DE1297475B - Method and apparatus for making electrophotographic images or copies - Google Patents

Description

The present invention relates to an electrophotographic Process in which a photoconductive layer is charged, imagewise exposed and is developed, with correction of the set point of charge and / or exposure Charging and / or deviating in the known size and local distribution Exposure values and devices for carrying out the method.

Even if the known processes are generally satisfactory Lead to results, there are cases in which with the known methods and facilities a satisfactory result cannot be obtained. In particular With the known methods, deviations from the target value of the exposure can be determined z. B. bad due to differences in the intensity of the illumination of an original balance. In some cases, such irregularities only arise by using the known methods themselves. B. an exposure process takes a very long time, so in the meantime the on the photoconductive Charge applied to the recording surface disappear, and despite uniform exposure the result is a picture that shows strong differences in the individual zones.

In the photographic imaging of locally different mean exposure levels having images, as they are, for. B. occur in radar screens, several means of compensation have been used. So were z. As used about the screen Laid graduated filter, the waste sorption in the middle areas is at its maximum and towards goes against the edge areas to the value zero. Likewise, by means of a corresponding additional electronic intensity control or density control of the electron beam, it can be weakened in the central areas of the screen, but the achievable brightness can be increased in the case of strong deflections corresponding to the edge areas of the screen.

The object of the invention is, in the case of a previously known legal deviation from the target value of the charge value at the time of exposure and / or to compensate for a deviation from the target value of the exposure, which enables evenly developed images. This task consists e.g. B. at the Recording of screen images in polar coordinates displaying Braunschweig tubes, # z. B. the mentioned radar screens, in which the electron beam respectively migrates radially from the center over the screen to on the next pass to be offset at a certain angle. The lighting density is im middle area of the screen highest and decreases, inversely proportional to that Radius, outwards, so that the production of satisfactory pictures is practical is impossible.

This object is achieved according to the invention in that the areas which at the time of exposure is lower than the nominal value previously known Show charge values and / or the areas with previously known values compared to the target value lower exposure values in relation to the size and local distribution of these Deviation relatively higher charged and / or relatively more developed.

Compensation via the charge can be achieved in that to carry out the charge an elongated, along its extent an effect gradient having charging electrode in a movement perpendicular to its extension in a short distance across the surface to be charged. It has proven itself here this movement as a rotation around the center point or an end point of the electrode perform. The method according to the invention can be used here to due to the effect gradient of the electrode, an even charge despite the rotary movement to reach; in this case the effect should be approximately linear along the electrode increase. When used for the reproduction of an electron beam tube The process shown in polar coordinates must have an effect on the outer areas of the electrode increase more than the radius.

With the help of this embodiment of the invention excellent, evenly developed images are achieved, although the target exposure level differs from Center changes towards the edge of the recording area. Are instead of z. B. at Radar screens present line images with images with flat areas to produce local deviations from the target value of the exposure level, so are when developing these images, use the aids known to those skilled in the art for better To apply development of planar areas. Such tools are z. B. special Development electrodes or a screening of the applied during exposure Image.

To compensate for the development, z. B. an isolated one Developer electrode are locally charged differently, which then is brought into the range of action of a developer powder. In another The process step is different depending on the charge Dense powder adhering to the developer electrode is transferred to the recording surface.

The increase in the effectiveness of the electrode required according to the invention can be achieved in different ways. Thus, an elongated electrode, which is guided over the surface to be charged, can have a uniform, elongated conductor charged to a potential, which is partially covered from the outside by an enveloping screen. The required characteristics can by the shape of non-shielded opening and by the spacing of the actual electrode are changed to the screen. The entire electrode can also have different distances from the surface to be charged along its extension. According to a further proposal, an electrode with a non-uniform cross-section can be used: the effectiveness decreases with increasing radius. The effectiveness can also be influenced by appropriately arranged screen wires. If a very weak electrode wire with a high resistance is used, a voltage drop can be achieved on the same so that a non-uniform effect is achieved as a result of non-uniform electrode voltage. Something similar can be achieved in that the electrode is broken up into a series of individual electrodes which receive different potentials by means of a voltage divider. Electrode elements arranged next to one another at different distances can also be used to apply a charge which has a potential gradient. In accordance with the invention, uniformly developed images are now obtained without the use of visual inspection of interfering filters or special electronic devices.

