DE2315763A1 - LOCKING DEVICE FOR COPY DEVICES - Google Patents

Description

Boeblingen, March 28, 1973 heb-oh

Applicant: International Business Machines

Corporation, Armonk, K.Y, 10504

Official File number; Registration

File number of the Anraelder: LE 972 003

Closure device for copiers

The invention relates to an exposure device for electrostatic Copiers for controlling the reflection of light and light directed onto a charged photoconductive surface Image / with a light source and an optical system for Illuminating an original plane and imaging an image in the original plane on the photoconductive layer.

In electrostatic copiers with a cascade developer, a photoconductive layer is electrostatically charged and then charged with exposed to the image of the original to be copied. This creates an electrostatic latent image in the photoconductive layer which is developed by strongly attracting the toner particles to the part of the electrostatic latent image that is still heavily charged after the exposure, big one, highly charged areas, which correspond to large black areas on the original, are generally used in a cascade developer developed only in the edge part of the large black area because the electrostatic field is in the edge or edge areas is strongly formed and concentrated between charged and adjacent, non-charged areas, so that the toner particles are most strongly attracted there. In the middle part of a large charged area, the electrostatic field is not like that

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strongly developed or concentrated that the toner particles are strong tightened enough so that this middle section appears faded and what remains is a development pattern known as edge development for large black areas.

For development facilities equipped with development electrodes and working magnetic brushes, the production has been good continuous Copies or halftone copies in which large gray and black areas of substantially uniform density develop have been improved more and more regardless of the fading occurring in the cascade developer.

With the ability to have large black areas that stand out through large Highly charged areas of the photoconductive layer resulted in a stronger tint, and the need for unused parts also increased precisely control the photoconductive layer. The tint of these areas must therefore be controlled more and more precisely because the photoconductive layer applied to a support is difficult to clean of non-transferred toner, the deposited in unused areas of the photoconductive layer and cannot be transferred because it is in the liormal area). of the copier no copy paper is fed to these areas. Also in electrostatic copiers is the cleaning system basically designed so that only the residual toner that remains on the photoconductive layer is removed, after most of the toner has been transferred to copy paper. If there is a large amount of untransferred toner the photoconductive layer remain, the cleaning system can basically no longer process these residual amounts of toner, and thus the cleaning of the photoconductive layer is insufficient. The faulty cleaning is reflected in toner deposits on the photoconductive layer, which in turn causes subsequent Exposure cycles the light is prevented from falling, causing additional toner to be knocked down at this point and the problem only gets worse.

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The one from the photoconductive layer in large, heavily tinted Toner removed from areas quickly overloads the cleaning system and in particular overfills its receptacle for the toner, thereby wasting toner material.

All previous techniques to solve the exposure problem go unused Parts of the photoconductive layer are directed to certain problems and, despite their general applicability, can Does not solve the problem of excessive tinting of all parts of the unused photoconductive layer.

In principle, the photoconductive layer applied to a support, such as a drum, will be wider than the one made Copy so as to ensure that all parts of the image directed onto the photoconductive layer are photoconductive on one part Materials. Thus there is on the photoconductive Layer Parts that are not exposed to the exposure from the image or that are on both sides of the image. This part of the photoconductive layer is developed with toner and goes through "the remaining procedural steps, if it does not otherwise treated. Since there is no copy paper in this part of the photoconductive layer, those that are strongly charged on this are Part of the photoconductive layer attracted and retained toner particles do not transfer and must pass through the cleaning station removed from the electrostatic copier. To avoid excessive tinting of these areas, So-called edge erase lamps were used so far, the light through a shield only on the edge sections of the photoconductive Throwing a layer that was outside of the image of the document to be copied. This discharge usually occurs after the exposure and before the development of the latent electrostatic charge image. Because the discharge lamps are the edge portions effectively expose, the photoconductive layer is conductive there and the charge in these parts of the photoconductive Layer drops to a residual value that is generally insufficient to attract and hold significant amounts of toner particles.

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to keep.

With the erase lamp process, parts of the photoconductive Layer exposed between images when the electrostatic copier is set for smaller copies and a portion of the photoconductive layer remains unused between the images. This process requires precise control the switch-on times of the extinguishing lamp.

