DE1209418B - Xerographic episcopic printing device - Google Patents

Description

Xerographic Episcopic Printer The invention relates to on a xerographic printing device with a projection device, the models to be episcopically reproduced with a changeable image scale on a xerographic, located at an exposure slit perpendicular to this with constant speed moving plate is projected, with the exposure slit Located in a housing part of the projection device and at least one Part of the width of the xerographic plate extends in the transport means to Movement of the originals, optical means with movable elements, an adjustable one Lens and means for illuminating the templates are provided.

In a known xerographic method, a xerographic Plate comprising a layer of photoconductive insulating material on a conductive base has given a uniform electrical charge over its surface, and then it is exposed to the object to be reproduced. The exposure discharges the plate areas according to the radiation intensity that occurs, thereby creating an electrostatic latent image on or in the photoconductive layer is produced. The latent image is developed by means of an electroscopic Powder that is brought into surface contact with the photoconductive layer and is held electrostatically on it in a pattern called the electrostatic corresponds to latent image. Then the developed xerographic powder image is in usually transferred to a support surface, on which it is by any suitable Funds can be fixed.

The projection of opaque originals onto a stationary surface usually takes place by using the usual projection technology, including means can be provided for enlargement between the original and the image to be projected or not. If an enlargement is desired, the usual enlarging means can be used which contain a variable focus objective lens, and further means for changing the optical path length for each enlargement ratio. However, if the surface receiving the projected image is constantly moving, then so the original must be projected while moving at a relative speed synchronized speed of the recording surface. The lens has it constantly different advancing parts of the original during its movement to project. The relative speeds of the moving original and the receiving surface must be precisely synchronized for any desired enlargement ratio. The synchronization must be carried out in such a way that, for example, not for one enlarged projection each unit length of the opaque original as the same Unit of length is projected onto the constantly moving recording surface. at an enlargement ratio of 2: 1 corresponds to the moved length of the opaque Originals half a moving length of the recording surface, or in other words: Two units of length on the recording surface correspond to the projection of one unit of length of the opaque original. Around a wide range of different magnification ratios Projecting onto a surface moving at constant speed is accordingly a coordination mechanism is required that allows a corresponding Set a range of speeds for transporting the opaque original. In addition, an objective lens must be provided which is selected according to a Magnification ratio can be focused, and it must be selected according to one The magnification ratio is the length of the optical path from the opaque one Original to be projected to the recording surface is exactly changed and set can be.

It is known in a printing device of the type mentioned at the beginning, a mirror over which the originals are to be depicted on a photoconductive Supports are projected to offset the scale changes in the image. The exposure slit provided there over the photoconductive support is but not changed in the case of such a transfer.

Independently of this, it is known to print a xerographically Original through an exposure slit onto a xerographically effective cylinder surface to project; one with an aperture - d. H. Aperture diaphragm - working Projection device can be used. The width of the exposure slit cannot be changed, the aperture of the projection device may be dependent be changeable by the focal length, so that not always worked with maximum aperture would. The latter, however, is precisely what is required in episcopic projection, to reduce the already relatively low luminous flux to the Bring plate.

The invention is based on the finding that, regardless of each set enlargement ratio, a xerographic plate one possible Uniform exposure is required, if not the development process constantly is adapted to the respective exposure level. An adaptation of the development process the respective exposure level is extremely expensive. For example if the enlargement ratio is relatively large, a relatively smaller medium one occurs Exposure of the xerographic plate. With a diascopic projection, there is one such adjustment in view of the great strength of the picture containing Lichstromes of minor importance, so that the invention is based does not even pose the task at hand. .

Around the mean exposure of the xerographic plate in the case of episcopic Projection essentially independent of the setting of the image scale to make, has in a xerographic printing device according to the invention Exposure slit also depends on the setting of the image scale adjustable width to be set. The exposure slit receives a large one Width, the exposure strength of the xerographic plate is relatively large, that is normal with a correspondingly large reproduction scale.