An increased charge corresponds to an increase in sensitivity. This can essentially be explained by the fact that with a relatively highly charged photoconductive layer, even relatively small exposure levels are sufficient to cause a sufficient discharge of the exposed areas. Such a weak one Exposure that has only a relatively small decrease in resistance to the exposed Areas of the photoconductive layer caused, namely still gives sufficient large discharge currents in these exposed areas when the charging potential is chosen accordingly high. The unexposed areas remain at the same time this high charging potential, so that sufficient potential differences between Ensure good development in exposed and non-exposed areas.

Instead of such a differently strong charge, however, it is also possible a different level of development or a combination of both applied will.

The invention is explained in more detail in the following description of exemplary embodiments and the drawings. It shows FIG . 1 shows a cross section through a rotating loading device designed according to the invention, FIG . 2 shows a plan view of the device according to FIG. 1, # F i g. 3 is a view of an embodiment of a corona charging electrode for charging a circular area; F i g. 4 and 8 show two further exemplary embodiments of a corona charging electrode in cross section; F i g. 5 to 7 and 9 schematically show alternative solutions of the exemplary embodiment according to FIG . 3, fig. 10, 12 and 13 exemplary embodiments for two-dimensionally effective charging electrodes for achieving a predetermined non-uniform charging, FIG . 11 is a side elevational view of a device for unevenly charging a rectangular electrophotographic plate, FIG . 14 shows, in cross section, an unevenly charged developer electrode coated with developing powder, and FIG. 15 and 16 each show a schematic representation of an exemplary embodiment of a cyclically operating electrophotographic device for recording cathode-ray tube screens.

As an exemplary embodiment, FIG. 1 describes a charging device which can be used in the production of images of the representations on the screen of cathode ray tubes.

By means of the motor 10 , the shaft 11 and with it the corona discharge device 12 connected to it is rotated via a belt drive 9; the rotation takes place above the electrophotographic plate 13 supported by rails 16 within a plane parallel to this plate. As shown on the basis of the elevation in FIG . 2, the corona discharge device 1L2 sweeps a circular area of the plate 13, the diameter of the circular area corresponding to the effective length of the discharge device. A suitable design of the discharge device is intended to ensure that the central areas of the circular surface are charged to a lower potential than the peripheral areas.

A charging electrode in the form of a corona discharge device suitable for achieving this different charge is shown schematically in FIG. 3 and 4 shown. The design of this device goes back to a known charging electrode which has a thin wire-shaped electrode within a shield 18 having an opening. The shield 18 surrounds the electrode wire 17 in a circular manner and leaves only a narrow slot 19 directed towards the surface to be charged free. According to the present invention, the width of this slot is varied along the electrode: the slot becomes wider towards the ends, and thus the effect of the discharge electrode 17 also becomes stronger in the end regions of the discharge device than in the central regions. The screen having the slot 19 thus controls and limits the charging current emitted by the corona discharge device.

On the basis of FIG. 2 it can easily be seen that, if a conventional corona discharge device were used, the inner regions of the plate 13 would be charged more than the outer ones, since the ends of the device 12 move at a constant angular velocity over the surface to be charged at a significantly greater speed than that more about the middle parts. As a result, however, in the middle areas, as a result of the lower speed, the effect of the corona discharge on a surface area is longer in time and is able to generate a higher potential. In order to compensate for the difference in the relative speeds, it is necessary to increase the effect of the charging electrode towards its ends.

In the present application, however, it is not only desirable to have a circular Uniformly charge surface within a rotational movement of a charging electrode, rather, it should be achieved that the applied charge density differs from the average Ranges linearly towards the circumference. It is therefore necessary that the The effect of the charging electrode is stronger from its middle section towards the ends as linear, for example approximately quadratically, increases.