Another solution to the problem has been proposed for the copiers, who expose the original receipt with a flash lamp. In such lighting systems, light can pass through a light guide, like optisch.leitende fiber bundles or similar devices and thrown onto the photoconductive layer at a point where the electrostatic charge is to be dissipated the tint of the charged but still unused parts of the photoconductive layer, such as the gaps between individual images, to prevent. However, this technique cannot be easily applied to an apparatus which uses scanning exposure is working.

The object of the invention is therefore to control the discharge and tinting of electrostatically charged photoconductive layers in the unused areas of the photoconductive layer, to reduce the tint of unexposed parts of the photoconductive layer which do not belong to the image produced. thus also an improved cleaning of the photoconductive layer in electrostatic copiers _e which can produce halftone copies.

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The object on which the invention is based is achieved by that a device is provided in the path of the light between the light source and the original plane, which the light beam in front Selectively interrupting impact on the template plane, deflects the light beam towards the photoconductive charged surface, exposes it there and thus discharges it.

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The arrangement is preferably such that the device can be actuated as a function of the relative movement of the light source with respect to the plane of the original and that in particular the device is a locking device which is adjustable in an open and a closed position.

summary

So that the photoconductive layer can be discharged in the part corresponding to the unused length of a 36 cm scan, if E.g. a sheet of paper with a length of only 28 cm is copied in the light path between the light source and the original plane a shutter or a reflector is provided, which reflects the light exactly as if an original on the original plane would be. This light reflector or shutter is operated so that it is in a position which is the end of the scan corresponds to a template with 28 or 36 cm or a different length if the copier uses other, non-standardized paper lengths is set. The shutter closes and thus offers the light rays emanating from the light source a white reflecting one The area that appears to the photoconductive layer like a white sheet of paper on the original plane in this area. When the light source is reversed or returned to the home position for another scan, remains the shutter closes and thereby discharges all parts of the photoconductive layer that the exposure station during the The return of the light source. This prevents tinting of the photoconductive layer in this area. At the At the end of the return movement of the light source, the shutter is opened at a point immediately in front of the edge of the original, so that at the beginning of the scanning movement of the light source, light falls from this onto the original document and its image passes through the from the Original reflected light is thrown onto the surface of the photoconductive layer. As a result, this layer is exposed and creates a latent electrostatic charge image that can be processed later. When the light source reaches the point

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the end of the scanning movement for the selected original size corresponds, the shutter is closed and the scanning cycle continued until the end of the full scanning movement. If there was no closure of the type described here, or this one would be left open during the last part of the scanning movement, not enough light was reflected on the photoconductive layer, because there is no original in this part of the original plane with which the photoconductive layer can be adequately discharged could. This results in a rather strong tint of the photoconductive layer because the electrostatic latent image projected thereon is essentially the same as if a thick one black area in the part of the template layer would be in which has no original »- This is especially true when operating an electrostatic copier with the original cover open, e.g. when making numerous one-sided copies or when copying a book.

But because the shutter closes and light is thrown from its underside onto the photoconductive layer, thereby discharging it When this area of the photoconductive layer is developed in the development station, the remaining charge is depleted the photoconductive layer fails to attract and hold toner particles, and therefore the photoconductive layer needs not to be cleaned so thoroughly at this point.

An embodiment of the invention is shown in the drawings and is described in more detail below.

It shows

Fig. 1 is a partial view of a scanning movement executing Light source with the reflective closure according to the invention,

Fig. 2 is a plan view of the template plane with the

Controls for actuating the shutter on the exposure device shown in Figure 1,

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3 is a sectional view taken along line 3-3 in FIG

Figure 1 and

FIG. 4 shows a schematic representation of a closure arrangement according to the invention shown in FIG exposure system containing.