In the following, an embodiment of the invention is noted described on the figures. F i g.1 shows a schematic view of the invention Apparatus in its connection with an automatic xerographic printing apparatus, which is supplemented by a microfilm projection apparatus; F i g. 2 shows in natural Size of the front of an automatic xerographic reproduction machine, which is equipped with an apparatus according to the invention; F i g. 3 shows in natural Size the apparatus similar to FIG. 2, however, cover parts have broken out to To show details of the mechanism of the invention; F i g. 4 shows a circuit diagram; F i g. S shows the device for controlling the exposure in the case of the invention Apparatus. The illustrated embodiment of the invention comprises a transport arrangement for the transport of opaque originals to be reproduced through an optical Way, a projection system 2 for projecting images with a variable magnification ratio and an exposure control system 5.

The apparatus of the present invention is shown (see Figs. 1, 2 and 3) together with the main parts of an automatic xerographic printer. This printer is essentially located in a housing 26 and comprises a xerographic plate in the form of a xerographic drum 10 which has a photoconductive peripheral surface 11. The drum is attached to a shaft 201 which runs on one side in a journal bearing 202 and on the other side in bearings (not shown). The shaft 201 is coupled via the coupling 210 to a shaft which rotatably runs in the journal bearing 203. The drum 10 is moved at a constant speed past a loading, an exposure, a development and a transfer station at a constant speed by the driving action of a synchronous motor 204.

The motor 204 transmits its driving force through the gear box 205 onto the drive shaft 206 and onto the drive roller fastened on this shaft. The drive belt 208 transmits the drive movement from the drive roller the drive roller 209, which is mounted on the shaft 211.

For applying an electrostatic charge to the surface 11 For example, a corona discharge device 20 is used which is of a known type can be and is excited by a suitable high voltage source. The angry Charge is derived in part by the apparatus of the invention by taking a photo of an opaque original is reproduced on the surface so that forms on this an electrostatic latent image corresponding to the original.

After exposure, the electrostatic latent image is developed using a developing unit 21. The unit 21 has a housing 217 in which there is a two-component developing material 218 which is cascaded over the drum surface. Such a unit is known. Dye portions 23 of the developer material which are used up during development are replenished from a storage container 27 in accordance with control means 222, so that the correct material concentration is maintained. A conveyor 219, which is driven by suitable drive means by a motor 220, picks up developer material and discharges it onto the chute 221, from which it cascades down over the electrostatic latent image on the surface 11 and adheres to the charged parts of this surface .

After development, the xerographic powder image runs past the lamp 49, as a result of which residual charges in the non-image areas of the drum surface are completely discharged. Thereafter, the powder image is transferred to the surface of a carrier tape 18 which is transported by the handling mechanism. Means known per se can be used here. The support surface onto which the powder image is transferred can be of any suitable type; however, the use of paper which is unwound from a feed roller 16 is preferred. A synchronous motor 227 drives a take-up reel 17 and drive rollers 15. Guide rollers 12 and 13 are used to support the carrier. surface in surface contact with the drum in the vicinity of a corona discharge device 14 which may be similar to the unit 20 discussed above. This corona discharge device 14 electrostatically transfers the powder image to the carrier surface.

To operate the handling mechanism, a motor 227 is provided which, via a gear box 228, drives the drive shaft 229 of the handling mechanism and thus the drive roller 230, which is fastened on this shaft. A drive belt 231 transmits the power from this roller 230 to the roller 232, which is mounted on the shaft 233. The shaft 233 runs in the journal bearings 267 and 268. The roller 269, which is also mounted on the shaft 233, transmits the rotational movement of the shaft via the belt 270 to the roller 271, which is mounted on the shaft 272. The shaft 272 runs in the journal bearing 273 and is to be coupled via a coupling to the shaft 275, which rotatably runs in the journal bearing 276. The take-up reel 17 is mounted on the shaft 275, which runs in bearings (not shown) and which can be removed from the apparatus by retracting suitable retaining teeth 278. A cover 277 on the front of the housing 26 encloses the drive mechanism.

After the transfer, the carrier surface is replaced by a suitable Hot melt apparatus 22 performed, which is of known type. In this apparatus is the powder image is permanently fixed on the carrier surface. The lamp 25 serves to to dissipate all residual electrostatic charges on the surface 11 after the surface has been cleaned by brushes 19 driven by a motor 23.