In the case of the charging electrode used in the exemplary embodiment, the charge released corresponds to the width of the axial slot. For the present application, the charging electrode was therefore according to FIG . 3 in such a way that the slot has its minimum width in the middle areas of the electrode and that it increases more than linearly towards the ends.

In the schematically illustrated embodiment, it has proven to be advantageous to design the charging device in such a way that an inner, circular surface area about 5 cm in diameter was charged to a potential of 100 volts, while outwardly up to a diameter of about 18 cm the potential rose to 1000 volts. However, these figures should only be used as guidelines, since the appropriate charge depends essentially on the development method used. If, for example, the scattering method is used for development, so. it may prove convenient to use a voltage range of 100 to 1400 volts. If, on the other hand, the development is carried out by spraying powder or as a liquid development, much lower voltages result in developable images. On the other hand, it has been shown here that, quite generally, higher voltages in the photoconductive layer result in higher sensitivities and a harder gradation.

However, the width of the slot 19 in the shield electrode 18 is not the only factor which influences the effectiveness of a charging electrode. In addition to the time it can act on the plate, the diameter of the corona discharge wire, its voltage, the distance between it and the surface to be charged, the shape and the electrical potential of shields, external fields and the like must also be taken into account will. A number of these influencing factors can be used to create a gradient charging electrode which can be used in accordance with the invention. One of these possibilities is shown in FIG. 5 explained. The corona charging device 12 shown there is like that of FIG. 1 and 2 held on a shaft 11 . However, this does not attack in the middle of the device, but at one end. The effective length of the charging electrode therefore does not need to correspond to the diameter of the circular area to be charged, but only to the radius. The charging electrode of FIG . 5 is shown in longitudinal section. The width of the slot formed by the shield 18 remains constant over the entire length of the charging electrode. The effect gradient that moves to the left, i.e. H. Seen from the pivot point outwards, increases is achieved here in that the actual corona discharge electrode 17 changes in diameter: At the pivot point the discharge electrode begins with a large diameter, and towards the outside its strength decreases according to the increase in effectiveness to be achieved.

Another embodiment of a loading device is shown schematically in section in FIG. 6 shown. The increase in activity is achieved here in that the lying at the same potential, carried out with the same intensity corona discharge electrode 17 with the same width of the slit of the exhaust shield 18 in the areas where a greater effect to be achieved, closer to the to be charged plate 13 is introduced. The F i g. 6 shows the plate 13 supported in strips 16 , the rear side of which is earthed. The corona charging electrode 12 is arranged so as to be rotatable about the shaft 11 and is designed such that it describes a conical surface during rotation which has a greater height in the central regions than in the edge regions. Since the effect of the electrode depends on the distance, the edge area will be charged more than the central area.

To achieve a different effect, according to FIG. 7 the voltage drop occurring on a wire is exploited. As the cross-section of the electrode shown schematically next to the high-voltage source shown in symbols shows, a current flows through the corona discharge electrode here. The corona discharge electrode 17 is represented by a high resistance wire. While the outer end is connected directly to the high-voltage terminal of the high-voltage generator 15 , the current is fed from the earth terminal of the high-voltage part via the resistor 21 to a point lying within the axis of rotation 12. There is thus a potential in the central area of the charging electrode 12 which corresponds to the voltage drop across the resistor 21, while an effect is achieved in the outer areas which corresponds to the full voltage of the generator 15. By appropriately designing the wire, it can be achieved that not only a linear voltage drop occurs along the wire; by using a wire whose unit resistance changes along its length, a change in potential can also be obtained which is proportional to a higher power than the first of the change in length. If the change in resistance is caused by a change in the cross section, then, acting in the same way, that of FIG. 5 described effect.