In an electrostatic copier capable of making copies of originals to be reproduced, a photoconductive layer 10 is preferably provided on a rotating drum. So that the drum surface and the optics of the copier move synchronously, a pull rope 12 is moved synchronously with the drum rotation. Such a drive is described in US Pat. No. 3,654,640. A slight change may be necessary to adapt the scanning direction and movement of the light source. The pull cable 12 is attached to the exposure carriage 14 in such a way that it is moved from left to right when the pull cable is moved in FIG. A light source 16 is attached to the exposure carriage 14 parallel to an original plane 22. A parabolic mirror 18 deflects the light beams coming from the light source 16 and focuses them. The parabolic mirror 18 surrounds the light source 16 in such a way that it reflects the light emanating from the light source and partially reflects it onto the mirror 20 and from there onto the original plane 22. The parabolic mirror 18 is mounted around the light source 16 in such a way that the light reaching the original plane 22 is focused on a relatively narrow exposure field or exposure band which illuminates the entire width of the original over a small section of length. The parabolic mirror 18, the light source 16 and the mirror 20 are all fastened to the exposure carriage 14, the transverse movement of which causes the original plane 22 to be scanned due to the timed rotation of the drum with the photoconductive layer 10. The position of the parabolic mirror 18 ¹ , the light source 16 'and the mirror 20' indicates the position of these components after part of a scanning movement.

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In order to redirect the light rays reflected from the exposed part of the original plane 22 and the original lying thereon, a mirror 26 is attached below the point at which the exposure field from the mirror 20 illuminates the original plane 22. The mirror 26 directs the light rays reflected from the original onto the surfaces of the mirrors 28, 30 and 32. The mirrors 28 and 30

are attached to a transverse carriage. When moving sideways of the exposure carriage 14 by the pull rope 12 move Mirror 28 and 30 also in the horizontal direction with their car, but only half as fast as the car 14, so from Each point of the original plane 22 from an optical path of constant length to the photoconductive via the mirrors 26, 28, 30 and 32 Layer 10 remains.

FIG. 1 shows the entire exposure device fastened on the exposure carriage 14. This exposure device includes the parabolic mirror 18 and in it the light source 16, which the from Parabolic mirror 18 partially reflected light on the mirror collects and generates an exposure field on the original plane 22. According to FIG. 3, the outgoing from the light source 16 and Rays reflected by mirror 20 are reflected as far from reflector or shutter 42 as it is closed. If that Light reflected from the generally white or slightly tinted surface reflector 42 includes this the image transmitted through the rest of the optical system does not contain any information of the original or of an object on the original plane 22. The photoconductive layer 10 is exposed to a light which is transmitted uniformly and thus the photoconductive layer 10 is exposed exactly as through completely white original reflected light. Those reflected by the shutter or reflector 42 in the closed position Light rays discharge an electrostatic charge on the photoconductive layer 10 by the Kororia charging station 34 according to FIG. 4 was applied.

The photoconductive layer 10, which in the embodiment on

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is attached to a drum, it continues to rotate clockwise with it and the portion of the photoconductive layer exposed by the light reflected from the reflector 42 becomes on a development station working with magnetic brushes or a cascade development station working with developer electrodes passed by.

Figure 2 shows the shutter or reflector 42 in the copying position 42 '. The movement of the reflector 42 from the closed to the open position 42 is carried out by the oscillating axis 44, which rotates the rocker arm 46. The rotation of the rocker arm 46 is brought about by a control lever 48 shown in FIG. The control lever 48 has a stop surface 50 which strikes the adjustment stop 52 when the length of the desired scan is smaller than the largest possible scan of the copier. However, the stop surface 50 also strikes the end stop 54 so that the reflector does not close until the end of the longest permitted scan.

In order to open the reflector 42 at a desired point before starting a scan, an opening stop 56 is provided. Of the Control lever 48 strikes the opening stop 56 at a point immediately before the exposure carriage 14, the parabolic mirror 18, mirror 20 and reflector 42 mark the end of carriage return before initiating the scanning movement.

When the control lever 48 rests against the opening stop 56, it rotates the control lever clockwise when looking at Figure 3 to a small piece of a circular motion about the axis 44. This moves the rocker arm 46 clockwise and the shutter 42 retracted to the position shown at 42 '. In this position the exposure system is ready for scanning and the light rays emanating from the light source 16 and falling on the mirror become an exposure field on the Original layer 22 in focus. Either the adjustment stop 52 or the end stop 54 close the reflector 42 at the desired point

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the subsequent scan. So that the reflector 42 either on Close to the end of a normal 28 cm scan or at a extended 36 cm scanning or when scanning another Length that the basic scanning mechanism can execute, opened remains, the adjustment stop 52 is pivotally mounted at 58 so that it is out of the path of the control lever 48 and the stop surface 50 with the help of a Bowden cable 60 or another suitable device, the adjustment stop 52 with the copy size selector 62 connects, can be pivoted out. The copy size selector 62 may be made from one shown in Fig. 2, for example Rocker arm 64 or some other suitable device that moves, e.g., by pressing a selection button, and so on Movement for choosing a specific copy size transfers. Press Option-66 to choose a 36cm copy; press Option-66 to choose Select 68 for a 28 cm copy. This "copy size selector" is used to ensure that the paper is in the correct Size or length fed by the paper transport system. .