When the above-described xerographic apparatus is equipped with an apparatus for reproducing microfilm images, a film projection apparatus is suitably used. The apparatus is used to project microfilm images to be reproduced onto the surface 11 with a variable enlargement ratio. This has a similar result as the reproduction of opaque originals by the apparatus according to the invention to be described below. It should be emphasized that the film projection apparatus completes the overall device according to the invention, but is not a functional part of it. The apparatus can be omitted without violating the concept of the invention. During operation, this apparatus continuously transports a microfilm strip 234 from a supply reel 235 via guide rollers 236 and 237 vertically past a slot 238 via guide rollers 239 and 240 onto a take-up reel 241 is synchronized with the speed of the drum 10. For this purpose, a motor (not shown) with two speeds is provided, which can be actuated by a selector switch 246, and also a variable speed transmission, not shown, which can be actuated by means of the selector handle 247. A projection with the desired magnification ratio is achieved by the lens assemblies 248, 249 and 250. There is a film guide on the back of each of these assemblies. In each of the lens arrangements there is an adjustable lens of different focal length. The lens assemblies are attached to a rotatable head 251 in such a way that the optical axes of the lens assemblies are radial to the rotary head and their nodes (nodal points) are on a common radius at a distance from the axis of rotation of the head 251 of the lenses with an optical axis in the optical path from the film scanning slit 238 to the exposure system 5 perpendicular to the surface 11.

The film scanning slit 238 is illuminated by means of a lamp 252 through a condenser lens 253 which concentrates the light in one area. The image is projected through the selected lens and through a slot in housing 257, through bellows 258, then through housing 259, and through exposure control system 5 onto drum surface 11. A mirror 127 is, when the microfilm projection apparatus is used, pivoted by the handle 186 into a vertical position so that it is out of the optical path. The parts above the base plate 260 are fastened to a support wall 261 which can be displaced perpendicularly with respect to the base plate 260. This shift is carried out by turning an adjusting knob 262. In this way, the exact optical path length between the film and the surface 11 can be adjusted in accordance with a desired magnification ratio. The respective setting is displayed on a scale 263.

If it is desired, opaque originals by the invention To reproduce apparatus, the original to be reproduced is transferred to an upper Support surface 41 (see FIG. F i g. 2) placed on it by means of adjustable guide rails 42 and 43 can be centered. Each of the guide rails 42 and 43 is on the Support 41 attached by knurled screws 44 and 45. From the through the guide rails 42 and 43, the original is inserted into the transport assembly by hand, by means of which it is guided vertically through an optical path in which the projection of the image on the surface 11 takes place.

The drive parts of the transport arrangement lie within the cover 112. The elements used for transport are fastened in the open housing 39 (see FIG. 3), which is provided with side walls 30 and 31 and a top plate 32 and a front strip 29. Inside the housing 29 there is a frame structure 33 which has essentially the same external dimensions as the internal dimensions of the housing 29, so that it can be moved in the longitudinal direction in this housing to the drum 10 . The transport elements of the arrangement are fastened on the frame 33. The frame has a head wall 34, a rear wall 35, a side wall 36, an opposite side wall (not shown) and a front strip 38.

For the transport of the opaque originals, the arrangement has two parallel rotatable shafts 46, 47 lying on one side of the apparatus, which are at a certain distance from one another and run in bearings (not shown). The axes of rotation of these shafts are parallel to the axis of the drum 10. Cylindrical rollers 48 and 49 are mounted on the shafts 46 and 47 and rotate with the shafts 46 and 47. A plurality of parallel endless belts 50 lie above these rollers 48, 49 and between them. These belts 50 preferably have a somewhat roughened outer surface, so that an opaque sheet of original paper 7 applied to them moves with them. A synchronous motor 57 transmits its driving force to a gear 4 for variable speed. The movement is transmitted from the drive shaft 55 via the roller 59 to the non-slipping belt 60 and from this to the roller 61 which is fastened to the splined shaft 62. A bevel gear 63 is slidably attached to the shaft 62 and engages in a bevel gear 64 attached to the shaft 46. Both gears 63 and 64 are located in a gear box. The splined shaft 62 is rotatably located in bearings in the gear box 65 and in journal bearings of brackets 69 which are fastened to the side wall 31. An idle roller 67, which is rotatably mounted, keeps the belt 60 under constant tension.

