DE1497125C - Device for imagewise charging an insulating electro-photographic recording mat as in accordance with an optically scanned master copy - Google Patents

Description

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all layer elements unier exposure of each fiber can for example have a diameter of recording electrodes so coated with an insulating of 0.01 mm and a length of 12 to 52 mm on layer that they face the free and the bundle width can be about 0.25 mm to the end face of the recording electrodes are a plane with a length of 300 mm.
Level forms. 5 A basic unit is developed for production

As a result of the measure according to the invention, FIG. 2, consisting of the fiber optic, became evident not only the above-mentioned sample bundle 10 and the blocks 12 and 13, as if completely solved from problem, but because not every Fig. 3 is recognizable, turned around. The required individual The structure was also covered with fibers if the floor area was cleaned and dried Much simplified: So it is simply an io with a coating of electrically conductive photoconductive material in a desired material, preferably tin-antimony oxide over pattern contracted onto an outer planar surface that is on the bottom surface of the unit added blocks in the further to be described is knocked down. To make sure the Way applied. Cover only on the bottom surface of the unit.

It is preferable to go to a facility, the rest of the unit is for example

device for pictorial charging so that the wise covered by a stencil, which only the

leaves a flat surface with a transparent dielectric bottom surface. The basic unit then becomes

Interlayer is covered. placed in an oven and then with a

It is useful if the electrically conductive atomized solution of an electrically conductive material

Rails or strips of selective coatings 20 terials sprayed around the electrically conductive film

exist. to obtain. Other occasions and known per se

Particularly favorable results are obtained when cleaning steps follow. The pattern is preserved the insulating layer at least partially from a one by optionally removing parts of the opaque glass frit. One can have deposited electrically conductive coating but also proceed so that the photoconductive and 25 on the base of this unit, including a thin the electrically conductive parts on the as a layer - uniform film made of a photosensitive etching carrier Serving intermediate layer of glass attached to protective layer over the previously on the floor surface attached to the flat surface, vapor-deposited or deposited electrically conductive coating are. is sprayed; the unit is then left with room

For example, embodiments of the invention 30 air dry at temperature,

should be explained in more detail using the drawings. The shape of the pattern is best seen

will. The drawing shows with reference to Figures 3 and 6 of the drawings.

Fig. 1 is a schematic representation of an inven- Here, 16 is a conductor rail of the first appropriate device for image-wise conductive coating denotes, the on the floor charge for use in an electrostatic 35 part of the control unit. This part extends Reproducing device, extending essentially the full length of the

F i g. 2, in perspective, a basic unit of the one-block 12 and can have a narrow part of the edge

Direction of blocks with the fiber optic bundle 10 arranged in between in the vicinity of the block 12

Fiber optic bundles, overlap. This coating can, for example, be a

Fig. 3 have the basic unit shown in Fig. 2 after 40 width of 2.5 mm and serves as an electrical

a first manufacturing stage from below, trische connecting conductive rail, as further

Fig. 4 is a similar view to another set forth in greater detail below. A variety of elec-

Manufacturing stage, trically conductive strip 18 remains along the edge

F i g. Figure 5 is a perspective sectional view of the block 13 in the vicinity of the fiber optic bundle

Device taken along line 5-5 in Figures 4, 45 10. One end of each of these contacts may, must

6 shows a perspective sectional illustration but not necessarily the edge of the fiber optic according to FIG. 5, with a part of the illustration bundles 10 overlapping in the vicinity of the block 13, reason was removed, and the fiber optic bundle 10 thus forms with its one

Fig. 7 is a section through the bottom portion of an end surface 10 'and the end surfaces 12', 13 'of the

Device according to the invention, according to one of the 50 blocks 12, 13 has a flat surface 14 and extends

modified embodiment. as a strip across the direction of the

According to Figs. 1 and 2, a fiber optic bundle of recording material is through the recording

10 from a large number of adjacent, light-guiding heads. The flat surface 14 can be made with a through-fiber, preferably made of glass between two visible dielectric intermediate layers 40 covered blocks 12 and 55 consisting of dielectric material, as can be clearly seen in FIGS. 6 and 7. 13 arranged. One block 13 is transparent; Each of these conductor rails can, for example the bundle is parallel to each other with a length of 2.5 mm and a width of 0.05 mm Fiber rope perpendicular to a recording plane. have, the rails for example so ver-Das Fiber optic bundle is at block 12 by staying up so that it is center-to-center spacing melt - if this block is made of a glass 60 of 0.1 mm, i. H. a gap of 0.05 mm Composition-consists-attached. Leave the second between you. The greater the number of Block 13 is transparent and preferably also provided along the fiber optic bundle 10 elekaus Glass made and on the other side of the trisch conductive rails is, all the better Fiber bundle 10 attached. The block 13 is obtained in the image resolution. Significant on block 13 half as high as the fiber optic bundle 65 also remains part of the electrically conductive over-