When 36 cm copy option 66 is pressed, the Movement of the rocker lever 64 is transmitted via the Bowden cable 60 and thereby the setting stop 52 into the position shown at 52 ' ver pivots and withdrawn from the path of movement of the control lever 48 with the stop surface 50 so that the reflector during the entire scanning of the exposure device remains open.

When the stop surface strikes either the Einteilanschlag 52 or the end stop 54 and thereby the reflector or closure 42 closes, is the exposure system for the return part of the Prepared for scanning movement. The closed during the return Reflector 42 throws white light onto the photoconductive layer and thereby ensures that the unused part of the photoconductive Layer 10 is discharged and not provided with toner.

Figure 4 shows the parabolic mirror 18, the light source 16, the Mirror 20 and the reflector or shutter 42 in their outermost Position in which the system is after the end of a previous

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* 11 "

the scanning is located.

An original to be copied is placed on the original plane 22 with one edge abutting the leading edge 24. The copier is put into operation. Then, the drum carrying the photoconductive layer 10 rotates clockwise, and the drum Exposure carriage 14 moves to the left. When the exposure optical system has reached its end point of movement in the previous cycle has reached, the end stop 54 ensures that the control lever 48 moves counterclockwise and thus the reflector 42 was closed. When the next copy cycle is initiated, the light source 16 is turned on during the return of the exposure carriage switched on in the working cycle and light from the parabolic mirror 18 and the mirror 20 on the underside of the reflector 42 thrown. The incident on the underside of the reflector 42 Rays are from this "on the mirrors 26, 28, 30 and 32 and in this way at the exposure point 33 on the photoconductive Thrown Layer 10. During the return of the exposure carriage, the photoconductive layer 10 becomes in its unused parts exposed and thus discharged from its dark potential, which was applied by the corona charging station 34.

While the exposure carriage 14 moves to the left in FIG. 4, the exposure path runs from the light source 16 and the parabolic mirror 18 to the mirror 20 under the guide edge 24. When the exposure carriage 14 approaches the end point of the return, the opening stop 56 rotates the control lever 48 clockwise around a small circular arc, whereby the rocker lever 46 also rotates about the axis 44 clockwise and thus the reflector 42 out of the optical path between the mirror 20 and the template plane 22 withdraws.

The exposure carriage 14 is then optically synchronized with the drum carrying the photoconductive layer 10 so that the previously placed on the template plane 22 template is scanned. The image of the template is based on the optical described above

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Transferred away to the photoconductive layer 10 and the charged photoconductive layer 10 exposed accordingly. Through this the photoconductive layer becomes conductive and the electrostatic one Charge disappears in the areas that are the bright areas of the Correspond to the original artwork. Reflect dark areas of the original no light, so that the charge does not flow off at the points in the photoconductive layer on which no light falls and thus the areas that correspond to black or dark parts of the original retain a high electrostatic charge, originally applied to the photoconductive surface. When the photoconductive layer 10 is rotated On the drum, this layer arrives at a development station 36 which works with magnetic brushes and which picks up the toner particles precipitates the areas of the photoconductive layer which have a high electrostatic charge. In this way areas of the photoconductive layer that correspond to the dark parts of the original document are highly electrostatic Have charge, provided with toner.

When the exposure carriage 14 runs to the right in Fig. 2 and the Takes the exposure device with it, the control lever 48 strikes the setting stop 52 with its stop surface 50. This one was by actuating the copy size selector in the, trajectory of the Stop surface 50 set. The selection button 68 acts via the rocker arm 64 and the Bowden cable 60 and pivots the adjustment stop 52 about the pivot point 58 in the movement path of the stop surface 50. When the stop surface 50 of the control lever 48 on the extended Part of the adjustment stop 52 strikes, the control lever 48 is moved counterclockwise and closes the reflector 42 via the rocker arm 46. Turning the control lever 48 counterclockwise lowers the stop surface 50 under the adjustment stop 52, so that during the return movement there is a distance between the upper part of the control lever 48 and the adjustment stop 52.