To change the speed transmission 4 of the transport, a handle 110 is actuated, which is attached to the rotatable shaft 111. This rotatable shaft is in turn attached to the transmission mechanism 4 in a manner not shown. A bevel gear 118 (see FIG. 2) is also attached to the shaft 111 and is in mesh with a suitable display mechanism 119 , which precisely displays the relative transmission speed through the window 120 and, accordingly, the conveying speed of the belt.

The contact of the opaque original sheets 7 with the belts 50 carrying them is ensured by rubber rollers 70. which normally touch the belts 50 tangentially and are mounted on parallel rotating shafts 71, 72, 73. The axes of the shafts 71, 73 are parallel and above the shafts 47 and 46. The shaft 72 lies with its axis in the same plane as the axes of rotation of the shafts 71 and 73 and parallel and above the central rotating shaft 74. There are also rollers on it 70 attached. Each shaft 71 to 74 is preferably provided with a roller 70 which is located approximately centered and is in tangential contact with each individual belt or belts 50th The shaft 71 is supported at each end in a bearing 79 in arms, which their-. are supported on the one hand in a Schaltnlager 8 so that they are removable. The shell bearing 8 is attached to the cap 41. The ends of the shafts 72 and 73 lie rotatably in bearings of brackets 92 and 93 which are fastened to the side walls 36. The shaft 74 runs in a bearing, not shown.

Approximately in the middle area between the waves 72 and 73 across the belts 50 is a rectangular clear glass 81, which at each end in some Distance from the bands 50 supported by holders 87 attached to the frame 33 is. The glass strip 81 keeps the sheet 7 flat and horizontal while it is under passes through it, so that creases and curls of the sheet, if any were to be eliminated. When the sheet 7 runs under the glass 81, it cuts one perpendicular to it and leading to the surface 11 optical path, as in is to be described below.

The lamp 3 is used to illuminate the opaque original, if it undermines the glass 81. The lamp 3 is in lamp sockets 78 at each end attached, which lie laterally and from opposing pockets 82 in the side walls 30 and 31 are enclosed. To prevent the lamp 3 from overheating To avoid this, a fan 84 is provided, which is driven by a motor 85 and blows a stream of ambient room air over the lamp surface. The lamp 3 is a commercially available lamp of a high light intensity type. In a preferred Embodiment, a high luminosity mercury vapor lamp is used, though other light sources can also be used. The cover plate 75, which is attached to the Side walls 30 and 31 is hinged, protects the operator from radiation effects the lamp 3.

After the sheet 7 has passed under the glass 81 and the shaft 73, it abuts the reversing guide 83 where its direction is reversed and then falls it on the lower receiver 88, which is below the housing 29. There will the original 7 in a predetermined position by the catcher 89 in a slot 90 of the Sensor 88 is saved.

The image of the original below the glass 81 is seen through the mirror 91, which is attached to the frame 33 parallel and at a distance above the glass 81, is reflected. The mirror is designed in such a way that it is the original in its entirety detected, and is inclined to the horizontal surface of the belts 50 so that it Image of the opaque original 7 reflected by the projection system 2.

To change the length of the optical path, the frame 33 is with the parts attached to it. towards the drum 10 and away from it movably attached. The mirror 91 and the glass 81 move with it. the Length of the optical path between the surface 11 and that which runs under the glass 81 Sheet 7 can be changed in that the position of the frame 33 as required the enlargement ratio at which the opaque original is reproduced is to be adjusted.