The exemplary embodiments according to FIG. 3 to 7 can be further characterized vary in that in place of a waste formed from sheet metal shield 18, a grid or a number of wires are arranged as shown in F i g. 8 are shown under the same reference number 18 . This arrangement is also known, and according to the known devices, the one orona discharge electrode described in the previous exemplary embodiments can also be formed by a plurality of such electrodes, for example three, as shown in FIG . 8 , can be replaced. Another variant of the discharge electrodes is shown in FIG . 9 shown. In principle, the design is similar to the arrangement according to FIG. 7, but the voltage drop causing the differential does not occur in the corona discharge wire 17 itself, but in a separate chain of resistance. The individual needles or tips 23, which are connected to individual points of the voltage divider 22, act here as the actual corona discharge electrode 17. With this form of training, it is particularly easy to control the potential gradient arbitrarily. It can not only be influenced by the choice of the tapping points of the voltage divider 22; Another variable factor is given by the distance or the density of the needles 23 . As usual, shields can also be arranged here as sheet metal surfaces or as grids made of wires for controlling or modifying the charging effect. The charging devices described so far are not only suitable for the purpose mentioned at the beginning of compensating for different illuminance levels. In a number of electrophotographic devices, quite complicated guide devices are provided for sweeping the plates to be charged with a charging electrode. When using charging electrodes designed according to the invention, these complicated guides can be avoided and replaced by a simple rotary or pivot axis. The different charging effects that usually occur here are compensated for by appropriately designing the effect of the charging electrode, as described above. The use of the above-mentioned charging electrodes therefore enables a considerable improvement and simplification of the existing devices. In Fig. 10 shows the charge of a plate 13 by means of a flat charging electrode, which therefore cannot be moved over the surface to be charged. The charging electrode of FIG. 10 has two interwoven corona discharge electrodes 17 , which are excited by direct current surges, the current surges or half-waves of the two electrodes being shifted from one another by 180 'in time. The exciting high-voltage generator 15 has three output terminals, one of which is grounded, while terminals 25 and 26 supply the high voltage. Above and below the high voltage source, the voltages that can be taken from the individual inputs are indicated in their curve shape. The corona discharge electrodes themselves are arranged as intertwined spirals, which in the middle areas of the surface to be charged have larger winding distances than the peripheral areas. By the unequal spacings to the invention required under various charges be achieved.

It is at the discretion of the designer to achieve the desired charging characteristics by appropriately shaping the electrodes. It is advantageous in this embodiment of the charging electrode that a movement or. Guide device for the charging electrode is completely eliminated and the effects of relative speeds do not need to be taken into account. A further embodiment of a loading device for a plate with non-uniform application of the charge is shown in FIG. 1 1 shown. A corona discharge device 12 is guided over a plate to be charged on support elements 16 by means of a drive device 10 in such a way that the distance to the plate and thus also the effect of the charging electrode on the plate changes during the guide. The transport is carried out by a two-flight, counter-rotating worm 27 in conjunction with a correspondingly trained nut running on this. The plate is charged to a higher potential on the side of the closer distance from the charging electrode than on the opposite side. Such a device can prove useful when it comes to charging a photoconductive layer with a high dark decay and then exposing the plate with a complete image. Since the first charged parts of the photoconductive layer at the time of exposure show a greater decrease in charge than the last charged areas because of the longer past charging, it is advantageous to raise the initially charged areas to a higher potential, i.e. H. with greater effect, to recharge. At the time of exposure taking place in all areas at the same time, a uniform charge is then also present.

In the previous processes it was assumed that the non-uniform Charging is intended to affect the electrophotographic plate prior to exposure. Appropriate However, results can also be obtained by applying the toner powder is effected by means of a special developer electrode, which is used to transfer the Developing powder is used by being electrostatically charged, developing powder binds to itself and this then during the development process to the to be developed Plate gives up. The developer electrode should have a voltage that about the potential of the heavily exposed and therefore heavily discharged surface areas currently corresponds to the development. The same potentials from developer electrode and the surface to be developed then cause that in these heavily exposed areas no transfer of colored powder takes place. As in the present invention The task is based on the assumption that the illuminance levels differ greatly To compensate, it must be expected that the most exposed parts of the image will be over the entire image area does not have approximately the same potential, but that, for example with the distribution of brightness given by radar screens of round search systems there is a much stronger discharge in the central districts than in the outskirts. But with this it becomes necessary for development and at the same time to use a developer electrode to compensate, the potential of which corresponds to that on the to be developed plate adapted to the prevailing potential curve after exposure and that has low values in the center of the developer electrode, while it rises linearly towards the outskirts.