11 and the block 12 and can, when the block 13 closes and forms a second conductive rail 17 consists of glass, on the fiber optic bundle 10 by similar to the rail 16 at a distance of example-fusing be attached. 0.0625 mm from the ends of the strips 18,

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which is located in the vicinity of the second rail 17- Cooling the control unit becomes the second glass frit end. layer of the desired areas of the strips, the conductor rails and electrical strips 18 are etched away. This is done using a 16, 17 and 18 produced, so first and photosensitive etch protection layer, similar to the second series of photoconductive layer elements 19 and 5 described above.
20 (Figs. 4 and 6) applied by precipitation. When the recording head is finished, the first row will appear evenly on the floor-to-floor surface as shown in FIG. 6 of the drawing; applied the end of the fiber optic bundle 10 (Fig. 4), voltages, wherein the insulating Glasschichten33 and · said electrically each of these layer elements called up 34, also cut glass encapsulation; the next one is insulated and one layer element io is drawn in each case, around which Anj located underneath is used for an electrically conductive strip 18. Each order of blocks 12 and 13 and fiber bundles; The layer element is intended to better reproduce an electrical resistance. ; connection between the ends of the corresponding When used in a reproduction device contact 18 in the vicinity or in over- the recording head - FIG. The second row of photo optics bundle 10 in the direction of the path of movement of conductive layer elements is installed on the block 13 of a template, for example a list 27 written with writing between the second ends of the strips 18 and the machine-written list 27, which is; Conductor rail 17 applied, one in each case in the direction of the layer element drawn in above the list is used for each strip 18 and an arrow with a speed of, for example, electrical resistance connection between the 5 cm / sec. emotional. The typescript of the list's second end of the associated electrically conductive is on the side facing towards the free-. ^. Strip 18 and the conductor rail 17 is produced. The laid end of the bundle 10 points, ie it is »FIGS. 1 and 6 of the drawings show the bottom of the list according to FIG. 1. A! End lines 38 and 39, which are attached to the conductor rails 25 special dielectric recording material, for. B. 16 and 17 are attached. This is done, for example, a paper 28 is inserted so that it is on the! wise by nickel plating a selected bottom side of the head to the charge-donating point on this rail and then moving past recording electrodes. The paper solder the conductor. moves in the direction of the

After the layer has been placed and sintered, the part drawn at a speed that corresponds to the speed of the elements made of photoconductive material and the speed of the list of electrical connection lines to be reproduced, ie in the present example in the manner described above , a two-layer speed of about 5 cm / sec. The dielectric hermetic glass encapsulation applied to the bottom top paper moves between the recording surface of the unit. The first glass layer 35 electrodes 31 on the bottom surface of the recording is applied in two parallel strips, the only voltage head and a rail as a counter electrode, the layer elements of the photoconductive material 32, which cover the entire length of the cover. This is done by covering the remainder of the direction, ie completely over the full width of the bottom surface of the unit with a masking paper 28. The light source 22 illuminates, by spraying a layer 40 as indicated at 26, the described surface of a selected glass frit over the areas not in the list 27 that are to be reproduced and the masked parts, ie over the layer elements made of non-colored (unprinted) areas the photoconductive material. The ser off for this layer surface reflect the light to the ends of the glass frit is selected with a softening point such ER- some of the optical fibers 11 of the overall Q on the paper which is substantially aligned above the ER- 45 bundle 10. The light travels through each softening point of the glass frit, which is used as a second individually illuminated fiber optic and meets a layer of the two-layer encapsulation, or several of the photoconductive layer elements 19 are used. The first layer serves as the row of such elements on the first end of the protective layer for the photoconductive layer elements. Fiber optic bundle, wherein the electric resistance-type, the stand surface areas of the electrically conductive strip-50 of each such illuminated element 19 wesentfenl8 which lent not deducted from the glass encapsulation, for example, a resistance value of, are revealed, can in various ways exposed 1 X 10 ¹⁰ Ohm on one in complete darkness. After a procedure one covers the resistance value of 5 X 10 ^s ohms is reduced. Surfaces with a metal rail with a width. The typed areas of list 27 of approximately 0.05 mm before and during the on- 55 reflect no light from the illuminated top spray of the second glass frit layer. One area of the list, and consequently the transfer of such rail, is at 36 in FIG. 5 of the individual fiber optics 11 corresponding to the drawing are indicated under the list. A preferred method for not exposing the associated photoconductive exposure of the areas of the strips 18 to light is to briefly reproduce layer elements 19 of the row of layer elements. · ⁶ ° on the bottom or first end of the fiber optic - the entire bottom surface of the unit and the bundle 10. The non-illuminated layer elements on top of it are covered by a relatively second glass frit layer at this time, which is sensitive to moderately high electrical resistance, such as is indicated above caustic. The blocks are given this effect.