The hand wheel 95 is used to adjust the frame 33. That Handwheel is attached to a screw shaft 96 which is rotatable in a transverse bar 39 runs and is guided by a threaded block 98 which is attached to the crossbar 38 of the Frame 33 is attached. A rotation of the handwheel 95 causes a shift of the block 98 and therefore moves the supports 104, which are located on the underside of the Frame 33 are attached to the housing 29 via guide rails 105 To enable adjustment of the frame 33, a bevel gear 106 is provided, which is attached to the screw shaft 96 and the relative position of the frame 33 on Another bevel gear 106, not shown, which is attached to the shaft 107, is broadcast. The shaft 107 determines the setting of a calibrated display device 108, at which the respective set relative position exactly through the viewing window 109 is displayed.

In addition to the mirror 91, the projection system 2 contains an objective lens 126 and a second mirror 127, the reflective surface of which covers the recording surface 11 and is inclined to the perpendicular of the surface 11. The lens 126 is held in a lens mount 128, which in turn is fastened to the shielding plate 129. The shape of the shield plate 129 is such that it fits snugly against the inside of the longitudinally extending guide 123 and is slidable along it. The lens mount 128 is firmly connected to the holder 130. The holder 130 is fastened to a threaded bushing 132 comprising the screw shaft 131. The longitudinal guide 124 is shaped on the inside in such a way that it allows a longitudinal movement of the threaded bushing 132 and the holder 130 and that, together with the guide 123, it forms a light-tight or radiation-tight housing that prevents external scattered light or radiation from entering the optical path. The image reflected by mirror 91 should only pass through the optical axis of lens 126. To prevent light or radiation from escaping from this path, a felt or other material with a rough surface (not shown) is applied to the components all around so that a block of light or radiation is formed perpendicularly across the interior of the guides 123 and 124 will. The lens 126 is focused in the optical path by rotating the handle 133, which is attached to the shaft 134. The shaft 134 is rotatably mounted in the rear wall 35. A gear 135 is fastened on the shaft 134 and thus rotates with the shaft 134. This gear 135 is in constant mesh with the gear 136, which is attached to the screw shaft 131.

In order to enable precise adjustment of the lens focus 126 in the optical path according to a selected magnification ratio, a bevel gear 142 is provided which is fastened to the screw shaft 131 and engages in a bevel gear 143 fastened on the shaft 144. The shaft 144 controls a calibrated display mechanism 145 which displays the exact position of the focus through the window 146.

Is the xerographic reproduction apparatus with a microfilm projection apparatus 6, the mirror 127 is mounted pivotably about pin 185 and can be adjusted by means of the handle 186 such that the optical path of the invention Apparatus can be adjusted as described above or that the mirror clockwise can be pivoted so that it can project an image from the microfilm projection apparatus not bother. If the latter is not provided, the mirror 127 is fixed in the in Fig. 1 shown arrangement.

To control the exposure, an exposure control system 5 (see FIGS. 1 and 5) is provided, which has a housing-like structure 160 to which side walls 161 and 162, a front wall 163 and a rear wall (not shown) are attached, which are attached all extend vertically downward onto the drum 10. At the lower end of this housing-like structure is a slot 168 of variable width which extends the axial length of the drum 10 and is formed by plates 169, 170 which are attached to pivots 171 and 172. These pivots 171 and 172 are rotatably located in the side walls 161, 162. The width of the slot 168 can be changed by turning the control knob 176, which is also attached to the pin 172 and to which a gear 179 is also attached, which is a gear 180, which is attached to the pin 171, engages. The control button 176 carries a pointer 181 which indicates the width of the set slot 168 on a calibrated scale 182. The slit opening 168 corresponds to the shutter of a camera in the sense that the time factor of the exposure can be adjusted with it. If the opening 168 is set to the maximum, the projected image is in contact with the constantly moving drum surface 11 for the longest time, so that maximum exposure is possible. If the opening 168 is set to a minimum, the opposite applies. The electrical system is shown schematically in the circuit diagram of FIG. 4 shown. Current is supplied from a voltage source 190 via the lines 191 and 192 via a switch 193 to the transport motor 57. Furthermore, a voltage is conducted via the lines 194 and 195 via the switch 196 and from there via lines 197, 198 to the fan motor 85 and via lines 188, 189 to the lamp 3.