A developer electrode with charging device that meets these requirements is shown in FIG. 12 shown. The developer electrode 29 consists of a graphite layer or graphite disk 30, which is circular in shape according to the area to be developed. The graphite layer is enclosed by a conductive ring 32 which is connected to one pole of the high-voltage source 31 which causes the charging. The other pole of the power source is grounded, and via a resistor 32 a connection leads to a conductor 35 which is arranged in the center of the graphite disc and is conductively connected to it. With this, however, the current flows from the power source via the resistor 32, here determining the basic voltage through a voltage drop, through the graphite disc 30 to the conductive ring 32. Due to the resistance characteristics of the graphite disc, there is a potential gradient on it, which causes a corresponding gradient in the charge . By selecting and changing the cross-section or the thickness of the graphite disk 30 in an annular manner, it is also possible to achieve a stress gradient other than a linear one. In general, the course of the thickness of the graphite disc along a radius should be chosen so that the potential distribution results in a corresponding charge distribution on the developer electrodes 29 to be charged underneath, so that their potential distribution corresponds to the course of the deviations of the charge pattern to be developed from the nominal value.

A second example of a developer electrode designed according to the invention is shown in FIG. 13 shown. A number of concentrically arranged conductive rings 36 are provided above the developer electrode 29 and are connected to taps of a voltage divider 37 which is fed by means of the high voltage source 31. The taps are provided in such a way that the ring with the largest diameter is connected to the tap with the highest voltage and that the ring that is furthest inward is connected to the tap with the lowest voltage as is the case with the graphite disc according to FIG. 12 can be achieved by the changing cross section.

It is also known to bring about the development of charge images by transferring the powder onto the image to be developed by means of a flake uniformly coated with developer powder. The compensation of different exposure or different charging to be effected according to the invention can also be brought about by a corresponding, in FIG. 14, sheet 61 carrying developer powder 62 is used. However, in such a developing sheet to be used according to the invention, the developer powder is not uniformly distributed on the surface of the sheet 61 , but its distribution depends on the non-uniformity of the charge image to be compensated. The application of the developer powder in the predetermined distribution can be effected, for example, in that the sheet 61 is charged with one of the aforementioned corona charging devices. Dusting the sheet consisting of an insulating material, for example a plastic film, with an electroscopic developer powder62 then results in the uneven distribution shown, in which less developer powder is applied in the center of the sheet 61 than in its peripheral areas. It has proven useful here to effect the charging of the sheet in such a way that, during development, an essentially complete transfer of the toner particles takes place in the peripheral areas, while a less dense transfer takes place in the central areas.

Another method for the uneven development that is intended in the given sense is to be specified below. In cases in which a photoconductive plate has been uniformly charged and uniformly exposed, a developing electrode will also generally have a uniform voltage which corresponds approximately to the potential which prevails in the exposed parts of the image. Changes from this optimal voltage of a development electrode lead to changed image densities, and only in the case of very large deviations does background development occur, i.e. H. the evolution of the lights, on. According to the invention, a non-uniform charge image can lead to normal development results in that, for example, by means of a device according to FIG. 13, the development electrode also has a non-uniform potential distribution, which corresponds to the potential profile of the charge image deviating from the target value. A conductive electrode, comparable to the electrodes 36 of FIG. 13, penetrating developer dust cloud is charged approximately to the potential that the electrodes adjacent to the penetrating particles carry. Through the potential distribution, however, the development, i. H. the precipitation of the powder, because the powder is deposited more densely in the areas in which there is a greater voltage between the overlying rings 36 and the charge image.

In addition to the described embodiments of charging electrodes, combinations of the individual features of the electrodes are also conceivable. For example, the device of FIG. 3 with a variable slot width can also be inclined towards the surface to be charged, as shown in FIG. 6 was explained. It has already been mentioned that the charging electrode with the conical corona discharge electrode according to FIG. 5 is constructed with high resistance in the charging device according to FIG . 7 could be used. It has also already been shown that the invention not only serves the purpose of compensating for non-uniform exposures, but that non-uniform charges or also non-uniform discharges over time can be compensated for by the appropriate methods and means.