12 and 13, the strips 18 and the fiber optic _{bundle 6 S} One can thus determine that the photoconductive ι

not exposed (e.g. nitric acid). These Verkap- layer elements 19 optionally and one on top of the other

Selung is then relatively conductive and non-conductive in the following described above

Wise tempered. After the tempering cycle and patterning, the arrangement of the

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Pressure corresponds to the list 27 and is in the voltage electrode 31. This current flows through this

Correspondence with the succession of way and brings an electric image charge to the

Changes to this arrangement change when the paper is at the point of contact of the paper with the

the list of the ends of the fiber optics 11 corresponding recording electrodes 31 on.

away. 5 Taking into account the previous

A direct current source 29 with, for example, 400 going description that electrostatic charges

up to 600 volts is recorded in patterns on the dielectric paper 28 for the copying process of the device.

intended. This direct current source, which corresponds to list 27, is pulsed. That so

for example with 500 Hertz. The charge image formed on the conductor rail on the dielectric paper

17 of the device according to FIG. 6 attached connector io 28 is then closed with a powder developer

line 38 leads to the negative terminal of this same - a toner image develops that is

power source, while the action is fixed on the conductor rail 16 in a known manner.

Device attached connecting line 39 to the After the examples described above

previously discussed counter electrode 32 and for the positive spacing of the individual photoconductive layer

tive terminal of the direct current source is performed. 15 elements, d. H. with a center-to-center distance of 0.1 mm,

The light coming from the light source 22 results in a resolution of 10 lines per mm through a mirror 23, as indicated by 24, over the width of the recording material 28 500 Hertz pulted and transmitted to the photoconductive layer element 20 of direct current source and a movement of the series of such layer elements on the ground 20 speed of the list 27 and the recording surface of the block 13. Each layer material 28 mm / sec. a resolution of anelement is thus kept relatively electrically conductive at approximately 10 lines per mm over the length of the image as long as light from the light source 22 reaches the drawing material. Of course, it is transferred to these layer elements, and the person skilled in the art knows that the resolution over the resistance of these cells at this instant 25 length of the paper from the resistance characteristic is of the order of magnitude of slightly less than 5 X 10 ⁸ ohms and the response speed of the photoconductive. Layer elements depending on the exposure

In operation of the device shown in FIG. 1 in connection with the speed of movement, when one of the photoconductive lists 27 and dielectric paper 28 and the layer elements 19 is illuminated, a circuit of the positive 30 pulsation speed of the power source terminal of the power source 28 is made via the Line 29 depends on the 29 coming energy.
Conductor rail 16 over the illuminated layer according to the in F i g. 7 reproduced modified "" elements 19 for the assigned contact via the respective embodiment of the recording head are speaking photoconductive layer elements 20 of the conductor rails 16, the electrically conductive strip series of such layer elements on the floor surface 18 and 31, the photoconductive ones Layer elements surface of the block 13 to the conductor rail 17 and over 19 and 20 and the encapsulations 33 and 34 all the connection line 38 to the negative terminal of the on one side of a thin flat transparent current source 29 is closed. At this moment the dielectric carrier 40 is provided or essentially no current flows from the counterpart, namely in configurations identical to the electrode 32 to the recording electrode 31 at the cone 40 with the one previously used for the arrangement of such compact 18 due to the relatively high resistance - nents on the bottom surfaces of the blocks 12 and level of the dielectric paper 28, which is in the order of magnitude of 5 X 10 ¹⁰ ohms described in FIG. 13 and the fiber optic bundle 10, in the configurations. The support 40 is preferably equal to the resistance of the associated photoconductive glass and by, for example, a transparent capable layer elements 19 and 20. As a result, 45 cement on the bottom surfaces of the blocks 12 is not attached at this time to any charge from the and 13 and the fiber optic bundle 10, recording electrode 31 on the recording so that «left components are applied to the intermediate layer of paper. However, each photoconductive 40 is in the same relationship in the vicinity of the fiber layer element 19 as soon as it is no longer illuminated optic bundle and the blocks than when this is because part of a printed symbol or the like 50 components directly on the floor surfaces on the list 27 of the fiber optics 11 that would sit on this one of these blocks and the bundle, how layer elements are assigned, appears in it in FIG. 6 is reproduced.
It can be seen that a sufficiently high resistance for the passage of the recording head in a device according to FIG. 7 is also substantially non-conductive. 1 of the electric current in comparison with the 55 operates in the same way as in a device according to resistance of the path from the counter electrode 32 Fig. 6, so that a further discussion of by the dielectric paper 28 of the photoconductive construction or operation of a recordable layer element 19 associated recording head according to FIG. 7 seems superfluous.