While the exposure device continues to run in the scanning direction,

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the light generated by the light source 16 is reflected by the parabolic mirror 18 and partially focused on the mirror 20 and then thrown onto the underside of reflector 42. This light comes through the slightly colored, highly reflective surface The photoconductive layer reflects and discharges during this part of the cycle in an unused portion of that layer.

When the exposure device and the exposure carriage 14 reach the scanning limit of the original plane 22, the stop surface runs 50 of the control lever 48 under the end stop 54. This is set so that the reflector is closed in the same way as by the adjustment stop 52. However, the reflector is closed at a point that is the rear edge of a 36 cm corresponds to a large template.

At this point a full scan cycle is complete and the exposure device, the exposure carriage 14 and the optical system with the mirrors 26, 28, 30 and 32 come to rest.

When next made a copy of a 36 cm long original is to be, the original is placed with the printed side down on the original level 22 and the selection key 66 pressed for a 36 cm long copy. As a result, the rocker arm is pivoted about its pivot point and the adjustment stop is pivoted via the Bowden cable 60 52 retracted to position 52 '. When the copier is then switched on, the exposure carriage 14 runs together with the exposure device to the leading edge of the original plane 22, the reflector being closed because it has remained closed since the stop surface 50 in the last scan on the adjustment stop 52. When the return movement has ended, the opening stop 56 rests on the control lever 48, opens the shutter or reflector 42 and allows the exposure of the original plane by the light source 16, the parabolic mirror 18 and mirror 20. This scanning part of the operation is identical to the process described in connection with the scanning of a 28 cm original, but remains the same

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Shutter or reflector 42 now open because of the adjustment stop 52 is withdrawn until the stop surface 50 of the control lever 48 rests against the end stop 54 and the reflector at the end of the The scanning of the 36 cm long original closes. Basically there is a slight oversampling which ensures that the Exposure system and the entire optics during the scanning move the entire original at the desired speed and synchronously with the photoconductive layer 10. This minor Oversampling is used to brake to a standstill the exposure device.

During exposure carriage moves in the scanning from left to right in Figure 4. 14, it moves in synchronism with the optically on the drum photoconductive layer 10 _f which passes the exposure station 33rd After the photoconductive layer 10 has been exposed to the light reflected from the original and an image corresponding to the light and dark areas of this original has been produced on it, the photoconductive layer 10 runs past the development station 36, which here works with magnetic brushes. However, the development station can also work with a development electrode. At the development station, the carrier particles, which are arranged in a bristle-like manner by magnets in the magnetic brush housing 36, brush against the surface of the photoconductive layer 10 and precipitate small electroscopic toner particles. The toner is attracted to and retained in the areas of a photoconductive layer containing a high electrostatic charge. These parts correspond to the dark parts of the original artwork. The photoconductive surface 10 guides the toner particles past a corona transfer station 38. The corona transfer station 38 is separated from the photoconductive layer 10 by a normal sheet of paper which receives the toner particles. The corona 39 at the transfer station counteracts the attraction between the toner particles and the photoconductive layer 10 and allows them to adhere to the sheet of paper to which they are subsequently fixed by heat.

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After the toner particles and the developed image from the photoconductive Layer 10 has been transferred to the paper, the photoconductive layer 10 next passes to a cleaning station 40 over. Here the photoconductive layer is cleaned by high-speed brushes with natural or synthetic bristles and the unwanted toner residue, which inevitably remains on the photoconductive surface, is brushed off therefrom and collected in a container. Other cleaning techniques are well known and can also be used. After cleaning ' the photoconductive layer 10 is recharged by the corona charging station 34 for a subsequent exposure.

A feature of using magnetic brushes and developing electrodes working development stations consists in the fact that these stations large dark areas of the original, which appear on the photoconductive layer 10 as large areas with a high Precipitate charge to be developed with essentially uniform darkness. Because pictures on a photoconductive Layer 10 are necessarily separated from each other by a certain distance, there is on the photoconductive layer Parts that can best be described as unused parts.