It will now be described by means of an exemplary embodiment how an electrophotographic apparatus designed according to the invention is formed from C, C ore. According to FIG. 15 is a movable in the direction of the arrow, a photoconductive layer belt 38 is arranged, which interrupts its movement in the loading and in the exposure position while the development, transfer and erasing device are passed during the movement.

In the first phase, the loading device 39, which corresponds to that of FIGS. 1 to 3 is rotated over a circular area of the belt 38. In accordance with what has already been described above, a charge is applied to the circular surface, which leads to low potentials in the central areas of the surface and to relatively high potentials on the circumference of the surface.

After the end of the charge, the belt 38 , which is joined to form an endless loop, is moved on over the transport rollers 40 until the charged area reaches the exposure position. The tape is brought to a standstill here, and when the tape is at a standstill, this is directly, i.e. H. in contact or quasi-contact, exposed. After the predetermined exposure time has elapsed, the belt 38 starts up again. It passes the developer container, from which developer particles are scattered over the charge image of the belt 38. When the tape continues to run and runs over the following transport roller 40, the excess developer particles falling off the tape are collected by means of the container 43.

Next, the now developed powder image reaches the transfer station where it is brought into contact with an image receiving material 45. The paper is pulled off the roller 46 and brought into contact with the belt 38 via the transport and pressure rollers 47. During the intimate contact with the belt 38 , the powder image, supported by a further electrostatic charging device, is transferred to the image receiving material 45, which is then after passing the second deflection roller 47 after fixing the transferred image by melting the toner powder by means of an ultra-red radiation source on the roller 48 is wound up. The tape then runs back to the originally described starting position via the erasing or cleaning device 49, the cyclical operation of the device ensures fast, smooth operation, and the special type of charging enables the device to be special, not yet released Tasks to be sufficient. Another embodiment of an electrophotographic device is shown in FIG . 16 shown. For the same purpose, namely to produce images of representations on a cathode ray tube screen, a hexagonal photoconductive plate drum 51 is provided here, which can be rotated into the individual treatment stations by means of a drive that can be operated step by step. The continuously operated drive motor 52 is followed by an electromagnetically actuated clutch 53 , so that the disk 54 driven by it rotates or stands still in accordance with the actuation of this clutch. The belt pulley 56 and, with it, the drum 51 connected to it, are operated from the pulley 54 via the belt 55.

During each phase of rotation of the drum 51 , one of the six surfaces is covered by the surfaces shown in FIG. 6 trained corona charger 39 charged. At the same time, the surface charged in the previous working process is exposed through an image of the screen of the electron beam tube 41 of a circular search device by means of an objective. At the same time, the one following to the right of the six surfaces is developed by means of a developing device 57 known per se. The surface following to the right transfers its image in a transfer device 58 to an image receiving material, where it is fixed in a fixing device, while nothing takes place on the fifth surface and the sixth surface is cleaned of image residues by means of the cleaning device 59. The individual stations arranged around the drum 51 are designed in such a way that they are pivoted out of the path of movement of the drum while the drum is rotated by a section.

Even if the invention is essentially based on exemplary embodiments with respect to caused by polar representations on cathode ray tube screens Brightness distribution is described, it is by no means restricted to this, but they were just both as a field of application and as a drastic example of use picked out on a plethora of possibilities.

Claims (2)