1 sheet of drawings

Claims (5)

ϊ 2 (40) made of vapor-deposited or deposited glass claims: are attached to the flat surface (14). 1. Device for pictorial charging
an insulating electrophotographic recording 5 Drawing material according to an optically ''. tactile master copy, consisting of a The invention relates to a device for image i electrostatic recording head with a moderate charge of an insulating electrophotographic A plurality of graphic recording material using photoconductive conversion elements according to a exposure-controlled, in one plane, io optically scanned master copy, consisting of i charge-releasing recording electrodes, on an electrostatic recording head with! to which the master copy and the recording of a large number of photoconductive converters- j material can be moved past synchronously elements exposure-controlled, in one plane ' are, characterized in that the lying, charge-releasing recording elec- ■ Recording head between two of dielectrodes, on which the master copy and the on- ■ existing blocks (12, 13), drawing material passes synchronously with each other. of which one block (13) is transparent, can be moved. arranged with its mutually parallel. With such a device, the fibers (11) perpendicular to the recording can be, for example, a unit of an electrostatic | Has flat standing fiber optic bundle (10), act 20 reproduction or office copier machine. With its one end face (10 ') and the use of fiber optics for such end faces (12', 13 ') of the blocks (12, 13) one purpose has so far been the production of a flat surface (14 forms) and extending as a strip voltage heads relatively difficult and thus Q transversely to the direction of recording the unit itself comparatively expensive, and so far j materials by the recording head ER- 25 every fiber with photoconductive ma- was j extended, where appropriate, the flat surface material coated, which is not only difficult, laborious,; {14) using a clear dielectric but also represented an expensive process. From | Intermediate layer (40) is covered, that the end technical standpoint also has the surface (10 ') of the fiber optic bundle with counter-melting of the individual coated other insulated, as strips of block (12) composed of 30 fibers with a solder glass frit a block (13) running, a first row partial influence on the behavior and the performance I forming photoconductive layer elements (19) of the photoconductive material itself. | is covered that on the end face (13 ') of the one It was also found that on the block (13) a second row forming photoconductive recording heads manufactured in this way (USA.-compatible layer elements (20), the 35 patent 3 007 049) only with great difficulty with the photoconductive layer elements (19) that were to be sealed and easily broke, the first row aligned and through, the expansion coefficients of glass fibers, soldering glass and electrically conductive strips (possibly due to the different heat emitting recording electrodes) 18) to pairs of conductive and photoconductive material. are prevented that the photoconductive shift 40 allows a device of the type mentioned elements one row at their free now produce significantly more efficient and zeitigt · ends by connection lines (38,39) up substantially better performance if they are ' facing layered conductor rails (16, 17) according to the invention in such a way that the recording head is connected to one another in a conductive manner between two blocks made of dielectric J and that all the layer elements are exposed to material, one of which leaves the recording electrodes so with a transparent block is arranged, with its to an insulating layer (33,34) covered mutually parallel fibers perpendicular to the surface, that this fiber optic bundle standing with the free end face of the plane of the drawing on the recording electrodes is a plane plane with its one end face and the Final forms. . 50 surfaces of the blocks a flat surface forms and itself 2. Device for imagewise charging as a strip transverse to the direction of passage of the Aufnach Claim 1 characterized in that drawing material is passed through the recording head the flat surface (14) with a transparent one extends, where appropriate, the flat surface with dielectric interlayer is covered. a clear interlayer dielectric 3. Device for imagewise charging 55 is covered that the end face of the fiber optic bundle according to claim 1, characterized in that with mutually insulated, as a strip of block the electrically conductive rails or strips running in blocks, forming a first row (16,17,18) of selective coatings photoconductive layer elements is covered that on stand. the end face of one block a second row 4. Device for imagewise charging 60 forming photoconductive layer elements arranged according to one of the preceding claims, there are those with the photoconductive layer elements characterized in that the insulating of the first row are aligned and through, the charge layer (33, 34) at least partially composed of an emitting recording electrodes, which are electrically opaque Consists of glass frit. trically conductive strips are connected in pairs, 5. Device according to claim 2, characterized in that the photoconductive layer elements each have one indicates that the photoconductive and the series are non-electrical at their free ends due to connecting lines Conductive parts (19, 20; 16, 17, 18) on layer-shaped conductor rail electrodes serving as the intermediate layer are trically conductively connected to one another, and that