized in that the electric field between the Electrodes (23, 24) for attracting the particles of the image areas is used on a recording medium (92) .. 6. The method according to any one of claims 1 to -3 »thereby characterized in that an electrode is used with a recording medium on which the particles are initially bound and the image and the edge of the image are generated. 7. The method according to any one of claims 1 to 6, characterized in that in the one with the separating electrode (5) and the electric field generated by the electrode (6), the particles of the image edges are removed from the electrode (6) and that the particles of the image areas remain on the electrode (6). 8. The method according to any one of claims 1 to 7 »characterized in that the electrical KLd by connection a potential difference across the separating electrode (86), which has the shape of a roller, and the electrode (24) is generated and that both electrodes (86, 24) are moved relative to one another in the presence of an electric field. 9. The method according to claim 4, characterized in, that the particles by connecting a potential difference to an image transfer electro <ienrolle (23) and the Electrode (24) are removed, whereby the image transfer «- 109846/1679 Electrodemiolle (23) and the electrode (90) relative to one another be moved. 10. The method according to claim 9 »characterized in that the charge is applied to the! Particles in the image areas while the edges of the picture are shielded, and that the application of the charge between the exposure the separating electrode (86) and the transfer electrode roller (23) takes place » 11. Method according to one of the preceding claims, characterized in that the electrostatic charge is generated by charging the separating electrode and by direct charging of the particles is generated in the image areas or the image edges. 109843/1873 Empty line