Claims: 1. An electrophotographic process, wherein said charging a photoconductive layer, is imagewise exposed and developed, with correction of the target value of the charging and / or exposure in previously known size and spatial distribution of different charge and / or exposure values, d a d u rch gekennzeichn et, that the regions, which develops at the time of exposure with respect to the target value prior art lower charging values indicate and / or the areas with respect to the target value prior art lower exposure values in proportion to the size and spatial distribution of these deviations relatively higher charged and / or relatively more will. 2. The method according to claim 1, characterized in that a toner layer of non-uniform layer thickness is applied to the photoconductive layer to develop the charge image. 3. The method according to claim 1, characterized in that an unevenly charged developer electrode is used for development, through which a non-uniform field strength acts on the photoconductive layer. 4. Device for performing the method according to one of claims 1 to 3, characterized in that the charging electrode or charging electrodes used to charge the photoconductive layer has or have a gradient of action. 5. Apparatus according to claim 4, characterized in that the charging electrode is movable relative to the photoconductive surface. 6. Apparatus according to claim 4 or 5, characterized in that an elongated charging electrode (17) about a perpendicular to the surface (13) extending through the center of rotation axis (11) is rotatable and its effect on the photoconductive surface of its near the Rotation axis located section increases towards its ends. 7. Apparatus according to claim 6, characterized in that the charging electrode is provided with a shield (18) a is to face the charged photoconductive surface (13), extending in the longitudinal direction of the charging electrode (17) slot (19) is limited, the width of which corresponds to the desired gradient of action, preferably increasing more than linearly towards the ends of the electrode facing away from the axis of rotation. 8. Apparatus according to claim 7, characterized denotes Ge, that the shielding is provided as a grating (18) formed between the or the charging electrode (17) and the photoconductive layer, the a corresponding effect the potential gradient is given. 9. Apparatus according to claim 8, characterized in that the grid is formed by wires (18) running parallel to one another. 10. Device according to one of claims 4 to 9, characterized in that the radius of curvature of the charging electrode (17) facing the surface to be charged (13) corresponds to the desired gradient of action. 11. Device according to one of claims 4 to 10, characterized in that the charging electrode (17) is oriented obliquely to the photoconductive surface (13) to be charged, so that its part located in the vicinity of the axis of rotation (11) is at a greater distance from the As its end remote from the axis. 12. Device according to one of the preceding claims, characterized in that the charging electrode (17) is connected to a high voltage source (15) and the current flowing through it determines a potential profile which corresponds to the desired gradient of action. 13. The device according to claim 12, characterized in that a charging electrode (17) of different wire thickness is used, so that there is a potential profile corresponding to the desired gradient of action. 14. The device according to claim 13, characterized in that the high voltage source (15) is connected to a voltage divider (22) and that electrodes are connected to tapping points of the voltage divider whose free ends (23) facing the surface to be charged are arranged according to the desired gradient of action . 15. The device according to claim 4, characterized in that the charging electrodes (25, 26) are arranged side by side in a surface that their mutual distance and / or their distance from the surface to be charged corresponds to the desired gradient and that they alternate with one of them DC voltage surges feeding high voltage source (15) are connected. 16. The device according to claim 4, characterized in that the charging electrodes (17) are arranged as a plurality of concentric conductive rings (36) in an area whose distance and / or their distance from the surface to be charged corresponds to the desired gradient of action. 17. The device according to claim 16, characterized in that the rings (36) are connected to a voltage divider (37) which is connected to a high voltage source (31) . 18. The device according to claim 4, characterized in that the charging electrodes have a number of needle-shaped electrodes (23) directed towards the surface to be charged. 19. The device according to claim 4, characterized in that the photoconductive surface (13) is arranged obliquely to the path of the movably arranged charging electrode (12) so that the strength of the charge reaching the photoconductive surface by the respective distance of the charging electrode from the surface given is. 20. Apparatus for performing the method according to any one of claims 1 to 3, characterized in that a developer sheet with a gradient of action is used to develop the photoconductive layer, the developer powder in a distribution corresponding to the desired gradient of action on the surface to be developed for the photoconductive surface to be developed contains. 21. The device according to claim 20, characterized in that the developer electrode has a disk surface which is connected to the two poles of a high voltage source via leads arranged in such a way that the desired gradient of action is formed on it. 22. The device according to claim 21, characterized in that the cross section of the disc serving as a developer electrode is selected according to the desired gradient of action. 23. The device according to claim 20, characterized in that the developer sheet can be coated with developer powder with the aid of powder cloud dusting. 24. Device for performing the method according to one of claims 1 to 3, characterized in that the developer electrode consists of a number of planar annular concentric electrodes which are connected via a voltage divider to a high voltage source in such a way that different potentials are used to generate the desired effect gradient to be applied to the various electrodes.