In operation, when the electrical system is on, a opaque original image to be reproduced, first on the support surface41 placed and aligned between the guide rails 42 and 43. Then an enlargement ratio becomes with which the opaque original is to be reproduced. The following Magnification ratios can be set, for example: 0.48x, 0.50x, 0.55x, 0.60x, 0.65x, 0.70x, 0.75x, 0.80x, 0.90x, 1.00x, 1.20x, 1.40x, 160, x, 2.00x. But it is obvious that by components of other dimensions and / or sizes other magnification ratios can also be set.

After the magnification ratio is selected, the lens will 126 focused in the optical path by rotating the handle 133 until the desired Focus value corresponding to the required lens position appears in window 146. The appropriate transport speed of the belts 50 is then determined by rotating the Handle 110 adjusted until the value, the required transport speed accordingly, appears in window 120. The length of the optical path then becomes precisely adjusted by turning the handle 95 to a value that is required Position of the frame 33 corresponds, in the window 109 is visible. Through the described Means is the apparatus according to the invention according to a selected enlargement ratio for the original image. The chronological order of the above Settings do not have to be adhered to.

The knob 176 is then rotated to a position in which the slot 168 provides the proper exposure of a projected image onto the constantly rotating drum surface 11 .

After all the necessary settings have been made, it becomes opaque Original? then from the support surface 41 between the belts 50 and the roller 70 introduced on the shaft 71. The original 7 then runs on the belts 50 with a Speed, which is the same as the belt speed, and goes underneath the pane of glass 81 where it intersects the optical path between tape 50 and mirror 91 perpendicularly. The image then lying in the optical path is at a right angle through the Mirror 91 reflects and passes through the optical axis of lens 126 and falls onto mirror 117 which reflects it back and through the exposure control system 5 directs perpendicular to the surface 11 and along the axial length of the surface 11 that was previously loaded. The opaque original? runs on the tapes continue until it meets the reversing guide 83, where its direction is redirected, and from where it falls onto the lower support surface 88 and is stopped by the catcher 89 will. After exposure, the formed electrostatic latent image becomes one xerographic powder image is developed by the developing unit 21 and then electrostatically transferred to a paper tape 81 and there by the heat melter 22 on it the way through the paper Handling mechanism 226 passes through, permanently fixed. The finished reproduction of the original 7 is then placed on the take-up reel 17, from which it can then be removed again if desired. If also the reproduction of a single opaque original was described above, in this way any number and quantity of opaque originals can be processed continuously and one after the other can be reproduced at the same enlargement ratio without the need for it is to make any settings on the device. When using the invention Apparatus can produce finished xerographic print copies with a variable enlargement ratio can be made from an opaque original in about 15 seconds. at Use of an apparatus according to the invention together with an automatic xerographic Apparatus is a fast and accurate correlation between the transport speed Easily adjust the drum surface, optical path length and lens focus, so as to obtain an improved reproduction of an opaque original. Is the apparatus according to the invention with a continuously operating xerographic Reproductive apparatus united and completed by a microfim reproductive apparatus, this results in an overall apparatus of extraordinarily great versatility and Usefulness.

Claims (4)

Claims: 1. Xerographic printing device with a projection device, the models to be episcopically reproduced with a changeable image scale on a xerographic, located at an exposure slit perpendicular to this with constant speed moving plate is projected, with the exposure slit Located in a housing part of the projection device and at least one Part of the width of the xerographic plate extends in the transport means to Movement of the originals, optical means with movable elements, an adjustable one Lens and means for illuminating the templates are provided, thereby marked e t that the exposure slit (168) is a function of the setting of the Has the image scale to be set changeable width. 2. Printing facility according to claim 1, characterized in that the optical path length between the Originals and the xerographic plate (11) for the purpose of changing the image scale by shifting the transport means (50) relative to the exposure slit (168) is to be changed. 3. Printing device according to claim 2, characterized in that the optical means a mirror (91) which is fixed relative to the transport means (50) and another mirror (127) fixed in relation to the exposure slit (168). 4. Projection apparatus according to claim 3, characterized in that there is between the mirrors (91, 127) is displaceable relative to these an objective lens (126). Documents considered: German Patent No. 1020 234; German Auslegeschrift No. 1056 920, 1046 477, 1059 287; British Patent No. 668 623.