For design reasons, most electrostatic copiers use either originals with a length of 28 cm or with 36 cm length and can make copies of it, the scanning path with these devices regardless of the actual length of the Original artwork is the same length. Thus, with a short template, the part of the scanning movement beyond the actual end of the Original artwork expose an area that is transferred to the photoconductive layer 10 as a dark area, at least but as an area that is darker than the original, even when trying to shape a white background material a white cover. This solution is not entirely satisfactory because it does not reflect the same amount of light like a white piece of paper, and thus the charge on the photoconductive layer does not disappear at these points

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as far as the transmission of white light to the. photoconductive Layer.

If the charge on the photoconductive layer 10 only partially disappears, this is detrimental when the device is operated continuously, as this part of the photoconductive layer will attract and hold toner particles when this layer is at the development station 36 passes when the charge is left significantly above the normal remaining charge for a white background. While "this part of the photoconductive layer 10 then at the Corona transfer station 38 passes, the photoconductive Do not oppose any paper to which the toner particles may transfer. Hence, they are transmitted to the corona stat ion 38 'past the cleaning station 40 carried.

Cleaning stations for electrostatic copiers are in generally constructed so that they remove small amounts of toner and residues from the photoconductive layer during cleaning after most of the toner has transferred to the copy paper. Such cleaning stations, e.g. station 4o, generally cannot remove large amounts of residual toner. Even if the cleaning station is able to however, represents the large one remote from the photoconductive layer 10 Amount of toner is a waste of toner, and the precipitation of this amount of toner in a filter container fills it very much quickly and clogs the filter, reducing its efficiency and deteriorating the operation of the copier.

By arranging the optionally actuated, timed arrangement for reflecting light onto the photoconductive layer 10 in the parts of a work cycle in which there is no original image to be copied, the photoconductive layer discharged before development and with it excessive tint these unused parts of the photoconductive layer avoided and thus the cleaning requirements for the cleaning station

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lowered.

When the electrostatic copier is used by the operator to make fewer copies of many documents it is common practice to leave the cover open in order to more easily place the originals on the platen 22 and to be able to remove from this. From this it follows, however, that the template level during the unused part of a single The light illuminating the scan does not have a reflective surface and therefore there is heavy precipitation of toner in the last part of the scan on the photoconductive layer in the area of the layer that lies behind a 28 cm copy. This unused Part is provided with more toner as it appears as a completely black template for the photoconductive layer.

When copying in this way, the high intensity of the light source 16 when concentrated in a narrow area for the operator can also be very annoying if they are during the unused part of the scanning and the return of the exposure carriage manually swap one template for another. This nuisance is caused by the reflector or closure device described reduced, if not completely switched off.

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Claims (9)

PAT EN TAN S TEST Exposure device for electrostatic copiers to regulate the reflection of light and of the light that is charged photoconductive surface directed image, with a light source and an optical system for illumination a master plane and imaging an image in the master plane on the photoconductive layer, thereby characterized in that in the path of the light between the light source (16, 18) and the original plane (22) a device (42, 44, 46) is provided that the light beam before impingement Allowed to selectively interrupt the light beam after the photoconductive charged on the original plane Deflects the surface, exposes it there and thus discharges it. 2. Exposure device according to claim 1, characterized in that that the device (42, 444, 46) as a function of the relative movement of the light source (16, 18) in relation can be operated on the template level (22) » 3. Exposure device according to claim 2, characterized in that that the device (42, 44, 46) is a closure device which is divided into an open and a closed Position is adjustable. 4. Exposure device according to claim 3, characterized in that that the shutter in a plane substantially parallel to the plane of the original into and out of the path of the Light is movable. 5. Exposure device according to claim 4, characterized in that that the surface of the closure facing the light source is highly reflective. LE 972 003 3 0 9 8 4 3/1056 6. Exposure device according to claim 5, characterized in that that the color of the highly reflective surface is practically the color of the normally reproduced Templates corresponds. 7. Exposure device according to claim 1 to 3, characterized in that that the locking device can be pivoted about an axis (44) on a rocker arm (46) Reflector (42). 8. Exposure device according to claim 7, characterized in that that the locking device can be actuated via a control lever (48), with its stop surface (50) Attacks (52, 54, 56) are able to work together. 9. Exposure device according to claim 8, characterized in that that between two end stops (54, 56) one can optionally be pivoted into the path of the control lever Adjustment stop is used to limit the opening time of the closure device. ^{LI 972003} 309843/1056